1 /* 2 * Copyright (c) 1998, 2016, Oracle and/or its affiliates. All rights reserved. 3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. 4 * 5 * This code is free software; you can redistribute it and/or modify it 6 * under the terms of the GNU General Public License version 2 only, as 7 * published by the Free Software Foundation. 8 * 9 * This code is distributed in the hope that it will be useful, but WITHOUT 10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 12 * version 2 for more details (a copy is included in the LICENSE file that 13 * accompanied this code). 14 * 15 * You should have received a copy of the GNU General Public License version 16 * 2 along with this work; if not, write to the Free Software Foundation, 17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 18 * 19 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 20 * or visit www.oracle.com if you need additional information or have any 21 * questions. 22 * 23 */ 24 25 // FORMS.CPP - Definitions for ADL Parser Forms Classes 26 #include "adlc.hpp" 27 28 //==============================Instructions=================================== 29 //------------------------------InstructForm----------------------------------- 30 InstructForm::InstructForm(const char *id, bool ideal_only) 31 : _ident(id), _ideal_only(ideal_only), 32 _localNames(cmpstr, hashstr, Form::arena), 33 _effects(cmpstr, hashstr, Form::arena), 34 _is_mach_constant(false), 35 _needs_constant_base(false), 36 _has_call(false) 37 { 38 _ftype = Form::INS; 39 40 _matrule = NULL; 41 _insencode = NULL; 42 _constant = NULL; 43 _is_postalloc_expand = false; 44 _opcode = NULL; 45 _size = NULL; 46 _attribs = NULL; 47 _predicate = NULL; 48 _exprule = NULL; 49 _rewrule = NULL; 50 _format = NULL; 51 _peephole = NULL; 52 _ins_pipe = NULL; 53 _uniq_idx = NULL; 54 _num_uniq = 0; 55 _cisc_spill_operand = Not_cisc_spillable;// Which operand may cisc-spill 56 _cisc_spill_alternate = NULL; // possible cisc replacement 57 _cisc_reg_mask_name = NULL; 58 _is_cisc_alternate = false; 59 _is_short_branch = false; 60 _short_branch_form = NULL; 61 _alignment = 1; 62 } 63 64 InstructForm::InstructForm(const char *id, InstructForm *instr, MatchRule *rule) 65 : _ident(id), _ideal_only(false), 66 _localNames(instr->_localNames), 67 _effects(instr->_effects), 68 _is_mach_constant(false), 69 _needs_constant_base(false), 70 _has_call(false) 71 { 72 _ftype = Form::INS; 73 74 _matrule = rule; 75 _insencode = instr->_insencode; 76 _constant = instr->_constant; 77 _is_postalloc_expand = instr->_is_postalloc_expand; 78 _opcode = instr->_opcode; 79 _size = instr->_size; 80 _attribs = instr->_attribs; 81 _predicate = instr->_predicate; 82 _exprule = instr->_exprule; 83 _rewrule = instr->_rewrule; 84 _format = instr->_format; 85 _peephole = instr->_peephole; 86 _ins_pipe = instr->_ins_pipe; 87 _uniq_idx = instr->_uniq_idx; 88 _num_uniq = instr->_num_uniq; 89 _cisc_spill_operand = Not_cisc_spillable; // Which operand may cisc-spill 90 _cisc_spill_alternate = NULL; // possible cisc replacement 91 _cisc_reg_mask_name = NULL; 92 _is_cisc_alternate = false; 93 _is_short_branch = false; 94 _short_branch_form = NULL; 95 _alignment = 1; 96 // Copy parameters 97 const char *name; 98 instr->_parameters.reset(); 99 for (; (name = instr->_parameters.iter()) != NULL;) 100 _parameters.addName(name); 101 } 102 103 InstructForm::~InstructForm() { 104 } 105 106 InstructForm *InstructForm::is_instruction() const { 107 return (InstructForm*)this; 108 } 109 110 bool InstructForm::ideal_only() const { 111 return _ideal_only; 112 } 113 114 bool InstructForm::sets_result() const { 115 return (_matrule != NULL && _matrule->sets_result()); 116 } 117 118 bool InstructForm::needs_projections() { 119 _components.reset(); 120 for( Component *comp; (comp = _components.iter()) != NULL; ) { 121 if (comp->isa(Component::KILL)) { 122 return true; 123 } 124 } 125 return false; 126 } 127 128 129 bool InstructForm::has_temps() { 130 if (_matrule) { 131 // Examine each component to see if it is a TEMP 132 _components.reset(); 133 // Skip the first component, if already handled as (SET dst (...)) 134 Component *comp = NULL; 135 if (sets_result()) comp = _components.iter(); 136 while ((comp = _components.iter()) != NULL) { 137 if (comp->isa(Component::TEMP)) { 138 return true; 139 } 140 } 141 } 142 143 return false; 144 } 145 146 uint InstructForm::num_defs_or_kills() { 147 uint defs_or_kills = 0; 148 149 _components.reset(); 150 for( Component *comp; (comp = _components.iter()) != NULL; ) { 151 if( comp->isa(Component::DEF) || comp->isa(Component::KILL) ) { 152 ++defs_or_kills; 153 } 154 } 155 156 return defs_or_kills; 157 } 158 159 // This instruction has an expand rule? 160 bool InstructForm::expands() const { 161 return ( _exprule != NULL ); 162 } 163 164 // This instruction has a late expand rule? 165 bool InstructForm::postalloc_expands() const { 166 return _is_postalloc_expand; 167 } 168 169 // This instruction has a peephole rule? 170 Peephole *InstructForm::peepholes() const { 171 return _peephole; 172 } 173 174 // This instruction has a peephole rule? 175 void InstructForm::append_peephole(Peephole *peephole) { 176 if( _peephole == NULL ) { 177 _peephole = peephole; 178 } else { 179 _peephole->append_peephole(peephole); 180 } 181 } 182 183 184 // ideal opcode enumeration 185 const char *InstructForm::ideal_Opcode( FormDict &globalNames ) const { 186 if( !_matrule ) return "Node"; // Something weird 187 // Chain rules do not really have ideal Opcodes; use their source 188 // operand ideal Opcode instead. 189 if( is_simple_chain_rule(globalNames) ) { 190 const char *src = _matrule->_rChild->_opType; 191 OperandForm *src_op = globalNames[src]->is_operand(); 192 assert( src_op, "Not operand class of chain rule" ); 193 if( !src_op->_matrule ) return "Node"; 194 return src_op->_matrule->_opType; 195 } 196 // Operand chain rules do not really have ideal Opcodes 197 if( _matrule->is_chain_rule(globalNames) ) 198 return "Node"; 199 return strcmp(_matrule->_opType,"Set") 200 ? _matrule->_opType 201 : _matrule->_rChild->_opType; 202 } 203 204 // Recursive check on all operands' match rules in my match rule 205 bool InstructForm::is_pinned(FormDict &globals) { 206 if ( ! _matrule) return false; 207 208 int index = 0; 209 if (_matrule->find_type("Goto", index)) return true; 210 if (_matrule->find_type("If", index)) return true; 211 if (_matrule->find_type("CountedLoopEnd",index)) return true; 212 if (_matrule->find_type("Return", index)) return true; 213 if (_matrule->find_type("Rethrow", index)) return true; 214 if (_matrule->find_type("TailCall", index)) return true; 215 if (_matrule->find_type("TailJump", index)) return true; 216 if (_matrule->find_type("Halt", index)) return true; 217 if (_matrule->find_type("Jump", index)) return true; 218 219 return is_parm(globals); 220 } 221 222 // Recursive check on all operands' match rules in my match rule 223 bool InstructForm::is_projection(FormDict &globals) { 224 if ( ! _matrule) return false; 225 226 int index = 0; 227 if (_matrule->find_type("Goto", index)) return true; 228 if (_matrule->find_type("Return", index)) return true; 229 if (_matrule->find_type("Rethrow", index)) return true; 230 if (_matrule->find_type("TailCall",index)) return true; 231 if (_matrule->find_type("TailJump",index)) return true; 232 if (_matrule->find_type("Halt", index)) return true; 233 234 return false; 235 } 236 237 // Recursive check on all operands' match rules in my match rule 238 bool InstructForm::is_parm(FormDict &globals) { 239 if ( ! _matrule) return false; 240 241 int index = 0; 242 if (_matrule->find_type("Parm",index)) return true; 243 244 return false; 245 } 246 247 bool InstructForm::is_ideal_negD() const { 248 return (_matrule && _matrule->_rChild && strcmp(_matrule->_rChild->_opType, "NegD") == 0); 249 } 250 251 // Return 'true' if this instruction matches an ideal 'Copy*' node 252 int InstructForm::is_ideal_copy() const { 253 return _matrule ? _matrule->is_ideal_copy() : 0; 254 } 255 256 // Return 'true' if this instruction is too complex to rematerialize. 257 int InstructForm::is_expensive() const { 258 // We can prove it is cheap if it has an empty encoding. 259 // This helps with platform-specific nops like ThreadLocal and RoundFloat. 260 if (is_empty_encoding()) 261 return 0; 262 263 if (is_tls_instruction()) 264 return 1; 265 266 if (_matrule == NULL) return 0; 267 268 return _matrule->is_expensive(); 269 } 270 271 // Has an empty encoding if _size is a constant zero or there 272 // are no ins_encode tokens. 273 int InstructForm::is_empty_encoding() const { 274 if (_insencode != NULL) { 275 _insencode->reset(); 276 if (_insencode->encode_class_iter() == NULL) { 277 return 1; 278 } 279 } 280 if (_size != NULL && strcmp(_size, "0") == 0) { 281 return 1; 282 } 283 return 0; 284 } 285 286 int InstructForm::is_tls_instruction() const { 287 if (_ident != NULL && 288 ( ! strcmp( _ident,"tlsLoadP") || 289 ! strncmp(_ident,"tlsLoadP_",9)) ) { 290 return 1; 291 } 292 293 if (_matrule != NULL && _insencode != NULL) { 294 const char* opType = _matrule->_opType; 295 if (strcmp(opType, "Set")==0) 296 opType = _matrule->_rChild->_opType; 297 if (strcmp(opType,"ThreadLocal")==0) { 298 fprintf(stderr, "Warning: ThreadLocal instruction %s should be named 'tlsLoadP_*'\n", 299 (_ident == NULL ? "NULL" : _ident)); 300 return 1; 301 } 302 } 303 304 return 0; 305 } 306 307 308 // Return 'true' if this instruction matches an ideal 'If' node 309 bool InstructForm::is_ideal_if() const { 310 if( _matrule == NULL ) return false; 311 312 return _matrule->is_ideal_if(); 313 } 314 315 // Return 'true' if this instruction matches an ideal 'FastLock' node 316 bool InstructForm::is_ideal_fastlock() const { 317 if( _matrule == NULL ) return false; 318 319 return _matrule->is_ideal_fastlock(); 320 } 321 322 // Return 'true' if this instruction matches an ideal 'MemBarXXX' node 323 bool InstructForm::is_ideal_membar() const { 324 if( _matrule == NULL ) return false; 325 326 return _matrule->is_ideal_membar(); 327 } 328 329 // Return 'true' if this instruction matches an ideal 'LoadPC' node 330 bool InstructForm::is_ideal_loadPC() const { 331 if( _matrule == NULL ) return false; 332 333 return _matrule->is_ideal_loadPC(); 334 } 335 336 // Return 'true' if this instruction matches an ideal 'Box' node 337 bool InstructForm::is_ideal_box() const { 338 if( _matrule == NULL ) return false; 339 340 return _matrule->is_ideal_box(); 341 } 342 343 // Return 'true' if this instruction matches an ideal 'Goto' node 344 bool InstructForm::is_ideal_goto() const { 345 if( _matrule == NULL ) return false; 346 347 return _matrule->is_ideal_goto(); 348 } 349 350 // Return 'true' if this instruction matches an ideal 'Jump' node 351 bool InstructForm::is_ideal_jump() const { 352 if( _matrule == NULL ) return false; 353 354 return _matrule->is_ideal_jump(); 355 } 356 357 // Return 'true' if instruction matches ideal 'If' | 'Goto' | 'CountedLoopEnd' 358 bool InstructForm::is_ideal_branch() const { 359 if( _matrule == NULL ) return false; 360 361 return _matrule->is_ideal_if() || _matrule->is_ideal_goto(); 362 } 363 364 365 // Return 'true' if this instruction matches an ideal 'Return' node 366 bool InstructForm::is_ideal_return() const { 367 if( _matrule == NULL ) return false; 368 369 // Check MatchRule to see if the first entry is the ideal "Return" node 370 int index = 0; 371 if (_matrule->find_type("Return",index)) return true; 372 if (_matrule->find_type("Rethrow",index)) return true; 373 if (_matrule->find_type("TailCall",index)) return true; 374 if (_matrule->find_type("TailJump",index)) return true; 375 376 return false; 377 } 378 379 // Return 'true' if this instruction matches an ideal 'Halt' node 380 bool InstructForm::is_ideal_halt() const { 381 int index = 0; 382 return _matrule && _matrule->find_type("Halt",index); 383 } 384 385 // Return 'true' if this instruction matches an ideal 'SafePoint' node 386 bool InstructForm::is_ideal_safepoint() const { 387 int index = 0; 388 return _matrule && _matrule->find_type("SafePoint",index); 389 } 390 391 // Return 'true' if this instruction matches an ideal 'Nop' node 392 bool InstructForm::is_ideal_nop() const { 393 return _ident && _ident[0] == 'N' && _ident[1] == 'o' && _ident[2] == 'p' && _ident[3] == '_'; 394 } 395 396 bool InstructForm::is_ideal_control() const { 397 if ( ! _matrule) return false; 398 399 return is_ideal_return() || is_ideal_branch() || _matrule->is_ideal_jump() || is_ideal_halt(); 400 } 401 402 // Return 'true' if this instruction matches an ideal 'Call' node 403 Form::CallType InstructForm::is_ideal_call() const { 404 if( _matrule == NULL ) return Form::invalid_type; 405 406 // Check MatchRule to see if the first entry is the ideal "Call" node 407 int idx = 0; 408 if(_matrule->find_type("CallStaticJava",idx)) return Form::JAVA_STATIC; 409 idx = 0; 410 if(_matrule->find_type("Lock",idx)) return Form::JAVA_STATIC; 411 idx = 0; 412 if(_matrule->find_type("Unlock",idx)) return Form::JAVA_STATIC; 413 idx = 0; 414 if(_matrule->find_type("CallDynamicJava",idx)) return Form::JAVA_DYNAMIC; 415 idx = 0; 416 if(_matrule->find_type("CallRuntime",idx)) return Form::JAVA_RUNTIME; 417 idx = 0; 418 if(_matrule->find_type("CallLeaf",idx)) return Form::JAVA_LEAF; 419 idx = 0; 420 if(_matrule->find_type("CallLeafNoFP",idx)) return Form::JAVA_LEAF; 421 idx = 0; 422 423 return Form::invalid_type; 424 } 425 426 // Return 'true' if this instruction matches an ideal 'Load?' node 427 Form::DataType InstructForm::is_ideal_load() const { 428 if( _matrule == NULL ) return Form::none; 429 430 return _matrule->is_ideal_load(); 431 } 432 433 // Return 'true' if this instruction matches an ideal 'LoadKlass' node 434 bool InstructForm::skip_antidep_check() const { 435 if( _matrule == NULL ) return false; 436 437 return _matrule->skip_antidep_check(); 438 } 439 440 // Return 'true' if this instruction matches an ideal 'Load?' node 441 Form::DataType InstructForm::is_ideal_store() const { 442 if( _matrule == NULL ) return Form::none; 443 444 return _matrule->is_ideal_store(); 445 } 446 447 // Return 'true' if this instruction matches an ideal vector node 448 bool InstructForm::is_vector() const { 449 if( _matrule == NULL ) return false; 450 451 return _matrule->is_vector(); 452 } 453 454 455 // Return the input register that must match the output register 456 // If this is not required, return 0 457 uint InstructForm::two_address(FormDict &globals) { 458 uint matching_input = 0; 459 if(_components.count() == 0) return 0; 460 461 _components.reset(); 462 Component *comp = _components.iter(); 463 // Check if there is a DEF 464 if( comp->isa(Component::DEF) ) { 465 // Check that this is a register 466 const char *def_type = comp->_type; 467 const Form *form = globals[def_type]; 468 OperandForm *op = form->is_operand(); 469 if( op ) { 470 if( op->constrained_reg_class() != NULL && 471 op->interface_type(globals) == Form::register_interface ) { 472 // Remember the local name for equality test later 473 const char *def_name = comp->_name; 474 // Check if a component has the same name and is a USE 475 do { 476 if( comp->isa(Component::USE) && strcmp(comp->_name,def_name)==0 ) { 477 return operand_position_format(def_name); 478 } 479 } while( (comp = _components.iter()) != NULL); 480 } 481 } 482 } 483 484 return 0; 485 } 486 487 488 // when chaining a constant to an instruction, returns 'true' and sets opType 489 Form::DataType InstructForm::is_chain_of_constant(FormDict &globals) { 490 const char *dummy = NULL; 491 const char *dummy2 = NULL; 492 return is_chain_of_constant(globals, dummy, dummy2); 493 } 494 Form::DataType InstructForm::is_chain_of_constant(FormDict &globals, 495 const char * &opTypeParam) { 496 const char *result = NULL; 497 498 return is_chain_of_constant(globals, opTypeParam, result); 499 } 500 501 Form::DataType InstructForm::is_chain_of_constant(FormDict &globals, 502 const char * &opTypeParam, const char * &resultParam) { 503 Form::DataType data_type = Form::none; 504 if ( ! _matrule) return data_type; 505 506 // !!!!! 507 // The source of the chain rule is 'position = 1' 508 uint position = 1; 509 const char *result = NULL; 510 const char *name = NULL; 511 const char *opType = NULL; 512 // Here base_operand is looking for an ideal type to be returned (opType). 513 if ( _matrule->is_chain_rule(globals) 514 && _matrule->base_operand(position, globals, result, name, opType) ) { 515 data_type = ideal_to_const_type(opType); 516 517 // if it isn't an ideal constant type, just return 518 if ( data_type == Form::none ) return data_type; 519 520 // Ideal constant types also adjust the opType parameter. 521 resultParam = result; 522 opTypeParam = opType; 523 return data_type; 524 } 525 526 return data_type; 527 } 528 529 // Check if a simple chain rule 530 bool InstructForm::is_simple_chain_rule(FormDict &globals) const { 531 if( _matrule && _matrule->sets_result() 532 && _matrule->_rChild->_lChild == NULL 533 && globals[_matrule->_rChild->_opType] 534 && globals[_matrule->_rChild->_opType]->is_opclass() ) { 535 return true; 536 } 537 return false; 538 } 539 540 // check for structural rematerialization 541 bool InstructForm::rematerialize(FormDict &globals, RegisterForm *registers ) { 542 bool rematerialize = false; 543 544 Form::DataType data_type = is_chain_of_constant(globals); 545 if( data_type != Form::none ) 546 rematerialize = true; 547 548 // Constants 549 if( _components.count() == 1 && _components[0]->is(Component::USE_DEF) ) 550 rematerialize = true; 551 552 // Pseudo-constants (values easily available to the runtime) 553 if (is_empty_encoding() && is_tls_instruction()) 554 rematerialize = true; 555 556 // 1-input, 1-output, such as copies or increments. 557 if( _components.count() == 2 && 558 _components[0]->is(Component::DEF) && 559 _components[1]->isa(Component::USE) ) 560 rematerialize = true; 561 562 // Check for an ideal 'Load?' and eliminate rematerialize option 563 if ( is_ideal_load() != Form::none || // Ideal load? Do not rematerialize 564 is_ideal_copy() != Form::none || // Ideal copy? Do not rematerialize 565 is_expensive() != Form::none) { // Expensive? Do not rematerialize 566 rematerialize = false; 567 } 568 569 // Always rematerialize the flags. They are more expensive to save & 570 // restore than to recompute (and possibly spill the compare's inputs). 571 if( _components.count() >= 1 ) { 572 Component *c = _components[0]; 573 const Form *form = globals[c->_type]; 574 OperandForm *opform = form->is_operand(); 575 if( opform ) { 576 // Avoid the special stack_slots register classes 577 const char *rc_name = opform->constrained_reg_class(); 578 if( rc_name ) { 579 if( strcmp(rc_name,"stack_slots") ) { 580 // Check for ideal_type of RegFlags 581 const char *type = opform->ideal_type( globals, registers ); 582 if( (type != NULL) && !strcmp(type, "RegFlags") ) 583 rematerialize = true; 584 } else 585 rematerialize = false; // Do not rematerialize things target stk 586 } 587 } 588 } 589 590 return rematerialize; 591 } 592 593 // loads from memory, so must check for anti-dependence 594 bool InstructForm::needs_anti_dependence_check(FormDict &globals) const { 595 if ( skip_antidep_check() ) return false; 596 597 // Machine independent loads must be checked for anti-dependences 598 if( is_ideal_load() != Form::none ) return true; 599 600 // !!!!! !!!!! !!!!! 601 // TEMPORARY 602 // if( is_simple_chain_rule(globals) ) return false; 603 604 // String.(compareTo/equals/indexOf) and Arrays.equals use many memorys edges, 605 // but writes none 606 if( _matrule && _matrule->_rChild && 607 ( strcmp(_matrule->_rChild->_opType,"StrComp" )==0 || 608 strcmp(_matrule->_rChild->_opType,"StrEquals" )==0 || 609 strcmp(_matrule->_rChild->_opType,"StrIndexOf" )==0 || 610 strcmp(_matrule->_rChild->_opType,"StrIndexOfChar" )==0 || 611 strcmp(_matrule->_rChild->_opType,"HasNegatives" )==0 || 612 strcmp(_matrule->_rChild->_opType,"AryEq" )==0 )) 613 return true; 614 615 // Check if instruction has a USE of a memory operand class, but no defs 616 bool USE_of_memory = false; 617 bool DEF_of_memory = false; 618 Component *comp = NULL; 619 ComponentList &components = (ComponentList &)_components; 620 621 components.reset(); 622 while( (comp = components.iter()) != NULL ) { 623 const Form *form = globals[comp->_type]; 624 if( !form ) continue; 625 OpClassForm *op = form->is_opclass(); 626 if( !op ) continue; 627 if( form->interface_type(globals) == Form::memory_interface ) { 628 if( comp->isa(Component::USE) ) USE_of_memory = true; 629 if( comp->isa(Component::DEF) ) { 630 OperandForm *oper = form->is_operand(); 631 if( oper && oper->is_user_name_for_sReg() ) { 632 // Stack slots are unaliased memory handled by allocator 633 oper = oper; // debug stopping point !!!!! 634 } else { 635 DEF_of_memory = true; 636 } 637 } 638 } 639 } 640 return (USE_of_memory && !DEF_of_memory); 641 } 642 643 644 bool InstructForm::is_wide_memory_kill(FormDict &globals) const { 645 if( _matrule == NULL ) return false; 646 if( !_matrule->_opType ) return false; 647 648 if( strcmp(_matrule->_opType,"MemBarRelease") == 0 ) return true; 649 if( strcmp(_matrule->_opType,"MemBarAcquire") == 0 ) return true; 650 if( strcmp(_matrule->_opType,"MemBarReleaseLock") == 0 ) return true; 651 if( strcmp(_matrule->_opType,"MemBarAcquireLock") == 0 ) return true; 652 if( strcmp(_matrule->_opType,"MemBarStoreStore") == 0 ) return true; 653 if( strcmp(_matrule->_opType,"MemBarVolatile") == 0 ) return true; 654 if( strcmp(_matrule->_opType,"StoreFence") == 0 ) return true; 655 if( strcmp(_matrule->_opType,"LoadFence") == 0 ) return true; 656 657 return false; 658 } 659 660 int InstructForm::memory_operand(FormDict &globals) const { 661 // Machine independent loads must be checked for anti-dependences 662 // Check if instruction has a USE of a memory operand class, or a def. 663 int USE_of_memory = 0; 664 int DEF_of_memory = 0; 665 const char* last_memory_DEF = NULL; // to test DEF/USE pairing in asserts 666 const char* last_memory_USE = NULL; 667 Component *unique = NULL; 668 Component *comp = NULL; 669 ComponentList &components = (ComponentList &)_components; 670 671 components.reset(); 672 while( (comp = components.iter()) != NULL ) { 673 const Form *form = globals[comp->_type]; 674 if( !form ) continue; 675 OpClassForm *op = form->is_opclass(); 676 if( !op ) continue; 677 if( op->stack_slots_only(globals) ) continue; 678 if( form->interface_type(globals) == Form::memory_interface ) { 679 if( comp->isa(Component::DEF) ) { 680 last_memory_DEF = comp->_name; 681 DEF_of_memory++; 682 unique = comp; 683 } else if( comp->isa(Component::USE) ) { 684 if( last_memory_DEF != NULL ) { 685 assert(0 == strcmp(last_memory_DEF, comp->_name), "every memory DEF is followed by a USE of the same name"); 686 last_memory_DEF = NULL; 687 } 688 // Handles same memory being used multiple times in the case of BMI1 instructions. 689 if (last_memory_USE != NULL) { 690 if (strcmp(comp->_name, last_memory_USE) != 0) { 691 USE_of_memory++; 692 } 693 } else { 694 USE_of_memory++; 695 } 696 last_memory_USE = comp->_name; 697 698 if (DEF_of_memory == 0) // defs take precedence 699 unique = comp; 700 } else { 701 assert(last_memory_DEF == NULL, "unpaired memory DEF"); 702 } 703 } 704 } 705 assert(last_memory_DEF == NULL, "unpaired memory DEF"); 706 assert(USE_of_memory >= DEF_of_memory, "unpaired memory DEF"); 707 USE_of_memory -= DEF_of_memory; // treat paired DEF/USE as one occurrence 708 if( (USE_of_memory + DEF_of_memory) > 0 ) { 709 if( is_simple_chain_rule(globals) ) { 710 //fprintf(stderr, "Warning: chain rule is not really a memory user.\n"); 711 //((InstructForm*)this)->dump(); 712 // Preceding code prints nothing on sparc and these insns on intel: 713 // leaP8 leaP32 leaPIdxOff leaPIdxScale leaPIdxScaleOff leaP8 leaP32 714 // leaPIdxOff leaPIdxScale leaPIdxScaleOff 715 return NO_MEMORY_OPERAND; 716 } 717 718 if( DEF_of_memory == 1 ) { 719 assert(unique != NULL, ""); 720 if( USE_of_memory == 0 ) { 721 // unique def, no uses 722 } else { 723 // // unique def, some uses 724 // // must return bottom unless all uses match def 725 // unique = NULL; 726 #ifdef S390 727 // This case is important for move instructions on s390x. 728 // On other platforms (e.g. x86), all uses always match the def. 729 unique = NULL; 730 #endif 731 } 732 } else if( DEF_of_memory > 0 ) { 733 // multiple defs, don't care about uses 734 unique = NULL; 735 } else if( USE_of_memory == 1) { 736 // unique use, no defs 737 assert(unique != NULL, ""); 738 } else if( USE_of_memory > 0 ) { 739 // multiple uses, no defs 740 unique = NULL; 741 } else { 742 assert(false, "bad case analysis"); 743 } 744 // process the unique DEF or USE, if there is one 745 if( unique == NULL ) { 746 return MANY_MEMORY_OPERANDS; 747 } else { 748 int pos = components.operand_position(unique->_name); 749 if( unique->isa(Component::DEF) ) { 750 pos += 1; // get corresponding USE from DEF 751 } 752 assert(pos >= 1, "I was just looking at it!"); 753 return pos; 754 } 755 } 756 757 // missed the memory op?? 758 if( true ) { // %%% should not be necessary 759 if( is_ideal_store() != Form::none ) { 760 fprintf(stderr, "Warning: cannot find memory opnd in instr.\n"); 761 ((InstructForm*)this)->dump(); 762 // pretend it has multiple defs and uses 763 return MANY_MEMORY_OPERANDS; 764 } 765 if( is_ideal_load() != Form::none ) { 766 fprintf(stderr, "Warning: cannot find memory opnd in instr.\n"); 767 ((InstructForm*)this)->dump(); 768 // pretend it has multiple uses and no defs 769 return MANY_MEMORY_OPERANDS; 770 } 771 } 772 773 return NO_MEMORY_OPERAND; 774 } 775 776 777 // This instruction captures the machine-independent bottom_type 778 // Expected use is for pointer vs oop determination for LoadP 779 bool InstructForm::captures_bottom_type(FormDict &globals) const { 780 if (_matrule && _matrule->_rChild && 781 (!strcmp(_matrule->_rChild->_opType,"CastPP") || // new result type 782 !strcmp(_matrule->_rChild->_opType,"CastX2P") || // new result type 783 !strcmp(_matrule->_rChild->_opType,"DecodeN") || 784 !strcmp(_matrule->_rChild->_opType,"EncodeP") || 785 !strcmp(_matrule->_rChild->_opType,"DecodeNKlass") || 786 !strcmp(_matrule->_rChild->_opType,"EncodePKlass") || 787 !strcmp(_matrule->_rChild->_opType,"LoadN") || 788 !strcmp(_matrule->_rChild->_opType,"LoadNKlass") || 789 !strcmp(_matrule->_rChild->_opType,"CreateEx") || // type of exception 790 !strcmp(_matrule->_rChild->_opType,"CheckCastPP") || 791 !strcmp(_matrule->_rChild->_opType,"GetAndSetP") || 792 !strcmp(_matrule->_rChild->_opType,"GetAndSetN") || 793 !strcmp(_matrule->_rChild->_opType,"CompareAndExchangeP") || 794 !strcmp(_matrule->_rChild->_opType,"CompareAndExchangeN"))) return true; 795 else if ( is_ideal_load() == Form::idealP ) return true; 796 else if ( is_ideal_store() != Form::none ) return true; 797 798 if (needs_base_oop_edge(globals)) return true; 799 800 if (is_vector()) return true; 801 if (is_mach_constant()) return true; 802 803 return false; 804 } 805 806 807 // Access instr_cost attribute or return NULL. 808 const char* InstructForm::cost() { 809 for (Attribute* cur = _attribs; cur != NULL; cur = (Attribute*)cur->_next) { 810 if( strcmp(cur->_ident,AttributeForm::_ins_cost) == 0 ) { 811 return cur->_val; 812 } 813 } 814 return NULL; 815 } 816 817 // Return count of top-level operands. 818 uint InstructForm::num_opnds() { 819 int num_opnds = _components.num_operands(); 820 821 // Need special handling for matching some ideal nodes 822 // i.e. Matching a return node 823 /* 824 if( _matrule ) { 825 if( strcmp(_matrule->_opType,"Return" )==0 || 826 strcmp(_matrule->_opType,"Halt" )==0 ) 827 return 3; 828 } 829 */ 830 return num_opnds; 831 } 832 833 const char* InstructForm::opnd_ident(int idx) { 834 return _components.at(idx)->_name; 835 } 836 837 const char* InstructForm::unique_opnd_ident(uint idx) { 838 uint i; 839 for (i = 1; i < num_opnds(); ++i) { 840 if (unique_opnds_idx(i) == idx) { 841 break; 842 } 843 } 844 return (_components.at(i) != NULL) ? _components.at(i)->_name : ""; 845 } 846 847 // Return count of unmatched operands. 848 uint InstructForm::num_post_match_opnds() { 849 uint num_post_match_opnds = _components.count(); 850 uint num_match_opnds = _components.match_count(); 851 num_post_match_opnds = num_post_match_opnds - num_match_opnds; 852 853 return num_post_match_opnds; 854 } 855 856 // Return the number of leaves below this complex operand 857 uint InstructForm::num_consts(FormDict &globals) const { 858 if ( ! _matrule) return 0; 859 860 // This is a recursive invocation on all operands in the matchrule 861 return _matrule->num_consts(globals); 862 } 863 864 // Constants in match rule with specified type 865 uint InstructForm::num_consts(FormDict &globals, Form::DataType type) const { 866 if ( ! _matrule) return 0; 867 868 // This is a recursive invocation on all operands in the matchrule 869 return _matrule->num_consts(globals, type); 870 } 871 872 873 // Return the register class associated with 'leaf'. 874 const char *InstructForm::out_reg_class(FormDict &globals) { 875 assert( false, "InstructForm::out_reg_class(FormDict &globals); Not Implemented"); 876 877 return NULL; 878 } 879 880 881 882 // Lookup the starting position of inputs we are interested in wrt. ideal nodes 883 uint InstructForm::oper_input_base(FormDict &globals) { 884 if( !_matrule ) return 1; // Skip control for most nodes 885 886 // Need special handling for matching some ideal nodes 887 // i.e. Matching a return node 888 if( strcmp(_matrule->_opType,"Return" )==0 || 889 strcmp(_matrule->_opType,"Rethrow" )==0 || 890 strcmp(_matrule->_opType,"TailCall" )==0 || 891 strcmp(_matrule->_opType,"TailJump" )==0 || 892 strcmp(_matrule->_opType,"SafePoint" )==0 || 893 strcmp(_matrule->_opType,"Halt" )==0 ) 894 return AdlcVMDeps::Parms; // Skip the machine-state edges 895 896 if( _matrule->_rChild && 897 ( strcmp(_matrule->_rChild->_opType,"AryEq" )==0 || 898 strcmp(_matrule->_rChild->_opType,"StrComp" )==0 || 899 strcmp(_matrule->_rChild->_opType,"StrEquals" )==0 || 900 strcmp(_matrule->_rChild->_opType,"StrInflatedCopy" )==0 || 901 strcmp(_matrule->_rChild->_opType,"StrCompressedCopy" )==0 || 902 strcmp(_matrule->_rChild->_opType,"StrIndexOf")==0 || 903 strcmp(_matrule->_rChild->_opType,"StrIndexOfChar")==0 || 904 strcmp(_matrule->_rChild->_opType,"HasNegatives")==0 || 905 strcmp(_matrule->_rChild->_opType,"EncodeISOArray")==0)) { 906 // String.(compareTo/equals/indexOf) and Arrays.equals 907 // and sun.nio.cs.iso8859_1$Encoder.EncodeISOArray 908 // take 1 control and 1 memory edges. 909 // Also String.(compressedCopy/inflatedCopy). 910 return 2; 911 } 912 913 // Check for handling of 'Memory' input/edge in the ideal world. 914 // The AD file writer is shielded from knowledge of these edges. 915 int base = 1; // Skip control 916 base += _matrule->needs_ideal_memory_edge(globals); 917 918 // Also skip the base-oop value for uses of derived oops. 919 // The AD file writer is shielded from knowledge of these edges. 920 base += needs_base_oop_edge(globals); 921 922 return base; 923 } 924 925 // This function determines the order of the MachOper in _opnds[] 926 // by writing the operand names into the _components list. 927 // 928 // Implementation does not modify state of internal structures 929 void InstructForm::build_components() { 930 // Add top-level operands to the components 931 if (_matrule) _matrule->append_components(_localNames, _components); 932 933 // Add parameters that "do not appear in match rule". 934 bool has_temp = false; 935 const char *name; 936 const char *kill_name = NULL; 937 for (_parameters.reset(); (name = _parameters.iter()) != NULL;) { 938 OperandForm *opForm = (OperandForm*)_localNames[name]; 939 940 Effect* e = NULL; 941 { 942 const Form* form = _effects[name]; 943 e = form ? form->is_effect() : NULL; 944 } 945 946 if (e != NULL) { 947 has_temp |= e->is(Component::TEMP); 948 949 // KILLs must be declared after any TEMPs because TEMPs are real 950 // uses so their operand numbering must directly follow the real 951 // inputs from the match rule. Fixing the numbering seems 952 // complex so simply enforce the restriction during parse. 953 if (kill_name != NULL && 954 e->isa(Component::TEMP) && !e->isa(Component::DEF)) { 955 OperandForm* kill = (OperandForm*)_localNames[kill_name]; 956 globalAD->syntax_err(_linenum, "%s: %s %s must be at the end of the argument list\n", 957 _ident, kill->_ident, kill_name); 958 } else if (e->isa(Component::KILL) && !e->isa(Component::USE)) { 959 kill_name = name; 960 } 961 } 962 963 const Component *component = _components.search(name); 964 if ( component == NULL ) { 965 if (e) { 966 _components.insert(name, opForm->_ident, e->_use_def, false); 967 component = _components.search(name); 968 if (component->isa(Component::USE) && !component->isa(Component::TEMP) && _matrule) { 969 const Form *form = globalAD->globalNames()[component->_type]; 970 assert( form, "component type must be a defined form"); 971 OperandForm *op = form->is_operand(); 972 if (op->_interface && op->_interface->is_RegInterface()) { 973 globalAD->syntax_err(_linenum, "%s: illegal USE of non-input: %s %s\n", 974 _ident, opForm->_ident, name); 975 } 976 } 977 } else { 978 // This would be a nice warning but it triggers in a few places in a benign way 979 // if (_matrule != NULL && !expands()) { 980 // globalAD->syntax_err(_linenum, "%s: %s %s not mentioned in effect or match rule\n", 981 // _ident, opForm->_ident, name); 982 // } 983 _components.insert(name, opForm->_ident, Component::INVALID, false); 984 } 985 } 986 else if (e) { 987 // Component was found in the list 988 // Check if there is a new effect that requires an extra component. 989 // This happens when adding 'USE' to a component that is not yet one. 990 if ((!component->isa( Component::USE) && ((e->_use_def & Component::USE) != 0))) { 991 if (component->isa(Component::USE) && _matrule) { 992 const Form *form = globalAD->globalNames()[component->_type]; 993 assert( form, "component type must be a defined form"); 994 OperandForm *op = form->is_operand(); 995 if (op->_interface && op->_interface->is_RegInterface()) { 996 globalAD->syntax_err(_linenum, "%s: illegal USE of non-input: %s %s\n", 997 _ident, opForm->_ident, name); 998 } 999 } 1000 _components.insert(name, opForm->_ident, e->_use_def, false); 1001 } else { 1002 Component *comp = (Component*)component; 1003 comp->promote_use_def_info(e->_use_def); 1004 } 1005 // Component positions are zero based. 1006 int pos = _components.operand_position(name); 1007 assert( ! (component->isa(Component::DEF) && (pos >= 1)), 1008 "Component::DEF can only occur in the first position"); 1009 } 1010 } 1011 1012 // Resolving the interactions between expand rules and TEMPs would 1013 // be complex so simply disallow it. 1014 if (_matrule == NULL && has_temp) { 1015 globalAD->syntax_err(_linenum, "%s: TEMPs without match rule isn't supported\n", _ident); 1016 } 1017 1018 return; 1019 } 1020 1021 // Return zero-based position in component list; -1 if not in list. 1022 int InstructForm::operand_position(const char *name, int usedef) { 1023 return unique_opnds_idx(_components.operand_position(name, usedef, this)); 1024 } 1025 1026 int InstructForm::operand_position_format(const char *name) { 1027 return unique_opnds_idx(_components.operand_position_format(name, this)); 1028 } 1029 1030 // Return zero-based position in component list; -1 if not in list. 1031 int InstructForm::label_position() { 1032 return unique_opnds_idx(_components.label_position()); 1033 } 1034 1035 int InstructForm::method_position() { 1036 return unique_opnds_idx(_components.method_position()); 1037 } 1038 1039 // Return number of relocation entries needed for this instruction. 1040 uint InstructForm::reloc(FormDict &globals) { 1041 uint reloc_entries = 0; 1042 // Check for "Call" nodes 1043 if ( is_ideal_call() ) ++reloc_entries; 1044 if ( is_ideal_return() ) ++reloc_entries; 1045 if ( is_ideal_safepoint() ) ++reloc_entries; 1046 1047 1048 // Check if operands MAYBE oop pointers, by checking for ConP elements 1049 // Proceed through the leaves of the match-tree and check for ConPs 1050 if ( _matrule != NULL ) { 1051 uint position = 0; 1052 const char *result = NULL; 1053 const char *name = NULL; 1054 const char *opType = NULL; 1055 while (_matrule->base_operand(position, globals, result, name, opType)) { 1056 if ( strcmp(opType,"ConP") == 0 ) { 1057 #ifdef SPARC 1058 reloc_entries += 2; // 1 for sethi + 1 for setlo 1059 #else 1060 ++reloc_entries; 1061 #endif 1062 } 1063 ++position; 1064 } 1065 } 1066 1067 // Above is only a conservative estimate 1068 // because it did not check contents of operand classes. 1069 // !!!!! !!!!! 1070 // Add 1 to reloc info for each operand class in the component list. 1071 Component *comp; 1072 _components.reset(); 1073 while ( (comp = _components.iter()) != NULL ) { 1074 const Form *form = globals[comp->_type]; 1075 assert( form, "Did not find component's type in global names"); 1076 const OpClassForm *opc = form->is_opclass(); 1077 const OperandForm *oper = form->is_operand(); 1078 if ( opc && (oper == NULL) ) { 1079 ++reloc_entries; 1080 } else if ( oper ) { 1081 // floats and doubles loaded out of method's constant pool require reloc info 1082 Form::DataType type = oper->is_base_constant(globals); 1083 if ( (type == Form::idealF) || (type == Form::idealD) ) { 1084 ++reloc_entries; 1085 } 1086 } 1087 } 1088 1089 // Float and Double constants may come from the CodeBuffer table 1090 // and require relocatable addresses for access 1091 // !!!!! 1092 // Check for any component being an immediate float or double. 1093 Form::DataType data_type = is_chain_of_constant(globals); 1094 if( data_type==idealD || data_type==idealF ) { 1095 #ifdef SPARC 1096 // sparc required more relocation entries for floating constants 1097 // (expires 9/98) 1098 reloc_entries += 6; 1099 #else 1100 reloc_entries++; 1101 #endif 1102 } 1103 1104 return reloc_entries; 1105 } 1106 1107 // Utility function defined in archDesc.cpp 1108 extern bool is_def(int usedef); 1109 1110 // Return the result of reducing an instruction 1111 const char *InstructForm::reduce_result() { 1112 const char* result = "Universe"; // default 1113 _components.reset(); 1114 Component *comp = _components.iter(); 1115 if (comp != NULL && comp->isa(Component::DEF)) { 1116 result = comp->_type; 1117 // Override this if the rule is a store operation: 1118 if (_matrule && _matrule->_rChild && 1119 is_store_to_memory(_matrule->_rChild->_opType)) 1120 result = "Universe"; 1121 } 1122 return result; 1123 } 1124 1125 // Return the name of the operand on the right hand side of the binary match 1126 // Return NULL if there is no right hand side 1127 const char *InstructForm::reduce_right(FormDict &globals) const { 1128 if( _matrule == NULL ) return NULL; 1129 return _matrule->reduce_right(globals); 1130 } 1131 1132 // Similar for left 1133 const char *InstructForm::reduce_left(FormDict &globals) const { 1134 if( _matrule == NULL ) return NULL; 1135 return _matrule->reduce_left(globals); 1136 } 1137 1138 1139 // Base class for this instruction, MachNode except for calls 1140 const char *InstructForm::mach_base_class(FormDict &globals) const { 1141 if( is_ideal_call() == Form::JAVA_STATIC ) { 1142 return "MachCallStaticJavaNode"; 1143 } 1144 else if( is_ideal_call() == Form::JAVA_DYNAMIC ) { 1145 return "MachCallDynamicJavaNode"; 1146 } 1147 else if( is_ideal_call() == Form::JAVA_RUNTIME ) { 1148 return "MachCallRuntimeNode"; 1149 } 1150 else if( is_ideal_call() == Form::JAVA_LEAF ) { 1151 return "MachCallLeafNode"; 1152 } 1153 else if (is_ideal_return()) { 1154 return "MachReturnNode"; 1155 } 1156 else if (is_ideal_halt()) { 1157 return "MachHaltNode"; 1158 } 1159 else if (is_ideal_safepoint()) { 1160 return "MachSafePointNode"; 1161 } 1162 else if (is_ideal_if()) { 1163 return "MachIfNode"; 1164 } 1165 else if (is_ideal_goto()) { 1166 return "MachGotoNode"; 1167 } 1168 else if (is_ideal_fastlock()) { 1169 return "MachFastLockNode"; 1170 } 1171 else if (is_ideal_nop()) { 1172 return "MachNopNode"; 1173 } 1174 else if (is_ideal_jump()) { 1175 return "MachJumpNode"; 1176 } 1177 else if (is_mach_constant()) { 1178 return "MachConstantNode"; 1179 } 1180 else if (captures_bottom_type(globals)) { 1181 return "MachTypeNode"; 1182 } else { 1183 return "MachNode"; 1184 } 1185 assert( false, "ShouldNotReachHere()"); 1186 return NULL; 1187 } 1188 1189 // Compare the instruction predicates for textual equality 1190 bool equivalent_predicates( const InstructForm *instr1, const InstructForm *instr2 ) { 1191 const Predicate *pred1 = instr1->_predicate; 1192 const Predicate *pred2 = instr2->_predicate; 1193 if( pred1 == NULL && pred2 == NULL ) { 1194 // no predicates means they are identical 1195 return true; 1196 } 1197 if( pred1 != NULL && pred2 != NULL ) { 1198 // compare the predicates 1199 if (ADLParser::equivalent_expressions(pred1->_pred, pred2->_pred)) { 1200 return true; 1201 } 1202 } 1203 1204 return false; 1205 } 1206 1207 // Check if this instruction can cisc-spill to 'alternate' 1208 bool InstructForm::cisc_spills_to(ArchDesc &AD, InstructForm *instr) { 1209 assert( _matrule != NULL && instr->_matrule != NULL, "must have match rules"); 1210 // Do not replace if a cisc-version has been found. 1211 if( cisc_spill_operand() != Not_cisc_spillable ) return false; 1212 1213 int cisc_spill_operand = Maybe_cisc_spillable; 1214 char *result = NULL; 1215 char *result2 = NULL; 1216 const char *op_name = NULL; 1217 const char *reg_type = NULL; 1218 FormDict &globals = AD.globalNames(); 1219 cisc_spill_operand = _matrule->matchrule_cisc_spill_match(globals, AD.get_registers(), instr->_matrule, op_name, reg_type); 1220 if( (cisc_spill_operand != Not_cisc_spillable) && (op_name != NULL) && equivalent_predicates(this, instr) ) { 1221 cisc_spill_operand = operand_position(op_name, Component::USE); 1222 int def_oper = operand_position(op_name, Component::DEF); 1223 if( def_oper == NameList::Not_in_list && instr->num_opnds() == num_opnds()) { 1224 // Do not support cisc-spilling for destination operands and 1225 // make sure they have the same number of operands. 1226 _cisc_spill_alternate = instr; 1227 instr->set_cisc_alternate(true); 1228 if( AD._cisc_spill_debug ) { 1229 fprintf(stderr, "Instruction %s cisc-spills-to %s\n", _ident, instr->_ident); 1230 fprintf(stderr, " using operand %s %s at index %d\n", reg_type, op_name, cisc_spill_operand); 1231 } 1232 // Record that a stack-version of the reg_mask is needed 1233 // !!!!! 1234 OperandForm *oper = (OperandForm*)(globals[reg_type]->is_operand()); 1235 assert( oper != NULL, "cisc-spilling non operand"); 1236 const char *reg_class_name = oper->constrained_reg_class(); 1237 AD.set_stack_or_reg(reg_class_name); 1238 const char *reg_mask_name = AD.reg_mask(*oper); 1239 set_cisc_reg_mask_name(reg_mask_name); 1240 const char *stack_or_reg_mask_name = AD.stack_or_reg_mask(*oper); 1241 } else { 1242 cisc_spill_operand = Not_cisc_spillable; 1243 } 1244 } else { 1245 cisc_spill_operand = Not_cisc_spillable; 1246 } 1247 1248 set_cisc_spill_operand(cisc_spill_operand); 1249 return (cisc_spill_operand != Not_cisc_spillable); 1250 } 1251 1252 // Check to see if this instruction can be replaced with the short branch 1253 // instruction `short-branch' 1254 bool InstructForm::check_branch_variant(ArchDesc &AD, InstructForm *short_branch) { 1255 if (_matrule != NULL && 1256 this != short_branch && // Don't match myself 1257 !is_short_branch() && // Don't match another short branch variant 1258 reduce_result() != NULL && 1259 strstr(_ident, "restoreMask") == NULL && // Don't match side effects 1260 strcmp(reduce_result(), short_branch->reduce_result()) == 0 && 1261 _matrule->equivalent(AD.globalNames(), short_branch->_matrule)) { 1262 // The instructions are equivalent. 1263 1264 // Now verify that both instructions have the same parameters and 1265 // the same effects. Both branch forms should have the same inputs 1266 // and resulting projections to correctly replace a long branch node 1267 // with corresponding short branch node during code generation. 1268 1269 bool different = false; 1270 if (short_branch->_components.count() != _components.count()) { 1271 different = true; 1272 } else if (_components.count() > 0) { 1273 short_branch->_components.reset(); 1274 _components.reset(); 1275 Component *comp; 1276 while ((comp = _components.iter()) != NULL) { 1277 Component *short_comp = short_branch->_components.iter(); 1278 if (short_comp == NULL || 1279 short_comp->_type != comp->_type || 1280 short_comp->_usedef != comp->_usedef) { 1281 different = true; 1282 break; 1283 } 1284 } 1285 if (short_branch->_components.iter() != NULL) 1286 different = true; 1287 } 1288 if (different) { 1289 globalAD->syntax_err(short_branch->_linenum, "Instruction %s and its short form %s have different parameters\n", _ident, short_branch->_ident); 1290 } 1291 if (AD._adl_debug > 1 || AD._short_branch_debug) { 1292 fprintf(stderr, "Instruction %s has short form %s\n", _ident, short_branch->_ident); 1293 } 1294 _short_branch_form = short_branch; 1295 return true; 1296 } 1297 return false; 1298 } 1299 1300 1301 // --------------------------- FILE *output_routines 1302 // 1303 // Generate the format call for the replacement variable 1304 void InstructForm::rep_var_format(FILE *fp, const char *rep_var) { 1305 // Handle special constant table variables. 1306 if (strcmp(rep_var, "constanttablebase") == 0) { 1307 fprintf(fp, "char reg[128]; ra->dump_register(in(mach_constant_base_node_input()), reg);\n"); 1308 fprintf(fp, " st->print(\"%%s\", reg);\n"); 1309 return; 1310 } 1311 if (strcmp(rep_var, "constantoffset") == 0) { 1312 fprintf(fp, "st->print(\"#%%d\", constant_offset_unchecked());\n"); 1313 return; 1314 } 1315 if (strcmp(rep_var, "constantaddress") == 0) { 1316 fprintf(fp, "st->print(\"constant table base + #%%d\", constant_offset_unchecked());\n"); 1317 return; 1318 } 1319 1320 // Find replacement variable's type 1321 const Form *form = _localNames[rep_var]; 1322 if (form == NULL) { 1323 globalAD->syntax_err(_linenum, "Unknown replacement variable %s in format statement of %s.", 1324 rep_var, _ident); 1325 return; 1326 } 1327 OpClassForm *opc = form->is_opclass(); 1328 assert( opc, "replacement variable was not found in local names"); 1329 // Lookup the index position of the replacement variable 1330 int idx = operand_position_format(rep_var); 1331 if ( idx == -1 ) { 1332 globalAD->syntax_err(_linenum, "Could not find replacement variable %s in format statement of %s.\n", 1333 rep_var, _ident); 1334 assert(strcmp(opc->_ident, "label") == 0, "Unimplemented"); 1335 return; 1336 } 1337 1338 if (is_noninput_operand(idx)) { 1339 // This component isn't in the input array. Print out the static 1340 // name of the register. 1341 OperandForm* oper = form->is_operand(); 1342 if (oper != NULL && oper->is_bound_register()) { 1343 const RegDef* first = oper->get_RegClass()->find_first_elem(); 1344 fprintf(fp, " st->print_raw(\"%s\");\n", first->_regname); 1345 } else { 1346 globalAD->syntax_err(_linenum, "In %s can't find format for %s %s", _ident, opc->_ident, rep_var); 1347 } 1348 } else { 1349 // Output the format call for this operand 1350 fprintf(fp,"opnd_array(%d)->",idx); 1351 if (idx == 0) 1352 fprintf(fp,"int_format(ra, this, st); // %s\n", rep_var); 1353 else 1354 fprintf(fp,"ext_format(ra, this,idx%d, st); // %s\n", idx, rep_var ); 1355 } 1356 } 1357 1358 // Seach through operands to determine parameters unique positions. 1359 void InstructForm::set_unique_opnds() { 1360 uint* uniq_idx = NULL; 1361 uint nopnds = num_opnds(); 1362 uint num_uniq = nopnds; 1363 uint i; 1364 _uniq_idx_length = 0; 1365 if (nopnds > 0) { 1366 // Allocate index array. Worst case we're mapping from each 1367 // component back to an index and any DEF always goes at 0 so the 1368 // length of the array has to be the number of components + 1. 1369 _uniq_idx_length = _components.count() + 1; 1370 uniq_idx = (uint*) malloc(sizeof(uint) * _uniq_idx_length); 1371 for (i = 0; i < _uniq_idx_length; i++) { 1372 uniq_idx[i] = i; 1373 } 1374 } 1375 // Do it only if there is a match rule and no expand rule. With an 1376 // expand rule it is done by creating new mach node in Expand() 1377 // method. 1378 if (nopnds > 0 && _matrule != NULL && _exprule == NULL) { 1379 const char *name; 1380 uint count; 1381 bool has_dupl_use = false; 1382 1383 _parameters.reset(); 1384 while ((name = _parameters.iter()) != NULL) { 1385 count = 0; 1386 uint position = 0; 1387 uint uniq_position = 0; 1388 _components.reset(); 1389 Component *comp = NULL; 1390 if (sets_result()) { 1391 comp = _components.iter(); 1392 position++; 1393 } 1394 // The next code is copied from the method operand_position(). 1395 for (; (comp = _components.iter()) != NULL; ++position) { 1396 // When the first component is not a DEF, 1397 // leave space for the result operand! 1398 if (position==0 && (!comp->isa(Component::DEF))) { 1399 ++position; 1400 } 1401 if (strcmp(name, comp->_name) == 0) { 1402 if (++count > 1) { 1403 assert(position < _uniq_idx_length, "out of bounds"); 1404 uniq_idx[position] = uniq_position; 1405 has_dupl_use = true; 1406 } else { 1407 uniq_position = position; 1408 } 1409 } 1410 if (comp->isa(Component::DEF) && comp->isa(Component::USE)) { 1411 ++position; 1412 if (position != 1) 1413 --position; // only use two slots for the 1st USE_DEF 1414 } 1415 } 1416 } 1417 if (has_dupl_use) { 1418 for (i = 1; i < nopnds; i++) { 1419 if (i != uniq_idx[i]) { 1420 break; 1421 } 1422 } 1423 uint j = i; 1424 for (; i < nopnds; i++) { 1425 if (i == uniq_idx[i]) { 1426 uniq_idx[i] = j++; 1427 } 1428 } 1429 num_uniq = j; 1430 } 1431 } 1432 _uniq_idx = uniq_idx; 1433 _num_uniq = num_uniq; 1434 } 1435 1436 // Generate index values needed for determining the operand position 1437 void InstructForm::index_temps(FILE *fp, FormDict &globals, const char *prefix, const char *receiver) { 1438 uint idx = 0; // position of operand in match rule 1439 int cur_num_opnds = num_opnds(); 1440 1441 // Compute the index into vector of operand pointers: 1442 // idx0=0 is used to indicate that info comes from this same node, not from input edge. 1443 // idx1 starts at oper_input_base() 1444 if ( cur_num_opnds >= 1 ) { 1445 fprintf(fp," // Start at oper_input_base() and count operands\n"); 1446 fprintf(fp," unsigned %sidx0 = %d;\n", prefix, oper_input_base(globals)); 1447 fprintf(fp," unsigned %sidx1 = %d;", prefix, oper_input_base(globals)); 1448 fprintf(fp," \t// %s\n", unique_opnd_ident(1)); 1449 1450 // Generate starting points for other unique operands if they exist 1451 for ( idx = 2; idx < num_unique_opnds(); ++idx ) { 1452 if( *receiver == 0 ) { 1453 fprintf(fp," unsigned %sidx%d = %sidx%d + opnd_array(%d)->num_edges();", 1454 prefix, idx, prefix, idx-1, idx-1 ); 1455 } else { 1456 fprintf(fp," unsigned %sidx%d = %sidx%d + %s_opnds[%d]->num_edges();", 1457 prefix, idx, prefix, idx-1, receiver, idx-1 ); 1458 } 1459 fprintf(fp," \t// %s\n", unique_opnd_ident(idx)); 1460 } 1461 } 1462 if( *receiver != 0 ) { 1463 // This value is used by generate_peepreplace when copying a node. 1464 // Don't emit it in other cases since it can hide bugs with the 1465 // use invalid idx's. 1466 fprintf(fp," unsigned %sidx%d = %sreq(); \n", prefix, idx, receiver); 1467 } 1468 1469 } 1470 1471 // --------------------------- 1472 bool InstructForm::verify() { 1473 // !!!!! !!!!! 1474 // Check that a "label" operand occurs last in the operand list, if present 1475 return true; 1476 } 1477 1478 void InstructForm::dump() { 1479 output(stderr); 1480 } 1481 1482 void InstructForm::output(FILE *fp) { 1483 fprintf(fp,"\nInstruction: %s\n", (_ident?_ident:"")); 1484 if (_matrule) _matrule->output(fp); 1485 if (_insencode) _insencode->output(fp); 1486 if (_constant) _constant->output(fp); 1487 if (_opcode) _opcode->output(fp); 1488 if (_attribs) _attribs->output(fp); 1489 if (_predicate) _predicate->output(fp); 1490 if (_effects.Size()) { 1491 fprintf(fp,"Effects\n"); 1492 _effects.dump(); 1493 } 1494 if (_exprule) _exprule->output(fp); 1495 if (_rewrule) _rewrule->output(fp); 1496 if (_format) _format->output(fp); 1497 if (_peephole) _peephole->output(fp); 1498 } 1499 1500 void MachNodeForm::dump() { 1501 output(stderr); 1502 } 1503 1504 void MachNodeForm::output(FILE *fp) { 1505 fprintf(fp,"\nMachNode: %s\n", (_ident?_ident:"")); 1506 } 1507 1508 //------------------------------build_predicate-------------------------------- 1509 // Build instruction predicates. If the user uses the same operand name 1510 // twice, we need to check that the operands are pointer-eequivalent in 1511 // the DFA during the labeling process. 1512 Predicate *InstructForm::build_predicate() { 1513 const int buflen = 1024; 1514 char buf[buflen], *s=buf; 1515 Dict names(cmpstr,hashstr,Form::arena); // Map Names to counts 1516 1517 MatchNode *mnode = 1518 strcmp(_matrule->_opType, "Set") ? _matrule : _matrule->_rChild; 1519 mnode->count_instr_names(names); 1520 1521 uint first = 1; 1522 // Start with the predicate supplied in the .ad file. 1523 if (_predicate) { 1524 if (first) first = 0; 1525 strcpy(s, "("); s += strlen(s); 1526 strncpy(s, _predicate->_pred, buflen - strlen(s) - 1); 1527 s += strlen(s); 1528 strcpy(s, ")"); s += strlen(s); 1529 } 1530 for( DictI i(&names); i.test(); ++i ) { 1531 uintptr_t cnt = (uintptr_t)i._value; 1532 if( cnt > 1 ) { // Need a predicate at all? 1533 assert( cnt == 2, "Unimplemented" ); 1534 // Handle many pairs 1535 if( first ) first=0; 1536 else { // All tests must pass, so use '&&' 1537 strcpy(s," && "); 1538 s += strlen(s); 1539 } 1540 // Add predicate to working buffer 1541 sprintf(s,"/*%s*/(",(char*)i._key); 1542 s += strlen(s); 1543 mnode->build_instr_pred(s,(char*)i._key,0); 1544 s += strlen(s); 1545 strcpy(s," == "); s += strlen(s); 1546 mnode->build_instr_pred(s,(char*)i._key,1); 1547 s += strlen(s); 1548 strcpy(s,")"); s += strlen(s); 1549 } 1550 } 1551 if( s == buf ) s = NULL; 1552 else { 1553 assert( strlen(buf) < sizeof(buf), "String buffer overflow" ); 1554 s = strdup(buf); 1555 } 1556 return new Predicate(s); 1557 } 1558 1559 //------------------------------EncodeForm------------------------------------- 1560 // Constructor 1561 EncodeForm::EncodeForm() 1562 : _encClass(cmpstr,hashstr, Form::arena) { 1563 } 1564 EncodeForm::~EncodeForm() { 1565 } 1566 1567 // record a new register class 1568 EncClass *EncodeForm::add_EncClass(const char *className) { 1569 EncClass *encClass = new EncClass(className); 1570 _eclasses.addName(className); 1571 _encClass.Insert(className,encClass); 1572 return encClass; 1573 } 1574 1575 // Lookup the function body for an encoding class 1576 EncClass *EncodeForm::encClass(const char *className) { 1577 assert( className != NULL, "Must provide a defined encoding name"); 1578 1579 EncClass *encClass = (EncClass*)_encClass[className]; 1580 return encClass; 1581 } 1582 1583 // Lookup the function body for an encoding class 1584 const char *EncodeForm::encClassBody(const char *className) { 1585 if( className == NULL ) return NULL; 1586 1587 EncClass *encClass = (EncClass*)_encClass[className]; 1588 assert( encClass != NULL, "Encode Class is missing."); 1589 encClass->_code.reset(); 1590 const char *code = (const char*)encClass->_code.iter(); 1591 assert( code != NULL, "Found an empty encode class body."); 1592 1593 return code; 1594 } 1595 1596 // Lookup the function body for an encoding class 1597 const char *EncodeForm::encClassPrototype(const char *className) { 1598 assert( className != NULL, "Encode class name must be non NULL."); 1599 1600 return className; 1601 } 1602 1603 void EncodeForm::dump() { // Debug printer 1604 output(stderr); 1605 } 1606 1607 void EncodeForm::output(FILE *fp) { // Write info to output files 1608 const char *name; 1609 fprintf(fp,"\n"); 1610 fprintf(fp,"-------------------- Dump EncodeForm --------------------\n"); 1611 for (_eclasses.reset(); (name = _eclasses.iter()) != NULL;) { 1612 ((EncClass*)_encClass[name])->output(fp); 1613 } 1614 fprintf(fp,"-------------------- end EncodeForm --------------------\n"); 1615 } 1616 //------------------------------EncClass--------------------------------------- 1617 EncClass::EncClass(const char *name) 1618 : _localNames(cmpstr,hashstr, Form::arena), _name(name) { 1619 } 1620 EncClass::~EncClass() { 1621 } 1622 1623 // Add a parameter <type,name> pair 1624 void EncClass::add_parameter(const char *parameter_type, const char *parameter_name) { 1625 _parameter_type.addName( parameter_type ); 1626 _parameter_name.addName( parameter_name ); 1627 } 1628 1629 // Verify operand types in parameter list 1630 bool EncClass::check_parameter_types(FormDict &globals) { 1631 // !!!!! 1632 return false; 1633 } 1634 1635 // Add the decomposed "code" sections of an encoding's code-block 1636 void EncClass::add_code(const char *code) { 1637 _code.addName(code); 1638 } 1639 1640 // Add the decomposed "replacement variables" of an encoding's code-block 1641 void EncClass::add_rep_var(char *replacement_var) { 1642 _code.addName(NameList::_signal); 1643 _rep_vars.addName(replacement_var); 1644 } 1645 1646 // Lookup the function body for an encoding class 1647 int EncClass::rep_var_index(const char *rep_var) { 1648 uint position = 0; 1649 const char *name = NULL; 1650 1651 _parameter_name.reset(); 1652 while ( (name = _parameter_name.iter()) != NULL ) { 1653 if ( strcmp(rep_var,name) == 0 ) return position; 1654 ++position; 1655 } 1656 1657 return -1; 1658 } 1659 1660 // Check after parsing 1661 bool EncClass::verify() { 1662 // 1!!!! 1663 // Check that each replacement variable, '$name' in architecture description 1664 // is actually a local variable for this encode class, or a reserved name 1665 // "primary, secondary, tertiary" 1666 return true; 1667 } 1668 1669 void EncClass::dump() { 1670 output(stderr); 1671 } 1672 1673 // Write info to output files 1674 void EncClass::output(FILE *fp) { 1675 fprintf(fp,"EncClass: %s", (_name ? _name : "")); 1676 1677 // Output the parameter list 1678 _parameter_type.reset(); 1679 _parameter_name.reset(); 1680 const char *type = _parameter_type.iter(); 1681 const char *name = _parameter_name.iter(); 1682 fprintf(fp, " ( "); 1683 for ( ; (type != NULL) && (name != NULL); 1684 (type = _parameter_type.iter()), (name = _parameter_name.iter()) ) { 1685 fprintf(fp, " %s %s,", type, name); 1686 } 1687 fprintf(fp, " ) "); 1688 1689 // Output the code block 1690 _code.reset(); 1691 _rep_vars.reset(); 1692 const char *code; 1693 while ( (code = _code.iter()) != NULL ) { 1694 if ( _code.is_signal(code) ) { 1695 // A replacement variable 1696 const char *rep_var = _rep_vars.iter(); 1697 fprintf(fp,"($%s)", rep_var); 1698 } else { 1699 // A section of code 1700 fprintf(fp,"%s", code); 1701 } 1702 } 1703 1704 } 1705 1706 //------------------------------Opcode----------------------------------------- 1707 Opcode::Opcode(char *primary, char *secondary, char *tertiary) 1708 : _primary(primary), _secondary(secondary), _tertiary(tertiary) { 1709 } 1710 1711 Opcode::~Opcode() { 1712 } 1713 1714 Opcode::opcode_type Opcode::as_opcode_type(const char *param) { 1715 if( strcmp(param,"primary") == 0 ) { 1716 return Opcode::PRIMARY; 1717 } 1718 else if( strcmp(param,"secondary") == 0 ) { 1719 return Opcode::SECONDARY; 1720 } 1721 else if( strcmp(param,"tertiary") == 0 ) { 1722 return Opcode::TERTIARY; 1723 } 1724 return Opcode::NOT_AN_OPCODE; 1725 } 1726 1727 bool Opcode::print_opcode(FILE *fp, Opcode::opcode_type desired_opcode) { 1728 // Default values previously provided by MachNode::primary()... 1729 const char *description = NULL; 1730 const char *value = NULL; 1731 // Check if user provided any opcode definitions 1732 if( this != NULL ) { 1733 // Update 'value' if user provided a definition in the instruction 1734 switch (desired_opcode) { 1735 case PRIMARY: 1736 description = "primary()"; 1737 if( _primary != NULL) { value = _primary; } 1738 break; 1739 case SECONDARY: 1740 description = "secondary()"; 1741 if( _secondary != NULL ) { value = _secondary; } 1742 break; 1743 case TERTIARY: 1744 description = "tertiary()"; 1745 if( _tertiary != NULL ) { value = _tertiary; } 1746 break; 1747 default: 1748 assert( false, "ShouldNotReachHere();"); 1749 break; 1750 } 1751 } 1752 if (value != NULL) { 1753 fprintf(fp, "(%s /*%s*/)", value, description); 1754 } 1755 return value != NULL; 1756 } 1757 1758 void Opcode::dump() { 1759 output(stderr); 1760 } 1761 1762 // Write info to output files 1763 void Opcode::output(FILE *fp) { 1764 if (_primary != NULL) fprintf(fp,"Primary opcode: %s\n", _primary); 1765 if (_secondary != NULL) fprintf(fp,"Secondary opcode: %s\n", _secondary); 1766 if (_tertiary != NULL) fprintf(fp,"Tertiary opcode: %s\n", _tertiary); 1767 } 1768 1769 //------------------------------InsEncode-------------------------------------- 1770 InsEncode::InsEncode() { 1771 } 1772 InsEncode::~InsEncode() { 1773 } 1774 1775 // Add "encode class name" and its parameters 1776 NameAndList *InsEncode::add_encode(char *encoding) { 1777 assert( encoding != NULL, "Must provide name for encoding"); 1778 1779 // add_parameter(NameList::_signal); 1780 NameAndList *encode = new NameAndList(encoding); 1781 _encoding.addName((char*)encode); 1782 1783 return encode; 1784 } 1785 1786 // Access the list of encodings 1787 void InsEncode::reset() { 1788 _encoding.reset(); 1789 // _parameter.reset(); 1790 } 1791 const char* InsEncode::encode_class_iter() { 1792 NameAndList *encode_class = (NameAndList*)_encoding.iter(); 1793 return ( encode_class != NULL ? encode_class->name() : NULL ); 1794 } 1795 // Obtain parameter name from zero based index 1796 const char *InsEncode::rep_var_name(InstructForm &inst, uint param_no) { 1797 NameAndList *params = (NameAndList*)_encoding.current(); 1798 assert( params != NULL, "Internal Error"); 1799 const char *param = (*params)[param_no]; 1800 1801 // Remove '$' if parser placed it there. 1802 return ( param != NULL && *param == '$') ? (param+1) : param; 1803 } 1804 1805 void InsEncode::dump() { 1806 output(stderr); 1807 } 1808 1809 // Write info to output files 1810 void InsEncode::output(FILE *fp) { 1811 NameAndList *encoding = NULL; 1812 const char *parameter = NULL; 1813 1814 fprintf(fp,"InsEncode: "); 1815 _encoding.reset(); 1816 1817 while ( (encoding = (NameAndList*)_encoding.iter()) != 0 ) { 1818 // Output the encoding being used 1819 fprintf(fp,"%s(", encoding->name() ); 1820 1821 // Output its parameter list, if any 1822 bool first_param = true; 1823 encoding->reset(); 1824 while ( (parameter = encoding->iter()) != 0 ) { 1825 // Output the ',' between parameters 1826 if ( ! first_param ) fprintf(fp,", "); 1827 first_param = false; 1828 // Output the parameter 1829 fprintf(fp,"%s", parameter); 1830 } // done with parameters 1831 fprintf(fp,") "); 1832 } // done with encodings 1833 1834 fprintf(fp,"\n"); 1835 } 1836 1837 //------------------------------Effect----------------------------------------- 1838 static int effect_lookup(const char *name) { 1839 if (!strcmp(name, "USE")) return Component::USE; 1840 if (!strcmp(name, "DEF")) return Component::DEF; 1841 if (!strcmp(name, "USE_DEF")) return Component::USE_DEF; 1842 if (!strcmp(name, "KILL")) return Component::KILL; 1843 if (!strcmp(name, "USE_KILL")) return Component::USE_KILL; 1844 if (!strcmp(name, "TEMP")) return Component::TEMP; 1845 if (!strcmp(name, "TEMP_DEF")) return Component::TEMP_DEF; 1846 if (!strcmp(name, "INVALID")) return Component::INVALID; 1847 if (!strcmp(name, "CALL")) return Component::CALL; 1848 assert(false,"Invalid effect name specified\n"); 1849 return Component::INVALID; 1850 } 1851 1852 const char *Component::getUsedefName() { 1853 switch (_usedef) { 1854 case Component::INVALID: return "INVALID"; break; 1855 case Component::USE: return "USE"; break; 1856 case Component::USE_DEF: return "USE_DEF"; break; 1857 case Component::USE_KILL: return "USE_KILL"; break; 1858 case Component::KILL: return "KILL"; break; 1859 case Component::TEMP: return "TEMP"; break; 1860 case Component::TEMP_DEF: return "TEMP_DEF"; break; 1861 case Component::DEF: return "DEF"; break; 1862 case Component::CALL: return "CALL"; break; 1863 default: assert(false, "unknown effect"); 1864 } 1865 return "Undefined Use/Def info"; 1866 } 1867 1868 Effect::Effect(const char *name) : _name(name), _use_def(effect_lookup(name)) { 1869 _ftype = Form::EFF; 1870 } 1871 1872 Effect::~Effect() { 1873 } 1874 1875 // Dynamic type check 1876 Effect *Effect::is_effect() const { 1877 return (Effect*)this; 1878 } 1879 1880 1881 // True if this component is equal to the parameter. 1882 bool Effect::is(int use_def_kill_enum) const { 1883 return (_use_def == use_def_kill_enum ? true : false); 1884 } 1885 // True if this component is used/def'd/kill'd as the parameter suggests. 1886 bool Effect::isa(int use_def_kill_enum) const { 1887 return (_use_def & use_def_kill_enum) == use_def_kill_enum; 1888 } 1889 1890 void Effect::dump() { 1891 output(stderr); 1892 } 1893 1894 void Effect::output(FILE *fp) { // Write info to output files 1895 fprintf(fp,"Effect: %s\n", (_name?_name:"")); 1896 } 1897 1898 //------------------------------ExpandRule------------------------------------- 1899 ExpandRule::ExpandRule() : _expand_instrs(), 1900 _newopconst(cmpstr, hashstr, Form::arena) { 1901 _ftype = Form::EXP; 1902 } 1903 1904 ExpandRule::~ExpandRule() { // Destructor 1905 } 1906 1907 void ExpandRule::add_instruction(NameAndList *instruction_name_and_operand_list) { 1908 _expand_instrs.addName((char*)instruction_name_and_operand_list); 1909 } 1910 1911 void ExpandRule::reset_instructions() { 1912 _expand_instrs.reset(); 1913 } 1914 1915 NameAndList* ExpandRule::iter_instructions() { 1916 return (NameAndList*)_expand_instrs.iter(); 1917 } 1918 1919 1920 void ExpandRule::dump() { 1921 output(stderr); 1922 } 1923 1924 void ExpandRule::output(FILE *fp) { // Write info to output files 1925 NameAndList *expand_instr = NULL; 1926 const char *opid = NULL; 1927 1928 fprintf(fp,"\nExpand Rule:\n"); 1929 1930 // Iterate over the instructions 'node' expands into 1931 for(reset_instructions(); (expand_instr = iter_instructions()) != NULL; ) { 1932 fprintf(fp,"%s(", expand_instr->name()); 1933 1934 // iterate over the operand list 1935 for( expand_instr->reset(); (opid = expand_instr->iter()) != NULL; ) { 1936 fprintf(fp,"%s ", opid); 1937 } 1938 fprintf(fp,");\n"); 1939 } 1940 } 1941 1942 //------------------------------RewriteRule------------------------------------ 1943 RewriteRule::RewriteRule(char* params, char* block) 1944 : _tempParams(params), _tempBlock(block) { }; // Constructor 1945 RewriteRule::~RewriteRule() { // Destructor 1946 } 1947 1948 void RewriteRule::dump() { 1949 output(stderr); 1950 } 1951 1952 void RewriteRule::output(FILE *fp) { // Write info to output files 1953 fprintf(fp,"\nRewrite Rule:\n%s\n%s\n", 1954 (_tempParams?_tempParams:""), 1955 (_tempBlock?_tempBlock:"")); 1956 } 1957 1958 1959 //==============================MachNodes====================================== 1960 //------------------------------MachNodeForm----------------------------------- 1961 MachNodeForm::MachNodeForm(char *id) 1962 : _ident(id) { 1963 } 1964 1965 MachNodeForm::~MachNodeForm() { 1966 } 1967 1968 MachNodeForm *MachNodeForm::is_machnode() const { 1969 return (MachNodeForm*)this; 1970 } 1971 1972 //==============================Operand Classes================================ 1973 //------------------------------OpClassForm------------------------------------ 1974 OpClassForm::OpClassForm(const char* id) : _ident(id) { 1975 _ftype = Form::OPCLASS; 1976 } 1977 1978 OpClassForm::~OpClassForm() { 1979 } 1980 1981 bool OpClassForm::ideal_only() const { return 0; } 1982 1983 OpClassForm *OpClassForm::is_opclass() const { 1984 return (OpClassForm*)this; 1985 } 1986 1987 Form::InterfaceType OpClassForm::interface_type(FormDict &globals) const { 1988 if( _oplst.count() == 0 ) return Form::no_interface; 1989 1990 // Check that my operands have the same interface type 1991 Form::InterfaceType interface; 1992 bool first = true; 1993 NameList &op_list = (NameList &)_oplst; 1994 op_list.reset(); 1995 const char *op_name; 1996 while( (op_name = op_list.iter()) != NULL ) { 1997 const Form *form = globals[op_name]; 1998 OperandForm *operand = form->is_operand(); 1999 assert( operand, "Entry in operand class that is not an operand"); 2000 if( first ) { 2001 first = false; 2002 interface = operand->interface_type(globals); 2003 } else { 2004 interface = (interface == operand->interface_type(globals) ? interface : Form::no_interface); 2005 } 2006 } 2007 return interface; 2008 } 2009 2010 bool OpClassForm::stack_slots_only(FormDict &globals) const { 2011 if( _oplst.count() == 0 ) return false; // how? 2012 2013 NameList &op_list = (NameList &)_oplst; 2014 op_list.reset(); 2015 const char *op_name; 2016 while( (op_name = op_list.iter()) != NULL ) { 2017 const Form *form = globals[op_name]; 2018 OperandForm *operand = form->is_operand(); 2019 assert( operand, "Entry in operand class that is not an operand"); 2020 if( !operand->stack_slots_only(globals) ) return false; 2021 } 2022 return true; 2023 } 2024 2025 2026 void OpClassForm::dump() { 2027 output(stderr); 2028 } 2029 2030 void OpClassForm::output(FILE *fp) { 2031 const char *name; 2032 fprintf(fp,"\nOperand Class: %s\n", (_ident?_ident:"")); 2033 fprintf(fp,"\nCount = %d\n", _oplst.count()); 2034 for(_oplst.reset(); (name = _oplst.iter()) != NULL;) { 2035 fprintf(fp,"%s, ",name); 2036 } 2037 fprintf(fp,"\n"); 2038 } 2039 2040 2041 //==============================Operands======================================= 2042 //------------------------------OperandForm------------------------------------ 2043 OperandForm::OperandForm(const char* id) 2044 : OpClassForm(id), _ideal_only(false), 2045 _localNames(cmpstr, hashstr, Form::arena) { 2046 _ftype = Form::OPER; 2047 2048 _matrule = NULL; 2049 _interface = NULL; 2050 _attribs = NULL; 2051 _predicate = NULL; 2052 _constraint= NULL; 2053 _construct = NULL; 2054 _format = NULL; 2055 } 2056 OperandForm::OperandForm(const char* id, bool ideal_only) 2057 : OpClassForm(id), _ideal_only(ideal_only), 2058 _localNames(cmpstr, hashstr, Form::arena) { 2059 _ftype = Form::OPER; 2060 2061 _matrule = NULL; 2062 _interface = NULL; 2063 _attribs = NULL; 2064 _predicate = NULL; 2065 _constraint= NULL; 2066 _construct = NULL; 2067 _format = NULL; 2068 } 2069 OperandForm::~OperandForm() { 2070 } 2071 2072 2073 OperandForm *OperandForm::is_operand() const { 2074 return (OperandForm*)this; 2075 } 2076 2077 bool OperandForm::ideal_only() const { 2078 return _ideal_only; 2079 } 2080 2081 Form::InterfaceType OperandForm::interface_type(FormDict &globals) const { 2082 if( _interface == NULL ) return Form::no_interface; 2083 2084 return _interface->interface_type(globals); 2085 } 2086 2087 2088 bool OperandForm::stack_slots_only(FormDict &globals) const { 2089 if( _constraint == NULL ) return false; 2090 return _constraint->stack_slots_only(); 2091 } 2092 2093 2094 // Access op_cost attribute or return NULL. 2095 const char* OperandForm::cost() { 2096 for (Attribute* cur = _attribs; cur != NULL; cur = (Attribute*)cur->_next) { 2097 if( strcmp(cur->_ident,AttributeForm::_op_cost) == 0 ) { 2098 return cur->_val; 2099 } 2100 } 2101 return NULL; 2102 } 2103 2104 // Return the number of leaves below this complex operand 2105 uint OperandForm::num_leaves() const { 2106 if ( ! _matrule) return 0; 2107 2108 int num_leaves = _matrule->_numleaves; 2109 return num_leaves; 2110 } 2111 2112 // Return the number of constants contained within this complex operand 2113 uint OperandForm::num_consts(FormDict &globals) const { 2114 if ( ! _matrule) return 0; 2115 2116 // This is a recursive invocation on all operands in the matchrule 2117 return _matrule->num_consts(globals); 2118 } 2119 2120 // Return the number of constants in match rule with specified type 2121 uint OperandForm::num_consts(FormDict &globals, Form::DataType type) const { 2122 if ( ! _matrule) return 0; 2123 2124 // This is a recursive invocation on all operands in the matchrule 2125 return _matrule->num_consts(globals, type); 2126 } 2127 2128 // Return the number of pointer constants contained within this complex operand 2129 uint OperandForm::num_const_ptrs(FormDict &globals) const { 2130 if ( ! _matrule) return 0; 2131 2132 // This is a recursive invocation on all operands in the matchrule 2133 return _matrule->num_const_ptrs(globals); 2134 } 2135 2136 uint OperandForm::num_edges(FormDict &globals) const { 2137 uint edges = 0; 2138 uint leaves = num_leaves(); 2139 uint consts = num_consts(globals); 2140 2141 // If we are matching a constant directly, there are no leaves. 2142 edges = ( leaves > consts ) ? leaves - consts : 0; 2143 2144 // !!!!! 2145 // Special case operands that do not have a corresponding ideal node. 2146 if( (edges == 0) && (consts == 0) ) { 2147 if( constrained_reg_class() != NULL ) { 2148 edges = 1; 2149 } else { 2150 if( _matrule 2151 && (_matrule->_lChild == NULL) && (_matrule->_rChild == NULL) ) { 2152 const Form *form = globals[_matrule->_opType]; 2153 OperandForm *oper = form ? form->is_operand() : NULL; 2154 if( oper ) { 2155 return oper->num_edges(globals); 2156 } 2157 } 2158 } 2159 } 2160 2161 return edges; 2162 } 2163 2164 2165 // Check if this operand is usable for cisc-spilling 2166 bool OperandForm::is_cisc_reg(FormDict &globals) const { 2167 const char *ideal = ideal_type(globals); 2168 bool is_cisc_reg = (ideal && (ideal_to_Reg_type(ideal) != none)); 2169 return is_cisc_reg; 2170 } 2171 2172 bool OpClassForm::is_cisc_mem(FormDict &globals) const { 2173 Form::InterfaceType my_interface = interface_type(globals); 2174 return (my_interface == memory_interface); 2175 } 2176 2177 2178 // node matches ideal 'Bool' 2179 bool OperandForm::is_ideal_bool() const { 2180 if( _matrule == NULL ) return false; 2181 2182 return _matrule->is_ideal_bool(); 2183 } 2184 2185 // Require user's name for an sRegX to be stackSlotX 2186 Form::DataType OperandForm::is_user_name_for_sReg() const { 2187 DataType data_type = none; 2188 if( _ident != NULL ) { 2189 if( strcmp(_ident,"stackSlotI") == 0 ) data_type = Form::idealI; 2190 else if( strcmp(_ident,"stackSlotP") == 0 ) data_type = Form::idealP; 2191 else if( strcmp(_ident,"stackSlotD") == 0 ) data_type = Form::idealD; 2192 else if( strcmp(_ident,"stackSlotF") == 0 ) data_type = Form::idealF; 2193 else if( strcmp(_ident,"stackSlotL") == 0 ) data_type = Form::idealL; 2194 } 2195 assert((data_type == none) || (_matrule == NULL), "No match-rule for stackSlotX"); 2196 2197 return data_type; 2198 } 2199 2200 2201 // Return ideal type, if there is a single ideal type for this operand 2202 const char *OperandForm::ideal_type(FormDict &globals, RegisterForm *registers) const { 2203 const char *type = NULL; 2204 if (ideal_only()) type = _ident; 2205 else if( _matrule == NULL ) { 2206 // Check for condition code register 2207 const char *rc_name = constrained_reg_class(); 2208 // !!!!! 2209 if (rc_name == NULL) return NULL; 2210 // !!!!! !!!!! 2211 // Check constraints on result's register class 2212 if( registers ) { 2213 RegClass *reg_class = registers->getRegClass(rc_name); 2214 assert( reg_class != NULL, "Register class is not defined"); 2215 2216 // Check for ideal type of entries in register class, all are the same type 2217 reg_class->reset(); 2218 RegDef *reg_def = reg_class->RegDef_iter(); 2219 assert( reg_def != NULL, "No entries in register class"); 2220 assert( reg_def->_idealtype != NULL, "Did not define ideal type for register"); 2221 // Return substring that names the register's ideal type 2222 type = reg_def->_idealtype + 3; 2223 assert( *(reg_def->_idealtype + 0) == 'O', "Expect Op_ prefix"); 2224 assert( *(reg_def->_idealtype + 1) == 'p', "Expect Op_ prefix"); 2225 assert( *(reg_def->_idealtype + 2) == '_', "Expect Op_ prefix"); 2226 } 2227 } 2228 else if( _matrule->_lChild == NULL && _matrule->_rChild == NULL ) { 2229 // This operand matches a single type, at the top level. 2230 // Check for ideal type 2231 type = _matrule->_opType; 2232 if( strcmp(type,"Bool") == 0 ) 2233 return "Bool"; 2234 // transitive lookup 2235 const Form *frm = globals[type]; 2236 OperandForm *op = frm->is_operand(); 2237 type = op->ideal_type(globals, registers); 2238 } 2239 return type; 2240 } 2241 2242 2243 // If there is a single ideal type for this interface field, return it. 2244 const char *OperandForm::interface_ideal_type(FormDict &globals, 2245 const char *field) const { 2246 const char *ideal_type = NULL; 2247 const char *value = NULL; 2248 2249 // Check if "field" is valid for this operand's interface 2250 if ( ! is_interface_field(field, value) ) return ideal_type; 2251 2252 // !!!!! !!!!! !!!!! 2253 // If a valid field has a constant value, identify "ConI" or "ConP" or ... 2254 2255 // Else, lookup type of field's replacement variable 2256 2257 return ideal_type; 2258 } 2259 2260 2261 RegClass* OperandForm::get_RegClass() const { 2262 if (_interface && !_interface->is_RegInterface()) return NULL; 2263 return globalAD->get_registers()->getRegClass(constrained_reg_class()); 2264 } 2265 2266 2267 bool OperandForm::is_bound_register() const { 2268 RegClass* reg_class = get_RegClass(); 2269 if (reg_class == NULL) { 2270 return false; 2271 } 2272 2273 const char* name = ideal_type(globalAD->globalNames()); 2274 if (name == NULL) { 2275 return false; 2276 } 2277 2278 uint size = 0; 2279 if (strcmp(name, "RegFlags") == 0) size = 1; 2280 if (strcmp(name, "RegI") == 0) size = 1; 2281 if (strcmp(name, "RegF") == 0) size = 1; 2282 if (strcmp(name, "RegD") == 0) size = 2; 2283 if (strcmp(name, "RegL") == 0) size = 2; 2284 if (strcmp(name, "RegN") == 0) size = 1; 2285 if (strcmp(name, "RegP") == 0) size = globalAD->get_preproc_def("_LP64") ? 2 : 1; 2286 if (size == 0) { 2287 return false; 2288 } 2289 return size == reg_class->size(); 2290 } 2291 2292 2293 // Check if this is a valid field for this operand, 2294 // Return 'true' if valid, and set the value to the string the user provided. 2295 bool OperandForm::is_interface_field(const char *field, 2296 const char * &value) const { 2297 return false; 2298 } 2299 2300 2301 // Return register class name if a constraint specifies the register class. 2302 const char *OperandForm::constrained_reg_class() const { 2303 const char *reg_class = NULL; 2304 if ( _constraint ) { 2305 // !!!!! 2306 Constraint *constraint = _constraint; 2307 if ( strcmp(_constraint->_func,"ALLOC_IN_RC") == 0 ) { 2308 reg_class = _constraint->_arg; 2309 } 2310 } 2311 2312 return reg_class; 2313 } 2314 2315 2316 // Return the register class associated with 'leaf'. 2317 const char *OperandForm::in_reg_class(uint leaf, FormDict &globals) { 2318 const char *reg_class = NULL; // "RegMask::Empty"; 2319 2320 if((_matrule == NULL) || (_matrule->is_chain_rule(globals))) { 2321 reg_class = constrained_reg_class(); 2322 return reg_class; 2323 } 2324 const char *result = NULL; 2325 const char *name = NULL; 2326 const char *type = NULL; 2327 // iterate through all base operands 2328 // until we reach the register that corresponds to "leaf" 2329 // This function is not looking for an ideal type. It needs the first 2330 // level user type associated with the leaf. 2331 for(uint idx = 0;_matrule->base_operand(idx,globals,result,name,type);++idx) { 2332 const Form *form = (_localNames[name] ? _localNames[name] : globals[result]); 2333 OperandForm *oper = form ? form->is_operand() : NULL; 2334 if( oper ) { 2335 reg_class = oper->constrained_reg_class(); 2336 if( reg_class ) { 2337 reg_class = reg_class; 2338 } else { 2339 // ShouldNotReachHere(); 2340 } 2341 } else { 2342 // ShouldNotReachHere(); 2343 } 2344 2345 // Increment our target leaf position if current leaf is not a candidate. 2346 if( reg_class == NULL) ++leaf; 2347 // Exit the loop with the value of reg_class when at the correct index 2348 if( idx == leaf ) break; 2349 // May iterate through all base operands if reg_class for 'leaf' is NULL 2350 } 2351 return reg_class; 2352 } 2353 2354 2355 // Recursive call to construct list of top-level operands. 2356 // Implementation does not modify state of internal structures 2357 void OperandForm::build_components() { 2358 if (_matrule) _matrule->append_components(_localNames, _components); 2359 2360 // Add parameters that "do not appear in match rule". 2361 const char *name; 2362 for (_parameters.reset(); (name = _parameters.iter()) != NULL;) { 2363 OperandForm *opForm = (OperandForm*)_localNames[name]; 2364 2365 if ( _components.operand_position(name) == -1 ) { 2366 _components.insert(name, opForm->_ident, Component::INVALID, false); 2367 } 2368 } 2369 2370 return; 2371 } 2372 2373 int OperandForm::operand_position(const char *name, int usedef) { 2374 return _components.operand_position(name, usedef, this); 2375 } 2376 2377 2378 // Return zero-based position in component list, only counting constants; 2379 // Return -1 if not in list. 2380 int OperandForm::constant_position(FormDict &globals, const Component *last) { 2381 // Iterate through components and count constants preceding 'constant' 2382 int position = 0; 2383 Component *comp; 2384 _components.reset(); 2385 while( (comp = _components.iter()) != NULL && (comp != last) ) { 2386 // Special case for operands that take a single user-defined operand 2387 // Skip the initial definition in the component list. 2388 if( strcmp(comp->_name,this->_ident) == 0 ) continue; 2389 2390 const char *type = comp->_type; 2391 // Lookup operand form for replacement variable's type 2392 const Form *form = globals[type]; 2393 assert( form != NULL, "Component's type not found"); 2394 OperandForm *oper = form ? form->is_operand() : NULL; 2395 if( oper ) { 2396 if( oper->_matrule->is_base_constant(globals) != Form::none ) { 2397 ++position; 2398 } 2399 } 2400 } 2401 2402 // Check for being passed a component that was not in the list 2403 if( comp != last ) position = -1; 2404 2405 return position; 2406 } 2407 // Provide position of constant by "name" 2408 int OperandForm::constant_position(FormDict &globals, const char *name) { 2409 const Component *comp = _components.search(name); 2410 int idx = constant_position( globals, comp ); 2411 2412 return idx; 2413 } 2414 2415 2416 // Return zero-based position in component list, only counting constants; 2417 // Return -1 if not in list. 2418 int OperandForm::register_position(FormDict &globals, const char *reg_name) { 2419 // Iterate through components and count registers preceding 'last' 2420 uint position = 0; 2421 Component *comp; 2422 _components.reset(); 2423 while( (comp = _components.iter()) != NULL 2424 && (strcmp(comp->_name,reg_name) != 0) ) { 2425 // Special case for operands that take a single user-defined operand 2426 // Skip the initial definition in the component list. 2427 if( strcmp(comp->_name,this->_ident) == 0 ) continue; 2428 2429 const char *type = comp->_type; 2430 // Lookup operand form for component's type 2431 const Form *form = globals[type]; 2432 assert( form != NULL, "Component's type not found"); 2433 OperandForm *oper = form ? form->is_operand() : NULL; 2434 if( oper ) { 2435 if( oper->_matrule->is_base_register(globals) ) { 2436 ++position; 2437 } 2438 } 2439 } 2440 2441 return position; 2442 } 2443 2444 2445 const char *OperandForm::reduce_result() const { 2446 return _ident; 2447 } 2448 // Return the name of the operand on the right hand side of the binary match 2449 // Return NULL if there is no right hand side 2450 const char *OperandForm::reduce_right(FormDict &globals) const { 2451 return ( _matrule ? _matrule->reduce_right(globals) : NULL ); 2452 } 2453 2454 // Similar for left 2455 const char *OperandForm::reduce_left(FormDict &globals) const { 2456 return ( _matrule ? _matrule->reduce_left(globals) : NULL ); 2457 } 2458 2459 2460 // --------------------------- FILE *output_routines 2461 // 2462 // Output code for disp_is_oop, if true. 2463 void OperandForm::disp_is_oop(FILE *fp, FormDict &globals) { 2464 // Check it is a memory interface with a non-user-constant disp field 2465 if ( this->_interface == NULL ) return; 2466 MemInterface *mem_interface = this->_interface->is_MemInterface(); 2467 if ( mem_interface == NULL ) return; 2468 const char *disp = mem_interface->_disp; 2469 if ( *disp != '$' ) return; 2470 2471 // Lookup replacement variable in operand's component list 2472 const char *rep_var = disp + 1; 2473 const Component *comp = this->_components.search(rep_var); 2474 assert( comp != NULL, "Replacement variable not found in components"); 2475 // Lookup operand form for replacement variable's type 2476 const char *type = comp->_type; 2477 Form *form = (Form*)globals[type]; 2478 assert( form != NULL, "Replacement variable's type not found"); 2479 OperandForm *op = form->is_operand(); 2480 assert( op, "Memory Interface 'disp' can only emit an operand form"); 2481 // Check if this is a ConP, which may require relocation 2482 if ( op->is_base_constant(globals) == Form::idealP ) { 2483 // Find the constant's index: _c0, _c1, _c2, ... , _cN 2484 uint idx = op->constant_position( globals, rep_var); 2485 fprintf(fp," virtual relocInfo::relocType disp_reloc() const {"); 2486 fprintf(fp, " return _c%d->reloc();", idx); 2487 fprintf(fp, " }\n"); 2488 } 2489 } 2490 2491 // Generate code for internal and external format methods 2492 // 2493 // internal access to reg# node->_idx 2494 // access to subsumed constant _c0, _c1, 2495 void OperandForm::int_format(FILE *fp, FormDict &globals, uint index) { 2496 Form::DataType dtype; 2497 if (_matrule && (_matrule->is_base_register(globals) || 2498 strcmp(ideal_type(globalAD->globalNames()), "RegFlags") == 0)) { 2499 // !!!!! !!!!! 2500 fprintf(fp," { char reg_str[128];\n"); 2501 fprintf(fp," ra->dump_register(node,reg_str);\n"); 2502 fprintf(fp," st->print(\"%cs\",reg_str);\n",'%'); 2503 fprintf(fp," }\n"); 2504 } else if (_matrule && (dtype = _matrule->is_base_constant(globals)) != Form::none) { 2505 format_constant( fp, index, dtype ); 2506 } else if (ideal_to_sReg_type(_ident) != Form::none) { 2507 // Special format for Stack Slot Register 2508 fprintf(fp," { char reg_str[128];\n"); 2509 fprintf(fp," ra->dump_register(node,reg_str);\n"); 2510 fprintf(fp," st->print(\"%cs\",reg_str);\n",'%'); 2511 fprintf(fp," }\n"); 2512 } else { 2513 fprintf(fp," st->print(\"No format defined for %s\n\");\n", _ident); 2514 fflush(fp); 2515 fprintf(stderr,"No format defined for %s\n", _ident); 2516 dump(); 2517 assert( false,"Internal error:\n output_internal_operand() attempting to output other than a Register or Constant"); 2518 } 2519 } 2520 2521 // Similar to "int_format" but for cases where data is external to operand 2522 // external access to reg# node->in(idx)->_idx, 2523 void OperandForm::ext_format(FILE *fp, FormDict &globals, uint index) { 2524 Form::DataType dtype; 2525 if (_matrule && (_matrule->is_base_register(globals) || 2526 strcmp(ideal_type(globalAD->globalNames()), "RegFlags") == 0)) { 2527 fprintf(fp," { char reg_str[128];\n"); 2528 fprintf(fp," ra->dump_register(node->in(idx"); 2529 if ( index != 0 ) fprintf(fp, "+%d",index); 2530 fprintf(fp, "),reg_str);\n"); 2531 fprintf(fp," st->print(\"%cs\",reg_str);\n",'%'); 2532 fprintf(fp," }\n"); 2533 } else if (_matrule && (dtype = _matrule->is_base_constant(globals)) != Form::none) { 2534 format_constant( fp, index, dtype ); 2535 } else if (ideal_to_sReg_type(_ident) != Form::none) { 2536 // Special format for Stack Slot Register 2537 fprintf(fp," { char reg_str[128];\n"); 2538 fprintf(fp," ra->dump_register(node->in(idx"); 2539 if ( index != 0 ) fprintf(fp, "+%d",index); 2540 fprintf(fp, "),reg_str);\n"); 2541 fprintf(fp," st->print(\"%cs\",reg_str);\n",'%'); 2542 fprintf(fp," }\n"); 2543 } else { 2544 fprintf(fp," st->print(\"No format defined for %s\n\");\n", _ident); 2545 assert( false,"Internal error:\n output_external_operand() attempting to output other than a Register or Constant"); 2546 } 2547 } 2548 2549 void OperandForm::format_constant(FILE *fp, uint const_index, uint const_type) { 2550 switch(const_type) { 2551 case Form::idealI: fprintf(fp," st->print(\"#%%d\", _c%d);\n", const_index); break; 2552 case Form::idealP: fprintf(fp," if (_c%d) _c%d->dump_on(st);\n", const_index, const_index); break; 2553 case Form::idealNKlass: 2554 case Form::idealN: fprintf(fp," if (_c%d) _c%d->dump_on(st);\n", const_index, const_index); break; 2555 case Form::idealL: fprintf(fp," st->print(\"#\" INT64_FORMAT, (int64_t)_c%d);\n", const_index); break; 2556 case Form::idealF: fprintf(fp," st->print(\"#%%f\", _c%d);\n", const_index); break; 2557 case Form::idealD: fprintf(fp," st->print(\"#%%f\", _c%d);\n", const_index); break; 2558 default: 2559 assert( false, "ShouldNotReachHere()"); 2560 } 2561 } 2562 2563 // Return the operand form corresponding to the given index, else NULL. 2564 OperandForm *OperandForm::constant_operand(FormDict &globals, 2565 uint index) { 2566 // !!!!! 2567 // Check behavior on complex operands 2568 uint n_consts = num_consts(globals); 2569 if( n_consts > 0 ) { 2570 uint i = 0; 2571 const char *type; 2572 Component *comp; 2573 _components.reset(); 2574 if ((comp = _components.iter()) == NULL) { 2575 assert(n_consts == 1, "Bad component list detected.\n"); 2576 // Current operand is THE operand 2577 if ( index == 0 ) { 2578 return this; 2579 } 2580 } // end if NULL 2581 else { 2582 // Skip the first component, it can not be a DEF of a constant 2583 do { 2584 type = comp->base_type(globals); 2585 // Check that "type" is a 'ConI', 'ConP', ... 2586 if ( ideal_to_const_type(type) != Form::none ) { 2587 // When at correct component, get corresponding Operand 2588 if ( index == 0 ) { 2589 return globals[comp->_type]->is_operand(); 2590 } 2591 // Decrement number of constants to go 2592 --index; 2593 } 2594 } while((comp = _components.iter()) != NULL); 2595 } 2596 } 2597 2598 // Did not find a constant for this index. 2599 return NULL; 2600 } 2601 2602 // If this operand has a single ideal type, return its type 2603 Form::DataType OperandForm::simple_type(FormDict &globals) const { 2604 const char *type_name = ideal_type(globals); 2605 Form::DataType type = type_name ? ideal_to_const_type( type_name ) 2606 : Form::none; 2607 return type; 2608 } 2609 2610 Form::DataType OperandForm::is_base_constant(FormDict &globals) const { 2611 if ( _matrule == NULL ) return Form::none; 2612 2613 return _matrule->is_base_constant(globals); 2614 } 2615 2616 // "true" if this operand is a simple type that is swallowed 2617 bool OperandForm::swallowed(FormDict &globals) const { 2618 Form::DataType type = simple_type(globals); 2619 if( type != Form::none ) { 2620 return true; 2621 } 2622 2623 return false; 2624 } 2625 2626 // Output code to access the value of the index'th constant 2627 void OperandForm::access_constant(FILE *fp, FormDict &globals, 2628 uint const_index) { 2629 OperandForm *oper = constant_operand(globals, const_index); 2630 assert( oper, "Index exceeds number of constants in operand"); 2631 Form::DataType dtype = oper->is_base_constant(globals); 2632 2633 switch(dtype) { 2634 case idealI: fprintf(fp,"_c%d", const_index); break; 2635 case idealP: fprintf(fp,"_c%d->get_con()",const_index); break; 2636 case idealL: fprintf(fp,"_c%d", const_index); break; 2637 case idealF: fprintf(fp,"_c%d", const_index); break; 2638 case idealD: fprintf(fp,"_c%d", const_index); break; 2639 default: 2640 assert( false, "ShouldNotReachHere()"); 2641 } 2642 } 2643 2644 2645 void OperandForm::dump() { 2646 output(stderr); 2647 } 2648 2649 void OperandForm::output(FILE *fp) { 2650 fprintf(fp,"\nOperand: %s\n", (_ident?_ident:"")); 2651 if (_matrule) _matrule->dump(); 2652 if (_interface) _interface->dump(); 2653 if (_attribs) _attribs->dump(); 2654 if (_predicate) _predicate->dump(); 2655 if (_constraint) _constraint->dump(); 2656 if (_construct) _construct->dump(); 2657 if (_format) _format->dump(); 2658 } 2659 2660 //------------------------------Constraint------------------------------------- 2661 Constraint::Constraint(const char *func, const char *arg) 2662 : _func(func), _arg(arg) { 2663 } 2664 Constraint::~Constraint() { /* not owner of char* */ 2665 } 2666 2667 bool Constraint::stack_slots_only() const { 2668 return strcmp(_func, "ALLOC_IN_RC") == 0 2669 && strcmp(_arg, "stack_slots") == 0; 2670 } 2671 2672 void Constraint::dump() { 2673 output(stderr); 2674 } 2675 2676 void Constraint::output(FILE *fp) { // Write info to output files 2677 assert((_func != NULL && _arg != NULL),"missing constraint function or arg"); 2678 fprintf(fp,"Constraint: %s ( %s )\n", _func, _arg); 2679 } 2680 2681 //------------------------------Predicate-------------------------------------- 2682 Predicate::Predicate(char *pr) 2683 : _pred(pr) { 2684 } 2685 Predicate::~Predicate() { 2686 } 2687 2688 void Predicate::dump() { 2689 output(stderr); 2690 } 2691 2692 void Predicate::output(FILE *fp) { 2693 fprintf(fp,"Predicate"); // Write to output files 2694 } 2695 //------------------------------Interface-------------------------------------- 2696 Interface::Interface(const char *name) : _name(name) { 2697 } 2698 Interface::~Interface() { 2699 } 2700 2701 Form::InterfaceType Interface::interface_type(FormDict &globals) const { 2702 Interface *thsi = (Interface*)this; 2703 if ( thsi->is_RegInterface() ) return Form::register_interface; 2704 if ( thsi->is_MemInterface() ) return Form::memory_interface; 2705 if ( thsi->is_ConstInterface() ) return Form::constant_interface; 2706 if ( thsi->is_CondInterface() ) return Form::conditional_interface; 2707 2708 return Form::no_interface; 2709 } 2710 2711 RegInterface *Interface::is_RegInterface() { 2712 if ( strcmp(_name,"REG_INTER") != 0 ) 2713 return NULL; 2714 return (RegInterface*)this; 2715 } 2716 MemInterface *Interface::is_MemInterface() { 2717 if ( strcmp(_name,"MEMORY_INTER") != 0 ) return NULL; 2718 return (MemInterface*)this; 2719 } 2720 ConstInterface *Interface::is_ConstInterface() { 2721 if ( strcmp(_name,"CONST_INTER") != 0 ) return NULL; 2722 return (ConstInterface*)this; 2723 } 2724 CondInterface *Interface::is_CondInterface() { 2725 if ( strcmp(_name,"COND_INTER") != 0 ) return NULL; 2726 return (CondInterface*)this; 2727 } 2728 2729 2730 void Interface::dump() { 2731 output(stderr); 2732 } 2733 2734 // Write info to output files 2735 void Interface::output(FILE *fp) { 2736 fprintf(fp,"Interface: %s\n", (_name ? _name : "") ); 2737 } 2738 2739 //------------------------------RegInterface----------------------------------- 2740 RegInterface::RegInterface() : Interface("REG_INTER") { 2741 } 2742 RegInterface::~RegInterface() { 2743 } 2744 2745 void RegInterface::dump() { 2746 output(stderr); 2747 } 2748 2749 // Write info to output files 2750 void RegInterface::output(FILE *fp) { 2751 Interface::output(fp); 2752 } 2753 2754 //------------------------------ConstInterface--------------------------------- 2755 ConstInterface::ConstInterface() : Interface("CONST_INTER") { 2756 } 2757 ConstInterface::~ConstInterface() { 2758 } 2759 2760 void ConstInterface::dump() { 2761 output(stderr); 2762 } 2763 2764 // Write info to output files 2765 void ConstInterface::output(FILE *fp) { 2766 Interface::output(fp); 2767 } 2768 2769 //------------------------------MemInterface----------------------------------- 2770 MemInterface::MemInterface(char *base, char *index, char *scale, char *disp) 2771 : Interface("MEMORY_INTER"), _base(base), _index(index), _scale(scale), _disp(disp) { 2772 } 2773 MemInterface::~MemInterface() { 2774 // not owner of any character arrays 2775 } 2776 2777 void MemInterface::dump() { 2778 output(stderr); 2779 } 2780 2781 // Write info to output files 2782 void MemInterface::output(FILE *fp) { 2783 Interface::output(fp); 2784 if ( _base != NULL ) fprintf(fp," base == %s\n", _base); 2785 if ( _index != NULL ) fprintf(fp," index == %s\n", _index); 2786 if ( _scale != NULL ) fprintf(fp," scale == %s\n", _scale); 2787 if ( _disp != NULL ) fprintf(fp," disp == %s\n", _disp); 2788 // fprintf(fp,"\n"); 2789 } 2790 2791 //------------------------------CondInterface---------------------------------- 2792 CondInterface::CondInterface(const char* equal, const char* equal_format, 2793 const char* not_equal, const char* not_equal_format, 2794 const char* less, const char* less_format, 2795 const char* greater_equal, const char* greater_equal_format, 2796 const char* less_equal, const char* less_equal_format, 2797 const char* greater, const char* greater_format, 2798 const char* overflow, const char* overflow_format, 2799 const char* no_overflow, const char* no_overflow_format) 2800 : Interface("COND_INTER"), 2801 _equal(equal), _equal_format(equal_format), 2802 _not_equal(not_equal), _not_equal_format(not_equal_format), 2803 _less(less), _less_format(less_format), 2804 _greater_equal(greater_equal), _greater_equal_format(greater_equal_format), 2805 _less_equal(less_equal), _less_equal_format(less_equal_format), 2806 _greater(greater), _greater_format(greater_format), 2807 _overflow(overflow), _overflow_format(overflow_format), 2808 _no_overflow(no_overflow), _no_overflow_format(no_overflow_format) { 2809 } 2810 CondInterface::~CondInterface() { 2811 // not owner of any character arrays 2812 } 2813 2814 void CondInterface::dump() { 2815 output(stderr); 2816 } 2817 2818 // Write info to output files 2819 void CondInterface::output(FILE *fp) { 2820 Interface::output(fp); 2821 if ( _equal != NULL ) fprintf(fp," equal == %s\n", _equal); 2822 if ( _not_equal != NULL ) fprintf(fp," not_equal == %s\n", _not_equal); 2823 if ( _less != NULL ) fprintf(fp," less == %s\n", _less); 2824 if ( _greater_equal != NULL ) fprintf(fp," greater_equal == %s\n", _greater_equal); 2825 if ( _less_equal != NULL ) fprintf(fp," less_equal == %s\n", _less_equal); 2826 if ( _greater != NULL ) fprintf(fp," greater == %s\n", _greater); 2827 if ( _overflow != NULL ) fprintf(fp," overflow == %s\n", _overflow); 2828 if ( _no_overflow != NULL ) fprintf(fp," no_overflow == %s\n", _no_overflow); 2829 // fprintf(fp,"\n"); 2830 } 2831 2832 //------------------------------ConstructRule---------------------------------- 2833 ConstructRule::ConstructRule(char *cnstr) 2834 : _construct(cnstr) { 2835 } 2836 ConstructRule::~ConstructRule() { 2837 } 2838 2839 void ConstructRule::dump() { 2840 output(stderr); 2841 } 2842 2843 void ConstructRule::output(FILE *fp) { 2844 fprintf(fp,"\nConstruct Rule\n"); // Write to output files 2845 } 2846 2847 2848 //==============================Shared Forms=================================== 2849 //------------------------------AttributeForm---------------------------------- 2850 int AttributeForm::_insId = 0; // start counter at 0 2851 int AttributeForm::_opId = 0; // start counter at 0 2852 const char* AttributeForm::_ins_cost = "ins_cost"; // required name 2853 const char* AttributeForm::_op_cost = "op_cost"; // required name 2854 2855 AttributeForm::AttributeForm(char *attr, int type, char *attrdef) 2856 : Form(Form::ATTR), _attrname(attr), _atype(type), _attrdef(attrdef) { 2857 if (type==OP_ATTR) { 2858 id = ++_opId; 2859 } 2860 else if (type==INS_ATTR) { 2861 id = ++_insId; 2862 } 2863 else assert( false,""); 2864 } 2865 AttributeForm::~AttributeForm() { 2866 } 2867 2868 // Dynamic type check 2869 AttributeForm *AttributeForm::is_attribute() const { 2870 return (AttributeForm*)this; 2871 } 2872 2873 2874 // inlined // int AttributeForm::type() { return id;} 2875 2876 void AttributeForm::dump() { 2877 output(stderr); 2878 } 2879 2880 void AttributeForm::output(FILE *fp) { 2881 if( _attrname && _attrdef ) { 2882 fprintf(fp,"\n// AttributeForm \nstatic const int %s = %s;\n", 2883 _attrname, _attrdef); 2884 } 2885 else { 2886 fprintf(fp,"\n// AttributeForm missing name %s or definition %s\n", 2887 (_attrname?_attrname:""), (_attrdef?_attrdef:"") ); 2888 } 2889 } 2890 2891 //------------------------------Component-------------------------------------- 2892 Component::Component(const char *name, const char *type, int usedef) 2893 : _name(name), _type(type), _usedef(usedef) { 2894 _ftype = Form::COMP; 2895 } 2896 Component::~Component() { 2897 } 2898 2899 // True if this component is equal to the parameter. 2900 bool Component::is(int use_def_kill_enum) const { 2901 return (_usedef == use_def_kill_enum ? true : false); 2902 } 2903 // True if this component is used/def'd/kill'd as the parameter suggests. 2904 bool Component::isa(int use_def_kill_enum) const { 2905 return (_usedef & use_def_kill_enum) == use_def_kill_enum; 2906 } 2907 2908 // Extend this component with additional use/def/kill behavior 2909 int Component::promote_use_def_info(int new_use_def) { 2910 _usedef |= new_use_def; 2911 2912 return _usedef; 2913 } 2914 2915 // Check the base type of this component, if it has one 2916 const char *Component::base_type(FormDict &globals) { 2917 const Form *frm = globals[_type]; 2918 if (frm == NULL) return NULL; 2919 OperandForm *op = frm->is_operand(); 2920 if (op == NULL) return NULL; 2921 if (op->ideal_only()) return op->_ident; 2922 return (char *)op->ideal_type(globals); 2923 } 2924 2925 void Component::dump() { 2926 output(stderr); 2927 } 2928 2929 void Component::output(FILE *fp) { 2930 fprintf(fp,"Component:"); // Write to output files 2931 fprintf(fp, " name = %s", _name); 2932 fprintf(fp, ", type = %s", _type); 2933 assert(_usedef != 0, "unknown effect"); 2934 fprintf(fp, ", use/def = %s\n", getUsedefName()); 2935 } 2936 2937 2938 //------------------------------ComponentList--------------------------------- 2939 ComponentList::ComponentList() : NameList(), _matchcnt(0) { 2940 } 2941 ComponentList::~ComponentList() { 2942 // // This list may not own its elements if copied via assignment 2943 // Component *component; 2944 // for (reset(); (component = iter()) != NULL;) { 2945 // delete component; 2946 // } 2947 } 2948 2949 void ComponentList::insert(Component *component, bool mflag) { 2950 NameList::addName((char *)component); 2951 if(mflag) _matchcnt++; 2952 } 2953 void ComponentList::insert(const char *name, const char *opType, int usedef, 2954 bool mflag) { 2955 Component * component = new Component(name, opType, usedef); 2956 insert(component, mflag); 2957 } 2958 Component *ComponentList::current() { return (Component*)NameList::current(); } 2959 Component *ComponentList::iter() { return (Component*)NameList::iter(); } 2960 Component *ComponentList::match_iter() { 2961 if(_iter < _matchcnt) return (Component*)NameList::iter(); 2962 return NULL; 2963 } 2964 Component *ComponentList::post_match_iter() { 2965 Component *comp = iter(); 2966 // At end of list? 2967 if ( comp == NULL ) { 2968 return comp; 2969 } 2970 // In post-match components? 2971 if (_iter > match_count()-1) { 2972 return comp; 2973 } 2974 2975 return post_match_iter(); 2976 } 2977 2978 void ComponentList::reset() { NameList::reset(); } 2979 int ComponentList::count() { return NameList::count(); } 2980 2981 Component *ComponentList::operator[](int position) { 2982 // Shortcut complete iteration if there are not enough entries 2983 if (position >= count()) return NULL; 2984 2985 int index = 0; 2986 Component *component = NULL; 2987 for (reset(); (component = iter()) != NULL;) { 2988 if (index == position) { 2989 return component; 2990 } 2991 ++index; 2992 } 2993 2994 return NULL; 2995 } 2996 2997 const Component *ComponentList::search(const char *name) { 2998 PreserveIter pi(this); 2999 reset(); 3000 for( Component *comp = NULL; ((comp = iter()) != NULL); ) { 3001 if( strcmp(comp->_name,name) == 0 ) return comp; 3002 } 3003 3004 return NULL; 3005 } 3006 3007 // Return number of USEs + number of DEFs 3008 // When there are no components, or the first component is a USE, 3009 // then we add '1' to hold a space for the 'result' operand. 3010 int ComponentList::num_operands() { 3011 PreserveIter pi(this); 3012 uint count = 1; // result operand 3013 uint position = 0; 3014 3015 Component *component = NULL; 3016 for( reset(); (component = iter()) != NULL; ++position ) { 3017 if( component->isa(Component::USE) || 3018 ( position == 0 && (! component->isa(Component::DEF))) ) { 3019 ++count; 3020 } 3021 } 3022 3023 return count; 3024 } 3025 3026 // Return zero-based position of operand 'name' in list; -1 if not in list. 3027 // if parameter 'usedef' is ::USE, it will match USE, USE_DEF, ... 3028 int ComponentList::operand_position(const char *name, int usedef, Form *fm) { 3029 PreserveIter pi(this); 3030 int position = 0; 3031 int num_opnds = num_operands(); 3032 Component *component; 3033 Component* preceding_non_use = NULL; 3034 Component* first_def = NULL; 3035 for (reset(); (component = iter()) != NULL; ++position) { 3036 // When the first component is not a DEF, 3037 // leave space for the result operand! 3038 if ( position==0 && (! component->isa(Component::DEF)) ) { 3039 ++position; 3040 ++num_opnds; 3041 } 3042 if (strcmp(name, component->_name)==0 && (component->isa(usedef))) { 3043 // When the first entry in the component list is a DEF and a USE 3044 // Treat them as being separate, a DEF first, then a USE 3045 if( position==0 3046 && usedef==Component::USE && component->isa(Component::DEF) ) { 3047 assert(position+1 < num_opnds, "advertised index in bounds"); 3048 return position+1; 3049 } else { 3050 if( preceding_non_use && strcmp(component->_name, preceding_non_use->_name) ) { 3051 fprintf(stderr, "the name '%s(%s)' should not precede the name '%s(%s)'", 3052 preceding_non_use->_name, preceding_non_use->getUsedefName(), 3053 name, component->getUsedefName()); 3054 if (fm && fm->is_instruction()) fprintf(stderr, "in form '%s'", fm->is_instruction()->_ident); 3055 if (fm && fm->is_operand()) fprintf(stderr, "in form '%s'", fm->is_operand()->_ident); 3056 fprintf(stderr, "\n"); 3057 } 3058 if( position >= num_opnds ) { 3059 fprintf(stderr, "the name '%s' is too late in its name list", name); 3060 if (fm && fm->is_instruction()) fprintf(stderr, "in form '%s'", fm->is_instruction()->_ident); 3061 if (fm && fm->is_operand()) fprintf(stderr, "in form '%s'", fm->is_operand()->_ident); 3062 fprintf(stderr, "\n"); 3063 } 3064 assert(position < num_opnds, "advertised index in bounds"); 3065 return position; 3066 } 3067 } 3068 if( component->isa(Component::DEF) 3069 && component->isa(Component::USE) ) { 3070 ++position; 3071 if( position != 1 ) --position; // only use two slots for the 1st USE_DEF 3072 } 3073 if( component->isa(Component::DEF) && !first_def ) { 3074 first_def = component; 3075 } 3076 if( !component->isa(Component::USE) && component != first_def ) { 3077 preceding_non_use = component; 3078 } else if( preceding_non_use && !strcmp(component->_name, preceding_non_use->_name) ) { 3079 preceding_non_use = NULL; 3080 } 3081 } 3082 return Not_in_list; 3083 } 3084 3085 // Find position for this name, regardless of use/def information 3086 int ComponentList::operand_position(const char *name) { 3087 PreserveIter pi(this); 3088 int position = 0; 3089 Component *component; 3090 for (reset(); (component = iter()) != NULL; ++position) { 3091 // When the first component is not a DEF, 3092 // leave space for the result operand! 3093 if ( position==0 && (! component->isa(Component::DEF)) ) { 3094 ++position; 3095 } 3096 if (strcmp(name, component->_name)==0) { 3097 return position; 3098 } 3099 if( component->isa(Component::DEF) 3100 && component->isa(Component::USE) ) { 3101 ++position; 3102 if( position != 1 ) --position; // only use two slots for the 1st USE_DEF 3103 } 3104 } 3105 return Not_in_list; 3106 } 3107 3108 int ComponentList::operand_position_format(const char *name, Form *fm) { 3109 PreserveIter pi(this); 3110 int first_position = operand_position(name); 3111 int use_position = operand_position(name, Component::USE, fm); 3112 3113 return ((first_position < use_position) ? use_position : first_position); 3114 } 3115 3116 int ComponentList::label_position() { 3117 PreserveIter pi(this); 3118 int position = 0; 3119 reset(); 3120 for( Component *comp; (comp = iter()) != NULL; ++position) { 3121 // When the first component is not a DEF, 3122 // leave space for the result operand! 3123 if ( position==0 && (! comp->isa(Component::DEF)) ) { 3124 ++position; 3125 } 3126 if (strcmp(comp->_type, "label")==0) { 3127 return position; 3128 } 3129 if( comp->isa(Component::DEF) 3130 && comp->isa(Component::USE) ) { 3131 ++position; 3132 if( position != 1 ) --position; // only use two slots for the 1st USE_DEF 3133 } 3134 } 3135 3136 return -1; 3137 } 3138 3139 int ComponentList::method_position() { 3140 PreserveIter pi(this); 3141 int position = 0; 3142 reset(); 3143 for( Component *comp; (comp = iter()) != NULL; ++position) { 3144 // When the first component is not a DEF, 3145 // leave space for the result operand! 3146 if ( position==0 && (! comp->isa(Component::DEF)) ) { 3147 ++position; 3148 } 3149 if (strcmp(comp->_type, "method")==0) { 3150 return position; 3151 } 3152 if( comp->isa(Component::DEF) 3153 && comp->isa(Component::USE) ) { 3154 ++position; 3155 if( position != 1 ) --position; // only use two slots for the 1st USE_DEF 3156 } 3157 } 3158 3159 return -1; 3160 } 3161 3162 void ComponentList::dump() { output(stderr); } 3163 3164 void ComponentList::output(FILE *fp) { 3165 PreserveIter pi(this); 3166 fprintf(fp, "\n"); 3167 Component *component; 3168 for (reset(); (component = iter()) != NULL;) { 3169 component->output(fp); 3170 } 3171 fprintf(fp, "\n"); 3172 } 3173 3174 //------------------------------MatchNode-------------------------------------- 3175 MatchNode::MatchNode(ArchDesc &ad, const char *result, const char *mexpr, 3176 const char *opType, MatchNode *lChild, MatchNode *rChild) 3177 : _AD(ad), _result(result), _name(mexpr), _opType(opType), 3178 _lChild(lChild), _rChild(rChild), _internalop(0), _numleaves(0), 3179 _commutative_id(0) { 3180 _numleaves = (lChild ? lChild->_numleaves : 0) 3181 + (rChild ? rChild->_numleaves : 0); 3182 } 3183 3184 MatchNode::MatchNode(ArchDesc &ad, MatchNode& mnode) 3185 : _AD(ad), _result(mnode._result), _name(mnode._name), 3186 _opType(mnode._opType), _lChild(mnode._lChild), _rChild(mnode._rChild), 3187 _internalop(0), _numleaves(mnode._numleaves), 3188 _commutative_id(mnode._commutative_id) { 3189 } 3190 3191 MatchNode::MatchNode(ArchDesc &ad, MatchNode& mnode, int clone) 3192 : _AD(ad), _result(mnode._result), _name(mnode._name), 3193 _opType(mnode._opType), 3194 _internalop(0), _numleaves(mnode._numleaves), 3195 _commutative_id(mnode._commutative_id) { 3196 if (mnode._lChild) { 3197 _lChild = new MatchNode(ad, *mnode._lChild, clone); 3198 } else { 3199 _lChild = NULL; 3200 } 3201 if (mnode._rChild) { 3202 _rChild = new MatchNode(ad, *mnode._rChild, clone); 3203 } else { 3204 _rChild = NULL; 3205 } 3206 } 3207 3208 MatchNode::~MatchNode() { 3209 // // This node may not own its children if copied via assignment 3210 // if( _lChild ) delete _lChild; 3211 // if( _rChild ) delete _rChild; 3212 } 3213 3214 bool MatchNode::find_type(const char *type, int &position) const { 3215 if ( (_lChild != NULL) && (_lChild->find_type(type, position)) ) return true; 3216 if ( (_rChild != NULL) && (_rChild->find_type(type, position)) ) return true; 3217 3218 if (strcmp(type,_opType)==0) { 3219 return true; 3220 } else { 3221 ++position; 3222 } 3223 return false; 3224 } 3225 3226 // Recursive call collecting info on top-level operands, not transitive. 3227 // Implementation does not modify state of internal structures. 3228 void MatchNode::append_components(FormDict& locals, ComponentList& components, 3229 bool def_flag) const { 3230 int usedef = def_flag ? Component::DEF : Component::USE; 3231 FormDict &globals = _AD.globalNames(); 3232 3233 assert (_name != NULL, "MatchNode::build_components encountered empty node\n"); 3234 // Base case 3235 if (_lChild==NULL && _rChild==NULL) { 3236 // If _opType is not an operation, do not build a component for it ##### 3237 const Form *f = globals[_opType]; 3238 if( f != NULL ) { 3239 // Add non-ideals that are operands, operand-classes, 3240 if( ! f->ideal_only() 3241 && (f->is_opclass() || f->is_operand()) ) { 3242 components.insert(_name, _opType, usedef, true); 3243 } 3244 } 3245 return; 3246 } 3247 // Promote results of "Set" to DEF 3248 bool tmpdef_flag = (!strcmp(_opType, "Set")) ? true : false; 3249 if (_lChild) _lChild->append_components(locals, components, tmpdef_flag); 3250 tmpdef_flag = false; // only applies to component immediately following 'Set' 3251 if (_rChild) _rChild->append_components(locals, components, tmpdef_flag); 3252 } 3253 3254 // Find the n'th base-operand in the match node, 3255 // recursively investigates match rules of user-defined operands. 3256 // 3257 // Implementation does not modify state of internal structures since they 3258 // can be shared. 3259 bool MatchNode::base_operand(uint &position, FormDict &globals, 3260 const char * &result, const char * &name, 3261 const char * &opType) const { 3262 assert (_name != NULL, "MatchNode::base_operand encountered empty node\n"); 3263 // Base case 3264 if (_lChild==NULL && _rChild==NULL) { 3265 // Check for special case: "Universe", "label" 3266 if (strcmp(_opType,"Universe") == 0 || strcmp(_opType,"label")==0 ) { 3267 if (position == 0) { 3268 result = _result; 3269 name = _name; 3270 opType = _opType; 3271 return 1; 3272 } else { 3273 -- position; 3274 return 0; 3275 } 3276 } 3277 3278 const Form *form = globals[_opType]; 3279 MatchNode *matchNode = NULL; 3280 // Check for user-defined type 3281 if (form) { 3282 // User operand or instruction? 3283 OperandForm *opForm = form->is_operand(); 3284 InstructForm *inForm = form->is_instruction(); 3285 if ( opForm ) { 3286 matchNode = (MatchNode*)opForm->_matrule; 3287 } else if ( inForm ) { 3288 matchNode = (MatchNode*)inForm->_matrule; 3289 } 3290 } 3291 // if this is user-defined, recurse on match rule 3292 // User-defined operand and instruction forms have a match-rule. 3293 if (matchNode) { 3294 return (matchNode->base_operand(position,globals,result,name,opType)); 3295 } else { 3296 // Either not a form, or a system-defined form (no match rule). 3297 if (position==0) { 3298 result = _result; 3299 name = _name; 3300 opType = _opType; 3301 return 1; 3302 } else { 3303 --position; 3304 return 0; 3305 } 3306 } 3307 3308 } else { 3309 // Examine the left child and right child as well 3310 if (_lChild) { 3311 if (_lChild->base_operand(position, globals, result, name, opType)) 3312 return 1; 3313 } 3314 3315 if (_rChild) { 3316 if (_rChild->base_operand(position, globals, result, name, opType)) 3317 return 1; 3318 } 3319 } 3320 3321 return 0; 3322 } 3323 3324 // Recursive call on all operands' match rules in my match rule. 3325 uint MatchNode::num_consts(FormDict &globals) const { 3326 uint index = 0; 3327 uint num_consts = 0; 3328 const char *result; 3329 const char *name; 3330 const char *opType; 3331 3332 for (uint position = index; 3333 base_operand(position,globals,result,name,opType); position = index) { 3334 ++index; 3335 if( ideal_to_const_type(opType) ) num_consts++; 3336 } 3337 3338 return num_consts; 3339 } 3340 3341 // Recursive call on all operands' match rules in my match rule. 3342 // Constants in match rule subtree with specified type 3343 uint MatchNode::num_consts(FormDict &globals, Form::DataType type) const { 3344 uint index = 0; 3345 uint num_consts = 0; 3346 const char *result; 3347 const char *name; 3348 const char *opType; 3349 3350 for (uint position = index; 3351 base_operand(position,globals,result,name,opType); position = index) { 3352 ++index; 3353 if( ideal_to_const_type(opType) == type ) num_consts++; 3354 } 3355 3356 return num_consts; 3357 } 3358 3359 // Recursive call on all operands' match rules in my match rule. 3360 uint MatchNode::num_const_ptrs(FormDict &globals) const { 3361 return num_consts( globals, Form::idealP ); 3362 } 3363 3364 bool MatchNode::sets_result() const { 3365 return ( (strcmp(_name,"Set") == 0) ? true : false ); 3366 } 3367 3368 const char *MatchNode::reduce_right(FormDict &globals) const { 3369 // If there is no right reduction, return NULL. 3370 const char *rightStr = NULL; 3371 3372 // If we are a "Set", start from the right child. 3373 const MatchNode *const mnode = sets_result() ? 3374 (const MatchNode *)this->_rChild : 3375 (const MatchNode *)this; 3376 3377 // If our right child exists, it is the right reduction 3378 if ( mnode->_rChild ) { 3379 rightStr = mnode->_rChild->_internalop ? mnode->_rChild->_internalop 3380 : mnode->_rChild->_opType; 3381 } 3382 // Else, May be simple chain rule: (Set dst operand_form), rightStr=NULL; 3383 return rightStr; 3384 } 3385 3386 const char *MatchNode::reduce_left(FormDict &globals) const { 3387 // If there is no left reduction, return NULL. 3388 const char *leftStr = NULL; 3389 3390 // If we are a "Set", start from the right child. 3391 const MatchNode *const mnode = sets_result() ? 3392 (const MatchNode *)this->_rChild : 3393 (const MatchNode *)this; 3394 3395 // If our left child exists, it is the left reduction 3396 if ( mnode->_lChild ) { 3397 leftStr = mnode->_lChild->_internalop ? mnode->_lChild->_internalop 3398 : mnode->_lChild->_opType; 3399 } else { 3400 // May be simple chain rule: (Set dst operand_form_source) 3401 if ( sets_result() ) { 3402 OperandForm *oper = globals[mnode->_opType]->is_operand(); 3403 if( oper ) { 3404 leftStr = mnode->_opType; 3405 } 3406 } 3407 } 3408 return leftStr; 3409 } 3410 3411 //------------------------------count_instr_names------------------------------ 3412 // Count occurrences of operands names in the leaves of the instruction 3413 // match rule. 3414 void MatchNode::count_instr_names( Dict &names ) { 3415 if( this == NULL ) return; 3416 if( _lChild ) _lChild->count_instr_names(names); 3417 if( _rChild ) _rChild->count_instr_names(names); 3418 if( !_lChild && !_rChild ) { 3419 uintptr_t cnt = (uintptr_t)names[_name]; 3420 cnt++; // One more name found 3421 names.Insert(_name,(void*)cnt); 3422 } 3423 } 3424 3425 //------------------------------build_instr_pred------------------------------- 3426 // Build a path to 'name' in buf. Actually only build if cnt is zero, so we 3427 // can skip some leading instances of 'name'. 3428 int MatchNode::build_instr_pred( char *buf, const char *name, int cnt ) { 3429 if( _lChild ) { 3430 if( !cnt ) strcpy( buf, "_kids[0]->" ); 3431 cnt = _lChild->build_instr_pred( buf+strlen(buf), name, cnt ); 3432 if( cnt < 0 ) return cnt; // Found it, all done 3433 } 3434 if( _rChild ) { 3435 if( !cnt ) strcpy( buf, "_kids[1]->" ); 3436 cnt = _rChild->build_instr_pred( buf+strlen(buf), name, cnt ); 3437 if( cnt < 0 ) return cnt; // Found it, all done 3438 } 3439 if( !_lChild && !_rChild ) { // Found a leaf 3440 // Wrong name? Give up... 3441 if( strcmp(name,_name) ) return cnt; 3442 if( !cnt ) strcpy(buf,"_leaf"); 3443 return cnt-1; 3444 } 3445 return cnt; 3446 } 3447 3448 3449 //------------------------------build_internalop------------------------------- 3450 // Build string representation of subtree 3451 void MatchNode::build_internalop( ) { 3452 char *iop, *subtree; 3453 const char *lstr, *rstr; 3454 // Build string representation of subtree 3455 // Operation lchildType rchildType 3456 int len = (int)strlen(_opType) + 4; 3457 lstr = (_lChild) ? ((_lChild->_internalop) ? 3458 _lChild->_internalop : _lChild->_opType) : ""; 3459 rstr = (_rChild) ? ((_rChild->_internalop) ? 3460 _rChild->_internalop : _rChild->_opType) : ""; 3461 len += (int)strlen(lstr) + (int)strlen(rstr); 3462 subtree = (char *)malloc(len); 3463 sprintf(subtree,"_%s_%s_%s", _opType, lstr, rstr); 3464 // Hash the subtree string in _internalOps; if a name exists, use it 3465 iop = (char *)_AD._internalOps[subtree]; 3466 // Else create a unique name, and add it to the hash table 3467 if (iop == NULL) { 3468 iop = subtree; 3469 _AD._internalOps.Insert(subtree, iop); 3470 _AD._internalOpNames.addName(iop); 3471 _AD._internalMatch.Insert(iop, this); 3472 } 3473 // Add the internal operand name to the MatchNode 3474 _internalop = iop; 3475 _result = iop; 3476 } 3477 3478 3479 void MatchNode::dump() { 3480 output(stderr); 3481 } 3482 3483 void MatchNode::output(FILE *fp) { 3484 if (_lChild==0 && _rChild==0) { 3485 fprintf(fp," %s",_name); // operand 3486 } 3487 else { 3488 fprintf(fp," (%s ",_name); // " (opcodeName " 3489 if(_lChild) _lChild->output(fp); // left operand 3490 if(_rChild) _rChild->output(fp); // right operand 3491 fprintf(fp,")"); // ")" 3492 } 3493 } 3494 3495 int MatchNode::needs_ideal_memory_edge(FormDict &globals) const { 3496 static const char *needs_ideal_memory_list[] = { 3497 "StoreI","StoreL","StoreP","StoreN","StoreNKlass","StoreD","StoreF" , 3498 "StoreB","StoreC","Store" ,"StoreFP", 3499 "LoadI", "LoadL", "LoadP" ,"LoadN", "LoadD" ,"LoadF" , 3500 "LoadB" , "LoadUB", "LoadUS" ,"LoadS" ,"Load" , 3501 "StoreVector", "LoadVector", 3502 "LoadRange", "LoadKlass", "LoadNKlass", "LoadL_unaligned", "LoadD_unaligned", 3503 "LoadPLocked", 3504 "StorePConditional", "StoreIConditional", "StoreLConditional", 3505 "CompareAndSwapB", "CompareAndSwapS", "CompareAndSwapI", "CompareAndSwapL", "CompareAndSwapP", "CompareAndSwapN", 3506 "WeakCompareAndSwapB", "WeakCompareAndSwapS", "WeakCompareAndSwapI", "WeakCompareAndSwapL", "WeakCompareAndSwapP", "WeakCompareAndSwapN", 3507 "CompareAndExchangeB", "CompareAndExchangeS", "CompareAndExchangeI", "CompareAndExchangeL", "CompareAndExchangeP", "CompareAndExchangeN", 3508 "StoreCM", 3509 "ClearArray", 3510 "GetAndSetB", "GetAndSetS", "GetAndAddI", "GetAndSetI", "GetAndSetP", 3511 "GetAndAddB", "GetAndAddS", "GetAndAddL", "GetAndSetL", "GetAndSetN", 3512 }; 3513 int cnt = sizeof(needs_ideal_memory_list)/sizeof(char*); 3514 if( strcmp(_opType,"PrefetchAllocation")==0 ) 3515 return 1; 3516 if( _lChild ) { 3517 const char *opType = _lChild->_opType; 3518 for( int i=0; i<cnt; i++ ) 3519 if( strcmp(opType,needs_ideal_memory_list[i]) == 0 ) 3520 return 1; 3521 if( _lChild->needs_ideal_memory_edge(globals) ) 3522 return 1; 3523 } 3524 if( _rChild ) { 3525 const char *opType = _rChild->_opType; 3526 for( int i=0; i<cnt; i++ ) 3527 if( strcmp(opType,needs_ideal_memory_list[i]) == 0 ) 3528 return 1; 3529 if( _rChild->needs_ideal_memory_edge(globals) ) 3530 return 1; 3531 } 3532 3533 return 0; 3534 } 3535 3536 // TRUE if defines a derived oop, and so needs a base oop edge present 3537 // post-matching. 3538 int MatchNode::needs_base_oop_edge() const { 3539 if( !strcmp(_opType,"AddP") ) return 1; 3540 if( strcmp(_opType,"Set") ) return 0; 3541 return !strcmp(_rChild->_opType,"AddP"); 3542 } 3543 3544 int InstructForm::needs_base_oop_edge(FormDict &globals) const { 3545 if( is_simple_chain_rule(globals) ) { 3546 const char *src = _matrule->_rChild->_opType; 3547 OperandForm *src_op = globals[src]->is_operand(); 3548 assert( src_op, "Not operand class of chain rule" ); 3549 return src_op->_matrule ? src_op->_matrule->needs_base_oop_edge() : 0; 3550 } // Else check instruction 3551 3552 return _matrule ? _matrule->needs_base_oop_edge() : 0; 3553 } 3554 3555 3556 //-------------------------cisc spilling methods------------------------------- 3557 // helper routines and methods for detecting cisc-spilling instructions 3558 //-------------------------cisc_spill_merge------------------------------------ 3559 int MatchNode::cisc_spill_merge(int left_spillable, int right_spillable) { 3560 int cisc_spillable = Maybe_cisc_spillable; 3561 3562 // Combine results of left and right checks 3563 if( (left_spillable == Maybe_cisc_spillable) && (right_spillable == Maybe_cisc_spillable) ) { 3564 // neither side is spillable, nor prevents cisc spilling 3565 cisc_spillable = Maybe_cisc_spillable; 3566 } 3567 else if( (left_spillable == Maybe_cisc_spillable) && (right_spillable > Maybe_cisc_spillable) ) { 3568 // right side is spillable 3569 cisc_spillable = right_spillable; 3570 } 3571 else if( (right_spillable == Maybe_cisc_spillable) && (left_spillable > Maybe_cisc_spillable) ) { 3572 // left side is spillable 3573 cisc_spillable = left_spillable; 3574 } 3575 else if( (left_spillable == Not_cisc_spillable) || (right_spillable == Not_cisc_spillable) ) { 3576 // left or right prevents cisc spilling this instruction 3577 cisc_spillable = Not_cisc_spillable; 3578 } 3579 else { 3580 // Only allow one to spill 3581 cisc_spillable = Not_cisc_spillable; 3582 } 3583 3584 return cisc_spillable; 3585 } 3586 3587 //-------------------------root_ops_match-------------------------------------- 3588 bool static root_ops_match(FormDict &globals, const char *op1, const char *op2) { 3589 // Base Case: check that the current operands/operations match 3590 assert( op1, "Must have op's name"); 3591 assert( op2, "Must have op's name"); 3592 const Form *form1 = globals[op1]; 3593 const Form *form2 = globals[op2]; 3594 3595 return (form1 == form2); 3596 } 3597 3598 //-------------------------cisc_spill_match_node------------------------------- 3599 // Recursively check two MatchRules for legal conversion via cisc-spilling 3600 int MatchNode::cisc_spill_match(FormDict& globals, RegisterForm* registers, MatchNode* mRule2, const char* &operand, const char* ®_type) { 3601 int cisc_spillable = Maybe_cisc_spillable; 3602 int left_spillable = Maybe_cisc_spillable; 3603 int right_spillable = Maybe_cisc_spillable; 3604 3605 // Check that each has same number of operands at this level 3606 if( (_lChild && !(mRule2->_lChild)) || (_rChild && !(mRule2->_rChild)) ) 3607 return Not_cisc_spillable; 3608 3609 // Base Case: check that the current operands/operations match 3610 // or are CISC spillable 3611 assert( _opType, "Must have _opType"); 3612 assert( mRule2->_opType, "Must have _opType"); 3613 const Form *form = globals[_opType]; 3614 const Form *form2 = globals[mRule2->_opType]; 3615 if( form == form2 ) { 3616 cisc_spillable = Maybe_cisc_spillable; 3617 } else { 3618 const InstructForm *form2_inst = form2 ? form2->is_instruction() : NULL; 3619 const char *name_left = mRule2->_lChild ? mRule2->_lChild->_opType : NULL; 3620 const char *name_right = mRule2->_rChild ? mRule2->_rChild->_opType : NULL; 3621 DataType data_type = Form::none; 3622 if (form->is_operand()) { 3623 // Make sure the loadX matches the type of the reg 3624 data_type = form->ideal_to_Reg_type(form->is_operand()->ideal_type(globals)); 3625 } 3626 // Detect reg vs (loadX memory) 3627 if( form->is_cisc_reg(globals) 3628 && form2_inst 3629 && data_type != Form::none 3630 && (is_load_from_memory(mRule2->_opType) == data_type) // reg vs. (load memory) 3631 && (name_left != NULL) // NOT (load) 3632 && (name_right == NULL) ) { // NOT (load memory foo) 3633 const Form *form2_left = name_left ? globals[name_left] : NULL; 3634 if( form2_left && form2_left->is_cisc_mem(globals) ) { 3635 cisc_spillable = Is_cisc_spillable; 3636 operand = _name; 3637 reg_type = _result; 3638 return Is_cisc_spillable; 3639 } else { 3640 cisc_spillable = Not_cisc_spillable; 3641 } 3642 } 3643 // Detect reg vs memory 3644 else if( form->is_cisc_reg(globals) && form2->is_cisc_mem(globals) ) { 3645 cisc_spillable = Is_cisc_spillable; 3646 operand = _name; 3647 reg_type = _result; 3648 return Is_cisc_spillable; 3649 } else { 3650 cisc_spillable = Not_cisc_spillable; 3651 } 3652 } 3653 3654 // If cisc is still possible, check rest of tree 3655 if( cisc_spillable == Maybe_cisc_spillable ) { 3656 // Check that each has same number of operands at this level 3657 if( (_lChild && !(mRule2->_lChild)) || (_rChild && !(mRule2->_rChild)) ) return Not_cisc_spillable; 3658 3659 // Check left operands 3660 if( (_lChild == NULL) && (mRule2->_lChild == NULL) ) { 3661 left_spillable = Maybe_cisc_spillable; 3662 } else if (_lChild != NULL) { 3663 left_spillable = _lChild->cisc_spill_match(globals, registers, mRule2->_lChild, operand, reg_type); 3664 } 3665 3666 // Check right operands 3667 if( (_rChild == NULL) && (mRule2->_rChild == NULL) ) { 3668 right_spillable = Maybe_cisc_spillable; 3669 } else if (_rChild != NULL) { 3670 right_spillable = _rChild->cisc_spill_match(globals, registers, mRule2->_rChild, operand, reg_type); 3671 } 3672 3673 // Combine results of left and right checks 3674 cisc_spillable = cisc_spill_merge(left_spillable, right_spillable); 3675 } 3676 3677 return cisc_spillable; 3678 } 3679 3680 //---------------------------cisc_spill_match_rule------------------------------ 3681 // Recursively check two MatchRules for legal conversion via cisc-spilling 3682 // This method handles the root of Match tree, 3683 // general recursive checks done in MatchNode 3684 int MatchRule::matchrule_cisc_spill_match(FormDict& globals, RegisterForm* registers, 3685 MatchRule* mRule2, const char* &operand, 3686 const char* ®_type) { 3687 int cisc_spillable = Maybe_cisc_spillable; 3688 int left_spillable = Maybe_cisc_spillable; 3689 int right_spillable = Maybe_cisc_spillable; 3690 3691 // Check that each sets a result 3692 if( !(sets_result() && mRule2->sets_result()) ) return Not_cisc_spillable; 3693 // Check that each has same number of operands at this level 3694 if( (_lChild && !(mRule2->_lChild)) || (_rChild && !(mRule2->_rChild)) ) return Not_cisc_spillable; 3695 3696 // Check left operands: at root, must be target of 'Set' 3697 if( (_lChild == NULL) || (mRule2->_lChild == NULL) ) { 3698 left_spillable = Not_cisc_spillable; 3699 } else { 3700 // Do not support cisc-spilling instruction's target location 3701 if( root_ops_match(globals, _lChild->_opType, mRule2->_lChild->_opType) ) { 3702 left_spillable = Maybe_cisc_spillable; 3703 } else { 3704 left_spillable = Not_cisc_spillable; 3705 } 3706 } 3707 3708 // Check right operands: recursive walk to identify reg->mem operand 3709 if( (_rChild == NULL) && (mRule2->_rChild == NULL) ) { 3710 right_spillable = Maybe_cisc_spillable; 3711 } else { 3712 right_spillable = _rChild->cisc_spill_match(globals, registers, mRule2->_rChild, operand, reg_type); 3713 } 3714 3715 // Combine results of left and right checks 3716 cisc_spillable = cisc_spill_merge(left_spillable, right_spillable); 3717 3718 return cisc_spillable; 3719 } 3720 3721 //----------------------------- equivalent ------------------------------------ 3722 // Recursively check to see if two match rules are equivalent. 3723 // This rule handles the root. 3724 bool MatchRule::equivalent(FormDict &globals, MatchNode *mRule2) { 3725 // Check that each sets a result 3726 if (sets_result() != mRule2->sets_result()) { 3727 return false; 3728 } 3729 3730 // Check that the current operands/operations match 3731 assert( _opType, "Must have _opType"); 3732 assert( mRule2->_opType, "Must have _opType"); 3733 const Form *form = globals[_opType]; 3734 const Form *form2 = globals[mRule2->_opType]; 3735 if( form != form2 ) { 3736 return false; 3737 } 3738 3739 if (_lChild ) { 3740 if( !_lChild->equivalent(globals, mRule2->_lChild) ) 3741 return false; 3742 } else if (mRule2->_lChild) { 3743 return false; // I have NULL left child, mRule2 has non-NULL left child. 3744 } 3745 3746 if (_rChild ) { 3747 if( !_rChild->equivalent(globals, mRule2->_rChild) ) 3748 return false; 3749 } else if (mRule2->_rChild) { 3750 return false; // I have NULL right child, mRule2 has non-NULL right child. 3751 } 3752 3753 // We've made it through the gauntlet. 3754 return true; 3755 } 3756 3757 //----------------------------- equivalent ------------------------------------ 3758 // Recursively check to see if two match rules are equivalent. 3759 // This rule handles the operands. 3760 bool MatchNode::equivalent(FormDict &globals, MatchNode *mNode2) { 3761 if( !mNode2 ) 3762 return false; 3763 3764 // Check that the current operands/operations match 3765 assert( _opType, "Must have _opType"); 3766 assert( mNode2->_opType, "Must have _opType"); 3767 const Form *form = globals[_opType]; 3768 const Form *form2 = globals[mNode2->_opType]; 3769 if( form != form2 ) { 3770 return false; 3771 } 3772 3773 // Check that their children also match 3774 if (_lChild ) { 3775 if( !_lChild->equivalent(globals, mNode2->_lChild) ) 3776 return false; 3777 } else if (mNode2->_lChild) { 3778 return false; // I have NULL left child, mNode2 has non-NULL left child. 3779 } 3780 3781 if (_rChild ) { 3782 if( !_rChild->equivalent(globals, mNode2->_rChild) ) 3783 return false; 3784 } else if (mNode2->_rChild) { 3785 return false; // I have NULL right child, mNode2 has non-NULL right child. 3786 } 3787 3788 // We've made it through the gauntlet. 3789 return true; 3790 } 3791 3792 //-------------------------- has_commutative_op ------------------------------- 3793 // Recursively check for commutative operations with subtree operands 3794 // which could be swapped. 3795 void MatchNode::count_commutative_op(int& count) { 3796 static const char *commut_op_list[] = { 3797 "AddI","AddL","AddF","AddD", 3798 "AddVB","AddVS","AddVI","AddVL","AddVF","AddVD", 3799 "AndI","AndL", 3800 "AndV", 3801 "MaxI","MinI", 3802 "MulI","MulL","MulF","MulD", 3803 "MulVS","MulVI","MulVL","MulVF","MulVD", 3804 "OrI","OrL", 3805 "OrV", 3806 "XorI","XorL", 3807 "XorV" 3808 }; 3809 int cnt = sizeof(commut_op_list)/sizeof(char*); 3810 3811 if( _lChild && _rChild && (_lChild->_lChild || _rChild->_lChild) ) { 3812 // Don't swap if right operand is an immediate constant. 3813 bool is_const = false; 3814 if( _rChild->_lChild == NULL && _rChild->_rChild == NULL ) { 3815 FormDict &globals = _AD.globalNames(); 3816 const Form *form = globals[_rChild->_opType]; 3817 if ( form ) { 3818 OperandForm *oper = form->is_operand(); 3819 if( oper && oper->interface_type(globals) == Form::constant_interface ) 3820 is_const = true; 3821 } 3822 } 3823 if( !is_const ) { 3824 for( int i=0; i<cnt; i++ ) { 3825 if( strcmp(_opType, commut_op_list[i]) == 0 ) { 3826 count++; 3827 _commutative_id = count; // id should be > 0 3828 break; 3829 } 3830 } 3831 } 3832 } 3833 if( _lChild ) 3834 _lChild->count_commutative_op(count); 3835 if( _rChild ) 3836 _rChild->count_commutative_op(count); 3837 } 3838 3839 //-------------------------- swap_commutative_op ------------------------------ 3840 // Recursively swap specified commutative operation with subtree operands. 3841 void MatchNode::swap_commutative_op(bool atroot, int id) { 3842 if( _commutative_id == id ) { // id should be > 0 3843 assert(_lChild && _rChild && (_lChild->_lChild || _rChild->_lChild ), 3844 "not swappable operation"); 3845 MatchNode* tmp = _lChild; 3846 _lChild = _rChild; 3847 _rChild = tmp; 3848 // Don't exit here since we need to build internalop. 3849 } 3850 3851 bool is_set = ( strcmp(_opType, "Set") == 0 ); 3852 if( _lChild ) 3853 _lChild->swap_commutative_op(is_set, id); 3854 if( _rChild ) 3855 _rChild->swap_commutative_op(is_set, id); 3856 3857 // If not the root, reduce this subtree to an internal operand 3858 if( !atroot && (_lChild || _rChild) ) { 3859 build_internalop(); 3860 } 3861 } 3862 3863 //-------------------------- swap_commutative_op ------------------------------ 3864 // Recursively swap specified commutative operation with subtree operands. 3865 void MatchRule::matchrule_swap_commutative_op(const char* instr_ident, int count, int& match_rules_cnt) { 3866 assert(match_rules_cnt < 100," too many match rule clones"); 3867 // Clone 3868 MatchRule* clone = new MatchRule(_AD, this); 3869 // Swap operands of commutative operation 3870 ((MatchNode*)clone)->swap_commutative_op(true, count); 3871 char* buf = (char*) malloc(strlen(instr_ident) + 4); 3872 sprintf(buf, "%s_%d", instr_ident, match_rules_cnt++); 3873 clone->_result = buf; 3874 3875 clone->_next = this->_next; 3876 this-> _next = clone; 3877 if( (--count) > 0 ) { 3878 this-> matchrule_swap_commutative_op(instr_ident, count, match_rules_cnt); 3879 clone->matchrule_swap_commutative_op(instr_ident, count, match_rules_cnt); 3880 } 3881 } 3882 3883 //------------------------------MatchRule-------------------------------------- 3884 MatchRule::MatchRule(ArchDesc &ad) 3885 : MatchNode(ad), _depth(0), _construct(NULL), _numchilds(0) { 3886 _next = NULL; 3887 } 3888 3889 MatchRule::MatchRule(ArchDesc &ad, MatchRule* mRule) 3890 : MatchNode(ad, *mRule, 0), _depth(mRule->_depth), 3891 _construct(mRule->_construct), _numchilds(mRule->_numchilds) { 3892 _next = NULL; 3893 } 3894 3895 MatchRule::MatchRule(ArchDesc &ad, MatchNode* mroot, int depth, char *cnstr, 3896 int numleaves) 3897 : MatchNode(ad,*mroot), _depth(depth), _construct(cnstr), 3898 _numchilds(0) { 3899 _next = NULL; 3900 mroot->_lChild = NULL; 3901 mroot->_rChild = NULL; 3902 delete mroot; 3903 _numleaves = numleaves; 3904 _numchilds = (_lChild ? 1 : 0) + (_rChild ? 1 : 0); 3905 } 3906 MatchRule::~MatchRule() { 3907 } 3908 3909 // Recursive call collecting info on top-level operands, not transitive. 3910 // Implementation does not modify state of internal structures. 3911 void MatchRule::append_components(FormDict& locals, ComponentList& components, bool def_flag) const { 3912 assert (_name != NULL, "MatchNode::build_components encountered empty node\n"); 3913 3914 MatchNode::append_components(locals, components, 3915 false /* not necessarily a def */); 3916 } 3917 3918 // Recursive call on all operands' match rules in my match rule. 3919 // Implementation does not modify state of internal structures since they 3920 // can be shared. 3921 // The MatchNode that is called first treats its 3922 bool MatchRule::base_operand(uint &position0, FormDict &globals, 3923 const char *&result, const char * &name, 3924 const char * &opType)const{ 3925 uint position = position0; 3926 3927 return (MatchNode::base_operand( position, globals, result, name, opType)); 3928 } 3929 3930 3931 bool MatchRule::is_base_register(FormDict &globals) const { 3932 uint position = 1; 3933 const char *result = NULL; 3934 const char *name = NULL; 3935 const char *opType = NULL; 3936 if (!base_operand(position, globals, result, name, opType)) { 3937 position = 0; 3938 if( base_operand(position, globals, result, name, opType) && 3939 (strcmp(opType,"RegI")==0 || 3940 strcmp(opType,"RegP")==0 || 3941 strcmp(opType,"RegN")==0 || 3942 strcmp(opType,"RegL")==0 || 3943 strcmp(opType,"RegF")==0 || 3944 strcmp(opType,"RegD")==0 || 3945 strcmp(opType,"VecS")==0 || 3946 strcmp(opType,"VecD")==0 || 3947 strcmp(opType,"VecX")==0 || 3948 strcmp(opType,"VecY")==0 || 3949 strcmp(opType,"VecZ")==0 || 3950 strcmp(opType,"Reg" )==0) ) { 3951 return 1; 3952 } 3953 } 3954 return 0; 3955 } 3956 3957 Form::DataType MatchRule::is_base_constant(FormDict &globals) const { 3958 uint position = 1; 3959 const char *result = NULL; 3960 const char *name = NULL; 3961 const char *opType = NULL; 3962 if (!base_operand(position, globals, result, name, opType)) { 3963 position = 0; 3964 if (base_operand(position, globals, result, name, opType)) { 3965 return ideal_to_const_type(opType); 3966 } 3967 } 3968 return Form::none; 3969 } 3970 3971 bool MatchRule::is_chain_rule(FormDict &globals) const { 3972 3973 // Check for chain rule, and do not generate a match list for it 3974 if ((_lChild == NULL) && (_rChild == NULL) ) { 3975 const Form *form = globals[_opType]; 3976 // If this is ideal, then it is a base match, not a chain rule. 3977 if ( form && form->is_operand() && (!form->ideal_only())) { 3978 return true; 3979 } 3980 } 3981 // Check for "Set" form of chain rule, and do not generate a match list 3982 if (_rChild) { 3983 const char *rch = _rChild->_opType; 3984 const Form *form = globals[rch]; 3985 if ((!strcmp(_opType,"Set") && 3986 ((form) && form->is_operand()))) { 3987 return true; 3988 } 3989 } 3990 return false; 3991 } 3992 3993 int MatchRule::is_ideal_copy() const { 3994 if( _rChild ) { 3995 const char *opType = _rChild->_opType; 3996 #if 1 3997 if( strcmp(opType,"CastIP")==0 ) 3998 return 1; 3999 #else 4000 if( strcmp(opType,"CastII")==0 ) 4001 return 1; 4002 // Do not treat *CastPP this way, because it 4003 // may transfer a raw pointer to an oop. 4004 // If the register allocator were to coalesce this 4005 // into a single LRG, the GC maps would be incorrect. 4006 //if( strcmp(opType,"CastPP")==0 ) 4007 // return 1; 4008 //if( strcmp(opType,"CheckCastPP")==0 ) 4009 // return 1; 4010 // 4011 // Do not treat CastX2P or CastP2X this way, because 4012 // raw pointers and int types are treated differently 4013 // when saving local & stack info for safepoints in 4014 // Output(). 4015 //if( strcmp(opType,"CastX2P")==0 ) 4016 // return 1; 4017 //if( strcmp(opType,"CastP2X")==0 ) 4018 // return 1; 4019 #endif 4020 } 4021 if( is_chain_rule(_AD.globalNames()) && 4022 _lChild && strncmp(_lChild->_opType,"stackSlot",9)==0 ) 4023 return 1; 4024 return 0; 4025 } 4026 4027 4028 int MatchRule::is_expensive() const { 4029 if( _rChild ) { 4030 const char *opType = _rChild->_opType; 4031 if( strcmp(opType,"AtanD")==0 || 4032 strcmp(opType,"DivD")==0 || 4033 strcmp(opType,"DivF")==0 || 4034 strcmp(opType,"DivI")==0 || 4035 strcmp(opType,"Log10D")==0 || 4036 strcmp(opType,"ModD")==0 || 4037 strcmp(opType,"ModF")==0 || 4038 strcmp(opType,"ModI")==0 || 4039 strcmp(opType,"SqrtD")==0 || 4040 strcmp(opType,"SqrtF")==0 || 4041 strcmp(opType,"TanD")==0 || 4042 strcmp(opType,"ConvD2F")==0 || 4043 strcmp(opType,"ConvD2I")==0 || 4044 strcmp(opType,"ConvD2L")==0 || 4045 strcmp(opType,"ConvF2D")==0 || 4046 strcmp(opType,"ConvF2I")==0 || 4047 strcmp(opType,"ConvF2L")==0 || 4048 strcmp(opType,"ConvI2D")==0 || 4049 strcmp(opType,"ConvI2F")==0 || 4050 strcmp(opType,"ConvI2L")==0 || 4051 strcmp(opType,"ConvL2D")==0 || 4052 strcmp(opType,"ConvL2F")==0 || 4053 strcmp(opType,"ConvL2I")==0 || 4054 strcmp(opType,"DecodeN")==0 || 4055 strcmp(opType,"EncodeP")==0 || 4056 strcmp(opType,"EncodePKlass")==0 || 4057 strcmp(opType,"DecodeNKlass")==0 || 4058 strcmp(opType,"FmaD") == 0 || 4059 strcmp(opType,"FmaF") == 0 || 4060 strcmp(opType,"RoundDouble")==0 || 4061 strcmp(opType,"RoundFloat")==0 || 4062 strcmp(opType,"ReverseBytesI")==0 || 4063 strcmp(opType,"ReverseBytesL")==0 || 4064 strcmp(opType,"ReverseBytesUS")==0 || 4065 strcmp(opType,"ReverseBytesS")==0 || 4066 strcmp(opType,"ReplicateB")==0 || 4067 strcmp(opType,"ReplicateS")==0 || 4068 strcmp(opType,"ReplicateI")==0 || 4069 strcmp(opType,"ReplicateL")==0 || 4070 strcmp(opType,"ReplicateF")==0 || 4071 strcmp(opType,"ReplicateD")==0 || 4072 strcmp(opType,"AddReductionVI")==0 || 4073 strcmp(opType,"AddReductionVL")==0 || 4074 strcmp(opType,"AddReductionVF")==0 || 4075 strcmp(opType,"AddReductionVD")==0 || 4076 strcmp(opType,"MulReductionVI")==0 || 4077 strcmp(opType,"MulReductionVL")==0 || 4078 strcmp(opType,"MulReductionVF")==0 || 4079 strcmp(opType,"MulReductionVD")==0 || 4080 0 /* 0 to line up columns nicely */ ) 4081 return 1; 4082 } 4083 return 0; 4084 } 4085 4086 bool MatchRule::is_ideal_if() const { 4087 if( !_opType ) return false; 4088 return 4089 !strcmp(_opType,"If" ) || 4090 !strcmp(_opType,"CountedLoopEnd"); 4091 } 4092 4093 bool MatchRule::is_ideal_fastlock() const { 4094 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4095 return (strcmp(_rChild->_opType,"FastLock") == 0); 4096 } 4097 return false; 4098 } 4099 4100 bool MatchRule::is_ideal_membar() const { 4101 if( !_opType ) return false; 4102 return 4103 !strcmp(_opType,"MemBarAcquire") || 4104 !strcmp(_opType,"MemBarRelease") || 4105 !strcmp(_opType,"MemBarAcquireLock") || 4106 !strcmp(_opType,"MemBarReleaseLock") || 4107 !strcmp(_opType,"LoadFence" ) || 4108 !strcmp(_opType,"StoreFence") || 4109 !strcmp(_opType,"MemBarVolatile") || 4110 !strcmp(_opType,"MemBarCPUOrder") || 4111 !strcmp(_opType,"MemBarStoreStore"); 4112 } 4113 4114 bool MatchRule::is_ideal_loadPC() const { 4115 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4116 return (strcmp(_rChild->_opType,"LoadPC") == 0); 4117 } 4118 return false; 4119 } 4120 4121 bool MatchRule::is_ideal_box() const { 4122 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4123 return (strcmp(_rChild->_opType,"Box") == 0); 4124 } 4125 return false; 4126 } 4127 4128 bool MatchRule::is_ideal_goto() const { 4129 bool ideal_goto = false; 4130 4131 if( _opType && (strcmp(_opType,"Goto") == 0) ) { 4132 ideal_goto = true; 4133 } 4134 return ideal_goto; 4135 } 4136 4137 bool MatchRule::is_ideal_jump() const { 4138 if( _opType ) { 4139 if( !strcmp(_opType,"Jump") ) 4140 return true; 4141 } 4142 return false; 4143 } 4144 4145 bool MatchRule::is_ideal_bool() const { 4146 if( _opType ) { 4147 if( !strcmp(_opType,"Bool") ) 4148 return true; 4149 } 4150 return false; 4151 } 4152 4153 4154 Form::DataType MatchRule::is_ideal_load() const { 4155 Form::DataType ideal_load = Form::none; 4156 4157 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4158 const char *opType = _rChild->_opType; 4159 ideal_load = is_load_from_memory(opType); 4160 } 4161 4162 return ideal_load; 4163 } 4164 4165 bool MatchRule::is_vector() const { 4166 static const char *vector_list[] = { 4167 "AddVB","AddVS","AddVI","AddVL","AddVF","AddVD", 4168 "SubVB","SubVS","SubVI","SubVL","SubVF","SubVD", 4169 "MulVS","MulVI","MulVL","MulVF","MulVD", 4170 "CMoveVD", "CMoveVF", 4171 "DivVF","DivVD", 4172 "AbsVF","AbsVD", 4173 "NegVF","NegVD", 4174 "SqrtVD","SqrtVF", 4175 "AndV" ,"XorV" ,"OrV", 4176 "AddReductionVI", "AddReductionVL", 4177 "AddReductionVF", "AddReductionVD", 4178 "MulReductionVI", "MulReductionVL", 4179 "MulReductionVF", "MulReductionVD", 4180 "LShiftCntV","RShiftCntV", 4181 "LShiftVB","LShiftVS","LShiftVI","LShiftVL", 4182 "RShiftVB","RShiftVS","RShiftVI","RShiftVL", 4183 "URShiftVB","URShiftVS","URShiftVI","URShiftVL", 4184 "ReplicateB","ReplicateS","ReplicateI","ReplicateL","ReplicateF","ReplicateD", 4185 "LoadVector","StoreVector", 4186 "FmaVD", "FmaVF","PopCountVI", 4187 // Next are not supported currently. 4188 "PackB","PackS","PackI","PackL","PackF","PackD","Pack2L","Pack2D", 4189 "ExtractB","ExtractUB","ExtractC","ExtractS","ExtractI","ExtractL","ExtractF","ExtractD" 4190 }; 4191 int cnt = sizeof(vector_list)/sizeof(char*); 4192 if (_rChild) { 4193 const char *opType = _rChild->_opType; 4194 for (int i=0; i<cnt; i++) 4195 if (strcmp(opType,vector_list[i]) == 0) 4196 return true; 4197 } 4198 return false; 4199 } 4200 4201 4202 bool MatchRule::skip_antidep_check() const { 4203 // Some loads operate on what is effectively immutable memory so we 4204 // should skip the anti dep computations. For some of these nodes 4205 // the rewritable field keeps the anti dep logic from triggering but 4206 // for certain kinds of LoadKlass it does not since they are 4207 // actually reading memory which could be rewritten by the runtime, 4208 // though never by generated code. This disables it uniformly for 4209 // the nodes that behave like this: LoadKlass, LoadNKlass and 4210 // LoadRange. 4211 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4212 const char *opType = _rChild->_opType; 4213 if (strcmp("LoadKlass", opType) == 0 || 4214 strcmp("LoadNKlass", opType) == 0 || 4215 strcmp("LoadRange", opType) == 0) { 4216 return true; 4217 } 4218 } 4219 4220 return false; 4221 } 4222 4223 4224 Form::DataType MatchRule::is_ideal_store() const { 4225 Form::DataType ideal_store = Form::none; 4226 4227 if ( _opType && (strcmp(_opType,"Set") == 0) && _rChild ) { 4228 const char *opType = _rChild->_opType; 4229 ideal_store = is_store_to_memory(opType); 4230 } 4231 4232 return ideal_store; 4233 } 4234 4235 4236 void MatchRule::dump() { 4237 output(stderr); 4238 } 4239 4240 // Write just one line. 4241 void MatchRule::output_short(FILE *fp) { 4242 fprintf(fp,"MatchRule: ( %s",_name); 4243 if (_lChild) _lChild->output(fp); 4244 if (_rChild) _rChild->output(fp); 4245 fprintf(fp," )"); 4246 } 4247 4248 void MatchRule::output(FILE *fp) { 4249 output_short(fp); 4250 fprintf(fp,"\n nesting depth = %d\n", _depth); 4251 if (_result) fprintf(fp," Result Type = %s", _result); 4252 fprintf(fp,"\n"); 4253 } 4254 4255 //------------------------------Attribute-------------------------------------- 4256 Attribute::Attribute(char *id, char* val, int type) 4257 : _ident(id), _val(val), _atype(type) { 4258 } 4259 Attribute::~Attribute() { 4260 } 4261 4262 int Attribute::int_val(ArchDesc &ad) { 4263 // Make sure it is an integer constant: 4264 int result = 0; 4265 if (!_val || !ADLParser::is_int_token(_val, result)) { 4266 ad.syntax_err(0, "Attribute %s must have an integer value: %s", 4267 _ident, _val ? _val : ""); 4268 } 4269 return result; 4270 } 4271 4272 void Attribute::dump() { 4273 output(stderr); 4274 } // Debug printer 4275 4276 // Write to output files 4277 void Attribute::output(FILE *fp) { 4278 fprintf(fp,"Attribute: %s %s\n", (_ident?_ident:""), (_val?_val:"")); 4279 } 4280 4281 //------------------------------FormatRule---------------------------------- 4282 FormatRule::FormatRule(char *temp) 4283 : _temp(temp) { 4284 } 4285 FormatRule::~FormatRule() { 4286 } 4287 4288 void FormatRule::dump() { 4289 output(stderr); 4290 } 4291 4292 // Write to output files 4293 void FormatRule::output(FILE *fp) { 4294 fprintf(fp,"\nFormat Rule: \n%s", (_temp?_temp:"")); 4295 fprintf(fp,"\n"); 4296 }