1 /* 2 * Copyright (c) 1997, 2010, 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 #ifndef CPU_SPARC_VM_ASSEMBLER_SPARC_HPP 26 #define CPU_SPARC_VM_ASSEMBLER_SPARC_HPP 27 28 class BiasedLockingCounters; 29 30 // <sys/trap.h> promises that the system will not use traps 16-31 31 #define ST_RESERVED_FOR_USER_0 0x10 32 33 /* Written: David Ungar 4/19/97 */ 34 35 // Contains all the definitions needed for sparc assembly code generation. 36 37 // Register aliases for parts of the system: 38 39 // 64 bit values can be kept in g1-g5, o1-o5 and o7 and all 64 bits are safe 40 // across context switches in V8+ ABI. Of course, there are no 64 bit regs 41 // in V8 ABI. All 64 bits are preserved in V9 ABI for all registers. 42 43 // g2-g4 are scratch registers called "application globals". Their 44 // meaning is reserved to the "compilation system"--which means us! 45 // They are are not supposed to be touched by ordinary C code, although 46 // highly-optimized C code might steal them for temps. They are safe 47 // across thread switches, and the ABI requires that they be safe 48 // across function calls. 49 // 50 // g1 and g3 are touched by more modules. V8 allows g1 to be clobbered 51 // across func calls, and V8+ also allows g5 to be clobbered across 52 // func calls. Also, g1 and g5 can get touched while doing shared 53 // library loading. 54 // 55 // We must not touch g7 (it is the thread-self register) and g6 is 56 // reserved for certain tools. g0, of course, is always zero. 57 // 58 // (Sources: SunSoft Compilers Group, thread library engineers.) 59 60 // %%%% The interpreter should be revisited to reduce global scratch regs. 61 62 // This global always holds the current JavaThread pointer: 63 64 REGISTER_DECLARATION(Register, G2_thread , G2); 65 REGISTER_DECLARATION(Register, G6_heapbase , G6); 66 67 // The following globals are part of the Java calling convention: 68 69 REGISTER_DECLARATION(Register, G5_method , G5); 70 REGISTER_DECLARATION(Register, G5_megamorphic_method , G5_method); 71 REGISTER_DECLARATION(Register, G5_inline_cache_reg , G5_method); 72 73 // The following globals are used for the new C1 & interpreter calling convention: 74 REGISTER_DECLARATION(Register, Gargs , G4); // pointing to the last argument 75 76 // This local is used to preserve G2_thread in the interpreter and in stubs: 77 REGISTER_DECLARATION(Register, L7_thread_cache , L7); 78 79 // These globals are used as scratch registers in the interpreter: 80 81 REGISTER_DECLARATION(Register, Gframe_size , G1); // SAME REG as G1_scratch 82 REGISTER_DECLARATION(Register, G1_scratch , G1); // also SAME 83 REGISTER_DECLARATION(Register, G3_scratch , G3); 84 REGISTER_DECLARATION(Register, G4_scratch , G4); 85 86 // These globals are used as short-lived scratch registers in the compiler: 87 88 REGISTER_DECLARATION(Register, Gtemp , G5); 89 90 // JSR 292 fixed register usages: 91 REGISTER_DECLARATION(Register, G5_method_type , G5); 92 REGISTER_DECLARATION(Register, G3_method_handle , G3); 93 REGISTER_DECLARATION(Register, L7_mh_SP_save , L7); 94 95 // The compiler requires that G5_megamorphic_method is G5_inline_cache_klass, 96 // because a single patchable "set" instruction (NativeMovConstReg, 97 // or NativeMovConstPatching for compiler1) instruction 98 // serves to set up either quantity, depending on whether the compiled 99 // call site is an inline cache or is megamorphic. See the function 100 // CompiledIC::set_to_megamorphic. 101 // 102 // If a inline cache targets an interpreted method, then the 103 // G5 register will be used twice during the call. First, 104 // the call site will be patched to load a compiledICHolder 105 // into G5. (This is an ordered pair of ic_klass, method.) 106 // The c2i adapter will first check the ic_klass, then load 107 // G5_method with the method part of the pair just before 108 // jumping into the interpreter. 109 // 110 // Note that G5_method is only the method-self for the interpreter, 111 // and is logically unrelated to G5_megamorphic_method. 112 // 113 // Invariants on G2_thread (the JavaThread pointer): 114 // - it should not be used for any other purpose anywhere 115 // - it must be re-initialized by StubRoutines::call_stub() 116 // - it must be preserved around every use of call_VM 117 118 // We can consider using g2/g3/g4 to cache more values than the 119 // JavaThread, such as the card-marking base or perhaps pointers into 120 // Eden. It's something of a waste to use them as scratch temporaries, 121 // since they are not supposed to be volatile. (Of course, if we find 122 // that Java doesn't benefit from application globals, then we can just 123 // use them as ordinary temporaries.) 124 // 125 // Since g1 and g5 (and/or g6) are the volatile (caller-save) registers, 126 // it makes sense to use them routinely for procedure linkage, 127 // whenever the On registers are not applicable. Examples: G5_method, 128 // G5_inline_cache_klass, and a double handful of miscellaneous compiler 129 // stubs. This means that compiler stubs, etc., should be kept to a 130 // maximum of two or three G-register arguments. 131 132 133 // stub frames 134 135 REGISTER_DECLARATION(Register, Lentry_args , L0); // pointer to args passed to callee (interpreter) not stub itself 136 137 // Interpreter frames 138 139 #ifdef CC_INTERP 140 REGISTER_DECLARATION(Register, Lstate , L0); // interpreter state object pointer 141 REGISTER_DECLARATION(Register, L1_scratch , L1); // scratch 142 REGISTER_DECLARATION(Register, Lmirror , L1); // mirror (for native methods only) 143 REGISTER_DECLARATION(Register, L2_scratch , L2); 144 REGISTER_DECLARATION(Register, L3_scratch , L3); 145 REGISTER_DECLARATION(Register, L4_scratch , L4); 146 REGISTER_DECLARATION(Register, Lscratch , L5); // C1 uses 147 REGISTER_DECLARATION(Register, Lscratch2 , L6); // C1 uses 148 REGISTER_DECLARATION(Register, L7_scratch , L7); // constant pool cache 149 REGISTER_DECLARATION(Register, O5_savedSP , O5); 150 REGISTER_DECLARATION(Register, I5_savedSP , I5); // Saved SP before bumping for locals. This is simply 151 // a copy SP, so in 64-bit it's a biased value. The bias 152 // is added and removed as needed in the frame code. 153 // Interface to signature handler 154 REGISTER_DECLARATION(Register, Llocals , L7); // pointer to locals for signature handler 155 REGISTER_DECLARATION(Register, Lmethod , L6); // methodOop when calling signature handler 156 157 #else 158 REGISTER_DECLARATION(Register, Lesp , L0); // expression stack pointer 159 REGISTER_DECLARATION(Register, Lbcp , L1); // pointer to next bytecode 160 REGISTER_DECLARATION(Register, Lmethod , L2); 161 REGISTER_DECLARATION(Register, Llocals , L3); 162 REGISTER_DECLARATION(Register, Largs , L3); // pointer to locals for signature handler 163 // must match Llocals in asm interpreter 164 REGISTER_DECLARATION(Register, Lmonitors , L4); 165 REGISTER_DECLARATION(Register, Lbyte_code , L5); 166 // When calling out from the interpreter we record SP so that we can remove any extra stack 167 // space allocated during adapter transitions. This register is only live from the point 168 // of the call until we return. 169 REGISTER_DECLARATION(Register, Llast_SP , L5); 170 REGISTER_DECLARATION(Register, Lscratch , L5); 171 REGISTER_DECLARATION(Register, Lscratch2 , L6); 172 REGISTER_DECLARATION(Register, LcpoolCache , L6); // constant pool cache 173 174 REGISTER_DECLARATION(Register, O5_savedSP , O5); 175 REGISTER_DECLARATION(Register, I5_savedSP , I5); // Saved SP before bumping for locals. This is simply 176 // a copy SP, so in 64-bit it's a biased value. The bias 177 // is added and removed as needed in the frame code. 178 REGISTER_DECLARATION(Register, IdispatchTables , I4); // Base address of the bytecode dispatch tables 179 REGISTER_DECLARATION(Register, IdispatchAddress , I3); // Register which saves the dispatch address for each bytecode 180 REGISTER_DECLARATION(Register, ImethodDataPtr , I2); // Pointer to the current method data 181 #endif /* CC_INTERP */ 182 183 // NOTE: Lscratch2 and LcpoolCache point to the same registers in 184 // the interpreter code. If Lscratch2 needs to be used for some 185 // purpose than LcpoolCache should be restore after that for 186 // the interpreter to work right 187 // (These assignments must be compatible with L7_thread_cache; see above.) 188 189 // Since Lbcp points into the middle of the method object, 190 // it is temporarily converted into a "bcx" during GC. 191 192 // Exception processing 193 // These registers are passed into exception handlers. 194 // All exception handlers require the exception object being thrown. 195 // In addition, an nmethod's exception handler must be passed 196 // the address of the call site within the nmethod, to allow 197 // proper selection of the applicable catch block. 198 // (Interpreter frames use their own bcp() for this purpose.) 199 // 200 // The Oissuing_pc value is not always needed. When jumping to a 201 // handler that is known to be interpreted, the Oissuing_pc value can be 202 // omitted. An actual catch block in compiled code receives (from its 203 // nmethod's exception handler) the thrown exception in the Oexception, 204 // but it doesn't need the Oissuing_pc. 205 // 206 // If an exception handler (either interpreted or compiled) 207 // discovers there is no applicable catch block, it updates 208 // the Oissuing_pc to the continuation PC of its own caller, 209 // pops back to that caller's stack frame, and executes that 210 // caller's exception handler. Obviously, this process will 211 // iterate until the control stack is popped back to a method 212 // containing an applicable catch block. A key invariant is 213 // that the Oissuing_pc value is always a value local to 214 // the method whose exception handler is currently executing. 215 // 216 // Note: The issuing PC value is __not__ a raw return address (I7 value). 217 // It is a "return pc", the address __following__ the call. 218 // Raw return addresses are converted to issuing PCs by frame::pc(), 219 // or by stubs. Issuing PCs can be used directly with PC range tables. 220 // 221 REGISTER_DECLARATION(Register, Oexception , O0); // exception being thrown 222 REGISTER_DECLARATION(Register, Oissuing_pc , O1); // where the exception is coming from 223 224 225 // These must occur after the declarations above 226 #ifndef DONT_USE_REGISTER_DEFINES 227 228 #define Gthread AS_REGISTER(Register, Gthread) 229 #define Gmethod AS_REGISTER(Register, Gmethod) 230 #define Gmegamorphic_method AS_REGISTER(Register, Gmegamorphic_method) 231 #define Ginline_cache_reg AS_REGISTER(Register, Ginline_cache_reg) 232 #define Gargs AS_REGISTER(Register, Gargs) 233 #define Lthread_cache AS_REGISTER(Register, Lthread_cache) 234 #define Gframe_size AS_REGISTER(Register, Gframe_size) 235 #define Gtemp AS_REGISTER(Register, Gtemp) 236 237 #ifdef CC_INTERP 238 #define Lstate AS_REGISTER(Register, Lstate) 239 #define Lesp AS_REGISTER(Register, Lesp) 240 #define L1_scratch AS_REGISTER(Register, L1_scratch) 241 #define Lmirror AS_REGISTER(Register, Lmirror) 242 #define L2_scratch AS_REGISTER(Register, L2_scratch) 243 #define L3_scratch AS_REGISTER(Register, L3_scratch) 244 #define L4_scratch AS_REGISTER(Register, L4_scratch) 245 #define Lscratch AS_REGISTER(Register, Lscratch) 246 #define Lscratch2 AS_REGISTER(Register, Lscratch2) 247 #define L7_scratch AS_REGISTER(Register, L7_scratch) 248 #define Ostate AS_REGISTER(Register, Ostate) 249 #else 250 #define Lesp AS_REGISTER(Register, Lesp) 251 #define Lbcp AS_REGISTER(Register, Lbcp) 252 #define Lmethod AS_REGISTER(Register, Lmethod) 253 #define Llocals AS_REGISTER(Register, Llocals) 254 #define Lmonitors AS_REGISTER(Register, Lmonitors) 255 #define Lbyte_code AS_REGISTER(Register, Lbyte_code) 256 #define Lscratch AS_REGISTER(Register, Lscratch) 257 #define Lscratch2 AS_REGISTER(Register, Lscratch2) 258 #define LcpoolCache AS_REGISTER(Register, LcpoolCache) 259 #endif /* ! CC_INTERP */ 260 261 #define Lentry_args AS_REGISTER(Register, Lentry_args) 262 #define I5_savedSP AS_REGISTER(Register, I5_savedSP) 263 #define O5_savedSP AS_REGISTER(Register, O5_savedSP) 264 #define IdispatchAddress AS_REGISTER(Register, IdispatchAddress) 265 #define ImethodDataPtr AS_REGISTER(Register, ImethodDataPtr) 266 #define IdispatchTables AS_REGISTER(Register, IdispatchTables) 267 268 #define Oexception AS_REGISTER(Register, Oexception) 269 #define Oissuing_pc AS_REGISTER(Register, Oissuing_pc) 270 271 272 #endif 273 274 // Address is an abstraction used to represent a memory location. 275 // 276 // Note: A register location is represented via a Register, not 277 // via an address for efficiency & simplicity reasons. 278 279 class Address VALUE_OBJ_CLASS_SPEC { 280 private: 281 Register _base; // Base register. 282 RegisterOrConstant _index_or_disp; // Index register or constant displacement. 283 RelocationHolder _rspec; 284 285 public: 286 Address() : _base(noreg), _index_or_disp(noreg) {} 287 288 Address(Register base, RegisterOrConstant index_or_disp) 289 : _base(base), 290 _index_or_disp(index_or_disp) { 291 } 292 293 Address(Register base, Register index) 294 : _base(base), 295 _index_or_disp(index) { 296 } 297 298 Address(Register base, int disp) 299 : _base(base), 300 _index_or_disp(disp) { 301 } 302 303 #ifdef ASSERT 304 // ByteSize is only a class when ASSERT is defined, otherwise it's an int. 305 Address(Register base, ByteSize disp) 306 : _base(base), 307 _index_or_disp(in_bytes(disp)) { 308 } 309 #endif 310 311 // accessors 312 Register base() const { return _base; } 313 Register index() const { return _index_or_disp.as_register(); } 314 int disp() const { return _index_or_disp.as_constant(); } 315 316 bool has_index() const { return _index_or_disp.is_register(); } 317 bool has_disp() const { return _index_or_disp.is_constant(); } 318 319 const relocInfo::relocType rtype() { return _rspec.type(); } 320 const RelocationHolder& rspec() { return _rspec; } 321 322 RelocationHolder rspec(int offset) const { 323 return offset == 0 ? _rspec : _rspec.plus(offset); 324 } 325 326 inline bool is_simm13(int offset = 0); // check disp+offset for overflow 327 328 Address plus_disp(int plusdisp) const { // bump disp by a small amount 329 assert(_index_or_disp.is_constant(), "must have a displacement"); 330 Address a(base(), disp() + plusdisp); 331 return a; 332 } 333 334 Address after_save() const { 335 Address a = (*this); 336 a._base = a._base->after_save(); 337 return a; 338 } 339 340 Address after_restore() const { 341 Address a = (*this); 342 a._base = a._base->after_restore(); 343 return a; 344 } 345 346 // Convert the raw encoding form into the form expected by the 347 // constructor for Address. 348 static Address make_raw(int base, int index, int scale, int disp, bool disp_is_oop); 349 350 friend class Assembler; 351 }; 352 353 354 class AddressLiteral VALUE_OBJ_CLASS_SPEC { 355 private: 356 address _address; 357 RelocationHolder _rspec; 358 359 RelocationHolder rspec_from_rtype(relocInfo::relocType rtype, address addr) { 360 switch (rtype) { 361 case relocInfo::external_word_type: 362 return external_word_Relocation::spec(addr); 363 case relocInfo::internal_word_type: 364 return internal_word_Relocation::spec(addr); 365 #ifdef _LP64 366 case relocInfo::opt_virtual_call_type: 367 return opt_virtual_call_Relocation::spec(); 368 case relocInfo::static_call_type: 369 return static_call_Relocation::spec(); 370 case relocInfo::runtime_call_type: 371 return runtime_call_Relocation::spec(); 372 #endif 373 case relocInfo::none: 374 return RelocationHolder(); 375 default: 376 ShouldNotReachHere(); 377 return RelocationHolder(); 378 } 379 } 380 381 protected: 382 // creation 383 AddressLiteral() : _address(NULL), _rspec(NULL) {} 384 385 public: 386 AddressLiteral(address addr, RelocationHolder const& rspec) 387 : _address(addr), 388 _rspec(rspec) {} 389 390 // Some constructors to avoid casting at the call site. 391 AddressLiteral(jobject obj, RelocationHolder const& rspec) 392 : _address((address) obj), 393 _rspec(rspec) {} 394 395 AddressLiteral(intptr_t value, RelocationHolder const& rspec) 396 : _address((address) value), 397 _rspec(rspec) {} 398 399 AddressLiteral(address addr, relocInfo::relocType rtype = relocInfo::none) 400 : _address((address) addr), 401 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 402 403 // Some constructors to avoid casting at the call site. 404 AddressLiteral(address* addr, relocInfo::relocType rtype = relocInfo::none) 405 : _address((address) addr), 406 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 407 408 AddressLiteral(bool* addr, relocInfo::relocType rtype = relocInfo::none) 409 : _address((address) addr), 410 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 411 412 AddressLiteral(const bool* addr, relocInfo::relocType rtype = relocInfo::none) 413 : _address((address) addr), 414 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 415 416 AddressLiteral(signed char* addr, relocInfo::relocType rtype = relocInfo::none) 417 : _address((address) addr), 418 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 419 420 AddressLiteral(int* addr, relocInfo::relocType rtype = relocInfo::none) 421 : _address((address) addr), 422 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 423 424 AddressLiteral(intptr_t addr, relocInfo::relocType rtype = relocInfo::none) 425 : _address((address) addr), 426 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 427 428 #ifdef _LP64 429 // 32-bit complains about a multiple declaration for int*. 430 AddressLiteral(intptr_t* addr, relocInfo::relocType rtype = relocInfo::none) 431 : _address((address) addr), 432 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 433 #endif 434 435 AddressLiteral(oop addr, relocInfo::relocType rtype = relocInfo::none) 436 : _address((address) addr), 437 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 438 439 AddressLiteral(float* addr, relocInfo::relocType rtype = relocInfo::none) 440 : _address((address) addr), 441 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 442 443 AddressLiteral(double* addr, relocInfo::relocType rtype = relocInfo::none) 444 : _address((address) addr), 445 _rspec(rspec_from_rtype(rtype, (address) addr)) {} 446 447 intptr_t value() const { return (intptr_t) _address; } 448 int low10() const; 449 450 const relocInfo::relocType rtype() const { return _rspec.type(); } 451 const RelocationHolder& rspec() const { return _rspec; } 452 453 RelocationHolder rspec(int offset) const { 454 return offset == 0 ? _rspec : _rspec.plus(offset); 455 } 456 }; 457 458 459 inline Address RegisterImpl::address_in_saved_window() const { 460 return (Address(SP, (sp_offset_in_saved_window() * wordSize) + STACK_BIAS)); 461 } 462 463 464 465 // Argument is an abstraction used to represent an outgoing 466 // actual argument or an incoming formal parameter, whether 467 // it resides in memory or in a register, in a manner consistent 468 // with the SPARC Application Binary Interface, or ABI. This is 469 // often referred to as the native or C calling convention. 470 471 class Argument VALUE_OBJ_CLASS_SPEC { 472 private: 473 int _number; 474 bool _is_in; 475 476 public: 477 #ifdef _LP64 478 enum { 479 n_register_parameters = 6, // only 6 registers may contain integer parameters 480 n_float_register_parameters = 16 // Can have up to 16 floating registers 481 }; 482 #else 483 enum { 484 n_register_parameters = 6 // only 6 registers may contain integer parameters 485 }; 486 #endif 487 488 // creation 489 Argument(int number, bool is_in) : _number(number), _is_in(is_in) {} 490 491 int number() const { return _number; } 492 bool is_in() const { return _is_in; } 493 bool is_out() const { return !is_in(); } 494 495 Argument successor() const { return Argument(number() + 1, is_in()); } 496 Argument as_in() const { return Argument(number(), true ); } 497 Argument as_out() const { return Argument(number(), false); } 498 499 // locating register-based arguments: 500 bool is_register() const { return _number < n_register_parameters; } 501 502 #ifdef _LP64 503 // locating Floating Point register-based arguments: 504 bool is_float_register() const { return _number < n_float_register_parameters; } 505 506 FloatRegister as_float_register() const { 507 assert(is_float_register(), "must be a register argument"); 508 return as_FloatRegister(( number() *2 ) + 1); 509 } 510 FloatRegister as_double_register() const { 511 assert(is_float_register(), "must be a register argument"); 512 return as_FloatRegister(( number() *2 )); 513 } 514 #endif 515 516 Register as_register() const { 517 assert(is_register(), "must be a register argument"); 518 return is_in() ? as_iRegister(number()) : as_oRegister(number()); 519 } 520 521 // locating memory-based arguments 522 Address as_address() const { 523 assert(!is_register(), "must be a memory argument"); 524 return address_in_frame(); 525 } 526 527 // When applied to a register-based argument, give the corresponding address 528 // into the 6-word area "into which callee may store register arguments" 529 // (This is a different place than the corresponding register-save area location.) 530 Address address_in_frame() const; 531 532 // debugging 533 const char* name() const; 534 535 friend class Assembler; 536 }; 537 538 539 // The SPARC Assembler: Pure assembler doing NO optimizations on the instruction 540 // level; i.e., what you write 541 // is what you get. The Assembler is generating code into a CodeBuffer. 542 543 class Assembler : public AbstractAssembler { 544 protected: 545 546 static void print_instruction(int inst); 547 static int patched_branch(int dest_pos, int inst, int inst_pos); 548 static int branch_destination(int inst, int pos); 549 550 551 friend class AbstractAssembler; 552 friend class AddressLiteral; 553 554 // code patchers need various routines like inv_wdisp() 555 friend class NativeInstruction; 556 friend class NativeGeneralJump; 557 friend class Relocation; 558 friend class Label; 559 560 public: 561 // op carries format info; see page 62 & 267 562 563 enum ops { 564 call_op = 1, // fmt 1 565 branch_op = 0, // also sethi (fmt2) 566 arith_op = 2, // fmt 3, arith & misc 567 ldst_op = 3 // fmt 3, load/store 568 }; 569 570 enum op2s { 571 bpr_op2 = 3, 572 fb_op2 = 6, 573 fbp_op2 = 5, 574 br_op2 = 2, 575 bp_op2 = 1, 576 cb_op2 = 7, // V8 577 sethi_op2 = 4 578 }; 579 580 enum op3s { 581 // selected op3s 582 add_op3 = 0x00, 583 and_op3 = 0x01, 584 or_op3 = 0x02, 585 xor_op3 = 0x03, 586 sub_op3 = 0x04, 587 andn_op3 = 0x05, 588 orn_op3 = 0x06, 589 xnor_op3 = 0x07, 590 addc_op3 = 0x08, 591 mulx_op3 = 0x09, 592 umul_op3 = 0x0a, 593 smul_op3 = 0x0b, 594 subc_op3 = 0x0c, 595 udivx_op3 = 0x0d, 596 udiv_op3 = 0x0e, 597 sdiv_op3 = 0x0f, 598 599 addcc_op3 = 0x10, 600 andcc_op3 = 0x11, 601 orcc_op3 = 0x12, 602 xorcc_op3 = 0x13, 603 subcc_op3 = 0x14, 604 andncc_op3 = 0x15, 605 orncc_op3 = 0x16, 606 xnorcc_op3 = 0x17, 607 addccc_op3 = 0x18, 608 umulcc_op3 = 0x1a, 609 smulcc_op3 = 0x1b, 610 subccc_op3 = 0x1c, 611 udivcc_op3 = 0x1e, 612 sdivcc_op3 = 0x1f, 613 614 taddcc_op3 = 0x20, 615 tsubcc_op3 = 0x21, 616 taddcctv_op3 = 0x22, 617 tsubcctv_op3 = 0x23, 618 mulscc_op3 = 0x24, 619 sll_op3 = 0x25, 620 sllx_op3 = 0x25, 621 srl_op3 = 0x26, 622 srlx_op3 = 0x26, 623 sra_op3 = 0x27, 624 srax_op3 = 0x27, 625 rdreg_op3 = 0x28, 626 membar_op3 = 0x28, 627 628 flushw_op3 = 0x2b, 629 movcc_op3 = 0x2c, 630 sdivx_op3 = 0x2d, 631 popc_op3 = 0x2e, 632 movr_op3 = 0x2f, 633 634 sir_op3 = 0x30, 635 wrreg_op3 = 0x30, 636 saved_op3 = 0x31, 637 638 fpop1_op3 = 0x34, 639 fpop2_op3 = 0x35, 640 impdep1_op3 = 0x36, 641 impdep2_op3 = 0x37, 642 jmpl_op3 = 0x38, 643 rett_op3 = 0x39, 644 trap_op3 = 0x3a, 645 flush_op3 = 0x3b, 646 save_op3 = 0x3c, 647 restore_op3 = 0x3d, 648 done_op3 = 0x3e, 649 retry_op3 = 0x3e, 650 651 lduw_op3 = 0x00, 652 ldub_op3 = 0x01, 653 lduh_op3 = 0x02, 654 ldd_op3 = 0x03, 655 stw_op3 = 0x04, 656 stb_op3 = 0x05, 657 sth_op3 = 0x06, 658 std_op3 = 0x07, 659 ldsw_op3 = 0x08, 660 ldsb_op3 = 0x09, 661 ldsh_op3 = 0x0a, 662 ldx_op3 = 0x0b, 663 664 ldstub_op3 = 0x0d, 665 stx_op3 = 0x0e, 666 swap_op3 = 0x0f, 667 668 stwa_op3 = 0x14, 669 stxa_op3 = 0x1e, 670 671 ldf_op3 = 0x20, 672 ldfsr_op3 = 0x21, 673 ldqf_op3 = 0x22, 674 lddf_op3 = 0x23, 675 stf_op3 = 0x24, 676 stfsr_op3 = 0x25, 677 stqf_op3 = 0x26, 678 stdf_op3 = 0x27, 679 680 prefetch_op3 = 0x2d, 681 682 683 ldc_op3 = 0x30, 684 ldcsr_op3 = 0x31, 685 lddc_op3 = 0x33, 686 stc_op3 = 0x34, 687 stcsr_op3 = 0x35, 688 stdcq_op3 = 0x36, 689 stdc_op3 = 0x37, 690 691 casa_op3 = 0x3c, 692 casxa_op3 = 0x3e, 693 694 alt_bit_op3 = 0x10, 695 cc_bit_op3 = 0x10 696 }; 697 698 enum opfs { 699 // selected opfs 700 fmovs_opf = 0x01, 701 fmovd_opf = 0x02, 702 703 fnegs_opf = 0x05, 704 fnegd_opf = 0x06, 705 706 fadds_opf = 0x41, 707 faddd_opf = 0x42, 708 fsubs_opf = 0x45, 709 fsubd_opf = 0x46, 710 711 fmuls_opf = 0x49, 712 fmuld_opf = 0x4a, 713 fdivs_opf = 0x4d, 714 fdivd_opf = 0x4e, 715 716 fcmps_opf = 0x51, 717 fcmpd_opf = 0x52, 718 719 fstox_opf = 0x81, 720 fdtox_opf = 0x82, 721 fxtos_opf = 0x84, 722 fxtod_opf = 0x88, 723 fitos_opf = 0xc4, 724 fdtos_opf = 0xc6, 725 fitod_opf = 0xc8, 726 fstod_opf = 0xc9, 727 fstoi_opf = 0xd1, 728 fdtoi_opf = 0xd2 729 }; 730 731 enum RCondition { rc_z = 1, rc_lez = 2, rc_lz = 3, rc_nz = 5, rc_gz = 6, rc_gez = 7 }; 732 733 enum Condition { 734 // for FBfcc & FBPfcc instruction 735 f_never = 0, 736 f_notEqual = 1, 737 f_notZero = 1, 738 f_lessOrGreater = 2, 739 f_unorderedOrLess = 3, 740 f_less = 4, 741 f_unorderedOrGreater = 5, 742 f_greater = 6, 743 f_unordered = 7, 744 f_always = 8, 745 f_equal = 9, 746 f_zero = 9, 747 f_unorderedOrEqual = 10, 748 f_greaterOrEqual = 11, 749 f_unorderedOrGreaterOrEqual = 12, 750 f_lessOrEqual = 13, 751 f_unorderedOrLessOrEqual = 14, 752 f_ordered = 15, 753 754 // V8 coproc, pp 123 v8 manual 755 756 cp_always = 8, 757 cp_never = 0, 758 cp_3 = 7, 759 cp_2 = 6, 760 cp_2or3 = 5, 761 cp_1 = 4, 762 cp_1or3 = 3, 763 cp_1or2 = 2, 764 cp_1or2or3 = 1, 765 cp_0 = 9, 766 cp_0or3 = 10, 767 cp_0or2 = 11, 768 cp_0or2or3 = 12, 769 cp_0or1 = 13, 770 cp_0or1or3 = 14, 771 cp_0or1or2 = 15, 772 773 774 // for integers 775 776 never = 0, 777 equal = 1, 778 zero = 1, 779 lessEqual = 2, 780 less = 3, 781 lessEqualUnsigned = 4, 782 lessUnsigned = 5, 783 carrySet = 5, 784 negative = 6, 785 overflowSet = 7, 786 always = 8, 787 notEqual = 9, 788 notZero = 9, 789 greater = 10, 790 greaterEqual = 11, 791 greaterUnsigned = 12, 792 greaterEqualUnsigned = 13, 793 carryClear = 13, 794 positive = 14, 795 overflowClear = 15 796 }; 797 798 enum CC { 799 icc = 0, xcc = 2, 800 // ptr_cc is the correct condition code for a pointer or intptr_t: 801 ptr_cc = NOT_LP64(icc) LP64_ONLY(xcc), 802 fcc0 = 0, fcc1 = 1, fcc2 = 2, fcc3 = 3 803 }; 804 805 enum PrefetchFcn { 806 severalReads = 0, oneRead = 1, severalWritesAndPossiblyReads = 2, oneWrite = 3, page = 4 807 }; 808 809 public: 810 // Helper functions for groups of instructions 811 812 enum Predict { pt = 1, pn = 0 }; // pt = predict taken 813 814 enum Membar_mask_bits { // page 184, v9 815 StoreStore = 1 << 3, 816 LoadStore = 1 << 2, 817 StoreLoad = 1 << 1, 818 LoadLoad = 1 << 0, 819 820 Sync = 1 << 6, 821 MemIssue = 1 << 5, 822 Lookaside = 1 << 4 823 }; 824 825 // test if x is within signed immediate range for nbits 826 static bool is_simm(int x, int nbits) { return -( 1 << nbits-1 ) <= x && x < ( 1 << nbits-1 ); } 827 828 // test if -4096 <= x <= 4095 829 static bool is_simm13(int x) { return is_simm(x, 13); } 830 831 // test if label is in simm16 range in words (wdisp16). 832 bool is_in_wdisp16_range(Label& L) { 833 intptr_t d = intptr_t(pc()) - intptr_t(target(L)); 834 return is_simm(d, 18); 835 } 836 837 enum ASIs { // page 72, v9 838 ASI_PRIMARY = 0x80, 839 ASI_PRIMARY_LITTLE = 0x88 840 // add more from book as needed 841 }; 842 843 protected: 844 // helpers 845 846 // x is supposed to fit in a field "nbits" wide 847 // and be sign-extended. Check the range. 848 849 static void assert_signed_range(intptr_t x, int nbits) { 850 assert( nbits == 32 851 || -(1 << nbits-1) <= x && x < ( 1 << nbits-1), 852 "value out of range"); 853 } 854 855 static void assert_signed_word_disp_range(intptr_t x, int nbits) { 856 assert( (x & 3) == 0, "not word aligned"); 857 assert_signed_range(x, nbits + 2); 858 } 859 860 static void assert_unsigned_const(int x, int nbits) { 861 assert( juint(x) < juint(1 << nbits), "unsigned constant out of range"); 862 } 863 864 // fields: note bits numbered from LSB = 0, 865 // fields known by inclusive bit range 866 867 static int fmask(juint hi_bit, juint lo_bit) { 868 assert( hi_bit >= lo_bit && 0 <= lo_bit && hi_bit < 32, "bad bits"); 869 return (1 << ( hi_bit-lo_bit + 1 )) - 1; 870 } 871 872 // inverse of u_field 873 874 static int inv_u_field(int x, int hi_bit, int lo_bit) { 875 juint r = juint(x) >> lo_bit; 876 r &= fmask( hi_bit, lo_bit); 877 return int(r); 878 } 879 880 881 // signed version: extract from field and sign-extend 882 883 static int inv_s_field(int x, int hi_bit, int lo_bit) { 884 int sign_shift = 31 - hi_bit; 885 return inv_u_field( ((x << sign_shift) >> sign_shift), hi_bit, lo_bit); 886 } 887 888 // given a field that ranges from hi_bit to lo_bit (inclusive, 889 // LSB = 0), and an unsigned value for the field, 890 // shift it into the field 891 892 #ifdef ASSERT 893 static int u_field(int x, int hi_bit, int lo_bit) { 894 assert( ( x & ~fmask(hi_bit, lo_bit)) == 0, 895 "value out of range"); 896 int r = x << lo_bit; 897 assert( inv_u_field(r, hi_bit, lo_bit) == x, "just checking"); 898 return r; 899 } 900 #else 901 // make sure this is inlined as it will reduce code size significantly 902 #define u_field(x, hi_bit, lo_bit) ((x) << (lo_bit)) 903 #endif 904 905 static int inv_op( int x ) { return inv_u_field(x, 31, 30); } 906 static int inv_op2( int x ) { return inv_u_field(x, 24, 22); } 907 static int inv_op3( int x ) { return inv_u_field(x, 24, 19); } 908 static int inv_cond( int x ){ return inv_u_field(x, 28, 25); } 909 910 static bool inv_immed( int x ) { return (x & Assembler::immed(true)) != 0; } 911 912 static Register inv_rd( int x ) { return as_Register(inv_u_field(x, 29, 25)); } 913 static Register inv_rs1( int x ) { return as_Register(inv_u_field(x, 18, 14)); } 914 static Register inv_rs2( int x ) { return as_Register(inv_u_field(x, 4, 0)); } 915 916 static int op( int x) { return u_field(x, 31, 30); } 917 static int rd( Register r) { return u_field(r->encoding(), 29, 25); } 918 static int fcn( int x) { return u_field(x, 29, 25); } 919 static int op3( int x) { return u_field(x, 24, 19); } 920 static int rs1( Register r) { return u_field(r->encoding(), 18, 14); } 921 static int rs2( Register r) { return u_field(r->encoding(), 4, 0); } 922 static int annul( bool a) { return u_field(a ? 1 : 0, 29, 29); } 923 static int cond( int x) { return u_field(x, 28, 25); } 924 static int cond_mov( int x) { return u_field(x, 17, 14); } 925 static int rcond( RCondition x) { return u_field(x, 12, 10); } 926 static int op2( int x) { return u_field(x, 24, 22); } 927 static int predict( bool p) { return u_field(p ? 1 : 0, 19, 19); } 928 static int branchcc( CC fcca) { return u_field(fcca, 21, 20); } 929 static int cmpcc( CC fcca) { return u_field(fcca, 26, 25); } 930 static int imm_asi( int x) { return u_field(x, 12, 5); } 931 static int immed( bool i) { return u_field(i ? 1 : 0, 13, 13); } 932 static int opf_low6( int w) { return u_field(w, 10, 5); } 933 static int opf_low5( int w) { return u_field(w, 9, 5); } 934 static int trapcc( CC cc) { return u_field(cc, 12, 11); } 935 static int sx( int i) { return u_field(i, 12, 12); } // shift x=1 means 64-bit 936 static int opf( int x) { return u_field(x, 13, 5); } 937 938 static int opf_cc( CC c, bool useFloat ) { return u_field((useFloat ? 0 : 4) + c, 13, 11); } 939 static int mov_cc( CC c, bool useFloat ) { return u_field(useFloat ? 0 : 1, 18, 18) | u_field(c, 12, 11); } 940 941 static int fd( FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 29, 25); }; 942 static int fs1(FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 18, 14); }; 943 static int fs2(FloatRegister r, FloatRegisterImpl::Width fwa) { return u_field(r->encoding(fwa), 4, 0); }; 944 945 // some float instructions use this encoding on the op3 field 946 static int alt_op3(int op, FloatRegisterImpl::Width w) { 947 int r; 948 switch(w) { 949 case FloatRegisterImpl::S: r = op + 0; break; 950 case FloatRegisterImpl::D: r = op + 3; break; 951 case FloatRegisterImpl::Q: r = op + 2; break; 952 default: ShouldNotReachHere(); break; 953 } 954 return op3(r); 955 } 956 957 958 // compute inverse of simm 959 static int inv_simm(int x, int nbits) { 960 return (int)(x << (32 - nbits)) >> (32 - nbits); 961 } 962 963 static int inv_simm13( int x ) { return inv_simm(x, 13); } 964 965 // signed immediate, in low bits, nbits long 966 static int simm(int x, int nbits) { 967 assert_signed_range(x, nbits); 968 return x & (( 1 << nbits ) - 1); 969 } 970 971 // compute inverse of wdisp16 972 static intptr_t inv_wdisp16(int x, intptr_t pos) { 973 int lo = x & (( 1 << 14 ) - 1); 974 int hi = (x >> 20) & 3; 975 if (hi >= 2) hi |= ~1; 976 return (((hi << 14) | lo) << 2) + pos; 977 } 978 979 // word offset, 14 bits at LSend, 2 bits at B21, B20 980 static int wdisp16(intptr_t x, intptr_t off) { 981 intptr_t xx = x - off; 982 assert_signed_word_disp_range(xx, 16); 983 int r = (xx >> 2) & ((1 << 14) - 1) 984 | ( ( (xx>>(2+14)) & 3 ) << 20 ); 985 assert( inv_wdisp16(r, off) == x, "inverse is not inverse"); 986 return r; 987 } 988 989 990 // word displacement in low-order nbits bits 991 992 static intptr_t inv_wdisp( int x, intptr_t pos, int nbits ) { 993 int pre_sign_extend = x & (( 1 << nbits ) - 1); 994 int r = pre_sign_extend >= ( 1 << (nbits-1) ) 995 ? pre_sign_extend | ~(( 1 << nbits ) - 1) 996 : pre_sign_extend; 997 return (r << 2) + pos; 998 } 999 1000 static int wdisp( intptr_t x, intptr_t off, int nbits ) { 1001 intptr_t xx = x - off; 1002 assert_signed_word_disp_range(xx, nbits); 1003 int r = (xx >> 2) & (( 1 << nbits ) - 1); 1004 assert( inv_wdisp( r, off, nbits ) == x, "inverse not inverse"); 1005 return r; 1006 } 1007 1008 1009 // Extract the top 32 bits in a 64 bit word 1010 static int32_t hi32( int64_t x ) { 1011 int32_t r = int32_t( (uint64_t)x >> 32 ); 1012 return r; 1013 } 1014 1015 // given a sethi instruction, extract the constant, left-justified 1016 static int inv_hi22( int x ) { 1017 return x << 10; 1018 } 1019 1020 // create an imm22 field, given a 32-bit left-justified constant 1021 static int hi22( int x ) { 1022 int r = int( juint(x) >> 10 ); 1023 assert( (r & ~((1 << 22) - 1)) == 0, "just checkin'"); 1024 return r; 1025 } 1026 1027 // create a low10 __value__ (not a field) for a given a 32-bit constant 1028 static int low10( int x ) { 1029 return x & ((1 << 10) - 1); 1030 } 1031 1032 // instruction only in v9 1033 static void v9_only() { assert( VM_Version::v9_instructions_work(), "This instruction only works on SPARC V9"); } 1034 1035 // instruction only in v8 1036 static void v8_only() { assert( VM_Version::v8_instructions_work(), "This instruction only works on SPARC V8"); } 1037 1038 // instruction deprecated in v9 1039 static void v9_dep() { } // do nothing for now 1040 1041 // some float instructions only exist for single prec. on v8 1042 static void v8_s_only(FloatRegisterImpl::Width w) { if (w != FloatRegisterImpl::S) v9_only(); } 1043 1044 // v8 has no CC field 1045 static void v8_no_cc(CC cc) { if (cc) v9_only(); } 1046 1047 protected: 1048 // Simple delay-slot scheme: 1049 // In order to check the programmer, the assembler keeps track of deley slots. 1050 // It forbids CTIs in delay slots (conservative, but should be OK). 1051 // Also, when putting an instruction into a delay slot, you must say 1052 // asm->delayed()->add(...), in order to check that you don't omit 1053 // delay-slot instructions. 1054 // To implement this, we use a simple FSA 1055 1056 #ifdef ASSERT 1057 #define CHECK_DELAY 1058 #endif 1059 #ifdef CHECK_DELAY 1060 enum Delay_state { no_delay, at_delay_slot, filling_delay_slot } delay_state; 1061 #endif 1062 1063 public: 1064 // Tells assembler next instruction must NOT be in delay slot. 1065 // Use at start of multinstruction macros. 1066 void assert_not_delayed() { 1067 // This is a separate overloading to avoid creation of string constants 1068 // in non-asserted code--with some compilers this pollutes the object code. 1069 #ifdef CHECK_DELAY 1070 assert_not_delayed("next instruction should not be a delay slot"); 1071 #endif 1072 } 1073 void assert_not_delayed(const char* msg) { 1074 #ifdef CHECK_DELAY 1075 assert(delay_state == no_delay, msg); 1076 #endif 1077 } 1078 1079 protected: 1080 // Delay slot helpers 1081 // cti is called when emitting control-transfer instruction, 1082 // BEFORE doing the emitting. 1083 // Only effective when assertion-checking is enabled. 1084 void cti() { 1085 #ifdef CHECK_DELAY 1086 assert_not_delayed("cti should not be in delay slot"); 1087 #endif 1088 } 1089 1090 // called when emitting cti with a delay slot, AFTER emitting 1091 void has_delay_slot() { 1092 #ifdef CHECK_DELAY 1093 assert_not_delayed("just checking"); 1094 delay_state = at_delay_slot; 1095 #endif 1096 } 1097 1098 public: 1099 // Tells assembler you know that next instruction is delayed 1100 Assembler* delayed() { 1101 #ifdef CHECK_DELAY 1102 assert ( delay_state == at_delay_slot, "delayed instruction is not in delay slot"); 1103 delay_state = filling_delay_slot; 1104 #endif 1105 return this; 1106 } 1107 1108 void flush() { 1109 #ifdef CHECK_DELAY 1110 assert ( delay_state == no_delay, "ending code with a delay slot"); 1111 #endif 1112 AbstractAssembler::flush(); 1113 } 1114 1115 inline void emit_long(int); // shadows AbstractAssembler::emit_long 1116 inline void emit_data(int x) { emit_long(x); } 1117 inline void emit_data(int, RelocationHolder const&); 1118 inline void emit_data(int, relocInfo::relocType rtype); 1119 // helper for above fcns 1120 inline void check_delay(); 1121 1122 1123 public: 1124 // instructions, refer to page numbers in the SPARC Architecture Manual, V9 1125 1126 // pp 135 (addc was addx in v8) 1127 1128 inline void add(Register s1, Register s2, Register d ); 1129 inline void add(Register s1, int simm13a, Register d, relocInfo::relocType rtype = relocInfo::none); 1130 inline void add(Register s1, int simm13a, Register d, RelocationHolder const& rspec); 1131 inline void add(Register s1, RegisterOrConstant s2, Register d, int offset = 0); 1132 inline void add(const Address& a, Register d, int offset = 0) { add( a.base(), a.disp() + offset, d, a.rspec(offset)); } 1133 1134 void addcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(add_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1135 void addcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(add_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1136 void addc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(addc_op3 ) | rs1(s1) | rs2(s2) ); } 1137 void addc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(addc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1138 void addccc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(addc_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1139 void addccc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(addc_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1140 1141 // pp 136 1142 1143 inline void bpr( RCondition c, bool a, Predict p, Register s1, address d, relocInfo::relocType rt = relocInfo::none ); 1144 inline void bpr( RCondition c, bool a, Predict p, Register s1, Label& L); 1145 1146 protected: // use MacroAssembler::br instead 1147 1148 // pp 138 1149 1150 inline void fb( Condition c, bool a, address d, relocInfo::relocType rt = relocInfo::none ); 1151 inline void fb( Condition c, bool a, Label& L ); 1152 1153 // pp 141 1154 1155 inline void fbp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1156 inline void fbp( Condition c, bool a, CC cc, Predict p, Label& L ); 1157 1158 public: 1159 1160 // pp 144 1161 1162 inline void br( Condition c, bool a, address d, relocInfo::relocType rt = relocInfo::none ); 1163 inline void br( Condition c, bool a, Label& L ); 1164 1165 // pp 146 1166 1167 inline void bp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1168 inline void bp( Condition c, bool a, CC cc, Predict p, Label& L ); 1169 1170 // pp 121 (V8) 1171 1172 inline void cb( Condition c, bool a, address d, relocInfo::relocType rt = relocInfo::none ); 1173 inline void cb( Condition c, bool a, Label& L ); 1174 1175 // pp 149 1176 1177 inline void call( address d, relocInfo::relocType rt = relocInfo::runtime_call_type ); 1178 inline void call( Label& L, relocInfo::relocType rt = relocInfo::runtime_call_type ); 1179 1180 // pp 150 1181 1182 // These instructions compare the contents of s2 with the contents of 1183 // memory at address in s1. If the values are equal, the contents of memory 1184 // at address s1 is swapped with the data in d. If the values are not equal, 1185 // the the contents of memory at s1 is loaded into d, without the swap. 1186 1187 void casa( Register s1, Register s2, Register d, int ia = -1 ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(casa_op3 ) | rs1(s1) | (ia == -1 ? immed(true) : imm_asi(ia)) | rs2(s2)); } 1188 void casxa( Register s1, Register s2, Register d, int ia = -1 ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(casxa_op3) | rs1(s1) | (ia == -1 ? immed(true) : imm_asi(ia)) | rs2(s2)); } 1189 1190 // pp 152 1191 1192 void udiv( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(udiv_op3 ) | rs1(s1) | rs2(s2)); } 1193 void udiv( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(udiv_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1194 void sdiv( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sdiv_op3 ) | rs1(s1) | rs2(s2)); } 1195 void sdiv( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sdiv_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1196 void udivcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(udiv_op3 | cc_bit_op3) | rs1(s1) | rs2(s2)); } 1197 void udivcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(udiv_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1198 void sdivcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sdiv_op3 | cc_bit_op3) | rs1(s1) | rs2(s2)); } 1199 void sdivcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sdiv_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1200 1201 // pp 155 1202 1203 void done() { v9_only(); cti(); emit_long( op(arith_op) | fcn(0) | op3(done_op3) ); } 1204 void retry() { v9_only(); cti(); emit_long( op(arith_op) | fcn(1) | op3(retry_op3) ); } 1205 1206 // pp 156 1207 1208 void fadd( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x40 + w) | fs2(s2, w)); } 1209 void fsub( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x44 + w) | fs2(s2, w)); } 1210 1211 // pp 157 1212 1213 void fcmp( FloatRegisterImpl::Width w, CC cc, FloatRegister s1, FloatRegister s2) { v8_no_cc(cc); emit_long( op(arith_op) | cmpcc(cc) | op3(fpop2_op3) | fs1(s1, w) | opf(0x50 + w) | fs2(s2, w)); } 1214 void fcmpe( FloatRegisterImpl::Width w, CC cc, FloatRegister s1, FloatRegister s2) { v8_no_cc(cc); emit_long( op(arith_op) | cmpcc(cc) | op3(fpop2_op3) | fs1(s1, w) | opf(0x54 + w) | fs2(s2, w)); } 1215 1216 // pp 159 1217 1218 void ftox( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v9_only(); emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x80 + w) | fs2(s, w)); } 1219 void ftoi( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0xd0 + w) | fs2(s, w)); } 1220 1221 // pp 160 1222 1223 void ftof( FloatRegisterImpl::Width sw, FloatRegisterImpl::Width dw, FloatRegister s, FloatRegister d ) { emit_long( op(arith_op) | fd(d, dw) | op3(fpop1_op3) | opf(0xc0 + sw + dw*4) | fs2(s, sw)); } 1224 1225 // pp 161 1226 1227 void fxtof( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v9_only(); emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x80 + w*4) | fs2(s, w)); } 1228 void fitof( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0xc0 + w*4) | fs2(s, w)); } 1229 1230 // pp 162 1231 1232 void fmov( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v8_s_only(w); emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x00 + w) | fs2(s, w)); } 1233 1234 void fneg( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v8_s_only(w); emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x04 + w) | fs2(s, w)); } 1235 1236 // page 144 sparc v8 architecture (double prec works on v8 if the source and destination registers are the same). fnegs is the only instruction available 1237 // on v8 to do negation of single, double and quad precision floats. 1238 1239 void fneg( FloatRegisterImpl::Width w, FloatRegister sd ) { if (VM_Version::v9_instructions_work()) emit_long( op(arith_op) | fd(sd, w) | op3(fpop1_op3) | opf(0x04 + w) | fs2(sd, w)); else emit_long( op(arith_op) | fd(sd, w) | op3(fpop1_op3) | opf(0x05) | fs2(sd, w)); } 1240 1241 void fabs( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { v8_s_only(w); emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x08 + w) | fs2(s, w)); } 1242 1243 // page 144 sparc v8 architecture (double prec works on v8 if the source and destination registers are the same). fabss is the only instruction available 1244 // on v8 to do abs operation on single/double/quad precision floats. 1245 1246 void fabs( FloatRegisterImpl::Width w, FloatRegister sd ) { if (VM_Version::v9_instructions_work()) emit_long( op(arith_op) | fd(sd, w) | op3(fpop1_op3) | opf(0x08 + w) | fs2(sd, w)); else emit_long( op(arith_op) | fd(sd, w) | op3(fpop1_op3) | opf(0x09) | fs2(sd, w)); } 1247 1248 // pp 163 1249 1250 void fmul( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x48 + w) | fs2(s2, w)); } 1251 void fmul( FloatRegisterImpl::Width sw, FloatRegisterImpl::Width dw, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_long( op(arith_op) | fd(d, dw) | op3(fpop1_op3) | fs1(s1, sw) | opf(0x60 + sw + dw*4) | fs2(s2, sw)); } 1252 void fdiv( FloatRegisterImpl::Width w, FloatRegister s1, FloatRegister s2, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | fs1(s1, w) | opf(0x4c + w) | fs2(s2, w)); } 1253 1254 // pp 164 1255 1256 void fsqrt( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d ) { emit_long( op(arith_op) | fd(d, w) | op3(fpop1_op3) | opf(0x28 + w) | fs2(s, w)); } 1257 1258 // pp 165 1259 1260 inline void flush( Register s1, Register s2 ); 1261 inline void flush( Register s1, int simm13a); 1262 1263 // pp 167 1264 1265 void flushw() { v9_only(); emit_long( op(arith_op) | op3(flushw_op3) ); } 1266 1267 // pp 168 1268 1269 void illtrap( int const22a) { if (const22a != 0) v9_only(); emit_long( op(branch_op) | u_field(const22a, 21, 0) ); } 1270 // v8 unimp == illtrap(0) 1271 1272 // pp 169 1273 1274 void impdep1( int id1, int const19a ) { v9_only(); emit_long( op(arith_op) | fcn(id1) | op3(impdep1_op3) | u_field(const19a, 18, 0)); } 1275 void impdep2( int id1, int const19a ) { v9_only(); emit_long( op(arith_op) | fcn(id1) | op3(impdep2_op3) | u_field(const19a, 18, 0)); } 1276 1277 // pp 149 (v8) 1278 1279 void cpop1( int opc, int cr1, int cr2, int crd ) { v8_only(); emit_long( op(arith_op) | fcn(crd) | op3(impdep1_op3) | u_field(cr1, 18, 14) | opf(opc) | u_field(cr2, 4, 0)); } 1280 void cpop2( int opc, int cr1, int cr2, int crd ) { v8_only(); emit_long( op(arith_op) | fcn(crd) | op3(impdep2_op3) | u_field(cr1, 18, 14) | opf(opc) | u_field(cr2, 4, 0)); } 1281 1282 // pp 170 1283 1284 void jmpl( Register s1, Register s2, Register d ); 1285 void jmpl( Register s1, int simm13a, Register d, RelocationHolder const& rspec = RelocationHolder() ); 1286 1287 // 171 1288 1289 inline void ldf(FloatRegisterImpl::Width w, Register s1, RegisterOrConstant s2, FloatRegister d); 1290 inline void ldf(FloatRegisterImpl::Width w, Register s1, Register s2, FloatRegister d); 1291 inline void ldf(FloatRegisterImpl::Width w, Register s1, int simm13a, FloatRegister d, RelocationHolder const& rspec = RelocationHolder()); 1292 1293 inline void ldf(FloatRegisterImpl::Width w, const Address& a, FloatRegister d, int offset = 0); 1294 1295 1296 inline void ldfsr( Register s1, Register s2 ); 1297 inline void ldfsr( Register s1, int simm13a); 1298 inline void ldxfsr( Register s1, Register s2 ); 1299 inline void ldxfsr( Register s1, int simm13a); 1300 1301 // pp 94 (v8) 1302 1303 inline void ldc( Register s1, Register s2, int crd ); 1304 inline void ldc( Register s1, int simm13a, int crd); 1305 inline void lddc( Register s1, Register s2, int crd ); 1306 inline void lddc( Register s1, int simm13a, int crd); 1307 inline void ldcsr( Register s1, Register s2, int crd ); 1308 inline void ldcsr( Register s1, int simm13a, int crd); 1309 1310 1311 // 173 1312 1313 void ldfa( FloatRegisterImpl::Width w, Register s1, Register s2, int ia, FloatRegister d ) { v9_only(); emit_long( op(ldst_op) | fd(d, w) | alt_op3(ldf_op3 | alt_bit_op3, w) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1314 void ldfa( FloatRegisterImpl::Width w, Register s1, int simm13a, FloatRegister d ) { v9_only(); emit_long( op(ldst_op) | fd(d, w) | alt_op3(ldf_op3 | alt_bit_op3, w) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1315 1316 // pp 175, lduw is ld on v8 1317 1318 inline void ldsb( Register s1, Register s2, Register d ); 1319 inline void ldsb( Register s1, int simm13a, Register d); 1320 inline void ldsh( Register s1, Register s2, Register d ); 1321 inline void ldsh( Register s1, int simm13a, Register d); 1322 inline void ldsw( Register s1, Register s2, Register d ); 1323 inline void ldsw( Register s1, int simm13a, Register d); 1324 inline void ldub( Register s1, Register s2, Register d ); 1325 inline void ldub( Register s1, int simm13a, Register d); 1326 inline void lduh( Register s1, Register s2, Register d ); 1327 inline void lduh( Register s1, int simm13a, Register d); 1328 inline void lduw( Register s1, Register s2, Register d ); 1329 inline void lduw( Register s1, int simm13a, Register d); 1330 inline void ldx( Register s1, Register s2, Register d ); 1331 inline void ldx( Register s1, int simm13a, Register d); 1332 inline void ld( Register s1, Register s2, Register d ); 1333 inline void ld( Register s1, int simm13a, Register d); 1334 inline void ldd( Register s1, Register s2, Register d ); 1335 inline void ldd( Register s1, int simm13a, Register d); 1336 1337 #ifdef ASSERT 1338 // ByteSize is only a class when ASSERT is defined, otherwise it's an int. 1339 inline void ld( Register s1, ByteSize simm13a, Register d); 1340 #endif 1341 1342 inline void ldsb(const Address& a, Register d, int offset = 0); 1343 inline void ldsh(const Address& a, Register d, int offset = 0); 1344 inline void ldsw(const Address& a, Register d, int offset = 0); 1345 inline void ldub(const Address& a, Register d, int offset = 0); 1346 inline void lduh(const Address& a, Register d, int offset = 0); 1347 inline void lduw(const Address& a, Register d, int offset = 0); 1348 inline void ldx( const Address& a, Register d, int offset = 0); 1349 inline void ld( const Address& a, Register d, int offset = 0); 1350 inline void ldd( const Address& a, Register d, int offset = 0); 1351 1352 inline void ldub( Register s1, RegisterOrConstant s2, Register d ); 1353 inline void ldsb( Register s1, RegisterOrConstant s2, Register d ); 1354 inline void lduh( Register s1, RegisterOrConstant s2, Register d ); 1355 inline void ldsh( Register s1, RegisterOrConstant s2, Register d ); 1356 inline void lduw( Register s1, RegisterOrConstant s2, Register d ); 1357 inline void ldsw( Register s1, RegisterOrConstant s2, Register d ); 1358 inline void ldx( Register s1, RegisterOrConstant s2, Register d ); 1359 inline void ld( Register s1, RegisterOrConstant s2, Register d ); 1360 inline void ldd( Register s1, RegisterOrConstant s2, Register d ); 1361 1362 // pp 177 1363 1364 void ldsba( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldsb_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1365 void ldsba( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldsb_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1366 void ldsha( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldsh_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1367 void ldsha( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldsh_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1368 void ldswa( Register s1, Register s2, int ia, Register d ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(ldsw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1369 void ldswa( Register s1, int simm13a, Register d ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(ldsw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1370 void lduba( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldub_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1371 void lduba( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldub_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1372 void lduha( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(lduh_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1373 void lduha( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(lduh_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1374 void lduwa( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(lduw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1375 void lduwa( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(lduw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1376 void ldxa( Register s1, Register s2, int ia, Register d ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(ldx_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1377 void ldxa( Register s1, int simm13a, Register d ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(ldx_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1378 void ldda( Register s1, Register s2, int ia, Register d ) { v9_dep(); emit_long( op(ldst_op) | rd(d) | op3(ldd_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1379 void ldda( Register s1, int simm13a, Register d ) { v9_dep(); emit_long( op(ldst_op) | rd(d) | op3(ldd_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1380 1381 // pp 179 1382 1383 inline void ldstub( Register s1, Register s2, Register d ); 1384 inline void ldstub( Register s1, int simm13a, Register d); 1385 1386 // pp 180 1387 1388 void ldstuba( Register s1, Register s2, int ia, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldstub_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1389 void ldstuba( Register s1, int simm13a, Register d ) { emit_long( op(ldst_op) | rd(d) | op3(ldstub_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1390 1391 // pp 181 1392 1393 void and3( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(and_op3 ) | rs1(s1) | rs2(s2) ); } 1394 void and3( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(and_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1395 void andcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(and_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1396 void andcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(and_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1397 void andn( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(andn_op3 ) | rs1(s1) | rs2(s2) ); } 1398 void andn( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(andn_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1399 void andn( Register s1, RegisterOrConstant s2, Register d); 1400 void andncc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(andn_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1401 void andncc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(andn_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1402 void or3( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(or_op3 ) | rs1(s1) | rs2(s2) ); } 1403 void or3( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(or_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1404 void orcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(or_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1405 void orcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(or_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1406 void orn( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(orn_op3) | rs1(s1) | rs2(s2) ); } 1407 void orn( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(orn_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1408 void orncc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(orn_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1409 void orncc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(orn_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1410 void xor3( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xor_op3 ) | rs1(s1) | rs2(s2) ); } 1411 void xor3( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xor_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1412 void xorcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xor_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1413 void xorcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xor_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1414 void xnor( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xnor_op3 ) | rs1(s1) | rs2(s2) ); } 1415 void xnor( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xnor_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1416 void xnorcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xnor_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1417 void xnorcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(xnor_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1418 1419 // pp 183 1420 1421 void membar( Membar_mask_bits const7a ) { v9_only(); emit_long( op(arith_op) | op3(membar_op3) | rs1(O7) | immed(true) | u_field( int(const7a), 6, 0)); } 1422 1423 // pp 185 1424 1425 void fmov( FloatRegisterImpl::Width w, Condition c, bool floatCC, CC cca, FloatRegister s2, FloatRegister d ) { v9_only(); emit_long( op(arith_op) | fd(d, w) | op3(fpop2_op3) | cond_mov(c) | opf_cc(cca, floatCC) | opf_low6(w) | fs2(s2, w)); } 1426 1427 // pp 189 1428 1429 void fmov( FloatRegisterImpl::Width w, RCondition c, Register s1, FloatRegister s2, FloatRegister d ) { v9_only(); emit_long( op(arith_op) | fd(d, w) | op3(fpop2_op3) | rs1(s1) | rcond(c) | opf_low5(4 + w) | fs2(s2, w)); } 1430 1431 // pp 191 1432 1433 void movcc( Condition c, bool floatCC, CC cca, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(movcc_op3) | mov_cc(cca, floatCC) | cond_mov(c) | rs2(s2) ); } 1434 void movcc( Condition c, bool floatCC, CC cca, int simm11a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(movcc_op3) | mov_cc(cca, floatCC) | cond_mov(c) | immed(true) | simm(simm11a, 11) ); } 1435 1436 // pp 195 1437 1438 void movr( RCondition c, Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(movr_op3) | rs1(s1) | rcond(c) | rs2(s2) ); } 1439 void movr( RCondition c, Register s1, int simm10a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(movr_op3) | rs1(s1) | rcond(c) | immed(true) | simm(simm10a, 10) ); } 1440 1441 // pp 196 1442 1443 void mulx( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(mulx_op3 ) | rs1(s1) | rs2(s2) ); } 1444 void mulx( Register s1, int simm13a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(mulx_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1445 void sdivx( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sdivx_op3) | rs1(s1) | rs2(s2) ); } 1446 void sdivx( Register s1, int simm13a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sdivx_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1447 void udivx( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(udivx_op3) | rs1(s1) | rs2(s2) ); } 1448 void udivx( Register s1, int simm13a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(udivx_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1449 1450 // pp 197 1451 1452 void umul( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(umul_op3 ) | rs1(s1) | rs2(s2) ); } 1453 void umul( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(umul_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1454 void smul( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(smul_op3 ) | rs1(s1) | rs2(s2) ); } 1455 void smul( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(smul_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1456 void umulcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(umul_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1457 void umulcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(umul_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1458 void smulcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(smul_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1459 void smulcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(smul_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1460 1461 // pp 199 1462 1463 void mulscc( Register s1, Register s2, Register d ) { v9_dep(); emit_long( op(arith_op) | rd(d) | op3(mulscc_op3) | rs1(s1) | rs2(s2) ); } 1464 void mulscc( Register s1, int simm13a, Register d ) { v9_dep(); emit_long( op(arith_op) | rd(d) | op3(mulscc_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1465 1466 // pp 201 1467 1468 void nop() { emit_long( op(branch_op) | op2(sethi_op2) ); } 1469 1470 1471 // pp 202 1472 1473 void popc( Register s, Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(popc_op3) | rs2(s)); } 1474 void popc( int simm13a, Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(popc_op3) | immed(true) | simm(simm13a, 13)); } 1475 1476 // pp 203 1477 1478 void prefetch( Register s1, Register s2, PrefetchFcn f); 1479 void prefetch( Register s1, int simm13a, PrefetchFcn f); 1480 void prefetcha( Register s1, Register s2, int ia, PrefetchFcn f ) { v9_only(); emit_long( op(ldst_op) | fcn(f) | op3(prefetch_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1481 void prefetcha( Register s1, int simm13a, PrefetchFcn f ) { v9_only(); emit_long( op(ldst_op) | fcn(f) | op3(prefetch_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1482 1483 inline void prefetch(const Address& a, PrefetchFcn F, int offset = 0); 1484 1485 // pp 208 1486 1487 // not implementing read privileged register 1488 1489 inline void rdy( Register d) { v9_dep(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(0, 18, 14)); } 1490 inline void rdccr( Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(2, 18, 14)); } 1491 inline void rdasi( Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(3, 18, 14)); } 1492 inline void rdtick( Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(4, 18, 14)); } // Spoon! 1493 inline void rdpc( Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(5, 18, 14)); } 1494 inline void rdfprs( Register d) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(rdreg_op3) | u_field(6, 18, 14)); } 1495 1496 // pp 213 1497 1498 inline void rett( Register s1, Register s2); 1499 inline void rett( Register s1, int simm13a, relocInfo::relocType rt = relocInfo::none); 1500 1501 // pp 214 1502 1503 void save( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(save_op3) | rs1(s1) | rs2(s2) ); } 1504 void save( Register s1, int simm13a, Register d ) { 1505 // make sure frame is at least large enough for the register save area 1506 assert(-simm13a >= 16 * wordSize, "frame too small"); 1507 emit_long( op(arith_op) | rd(d) | op3(save_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); 1508 } 1509 1510 void restore( Register s1 = G0, Register s2 = G0, Register d = G0 ) { emit_long( op(arith_op) | rd(d) | op3(restore_op3) | rs1(s1) | rs2(s2) ); } 1511 void restore( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(restore_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1512 1513 // pp 216 1514 1515 void saved() { v9_only(); emit_long( op(arith_op) | fcn(0) | op3(saved_op3)); } 1516 void restored() { v9_only(); emit_long( op(arith_op) | fcn(1) | op3(saved_op3)); } 1517 1518 // pp 217 1519 1520 inline void sethi( int imm22a, Register d, RelocationHolder const& rspec = RelocationHolder() ); 1521 // pp 218 1522 1523 void sll( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(0) | rs2(s2) ); } 1524 void sll( Register s1, int imm5a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } 1525 void srl( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(0) | rs2(s2) ); } 1526 void srl( Register s1, int imm5a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } 1527 void sra( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(0) | rs2(s2) ); } 1528 void sra( Register s1, int imm5a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(0) | immed(true) | u_field(imm5a, 4, 0) ); } 1529 1530 void sllx( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(1) | rs2(s2) ); } 1531 void sllx( Register s1, int imm6a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sll_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } 1532 void srlx( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(1) | rs2(s2) ); } 1533 void srlx( Register s1, int imm6a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(srl_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } 1534 void srax( Register s1, Register s2, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(1) | rs2(s2) ); } 1535 void srax( Register s1, int imm6a, Register d ) { v9_only(); emit_long( op(arith_op) | rd(d) | op3(sra_op3) | rs1(s1) | sx(1) | immed(true) | u_field(imm6a, 5, 0) ); } 1536 1537 // pp 220 1538 1539 void sir( int simm13a ) { emit_long( op(arith_op) | fcn(15) | op3(sir_op3) | immed(true) | simm(simm13a, 13)); } 1540 1541 // pp 221 1542 1543 void stbar() { emit_long( op(arith_op) | op3(membar_op3) | u_field(15, 18, 14)); } 1544 1545 // pp 222 1546 1547 inline void stf( FloatRegisterImpl::Width w, FloatRegister d, Register s1, RegisterOrConstant s2); 1548 inline void stf( FloatRegisterImpl::Width w, FloatRegister d, Register s1, Register s2); 1549 inline void stf( FloatRegisterImpl::Width w, FloatRegister d, Register s1, int simm13a); 1550 inline void stf( FloatRegisterImpl::Width w, FloatRegister d, const Address& a, int offset = 0); 1551 1552 inline void stfsr( Register s1, Register s2 ); 1553 inline void stfsr( Register s1, int simm13a); 1554 inline void stxfsr( Register s1, Register s2 ); 1555 inline void stxfsr( Register s1, int simm13a); 1556 1557 // pp 224 1558 1559 void stfa( FloatRegisterImpl::Width w, FloatRegister d, Register s1, Register s2, int ia ) { v9_only(); emit_long( op(ldst_op) | fd(d, w) | alt_op3(stf_op3 | alt_bit_op3, w) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1560 void stfa( FloatRegisterImpl::Width w, FloatRegister d, Register s1, int simm13a ) { v9_only(); emit_long( op(ldst_op) | fd(d, w) | alt_op3(stf_op3 | alt_bit_op3, w) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1561 1562 // p 226 1563 1564 inline void stb( Register d, Register s1, Register s2 ); 1565 inline void stb( Register d, Register s1, int simm13a); 1566 inline void sth( Register d, Register s1, Register s2 ); 1567 inline void sth( Register d, Register s1, int simm13a); 1568 inline void stw( Register d, Register s1, Register s2 ); 1569 inline void stw( Register d, Register s1, int simm13a); 1570 inline void st( Register d, Register s1, Register s2 ); 1571 inline void st( Register d, Register s1, int simm13a); 1572 inline void stx( Register d, Register s1, Register s2 ); 1573 inline void stx( Register d, Register s1, int simm13a); 1574 inline void std( Register d, Register s1, Register s2 ); 1575 inline void std( Register d, Register s1, int simm13a); 1576 1577 #ifdef ASSERT 1578 // ByteSize is only a class when ASSERT is defined, otherwise it's an int. 1579 inline void st( Register d, Register s1, ByteSize simm13a); 1580 #endif 1581 1582 inline void stb( Register d, const Address& a, int offset = 0 ); 1583 inline void sth( Register d, const Address& a, int offset = 0 ); 1584 inline void stw( Register d, const Address& a, int offset = 0 ); 1585 inline void stx( Register d, const Address& a, int offset = 0 ); 1586 inline void st( Register d, const Address& a, int offset = 0 ); 1587 inline void std( Register d, const Address& a, int offset = 0 ); 1588 1589 inline void stb( Register d, Register s1, RegisterOrConstant s2 ); 1590 inline void sth( Register d, Register s1, RegisterOrConstant s2 ); 1591 inline void stw( Register d, Register s1, RegisterOrConstant s2 ); 1592 inline void stx( Register d, Register s1, RegisterOrConstant s2 ); 1593 inline void std( Register d, Register s1, RegisterOrConstant s2 ); 1594 inline void st( Register d, Register s1, RegisterOrConstant s2 ); 1595 1596 // pp 177 1597 1598 void stba( Register d, Register s1, Register s2, int ia ) { emit_long( op(ldst_op) | rd(d) | op3(stb_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1599 void stba( Register d, Register s1, int simm13a ) { emit_long( op(ldst_op) | rd(d) | op3(stb_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1600 void stha( Register d, Register s1, Register s2, int ia ) { emit_long( op(ldst_op) | rd(d) | op3(sth_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1601 void stha( Register d, Register s1, int simm13a ) { emit_long( op(ldst_op) | rd(d) | op3(sth_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1602 void stwa( Register d, Register s1, Register s2, int ia ) { emit_long( op(ldst_op) | rd(d) | op3(stw_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1603 void stwa( Register d, Register s1, int simm13a ) { emit_long( op(ldst_op) | rd(d) | op3(stw_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1604 void stxa( Register d, Register s1, Register s2, int ia ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(stx_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1605 void stxa( Register d, Register s1, int simm13a ) { v9_only(); emit_long( op(ldst_op) | rd(d) | op3(stx_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1606 void stda( Register d, Register s1, Register s2, int ia ) { emit_long( op(ldst_op) | rd(d) | op3(std_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1607 void stda( Register d, Register s1, int simm13a ) { emit_long( op(ldst_op) | rd(d) | op3(std_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1608 1609 // pp 97 (v8) 1610 1611 inline void stc( int crd, Register s1, Register s2 ); 1612 inline void stc( int crd, Register s1, int simm13a); 1613 inline void stdc( int crd, Register s1, Register s2 ); 1614 inline void stdc( int crd, Register s1, int simm13a); 1615 inline void stcsr( int crd, Register s1, Register s2 ); 1616 inline void stcsr( int crd, Register s1, int simm13a); 1617 inline void stdcq( int crd, Register s1, Register s2 ); 1618 inline void stdcq( int crd, Register s1, int simm13a); 1619 1620 // pp 230 1621 1622 void sub( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sub_op3 ) | rs1(s1) | rs2(s2) ); } 1623 void sub( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sub_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1624 void subcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sub_op3 | cc_bit_op3 ) | rs1(s1) | rs2(s2) ); } 1625 void subcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(sub_op3 | cc_bit_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1626 void subc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(subc_op3 ) | rs1(s1) | rs2(s2) ); } 1627 void subc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(subc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1628 void subccc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(subc_op3 | cc_bit_op3) | rs1(s1) | rs2(s2) ); } 1629 void subccc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(subc_op3 | cc_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1630 1631 // pp 231 1632 1633 inline void swap( Register s1, Register s2, Register d ); 1634 inline void swap( Register s1, int simm13a, Register d); 1635 inline void swap( Address& a, Register d, int offset = 0 ); 1636 1637 // pp 232 1638 1639 void swapa( Register s1, Register s2, int ia, Register d ) { v9_dep(); emit_long( op(ldst_op) | rd(d) | op3(swap_op3 | alt_bit_op3) | rs1(s1) | imm_asi(ia) | rs2(s2) ); } 1640 void swapa( Register s1, int simm13a, Register d ) { v9_dep(); emit_long( op(ldst_op) | rd(d) | op3(swap_op3 | alt_bit_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1641 1642 // pp 234, note op in book is wrong, see pp 268 1643 1644 void taddcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(taddcc_op3 ) | rs1(s1) | rs2(s2) ); } 1645 void taddcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(taddcc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1646 void taddcctv( Register s1, Register s2, Register d ) { v9_dep(); emit_long( op(arith_op) | rd(d) | op3(taddcctv_op3) | rs1(s1) | rs2(s2) ); } 1647 void taddcctv( Register s1, int simm13a, Register d ) { v9_dep(); emit_long( op(arith_op) | rd(d) | op3(taddcctv_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1648 1649 // pp 235 1650 1651 void tsubcc( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(tsubcc_op3 ) | rs1(s1) | rs2(s2) ); } 1652 void tsubcc( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(tsubcc_op3 ) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1653 void tsubcctv( Register s1, Register s2, Register d ) { emit_long( op(arith_op) | rd(d) | op3(tsubcctv_op3) | rs1(s1) | rs2(s2) ); } 1654 void tsubcctv( Register s1, int simm13a, Register d ) { emit_long( op(arith_op) | rd(d) | op3(tsubcctv_op3) | rs1(s1) | immed(true) | simm(simm13a, 13) ); } 1655 1656 // pp 237 1657 1658 void trap( Condition c, CC cc, Register s1, Register s2 ) { v8_no_cc(cc); emit_long( op(arith_op) | cond(c) | op3(trap_op3) | rs1(s1) | trapcc(cc) | rs2(s2)); } 1659 void trap( Condition c, CC cc, Register s1, int trapa ) { v8_no_cc(cc); emit_long( op(arith_op) | cond(c) | op3(trap_op3) | rs1(s1) | trapcc(cc) | immed(true) | u_field(trapa, 6, 0)); } 1660 // simple uncond. trap 1661 void trap( int trapa ) { trap( always, icc, G0, trapa ); } 1662 1663 // pp 239 omit write priv register for now 1664 1665 inline void wry( Register d) { v9_dep(); emit_long( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(0, 29, 25)); } 1666 inline void wrccr(Register s) { v9_only(); emit_long( op(arith_op) | rs1(s) | op3(wrreg_op3) | u_field(2, 29, 25)); } 1667 inline void wrccr(Register s, int simm13a) { v9_only(); emit_long( op(arith_op) | 1668 rs1(s) | 1669 op3(wrreg_op3) | 1670 u_field(2, 29, 25) | 1671 u_field(1, 13, 13) | 1672 simm(simm13a, 13)); } 1673 inline void wrasi( Register d) { v9_only(); emit_long( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(3, 29, 25)); } 1674 inline void wrfprs( Register d) { v9_only(); emit_long( op(arith_op) | rs1(d) | op3(wrreg_op3) | u_field(6, 29, 25)); } 1675 1676 // For a given register condition, return the appropriate condition code 1677 // Condition (the one you would use to get the same effect after "tst" on 1678 // the target register.) 1679 Assembler::Condition reg_cond_to_cc_cond(RCondition in); 1680 1681 1682 // Creation 1683 Assembler(CodeBuffer* code) : AbstractAssembler(code) { 1684 #ifdef CHECK_DELAY 1685 delay_state = no_delay; 1686 #endif 1687 } 1688 1689 // Testing 1690 #ifndef PRODUCT 1691 void test_v9(); 1692 void test_v8_onlys(); 1693 #endif 1694 }; 1695 1696 1697 class RegistersForDebugging : public StackObj { 1698 public: 1699 intptr_t i[8], l[8], o[8], g[8]; 1700 float f[32]; 1701 double d[32]; 1702 1703 void print(outputStream* s); 1704 1705 static int i_offset(int j) { return offset_of(RegistersForDebugging, i[j]); } 1706 static int l_offset(int j) { return offset_of(RegistersForDebugging, l[j]); } 1707 static int o_offset(int j) { return offset_of(RegistersForDebugging, o[j]); } 1708 static int g_offset(int j) { return offset_of(RegistersForDebugging, g[j]); } 1709 static int f_offset(int j) { return offset_of(RegistersForDebugging, f[j]); } 1710 static int d_offset(int j) { return offset_of(RegistersForDebugging, d[j / 2]); } 1711 1712 // gen asm code to save regs 1713 static void save_registers(MacroAssembler* a); 1714 1715 // restore global registers in case C code disturbed them 1716 static void restore_registers(MacroAssembler* a, Register r); 1717 1718 1719 }; 1720 1721 1722 // MacroAssembler extends Assembler by a few frequently used macros. 1723 // 1724 // Most of the standard SPARC synthetic ops are defined here. 1725 // Instructions for which a 'better' code sequence exists depending 1726 // on arguments should also go in here. 1727 1728 #define JMP2(r1, r2) jmp(r1, r2, __FILE__, __LINE__) 1729 #define JMP(r1, off) jmp(r1, off, __FILE__, __LINE__) 1730 #define JUMP(a, temp, off) jump(a, temp, off, __FILE__, __LINE__) 1731 #define JUMPL(a, temp, d, off) jumpl(a, temp, d, off, __FILE__, __LINE__) 1732 1733 1734 class MacroAssembler: public Assembler { 1735 protected: 1736 // Support for VM calls 1737 // This is the base routine called by the different versions of call_VM_leaf. The interpreter 1738 // may customize this version by overriding it for its purposes (e.g., to save/restore 1739 // additional registers when doing a VM call). 1740 #ifdef CC_INTERP 1741 #define VIRTUAL 1742 #else 1743 #define VIRTUAL virtual 1744 #endif 1745 1746 VIRTUAL void call_VM_leaf_base(Register thread_cache, address entry_point, int number_of_arguments); 1747 1748 // 1749 // It is imperative that all calls into the VM are handled via the call_VM macros. 1750 // They make sure that the stack linkage is setup correctly. call_VM's correspond 1751 // to ENTRY/ENTRY_X entry points while call_VM_leaf's correspond to LEAF entry points. 1752 // 1753 // This is the base routine called by the different versions of call_VM. The interpreter 1754 // may customize this version by overriding it for its purposes (e.g., to save/restore 1755 // additional registers when doing a VM call). 1756 // 1757 // A non-volatile java_thread_cache register should be specified so 1758 // that the G2_thread value can be preserved across the call. 1759 // (If java_thread_cache is noreg, then a slow get_thread call 1760 // will re-initialize the G2_thread.) call_VM_base returns the register that contains the 1761 // thread. 1762 // 1763 // If no last_java_sp is specified (noreg) than SP will be used instead. 1764 1765 virtual void call_VM_base( 1766 Register oop_result, // where an oop-result ends up if any; use noreg otherwise 1767 Register java_thread_cache, // the thread if computed before ; use noreg otherwise 1768 Register last_java_sp, // to set up last_Java_frame in stubs; use noreg otherwise 1769 address entry_point, // the entry point 1770 int number_of_arguments, // the number of arguments (w/o thread) to pop after call 1771 bool check_exception=true // flag which indicates if exception should be checked 1772 ); 1773 1774 // This routine should emit JVMTI PopFrame and ForceEarlyReturn handling code. 1775 // The implementation is only non-empty for the InterpreterMacroAssembler, 1776 // as only the interpreter handles and ForceEarlyReturn PopFrame requests. 1777 virtual void check_and_handle_popframe(Register scratch_reg); 1778 virtual void check_and_handle_earlyret(Register scratch_reg); 1779 1780 public: 1781 MacroAssembler(CodeBuffer* code) : Assembler(code) {} 1782 1783 // Support for NULL-checks 1784 // 1785 // Generates code that causes a NULL OS exception if the content of reg is NULL. 1786 // If the accessed location is M[reg + offset] and the offset is known, provide the 1787 // offset. No explicit code generation is needed if the offset is within a certain 1788 // range (0 <= offset <= page_size). 1789 // 1790 // %%%%%% Currently not done for SPARC 1791 1792 void null_check(Register reg, int offset = -1); 1793 static bool needs_explicit_null_check(intptr_t offset); 1794 1795 // support for delayed instructions 1796 MacroAssembler* delayed() { Assembler::delayed(); return this; } 1797 1798 // branches that use right instruction for v8 vs. v9 1799 inline void br( Condition c, bool a, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1800 inline void br( Condition c, bool a, Predict p, Label& L ); 1801 inline void fb( Condition c, bool a, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1802 inline void fb( Condition c, bool a, Predict p, Label& L ); 1803 1804 // compares register with zero and branches (V9 and V8 instructions) 1805 void br_zero( Condition c, bool a, Predict p, Register s1, Label& L); 1806 // Compares a pointer register with zero and branches on (not)null. 1807 // Does a test & branch on 32-bit systems and a register-branch on 64-bit. 1808 void br_null ( Register s1, bool a, Predict p, Label& L ); 1809 void br_notnull( Register s1, bool a, Predict p, Label& L ); 1810 1811 // These versions will do the most efficient thing on v8 and v9. Perhaps 1812 // this is what the routine above was meant to do, but it didn't (and 1813 // didn't cover both target address kinds.) 1814 void br_on_reg_cond( RCondition c, bool a, Predict p, Register s1, address d, relocInfo::relocType rt = relocInfo::none ); 1815 void br_on_reg_cond( RCondition c, bool a, Predict p, Register s1, Label& L); 1816 1817 inline void bp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1818 inline void bp( Condition c, bool a, CC cc, Predict p, Label& L ); 1819 1820 // Branch that tests xcc in LP64 and icc in !LP64 1821 inline void brx( Condition c, bool a, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1822 inline void brx( Condition c, bool a, Predict p, Label& L ); 1823 1824 // unconditional short branch 1825 inline void ba( bool a, Label& L ); 1826 1827 // Branch that tests fp condition codes 1828 inline void fbp( Condition c, bool a, CC cc, Predict p, address d, relocInfo::relocType rt = relocInfo::none ); 1829 inline void fbp( Condition c, bool a, CC cc, Predict p, Label& L ); 1830 1831 // get PC the best way 1832 inline int get_pc( Register d ); 1833 1834 // Sparc shorthands(pp 85, V8 manual, pp 289 V9 manual) 1835 inline void cmp( Register s1, Register s2 ) { subcc( s1, s2, G0 ); } 1836 inline void cmp( Register s1, int simm13a ) { subcc( s1, simm13a, G0 ); } 1837 1838 inline void jmp( Register s1, Register s2 ); 1839 inline void jmp( Register s1, int simm13a, RelocationHolder const& rspec = RelocationHolder() ); 1840 1841 inline void call( address d, relocInfo::relocType rt = relocInfo::runtime_call_type ); 1842 inline void call( Label& L, relocInfo::relocType rt = relocInfo::runtime_call_type ); 1843 inline void callr( Register s1, Register s2 ); 1844 inline void callr( Register s1, int simm13a, RelocationHolder const& rspec = RelocationHolder() ); 1845 1846 // Emits nothing on V8 1847 inline void iprefetch( address d, relocInfo::relocType rt = relocInfo::none ); 1848 inline void iprefetch( Label& L); 1849 1850 inline void tst( Register s ) { orcc( G0, s, G0 ); } 1851 1852 #ifdef PRODUCT 1853 inline void ret( bool trace = TraceJumps ) { if (trace) { 1854 mov(I7, O7); // traceable register 1855 JMP(O7, 2 * BytesPerInstWord); 1856 } else { 1857 jmpl( I7, 2 * BytesPerInstWord, G0 ); 1858 } 1859 } 1860 1861 inline void retl( bool trace = TraceJumps ) { if (trace) JMP(O7, 2 * BytesPerInstWord); 1862 else jmpl( O7, 2 * BytesPerInstWord, G0 ); } 1863 #else 1864 void ret( bool trace = TraceJumps ); 1865 void retl( bool trace = TraceJumps ); 1866 #endif /* PRODUCT */ 1867 1868 // Required platform-specific helpers for Label::patch_instructions. 1869 // They _shadow_ the declarations in AbstractAssembler, which are undefined. 1870 void pd_patch_instruction(address branch, address target); 1871 #ifndef PRODUCT 1872 static void pd_print_patched_instruction(address branch); 1873 #endif 1874 1875 // sethi Macro handles optimizations and relocations 1876 private: 1877 void internal_sethi(const AddressLiteral& addrlit, Register d, bool ForceRelocatable); 1878 public: 1879 void sethi(const AddressLiteral& addrlit, Register d); 1880 void patchable_sethi(const AddressLiteral& addrlit, Register d); 1881 1882 // compute the size of a sethi/set 1883 static int size_of_sethi( address a, bool worst_case = false ); 1884 static int worst_case_size_of_set(); 1885 1886 // set may be either setsw or setuw (high 32 bits may be zero or sign) 1887 private: 1888 void internal_set(const AddressLiteral& al, Register d, bool ForceRelocatable); 1889 public: 1890 void set(const AddressLiteral& addrlit, Register d); 1891 void set(intptr_t value, Register d); 1892 void set(address addr, Register d, RelocationHolder const& rspec); 1893 void patchable_set(const AddressLiteral& addrlit, Register d); 1894 void patchable_set(intptr_t value, Register d); 1895 void set64(jlong value, Register d, Register tmp); 1896 1897 // sign-extend 32 to 64 1898 inline void signx( Register s, Register d ) { sra( s, G0, d); } 1899 inline void signx( Register d ) { sra( d, G0, d); } 1900 1901 inline void not1( Register s, Register d ) { xnor( s, G0, d ); } 1902 inline void not1( Register d ) { xnor( d, G0, d ); } 1903 1904 inline void neg( Register s, Register d ) { sub( G0, s, d ); } 1905 inline void neg( Register d ) { sub( G0, d, d ); } 1906 1907 inline void cas( Register s1, Register s2, Register d) { casa( s1, s2, d, ASI_PRIMARY); } 1908 inline void casx( Register s1, Register s2, Register d) { casxa(s1, s2, d, ASI_PRIMARY); } 1909 // Functions for isolating 64 bit atomic swaps for LP64 1910 // cas_ptr will perform cas for 32 bit VM's and casx for 64 bit VM's 1911 inline void cas_ptr( Register s1, Register s2, Register d) { 1912 #ifdef _LP64 1913 casx( s1, s2, d ); 1914 #else 1915 cas( s1, s2, d ); 1916 #endif 1917 } 1918 1919 // Functions for isolating 64 bit shifts for LP64 1920 inline void sll_ptr( Register s1, Register s2, Register d ); 1921 inline void sll_ptr( Register s1, int imm6a, Register d ); 1922 inline void sll_ptr( Register s1, RegisterOrConstant s2, Register d ); 1923 inline void srl_ptr( Register s1, Register s2, Register d ); 1924 inline void srl_ptr( Register s1, int imm6a, Register d ); 1925 1926 // little-endian 1927 inline void casl( Register s1, Register s2, Register d) { casa( s1, s2, d, ASI_PRIMARY_LITTLE); } 1928 inline void casxl( Register s1, Register s2, Register d) { casxa(s1, s2, d, ASI_PRIMARY_LITTLE); } 1929 1930 inline void inc( Register d, int const13 = 1 ) { add( d, const13, d); } 1931 inline void inccc( Register d, int const13 = 1 ) { addcc( d, const13, d); } 1932 1933 inline void dec( Register d, int const13 = 1 ) { sub( d, const13, d); } 1934 inline void deccc( Register d, int const13 = 1 ) { subcc( d, const13, d); } 1935 1936 inline void btst( Register s1, Register s2 ) { andcc( s1, s2, G0 ); } 1937 inline void btst( int simm13a, Register s ) { andcc( s, simm13a, G0 ); } 1938 1939 inline void bset( Register s1, Register s2 ) { or3( s1, s2, s2 ); } 1940 inline void bset( int simm13a, Register s ) { or3( s, simm13a, s ); } 1941 1942 inline void bclr( Register s1, Register s2 ) { andn( s1, s2, s2 ); } 1943 inline void bclr( int simm13a, Register s ) { andn( s, simm13a, s ); } 1944 1945 inline void btog( Register s1, Register s2 ) { xor3( s1, s2, s2 ); } 1946 inline void btog( int simm13a, Register s ) { xor3( s, simm13a, s ); } 1947 1948 inline void clr( Register d ) { or3( G0, G0, d ); } 1949 1950 inline void clrb( Register s1, Register s2); 1951 inline void clrh( Register s1, Register s2); 1952 inline void clr( Register s1, Register s2); 1953 inline void clrx( Register s1, Register s2); 1954 1955 inline void clrb( Register s1, int simm13a); 1956 inline void clrh( Register s1, int simm13a); 1957 inline void clr( Register s1, int simm13a); 1958 inline void clrx( Register s1, int simm13a); 1959 1960 // copy & clear upper word 1961 inline void clruw( Register s, Register d ) { srl( s, G0, d); } 1962 // clear upper word 1963 inline void clruwu( Register d ) { srl( d, G0, d); } 1964 1965 // membar psuedo instruction. takes into account target memory model. 1966 inline void membar( Assembler::Membar_mask_bits const7a ); 1967 1968 // returns if membar generates anything. 1969 inline bool membar_has_effect( Assembler::Membar_mask_bits const7a ); 1970 1971 // mov pseudo instructions 1972 inline void mov( Register s, Register d) { 1973 if ( s != d ) or3( G0, s, d); 1974 else assert_not_delayed(); // Put something useful in the delay slot! 1975 } 1976 1977 inline void mov_or_nop( Register s, Register d) { 1978 if ( s != d ) or3( G0, s, d); 1979 else nop(); 1980 } 1981 1982 inline void mov( int simm13a, Register d) { or3( G0, simm13a, d); } 1983 1984 // address pseudos: make these names unlike instruction names to avoid confusion 1985 inline intptr_t load_pc_address( Register reg, int bytes_to_skip ); 1986 inline void load_contents(const AddressLiteral& addrlit, Register d, int offset = 0); 1987 inline void load_ptr_contents(const AddressLiteral& addrlit, Register d, int offset = 0); 1988 inline void store_contents(Register s, const AddressLiteral& addrlit, Register temp, int offset = 0); 1989 inline void store_ptr_contents(Register s, const AddressLiteral& addrlit, Register temp, int offset = 0); 1990 inline void jumpl_to(const AddressLiteral& addrlit, Register temp, Register d, int offset = 0); 1991 inline void jump_to(const AddressLiteral& addrlit, Register temp, int offset = 0); 1992 inline void jump_indirect_to(Address& a, Register temp, int ld_offset = 0, int jmp_offset = 0); 1993 1994 // ring buffer traceable jumps 1995 1996 void jmp2( Register r1, Register r2, const char* file, int line ); 1997 void jmp ( Register r1, int offset, const char* file, int line ); 1998 1999 void jumpl(const AddressLiteral& addrlit, Register temp, Register d, int offset, const char* file, int line); 2000 void jump (const AddressLiteral& addrlit, Register temp, int offset, const char* file, int line); 2001 2002 2003 // argument pseudos: 2004 2005 inline void load_argument( Argument& a, Register d ); 2006 inline void store_argument( Register s, Argument& a ); 2007 inline void store_ptr_argument( Register s, Argument& a ); 2008 inline void store_float_argument( FloatRegister s, Argument& a ); 2009 inline void store_double_argument( FloatRegister s, Argument& a ); 2010 inline void store_long_argument( Register s, Argument& a ); 2011 2012 // handy macros: 2013 2014 inline void round_to( Register r, int modulus ) { 2015 assert_not_delayed(); 2016 inc( r, modulus - 1 ); 2017 and3( r, -modulus, r ); 2018 } 2019 2020 // -------------------------------------------------- 2021 2022 // Functions for isolating 64 bit loads for LP64 2023 // ld_ptr will perform ld for 32 bit VM's and ldx for 64 bit VM's 2024 // st_ptr will perform st for 32 bit VM's and stx for 64 bit VM's 2025 inline void ld_ptr(Register s1, Register s2, Register d); 2026 inline void ld_ptr(Register s1, int simm13a, Register d); 2027 inline void ld_ptr(Register s1, RegisterOrConstant s2, Register d); 2028 inline void ld_ptr(const Address& a, Register d, int offset = 0); 2029 inline void st_ptr(Register d, Register s1, Register s2); 2030 inline void st_ptr(Register d, Register s1, int simm13a); 2031 inline void st_ptr(Register d, Register s1, RegisterOrConstant s2); 2032 inline void st_ptr(Register d, const Address& a, int offset = 0); 2033 2034 #ifdef ASSERT 2035 // ByteSize is only a class when ASSERT is defined, otherwise it's an int. 2036 inline void ld_ptr(Register s1, ByteSize simm13a, Register d); 2037 inline void st_ptr(Register d, Register s1, ByteSize simm13a); 2038 #endif 2039 2040 // ld_long will perform ldd for 32 bit VM's and ldx for 64 bit VM's 2041 // st_long will perform std for 32 bit VM's and stx for 64 bit VM's 2042 inline void ld_long(Register s1, Register s2, Register d); 2043 inline void ld_long(Register s1, int simm13a, Register d); 2044 inline void ld_long(Register s1, RegisterOrConstant s2, Register d); 2045 inline void ld_long(const Address& a, Register d, int offset = 0); 2046 inline void st_long(Register d, Register s1, Register s2); 2047 inline void st_long(Register d, Register s1, int simm13a); 2048 inline void st_long(Register d, Register s1, RegisterOrConstant s2); 2049 inline void st_long(Register d, const Address& a, int offset = 0); 2050 2051 // Helpers for address formation. 2052 // - They emit only a move if s2 is a constant zero. 2053 // - If dest is a constant and either s1 or s2 is a register, the temp argument is required and becomes the result. 2054 // - If dest is a register and either s1 or s2 is a non-simm13 constant, the temp argument is required and used to materialize the constant. 2055 RegisterOrConstant regcon_andn_ptr(RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp = noreg); 2056 RegisterOrConstant regcon_inc_ptr( RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp = noreg); 2057 RegisterOrConstant regcon_sll_ptr( RegisterOrConstant s1, RegisterOrConstant s2, RegisterOrConstant d, Register temp = noreg); 2058 2059 RegisterOrConstant ensure_simm13_or_reg(RegisterOrConstant src, Register temp) { 2060 if (is_simm13(src.constant_or_zero())) 2061 return src; // register or short constant 2062 guarantee(temp != noreg, "constant offset overflow"); 2063 set(src.as_constant(), temp); 2064 return temp; 2065 } 2066 2067 // -------------------------------------------------- 2068 2069 public: 2070 // traps as per trap.h (SPARC ABI?) 2071 2072 void breakpoint_trap(); 2073 void breakpoint_trap(Condition c, CC cc = icc); 2074 void flush_windows_trap(); 2075 void clean_windows_trap(); 2076 void get_psr_trap(); 2077 void set_psr_trap(); 2078 2079 // V8/V9 flush_windows 2080 void flush_windows(); 2081 2082 // Support for serializing memory accesses between threads 2083 void serialize_memory(Register thread, Register tmp1, Register tmp2); 2084 2085 // Stack frame creation/removal 2086 void enter(); 2087 void leave(); 2088 2089 // V8/V9 integer multiply 2090 void mult(Register s1, Register s2, Register d); 2091 void mult(Register s1, int simm13a, Register d); 2092 2093 // V8/V9 read and write of condition codes. 2094 void read_ccr(Register d); 2095 void write_ccr(Register s); 2096 2097 // Manipulation of C++ bools 2098 // These are idioms to flag the need for care with accessing bools but on 2099 // this platform we assume byte size 2100 2101 inline void stbool(Register d, const Address& a) { stb(d, a); } 2102 inline void ldbool(const Address& a, Register d) { ldsb(a, d); } 2103 inline void tstbool( Register s ) { tst(s); } 2104 inline void movbool( bool boolconst, Register d) { mov( (int) boolconst, d); } 2105 2106 // klass oop manipulations if compressed 2107 void load_klass(Register src_oop, Register klass); 2108 void store_klass(Register klass, Register dst_oop); 2109 void store_klass_gap(Register s, Register dst_oop); 2110 2111 // oop manipulations 2112 void load_heap_oop(const Address& s, Register d); 2113 void load_heap_oop(Register s1, Register s2, Register d); 2114 void load_heap_oop(Register s1, int simm13a, Register d); 2115 void load_heap_oop(Register s1, RegisterOrConstant s2, Register d); 2116 void store_heap_oop(Register d, Register s1, Register s2); 2117 void store_heap_oop(Register d, Register s1, int simm13a); 2118 void store_heap_oop(Register d, const Address& a, int offset = 0); 2119 2120 void encode_heap_oop(Register src, Register dst); 2121 void encode_heap_oop(Register r) { 2122 encode_heap_oop(r, r); 2123 } 2124 void decode_heap_oop(Register src, Register dst); 2125 void decode_heap_oop(Register r) { 2126 decode_heap_oop(r, r); 2127 } 2128 void encode_heap_oop_not_null(Register r); 2129 void decode_heap_oop_not_null(Register r); 2130 void encode_heap_oop_not_null(Register src, Register dst); 2131 void decode_heap_oop_not_null(Register src, Register dst); 2132 2133 // Support for managing the JavaThread pointer (i.e.; the reference to 2134 // thread-local information). 2135 void get_thread(); // load G2_thread 2136 void verify_thread(); // verify G2_thread contents 2137 void save_thread (const Register threache); // save to cache 2138 void restore_thread(const Register thread_cache); // restore from cache 2139 2140 // Support for last Java frame (but use call_VM instead where possible) 2141 void set_last_Java_frame(Register last_java_sp, Register last_Java_pc); 2142 void reset_last_Java_frame(void); 2143 2144 // Call into the VM. 2145 // Passes the thread pointer (in O0) as a prepended argument. 2146 // Makes sure oop return values are visible to the GC. 2147 void call_VM(Register oop_result, address entry_point, int number_of_arguments = 0, bool check_exceptions = true); 2148 void call_VM(Register oop_result, address entry_point, Register arg_1, bool check_exceptions = true); 2149 void call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, bool check_exceptions = true); 2150 void call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions = true); 2151 2152 // these overloadings are not presently used on SPARC: 2153 void call_VM(Register oop_result, Register last_java_sp, address entry_point, int number_of_arguments = 0, bool check_exceptions = true); 2154 void call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, bool check_exceptions = true); 2155 void call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, bool check_exceptions = true); 2156 void call_VM(Register oop_result, Register last_java_sp, address entry_point, Register arg_1, Register arg_2, Register arg_3, bool check_exceptions = true); 2157 2158 void call_VM_leaf(Register thread_cache, address entry_point, int number_of_arguments = 0); 2159 void call_VM_leaf(Register thread_cache, address entry_point, Register arg_1); 2160 void call_VM_leaf(Register thread_cache, address entry_point, Register arg_1, Register arg_2); 2161 void call_VM_leaf(Register thread_cache, address entry_point, Register arg_1, Register arg_2, Register arg_3); 2162 2163 void get_vm_result (Register oop_result); 2164 void get_vm_result_2(Register oop_result); 2165 2166 // vm result is currently getting hijacked to for oop preservation 2167 void set_vm_result(Register oop_result); 2168 2169 // if call_VM_base was called with check_exceptions=false, then call 2170 // check_and_forward_exception to handle exceptions when it is safe 2171 void check_and_forward_exception(Register scratch_reg); 2172 2173 private: 2174 // For V8 2175 void read_ccr_trap(Register ccr_save); 2176 void write_ccr_trap(Register ccr_save1, Register scratch1, Register scratch2); 2177 2178 #ifdef ASSERT 2179 // For V8 debugging. Uses V8 instruction sequence and checks 2180 // result with V9 insturctions rdccr and wrccr. 2181 // Uses Gscatch and Gscatch2 2182 void read_ccr_v8_assert(Register ccr_save); 2183 void write_ccr_v8_assert(Register ccr_save); 2184 #endif // ASSERT 2185 2186 public: 2187 2188 // Write to card table for - register is destroyed afterwards. 2189 void card_table_write(jbyte* byte_map_base, Register tmp, Register obj); 2190 2191 void card_write_barrier_post(Register store_addr, Register new_val, Register tmp); 2192 2193 #ifndef SERIALGC 2194 // Array store and offset 2195 void g1_write_barrier_pre(Register obj, Register index, int offset, Register tmp, bool preserve_o_regs); 2196 2197 void g1_write_barrier_post(Register store_addr, Register new_val, Register tmp); 2198 2199 // May do filtering, depending on the boolean arguments. 2200 void g1_card_table_write(jbyte* byte_map_base, 2201 Register tmp, Register obj, Register new_val, 2202 bool region_filter, bool null_filter); 2203 #endif // SERIALGC 2204 2205 // pushes double TOS element of FPU stack on CPU stack; pops from FPU stack 2206 void push_fTOS(); 2207 2208 // pops double TOS element from CPU stack and pushes on FPU stack 2209 void pop_fTOS(); 2210 2211 void empty_FPU_stack(); 2212 2213 void push_IU_state(); 2214 void pop_IU_state(); 2215 2216 void push_FPU_state(); 2217 void pop_FPU_state(); 2218 2219 void push_CPU_state(); 2220 void pop_CPU_state(); 2221 2222 // if heap base register is used - reinit it with the correct value 2223 void reinit_heapbase(); 2224 2225 // Debugging 2226 void _verify_oop(Register reg, const char * msg, const char * file, int line); 2227 void _verify_oop_addr(Address addr, const char * msg, const char * file, int line); 2228 2229 #define verify_oop(reg) _verify_oop(reg, "broken oop " #reg, __FILE__, __LINE__) 2230 #define verify_oop_addr(addr) _verify_oop_addr(addr, "broken oop addr ", __FILE__, __LINE__) 2231 2232 // only if +VerifyOops 2233 void verify_FPU(int stack_depth, const char* s = "illegal FPU state"); 2234 // only if +VerifyFPU 2235 void stop(const char* msg); // prints msg, dumps registers and stops execution 2236 void warn(const char* msg); // prints msg, but don't stop 2237 void untested(const char* what = ""); 2238 void unimplemented(const char* what = "") { char* b = new char[1024]; jio_snprintf(b, 1024, "unimplemented: %s", what); stop(b); } 2239 void should_not_reach_here() { stop("should not reach here"); } 2240 void print_CPU_state(); 2241 2242 // oops in code 2243 AddressLiteral allocate_oop_address(jobject obj); // allocate_index 2244 AddressLiteral constant_oop_address(jobject obj); // find_index 2245 inline void set_oop (jobject obj, Register d); // uses allocate_oop_address 2246 inline void set_oop_constant (jobject obj, Register d); // uses constant_oop_address 2247 inline void set_oop (const AddressLiteral& obj_addr, Register d); // same as load_address 2248 2249 void set_narrow_oop( jobject obj, Register d ); 2250 2251 // nop padding 2252 void align(int modulus); 2253 2254 // declare a safepoint 2255 void safepoint(); 2256 2257 // factor out part of stop into subroutine to save space 2258 void stop_subroutine(); 2259 // factor out part of verify_oop into subroutine to save space 2260 void verify_oop_subroutine(); 2261 2262 // side-door communication with signalHandler in os_solaris.cpp 2263 static address _verify_oop_implicit_branch[3]; 2264 2265 #ifndef PRODUCT 2266 static void test(); 2267 #endif 2268 2269 // convert an incoming arglist to varargs format; put the pointer in d 2270 void set_varargs( Argument a, Register d ); 2271 2272 int total_frame_size_in_bytes(int extraWords); 2273 2274 // used when extraWords known statically 2275 void save_frame(int extraWords); 2276 void save_frame_c1(int size_in_bytes); 2277 // make a frame, and simultaneously pass up one or two register value 2278 // into the new register window 2279 void save_frame_and_mov(int extraWords, Register s1, Register d1, Register s2 = Register(), Register d2 = Register()); 2280 2281 // give no. (outgoing) params, calc # of words will need on frame 2282 void calc_mem_param_words(Register Rparam_words, Register Rresult); 2283 2284 // used to calculate frame size dynamically 2285 // result is in bytes and must be negated for save inst 2286 void calc_frame_size(Register extraWords, Register resultReg); 2287 2288 // calc and also save 2289 void calc_frame_size_and_save(Register extraWords, Register resultReg); 2290 2291 static void debug(char* msg, RegistersForDebugging* outWindow); 2292 2293 // implementations of bytecodes used by both interpreter and compiler 2294 2295 void lcmp( Register Ra_hi, Register Ra_low, 2296 Register Rb_hi, Register Rb_low, 2297 Register Rresult); 2298 2299 void lneg( Register Rhi, Register Rlow ); 2300 2301 void lshl( Register Rin_high, Register Rin_low, Register Rcount, 2302 Register Rout_high, Register Rout_low, Register Rtemp ); 2303 2304 void lshr( Register Rin_high, Register Rin_low, Register Rcount, 2305 Register Rout_high, Register Rout_low, Register Rtemp ); 2306 2307 void lushr( Register Rin_high, Register Rin_low, Register Rcount, 2308 Register Rout_high, Register Rout_low, Register Rtemp ); 2309 2310 #ifdef _LP64 2311 void lcmp( Register Ra, Register Rb, Register Rresult); 2312 #endif 2313 2314 // Loading values by size and signed-ness 2315 void load_sized_value(Address src, Register dst, size_t size_in_bytes, bool is_signed); 2316 2317 void float_cmp( bool is_float, int unordered_result, 2318 FloatRegister Fa, FloatRegister Fb, 2319 Register Rresult); 2320 2321 void fneg( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d); 2322 void fneg( FloatRegisterImpl::Width w, FloatRegister sd ) { Assembler::fneg(w, sd); } 2323 void fmov( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d); 2324 void fabs( FloatRegisterImpl::Width w, FloatRegister s, FloatRegister d); 2325 2326 void save_all_globals_into_locals(); 2327 void restore_globals_from_locals(); 2328 2329 void casx_under_lock(Register top_ptr_reg, Register top_reg, Register ptr_reg, 2330 address lock_addr=0, bool use_call_vm=false); 2331 void cas_under_lock(Register top_ptr_reg, Register top_reg, Register ptr_reg, 2332 address lock_addr=0, bool use_call_vm=false); 2333 void casn (Register addr_reg, Register cmp_reg, Register set_reg) ; 2334 2335 // These set the icc condition code to equal if the lock succeeded 2336 // and notEqual if it failed and requires a slow case 2337 void compiler_lock_object(Register Roop, Register Rmark, Register Rbox, 2338 Register Rscratch, 2339 BiasedLockingCounters* counters = NULL, 2340 bool try_bias = UseBiasedLocking); 2341 void compiler_unlock_object(Register Roop, Register Rmark, Register Rbox, 2342 Register Rscratch, 2343 bool try_bias = UseBiasedLocking); 2344 2345 // Biased locking support 2346 // Upon entry, lock_reg must point to the lock record on the stack, 2347 // obj_reg must contain the target object, and mark_reg must contain 2348 // the target object's header. 2349 // Destroys mark_reg if an attempt is made to bias an anonymously 2350 // biased lock. In this case a failure will go either to the slow 2351 // case or fall through with the notEqual condition code set with 2352 // the expectation that the slow case in the runtime will be called. 2353 // In the fall-through case where the CAS-based lock is done, 2354 // mark_reg is not destroyed. 2355 void biased_locking_enter(Register obj_reg, Register mark_reg, Register temp_reg, 2356 Label& done, Label* slow_case = NULL, 2357 BiasedLockingCounters* counters = NULL); 2358 // Upon entry, the base register of mark_addr must contain the oop. 2359 // Destroys temp_reg. 2360 2361 // If allow_delay_slot_filling is set to true, the next instruction 2362 // emitted after this one will go in an annulled delay slot if the 2363 // biased locking exit case failed. 2364 void biased_locking_exit(Address mark_addr, Register temp_reg, Label& done, bool allow_delay_slot_filling = false); 2365 2366 // allocation 2367 void eden_allocate( 2368 Register obj, // result: pointer to object after successful allocation 2369 Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise 2370 int con_size_in_bytes, // object size in bytes if known at compile time 2371 Register t1, // temp register 2372 Register t2, // temp register 2373 Label& slow_case // continuation point if fast allocation fails 2374 ); 2375 void tlab_allocate( 2376 Register obj, // result: pointer to object after successful allocation 2377 Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise 2378 int con_size_in_bytes, // object size in bytes if known at compile time 2379 Register t1, // temp register 2380 Label& slow_case // continuation point if fast allocation fails 2381 ); 2382 void tlab_refill(Label& retry_tlab, Label& try_eden, Label& slow_case); 2383 2384 // interface method calling 2385 void lookup_interface_method(Register recv_klass, 2386 Register intf_klass, 2387 RegisterOrConstant itable_index, 2388 Register method_result, 2389 Register temp_reg, Register temp2_reg, 2390 Label& no_such_interface); 2391 2392 // Test sub_klass against super_klass, with fast and slow paths. 2393 2394 // The fast path produces a tri-state answer: yes / no / maybe-slow. 2395 // One of the three labels can be NULL, meaning take the fall-through. 2396 // If super_check_offset is -1, the value is loaded up from super_klass. 2397 // No registers are killed, except temp_reg and temp2_reg. 2398 // If super_check_offset is not -1, temp2_reg is not used and can be noreg. 2399 void check_klass_subtype_fast_path(Register sub_klass, 2400 Register super_klass, 2401 Register temp_reg, 2402 Register temp2_reg, 2403 Label* L_success, 2404 Label* L_failure, 2405 Label* L_slow_path, 2406 RegisterOrConstant super_check_offset = RegisterOrConstant(-1), 2407 Register instanceof_hack = noreg); 2408 2409 // The rest of the type check; must be wired to a corresponding fast path. 2410 // It does not repeat the fast path logic, so don't use it standalone. 2411 // The temp_reg can be noreg, if no temps are available. 2412 // It can also be sub_klass or super_klass, meaning it's OK to kill that one. 2413 // Updates the sub's secondary super cache as necessary. 2414 void check_klass_subtype_slow_path(Register sub_klass, 2415 Register super_klass, 2416 Register temp_reg, 2417 Register temp2_reg, 2418 Register temp3_reg, 2419 Register temp4_reg, 2420 Label* L_success, 2421 Label* L_failure); 2422 2423 // Simplified, combined version, good for typical uses. 2424 // Falls through on failure. 2425 void check_klass_subtype(Register sub_klass, 2426 Register super_klass, 2427 Register temp_reg, 2428 Register temp2_reg, 2429 Label& L_success); 2430 2431 // method handles (JSR 292) 2432 void check_method_handle_type(Register mtype_reg, Register mh_reg, 2433 Register temp_reg, 2434 Label& wrong_method_type); 2435 void load_method_handle_vmslots(Register vmslots_reg, Register mh_reg, 2436 Register temp_reg); 2437 void jump_to_method_handle_entry(Register mh_reg, Register temp_reg, bool emit_delayed_nop = true); 2438 // offset relative to Gargs of argument at tos[arg_slot]. 2439 // (arg_slot == 0 means the last argument, not the first). 2440 RegisterOrConstant argument_offset(RegisterOrConstant arg_slot, 2441 int extra_slot_offset = 0); 2442 // Address of Gargs and argument_offset. 2443 Address argument_address(RegisterOrConstant arg_slot, 2444 int extra_slot_offset = 0); 2445 2446 // Stack overflow checking 2447 2448 // Note: this clobbers G3_scratch 2449 void bang_stack_with_offset(int offset) { 2450 // stack grows down, caller passes positive offset 2451 assert(offset > 0, "must bang with negative offset"); 2452 set((-offset)+STACK_BIAS, G3_scratch); 2453 st(G0, SP, G3_scratch); 2454 } 2455 2456 // Writes to stack successive pages until offset reached to check for 2457 // stack overflow + shadow pages. Clobbers tsp and scratch registers. 2458 void bang_stack_size(Register Rsize, Register Rtsp, Register Rscratch); 2459 2460 virtual RegisterOrConstant delayed_value_impl(intptr_t* delayed_value_addr, Register tmp, int offset); 2461 2462 void verify_tlab(); 2463 2464 Condition negate_condition(Condition cond); 2465 2466 // Helper functions for statistics gathering. 2467 // Conditionally (non-atomically) increments passed counter address, preserving condition codes. 2468 void cond_inc(Condition cond, address counter_addr, Register Rtemp1, Register Rtemp2); 2469 // Unconditional increment. 2470 void inc_counter(address counter_addr, Register Rtmp1, Register Rtmp2); 2471 void inc_counter(int* counter_addr, Register Rtmp1, Register Rtmp2); 2472 2473 // Compare char[] arrays aligned to 4 bytes. 2474 void char_arrays_equals(Register ary1, Register ary2, 2475 Register limit, Register result, 2476 Register chr1, Register chr2, Label& Ldone); 2477 2478 #undef VIRTUAL 2479 2480 }; 2481 2482 /** 2483 * class SkipIfEqual: 2484 * 2485 * Instantiating this class will result in assembly code being output that will 2486 * jump around any code emitted between the creation of the instance and it's 2487 * automatic destruction at the end of a scope block, depending on the value of 2488 * the flag passed to the constructor, which will be checked at run-time. 2489 */ 2490 class SkipIfEqual : public StackObj { 2491 private: 2492 MacroAssembler* _masm; 2493 Label _label; 2494 2495 public: 2496 // 'temp' is a temp register that this object can use (and trash) 2497 SkipIfEqual(MacroAssembler*, Register temp, 2498 const bool* flag_addr, Assembler::Condition condition); 2499 ~SkipIfEqual(); 2500 }; 2501 2502 #ifdef ASSERT 2503 // On RISC, there's no benefit to verifying instruction boundaries. 2504 inline bool AbstractAssembler::pd_check_instruction_mark() { return false; } 2505 #endif 2506 2507 #endif // CPU_SPARC_VM_ASSEMBLER_SPARC_HPP