Tue, 28 Jun 2016 16:34:47 +0800
[Code Reorganization] Moved fast_lock and fast_unlock from mips_64.ad to MacroAssembler.
1 /*
2 * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
3 * Copyright (c) 2015, 2016, Loongson Technology. All rights reserved.
4 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
5 *
6 * This code is free software; you can redistribute it and/or modify it
7 * under the terms of the GNU General Public License version 2 only, as
8 * published by the Free Software Foundation.
9 *
10 * This code is distributed in the hope that it will be useful, but WITHOUT
11 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
12 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
13 * version 2 for more details (a copy is included in the LICENSE file that
14 * accompanied this code).
15 *
16 * You should have received a copy of the GNU General Public License version
17 * 2 along with this work; if not, write to the Free Software Foundation,
18 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
19 *
20 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
21 * or visit www.oracle.com if you need additional information or have any
22 * questions.
23 *
24 */
26 #ifndef CPU_MIPS_VM_ASSEMBLER_MIPS_HPP
27 #define CPU_MIPS_VM_ASSEMBLER_MIPS_HPP
29 #include "asm/register.hpp"
31 class BiasedLockingCounters;
34 // Note: A register location is represented via a Register, not
35 // via an address for efficiency & simplicity reasons.
37 class ArrayAddress;
39 class Address VALUE_OBJ_CLASS_SPEC {
41 public:
42 enum ScaleFactor {
43 no_scale = -1,
44 times_1 = 0,
45 times_2 = 1,
46 times_4 = 2,
47 times_8 = 3,
48 times_ptr = LP64_ONLY(times_8) NOT_LP64(times_4)
49 };
51 static ScaleFactor times(int size) {
52 assert(size >= 1 && size <= 8 && is_power_of_2(size), "bad scale size");
53 if (size == 8) return times_8;
54 if (size == 4) return times_4;
55 if (size == 2) return times_2;
56 return times_1;
57 }
59 private:
60 Register _base;
61 Register _index;
62 ScaleFactor _scale;
63 int _disp;
64 RelocationHolder _rspec;
66 // Easily misused constructors make them private
67 // %%% can we make these go away?
68 //FIXME aoqi
69 //NOT_LP64(Address(address loc, RelocationHolder spec);)
70 Address(address loc, RelocationHolder spec);
71 Address(int disp, address loc, relocInfo::relocType rtype);
72 Address(int disp, address loc, RelocationHolder spec);
74 public:
76 int disp() { return _disp; }
77 // creation
78 Address()
79 : _base(noreg),
80 _index(noreg),
81 _scale(no_scale),
82 _disp(0) {
83 }
85 // No default displacement otherwise Register can be implicitly
86 // converted to 0(Register) which is quite a different animal.
88 Address(Register base, int disp)
89 : _base(base),
90 _index(noreg),
91 _scale(no_scale),
92 _disp(disp) {
93 }
95 Address(Register base)
96 : _base(base),
97 _index(noreg),
98 _scale(no_scale),
99 _disp(0) {
100 }
102 Address(Register base, Register index, ScaleFactor scale, int disp = 0)
103 : _base (base),
104 _index(index),
105 _scale(scale),
106 _disp (disp) {
107 assert(!index->is_valid() == (scale == Address::no_scale),
108 "inconsistent address");
109 }
111 // The following two overloads are used in connection with the
112 // ByteSize type (see sizes.hpp). They simplify the use of
113 // ByteSize'd arguments in assembly code. Note that their equivalent
114 // for the optimized build are the member functions with int disp
115 // argument since ByteSize is mapped to an int type in that case.
116 //
117 // Note: DO NOT introduce similar overloaded functions for WordSize
118 // arguments as in the optimized mode, both ByteSize and WordSize
119 // are mapped to the same type and thus the compiler cannot make a
120 // distinction anymore (=> compiler errors).
122 #ifdef ASSERT
123 Address(Register base, ByteSize disp)
124 : _base(base),
125 _index(noreg),
126 _scale(no_scale),
127 _disp(in_bytes(disp)) {
128 }
130 Address(Register base, Register index, ScaleFactor scale, ByteSize disp)
131 : _base(base),
132 _index(index),
133 _scale(scale),
134 _disp(in_bytes(disp)) {
135 assert(!index->is_valid() == (scale == Address::no_scale),
136 "inconsistent address");
137 }
138 #endif // ASSERT
140 // accessors
141 bool uses(Register reg) const { return _base == reg || _index == reg; }
142 Register base() const { return _base; }
143 Register index() const { return _index; }
144 ScaleFactor scale() const { return _scale; }
145 int disp() const { return _disp; }
147 // Convert the raw encoding form into the form expected by the constructor for
148 // Address. An index of 4 (rsp) corresponds to having no index, so convert
149 // that to noreg for the Address constructor.
150 //static Address make_raw(int base, int index, int scale, int disp);
152 static Address make_array(ArrayAddress);
154 /*
155 private:
156 bool base_needs_rex() const {
157 return _base != noreg && _base->encoding() >= 8;
158 }
160 bool index_needs_rex() const {
161 return _index != noreg &&_index->encoding() >= 8;
162 }
164 relocInfo::relocType reloc() const { return _rspec.type(); }
165 */
166 friend class Assembler;
167 friend class MacroAssembler;
168 friend class LIR_Assembler; // base/index/scale/disp
169 };
172 // Calling convention
173 class Argument VALUE_OBJ_CLASS_SPEC {
174 private:
175 int _number;
176 public:
177 enum {
178 #ifdef _LP64
179 n_register_parameters = 8, // 8 integer registers used to pass parameters
180 n_float_register_parameters = 8 // 4 float registers used to pass parameters
181 #else
182 n_register_parameters = 4, // 4 integer registers used to pass parameters
183 n_float_register_parameters = 4 // 4 float registers used to pass parameters
184 #endif
185 };
187 Argument(int number):_number(number){ }
188 Argument successor() {return Argument(number() + 1);}
190 int number()const {return _number;}
191 bool is_Register()const {return _number < n_register_parameters;}
192 bool is_FloatRegister()const {return _number < n_float_register_parameters;}
194 Register as_Register()const {
195 assert(is_Register(), "must be a register argument");
196 return ::as_Register(A0->encoding() + _number);
197 }
198 FloatRegister as_FloatRegister()const {
199 assert(is_FloatRegister(), "must be a float register argument");
200 return ::as_FloatRegister(F12->encoding() + _number);
201 }
203 Address as_caller_address()const {return Address(SP, (number() LP64_ONLY( -n_register_parameters)) * wordSize);}
204 };
208 //
209 // AddressLiteral has been split out from Address because operands of this type
210 // need to be treated specially on 32bit vs. 64bit platforms. By splitting it out
211 // the few instructions that need to deal with address literals are unique and the
212 // MacroAssembler does not have to implement every instruction in the Assembler
213 // in order to search for address literals that may need special handling depending
214 // on the instruction and the platform. As small step on the way to merging i486/amd64
215 // directories.
216 //
217 class AddressLiteral VALUE_OBJ_CLASS_SPEC {
218 friend class ArrayAddress;
219 RelocationHolder _rspec;
220 // Typically we use AddressLiterals we want to use their rval
221 // However in some situations we want the lval (effect address) of the item.
222 // We provide a special factory for making those lvals.
223 bool _is_lval;
225 // If the target is far we'll need to load the ea of this to
226 // a register to reach it. Otherwise if near we can do rip
227 // relative addressing.
229 address _target;
231 protected:
232 // creation
233 AddressLiteral()
234 : _is_lval(false),
235 _target(NULL)
236 {}
238 public:
240 AddressLiteral(address target, relocInfo::relocType rtype);
242 AddressLiteral(address target, RelocationHolder const& rspec)
243 : _rspec(rspec),
244 _is_lval(false),
245 _target(target)
246 {}
247 #ifdef _LP64
248 // 32-bit complains about a multiple declaration for int*.
249 AddressLiteral(intptr_t* addr, relocInfo::relocType rtype = relocInfo::none)
250 : _target((address) addr),
251 _rspec(rspec_from_rtype(rtype, (address) addr)) {}
252 #endif
255 AddressLiteral addr() {
256 AddressLiteral ret = *this;
257 ret._is_lval = true;
258 return ret;
259 }
262 private:
264 address target() { return _target; }
265 bool is_lval() { return _is_lval; }
267 relocInfo::relocType reloc() const { return _rspec.type(); }
268 const RelocationHolder& rspec() const { return _rspec; }
270 friend class Assembler;
271 friend class MacroAssembler;
272 friend class Address;
273 friend class LIR_Assembler;
274 RelocationHolder rspec_from_rtype(relocInfo::relocType rtype, address addr) {
275 switch (rtype) {
276 case relocInfo::external_word_type:
277 return external_word_Relocation::spec(addr);
278 case relocInfo::internal_word_type:
279 return internal_word_Relocation::spec(addr);
280 case relocInfo::opt_virtual_call_type:
281 return opt_virtual_call_Relocation::spec();
282 case relocInfo::static_call_type:
283 return static_call_Relocation::spec();
284 case relocInfo::runtime_call_type:
285 return runtime_call_Relocation::spec();
286 case relocInfo::poll_type:
287 case relocInfo::poll_return_type:
288 return Relocation::spec_simple(rtype);
289 case relocInfo::none:
290 case relocInfo::oop_type:
291 // Oops are a special case. Normally they would be their own section
292 // but in cases like icBuffer they are literals in the code stream that
293 // we don't have a section for. We use none so that we get a literal address
294 // which is always patchable.
295 return RelocationHolder();
296 default:
297 ShouldNotReachHere();
298 return RelocationHolder();
299 }
300 }
302 };
304 // Convience classes
305 class RuntimeAddress: public AddressLiteral {
307 public:
309 RuntimeAddress(address target) : AddressLiteral(target, relocInfo::runtime_call_type) {}
311 };
313 class OopAddress: public AddressLiteral {
315 public:
317 OopAddress(address target) : AddressLiteral(target, relocInfo::oop_type){}
319 };
321 class ExternalAddress: public AddressLiteral {
323 public:
325 ExternalAddress(address target) : AddressLiteral(target, relocInfo::external_word_type){}
327 };
329 class InternalAddress: public AddressLiteral {
331 public:
333 InternalAddress(address target) : AddressLiteral(target, relocInfo::internal_word_type) {}
335 };
337 // x86 can do array addressing as a single operation since disp can be an absolute
338 // address amd64 can't. We create a class that expresses the concept but does extra
339 // magic on amd64 to get the final result
341 class ArrayAddress VALUE_OBJ_CLASS_SPEC {
342 private:
344 AddressLiteral _base;
345 Address _index;
347 public:
349 ArrayAddress() {};
350 ArrayAddress(AddressLiteral base, Address index): _base(base), _index(index) {};
351 AddressLiteral base() { return _base; }
352 Address index() { return _index; }
354 };
356 const int FPUStateSizeInWords = NOT_LP64(27) LP64_ONLY( 512 / wordSize);
358 // The MIPS LOONGSON Assembler: Pure assembler doing NO optimizations on the instruction
359 // level ; i.e., what you write is what you get. The Assembler is generating code into
360 // a CodeBuffer.
362 class Assembler : public AbstractAssembler {
363 friend class AbstractAssembler; // for the non-virtual hack
364 friend class LIR_Assembler; // as_Address()
365 friend class StubGenerator;
367 public:
368 enum ops {
369 special_op = 0x00,
370 regimm_op = 0x01,
371 j_op = 0x02,
372 jal_op = 0x03,
373 beq_op = 0x04,
374 bne_op = 0x05,
375 blez_op = 0x06,
376 bgtz_op = 0x07,
377 addi_op = 0x08,
378 addiu_op = 0x09,
379 slti_op = 0x0a,
380 sltiu_op = 0x0b,
381 andi_op = 0x0c,
382 ori_op = 0x0d,
383 xori_op = 0x0e,
384 lui_op = 0x0f,
385 cop0_op = 0x10,
386 cop1_op = 0x11,
387 cop2_op = 0x12,
388 cop3_op = 0x13,
389 beql_op = 0x14,
390 bnel_op = 0x15,
391 blezl_op = 0x16,
392 bgtzl_op = 0x17,
393 daddi_op = 0x18,
394 daddiu_op = 0x19,
395 ldl_op = 0x1a,
396 ldr_op = 0x1b,
397 lb_op = 0x20,
398 lh_op = 0x21,
399 lwl_op = 0x22,
400 lw_op = 0x23,
401 lbu_op = 0x24,
402 lhu_op = 0x25,
403 lwr_op = 0x26,
404 lwu_op = 0x27,
405 sb_op = 0x28,
406 sh_op = 0x29,
407 swl_op = 0x2a,
408 sw_op = 0x2b,
409 sdl_op = 0x2c,
410 sdr_op = 0x2d,
411 swr_op = 0x2e,
412 cache_op = 0x2f,
413 ll_op = 0x30,
414 lwc1_op = 0x31,
415 lld_op = 0x34,
416 ldc1_op = 0x35,
417 ld_op = 0x37,
418 sc_op = 0x38,
419 swc1_op = 0x39,
420 scd_op = 0x3c,
421 sdc1_op = 0x3d,
422 sd_op = 0x3f
423 };
425 static const char *ops_name[];
427 //special family, the opcode is in low 6 bits.
428 enum special_ops {
429 sll_op = 0x00,
430 srl_op = 0x02,
431 sra_op = 0x03,
432 sllv_op = 0x04,
433 srlv_op = 0x06,
434 srav_op = 0x07,
435 jr_op = 0x08,
436 jalr_op = 0x09,
437 syscall_op = 0x0c,
438 break_op = 0x0d,
439 sync_op = 0x0f,
440 mfhi_op = 0x10,
441 mthi_op = 0x11,
442 mflo_op = 0x12,
443 mtlo_op = 0x13,
444 dsllv_op = 0x14,
445 dsrlv_op = 0x16,
446 dsrav_op = 0x17,
447 mult_op = 0x18,
448 multu_op = 0x19,
449 div_op = 0x1a,
450 divu_op = 0x1b,
451 dmult_op = 0x1c,
452 dmultu_op = 0x1d,
453 ddiv_op = 0x1e,
454 ddivu_op = 0x1f,
455 add_op = 0x20,
456 addu_op = 0x21,
457 sub_op = 0x22,
458 subu_op = 0x23,
459 and_op = 0x24,
460 or_op = 0x25,
461 xor_op = 0x26,
462 nor_op = 0x27,
463 slt_op = 0x2a,
464 sltu_op = 0x2b,
465 dadd_op = 0x2c,
466 daddu_op = 0x2d,
467 dsub_op = 0x2e,
468 dsubu_op = 0x2f,
469 tge_op = 0x30,
470 tgeu_op = 0x31,
471 tlt_op = 0x32,
472 tltu_op = 0x33,
473 teq_op = 0x34,
474 tne_op = 0x36,
475 dsll_op = 0x38,
476 dsrl_op = 0x3a,
477 dsra_op = 0x3b,
478 dsll32_op = 0x3c,
479 dsrl32_op = 0x3e,
480 dsra32_op = 0x3f
481 };
483 static const char* special_name[];
485 //regimm family, the opcode is in rt[16...20], 5 bits
486 enum regimm_ops {
487 bltz_op = 0x00,
488 bgez_op = 0x01,
489 bltzl_op = 0x02,
490 bgezl_op = 0x03,
491 tgei_op = 0x08,
492 tgeiu_op = 0x09,
493 tlti_op = 0x0a,
494 tltiu_op = 0x0b,
495 teqi_op = 0x0c,
496 tnei_op = 0x0e,
497 bltzal_op = 0x10,
498 bgezal_op = 0x11,
499 bltzall_op = 0x12,
500 bgezall_op = 0x13,
501 };
503 static const char* regimm_name[];
505 //copx family,the op in rs, 5 bits
506 enum cop_ops {
507 mf_op = 0x00,
508 dmf_op = 0x01,
509 cf_op = 0x02,
510 mt_op = 0x04,
511 dmt_op = 0x05,
512 ct_op = 0x06,
513 bc_op = 0x08,
514 single_fmt = 0x10,
515 double_fmt = 0x11,
516 word_fmt = 0x14,
517 long_fmt = 0x15
518 };
520 enum bc_ops {
521 bcf_op = 0x00,
522 bct_op = 0x01,
523 bcfl_op = 0x02,
524 bctl_op = 0x03,
525 };
527 enum c_conds {
528 f_cond = 0x30,
529 un_cond = 0x31,
530 eq_cond = 0x32,
531 ueq_cond = 0x33,
532 olt_cond = 0x34,
533 ult_cond = 0x35,
534 ole_cond = 0x36,
535 ule_cond = 0x37,
536 sf_cond = 0x38,
537 ngle_cond = 0x39,
538 seq_cond = 0x3a,
539 ngl_cond = 0x3b,
540 lt_cond = 0x3c,
541 nge_cond = 0x3d,
542 le_cond = 0x3e,
543 ngt_cond = 0x3f
544 };
546 //low 6 bits of cp1 instruction
547 enum float_ops {
548 fadd_op = 0x00,
549 fsub_op = 0x01,
550 fmul_op = 0x02,
551 fdiv_op = 0x03,
552 fsqrt_op = 0x04,
553 fabs_op = 0x05,
554 fmov_op = 0x06,
555 fneg_op = 0x07,
556 froundl_op = 0x08,
557 ftruncl_op = 0x09,
558 fceill_op = 0x0a,
559 ffloorl_op = 0x0b,
560 froundw_op = 0x0c,
561 ftruncw_op = 0x0d,
562 fceilw_op = 0x0e,
563 ffloorw_op = 0x0f,
564 fcvts_op = 0x20,
565 fcvtd_op = 0x21,
566 fcvtw_op = 0x24,
567 fcvtl_op = 0x25,
568 fpll_op =0x2c,
569 fplu_op =0x2d,
570 fpul_op =0x2e,
571 fpuu_op =0x2f,
573 };
575 /* 2013.10.16 Jin: merge from OpenJDK 8 */
576 enum WhichOperand {
577 // input to locate_operand, and format code for relocations
578 imm_operand = 0, // embedded 32-bit|64-bit immediate operand
579 disp32_operand = 1, // embedded 32-bit displacement or address
580 call32_operand = 2, // embedded 32-bit self-relative displacement
581 #ifndef _LP64
582 _WhichOperand_limit = 3
583 #else
584 narrow_oop_operand = 3, // embedded 32-bit immediate narrow oop
585 _WhichOperand_limit = 4
586 #endif
587 };
589 /* Godson3 extension */
590 enum godson3_ops {
591 gsldx_op = (0x36 << 26) | 0x3,
592 gslwx_op = (0x36 << 26) | 0x2,
593 };
595 static const char* float_name[];
597 static int opcode(int insn) { return (insn>>26)&0x3f; }
598 static int rs(int insn) { return (insn>>21)&0x1f; }
599 static int rt(int insn) { return (insn>>16)&0x1f; }
600 static int rd(int insn) { return (insn>>11)&0x1f; }
601 static int sa(int insn) { return (insn>>6)&0x1f; }
602 static int special(int insn) { return insn&0x3f; }
603 static int imm_off(int insn) { return (short)low16(insn); }
605 static int low (int x, int l) { return bitfield(x, 0, l); }
606 static int low16(int x) { return low(x, 16); }
607 static int low26(int x) { return low(x, 26); }
609 protected:
610 //help methods for instruction ejection
612 //I-Type (Immediate)
613 // 31 26 25 21 20 16 15 0
614 //| opcode | rs | rt | immediat |
615 //| | | | |
616 // 6 5 5 16
617 static int insn_ORRI(int op, int rs, int rt, int imm) { return (op<<26) | (rs<<21) | (rt<<16) | low16(imm); }
619 //R-Type (Register)
620 // 31 26 25 21 20 16 15 11 10 6 5 0
621 //| special | rs | rt | rd | 0 | opcode |
622 //| 0 0 0 0 0 0 | | | | 0 0 0 0 0 | |
623 // 6 5 5 5 5 6
624 static int insn_RRRO(int rs, int rt, int rd, int op) { return (rs<<21) | (rt<<16) | (rd<<11) | op; }
625 static int insn_RRSO(int rt, int rd, int sa, int op) { return (rt<<16) | (rd<<11) | (sa<<6) | op; }
626 static int insn_RRCO(int rs, int rt, int code, int op) { return (rs<<21) | (rt<<16) | (code<<6) | op; }
628 static int insn_COP0(int op, int rt, int rd) { return (cop0_op<<26) | (op<<21) | (rt<<16) | (rd<<11); }
629 static int insn_COP1(int op, int rt, int fs) { return (cop1_op<<26) | (op<<21) | (rt<<16) | (fs<<11); }
631 static int insn_F3RO(int fmt, int ft, int fs, int fd, int func) {
632 return (cop1_op<<26) | (fmt<<21) | (ft<<16) | (fs<<11) | (fd<<6) | func;
633 }
636 //static int low (int x, int l) { return bitfield(x, 0, l); }
637 //static int low16(int x) { return low(x, 16); }
638 //static int low26(int x) { return low(x, 26); }
640 static int high (int x, int l) { return bitfield(x, 32-l, l); }
641 static int high16(int x) { return high(x, 16); }
642 static int high6 (int x) { return high(x, 6); }
644 //get the offset field of jump/branch instruction
645 int offset(address entry) {
646 assert(is_simm16((entry - pc() - 4) / 4), "change this code");
647 if (!is_simm16((entry - pc() - 4) / 4)) {
648 tty->print_cr("!!! is_simm16: %x", (entry - pc() - 4) / 4);
649 }
650 return (entry - pc() - 4) / 4;
651 }
654 public:
655 using AbstractAssembler::offset;
657 //sign expand with the sign bit is h
658 static int expand(int x, int h) { return -(x & (1<<h)) | x; }
660 // mips lui/addiu is both sign extended, so if you wan't to use off32/imm32, you have to use the follow three
661 // by yjl 6/22/2005
662 static int split_low(int x) {
663 return (x & 0xffff);
664 }
666 static int split_high(int x) {
667 return ( (x >> 16) + ((x & 0x8000) != 0) ) & 0xffff;
668 }
670 static int merge(int low, int high) {
671 return expand(low, 15) + (high<<16);
672 }
674 #ifdef _LP64
675 static intptr_t merge(intptr_t x0, intptr_t x16, intptr_t x32, intptr_t x48) {
676 return (x48 << 48) | (x32 << 32) | (x16 << 16) | x0;
677 /*
678 return ((intptr_t)(long_at(0) & 0xffff) << 48)
679 + expand((intptr_t)(long_at(4) & 0xffff) << 32, 47)
680 + expand((intptr_t)(long_at(12) & 0xffff) << 16, 31)
681 + expand((intptr_t)(long_at(20) & 0xffff), 15);
682 return expand(low, 15) + (high<<16);
683 */
684 }
685 #endif
687 // modified by spark 2005/08/18
688 static bool is_simm (int x, int nbits) { return -( 1 << nbits-1 ) <= x && x < ( 1 << nbits-1 ); }
689 static bool is_simm16(int x) { return is_simm(x, 16); }
691 // test if imm can be coded in a instruction with 16-bit imm/off
692 // by yjl 6/23/2005
693 /*static bool fit_in_insn(int imm) {
694 return imm == (short)imm;
695 }*/
697 static bool fit_in_jal(int offset) {
698 return is_simm(offset, 26);
699 }
702 // test if entry can be filled in the jl/jal,
703 // must be used just before you emit jl/jal
704 // by yjl 6/27/2005
705 bool fit_int_jal(address entry) {
706 return fit_in_jal(offset(entry));
707 }
709 bool fit_int_branch(address entry) {
710 return is_simm16(offset(entry));
711 }
713 protected:
714 #ifdef ASSERT
715 #define CHECK_DELAY
716 #endif
717 #ifdef CHECK_DELAY
718 enum Delay_state { no_delay, at_delay_slot, filling_delay_slot } delay_state;
719 #endif
721 public:
722 void assert_not_delayed() {
723 #ifdef CHECK_DELAY
724 assert_not_delayed("next instruction should not be a delay slot");
725 #endif
726 }
728 void assert_not_delayed(const char* msg) {
729 #ifdef CHECK_DELAY
730 //guarantee( delay_state == no_delay, msg );
731 //aoqi_test
732 if(delay_state != no_delay){
733 tty->print_cr("%s:%d, pc: %lx", __func__, __LINE__, pc());
734 }
735 assert(delay_state == no_delay, msg);
736 #endif
737 }
739 protected:
740 // Delay slot helpers
741 // cti is called when emitting control-transfer instruction,
742 // BEFORE doing the emitting.
743 // Only effective when assertion-checking is enabled.
745 // called when emitting cti with a delay slot, AFTER emitting
746 void has_delay_slot() {
747 #ifdef CHECK_DELAY
748 assert_not_delayed("just checking");
749 delay_state = at_delay_slot;
750 #endif
751 }
753 public:
754 Assembler* delayed() {
755 #ifdef CHECK_DELAY
756 guarantee( delay_state == at_delay_slot, "delayed instructition is not in delay slot");
757 delay_state = filling_delay_slot;
758 #endif
759 return this;
760 }
762 void flush() {
763 #ifdef CHECK_DELAY
764 guarantee( delay_state == no_delay, "ending code with a delay slot");
765 #endif
766 AbstractAssembler::flush();
767 }
769 inline void emit_long(int); // shadows AbstractAssembler::emit_long
770 inline void emit_data(int x) { emit_long(x); }
771 inline void emit_data(int, RelocationHolder const&);
772 inline void emit_data(int, relocInfo::relocType rtype);
773 inline void check_delay();
776 // Generic instructions
777 // Does 32bit or 64bit as needed for the platform. In some sense these
778 // belong in macro assembler but there is no need for both varieties to exist
780 #ifndef _LP64
781 void add(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), add_op)); }
782 void addi(Register rt, Register rs, int imm) { emit_long(insn_ORRI(addi_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
783 void addiu(Register rt, Register rs, int imm) { emit_long(insn_ORRI(addiu_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
784 void addu(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), addu_op)); }
785 #else
786 void add(Register rd, Register rs, Register rt) { dadd (rd, rs, rt); }
787 void add32(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), add_op)); }
788 void addu32(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), addu_op)); }
789 void addiu32(Register rt, Register rs, int imm) { emit_long(insn_ORRI(addiu_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
790 void addi(Register rt, Register rs, int imm) { daddi (rt, rs, imm);}
791 void addiu(Register rt, Register rs, int imm) { daddiu (rt, rs, imm);}
792 void addu(Register rd, Register rs, Register rt) { daddu (rd, rs, rt); }
793 #endif
795 void andr(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), and_op)); }
796 void andi(Register rt, Register rs, int imm) { emit_long(insn_ORRI(andi_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
798 void beq (Register rs, Register rt, int off) { emit_long(insn_ORRI(beq_op, (int)rs->encoding(), (int)rt->encoding(), off)); has_delay_slot(); }
799 void beql (Register rs, Register rt, int off) { emit_long(insn_ORRI(beql_op, (int)rs->encoding(), (int)rt->encoding(), off)); has_delay_slot(); }
800 void bgez (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bgez_op, off)); has_delay_slot(); }
801 void bgezal (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bgezal_op, off)); has_delay_slot(); }
802 void bgezall(Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bgezall_op, off)); has_delay_slot(); }
803 void bgezl (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bgezl_op, off)); has_delay_slot(); }
804 void bgtz (Register rs, int off) { emit_long(insn_ORRI(bgtz_op, (int)rs->encoding(), 0, off)); has_delay_slot(); }
805 void bgtzl (Register rs, int off) { emit_long(insn_ORRI(bgtzl_op, (int)rs->encoding(), 0, off)); has_delay_slot(); }
806 void blez (Register rs, int off) { emit_long(insn_ORRI(blez_op, (int)rs->encoding(), 0, off)); has_delay_slot(); }
807 void blezl (Register rs, int off) { emit_long(insn_ORRI(blezl_op, (int)rs->encoding(), 0, off)); has_delay_slot(); }
808 void bltz (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bltz_op, off)); has_delay_slot(); }
809 void bltzal (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bltzal_op, off)); has_delay_slot(); }
810 void bltzall(Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bltzall_op, off)); has_delay_slot(); }
811 void bltzl (Register rs, int off) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), bltzl_op, off)); has_delay_slot(); }
812 void bne (Register rs, Register rt, int off) { emit_long(insn_ORRI(bne_op, (int)rs->encoding(), (int)rt->encoding(), off)); has_delay_slot(); }
813 void bnel (Register rs, Register rt, int off) { emit_long(insn_ORRI(bnel_op, (int)rs->encoding(), (int)rt->encoding(), off)); has_delay_slot(); }
814 void brk (int code) { emit_long(break_op | (code<<16)); }
816 void beq (Register rs, Register rt, address entry) { beq(rs, rt, offset(entry)); }
817 void beql (Register rs, Register rt, address entry) { beql(rs, rt, offset(entry));}
818 void bgez (Register rs, address entry) { bgez (rs, offset(entry)); }
819 void bgezal (Register rs, address entry) { bgezal (rs, offset(entry)); }
820 void bgezall(Register rs, address entry) { bgezall(rs, offset(entry)); }
821 void bgezl (Register rs, address entry) { bgezl (rs, offset(entry)); }
822 void bgtz (Register rs, address entry) { bgtz (rs, offset(entry)); }
823 void bgtzl (Register rs, address entry) { bgtzl (rs, offset(entry)); }
824 void blez (Register rs, address entry) { blez (rs, offset(entry)); }
825 void blezl (Register rs, address entry) { blezl (rs, offset(entry)); }
826 void bltz (Register rs, address entry) { bltz (rs, offset(entry)); }
827 void bltzal (Register rs, address entry) { bltzal (rs, offset(entry)); }
828 void bltzall(Register rs, address entry) { bltzall(rs, offset(entry)); }
829 void bltzl (Register rs, address entry) { bltzl (rs, offset(entry)); }
830 void bne (Register rs, Register rt, address entry) { bne(rs, rt, offset(entry)); }
831 void bnel (Register rs, Register rt, address entry) { bnel(rs, rt, offset(entry)); }
833 void beq (Register rs, Register rt, Label& L) { beq(rs, rt, target(L)); }
834 void beql (Register rs, Register rt, Label& L) { beql(rs, rt, target(L)); }
835 void bgez (Register rs, Label& L){ bgez (rs, target(L)); }
836 void bgezal (Register rs, Label& L){ bgezal (rs, target(L)); }
837 void bgezall(Register rs, Label& L){ bgezall(rs, target(L)); }
838 void bgezl (Register rs, Label& L){ bgezl (rs, target(L)); }
839 void bgtz (Register rs, Label& L){ bgtz (rs, target(L)); }
840 void bgtzl (Register rs, Label& L){ bgtzl (rs, target(L)); }
841 void blez (Register rs, Label& L){ blez (rs, target(L)); }
842 void blezl (Register rs, Label& L){ blezl (rs, target(L)); }
843 void bltz (Register rs, Label& L){ bltz (rs, target(L)); }
844 void bltzal (Register rs, Label& L){ bltzal (rs, target(L)); }
845 void bltzall(Register rs, Label& L){ bltzall(rs, target(L)); }
846 void bltzl (Register rs, Label& L){ bltzl (rs, target(L)); }
847 void bne (Register rs, Register rt, Label& L){ bne(rs, rt, target(L)); }
848 void bnel (Register rs, Register rt, Label& L){ bnel(rs, rt, target(L)); }
850 void dadd (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dadd_op)); }
851 void daddi (Register rt, Register rs, int imm) { emit_long(insn_ORRI(daddi_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
852 void daddiu(Register rt, Register rs, int imm) { emit_long(insn_ORRI(daddiu_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
853 void daddu (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), daddu_op)); }
854 void ddiv (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, ddiv_op)); }
855 void ddivu (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, ddivu_op)); }
856 // Do mult and div need both 32-bit and 64-bit version? FIXME aoqi
857 //#ifndef _LP64
858 #if 1
859 void div (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, div_op)); }
860 void divu (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, divu_op)); }
861 #else
862 void div (Register rs, Register rt) { ddiv (rs, rt);}
863 void divu (Register rs, Register rt) { ddivu(rs, rt);}
864 #endif
865 void dmfc0 (Register rt, FloatRegister rd) { emit_long(insn_COP0(dmf_op, (int)rt->encoding(), (int)rd->encoding())); }
866 void dmtc0 (Register rt, FloatRegister rd) { emit_long(insn_COP0(dmt_op, (int)rt->encoding(), (int)rd->encoding())); }
867 void dmult (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, dmult_op)); }
868 void dmultu(Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, dmultu_op)); }
869 void dsll (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsll_op)); }
870 void dsllv (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dsllv_op)); }
871 void dsll32(Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsll32_op)); }
872 void dsra (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsra_op)); }
873 void dsrav (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dsrav_op)); }
874 void dsra32(Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsra32_op)); }
875 void dsrl (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsrl_op)); }
876 void dsrlv (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dsrlv_op)); }
877 void dsrl32(Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, dsrl32_op)); }
878 void dsub (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dsub_op)); }
879 void dsubu (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), dsubu_op)); }
881 void b(int off) { beq(R0, R0, off); }
882 void b(address entry) { b(offset(entry)); }
883 void b(Label& L) { b(target(L)); }
885 void j(address entry);
886 void jal(address entry);
888 void jalr(Register rd, Register rs) { emit_long( ((int)rs->encoding()<<21) | ((int)rd->encoding()<<11) | jalr_op); has_delay_slot(); }
889 void jalr(Register rs) { jalr(RA, rs); }
890 void jalr() { jalr(T9); }
892 void jr(Register rs) { emit_long(((int)rs->encoding()<<21) | jr_op); has_delay_slot(); }
894 void lb (Register rt, Register base, int off) { emit_long(insn_ORRI(lb_op, (int)base->encoding(), (int)rt->encoding(), off)); }
895 void lbu(Register rt, Register base, int off) { emit_long(insn_ORRI(lbu_op, (int)base->encoding(), (int)rt->encoding(), off)); }
896 void ld (Register rt, Register base, int off) { emit_long(insn_ORRI(ld_op, (int)base->encoding(), (int)rt->encoding(), off)); }
897 void ldl(Register rt, Register base, int off) { emit_long(insn_ORRI(ldl_op, (int)base->encoding(), (int)rt->encoding(), off)); }
898 void ldr(Register rt, Register base, int off) { emit_long(insn_ORRI(ldr_op, (int)base->encoding(), (int)rt->encoding(), off)); }
899 void lh (Register rt, Register base, int off) { emit_long(insn_ORRI(lh_op, (int)base->encoding(), (int)rt->encoding(), off)); }
900 void lhu(Register rt, Register base, int off) { emit_long(insn_ORRI(lhu_op, (int)base->encoding(), (int)rt->encoding(), off)); }
901 void ll (Register rt, Register base, int off) { emit_long(insn_ORRI(ll_op, (int)base->encoding(), (int)rt->encoding(), off)); }
902 void lld(Register rt, Register base, int off) { emit_long(insn_ORRI(lld_op, (int)base->encoding(), (int)rt->encoding(), off)); }
903 void lui(Register rt, int imm) { emit_long(insn_ORRI(lui_op, 0, (int)rt->encoding(), imm)); }
904 void lw (Register rt, Register base, int off) { emit_long(insn_ORRI(lw_op, (int)base->encoding(), (int)rt->encoding(), off)); }
905 void lwl(Register rt, Register base, int off) { emit_long(insn_ORRI(lwl_op, (int)base->encoding(), (int)rt->encoding(), off)); }
906 void lwr(Register rt, Register base, int off) { emit_long(insn_ORRI(lwr_op, (int)base->encoding(), (int)rt->encoding(), off)); }
907 void lwu(Register rt, Register base, int off) { emit_long(insn_ORRI(lwu_op, (int)base->encoding(), (int)rt->encoding(), off)); }
909 void lb (Register rt, Address src);
910 void lbu(Register rt, Address src);
911 void ld (Register rt, Address src);
912 void ldl(Register rt, Address src);
913 void ldr(Register rt, Address src);
914 void lh (Register rt, Address src);
915 void lhu(Register rt, Address src);
916 void ll (Register rt, Address src);
917 void lld(Register rt, Address src);
918 void lw (Register rt, Address src);
919 void lwl(Register rt, Address src);
920 void lwr(Register rt, Address src);
921 void lwu(Register rt, Address src);
922 void lea(Register rt, Address src);
924 void mfc0 (Register rt, Register rd) { emit_long(insn_COP0(mf_op, (int)rt->encoding(), (int)rd->encoding())); }
925 void mfhi (Register rd) { emit_long( ((int)rd->encoding()<<11) | mfhi_op ); }
926 void mflo (Register rd) { emit_long( ((int)rd->encoding()<<11) | mflo_op ); }
927 void mtc0 (Register rt, Register rd) { emit_long(insn_COP0(mt_op, (int)rt->encoding(), (int)rd->encoding())); }
928 void mthi (Register rs) { emit_long( ((int)rs->encoding()<<21) | mthi_op ); }
929 void mtlo (Register rs) { emit_long( ((int)rs->encoding()<<21) | mtlo_op ); }
930 // Do mult and div need both 32-bit and 64-bit version? FIXME aoqi
931 //#ifndef _LP64
932 #if 1
933 void mult (Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, mult_op)); }
934 void multu(Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), 0, multu_op)); }
935 #else
936 void mult (Register rs, Register rt) { dmult (rs, rt); }
937 void multu(Register rs, Register rt) { dmultu (rs, rt); }
938 #endif
940 void nor(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), nor_op)); }
942 void orr(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), or_op)); }
943 void ori(Register rt, Register rs, int imm) { emit_long(insn_ORRI(ori_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
945 void sb (Register rt, Register base, int off) { emit_long(insn_ORRI(sb_op, (int)base->encoding(), (int)rt->encoding(), off)); }
946 void sc (Register rt, Register base, int off) { emit_long(insn_ORRI(sc_op, (int)base->encoding(), (int)rt->encoding(), off)); }
947 void scd (Register rt, Register base, int off) { emit_long(insn_ORRI(scd_op, (int)base->encoding(), (int)rt->encoding(), off)); }
948 void sd (Register rt, Register base, int off) { emit_long(insn_ORRI(sd_op, (int)base->encoding(), (int)rt->encoding(), off)); }
949 void sdl (Register rt, Register base, int off) { emit_long(insn_ORRI(sdl_op, (int)base->encoding(), (int)rt->encoding(), off)); }
950 void sdr (Register rt, Register base, int off) { emit_long(insn_ORRI(sdr_op, (int)base->encoding(), (int)rt->encoding(), off)); }
951 void sh (Register rt, Register base, int off) { emit_long(insn_ORRI(sh_op, (int)base->encoding(), (int)rt->encoding(), off)); }
952 //#ifndef _LP64
953 #if 1
954 void sll (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, sll_op)); }
955 void sllv (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), sllv_op)); }
956 #else
957 void sll (Register rd, Register rt , int sa) { dsll (rd, rt, sa);}
958 void sllv (Register rd, Register rt, Register rs) { dsllv (rd, rt, rs); }
959 #endif
960 void slt (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), slt_op)); }
961 void slti (Register rt, Register rs, int imm) { emit_long(insn_ORRI(slti_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
962 void sltiu(Register rt, Register rs, int imm) { emit_long(insn_ORRI(sltiu_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
963 void sltu (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), sltu_op)); }
964 //#ifndef _LP64
965 #if 1
966 void sra (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, sra_op)); }
967 void srav (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), srav_op)); }
968 void srl (Register rd, Register rt , int sa) { emit_long(insn_RRSO((int)rt->encoding(), (int)rd->encoding(), sa, srl_op)); }
969 void srlv (Register rd, Register rt, Register rs) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), srlv_op)); }
970 #else
971 void sra (Register rd, Register rt , int sa) { dsra (rd, rt, sa); }
972 void srav (Register rd, Register rt, Register rs) { dsrav (rd, rt, rs); }
973 void srl (Register rd, Register rt , int sa) { dsrl (rd, rt, sa); }
974 void srlv (Register rd, Register rt, Register rs) { dsrlv (rd, rt, rs); }
975 #endif
976 #ifndef _LP64
977 void sub (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), sub_op)); }
978 void subu (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), subu_op)); }
979 #else
980 void sub (Register rd, Register rs, Register rt) { dsub (rd, rs, rt); }
981 void subu (Register rd, Register rs, Register rt) { dsubu (rd, rs, rt); }
982 void subu32 (Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), subu_op)); }
983 #endif
984 void sw (Register rt, Register base, int off) { emit_long(insn_ORRI(sw_op, (int)base->encoding(), (int)rt->encoding(), off)); }
985 void swl (Register rt, Register base, int off) { emit_long(insn_ORRI(swl_op, (int)base->encoding(), (int)rt->encoding(), off)); }
986 void swr (Register rt, Register base, int off) { emit_long(insn_ORRI(swr_op, (int)base->encoding(), (int)rt->encoding(), off)); }
987 void sync () { emit_long(sync_op); }
988 void syscall(int code) { emit_long( (code<<6) | syscall_op ); }
990 void sb(Register rt, Address dst);
991 void sc(Register rt, Address dst);
992 void scd(Register rt, Address dst);
993 void sd(Register rt, Address dst);
994 void sdl(Register rt, Address dst);
995 void sdr(Register rt, Address dst);
996 void sh(Register rt, Address dst);
997 void sw(Register rt, Address dst);
998 void swl(Register rt, Address dst);
999 void swr(Register rt, Address dst);
1001 void teq (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, teq_op)); }
1002 void teqi (Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), teqi_op, imm)); }
1003 void tge (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, tge_op)); }
1004 void tgei (Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), tgei_op, imm)); }
1005 void tgeiu(Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), tgeiu_op, imm)); }
1006 void tgeu (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, tgeu_op)); }
1007 void tlt (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, tlt_op)); }
1008 void tlti (Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), tlti_op, imm)); }
1009 void tltiu(Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), tltiu_op, imm)); }
1010 void tltu (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, tltu_op)); }
1011 void tne (Register rs, Register rt, int code) { emit_long(insn_RRCO((int)rs->encoding(), (int)rt->encoding(), code, tne_op)); }
1012 void tnei (Register rs, int imm) { emit_long(insn_ORRI(regimm_op, (int)rs->encoding(), tnei_op, imm)); }
1014 void xorr(Register rd, Register rs, Register rt) { emit_long(insn_RRRO((int)rs->encoding(), (int)rt->encoding(), (int)rd->encoding(), xor_op)); }
1015 void xori(Register rt, Register rs, int imm) { emit_long(insn_ORRI(xori_op, (int)rs->encoding(), (int)rt->encoding(), imm)); }
1017 void nop() { emit_long(0); }
1018 //float instructions for mips
1019 void abs_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fabs_op));}
1020 void abs_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fabs_op));}
1021 void add_s(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fadd_op));}
1022 void add_d(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fadd_op));}
1024 void bc1f (int off) { emit_long(insn_ORRI(cop1_op, bc_op, bcf_op, off)); has_delay_slot(); }
1025 void bc1fl(int off) { emit_long(insn_ORRI(cop1_op, bc_op, bcfl_op, off)); has_delay_slot(); }
1026 void bc1t (int off) { emit_long(insn_ORRI(cop1_op, bc_op, bct_op, off)); has_delay_slot(); }
1027 void bc1tl(int off) { emit_long(insn_ORRI(cop1_op, bc_op, bctl_op, off)); has_delay_slot(); }
1029 void bc1f (address entry) { bc1f(offset(entry)); }
1030 void bc1fl(address entry) { bc1fl(offset(entry)); }
1031 void bc1t (address entry) { bc1t(offset(entry)); }
1032 void bc1tl(address entry) { bc1tl(offset(entry)); }
1034 void bc1f (Label& L) { bc1f(target(L)); }
1035 void bc1fl(Label& L) { bc1fl(target(L)); }
1036 void bc1t (Label& L) { bc1t(target(L)); }
1037 void bc1tl(Label& L) { bc1tl(target(L)); }
1039 void c_f_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, f_cond)); }
1040 void c_f_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, f_cond)); }
1041 void c_un_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, un_cond)); }
1042 void c_un_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, un_cond)); }
1043 void c_eq_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, eq_cond)); }
1044 void c_eq_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, eq_cond)); }
1045 void c_ueq_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ueq_cond)); }
1046 void c_ueq_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ueq_cond)); }
1047 void c_olt_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, olt_cond)); }
1048 void c_olt_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, olt_cond)); }
1049 void c_ult_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ult_cond)); }
1050 void c_ult_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ult_cond)); }
1051 void c_ole_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ole_cond)); }
1052 void c_ole_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ole_cond)); }
1053 void c_ule_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ule_cond)); }
1054 void c_ule_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ule_cond)); }
1055 void c_sf_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, sf_cond)); }
1056 void c_sf_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, sf_cond)); }
1057 void c_ngle_s(FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngle_cond)); }
1058 void c_ngle_d(FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngle_cond)); }
1059 void c_seq_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, seq_cond)); }
1060 void c_seq_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, seq_cond)); }
1061 void c_ngl_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngl_cond)); }
1062 void c_ngl_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngl_cond)); }
1063 void c_lt_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, lt_cond)); }
1064 void c_lt_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, lt_cond)); }
1065 void c_nge_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, nge_cond)); }
1066 void c_nge_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, nge_cond)); }
1067 void c_le_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, le_cond)); }
1068 void c_le_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, le_cond)); }
1069 void c_ngt_s (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngt_cond)); }
1070 void c_ngt_d (FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), 0, ngt_cond)); }
1072 void ceil_l_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fceill_op)); }
1073 void ceil_l_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fceill_op)); }
1074 void ceil_w_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fceilw_op)); }
1075 void ceil_w_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fceilw_op)); }
1076 void cfc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(cf_op, (int)rt->encoding(), (int)fs->encoding())); }
1077 void ctc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(ct_op, (int)rt->encoding(), (int)fs->encoding())); }
1078 void cfc1(Register rt, int fs) { emit_long(insn_COP1(cf_op, (int)rt->encoding(), fs)); }
1079 void ctc1(Register rt, int fs) { emit_long(insn_COP1(ct_op, (int)rt->encoding(), fs)); }
1081 void cvt_d_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtd_op)); }
1082 void cvt_d_w(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(word_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtd_op)); }
1083 void cvt_d_l(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(long_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtd_op)); }
1084 void cvt_l_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtl_op)); }
1085 void cvt_l_w(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(word_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtl_op)); }
1086 void cvt_l_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtl_op)); }
1087 void cvt_s_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvts_op)); }
1088 void cvt_s_w(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(word_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvts_op)); }
1089 void cvt_s_l(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(long_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvts_op)); }
1090 void cvt_w_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtw_op)); }
1091 void cvt_w_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtw_op)); }
1092 void cvt_w_l(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(long_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fcvtw_op)); }
1093 void pll(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(long_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fpll_op)); }
1094 void plu(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(long_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fplu_op)); }
1095 void pul(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(long_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fpul_op)); }
1096 void puu(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(long_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fpuu_op)); }
1098 void div_s(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fdiv_op)); }
1099 void div_d(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fdiv_op)); }
1100 void dmfc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(dmf_op, (int)rt->encoding(), (int)fs->encoding())); }
1101 void dmtc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(dmt_op, (int)rt->encoding(), (int)fs->encoding())); }
1103 void floor_l_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ffloorl_op)); }
1104 void floor_l_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ffloorl_op)); }
1105 void floor_w_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ffloorw_op)); }
1106 void floor_w_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ffloorw_op)); }
1108 void ldc1(FloatRegister ft, Register base, int off) { emit_long(insn_ORRI(ldc1_op, (int)base->encoding(), (int)ft->encoding(), off)); }
1109 void lwc1(FloatRegister ft, Register base, int off) { emit_long(insn_ORRI(lwc1_op, (int)base->encoding(), (int)ft->encoding(), off)); }
1110 void ldc1(FloatRegister ft, Address src);
1111 void lwc1(FloatRegister ft, Address src);
1113 void mfc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(mf_op, (int)rt->encoding(), (int)fs->encoding())); }
1114 void mov_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fmov_op)); }
1115 void mov_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fmov_op)); }
1116 void mtc1(Register rt, FloatRegister fs) { emit_long(insn_COP1(mt_op, (int)rt->encoding(), (int)fs->encoding())); }
1117 void mul_s(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fmul_op)); }
1118 void mul_d(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fmul_op)); }
1120 void neg_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fneg_op)); }
1121 void neg_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fneg_op)); }
1123 void round_l_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), froundl_op)); }
1124 void round_l_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), froundl_op)); }
1125 void round_w_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), froundw_op)); }
1126 void round_w_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), froundw_op)); }
1128 void sdc1(FloatRegister ft, Register base, int off) { emit_long(insn_ORRI(sdc1_op, (int)base->encoding(), (int)ft->encoding(), off)); }
1129 void sdc1(FloatRegister ft, Address dst);
1130 void sqrt_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fsqrt_op)); }
1131 void sqrt_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), fsqrt_op)); }
1132 void sub_s(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(single_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fsub_op)); }
1133 void sub_d(FloatRegister fd, FloatRegister fs, FloatRegister ft) { emit_long(insn_F3RO(double_fmt, (int)ft->encoding(), (int)fs->encoding(), (int)fd->encoding(), fsub_op)); }
1134 void swc1(FloatRegister ft, Register base, int off) { emit_long(insn_ORRI(swc1_op, (int)base->encoding(), (int)ft->encoding(), off)); }
1135 void swc1(FloatRegister ft, Address dst);
1137 void trunc_l_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ftruncl_op)); }
1138 void trunc_l_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ftruncl_op)); }
1139 void trunc_w_s(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(single_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ftruncw_op)); }
1140 void trunc_w_d(FloatRegister fd, FloatRegister fs) { emit_long(insn_F3RO(double_fmt, 0, (int)fs->encoding(), (int)fd->encoding(), ftruncw_op)); }
1142 void int3();
1143 static void print_instruction(int);
1144 int patched_branch(int dest_pos, int inst, int inst_pos);
1145 int branch_destination(int inst, int pos);
1147 /* Godson3 extension */
1148 void gsldx(Register rt, Register base, Register index, int off) {
1149 assert(is_simm(off, 8), "gsldx: off exceeds 8 bits");
1150 emit_long(gsldx_op | ((int)base->encoding() << 21) | ((int)rt->encoding() << 16) | ((int)index->encoding() << 11) | (off << 3));
1151 }
1153 void gslwx(Register rt, Register base, Register index, int off) {
1154 assert(is_simm(off, 8), "gslwx: off exceeds 8 bits");
1155 emit_long(gslwx_op | ((int)base->encoding() << 21) | ((int)rt->encoding() << 16) | ((int)index->encoding() << 11) | (off << 3));
1156 }
1158 public:
1159 // Creation
1160 Assembler(CodeBuffer* code) : AbstractAssembler(code) {
1161 #ifdef CHECK_DELAY
1162 delay_state = no_delay;
1163 #endif
1164 }
1166 // Decoding
1167 static address locate_operand(address inst, WhichOperand which);
1168 static address locate_next_instruction(address inst);
1169 };
1172 // MacroAssembler extends Assembler by frequently used macros.
1173 //
1174 // Instructions for which a 'better' code sequence exists depending
1175 // on arguments should also go in here.
1177 class MacroAssembler: public Assembler {
1178 friend class LIR_Assembler;
1179 friend class Runtime1; // as_Address()
1181 public:
1182 static intptr_t i[32];
1183 static float f[32];
1184 static void print(outputStream *s);
1186 static int i_offset(unsigned int k);
1187 static int f_offset(unsigned int k);
1189 static void save_registers(MacroAssembler *masm);
1190 static void restore_registers(MacroAssembler *masm);
1192 protected:
1194 Address as_Address(AddressLiteral adr);
1195 Address as_Address(ArrayAddress adr);
1197 // Support for VM calls
1198 //
1199 // This is the base routine called by the different versions of call_VM_leaf. The interpreter
1200 // may customize this version by overriding it for its purposes (e.g., to save/restore
1201 // additional registers when doing a VM call).
1202 #ifdef CC_INTERP
1203 // c++ interpreter never wants to use interp_masm version of call_VM
1204 #define VIRTUAL
1205 #else
1206 #define VIRTUAL virtual
1207 #endif
1209 VIRTUAL void call_VM_leaf_base(
1210 address entry_point, // the entry point
1211 int number_of_arguments // the number of arguments to pop after the call
1212 );
1214 // This is the base routine called by the different versions of call_VM. The interpreter
1215 // may customize this version by overriding it for its purposes (e.g., to save/restore
1216 // additional registers when doing a VM call).
1217 //
1218 // If no java_thread register is specified (noreg) than rdi will be used instead. call_VM_base
1219 // returns the register which contains the thread upon return. If a thread register has been
1220 // specified, the return value will correspond to that register. If no last_java_sp is specified
1221 // (noreg) than rsp will be used instead.
1222 VIRTUAL void call_VM_base( // returns the register containing the thread upon return
1223 Register oop_result, // where an oop-result ends up if any; use noreg otherwise
1224 Register java_thread, // the thread if computed before ; use noreg otherwise
1225 Register last_java_sp, // to set up last_Java_frame in stubs; use noreg otherwise
1226 address entry_point, // the entry point
1227 int number_of_arguments, // the number of arguments (w/o thread) to pop after the call
1228 bool check_exceptions // whether to check for pending exceptions after return
1229 );
1231 // These routines should emit JVMTI PopFrame and ForceEarlyReturn handling code.
1232 // The implementation is only non-empty for the InterpreterMacroAssembler,
1233 // as only the interpreter handles PopFrame and ForceEarlyReturn requests.
1234 virtual void check_and_handle_popframe(Register java_thread);
1235 virtual void check_and_handle_earlyret(Register java_thread);
1237 void call_VM_helper(Register oop_result, address entry_point, int number_of_arguments, bool check_exceptions = true);
1239 // helpers for FPU flag access
1240 // tmp is a temporary register, if none is available use noreg
1241 //void save_rax (Register tmp);
1242 //void restore_rax(Register tmp);
1244 public:
1245 MacroAssembler(CodeBuffer* code) : Assembler(code) {}
1247 // Support for NULL-checks
1248 //
1249 // Generates code that causes a NULL OS exception if the content of reg is NULL.
1250 // If the accessed location is M[reg + offset] and the offset is known, provide the
1251 // offset. No explicit code generation is needed if the offset is within a certain
1252 // range (0 <= offset <= page_size).
1253 // use "teq 83, reg" in mips now, by yjl 6/20/2005
1254 void null_check(Register reg, int offset = -1);
1255 static bool needs_explicit_null_check(intptr_t offset);
1257 // Required platform-specific helpers for Label::patch_instructions.
1258 // They _shadow_ the declarations in AbstractAssembler, which are undefined.
1259 void pd_patch_instruction(address branch, address target);
1261 // Alignment
1262 void align(int modulus);
1264 // Misc
1265 //void fat_nop(); // 5 byte nop
1267 // Stack frame creation/removal
1268 void enter();
1269 void leave();
1271 // Support for getting the JavaThread pointer (i.e.; a reference to thread-local information)
1272 // The pointer will be loaded into the thread register.
1273 void get_thread(Register thread);
1276 // Support for VM calls
1277 //
1278 // It is imperative that all calls into the VM are handled via the call_VM macros.
1279 // They make sure that the stack linkage is setup correctly. call_VM's correspond
1280 // to ENTRY/ENTRY_X entry points while call_VM_leaf's correspond to LEAF entry points.
1283 void call_VM(Register oop_result,
1284 address entry_point,
1285 bool check_exceptions = true);
1286 void call_VM(Register oop_result,
1287 address entry_point,
1288 Register arg_1,
1289 bool check_exceptions = true);
1290 void call_VM(Register oop_result,
1291 address entry_point,
1292 Register arg_1, Register arg_2,
1293 bool check_exceptions = true);
1294 void call_VM(Register oop_result,
1295 address entry_point,
1296 Register arg_1, Register arg_2, Register arg_3,
1297 bool check_exceptions = true);
1298 // Super call_VM calls - correspond to MacroAssembler::call_VM(_leaf) calls
1299 void super_call_VM_leaf(address entry_point);
1300 void super_call_VM_leaf(address entry_point, Register arg_1);
1301 void super_call_VM_leaf(address entry_point, Register arg_1, Register arg_2);
1302 void super_call_VM_leaf(address entry_point,
1303 Register arg_1, Register arg_2, Register arg_3);
1305 // Overloadings with last_Java_sp
1306 void call_VM(Register oop_result,
1307 Register last_java_sp,
1308 address entry_point,
1309 int number_of_arguments = 0,
1310 bool check_exceptions = true);
1311 void call_VM(Register oop_result,
1312 Register last_java_sp,
1313 address entry_point,
1314 Register arg_1, bool
1315 check_exceptions = true);
1316 void call_VM(Register oop_result,
1317 Register last_java_sp,
1318 address entry_point,
1319 Register arg_1, Register arg_2,
1320 bool check_exceptions = true);
1321 void call_VM(Register oop_result,
1322 Register last_java_sp,
1323 address entry_point,
1324 Register arg_1, Register arg_2, Register arg_3,
1325 bool check_exceptions = true);
1327 void call_VM_leaf(address entry_point,
1328 int number_of_arguments = 0);
1329 void call_VM_leaf(address entry_point,
1330 Register arg_1);
1331 void call_VM_leaf(address entry_point,
1332 Register arg_1, Register arg_2);
1333 void call_VM_leaf(address entry_point,
1334 Register arg_1, Register arg_2, Register arg_3);
1336 // last Java Frame (fills frame anchor)
1337 void set_last_Java_frame(Register thread,
1338 Register last_java_sp,
1339 Register last_java_fp,
1340 address last_java_pc);
1342 // thread in the default location (r15_thread on 64bit)
1343 void set_last_Java_frame(Register last_java_sp,
1344 Register last_java_fp,
1345 address last_java_pc);
1347 void reset_last_Java_frame(Register thread, bool clear_fp, bool clear_pc);
1349 // thread in the default location (r15_thread on 64bit)
1350 void reset_last_Java_frame(bool clear_fp, bool clear_pc);
1352 // Stores
1353 void store_check(Register obj); // store check for obj - register is destroyed afterwards
1354 void store_check(Register obj, Address dst); // same as above, dst is exact store location (reg. is destroyed)
1357 void g1_write_barrier_pre(Register obj,
1358 #ifndef _LP64
1359 Register thread,
1360 #endif
1361 Register tmp,
1362 Register tmp2,
1363 bool tosca_live);
1364 void g1_write_barrier_post(Register store_addr,
1365 Register new_val,
1366 #ifndef _LP64
1367 Register thread,
1368 #endif
1369 Register tmp,
1370 Register tmp2);
1374 // split store_check(Register obj) to enhance instruction interleaving
1375 void store_check_part_1(Register obj);
1376 void store_check_part_2(Register obj);
1378 // C 'boolean' to Java boolean: x == 0 ? 0 : 1
1379 void c2bool(Register x);
1380 //add for compressedoops
1381 void load_klass(Register dst, Register src);
1382 void store_klass(Register dst, Register src);
1383 void load_prototype_header(Register dst, Register src);
1384 /*
1385 // C++ bool manipulation
1387 void movbool(Register dst, Address src);
1388 void movbool(Address dst, bool boolconst);
1389 void movbool(Address dst, Register src);
1390 void testbool(Register dst);
1392 // oop manipulations
1393 void load_klass(Register dst, Register src);
1394 void store_klass(Register dst, Register src);
1396 void load_prototype_header(Register dst, Register src);*/
1398 #ifdef _LP64
1399 void store_klass_gap(Register dst, Register src);
1401 void load_heap_oop(Register dst, Address src);
1402 void store_heap_oop(Address dst, Register src);
1403 void encode_heap_oop(Register r);
1404 void decode_heap_oop(Register r);
1405 void encode_heap_oop_not_null(Register r);
1406 void decode_heap_oop_not_null(Register r);
1407 void encode_heap_oop_not_null(Register dst, Register src);
1408 void decode_heap_oop_not_null(Register dst, Register src);
1410 void encode_klass_not_null(Register r);
1411 void decode_klass_not_null(Register r);
1412 void encode_klass_not_null(Register dst, Register src);
1413 void decode_klass_not_null(Register dst, Register src);
1415 //void set_narrow_oop(Register dst, jobject obj);
1417 // Returns the byte size of the instructions generated by decode_klass_not_null()
1418 // when compressed klass pointers are being used.
1419 static int instr_size_for_decode_klass_not_null();
1421 // if heap base register is used - reinit it with the correct value
1422 void reinit_heapbase();
1423 DEBUG_ONLY(void verify_heapbase(const char* msg);)
1425 #endif // _LP64
1427 void incrementl(Register reg, int value = 1);
1429 void decrementl(Register reg, int value = 1);
1431 /*
1432 // Int division/remainder for Java
1433 // (as idivl, but checks for special case as described in JVM spec.)
1434 // returns idivl instruction offset for implicit exception handling
1435 int corrected_idivl(Register reg);
1437 // Long division/remainder for Java
1438 // (as idivq, but checks for special case as described in JVM spec.)
1439 // returns idivq instruction offset for implicit exception handling
1440 int corrected_idivq(Register reg);
1441 */
1443 void int3();
1444 /*
1445 // Long operation macros for a 32bit cpu
1446 // Long negation for Java
1447 void lneg(Register hi, Register lo);
1449 // Long multiplication for Java
1450 // (destroys contents of eax, ebx, ecx and edx)
1451 void lmul(int x_rsp_offset, int y_rsp_offset); // rdx:rax = x * y
1453 // Long shifts for Java
1454 // (semantics as described in JVM spec.)
1455 void lshl(Register hi, Register lo); // hi:lo << (rcx & 0x3f)
1456 void lshr(Register hi, Register lo, bool sign_extension = false); // hi:lo >> (rcx & 0x3f)
1458 // Long compare for Java
1459 // (semantics as described in JVM spec.)
1460 void lcmp2int(Register x_hi, Register x_lo, Register y_hi, Register y_lo); // x_hi = lcmp(x, y)
1463 // misc
1464 */
1465 // Sign extension
1466 #ifdef _LP64
1467 void sign_extend_short(Register reg) { dsll32(reg, reg, 16); dsra32(reg, reg, 16); }
1468 void sign_extend_byte(Register reg) { dsll32(reg, reg, 24); dsra32(reg, reg, 24); }
1469 #else
1470 void sign_extend_short(Register reg) { sll(reg, reg, 16); sra(reg, reg, 16); }
1471 void sign_extend_byte(Register reg) { sll(reg, reg, 24); sra(reg, reg, 24); }
1472 #endif
1473 void rem_s(FloatRegister fd, FloatRegister fs, FloatRegister ft, FloatRegister tmp);
1474 void rem_d(FloatRegister fd, FloatRegister fs, FloatRegister ft, FloatRegister tmp);
1476 // Inlined sin/cos generator for Java; must not use CPU instruction
1477 // directly on Intel as it does not have high enough precision
1478 // outside of the range [-pi/4, pi/4]. Extra argument indicate the
1479 // number of FPU stack slots in use; all but the topmost will
1480 // require saving if a slow case is necessary. Assumes argument is
1481 // on FP TOS; result is on FP TOS. No cpu registers are changed by
1482 // this code.
1483 void trigfunc(char trig, int num_fpu_regs_in_use = 1);
1484 /*
1485 // branch to L if FPU flag C2 is set/not set
1486 // tmp is a temporary register, if none is available use noreg
1487 void jC2 (Register tmp, Label& L);
1488 void jnC2(Register tmp, Label& L);
1490 // Pop ST (ffree & fincstp combined)
1491 void fpop();
1493 // pushes double TOS element of FPU stack on CPU stack; pops from FPU stack
1494 void push_fTOS();
1496 // pops double TOS element from CPU stack and pushes on FPU stack
1497 void pop_fTOS();
1499 void empty_FPU_stack();
1501 void push_IU_state();
1502 void pop_IU_state();
1504 void push_FPU_state();
1505 void pop_FPU_state();
1507 void push_CPU_state();
1508 void pop_CPU_state();
1510 // Round up to a power of two
1511 void round_to(Register reg, int modulus);
1513 // Callee saved registers handling
1514 void push_callee_saved_registers();
1515 void pop_callee_saved_registers();
1516 */
1517 // allocation
1518 void eden_allocate(
1519 Register obj, // result: pointer to object after successful allocation
1520 Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise
1521 int con_size_in_bytes, // object size in bytes if known at compile time
1522 Register t1, // temp register
1523 Register t2,
1524 Label& slow_case // continuation point if fast allocation fails
1525 );
1526 void tlab_allocate(
1527 Register obj, // result: pointer to object after successful allocation
1528 Register var_size_in_bytes, // object size in bytes if unknown at compile time; invalid otherwise
1529 int con_size_in_bytes, // object size in bytes if known at compile time
1530 Register t1, // temp register
1531 Register t2, // temp register
1532 Label& slow_case // continuation point if fast allocation fails
1533 );
1534 void tlab_refill(Label& retry_tlab, Label& try_eden, Label& slow_case);
1536 //----
1537 // void set_word_if_not_zero(Register reg); // sets reg to 1 if not zero, otherwise 0
1540 // Debugging
1542 // only if +VerifyOops
1543 void verify_oop(Register reg, const char* s = "broken oop");
1544 void verify_oop_addr(Address addr, const char * s = "broken oop addr");
1545 void verify_oop_subroutine();
1546 // TODO: verify method and klass metadata (compare against vptr?)
1547 void _verify_method_ptr(Register reg, const char * msg, const char * file, int line) {}
1548 void _verify_klass_ptr(Register reg, const char * msg, const char * file, int line){}
1550 #define verify_method_ptr(reg) _verify_method_ptr(reg, "broken method " #reg, __FILE__, __LINE__)
1551 #define verify_klass_ptr(reg) _verify_klass_ptr(reg, "broken klass " #reg, __FILE__, __LINE__)
1553 // only if +VerifyFPU
1554 void verify_FPU(int stack_depth, const char* s = "illegal FPU state");
1556 // prints msg, dumps registers and stops execution
1557 void stop(const char* msg);
1559 // prints msg and continues
1560 void warn(const char* msg);
1562 static void debug(char* msg/*, RegistersForDebugging* regs*/);
1563 static void debug32(int rdi, int rsi, int rbp, int rsp, int rbx, int rdx, int rcx, int rax, int eip, char* msg);
1564 static void debug64(char* msg, int64_t pc, int64_t regs[]);
1566 void print_reg(Register reg);
1567 void print_reg(FloatRegister reg);
1568 //void os_breakpoint();
1570 void untested() { stop("untested"); }
1572 void unimplemented(const char* what = "") { char* b = new char[1024]; jio_snprintf(b, sizeof(b), "unimplemented: %s", what); stop(b); }
1574 void should_not_reach_here() { stop("should not reach here"); }
1576 void print_CPU_state();
1578 // Stack overflow checking
1579 void bang_stack_with_offset(int offset) {
1580 // stack grows down, caller passes positive offset
1581 assert(offset > 0, "must bang with negative offset");
1582 if (offset <= 32768) {
1583 sw(A0, SP, -offset);
1584 } else {
1585 #ifdef _LP64
1586 li(AT, offset);
1587 dsub(AT, SP, AT);
1588 #else
1589 move(AT, offset);
1590 sub(AT, SP, AT);
1591 #endif
1592 sw(A0, AT, 0);
1593 }
1594 }
1596 // Writes to stack successive pages until offset reached to check for
1597 // stack overflow + shadow pages. Also, clobbers tmp
1598 void bang_stack_size(Register size, Register tmp);
1599 virtual RegisterOrConstant delayed_value_impl(intptr_t* delayed_value_addr,
1600 Register tmp,
1601 int offset);
1603 // Support for serializing memory accesses between threads
1604 void serialize_memory(Register thread, Register tmp);
1606 //void verify_tlab();
1607 void verify_tlab(Register t1, Register t2);
1609 // Biased locking support
1610 // lock_reg and obj_reg must be loaded up with the appropriate values.
1611 // swap_reg must be rax, and is killed.
1612 // tmp_reg is optional. If it is supplied (i.e., != noreg) it will
1613 // be killed; if not supplied, push/pop will be used internally to
1614 // allocate a temporary (inefficient, avoid if possible).
1615 // Optional slow case is for implementations (interpreter and C1) which branch to
1616 // slow case directly. Leaves condition codes set for C2's Fast_Lock node.
1617 // Returns offset of first potentially-faulting instruction for null
1618 // check info (currently consumed only by C1). If
1619 // swap_reg_contains_mark is true then returns -1 as it is assumed
1620 // the calling code has already passed any potential faults.
1621 int biased_locking_enter(Register lock_reg, Register obj_reg,
1622 Register swap_reg, Register tmp_reg,
1623 bool swap_reg_contains_mark,
1624 Label& done, Label* slow_case = NULL,
1625 BiasedLockingCounters* counters = NULL);
1626 void biased_locking_exit (Register obj_reg, Register temp_reg, Label& done);
1629 // Calls
1631 void call(address entry);
1632 void call(address entry, relocInfo::relocType rtype);
1633 void call(address entry, RelocationHolder& rh);
1634 // Emit the CompiledIC call idiom
1635 void ic_call(address entry);
1637 void jmp(address entry);
1638 void jmp(address entry, relocInfo::relocType rtype);
1640 // Argument ops
1641 /*inline void store_int_argument(Register s, Argument& a);
1642 inline void store_long_argument(Register s, Argument& a);
1643 inline void store_float_argument(FloatRegister s, Argument& a);
1644 inline void store_double_argument(FloatRegister s, Argument& a);
1645 inline void store_ptr_argument(Register s, Argument& a);*/
1646 inline void store_int_argument(Register s, Argument &a) {
1647 if(a.is_Register()) {
1648 move(a.as_Register(), s);
1649 } else {
1650 sw(s, a.as_caller_address());
1651 }
1652 }
1654 inline void store_long_argument(Register s, Argument &a) {
1655 Argument a1 = a.successor();
1656 if(a.is_Register() && a1.is_Register()) {
1657 move(a.as_Register(), s);
1658 move(a.as_Register(), s);
1659 } else {
1660 sd(s, a.as_caller_address());
1661 }
1662 }
1664 inline void store_float_argument(FloatRegister s, Argument &a) {
1665 if(a.is_Register()) {
1666 mov_s(a.as_FloatRegister(), s);
1667 } else {
1668 swc1(s, a.as_caller_address());
1669 }
1670 }
1671 inline void store_double_argument(FloatRegister s, Argument &a) {
1672 if(a.is_Register()) {
1673 mov_d(a.as_FloatRegister(), s);
1674 } else {
1675 sdc1(s, a.as_caller_address());
1676 }
1677 }
1679 inline void store_ptr_argument(Register s, Argument &a) {
1680 if(a.is_Register()) {
1681 move(a.as_Register(), s);
1682 } else {
1683 st_ptr(s, a.as_caller_address());
1684 }
1685 }
1687 // Load and store values by size and signed-ness
1688 void load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed, Register dst2 = noreg);
1689 void store_sized_value(Address dst, Register src, size_t size_in_bytes, Register src2 = noreg);
1691 // interface method calling
1692 void lookup_interface_method(Register recv_klass,
1693 Register intf_klass,
1694 RegisterOrConstant itable_index,
1695 Register method_result,
1696 Register scan_temp,
1697 Label& no_such_interface);
1698 // virtual method calling
1699 void lookup_virtual_method(Register recv_klass,
1700 RegisterOrConstant vtable_index,
1701 Register method_result);
1703 // ld_ptr will perform lw for 32 bit VMs and ld for 64 bit VMs
1704 // st_ptr will perform sw for 32 bit VMs and sd for 64 bit VMs
1705 inline void ld_ptr(Register rt, Address a){
1706 #ifdef _LP64
1707 ld(rt, a.base(), a.disp());
1708 #else
1709 lw(rt, a.base(), a.disp());
1710 #endif
1711 }
1712 inline void ld_ptr(Register rt, Register base, int offset16){
1713 #ifdef _LP64
1714 ld(rt, base, offset16);
1715 #else
1716 lw(rt, base, offset16);
1717 #endif
1719 }
1720 inline void st_ptr(Register rt, Address a){
1721 #ifdef _LP64
1722 sd(rt, a.base(), a.disp());
1723 #else
1724 sw(rt, a.base(), a.disp());
1725 #endif
1726 }
1727 inline void st_ptr(Register rt, Register base, int offset16) {
1728 #ifdef _LP64
1729 sd(rt, base, offset16);
1730 #else
1731 sw(rt, base, offset16);
1732 #endif
1734 }
1736 void ld_ptr(Register rt, Register offset, Register base);
1737 void st_ptr(Register rt, Register offset, Register base);
1739 // ld_long will perform lw for 32 bit VMs and ld for 64 bit VMs
1740 // st_long will perform sw for 32 bit VMs and sd for 64 bit VMs
1741 inline void ld_long(Register rt, Register base, int offset16);
1742 inline void st_long(Register rt, Register base, int offset16);
1743 inline void ld_long(Register rt, Address a);
1744 inline void st_long(Register rt, Address a);
1747 void ld_long(Register rt, Register offset, Register base);
1748 void st_long(Register rt, Register offset, Register base);
1749 // Regular vs. d* versions
1750 inline void addu_long(Register rd, Register rs, Register rt) {
1751 #ifdef _LP64
1752 daddu(rd, rs, rt);
1753 #else
1754 addu(rd, rs, rt);
1755 #endif
1756 }
1757 inline void addu_long(Register rd, Register rs, long imm32_64) {
1758 #ifdef _LP64
1759 daddiu(rd, rs, imm32_64);
1760 #else
1761 addiu(rd, rs, imm32_64);
1762 #endif
1764 }
1766 // Floating
1767 public:
1768 // swap the two byte of the low 16-bit halfword
1769 // this directive will use AT, be sure the high 16-bit of reg is zero
1770 // by yjl 6/28/2005
1771 void hswap(Register reg);
1772 void huswap(Register reg);
1774 // convert big endian integer to little endian integer
1775 // by yjl 6/29/2005
1776 void swap(Register reg);
1778 // implement the x86 instruction semantic
1779 // if c_reg == *dest then *dest <= x_reg
1780 // else c_reg <= *dest
1781 // the AT indicate if xchg occurred, 1 for xchged, else 0
1782 // by yjl 6/28/2005
1783 void cmpxchg(Register x_reg, Address dest, Register c_reg);
1784 #ifdef _LP64
1785 void cmpxchg32(Register x_reg, Address dest, Register c_reg);
1786 #endif
1787 void cmpxchg8(Register x_regLo, Register x_regHi, Address dest, Register c_regLo, Register c_regHi);
1791 void round_to(Register reg, int modulus) {
1792 assert_different_registers(reg, AT);
1793 increment(reg, modulus - 1);
1794 move(AT, - modulus);
1795 andr(reg, reg, AT);
1796 }
1798 //pop & push, added by aoqi
1799 #ifdef _LP64
1800 void extend_sign(Register rh, Register rl) { stop("extend_sign"); }
1801 void neg(Register reg) { dsubu(reg, R0, reg); }
1802 void push (Register reg) { sd (reg, SP, -8); daddi(SP, SP, -8); }
1803 void push (FloatRegister reg) { sdc1(reg, SP, -8); daddi(SP, SP, -8); }
1804 void pop (Register reg) { ld (reg, SP, 0); daddi(SP, SP, 8); }
1805 void pop (FloatRegister reg) { ldc1(reg, SP, 0); daddi(SP, SP, 8); }
1806 void pop () { daddi(SP, SP, 8); }
1807 void pop2 () { daddi(SP, SP, 16); }
1808 #else
1809 void extend_sign(Register rh, Register rl) { sra(rh, rl, 31); }
1810 void neg(Register reg) { subu(reg, R0, reg); }
1811 void push (Register reg) { sw (reg, SP, -4); addi(SP, SP, -4); }
1812 void push (FloatRegister reg) { swc1(reg, SP, -4); addi(SP, SP, -4); }
1813 void pop (Register reg) { lw (reg, SP, 0); addi(SP, SP, 4); }
1814 void pop (FloatRegister reg) { lwc1(reg, SP, 0); addi(SP, SP, 4); }
1815 void pop () { addi(SP, SP, 4); }
1816 void pop2 () { addi(SP, SP, 8); }
1817 #endif
1818 void push2(Register reg1, Register reg2);
1819 void pop2 (Register reg1, Register reg2);
1820 void dpush (Register reg) { sd (reg, SP, -8); daddi(SP, SP, -8); }
1821 void dpop (Register reg) { ld (reg, SP, 0); daddi(SP, SP, 8); }
1823 /* branches may exceed 16-bit offset */
1824 void b_far(address entry);
1825 void b_far(Label& L);
1827 void bne_far (Register rs, Register rt, address entry);
1828 void bne_far (Register rs, Register rt, Label& L);
1830 void beq_far (Register rs, Register rt, address entry);
1831 void beq_far (Register rs, Register rt, Label& L);
1833 //move an 32-bit immediate to Register
1834 void move(Register reg, int imm32) { li32(reg, imm32); }
1835 void li (Register rd, long imm);
1836 void li (Register rd, address addr) { li(rd, (long)addr); }
1837 //replace move(Register reg, int imm)
1838 void li32(Register rd, int imm32); // sign-extends to 64 bits on mips64
1839 #ifdef _LP64
1840 void dli(Register rd, long imm) { li(rd, imm); }
1841 void li64(Register rd, long imm);
1842 void li48(Register rd, long imm);
1843 #endif
1845 #ifdef _LP64
1846 void move(Register rd, Register rs) { dadd(rd, rs, R0); }
1847 void move_u32(Register rd, Register rs) { addu32(rd, rs, R0); }
1848 #else
1849 void move(Register rd, Register rs) { add(rd, rs, R0); }
1850 #endif
1851 void dmove(Register rd, Register rs) { dadd(rd, rs, R0); }
1853 #ifdef _LP64
1854 void shl(Register reg, int sa) { dsll(reg, reg, sa); }
1855 void shr(Register reg, int sa) { dsrl(reg, reg, sa); }
1856 void sar(Register reg, int sa) { dsra(reg, reg, sa); }
1857 #else
1858 void shl(Register reg, int sa) { sll(reg, reg, sa); }
1859 void shr(Register reg, int sa) { srl(reg, reg, sa); }
1860 void sar(Register reg, int sa) { sra(reg, reg, sa); }
1861 #endif
1863 #ifndef PRODUCT
1864 static void pd_print_patched_instruction(address branch) {
1865 jint stub_inst = *(jint*) branch;
1866 print_instruction(stub_inst);
1867 ::tty->print("%s", " (unresolved)");
1869 }
1870 #endif
1872 // the follow two might use AT register, be sure you have no meanful data in AT before you call them
1873 // by yjl 6/23/2005
1874 void increment(Register reg, int imm);
1875 void decrement(Register reg, int imm);
1877 //FIXME
1878 void empty_FPU_stack(){/*need implemented*/};
1880 //we need 2 fun to save and resotre general register
1881 void pushad();
1882 void popad();
1884 // Test sub_klass against super_klass, with fast and slow paths.
1886 // The fast path produces a tri-state answer: yes / no / maybe-slow.
1887 // One of the three labels can be NULL, meaning take the fall-through.
1888 // If super_check_offset is -1, the value is loaded up from super_klass.
1889 // No registers are killed, except temp_reg.
1890 void check_klass_subtype_fast_path(Register sub_klass,
1891 Register super_klass,
1892 Register temp_reg,
1893 Label* L_success,
1894 Label* L_failure,
1895 Label* L_slow_path,
1896 RegisterOrConstant super_check_offset = RegisterOrConstant(-1));
1898 // The rest of the type check; must be wired to a corresponding fast path.
1899 // It does not repeat the fast path logic, so don't use it standalone.
1900 // The temp_reg and temp2_reg can be noreg, if no temps are available.
1901 // Updates the sub's secondary super cache as necessary.
1902 // If set_cond_codes, condition codes will be Z on success, NZ on failure.
1903 void check_klass_subtype_slow_path(Register sub_klass,
1904 Register super_klass,
1905 Register temp_reg,
1906 Register temp2_reg,
1907 Label* L_success,
1908 Label* L_failure,
1909 bool set_cond_codes = false);
1911 // Simplified, combined version, good for typical uses.
1912 // Falls through on failure.
1913 void check_klass_subtype(Register sub_klass,
1914 Register super_klass,
1915 Register temp_reg,
1916 Label& L_success);
1918 // method handles (JSR 292)
1919 Address argument_address(RegisterOrConstant arg_slot, int extra_slot_offset = 0);
1921 void get_vm_result (Register oop_result, Register thread);
1922 void get_vm_result_2(Register metadata_result, Register thread);
1923 #undef VIRTUAL
1924 void atomic_inc32(address counter_addr, int inc, Register tmp_reg1, Register tmp_reg2);
1926 void fast_lock(Register obj, Register box, Register tmp, Register scr);
1927 void fast_unlock(Register obj, Register box, Register tmp);
1928 };
1930 /**
1931 * class SkipIfEqual:
1932 *
1933 * Instantiating this class will result in assembly code being output that will
1934 * jump around any code emitted between the creation of the instance and it's
1935 * automatic destruction at the end of a scope block, depending on the value of
1936 * the flag passed to the constructor, which will be checked at run-time.
1937 */
1938 class SkipIfEqual {
1939 private:
1940 MacroAssembler* _masm;
1941 Label _label;
1943 public:
1944 SkipIfEqual(MacroAssembler*, const bool* flag_addr, bool value);
1945 ~SkipIfEqual();
1946 };
1948 #ifdef ASSERT
1949 inline bool AbstractAssembler::pd_check_instruction_mark() { return true; }
1950 #endif
1952 #endif // CPU_MIPS_VM_ASSEMBLER_MIPS_HPP