Thu, 20 Mar 2014 11:03:06 +0100
8037915: PPC64/AIX: Several smaller fixes
Reviewed-by: kvn
1 /*
2 * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
3 * Copyright 2012, 2014 SAP AG. 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.
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24 */
26 #include "precompiled.hpp"
27 #include "asm/macroAssembler.inline.hpp"
28 #include "compiler/disassembler.hpp"
29 #include "gc_interface/collectedHeap.inline.hpp"
30 #include "interpreter/interpreter.hpp"
31 #include "memory/cardTableModRefBS.hpp"
32 #include "memory/resourceArea.hpp"
33 #include "prims/methodHandles.hpp"
34 #include "runtime/biasedLocking.hpp"
35 #include "runtime/interfaceSupport.hpp"
36 #include "runtime/objectMonitor.hpp"
37 #include "runtime/os.hpp"
38 #include "runtime/sharedRuntime.hpp"
39 #include "runtime/stubRoutines.hpp"
40 #include "utilities/macros.hpp"
41 #if INCLUDE_ALL_GCS
42 #include "gc_implementation/g1/g1CollectedHeap.inline.hpp"
43 #include "gc_implementation/g1/g1SATBCardTableModRefBS.hpp"
44 #include "gc_implementation/g1/heapRegion.hpp"
45 #endif // INCLUDE_ALL_GCS
47 #ifdef PRODUCT
48 #define BLOCK_COMMENT(str) // nothing
49 #else
50 #define BLOCK_COMMENT(str) block_comment(str)
51 #endif
53 #ifdef ASSERT
54 // On RISC, there's no benefit to verifying instruction boundaries.
55 bool AbstractAssembler::pd_check_instruction_mark() { return false; }
56 #endif
58 void MacroAssembler::ld_largeoffset_unchecked(Register d, int si31, Register a, int emit_filler_nop) {
59 assert(Assembler::is_simm(si31, 31) && si31 >= 0, "si31 out of range");
60 if (Assembler::is_simm(si31, 16)) {
61 ld(d, si31, a);
62 if (emit_filler_nop) nop();
63 } else {
64 const int hi = MacroAssembler::largeoffset_si16_si16_hi(si31);
65 const int lo = MacroAssembler::largeoffset_si16_si16_lo(si31);
66 addis(d, a, hi);
67 ld(d, lo, d);
68 }
69 }
71 void MacroAssembler::ld_largeoffset(Register d, int si31, Register a, int emit_filler_nop) {
72 assert_different_registers(d, a);
73 ld_largeoffset_unchecked(d, si31, a, emit_filler_nop);
74 }
76 void MacroAssembler::load_sized_value(Register dst, RegisterOrConstant offs, Register base,
77 size_t size_in_bytes, bool is_signed) {
78 switch (size_in_bytes) {
79 case 8: ld(dst, offs, base); break;
80 case 4: is_signed ? lwa(dst, offs, base) : lwz(dst, offs, base); break;
81 case 2: is_signed ? lha(dst, offs, base) : lhz(dst, offs, base); break;
82 case 1: lbz(dst, offs, base); if (is_signed) extsb(dst, dst); break; // lba doesn't exist :(
83 default: ShouldNotReachHere();
84 }
85 }
87 void MacroAssembler::store_sized_value(Register dst, RegisterOrConstant offs, Register base,
88 size_t size_in_bytes) {
89 switch (size_in_bytes) {
90 case 8: std(dst, offs, base); break;
91 case 4: stw(dst, offs, base); break;
92 case 2: sth(dst, offs, base); break;
93 case 1: stb(dst, offs, base); break;
94 default: ShouldNotReachHere();
95 }
96 }
98 void MacroAssembler::align(int modulus, int max, int rem) {
99 int padding = (rem + modulus - (offset() % modulus)) % modulus;
100 if (padding > max) return;
101 for (int c = (padding >> 2); c > 0; --c) { nop(); }
102 }
104 // Issue instructions that calculate given TOC from global TOC.
105 void MacroAssembler::calculate_address_from_global_toc(Register dst, address addr, bool hi16, bool lo16,
106 bool add_relocation, bool emit_dummy_addr) {
107 int offset = -1;
108 if (emit_dummy_addr) {
109 offset = -128; // dummy address
110 } else if (addr != (address)(intptr_t)-1) {
111 offset = MacroAssembler::offset_to_global_toc(addr);
112 }
114 if (hi16) {
115 addis(dst, R29, MacroAssembler::largeoffset_si16_si16_hi(offset));
116 }
117 if (lo16) {
118 if (add_relocation) {
119 // Relocate at the addi to avoid confusion with a load from the method's TOC.
120 relocate(internal_word_Relocation::spec(addr));
121 }
122 addi(dst, dst, MacroAssembler::largeoffset_si16_si16_lo(offset));
123 }
124 }
126 int MacroAssembler::patch_calculate_address_from_global_toc_at(address a, address bound, address addr) {
127 const int offset = MacroAssembler::offset_to_global_toc(addr);
129 const address inst2_addr = a;
130 const int inst2 = *(int *)inst2_addr;
132 // The relocation points to the second instruction, the addi,
133 // and the addi reads and writes the same register dst.
134 const int dst = inv_rt_field(inst2);
135 assert(is_addi(inst2) && inv_ra_field(inst2) == dst, "must be addi reading and writing dst");
137 // Now, find the preceding addis which writes to dst.
138 int inst1 = 0;
139 address inst1_addr = inst2_addr - BytesPerInstWord;
140 while (inst1_addr >= bound) {
141 inst1 = *(int *) inst1_addr;
142 if (is_addis(inst1) && inv_rt_field(inst1) == dst) {
143 // Stop, found the addis which writes dst.
144 break;
145 }
146 inst1_addr -= BytesPerInstWord;
147 }
149 assert(is_addis(inst1) && inv_ra_field(inst1) == 29 /* R29 */, "source must be global TOC");
150 set_imm((int *)inst1_addr, MacroAssembler::largeoffset_si16_si16_hi(offset));
151 set_imm((int *)inst2_addr, MacroAssembler::largeoffset_si16_si16_lo(offset));
152 return (int)((intptr_t)addr - (intptr_t)inst1_addr);
153 }
155 address MacroAssembler::get_address_of_calculate_address_from_global_toc_at(address a, address bound) {
156 const address inst2_addr = a;
157 const int inst2 = *(int *)inst2_addr;
159 // The relocation points to the second instruction, the addi,
160 // and the addi reads and writes the same register dst.
161 const int dst = inv_rt_field(inst2);
162 assert(is_addi(inst2) && inv_ra_field(inst2) == dst, "must be addi reading and writing dst");
164 // Now, find the preceding addis which writes to dst.
165 int inst1 = 0;
166 address inst1_addr = inst2_addr - BytesPerInstWord;
167 while (inst1_addr >= bound) {
168 inst1 = *(int *) inst1_addr;
169 if (is_addis(inst1) && inv_rt_field(inst1) == dst) {
170 // stop, found the addis which writes dst
171 break;
172 }
173 inst1_addr -= BytesPerInstWord;
174 }
176 assert(is_addis(inst1) && inv_ra_field(inst1) == 29 /* R29 */, "source must be global TOC");
178 int offset = (get_imm(inst1_addr, 0) << 16) + get_imm(inst2_addr, 0);
179 // -1 is a special case
180 if (offset == -1) {
181 return (address)(intptr_t)-1;
182 } else {
183 return global_toc() + offset;
184 }
185 }
187 #ifdef _LP64
188 // Patch compressed oops or klass constants.
189 // Assembler sequence is
190 // 1) compressed oops:
191 // lis rx = const.hi
192 // ori rx = rx | const.lo
193 // 2) compressed klass:
194 // lis rx = const.hi
195 // clrldi rx = rx & 0xFFFFffff // clearMS32b, optional
196 // ori rx = rx | const.lo
197 // Clrldi will be passed by.
198 int MacroAssembler::patch_set_narrow_oop(address a, address bound, narrowOop data) {
199 assert(UseCompressedOops, "Should only patch compressed oops");
201 const address inst2_addr = a;
202 const int inst2 = *(int *)inst2_addr;
204 // The relocation points to the second instruction, the ori,
205 // and the ori reads and writes the same register dst.
206 const int dst = inv_rta_field(inst2);
207 assert(is_ori(inst2) && inv_rs_field(inst2) == dst, "must be ori reading and writing dst");
208 // Now, find the preceding addis which writes to dst.
209 int inst1 = 0;
210 address inst1_addr = inst2_addr - BytesPerInstWord;
211 bool inst1_found = false;
212 while (inst1_addr >= bound) {
213 inst1 = *(int *)inst1_addr;
214 if (is_lis(inst1) && inv_rs_field(inst1) == dst) { inst1_found = true; break; }
215 inst1_addr -= BytesPerInstWord;
216 }
217 assert(inst1_found, "inst is not lis");
219 int xc = (data >> 16) & 0xffff;
220 int xd = (data >> 0) & 0xffff;
222 set_imm((int *)inst1_addr, (short)(xc)); // see enc_load_con_narrow_hi/_lo
223 set_imm((int *)inst2_addr, (xd)); // unsigned int
224 return (int)((intptr_t)inst2_addr - (intptr_t)inst1_addr);
225 }
227 // Get compressed oop or klass constant.
228 narrowOop MacroAssembler::get_narrow_oop(address a, address bound) {
229 assert(UseCompressedOops, "Should only patch compressed oops");
231 const address inst2_addr = a;
232 const int inst2 = *(int *)inst2_addr;
234 // The relocation points to the second instruction, the ori,
235 // and the ori reads and writes the same register dst.
236 const int dst = inv_rta_field(inst2);
237 assert(is_ori(inst2) && inv_rs_field(inst2) == dst, "must be ori reading and writing dst");
238 // Now, find the preceding lis which writes to dst.
239 int inst1 = 0;
240 address inst1_addr = inst2_addr - BytesPerInstWord;
241 bool inst1_found = false;
243 while (inst1_addr >= bound) {
244 inst1 = *(int *) inst1_addr;
245 if (is_lis(inst1) && inv_rs_field(inst1) == dst) { inst1_found = true; break;}
246 inst1_addr -= BytesPerInstWord;
247 }
248 assert(inst1_found, "inst is not lis");
250 uint xl = ((unsigned int) (get_imm(inst2_addr, 0) & 0xffff));
251 uint xh = (((get_imm(inst1_addr, 0)) & 0xffff) << 16);
253 return (int) (xl | xh);
254 }
255 #endif // _LP64
257 void MacroAssembler::load_const_from_method_toc(Register dst, AddressLiteral& a, Register toc) {
258 int toc_offset = 0;
259 // Use RelocationHolder::none for the constant pool entry, otherwise
260 // we will end up with a failing NativeCall::verify(x) where x is
261 // the address of the constant pool entry.
262 // FIXME: We should insert relocation information for oops at the constant
263 // pool entries instead of inserting it at the loads; patching of a constant
264 // pool entry should be less expensive.
265 address oop_address = address_constant((address)a.value(), RelocationHolder::none);
266 // Relocate at the pc of the load.
267 relocate(a.rspec());
268 toc_offset = (int)(oop_address - code()->consts()->start());
269 ld_largeoffset_unchecked(dst, toc_offset, toc, true);
270 }
272 bool MacroAssembler::is_load_const_from_method_toc_at(address a) {
273 const address inst1_addr = a;
274 const int inst1 = *(int *)inst1_addr;
276 // The relocation points to the ld or the addis.
277 return (is_ld(inst1)) ||
278 (is_addis(inst1) && inv_ra_field(inst1) != 0);
279 }
281 int MacroAssembler::get_offset_of_load_const_from_method_toc_at(address a) {
282 assert(is_load_const_from_method_toc_at(a), "must be load_const_from_method_toc");
284 const address inst1_addr = a;
285 const int inst1 = *(int *)inst1_addr;
287 if (is_ld(inst1)) {
288 return inv_d1_field(inst1);
289 } else if (is_addis(inst1)) {
290 const int dst = inv_rt_field(inst1);
292 // Now, find the succeeding ld which reads and writes to dst.
293 address inst2_addr = inst1_addr + BytesPerInstWord;
294 int inst2 = 0;
295 while (true) {
296 inst2 = *(int *) inst2_addr;
297 if (is_ld(inst2) && inv_ra_field(inst2) == dst && inv_rt_field(inst2) == dst) {
298 // Stop, found the ld which reads and writes dst.
299 break;
300 }
301 inst2_addr += BytesPerInstWord;
302 }
303 return (inv_d1_field(inst1) << 16) + inv_d1_field(inst2);
304 }
305 ShouldNotReachHere();
306 return 0;
307 }
309 // Get the constant from a `load_const' sequence.
310 long MacroAssembler::get_const(address a) {
311 assert(is_load_const_at(a), "not a load of a constant");
312 const int *p = (const int*) a;
313 unsigned long x = (((unsigned long) (get_imm(a,0) & 0xffff)) << 48);
314 if (is_ori(*(p+1))) {
315 x |= (((unsigned long) (get_imm(a,1) & 0xffff)) << 32);
316 x |= (((unsigned long) (get_imm(a,3) & 0xffff)) << 16);
317 x |= (((unsigned long) (get_imm(a,4) & 0xffff)));
318 } else if (is_lis(*(p+1))) {
319 x |= (((unsigned long) (get_imm(a,2) & 0xffff)) << 32);
320 x |= (((unsigned long) (get_imm(a,1) & 0xffff)) << 16);
321 x |= (((unsigned long) (get_imm(a,3) & 0xffff)));
322 } else {
323 ShouldNotReachHere();
324 return (long) 0;
325 }
326 return (long) x;
327 }
329 // Patch the 64 bit constant of a `load_const' sequence. This is a low
330 // level procedure. It neither flushes the instruction cache nor is it
331 // mt safe.
332 void MacroAssembler::patch_const(address a, long x) {
333 assert(is_load_const_at(a), "not a load of a constant");
334 int *p = (int*) a;
335 if (is_ori(*(p+1))) {
336 set_imm(0 + p, (x >> 48) & 0xffff);
337 set_imm(1 + p, (x >> 32) & 0xffff);
338 set_imm(3 + p, (x >> 16) & 0xffff);
339 set_imm(4 + p, x & 0xffff);
340 } else if (is_lis(*(p+1))) {
341 set_imm(0 + p, (x >> 48) & 0xffff);
342 set_imm(2 + p, (x >> 32) & 0xffff);
343 set_imm(1 + p, (x >> 16) & 0xffff);
344 set_imm(3 + p, x & 0xffff);
345 } else {
346 ShouldNotReachHere();
347 }
348 }
350 AddressLiteral MacroAssembler::allocate_metadata_address(Metadata* obj) {
351 assert(oop_recorder() != NULL, "this assembler needs a Recorder");
352 int index = oop_recorder()->allocate_metadata_index(obj);
353 RelocationHolder rspec = metadata_Relocation::spec(index);
354 return AddressLiteral((address)obj, rspec);
355 }
357 AddressLiteral MacroAssembler::constant_metadata_address(Metadata* obj) {
358 assert(oop_recorder() != NULL, "this assembler needs a Recorder");
359 int index = oop_recorder()->find_index(obj);
360 RelocationHolder rspec = metadata_Relocation::spec(index);
361 return AddressLiteral((address)obj, rspec);
362 }
364 AddressLiteral MacroAssembler::allocate_oop_address(jobject obj) {
365 assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
366 int oop_index = oop_recorder()->allocate_oop_index(obj);
367 return AddressLiteral(address(obj), oop_Relocation::spec(oop_index));
368 }
370 AddressLiteral MacroAssembler::constant_oop_address(jobject obj) {
371 assert(oop_recorder() != NULL, "this assembler needs an OopRecorder");
372 int oop_index = oop_recorder()->find_index(obj);
373 return AddressLiteral(address(obj), oop_Relocation::spec(oop_index));
374 }
376 RegisterOrConstant MacroAssembler::delayed_value_impl(intptr_t* delayed_value_addr,
377 Register tmp, int offset) {
378 intptr_t value = *delayed_value_addr;
379 if (value != 0) {
380 return RegisterOrConstant(value + offset);
381 }
383 // Load indirectly to solve generation ordering problem.
384 // static address, no relocation
385 int simm16_offset = load_const_optimized(tmp, delayed_value_addr, noreg, true);
386 ld(tmp, simm16_offset, tmp); // must be aligned ((xa & 3) == 0)
388 if (offset != 0) {
389 addi(tmp, tmp, offset);
390 }
392 return RegisterOrConstant(tmp);
393 }
395 #ifndef PRODUCT
396 void MacroAssembler::pd_print_patched_instruction(address branch) {
397 Unimplemented(); // TODO: PPC port
398 }
399 #endif // ndef PRODUCT
401 // Conditional far branch for destinations encodable in 24+2 bits.
402 void MacroAssembler::bc_far(int boint, int biint, Label& dest, int optimize) {
404 // If requested by flag optimize, relocate the bc_far as a
405 // runtime_call and prepare for optimizing it when the code gets
406 // relocated.
407 if (optimize == bc_far_optimize_on_relocate) {
408 relocate(relocInfo::runtime_call_type);
409 }
411 // variant 2:
412 //
413 // b!cxx SKIP
414 // bxx DEST
415 // SKIP:
416 //
418 const int opposite_boint = add_bhint_to_boint(opposite_bhint(inv_boint_bhint(boint)),
419 opposite_bcond(inv_boint_bcond(boint)));
421 // We emit two branches.
422 // First, a conditional branch which jumps around the far branch.
423 const address not_taken_pc = pc() + 2 * BytesPerInstWord;
424 const address bc_pc = pc();
425 bc(opposite_boint, biint, not_taken_pc);
427 const int bc_instr = *(int*)bc_pc;
428 assert(not_taken_pc == (address)inv_bd_field(bc_instr, (intptr_t)bc_pc), "postcondition");
429 assert(opposite_boint == inv_bo_field(bc_instr), "postcondition");
430 assert(boint == add_bhint_to_boint(opposite_bhint(inv_boint_bhint(inv_bo_field(bc_instr))),
431 opposite_bcond(inv_boint_bcond(inv_bo_field(bc_instr)))),
432 "postcondition");
433 assert(biint == inv_bi_field(bc_instr), "postcondition");
435 // Second, an unconditional far branch which jumps to dest.
436 // Note: target(dest) remembers the current pc (see CodeSection::target)
437 // and returns the current pc if the label is not bound yet; when
438 // the label gets bound, the unconditional far branch will be patched.
439 const address target_pc = target(dest);
440 const address b_pc = pc();
441 b(target_pc);
443 assert(not_taken_pc == pc(), "postcondition");
444 assert(dest.is_bound() || target_pc == b_pc, "postcondition");
445 }
447 bool MacroAssembler::is_bc_far_at(address instruction_addr) {
448 return is_bc_far_variant1_at(instruction_addr) ||
449 is_bc_far_variant2_at(instruction_addr) ||
450 is_bc_far_variant3_at(instruction_addr);
451 }
453 address MacroAssembler::get_dest_of_bc_far_at(address instruction_addr) {
454 if (is_bc_far_variant1_at(instruction_addr)) {
455 const address instruction_1_addr = instruction_addr;
456 const int instruction_1 = *(int*)instruction_1_addr;
457 return (address)inv_bd_field(instruction_1, (intptr_t)instruction_1_addr);
458 } else if (is_bc_far_variant2_at(instruction_addr)) {
459 const address instruction_2_addr = instruction_addr + 4;
460 return bxx_destination(instruction_2_addr);
461 } else if (is_bc_far_variant3_at(instruction_addr)) {
462 return instruction_addr + 8;
463 }
464 // variant 4 ???
465 ShouldNotReachHere();
466 return NULL;
467 }
468 void MacroAssembler::set_dest_of_bc_far_at(address instruction_addr, address dest) {
470 if (is_bc_far_variant3_at(instruction_addr)) {
471 // variant 3, far cond branch to the next instruction, already patched to nops:
472 //
473 // nop
474 // endgroup
475 // SKIP/DEST:
476 //
477 return;
478 }
480 // first, extract boint and biint from the current branch
481 int boint = 0;
482 int biint = 0;
484 ResourceMark rm;
485 const int code_size = 2 * BytesPerInstWord;
486 CodeBuffer buf(instruction_addr, code_size);
487 MacroAssembler masm(&buf);
488 if (is_bc_far_variant2_at(instruction_addr) && dest == instruction_addr + 8) {
489 // Far branch to next instruction: Optimize it by patching nops (produce variant 3).
490 masm.nop();
491 masm.endgroup();
492 } else {
493 if (is_bc_far_variant1_at(instruction_addr)) {
494 // variant 1, the 1st instruction contains the destination address:
495 //
496 // bcxx DEST
497 // endgroup
498 //
499 const int instruction_1 = *(int*)(instruction_addr);
500 boint = inv_bo_field(instruction_1);
501 biint = inv_bi_field(instruction_1);
502 } else if (is_bc_far_variant2_at(instruction_addr)) {
503 // variant 2, the 2nd instruction contains the destination address:
504 //
505 // b!cxx SKIP
506 // bxx DEST
507 // SKIP:
508 //
509 const int instruction_1 = *(int*)(instruction_addr);
510 boint = add_bhint_to_boint(opposite_bhint(inv_boint_bhint(inv_bo_field(instruction_1))),
511 opposite_bcond(inv_boint_bcond(inv_bo_field(instruction_1))));
512 biint = inv_bi_field(instruction_1);
513 } else {
514 // variant 4???
515 ShouldNotReachHere();
516 }
518 // second, set the new branch destination and optimize the code
519 if (dest != instruction_addr + 4 && // the bc_far is still unbound!
520 masm.is_within_range_of_bcxx(dest, instruction_addr)) {
521 // variant 1:
522 //
523 // bcxx DEST
524 // endgroup
525 //
526 masm.bc(boint, biint, dest);
527 masm.endgroup();
528 } else {
529 // variant 2:
530 //
531 // b!cxx SKIP
532 // bxx DEST
533 // SKIP:
534 //
535 const int opposite_boint = add_bhint_to_boint(opposite_bhint(inv_boint_bhint(boint)),
536 opposite_bcond(inv_boint_bcond(boint)));
537 const address not_taken_pc = masm.pc() + 2 * BytesPerInstWord;
538 masm.bc(opposite_boint, biint, not_taken_pc);
539 masm.b(dest);
540 }
541 }
542 ICache::ppc64_flush_icache_bytes(instruction_addr, code_size);
543 }
545 // Emit a NOT mt-safe patchable 64 bit absolute call/jump.
546 void MacroAssembler::bxx64_patchable(address dest, relocInfo::relocType rt, bool link) {
547 // get current pc
548 uint64_t start_pc = (uint64_t) pc();
550 const address pc_of_bl = (address) (start_pc + (6*BytesPerInstWord)); // bl is last
551 const address pc_of_b = (address) (start_pc + (0*BytesPerInstWord)); // b is first
553 // relocate here
554 if (rt != relocInfo::none) {
555 relocate(rt);
556 }
558 if ( ReoptimizeCallSequences &&
559 (( link && is_within_range_of_b(dest, pc_of_bl)) ||
560 (!link && is_within_range_of_b(dest, pc_of_b)))) {
561 // variant 2:
562 // Emit an optimized, pc-relative call/jump.
564 if (link) {
565 // some padding
566 nop();
567 nop();
568 nop();
569 nop();
570 nop();
571 nop();
573 // do the call
574 assert(pc() == pc_of_bl, "just checking");
575 bl(dest, relocInfo::none);
576 } else {
577 // do the jump
578 assert(pc() == pc_of_b, "just checking");
579 b(dest, relocInfo::none);
581 // some padding
582 nop();
583 nop();
584 nop();
585 nop();
586 nop();
587 nop();
588 }
590 // Assert that we can identify the emitted call/jump.
591 assert(is_bxx64_patchable_variant2_at((address)start_pc, link),
592 "can't identify emitted call");
593 } else {
594 // variant 1:
595 #if defined(ABI_ELFv2)
596 nop();
597 calculate_address_from_global_toc(R12, dest, true, true, false);
598 mtctr(R12);
599 nop();
600 nop();
601 #else
602 mr(R0, R11); // spill R11 -> R0.
604 // Load the destination address into CTR,
605 // calculate destination relative to global toc.
606 calculate_address_from_global_toc(R11, dest, true, true, false);
608 mtctr(R11);
609 mr(R11, R0); // spill R11 <- R0.
610 nop();
611 #endif
613 // do the call/jump
614 if (link) {
615 bctrl();
616 } else{
617 bctr();
618 }
619 // Assert that we can identify the emitted call/jump.
620 assert(is_bxx64_patchable_variant1b_at((address)start_pc, link),
621 "can't identify emitted call");
622 }
624 // Assert that we can identify the emitted call/jump.
625 assert(is_bxx64_patchable_at((address)start_pc, link),
626 "can't identify emitted call");
627 assert(get_dest_of_bxx64_patchable_at((address)start_pc, link) == dest,
628 "wrong encoding of dest address");
629 }
631 // Identify a bxx64_patchable instruction.
632 bool MacroAssembler::is_bxx64_patchable_at(address instruction_addr, bool link) {
633 return is_bxx64_patchable_variant1b_at(instruction_addr, link)
634 //|| is_bxx64_patchable_variant1_at(instruction_addr, link)
635 || is_bxx64_patchable_variant2_at(instruction_addr, link);
636 }
638 // Does the call64_patchable instruction use a pc-relative encoding of
639 // the call destination?
640 bool MacroAssembler::is_bxx64_patchable_pcrelative_at(address instruction_addr, bool link) {
641 // variant 2 is pc-relative
642 return is_bxx64_patchable_variant2_at(instruction_addr, link);
643 }
645 // Identify variant 1.
646 bool MacroAssembler::is_bxx64_patchable_variant1_at(address instruction_addr, bool link) {
647 unsigned int* instr = (unsigned int*) instruction_addr;
648 return (link ? is_bctrl(instr[6]) : is_bctr(instr[6])) // bctr[l]
649 && is_mtctr(instr[5]) // mtctr
650 && is_load_const_at(instruction_addr);
651 }
653 // Identify variant 1b: load destination relative to global toc.
654 bool MacroAssembler::is_bxx64_patchable_variant1b_at(address instruction_addr, bool link) {
655 unsigned int* instr = (unsigned int*) instruction_addr;
656 return (link ? is_bctrl(instr[6]) : is_bctr(instr[6])) // bctr[l]
657 && is_mtctr(instr[3]) // mtctr
658 && is_calculate_address_from_global_toc_at(instruction_addr + 2*BytesPerInstWord, instruction_addr);
659 }
661 // Identify variant 2.
662 bool MacroAssembler::is_bxx64_patchable_variant2_at(address instruction_addr, bool link) {
663 unsigned int* instr = (unsigned int*) instruction_addr;
664 if (link) {
665 return is_bl (instr[6]) // bl dest is last
666 && is_nop(instr[0]) // nop
667 && is_nop(instr[1]) // nop
668 && is_nop(instr[2]) // nop
669 && is_nop(instr[3]) // nop
670 && is_nop(instr[4]) // nop
671 && is_nop(instr[5]); // nop
672 } else {
673 return is_b (instr[0]) // b dest is first
674 && is_nop(instr[1]) // nop
675 && is_nop(instr[2]) // nop
676 && is_nop(instr[3]) // nop
677 && is_nop(instr[4]) // nop
678 && is_nop(instr[5]) // nop
679 && is_nop(instr[6]); // nop
680 }
681 }
683 // Set dest address of a bxx64_patchable instruction.
684 void MacroAssembler::set_dest_of_bxx64_patchable_at(address instruction_addr, address dest, bool link) {
685 ResourceMark rm;
686 int code_size = MacroAssembler::bxx64_patchable_size;
687 CodeBuffer buf(instruction_addr, code_size);
688 MacroAssembler masm(&buf);
689 masm.bxx64_patchable(dest, relocInfo::none, link);
690 ICache::ppc64_flush_icache_bytes(instruction_addr, code_size);
691 }
693 // Get dest address of a bxx64_patchable instruction.
694 address MacroAssembler::get_dest_of_bxx64_patchable_at(address instruction_addr, bool link) {
695 if (is_bxx64_patchable_variant1_at(instruction_addr, link)) {
696 return (address) (unsigned long) get_const(instruction_addr);
697 } else if (is_bxx64_patchable_variant2_at(instruction_addr, link)) {
698 unsigned int* instr = (unsigned int*) instruction_addr;
699 if (link) {
700 const int instr_idx = 6; // bl is last
701 int branchoffset = branch_destination(instr[instr_idx], 0);
702 return instruction_addr + branchoffset + instr_idx*BytesPerInstWord;
703 } else {
704 const int instr_idx = 0; // b is first
705 int branchoffset = branch_destination(instr[instr_idx], 0);
706 return instruction_addr + branchoffset + instr_idx*BytesPerInstWord;
707 }
708 // Load dest relative to global toc.
709 } else if (is_bxx64_patchable_variant1b_at(instruction_addr, link)) {
710 return get_address_of_calculate_address_from_global_toc_at(instruction_addr + 2*BytesPerInstWord,
711 instruction_addr);
712 } else {
713 ShouldNotReachHere();
714 return NULL;
715 }
716 }
718 // Uses ordering which corresponds to ABI:
719 // _savegpr0_14: std r14,-144(r1)
720 // _savegpr0_15: std r15,-136(r1)
721 // _savegpr0_16: std r16,-128(r1)
722 void MacroAssembler::save_nonvolatile_gprs(Register dst, int offset) {
723 std(R14, offset, dst); offset += 8;
724 std(R15, offset, dst); offset += 8;
725 std(R16, offset, dst); offset += 8;
726 std(R17, offset, dst); offset += 8;
727 std(R18, offset, dst); offset += 8;
728 std(R19, offset, dst); offset += 8;
729 std(R20, offset, dst); offset += 8;
730 std(R21, offset, dst); offset += 8;
731 std(R22, offset, dst); offset += 8;
732 std(R23, offset, dst); offset += 8;
733 std(R24, offset, dst); offset += 8;
734 std(R25, offset, dst); offset += 8;
735 std(R26, offset, dst); offset += 8;
736 std(R27, offset, dst); offset += 8;
737 std(R28, offset, dst); offset += 8;
738 std(R29, offset, dst); offset += 8;
739 std(R30, offset, dst); offset += 8;
740 std(R31, offset, dst); offset += 8;
742 stfd(F14, offset, dst); offset += 8;
743 stfd(F15, offset, dst); offset += 8;
744 stfd(F16, offset, dst); offset += 8;
745 stfd(F17, offset, dst); offset += 8;
746 stfd(F18, offset, dst); offset += 8;
747 stfd(F19, offset, dst); offset += 8;
748 stfd(F20, offset, dst); offset += 8;
749 stfd(F21, offset, dst); offset += 8;
750 stfd(F22, offset, dst); offset += 8;
751 stfd(F23, offset, dst); offset += 8;
752 stfd(F24, offset, dst); offset += 8;
753 stfd(F25, offset, dst); offset += 8;
754 stfd(F26, offset, dst); offset += 8;
755 stfd(F27, offset, dst); offset += 8;
756 stfd(F28, offset, dst); offset += 8;
757 stfd(F29, offset, dst); offset += 8;
758 stfd(F30, offset, dst); offset += 8;
759 stfd(F31, offset, dst);
760 }
762 // Uses ordering which corresponds to ABI:
763 // _restgpr0_14: ld r14,-144(r1)
764 // _restgpr0_15: ld r15,-136(r1)
765 // _restgpr0_16: ld r16,-128(r1)
766 void MacroAssembler::restore_nonvolatile_gprs(Register src, int offset) {
767 ld(R14, offset, src); offset += 8;
768 ld(R15, offset, src); offset += 8;
769 ld(R16, offset, src); offset += 8;
770 ld(R17, offset, src); offset += 8;
771 ld(R18, offset, src); offset += 8;
772 ld(R19, offset, src); offset += 8;
773 ld(R20, offset, src); offset += 8;
774 ld(R21, offset, src); offset += 8;
775 ld(R22, offset, src); offset += 8;
776 ld(R23, offset, src); offset += 8;
777 ld(R24, offset, src); offset += 8;
778 ld(R25, offset, src); offset += 8;
779 ld(R26, offset, src); offset += 8;
780 ld(R27, offset, src); offset += 8;
781 ld(R28, offset, src); offset += 8;
782 ld(R29, offset, src); offset += 8;
783 ld(R30, offset, src); offset += 8;
784 ld(R31, offset, src); offset += 8;
786 // FP registers
787 lfd(F14, offset, src); offset += 8;
788 lfd(F15, offset, src); offset += 8;
789 lfd(F16, offset, src); offset += 8;
790 lfd(F17, offset, src); offset += 8;
791 lfd(F18, offset, src); offset += 8;
792 lfd(F19, offset, src); offset += 8;
793 lfd(F20, offset, src); offset += 8;
794 lfd(F21, offset, src); offset += 8;
795 lfd(F22, offset, src); offset += 8;
796 lfd(F23, offset, src); offset += 8;
797 lfd(F24, offset, src); offset += 8;
798 lfd(F25, offset, src); offset += 8;
799 lfd(F26, offset, src); offset += 8;
800 lfd(F27, offset, src); offset += 8;
801 lfd(F28, offset, src); offset += 8;
802 lfd(F29, offset, src); offset += 8;
803 lfd(F30, offset, src); offset += 8;
804 lfd(F31, offset, src);
805 }
807 // For verify_oops.
808 void MacroAssembler::save_volatile_gprs(Register dst, int offset) {
809 std(R3, offset, dst); offset += 8;
810 std(R4, offset, dst); offset += 8;
811 std(R5, offset, dst); offset += 8;
812 std(R6, offset, dst); offset += 8;
813 std(R7, offset, dst); offset += 8;
814 std(R8, offset, dst); offset += 8;
815 std(R9, offset, dst); offset += 8;
816 std(R10, offset, dst); offset += 8;
817 std(R11, offset, dst); offset += 8;
818 std(R12, offset, dst);
819 }
821 // For verify_oops.
822 void MacroAssembler::restore_volatile_gprs(Register src, int offset) {
823 ld(R3, offset, src); offset += 8;
824 ld(R4, offset, src); offset += 8;
825 ld(R5, offset, src); offset += 8;
826 ld(R6, offset, src); offset += 8;
827 ld(R7, offset, src); offset += 8;
828 ld(R8, offset, src); offset += 8;
829 ld(R9, offset, src); offset += 8;
830 ld(R10, offset, src); offset += 8;
831 ld(R11, offset, src); offset += 8;
832 ld(R12, offset, src);
833 }
835 void MacroAssembler::save_LR_CR(Register tmp) {
836 mfcr(tmp);
837 std(tmp, _abi(cr), R1_SP);
838 mflr(tmp);
839 std(tmp, _abi(lr), R1_SP);
840 // Tmp must contain lr on exit! (see return_addr and prolog in ppc64.ad)
841 }
843 void MacroAssembler::restore_LR_CR(Register tmp) {
844 assert(tmp != R1_SP, "must be distinct");
845 ld(tmp, _abi(lr), R1_SP);
846 mtlr(tmp);
847 ld(tmp, _abi(cr), R1_SP);
848 mtcr(tmp);
849 }
851 address MacroAssembler::get_PC_trash_LR(Register result) {
852 Label L;
853 bl(L);
854 bind(L);
855 address lr_pc = pc();
856 mflr(result);
857 return lr_pc;
858 }
860 void MacroAssembler::resize_frame(Register offset, Register tmp) {
861 #ifdef ASSERT
862 assert_different_registers(offset, tmp, R1_SP);
863 andi_(tmp, offset, frame::alignment_in_bytes-1);
864 asm_assert_eq("resize_frame: unaligned", 0x204);
865 #endif
867 // tmp <- *(SP)
868 ld(tmp, _abi(callers_sp), R1_SP);
869 // addr <- SP + offset;
870 // *(addr) <- tmp;
871 // SP <- addr
872 stdux(tmp, R1_SP, offset);
873 }
875 void MacroAssembler::resize_frame(int offset, Register tmp) {
876 assert(is_simm(offset, 16), "too big an offset");
877 assert_different_registers(tmp, R1_SP);
878 assert((offset & (frame::alignment_in_bytes-1))==0, "resize_frame: unaligned");
879 // tmp <- *(SP)
880 ld(tmp, _abi(callers_sp), R1_SP);
881 // addr <- SP + offset;
882 // *(addr) <- tmp;
883 // SP <- addr
884 stdu(tmp, offset, R1_SP);
885 }
887 void MacroAssembler::resize_frame_absolute(Register addr, Register tmp1, Register tmp2) {
888 // (addr == tmp1) || (addr == tmp2) is allowed here!
889 assert(tmp1 != tmp2, "must be distinct");
891 // compute offset w.r.t. current stack pointer
892 // tmp_1 <- addr - SP (!)
893 subf(tmp1, R1_SP, addr);
895 // atomically update SP keeping back link.
896 resize_frame(tmp1/* offset */, tmp2/* tmp */);
897 }
899 void MacroAssembler::push_frame(Register bytes, Register tmp) {
900 #ifdef ASSERT
901 assert(bytes != R0, "r0 not allowed here");
902 andi_(R0, bytes, frame::alignment_in_bytes-1);
903 asm_assert_eq("push_frame(Reg, Reg): unaligned", 0x203);
904 #endif
905 neg(tmp, bytes);
906 stdux(R1_SP, R1_SP, tmp);
907 }
909 // Push a frame of size `bytes'.
910 void MacroAssembler::push_frame(unsigned int bytes, Register tmp) {
911 long offset = align_addr(bytes, frame::alignment_in_bytes);
912 if (is_simm(-offset, 16)) {
913 stdu(R1_SP, -offset, R1_SP);
914 } else {
915 load_const(tmp, -offset);
916 stdux(R1_SP, R1_SP, tmp);
917 }
918 }
920 // Push a frame of size `bytes' plus abi_reg_args on top.
921 void MacroAssembler::push_frame_reg_args(unsigned int bytes, Register tmp) {
922 push_frame(bytes + frame::abi_reg_args_size, tmp);
923 }
925 // Setup up a new C frame with a spill area for non-volatile GPRs and
926 // additional space for local variables.
927 void MacroAssembler::push_frame_reg_args_nonvolatiles(unsigned int bytes,
928 Register tmp) {
929 push_frame(bytes + frame::abi_reg_args_size + frame::spill_nonvolatiles_size, tmp);
930 }
932 // Pop current C frame.
933 void MacroAssembler::pop_frame() {
934 ld(R1_SP, _abi(callers_sp), R1_SP);
935 }
937 #if defined(ABI_ELFv2)
938 address MacroAssembler::branch_to(Register r_function_entry, bool and_link) {
939 // TODO(asmundak): make sure the caller uses R12 as function descriptor
940 // most of the times.
941 if (R12 != r_function_entry) {
942 mr(R12, r_function_entry);
943 }
944 mtctr(R12);
945 // Do a call or a branch.
946 if (and_link) {
947 bctrl();
948 } else {
949 bctr();
950 }
951 _last_calls_return_pc = pc();
953 return _last_calls_return_pc;
954 }
956 // Call a C function via a function descriptor and use full C
957 // calling conventions. Updates and returns _last_calls_return_pc.
958 address MacroAssembler::call_c(Register r_function_entry) {
959 return branch_to(r_function_entry, /*and_link=*/true);
960 }
962 // For tail calls: only branch, don't link, so callee returns to caller of this function.
963 address MacroAssembler::call_c_and_return_to_caller(Register r_function_entry) {
964 return branch_to(r_function_entry, /*and_link=*/false);
965 }
967 address MacroAssembler::call_c(address function_entry, relocInfo::relocType rt) {
968 load_const(R12, function_entry, R0);
969 return branch_to(R12, /*and_link=*/true);
970 }
972 #else
973 // Generic version of a call to C function via a function descriptor
974 // with variable support for C calling conventions (TOC, ENV, etc.).
975 // Updates and returns _last_calls_return_pc.
976 address MacroAssembler::branch_to(Register function_descriptor, bool and_link, bool save_toc_before_call,
977 bool restore_toc_after_call, bool load_toc_of_callee, bool load_env_of_callee) {
978 // we emit standard ptrgl glue code here
979 assert((function_descriptor != R0), "function_descriptor cannot be R0");
981 // retrieve necessary entries from the function descriptor
982 ld(R0, in_bytes(FunctionDescriptor::entry_offset()), function_descriptor);
983 mtctr(R0);
985 if (load_toc_of_callee) {
986 ld(R2_TOC, in_bytes(FunctionDescriptor::toc_offset()), function_descriptor);
987 }
988 if (load_env_of_callee) {
989 ld(R11, in_bytes(FunctionDescriptor::env_offset()), function_descriptor);
990 } else if (load_toc_of_callee) {
991 li(R11, 0);
992 }
994 // do a call or a branch
995 if (and_link) {
996 bctrl();
997 } else {
998 bctr();
999 }
1000 _last_calls_return_pc = pc();
1002 return _last_calls_return_pc;
1003 }
1005 // Call a C function via a function descriptor and use full C calling
1006 // conventions.
1007 // We don't use the TOC in generated code, so there is no need to save
1008 // and restore its value.
1009 address MacroAssembler::call_c(Register fd) {
1010 return branch_to(fd, /*and_link=*/true,
1011 /*save toc=*/false,
1012 /*restore toc=*/false,
1013 /*load toc=*/true,
1014 /*load env=*/true);
1015 }
1017 address MacroAssembler::call_c_and_return_to_caller(Register fd) {
1018 return branch_to(fd, /*and_link=*/false,
1019 /*save toc=*/false,
1020 /*restore toc=*/false,
1021 /*load toc=*/true,
1022 /*load env=*/true);
1023 }
1025 address MacroAssembler::call_c(const FunctionDescriptor* fd, relocInfo::relocType rt) {
1026 if (rt != relocInfo::none) {
1027 // this call needs to be relocatable
1028 if (!ReoptimizeCallSequences
1029 || (rt != relocInfo::runtime_call_type && rt != relocInfo::none)
1030 || fd == NULL // support code-size estimation
1031 || !fd->is_friend_function()
1032 || fd->entry() == NULL) {
1033 // it's not a friend function as defined by class FunctionDescriptor,
1034 // so do a full call-c here.
1035 load_const(R11, (address)fd, R0);
1037 bool has_env = (fd != NULL && fd->env() != NULL);
1038 return branch_to(R11, /*and_link=*/true,
1039 /*save toc=*/false,
1040 /*restore toc=*/false,
1041 /*load toc=*/true,
1042 /*load env=*/has_env);
1043 } else {
1044 // It's a friend function. Load the entry point and don't care about
1045 // toc and env. Use an optimizable call instruction, but ensure the
1046 // same code-size as in the case of a non-friend function.
1047 nop();
1048 nop();
1049 nop();
1050 bl64_patchable(fd->entry(), rt);
1051 _last_calls_return_pc = pc();
1052 return _last_calls_return_pc;
1053 }
1054 } else {
1055 // This call does not need to be relocatable, do more aggressive
1056 // optimizations.
1057 if (!ReoptimizeCallSequences
1058 || !fd->is_friend_function()) {
1059 // It's not a friend function as defined by class FunctionDescriptor,
1060 // so do a full call-c here.
1061 load_const(R11, (address)fd, R0);
1062 return branch_to(R11, /*and_link=*/true,
1063 /*save toc=*/false,
1064 /*restore toc=*/false,
1065 /*load toc=*/true,
1066 /*load env=*/true);
1067 } else {
1068 // it's a friend function, load the entry point and don't care about
1069 // toc and env.
1070 address dest = fd->entry();
1071 if (is_within_range_of_b(dest, pc())) {
1072 bl(dest);
1073 } else {
1074 bl64_patchable(dest, rt);
1075 }
1076 _last_calls_return_pc = pc();
1077 return _last_calls_return_pc;
1078 }
1079 }
1080 }
1082 // Call a C function. All constants needed reside in TOC.
1083 //
1084 // Read the address to call from the TOC.
1085 // Read env from TOC, if fd specifies an env.
1086 // Read new TOC from TOC.
1087 address MacroAssembler::call_c_using_toc(const FunctionDescriptor* fd,
1088 relocInfo::relocType rt, Register toc) {
1089 if (!ReoptimizeCallSequences
1090 || (rt != relocInfo::runtime_call_type && rt != relocInfo::none)
1091 || !fd->is_friend_function()) {
1092 // It's not a friend function as defined by class FunctionDescriptor,
1093 // so do a full call-c here.
1094 assert(fd->entry() != NULL, "function must be linked");
1096 AddressLiteral fd_entry(fd->entry());
1097 load_const_from_method_toc(R11, fd_entry, toc);
1098 mtctr(R11);
1099 if (fd->env() == NULL) {
1100 li(R11, 0);
1101 nop();
1102 } else {
1103 AddressLiteral fd_env(fd->env());
1104 load_const_from_method_toc(R11, fd_env, toc);
1105 }
1106 AddressLiteral fd_toc(fd->toc());
1107 load_toc_from_toc(R2_TOC, fd_toc, toc);
1108 // R2_TOC is killed.
1109 bctrl();
1110 _last_calls_return_pc = pc();
1111 } else {
1112 // It's a friend function, load the entry point and don't care about
1113 // toc and env. Use an optimizable call instruction, but ensure the
1114 // same code-size as in the case of a non-friend function.
1115 nop();
1116 bl64_patchable(fd->entry(), rt);
1117 _last_calls_return_pc = pc();
1118 }
1119 return _last_calls_return_pc;
1120 }
1121 #endif // ABI_ELFv2
1123 void MacroAssembler::call_VM_base(Register oop_result,
1124 Register last_java_sp,
1125 address entry_point,
1126 bool check_exceptions) {
1127 BLOCK_COMMENT("call_VM {");
1128 // Determine last_java_sp register.
1129 if (!last_java_sp->is_valid()) {
1130 last_java_sp = R1_SP;
1131 }
1132 set_top_ijava_frame_at_SP_as_last_Java_frame(last_java_sp, R11_scratch1);
1134 // ARG1 must hold thread address.
1135 mr(R3_ARG1, R16_thread);
1136 #if defined(ABI_ELFv2)
1137 address return_pc = call_c(entry_point, relocInfo::none);
1138 #else
1139 address return_pc = call_c((FunctionDescriptor*)entry_point, relocInfo::none);
1140 #endif
1142 reset_last_Java_frame();
1144 // Check for pending exceptions.
1145 if (check_exceptions) {
1146 // We don't check for exceptions here.
1147 ShouldNotReachHere();
1148 }
1150 // Get oop result if there is one and reset the value in the thread.
1151 if (oop_result->is_valid()) {
1152 get_vm_result(oop_result);
1153 }
1155 _last_calls_return_pc = return_pc;
1156 BLOCK_COMMENT("} call_VM");
1157 }
1159 void MacroAssembler::call_VM_leaf_base(address entry_point) {
1160 BLOCK_COMMENT("call_VM_leaf {");
1161 #if defined(ABI_ELFv2)
1162 call_c(entry_point, relocInfo::none);
1163 #else
1164 call_c(CAST_FROM_FN_PTR(FunctionDescriptor*, entry_point), relocInfo::none);
1165 #endif
1166 BLOCK_COMMENT("} call_VM_leaf");
1167 }
1169 void MacroAssembler::call_VM(Register oop_result, address entry_point, bool check_exceptions) {
1170 call_VM_base(oop_result, noreg, entry_point, check_exceptions);
1171 }
1173 void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1,
1174 bool check_exceptions) {
1175 // R3_ARG1 is reserved for the thread.
1176 mr_if_needed(R4_ARG2, arg_1);
1177 call_VM(oop_result, entry_point, check_exceptions);
1178 }
1180 void MacroAssembler::call_VM(Register oop_result, address entry_point, Register arg_1, Register arg_2,
1181 bool check_exceptions) {
1182 // R3_ARG1 is reserved for the thread
1183 mr_if_needed(R4_ARG2, arg_1);
1184 assert(arg_2 != R4_ARG2, "smashed argument");
1185 mr_if_needed(R5_ARG3, arg_2);
1186 call_VM(oop_result, entry_point, check_exceptions);
1187 }
1189 void MacroAssembler::call_VM_leaf(address entry_point) {
1190 call_VM_leaf_base(entry_point);
1191 }
1193 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1) {
1194 mr_if_needed(R3_ARG1, arg_1);
1195 call_VM_leaf(entry_point);
1196 }
1198 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1, Register arg_2) {
1199 mr_if_needed(R3_ARG1, arg_1);
1200 assert(arg_2 != R3_ARG1, "smashed argument");
1201 mr_if_needed(R4_ARG2, arg_2);
1202 call_VM_leaf(entry_point);
1203 }
1205 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_1, Register arg_2, Register arg_3) {
1206 mr_if_needed(R3_ARG1, arg_1);
1207 assert(arg_2 != R3_ARG1, "smashed argument");
1208 mr_if_needed(R4_ARG2, arg_2);
1209 assert(arg_3 != R3_ARG1 && arg_3 != R4_ARG2, "smashed argument");
1210 mr_if_needed(R5_ARG3, arg_3);
1211 call_VM_leaf(entry_point);
1212 }
1214 // Check whether instruction is a read access to the polling page
1215 // which was emitted by load_from_polling_page(..).
1216 bool MacroAssembler::is_load_from_polling_page(int instruction, void* ucontext,
1217 address* polling_address_ptr) {
1218 if (!is_ld(instruction))
1219 return false; // It's not a ld. Fail.
1221 int rt = inv_rt_field(instruction);
1222 int ra = inv_ra_field(instruction);
1223 int ds = inv_ds_field(instruction);
1224 if (!(ds == 0 && ra != 0 && rt == 0)) {
1225 return false; // It's not a ld(r0, X, ra). Fail.
1226 }
1228 if (!ucontext) {
1229 // Set polling address.
1230 if (polling_address_ptr != NULL) {
1231 *polling_address_ptr = NULL;
1232 }
1233 return true; // No ucontext given. Can't check value of ra. Assume true.
1234 }
1236 #ifdef LINUX
1237 // Ucontext given. Check that register ra contains the address of
1238 // the safepoing polling page.
1239 ucontext_t* uc = (ucontext_t*) ucontext;
1240 // Set polling address.
1241 address addr = (address)uc->uc_mcontext.regs->gpr[ra] + (ssize_t)ds;
1242 if (polling_address_ptr != NULL) {
1243 *polling_address_ptr = addr;
1244 }
1245 return os::is_poll_address(addr);
1246 #else
1247 // Not on Linux, ucontext must be NULL.
1248 ShouldNotReachHere();
1249 return false;
1250 #endif
1251 }
1253 bool MacroAssembler::is_memory_serialization(int instruction, JavaThread* thread, void* ucontext) {
1254 #ifdef LINUX
1255 ucontext_t* uc = (ucontext_t*) ucontext;
1257 if (is_stwx(instruction) || is_stwux(instruction)) {
1258 int ra = inv_ra_field(instruction);
1259 int rb = inv_rb_field(instruction);
1261 // look up content of ra and rb in ucontext
1262 address ra_val=(address)uc->uc_mcontext.regs->gpr[ra];
1263 long rb_val=(long)uc->uc_mcontext.regs->gpr[rb];
1264 return os::is_memory_serialize_page(thread, ra_val+rb_val);
1265 } else if (is_stw(instruction) || is_stwu(instruction)) {
1266 int ra = inv_ra_field(instruction);
1267 int d1 = inv_d1_field(instruction);
1269 // look up content of ra in ucontext
1270 address ra_val=(address)uc->uc_mcontext.regs->gpr[ra];
1271 return os::is_memory_serialize_page(thread, ra_val+d1);
1272 } else {
1273 return false;
1274 }
1275 #else
1276 // workaround not needed on !LINUX :-)
1277 ShouldNotCallThis();
1278 return false;
1279 #endif
1280 }
1282 void MacroAssembler::bang_stack_with_offset(int offset) {
1283 // When increasing the stack, the old stack pointer will be written
1284 // to the new top of stack according to the PPC64 abi.
1285 // Therefore, stack banging is not necessary when increasing
1286 // the stack by <= os::vm_page_size() bytes.
1287 // When increasing the stack by a larger amount, this method is
1288 // called repeatedly to bang the intermediate pages.
1290 // Stack grows down, caller passes positive offset.
1291 assert(offset > 0, "must bang with positive offset");
1293 long stdoffset = -offset;
1295 if (is_simm(stdoffset, 16)) {
1296 // Signed 16 bit offset, a simple std is ok.
1297 if (UseLoadInstructionsForStackBangingPPC64) {
1298 ld(R0, (int)(signed short)stdoffset, R1_SP);
1299 } else {
1300 std(R0,(int)(signed short)stdoffset, R1_SP);
1301 }
1302 } else if (is_simm(stdoffset, 31)) {
1303 const int hi = MacroAssembler::largeoffset_si16_si16_hi(stdoffset);
1304 const int lo = MacroAssembler::largeoffset_si16_si16_lo(stdoffset);
1306 Register tmp = R11;
1307 addis(tmp, R1_SP, hi);
1308 if (UseLoadInstructionsForStackBangingPPC64) {
1309 ld(R0, lo, tmp);
1310 } else {
1311 std(R0, lo, tmp);
1312 }
1313 } else {
1314 ShouldNotReachHere();
1315 }
1316 }
1318 // If instruction is a stack bang of the form
1319 // std R0, x(Ry), (see bang_stack_with_offset())
1320 // stdu R1_SP, x(R1_SP), (see push_frame(), resize_frame())
1321 // or stdux R1_SP, Rx, R1_SP (see push_frame(), resize_frame())
1322 // return the banged address. Otherwise, return 0.
1323 address MacroAssembler::get_stack_bang_address(int instruction, void *ucontext) {
1324 #ifdef LINUX
1325 ucontext_t* uc = (ucontext_t*) ucontext;
1326 int rs = inv_rs_field(instruction);
1327 int ra = inv_ra_field(instruction);
1328 if ( (is_ld(instruction) && rs == 0 && UseLoadInstructionsForStackBangingPPC64)
1329 || (is_std(instruction) && rs == 0 && !UseLoadInstructionsForStackBangingPPC64)
1330 || (is_stdu(instruction) && rs == 1)) {
1331 int ds = inv_ds_field(instruction);
1332 // return banged address
1333 return ds+(address)uc->uc_mcontext.regs->gpr[ra];
1334 } else if (is_stdux(instruction) && rs == 1) {
1335 int rb = inv_rb_field(instruction);
1336 address sp = (address)uc->uc_mcontext.regs->gpr[1];
1337 long rb_val = (long)uc->uc_mcontext.regs->gpr[rb];
1338 return ra != 1 || rb_val >= 0 ? NULL // not a stack bang
1339 : sp + rb_val; // banged address
1340 }
1341 return NULL; // not a stack bang
1342 #else
1343 // workaround not needed on !LINUX :-)
1344 ShouldNotCallThis();
1345 return NULL;
1346 #endif
1347 }
1349 // CmpxchgX sets condition register to cmpX(current, compare).
1350 void MacroAssembler::cmpxchgw(ConditionRegister flag, Register dest_current_value,
1351 Register compare_value, Register exchange_value,
1352 Register addr_base, int semantics, bool cmpxchgx_hint,
1353 Register int_flag_success, bool contention_hint) {
1354 Label retry;
1355 Label failed;
1356 Label done;
1358 // Save one branch if result is returned via register and
1359 // result register is different from the other ones.
1360 bool use_result_reg = (int_flag_success != noreg);
1361 bool preset_result_reg = (int_flag_success != dest_current_value && int_flag_success != compare_value &&
1362 int_flag_success != exchange_value && int_flag_success != addr_base);
1364 // release/fence semantics
1365 if (semantics & MemBarRel) {
1366 release();
1367 }
1369 if (use_result_reg && preset_result_reg) {
1370 li(int_flag_success, 0); // preset (assume cas failed)
1371 }
1373 // Add simple guard in order to reduce risk of starving under high contention (recommended by IBM).
1374 if (contention_hint) { // Don't try to reserve if cmp fails.
1375 lwz(dest_current_value, 0, addr_base);
1376 cmpw(flag, dest_current_value, compare_value);
1377 bne(flag, failed);
1378 }
1380 // atomic emulation loop
1381 bind(retry);
1383 lwarx(dest_current_value, addr_base, cmpxchgx_hint);
1384 cmpw(flag, dest_current_value, compare_value);
1385 if (UseStaticBranchPredictionInCompareAndSwapPPC64) {
1386 bne_predict_not_taken(flag, failed);
1387 } else {
1388 bne( flag, failed);
1389 }
1390 // branch to done => (flag == ne), (dest_current_value != compare_value)
1391 // fall through => (flag == eq), (dest_current_value == compare_value)
1393 stwcx_(exchange_value, addr_base);
1394 if (UseStaticBranchPredictionInCompareAndSwapPPC64) {
1395 bne_predict_not_taken(CCR0, retry); // StXcx_ sets CCR0.
1396 } else {
1397 bne( CCR0, retry); // StXcx_ sets CCR0.
1398 }
1399 // fall through => (flag == eq), (dest_current_value == compare_value), (swapped)
1401 // Result in register (must do this at the end because int_flag_success can be the
1402 // same register as one above).
1403 if (use_result_reg) {
1404 li(int_flag_success, 1);
1405 }
1407 if (semantics & MemBarFenceAfter) {
1408 fence();
1409 } else if (semantics & MemBarAcq) {
1410 isync();
1411 }
1413 if (use_result_reg && !preset_result_reg) {
1414 b(done);
1415 }
1417 bind(failed);
1418 if (use_result_reg && !preset_result_reg) {
1419 li(int_flag_success, 0);
1420 }
1422 bind(done);
1423 // (flag == ne) => (dest_current_value != compare_value), (!swapped)
1424 // (flag == eq) => (dest_current_value == compare_value), ( swapped)
1425 }
1427 // Preforms atomic compare exchange:
1428 // if (compare_value == *addr_base)
1429 // *addr_base = exchange_value
1430 // int_flag_success = 1;
1431 // else
1432 // int_flag_success = 0;
1433 //
1434 // ConditionRegister flag = cmp(compare_value, *addr_base)
1435 // Register dest_current_value = *addr_base
1436 // Register compare_value Used to compare with value in memory
1437 // Register exchange_value Written to memory if compare_value == *addr_base
1438 // Register addr_base The memory location to compareXChange
1439 // Register int_flag_success Set to 1 if exchange_value was written to *addr_base
1440 //
1441 // To avoid the costly compare exchange the value is tested beforehand.
1442 // Several special cases exist to avoid that unnecessary information is generated.
1443 //
1444 void MacroAssembler::cmpxchgd(ConditionRegister flag,
1445 Register dest_current_value, Register compare_value, Register exchange_value,
1446 Register addr_base, int semantics, bool cmpxchgx_hint,
1447 Register int_flag_success, Label* failed_ext, bool contention_hint) {
1448 Label retry;
1449 Label failed_int;
1450 Label& failed = (failed_ext != NULL) ? *failed_ext : failed_int;
1451 Label done;
1453 // Save one branch if result is returned via register and result register is different from the other ones.
1454 bool use_result_reg = (int_flag_success!=noreg);
1455 bool preset_result_reg = (int_flag_success!=dest_current_value && int_flag_success!=compare_value &&
1456 int_flag_success!=exchange_value && int_flag_success!=addr_base);
1457 assert(int_flag_success == noreg || failed_ext == NULL, "cannot have both");
1459 // release/fence semantics
1460 if (semantics & MemBarRel) {
1461 release();
1462 }
1464 if (use_result_reg && preset_result_reg) {
1465 li(int_flag_success, 0); // preset (assume cas failed)
1466 }
1468 // Add simple guard in order to reduce risk of starving under high contention (recommended by IBM).
1469 if (contention_hint) { // Don't try to reserve if cmp fails.
1470 ld(dest_current_value, 0, addr_base);
1471 cmpd(flag, dest_current_value, compare_value);
1472 bne(flag, failed);
1473 }
1475 // atomic emulation loop
1476 bind(retry);
1478 ldarx(dest_current_value, addr_base, cmpxchgx_hint);
1479 cmpd(flag, dest_current_value, compare_value);
1480 if (UseStaticBranchPredictionInCompareAndSwapPPC64) {
1481 bne_predict_not_taken(flag, failed);
1482 } else {
1483 bne( flag, failed);
1484 }
1486 stdcx_(exchange_value, addr_base);
1487 if (UseStaticBranchPredictionInCompareAndSwapPPC64) {
1488 bne_predict_not_taken(CCR0, retry); // stXcx_ sets CCR0
1489 } else {
1490 bne( CCR0, retry); // stXcx_ sets CCR0
1491 }
1493 // result in register (must do this at the end because int_flag_success can be the same register as one above)
1494 if (use_result_reg) {
1495 li(int_flag_success, 1);
1496 }
1498 // POWER6 doesn't need isync in CAS.
1499 // Always emit isync to be on the safe side.
1500 if (semantics & MemBarFenceAfter) {
1501 fence();
1502 } else if (semantics & MemBarAcq) {
1503 isync();
1504 }
1506 if (use_result_reg && !preset_result_reg) {
1507 b(done);
1508 }
1510 bind(failed_int);
1511 if (use_result_reg && !preset_result_reg) {
1512 li(int_flag_success, 0);
1513 }
1515 bind(done);
1516 // (flag == ne) => (dest_current_value != compare_value), (!swapped)
1517 // (flag == eq) => (dest_current_value == compare_value), ( swapped)
1518 }
1520 // Look up the method for a megamorphic invokeinterface call.
1521 // The target method is determined by <intf_klass, itable_index>.
1522 // The receiver klass is in recv_klass.
1523 // On success, the result will be in method_result, and execution falls through.
1524 // On failure, execution transfers to the given label.
1525 void MacroAssembler::lookup_interface_method(Register recv_klass,
1526 Register intf_klass,
1527 RegisterOrConstant itable_index,
1528 Register method_result,
1529 Register scan_temp,
1530 Register sethi_temp,
1531 Label& L_no_such_interface) {
1532 assert_different_registers(recv_klass, intf_klass, method_result, scan_temp);
1533 assert(itable_index.is_constant() || itable_index.as_register() == method_result,
1534 "caller must use same register for non-constant itable index as for method");
1536 // Compute start of first itableOffsetEntry (which is at the end of the vtable).
1537 int vtable_base = InstanceKlass::vtable_start_offset() * wordSize;
1538 int itentry_off = itableMethodEntry::method_offset_in_bytes();
1539 int logMEsize = exact_log2(itableMethodEntry::size() * wordSize);
1540 int scan_step = itableOffsetEntry::size() * wordSize;
1541 int log_vte_size= exact_log2(vtableEntry::size() * wordSize);
1543 lwz(scan_temp, InstanceKlass::vtable_length_offset() * wordSize, recv_klass);
1544 // %%% We should store the aligned, prescaled offset in the klassoop.
1545 // Then the next several instructions would fold away.
1547 sldi(scan_temp, scan_temp, log_vte_size);
1548 addi(scan_temp, scan_temp, vtable_base);
1549 add(scan_temp, recv_klass, scan_temp);
1551 // Adjust recv_klass by scaled itable_index, so we can free itable_index.
1552 if (itable_index.is_register()) {
1553 Register itable_offset = itable_index.as_register();
1554 sldi(itable_offset, itable_offset, logMEsize);
1555 if (itentry_off) addi(itable_offset, itable_offset, itentry_off);
1556 add(recv_klass, itable_offset, recv_klass);
1557 } else {
1558 long itable_offset = (long)itable_index.as_constant();
1559 load_const_optimized(sethi_temp, (itable_offset<<logMEsize)+itentry_off); // static address, no relocation
1560 add(recv_klass, sethi_temp, recv_klass);
1561 }
1563 // for (scan = klass->itable(); scan->interface() != NULL; scan += scan_step) {
1564 // if (scan->interface() == intf) {
1565 // result = (klass + scan->offset() + itable_index);
1566 // }
1567 // }
1568 Label search, found_method;
1570 for (int peel = 1; peel >= 0; peel--) {
1571 // %%%% Could load both offset and interface in one ldx, if they were
1572 // in the opposite order. This would save a load.
1573 ld(method_result, itableOffsetEntry::interface_offset_in_bytes(), scan_temp);
1575 // Check that this entry is non-null. A null entry means that
1576 // the receiver class doesn't implement the interface, and wasn't the
1577 // same as when the caller was compiled.
1578 cmpd(CCR0, method_result, intf_klass);
1580 if (peel) {
1581 beq(CCR0, found_method);
1582 } else {
1583 bne(CCR0, search);
1584 // (invert the test to fall through to found_method...)
1585 }
1587 if (!peel) break;
1589 bind(search);
1591 cmpdi(CCR0, method_result, 0);
1592 beq(CCR0, L_no_such_interface);
1593 addi(scan_temp, scan_temp, scan_step);
1594 }
1596 bind(found_method);
1598 // Got a hit.
1599 int ito_offset = itableOffsetEntry::offset_offset_in_bytes();
1600 lwz(scan_temp, ito_offset, scan_temp);
1601 ldx(method_result, scan_temp, recv_klass);
1602 }
1604 // virtual method calling
1605 void MacroAssembler::lookup_virtual_method(Register recv_klass,
1606 RegisterOrConstant vtable_index,
1607 Register method_result) {
1609 assert_different_registers(recv_klass, method_result, vtable_index.register_or_noreg());
1611 const int base = InstanceKlass::vtable_start_offset() * wordSize;
1612 assert(vtableEntry::size() * wordSize == wordSize, "adjust the scaling in the code below");
1614 if (vtable_index.is_register()) {
1615 sldi(vtable_index.as_register(), vtable_index.as_register(), LogBytesPerWord);
1616 add(recv_klass, vtable_index.as_register(), recv_klass);
1617 } else {
1618 addi(recv_klass, recv_klass, vtable_index.as_constant() << LogBytesPerWord);
1619 }
1620 ld(R19_method, base + vtableEntry::method_offset_in_bytes(), recv_klass);
1621 }
1623 /////////////////////////////////////////// subtype checking ////////////////////////////////////////////
1625 void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass,
1626 Register super_klass,
1627 Register temp1_reg,
1628 Register temp2_reg,
1629 Label& L_success,
1630 Label& L_failure) {
1632 const Register check_cache_offset = temp1_reg;
1633 const Register cached_super = temp2_reg;
1635 assert_different_registers(sub_klass, super_klass, check_cache_offset, cached_super);
1637 int sco_offset = in_bytes(Klass::super_check_offset_offset());
1638 int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
1640 // If the pointers are equal, we are done (e.g., String[] elements).
1641 // This self-check enables sharing of secondary supertype arrays among
1642 // non-primary types such as array-of-interface. Otherwise, each such
1643 // type would need its own customized SSA.
1644 // We move this check to the front of the fast path because many
1645 // type checks are in fact trivially successful in this manner,
1646 // so we get a nicely predicted branch right at the start of the check.
1647 cmpd(CCR0, sub_klass, super_klass);
1648 beq(CCR0, L_success);
1650 // Check the supertype display:
1651 lwz(check_cache_offset, sco_offset, super_klass);
1652 // The loaded value is the offset from KlassOopDesc.
1654 ldx(cached_super, check_cache_offset, sub_klass);
1655 cmpd(CCR0, cached_super, super_klass);
1656 beq(CCR0, L_success);
1658 // This check has worked decisively for primary supers.
1659 // Secondary supers are sought in the super_cache ('super_cache_addr').
1660 // (Secondary supers are interfaces and very deeply nested subtypes.)
1661 // This works in the same check above because of a tricky aliasing
1662 // between the super_cache and the primary super display elements.
1663 // (The 'super_check_addr' can address either, as the case requires.)
1664 // Note that the cache is updated below if it does not help us find
1665 // what we need immediately.
1666 // So if it was a primary super, we can just fail immediately.
1667 // Otherwise, it's the slow path for us (no success at this point).
1669 cmpwi(CCR0, check_cache_offset, sc_offset);
1670 bne(CCR0, L_failure);
1671 // bind(slow_path); // fallthru
1672 }
1674 void MacroAssembler::check_klass_subtype_slow_path(Register sub_klass,
1675 Register super_klass,
1676 Register temp1_reg,
1677 Register temp2_reg,
1678 Label* L_success,
1679 Register result_reg) {
1680 const Register array_ptr = temp1_reg; // current value from cache array
1681 const Register temp = temp2_reg;
1683 assert_different_registers(sub_klass, super_klass, array_ptr, temp);
1685 int source_offset = in_bytes(Klass::secondary_supers_offset());
1686 int target_offset = in_bytes(Klass::secondary_super_cache_offset());
1688 int length_offset = Array<Klass*>::length_offset_in_bytes();
1689 int base_offset = Array<Klass*>::base_offset_in_bytes();
1691 Label hit, loop, failure, fallthru;
1693 ld(array_ptr, source_offset, sub_klass);
1695 //assert(4 == arrayOopDesc::length_length_in_bytes(), "precondition violated.");
1696 lwz(temp, length_offset, array_ptr);
1697 cmpwi(CCR0, temp, 0);
1698 beq(CCR0, result_reg!=noreg ? failure : fallthru); // length 0
1700 mtctr(temp); // load ctr
1702 bind(loop);
1703 // Oops in table are NO MORE compressed.
1704 ld(temp, base_offset, array_ptr);
1705 cmpd(CCR0, temp, super_klass);
1706 beq(CCR0, hit);
1707 addi(array_ptr, array_ptr, BytesPerWord);
1708 bdnz(loop);
1710 bind(failure);
1711 if (result_reg!=noreg) li(result_reg, 1); // load non-zero result (indicates a miss)
1712 b(fallthru);
1714 bind(hit);
1715 std(super_klass, target_offset, sub_klass); // save result to cache
1716 if (result_reg != noreg) li(result_reg, 0); // load zero result (indicates a hit)
1717 if (L_success != NULL) b(*L_success);
1719 bind(fallthru);
1720 }
1722 // Try fast path, then go to slow one if not successful
1723 void MacroAssembler::check_klass_subtype(Register sub_klass,
1724 Register super_klass,
1725 Register temp1_reg,
1726 Register temp2_reg,
1727 Label& L_success) {
1728 Label L_failure;
1729 check_klass_subtype_fast_path(sub_klass, super_klass, temp1_reg, temp2_reg, L_success, L_failure);
1730 check_klass_subtype_slow_path(sub_klass, super_klass, temp1_reg, temp2_reg, &L_success);
1731 bind(L_failure); // Fallthru if not successful.
1732 }
1734 void MacroAssembler::check_method_handle_type(Register mtype_reg, Register mh_reg,
1735 Register temp_reg,
1736 Label& wrong_method_type) {
1737 assert_different_registers(mtype_reg, mh_reg, temp_reg);
1738 // Compare method type against that of the receiver.
1739 load_heap_oop_not_null(temp_reg, delayed_value(java_lang_invoke_MethodHandle::type_offset_in_bytes, temp_reg), mh_reg);
1740 cmpd(CCR0, temp_reg, mtype_reg);
1741 bne(CCR0, wrong_method_type);
1742 }
1744 RegisterOrConstant MacroAssembler::argument_offset(RegisterOrConstant arg_slot,
1745 Register temp_reg,
1746 int extra_slot_offset) {
1747 // cf. TemplateTable::prepare_invoke(), if (load_receiver).
1748 int stackElementSize = Interpreter::stackElementSize;
1749 int offset = extra_slot_offset * stackElementSize;
1750 if (arg_slot.is_constant()) {
1751 offset += arg_slot.as_constant() * stackElementSize;
1752 return offset;
1753 } else {
1754 assert(temp_reg != noreg, "must specify");
1755 sldi(temp_reg, arg_slot.as_register(), exact_log2(stackElementSize));
1756 if (offset != 0)
1757 addi(temp_reg, temp_reg, offset);
1758 return temp_reg;
1759 }
1760 }
1762 void MacroAssembler::biased_locking_enter(ConditionRegister cr_reg, Register obj_reg,
1763 Register mark_reg, Register temp_reg,
1764 Register temp2_reg, Label& done, Label* slow_case) {
1765 assert(UseBiasedLocking, "why call this otherwise?");
1767 #ifdef ASSERT
1768 assert_different_registers(obj_reg, mark_reg, temp_reg, temp2_reg);
1769 #endif
1771 Label cas_label;
1773 // Branch to done if fast path fails and no slow_case provided.
1774 Label *slow_case_int = (slow_case != NULL) ? slow_case : &done;
1776 // Biased locking
1777 // See whether the lock is currently biased toward our thread and
1778 // whether the epoch is still valid
1779 // Note that the runtime guarantees sufficient alignment of JavaThread
1780 // pointers to allow age to be placed into low bits
1781 assert(markOopDesc::age_shift == markOopDesc::lock_bits + markOopDesc::biased_lock_bits,
1782 "biased locking makes assumptions about bit layout");
1784 if (PrintBiasedLockingStatistics) {
1785 load_const(temp_reg, (address) BiasedLocking::total_entry_count_addr(), temp2_reg);
1786 lwz(temp2_reg, 0, temp_reg);
1787 addi(temp2_reg, temp2_reg, 1);
1788 stw(temp2_reg, 0, temp_reg);
1789 }
1791 andi(temp_reg, mark_reg, markOopDesc::biased_lock_mask_in_place);
1792 cmpwi(cr_reg, temp_reg, markOopDesc::biased_lock_pattern);
1793 bne(cr_reg, cas_label);
1795 load_klass(temp_reg, obj_reg);
1797 load_const_optimized(temp2_reg, ~((int) markOopDesc::age_mask_in_place));
1798 ld(temp_reg, in_bytes(Klass::prototype_header_offset()), temp_reg);
1799 orr(temp_reg, R16_thread, temp_reg);
1800 xorr(temp_reg, mark_reg, temp_reg);
1801 andr(temp_reg, temp_reg, temp2_reg);
1802 cmpdi(cr_reg, temp_reg, 0);
1803 if (PrintBiasedLockingStatistics) {
1804 Label l;
1805 bne(cr_reg, l);
1806 load_const(mark_reg, (address) BiasedLocking::biased_lock_entry_count_addr());
1807 lwz(temp2_reg, 0, mark_reg);
1808 addi(temp2_reg, temp2_reg, 1);
1809 stw(temp2_reg, 0, mark_reg);
1810 // restore mark_reg
1811 ld(mark_reg, oopDesc::mark_offset_in_bytes(), obj_reg);
1812 bind(l);
1813 }
1814 beq(cr_reg, done);
1816 Label try_revoke_bias;
1817 Label try_rebias;
1819 // At this point we know that the header has the bias pattern and
1820 // that we are not the bias owner in the current epoch. We need to
1821 // figure out more details about the state of the header in order to
1822 // know what operations can be legally performed on the object's
1823 // header.
1825 // If the low three bits in the xor result aren't clear, that means
1826 // the prototype header is no longer biased and we have to revoke
1827 // the bias on this object.
1828 andi(temp2_reg, temp_reg, markOopDesc::biased_lock_mask_in_place);
1829 cmpwi(cr_reg, temp2_reg, 0);
1830 bne(cr_reg, try_revoke_bias);
1832 // Biasing is still enabled for this data type. See whether the
1833 // epoch of the current bias is still valid, meaning that the epoch
1834 // bits of the mark word are equal to the epoch bits of the
1835 // prototype header. (Note that the prototype header's epoch bits
1836 // only change at a safepoint.) If not, attempt to rebias the object
1837 // toward the current thread. Note that we must be absolutely sure
1838 // that the current epoch is invalid in order to do this because
1839 // otherwise the manipulations it performs on the mark word are
1840 // illegal.
1842 int shift_amount = 64 - markOopDesc::epoch_shift;
1843 // rotate epoch bits to right (little) end and set other bits to 0
1844 // [ big part | epoch | little part ] -> [ 0..0 | epoch ]
1845 rldicl_(temp2_reg, temp_reg, shift_amount, 64 - markOopDesc::epoch_bits);
1846 // branch if epoch bits are != 0, i.e. they differ, because the epoch has been incremented
1847 bne(CCR0, try_rebias);
1849 // The epoch of the current bias is still valid but we know nothing
1850 // about the owner; it might be set or it might be clear. Try to
1851 // acquire the bias of the object using an atomic operation. If this
1852 // fails we will go in to the runtime to revoke the object's bias.
1853 // Note that we first construct the presumed unbiased header so we
1854 // don't accidentally blow away another thread's valid bias.
1855 andi(mark_reg, mark_reg, (markOopDesc::biased_lock_mask_in_place |
1856 markOopDesc::age_mask_in_place |
1857 markOopDesc::epoch_mask_in_place));
1858 orr(temp_reg, R16_thread, mark_reg);
1860 assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
1862 // CmpxchgX sets cr_reg to cmpX(temp2_reg, mark_reg).
1863 fence(); // TODO: replace by MacroAssembler::MemBarRel | MacroAssembler::MemBarAcq ?
1864 cmpxchgd(/*flag=*/cr_reg, /*current_value=*/temp2_reg,
1865 /*compare_value=*/mark_reg, /*exchange_value=*/temp_reg,
1866 /*where=*/obj_reg,
1867 MacroAssembler::MemBarAcq,
1868 MacroAssembler::cmpxchgx_hint_acquire_lock(),
1869 noreg, slow_case_int); // bail out if failed
1871 // If the biasing toward our thread failed, this means that
1872 // another thread succeeded in biasing it toward itself and we
1873 // need to revoke that bias. The revocation will occur in the
1874 // interpreter runtime in the slow case.
1875 if (PrintBiasedLockingStatistics) {
1876 load_const(temp_reg, (address) BiasedLocking::anonymously_biased_lock_entry_count_addr(), temp2_reg);
1877 lwz(temp2_reg, 0, temp_reg);
1878 addi(temp2_reg, temp2_reg, 1);
1879 stw(temp2_reg, 0, temp_reg);
1880 }
1881 b(done);
1883 bind(try_rebias);
1884 // At this point we know the epoch has expired, meaning that the
1885 // current "bias owner", if any, is actually invalid. Under these
1886 // circumstances _only_, we are allowed to use the current header's
1887 // value as the comparison value when doing the cas to acquire the
1888 // bias in the current epoch. In other words, we allow transfer of
1889 // the bias from one thread to another directly in this situation.
1890 andi(temp_reg, mark_reg, markOopDesc::age_mask_in_place);
1891 orr(temp_reg, R16_thread, temp_reg);
1892 load_klass(temp2_reg, obj_reg);
1893 ld(temp2_reg, in_bytes(Klass::prototype_header_offset()), temp2_reg);
1894 orr(temp_reg, temp_reg, temp2_reg);
1896 assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
1898 // CmpxchgX sets cr_reg to cmpX(temp2_reg, mark_reg).
1899 fence(); // TODO: replace by MacroAssembler::MemBarRel | MacroAssembler::MemBarAcq ?
1900 cmpxchgd(/*flag=*/cr_reg, /*current_value=*/temp2_reg,
1901 /*compare_value=*/mark_reg, /*exchange_value=*/temp_reg,
1902 /*where=*/obj_reg,
1903 MacroAssembler::MemBarAcq,
1904 MacroAssembler::cmpxchgx_hint_acquire_lock(),
1905 noreg, slow_case_int); // bail out if failed
1907 // If the biasing toward our thread failed, this means that
1908 // another thread succeeded in biasing it toward itself and we
1909 // need to revoke that bias. The revocation will occur in the
1910 // interpreter runtime in the slow case.
1911 if (PrintBiasedLockingStatistics) {
1912 load_const(temp_reg, (address) BiasedLocking::rebiased_lock_entry_count_addr(), temp2_reg);
1913 lwz(temp2_reg, 0, temp_reg);
1914 addi(temp2_reg, temp2_reg, 1);
1915 stw(temp2_reg, 0, temp_reg);
1916 }
1917 b(done);
1919 bind(try_revoke_bias);
1920 // The prototype mark in the klass doesn't have the bias bit set any
1921 // more, indicating that objects of this data type are not supposed
1922 // to be biased any more. We are going to try to reset the mark of
1923 // this object to the prototype value and fall through to the
1924 // CAS-based locking scheme. Note that if our CAS fails, it means
1925 // that another thread raced us for the privilege of revoking the
1926 // bias of this particular object, so it's okay to continue in the
1927 // normal locking code.
1928 load_klass(temp_reg, obj_reg);
1929 ld(temp_reg, in_bytes(Klass::prototype_header_offset()), temp_reg);
1930 andi(temp2_reg, mark_reg, markOopDesc::age_mask_in_place);
1931 orr(temp_reg, temp_reg, temp2_reg);
1933 assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
1935 // CmpxchgX sets cr_reg to cmpX(temp2_reg, mark_reg).
1936 fence(); // TODO: replace by MacroAssembler::MemBarRel | MacroAssembler::MemBarAcq ?
1937 cmpxchgd(/*flag=*/cr_reg, /*current_value=*/temp2_reg,
1938 /*compare_value=*/mark_reg, /*exchange_value=*/temp_reg,
1939 /*where=*/obj_reg,
1940 MacroAssembler::MemBarAcq,
1941 MacroAssembler::cmpxchgx_hint_acquire_lock());
1943 // reload markOop in mark_reg before continuing with lightweight locking
1944 ld(mark_reg, oopDesc::mark_offset_in_bytes(), obj_reg);
1946 // Fall through to the normal CAS-based lock, because no matter what
1947 // the result of the above CAS, some thread must have succeeded in
1948 // removing the bias bit from the object's header.
1949 if (PrintBiasedLockingStatistics) {
1950 Label l;
1951 bne(cr_reg, l);
1952 load_const(temp_reg, (address) BiasedLocking::revoked_lock_entry_count_addr(), temp2_reg);
1953 lwz(temp2_reg, 0, temp_reg);
1954 addi(temp2_reg, temp2_reg, 1);
1955 stw(temp2_reg, 0, temp_reg);
1956 bind(l);
1957 }
1959 bind(cas_label);
1960 }
1962 void MacroAssembler::biased_locking_exit (ConditionRegister cr_reg, Register mark_addr, Register temp_reg, Label& done) {
1963 // Check for biased locking unlock case, which is a no-op
1964 // Note: we do not have to check the thread ID for two reasons.
1965 // First, the interpreter checks for IllegalMonitorStateException at
1966 // a higher level. Second, if the bias was revoked while we held the
1967 // lock, the object could not be rebiased toward another thread, so
1968 // the bias bit would be clear.
1970 ld(temp_reg, 0, mark_addr);
1971 andi(temp_reg, temp_reg, markOopDesc::biased_lock_mask_in_place);
1973 cmpwi(cr_reg, temp_reg, markOopDesc::biased_lock_pattern);
1974 beq(cr_reg, done);
1975 }
1977 // "The box" is the space on the stack where we copy the object mark.
1978 void MacroAssembler::compiler_fast_lock_object(ConditionRegister flag, Register oop, Register box,
1979 Register temp, Register displaced_header, Register current_header) {
1980 assert_different_registers(oop, box, temp, displaced_header, current_header);
1981 assert(flag != CCR0, "bad condition register");
1982 Label cont;
1983 Label object_has_monitor;
1984 Label cas_failed;
1986 // Load markOop from object into displaced_header.
1987 ld(displaced_header, oopDesc::mark_offset_in_bytes(), oop);
1990 // Always do locking in runtime.
1991 if (EmitSync & 0x01) {
1992 cmpdi(flag, oop, 0); // Oop can't be 0 here => always false.
1993 return;
1994 }
1996 if (UseBiasedLocking) {
1997 biased_locking_enter(flag, oop, displaced_header, temp, current_header, cont);
1998 }
2000 // Handle existing monitor.
2001 if ((EmitSync & 0x02) == 0) {
2002 // The object has an existing monitor iff (mark & monitor_value) != 0.
2003 andi_(temp, displaced_header, markOopDesc::monitor_value);
2004 bne(CCR0, object_has_monitor);
2005 }
2007 // Set displaced_header to be (markOop of object | UNLOCK_VALUE).
2008 ori(displaced_header, displaced_header, markOopDesc::unlocked_value);
2010 // Load Compare Value application register.
2012 // Initialize the box. (Must happen before we update the object mark!)
2013 std(displaced_header, BasicLock::displaced_header_offset_in_bytes(), box);
2015 // Must fence, otherwise, preceding store(s) may float below cmpxchg.
2016 // Compare object markOop with mark and if equal exchange scratch1 with object markOop.
2017 // CmpxchgX sets cr_reg to cmpX(current, displaced).
2018 membar(Assembler::StoreStore);
2019 cmpxchgd(/*flag=*/flag,
2020 /*current_value=*/current_header,
2021 /*compare_value=*/displaced_header,
2022 /*exchange_value=*/box,
2023 /*where=*/oop,
2024 MacroAssembler::MemBarAcq,
2025 MacroAssembler::cmpxchgx_hint_acquire_lock(),
2026 noreg,
2027 &cas_failed);
2028 assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
2030 // If the compare-and-exchange succeeded, then we found an unlocked
2031 // object and we have now locked it.
2032 b(cont);
2034 bind(cas_failed);
2035 // We did not see an unlocked object so try the fast recursive case.
2037 // Check if the owner is self by comparing the value in the markOop of object
2038 // (current_header) with the stack pointer.
2039 sub(current_header, current_header, R1_SP);
2040 load_const_optimized(temp, (address) (~(os::vm_page_size()-1) |
2041 markOopDesc::lock_mask_in_place));
2043 and_(R0/*==0?*/, current_header, temp);
2044 // If condition is true we are cont and hence we can store 0 as the
2045 // displaced header in the box, which indicates that it is a recursive lock.
2046 mcrf(flag,CCR0);
2047 std(R0/*==0, perhaps*/, BasicLock::displaced_header_offset_in_bytes(), box);
2049 // Handle existing monitor.
2050 if ((EmitSync & 0x02) == 0) {
2051 b(cont);
2053 bind(object_has_monitor);
2054 // The object's monitor m is unlocked iff m->owner == NULL,
2055 // otherwise m->owner may contain a thread or a stack address.
2056 //
2057 // Try to CAS m->owner from NULL to current thread.
2058 addi(temp, displaced_header, ObjectMonitor::owner_offset_in_bytes()-markOopDesc::monitor_value);
2059 li(displaced_header, 0);
2060 // CmpxchgX sets flag to cmpX(current, displaced).
2061 cmpxchgd(/*flag=*/flag,
2062 /*current_value=*/current_header,
2063 /*compare_value=*/displaced_header,
2064 /*exchange_value=*/R16_thread,
2065 /*where=*/temp,
2066 MacroAssembler::MemBarRel | MacroAssembler::MemBarAcq,
2067 MacroAssembler::cmpxchgx_hint_acquire_lock());
2069 // Store a non-null value into the box.
2070 std(box, BasicLock::displaced_header_offset_in_bytes(), box);
2072 # ifdef ASSERT
2073 bne(flag, cont);
2074 // We have acquired the monitor, check some invariants.
2075 addi(/*monitor=*/temp, temp, -ObjectMonitor::owner_offset_in_bytes());
2076 // Invariant 1: _recursions should be 0.
2077 //assert(ObjectMonitor::recursions_size_in_bytes() == 8, "unexpected size");
2078 asm_assert_mem8_is_zero(ObjectMonitor::recursions_offset_in_bytes(), temp,
2079 "monitor->_recursions should be 0", -1);
2080 // Invariant 2: OwnerIsThread shouldn't be 0.
2081 //assert(ObjectMonitor::OwnerIsThread_size_in_bytes() == 4, "unexpected size");
2082 //asm_assert_mem4_isnot_zero(ObjectMonitor::OwnerIsThread_offset_in_bytes(), temp,
2083 // "monitor->OwnerIsThread shouldn't be 0", -1);
2084 # endif
2085 }
2087 bind(cont);
2088 // flag == EQ indicates success
2089 // flag == NE indicates failure
2090 }
2092 void MacroAssembler::compiler_fast_unlock_object(ConditionRegister flag, Register oop, Register box,
2093 Register temp, Register displaced_header, Register current_header) {
2094 assert_different_registers(oop, box, temp, displaced_header, current_header);
2095 assert(flag != CCR0, "bad condition register");
2096 Label cont;
2097 Label object_has_monitor;
2099 // Always do locking in runtime.
2100 if (EmitSync & 0x01) {
2101 cmpdi(flag, oop, 0); // Oop can't be 0 here => always false.
2102 return;
2103 }
2105 if (UseBiasedLocking) {
2106 biased_locking_exit(flag, oop, current_header, cont);
2107 }
2109 // Find the lock address and load the displaced header from the stack.
2110 ld(displaced_header, BasicLock::displaced_header_offset_in_bytes(), box);
2112 // If the displaced header is 0, we have a recursive unlock.
2113 cmpdi(flag, displaced_header, 0);
2114 beq(flag, cont);
2116 // Handle existing monitor.
2117 if ((EmitSync & 0x02) == 0) {
2118 // The object has an existing monitor iff (mark & monitor_value) != 0.
2119 ld(current_header, oopDesc::mark_offset_in_bytes(), oop);
2120 andi(temp, current_header, markOopDesc::monitor_value);
2121 cmpdi(flag, temp, 0);
2122 bne(flag, object_has_monitor);
2123 }
2126 // Check if it is still a light weight lock, this is is true if we see
2127 // the stack address of the basicLock in the markOop of the object.
2128 // Cmpxchg sets flag to cmpd(current_header, box).
2129 cmpxchgd(/*flag=*/flag,
2130 /*current_value=*/current_header,
2131 /*compare_value=*/box,
2132 /*exchange_value=*/displaced_header,
2133 /*where=*/oop,
2134 MacroAssembler::MemBarRel,
2135 MacroAssembler::cmpxchgx_hint_release_lock(),
2136 noreg,
2137 &cont);
2139 assert(oopDesc::mark_offset_in_bytes() == 0, "offset of _mark is not 0");
2141 // Handle existing monitor.
2142 if ((EmitSync & 0x02) == 0) {
2143 b(cont);
2145 bind(object_has_monitor);
2146 addi(current_header, current_header, -markOopDesc::monitor_value); // monitor
2147 ld(temp, ObjectMonitor::owner_offset_in_bytes(), current_header);
2148 ld(displaced_header, ObjectMonitor::recursions_offset_in_bytes(), current_header);
2149 xorr(temp, R16_thread, temp); // Will be 0 if we are the owner.
2150 orr(temp, temp, displaced_header); // Will be 0 if there are 0 recursions.
2151 cmpdi(flag, temp, 0);
2152 bne(flag, cont);
2154 ld(temp, ObjectMonitor::EntryList_offset_in_bytes(), current_header);
2155 ld(displaced_header, ObjectMonitor::cxq_offset_in_bytes(), current_header);
2156 orr(temp, temp, displaced_header); // Will be 0 if both are 0.
2157 cmpdi(flag, temp, 0);
2158 bne(flag, cont);
2159 release();
2160 std(temp, ObjectMonitor::owner_offset_in_bytes(), current_header);
2161 }
2163 bind(cont);
2164 // flag == EQ indicates success
2165 // flag == NE indicates failure
2166 }
2168 // Write serialization page so VM thread can do a pseudo remote membar.
2169 // We use the current thread pointer to calculate a thread specific
2170 // offset to write to within the page. This minimizes bus traffic
2171 // due to cache line collision.
2172 void MacroAssembler::serialize_memory(Register thread, Register tmp1, Register tmp2) {
2173 srdi(tmp2, thread, os::get_serialize_page_shift_count());
2175 int mask = os::vm_page_size() - sizeof(int);
2176 if (Assembler::is_simm(mask, 16)) {
2177 andi(tmp2, tmp2, mask);
2178 } else {
2179 lis(tmp1, (int)((signed short) (mask >> 16)));
2180 ori(tmp1, tmp1, mask & 0x0000ffff);
2181 andr(tmp2, tmp2, tmp1);
2182 }
2184 load_const(tmp1, (long) os::get_memory_serialize_page());
2185 release();
2186 stwx(R0, tmp1, tmp2);
2187 }
2190 // GC barrier helper macros
2192 // Write the card table byte if needed.
2193 void MacroAssembler::card_write_barrier_post(Register Rstore_addr, Register Rnew_val, Register Rtmp) {
2194 CardTableModRefBS* bs = (CardTableModRefBS*) Universe::heap()->barrier_set();
2195 assert(bs->kind() == BarrierSet::CardTableModRef ||
2196 bs->kind() == BarrierSet::CardTableExtension, "wrong barrier");
2197 #ifdef ASSERT
2198 cmpdi(CCR0, Rnew_val, 0);
2199 asm_assert_ne("null oop not allowed", 0x321);
2200 #endif
2201 card_table_write(bs->byte_map_base, Rtmp, Rstore_addr);
2202 }
2204 // Write the card table byte.
2205 void MacroAssembler::card_table_write(jbyte* byte_map_base, Register Rtmp, Register Robj) {
2206 assert_different_registers(Robj, Rtmp, R0);
2207 load_const_optimized(Rtmp, (address)byte_map_base, R0);
2208 srdi(Robj, Robj, CardTableModRefBS::card_shift);
2209 li(R0, 0); // dirty
2210 if (UseConcMarkSweepGC) membar(Assembler::StoreStore);
2211 stbx(R0, Rtmp, Robj);
2212 }
2214 #if INCLUDE_ALL_GCS
2215 // General G1 pre-barrier generator.
2216 // Goal: record the previous value if it is not null.
2217 void MacroAssembler::g1_write_barrier_pre(Register Robj, RegisterOrConstant offset, Register Rpre_val,
2218 Register Rtmp1, Register Rtmp2, bool needs_frame) {
2219 Label runtime, filtered;
2221 // Is marking active?
2222 if (in_bytes(PtrQueue::byte_width_of_active()) == 4) {
2223 lwz(Rtmp1, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_active()), R16_thread);
2224 } else {
2225 guarantee(in_bytes(PtrQueue::byte_width_of_active()) == 1, "Assumption");
2226 lbz(Rtmp1, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_active()), R16_thread);
2227 }
2228 cmpdi(CCR0, Rtmp1, 0);
2229 beq(CCR0, filtered);
2231 // Do we need to load the previous value?
2232 if (Robj != noreg) {
2233 // Load the previous value...
2234 if (UseCompressedOops) {
2235 lwz(Rpre_val, offset, Robj);
2236 } else {
2237 ld(Rpre_val, offset, Robj);
2238 }
2239 // Previous value has been loaded into Rpre_val.
2240 }
2241 assert(Rpre_val != noreg, "must have a real register");
2243 // Is the previous value null?
2244 cmpdi(CCR0, Rpre_val, 0);
2245 beq(CCR0, filtered);
2247 if (Robj != noreg && UseCompressedOops) {
2248 decode_heap_oop_not_null(Rpre_val);
2249 }
2251 // OK, it's not filtered, so we'll need to call enqueue. In the normal
2252 // case, pre_val will be a scratch G-reg, but there are some cases in
2253 // which it's an O-reg. In the first case, do a normal call. In the
2254 // latter, do a save here and call the frameless version.
2256 // Can we store original value in the thread's buffer?
2257 // Is index == 0?
2258 // (The index field is typed as size_t.)
2259 const Register Rbuffer = Rtmp1, Rindex = Rtmp2;
2261 ld(Rindex, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_index()), R16_thread);
2262 cmpdi(CCR0, Rindex, 0);
2263 beq(CCR0, runtime); // If index == 0, goto runtime.
2264 ld(Rbuffer, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_buf()), R16_thread);
2266 addi(Rindex, Rindex, -wordSize); // Decrement index.
2267 std(Rindex, in_bytes(JavaThread::satb_mark_queue_offset() + PtrQueue::byte_offset_of_index()), R16_thread);
2269 // Record the previous value.
2270 stdx(Rpre_val, Rbuffer, Rindex);
2271 b(filtered);
2273 bind(runtime);
2275 // VM call need frame to access(write) O register.
2276 if (needs_frame) {
2277 save_LR_CR(Rtmp1);
2278 push_frame_reg_args(0, Rtmp2);
2279 }
2281 if (Rpre_val->is_volatile() && Robj == noreg) mr(R31, Rpre_val); // Save pre_val across C call if it was preloaded.
2282 call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_pre), Rpre_val, R16_thread);
2283 if (Rpre_val->is_volatile() && Robj == noreg) mr(Rpre_val, R31); // restore
2285 if (needs_frame) {
2286 pop_frame();
2287 restore_LR_CR(Rtmp1);
2288 }
2290 bind(filtered);
2291 }
2293 // General G1 post-barrier generator
2294 // Store cross-region card.
2295 void MacroAssembler::g1_write_barrier_post(Register Rstore_addr, Register Rnew_val, Register Rtmp1, Register Rtmp2, Register Rtmp3, Label *filtered_ext) {
2296 Label runtime, filtered_int;
2297 Label& filtered = (filtered_ext != NULL) ? *filtered_ext : filtered_int;
2298 assert_different_registers(Rstore_addr, Rnew_val, Rtmp1, Rtmp2);
2300 G1SATBCardTableModRefBS* bs = (G1SATBCardTableModRefBS*) Universe::heap()->barrier_set();
2301 assert(bs->kind() == BarrierSet::G1SATBCT ||
2302 bs->kind() == BarrierSet::G1SATBCTLogging, "wrong barrier");
2304 // Does store cross heap regions?
2305 if (G1RSBarrierRegionFilter) {
2306 xorr(Rtmp1, Rstore_addr, Rnew_val);
2307 srdi_(Rtmp1, Rtmp1, HeapRegion::LogOfHRGrainBytes);
2308 beq(CCR0, filtered);
2309 }
2311 // Crosses regions, storing NULL?
2312 #ifdef ASSERT
2313 cmpdi(CCR0, Rnew_val, 0);
2314 asm_assert_ne("null oop not allowed (G1)", 0x322); // Checked by caller on PPC64, so following branch is obsolete:
2315 //beq(CCR0, filtered);
2316 #endif
2318 // Storing region crossing non-NULL, is card already dirty?
2319 assert(sizeof(*bs->byte_map_base) == sizeof(jbyte), "adjust this code");
2320 const Register Rcard_addr = Rtmp1;
2321 Register Rbase = Rtmp2;
2322 load_const_optimized(Rbase, (address)bs->byte_map_base, /*temp*/ Rtmp3);
2324 srdi(Rcard_addr, Rstore_addr, CardTableModRefBS::card_shift);
2326 // Get the address of the card.
2327 lbzx(/*card value*/ Rtmp3, Rbase, Rcard_addr);
2328 cmpwi(CCR0, Rtmp3, (int)G1SATBCardTableModRefBS::g1_young_card_val());
2329 beq(CCR0, filtered);
2331 membar(Assembler::StoreLoad);
2332 lbzx(/*card value*/ Rtmp3, Rbase, Rcard_addr); // Reload after membar.
2333 cmpwi(CCR0, Rtmp3 /* card value */, CardTableModRefBS::dirty_card_val());
2334 beq(CCR0, filtered);
2336 // Storing a region crossing, non-NULL oop, card is clean.
2337 // Dirty card and log.
2338 li(Rtmp3, CardTableModRefBS::dirty_card_val());
2339 //release(); // G1: oops are allowed to get visible after dirty marking.
2340 stbx(Rtmp3, Rbase, Rcard_addr);
2342 add(Rcard_addr, Rbase, Rcard_addr); // This is the address which needs to get enqueued.
2343 Rbase = noreg; // end of lifetime
2345 const Register Rqueue_index = Rtmp2,
2346 Rqueue_buf = Rtmp3;
2347 ld(Rqueue_index, in_bytes(JavaThread::dirty_card_queue_offset() + PtrQueue::byte_offset_of_index()), R16_thread);
2348 cmpdi(CCR0, Rqueue_index, 0);
2349 beq(CCR0, runtime); // index == 0 then jump to runtime
2350 ld(Rqueue_buf, in_bytes(JavaThread::dirty_card_queue_offset() + PtrQueue::byte_offset_of_buf()), R16_thread);
2352 addi(Rqueue_index, Rqueue_index, -wordSize); // decrement index
2353 std(Rqueue_index, in_bytes(JavaThread::dirty_card_queue_offset() + PtrQueue::byte_offset_of_index()), R16_thread);
2355 stdx(Rcard_addr, Rqueue_buf, Rqueue_index); // store card
2356 b(filtered);
2358 bind(runtime);
2360 // Save the live input values.
2361 call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::g1_wb_post), Rcard_addr, R16_thread);
2363 bind(filtered_int);
2364 }
2365 #endif // INCLUDE_ALL_GCS
2367 // Values for last_Java_pc, and last_Java_sp must comply to the rules
2368 // in frame_ppc64.hpp.
2369 void MacroAssembler::set_last_Java_frame(Register last_Java_sp, Register last_Java_pc) {
2370 // Always set last_Java_pc and flags first because once last_Java_sp
2371 // is visible has_last_Java_frame is true and users will look at the
2372 // rest of the fields. (Note: flags should always be zero before we
2373 // get here so doesn't need to be set.)
2375 // Verify that last_Java_pc was zeroed on return to Java
2376 asm_assert_mem8_is_zero(in_bytes(JavaThread::last_Java_pc_offset()), R16_thread,
2377 "last_Java_pc not zeroed before leaving Java", 0x200);
2379 // When returning from calling out from Java mode the frame anchor's
2380 // last_Java_pc will always be set to NULL. It is set here so that
2381 // if we are doing a call to native (not VM) that we capture the
2382 // known pc and don't have to rely on the native call having a
2383 // standard frame linkage where we can find the pc.
2384 if (last_Java_pc != noreg)
2385 std(last_Java_pc, in_bytes(JavaThread::last_Java_pc_offset()), R16_thread);
2387 // Set last_Java_sp last.
2388 std(last_Java_sp, in_bytes(JavaThread::last_Java_sp_offset()), R16_thread);
2389 }
2391 void MacroAssembler::reset_last_Java_frame(void) {
2392 asm_assert_mem8_isnot_zero(in_bytes(JavaThread::last_Java_sp_offset()),
2393 R16_thread, "SP was not set, still zero", 0x202);
2395 BLOCK_COMMENT("reset_last_Java_frame {");
2396 li(R0, 0);
2398 // _last_Java_sp = 0
2399 std(R0, in_bytes(JavaThread::last_Java_sp_offset()), R16_thread);
2401 // _last_Java_pc = 0
2402 std(R0, in_bytes(JavaThread::last_Java_pc_offset()), R16_thread);
2403 BLOCK_COMMENT("} reset_last_Java_frame");
2404 }
2406 void MacroAssembler::set_top_ijava_frame_at_SP_as_last_Java_frame(Register sp, Register tmp1) {
2407 assert_different_registers(sp, tmp1);
2409 // sp points to a TOP_IJAVA_FRAME, retrieve frame's PC via
2410 // TOP_IJAVA_FRAME_ABI.
2411 // FIXME: assert that we really have a TOP_IJAVA_FRAME here!
2412 #ifdef CC_INTERP
2413 ld(tmp1/*pc*/, _top_ijava_frame_abi(frame_manager_lr), sp);
2414 #else
2415 address entry = pc();
2416 load_const_optimized(tmp1, entry);
2417 #endif
2419 set_last_Java_frame(/*sp=*/sp, /*pc=*/tmp1);
2420 }
2422 void MacroAssembler::get_vm_result(Register oop_result) {
2423 // Read:
2424 // R16_thread
2425 // R16_thread->in_bytes(JavaThread::vm_result_offset())
2426 //
2427 // Updated:
2428 // oop_result
2429 // R16_thread->in_bytes(JavaThread::vm_result_offset())
2431 ld(oop_result, in_bytes(JavaThread::vm_result_offset()), R16_thread);
2432 li(R0, 0);
2433 std(R0, in_bytes(JavaThread::vm_result_offset()), R16_thread);
2435 verify_oop(oop_result);
2436 }
2438 void MacroAssembler::get_vm_result_2(Register metadata_result) {
2439 // Read:
2440 // R16_thread
2441 // R16_thread->in_bytes(JavaThread::vm_result_2_offset())
2442 //
2443 // Updated:
2444 // metadata_result
2445 // R16_thread->in_bytes(JavaThread::vm_result_2_offset())
2447 ld(metadata_result, in_bytes(JavaThread::vm_result_2_offset()), R16_thread);
2448 li(R0, 0);
2449 std(R0, in_bytes(JavaThread::vm_result_2_offset()), R16_thread);
2450 }
2453 void MacroAssembler::encode_klass_not_null(Register dst, Register src) {
2454 Register current = (src != noreg) ? src : dst; // Klass is in dst if no src provided.
2455 if (Universe::narrow_klass_base() != 0) {
2456 // Use dst as temp if it is free.
2457 load_const(R0, Universe::narrow_klass_base(), (dst != current && dst != R0) ? dst : noreg);
2458 sub(dst, current, R0);
2459 current = dst;
2460 }
2461 if (Universe::narrow_klass_shift() != 0) {
2462 srdi(dst, current, Universe::narrow_klass_shift());
2463 current = dst;
2464 }
2465 mr_if_needed(dst, current); // Move may be required.
2466 }
2468 void MacroAssembler::store_klass(Register dst_oop, Register klass, Register ck) {
2469 if (UseCompressedClassPointers) {
2470 encode_klass_not_null(ck, klass);
2471 stw(ck, oopDesc::klass_offset_in_bytes(), dst_oop);
2472 } else {
2473 std(klass, oopDesc::klass_offset_in_bytes(), dst_oop);
2474 }
2475 }
2477 void MacroAssembler::store_klass_gap(Register dst_oop, Register val) {
2478 if (UseCompressedClassPointers) {
2479 if (val == noreg) {
2480 val = R0;
2481 li(val, 0);
2482 }
2483 stw(val, oopDesc::klass_gap_offset_in_bytes(), dst_oop); // klass gap if compressed
2484 }
2485 }
2487 int MacroAssembler::instr_size_for_decode_klass_not_null() {
2488 if (!UseCompressedClassPointers) return 0;
2489 int num_instrs = 1; // shift or move
2490 if (Universe::narrow_klass_base() != 0) num_instrs = 7; // shift + load const + add
2491 return num_instrs * BytesPerInstWord;
2492 }
2494 void MacroAssembler::decode_klass_not_null(Register dst, Register src) {
2495 if (src == noreg) src = dst;
2496 Register shifted_src = src;
2497 if (Universe::narrow_klass_shift() != 0 ||
2498 Universe::narrow_klass_base() == 0 && src != dst) { // Move required.
2499 shifted_src = dst;
2500 sldi(shifted_src, src, Universe::narrow_klass_shift());
2501 }
2502 if (Universe::narrow_klass_base() != 0) {
2503 load_const(R0, Universe::narrow_klass_base());
2504 add(dst, shifted_src, R0);
2505 }
2506 }
2508 void MacroAssembler::load_klass(Register dst, Register src) {
2509 if (UseCompressedClassPointers) {
2510 lwz(dst, oopDesc::klass_offset_in_bytes(), src);
2511 // Attention: no null check here!
2512 decode_klass_not_null(dst, dst);
2513 } else {
2514 ld(dst, oopDesc::klass_offset_in_bytes(), src);
2515 }
2516 }
2518 void MacroAssembler::load_klass_with_trap_null_check(Register dst, Register src) {
2519 if (!os::zero_page_read_protected()) {
2520 if (TrapBasedNullChecks) {
2521 trap_null_check(src);
2522 }
2523 }
2524 load_klass(dst, src);
2525 }
2527 void MacroAssembler::reinit_heapbase(Register d, Register tmp) {
2528 if (Universe::heap() != NULL) {
2529 if (Universe::narrow_oop_base() == NULL) {
2530 Assembler::xorr(R30, R30, R30);
2531 } else {
2532 load_const(R30, Universe::narrow_ptrs_base(), tmp);
2533 }
2534 } else {
2535 load_const(R30, Universe::narrow_ptrs_base_addr(), tmp);
2536 ld(R30, 0, R30);
2537 }
2538 }
2540 // Clear Array
2541 // Kills both input registers. tmp == R0 is allowed.
2542 void MacroAssembler::clear_memory_doubleword(Register base_ptr, Register cnt_dwords, Register tmp) {
2543 // Procedure for large arrays (uses data cache block zero instruction).
2544 Label startloop, fast, fastloop, small_rest, restloop, done;
2545 const int cl_size = VM_Version::get_cache_line_size(),
2546 cl_dwords = cl_size>>3,
2547 cl_dw_addr_bits = exact_log2(cl_dwords),
2548 dcbz_min = 1; // Min count of dcbz executions, needs to be >0.
2550 //2:
2551 cmpdi(CCR1, cnt_dwords, ((dcbz_min+1)<<cl_dw_addr_bits)-1); // Big enough? (ensure >=dcbz_min lines included).
2552 blt(CCR1, small_rest); // Too small.
2553 rldicl_(tmp, base_ptr, 64-3, 64-cl_dw_addr_bits); // Extract dword offset within first cache line.
2554 beq(CCR0, fast); // Already 128byte aligned.
2556 subfic(tmp, tmp, cl_dwords);
2557 mtctr(tmp); // Set ctr to hit 128byte boundary (0<ctr<cl_dwords).
2558 subf(cnt_dwords, tmp, cnt_dwords); // rest.
2559 li(tmp, 0);
2560 //10:
2561 bind(startloop); // Clear at the beginning to reach 128byte boundary.
2562 std(tmp, 0, base_ptr); // Clear 8byte aligned block.
2563 addi(base_ptr, base_ptr, 8);
2564 bdnz(startloop);
2565 //13:
2566 bind(fast); // Clear 128byte blocks.
2567 srdi(tmp, cnt_dwords, cl_dw_addr_bits); // Loop count for 128byte loop (>0).
2568 andi(cnt_dwords, cnt_dwords, cl_dwords-1); // Rest in dwords.
2569 mtctr(tmp); // Load counter.
2570 //16:
2571 bind(fastloop);
2572 dcbz(base_ptr); // Clear 128byte aligned block.
2573 addi(base_ptr, base_ptr, cl_size);
2574 bdnz(fastloop);
2575 if (InsertEndGroupPPC64) { endgroup(); } else { nop(); }
2576 //20:
2577 bind(small_rest);
2578 cmpdi(CCR0, cnt_dwords, 0); // size 0?
2579 beq(CCR0, done); // rest == 0
2580 li(tmp, 0);
2581 mtctr(cnt_dwords); // Load counter.
2582 //24:
2583 bind(restloop); // Clear rest.
2584 std(tmp, 0, base_ptr); // Clear 8byte aligned block.
2585 addi(base_ptr, base_ptr, 8);
2586 bdnz(restloop);
2587 //27:
2588 bind(done);
2589 }
2591 /////////////////////////////////////////// String intrinsics ////////////////////////////////////////////
2593 // Search for a single jchar in an jchar[].
2594 //
2595 // Assumes that result differs from all other registers.
2596 //
2597 // Haystack, needle are the addresses of jchar-arrays.
2598 // NeedleChar is needle[0] if it is known at compile time.
2599 // Haycnt is the length of the haystack. We assume haycnt >=1.
2600 //
2601 // Preserves haystack, haycnt, kills all other registers.
2602 //
2603 // If needle == R0, we search for the constant needleChar.
2604 void MacroAssembler::string_indexof_1(Register result, Register haystack, Register haycnt,
2605 Register needle, jchar needleChar,
2606 Register tmp1, Register tmp2) {
2608 assert_different_registers(result, haystack, haycnt, needle, tmp1, tmp2);
2610 Label L_InnerLoop, L_FinalCheck, L_Found1, L_Found2, L_Found3, L_NotFound, L_End;
2611 Register needle0 = needle, // Contains needle[0].
2612 addr = tmp1,
2613 ch1 = tmp2,
2614 ch2 = R0;
2616 //2 (variable) or 3 (const):
2617 if (needle != R0) lhz(needle0, 0, needle); // Preload needle character, needle has len==1.
2618 dcbtct(haystack, 0x00); // Indicate R/O access to haystack.
2620 srwi_(tmp2, haycnt, 1); // Shift right by exact_log2(UNROLL_FACTOR).
2621 mr(addr, haystack);
2622 beq(CCR0, L_FinalCheck);
2623 mtctr(tmp2); // Move to count register.
2624 //8:
2625 bind(L_InnerLoop); // Main work horse (2x unrolled search loop).
2626 lhz(ch1, 0, addr); // Load characters from haystack.
2627 lhz(ch2, 2, addr);
2628 (needle != R0) ? cmpw(CCR0, ch1, needle0) : cmplwi(CCR0, ch1, needleChar);
2629 (needle != R0) ? cmpw(CCR1, ch2, needle0) : cmplwi(CCR1, ch2, needleChar);
2630 beq(CCR0, L_Found1); // Did we find the needle?
2631 beq(CCR1, L_Found2);
2632 addi(addr, addr, 4);
2633 bdnz(L_InnerLoop);
2634 //16:
2635 bind(L_FinalCheck);
2636 andi_(R0, haycnt, 1);
2637 beq(CCR0, L_NotFound);
2638 lhz(ch1, 0, addr); // One position left at which we have to compare.
2639 (needle != R0) ? cmpw(CCR1, ch1, needle0) : cmplwi(CCR1, ch1, needleChar);
2640 beq(CCR1, L_Found3);
2641 //21:
2642 bind(L_NotFound);
2643 li(result, -1); // Not found.
2644 b(L_End);
2646 bind(L_Found2);
2647 addi(addr, addr, 2);
2648 //24:
2649 bind(L_Found1);
2650 bind(L_Found3); // Return index ...
2651 subf(addr, haystack, addr); // relative to haystack,
2652 srdi(result, addr, 1); // in characters.
2653 bind(L_End);
2654 }
2657 // Implementation of IndexOf for jchar arrays.
2658 //
2659 // The length of haystack and needle are not constant, i.e. passed in a register.
2660 //
2661 // Preserves registers haystack, needle.
2662 // Kills registers haycnt, needlecnt.
2663 // Assumes that result differs from all other registers.
2664 // Haystack, needle are the addresses of jchar-arrays.
2665 // Haycnt, needlecnt are the lengths of them, respectively.
2666 //
2667 // Needlecntval must be zero or 15-bit unsigned immediate and > 1.
2668 void MacroAssembler::string_indexof(Register result, Register haystack, Register haycnt,
2669 Register needle, ciTypeArray* needle_values, Register needlecnt, int needlecntval,
2670 Register tmp1, Register tmp2, Register tmp3, Register tmp4) {
2672 // Ensure 0<needlecnt<=haycnt in ideal graph as prerequisite!
2673 Label L_TooShort, L_Found, L_NotFound, L_End;
2674 Register last_addr = haycnt, // Kill haycnt at the beginning.
2675 addr = tmp1,
2676 n_start = tmp2,
2677 ch1 = tmp3,
2678 ch2 = R0;
2680 // **************************************************************************************************
2681 // Prepare for main loop: optimized for needle count >=2, bail out otherwise.
2682 // **************************************************************************************************
2684 //1 (variable) or 3 (const):
2685 dcbtct(needle, 0x00); // Indicate R/O access to str1.
2686 dcbtct(haystack, 0x00); // Indicate R/O access to str2.
2688 // Compute last haystack addr to use if no match gets found.
2689 if (needlecntval == 0) { // variable needlecnt
2690 //3:
2691 subf(ch1, needlecnt, haycnt); // Last character index to compare is haycnt-needlecnt.
2692 addi(addr, haystack, -2); // Accesses use pre-increment.
2693 cmpwi(CCR6, needlecnt, 2);
2694 blt(CCR6, L_TooShort); // Variable needlecnt: handle short needle separately.
2695 slwi(ch1, ch1, 1); // Scale to number of bytes.
2696 lwz(n_start, 0, needle); // Load first 2 characters of needle.
2697 add(last_addr, haystack, ch1); // Point to last address to compare (haystack+2*(haycnt-needlecnt)).
2698 addi(needlecnt, needlecnt, -2); // Rest of needle.
2699 } else { // constant needlecnt
2700 guarantee(needlecntval != 1, "IndexOf with single-character needle must be handled separately");
2701 assert((needlecntval & 0x7fff) == needlecntval, "wrong immediate");
2702 //5:
2703 addi(ch1, haycnt, -needlecntval); // Last character index to compare is haycnt-needlecnt.
2704 lwz(n_start, 0, needle); // Load first 2 characters of needle.
2705 addi(addr, haystack, -2); // Accesses use pre-increment.
2706 slwi(ch1, ch1, 1); // Scale to number of bytes.
2707 add(last_addr, haystack, ch1); // Point to last address to compare (haystack+2*(haycnt-needlecnt)).
2708 li(needlecnt, needlecntval-2); // Rest of needle.
2709 }
2711 // Main Loop (now we have at least 3 characters).
2712 //11:
2713 Label L_OuterLoop, L_InnerLoop, L_FinalCheck, L_Comp1, L_Comp2, L_Comp3;
2714 bind(L_OuterLoop); // Search for 1st 2 characters.
2715 Register addr_diff = tmp4;
2716 subf(addr_diff, addr, last_addr); // Difference between already checked address and last address to check.
2717 addi(addr, addr, 2); // This is the new address we want to use for comparing.
2718 srdi_(ch2, addr_diff, 2);
2719 beq(CCR0, L_FinalCheck); // 2 characters left?
2720 mtctr(ch2); // addr_diff/4
2721 //16:
2722 bind(L_InnerLoop); // Main work horse (2x unrolled search loop)
2723 lwz(ch1, 0, addr); // Load 2 characters of haystack (ignore alignment).
2724 lwz(ch2, 2, addr);
2725 cmpw(CCR0, ch1, n_start); // Compare 2 characters (1 would be sufficient but try to reduce branches to CompLoop).
2726 cmpw(CCR1, ch2, n_start);
2727 beq(CCR0, L_Comp1); // Did we find the needle start?
2728 beq(CCR1, L_Comp2);
2729 addi(addr, addr, 4);
2730 bdnz(L_InnerLoop);
2731 //24:
2732 bind(L_FinalCheck);
2733 rldicl_(addr_diff, addr_diff, 64-1, 63); // Remaining characters not covered by InnerLoop: (addr_diff>>1)&1.
2734 beq(CCR0, L_NotFound);
2735 lwz(ch1, 0, addr); // One position left at which we have to compare.
2736 cmpw(CCR1, ch1, n_start);
2737 beq(CCR1, L_Comp3);
2738 //29:
2739 bind(L_NotFound);
2740 li(result, -1); // not found
2741 b(L_End);
2744 // **************************************************************************************************
2745 // Special Case: unfortunately, the variable needle case can be called with needlecnt<2
2746 // **************************************************************************************************
2747 //31:
2748 if ((needlecntval>>1) !=1 ) { // Const needlecnt is 2 or 3? Reduce code size.
2749 int nopcnt = 5;
2750 if (needlecntval !=0 ) ++nopcnt; // Balance alignment (other case: see below).
2751 if (needlecntval == 0) { // We have to handle these cases separately.
2752 Label L_OneCharLoop;
2753 bind(L_TooShort);
2754 mtctr(haycnt);
2755 lhz(n_start, 0, needle); // First character of needle
2756 bind(L_OneCharLoop);
2757 lhzu(ch1, 2, addr);
2758 cmpw(CCR1, ch1, n_start);
2759 beq(CCR1, L_Found); // Did we find the one character needle?
2760 bdnz(L_OneCharLoop);
2761 li(result, -1); // Not found.
2762 b(L_End);
2763 } // 8 instructions, so no impact on alignment.
2764 for (int x = 0; x < nopcnt; ++x) nop();
2765 }
2767 // **************************************************************************************************
2768 // Regular Case Part II: compare rest of needle (first 2 characters have been compared already)
2769 // **************************************************************************************************
2771 // Compare the rest
2772 //36 if needlecntval==0, else 37:
2773 bind(L_Comp2);
2774 addi(addr, addr, 2); // First comparison has failed, 2nd one hit.
2775 bind(L_Comp1); // Addr points to possible needle start.
2776 bind(L_Comp3); // Could have created a copy and use a different return address but saving code size here.
2777 if (needlecntval != 2) { // Const needlecnt==2?
2778 if (needlecntval != 3) {
2779 if (needlecntval == 0) beq(CCR6, L_Found); // Variable needlecnt==2?
2780 Register ind_reg = tmp4;
2781 li(ind_reg, 2*2); // First 2 characters are already compared, use index 2.
2782 mtctr(needlecnt); // Decremented by 2, still > 0.
2783 //40:
2784 Label L_CompLoop;
2785 bind(L_CompLoop);
2786 lhzx(ch2, needle, ind_reg);
2787 lhzx(ch1, addr, ind_reg);
2788 cmpw(CCR1, ch1, ch2);
2789 bne(CCR1, L_OuterLoop);
2790 addi(ind_reg, ind_reg, 2);
2791 bdnz(L_CompLoop);
2792 } else { // No loop required if there's only one needle character left.
2793 lhz(ch2, 2*2, needle);
2794 lhz(ch1, 2*2, addr);
2795 cmpw(CCR1, ch1, ch2);
2796 bne(CCR1, L_OuterLoop);
2797 }
2798 }
2799 // Return index ...
2800 //46:
2801 bind(L_Found);
2802 subf(addr, haystack, addr); // relative to haystack, ...
2803 srdi(result, addr, 1); // in characters.
2804 //48:
2805 bind(L_End);
2806 }
2808 // Implementation of Compare for jchar arrays.
2809 //
2810 // Kills the registers str1, str2, cnt1, cnt2.
2811 // Kills cr0, ctr.
2812 // Assumes that result differes from the input registers.
2813 void MacroAssembler::string_compare(Register str1_reg, Register str2_reg, Register cnt1_reg, Register cnt2_reg,
2814 Register result_reg, Register tmp_reg) {
2815 assert_different_registers(result_reg, str1_reg, str2_reg, cnt1_reg, cnt2_reg, tmp_reg);
2817 Label Ldone, Lslow_case, Lslow_loop, Lfast_loop;
2818 Register cnt_diff = R0,
2819 limit_reg = cnt1_reg,
2820 chr1_reg = result_reg,
2821 chr2_reg = cnt2_reg,
2822 addr_diff = str2_reg;
2824 // Offset 0 should be 32 byte aligned.
2825 //-4:
2826 dcbtct(str1_reg, 0x00); // Indicate R/O access to str1.
2827 dcbtct(str2_reg, 0x00); // Indicate R/O access to str2.
2828 //-2:
2829 // Compute min(cnt1, cnt2) and check if 0 (bail out if we don't need to compare characters).
2830 subf(result_reg, cnt2_reg, cnt1_reg); // difference between cnt1/2
2831 subf_(addr_diff, str1_reg, str2_reg); // alias?
2832 beq(CCR0, Ldone); // return cnt difference if both ones are identical
2833 srawi(limit_reg, result_reg, 31); // generate signmask (cnt1/2 must be non-negative so cnt_diff can't overflow)
2834 mr(cnt_diff, result_reg);
2835 andr(limit_reg, result_reg, limit_reg); // difference or zero (negative): cnt1<cnt2 ? cnt1-cnt2 : 0
2836 add_(limit_reg, cnt2_reg, limit_reg); // min(cnt1, cnt2)==0?
2837 beq(CCR0, Ldone); // return cnt difference if one has 0 length
2839 lhz(chr1_reg, 0, str1_reg); // optional: early out if first characters mismatch
2840 lhzx(chr2_reg, str1_reg, addr_diff); // optional: early out if first characters mismatch
2841 addi(tmp_reg, limit_reg, -1); // min(cnt1, cnt2)-1
2842 subf_(result_reg, chr2_reg, chr1_reg); // optional: early out if first characters mismatch
2843 bne(CCR0, Ldone); // optional: early out if first characters mismatch
2845 // Set loop counter by scaling down tmp_reg
2846 srawi_(chr2_reg, tmp_reg, exact_log2(4)); // (min(cnt1, cnt2)-1)/4
2847 ble(CCR0, Lslow_case); // need >4 characters for fast loop
2848 andi(limit_reg, tmp_reg, 4-1); // remaining characters
2850 // Adapt str1_reg str2_reg for the first loop iteration
2851 mtctr(chr2_reg); // (min(cnt1, cnt2)-1)/4
2852 addi(limit_reg, limit_reg, 4+1); // compare last 5-8 characters in slow_case if mismatch found in fast_loop
2853 //16:
2854 // Compare the rest of the characters
2855 bind(Lfast_loop);
2856 ld(chr1_reg, 0, str1_reg);
2857 ldx(chr2_reg, str1_reg, addr_diff);
2858 cmpd(CCR0, chr2_reg, chr1_reg);
2859 bne(CCR0, Lslow_case); // return chr1_reg
2860 addi(str1_reg, str1_reg, 4*2);
2861 bdnz(Lfast_loop);
2862 addi(limit_reg, limit_reg, -4); // no mismatch found in fast_loop, only 1-4 characters missing
2863 //23:
2864 bind(Lslow_case);
2865 mtctr(limit_reg);
2866 //24:
2867 bind(Lslow_loop);
2868 lhz(chr1_reg, 0, str1_reg);
2869 lhzx(chr2_reg, str1_reg, addr_diff);
2870 subf_(result_reg, chr2_reg, chr1_reg);
2871 bne(CCR0, Ldone); // return chr1_reg
2872 addi(str1_reg, str1_reg, 1*2);
2873 bdnz(Lslow_loop);
2874 //30:
2875 // If strings are equal up to min length, return the length difference.
2876 mr(result_reg, cnt_diff);
2877 nop(); // alignment
2878 //32:
2879 // Otherwise, return the difference between the first mismatched chars.
2880 bind(Ldone);
2881 }
2884 // Compare char[] arrays.
2885 //
2886 // str1_reg USE only
2887 // str2_reg USE only
2888 // cnt_reg USE_DEF, due to tmp reg shortage
2889 // result_reg DEF only, might compromise USE only registers
2890 void MacroAssembler::char_arrays_equals(Register str1_reg, Register str2_reg, Register cnt_reg, Register result_reg,
2891 Register tmp1_reg, Register tmp2_reg, Register tmp3_reg, Register tmp4_reg,
2892 Register tmp5_reg) {
2894 // Str1 may be the same register as str2 which can occur e.g. after scalar replacement.
2895 assert_different_registers(result_reg, str1_reg, cnt_reg, tmp1_reg, tmp2_reg, tmp3_reg, tmp4_reg, tmp5_reg);
2896 assert_different_registers(result_reg, str2_reg, cnt_reg, tmp1_reg, tmp2_reg, tmp3_reg, tmp4_reg, tmp5_reg);
2898 // Offset 0 should be 32 byte aligned.
2899 Label Linit_cbc, Lcbc, Lloop, Ldone_true, Ldone_false;
2900 Register index_reg = tmp5_reg;
2901 Register cbc_iter = tmp4_reg;
2903 //-1:
2904 dcbtct(str1_reg, 0x00); // Indicate R/O access to str1.
2905 dcbtct(str2_reg, 0x00); // Indicate R/O access to str2.
2906 //1:
2907 andi(cbc_iter, cnt_reg, 4-1); // Remaining iterations after 4 java characters per iteration loop.
2908 li(index_reg, 0); // init
2909 li(result_reg, 0); // assume false
2910 srwi_(tmp2_reg, cnt_reg, exact_log2(4)); // Div: 4 java characters per iteration (main loop).
2912 cmpwi(CCR1, cbc_iter, 0); // CCR1 = (cbc_iter==0)
2913 beq(CCR0, Linit_cbc); // too short
2914 mtctr(tmp2_reg);
2915 //8:
2916 bind(Lloop);
2917 ldx(tmp1_reg, str1_reg, index_reg);
2918 ldx(tmp2_reg, str2_reg, index_reg);
2919 cmpd(CCR0, tmp1_reg, tmp2_reg);
2920 bne(CCR0, Ldone_false); // Unequal char pair found -> done.
2921 addi(index_reg, index_reg, 4*sizeof(jchar));
2922 bdnz(Lloop);
2923 //14:
2924 bind(Linit_cbc);
2925 beq(CCR1, Ldone_true);
2926 mtctr(cbc_iter);
2927 //16:
2928 bind(Lcbc);
2929 lhzx(tmp1_reg, str1_reg, index_reg);
2930 lhzx(tmp2_reg, str2_reg, index_reg);
2931 cmpw(CCR0, tmp1_reg, tmp2_reg);
2932 bne(CCR0, Ldone_false); // Unequal char pair found -> done.
2933 addi(index_reg, index_reg, 1*sizeof(jchar));
2934 bdnz(Lcbc);
2935 nop();
2936 bind(Ldone_true);
2937 li(result_reg, 1);
2938 //24:
2939 bind(Ldone_false);
2940 }
2943 void MacroAssembler::char_arrays_equalsImm(Register str1_reg, Register str2_reg, int cntval, Register result_reg,
2944 Register tmp1_reg, Register tmp2_reg) {
2945 // Str1 may be the same register as str2 which can occur e.g. after scalar replacement.
2946 assert_different_registers(result_reg, str1_reg, tmp1_reg, tmp2_reg);
2947 assert_different_registers(result_reg, str2_reg, tmp1_reg, tmp2_reg);
2948 assert(sizeof(jchar) == 2, "must be");
2949 assert(cntval >= 0 && ((cntval & 0x7fff) == cntval), "wrong immediate");
2951 Label Ldone_false;
2953 if (cntval < 16) { // short case
2954 if (cntval != 0) li(result_reg, 0); // assume false
2956 const int num_bytes = cntval*sizeof(jchar);
2957 int index = 0;
2958 for (int next_index; (next_index = index + 8) <= num_bytes; index = next_index) {
2959 ld(tmp1_reg, index, str1_reg);
2960 ld(tmp2_reg, index, str2_reg);
2961 cmpd(CCR0, tmp1_reg, tmp2_reg);
2962 bne(CCR0, Ldone_false);
2963 }
2964 if (cntval & 2) {
2965 lwz(tmp1_reg, index, str1_reg);
2966 lwz(tmp2_reg, index, str2_reg);
2967 cmpw(CCR0, tmp1_reg, tmp2_reg);
2968 bne(CCR0, Ldone_false);
2969 index += 4;
2970 }
2971 if (cntval & 1) {
2972 lhz(tmp1_reg, index, str1_reg);
2973 lhz(tmp2_reg, index, str2_reg);
2974 cmpw(CCR0, tmp1_reg, tmp2_reg);
2975 bne(CCR0, Ldone_false);
2976 }
2977 // fallthrough: true
2978 } else {
2979 Label Lloop;
2980 Register index_reg = tmp1_reg;
2981 const int loopcnt = cntval/4;
2982 assert(loopcnt > 0, "must be");
2983 // Offset 0 should be 32 byte aligned.
2984 //2:
2985 dcbtct(str1_reg, 0x00); // Indicate R/O access to str1.
2986 dcbtct(str2_reg, 0x00); // Indicate R/O access to str2.
2987 li(tmp2_reg, loopcnt);
2988 li(index_reg, 0); // init
2989 li(result_reg, 0); // assume false
2990 mtctr(tmp2_reg);
2991 //8:
2992 bind(Lloop);
2993 ldx(R0, str1_reg, index_reg);
2994 ldx(tmp2_reg, str2_reg, index_reg);
2995 cmpd(CCR0, R0, tmp2_reg);
2996 bne(CCR0, Ldone_false); // Unequal char pair found -> done.
2997 addi(index_reg, index_reg, 4*sizeof(jchar));
2998 bdnz(Lloop);
2999 //14:
3000 if (cntval & 2) {
3001 lwzx(R0, str1_reg, index_reg);
3002 lwzx(tmp2_reg, str2_reg, index_reg);
3003 cmpw(CCR0, R0, tmp2_reg);
3004 bne(CCR0, Ldone_false);
3005 if (cntval & 1) addi(index_reg, index_reg, 2*sizeof(jchar));
3006 }
3007 if (cntval & 1) {
3008 lhzx(R0, str1_reg, index_reg);
3009 lhzx(tmp2_reg, str2_reg, index_reg);
3010 cmpw(CCR0, R0, tmp2_reg);
3011 bne(CCR0, Ldone_false);
3012 }
3013 // fallthru: true
3014 }
3015 li(result_reg, 1);
3016 bind(Ldone_false);
3017 }
3020 void MacroAssembler::asm_assert(bool check_equal, const char *msg, int id) {
3021 #ifdef ASSERT
3022 Label ok;
3023 if (check_equal) {
3024 beq(CCR0, ok);
3025 } else {
3026 bne(CCR0, ok);
3027 }
3028 stop(msg, id);
3029 bind(ok);
3030 #endif
3031 }
3033 void MacroAssembler::asm_assert_mems_zero(bool check_equal, int size, int mem_offset,
3034 Register mem_base, const char* msg, int id) {
3035 #ifdef ASSERT
3036 switch (size) {
3037 case 4:
3038 lwz(R0, mem_offset, mem_base);
3039 cmpwi(CCR0, R0, 0);
3040 break;
3041 case 8:
3042 ld(R0, mem_offset, mem_base);
3043 cmpdi(CCR0, R0, 0);
3044 break;
3045 default:
3046 ShouldNotReachHere();
3047 }
3048 asm_assert(check_equal, msg, id);
3049 #endif // ASSERT
3050 }
3052 void MacroAssembler::verify_thread() {
3053 if (VerifyThread) {
3054 unimplemented("'VerifyThread' currently not implemented on PPC");
3055 }
3056 }
3058 // READ: oop. KILL: R0. Volatile floats perhaps.
3059 void MacroAssembler::verify_oop(Register oop, const char* msg) {
3060 if (!VerifyOops) {
3061 return;
3062 }
3063 // Will be preserved.
3064 Register tmp = R11;
3065 assert(oop != tmp, "precondition");
3066 unsigned int nbytes_save = 10*8; // 10 volatile gprs
3067 address/* FunctionDescriptor** */fd = StubRoutines::verify_oop_subroutine_entry_address();
3068 // save tmp
3069 mr(R0, tmp);
3070 // kill tmp
3071 save_LR_CR(tmp);
3072 push_frame_reg_args(nbytes_save, tmp);
3073 // restore tmp
3074 mr(tmp, R0);
3075 save_volatile_gprs(R1_SP, 112); // except R0
3076 // load FunctionDescriptor** / entry_address *
3077 load_const(tmp, fd);
3078 // load FunctionDescriptor* / entry_address
3079 ld(tmp, 0, tmp);
3080 mr(R4_ARG2, oop);
3081 load_const(R3_ARG1, (address)msg);
3082 // call destination for its side effect
3083 call_c(tmp);
3084 restore_volatile_gprs(R1_SP, 112); // except R0
3085 pop_frame();
3086 // save tmp
3087 mr(R0, tmp);
3088 // kill tmp
3089 restore_LR_CR(tmp);
3090 // restore tmp
3091 mr(tmp, R0);
3092 }
3094 const char* stop_types[] = {
3095 "stop",
3096 "untested",
3097 "unimplemented",
3098 "shouldnotreachhere"
3099 };
3101 static void stop_on_request(int tp, const char* msg) {
3102 tty->print("PPC assembly code requires stop: (%s) %s\n", (void *)stop_types[tp%/*stop_end*/4], msg);
3103 guarantee(false, err_msg("PPC assembly code requires stop: %s", msg));
3104 }
3106 // Call a C-function that prints output.
3107 void MacroAssembler::stop(int type, const char* msg, int id) {
3108 #ifndef PRODUCT
3109 block_comment(err_msg("stop: %s %s {", stop_types[type%stop_end], msg));
3110 #else
3111 block_comment("stop {");
3112 #endif
3114 // setup arguments
3115 load_const_optimized(R3_ARG1, type);
3116 load_const_optimized(R4_ARG2, (void *)msg, /*tmp=*/R0);
3117 call_VM_leaf(CAST_FROM_FN_PTR(address, stop_on_request), R3_ARG1, R4_ARG2);
3118 illtrap();
3119 emit_int32(id);
3120 block_comment("} stop;");
3121 }
3123 #ifndef PRODUCT
3124 // Write pattern 0x0101010101010101 in memory region [low-before, high+after].
3125 // Val, addr are temp registers.
3126 // If low == addr, addr is killed.
3127 // High is preserved.
3128 void MacroAssembler::zap_from_to(Register low, int before, Register high, int after, Register val, Register addr) {
3129 if (!ZapMemory) return;
3131 assert_different_registers(low, val);
3133 BLOCK_COMMENT("zap memory region {");
3134 load_const_optimized(val, 0x0101010101010101);
3135 int size = before + after;
3136 if (low == high && size < 5 && size > 0) {
3137 int offset = -before*BytesPerWord;
3138 for (int i = 0; i < size; ++i) {
3139 std(val, offset, low);
3140 offset += (1*BytesPerWord);
3141 }
3142 } else {
3143 addi(addr, low, -before*BytesPerWord);
3144 assert_different_registers(high, val);
3145 if (after) addi(high, high, after * BytesPerWord);
3146 Label loop;
3147 bind(loop);
3148 std(val, 0, addr);
3149 addi(addr, addr, 8);
3150 cmpd(CCR6, addr, high);
3151 ble(CCR6, loop);
3152 if (after) addi(high, high, -after * BytesPerWord); // Correct back to old value.
3153 }
3154 BLOCK_COMMENT("} zap memory region");
3155 }
3157 #endif // !PRODUCT
3159 SkipIfEqualZero::SkipIfEqualZero(MacroAssembler* masm, Register temp, const bool* flag_addr) : _masm(masm), _label() {
3160 int simm16_offset = masm->load_const_optimized(temp, (address)flag_addr, R0, true);
3161 assert(sizeof(bool) == 1, "PowerPC ABI");
3162 masm->lbz(temp, simm16_offset, temp);
3163 masm->cmpwi(CCR0, temp, 0);
3164 masm->beq(CCR0, _label);
3165 }
3167 SkipIfEqualZero::~SkipIfEqualZero() {
3168 _masm->bind(_label);
3169 }