1 /*
   2  * Copyright (c) 1997, 2015, Oracle and/or its affiliates. All rights reserved.
   3  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
   4  *
   5  * This code is free software; you can redistribute it and/or modify it
   6  * under the terms of the GNU General Public License version 2 only, as
   7  * published by the Free Software Foundation.
   8  *
   9  * This code is distributed in the hope that it will be useful, but WITHOUT
  10  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  11  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  12  * version 2 for more details (a copy is included in the LICENSE file that
  13  * accompanied this code).
  14  *
  15  * You should have received a copy of the GNU General Public License version
  16  * 2 along with this work; if not, write to the Free Software Foundation,
  17  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  18  *
  19  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  20  * or visit www.oracle.com if you need additional information or have any
  21  * questions.
  22  *
  23  */
  24 
  25 #include "precompiled.hpp"
  26 #include "asm/macroAssembler.inline.hpp"
  27 #include "interpreter/interpreter.hpp"
  28 #include "nativeInst_sparc.hpp"
  29 #include "oops/instanceOop.hpp"
  30 #include "oops/method.hpp"
  31 #include "oops/objArrayKlass.hpp"
  32 #include "oops/oop.inline.hpp"
  33 #include "prims/methodHandles.hpp"
  34 #include "runtime/frame.inline.hpp"
  35 #include "runtime/handles.inline.hpp"
  36 #include "runtime/sharedRuntime.hpp"
  37 #include "runtime/stubCodeGenerator.hpp"
  38 #include "runtime/stubRoutines.hpp"
  39 #include "runtime/thread.inline.hpp"
  40 #include "utilities/top.hpp"
  41 #ifdef COMPILER2
  42 #include "opto/runtime.hpp"
  43 #endif
  44 
  45 // Declaration and definition of StubGenerator (no .hpp file).
  46 // For a more detailed description of the stub routine structure
  47 // see the comment in stubRoutines.hpp.
  48 
  49 #define __ _masm->
  50 
  51 #ifdef PRODUCT
  52 #define BLOCK_COMMENT(str) /* nothing */
  53 #else
  54 #define BLOCK_COMMENT(str) __ block_comment(str)
  55 #endif
  56 
  57 #define BIND(label) bind(label); BLOCK_COMMENT(#label ":")
  58 
  59 // Note:  The register L7 is used as L7_thread_cache, and may not be used
  60 //        any other way within this module.
  61 
  62 
  63 static const Register& Lstub_temp = L2;
  64 
  65 // -------------------------------------------------------------------------------------------------------------------------
  66 // Stub Code definitions
  67 
  68 static address handle_unsafe_access() {
  69   JavaThread* thread = JavaThread::current();
  70   address pc  = thread->saved_exception_pc();
  71   address npc = thread->saved_exception_npc();
  72   // pc is the instruction which we must emulate
  73   // doing a no-op is fine:  return garbage from the load
  74 
  75   // request an async exception
  76   thread->set_pending_unsafe_access_error();
  77 
  78   // return address of next instruction to execute
  79   return npc;
  80 }
  81 
  82 class StubGenerator: public StubCodeGenerator {
  83  private:
  84 
  85 #ifdef PRODUCT
  86 #define inc_counter_np(a,b,c)
  87 #else
  88 #define inc_counter_np(counter, t1, t2) \
  89   BLOCK_COMMENT("inc_counter " #counter); \
  90   __ inc_counter(&counter, t1, t2);
  91 #endif
  92 
  93   //----------------------------------------------------------------------------------------------------
  94   // Call stubs are used to call Java from C
  95 
  96   address generate_call_stub(address& return_pc) {
  97     StubCodeMark mark(this, "StubRoutines", "call_stub");
  98     address start = __ pc();
  99 
 100     // Incoming arguments:
 101     //
 102     // o0         : call wrapper address
 103     // o1         : result (address)
 104     // o2         : result type
 105     // o3         : method
 106     // o4         : (interpreter) entry point
 107     // o5         : parameters (address)
 108     // [sp + 0x5c]: parameter size (in words)
 109     // [sp + 0x60]: thread
 110     //
 111     // +---------------+ <--- sp + 0
 112     // |               |
 113     // . reg save area .
 114     // |               |
 115     // +---------------+ <--- sp + 0x40
 116     // |               |
 117     // . extra 7 slots .
 118     // |               |
 119     // +---------------+ <--- sp + 0x5c
 120     // |  param. size  |
 121     // +---------------+ <--- sp + 0x60
 122     // |    thread     |
 123     // +---------------+
 124     // |               |
 125 
 126     // note: if the link argument position changes, adjust
 127     //       the code in frame::entry_frame_call_wrapper()
 128 
 129     const Argument link           = Argument(0, false); // used only for GC
 130     const Argument result         = Argument(1, false);
 131     const Argument result_type    = Argument(2, false);
 132     const Argument method         = Argument(3, false);
 133     const Argument entry_point    = Argument(4, false);
 134     const Argument parameters     = Argument(5, false);
 135     const Argument parameter_size = Argument(6, false);
 136     const Argument thread         = Argument(7, false);
 137 
 138     // setup thread register
 139     __ ld_ptr(thread.as_address(), G2_thread);
 140     __ reinit_heapbase();
 141 
 142 #ifdef ASSERT
 143     // make sure we have no pending exceptions
 144     { const Register t = G3_scratch;
 145       Label L;
 146       __ ld_ptr(G2_thread, in_bytes(Thread::pending_exception_offset()), t);
 147       __ br_null_short(t, Assembler::pt, L);
 148       __ stop("StubRoutines::call_stub: entered with pending exception");
 149       __ bind(L);
 150     }
 151 #endif
 152 
 153     // create activation frame & allocate space for parameters
 154     { const Register t = G3_scratch;
 155       __ ld_ptr(parameter_size.as_address(), t);                // get parameter size (in words)
 156       __ add(t, frame::memory_parameter_word_sp_offset, t);     // add space for save area (in words)
 157       __ round_to(t, WordsPerLong);                             // make sure it is multiple of 2 (in words)
 158       __ sll(t, Interpreter::logStackElementSize, t);           // compute number of bytes
 159       __ neg(t);                                                // negate so it can be used with save
 160       __ save(SP, t, SP);                                       // setup new frame
 161     }
 162 
 163     // +---------------+ <--- sp + 0
 164     // |               |
 165     // . reg save area .
 166     // |               |
 167     // +---------------+ <--- sp + 0x40
 168     // |               |
 169     // . extra 7 slots .
 170     // |               |
 171     // +---------------+ <--- sp + 0x5c
 172     // |  empty slot   |      (only if parameter size is even)
 173     // +---------------+
 174     // |               |
 175     // .  parameters   .
 176     // |               |
 177     // +---------------+ <--- fp + 0
 178     // |               |
 179     // . reg save area .
 180     // |               |
 181     // +---------------+ <--- fp + 0x40
 182     // |               |
 183     // . extra 7 slots .
 184     // |               |
 185     // +---------------+ <--- fp + 0x5c
 186     // |  param. size  |
 187     // +---------------+ <--- fp + 0x60
 188     // |    thread     |
 189     // +---------------+
 190     // |               |
 191 
 192     // pass parameters if any
 193     BLOCK_COMMENT("pass parameters if any");
 194     { const Register src = parameters.as_in().as_register();
 195       const Register dst = Lentry_args;
 196       const Register tmp = G3_scratch;
 197       const Register cnt = G4_scratch;
 198 
 199       // test if any parameters & setup of Lentry_args
 200       Label exit;
 201       __ ld_ptr(parameter_size.as_in().as_address(), cnt);      // parameter counter
 202       __ add( FP, STACK_BIAS, dst );
 203       __ cmp_zero_and_br(Assembler::zero, cnt, exit);
 204       __ delayed()->sub(dst, BytesPerWord, dst);                 // setup Lentry_args
 205 
 206       // copy parameters if any
 207       Label loop;
 208       __ BIND(loop);
 209       // Store parameter value
 210       __ ld_ptr(src, 0, tmp);
 211       __ add(src, BytesPerWord, src);
 212       __ st_ptr(tmp, dst, 0);
 213       __ deccc(cnt);
 214       __ br(Assembler::greater, false, Assembler::pt, loop);
 215       __ delayed()->sub(dst, Interpreter::stackElementSize, dst);
 216 
 217       // done
 218       __ BIND(exit);
 219     }
 220 
 221     // setup parameters, method & call Java function
 222 #ifdef ASSERT
 223     // layout_activation_impl checks it's notion of saved SP against
 224     // this register, so if this changes update it as well.
 225     const Register saved_SP = Lscratch;
 226     __ mov(SP, saved_SP);                               // keep track of SP before call
 227 #endif
 228 
 229     // setup parameters
 230     const Register t = G3_scratch;
 231     __ ld_ptr(parameter_size.as_in().as_address(), t); // get parameter size (in words)
 232     __ sll(t, Interpreter::logStackElementSize, t);    // compute number of bytes
 233     __ sub(FP, t, Gargs);                              // setup parameter pointer
 234 #ifdef _LP64
 235     __ add( Gargs, STACK_BIAS, Gargs );                // Account for LP64 stack bias
 236 #endif
 237     __ mov(SP, O5_savedSP);
 238 
 239 
 240     // do the call
 241     //
 242     // the following register must be setup:
 243     //
 244     // G2_thread
 245     // G5_method
 246     // Gargs
 247     BLOCK_COMMENT("call Java function");
 248     __ jmpl(entry_point.as_in().as_register(), G0, O7);
 249     __ delayed()->mov(method.as_in().as_register(), G5_method);   // setup method
 250 
 251     BLOCK_COMMENT("call_stub_return_address:");
 252     return_pc = __ pc();
 253 
 254     // The callee, if it wasn't interpreted, can return with SP changed so
 255     // we can no longer assert of change of SP.
 256 
 257     // store result depending on type
 258     // (everything that is not T_OBJECT, T_LONG, T_FLOAT, or T_DOUBLE
 259     //  is treated as T_INT)
 260     { const Register addr = result     .as_in().as_register();
 261       const Register type = result_type.as_in().as_register();
 262       Label is_long, is_float, is_double, is_object, exit;
 263       __            cmp(type, T_OBJECT);  __ br(Assembler::equal, false, Assembler::pn, is_object);
 264       __ delayed()->cmp(type, T_FLOAT);   __ br(Assembler::equal, false, Assembler::pn, is_float);
 265       __ delayed()->cmp(type, T_DOUBLE);  __ br(Assembler::equal, false, Assembler::pn, is_double);
 266       __ delayed()->cmp(type, T_LONG);    __ br(Assembler::equal, false, Assembler::pn, is_long);
 267       __ delayed()->nop();
 268 
 269       // store int result
 270       __ st(O0, addr, G0);
 271 
 272       __ BIND(exit);
 273       __ ret();
 274       __ delayed()->restore();
 275 
 276       __ BIND(is_object);
 277       __ ba(exit);
 278       __ delayed()->st_ptr(O0, addr, G0);
 279 
 280       __ BIND(is_float);
 281       __ ba(exit);
 282       __ delayed()->stf(FloatRegisterImpl::S, F0, addr, G0);
 283 
 284       __ BIND(is_double);
 285       __ ba(exit);
 286       __ delayed()->stf(FloatRegisterImpl::D, F0, addr, G0);
 287 
 288       __ BIND(is_long);
 289 #ifdef _LP64
 290       __ ba(exit);
 291       __ delayed()->st_long(O0, addr, G0);      // store entire long
 292 #else
 293 #if defined(COMPILER2)
 294   // All return values are where we want them, except for Longs.  C2 returns
 295   // longs in G1 in the 32-bit build whereas the interpreter wants them in O0/O1.
 296   // Since the interpreter will return longs in G1 and O0/O1 in the 32bit
 297   // build we simply always use G1.
 298   // Note: I tried to make c2 return longs in O0/O1 and G1 so we wouldn't have to
 299   // do this here. Unfortunately if we did a rethrow we'd see an machepilog node
 300   // first which would move g1 -> O0/O1 and destroy the exception we were throwing.
 301 
 302       __ ba(exit);
 303       __ delayed()->stx(G1, addr, G0);  // store entire long
 304 #else
 305       __ st(O1, addr, BytesPerInt);
 306       __ ba(exit);
 307       __ delayed()->st(O0, addr, G0);
 308 #endif /* COMPILER2 */
 309 #endif /* _LP64 */
 310      }
 311      return start;
 312   }
 313 
 314 
 315   //----------------------------------------------------------------------------------------------------
 316   // Return point for a Java call if there's an exception thrown in Java code.
 317   // The exception is caught and transformed into a pending exception stored in
 318   // JavaThread that can be tested from within the VM.
 319   //
 320   // Oexception: exception oop
 321 
 322   address generate_catch_exception() {
 323     StubCodeMark mark(this, "StubRoutines", "catch_exception");
 324 
 325     address start = __ pc();
 326     // verify that thread corresponds
 327     __ verify_thread();
 328 
 329     const Register& temp_reg = Gtemp;
 330     Address pending_exception_addr    (G2_thread, Thread::pending_exception_offset());
 331     Address exception_file_offset_addr(G2_thread, Thread::exception_file_offset   ());
 332     Address exception_line_offset_addr(G2_thread, Thread::exception_line_offset   ());
 333 
 334     // set pending exception
 335     __ verify_oop(Oexception);
 336     __ st_ptr(Oexception, pending_exception_addr);
 337     __ set((intptr_t)__FILE__, temp_reg);
 338     __ st_ptr(temp_reg, exception_file_offset_addr);
 339     __ set((intptr_t)__LINE__, temp_reg);
 340     __ st(temp_reg, exception_line_offset_addr);
 341 
 342     // complete return to VM
 343     assert(StubRoutines::_call_stub_return_address != NULL, "must have been generated before");
 344 
 345     AddressLiteral stub_ret(StubRoutines::_call_stub_return_address);
 346     __ jump_to(stub_ret, temp_reg);
 347     __ delayed()->nop();
 348 
 349     return start;
 350   }
 351 
 352 
 353   //----------------------------------------------------------------------------------------------------
 354   // Continuation point for runtime calls returning with a pending exception
 355   // The pending exception check happened in the runtime or native call stub
 356   // The pending exception in Thread is converted into a Java-level exception
 357   //
 358   // Contract with Java-level exception handler: O0 = exception
 359   //                                             O1 = throwing pc
 360 
 361   address generate_forward_exception() {
 362     StubCodeMark mark(this, "StubRoutines", "forward_exception");
 363     address start = __ pc();
 364 
 365     // Upon entry, O7 has the return address returning into Java
 366     // (interpreted or compiled) code; i.e. the return address
 367     // becomes the throwing pc.
 368 
 369     const Register& handler_reg = Gtemp;
 370 
 371     Address exception_addr(G2_thread, Thread::pending_exception_offset());
 372 
 373 #ifdef ASSERT
 374     // make sure that this code is only executed if there is a pending exception
 375     { Label L;
 376       __ ld_ptr(exception_addr, Gtemp);
 377       __ br_notnull_short(Gtemp, Assembler::pt, L);
 378       __ stop("StubRoutines::forward exception: no pending exception (1)");
 379       __ bind(L);
 380     }
 381 #endif
 382 
 383     // compute exception handler into handler_reg
 384     __ get_thread();
 385     __ ld_ptr(exception_addr, Oexception);
 386     __ verify_oop(Oexception);
 387     __ save_frame(0);             // compensates for compiler weakness
 388     __ add(O7->after_save(), frame::pc_return_offset, Lscratch); // save the issuing PC
 389     BLOCK_COMMENT("call exception_handler_for_return_address");
 390     __ call_VM_leaf(L7_thread_cache, CAST_FROM_FN_PTR(address, SharedRuntime::exception_handler_for_return_address), G2_thread, Lscratch);
 391     __ mov(O0, handler_reg);
 392     __ restore();                 // compensates for compiler weakness
 393 
 394     __ ld_ptr(exception_addr, Oexception);
 395     __ add(O7, frame::pc_return_offset, Oissuing_pc); // save the issuing PC
 396 
 397 #ifdef ASSERT
 398     // make sure exception is set
 399     { Label L;
 400       __ br_notnull_short(Oexception, Assembler::pt, L);
 401       __ stop("StubRoutines::forward exception: no pending exception (2)");
 402       __ bind(L);
 403     }
 404 #endif
 405     // jump to exception handler
 406     __ jmp(handler_reg, 0);
 407     // clear pending exception
 408     __ delayed()->st_ptr(G0, exception_addr);
 409 
 410     return start;
 411   }
 412 
 413   // Safefetch stubs.
 414   void generate_safefetch(const char* name, int size, address* entry,
 415                           address* fault_pc, address* continuation_pc) {
 416     // safefetch signatures:
 417     //   int      SafeFetch32(int*      adr, int      errValue);
 418     //   intptr_t SafeFetchN (intptr_t* adr, intptr_t errValue);
 419     //
 420     // arguments:
 421     //   o0 = adr
 422     //   o1 = errValue
 423     //
 424     // result:
 425     //   o0  = *adr or errValue
 426 
 427     StubCodeMark mark(this, "StubRoutines", name);
 428 
 429     // Entry point, pc or function descriptor.
 430     __ align(CodeEntryAlignment);
 431     *entry = __ pc();
 432 
 433     __ mov(O0, G1);  // g1 = o0
 434     __ mov(O1, O0);  // o0 = o1
 435     // Load *adr into c_rarg1, may fault.
 436     *fault_pc = __ pc();
 437     switch (size) {
 438       case 4:
 439         // int32_t
 440         __ ldsw(G1, 0, O0);  // o0 = [g1]
 441         break;
 442       case 8:
 443         // int64_t
 444         __ ldx(G1, 0, O0);   // o0 = [g1]
 445         break;
 446       default:
 447         ShouldNotReachHere();
 448     }
 449 
 450     // return errValue or *adr
 451     *continuation_pc = __ pc();
 452     // By convention with the trap handler we ensure there is a non-CTI
 453     // instruction in the trap shadow.
 454     __ nop();
 455     __ retl();
 456     __ delayed()->nop();
 457   }
 458 
 459   //------------------------------------------------------------------------------------------------------------------------
 460   // Continuation point for throwing of implicit exceptions that are not handled in
 461   // the current activation. Fabricates an exception oop and initiates normal
 462   // exception dispatching in this frame. Only callee-saved registers are preserved
 463   // (through the normal register window / RegisterMap handling).
 464   // If the compiler needs all registers to be preserved between the fault
 465   // point and the exception handler then it must assume responsibility for that in
 466   // AbstractCompiler::continuation_for_implicit_null_exception or
 467   // continuation_for_implicit_division_by_zero_exception. All other implicit
 468   // exceptions (e.g., NullPointerException or AbstractMethodError on entry) are
 469   // either at call sites or otherwise assume that stack unwinding will be initiated,
 470   // so caller saved registers were assumed volatile in the compiler.
 471 
 472   // Note that we generate only this stub into a RuntimeStub, because it needs to be
 473   // properly traversed and ignored during GC, so we change the meaning of the "__"
 474   // macro within this method.
 475 #undef __
 476 #define __ masm->
 477 
 478   address generate_throw_exception(const char* name, address runtime_entry,
 479                                    Register arg1 = noreg, Register arg2 = noreg) {
 480 #ifdef ASSERT
 481     int insts_size = VerifyThread ? 1 * K : 600;
 482 #else
 483     int insts_size = VerifyThread ? 1 * K : 256;
 484 #endif /* ASSERT */
 485     int locs_size  = 32;
 486 
 487     CodeBuffer      code(name, insts_size, locs_size);
 488     MacroAssembler* masm = new MacroAssembler(&code);
 489 
 490     __ verify_thread();
 491 
 492     // This is an inlined and slightly modified version of call_VM
 493     // which has the ability to fetch the return PC out of thread-local storage
 494     __ assert_not_delayed();
 495 
 496     // Note that we always push a frame because on the SPARC
 497     // architecture, for all of our implicit exception kinds at call
 498     // sites, the implicit exception is taken before the callee frame
 499     // is pushed.
 500     __ save_frame(0);
 501 
 502     int frame_complete = __ offset();
 503 
 504     // Note that we always have a runtime stub frame on the top of stack by this point
 505     Register last_java_sp = SP;
 506     // 64-bit last_java_sp is biased!
 507     __ set_last_Java_frame(last_java_sp, G0);
 508     if (VerifyThread)  __ mov(G2_thread, O0); // about to be smashed; pass early
 509     __ save_thread(noreg);
 510     if (arg1 != noreg) {
 511       assert(arg2 != O1, "clobbered");
 512       __ mov(arg1, O1);
 513     }
 514     if (arg2 != noreg) {
 515       __ mov(arg2, O2);
 516     }
 517     // do the call
 518     BLOCK_COMMENT("call runtime_entry");
 519     __ call(runtime_entry, relocInfo::runtime_call_type);
 520     if (!VerifyThread)
 521       __ delayed()->mov(G2_thread, O0);  // pass thread as first argument
 522     else
 523       __ delayed()->nop();             // (thread already passed)
 524     __ restore_thread(noreg);
 525     __ reset_last_Java_frame();
 526 
 527     // check for pending exceptions. use Gtemp as scratch register.
 528 #ifdef ASSERT
 529     Label L;
 530 
 531     Address exception_addr(G2_thread, Thread::pending_exception_offset());
 532     Register scratch_reg = Gtemp;
 533     __ ld_ptr(exception_addr, scratch_reg);
 534     __ br_notnull_short(scratch_reg, Assembler::pt, L);
 535     __ should_not_reach_here();
 536     __ bind(L);
 537 #endif // ASSERT
 538     BLOCK_COMMENT("call forward_exception_entry");
 539     __ call(StubRoutines::forward_exception_entry(), relocInfo::runtime_call_type);
 540     // we use O7 linkage so that forward_exception_entry has the issuing PC
 541     __ delayed()->restore();
 542 
 543     RuntimeStub* stub = RuntimeStub::new_runtime_stub(name, &code, frame_complete, masm->total_frame_size_in_bytes(0), NULL, false);
 544     return stub->entry_point();
 545   }
 546 
 547 #undef __
 548 #define __ _masm->
 549 
 550 
 551   // Generate a routine that sets all the registers so we
 552   // can tell if the stop routine prints them correctly.
 553   address generate_test_stop() {
 554     StubCodeMark mark(this, "StubRoutines", "test_stop");
 555     address start = __ pc();
 556 
 557     int i;
 558 
 559     __ save_frame(0);
 560 
 561     static jfloat zero = 0.0, one = 1.0;
 562 
 563     // put addr in L0, then load through L0 to F0
 564     __ set((intptr_t)&zero, L0);  __ ldf( FloatRegisterImpl::S, L0, 0, F0);
 565     __ set((intptr_t)&one,  L0);  __ ldf( FloatRegisterImpl::S, L0, 0, F1); // 1.0 to F1
 566 
 567     // use add to put 2..18 in F2..F18
 568     for ( i = 2;  i <= 18;  ++i ) {
 569       __ fadd( FloatRegisterImpl::S, F1, as_FloatRegister(i-1),  as_FloatRegister(i));
 570     }
 571 
 572     // Now put double 2 in F16, double 18 in F18
 573     __ ftof( FloatRegisterImpl::S, FloatRegisterImpl::D, F2, F16 );
 574     __ ftof( FloatRegisterImpl::S, FloatRegisterImpl::D, F18, F18 );
 575 
 576     // use add to put 20..32 in F20..F32
 577     for (i = 20; i < 32; i += 2) {
 578       __ fadd( FloatRegisterImpl::D, F16, as_FloatRegister(i-2),  as_FloatRegister(i));
 579     }
 580 
 581     // put 0..7 in i's, 8..15 in l's, 16..23 in o's, 24..31 in g's
 582     for ( i = 0; i < 8; ++i ) {
 583       if (i < 6) {
 584         __ set(     i, as_iRegister(i));
 585         __ set(16 + i, as_oRegister(i));
 586         __ set(24 + i, as_gRegister(i));
 587       }
 588       __ set( 8 + i, as_lRegister(i));
 589     }
 590 
 591     __ stop("testing stop");
 592 
 593 
 594     __ ret();
 595     __ delayed()->restore();
 596 
 597     return start;
 598   }
 599 
 600 
 601   address generate_stop_subroutine() {
 602     StubCodeMark mark(this, "StubRoutines", "stop_subroutine");
 603     address start = __ pc();
 604 
 605     __ stop_subroutine();
 606 
 607     return start;
 608   }
 609 
 610   address generate_flush_callers_register_windows() {
 611     StubCodeMark mark(this, "StubRoutines", "flush_callers_register_windows");
 612     address start = __ pc();
 613 
 614     __ flushw();
 615     __ retl(false);
 616     __ delayed()->add( FP, STACK_BIAS, O0 );
 617     // The returned value must be a stack pointer whose register save area
 618     // is flushed, and will stay flushed while the caller executes.
 619 
 620     return start;
 621   }
 622 
 623   // Support for jint Atomic::xchg(jint exchange_value, volatile jint* dest).
 624   //
 625   // Arguments:
 626   //
 627   //      exchange_value: O0
 628   //      dest:           O1
 629   //
 630   // Results:
 631   //
 632   //     O0: the value previously stored in dest
 633   //
 634   address generate_atomic_xchg() {
 635     StubCodeMark mark(this, "StubRoutines", "atomic_xchg");
 636     address start = __ pc();
 637 
 638     if (UseCASForSwap) {
 639       // Use CAS instead of swap, just in case the MP hardware
 640       // prefers to work with just one kind of synch. instruction.
 641       Label retry;
 642       __ BIND(retry);
 643       __ mov(O0, O3);       // scratch copy of exchange value
 644       __ ld(O1, 0, O2);     // observe the previous value
 645       // try to replace O2 with O3
 646       __ cas(O1, O2, O3);
 647       __ cmp_and_br_short(O2, O3, Assembler::notEqual, Assembler::pn, retry);
 648 
 649       __ retl(false);
 650       __ delayed()->mov(O2, O0);  // report previous value to caller
 651     } else {
 652       __ retl(false);
 653       __ delayed()->swap(O1, 0, O0);
 654     }
 655 
 656     return start;
 657   }
 658 
 659 
 660   // Support for jint Atomic::cmpxchg(jint exchange_value, volatile jint* dest, jint compare_value)
 661   //
 662   // Arguments:
 663   //
 664   //      exchange_value: O0
 665   //      dest:           O1
 666   //      compare_value:  O2
 667   //
 668   // Results:
 669   //
 670   //     O0: the value previously stored in dest
 671   //
 672   address generate_atomic_cmpxchg() {
 673     StubCodeMark mark(this, "StubRoutines", "atomic_cmpxchg");
 674     address start = __ pc();
 675 
 676     // cmpxchg(dest, compare_value, exchange_value)
 677     __ cas(O1, O2, O0);
 678     __ retl(false);
 679     __ delayed()->nop();
 680 
 681     return start;
 682   }
 683 
 684   // Support for jlong Atomic::cmpxchg(jlong exchange_value, volatile jlong *dest, jlong compare_value)
 685   //
 686   // Arguments:
 687   //
 688   //      exchange_value: O1:O0
 689   //      dest:           O2
 690   //      compare_value:  O4:O3
 691   //
 692   // Results:
 693   //
 694   //     O1:O0: the value previously stored in dest
 695   //
 696   // Overwrites: G1,G2,G3
 697   //
 698   address generate_atomic_cmpxchg_long() {
 699     StubCodeMark mark(this, "StubRoutines", "atomic_cmpxchg_long");
 700     address start = __ pc();
 701 
 702     __ sllx(O0, 32, O0);
 703     __ srl(O1, 0, O1);
 704     __ or3(O0,O1,O0);      // O0 holds 64-bit value from compare_value
 705     __ sllx(O3, 32, O3);
 706     __ srl(O4, 0, O4);
 707     __ or3(O3,O4,O3);     // O3 holds 64-bit value from exchange_value
 708     __ casx(O2, O3, O0);
 709     __ srl(O0, 0, O1);    // unpacked return value in O1:O0
 710     __ retl(false);
 711     __ delayed()->srlx(O0, 32, O0);
 712 
 713     return start;
 714   }
 715 
 716 
 717   // Support for jint Atomic::add(jint add_value, volatile jint* dest).
 718   //
 719   // Arguments:
 720   //
 721   //      add_value: O0   (e.g., +1 or -1)
 722   //      dest:      O1
 723   //
 724   // Results:
 725   //
 726   //     O0: the new value stored in dest
 727   //
 728   // Overwrites: O3
 729   //
 730   address generate_atomic_add() {
 731     StubCodeMark mark(this, "StubRoutines", "atomic_add");
 732     address start = __ pc();
 733     __ BIND(_atomic_add_stub);
 734 
 735     Label(retry);
 736     __ BIND(retry);
 737 
 738     __ lduw(O1, 0, O2);
 739     __ add(O0, O2, O3);
 740     __ cas(O1, O2, O3);
 741     __ cmp_and_br_short(O2, O3, Assembler::notEqual, Assembler::pn, retry);
 742     __ retl(false);
 743     __ delayed()->add(O0, O2, O0); // note that cas made O2==O3
 744 
 745     return start;
 746   }
 747   Label _atomic_add_stub;  // called from other stubs
 748 
 749 
 750   //------------------------------------------------------------------------------------------------------------------------
 751   // The following routine generates a subroutine to throw an asynchronous
 752   // UnknownError when an unsafe access gets a fault that could not be
 753   // reasonably prevented by the programmer.  (Example: SIGBUS/OBJERR.)
 754   //
 755   // Arguments :
 756   //
 757   //      trapping PC:    O7
 758   //
 759   // Results:
 760   //     posts an asynchronous exception, skips the trapping instruction
 761   //
 762 
 763   address generate_handler_for_unsafe_access() {
 764     StubCodeMark mark(this, "StubRoutines", "handler_for_unsafe_access");
 765     address start = __ pc();
 766 
 767     const int preserve_register_words = (64 * 2);
 768     Address preserve_addr(FP, (-preserve_register_words * wordSize) + STACK_BIAS);
 769 
 770     Register Lthread = L7_thread_cache;
 771     int i;
 772 
 773     __ save_frame(0);
 774     __ mov(G1, L1);
 775     __ mov(G2, L2);
 776     __ mov(G3, L3);
 777     __ mov(G4, L4);
 778     __ mov(G5, L5);
 779     for (i = 0; i < 64; i += 2) {
 780       __ stf(FloatRegisterImpl::D, as_FloatRegister(i), preserve_addr, i * wordSize);
 781     }
 782 
 783     address entry_point = CAST_FROM_FN_PTR(address, handle_unsafe_access);
 784     BLOCK_COMMENT("call handle_unsafe_access");
 785     __ call(entry_point, relocInfo::runtime_call_type);
 786     __ delayed()->nop();
 787 
 788     __ mov(L1, G1);
 789     __ mov(L2, G2);
 790     __ mov(L3, G3);
 791     __ mov(L4, G4);
 792     __ mov(L5, G5);
 793     for (i = 0; i < 64; i += 2) {
 794       __ ldf(FloatRegisterImpl::D, preserve_addr, as_FloatRegister(i), i * wordSize);
 795     }
 796 
 797     __ verify_thread();
 798 
 799     __ jmp(O0, 0);
 800     __ delayed()->restore();
 801 
 802     return start;
 803   }
 804 
 805 
 806   // Support for uint StubRoutine::Sparc::partial_subtype_check( Klass sub, Klass super );
 807   // Arguments :
 808   //
 809   //      ret  : O0, returned
 810   //      icc/xcc: set as O0 (depending on wordSize)
 811   //      sub  : O1, argument, not changed
 812   //      super: O2, argument, not changed
 813   //      raddr: O7, blown by call
 814   address generate_partial_subtype_check() {
 815     __ align(CodeEntryAlignment);
 816     StubCodeMark mark(this, "StubRoutines", "partial_subtype_check");
 817     address start = __ pc();
 818     Label miss;
 819 
 820 #if defined(COMPILER2) && !defined(_LP64)
 821     // Do not use a 'save' because it blows the 64-bit O registers.
 822     __ add(SP,-4*wordSize,SP);  // Make space for 4 temps (stack must be 2 words aligned)
 823     __ st_ptr(L0,SP,(frame::register_save_words+0)*wordSize);
 824     __ st_ptr(L1,SP,(frame::register_save_words+1)*wordSize);
 825     __ st_ptr(L2,SP,(frame::register_save_words+2)*wordSize);
 826     __ st_ptr(L3,SP,(frame::register_save_words+3)*wordSize);
 827     Register Rret   = O0;
 828     Register Rsub   = O1;
 829     Register Rsuper = O2;
 830 #else
 831     __ save_frame(0);
 832     Register Rret   = I0;
 833     Register Rsub   = I1;
 834     Register Rsuper = I2;
 835 #endif
 836 
 837     Register L0_ary_len = L0;
 838     Register L1_ary_ptr = L1;
 839     Register L2_super   = L2;
 840     Register L3_index   = L3;
 841 
 842     __ check_klass_subtype_slow_path(Rsub, Rsuper,
 843                                      L0, L1, L2, L3,
 844                                      NULL, &miss);
 845 
 846     // Match falls through here.
 847     __ addcc(G0,0,Rret);        // set Z flags, Z result
 848 
 849 #if defined(COMPILER2) && !defined(_LP64)
 850     __ ld_ptr(SP,(frame::register_save_words+0)*wordSize,L0);
 851     __ ld_ptr(SP,(frame::register_save_words+1)*wordSize,L1);
 852     __ ld_ptr(SP,(frame::register_save_words+2)*wordSize,L2);
 853     __ ld_ptr(SP,(frame::register_save_words+3)*wordSize,L3);
 854     __ retl();                  // Result in Rret is zero; flags set to Z
 855     __ delayed()->add(SP,4*wordSize,SP);
 856 #else
 857     __ ret();                   // Result in Rret is zero; flags set to Z
 858     __ delayed()->restore();
 859 #endif
 860 
 861     __ BIND(miss);
 862     __ addcc(G0,1,Rret);        // set NZ flags, NZ result
 863 
 864 #if defined(COMPILER2) && !defined(_LP64)
 865     __ ld_ptr(SP,(frame::register_save_words+0)*wordSize,L0);
 866     __ ld_ptr(SP,(frame::register_save_words+1)*wordSize,L1);
 867     __ ld_ptr(SP,(frame::register_save_words+2)*wordSize,L2);
 868     __ ld_ptr(SP,(frame::register_save_words+3)*wordSize,L3);
 869     __ retl();                  // Result in Rret is != 0; flags set to NZ
 870     __ delayed()->add(SP,4*wordSize,SP);
 871 #else
 872     __ ret();                   // Result in Rret is != 0; flags set to NZ
 873     __ delayed()->restore();
 874 #endif
 875 
 876     return start;
 877   }
 878 
 879 
 880   // Called from MacroAssembler::verify_oop
 881   //
 882   address generate_verify_oop_subroutine() {
 883     StubCodeMark mark(this, "StubRoutines", "verify_oop_stub");
 884 
 885     address start = __ pc();
 886 
 887     __ verify_oop_subroutine();
 888 
 889     return start;
 890   }
 891 
 892 
 893   //
 894   // Verify that a register contains clean 32-bits positive value
 895   // (high 32-bits are 0) so it could be used in 64-bits shifts (sllx, srax).
 896   //
 897   //  Input:
 898   //    Rint  -  32-bits value
 899   //    Rtmp  -  scratch
 900   //
 901   void assert_clean_int(Register Rint, Register Rtmp) {
 902 #if defined(ASSERT) && defined(_LP64)
 903     __ signx(Rint, Rtmp);
 904     __ cmp(Rint, Rtmp);
 905     __ breakpoint_trap(Assembler::notEqual, Assembler::xcc);
 906 #endif
 907   }
 908 
 909   //
 910   //  Generate overlap test for array copy stubs
 911   //
 912   //  Input:
 913   //    O0    -  array1
 914   //    O1    -  array2
 915   //    O2    -  element count
 916   //
 917   //  Kills temps:  O3, O4
 918   //
 919   void array_overlap_test(address no_overlap_target, int log2_elem_size) {
 920     assert(no_overlap_target != NULL, "must be generated");
 921     array_overlap_test(no_overlap_target, NULL, log2_elem_size);
 922   }
 923   void array_overlap_test(Label& L_no_overlap, int log2_elem_size) {
 924     array_overlap_test(NULL, &L_no_overlap, log2_elem_size);
 925   }
 926   void array_overlap_test(address no_overlap_target, Label* NOLp, int log2_elem_size) {
 927     const Register from       = O0;
 928     const Register to         = O1;
 929     const Register count      = O2;
 930     const Register to_from    = O3; // to - from
 931     const Register byte_count = O4; // count << log2_elem_size
 932 
 933       __ subcc(to, from, to_from);
 934       __ sll_ptr(count, log2_elem_size, byte_count);
 935       if (NOLp == NULL)
 936         __ brx(Assembler::lessEqualUnsigned, false, Assembler::pt, no_overlap_target);
 937       else
 938         __ brx(Assembler::lessEqualUnsigned, false, Assembler::pt, (*NOLp));
 939       __ delayed()->cmp(to_from, byte_count);
 940       if (NOLp == NULL)
 941         __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, no_overlap_target);
 942       else
 943         __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, (*NOLp));
 944       __ delayed()->nop();
 945   }
 946 
 947   //
 948   //  Generate pre-write barrier for array.
 949   //
 950   //  Input:
 951   //     addr     - register containing starting address
 952   //     count    - register containing element count
 953   //     tmp      - scratch register
 954   //
 955   //  The input registers are overwritten.
 956   //
 957   void gen_write_ref_array_pre_barrier(Register addr, Register count, bool dest_uninitialized) {
 958     BarrierSet* bs = Universe::heap()->barrier_set();
 959     switch (bs->kind()) {
 960       case BarrierSet::G1SATBCT:
 961       case BarrierSet::G1SATBCTLogging:
 962         // With G1, don't generate the call if we statically know that the target in uninitialized
 963         if (!dest_uninitialized) {
 964           __ save_frame(0);
 965           // Save the necessary global regs... will be used after.
 966           if (addr->is_global()) {
 967             __ mov(addr, L0);
 968           }
 969           if (count->is_global()) {
 970             __ mov(count, L1);
 971           }
 972           __ mov(addr->after_save(), O0);
 973           // Get the count into O1
 974           __ call(CAST_FROM_FN_PTR(address, BarrierSet::static_write_ref_array_pre));
 975           __ delayed()->mov(count->after_save(), O1);
 976           if (addr->is_global()) {
 977             __ mov(L0, addr);
 978           }
 979           if (count->is_global()) {
 980             __ mov(L1, count);
 981           }
 982           __ restore();
 983         }
 984         break;
 985       case BarrierSet::CardTableModRef:
 986       case BarrierSet::CardTableExtension:
 987       case BarrierSet::ModRef:
 988         break;
 989       default:
 990         ShouldNotReachHere();
 991     }
 992   }
 993   //
 994   //  Generate post-write barrier for array.
 995   //
 996   //  Input:
 997   //     addr     - register containing starting address
 998   //     count    - register containing element count
 999   //     tmp      - scratch register
1000   //
1001   //  The input registers are overwritten.
1002   //
1003   void gen_write_ref_array_post_barrier(Register addr, Register count,
1004                                         Register tmp) {
1005     BarrierSet* bs = Universe::heap()->barrier_set();
1006 
1007     switch (bs->kind()) {
1008       case BarrierSet::G1SATBCT:
1009       case BarrierSet::G1SATBCTLogging:
1010         {
1011           // Get some new fresh output registers.
1012           __ save_frame(0);
1013           __ mov(addr->after_save(), O0);
1014           __ call(CAST_FROM_FN_PTR(address, BarrierSet::static_write_ref_array_post));
1015           __ delayed()->mov(count->after_save(), O1);
1016           __ restore();
1017         }
1018         break;
1019       case BarrierSet::CardTableModRef:
1020       case BarrierSet::CardTableExtension:
1021         {
1022           CardTableModRefBS* ct = (CardTableModRefBS*)bs;
1023           assert(sizeof(*ct->byte_map_base) == sizeof(jbyte), "adjust this code");
1024           assert_different_registers(addr, count, tmp);
1025 
1026           Label L_loop;
1027 
1028           __ sll_ptr(count, LogBytesPerHeapOop, count);
1029           __ sub(count, BytesPerHeapOop, count);
1030           __ add(count, addr, count);
1031           // Use two shifts to clear out those low order two bits! (Cannot opt. into 1.)
1032           __ srl_ptr(addr, CardTableModRefBS::card_shift, addr);
1033           __ srl_ptr(count, CardTableModRefBS::card_shift, count);
1034           __ sub(count, addr, count);
1035           AddressLiteral rs(ct->byte_map_base);
1036           __ set(rs, tmp);
1037         __ BIND(L_loop);
1038           __ stb(G0, tmp, addr);
1039           __ subcc(count, 1, count);
1040           __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
1041           __ delayed()->add(addr, 1, addr);
1042         }
1043         break;
1044       case BarrierSet::ModRef:
1045         break;
1046       default:
1047         ShouldNotReachHere();
1048     }
1049   }
1050 
1051   //
1052   // Generate main code for disjoint arraycopy
1053   //
1054   typedef void (StubGenerator::*CopyLoopFunc)(Register from, Register to, Register count, int count_dec,
1055                                               Label& L_loop, bool use_prefetch, bool use_bis);
1056 
1057   void disjoint_copy_core(Register from, Register to, Register count, int log2_elem_size,
1058                           int iter_size, StubGenerator::CopyLoopFunc copy_loop_func) {
1059     Label L_copy;
1060 
1061     assert(log2_elem_size <= 3, "the following code should be changed");
1062     int count_dec = 16>>log2_elem_size;
1063 
1064     int prefetch_dist = MAX2(ArraycopySrcPrefetchDistance, ArraycopyDstPrefetchDistance);
1065     assert(prefetch_dist < 4096, "invalid value");
1066     prefetch_dist = (prefetch_dist + (iter_size-1)) & (-iter_size); // round up to one iteration copy size
1067     int prefetch_count = (prefetch_dist >> log2_elem_size); // elements count
1068 
1069     if (UseBlockCopy) {
1070       Label L_block_copy, L_block_copy_prefetch, L_skip_block_copy;
1071 
1072       // 64 bytes tail + bytes copied in one loop iteration
1073       int tail_size = 64 + iter_size;
1074       int block_copy_count = (MAX2(tail_size, (int)BlockCopyLowLimit)) >> log2_elem_size;
1075       // Use BIS copy only for big arrays since it requires membar.
1076       __ set(block_copy_count, O4);
1077       __ cmp_and_br_short(count, O4, Assembler::lessUnsigned, Assembler::pt, L_skip_block_copy);
1078       // This code is for disjoint source and destination:
1079       //   to <= from || to >= from+count
1080       // but BIS will stomp over 'from' if (to > from-tail_size && to <= from)
1081       __ sub(from, to, O4);
1082       __ srax(O4, 4, O4); // divide by 16 since following short branch have only 5 bits for imm.
1083       __ cmp_and_br_short(O4, (tail_size>>4), Assembler::lessEqualUnsigned, Assembler::pn, L_skip_block_copy);
1084 
1085       __ wrasi(G0, Assembler::ASI_ST_BLKINIT_PRIMARY);
1086       // BIS should not be used to copy tail (64 bytes+iter_size)
1087       // to avoid zeroing of following values.
1088       __ sub(count, (tail_size>>log2_elem_size), count); // count is still positive >= 0
1089 
1090       if (prefetch_count > 0) { // rounded up to one iteration count
1091         // Do prefetching only if copy size is bigger
1092         // than prefetch distance.
1093         __ set(prefetch_count, O4);
1094         __ cmp_and_brx_short(count, O4, Assembler::less, Assembler::pt, L_block_copy);
1095         __ sub(count, prefetch_count, count);
1096 
1097         (this->*copy_loop_func)(from, to, count, count_dec, L_block_copy_prefetch, true, true);
1098         __ add(count, prefetch_count, count); // restore count
1099 
1100       } // prefetch_count > 0
1101 
1102       (this->*copy_loop_func)(from, to, count, count_dec, L_block_copy, false, true);
1103       __ add(count, (tail_size>>log2_elem_size), count); // restore count
1104 
1105       __ wrasi(G0, Assembler::ASI_PRIMARY_NOFAULT);
1106       // BIS needs membar.
1107       __ membar(Assembler::StoreLoad);
1108       // Copy tail
1109       __ ba_short(L_copy);
1110 
1111       __ BIND(L_skip_block_copy);
1112     } // UseBlockCopy
1113 
1114     if (prefetch_count > 0) { // rounded up to one iteration count
1115       // Do prefetching only if copy size is bigger
1116       // than prefetch distance.
1117       __ set(prefetch_count, O4);
1118       __ cmp_and_brx_short(count, O4, Assembler::lessUnsigned, Assembler::pt, L_copy);
1119       __ sub(count, prefetch_count, count);
1120 
1121       Label L_copy_prefetch;
1122       (this->*copy_loop_func)(from, to, count, count_dec, L_copy_prefetch, true, false);
1123       __ add(count, prefetch_count, count); // restore count
1124 
1125     } // prefetch_count > 0
1126 
1127     (this->*copy_loop_func)(from, to, count, count_dec, L_copy, false, false);
1128   }
1129 
1130 
1131 
1132   //
1133   // Helper methods for copy_16_bytes_forward_with_shift()
1134   //
1135   void copy_16_bytes_shift_loop(Register from, Register to, Register count, int count_dec,
1136                                 Label& L_loop, bool use_prefetch, bool use_bis) {
1137 
1138     const Register left_shift  = G1; // left  shift bit counter
1139     const Register right_shift = G5; // right shift bit counter
1140 
1141     __ align(OptoLoopAlignment);
1142     __ BIND(L_loop);
1143     if (use_prefetch) {
1144       if (ArraycopySrcPrefetchDistance > 0) {
1145         __ prefetch(from, ArraycopySrcPrefetchDistance, Assembler::severalReads);
1146       }
1147       if (ArraycopyDstPrefetchDistance > 0) {
1148         __ prefetch(to, ArraycopyDstPrefetchDistance, Assembler::severalWritesAndPossiblyReads);
1149       }
1150     }
1151     __ ldx(from, 0, O4);
1152     __ ldx(from, 8, G4);
1153     __ inc(to, 16);
1154     __ inc(from, 16);
1155     __ deccc(count, count_dec); // Can we do next iteration after this one?
1156     __ srlx(O4, right_shift, G3);
1157     __ bset(G3, O3);
1158     __ sllx(O4, left_shift,  O4);
1159     __ srlx(G4, right_shift, G3);
1160     __ bset(G3, O4);
1161     if (use_bis) {
1162       __ stxa(O3, to, -16);
1163       __ stxa(O4, to, -8);
1164     } else {
1165       __ stx(O3, to, -16);
1166       __ stx(O4, to, -8);
1167     }
1168     __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
1169     __ delayed()->sllx(G4, left_shift,  O3);
1170   }
1171 
1172   // Copy big chunks forward with shift
1173   //
1174   // Inputs:
1175   //   from      - source arrays
1176   //   to        - destination array aligned to 8-bytes
1177   //   count     - elements count to copy >= the count equivalent to 16 bytes
1178   //   count_dec - elements count's decrement equivalent to 16 bytes
1179   //   L_copy_bytes - copy exit label
1180   //
1181   void copy_16_bytes_forward_with_shift(Register from, Register to,
1182                      Register count, int log2_elem_size, Label& L_copy_bytes) {
1183     Label L_aligned_copy, L_copy_last_bytes;
1184     assert(log2_elem_size <= 3, "the following code should be changed");
1185     int count_dec = 16>>log2_elem_size;
1186 
1187     // if both arrays have the same alignment mod 8, do 8 bytes aligned copy
1188     __ andcc(from, 7, G1); // misaligned bytes
1189     __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
1190     __ delayed()->nop();
1191 
1192     const Register left_shift  = G1; // left  shift bit counter
1193     const Register right_shift = G5; // right shift bit counter
1194 
1195     __ sll(G1, LogBitsPerByte, left_shift);
1196     __ mov(64, right_shift);
1197     __ sub(right_shift, left_shift, right_shift);
1198 
1199     //
1200     // Load 2 aligned 8-bytes chunks and use one from previous iteration
1201     // to form 2 aligned 8-bytes chunks to store.
1202     //
1203     __ dec(count, count_dec);   // Pre-decrement 'count'
1204     __ andn(from, 7, from);     // Align address
1205     __ ldx(from, 0, O3);
1206     __ inc(from, 8);
1207     __ sllx(O3, left_shift,  O3);
1208 
1209     disjoint_copy_core(from, to, count, log2_elem_size, 16, &StubGenerator::copy_16_bytes_shift_loop);
1210 
1211     __ inccc(count, count_dec>>1 ); // + 8 bytes
1212     __ brx(Assembler::negative, true, Assembler::pn, L_copy_last_bytes);
1213     __ delayed()->inc(count, count_dec>>1); // restore 'count'
1214 
1215     // copy 8 bytes, part of them already loaded in O3
1216     __ ldx(from, 0, O4);
1217     __ inc(to, 8);
1218     __ inc(from, 8);
1219     __ srlx(O4, right_shift, G3);
1220     __ bset(O3, G3);
1221     __ stx(G3, to, -8);
1222 
1223     __ BIND(L_copy_last_bytes);
1224     __ srl(right_shift, LogBitsPerByte, right_shift); // misaligned bytes
1225     __ br(Assembler::always, false, Assembler::pt, L_copy_bytes);
1226     __ delayed()->sub(from, right_shift, from);       // restore address
1227 
1228     __ BIND(L_aligned_copy);
1229   }
1230 
1231   // Copy big chunks backward with shift
1232   //
1233   // Inputs:
1234   //   end_from  - source arrays end address
1235   //   end_to    - destination array end address aligned to 8-bytes
1236   //   count     - elements count to copy >= the count equivalent to 16 bytes
1237   //   count_dec - elements count's decrement equivalent to 16 bytes
1238   //   L_aligned_copy - aligned copy exit label
1239   //   L_copy_bytes   - copy exit label
1240   //
1241   void copy_16_bytes_backward_with_shift(Register end_from, Register end_to,
1242                      Register count, int count_dec,
1243                      Label& L_aligned_copy, Label& L_copy_bytes) {
1244     Label L_loop, L_copy_last_bytes;
1245 
1246     // if both arrays have the same alignment mod 8, do 8 bytes aligned copy
1247       __ andcc(end_from, 7, G1); // misaligned bytes
1248       __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
1249       __ delayed()->deccc(count, count_dec); // Pre-decrement 'count'
1250 
1251     const Register left_shift  = G1; // left  shift bit counter
1252     const Register right_shift = G5; // right shift bit counter
1253 
1254       __ sll(G1, LogBitsPerByte, left_shift);
1255       __ mov(64, right_shift);
1256       __ sub(right_shift, left_shift, right_shift);
1257 
1258     //
1259     // Load 2 aligned 8-bytes chunks and use one from previous iteration
1260     // to form 2 aligned 8-bytes chunks to store.
1261     //
1262       __ andn(end_from, 7, end_from);     // Align address
1263       __ ldx(end_from, 0, O3);
1264       __ align(OptoLoopAlignment);
1265     __ BIND(L_loop);
1266       __ ldx(end_from, -8, O4);
1267       __ deccc(count, count_dec); // Can we do next iteration after this one?
1268       __ ldx(end_from, -16, G4);
1269       __ dec(end_to, 16);
1270       __ dec(end_from, 16);
1271       __ srlx(O3, right_shift, O3);
1272       __ sllx(O4, left_shift,  G3);
1273       __ bset(G3, O3);
1274       __ stx(O3, end_to, 8);
1275       __ srlx(O4, right_shift, O4);
1276       __ sllx(G4, left_shift,  G3);
1277       __ bset(G3, O4);
1278       __ stx(O4, end_to, 0);
1279       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
1280       __ delayed()->mov(G4, O3);
1281 
1282       __ inccc(count, count_dec>>1 ); // + 8 bytes
1283       __ brx(Assembler::negative, true, Assembler::pn, L_copy_last_bytes);
1284       __ delayed()->inc(count, count_dec>>1); // restore 'count'
1285 
1286       // copy 8 bytes, part of them already loaded in O3
1287       __ ldx(end_from, -8, O4);
1288       __ dec(end_to, 8);
1289       __ dec(end_from, 8);
1290       __ srlx(O3, right_shift, O3);
1291       __ sllx(O4, left_shift,  G3);
1292       __ bset(O3, G3);
1293       __ stx(G3, end_to, 0);
1294 
1295     __ BIND(L_copy_last_bytes);
1296       __ srl(left_shift, LogBitsPerByte, left_shift);    // misaligned bytes
1297       __ br(Assembler::always, false, Assembler::pt, L_copy_bytes);
1298       __ delayed()->add(end_from, left_shift, end_from); // restore address
1299   }
1300 
1301   //
1302   //  Generate stub for disjoint byte copy.  If "aligned" is true, the
1303   //  "from" and "to" addresses are assumed to be heapword aligned.
1304   //
1305   // Arguments for generated stub:
1306   //      from:  O0
1307   //      to:    O1
1308   //      count: O2 treated as signed
1309   //
1310   address generate_disjoint_byte_copy(bool aligned, address *entry, const char *name) {
1311     __ align(CodeEntryAlignment);
1312     StubCodeMark mark(this, "StubRoutines", name);
1313     address start = __ pc();
1314 
1315     Label L_skip_alignment, L_align;
1316     Label L_copy_byte, L_copy_byte_loop, L_exit;
1317 
1318     const Register from      = O0;   // source array address
1319     const Register to        = O1;   // destination array address
1320     const Register count     = O2;   // elements count
1321     const Register offset    = O5;   // offset from start of arrays
1322     // O3, O4, G3, G4 are used as temp registers
1323 
1324     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
1325 
1326     if (entry != NULL) {
1327       *entry = __ pc();
1328       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
1329       BLOCK_COMMENT("Entry:");
1330     }
1331 
1332     // for short arrays, just do single element copy
1333     __ cmp(count, 23); // 16 + 7
1334     __ brx(Assembler::less, false, Assembler::pn, L_copy_byte);
1335     __ delayed()->mov(G0, offset);
1336 
1337     if (aligned) {
1338       // 'aligned' == true when it is known statically during compilation
1339       // of this arraycopy call site that both 'from' and 'to' addresses
1340       // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
1341       //
1342       // Aligned arrays have 4 bytes alignment in 32-bits VM
1343       // and 8 bytes - in 64-bits VM. So we do it only for 32-bits VM
1344       //
1345 #ifndef _LP64
1346       // copy a 4-bytes word if necessary to align 'to' to 8 bytes
1347       __ andcc(to, 7, G0);
1348       __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment);
1349       __ delayed()->ld(from, 0, O3);
1350       __ inc(from, 4);
1351       __ inc(to, 4);
1352       __ dec(count, 4);
1353       __ st(O3, to, -4);
1354     __ BIND(L_skip_alignment);
1355 #endif
1356     } else {
1357       // copy bytes to align 'to' on 8 byte boundary
1358       __ andcc(to, 7, G1); // misaligned bytes
1359       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
1360       __ delayed()->neg(G1);
1361       __ inc(G1, 8);       // bytes need to copy to next 8-bytes alignment
1362       __ sub(count, G1, count);
1363     __ BIND(L_align);
1364       __ ldub(from, 0, O3);
1365       __ deccc(G1);
1366       __ inc(from);
1367       __ stb(O3, to, 0);
1368       __ br(Assembler::notZero, false, Assembler::pt, L_align);
1369       __ delayed()->inc(to);
1370     __ BIND(L_skip_alignment);
1371     }
1372 #ifdef _LP64
1373     if (!aligned)
1374 #endif
1375     {
1376       // Copy with shift 16 bytes per iteration if arrays do not have
1377       // the same alignment mod 8, otherwise fall through to the next
1378       // code for aligned copy.
1379       // The compare above (count >= 23) guarantes 'count' >= 16 bytes.
1380       // Also jump over aligned copy after the copy with shift completed.
1381 
1382       copy_16_bytes_forward_with_shift(from, to, count, 0, L_copy_byte);
1383     }
1384 
1385     // Both array are 8 bytes aligned, copy 16 bytes at a time
1386       __ and3(count, 7, G4); // Save count
1387       __ srl(count, 3, count);
1388      generate_disjoint_long_copy_core(aligned);
1389       __ mov(G4, count);     // Restore count
1390 
1391     // copy tailing bytes
1392     __ BIND(L_copy_byte);
1393       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1394       __ align(OptoLoopAlignment);
1395     __ BIND(L_copy_byte_loop);
1396       __ ldub(from, offset, O3);
1397       __ deccc(count);
1398       __ stb(O3, to, offset);
1399       __ brx(Assembler::notZero, false, Assembler::pt, L_copy_byte_loop);
1400       __ delayed()->inc(offset);
1401 
1402     __ BIND(L_exit);
1403       // O3, O4 are used as temp registers
1404       inc_counter_np(SharedRuntime::_jbyte_array_copy_ctr, O3, O4);
1405       __ retl();
1406       __ delayed()->mov(G0, O0); // return 0
1407     return start;
1408   }
1409 
1410   //
1411   //  Generate stub for conjoint byte copy.  If "aligned" is true, the
1412   //  "from" and "to" addresses are assumed to be heapword aligned.
1413   //
1414   // Arguments for generated stub:
1415   //      from:  O0
1416   //      to:    O1
1417   //      count: O2 treated as signed
1418   //
1419   address generate_conjoint_byte_copy(bool aligned, address nooverlap_target,
1420                                       address *entry, const char *name) {
1421     // Do reverse copy.
1422 
1423     __ align(CodeEntryAlignment);
1424     StubCodeMark mark(this, "StubRoutines", name);
1425     address start = __ pc();
1426 
1427     Label L_skip_alignment, L_align, L_aligned_copy;
1428     Label L_copy_byte, L_copy_byte_loop, L_exit;
1429 
1430     const Register from      = O0;   // source array address
1431     const Register to        = O1;   // destination array address
1432     const Register count     = O2;   // elements count
1433     const Register end_from  = from; // source array end address
1434     const Register end_to    = to;   // destination array end address
1435 
1436     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
1437 
1438     if (entry != NULL) {
1439       *entry = __ pc();
1440       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
1441       BLOCK_COMMENT("Entry:");
1442     }
1443 
1444     array_overlap_test(nooverlap_target, 0);
1445 
1446     __ add(to, count, end_to);       // offset after last copied element
1447 
1448     // for short arrays, just do single element copy
1449     __ cmp(count, 23); // 16 + 7
1450     __ brx(Assembler::less, false, Assembler::pn, L_copy_byte);
1451     __ delayed()->add(from, count, end_from);
1452 
1453     {
1454       // Align end of arrays since they could be not aligned even
1455       // when arrays itself are aligned.
1456 
1457       // copy bytes to align 'end_to' on 8 byte boundary
1458       __ andcc(end_to, 7, G1); // misaligned bytes
1459       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
1460       __ delayed()->nop();
1461       __ sub(count, G1, count);
1462     __ BIND(L_align);
1463       __ dec(end_from);
1464       __ dec(end_to);
1465       __ ldub(end_from, 0, O3);
1466       __ deccc(G1);
1467       __ brx(Assembler::notZero, false, Assembler::pt, L_align);
1468       __ delayed()->stb(O3, end_to, 0);
1469     __ BIND(L_skip_alignment);
1470     }
1471 #ifdef _LP64
1472     if (aligned) {
1473       // Both arrays are aligned to 8-bytes in 64-bits VM.
1474       // The 'count' is decremented in copy_16_bytes_backward_with_shift()
1475       // in unaligned case.
1476       __ dec(count, 16);
1477     } else
1478 #endif
1479     {
1480       // Copy with shift 16 bytes per iteration if arrays do not have
1481       // the same alignment mod 8, otherwise jump to the next
1482       // code for aligned copy (and substracting 16 from 'count' before jump).
1483       // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
1484       // Also jump over aligned copy after the copy with shift completed.
1485 
1486       copy_16_bytes_backward_with_shift(end_from, end_to, count, 16,
1487                                         L_aligned_copy, L_copy_byte);
1488     }
1489     // copy 4 elements (16 bytes) at a time
1490       __ align(OptoLoopAlignment);
1491     __ BIND(L_aligned_copy);
1492       __ dec(end_from, 16);
1493       __ ldx(end_from, 8, O3);
1494       __ ldx(end_from, 0, O4);
1495       __ dec(end_to, 16);
1496       __ deccc(count, 16);
1497       __ stx(O3, end_to, 8);
1498       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
1499       __ delayed()->stx(O4, end_to, 0);
1500       __ inc(count, 16);
1501 
1502     // copy 1 element (2 bytes) at a time
1503     __ BIND(L_copy_byte);
1504       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1505       __ align(OptoLoopAlignment);
1506     __ BIND(L_copy_byte_loop);
1507       __ dec(end_from);
1508       __ dec(end_to);
1509       __ ldub(end_from, 0, O4);
1510       __ deccc(count);
1511       __ brx(Assembler::greater, false, Assembler::pt, L_copy_byte_loop);
1512       __ delayed()->stb(O4, end_to, 0);
1513 
1514     __ BIND(L_exit);
1515     // O3, O4 are used as temp registers
1516     inc_counter_np(SharedRuntime::_jbyte_array_copy_ctr, O3, O4);
1517     __ retl();
1518     __ delayed()->mov(G0, O0); // return 0
1519     return start;
1520   }
1521 
1522   //
1523   //  Generate stub for disjoint short copy.  If "aligned" is true, the
1524   //  "from" and "to" addresses are assumed to be heapword aligned.
1525   //
1526   // Arguments for generated stub:
1527   //      from:  O0
1528   //      to:    O1
1529   //      count: O2 treated as signed
1530   //
1531   address generate_disjoint_short_copy(bool aligned, address *entry, const char * name) {
1532     __ align(CodeEntryAlignment);
1533     StubCodeMark mark(this, "StubRoutines", name);
1534     address start = __ pc();
1535 
1536     Label L_skip_alignment, L_skip_alignment2;
1537     Label L_copy_2_bytes, L_copy_2_bytes_loop, L_exit;
1538 
1539     const Register from      = O0;   // source array address
1540     const Register to        = O1;   // destination array address
1541     const Register count     = O2;   // elements count
1542     const Register offset    = O5;   // offset from start of arrays
1543     // O3, O4, G3, G4 are used as temp registers
1544 
1545     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
1546 
1547     if (entry != NULL) {
1548       *entry = __ pc();
1549       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
1550       BLOCK_COMMENT("Entry:");
1551     }
1552 
1553     // for short arrays, just do single element copy
1554     __ cmp(count, 11); // 8 + 3  (22 bytes)
1555     __ brx(Assembler::less, false, Assembler::pn, L_copy_2_bytes);
1556     __ delayed()->mov(G0, offset);
1557 
1558     if (aligned) {
1559       // 'aligned' == true when it is known statically during compilation
1560       // of this arraycopy call site that both 'from' and 'to' addresses
1561       // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
1562       //
1563       // Aligned arrays have 4 bytes alignment in 32-bits VM
1564       // and 8 bytes - in 64-bits VM.
1565       //
1566 #ifndef _LP64
1567       // copy a 2-elements word if necessary to align 'to' to 8 bytes
1568       __ andcc(to, 7, G0);
1569       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
1570       __ delayed()->ld(from, 0, O3);
1571       __ inc(from, 4);
1572       __ inc(to, 4);
1573       __ dec(count, 2);
1574       __ st(O3, to, -4);
1575     __ BIND(L_skip_alignment);
1576 #endif
1577     } else {
1578       // copy 1 element if necessary to align 'to' on an 4 bytes
1579       __ andcc(to, 3, G0);
1580       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
1581       __ delayed()->lduh(from, 0, O3);
1582       __ inc(from, 2);
1583       __ inc(to, 2);
1584       __ dec(count);
1585       __ sth(O3, to, -2);
1586     __ BIND(L_skip_alignment);
1587 
1588       // copy 2 elements to align 'to' on an 8 byte boundary
1589       __ andcc(to, 7, G0);
1590       __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment2);
1591       __ delayed()->lduh(from, 0, O3);
1592       __ dec(count, 2);
1593       __ lduh(from, 2, O4);
1594       __ inc(from, 4);
1595       __ inc(to, 4);
1596       __ sth(O3, to, -4);
1597       __ sth(O4, to, -2);
1598     __ BIND(L_skip_alignment2);
1599     }
1600 #ifdef _LP64
1601     if (!aligned)
1602 #endif
1603     {
1604       // Copy with shift 16 bytes per iteration if arrays do not have
1605       // the same alignment mod 8, otherwise fall through to the next
1606       // code for aligned copy.
1607       // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
1608       // Also jump over aligned copy after the copy with shift completed.
1609 
1610       copy_16_bytes_forward_with_shift(from, to, count, 1, L_copy_2_bytes);
1611     }
1612 
1613     // Both array are 8 bytes aligned, copy 16 bytes at a time
1614       __ and3(count, 3, G4); // Save
1615       __ srl(count, 2, count);
1616      generate_disjoint_long_copy_core(aligned);
1617       __ mov(G4, count); // restore
1618 
1619     // copy 1 element at a time
1620     __ BIND(L_copy_2_bytes);
1621       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1622       __ align(OptoLoopAlignment);
1623     __ BIND(L_copy_2_bytes_loop);
1624       __ lduh(from, offset, O3);
1625       __ deccc(count);
1626       __ sth(O3, to, offset);
1627       __ brx(Assembler::notZero, false, Assembler::pt, L_copy_2_bytes_loop);
1628       __ delayed()->inc(offset, 2);
1629 
1630     __ BIND(L_exit);
1631       // O3, O4 are used as temp registers
1632       inc_counter_np(SharedRuntime::_jshort_array_copy_ctr, O3, O4);
1633       __ retl();
1634       __ delayed()->mov(G0, O0); // return 0
1635     return start;
1636   }
1637 
1638   //
1639   //  Generate stub for disjoint short fill.  If "aligned" is true, the
1640   //  "to" address is assumed to be heapword aligned.
1641   //
1642   // Arguments for generated stub:
1643   //      to:    O0
1644   //      value: O1
1645   //      count: O2 treated as signed
1646   //
1647   address generate_fill(BasicType t, bool aligned, const char* name) {
1648     __ align(CodeEntryAlignment);
1649     StubCodeMark mark(this, "StubRoutines", name);
1650     address start = __ pc();
1651 
1652     const Register to        = O0;   // source array address
1653     const Register value     = O1;   // fill value
1654     const Register count     = O2;   // elements count
1655     // O3 is used as a temp register
1656 
1657     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
1658 
1659     Label L_exit, L_skip_align1, L_skip_align2, L_fill_byte;
1660     Label L_fill_2_bytes, L_fill_elements, L_fill_32_bytes;
1661 
1662     int shift = -1;
1663     switch (t) {
1664        case T_BYTE:
1665         shift = 2;
1666         break;
1667        case T_SHORT:
1668         shift = 1;
1669         break;
1670       case T_INT:
1671          shift = 0;
1672         break;
1673       default: ShouldNotReachHere();
1674     }
1675 
1676     BLOCK_COMMENT("Entry:");
1677 
1678     if (t == T_BYTE) {
1679       // Zero extend value
1680       __ and3(value, 0xff, value);
1681       __ sllx(value, 8, O3);
1682       __ or3(value, O3, value);
1683     }
1684     if (t == T_SHORT) {
1685       // Zero extend value
1686       __ sllx(value, 48, value);
1687       __ srlx(value, 48, value);
1688     }
1689     if (t == T_BYTE || t == T_SHORT) {
1690       __ sllx(value, 16, O3);
1691       __ or3(value, O3, value);
1692     }
1693 
1694     __ cmp(count, 2<<shift); // Short arrays (< 8 bytes) fill by element
1695     __ brx(Assembler::lessUnsigned, false, Assembler::pn, L_fill_elements); // use unsigned cmp
1696     __ delayed()->andcc(count, 1, G0);
1697 
1698     if (!aligned && (t == T_BYTE || t == T_SHORT)) {
1699       // align source address at 4 bytes address boundary
1700       if (t == T_BYTE) {
1701         // One byte misalignment happens only for byte arrays
1702         __ andcc(to, 1, G0);
1703         __ br(Assembler::zero, false, Assembler::pt, L_skip_align1);
1704         __ delayed()->nop();
1705         __ stb(value, to, 0);
1706         __ inc(to, 1);
1707         __ dec(count, 1);
1708         __ BIND(L_skip_align1);
1709       }
1710       // Two bytes misalignment happens only for byte and short (char) arrays
1711       __ andcc(to, 2, G0);
1712       __ br(Assembler::zero, false, Assembler::pt, L_skip_align2);
1713       __ delayed()->nop();
1714       __ sth(value, to, 0);
1715       __ inc(to, 2);
1716       __ dec(count, 1 << (shift - 1));
1717       __ BIND(L_skip_align2);
1718     }
1719 #ifdef _LP64
1720     if (!aligned) {
1721 #endif
1722     // align to 8 bytes, we know we are 4 byte aligned to start
1723     __ andcc(to, 7, G0);
1724     __ br(Assembler::zero, false, Assembler::pt, L_fill_32_bytes);
1725     __ delayed()->nop();
1726     __ stw(value, to, 0);
1727     __ inc(to, 4);
1728     __ dec(count, 1 << shift);
1729     __ BIND(L_fill_32_bytes);
1730 #ifdef _LP64
1731     }
1732 #endif
1733 
1734     if (t == T_INT) {
1735       // Zero extend value
1736       __ srl(value, 0, value);
1737     }
1738     if (t == T_BYTE || t == T_SHORT || t == T_INT) {
1739       __ sllx(value, 32, O3);
1740       __ or3(value, O3, value);
1741     }
1742 
1743     Label L_check_fill_8_bytes;
1744     // Fill 32-byte chunks
1745     __ subcc(count, 8 << shift, count);
1746     __ brx(Assembler::less, false, Assembler::pt, L_check_fill_8_bytes);
1747     __ delayed()->nop();
1748 
1749     Label L_fill_32_bytes_loop, L_fill_4_bytes;
1750     __ align(16);
1751     __ BIND(L_fill_32_bytes_loop);
1752 
1753     __ stx(value, to, 0);
1754     __ stx(value, to, 8);
1755     __ stx(value, to, 16);
1756     __ stx(value, to, 24);
1757 
1758     __ subcc(count, 8 << shift, count);
1759     __ brx(Assembler::greaterEqual, false, Assembler::pt, L_fill_32_bytes_loop);
1760     __ delayed()->add(to, 32, to);
1761 
1762     __ BIND(L_check_fill_8_bytes);
1763     __ addcc(count, 8 << shift, count);
1764     __ brx(Assembler::zero, false, Assembler::pn, L_exit);
1765     __ delayed()->subcc(count, 1 << (shift + 1), count);
1766     __ brx(Assembler::less, false, Assembler::pn, L_fill_4_bytes);
1767     __ delayed()->andcc(count, 1<<shift, G0);
1768 
1769     //
1770     // length is too short, just fill 8 bytes at a time
1771     //
1772     Label L_fill_8_bytes_loop;
1773     __ BIND(L_fill_8_bytes_loop);
1774     __ stx(value, to, 0);
1775     __ subcc(count, 1 << (shift + 1), count);
1776     __ brx(Assembler::greaterEqual, false, Assembler::pn, L_fill_8_bytes_loop);
1777     __ delayed()->add(to, 8, to);
1778 
1779     // fill trailing 4 bytes
1780     __ andcc(count, 1<<shift, G0);  // in delay slot of branches
1781     if (t == T_INT) {
1782       __ BIND(L_fill_elements);
1783     }
1784     __ BIND(L_fill_4_bytes);
1785     __ brx(Assembler::zero, false, Assembler::pt, L_fill_2_bytes);
1786     if (t == T_BYTE || t == T_SHORT) {
1787       __ delayed()->andcc(count, 1<<(shift-1), G0);
1788     } else {
1789       __ delayed()->nop();
1790     }
1791     __ stw(value, to, 0);
1792     if (t == T_BYTE || t == T_SHORT) {
1793       __ inc(to, 4);
1794       // fill trailing 2 bytes
1795       __ andcc(count, 1<<(shift-1), G0); // in delay slot of branches
1796       __ BIND(L_fill_2_bytes);
1797       __ brx(Assembler::zero, false, Assembler::pt, L_fill_byte);
1798       __ delayed()->andcc(count, 1, count);
1799       __ sth(value, to, 0);
1800       if (t == T_BYTE) {
1801         __ inc(to, 2);
1802         // fill trailing byte
1803         __ andcc(count, 1, count);  // in delay slot of branches
1804         __ BIND(L_fill_byte);
1805         __ brx(Assembler::zero, false, Assembler::pt, L_exit);
1806         __ delayed()->nop();
1807         __ stb(value, to, 0);
1808       } else {
1809         __ BIND(L_fill_byte);
1810       }
1811     } else {
1812       __ BIND(L_fill_2_bytes);
1813     }
1814     __ BIND(L_exit);
1815     __ retl();
1816     __ delayed()->nop();
1817 
1818     // Handle copies less than 8 bytes.  Int is handled elsewhere.
1819     if (t == T_BYTE) {
1820       __ BIND(L_fill_elements);
1821       Label L_fill_2, L_fill_4;
1822       // in delay slot __ andcc(count, 1, G0);
1823       __ brx(Assembler::zero, false, Assembler::pt, L_fill_2);
1824       __ delayed()->andcc(count, 2, G0);
1825       __ stb(value, to, 0);
1826       __ inc(to, 1);
1827       __ BIND(L_fill_2);
1828       __ brx(Assembler::zero, false, Assembler::pt, L_fill_4);
1829       __ delayed()->andcc(count, 4, G0);
1830       __ stb(value, to, 0);
1831       __ stb(value, to, 1);
1832       __ inc(to, 2);
1833       __ BIND(L_fill_4);
1834       __ brx(Assembler::zero, false, Assembler::pt, L_exit);
1835       __ delayed()->nop();
1836       __ stb(value, to, 0);
1837       __ stb(value, to, 1);
1838       __ stb(value, to, 2);
1839       __ retl();
1840       __ delayed()->stb(value, to, 3);
1841     }
1842 
1843     if (t == T_SHORT) {
1844       Label L_fill_2;
1845       __ BIND(L_fill_elements);
1846       // in delay slot __ andcc(count, 1, G0);
1847       __ brx(Assembler::zero, false, Assembler::pt, L_fill_2);
1848       __ delayed()->andcc(count, 2, G0);
1849       __ sth(value, to, 0);
1850       __ inc(to, 2);
1851       __ BIND(L_fill_2);
1852       __ brx(Assembler::zero, false, Assembler::pt, L_exit);
1853       __ delayed()->nop();
1854       __ sth(value, to, 0);
1855       __ retl();
1856       __ delayed()->sth(value, to, 2);
1857     }
1858     return start;
1859   }
1860 
1861   //
1862   //  Generate stub for conjoint short copy.  If "aligned" is true, the
1863   //  "from" and "to" addresses are assumed to be heapword aligned.
1864   //
1865   // Arguments for generated stub:
1866   //      from:  O0
1867   //      to:    O1
1868   //      count: O2 treated as signed
1869   //
1870   address generate_conjoint_short_copy(bool aligned, address nooverlap_target,
1871                                        address *entry, const char *name) {
1872     // Do reverse copy.
1873 
1874     __ align(CodeEntryAlignment);
1875     StubCodeMark mark(this, "StubRoutines", name);
1876     address start = __ pc();
1877 
1878     Label L_skip_alignment, L_skip_alignment2, L_aligned_copy;
1879     Label L_copy_2_bytes, L_copy_2_bytes_loop, L_exit;
1880 
1881     const Register from      = O0;   // source array address
1882     const Register to        = O1;   // destination array address
1883     const Register count     = O2;   // elements count
1884     const Register end_from  = from; // source array end address
1885     const Register end_to    = to;   // destination array end address
1886 
1887     const Register byte_count = O3;  // bytes count to copy
1888 
1889     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
1890 
1891     if (entry != NULL) {
1892       *entry = __ pc();
1893       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
1894       BLOCK_COMMENT("Entry:");
1895     }
1896 
1897     array_overlap_test(nooverlap_target, 1);
1898 
1899     __ sllx(count, LogBytesPerShort, byte_count);
1900     __ add(to, byte_count, end_to);  // offset after last copied element
1901 
1902     // for short arrays, just do single element copy
1903     __ cmp(count, 11); // 8 + 3  (22 bytes)
1904     __ brx(Assembler::less, false, Assembler::pn, L_copy_2_bytes);
1905     __ delayed()->add(from, byte_count, end_from);
1906 
1907     {
1908       // Align end of arrays since they could be not aligned even
1909       // when arrays itself are aligned.
1910 
1911       // copy 1 element if necessary to align 'end_to' on an 4 bytes
1912       __ andcc(end_to, 3, G0);
1913       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
1914       __ delayed()->lduh(end_from, -2, O3);
1915       __ dec(end_from, 2);
1916       __ dec(end_to, 2);
1917       __ dec(count);
1918       __ sth(O3, end_to, 0);
1919     __ BIND(L_skip_alignment);
1920 
1921       // copy 2 elements to align 'end_to' on an 8 byte boundary
1922       __ andcc(end_to, 7, G0);
1923       __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment2);
1924       __ delayed()->lduh(end_from, -2, O3);
1925       __ dec(count, 2);
1926       __ lduh(end_from, -4, O4);
1927       __ dec(end_from, 4);
1928       __ dec(end_to, 4);
1929       __ sth(O3, end_to, 2);
1930       __ sth(O4, end_to, 0);
1931     __ BIND(L_skip_alignment2);
1932     }
1933 #ifdef _LP64
1934     if (aligned) {
1935       // Both arrays are aligned to 8-bytes in 64-bits VM.
1936       // The 'count' is decremented in copy_16_bytes_backward_with_shift()
1937       // in unaligned case.
1938       __ dec(count, 8);
1939     } else
1940 #endif
1941     {
1942       // Copy with shift 16 bytes per iteration if arrays do not have
1943       // the same alignment mod 8, otherwise jump to the next
1944       // code for aligned copy (and substracting 8 from 'count' before jump).
1945       // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
1946       // Also jump over aligned copy after the copy with shift completed.
1947 
1948       copy_16_bytes_backward_with_shift(end_from, end_to, count, 8,
1949                                         L_aligned_copy, L_copy_2_bytes);
1950     }
1951     // copy 4 elements (16 bytes) at a time
1952       __ align(OptoLoopAlignment);
1953     __ BIND(L_aligned_copy);
1954       __ dec(end_from, 16);
1955       __ ldx(end_from, 8, O3);
1956       __ ldx(end_from, 0, O4);
1957       __ dec(end_to, 16);
1958       __ deccc(count, 8);
1959       __ stx(O3, end_to, 8);
1960       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
1961       __ delayed()->stx(O4, end_to, 0);
1962       __ inc(count, 8);
1963 
1964     // copy 1 element (2 bytes) at a time
1965     __ BIND(L_copy_2_bytes);
1966       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1967     __ BIND(L_copy_2_bytes_loop);
1968       __ dec(end_from, 2);
1969       __ dec(end_to, 2);
1970       __ lduh(end_from, 0, O4);
1971       __ deccc(count);
1972       __ brx(Assembler::greater, false, Assembler::pt, L_copy_2_bytes_loop);
1973       __ delayed()->sth(O4, end_to, 0);
1974 
1975     __ BIND(L_exit);
1976     // O3, O4 are used as temp registers
1977     inc_counter_np(SharedRuntime::_jshort_array_copy_ctr, O3, O4);
1978     __ retl();
1979     __ delayed()->mov(G0, O0); // return 0
1980     return start;
1981   }
1982 
1983   //
1984   // Helper methods for generate_disjoint_int_copy_core()
1985   //
1986   void copy_16_bytes_loop(Register from, Register to, Register count, int count_dec,
1987                           Label& L_loop, bool use_prefetch, bool use_bis) {
1988 
1989     __ align(OptoLoopAlignment);
1990     __ BIND(L_loop);
1991     if (use_prefetch) {
1992       if (ArraycopySrcPrefetchDistance > 0) {
1993         __ prefetch(from, ArraycopySrcPrefetchDistance, Assembler::severalReads);
1994       }
1995       if (ArraycopyDstPrefetchDistance > 0) {
1996         __ prefetch(to, ArraycopyDstPrefetchDistance, Assembler::severalWritesAndPossiblyReads);
1997       }
1998     }
1999     __ ldx(from, 4, O4);
2000     __ ldx(from, 12, G4);
2001     __ inc(to, 16);
2002     __ inc(from, 16);
2003     __ deccc(count, 4); // Can we do next iteration after this one?
2004 
2005     __ srlx(O4, 32, G3);
2006     __ bset(G3, O3);
2007     __ sllx(O4, 32, O4);
2008     __ srlx(G4, 32, G3);
2009     __ bset(G3, O4);
2010     if (use_bis) {
2011       __ stxa(O3, to, -16);
2012       __ stxa(O4, to, -8);
2013     } else {
2014       __ stx(O3, to, -16);
2015       __ stx(O4, to, -8);
2016     }
2017     __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
2018     __ delayed()->sllx(G4, 32,  O3);
2019 
2020   }
2021 
2022   //
2023   //  Generate core code for disjoint int copy (and oop copy on 32-bit).
2024   //  If "aligned" is true, the "from" and "to" addresses are assumed
2025   //  to be heapword aligned.
2026   //
2027   // Arguments:
2028   //      from:  O0
2029   //      to:    O1
2030   //      count: O2 treated as signed
2031   //
2032   void generate_disjoint_int_copy_core(bool aligned) {
2033 
2034     Label L_skip_alignment, L_aligned_copy;
2035     Label L_copy_4_bytes, L_copy_4_bytes_loop, L_exit;
2036 
2037     const Register from      = O0;   // source array address
2038     const Register to        = O1;   // destination array address
2039     const Register count     = O2;   // elements count
2040     const Register offset    = O5;   // offset from start of arrays
2041     // O3, O4, G3, G4 are used as temp registers
2042 
2043     // 'aligned' == true when it is known statically during compilation
2044     // of this arraycopy call site that both 'from' and 'to' addresses
2045     // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
2046     //
2047     // Aligned arrays have 4 bytes alignment in 32-bits VM
2048     // and 8 bytes - in 64-bits VM.
2049     //
2050 #ifdef _LP64
2051     if (!aligned)
2052 #endif
2053     {
2054       // The next check could be put under 'ifndef' since the code in
2055       // generate_disjoint_long_copy_core() has own checks and set 'offset'.
2056 
2057       // for short arrays, just do single element copy
2058       __ cmp(count, 5); // 4 + 1 (20 bytes)
2059       __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_4_bytes);
2060       __ delayed()->mov(G0, offset);
2061 
2062       // copy 1 element to align 'to' on an 8 byte boundary
2063       __ andcc(to, 7, G0);
2064       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
2065       __ delayed()->ld(from, 0, O3);
2066       __ inc(from, 4);
2067       __ inc(to, 4);
2068       __ dec(count);
2069       __ st(O3, to, -4);
2070     __ BIND(L_skip_alignment);
2071 
2072     // if arrays have same alignment mod 8, do 4 elements copy
2073       __ andcc(from, 7, G0);
2074       __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
2075       __ delayed()->ld(from, 0, O3);
2076 
2077     //
2078     // Load 2 aligned 8-bytes chunks and use one from previous iteration
2079     // to form 2 aligned 8-bytes chunks to store.
2080     //
2081     // copy_16_bytes_forward_with_shift() is not used here since this
2082     // code is more optimal.
2083 
2084     // copy with shift 4 elements (16 bytes) at a time
2085       __ dec(count, 4);   // The cmp at the beginning guaranty count >= 4
2086       __ sllx(O3, 32,  O3);
2087 
2088       disjoint_copy_core(from, to, count, 2, 16, &StubGenerator::copy_16_bytes_loop);
2089 
2090       __ br(Assembler::always, false, Assembler::pt, L_copy_4_bytes);
2091       __ delayed()->inc(count, 4); // restore 'count'
2092 
2093     __ BIND(L_aligned_copy);
2094     } // !aligned
2095 
2096     // copy 4 elements (16 bytes) at a time
2097       __ and3(count, 1, G4); // Save
2098       __ srl(count, 1, count);
2099      generate_disjoint_long_copy_core(aligned);
2100       __ mov(G4, count);     // Restore
2101 
2102     // copy 1 element at a time
2103     __ BIND(L_copy_4_bytes);
2104       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
2105     __ BIND(L_copy_4_bytes_loop);
2106       __ ld(from, offset, O3);
2107       __ deccc(count);
2108       __ st(O3, to, offset);
2109       __ brx(Assembler::notZero, false, Assembler::pt, L_copy_4_bytes_loop);
2110       __ delayed()->inc(offset, 4);
2111     __ BIND(L_exit);
2112   }
2113 
2114   //
2115   //  Generate stub for disjoint int copy.  If "aligned" is true, the
2116   //  "from" and "to" addresses are assumed to be heapword aligned.
2117   //
2118   // Arguments for generated stub:
2119   //      from:  O0
2120   //      to:    O1
2121   //      count: O2 treated as signed
2122   //
2123   address generate_disjoint_int_copy(bool aligned, address *entry, const char *name) {
2124     __ align(CodeEntryAlignment);
2125     StubCodeMark mark(this, "StubRoutines", name);
2126     address start = __ pc();
2127 
2128     const Register count = O2;
2129     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
2130 
2131     if (entry != NULL) {
2132       *entry = __ pc();
2133       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
2134       BLOCK_COMMENT("Entry:");
2135     }
2136 
2137     generate_disjoint_int_copy_core(aligned);
2138 
2139     // O3, O4 are used as temp registers
2140     inc_counter_np(SharedRuntime::_jint_array_copy_ctr, O3, O4);
2141     __ retl();
2142     __ delayed()->mov(G0, O0); // return 0
2143     return start;
2144   }
2145 
2146   //
2147   //  Generate core code for conjoint int copy (and oop copy on 32-bit).
2148   //  If "aligned" is true, the "from" and "to" addresses are assumed
2149   //  to be heapword aligned.
2150   //
2151   // Arguments:
2152   //      from:  O0
2153   //      to:    O1
2154   //      count: O2 treated as signed
2155   //
2156   void generate_conjoint_int_copy_core(bool aligned) {
2157     // Do reverse copy.
2158 
2159     Label L_skip_alignment, L_aligned_copy;
2160     Label L_copy_16_bytes,  L_copy_4_bytes, L_copy_4_bytes_loop, L_exit;
2161 
2162     const Register from      = O0;   // source array address
2163     const Register to        = O1;   // destination array address
2164     const Register count     = O2;   // elements count
2165     const Register end_from  = from; // source array end address
2166     const Register end_to    = to;   // destination array end address
2167     // O3, O4, O5, G3 are used as temp registers
2168 
2169     const Register byte_count = O3;  // bytes count to copy
2170 
2171       __ sllx(count, LogBytesPerInt, byte_count);
2172       __ add(to, byte_count, end_to); // offset after last copied element
2173 
2174       __ cmp(count, 5); // for short arrays, just do single element copy
2175       __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_4_bytes);
2176       __ delayed()->add(from, byte_count, end_from);
2177 
2178     // copy 1 element to align 'to' on an 8 byte boundary
2179       __ andcc(end_to, 7, G0);
2180       __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
2181       __ delayed()->nop();
2182       __ dec(count);
2183       __ dec(end_from, 4);
2184       __ dec(end_to,   4);
2185       __ ld(end_from, 0, O4);
2186       __ st(O4, end_to, 0);
2187     __ BIND(L_skip_alignment);
2188 
2189     // Check if 'end_from' and 'end_to' has the same alignment.
2190       __ andcc(end_from, 7, G0);
2191       __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
2192       __ delayed()->dec(count, 4); // The cmp at the start guaranty cnt >= 4
2193 
2194     // copy with shift 4 elements (16 bytes) at a time
2195     //
2196     // Load 2 aligned 8-bytes chunks and use one from previous iteration
2197     // to form 2 aligned 8-bytes chunks to store.
2198     //
2199       __ ldx(end_from, -4, O3);
2200       __ align(OptoLoopAlignment);
2201     __ BIND(L_copy_16_bytes);
2202       __ ldx(end_from, -12, O4);
2203       __ deccc(count, 4);
2204       __ ldx(end_from, -20, O5);
2205       __ dec(end_to, 16);
2206       __ dec(end_from, 16);
2207       __ srlx(O3, 32, O3);
2208       __ sllx(O4, 32, G3);
2209       __ bset(G3, O3);
2210       __ stx(O3, end_to, 8);
2211       __ srlx(O4, 32, O4);
2212       __ sllx(O5, 32, G3);
2213       __ bset(O4, G3);
2214       __ stx(G3, end_to, 0);
2215       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_copy_16_bytes);
2216       __ delayed()->mov(O5, O3);
2217 
2218       __ br(Assembler::always, false, Assembler::pt, L_copy_4_bytes);
2219       __ delayed()->inc(count, 4);
2220 
2221     // copy 4 elements (16 bytes) at a time
2222       __ align(OptoLoopAlignment);
2223     __ BIND(L_aligned_copy);
2224       __ dec(end_from, 16);
2225       __ ldx(end_from, 8, O3);
2226       __ ldx(end_from, 0, O4);
2227       __ dec(end_to, 16);
2228       __ deccc(count, 4);
2229       __ stx(O3, end_to, 8);
2230       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
2231       __ delayed()->stx(O4, end_to, 0);
2232       __ inc(count, 4);
2233 
2234     // copy 1 element (4 bytes) at a time
2235     __ BIND(L_copy_4_bytes);
2236       __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
2237     __ BIND(L_copy_4_bytes_loop);
2238       __ dec(end_from, 4);
2239       __ dec(end_to, 4);
2240       __ ld(end_from, 0, O4);
2241       __ deccc(count);
2242       __ brx(Assembler::greater, false, Assembler::pt, L_copy_4_bytes_loop);
2243       __ delayed()->st(O4, end_to, 0);
2244     __ BIND(L_exit);
2245   }
2246 
2247   //
2248   //  Generate stub for conjoint int copy.  If "aligned" is true, the
2249   //  "from" and "to" addresses are assumed to be heapword aligned.
2250   //
2251   // Arguments for generated stub:
2252   //      from:  O0
2253   //      to:    O1
2254   //      count: O2 treated as signed
2255   //
2256   address generate_conjoint_int_copy(bool aligned, address nooverlap_target,
2257                                      address *entry, const char *name) {
2258     __ align(CodeEntryAlignment);
2259     StubCodeMark mark(this, "StubRoutines", name);
2260     address start = __ pc();
2261 
2262     assert_clean_int(O2, O3);     // Make sure 'count' is clean int.
2263 
2264     if (entry != NULL) {
2265       *entry = __ pc();
2266       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
2267       BLOCK_COMMENT("Entry:");
2268     }
2269 
2270     array_overlap_test(nooverlap_target, 2);
2271 
2272     generate_conjoint_int_copy_core(aligned);
2273 
2274     // O3, O4 are used as temp registers
2275     inc_counter_np(SharedRuntime::_jint_array_copy_ctr, O3, O4);
2276     __ retl();
2277     __ delayed()->mov(G0, O0); // return 0
2278     return start;
2279   }
2280 
2281   //
2282   // Helper methods for generate_disjoint_long_copy_core()
2283   //
2284   void copy_64_bytes_loop(Register from, Register to, Register count, int count_dec,
2285                           Label& L_loop, bool use_prefetch, bool use_bis) {
2286     __ align(OptoLoopAlignment);
2287     __ BIND(L_loop);
2288     for (int off = 0; off < 64; off += 16) {
2289       if (use_prefetch && (off & 31) == 0) {
2290         if (ArraycopySrcPrefetchDistance > 0) {
2291           __ prefetch(from, ArraycopySrcPrefetchDistance+off, Assembler::severalReads);
2292         }
2293         if (ArraycopyDstPrefetchDistance > 0) {
2294           __ prefetch(to, ArraycopyDstPrefetchDistance+off, Assembler::severalWritesAndPossiblyReads);
2295         }
2296       }
2297       __ ldx(from,  off+0, O4);
2298       __ ldx(from,  off+8, O5);
2299       if (use_bis) {
2300         __ stxa(O4, to,  off+0);
2301         __ stxa(O5, to,  off+8);
2302       } else {
2303         __ stx(O4, to,  off+0);
2304         __ stx(O5, to,  off+8);
2305       }
2306     }
2307     __ deccc(count, 8);
2308     __ inc(from, 64);
2309     __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
2310     __ delayed()->inc(to, 64);
2311   }
2312 
2313   //
2314   //  Generate core code for disjoint long copy (and oop copy on 64-bit).
2315   //  "aligned" is ignored, because we must make the stronger
2316   //  assumption that both addresses are always 64-bit aligned.
2317   //
2318   // Arguments:
2319   //      from:  O0
2320   //      to:    O1
2321   //      count: O2 treated as signed
2322   //
2323   // count -= 2;
2324   // if ( count >= 0 ) { // >= 2 elements
2325   //   if ( count > 6) { // >= 8 elements
2326   //     count -= 6; // original count - 8
2327   //     do {
2328   //       copy_8_elements;
2329   //       count -= 8;
2330   //     } while ( count >= 0 );
2331   //     count += 6;
2332   //   }
2333   //   if ( count >= 0 ) { // >= 2 elements
2334   //     do {
2335   //       copy_2_elements;
2336   //     } while ( (count=count-2) >= 0 );
2337   //   }
2338   // }
2339   // count += 2;
2340   // if ( count != 0 ) { // 1 element left
2341   //   copy_1_element;
2342   // }
2343   //
2344   void generate_disjoint_long_copy_core(bool aligned) {
2345     Label L_copy_8_bytes, L_copy_16_bytes, L_exit;
2346     const Register from    = O0;  // source array address
2347     const Register to      = O1;  // destination array address
2348     const Register count   = O2;  // elements count
2349     const Register offset0 = O4;  // element offset
2350     const Register offset8 = O5;  // next element offset
2351 
2352     __ deccc(count, 2);
2353     __ mov(G0, offset0);   // offset from start of arrays (0)
2354     __ brx(Assembler::negative, false, Assembler::pn, L_copy_8_bytes );
2355     __ delayed()->add(offset0, 8, offset8);
2356 
2357     // Copy by 64 bytes chunks
2358 
2359     const Register from64 = O3;  // source address
2360     const Register to64   = G3;  // destination address
2361     __ subcc(count, 6, O3);
2362     __ brx(Assembler::negative, false, Assembler::pt, L_copy_16_bytes );
2363     __ delayed()->mov(to,   to64);
2364     // Now we can use O4(offset0), O5(offset8) as temps
2365     __ mov(O3, count);
2366     // count >= 0 (original count - 8)
2367     __ mov(from, from64);
2368 
2369     disjoint_copy_core(from64, to64, count, 3, 64, &StubGenerator::copy_64_bytes_loop);
2370 
2371       // Restore O4(offset0), O5(offset8)
2372       __ sub(from64, from, offset0);
2373       __ inccc(count, 6); // restore count
2374       __ brx(Assembler::negative, false, Assembler::pn, L_copy_8_bytes );
2375       __ delayed()->add(offset0, 8, offset8);
2376 
2377       // Copy by 16 bytes chunks
2378       __ align(OptoLoopAlignment);
2379     __ BIND(L_copy_16_bytes);
2380       __ ldx(from, offset0, O3);
2381       __ ldx(from, offset8, G3);
2382       __ deccc(count, 2);
2383       __ stx(O3, to, offset0);
2384       __ inc(offset0, 16);
2385       __ stx(G3, to, offset8);
2386       __ brx(Assembler::greaterEqual, false, Assembler::pt, L_copy_16_bytes);
2387       __ delayed()->inc(offset8, 16);
2388 
2389       // Copy last 8 bytes
2390     __ BIND(L_copy_8_bytes);
2391       __ inccc(count, 2);
2392       __ brx(Assembler::zero, true, Assembler::pn, L_exit );
2393       __ delayed()->mov(offset0, offset8); // Set O5 used by other stubs
2394       __ ldx(from, offset0, O3);
2395       __ stx(O3, to, offset0);
2396     __ BIND(L_exit);
2397   }
2398 
2399   //
2400   //  Generate stub for disjoint long copy.
2401   //  "aligned" is ignored, because we must make the stronger
2402   //  assumption that both addresses are always 64-bit aligned.
2403   //
2404   // Arguments for generated stub:
2405   //      from:  O0
2406   //      to:    O1
2407   //      count: O2 treated as signed
2408   //
2409   address generate_disjoint_long_copy(bool aligned, address *entry, const char *name) {
2410     __ align(CodeEntryAlignment);
2411     StubCodeMark mark(this, "StubRoutines", name);
2412     address start = __ pc();
2413 
2414     assert_clean_int(O2, O3);     // Make sure 'count' is clean int.
2415 
2416     if (entry != NULL) {
2417       *entry = __ pc();
2418       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
2419       BLOCK_COMMENT("Entry:");
2420     }
2421 
2422     generate_disjoint_long_copy_core(aligned);
2423 
2424     // O3, O4 are used as temp registers
2425     inc_counter_np(SharedRuntime::_jlong_array_copy_ctr, O3, O4);
2426     __ retl();
2427     __ delayed()->mov(G0, O0); // return 0
2428     return start;
2429   }
2430 
2431   //
2432   //  Generate core code for conjoint long copy (and oop copy on 64-bit).
2433   //  "aligned" is ignored, because we must make the stronger
2434   //  assumption that both addresses are always 64-bit aligned.
2435   //
2436   // Arguments:
2437   //      from:  O0
2438   //      to:    O1
2439   //      count: O2 treated as signed
2440   //
2441   void generate_conjoint_long_copy_core(bool aligned) {
2442     // Do reverse copy.
2443     Label L_copy_8_bytes, L_copy_16_bytes, L_exit;
2444     const Register from    = O0;  // source array address
2445     const Register to      = O1;  // destination array address
2446     const Register count   = O2;  // elements count
2447     const Register offset8 = O4;  // element offset
2448     const Register offset0 = O5;  // previous element offset
2449 
2450       __ subcc(count, 1, count);
2451       __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_8_bytes );
2452       __ delayed()->sllx(count, LogBytesPerLong, offset8);
2453       __ sub(offset8, 8, offset0);
2454       __ align(OptoLoopAlignment);
2455     __ BIND(L_copy_16_bytes);
2456       __ ldx(from, offset8, O2);
2457       __ ldx(from, offset0, O3);
2458       __ stx(O2, to, offset8);
2459       __ deccc(offset8, 16);      // use offset8 as counter
2460       __ stx(O3, to, offset0);
2461       __ brx(Assembler::greater, false, Assembler::pt, L_copy_16_bytes);
2462       __ delayed()->dec(offset0, 16);
2463 
2464     __ BIND(L_copy_8_bytes);
2465       __ brx(Assembler::negative, false, Assembler::pn, L_exit );
2466       __ delayed()->nop();
2467       __ ldx(from, 0, O3);
2468       __ stx(O3, to, 0);
2469     __ BIND(L_exit);
2470   }
2471 
2472   //  Generate stub for conjoint long copy.
2473   //  "aligned" is ignored, because we must make the stronger
2474   //  assumption that both addresses are always 64-bit aligned.
2475   //
2476   // Arguments for generated stub:
2477   //      from:  O0
2478   //      to:    O1
2479   //      count: O2 treated as signed
2480   //
2481   address generate_conjoint_long_copy(bool aligned, address nooverlap_target,
2482                                       address *entry, const char *name) {
2483     __ align(CodeEntryAlignment);
2484     StubCodeMark mark(this, "StubRoutines", name);
2485     address start = __ pc();
2486 
2487     assert(aligned, "Should always be aligned");
2488 
2489     assert_clean_int(O2, O3);     // Make sure 'count' is clean int.
2490 
2491     if (entry != NULL) {
2492       *entry = __ pc();
2493       // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
2494       BLOCK_COMMENT("Entry:");
2495     }
2496 
2497     array_overlap_test(nooverlap_target, 3);
2498 
2499     generate_conjoint_long_copy_core(aligned);
2500 
2501     // O3, O4 are used as temp registers
2502     inc_counter_np(SharedRuntime::_jlong_array_copy_ctr, O3, O4);
2503     __ retl();
2504     __ delayed()->mov(G0, O0); // return 0
2505     return start;
2506   }
2507 
2508   //  Generate stub for disjoint oop copy.  If "aligned" is true, the
2509   //  "from" and "to" addresses are assumed to be heapword aligned.
2510   //
2511   // Arguments for generated stub:
2512   //      from:  O0
2513   //      to:    O1
2514   //      count: O2 treated as signed
2515   //
2516   address generate_disjoint_oop_copy(bool aligned, address *entry, const char *name,
2517                                      bool dest_uninitialized = false) {
2518 
2519     const Register from  = O0;  // source array address
2520     const Register to    = O1;  // destination array address
2521     const Register count = O2;  // elements count
2522 
2523     __ align(CodeEntryAlignment);
2524     StubCodeMark mark(this, "StubRoutines", name);
2525     address start = __ pc();
2526 
2527     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
2528 
2529     if (entry != NULL) {
2530       *entry = __ pc();
2531       // caller can pass a 64-bit byte count here
2532       BLOCK_COMMENT("Entry:");
2533     }
2534 
2535     // save arguments for barrier generation
2536     __ mov(to, G1);
2537     __ mov(count, G5);
2538     gen_write_ref_array_pre_barrier(G1, G5, dest_uninitialized);
2539   #ifdef _LP64
2540     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
2541     if (UseCompressedOops) {
2542       generate_disjoint_int_copy_core(aligned);
2543     } else {
2544       generate_disjoint_long_copy_core(aligned);
2545     }
2546   #else
2547     generate_disjoint_int_copy_core(aligned);
2548   #endif
2549     // O0 is used as temp register
2550     gen_write_ref_array_post_barrier(G1, G5, O0);
2551 
2552     // O3, O4 are used as temp registers
2553     inc_counter_np(SharedRuntime::_oop_array_copy_ctr, O3, O4);
2554     __ retl();
2555     __ delayed()->mov(G0, O0); // return 0
2556     return start;
2557   }
2558 
2559   //  Generate stub for conjoint oop copy.  If "aligned" is true, the
2560   //  "from" and "to" addresses are assumed to be heapword aligned.
2561   //
2562   // Arguments for generated stub:
2563   //      from:  O0
2564   //      to:    O1
2565   //      count: O2 treated as signed
2566   //
2567   address generate_conjoint_oop_copy(bool aligned, address nooverlap_target,
2568                                      address *entry, const char *name,
2569                                      bool dest_uninitialized = false) {
2570 
2571     const Register from  = O0;  // source array address
2572     const Register to    = O1;  // destination array address
2573     const Register count = O2;  // elements count
2574 
2575     __ align(CodeEntryAlignment);
2576     StubCodeMark mark(this, "StubRoutines", name);
2577     address start = __ pc();
2578 
2579     assert_clean_int(count, O3);     // Make sure 'count' is clean int.
2580 
2581     if (entry != NULL) {
2582       *entry = __ pc();
2583       // caller can pass a 64-bit byte count here
2584       BLOCK_COMMENT("Entry:");
2585     }
2586 
2587     array_overlap_test(nooverlap_target, LogBytesPerHeapOop);
2588 
2589     // save arguments for barrier generation
2590     __ mov(to, G1);
2591     __ mov(count, G5);
2592     gen_write_ref_array_pre_barrier(G1, G5, dest_uninitialized);
2593 
2594   #ifdef _LP64
2595     if (UseCompressedOops) {
2596       generate_conjoint_int_copy_core(aligned);
2597     } else {
2598       generate_conjoint_long_copy_core(aligned);
2599     }
2600   #else
2601     generate_conjoint_int_copy_core(aligned);
2602   #endif
2603 
2604     // O0 is used as temp register
2605     gen_write_ref_array_post_barrier(G1, G5, O0);
2606 
2607     // O3, O4 are used as temp registers
2608     inc_counter_np(SharedRuntime::_oop_array_copy_ctr, O3, O4);
2609     __ retl();
2610     __ delayed()->mov(G0, O0); // return 0
2611     return start;
2612   }
2613 
2614 
2615   // Helper for generating a dynamic type check.
2616   // Smashes only the given temp registers.
2617   void generate_type_check(Register sub_klass,
2618                            Register super_check_offset,
2619                            Register super_klass,
2620                            Register temp,
2621                            Label& L_success) {
2622     assert_different_registers(sub_klass, super_check_offset, super_klass, temp);
2623 
2624     BLOCK_COMMENT("type_check:");
2625 
2626     Label L_miss, L_pop_to_miss;
2627 
2628     assert_clean_int(super_check_offset, temp);
2629 
2630     __ check_klass_subtype_fast_path(sub_klass, super_klass, temp, noreg,
2631                                      &L_success, &L_miss, NULL,
2632                                      super_check_offset);
2633 
2634     BLOCK_COMMENT("type_check_slow_path:");
2635     __ save_frame(0);
2636     __ check_klass_subtype_slow_path(sub_klass->after_save(),
2637                                      super_klass->after_save(),
2638                                      L0, L1, L2, L4,
2639                                      NULL, &L_pop_to_miss);
2640     __ ba(L_success);
2641     __ delayed()->restore();
2642 
2643     __ bind(L_pop_to_miss);
2644     __ restore();
2645 
2646     // Fall through on failure!
2647     __ BIND(L_miss);
2648   }
2649 
2650 
2651   //  Generate stub for checked oop copy.
2652   //
2653   // Arguments for generated stub:
2654   //      from:  O0
2655   //      to:    O1
2656   //      count: O2 treated as signed
2657   //      ckoff: O3 (super_check_offset)
2658   //      ckval: O4 (super_klass)
2659   //      ret:   O0 zero for success; (-1^K) where K is partial transfer count
2660   //
2661   address generate_checkcast_copy(const char *name, address *entry, bool dest_uninitialized = false) {
2662 
2663     const Register O0_from   = O0;      // source array address
2664     const Register O1_to     = O1;      // destination array address
2665     const Register O2_count  = O2;      // elements count
2666     const Register O3_ckoff  = O3;      // super_check_offset
2667     const Register O4_ckval  = O4;      // super_klass
2668 
2669     const Register O5_offset = O5;      // loop var, with stride wordSize
2670     const Register G1_remain = G1;      // loop var, with stride -1
2671     const Register G3_oop    = G3;      // actual oop copied
2672     const Register G4_klass  = G4;      // oop._klass
2673     const Register G5_super  = G5;      // oop._klass._primary_supers[ckval]
2674 
2675     __ align(CodeEntryAlignment);
2676     StubCodeMark mark(this, "StubRoutines", name);
2677     address start = __ pc();
2678 
2679 #ifdef ASSERT
2680     // We sometimes save a frame (see generate_type_check below).
2681     // If this will cause trouble, let's fail now instead of later.
2682     __ save_frame(0);
2683     __ restore();
2684 #endif
2685 
2686     assert_clean_int(O2_count, G1);     // Make sure 'count' is clean int.
2687 
2688 #ifdef ASSERT
2689     // caller guarantees that the arrays really are different
2690     // otherwise, we would have to make conjoint checks
2691     { Label L;
2692       __ mov(O3, G1);           // spill: overlap test smashes O3
2693       __ mov(O4, G4);           // spill: overlap test smashes O4
2694       array_overlap_test(L, LogBytesPerHeapOop);
2695       __ stop("checkcast_copy within a single array");
2696       __ bind(L);
2697       __ mov(G1, O3);
2698       __ mov(G4, O4);
2699     }
2700 #endif //ASSERT
2701 
2702     if (entry != NULL) {
2703       *entry = __ pc();
2704       // caller can pass a 64-bit byte count here (from generic stub)
2705       BLOCK_COMMENT("Entry:");
2706     }
2707     gen_write_ref_array_pre_barrier(O1_to, O2_count, dest_uninitialized);
2708 
2709     Label load_element, store_element, do_card_marks, fail, done;
2710     __ addcc(O2_count, 0, G1_remain);   // initialize loop index, and test it
2711     __ brx(Assembler::notZero, false, Assembler::pt, load_element);
2712     __ delayed()->mov(G0, O5_offset);   // offset from start of arrays
2713 
2714     // Empty array:  Nothing to do.
2715     inc_counter_np(SharedRuntime::_checkcast_array_copy_ctr, O3, O4);
2716     __ retl();
2717     __ delayed()->set(0, O0);           // return 0 on (trivial) success
2718 
2719     // ======== begin loop ========
2720     // (Loop is rotated; its entry is load_element.)
2721     // Loop variables:
2722     //   (O5 = 0; ; O5 += wordSize) --- offset from src, dest arrays
2723     //   (O2 = len; O2 != 0; O2--) --- number of oops *remaining*
2724     //   G3, G4, G5 --- current oop, oop.klass, oop.klass.super
2725     __ align(OptoLoopAlignment);
2726 
2727     __ BIND(store_element);
2728     __ deccc(G1_remain);                // decrement the count
2729     __ store_heap_oop(G3_oop, O1_to, O5_offset); // store the oop
2730     __ inc(O5_offset, heapOopSize);     // step to next offset
2731     __ brx(Assembler::zero, true, Assembler::pt, do_card_marks);
2732     __ delayed()->set(0, O0);           // return -1 on success
2733 
2734     // ======== loop entry is here ========
2735     __ BIND(load_element);
2736     __ load_heap_oop(O0_from, O5_offset, G3_oop);  // load the oop
2737     __ br_null_short(G3_oop, Assembler::pt, store_element);
2738 
2739     __ load_klass(G3_oop, G4_klass); // query the object klass
2740 
2741     generate_type_check(G4_klass, O3_ckoff, O4_ckval, G5_super,
2742                         // branch to this on success:
2743                         store_element);
2744     // ======== end loop ========
2745 
2746     // It was a real error; we must depend on the caller to finish the job.
2747     // Register G1 has number of *remaining* oops, O2 number of *total* oops.
2748     // Emit GC store barriers for the oops we have copied (O2 minus G1),
2749     // and report their number to the caller.
2750     __ BIND(fail);
2751     __ subcc(O2_count, G1_remain, O2_count);
2752     __ brx(Assembler::zero, false, Assembler::pt, done);
2753     __ delayed()->not1(O2_count, O0);   // report (-1^K) to caller
2754 
2755     __ BIND(do_card_marks);
2756     gen_write_ref_array_post_barrier(O1_to, O2_count, O3);   // store check on O1[0..O2]
2757 
2758     __ BIND(done);
2759     inc_counter_np(SharedRuntime::_checkcast_array_copy_ctr, O3, O4);
2760     __ retl();
2761     __ delayed()->nop();             // return value in 00
2762 
2763     return start;
2764   }
2765 
2766 
2767   //  Generate 'unsafe' array copy stub
2768   //  Though just as safe as the other stubs, it takes an unscaled
2769   //  size_t argument instead of an element count.
2770   //
2771   // Arguments for generated stub:
2772   //      from:  O0
2773   //      to:    O1
2774   //      count: O2 byte count, treated as ssize_t, can be zero
2775   //
2776   // Examines the alignment of the operands and dispatches
2777   // to a long, int, short, or byte copy loop.
2778   //
2779   address generate_unsafe_copy(const char* name,
2780                                address byte_copy_entry,
2781                                address short_copy_entry,
2782                                address int_copy_entry,
2783                                address long_copy_entry) {
2784 
2785     const Register O0_from   = O0;      // source array address
2786     const Register O1_to     = O1;      // destination array address
2787     const Register O2_count  = O2;      // elements count
2788 
2789     const Register G1_bits   = G1;      // test copy of low bits
2790 
2791     __ align(CodeEntryAlignment);
2792     StubCodeMark mark(this, "StubRoutines", name);
2793     address start = __ pc();
2794 
2795     // bump this on entry, not on exit:
2796     inc_counter_np(SharedRuntime::_unsafe_array_copy_ctr, G1, G3);
2797 
2798     __ or3(O0_from, O1_to, G1_bits);
2799     __ or3(O2_count,       G1_bits, G1_bits);
2800 
2801     __ btst(BytesPerLong-1, G1_bits);
2802     __ br(Assembler::zero, true, Assembler::pt,
2803           long_copy_entry, relocInfo::runtime_call_type);
2804     // scale the count on the way out:
2805     __ delayed()->srax(O2_count, LogBytesPerLong, O2_count);
2806 
2807     __ btst(BytesPerInt-1, G1_bits);
2808     __ br(Assembler::zero, true, Assembler::pt,
2809           int_copy_entry, relocInfo::runtime_call_type);
2810     // scale the count on the way out:
2811     __ delayed()->srax(O2_count, LogBytesPerInt, O2_count);
2812 
2813     __ btst(BytesPerShort-1, G1_bits);
2814     __ br(Assembler::zero, true, Assembler::pt,
2815           short_copy_entry, relocInfo::runtime_call_type);
2816     // scale the count on the way out:
2817     __ delayed()->srax(O2_count, LogBytesPerShort, O2_count);
2818 
2819     __ br(Assembler::always, false, Assembler::pt,
2820           byte_copy_entry, relocInfo::runtime_call_type);
2821     __ delayed()->nop();
2822 
2823     return start;
2824   }
2825 
2826 
2827   // Perform range checks on the proposed arraycopy.
2828   // Kills the two temps, but nothing else.
2829   // Also, clean the sign bits of src_pos and dst_pos.
2830   void arraycopy_range_checks(Register src,     // source array oop (O0)
2831                               Register src_pos, // source position (O1)
2832                               Register dst,     // destination array oo (O2)
2833                               Register dst_pos, // destination position (O3)
2834                               Register length,  // length of copy (O4)
2835                               Register temp1, Register temp2,
2836                               Label& L_failed) {
2837     BLOCK_COMMENT("arraycopy_range_checks:");
2838 
2839     //  if (src_pos + length > arrayOop(src)->length() ) FAIL;
2840 
2841     const Register array_length = temp1;  // scratch
2842     const Register end_pos      = temp2;  // scratch
2843 
2844     // Note:  This next instruction may be in the delay slot of a branch:
2845     __ add(length, src_pos, end_pos);  // src_pos + length
2846     __ lduw(src, arrayOopDesc::length_offset_in_bytes(), array_length);
2847     __ cmp(end_pos, array_length);
2848     __ br(Assembler::greater, false, Assembler::pn, L_failed);
2849 
2850     //  if (dst_pos + length > arrayOop(dst)->length() ) FAIL;
2851     __ delayed()->add(length, dst_pos, end_pos); // dst_pos + length
2852     __ lduw(dst, arrayOopDesc::length_offset_in_bytes(), array_length);
2853     __ cmp(end_pos, array_length);
2854     __ br(Assembler::greater, false, Assembler::pn, L_failed);
2855 
2856     // Have to clean up high 32-bits of 'src_pos' and 'dst_pos'.
2857     // Move with sign extension can be used since they are positive.
2858     __ delayed()->signx(src_pos, src_pos);
2859     __ signx(dst_pos, dst_pos);
2860 
2861     BLOCK_COMMENT("arraycopy_range_checks done");
2862   }
2863 
2864 
2865   //
2866   //  Generate generic array copy stubs
2867   //
2868   //  Input:
2869   //    O0    -  src oop
2870   //    O1    -  src_pos
2871   //    O2    -  dst oop
2872   //    O3    -  dst_pos
2873   //    O4    -  element count
2874   //
2875   //  Output:
2876   //    O0 ==  0  -  success
2877   //    O0 == -1  -  need to call System.arraycopy
2878   //
2879   address generate_generic_copy(const char *name,
2880                                 address entry_jbyte_arraycopy,
2881                                 address entry_jshort_arraycopy,
2882                                 address entry_jint_arraycopy,
2883                                 address entry_oop_arraycopy,
2884                                 address entry_jlong_arraycopy,
2885                                 address entry_checkcast_arraycopy) {
2886     Label L_failed, L_objArray;
2887 
2888     // Input registers
2889     const Register src      = O0;  // source array oop
2890     const Register src_pos  = O1;  // source position
2891     const Register dst      = O2;  // destination array oop
2892     const Register dst_pos  = O3;  // destination position
2893     const Register length   = O4;  // elements count
2894 
2895     // registers used as temp
2896     const Register G3_src_klass = G3; // source array klass
2897     const Register G4_dst_klass = G4; // destination array klass
2898     const Register G5_lh        = G5; // layout handler
2899     const Register O5_temp      = O5;
2900 
2901     __ align(CodeEntryAlignment);
2902     StubCodeMark mark(this, "StubRoutines", name);
2903     address start = __ pc();
2904 
2905     // bump this on entry, not on exit:
2906     inc_counter_np(SharedRuntime::_generic_array_copy_ctr, G1, G3);
2907 
2908     // In principle, the int arguments could be dirty.
2909     //assert_clean_int(src_pos, G1);
2910     //assert_clean_int(dst_pos, G1);
2911     //assert_clean_int(length, G1);
2912 
2913     //-----------------------------------------------------------------------
2914     // Assembler stubs will be used for this call to arraycopy
2915     // if the following conditions are met:
2916     //
2917     // (1) src and dst must not be null.
2918     // (2) src_pos must not be negative.
2919     // (3) dst_pos must not be negative.
2920     // (4) length  must not be negative.
2921     // (5) src klass and dst klass should be the same and not NULL.
2922     // (6) src and dst should be arrays.
2923     // (7) src_pos + length must not exceed length of src.
2924     // (8) dst_pos + length must not exceed length of dst.
2925     BLOCK_COMMENT("arraycopy initial argument checks");
2926 
2927     //  if (src == NULL) return -1;
2928     __ br_null(src, false, Assembler::pn, L_failed);
2929 
2930     //  if (src_pos < 0) return -1;
2931     __ delayed()->tst(src_pos);
2932     __ br(Assembler::negative, false, Assembler::pn, L_failed);
2933     __ delayed()->nop();
2934 
2935     //  if (dst == NULL) return -1;
2936     __ br_null(dst, false, Assembler::pn, L_failed);
2937 
2938     //  if (dst_pos < 0) return -1;
2939     __ delayed()->tst(dst_pos);
2940     __ br(Assembler::negative, false, Assembler::pn, L_failed);
2941 
2942     //  if (length < 0) return -1;
2943     __ delayed()->tst(length);
2944     __ br(Assembler::negative, false, Assembler::pn, L_failed);
2945 
2946     BLOCK_COMMENT("arraycopy argument klass checks");
2947     //  get src->klass()
2948     if (UseCompressedClassPointers) {
2949       __ delayed()->nop(); // ??? not good
2950       __ load_klass(src, G3_src_klass);
2951     } else {
2952       __ delayed()->ld_ptr(src, oopDesc::klass_offset_in_bytes(), G3_src_klass);
2953     }
2954 
2955 #ifdef ASSERT
2956     //  assert(src->klass() != NULL);
2957     BLOCK_COMMENT("assert klasses not null");
2958     { Label L_a, L_b;
2959       __ br_notnull_short(G3_src_klass, Assembler::pt, L_b); // it is broken if klass is NULL
2960       __ bind(L_a);
2961       __ stop("broken null klass");
2962       __ bind(L_b);
2963       __ load_klass(dst, G4_dst_klass);
2964       __ br_null(G4_dst_klass, false, Assembler::pn, L_a); // this would be broken also
2965       __ delayed()->mov(G0, G4_dst_klass);      // scribble the temp
2966       BLOCK_COMMENT("assert done");
2967     }
2968 #endif
2969 
2970     // Load layout helper
2971     //
2972     //  |array_tag|     | header_size | element_type |     |log2_element_size|
2973     // 32        30    24            16              8     2                 0
2974     //
2975     //   array_tag: typeArray = 0x3, objArray = 0x2, non-array = 0x0
2976     //
2977 
2978     int lh_offset = in_bytes(Klass::layout_helper_offset());
2979 
2980     // Load 32-bits signed value. Use br() instruction with it to check icc.
2981     __ lduw(G3_src_klass, lh_offset, G5_lh);
2982 
2983     if (UseCompressedClassPointers) {
2984       __ load_klass(dst, G4_dst_klass);
2985     }
2986     // Handle objArrays completely differently...
2987     juint objArray_lh = Klass::array_layout_helper(T_OBJECT);
2988     __ set(objArray_lh, O5_temp);
2989     __ cmp(G5_lh,       O5_temp);
2990     __ br(Assembler::equal, false, Assembler::pt, L_objArray);
2991     if (UseCompressedClassPointers) {
2992       __ delayed()->nop();
2993     } else {
2994       __ delayed()->ld_ptr(dst, oopDesc::klass_offset_in_bytes(), G4_dst_klass);
2995     }
2996 
2997     //  if (src->klass() != dst->klass()) return -1;
2998     __ cmp_and_brx_short(G3_src_klass, G4_dst_klass, Assembler::notEqual, Assembler::pn, L_failed);
2999 
3000     //  if (!src->is_Array()) return -1;
3001     __ cmp(G5_lh, Klass::_lh_neutral_value); // < 0
3002     __ br(Assembler::greaterEqual, false, Assembler::pn, L_failed);
3003 
3004     // At this point, it is known to be a typeArray (array_tag 0x3).
3005 #ifdef ASSERT
3006     __ delayed()->nop();
3007     { Label L;
3008       jint lh_prim_tag_in_place = (Klass::_lh_array_tag_type_value << Klass::_lh_array_tag_shift);
3009       __ set(lh_prim_tag_in_place, O5_temp);
3010       __ cmp(G5_lh,                O5_temp);
3011       __ br(Assembler::greaterEqual, false, Assembler::pt, L);
3012       __ delayed()->nop();
3013       __ stop("must be a primitive array");
3014       __ bind(L);
3015     }
3016 #else
3017     __ delayed();                               // match next insn to prev branch
3018 #endif
3019 
3020     arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
3021                            O5_temp, G4_dst_klass, L_failed);
3022 
3023     // TypeArrayKlass
3024     //
3025     // src_addr = (src + array_header_in_bytes()) + (src_pos << log2elemsize);
3026     // dst_addr = (dst + array_header_in_bytes()) + (dst_pos << log2elemsize);
3027     //
3028 
3029     const Register G4_offset = G4_dst_klass;    // array offset
3030     const Register G3_elsize = G3_src_klass;    // log2 element size
3031 
3032     __ srl(G5_lh, Klass::_lh_header_size_shift, G4_offset);
3033     __ and3(G4_offset, Klass::_lh_header_size_mask, G4_offset); // array_offset
3034     __ add(src, G4_offset, src);       // src array offset
3035     __ add(dst, G4_offset, dst);       // dst array offset
3036     __ and3(G5_lh, Klass::_lh_log2_element_size_mask, G3_elsize); // log2 element size
3037 
3038     // next registers should be set before the jump to corresponding stub
3039     const Register from     = O0;  // source array address
3040     const Register to       = O1;  // destination array address
3041     const Register count    = O2;  // elements count
3042 
3043     // 'from', 'to', 'count' registers should be set in this order
3044     // since they are the same as 'src', 'src_pos', 'dst'.
3045 
3046     BLOCK_COMMENT("scale indexes to element size");
3047     __ sll_ptr(src_pos, G3_elsize, src_pos);
3048     __ sll_ptr(dst_pos, G3_elsize, dst_pos);
3049     __ add(src, src_pos, from);       // src_addr
3050     __ add(dst, dst_pos, to);         // dst_addr
3051 
3052     BLOCK_COMMENT("choose copy loop based on element size");
3053     __ cmp(G3_elsize, 0);
3054     __ br(Assembler::equal, true, Assembler::pt, entry_jbyte_arraycopy);
3055     __ delayed()->signx(length, count); // length
3056 
3057     __ cmp(G3_elsize, LogBytesPerShort);
3058     __ br(Assembler::equal, true, Assembler::pt, entry_jshort_arraycopy);
3059     __ delayed()->signx(length, count); // length
3060 
3061     __ cmp(G3_elsize, LogBytesPerInt);
3062     __ br(Assembler::equal, true, Assembler::pt, entry_jint_arraycopy);
3063     __ delayed()->signx(length, count); // length
3064 #ifdef ASSERT
3065     { Label L;
3066       __ cmp_and_br_short(G3_elsize, LogBytesPerLong, Assembler::equal, Assembler::pt, L);
3067       __ stop("must be long copy, but elsize is wrong");
3068       __ bind(L);
3069     }
3070 #endif
3071     __ br(Assembler::always, false, Assembler::pt, entry_jlong_arraycopy);
3072     __ delayed()->signx(length, count); // length
3073 
3074     // ObjArrayKlass
3075   __ BIND(L_objArray);
3076     // live at this point:  G3_src_klass, G4_dst_klass, src[_pos], dst[_pos], length
3077 
3078     Label L_plain_copy, L_checkcast_copy;
3079     //  test array classes for subtyping
3080     __ cmp(G3_src_klass, G4_dst_klass);         // usual case is exact equality
3081     __ brx(Assembler::notEqual, true, Assembler::pn, L_checkcast_copy);
3082     __ delayed()->lduw(G4_dst_klass, lh_offset, O5_temp); // hoisted from below
3083 
3084     // Identically typed arrays can be copied without element-wise checks.
3085     arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
3086                            O5_temp, G5_lh, L_failed);
3087 
3088     __ add(src, arrayOopDesc::base_offset_in_bytes(T_OBJECT), src); //src offset
3089     __ add(dst, arrayOopDesc::base_offset_in_bytes(T_OBJECT), dst); //dst offset
3090     __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
3091     __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
3092     __ add(src, src_pos, from);       // src_addr
3093     __ add(dst, dst_pos, to);         // dst_addr
3094   __ BIND(L_plain_copy);
3095     __ br(Assembler::always, false, Assembler::pt, entry_oop_arraycopy);
3096     __ delayed()->signx(length, count); // length
3097 
3098   __ BIND(L_checkcast_copy);
3099     // live at this point:  G3_src_klass, G4_dst_klass
3100     {
3101       // Before looking at dst.length, make sure dst is also an objArray.
3102       // lduw(G4_dst_klass, lh_offset, O5_temp); // hoisted to delay slot
3103       __ cmp(G5_lh,                    O5_temp);
3104       __ br(Assembler::notEqual, false, Assembler::pn, L_failed);
3105 
3106       // It is safe to examine both src.length and dst.length.
3107       __ delayed();                             // match next insn to prev branch
3108       arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
3109                              O5_temp, G5_lh, L_failed);
3110 
3111       // Marshal the base address arguments now, freeing registers.
3112       __ add(src, arrayOopDesc::base_offset_in_bytes(T_OBJECT), src); //src offset
3113       __ add(dst, arrayOopDesc::base_offset_in_bytes(T_OBJECT), dst); //dst offset
3114       __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
3115       __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
3116       __ add(src, src_pos, from);               // src_addr
3117       __ add(dst, dst_pos, to);                 // dst_addr
3118       __ signx(length, count);                  // length (reloaded)
3119 
3120       Register sco_temp = O3;                   // this register is free now
3121       assert_different_registers(from, to, count, sco_temp,
3122                                  G4_dst_klass, G3_src_klass);
3123 
3124       // Generate the type check.
3125       int sco_offset = in_bytes(Klass::super_check_offset_offset());
3126       __ lduw(G4_dst_klass, sco_offset, sco_temp);
3127       generate_type_check(G3_src_klass, sco_temp, G4_dst_klass,
3128                           O5_temp, L_plain_copy);
3129 
3130       // Fetch destination element klass from the ObjArrayKlass header.
3131       int ek_offset = in_bytes(ObjArrayKlass::element_klass_offset());
3132 
3133       // the checkcast_copy loop needs two extra arguments:
3134       __ ld_ptr(G4_dst_klass, ek_offset, O4);   // dest elem klass
3135       // lduw(O4, sco_offset, O3);              // sco of elem klass
3136 
3137       __ br(Assembler::always, false, Assembler::pt, entry_checkcast_arraycopy);
3138       __ delayed()->lduw(O4, sco_offset, O3);
3139     }
3140 
3141   __ BIND(L_failed);
3142     __ retl();
3143     __ delayed()->sub(G0, 1, O0); // return -1
3144     return start;
3145   }
3146 
3147   //
3148   //  Generate stub for heap zeroing.
3149   //  "to" address is aligned to jlong (8 bytes).
3150   //
3151   // Arguments for generated stub:
3152   //      to:    O0
3153   //      count: O1 treated as signed (count of HeapWord)
3154   //             count could be 0
3155   //
3156   address generate_zero_aligned_words(const char* name) {
3157     __ align(CodeEntryAlignment);
3158     StubCodeMark mark(this, "StubRoutines", name);
3159     address start = __ pc();
3160 
3161     const Register to    = O0;   // source array address
3162     const Register count = O1;   // HeapWords count
3163     const Register temp  = O2;   // scratch
3164 
3165     Label Ldone;
3166     __ sllx(count, LogHeapWordSize, count); // to bytes count
3167     // Use BIS for zeroing
3168     __ bis_zeroing(to, count, temp, Ldone);
3169     __ bind(Ldone);
3170     __ retl();
3171     __ delayed()->nop();
3172     return start;
3173 }
3174 
3175   void generate_arraycopy_stubs() {
3176     address entry;
3177     address entry_jbyte_arraycopy;
3178     address entry_jshort_arraycopy;
3179     address entry_jint_arraycopy;
3180     address entry_oop_arraycopy;
3181     address entry_jlong_arraycopy;
3182     address entry_checkcast_arraycopy;
3183 
3184     //*** jbyte
3185     // Always need aligned and unaligned versions
3186     StubRoutines::_jbyte_disjoint_arraycopy         = generate_disjoint_byte_copy(false, &entry,
3187                                                                                   "jbyte_disjoint_arraycopy");
3188     StubRoutines::_jbyte_arraycopy                  = generate_conjoint_byte_copy(false, entry,
3189                                                                                   &entry_jbyte_arraycopy,
3190                                                                                   "jbyte_arraycopy");
3191     StubRoutines::_arrayof_jbyte_disjoint_arraycopy = generate_disjoint_byte_copy(true, &entry,
3192                                                                                   "arrayof_jbyte_disjoint_arraycopy");
3193     StubRoutines::_arrayof_jbyte_arraycopy          = generate_conjoint_byte_copy(true, entry, NULL,
3194                                                                                   "arrayof_jbyte_arraycopy");
3195 
3196     //*** jshort
3197     // Always need aligned and unaligned versions
3198     StubRoutines::_jshort_disjoint_arraycopy         = generate_disjoint_short_copy(false, &entry,
3199                                                                                     "jshort_disjoint_arraycopy");
3200     StubRoutines::_jshort_arraycopy                  = generate_conjoint_short_copy(false, entry,
3201                                                                                     &entry_jshort_arraycopy,
3202                                                                                     "jshort_arraycopy");
3203     StubRoutines::_arrayof_jshort_disjoint_arraycopy = generate_disjoint_short_copy(true, &entry,
3204                                                                                     "arrayof_jshort_disjoint_arraycopy");
3205     StubRoutines::_arrayof_jshort_arraycopy          = generate_conjoint_short_copy(true, entry, NULL,
3206                                                                                     "arrayof_jshort_arraycopy");
3207 
3208     //*** jint
3209     // Aligned versions
3210     StubRoutines::_arrayof_jint_disjoint_arraycopy = generate_disjoint_int_copy(true, &entry,
3211                                                                                 "arrayof_jint_disjoint_arraycopy");
3212     StubRoutines::_arrayof_jint_arraycopy          = generate_conjoint_int_copy(true, entry, &entry_jint_arraycopy,
3213                                                                                 "arrayof_jint_arraycopy");
3214 #ifdef _LP64
3215     // In 64 bit we need both aligned and unaligned versions of jint arraycopy.
3216     // entry_jint_arraycopy always points to the unaligned version (notice that we overwrite it).
3217     StubRoutines::_jint_disjoint_arraycopy         = generate_disjoint_int_copy(false, &entry,
3218                                                                                 "jint_disjoint_arraycopy");
3219     StubRoutines::_jint_arraycopy                  = generate_conjoint_int_copy(false, entry,
3220                                                                                 &entry_jint_arraycopy,
3221                                                                                 "jint_arraycopy");
3222 #else
3223     // In 32 bit jints are always HeapWordSize aligned, so always use the aligned version
3224     // (in fact in 32bit we always have a pre-loop part even in the aligned version,
3225     //  because it uses 64-bit loads/stores, so the aligned flag is actually ignored).
3226     StubRoutines::_jint_disjoint_arraycopy = StubRoutines::_arrayof_jint_disjoint_arraycopy;
3227     StubRoutines::_jint_arraycopy          = StubRoutines::_arrayof_jint_arraycopy;
3228 #endif
3229 
3230 
3231     //*** jlong
3232     // It is always aligned
3233     StubRoutines::_arrayof_jlong_disjoint_arraycopy = generate_disjoint_long_copy(true, &entry,
3234                                                                                   "arrayof_jlong_disjoint_arraycopy");
3235     StubRoutines::_arrayof_jlong_arraycopy          = generate_conjoint_long_copy(true, entry, &entry_jlong_arraycopy,
3236                                                                                   "arrayof_jlong_arraycopy");
3237     StubRoutines::_jlong_disjoint_arraycopy         = StubRoutines::_arrayof_jlong_disjoint_arraycopy;
3238     StubRoutines::_jlong_arraycopy                  = StubRoutines::_arrayof_jlong_arraycopy;
3239 
3240 
3241     //*** oops
3242     // Aligned versions
3243     StubRoutines::_arrayof_oop_disjoint_arraycopy        = generate_disjoint_oop_copy(true, &entry,
3244                                                                                       "arrayof_oop_disjoint_arraycopy");
3245     StubRoutines::_arrayof_oop_arraycopy                 = generate_conjoint_oop_copy(true, entry, &entry_oop_arraycopy,
3246                                                                                       "arrayof_oop_arraycopy");
3247     // Aligned versions without pre-barriers
3248     StubRoutines::_arrayof_oop_disjoint_arraycopy_uninit = generate_disjoint_oop_copy(true, &entry,
3249                                                                                       "arrayof_oop_disjoint_arraycopy_uninit",
3250                                                                                       /*dest_uninitialized*/true);
3251     StubRoutines::_arrayof_oop_arraycopy_uninit          = generate_conjoint_oop_copy(true, entry, NULL,
3252                                                                                       "arrayof_oop_arraycopy_uninit",
3253                                                                                       /*dest_uninitialized*/true);
3254 #ifdef _LP64
3255     if (UseCompressedOops) {
3256       // With compressed oops we need unaligned versions, notice that we overwrite entry_oop_arraycopy.
3257       StubRoutines::_oop_disjoint_arraycopy            = generate_disjoint_oop_copy(false, &entry,
3258                                                                                     "oop_disjoint_arraycopy");
3259       StubRoutines::_oop_arraycopy                     = generate_conjoint_oop_copy(false, entry, &entry_oop_arraycopy,
3260                                                                                     "oop_arraycopy");
3261       // Unaligned versions without pre-barriers
3262       StubRoutines::_oop_disjoint_arraycopy_uninit     = generate_disjoint_oop_copy(false, &entry,
3263                                                                                     "oop_disjoint_arraycopy_uninit",
3264                                                                                     /*dest_uninitialized*/true);
3265       StubRoutines::_oop_arraycopy_uninit              = generate_conjoint_oop_copy(false, entry, NULL,
3266                                                                                     "oop_arraycopy_uninit",
3267                                                                                     /*dest_uninitialized*/true);
3268     } else
3269 #endif
3270     {
3271       // oop arraycopy is always aligned on 32bit and 64bit without compressed oops
3272       StubRoutines::_oop_disjoint_arraycopy            = StubRoutines::_arrayof_oop_disjoint_arraycopy;
3273       StubRoutines::_oop_arraycopy                     = StubRoutines::_arrayof_oop_arraycopy;
3274       StubRoutines::_oop_disjoint_arraycopy_uninit     = StubRoutines::_arrayof_oop_disjoint_arraycopy_uninit;
3275       StubRoutines::_oop_arraycopy_uninit              = StubRoutines::_arrayof_oop_arraycopy_uninit;
3276     }
3277 
3278     StubRoutines::_checkcast_arraycopy        = generate_checkcast_copy("checkcast_arraycopy", &entry_checkcast_arraycopy);
3279     StubRoutines::_checkcast_arraycopy_uninit = generate_checkcast_copy("checkcast_arraycopy_uninit", NULL,
3280                                                                         /*dest_uninitialized*/true);
3281 
3282     StubRoutines::_unsafe_arraycopy    = generate_unsafe_copy("unsafe_arraycopy",
3283                                                               entry_jbyte_arraycopy,
3284                                                               entry_jshort_arraycopy,
3285                                                               entry_jint_arraycopy,
3286                                                               entry_jlong_arraycopy);
3287     StubRoutines::_generic_arraycopy   = generate_generic_copy("generic_arraycopy",
3288                                                                entry_jbyte_arraycopy,
3289                                                                entry_jshort_arraycopy,
3290                                                                entry_jint_arraycopy,
3291                                                                entry_oop_arraycopy,
3292                                                                entry_jlong_arraycopy,
3293                                                                entry_checkcast_arraycopy);
3294 
3295     StubRoutines::_jbyte_fill = generate_fill(T_BYTE, false, "jbyte_fill");
3296     StubRoutines::_jshort_fill = generate_fill(T_SHORT, false, "jshort_fill");
3297     StubRoutines::_jint_fill = generate_fill(T_INT, false, "jint_fill");
3298     StubRoutines::_arrayof_jbyte_fill = generate_fill(T_BYTE, true, "arrayof_jbyte_fill");
3299     StubRoutines::_arrayof_jshort_fill = generate_fill(T_SHORT, true, "arrayof_jshort_fill");
3300     StubRoutines::_arrayof_jint_fill = generate_fill(T_INT, true, "arrayof_jint_fill");
3301 
3302     if (UseBlockZeroing) {
3303       StubRoutines::_zero_aligned_words = generate_zero_aligned_words("zero_aligned_words");
3304     }
3305   }
3306 
3307   address generate_aescrypt_encryptBlock() {
3308     // required since we read expanded key 'int' array starting first element without alignment considerations
3309     assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
3310            "the following code assumes that first element of an int array is aligned to 8 bytes");
3311     __ align(CodeEntryAlignment);
3312     StubCodeMark mark(this, "StubRoutines", "aescrypt_encryptBlock");
3313     Label L_load_misaligned_input, L_load_expanded_key, L_doLast128bit, L_storeOutput, L_store_misaligned_output;
3314     address start = __ pc();
3315     Register from = O0; // source byte array
3316     Register to = O1;   // destination byte array
3317     Register key = O2;  // expanded key array
3318     const Register keylen = O4; //reg for storing expanded key array length
3319 
3320     // read expanded key length
3321     __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);
3322 
3323     // Method to address arbitrary alignment for load instructions:
3324     // Check last 3 bits of 'from' address to see if it is aligned to 8-byte boundary
3325     // If zero/aligned then continue with double FP load instructions
3326     // If not zero/mis-aligned then alignaddr will set GSR.align with number of bytes to skip during faligndata
3327     // alignaddr will also convert arbitrary aligned 'from' address to nearest 8-byte aligned address
3328     // load 3 * 8-byte components (to read 16 bytes input) in 3 different FP regs starting at this aligned address
3329     // faligndata will then extract (based on GSR.align value) the appropriate 8 bytes from the 2 source regs
3330 
3331     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
3332     __ andcc(from, 7, G0);
3333     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input);
3334     __ delayed()->alignaddr(from, G0, from);
3335 
3336     // aligned case: load input into F54-F56
3337     __ ldf(FloatRegisterImpl::D, from, 0, F54);
3338     __ ldf(FloatRegisterImpl::D, from, 8, F56);
3339     __ ba_short(L_load_expanded_key);
3340 
3341     __ BIND(L_load_misaligned_input);
3342     __ ldf(FloatRegisterImpl::D, from, 0, F54);
3343     __ ldf(FloatRegisterImpl::D, from, 8, F56);
3344     __ ldf(FloatRegisterImpl::D, from, 16, F58);
3345     __ faligndata(F54, F56, F54);
3346     __ faligndata(F56, F58, F56);
3347 
3348     __ BIND(L_load_expanded_key);
3349     // Since we load expanded key buffers starting first element, 8-byte alignment is guaranteed
3350     for ( int i = 0;  i <= 38; i += 2 ) {
3351       __ ldf(FloatRegisterImpl::D, key, i*4, as_FloatRegister(i));
3352     }
3353 
3354     // perform cipher transformation
3355     __ fxor(FloatRegisterImpl::D, F0, F54, F54);
3356     __ fxor(FloatRegisterImpl::D, F2, F56, F56);
3357     // rounds 1 through 8
3358     for ( int i = 4;  i <= 28; i += 8 ) {
3359       __ aes_eround01(as_FloatRegister(i), F54, F56, F58);
3360       __ aes_eround23(as_FloatRegister(i+2), F54, F56, F60);
3361       __ aes_eround01(as_FloatRegister(i+4), F58, F60, F54);
3362       __ aes_eround23(as_FloatRegister(i+6), F58, F60, F56);
3363     }
3364     __ aes_eround01(F36, F54, F56, F58); //round 9
3365     __ aes_eround23(F38, F54, F56, F60);
3366 
3367     // 128-bit original key size
3368     __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pt, L_doLast128bit);
3369 
3370     for ( int i = 40;  i <= 50; i += 2 ) {
3371       __ ldf(FloatRegisterImpl::D, key, i*4, as_FloatRegister(i) );
3372     }
3373     __ aes_eround01(F40, F58, F60, F54); //round 10
3374     __ aes_eround23(F42, F58, F60, F56);
3375     __ aes_eround01(F44, F54, F56, F58); //round 11
3376     __ aes_eround23(F46, F54, F56, F60);
3377 
3378     // 192-bit original key size
3379     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pt, L_storeOutput);
3380 
3381     __ ldf(FloatRegisterImpl::D, key, 208, F52);
3382     __ aes_eround01(F48, F58, F60, F54); //round 12
3383     __ aes_eround23(F50, F58, F60, F56);
3384     __ ldf(FloatRegisterImpl::D, key, 216, F46);
3385     __ ldf(FloatRegisterImpl::D, key, 224, F48);
3386     __ ldf(FloatRegisterImpl::D, key, 232, F50);
3387     __ aes_eround01(F52, F54, F56, F58); //round 13
3388     __ aes_eround23(F46, F54, F56, F60);
3389     __ ba_short(L_storeOutput);
3390 
3391     __ BIND(L_doLast128bit);
3392     __ ldf(FloatRegisterImpl::D, key, 160, F48);
3393     __ ldf(FloatRegisterImpl::D, key, 168, F50);
3394 
3395     __ BIND(L_storeOutput);
3396     // perform last round of encryption common for all key sizes
3397     __ aes_eround01_l(F48, F58, F60, F54); //last round
3398     __ aes_eround23_l(F50, F58, F60, F56);
3399 
3400     // Method to address arbitrary alignment for store instructions:
3401     // Check last 3 bits of 'dest' address to see if it is aligned to 8-byte boundary
3402     // If zero/aligned then continue with double FP store instructions
3403     // If not zero/mis-aligned then edge8n will generate edge mask in result reg (O3 in below case)
3404     // Example: If dest address is 0x07 and nearest 8-byte aligned address is 0x00 then edge mask will be 00000001
3405     // Compute (8-n) where n is # of bytes skipped by partial store(stpartialf) inst from edge mask, n=7 in this case
3406     // We get the value of n from the andcc that checks 'dest' alignment. n is available in O5 in below case.
3407     // Set GSR.align to (8-n) using alignaddr
3408     // Circular byte shift store values by n places so that the original bytes are at correct position for stpartialf
3409     // Set the arbitrarily aligned 'dest' address to nearest 8-byte aligned address
3410     // Store (partial) the original first (8-n) bytes starting at the original 'dest' address
3411     // Negate the edge mask so that the subsequent stpartialf can store the original (8-n-1)th through 8th bytes at appropriate address
3412     // We need to execute this process for both the 8-byte result values
3413 
3414     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
3415     __ andcc(to, 7, O5);
3416     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output);
3417     __ delayed()->edge8n(to, G0, O3);
3418 
3419     // aligned case: store output into the destination array
3420     __ stf(FloatRegisterImpl::D, F54, to, 0);
3421     __ retl();
3422     __ delayed()->stf(FloatRegisterImpl::D, F56, to, 8);
3423 
3424     __ BIND(L_store_misaligned_output);
3425     __ add(to, 8, O4);
3426     __ mov(8, O2);
3427     __ sub(O2, O5, O2);
3428     __ alignaddr(O2, G0, O2);
3429     __ faligndata(F54, F54, F54);
3430     __ faligndata(F56, F56, F56);
3431     __ and3(to, -8, to);
3432     __ and3(O4, -8, O4);
3433     __ stpartialf(to, O3, F54, Assembler::ASI_PST8_PRIMARY);
3434     __ stpartialf(O4, O3, F56, Assembler::ASI_PST8_PRIMARY);
3435     __ add(to, 8, to);
3436     __ add(O4, 8, O4);
3437     __ orn(G0, O3, O3);
3438     __ stpartialf(to, O3, F54, Assembler::ASI_PST8_PRIMARY);
3439     __ retl();
3440     __ delayed()->stpartialf(O4, O3, F56, Assembler::ASI_PST8_PRIMARY);
3441 
3442     return start;
3443   }
3444 
3445   address generate_aescrypt_decryptBlock() {
3446     assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
3447            "the following code assumes that first element of an int array is aligned to 8 bytes");
3448     // required since we read original key 'byte' array as well in the decryption stubs
3449     assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
3450            "the following code assumes that first element of a byte array is aligned to 8 bytes");
3451     __ align(CodeEntryAlignment);
3452     StubCodeMark mark(this, "StubRoutines", "aescrypt_decryptBlock");
3453     address start = __ pc();
3454     Label L_load_misaligned_input, L_load_original_key, L_expand192bit, L_expand256bit, L_reload_misaligned_input;
3455     Label L_256bit_transform, L_common_transform, L_store_misaligned_output;
3456     Register from = O0; // source byte array
3457     Register to = O1;   // destination byte array
3458     Register key = O2;  // expanded key array
3459     Register original_key = O3;  // original key array only required during decryption
3460     const Register keylen = O4;  // reg for storing expanded key array length
3461 
3462     // read expanded key array length
3463     __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);
3464 
3465     // save 'from' since we may need to recheck alignment in case of 256-bit decryption
3466     __ mov(from, G1);
3467 
3468     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
3469     __ andcc(from, 7, G0);
3470     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input);
3471     __ delayed()->alignaddr(from, G0, from);
3472 
3473     // aligned case: load input into F52-F54
3474     __ ldf(FloatRegisterImpl::D, from, 0, F52);
3475     __ ldf(FloatRegisterImpl::D, from, 8, F54);
3476     __ ba_short(L_load_original_key);
3477 
3478     __ BIND(L_load_misaligned_input);
3479     __ ldf(FloatRegisterImpl::D, from, 0, F52);
3480     __ ldf(FloatRegisterImpl::D, from, 8, F54);
3481     __ ldf(FloatRegisterImpl::D, from, 16, F56);
3482     __ faligndata(F52, F54, F52);
3483     __ faligndata(F54, F56, F54);
3484 
3485     __ BIND(L_load_original_key);
3486     // load original key from SunJCE expanded decryption key
3487     // Since we load original key buffer starting first element, 8-byte alignment is guaranteed
3488     for ( int i = 0;  i <= 3; i++ ) {
3489       __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
3490     }
3491 
3492     // 256-bit original key size
3493     __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_expand256bit);
3494 
3495     // 192-bit original key size
3496     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_expand192bit);
3497 
3498     // 128-bit original key size
3499     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
3500     for ( int i = 0;  i <= 36; i += 4 ) {
3501       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+2), i/4, as_FloatRegister(i+4));
3502       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+4), as_FloatRegister(i+6));
3503     }
3504 
3505     // perform 128-bit key specific inverse cipher transformation
3506     __ fxor(FloatRegisterImpl::D, F42, F54, F54);
3507     __ fxor(FloatRegisterImpl::D, F40, F52, F52);
3508     __ ba_short(L_common_transform);
3509 
3510     __ BIND(L_expand192bit);
3511 
3512     // start loading rest of the 192-bit key
3513     __ ldf(FloatRegisterImpl::S, original_key, 16, F4);
3514     __ ldf(FloatRegisterImpl::S, original_key, 20, F5);
3515 
3516     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
3517     for ( int i = 0;  i <= 36; i += 6 ) {
3518       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+4), i/6, as_FloatRegister(i+6));
3519       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+6), as_FloatRegister(i+8));
3520       __ aes_kexpand2(as_FloatRegister(i+4), as_FloatRegister(i+8), as_FloatRegister(i+10));
3521     }
3522     __ aes_kexpand1(F42, F46, 7, F48);
3523     __ aes_kexpand2(F44, F48, F50);
3524 
3525     // perform 192-bit key specific inverse cipher transformation
3526     __ fxor(FloatRegisterImpl::D, F50, F54, F54);
3527     __ fxor(FloatRegisterImpl::D, F48, F52, F52);
3528     __ aes_dround23(F46, F52, F54, F58);
3529     __ aes_dround01(F44, F52, F54, F56);
3530     __ aes_dround23(F42, F56, F58, F54);
3531     __ aes_dround01(F40, F56, F58, F52);
3532     __ ba_short(L_common_transform);
3533 
3534     __ BIND(L_expand256bit);
3535 
3536     // load rest of the 256-bit key
3537     for ( int i = 4;  i <= 7; i++ ) {
3538       __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
3539     }
3540 
3541     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
3542     for ( int i = 0;  i <= 40; i += 8 ) {
3543       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+6), i/8, as_FloatRegister(i+8));
3544       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+8), as_FloatRegister(i+10));
3545       __ aes_kexpand0(as_FloatRegister(i+4), as_FloatRegister(i+10), as_FloatRegister(i+12));
3546       __ aes_kexpand2(as_FloatRegister(i+6), as_FloatRegister(i+12), as_FloatRegister(i+14));
3547     }
3548     __ aes_kexpand1(F48, F54, 6, F56);
3549     __ aes_kexpand2(F50, F56, F58);
3550 
3551     for ( int i = 0;  i <= 6; i += 2 ) {
3552       __ fsrc2(FloatRegisterImpl::D, as_FloatRegister(58-i), as_FloatRegister(i));
3553     }
3554 
3555     // reload original 'from' address
3556     __ mov(G1, from);
3557 
3558     // re-check 8-byte alignment
3559     __ andcc(from, 7, G0);
3560     __ br(Assembler::notZero, true, Assembler::pn, L_reload_misaligned_input);
3561     __ delayed()->alignaddr(from, G0, from);
3562 
3563     // aligned case: load input into F52-F54
3564     __ ldf(FloatRegisterImpl::D, from, 0, F52);
3565     __ ldf(FloatRegisterImpl::D, from, 8, F54);
3566     __ ba_short(L_256bit_transform);
3567 
3568     __ BIND(L_reload_misaligned_input);
3569     __ ldf(FloatRegisterImpl::D, from, 0, F52);
3570     __ ldf(FloatRegisterImpl::D, from, 8, F54);
3571     __ ldf(FloatRegisterImpl::D, from, 16, F56);
3572     __ faligndata(F52, F54, F52);
3573     __ faligndata(F54, F56, F54);
3574 
3575     // perform 256-bit key specific inverse cipher transformation
3576     __ BIND(L_256bit_transform);
3577     __ fxor(FloatRegisterImpl::D, F0, F54, F54);
3578     __ fxor(FloatRegisterImpl::D, F2, F52, F52);
3579     __ aes_dround23(F4, F52, F54, F58);
3580     __ aes_dround01(F6, F52, F54, F56);
3581     __ aes_dround23(F50, F56, F58, F54);
3582     __ aes_dround01(F48, F56, F58, F52);
3583     __ aes_dround23(F46, F52, F54, F58);
3584     __ aes_dround01(F44, F52, F54, F56);
3585     __ aes_dround23(F42, F56, F58, F54);
3586     __ aes_dround01(F40, F56, F58, F52);
3587 
3588     for ( int i = 0;  i <= 7; i++ ) {
3589       __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
3590     }
3591 
3592     // perform inverse cipher transformations common for all key sizes
3593     __ BIND(L_common_transform);
3594     for ( int i = 38;  i >= 6; i -= 8 ) {
3595       __ aes_dround23(as_FloatRegister(i), F52, F54, F58);
3596       __ aes_dround01(as_FloatRegister(i-2), F52, F54, F56);
3597       if ( i != 6) {
3598         __ aes_dround23(as_FloatRegister(i-4), F56, F58, F54);
3599         __ aes_dround01(as_FloatRegister(i-6), F56, F58, F52);
3600       } else {
3601         __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F54);
3602         __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F52);
3603       }
3604     }
3605 
3606     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
3607     __ andcc(to, 7, O5);
3608     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output);
3609     __ delayed()->edge8n(to, G0, O3);
3610 
3611     // aligned case: store output into the destination array
3612     __ stf(FloatRegisterImpl::D, F52, to, 0);
3613     __ retl();
3614     __ delayed()->stf(FloatRegisterImpl::D, F54, to, 8);
3615 
3616     __ BIND(L_store_misaligned_output);
3617     __ add(to, 8, O4);
3618     __ mov(8, O2);
3619     __ sub(O2, O5, O2);
3620     __ alignaddr(O2, G0, O2);
3621     __ faligndata(F52, F52, F52);
3622     __ faligndata(F54, F54, F54);
3623     __ and3(to, -8, to);
3624     __ and3(O4, -8, O4);
3625     __ stpartialf(to, O3, F52, Assembler::ASI_PST8_PRIMARY);
3626     __ stpartialf(O4, O3, F54, Assembler::ASI_PST8_PRIMARY);
3627     __ add(to, 8, to);
3628     __ add(O4, 8, O4);
3629     __ orn(G0, O3, O3);
3630     __ stpartialf(to, O3, F52, Assembler::ASI_PST8_PRIMARY);
3631     __ retl();
3632     __ delayed()->stpartialf(O4, O3, F54, Assembler::ASI_PST8_PRIMARY);
3633 
3634     return start;
3635   }
3636 
3637   address generate_cipherBlockChaining_encryptAESCrypt() {
3638     assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
3639            "the following code assumes that first element of an int array is aligned to 8 bytes");
3640     assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
3641            "the following code assumes that first element of a byte array is aligned to 8 bytes");
3642     __ align(CodeEntryAlignment);
3643     StubCodeMark mark(this, "StubRoutines", "cipherBlockChaining_encryptAESCrypt");
3644     Label L_cbcenc128, L_load_misaligned_input_128bit, L_128bit_transform, L_store_misaligned_output_128bit;
3645     Label L_check_loop_end_128bit, L_cbcenc192, L_load_misaligned_input_192bit, L_192bit_transform;
3646     Label L_store_misaligned_output_192bit, L_check_loop_end_192bit, L_cbcenc256, L_load_misaligned_input_256bit;
3647     Label L_256bit_transform, L_store_misaligned_output_256bit, L_check_loop_end_256bit;
3648     address start = __ pc();
3649     Register from = I0; // source byte array
3650     Register to = I1;   // destination byte array
3651     Register key = I2;  // expanded key array
3652     Register rvec = I3; // init vector
3653     const Register len_reg = I4; // cipher length
3654     const Register keylen = I5;  // reg for storing expanded key array length
3655 
3656     __ save_frame(0);
3657     // save cipher len to return in the end
3658     __ mov(len_reg, L0);
3659 
3660     // read expanded key length
3661     __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);
3662 
3663     // load initial vector, 8-byte alignment is guranteed
3664     __ ldf(FloatRegisterImpl::D, rvec, 0, F60);
3665     __ ldf(FloatRegisterImpl::D, rvec, 8, F62);
3666     // load key, 8-byte alignment is guranteed
3667     __ ldx(key,0,G1);
3668     __ ldx(key,8,G5);
3669 
3670     // start loading expanded key, 8-byte alignment is guranteed
3671     for ( int i = 0, j = 16;  i <= 38; i += 2, j += 8 ) {
3672       __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
3673     }
3674 
3675     // 128-bit original key size
3676     __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pt, L_cbcenc128);
3677 
3678     for ( int i = 40, j = 176;  i <= 46; i += 2, j += 8 ) {
3679       __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
3680     }
3681 
3682     // 192-bit original key size
3683     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pt, L_cbcenc192);
3684 
3685     for ( int i = 48, j = 208;  i <= 54; i += 2, j += 8 ) {
3686       __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
3687     }
3688 
3689     // 256-bit original key size
3690     __ ba_short(L_cbcenc256);
3691 
3692     __ align(OptoLoopAlignment);
3693     __ BIND(L_cbcenc128);
3694     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
3695     __ andcc(from, 7, G0);
3696     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_128bit);
3697     __ delayed()->mov(from, L1); // save original 'from' address before alignaddr
3698 
3699     // aligned case: load input into G3 and G4
3700     __ ldx(from,0,G3);
3701     __ ldx(from,8,G4);
3702     __ ba_short(L_128bit_transform);
3703 
3704     __ BIND(L_load_misaligned_input_128bit);
3705     // can clobber F48, F50 and F52 as they are not used in 128 and 192-bit key encryption
3706     __ alignaddr(from, G0, from);
3707     __ ldf(FloatRegisterImpl::D, from, 0, F48);
3708     __ ldf(FloatRegisterImpl::D, from, 8, F50);
3709     __ ldf(FloatRegisterImpl::D, from, 16, F52);
3710     __ faligndata(F48, F50, F48);
3711     __ faligndata(F50, F52, F50);
3712     __ movdtox(F48, G3);
3713     __ movdtox(F50, G4);
3714     __ mov(L1, from);
3715 
3716     __ BIND(L_128bit_transform);
3717     __ xor3(G1,G3,G3);
3718     __ xor3(G5,G4,G4);
3719     __ movxtod(G3,F56);
3720     __ movxtod(G4,F58);
3721     __ fxor(FloatRegisterImpl::D, F60, F56, F60);
3722     __ fxor(FloatRegisterImpl::D, F62, F58, F62);
3723 
3724     // TEN_EROUNDS
3725     for ( int i = 0;  i <= 32; i += 8 ) {
3726       __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
3727       __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
3728       if (i != 32 ) {
3729         __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
3730         __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
3731       } else {
3732         __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
3733         __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
3734       }
3735     }
3736 
3737     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
3738     __ andcc(to, 7, L1);
3739     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_128bit);
3740     __ delayed()->edge8n(to, G0, L2);
3741 
3742     // aligned case: store output into the destination array
3743     __ stf(FloatRegisterImpl::D, F60, to, 0);
3744     __ stf(FloatRegisterImpl::D, F62, to, 8);
3745     __ ba_short(L_check_loop_end_128bit);
3746 
3747     __ BIND(L_store_misaligned_output_128bit);
3748     __ add(to, 8, L3);
3749     __ mov(8, L4);
3750     __ sub(L4, L1, L4);
3751     __ alignaddr(L4, G0, L4);
3752     // save cipher text before circular right shift
3753     // as it needs to be stored as iv for next block (see code before next retl)
3754     __ movdtox(F60, L6);
3755     __ movdtox(F62, L7);
3756     __ faligndata(F60, F60, F60);
3757     __ faligndata(F62, F62, F62);
3758     __ mov(to, L5);
3759     __ and3(to, -8, to);
3760     __ and3(L3, -8, L3);
3761     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3762     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3763     __ add(to, 8, to);
3764     __ add(L3, 8, L3);
3765     __ orn(G0, L2, L2);
3766     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3767     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3768     __ mov(L5, to);
3769     __ movxtod(L6, F60);
3770     __ movxtod(L7, F62);
3771 
3772     __ BIND(L_check_loop_end_128bit);
3773     __ add(from, 16, from);
3774     __ add(to, 16, to);
3775     __ subcc(len_reg, 16, len_reg);
3776     __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc128);
3777     __ delayed()->nop();
3778     // re-init intial vector for next block, 8-byte alignment is guaranteed
3779     __ stf(FloatRegisterImpl::D, F60, rvec, 0);
3780     __ stf(FloatRegisterImpl::D, F62, rvec, 8);
3781     __ mov(L0, I0);
3782     __ ret();
3783     __ delayed()->restore();
3784 
3785     __ align(OptoLoopAlignment);
3786     __ BIND(L_cbcenc192);
3787     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
3788     __ andcc(from, 7, G0);
3789     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_192bit);
3790     __ delayed()->mov(from, L1); // save original 'from' address before alignaddr
3791 
3792     // aligned case: load input into G3 and G4
3793     __ ldx(from,0,G3);
3794     __ ldx(from,8,G4);
3795     __ ba_short(L_192bit_transform);
3796 
3797     __ BIND(L_load_misaligned_input_192bit);
3798     // can clobber F48, F50 and F52 as they are not used in 128 and 192-bit key encryption
3799     __ alignaddr(from, G0, from);
3800     __ ldf(FloatRegisterImpl::D, from, 0, F48);
3801     __ ldf(FloatRegisterImpl::D, from, 8, F50);
3802     __ ldf(FloatRegisterImpl::D, from, 16, F52);
3803     __ faligndata(F48, F50, F48);
3804     __ faligndata(F50, F52, F50);
3805     __ movdtox(F48, G3);
3806     __ movdtox(F50, G4);
3807     __ mov(L1, from);
3808 
3809     __ BIND(L_192bit_transform);
3810     __ xor3(G1,G3,G3);
3811     __ xor3(G5,G4,G4);
3812     __ movxtod(G3,F56);
3813     __ movxtod(G4,F58);
3814     __ fxor(FloatRegisterImpl::D, F60, F56, F60);
3815     __ fxor(FloatRegisterImpl::D, F62, F58, F62);
3816 
3817     // TWELEVE_EROUNDS
3818     for ( int i = 0;  i <= 40; i += 8 ) {
3819       __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
3820       __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
3821       if (i != 40 ) {
3822         __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
3823         __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
3824       } else {
3825         __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
3826         __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
3827       }
3828     }
3829 
3830     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
3831     __ andcc(to, 7, L1);
3832     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_192bit);
3833     __ delayed()->edge8n(to, G0, L2);
3834 
3835     // aligned case: store output into the destination array
3836     __ stf(FloatRegisterImpl::D, F60, to, 0);
3837     __ stf(FloatRegisterImpl::D, F62, to, 8);
3838     __ ba_short(L_check_loop_end_192bit);
3839 
3840     __ BIND(L_store_misaligned_output_192bit);
3841     __ add(to, 8, L3);
3842     __ mov(8, L4);
3843     __ sub(L4, L1, L4);
3844     __ alignaddr(L4, G0, L4);
3845     __ movdtox(F60, L6);
3846     __ movdtox(F62, L7);
3847     __ faligndata(F60, F60, F60);
3848     __ faligndata(F62, F62, F62);
3849     __ mov(to, L5);
3850     __ and3(to, -8, to);
3851     __ and3(L3, -8, L3);
3852     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3853     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3854     __ add(to, 8, to);
3855     __ add(L3, 8, L3);
3856     __ orn(G0, L2, L2);
3857     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3858     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3859     __ mov(L5, to);
3860     __ movxtod(L6, F60);
3861     __ movxtod(L7, F62);
3862 
3863     __ BIND(L_check_loop_end_192bit);
3864     __ add(from, 16, from);
3865     __ subcc(len_reg, 16, len_reg);
3866     __ add(to, 16, to);
3867     __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc192);
3868     __ delayed()->nop();
3869     // re-init intial vector for next block, 8-byte alignment is guaranteed
3870     __ stf(FloatRegisterImpl::D, F60, rvec, 0);
3871     __ stf(FloatRegisterImpl::D, F62, rvec, 8);
3872     __ mov(L0, I0);
3873     __ ret();
3874     __ delayed()->restore();
3875 
3876     __ align(OptoLoopAlignment);
3877     __ BIND(L_cbcenc256);
3878     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
3879     __ andcc(from, 7, G0);
3880     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_256bit);
3881     __ delayed()->mov(from, L1); // save original 'from' address before alignaddr
3882 
3883     // aligned case: load input into G3 and G4
3884     __ ldx(from,0,G3);
3885     __ ldx(from,8,G4);
3886     __ ba_short(L_256bit_transform);
3887 
3888     __ BIND(L_load_misaligned_input_256bit);
3889     // cannot clobber F48, F50 and F52. F56, F58 can be used though
3890     __ alignaddr(from, G0, from);
3891     __ movdtox(F60, L2); // save F60 before overwriting
3892     __ ldf(FloatRegisterImpl::D, from, 0, F56);
3893     __ ldf(FloatRegisterImpl::D, from, 8, F58);
3894     __ ldf(FloatRegisterImpl::D, from, 16, F60);
3895     __ faligndata(F56, F58, F56);
3896     __ faligndata(F58, F60, F58);
3897     __ movdtox(F56, G3);
3898     __ movdtox(F58, G4);
3899     __ mov(L1, from);
3900     __ movxtod(L2, F60);
3901 
3902     __ BIND(L_256bit_transform);
3903     __ xor3(G1,G3,G3);
3904     __ xor3(G5,G4,G4);
3905     __ movxtod(G3,F56);
3906     __ movxtod(G4,F58);
3907     __ fxor(FloatRegisterImpl::D, F60, F56, F60);
3908     __ fxor(FloatRegisterImpl::D, F62, F58, F62);
3909 
3910     // FOURTEEN_EROUNDS
3911     for ( int i = 0;  i <= 48; i += 8 ) {
3912       __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
3913       __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
3914       if (i != 48 ) {
3915         __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
3916         __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
3917       } else {
3918         __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
3919         __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
3920       }
3921     }
3922 
3923     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
3924     __ andcc(to, 7, L1);
3925     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_256bit);
3926     __ delayed()->edge8n(to, G0, L2);
3927 
3928     // aligned case: store output into the destination array
3929     __ stf(FloatRegisterImpl::D, F60, to, 0);
3930     __ stf(FloatRegisterImpl::D, F62, to, 8);
3931     __ ba_short(L_check_loop_end_256bit);
3932 
3933     __ BIND(L_store_misaligned_output_256bit);
3934     __ add(to, 8, L3);
3935     __ mov(8, L4);
3936     __ sub(L4, L1, L4);
3937     __ alignaddr(L4, G0, L4);
3938     __ movdtox(F60, L6);
3939     __ movdtox(F62, L7);
3940     __ faligndata(F60, F60, F60);
3941     __ faligndata(F62, F62, F62);
3942     __ mov(to, L5);
3943     __ and3(to, -8, to);
3944     __ and3(L3, -8, L3);
3945     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3946     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3947     __ add(to, 8, to);
3948     __ add(L3, 8, L3);
3949     __ orn(G0, L2, L2);
3950     __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
3951     __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
3952     __ mov(L5, to);
3953     __ movxtod(L6, F60);
3954     __ movxtod(L7, F62);
3955 
3956     __ BIND(L_check_loop_end_256bit);
3957     __ add(from, 16, from);
3958     __ subcc(len_reg, 16, len_reg);
3959     __ add(to, 16, to);
3960     __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc256);
3961     __ delayed()->nop();
3962     // re-init intial vector for next block, 8-byte alignment is guaranteed
3963     __ stf(FloatRegisterImpl::D, F60, rvec, 0);
3964     __ stf(FloatRegisterImpl::D, F62, rvec, 8);
3965     __ mov(L0, I0);
3966     __ ret();
3967     __ delayed()->restore();
3968 
3969     return start;
3970   }
3971 
3972   address generate_cipherBlockChaining_decryptAESCrypt_Parallel() {
3973     assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
3974            "the following code assumes that first element of an int array is aligned to 8 bytes");
3975     assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
3976            "the following code assumes that first element of a byte array is aligned to 8 bytes");
3977     __ align(CodeEntryAlignment);
3978     StubCodeMark mark(this, "StubRoutines", "cipherBlockChaining_decryptAESCrypt");
3979     Label L_cbcdec_end, L_expand192bit, L_expand256bit, L_dec_first_block_start;
3980     Label L_dec_first_block128, L_dec_first_block192, L_dec_next2_blocks128, L_dec_next2_blocks192, L_dec_next2_blocks256;
3981     Label L_load_misaligned_input_first_block, L_transform_first_block, L_load_misaligned_next2_blocks128, L_transform_next2_blocks128;
3982     Label L_load_misaligned_next2_blocks192, L_transform_next2_blocks192, L_load_misaligned_next2_blocks256, L_transform_next2_blocks256;
3983     Label L_store_misaligned_output_first_block, L_check_decrypt_end, L_store_misaligned_output_next2_blocks128;
3984     Label L_check_decrypt_loop_end128, L_store_misaligned_output_next2_blocks192, L_check_decrypt_loop_end192;
3985     Label L_store_misaligned_output_next2_blocks256, L_check_decrypt_loop_end256;
3986     address start = __ pc();
3987     Register from = I0; // source byte array
3988     Register to = I1;   // destination byte array
3989     Register key = I2;  // expanded key array
3990     Register rvec = I3; // init vector
3991     const Register len_reg = I4; // cipher length
3992     const Register original_key = I5;  // original key array only required during decryption
3993     const Register keylen = L6;  // reg for storing expanded key array length
3994 
3995     __ save_frame(0); //args are read from I* registers since we save the frame in the beginning
3996     // save cipher len to return in the end
3997     __ mov(len_reg, L7);
3998 
3999     // load original key from SunJCE expanded decryption key
4000     // Since we load original key buffer starting first element, 8-byte alignment is guaranteed
4001     for ( int i = 0;  i <= 3; i++ ) {
4002       __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
4003     }
4004 
4005     // load initial vector, 8-byte alignment is guaranteed
4006     __ ldx(rvec,0,L0);
4007     __ ldx(rvec,8,L1);
4008 
4009     // read expanded key array length
4010     __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);
4011 
4012     // 256-bit original key size
4013     __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_expand256bit);
4014 
4015     // 192-bit original key size
4016     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_expand192bit);
4017 
4018     // 128-bit original key size
4019     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
4020     for ( int i = 0;  i <= 36; i += 4 ) {
4021       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+2), i/4, as_FloatRegister(i+4));
4022       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+4), as_FloatRegister(i+6));
4023     }
4024 
4025     // load expanded key[last-1] and key[last] elements
4026     __ movdtox(F40,L2);
4027     __ movdtox(F42,L3);
4028 
4029     __ and3(len_reg, 16, L4);
4030     __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks128);
4031     __ nop();
4032 
4033     __ ba_short(L_dec_first_block_start);
4034 
4035     __ BIND(L_expand192bit);
4036     // load rest of the 192-bit key
4037     __ ldf(FloatRegisterImpl::S, original_key, 16, F4);
4038     __ ldf(FloatRegisterImpl::S, original_key, 20, F5);
4039 
4040     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
4041     for ( int i = 0;  i <= 36; i += 6 ) {
4042       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+4), i/6, as_FloatRegister(i+6));
4043       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+6), as_FloatRegister(i+8));
4044       __ aes_kexpand2(as_FloatRegister(i+4), as_FloatRegister(i+8), as_FloatRegister(i+10));
4045     }
4046     __ aes_kexpand1(F42, F46, 7, F48);
4047     __ aes_kexpand2(F44, F48, F50);
4048 
4049     // load expanded key[last-1] and key[last] elements
4050     __ movdtox(F48,L2);
4051     __ movdtox(F50,L3);
4052 
4053     __ and3(len_reg, 16, L4);
4054     __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks192);
4055     __ nop();
4056 
4057     __ ba_short(L_dec_first_block_start);
4058 
4059     __ BIND(L_expand256bit);
4060     // load rest of the 256-bit key
4061     for ( int i = 4;  i <= 7; i++ ) {
4062       __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
4063     }
4064 
4065     // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
4066     for ( int i = 0;  i <= 40; i += 8 ) {
4067       __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+6), i/8, as_FloatRegister(i+8));
4068       __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+8), as_FloatRegister(i+10));
4069       __ aes_kexpand0(as_FloatRegister(i+4), as_FloatRegister(i+10), as_FloatRegister(i+12));
4070       __ aes_kexpand2(as_FloatRegister(i+6), as_FloatRegister(i+12), as_FloatRegister(i+14));
4071     }
4072     __ aes_kexpand1(F48, F54, 6, F56);
4073     __ aes_kexpand2(F50, F56, F58);
4074 
4075     // load expanded key[last-1] and key[last] elements
4076     __ movdtox(F56,L2);
4077     __ movdtox(F58,L3);
4078 
4079     __ and3(len_reg, 16, L4);
4080     __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks256);
4081 
4082     __ BIND(L_dec_first_block_start);
4083     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
4084     __ andcc(from, 7, G0);
4085     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_first_block);
4086     __ delayed()->mov(from, G1); // save original 'from' address before alignaddr
4087 
4088     // aligned case: load input into L4 and L5
4089     __ ldx(from,0,L4);
4090     __ ldx(from,8,L5);
4091     __ ba_short(L_transform_first_block);
4092 
4093     __ BIND(L_load_misaligned_input_first_block);
4094     __ alignaddr(from, G0, from);
4095     // F58, F60, F62 can be clobbered
4096     __ ldf(FloatRegisterImpl::D, from, 0, F58);
4097     __ ldf(FloatRegisterImpl::D, from, 8, F60);
4098     __ ldf(FloatRegisterImpl::D, from, 16, F62);
4099     __ faligndata(F58, F60, F58);
4100     __ faligndata(F60, F62, F60);
4101     __ movdtox(F58, L4);
4102     __ movdtox(F60, L5);
4103     __ mov(G1, from);
4104 
4105     __ BIND(L_transform_first_block);
4106     __ xor3(L2,L4,G1);
4107     __ movxtod(G1,F60);
4108     __ xor3(L3,L5,G1);
4109     __ movxtod(G1,F62);
4110 
4111     // 128-bit original key size
4112     __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pn, L_dec_first_block128);
4113 
4114     // 192-bit original key size
4115     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_dec_first_block192);
4116 
4117     __ aes_dround23(F54, F60, F62, F58);
4118     __ aes_dround01(F52, F60, F62, F56);
4119     __ aes_dround23(F50, F56, F58, F62);
4120     __ aes_dround01(F48, F56, F58, F60);
4121 
4122     __ BIND(L_dec_first_block192);
4123     __ aes_dround23(F46, F60, F62, F58);
4124     __ aes_dround01(F44, F60, F62, F56);
4125     __ aes_dround23(F42, F56, F58, F62);
4126     __ aes_dround01(F40, F56, F58, F60);
4127 
4128     __ BIND(L_dec_first_block128);
4129     for ( int i = 38;  i >= 6; i -= 8 ) {
4130       __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
4131       __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
4132       if ( i != 6) {
4133         __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
4134         __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
4135       } else {
4136         __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
4137         __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
4138       }
4139     }
4140 
4141     __ movxtod(L0,F56);
4142     __ movxtod(L1,F58);
4143     __ mov(L4,L0);
4144     __ mov(L5,L1);
4145     __ fxor(FloatRegisterImpl::D, F56, F60, F60);
4146     __ fxor(FloatRegisterImpl::D, F58, F62, F62);
4147 
4148     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
4149     __ andcc(to, 7, G1);
4150     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_first_block);
4151     __ delayed()->edge8n(to, G0, G2);
4152 
4153     // aligned case: store output into the destination array
4154     __ stf(FloatRegisterImpl::D, F60, to, 0);
4155     __ stf(FloatRegisterImpl::D, F62, to, 8);
4156     __ ba_short(L_check_decrypt_end);
4157 
4158     __ BIND(L_store_misaligned_output_first_block);
4159     __ add(to, 8, G3);
4160     __ mov(8, G4);
4161     __ sub(G4, G1, G4);
4162     __ alignaddr(G4, G0, G4);
4163     __ faligndata(F60, F60, F60);
4164     __ faligndata(F62, F62, F62);
4165     __ mov(to, G1);
4166     __ and3(to, -8, to);
4167     __ and3(G3, -8, G3);
4168     __ stpartialf(to, G2, F60, Assembler::ASI_PST8_PRIMARY);
4169     __ stpartialf(G3, G2, F62, Assembler::ASI_PST8_PRIMARY);
4170     __ add(to, 8, to);
4171     __ add(G3, 8, G3);
4172     __ orn(G0, G2, G2);
4173     __ stpartialf(to, G2, F60, Assembler::ASI_PST8_PRIMARY);
4174     __ stpartialf(G3, G2, F62, Assembler::ASI_PST8_PRIMARY);
4175     __ mov(G1, to);
4176 
4177     __ BIND(L_check_decrypt_end);
4178     __ add(from, 16, from);
4179     __ add(to, 16, to);
4180     __ subcc(len_reg, 16, len_reg);
4181     __ br(Assembler::equal, false, Assembler::pt, L_cbcdec_end);
4182     __ delayed()->nop();
4183 
4184     // 256-bit original key size
4185     __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_dec_next2_blocks256);
4186 
4187     // 192-bit original key size
4188     __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_dec_next2_blocks192);
4189 
4190     __ align(OptoLoopAlignment);
4191     __ BIND(L_dec_next2_blocks128);
4192     __ nop();
4193 
4194     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
4195     __ andcc(from, 7, G0);
4196     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks128);
4197     __ delayed()->mov(from, G1); // save original 'from' address before alignaddr
4198 
4199     // aligned case: load input into G4, G5, L4 and L5
4200     __ ldx(from,0,G4);
4201     __ ldx(from,8,G5);
4202     __ ldx(from,16,L4);
4203     __ ldx(from,24,L5);
4204     __ ba_short(L_transform_next2_blocks128);
4205 
4206     __ BIND(L_load_misaligned_next2_blocks128);
4207     __ alignaddr(from, G0, from);
4208     // F40, F42, F58, F60, F62 can be clobbered
4209     __ ldf(FloatRegisterImpl::D, from, 0, F40);
4210     __ ldf(FloatRegisterImpl::D, from, 8, F42);
4211     __ ldf(FloatRegisterImpl::D, from, 16, F60);
4212     __ ldf(FloatRegisterImpl::D, from, 24, F62);
4213     __ ldf(FloatRegisterImpl::D, from, 32, F58);
4214     __ faligndata(F40, F42, F40);
4215     __ faligndata(F42, F60, F42);
4216     __ faligndata(F60, F62, F60);
4217     __ faligndata(F62, F58, F62);
4218     __ movdtox(F40, G4);
4219     __ movdtox(F42, G5);
4220     __ movdtox(F60, L4);
4221     __ movdtox(F62, L5);
4222     __ mov(G1, from);
4223 
4224     __ BIND(L_transform_next2_blocks128);
4225     // F40:F42 used for first 16-bytes
4226     __ xor3(L2,G4,G1);
4227     __ movxtod(G1,F40);
4228     __ xor3(L3,G5,G1);
4229     __ movxtod(G1,F42);
4230 
4231     // F60:F62 used for next 16-bytes
4232     __ xor3(L2,L4,G1);
4233     __ movxtod(G1,F60);
4234     __ xor3(L3,L5,G1);
4235     __ movxtod(G1,F62);
4236 
4237     for ( int i = 38;  i >= 6; i -= 8 ) {
4238       __ aes_dround23(as_FloatRegister(i), F40, F42, F44);
4239       __ aes_dround01(as_FloatRegister(i-2), F40, F42, F46);
4240       __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
4241       __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
4242       if (i != 6 ) {
4243         __ aes_dround23(as_FloatRegister(i-4), F46, F44, F42);
4244         __ aes_dround01(as_FloatRegister(i-6), F46, F44, F40);
4245         __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
4246         __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
4247       } else {
4248         __ aes_dround23_l(as_FloatRegister(i-4), F46, F44, F42);
4249         __ aes_dround01_l(as_FloatRegister(i-6), F46, F44, F40);
4250         __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
4251         __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
4252       }
4253     }
4254 
4255     __ movxtod(L0,F46);
4256     __ movxtod(L1,F44);
4257     __ fxor(FloatRegisterImpl::D, F46, F40, F40);
4258     __ fxor(FloatRegisterImpl::D, F44, F42, F42);
4259 
4260     __ movxtod(G4,F56);
4261     __ movxtod(G5,F58);
4262     __ mov(L4,L0);
4263     __ mov(L5,L1);
4264     __ fxor(FloatRegisterImpl::D, F56, F60, F60);
4265     __ fxor(FloatRegisterImpl::D, F58, F62, F62);
4266 
4267     // For mis-aligned store of 32 bytes of result we can do:
4268     // Circular right-shift all 4 FP registers so that 'head' and 'tail'
4269     // parts that need to be stored starting at mis-aligned address are in a FP reg
4270     // the other 3 FP regs can thus be stored using regular store
4271     // we then use the edge + partial-store mechanism to store the 'head' and 'tail' parts
4272 
4273     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
4274     __ andcc(to, 7, G1);
4275     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks128);
4276     __ delayed()->edge8n(to, G0, G2);
4277 
4278     // aligned case: store output into the destination array
4279     __ stf(FloatRegisterImpl::D, F40, to, 0);
4280     __ stf(FloatRegisterImpl::D, F42, to, 8);
4281     __ stf(FloatRegisterImpl::D, F60, to, 16);
4282     __ stf(FloatRegisterImpl::D, F62, to, 24);
4283     __ ba_short(L_check_decrypt_loop_end128);
4284 
4285     __ BIND(L_store_misaligned_output_next2_blocks128);
4286     __ mov(8, G4);
4287     __ sub(G4, G1, G4);
4288     __ alignaddr(G4, G0, G4);
4289     __ faligndata(F40, F42, F56); // F56 can be clobbered
4290     __ faligndata(F42, F60, F42);
4291     __ faligndata(F60, F62, F60);
4292     __ faligndata(F62, F40, F40);
4293     __ mov(to, G1);
4294     __ and3(to, -8, to);
4295     __ stpartialf(to, G2, F40, Assembler::ASI_PST8_PRIMARY);
4296     __ stf(FloatRegisterImpl::D, F56, to, 8);
4297     __ stf(FloatRegisterImpl::D, F42, to, 16);
4298     __ stf(FloatRegisterImpl::D, F60, to, 24);
4299     __ add(to, 32, to);
4300     __ orn(G0, G2, G2);
4301     __ stpartialf(to, G2, F40, Assembler::ASI_PST8_PRIMARY);
4302     __ mov(G1, to);
4303 
4304     __ BIND(L_check_decrypt_loop_end128);
4305     __ add(from, 32, from);
4306     __ add(to, 32, to);
4307     __ subcc(len_reg, 32, len_reg);
4308     __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks128);
4309     __ delayed()->nop();
4310     __ ba_short(L_cbcdec_end);
4311 
4312     __ align(OptoLoopAlignment);
4313     __ BIND(L_dec_next2_blocks192);
4314     __ nop();
4315 
4316     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
4317     __ andcc(from, 7, G0);
4318     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks192);
4319     __ delayed()->mov(from, G1); // save original 'from' address before alignaddr
4320 
4321     // aligned case: load input into G4, G5, L4 and L5
4322     __ ldx(from,0,G4);
4323     __ ldx(from,8,G5);
4324     __ ldx(from,16,L4);
4325     __ ldx(from,24,L5);
4326     __ ba_short(L_transform_next2_blocks192);
4327 
4328     __ BIND(L_load_misaligned_next2_blocks192);
4329     __ alignaddr(from, G0, from);
4330     // F48, F50, F52, F60, F62 can be clobbered
4331     __ ldf(FloatRegisterImpl::D, from, 0, F48);
4332     __ ldf(FloatRegisterImpl::D, from, 8, F50);
4333     __ ldf(FloatRegisterImpl::D, from, 16, F60);
4334     __ ldf(FloatRegisterImpl::D, from, 24, F62);
4335     __ ldf(FloatRegisterImpl::D, from, 32, F52);
4336     __ faligndata(F48, F50, F48);
4337     __ faligndata(F50, F60, F50);
4338     __ faligndata(F60, F62, F60);
4339     __ faligndata(F62, F52, F62);
4340     __ movdtox(F48, G4);
4341     __ movdtox(F50, G5);
4342     __ movdtox(F60, L4);
4343     __ movdtox(F62, L5);
4344     __ mov(G1, from);
4345 
4346     __ BIND(L_transform_next2_blocks192);
4347     // F48:F50 used for first 16-bytes
4348     __ xor3(L2,G4,G1);
4349     __ movxtod(G1,F48);
4350     __ xor3(L3,G5,G1);
4351     __ movxtod(G1,F50);
4352 
4353     // F60:F62 used for next 16-bytes
4354     __ xor3(L2,L4,G1);
4355     __ movxtod(G1,F60);
4356     __ xor3(L3,L5,G1);
4357     __ movxtod(G1,F62);
4358 
4359     for ( int i = 46;  i >= 6; i -= 8 ) {
4360       __ aes_dround23(as_FloatRegister(i), F48, F50, F52);
4361       __ aes_dround01(as_FloatRegister(i-2), F48, F50, F54);
4362       __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
4363       __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
4364       if (i != 6 ) {
4365         __ aes_dround23(as_FloatRegister(i-4), F54, F52, F50);
4366         __ aes_dround01(as_FloatRegister(i-6), F54, F52, F48);
4367         __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
4368         __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
4369       } else {
4370         __ aes_dround23_l(as_FloatRegister(i-4), F54, F52, F50);
4371         __ aes_dround01_l(as_FloatRegister(i-6), F54, F52, F48);
4372         __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
4373         __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
4374       }
4375     }
4376 
4377     __ movxtod(L0,F54);
4378     __ movxtod(L1,F52);
4379     __ fxor(FloatRegisterImpl::D, F54, F48, F48);
4380     __ fxor(FloatRegisterImpl::D, F52, F50, F50);
4381 
4382     __ movxtod(G4,F56);
4383     __ movxtod(G5,F58);
4384     __ mov(L4,L0);
4385     __ mov(L5,L1);
4386     __ fxor(FloatRegisterImpl::D, F56, F60, F60);
4387     __ fxor(FloatRegisterImpl::D, F58, F62, F62);
4388 
4389     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
4390     __ andcc(to, 7, G1);
4391     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks192);
4392     __ delayed()->edge8n(to, G0, G2);
4393 
4394     // aligned case: store output into the destination array
4395     __ stf(FloatRegisterImpl::D, F48, to, 0);
4396     __ stf(FloatRegisterImpl::D, F50, to, 8);
4397     __ stf(FloatRegisterImpl::D, F60, to, 16);
4398     __ stf(FloatRegisterImpl::D, F62, to, 24);
4399     __ ba_short(L_check_decrypt_loop_end192);
4400 
4401     __ BIND(L_store_misaligned_output_next2_blocks192);
4402     __ mov(8, G4);
4403     __ sub(G4, G1, G4);
4404     __ alignaddr(G4, G0, G4);
4405     __ faligndata(F48, F50, F56); // F56 can be clobbered
4406     __ faligndata(F50, F60, F50);
4407     __ faligndata(F60, F62, F60);
4408     __ faligndata(F62, F48, F48);
4409     __ mov(to, G1);
4410     __ and3(to, -8, to);
4411     __ stpartialf(to, G2, F48, Assembler::ASI_PST8_PRIMARY);
4412     __ stf(FloatRegisterImpl::D, F56, to, 8);
4413     __ stf(FloatRegisterImpl::D, F50, to, 16);
4414     __ stf(FloatRegisterImpl::D, F60, to, 24);
4415     __ add(to, 32, to);
4416     __ orn(G0, G2, G2);
4417     __ stpartialf(to, G2, F48, Assembler::ASI_PST8_PRIMARY);
4418     __ mov(G1, to);
4419 
4420     __ BIND(L_check_decrypt_loop_end192);
4421     __ add(from, 32, from);
4422     __ add(to, 32, to);
4423     __ subcc(len_reg, 32, len_reg);
4424     __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks192);
4425     __ delayed()->nop();
4426     __ ba_short(L_cbcdec_end);
4427 
4428     __ align(OptoLoopAlignment);
4429     __ BIND(L_dec_next2_blocks256);
4430     __ nop();
4431 
4432     // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
4433     __ andcc(from, 7, G0);
4434     __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks256);
4435     __ delayed()->mov(from, G1); // save original 'from' address before alignaddr
4436 
4437     // aligned case: load input into G4, G5, L4 and L5
4438     __ ldx(from,0,G4);
4439     __ ldx(from,8,G5);
4440     __ ldx(from,16,L4);
4441     __ ldx(from,24,L5);
4442     __ ba_short(L_transform_next2_blocks256);
4443 
4444     __ BIND(L_load_misaligned_next2_blocks256);
4445     __ alignaddr(from, G0, from);
4446     // F0, F2, F4, F60, F62 can be clobbered
4447     __ ldf(FloatRegisterImpl::D, from, 0, F0);
4448     __ ldf(FloatRegisterImpl::D, from, 8, F2);
4449     __ ldf(FloatRegisterImpl::D, from, 16, F60);
4450     __ ldf(FloatRegisterImpl::D, from, 24, F62);
4451     __ ldf(FloatRegisterImpl::D, from, 32, F4);
4452     __ faligndata(F0, F2, F0);
4453     __ faligndata(F2, F60, F2);
4454     __ faligndata(F60, F62, F60);
4455     __ faligndata(F62, F4, F62);
4456     __ movdtox(F0, G4);
4457     __ movdtox(F2, G5);
4458     __ movdtox(F60, L4);
4459     __ movdtox(F62, L5);
4460     __ mov(G1, from);
4461 
4462     __ BIND(L_transform_next2_blocks256);
4463     // F0:F2 used for first 16-bytes
4464     __ xor3(L2,G4,G1);
4465     __ movxtod(G1,F0);
4466     __ xor3(L3,G5,G1);
4467     __ movxtod(G1,F2);
4468 
4469     // F60:F62 used for next 16-bytes
4470     __ xor3(L2,L4,G1);
4471     __ movxtod(G1,F60);
4472     __ xor3(L3,L5,G1);
4473     __ movxtod(G1,F62);
4474 
4475     __ aes_dround23(F54, F0, F2, F4);
4476     __ aes_dround01(F52, F0, F2, F6);
4477     __ aes_dround23(F54, F60, F62, F58);
4478     __ aes_dround01(F52, F60, F62, F56);
4479     __ aes_dround23(F50, F6, F4, F2);
4480     __ aes_dround01(F48, F6, F4, F0);
4481     __ aes_dround23(F50, F56, F58, F62);
4482     __ aes_dround01(F48, F56, F58, F60);
4483     // save F48:F54 in temp registers
4484     __ movdtox(F54,G2);
4485     __ movdtox(F52,G3);
4486     __ movdtox(F50,G6);
4487     __ movdtox(F48,G1);
4488     for ( int i = 46;  i >= 14; i -= 8 ) {
4489       __ aes_dround23(as_FloatRegister(i), F0, F2, F4);
4490       __ aes_dround01(as_FloatRegister(i-2), F0, F2, F6);
4491       __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
4492       __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
4493       __ aes_dround23(as_FloatRegister(i-4), F6, F4, F2);
4494       __ aes_dround01(as_FloatRegister(i-6), F6, F4, F0);
4495       __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
4496       __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
4497     }
4498     // init F48:F54 with F0:F6 values (original key)
4499     __ ldf(FloatRegisterImpl::D, original_key, 0, F48);
4500     __ ldf(FloatRegisterImpl::D, original_key, 8, F50);
4501     __ ldf(FloatRegisterImpl::D, original_key, 16, F52);
4502     __ ldf(FloatRegisterImpl::D, original_key, 24, F54);
4503     __ aes_dround23(F54, F0, F2, F4);
4504     __ aes_dround01(F52, F0, F2, F6);
4505     __ aes_dround23(F54, F60, F62, F58);
4506     __ aes_dround01(F52, F60, F62, F56);
4507     __ aes_dround23_l(F50, F6, F4, F2);
4508     __ aes_dround01_l(F48, F6, F4, F0);
4509     __ aes_dround23_l(F50, F56, F58, F62);
4510     __ aes_dround01_l(F48, F56, F58, F60);
4511     // re-init F48:F54 with their original values
4512     __ movxtod(G2,F54);
4513     __ movxtod(G3,F52);
4514     __ movxtod(G6,F50);
4515     __ movxtod(G1,F48);
4516 
4517     __ movxtod(L0,F6);
4518     __ movxtod(L1,F4);
4519     __ fxor(FloatRegisterImpl::D, F6, F0, F0);
4520     __ fxor(FloatRegisterImpl::D, F4, F2, F2);
4521 
4522     __ movxtod(G4,F56);
4523     __ movxtod(G5,F58);
4524     __ mov(L4,L0);
4525     __ mov(L5,L1);
4526     __ fxor(FloatRegisterImpl::D, F56, F60, F60);
4527     __ fxor(FloatRegisterImpl::D, F58, F62, F62);
4528 
4529     // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
4530     __ andcc(to, 7, G1);
4531     __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks256);
4532     __ delayed()->edge8n(to, G0, G2);
4533 
4534     // aligned case: store output into the destination array
4535     __ stf(FloatRegisterImpl::D, F0, to, 0);
4536     __ stf(FloatRegisterImpl::D, F2, to, 8);
4537     __ stf(FloatRegisterImpl::D, F60, to, 16);
4538     __ stf(FloatRegisterImpl::D, F62, to, 24);
4539     __ ba_short(L_check_decrypt_loop_end256);
4540 
4541     __ BIND(L_store_misaligned_output_next2_blocks256);
4542     __ mov(8, G4);
4543     __ sub(G4, G1, G4);
4544     __ alignaddr(G4, G0, G4);
4545     __ faligndata(F0, F2, F56); // F56 can be clobbered
4546     __ faligndata(F2, F60, F2);
4547     __ faligndata(F60, F62, F60);
4548     __ faligndata(F62, F0, F0);
4549     __ mov(to, G1);
4550     __ and3(to, -8, to);
4551     __ stpartialf(to, G2, F0, Assembler::ASI_PST8_PRIMARY);
4552     __ stf(FloatRegisterImpl::D, F56, to, 8);
4553     __ stf(FloatRegisterImpl::D, F2, to, 16);
4554     __ stf(FloatRegisterImpl::D, F60, to, 24);
4555     __ add(to, 32, to);
4556     __ orn(G0, G2, G2);
4557     __ stpartialf(to, G2, F0, Assembler::ASI_PST8_PRIMARY);
4558     __ mov(G1, to);
4559 
4560     __ BIND(L_check_decrypt_loop_end256);
4561     __ add(from, 32, from);
4562     __ add(to, 32, to);
4563     __ subcc(len_reg, 32, len_reg);
4564     __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks256);
4565     __ delayed()->nop();
4566 
4567     __ BIND(L_cbcdec_end);
4568     // re-init intial vector for next block, 8-byte alignment is guaranteed
4569     __ stx(L0, rvec, 0);
4570     __ stx(L1, rvec, 8);
4571     __ mov(L7, I0);
4572     __ ret();
4573     __ delayed()->restore();
4574 
4575     return start;
4576   }
4577 
4578   address generate_sha1_implCompress(bool multi_block, const char *name) {
4579     __ align(CodeEntryAlignment);
4580     StubCodeMark mark(this, "StubRoutines", name);
4581     address start = __ pc();
4582 
4583     Label L_sha1_loop, L_sha1_unaligned_input, L_sha1_unaligned_input_loop;
4584     int i;
4585 
4586     Register buf   = O0; // byte[] source+offset
4587     Register state = O1; // int[]  SHA.state
4588     Register ofs   = O2; // int    offset
4589     Register limit = O3; // int    limit
4590 
4591     // load state into F0-F4
4592     for (i = 0; i < 5; i++) {
4593       __ ldf(FloatRegisterImpl::S, state, i*4, as_FloatRegister(i));
4594     }
4595 
4596     __ andcc(buf, 7, G0);
4597     __ br(Assembler::notZero, false, Assembler::pn, L_sha1_unaligned_input);
4598     __ delayed()->nop();
4599 
4600     __ BIND(L_sha1_loop);
4601     // load buf into F8-F22
4602     for (i = 0; i < 8; i++) {
4603       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
4604     }
4605     __ sha1();
4606     if (multi_block) {
4607       __ add(ofs, 64, ofs);
4608       __ add(buf, 64, buf);
4609       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha1_loop);
4610       __ mov(ofs, O0); // to be returned
4611     }
4612 
4613     // store F0-F4 into state and return
4614     for (i = 0; i < 4; i++) {
4615       __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
4616     }
4617     __ retl();
4618     __ delayed()->stf(FloatRegisterImpl::S, F4, state, 0x10);
4619 
4620     __ BIND(L_sha1_unaligned_input);
4621     __ alignaddr(buf, G0, buf);
4622 
4623     __ BIND(L_sha1_unaligned_input_loop);
4624     // load buf into F8-F22
4625     for (i = 0; i < 9; i++) {
4626       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
4627     }
4628     for (i = 0; i < 8; i++) {
4629       __ faligndata(as_FloatRegister(i*2 + 8), as_FloatRegister(i*2 + 10), as_FloatRegister(i*2 + 8));
4630     }
4631     __ sha1();
4632     if (multi_block) {
4633       __ add(ofs, 64, ofs);
4634       __ add(buf, 64, buf);
4635       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha1_unaligned_input_loop);
4636       __ mov(ofs, O0); // to be returned
4637     }
4638 
4639     // store F0-F4 into state and return
4640     for (i = 0; i < 4; i++) {
4641       __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
4642     }
4643     __ retl();
4644     __ delayed()->stf(FloatRegisterImpl::S, F4, state, 0x10);
4645 
4646     return start;
4647   }
4648 
4649   address generate_sha256_implCompress(bool multi_block, const char *name) {
4650     __ align(CodeEntryAlignment);
4651     StubCodeMark mark(this, "StubRoutines", name);
4652     address start = __ pc();
4653 
4654     Label L_sha256_loop, L_sha256_unaligned_input, L_sha256_unaligned_input_loop;
4655     int i;
4656 
4657     Register buf   = O0; // byte[] source+offset
4658     Register state = O1; // int[]  SHA2.state
4659     Register ofs   = O2; // int    offset
4660     Register limit = O3; // int    limit
4661 
4662     // load state into F0-F7
4663     for (i = 0; i < 8; i++) {
4664       __ ldf(FloatRegisterImpl::S, state, i*4, as_FloatRegister(i));
4665     }
4666 
4667     __ andcc(buf, 7, G0);
4668     __ br(Assembler::notZero, false, Assembler::pn, L_sha256_unaligned_input);
4669     __ delayed()->nop();
4670 
4671     __ BIND(L_sha256_loop);
4672     // load buf into F8-F22
4673     for (i = 0; i < 8; i++) {
4674       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
4675     }
4676     __ sha256();
4677     if (multi_block) {
4678       __ add(ofs, 64, ofs);
4679       __ add(buf, 64, buf);
4680       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha256_loop);
4681       __ mov(ofs, O0); // to be returned
4682     }
4683 
4684     // store F0-F7 into state and return
4685     for (i = 0; i < 7; i++) {
4686       __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
4687     }
4688     __ retl();
4689     __ delayed()->stf(FloatRegisterImpl::S, F7, state, 0x1c);
4690 
4691     __ BIND(L_sha256_unaligned_input);
4692     __ alignaddr(buf, G0, buf);
4693 
4694     __ BIND(L_sha256_unaligned_input_loop);
4695     // load buf into F8-F22
4696     for (i = 0; i < 9; i++) {
4697       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
4698     }
4699     for (i = 0; i < 8; i++) {
4700       __ faligndata(as_FloatRegister(i*2 + 8), as_FloatRegister(i*2 + 10), as_FloatRegister(i*2 + 8));
4701     }
4702     __ sha256();
4703     if (multi_block) {
4704       __ add(ofs, 64, ofs);
4705       __ add(buf, 64, buf);
4706       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha256_unaligned_input_loop);
4707       __ mov(ofs, O0); // to be returned
4708     }
4709 
4710     // store F0-F7 into state and return
4711     for (i = 0; i < 7; i++) {
4712       __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
4713     }
4714     __ retl();
4715     __ delayed()->stf(FloatRegisterImpl::S, F7, state, 0x1c);
4716 
4717     return start;
4718   }
4719 
4720   address generate_sha512_implCompress(bool multi_block, const char *name) {
4721     __ align(CodeEntryAlignment);
4722     StubCodeMark mark(this, "StubRoutines", name);
4723     address start = __ pc();
4724 
4725     Label L_sha512_loop, L_sha512_unaligned_input, L_sha512_unaligned_input_loop;
4726     int i;
4727 
4728     Register buf   = O0; // byte[] source+offset
4729     Register state = O1; // long[] SHA5.state
4730     Register ofs   = O2; // int    offset
4731     Register limit = O3; // int    limit
4732 
4733     // load state into F0-F14
4734     for (i = 0; i < 8; i++) {
4735       __ ldf(FloatRegisterImpl::D, state, i*8, as_FloatRegister(i*2));
4736     }
4737 
4738     __ andcc(buf, 7, G0);
4739     __ br(Assembler::notZero, false, Assembler::pn, L_sha512_unaligned_input);
4740     __ delayed()->nop();
4741 
4742     __ BIND(L_sha512_loop);
4743     // load buf into F16-F46
4744     for (i = 0; i < 16; i++) {
4745       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 16));
4746     }
4747     __ sha512();
4748     if (multi_block) {
4749       __ add(ofs, 128, ofs);
4750       __ add(buf, 128, buf);
4751       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha512_loop);
4752       __ mov(ofs, O0); // to be returned
4753     }
4754 
4755     // store F0-F14 into state and return
4756     for (i = 0; i < 7; i++) {
4757       __ stf(FloatRegisterImpl::D, as_FloatRegister(i*2), state, i*8);
4758     }
4759     __ retl();
4760     __ delayed()->stf(FloatRegisterImpl::D, F14, state, 0x38);
4761 
4762     __ BIND(L_sha512_unaligned_input);
4763     __ alignaddr(buf, G0, buf);
4764 
4765     __ BIND(L_sha512_unaligned_input_loop);
4766     // load buf into F16-F46
4767     for (i = 0; i < 17; i++) {
4768       __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 16));
4769     }
4770     for (i = 0; i < 16; i++) {
4771       __ faligndata(as_FloatRegister(i*2 + 16), as_FloatRegister(i*2 + 18), as_FloatRegister(i*2 + 16));
4772     }
4773     __ sha512();
4774     if (multi_block) {
4775       __ add(ofs, 128, ofs);
4776       __ add(buf, 128, buf);
4777       __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha512_unaligned_input_loop);
4778       __ mov(ofs, O0); // to be returned
4779     }
4780 
4781     // store F0-F14 into state and return
4782     for (i = 0; i < 7; i++) {
4783       __ stf(FloatRegisterImpl::D, as_FloatRegister(i*2), state, i*8);
4784     }
4785     __ retl();
4786     __ delayed()->stf(FloatRegisterImpl::D, F14, state, 0x38);
4787 
4788     return start;
4789   }
4790 
4791   /* Single and multi-block ghash operations */
4792   address generate_ghash_processBlocks() {
4793       __ align(CodeEntryAlignment);
4794       Label L_ghash_loop, L_aligned, L_main;
4795       StubCodeMark mark(this, "StubRoutines", "ghash_processBlocks");
4796       address start = __ pc();
4797 
4798       Register state = I0;
4799       Register subkeyH = I1;
4800       Register data = I2;
4801       Register len = I3;
4802 
4803       __ save_frame(0);
4804 
4805       __ ldx(state, 0, O0);
4806       __ ldx(state, 8, O1);
4807 
4808       // Loop label for multiblock operations
4809       __ BIND(L_ghash_loop);
4810 
4811       // Check if 'data' is unaligned
4812       __ andcc(data, 7, G1);
4813       __ br(Assembler::zero, false, Assembler::pt, L_aligned);
4814       __ delayed()->nop();
4815 
4816       Register left_shift = L1;
4817       Register right_shift = L2;
4818       Register data_ptr = L3;
4819 
4820       // Get left and right shift values in bits
4821       __ sll(G1, LogBitsPerByte, left_shift);
4822       __ mov(64, right_shift);
4823       __ sub(right_shift, left_shift, right_shift);
4824 
4825       // Align to read 'data'
4826       __ sub(data, G1, data_ptr);
4827 
4828       // Load first 8 bytes of 'data'
4829       __ ldx(data_ptr, 0, O4);
4830       __ sllx(O4, left_shift, O4);
4831       __ ldx(data_ptr, 8, O5);
4832       __ srlx(O5, right_shift, G4);
4833       __ bset(G4, O4);
4834 
4835       // Load second 8 bytes of 'data'
4836       __ sllx(O5, left_shift, O5);
4837       __ ldx(data_ptr, 16, G4);
4838       __ srlx(G4, right_shift, G4);
4839       __ ba(L_main);
4840       __ delayed()->bset(G4, O5);
4841 
4842       // If 'data' is aligned, load normally
4843       __ BIND(L_aligned);
4844       __ ldx(data, 0, O4);
4845       __ ldx(data, 8, O5);
4846 
4847       __ BIND(L_main);
4848       __ ldx(subkeyH, 0, O2);
4849       __ ldx(subkeyH, 8, O3);
4850 
4851       __ xor3(O0, O4, O0);
4852       __ xor3(O1, O5, O1);
4853 
4854       __ xmulxhi(O0, O3, G3);
4855       __ xmulx(O0, O2, O5);
4856       __ xmulxhi(O1, O2, G4);
4857       __ xmulxhi(O1, O3, G5);
4858       __ xmulx(O0, O3, G1);
4859       __ xmulx(O1, O3, G2);
4860       __ xmulx(O1, O2, O3);
4861       __ xmulxhi(O0, O2, O4);
4862 
4863       __ mov(0xE1, O0);
4864       __ sllx(O0, 56, O0);
4865 
4866       __ xor3(O5, G3, O5);
4867       __ xor3(O5, G4, O5);
4868       __ xor3(G5, G1, G1);
4869       __ xor3(G1, O3, G1);
4870       __ srlx(G2, 63, O1);
4871       __ srlx(G1, 63, G3);
4872       __ sllx(G2, 63, O3);
4873       __ sllx(G2, 58, O2);
4874       __ xor3(O3, O2, O2);
4875 
4876       __ sllx(G1, 1, G1);
4877       __ or3(G1, O1, G1);
4878 
4879       __ xor3(G1, O2, G1);
4880 
4881       __ sllx(G2, 1, G2);
4882 
4883       __ xmulxhi(G1, O0, O1);
4884       __ xmulx(G1, O0, O2);
4885       __ xmulxhi(G2, O0, O3);
4886       __ xmulx(G2, O0, G1);
4887 
4888       __ xor3(O4, O1, O4);
4889       __ xor3(O5, O2, O5);
4890       __ xor3(O5, O3, O5);
4891 
4892       __ sllx(O4, 1, O2);
4893       __ srlx(O5, 63, O3);
4894 
4895       __ or3(O2, O3, O0);
4896 
4897       __ sllx(O5, 1, O1);
4898       __ srlx(G1, 63, O2);
4899       __ or3(O1, O2, O1);
4900       __ xor3(O1, G3, O1);
4901 
4902       __ deccc(len);
4903       __ br(Assembler::notZero, true, Assembler::pt, L_ghash_loop);
4904       __ delayed()->add(data, 16, data);
4905 
4906       __ stx(O0, I0, 0);
4907       __ stx(O1, I0, 8);
4908 
4909       __ ret();
4910       __ delayed()->restore();
4911 
4912       return start;
4913   }
4914 
4915   void generate_initial() {
4916     // Generates all stubs and initializes the entry points
4917 
4918     //------------------------------------------------------------------------------------------------------------------------
4919     // entry points that exist in all platforms
4920     // Note: This is code that could be shared among different platforms - however the benefit seems to be smaller than
4921     //       the disadvantage of having a much more complicated generator structure. See also comment in stubRoutines.hpp.
4922     StubRoutines::_forward_exception_entry                 = generate_forward_exception();
4923 
4924     StubRoutines::_call_stub_entry                         = generate_call_stub(StubRoutines::_call_stub_return_address);
4925     StubRoutines::_catch_exception_entry                   = generate_catch_exception();
4926 
4927     //------------------------------------------------------------------------------------------------------------------------
4928     // entry points that are platform specific
4929     StubRoutines::Sparc::_test_stop_entry                  = generate_test_stop();
4930 
4931     StubRoutines::Sparc::_stop_subroutine_entry            = generate_stop_subroutine();
4932     StubRoutines::Sparc::_flush_callers_register_windows_entry = generate_flush_callers_register_windows();
4933 
4934 #if !defined(COMPILER2) && !defined(_LP64)
4935     StubRoutines::_atomic_xchg_entry         = generate_atomic_xchg();
4936     StubRoutines::_atomic_cmpxchg_entry      = generate_atomic_cmpxchg();
4937     StubRoutines::_atomic_add_entry          = generate_atomic_add();
4938     StubRoutines::_atomic_xchg_ptr_entry     = StubRoutines::_atomic_xchg_entry;
4939     StubRoutines::_atomic_cmpxchg_ptr_entry  = StubRoutines::_atomic_cmpxchg_entry;
4940     StubRoutines::_atomic_cmpxchg_byte_entry = ShouldNotCallThisStub();
4941     StubRoutines::_atomic_cmpxchg_long_entry = generate_atomic_cmpxchg_long();
4942     StubRoutines::_atomic_add_ptr_entry      = StubRoutines::_atomic_add_entry;
4943 #endif  // COMPILER2 !=> _LP64
4944 
4945     // Build this early so it's available for the interpreter.
4946     StubRoutines::_throw_StackOverflowError_entry          = generate_throw_exception("StackOverflowError throw_exception",           CAST_FROM_FN_PTR(address, SharedRuntime::throw_StackOverflowError));
4947   }
4948 
4949 
4950   void generate_all() {
4951     // Generates all stubs and initializes the entry points
4952 
4953     // Generate partial_subtype_check first here since its code depends on
4954     // UseZeroBaseCompressedOops which is defined after heap initialization.
4955     StubRoutines::Sparc::_partial_subtype_check                = generate_partial_subtype_check();
4956     // These entry points require SharedInfo::stack0 to be set up in non-core builds
4957     StubRoutines::_throw_AbstractMethodError_entry         = generate_throw_exception("AbstractMethodError throw_exception",          CAST_FROM_FN_PTR(address, SharedRuntime::throw_AbstractMethodError));
4958     StubRoutines::_throw_IncompatibleClassChangeError_entry= generate_throw_exception("IncompatibleClassChangeError throw_exception", CAST_FROM_FN_PTR(address, SharedRuntime::throw_IncompatibleClassChangeError));
4959     StubRoutines::_throw_NullPointerException_at_call_entry= generate_throw_exception("NullPointerException at call throw_exception", CAST_FROM_FN_PTR(address, SharedRuntime::throw_NullPointerException_at_call));
4960 
4961     StubRoutines::_handler_for_unsafe_access_entry =
4962       generate_handler_for_unsafe_access();
4963 
4964     // support for verify_oop (must happen after universe_init)
4965     StubRoutines::_verify_oop_subroutine_entry     = generate_verify_oop_subroutine();
4966 
4967     // arraycopy stubs used by compilers
4968     generate_arraycopy_stubs();
4969 
4970     // Don't initialize the platform math functions since sparc
4971     // doesn't have intrinsics for these operations.
4972 
4973     // Safefetch stubs.
4974     generate_safefetch("SafeFetch32", sizeof(int),     &StubRoutines::_safefetch32_entry,
4975                                                        &StubRoutines::_safefetch32_fault_pc,
4976                                                        &StubRoutines::_safefetch32_continuation_pc);
4977     generate_safefetch("SafeFetchN", sizeof(intptr_t), &StubRoutines::_safefetchN_entry,
4978                                                        &StubRoutines::_safefetchN_fault_pc,
4979                                                        &StubRoutines::_safefetchN_continuation_pc);
4980 
4981     // generate AES intrinsics code
4982     if (UseAESIntrinsics) {
4983       StubRoutines::_aescrypt_encryptBlock = generate_aescrypt_encryptBlock();
4984       StubRoutines::_aescrypt_decryptBlock = generate_aescrypt_decryptBlock();
4985       StubRoutines::_cipherBlockChaining_encryptAESCrypt = generate_cipherBlockChaining_encryptAESCrypt();
4986       StubRoutines::_cipherBlockChaining_decryptAESCrypt = generate_cipherBlockChaining_decryptAESCrypt_Parallel();
4987     }
4988     // generate GHASH intrinsics code
4989     if (UseGHASHIntrinsics) {
4990       StubRoutines::_ghash_processBlocks = generate_ghash_processBlocks();
4991     }
4992 
4993     // generate SHA1/SHA256/SHA512 intrinsics code
4994     if (UseSHA1Intrinsics) {
4995       StubRoutines::_sha1_implCompress     = generate_sha1_implCompress(false,   "sha1_implCompress");
4996       StubRoutines::_sha1_implCompressMB   = generate_sha1_implCompress(true,    "sha1_implCompressMB");
4997     }
4998     if (UseSHA256Intrinsics) {
4999       StubRoutines::_sha256_implCompress   = generate_sha256_implCompress(false, "sha256_implCompress");
5000       StubRoutines::_sha256_implCompressMB = generate_sha256_implCompress(true,  "sha256_implCompressMB");
5001     }
5002     if (UseSHA512Intrinsics) {
5003       StubRoutines::_sha512_implCompress   = generate_sha512_implCompress(false, "sha512_implCompress");
5004       StubRoutines::_sha512_implCompressMB = generate_sha512_implCompress(true,  "sha512_implCompressMB");
5005     }
5006   }
5007 
5008 
5009  public:
5010   StubGenerator(CodeBuffer* code, bool all) : StubCodeGenerator(code) {
5011     // replace the standard masm with a special one:
5012     _masm = new MacroAssembler(code);
5013 
5014     _stub_count = !all ? 0x100 : 0x200;
5015     if (all) {
5016       generate_all();
5017     } else {
5018       generate_initial();
5019     }
5020 
5021     // make sure this stub is available for all local calls
5022     if (_atomic_add_stub.is_unbound()) {
5023       // generate a second time, if necessary
5024       (void) generate_atomic_add();
5025     }
5026   }
5027 
5028 
5029  private:
5030   int _stub_count;
5031   void stub_prolog(StubCodeDesc* cdesc) {
5032     # ifdef ASSERT
5033       // put extra information in the stub code, to make it more readable
5034 #ifdef _LP64
5035 // Write the high part of the address
5036 // [RGV] Check if there is a dependency on the size of this prolog
5037       __ emit_data((intptr_t)cdesc >> 32,    relocInfo::none);
5038 #endif
5039       __ emit_data((intptr_t)cdesc,    relocInfo::none);
5040       __ emit_data(++_stub_count, relocInfo::none);
5041     # endif
5042     align(true);
5043   }
5044 
5045   void align(bool at_header = false) {
5046     // %%%%% move this constant somewhere else
5047     // UltraSPARC cache line size is 8 instructions:
5048     const unsigned int icache_line_size = 32;
5049     const unsigned int icache_half_line_size = 16;
5050 
5051     if (at_header) {
5052       while ((intptr_t)(__ pc()) % icache_line_size != 0) {
5053         __ emit_data(0, relocInfo::none);
5054       }
5055     } else {
5056       while ((intptr_t)(__ pc()) % icache_half_line_size != 0) {
5057         __ nop();
5058       }
5059     }
5060   }
5061 
5062 }; // end class declaration
5063 
5064 void StubGenerator_generate(CodeBuffer* code, bool all) {
5065   StubGenerator g(code, all);
5066 }