src/hotspot/cpu/sparc/stubGenerator_sparc.cpp
author naoto
Tue, 09 Jul 2019 08:05:38 -0700
changeset 55627 9c1885fb2a42
parent 53591 bf4c38b9afaf
child 55490 3f3dc00a69a5
permissions -rw-r--r--
8227127: Era designator not displayed correctly using the COMPAT provider Reviewed-by: rriggs

/*
 * Copyright (c) 1997, 2019, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.
 *
 * This code is distributed in the hope that it will be useful, but WITHOUT
 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
 * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
 * or visit www.oracle.com if you need additional information or have any
 * questions.
 *
 */

#include "precompiled.hpp"
#include "asm/macroAssembler.inline.hpp"
#include "gc/shared/barrierSet.hpp"
#include "gc/shared/barrierSetAssembler.hpp"
#include "interpreter/interpreter.hpp"
#include "nativeInst_sparc.hpp"
#include "oops/instanceOop.hpp"
#include "oops/method.hpp"
#include "oops/objArrayKlass.hpp"
#include "oops/oop.inline.hpp"
#include "prims/methodHandles.hpp"
#include "runtime/frame.inline.hpp"
#include "runtime/handles.inline.hpp"
#include "runtime/sharedRuntime.hpp"
#include "runtime/stubCodeGenerator.hpp"
#include "runtime/stubRoutines.hpp"
#include "runtime/thread.inline.hpp"
#ifdef COMPILER2
#include "opto/runtime.hpp"
#endif

// Declaration and definition of StubGenerator (no .hpp file).
// For a more detailed description of the stub routine structure
// see the comment in stubRoutines.hpp.

#define __ _masm->

#ifdef PRODUCT
#define BLOCK_COMMENT(str) /* nothing */
#else
#define BLOCK_COMMENT(str) __ block_comment(str)
#endif

#define BIND(label) bind(label); BLOCK_COMMENT(#label ":")

// Note:  The register L7 is used as L7_thread_cache, and may not be used
//        any other way within this module.

static const Register& Lstub_temp = L2;

// -------------------------------------------------------------------------------------------------------------------------
// Stub Code definitions

class StubGenerator: public StubCodeGenerator {
 private:

#ifdef PRODUCT
#define inc_counter_np(a,b,c)
#else
#define inc_counter_np(counter, t1, t2) \
  BLOCK_COMMENT("inc_counter " #counter); \
  __ inc_counter(&counter, t1, t2);
#endif

  //----------------------------------------------------------------------------------------------------
  // Call stubs are used to call Java from C

  address generate_call_stub(address& return_pc) {
    StubCodeMark mark(this, "StubRoutines", "call_stub");
    address start = __ pc();

    // Incoming arguments:
    //
    // o0         : call wrapper address
    // o1         : result (address)
    // o2         : result type
    // o3         : method
    // o4         : (interpreter) entry point
    // o5         : parameters (address)
    // [sp + 0x5c]: parameter size (in words)
    // [sp + 0x60]: thread
    //
    // +---------------+ <--- sp + 0
    // |               |
    // . reg save area .
    // |               |
    // +---------------+ <--- sp + 0x40
    // |               |
    // . extra 7 slots .
    // |               |
    // +---------------+ <--- sp + 0x5c
    // |  param. size  |
    // +---------------+ <--- sp + 0x60
    // |    thread     |
    // +---------------+
    // |               |

    // note: if the link argument position changes, adjust
    //       the code in frame::entry_frame_call_wrapper()

    const Argument link           = Argument(0, false); // used only for GC
    const Argument result         = Argument(1, false);
    const Argument result_type    = Argument(2, false);
    const Argument method         = Argument(3, false);
    const Argument entry_point    = Argument(4, false);
    const Argument parameters     = Argument(5, false);
    const Argument parameter_size = Argument(6, false);
    const Argument thread         = Argument(7, false);

    // setup thread register
    __ ld_ptr(thread.as_address(), G2_thread);
    __ reinit_heapbase();

#ifdef ASSERT
    // make sure we have no pending exceptions
    { const Register t = G3_scratch;
      Label L;
      __ ld_ptr(G2_thread, in_bytes(Thread::pending_exception_offset()), t);
      __ br_null_short(t, Assembler::pt, L);
      __ stop("StubRoutines::call_stub: entered with pending exception");
      __ bind(L);
    }
#endif

    // create activation frame & allocate space for parameters
    { const Register t = G3_scratch;
      __ ld_ptr(parameter_size.as_address(), t);                // get parameter size (in words)
      __ add(t, frame::memory_parameter_word_sp_offset, t);     // add space for save area (in words)
      __ round_to(t, WordsPerLong);                             // make sure it is multiple of 2 (in words)
      __ sll(t, Interpreter::logStackElementSize, t);           // compute number of bytes
      __ neg(t);                                                // negate so it can be used with save
      __ save(SP, t, SP);                                       // setup new frame
    }

    // +---------------+ <--- sp + 0
    // |               |
    // . reg save area .
    // |               |
    // +---------------+ <--- sp + 0x40
    // |               |
    // . extra 7 slots .
    // |               |
    // +---------------+ <--- sp + 0x5c
    // |  empty slot   |      (only if parameter size is even)
    // +---------------+
    // |               |
    // .  parameters   .
    // |               |
    // +---------------+ <--- fp + 0
    // |               |
    // . reg save area .
    // |               |
    // +---------------+ <--- fp + 0x40
    // |               |
    // . extra 7 slots .
    // |               |
    // +---------------+ <--- fp + 0x5c
    // |  param. size  |
    // +---------------+ <--- fp + 0x60
    // |    thread     |
    // +---------------+
    // |               |

    // pass parameters if any
    BLOCK_COMMENT("pass parameters if any");
    { const Register src = parameters.as_in().as_register();
      const Register dst = Lentry_args;
      const Register tmp = G3_scratch;
      const Register cnt = G4_scratch;

      // test if any parameters & setup of Lentry_args
      Label exit;
      __ ld_ptr(parameter_size.as_in().as_address(), cnt);      // parameter counter
      __ add( FP, STACK_BIAS, dst );
      __ cmp_zero_and_br(Assembler::zero, cnt, exit);
      __ delayed()->sub(dst, BytesPerWord, dst);                 // setup Lentry_args

      // copy parameters if any
      Label loop;
      __ BIND(loop);
      // Store parameter value
      __ ld_ptr(src, 0, tmp);
      __ add(src, BytesPerWord, src);
      __ st_ptr(tmp, dst, 0);
      __ deccc(cnt);
      __ br(Assembler::greater, false, Assembler::pt, loop);
      __ delayed()->sub(dst, Interpreter::stackElementSize, dst);

      // done
      __ BIND(exit);
    }

    // setup parameters, method & call Java function
#ifdef ASSERT
    // layout_activation_impl checks it's notion of saved SP against
    // this register, so if this changes update it as well.
    const Register saved_SP = Lscratch;
    __ mov(SP, saved_SP);                               // keep track of SP before call
#endif

    // setup parameters
    const Register t = G3_scratch;
    __ ld_ptr(parameter_size.as_in().as_address(), t); // get parameter size (in words)
    __ sll(t, Interpreter::logStackElementSize, t);    // compute number of bytes
    __ sub(FP, t, Gargs);                              // setup parameter pointer
    __ add( Gargs, STACK_BIAS, Gargs );                // Account for LP64 stack bias
    __ mov(SP, O5_savedSP);


    // do the call
    //
    // the following register must be setup:
    //
    // G2_thread
    // G5_method
    // Gargs
    BLOCK_COMMENT("call Java function");
    __ jmpl(entry_point.as_in().as_register(), G0, O7);
    __ delayed()->mov(method.as_in().as_register(), G5_method);   // setup method

    BLOCK_COMMENT("call_stub_return_address:");
    return_pc = __ pc();

    // The callee, if it wasn't interpreted, can return with SP changed so
    // we can no longer assert of change of SP.

    // store result depending on type
    // (everything that is not T_OBJECT, T_LONG, T_FLOAT, or T_DOUBLE
    //  is treated as T_INT)
    { const Register addr = result     .as_in().as_register();
      const Register type = result_type.as_in().as_register();
      Label is_long, is_float, is_double, is_object, exit;
      __            cmp(type, T_OBJECT);  __ br(Assembler::equal, false, Assembler::pn, is_object);
      __ delayed()->cmp(type, T_FLOAT);   __ br(Assembler::equal, false, Assembler::pn, is_float);
      __ delayed()->cmp(type, T_DOUBLE);  __ br(Assembler::equal, false, Assembler::pn, is_double);
      __ delayed()->cmp(type, T_LONG);    __ br(Assembler::equal, false, Assembler::pn, is_long);
      __ delayed()->nop();

      // store int result
      __ st(O0, addr, G0);

      __ BIND(exit);
      __ ret();
      __ delayed()->restore();

      __ BIND(is_object);
      __ ba(exit);
      __ delayed()->st_ptr(O0, addr, G0);

      __ BIND(is_float);
      __ ba(exit);
      __ delayed()->stf(FloatRegisterImpl::S, F0, addr, G0);

      __ BIND(is_double);
      __ ba(exit);
      __ delayed()->stf(FloatRegisterImpl::D, F0, addr, G0);

      __ BIND(is_long);
      __ ba(exit);
      __ delayed()->st_long(O0, addr, G0);      // store entire long
     }
     return start;
  }


  //----------------------------------------------------------------------------------------------------
  // Return point for a Java call if there's an exception thrown in Java code.
  // The exception is caught and transformed into a pending exception stored in
  // JavaThread that can be tested from within the VM.
  //
  // Oexception: exception oop

  address generate_catch_exception() {
    StubCodeMark mark(this, "StubRoutines", "catch_exception");

    address start = __ pc();
    // verify that thread corresponds
    __ verify_thread();

    const Register& temp_reg = Gtemp;
    Address pending_exception_addr    (G2_thread, Thread::pending_exception_offset());
    Address exception_file_offset_addr(G2_thread, Thread::exception_file_offset   ());
    Address exception_line_offset_addr(G2_thread, Thread::exception_line_offset   ());

    // set pending exception
    __ verify_oop(Oexception);
    __ st_ptr(Oexception, pending_exception_addr);
    __ set((intptr_t)__FILE__, temp_reg);
    __ st_ptr(temp_reg, exception_file_offset_addr);
    __ set((intptr_t)__LINE__, temp_reg);
    __ st(temp_reg, exception_line_offset_addr);

    // complete return to VM
    assert(StubRoutines::_call_stub_return_address != NULL, "must have been generated before");

    AddressLiteral stub_ret(StubRoutines::_call_stub_return_address);
    __ jump_to(stub_ret, temp_reg);
    __ delayed()->nop();

    return start;
  }


  //----------------------------------------------------------------------------------------------------
  // Continuation point for runtime calls returning with a pending exception
  // The pending exception check happened in the runtime or native call stub
  // The pending exception in Thread is converted into a Java-level exception
  //
  // Contract with Java-level exception handler: O0 = exception
  //                                             O1 = throwing pc

  address generate_forward_exception() {
    StubCodeMark mark(this, "StubRoutines", "forward_exception");
    address start = __ pc();

    // Upon entry, O7 has the return address returning into Java
    // (interpreted or compiled) code; i.e. the return address
    // becomes the throwing pc.

    const Register& handler_reg = Gtemp;

    Address exception_addr(G2_thread, Thread::pending_exception_offset());

#ifdef ASSERT
    // make sure that this code is only executed if there is a pending exception
    { Label L;
      __ ld_ptr(exception_addr, Gtemp);
      __ br_notnull_short(Gtemp, Assembler::pt, L);
      __ stop("StubRoutines::forward exception: no pending exception (1)");
      __ bind(L);
    }
#endif

    // compute exception handler into handler_reg
    __ get_thread();
    __ ld_ptr(exception_addr, Oexception);
    __ verify_oop(Oexception);
    __ save_frame(0);             // compensates for compiler weakness
    __ add(O7->after_save(), frame::pc_return_offset, Lscratch); // save the issuing PC
    BLOCK_COMMENT("call exception_handler_for_return_address");
    __ call_VM_leaf(L7_thread_cache, CAST_FROM_FN_PTR(address, SharedRuntime::exception_handler_for_return_address), G2_thread, Lscratch);
    __ mov(O0, handler_reg);
    __ restore();                 // compensates for compiler weakness

    __ ld_ptr(exception_addr, Oexception);
    __ add(O7, frame::pc_return_offset, Oissuing_pc); // save the issuing PC

#ifdef ASSERT
    // make sure exception is set
    { Label L;
      __ br_notnull_short(Oexception, Assembler::pt, L);
      __ stop("StubRoutines::forward exception: no pending exception (2)");
      __ bind(L);
    }
#endif
    // jump to exception handler
    __ jmp(handler_reg, 0);
    // clear pending exception
    __ delayed()->st_ptr(G0, exception_addr);

    return start;
  }

  // Safefetch stubs.
  void generate_safefetch(const char* name, int size, address* entry,
                          address* fault_pc, address* continuation_pc) {
    // safefetch signatures:
    //   int      SafeFetch32(int*      adr, int      errValue);
    //   intptr_t SafeFetchN (intptr_t* adr, intptr_t errValue);
    //
    // arguments:
    //   o0 = adr
    //   o1 = errValue
    //
    // result:
    //   o0  = *adr or errValue

    StubCodeMark mark(this, "StubRoutines", name);

    // Entry point, pc or function descriptor.
    __ align(CodeEntryAlignment);
    *entry = __ pc();

    __ mov(O0, G1);  // g1 = o0
    __ mov(O1, O0);  // o0 = o1
    // Load *adr into c_rarg1, may fault.
    *fault_pc = __ pc();
    switch (size) {
      case 4:
        // int32_t
        __ ldsw(G1, 0, O0);  // o0 = [g1]
        break;
      case 8:
        // int64_t
        __ ldx(G1, 0, O0);   // o0 = [g1]
        break;
      default:
        ShouldNotReachHere();
    }

    // return errValue or *adr
    *continuation_pc = __ pc();
    // By convention with the trap handler we ensure there is a non-CTI
    // instruction in the trap shadow.
    __ nop();
    __ retl();
    __ delayed()->nop();
  }

  //------------------------------------------------------------------------------------------------------------------------
  // Continuation point for throwing of implicit exceptions that are not handled in
  // the current activation. Fabricates an exception oop and initiates normal
  // exception dispatching in this frame. Only callee-saved registers are preserved
  // (through the normal register window / RegisterMap handling).
  // If the compiler needs all registers to be preserved between the fault
  // point and the exception handler then it must assume responsibility for that in
  // AbstractCompiler::continuation_for_implicit_null_exception or
  // continuation_for_implicit_division_by_zero_exception. All other implicit
  // exceptions (e.g., NullPointerException or AbstractMethodError on entry) are
  // either at call sites or otherwise assume that stack unwinding will be initiated,
  // so caller saved registers were assumed volatile in the compiler.

  // Note that we generate only this stub into a RuntimeStub, because it needs to be
  // properly traversed and ignored during GC, so we change the meaning of the "__"
  // macro within this method.
#undef __
#define __ masm->

  address generate_throw_exception(const char* name, address runtime_entry,
                                   Register arg1 = noreg, Register arg2 = noreg) {
#ifdef ASSERT
    int insts_size = VerifyThread ? 1 * K : 600;
#else
    int insts_size = VerifyThread ? 1 * K : 256;
#endif /* ASSERT */
    int locs_size  = 32;

    CodeBuffer      code(name, insts_size, locs_size);
    MacroAssembler* masm = new MacroAssembler(&code);

    __ verify_thread();

    // This is an inlined and slightly modified version of call_VM
    // which has the ability to fetch the return PC out of thread-local storage
    __ assert_not_delayed();

    // Note that we always push a frame because on the SPARC
    // architecture, for all of our implicit exception kinds at call
    // sites, the implicit exception is taken before the callee frame
    // is pushed.
    __ save_frame(0);

    int frame_complete = __ offset();

    // Note that we always have a runtime stub frame on the top of stack by this point
    Register last_java_sp = SP;
    // 64-bit last_java_sp is biased!
    __ set_last_Java_frame(last_java_sp, G0);
    if (VerifyThread)  __ mov(G2_thread, O0); // about to be smashed; pass early
    __ save_thread(noreg);
    if (arg1 != noreg) {
      assert(arg2 != O1, "clobbered");
      __ mov(arg1, O1);
    }
    if (arg2 != noreg) {
      __ mov(arg2, O2);
    }
    // do the call
    BLOCK_COMMENT("call runtime_entry");
    __ call(runtime_entry, relocInfo::runtime_call_type);
    if (!VerifyThread)
      __ delayed()->mov(G2_thread, O0);  // pass thread as first argument
    else
      __ delayed()->nop();             // (thread already passed)
    __ restore_thread(noreg);
    __ reset_last_Java_frame();

    // check for pending exceptions. use Gtemp as scratch register.
#ifdef ASSERT
    Label L;

    Address exception_addr(G2_thread, Thread::pending_exception_offset());
    Register scratch_reg = Gtemp;
    __ ld_ptr(exception_addr, scratch_reg);
    __ br_notnull_short(scratch_reg, Assembler::pt, L);
    __ should_not_reach_here();
    __ bind(L);
#endif // ASSERT
    BLOCK_COMMENT("call forward_exception_entry");
    __ call(StubRoutines::forward_exception_entry(), relocInfo::runtime_call_type);
    // we use O7 linkage so that forward_exception_entry has the issuing PC
    __ delayed()->restore();

    RuntimeStub* stub = RuntimeStub::new_runtime_stub(name, &code, frame_complete, masm->total_frame_size_in_bytes(0), NULL, false);
    return stub->entry_point();
  }

#undef __
#define __ _masm->


  // Generate a routine that sets all the registers so we
  // can tell if the stop routine prints them correctly.
  address generate_test_stop() {
    StubCodeMark mark(this, "StubRoutines", "test_stop");
    address start = __ pc();

    int i;

    __ save_frame(0);

    static jfloat zero = 0.0, one = 1.0;

    // put addr in L0, then load through L0 to F0
    __ set((intptr_t)&zero, L0);  __ ldf( FloatRegisterImpl::S, L0, 0, F0);
    __ set((intptr_t)&one,  L0);  __ ldf( FloatRegisterImpl::S, L0, 0, F1); // 1.0 to F1

    // use add to put 2..18 in F2..F18
    for ( i = 2;  i <= 18;  ++i ) {
      __ fadd( FloatRegisterImpl::S, F1, as_FloatRegister(i-1),  as_FloatRegister(i));
    }

    // Now put double 2 in F16, double 18 in F18
    __ ftof( FloatRegisterImpl::S, FloatRegisterImpl::D, F2, F16 );
    __ ftof( FloatRegisterImpl::S, FloatRegisterImpl::D, F18, F18 );

    // use add to put 20..32 in F20..F32
    for (i = 20; i < 32; i += 2) {
      __ fadd( FloatRegisterImpl::D, F16, as_FloatRegister(i-2),  as_FloatRegister(i));
    }

    // put 0..7 in i's, 8..15 in l's, 16..23 in o's, 24..31 in g's
    for ( i = 0; i < 8; ++i ) {
      if (i < 6) {
        __ set(     i, as_iRegister(i));
        __ set(16 + i, as_oRegister(i));
        __ set(24 + i, as_gRegister(i));
      }
      __ set( 8 + i, as_lRegister(i));
    }

    __ stop("testing stop");


    __ ret();
    __ delayed()->restore();

    return start;
  }


  address generate_stop_subroutine() {
    StubCodeMark mark(this, "StubRoutines", "stop_subroutine");
    address start = __ pc();

    __ stop_subroutine();

    return start;
  }

  address generate_flush_callers_register_windows() {
    StubCodeMark mark(this, "StubRoutines", "flush_callers_register_windows");
    address start = __ pc();

    __ flushw();
    __ retl(false);
    __ delayed()->add( FP, STACK_BIAS, O0 );
    // The returned value must be a stack pointer whose register save area
    // is flushed, and will stay flushed while the caller executes.

    return start;
  }

  // Support for jint Atomic::xchg(jint exchange_value, volatile jint* dest).
  //
  // Arguments:
  //
  //      exchange_value: O0
  //      dest:           O1
  //
  // Results:
  //
  //     O0: the value previously stored in dest
  //
  address generate_atomic_xchg() {
    StubCodeMark mark(this, "StubRoutines", "atomic_xchg");
    address start = __ pc();

    if (UseCASForSwap) {
      // Use CAS instead of swap, just in case the MP hardware
      // prefers to work with just one kind of synch. instruction.
      Label retry;
      __ BIND(retry);
      __ mov(O0, O3);       // scratch copy of exchange value
      __ ld(O1, 0, O2);     // observe the previous value
      // try to replace O2 with O3
      __ cas(O1, O2, O3);
      __ cmp_and_br_short(O2, O3, Assembler::notEqual, Assembler::pn, retry);

      __ retl(false);
      __ delayed()->mov(O2, O0);  // report previous value to caller
    } else {
      __ retl(false);
      __ delayed()->swap(O1, 0, O0);
    }

    return start;
  }


  // Support for jint Atomic::cmpxchg(jint exchange_value, volatile jint* dest, jint compare_value)
  //
  // Arguments:
  //
  //      exchange_value: O0
  //      dest:           O1
  //      compare_value:  O2
  //
  // Results:
  //
  //     O0: the value previously stored in dest
  //
  address generate_atomic_cmpxchg() {
    StubCodeMark mark(this, "StubRoutines", "atomic_cmpxchg");
    address start = __ pc();

    // cmpxchg(dest, compare_value, exchange_value)
    __ cas(O1, O2, O0);
    __ retl(false);
    __ delayed()->nop();

    return start;
  }

  // Support for jlong Atomic::cmpxchg(jlong exchange_value, volatile jlong *dest, jlong compare_value)
  //
  // Arguments:
  //
  //      exchange_value: O1:O0
  //      dest:           O2
  //      compare_value:  O4:O3
  //
  // Results:
  //
  //     O1:O0: the value previously stored in dest
  //
  // Overwrites: G1,G2,G3
  //
  address generate_atomic_cmpxchg_long() {
    StubCodeMark mark(this, "StubRoutines", "atomic_cmpxchg_long");
    address start = __ pc();

    __ sllx(O0, 32, O0);
    __ srl(O1, 0, O1);
    __ or3(O0,O1,O0);      // O0 holds 64-bit value from compare_value
    __ sllx(O3, 32, O3);
    __ srl(O4, 0, O4);
    __ or3(O3,O4,O3);     // O3 holds 64-bit value from exchange_value
    __ casx(O2, O3, O0);
    __ srl(O0, 0, O1);    // unpacked return value in O1:O0
    __ retl(false);
    __ delayed()->srlx(O0, 32, O0);

    return start;
  }


  // Support for jint Atomic::add(jint add_value, volatile jint* dest).
  //
  // Arguments:
  //
  //      add_value: O0   (e.g., +1 or -1)
  //      dest:      O1
  //
  // Results:
  //
  //     O0: the new value stored in dest
  //
  // Overwrites: O3
  //
  address generate_atomic_add() {
    StubCodeMark mark(this, "StubRoutines", "atomic_add");
    address start = __ pc();
    __ BIND(_atomic_add_stub);

    Label(retry);
    __ BIND(retry);

    __ lduw(O1, 0, O2);
    __ add(O0, O2, O3);
    __ cas(O1, O2, O3);
    __ cmp_and_br_short(O2, O3, Assembler::notEqual, Assembler::pn, retry);
    __ retl(false);
    __ delayed()->add(O0, O2, O0); // note that cas made O2==O3

    return start;
  }
  Label _atomic_add_stub;  // called from other stubs


  // Support for uint StubRoutine::Sparc::partial_subtype_check( Klass sub, Klass super );
  // Arguments :
  //
  //      ret  : O0, returned
  //      icc/xcc: set as O0 (depending on wordSize)
  //      sub  : O1, argument, not changed
  //      super: O2, argument, not changed
  //      raddr: O7, blown by call
  address generate_partial_subtype_check() {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "partial_subtype_check");
    address start = __ pc();
    Label miss;

    __ save_frame(0);
    Register Rret   = I0;
    Register Rsub   = I1;
    Register Rsuper = I2;

    Register L0_ary_len = L0;
    Register L1_ary_ptr = L1;
    Register L2_super   = L2;
    Register L3_index   = L3;

    __ check_klass_subtype_slow_path(Rsub, Rsuper,
                                     L0, L1, L2, L3,
                                     NULL, &miss);

    // Match falls through here.
    __ addcc(G0,0,Rret);        // set Z flags, Z result

    __ ret();                   // Result in Rret is zero; flags set to Z
    __ delayed()->restore();

    __ BIND(miss);
    __ addcc(G0,1,Rret);        // set NZ flags, NZ result

    __ ret();                   // Result in Rret is != 0; flags set to NZ
    __ delayed()->restore();

    return start;
  }


  // Called from MacroAssembler::verify_oop
  //
  address generate_verify_oop_subroutine() {
    StubCodeMark mark(this, "StubRoutines", "verify_oop_stub");

    address start = __ pc();

    __ verify_oop_subroutine();

    return start;
  }


  //
  // Verify that a register contains clean 32-bits positive value
  // (high 32-bits are 0) so it could be used in 64-bits shifts (sllx, srax).
  //
  //  Input:
  //    Rint  -  32-bits value
  //    Rtmp  -  scratch
  //
  void assert_clean_int(Register Rint, Register Rtmp) {
  #if defined(ASSERT)
    __ signx(Rint, Rtmp);
    __ cmp(Rint, Rtmp);
    __ breakpoint_trap(Assembler::notEqual, Assembler::xcc);
  #endif
  }

  //
  //  Generate overlap test for array copy stubs
  //
  //  Input:
  //    O0    -  array1
  //    O1    -  array2
  //    O2    -  element count
  //
  //  Kills temps:  O3, O4
  //
  void array_overlap_test(address no_overlap_target, int log2_elem_size) {
    assert(no_overlap_target != NULL, "must be generated");
    array_overlap_test(no_overlap_target, NULL, log2_elem_size);
  }
  void array_overlap_test(Label& L_no_overlap, int log2_elem_size) {
    array_overlap_test(NULL, &L_no_overlap, log2_elem_size);
  }
  void array_overlap_test(address no_overlap_target, Label* NOLp, int log2_elem_size) {
    const Register from       = O0;
    const Register to         = O1;
    const Register count      = O2;
    const Register to_from    = O3; // to - from
    const Register byte_count = O4; // count << log2_elem_size

      __ subcc(to, from, to_from);
      __ sll_ptr(count, log2_elem_size, byte_count);
      if (NOLp == NULL)
        __ brx(Assembler::lessEqualUnsigned, false, Assembler::pt, no_overlap_target);
      else
        __ brx(Assembler::lessEqualUnsigned, false, Assembler::pt, (*NOLp));
      __ delayed()->cmp(to_from, byte_count);
      if (NOLp == NULL)
        __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, no_overlap_target);
      else
        __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, (*NOLp));
      __ delayed()->nop();
  }


  //
  // Generate main code for disjoint arraycopy
  //
  typedef void (StubGenerator::*CopyLoopFunc)(Register from, Register to, Register count, int count_dec,
                                              Label& L_loop, bool use_prefetch, bool use_bis);

  void disjoint_copy_core(Register from, Register to, Register count, int log2_elem_size,
                          int iter_size, StubGenerator::CopyLoopFunc copy_loop_func) {
    Label L_copy;

    assert(log2_elem_size <= 3, "the following code should be changed");
    int count_dec = 16>>log2_elem_size;

    int prefetch_dist = MAX2(ArraycopySrcPrefetchDistance, ArraycopyDstPrefetchDistance);
    assert(prefetch_dist < 4096, "invalid value");
    prefetch_dist = (prefetch_dist + (iter_size-1)) & (-iter_size); // round up to one iteration copy size
    int prefetch_count = (prefetch_dist >> log2_elem_size); // elements count

    if (UseBlockCopy) {
      Label L_block_copy, L_block_copy_prefetch, L_skip_block_copy;

      // 64 bytes tail + bytes copied in one loop iteration
      int tail_size = 64 + iter_size;
      int block_copy_count = (MAX2(tail_size, (int)BlockCopyLowLimit)) >> log2_elem_size;
      // Use BIS copy only for big arrays since it requires membar.
      __ set(block_copy_count, O4);
      __ cmp_and_br_short(count, O4, Assembler::lessUnsigned, Assembler::pt, L_skip_block_copy);
      // This code is for disjoint source and destination:
      //   to <= from || to >= from+count
      // but BIS will stomp over 'from' if (to > from-tail_size && to <= from)
      __ sub(from, to, O4);
      __ srax(O4, 4, O4); // divide by 16 since following short branch have only 5 bits for imm.
      __ cmp_and_br_short(O4, (tail_size>>4), Assembler::lessEqualUnsigned, Assembler::pn, L_skip_block_copy);

      __ wrasi(G0, Assembler::ASI_ST_BLKINIT_PRIMARY);
      // BIS should not be used to copy tail (64 bytes+iter_size)
      // to avoid zeroing of following values.
      __ sub(count, (tail_size>>log2_elem_size), count); // count is still positive >= 0

      if (prefetch_count > 0) { // rounded up to one iteration count
        // Do prefetching only if copy size is bigger
        // than prefetch distance.
        __ set(prefetch_count, O4);
        __ cmp_and_brx_short(count, O4, Assembler::less, Assembler::pt, L_block_copy);
        __ sub(count, O4, count);

        (this->*copy_loop_func)(from, to, count, count_dec, L_block_copy_prefetch, true, true);
        __ set(prefetch_count, O4);
        __ add(count, O4, count);

      } // prefetch_count > 0

      (this->*copy_loop_func)(from, to, count, count_dec, L_block_copy, false, true);
      __ add(count, (tail_size>>log2_elem_size), count); // restore count

      __ wrasi(G0, Assembler::ASI_PRIMARY_NOFAULT);
      // BIS needs membar.
      __ membar(Assembler::StoreLoad);
      // Copy tail
      __ ba_short(L_copy);

      __ BIND(L_skip_block_copy);
    } // UseBlockCopy

    if (prefetch_count > 0) { // rounded up to one iteration count
      // Do prefetching only if copy size is bigger
      // than prefetch distance.
      __ set(prefetch_count, O4);
      __ cmp_and_brx_short(count, O4, Assembler::lessUnsigned, Assembler::pt, L_copy);
      __ sub(count, O4, count);

      Label L_copy_prefetch;
      (this->*copy_loop_func)(from, to, count, count_dec, L_copy_prefetch, true, false);
      __ set(prefetch_count, O4);
      __ add(count, O4, count);

    } // prefetch_count > 0

    (this->*copy_loop_func)(from, to, count, count_dec, L_copy, false, false);
  }



  //
  // Helper methods for copy_16_bytes_forward_with_shift()
  //
  void copy_16_bytes_shift_loop(Register from, Register to, Register count, int count_dec,
                                Label& L_loop, bool use_prefetch, bool use_bis) {

    const Register left_shift  = G1; // left  shift bit counter
    const Register right_shift = G5; // right shift bit counter

    __ align(OptoLoopAlignment);
    __ BIND(L_loop);
    if (use_prefetch) {
      if (ArraycopySrcPrefetchDistance > 0) {
        __ prefetch(from, ArraycopySrcPrefetchDistance, Assembler::severalReads);
      }
      if (ArraycopyDstPrefetchDistance > 0) {
        __ prefetch(to, ArraycopyDstPrefetchDistance, Assembler::severalWritesAndPossiblyReads);
      }
    }
    __ ldx(from, 0, O4);
    __ ldx(from, 8, G4);
    __ inc(to, 16);
    __ inc(from, 16);
    __ deccc(count, count_dec); // Can we do next iteration after this one?
    __ srlx(O4, right_shift, G3);
    __ bset(G3, O3);
    __ sllx(O4, left_shift,  O4);
    __ srlx(G4, right_shift, G3);
    __ bset(G3, O4);
    if (use_bis) {
      __ stxa(O3, to, -16);
      __ stxa(O4, to, -8);
    } else {
      __ stx(O3, to, -16);
      __ stx(O4, to, -8);
    }
    __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
    __ delayed()->sllx(G4, left_shift,  O3);
  }

  // Copy big chunks forward with shift
  //
  // Inputs:
  //   from      - source arrays
  //   to        - destination array aligned to 8-bytes
  //   count     - elements count to copy >= the count equivalent to 16 bytes
  //   count_dec - elements count's decrement equivalent to 16 bytes
  //   L_copy_bytes - copy exit label
  //
  void copy_16_bytes_forward_with_shift(Register from, Register to,
                     Register count, int log2_elem_size, Label& L_copy_bytes) {
    Label L_aligned_copy, L_copy_last_bytes;
    assert(log2_elem_size <= 3, "the following code should be changed");
    int count_dec = 16>>log2_elem_size;

    // if both arrays have the same alignment mod 8, do 8 bytes aligned copy
    __ andcc(from, 7, G1); // misaligned bytes
    __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
    __ delayed()->nop();

    const Register left_shift  = G1; // left  shift bit counter
    const Register right_shift = G5; // right shift bit counter

    __ sll(G1, LogBitsPerByte, left_shift);
    __ mov(64, right_shift);
    __ sub(right_shift, left_shift, right_shift);

    //
    // Load 2 aligned 8-bytes chunks and use one from previous iteration
    // to form 2 aligned 8-bytes chunks to store.
    //
    __ dec(count, count_dec);   // Pre-decrement 'count'
    __ andn(from, 7, from);     // Align address
    __ ldx(from, 0, O3);
    __ inc(from, 8);
    __ sllx(O3, left_shift,  O3);

    disjoint_copy_core(from, to, count, log2_elem_size, 16, &StubGenerator::copy_16_bytes_shift_loop);

    __ inccc(count, count_dec>>1 ); // + 8 bytes
    __ brx(Assembler::negative, true, Assembler::pn, L_copy_last_bytes);
    __ delayed()->inc(count, count_dec>>1); // restore 'count'

    // copy 8 bytes, part of them already loaded in O3
    __ ldx(from, 0, O4);
    __ inc(to, 8);
    __ inc(from, 8);
    __ srlx(O4, right_shift, G3);
    __ bset(O3, G3);
    __ stx(G3, to, -8);

    __ BIND(L_copy_last_bytes);
    __ srl(right_shift, LogBitsPerByte, right_shift); // misaligned bytes
    __ br(Assembler::always, false, Assembler::pt, L_copy_bytes);
    __ delayed()->sub(from, right_shift, from);       // restore address

    __ BIND(L_aligned_copy);
  }

  // Copy big chunks backward with shift
  //
  // Inputs:
  //   end_from  - source arrays end address
  //   end_to    - destination array end address aligned to 8-bytes
  //   count     - elements count to copy >= the count equivalent to 16 bytes
  //   count_dec - elements count's decrement equivalent to 16 bytes
  //   L_aligned_copy - aligned copy exit label
  //   L_copy_bytes   - copy exit label
  //
  void copy_16_bytes_backward_with_shift(Register end_from, Register end_to,
                     Register count, int count_dec,
                     Label& L_aligned_copy, Label& L_copy_bytes) {
    Label L_loop, L_copy_last_bytes;

    // if both arrays have the same alignment mod 8, do 8 bytes aligned copy
      __ andcc(end_from, 7, G1); // misaligned bytes
      __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
      __ delayed()->deccc(count, count_dec); // Pre-decrement 'count'

    const Register left_shift  = G1; // left  shift bit counter
    const Register right_shift = G5; // right shift bit counter

      __ sll(G1, LogBitsPerByte, left_shift);
      __ mov(64, right_shift);
      __ sub(right_shift, left_shift, right_shift);

    //
    // Load 2 aligned 8-bytes chunks and use one from previous iteration
    // to form 2 aligned 8-bytes chunks to store.
    //
      __ andn(end_from, 7, end_from);     // Align address
      __ ldx(end_from, 0, O3);
      __ align(OptoLoopAlignment);
    __ BIND(L_loop);
      __ ldx(end_from, -8, O4);
      __ deccc(count, count_dec); // Can we do next iteration after this one?
      __ ldx(end_from, -16, G4);
      __ dec(end_to, 16);
      __ dec(end_from, 16);
      __ srlx(O3, right_shift, O3);
      __ sllx(O4, left_shift,  G3);
      __ bset(G3, O3);
      __ stx(O3, end_to, 8);
      __ srlx(O4, right_shift, O4);
      __ sllx(G4, left_shift,  G3);
      __ bset(G3, O4);
      __ stx(O4, end_to, 0);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
      __ delayed()->mov(G4, O3);

      __ inccc(count, count_dec>>1 ); // + 8 bytes
      __ brx(Assembler::negative, true, Assembler::pn, L_copy_last_bytes);
      __ delayed()->inc(count, count_dec>>1); // restore 'count'

      // copy 8 bytes, part of them already loaded in O3
      __ ldx(end_from, -8, O4);
      __ dec(end_to, 8);
      __ dec(end_from, 8);
      __ srlx(O3, right_shift, O3);
      __ sllx(O4, left_shift,  G3);
      __ bset(O3, G3);
      __ stx(G3, end_to, 0);

    __ BIND(L_copy_last_bytes);
      __ srl(left_shift, LogBitsPerByte, left_shift);    // misaligned bytes
      __ br(Assembler::always, false, Assembler::pt, L_copy_bytes);
      __ delayed()->add(end_from, left_shift, end_from); // restore address
  }

  //
  //  Generate stub for disjoint byte copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_disjoint_byte_copy(bool aligned, address *entry, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_skip_alignment, L_align;
    Label L_copy_byte, L_copy_byte_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register offset    = O5;   // offset from start of arrays
    // O3, O4, G3, G4 are used as temp registers

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    // for short arrays, just do single element copy
    __ cmp(count, 23); // 16 + 7
    __ brx(Assembler::less, false, Assembler::pn, L_copy_byte);
    __ delayed()->mov(G0, offset);

    if (aligned) {
      // 'aligned' == true when it is known statically during compilation
      // of this arraycopy call site that both 'from' and 'to' addresses
      // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
      //
      // Aligned arrays have 4 bytes alignment in 32-bits VM
      // and 8 bytes - in 64-bits VM. So we do it only for 32-bits VM
      //
    } else {
      // copy bytes to align 'to' on 8 byte boundary
      __ andcc(to, 7, G1); // misaligned bytes
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->neg(G1);
      __ inc(G1, 8);       // bytes need to copy to next 8-bytes alignment
      __ sub(count, G1, count);
    __ BIND(L_align);
      __ ldub(from, 0, O3);
      __ deccc(G1);
      __ inc(from);
      __ stb(O3, to, 0);
      __ br(Assembler::notZero, false, Assembler::pt, L_align);
      __ delayed()->inc(to);
    __ BIND(L_skip_alignment);
    }
    if (!aligned) {
      // Copy with shift 16 bytes per iteration if arrays do not have
      // the same alignment mod 8, otherwise fall through to the next
      // code for aligned copy.
      // The compare above (count >= 23) guarantes 'count' >= 16 bytes.
      // Also jump over aligned copy after the copy with shift completed.

      copy_16_bytes_forward_with_shift(from, to, count, 0, L_copy_byte);
    }

    // Both array are 8 bytes aligned, copy 16 bytes at a time
      __ and3(count, 7, G4); // Save count
      __ srl(count, 3, count);
     generate_disjoint_long_copy_core(aligned);
      __ mov(G4, count);     // Restore count

    // copy tailing bytes
    __ BIND(L_copy_byte);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_byte_loop);
      __ ldub(from, offset, O3);
      __ deccc(count);
      __ stb(O3, to, offset);
      __ brx(Assembler::notZero, false, Assembler::pt, L_copy_byte_loop);
      __ delayed()->inc(offset);

    __ BIND(L_exit);
      // O3, O4 are used as temp registers
      inc_counter_np(SharedRuntime::_jbyte_array_copy_ctr, O3, O4);
      __ retl();
      __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  //  Generate stub for conjoint byte copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_conjoint_byte_copy(bool aligned, address nooverlap_target,
                                      address *entry, const char *name) {
    // Do reverse copy.

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_skip_alignment, L_align, L_aligned_copy;
    Label L_copy_byte, L_copy_byte_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register end_from  = from; // source array end address
    const Register end_to    = to;   // destination array end address

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, 0);

    __ add(to, count, end_to);       // offset after last copied element

    // for short arrays, just do single element copy
    __ cmp(count, 23); // 16 + 7
    __ brx(Assembler::less, false, Assembler::pn, L_copy_byte);
    __ delayed()->add(from, count, end_from);

    {
      // Align end of arrays since they could be not aligned even
      // when arrays itself are aligned.

      // copy bytes to align 'end_to' on 8 byte boundary
      __ andcc(end_to, 7, G1); // misaligned bytes
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->nop();
      __ sub(count, G1, count);
    __ BIND(L_align);
      __ dec(end_from);
      __ dec(end_to);
      __ ldub(end_from, 0, O3);
      __ deccc(G1);
      __ brx(Assembler::notZero, false, Assembler::pt, L_align);
      __ delayed()->stb(O3, end_to, 0);
    __ BIND(L_skip_alignment);
    }
    if (aligned) {
      // Both arrays are aligned to 8-bytes in 64-bits VM.
      // The 'count' is decremented in copy_16_bytes_backward_with_shift()
      // in unaligned case.
      __ dec(count, 16);
    } else {
      // Copy with shift 16 bytes per iteration if arrays do not have
      // the same alignment mod 8, otherwise jump to the next
      // code for aligned copy (and substracting 16 from 'count' before jump).
      // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
      // Also jump over aligned copy after the copy with shift completed.

      copy_16_bytes_backward_with_shift(end_from, end_to, count, 16,
                                        L_aligned_copy, L_copy_byte);
    }
    // copy 4 elements (16 bytes) at a time
      __ align(OptoLoopAlignment);
    __ BIND(L_aligned_copy);
      __ dec(end_from, 16);
      __ ldx(end_from, 8, O3);
      __ ldx(end_from, 0, O4);
      __ dec(end_to, 16);
      __ deccc(count, 16);
      __ stx(O3, end_to, 8);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
      __ delayed()->stx(O4, end_to, 0);
      __ inc(count, 16);

    // copy 1 element (2 bytes) at a time
    __ BIND(L_copy_byte);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_byte_loop);
      __ dec(end_from);
      __ dec(end_to);
      __ ldub(end_from, 0, O4);
      __ deccc(count);
      __ brx(Assembler::greater, false, Assembler::pt, L_copy_byte_loop);
      __ delayed()->stb(O4, end_to, 0);

    __ BIND(L_exit);
    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jbyte_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  //  Generate stub for disjoint short copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_disjoint_short_copy(bool aligned, address *entry, const char * name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_skip_alignment, L_skip_alignment2;
    Label L_copy_2_bytes, L_copy_2_bytes_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register offset    = O5;   // offset from start of arrays
    // O3, O4, G3, G4 are used as temp registers

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    // for short arrays, just do single element copy
    __ cmp(count, 11); // 8 + 3  (22 bytes)
    __ brx(Assembler::less, false, Assembler::pn, L_copy_2_bytes);
    __ delayed()->mov(G0, offset);

    if (aligned) {
      // 'aligned' == true when it is known statically during compilation
      // of this arraycopy call site that both 'from' and 'to' addresses
      // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
      //
      // Aligned arrays have 4 bytes alignment in 32-bits VM
      // and 8 bytes - in 64-bits VM.
      //
    } else {
      // copy 1 element if necessary to align 'to' on an 4 bytes
      __ andcc(to, 3, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->lduh(from, 0, O3);
      __ inc(from, 2);
      __ inc(to, 2);
      __ dec(count);
      __ sth(O3, to, -2);
    __ BIND(L_skip_alignment);

      // copy 2 elements to align 'to' on an 8 byte boundary
      __ andcc(to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment2);
      __ delayed()->lduh(from, 0, O3);
      __ dec(count, 2);
      __ lduh(from, 2, O4);
      __ inc(from, 4);
      __ inc(to, 4);
      __ sth(O3, to, -4);
      __ sth(O4, to, -2);
    __ BIND(L_skip_alignment2);
    }
    if (!aligned) {
      // Copy with shift 16 bytes per iteration if arrays do not have
      // the same alignment mod 8, otherwise fall through to the next
      // code for aligned copy.
      // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
      // Also jump over aligned copy after the copy with shift completed.

      copy_16_bytes_forward_with_shift(from, to, count, 1, L_copy_2_bytes);
    }

    // Both array are 8 bytes aligned, copy 16 bytes at a time
      __ and3(count, 3, G4); // Save
      __ srl(count, 2, count);
     generate_disjoint_long_copy_core(aligned);
      __ mov(G4, count); // restore

    // copy 1 element at a time
    __ BIND(L_copy_2_bytes);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_2_bytes_loop);
      __ lduh(from, offset, O3);
      __ deccc(count);
      __ sth(O3, to, offset);
      __ brx(Assembler::notZero, false, Assembler::pt, L_copy_2_bytes_loop);
      __ delayed()->inc(offset, 2);

    __ BIND(L_exit);
      // O3, O4 are used as temp registers
      inc_counter_np(SharedRuntime::_jshort_array_copy_ctr, O3, O4);
      __ retl();
      __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  //  Generate stub for disjoint short fill.  If "aligned" is true, the
  //  "to" address is assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      to:    O0
  //      value: O1
  //      count: O2 treated as signed
  //
  address generate_fill(BasicType t, bool aligned, const char* name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    const Register to        = O0;   // source array address
    const Register value     = O1;   // fill value
    const Register count     = O2;   // elements count
    // O3 is used as a temp register

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    Label L_exit, L_skip_align1, L_skip_align2, L_fill_byte;
    Label L_fill_2_bytes, L_fill_elements, L_fill_32_bytes;

    int shift = -1;
    switch (t) {
       case T_BYTE:
        shift = 2;
        break;
       case T_SHORT:
        shift = 1;
        break;
      case T_INT:
         shift = 0;
        break;
      default: ShouldNotReachHere();
    }

    BLOCK_COMMENT("Entry:");

    if (t == T_BYTE) {
      // Zero extend value
      __ and3(value, 0xff, value);
      __ sllx(value, 8, O3);
      __ or3(value, O3, value);
    }
    if (t == T_SHORT) {
      // Zero extend value
      __ sllx(value, 48, value);
      __ srlx(value, 48, value);
    }
    if (t == T_BYTE || t == T_SHORT) {
      __ sllx(value, 16, O3);
      __ or3(value, O3, value);
    }

    __ cmp(count, 2<<shift); // Short arrays (< 8 bytes) fill by element
    __ brx(Assembler::lessUnsigned, false, Assembler::pn, L_fill_elements); // use unsigned cmp
    __ delayed()->andcc(count, 1, G0);

    if (!aligned && (t == T_BYTE || t == T_SHORT)) {
      // align source address at 4 bytes address boundary
      if (t == T_BYTE) {
        // One byte misalignment happens only for byte arrays
        __ andcc(to, 1, G0);
        __ br(Assembler::zero, false, Assembler::pt, L_skip_align1);
        __ delayed()->nop();
        __ stb(value, to, 0);
        __ inc(to, 1);
        __ dec(count, 1);
        __ BIND(L_skip_align1);
      }
      // Two bytes misalignment happens only for byte and short (char) arrays
      __ andcc(to, 2, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_skip_align2);
      __ delayed()->nop();
      __ sth(value, to, 0);
      __ inc(to, 2);
      __ dec(count, 1 << (shift - 1));
      __ BIND(L_skip_align2);
    }
    if (!aligned) {
      // align to 8 bytes, we know we are 4 byte aligned to start
      __ andcc(to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_fill_32_bytes);
      __ delayed()->nop();
      __ stw(value, to, 0);
      __ inc(to, 4);
      __ dec(count, 1 << shift);
      __ BIND(L_fill_32_bytes);
    }

    if (t == T_INT) {
      // Zero extend value
      __ srl(value, 0, value);
    }
    if (t == T_BYTE || t == T_SHORT || t == T_INT) {
      __ sllx(value, 32, O3);
      __ or3(value, O3, value);
    }

    Label L_check_fill_8_bytes;
    // Fill 32-byte chunks
    __ subcc(count, 8 << shift, count);
    __ brx(Assembler::less, false, Assembler::pt, L_check_fill_8_bytes);
    __ delayed()->nop();

    Label L_fill_32_bytes_loop, L_fill_4_bytes;
    __ align(16);
    __ BIND(L_fill_32_bytes_loop);

    __ stx(value, to, 0);
    __ stx(value, to, 8);
    __ stx(value, to, 16);
    __ stx(value, to, 24);

    __ subcc(count, 8 << shift, count);
    __ brx(Assembler::greaterEqual, false, Assembler::pt, L_fill_32_bytes_loop);
    __ delayed()->add(to, 32, to);

    __ BIND(L_check_fill_8_bytes);
    __ addcc(count, 8 << shift, count);
    __ brx(Assembler::zero, false, Assembler::pn, L_exit);
    __ delayed()->subcc(count, 1 << (shift + 1), count);
    __ brx(Assembler::less, false, Assembler::pn, L_fill_4_bytes);
    __ delayed()->andcc(count, 1<<shift, G0);

    //
    // length is too short, just fill 8 bytes at a time
    //
    Label L_fill_8_bytes_loop;
    __ BIND(L_fill_8_bytes_loop);
    __ stx(value, to, 0);
    __ subcc(count, 1 << (shift + 1), count);
    __ brx(Assembler::greaterEqual, false, Assembler::pn, L_fill_8_bytes_loop);
    __ delayed()->add(to, 8, to);

    // fill trailing 4 bytes
    __ andcc(count, 1<<shift, G0);  // in delay slot of branches
    if (t == T_INT) {
      __ BIND(L_fill_elements);
    }
    __ BIND(L_fill_4_bytes);
    __ brx(Assembler::zero, false, Assembler::pt, L_fill_2_bytes);
    if (t == T_BYTE || t == T_SHORT) {
      __ delayed()->andcc(count, 1<<(shift-1), G0);
    } else {
      __ delayed()->nop();
    }
    __ stw(value, to, 0);
    if (t == T_BYTE || t == T_SHORT) {
      __ inc(to, 4);
      // fill trailing 2 bytes
      __ andcc(count, 1<<(shift-1), G0); // in delay slot of branches
      __ BIND(L_fill_2_bytes);
      __ brx(Assembler::zero, false, Assembler::pt, L_fill_byte);
      __ delayed()->andcc(count, 1, count);
      __ sth(value, to, 0);
      if (t == T_BYTE) {
        __ inc(to, 2);
        // fill trailing byte
        __ andcc(count, 1, count);  // in delay slot of branches
        __ BIND(L_fill_byte);
        __ brx(Assembler::zero, false, Assembler::pt, L_exit);
        __ delayed()->nop();
        __ stb(value, to, 0);
      } else {
        __ BIND(L_fill_byte);
      }
    } else {
      __ BIND(L_fill_2_bytes);
    }
    __ BIND(L_exit);
    __ retl();
    __ delayed()->nop();

    // Handle copies less than 8 bytes.  Int is handled elsewhere.
    if (t == T_BYTE) {
      __ BIND(L_fill_elements);
      Label L_fill_2, L_fill_4;
      // in delay slot __ andcc(count, 1, G0);
      __ brx(Assembler::zero, false, Assembler::pt, L_fill_2);
      __ delayed()->andcc(count, 2, G0);
      __ stb(value, to, 0);
      __ inc(to, 1);
      __ BIND(L_fill_2);
      __ brx(Assembler::zero, false, Assembler::pt, L_fill_4);
      __ delayed()->andcc(count, 4, G0);
      __ stb(value, to, 0);
      __ stb(value, to, 1);
      __ inc(to, 2);
      __ BIND(L_fill_4);
      __ brx(Assembler::zero, false, Assembler::pt, L_exit);
      __ delayed()->nop();
      __ stb(value, to, 0);
      __ stb(value, to, 1);
      __ stb(value, to, 2);
      __ retl();
      __ delayed()->stb(value, to, 3);
    }

    if (t == T_SHORT) {
      Label L_fill_2;
      __ BIND(L_fill_elements);
      // in delay slot __ andcc(count, 1, G0);
      __ brx(Assembler::zero, false, Assembler::pt, L_fill_2);
      __ delayed()->andcc(count, 2, G0);
      __ sth(value, to, 0);
      __ inc(to, 2);
      __ BIND(L_fill_2);
      __ brx(Assembler::zero, false, Assembler::pt, L_exit);
      __ delayed()->nop();
      __ sth(value, to, 0);
      __ retl();
      __ delayed()->sth(value, to, 2);
    }
    return start;
  }

  //
  //  Generate stub for conjoint short copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_conjoint_short_copy(bool aligned, address nooverlap_target,
                                       address *entry, const char *name) {
    // Do reverse copy.

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_skip_alignment, L_skip_alignment2, L_aligned_copy;
    Label L_copy_2_bytes, L_copy_2_bytes_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register end_from  = from; // source array end address
    const Register end_to    = to;   // destination array end address

    const Register byte_count = O3;  // bytes count to copy

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, 1);

    __ sllx(count, LogBytesPerShort, byte_count);
    __ add(to, byte_count, end_to);  // offset after last copied element

    // for short arrays, just do single element copy
    __ cmp(count, 11); // 8 + 3  (22 bytes)
    __ brx(Assembler::less, false, Assembler::pn, L_copy_2_bytes);
    __ delayed()->add(from, byte_count, end_from);

    {
      // Align end of arrays since they could be not aligned even
      // when arrays itself are aligned.

      // copy 1 element if necessary to align 'end_to' on an 4 bytes
      __ andcc(end_to, 3, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->lduh(end_from, -2, O3);
      __ dec(end_from, 2);
      __ dec(end_to, 2);
      __ dec(count);
      __ sth(O3, end_to, 0);
    __ BIND(L_skip_alignment);

      // copy 2 elements to align 'end_to' on an 8 byte boundary
      __ andcc(end_to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment2);
      __ delayed()->lduh(end_from, -2, O3);
      __ dec(count, 2);
      __ lduh(end_from, -4, O4);
      __ dec(end_from, 4);
      __ dec(end_to, 4);
      __ sth(O3, end_to, 2);
      __ sth(O4, end_to, 0);
    __ BIND(L_skip_alignment2);
    }
    if (aligned) {
      // Both arrays are aligned to 8-bytes in 64-bits VM.
      // The 'count' is decremented in copy_16_bytes_backward_with_shift()
      // in unaligned case.
      __ dec(count, 8);
    } else {
      // Copy with shift 16 bytes per iteration if arrays do not have
      // the same alignment mod 8, otherwise jump to the next
      // code for aligned copy (and substracting 8 from 'count' before jump).
      // The compare above (count >= 11) guarantes 'count' >= 16 bytes.
      // Also jump over aligned copy after the copy with shift completed.

      copy_16_bytes_backward_with_shift(end_from, end_to, count, 8,
                                        L_aligned_copy, L_copy_2_bytes);
    }
    // copy 4 elements (16 bytes) at a time
      __ align(OptoLoopAlignment);
    __ BIND(L_aligned_copy);
      __ dec(end_from, 16);
      __ ldx(end_from, 8, O3);
      __ ldx(end_from, 0, O4);
      __ dec(end_to, 16);
      __ deccc(count, 8);
      __ stx(O3, end_to, 8);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
      __ delayed()->stx(O4, end_to, 0);
      __ inc(count, 8);

    // copy 1 element (2 bytes) at a time
    __ BIND(L_copy_2_bytes);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
    __ BIND(L_copy_2_bytes_loop);
      __ dec(end_from, 2);
      __ dec(end_to, 2);
      __ lduh(end_from, 0, O4);
      __ deccc(count);
      __ brx(Assembler::greater, false, Assembler::pt, L_copy_2_bytes_loop);
      __ delayed()->sth(O4, end_to, 0);

    __ BIND(L_exit);
    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jshort_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  // Helper methods for generate_disjoint_int_copy_core()
  //
  void copy_16_bytes_loop(Register from, Register to, Register count, int count_dec,
                          Label& L_loop, bool use_prefetch, bool use_bis) {

    __ align(OptoLoopAlignment);
    __ BIND(L_loop);
    if (use_prefetch) {
      if (ArraycopySrcPrefetchDistance > 0) {
        __ prefetch(from, ArraycopySrcPrefetchDistance, Assembler::severalReads);
      }
      if (ArraycopyDstPrefetchDistance > 0) {
        __ prefetch(to, ArraycopyDstPrefetchDistance, Assembler::severalWritesAndPossiblyReads);
      }
    }
    __ ldx(from, 4, O4);
    __ ldx(from, 12, G4);
    __ inc(to, 16);
    __ inc(from, 16);
    __ deccc(count, 4); // Can we do next iteration after this one?

    __ srlx(O4, 32, G3);
    __ bset(G3, O3);
    __ sllx(O4, 32, O4);
    __ srlx(G4, 32, G3);
    __ bset(G3, O4);
    if (use_bis) {
      __ stxa(O3, to, -16);
      __ stxa(O4, to, -8);
    } else {
      __ stx(O3, to, -16);
      __ stx(O4, to, -8);
    }
    __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
    __ delayed()->sllx(G4, 32,  O3);

  }

  //
  //  Generate core code for disjoint int copy (and oop copy on 32-bit).
  //  If "aligned" is true, the "from" and "to" addresses are assumed
  //  to be heapword aligned.
  //
  // Arguments:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  void generate_disjoint_int_copy_core(bool aligned) {

    Label L_skip_alignment, L_aligned_copy;
    Label L_copy_4_bytes, L_copy_4_bytes_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register offset    = O5;   // offset from start of arrays
    // O3, O4, G3, G4 are used as temp registers

    // 'aligned' == true when it is known statically during compilation
    // of this arraycopy call site that both 'from' and 'to' addresses
    // are HeapWordSize aligned (see LibraryCallKit::basictype2arraycopy()).
    //
    // Aligned arrays have 4 bytes alignment in 32-bits VM
    // and 8 bytes - in 64-bits VM.
    //
    if (!aligned) {
      // The next check could be put under 'ifndef' since the code in
      // generate_disjoint_long_copy_core() has own checks and set 'offset'.

      // for short arrays, just do single element copy
      __ cmp(count, 5); // 4 + 1 (20 bytes)
      __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_4_bytes);
      __ delayed()->mov(G0, offset);

      // copy 1 element to align 'to' on an 8 byte boundary
      __ andcc(to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->ld(from, 0, O3);
      __ inc(from, 4);
      __ inc(to, 4);
      __ dec(count);
      __ st(O3, to, -4);
    __ BIND(L_skip_alignment);

    // if arrays have same alignment mod 8, do 4 elements copy
      __ andcc(from, 7, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
      __ delayed()->ld(from, 0, O3);

    //
    // Load 2 aligned 8-bytes chunks and use one from previous iteration
    // to form 2 aligned 8-bytes chunks to store.
    //
    // copy_16_bytes_forward_with_shift() is not used here since this
    // code is more optimal.

    // copy with shift 4 elements (16 bytes) at a time
      __ dec(count, 4);   // The cmp at the beginning guaranty count >= 4
      __ sllx(O3, 32,  O3);

      disjoint_copy_core(from, to, count, 2, 16, &StubGenerator::copy_16_bytes_loop);

      __ br(Assembler::always, false, Assembler::pt, L_copy_4_bytes);
      __ delayed()->inc(count, 4); // restore 'count'

    __ BIND(L_aligned_copy);
    } // !aligned

    // copy 4 elements (16 bytes) at a time
      __ and3(count, 1, G4); // Save
      __ srl(count, 1, count);
     generate_disjoint_long_copy_core(aligned);
      __ mov(G4, count);     // Restore

    // copy 1 element at a time
    __ BIND(L_copy_4_bytes);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
    __ BIND(L_copy_4_bytes_loop);
      __ ld(from, offset, O3);
      __ deccc(count);
      __ st(O3, to, offset);
      __ brx(Assembler::notZero, false, Assembler::pt, L_copy_4_bytes_loop);
      __ delayed()->inc(offset, 4);
    __ BIND(L_exit);
  }

  //
  //  Generate stub for disjoint int copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_disjoint_int_copy(bool aligned, address *entry, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    const Register count = O2;
    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    generate_disjoint_int_copy_core(aligned);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jint_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  //  Generate core code for conjoint int copy (and oop copy on 32-bit).
  //  If "aligned" is true, the "from" and "to" addresses are assumed
  //  to be heapword aligned.
  //
  // Arguments:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  void generate_conjoint_int_copy_core(bool aligned) {
    // Do reverse copy.

    Label L_skip_alignment, L_aligned_copy;
    Label L_copy_16_bytes,  L_copy_4_bytes, L_copy_4_bytes_loop, L_exit;

    const Register from      = O0;   // source array address
    const Register to        = O1;   // destination array address
    const Register count     = O2;   // elements count
    const Register end_from  = from; // source array end address
    const Register end_to    = to;   // destination array end address
    // O3, O4, O5, G3 are used as temp registers

    const Register byte_count = O3;  // bytes count to copy

      __ sllx(count, LogBytesPerInt, byte_count);
      __ add(to, byte_count, end_to); // offset after last copied element

      __ cmp(count, 5); // for short arrays, just do single element copy
      __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_4_bytes);
      __ delayed()->add(from, byte_count, end_from);

    // copy 1 element to align 'to' on an 8 byte boundary
      __ andcc(end_to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_skip_alignment);
      __ delayed()->nop();
      __ dec(count);
      __ dec(end_from, 4);
      __ dec(end_to,   4);
      __ ld(end_from, 0, O4);
      __ st(O4, end_to, 0);
    __ BIND(L_skip_alignment);

    // Check if 'end_from' and 'end_to' has the same alignment.
      __ andcc(end_from, 7, G0);
      __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
      __ delayed()->dec(count, 4); // The cmp at the start guaranty cnt >= 4

    // copy with shift 4 elements (16 bytes) at a time
    //
    // Load 2 aligned 8-bytes chunks and use one from previous iteration
    // to form 2 aligned 8-bytes chunks to store.
    //
      __ ldx(end_from, -4, O3);
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_16_bytes);
      __ ldx(end_from, -12, O4);
      __ deccc(count, 4);
      __ ldx(end_from, -20, O5);
      __ dec(end_to, 16);
      __ dec(end_from, 16);
      __ srlx(O3, 32, O3);
      __ sllx(O4, 32, G3);
      __ bset(G3, O3);
      __ stx(O3, end_to, 8);
      __ srlx(O4, 32, O4);
      __ sllx(O5, 32, G3);
      __ bset(O4, G3);
      __ stx(G3, end_to, 0);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_copy_16_bytes);
      __ delayed()->mov(O5, O3);

      __ br(Assembler::always, false, Assembler::pt, L_copy_4_bytes);
      __ delayed()->inc(count, 4);

    // copy 4 elements (16 bytes) at a time
      __ align(OptoLoopAlignment);
    __ BIND(L_aligned_copy);
      __ dec(end_from, 16);
      __ ldx(end_from, 8, O3);
      __ ldx(end_from, 0, O4);
      __ dec(end_to, 16);
      __ deccc(count, 4);
      __ stx(O3, end_to, 8);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_aligned_copy);
      __ delayed()->stx(O4, end_to, 0);
      __ inc(count, 4);

    // copy 1 element (4 bytes) at a time
    __ BIND(L_copy_4_bytes);
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
    __ BIND(L_copy_4_bytes_loop);
      __ dec(end_from, 4);
      __ dec(end_to, 4);
      __ ld(end_from, 0, O4);
      __ deccc(count);
      __ brx(Assembler::greater, false, Assembler::pt, L_copy_4_bytes_loop);
      __ delayed()->st(O4, end_to, 0);
    __ BIND(L_exit);
  }

  //
  //  Generate stub for conjoint int copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_conjoint_int_copy(bool aligned, address nooverlap_target,
                                     address *entry, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    assert_clean_int(O2, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, 2);

    generate_conjoint_int_copy_core(aligned);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jint_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  // Helper methods for generate_disjoint_long_copy_core()
  //
  void copy_64_bytes_loop(Register from, Register to, Register count, int count_dec,
                          Label& L_loop, bool use_prefetch, bool use_bis) {
    __ align(OptoLoopAlignment);
    __ BIND(L_loop);
    for (int off = 0; off < 64; off += 16) {
      if (use_prefetch && (off & 31) == 0) {
        if (ArraycopySrcPrefetchDistance > 0) {
          __ prefetch(from, ArraycopySrcPrefetchDistance+off, Assembler::severalReads);
        }
        if (ArraycopyDstPrefetchDistance > 0) {
          __ prefetch(to, ArraycopyDstPrefetchDistance+off, Assembler::severalWritesAndPossiblyReads);
        }
      }
      __ ldx(from,  off+0, O4);
      __ ldx(from,  off+8, O5);
      if (use_bis) {
        __ stxa(O4, to,  off+0);
        __ stxa(O5, to,  off+8);
      } else {
        __ stx(O4, to,  off+0);
        __ stx(O5, to,  off+8);
      }
    }
    __ deccc(count, 8);
    __ inc(from, 64);
    __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
    __ delayed()->inc(to, 64);
  }

  //
  //  Generate core code for disjoint long copy (and oop copy on 64-bit).
  //  "aligned" is ignored, because we must make the stronger
  //  assumption that both addresses are always 64-bit aligned.
  //
  // Arguments:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  // count -= 2;
  // if ( count >= 0 ) { // >= 2 elements
  //   if ( count > 6) { // >= 8 elements
  //     count -= 6; // original count - 8
  //     do {
  //       copy_8_elements;
  //       count -= 8;
  //     } while ( count >= 0 );
  //     count += 6;
  //   }
  //   if ( count >= 0 ) { // >= 2 elements
  //     do {
  //       copy_2_elements;
  //     } while ( (count=count-2) >= 0 );
  //   }
  // }
  // count += 2;
  // if ( count != 0 ) { // 1 element left
  //   copy_1_element;
  // }
  //
  void generate_disjoint_long_copy_core(bool aligned) {
    Label L_copy_8_bytes, L_copy_16_bytes, L_exit;
    const Register from    = O0;  // source array address
    const Register to      = O1;  // destination array address
    const Register count   = O2;  // elements count
    const Register offset0 = O4;  // element offset
    const Register offset8 = O5;  // next element offset

    __ deccc(count, 2);
    __ mov(G0, offset0);   // offset from start of arrays (0)
    __ brx(Assembler::negative, false, Assembler::pn, L_copy_8_bytes );
    __ delayed()->add(offset0, 8, offset8);

    // Copy by 64 bytes chunks

    const Register from64 = O3;  // source address
    const Register to64   = G3;  // destination address
    __ subcc(count, 6, O3);
    __ brx(Assembler::negative, false, Assembler::pt, L_copy_16_bytes );
    __ delayed()->mov(to,   to64);
    // Now we can use O4(offset0), O5(offset8) as temps
    __ mov(O3, count);
    // count >= 0 (original count - 8)
    __ mov(from, from64);

    disjoint_copy_core(from64, to64, count, 3, 64, &StubGenerator::copy_64_bytes_loop);

      // Restore O4(offset0), O5(offset8)
      __ sub(from64, from, offset0);
      __ inccc(count, 6); // restore count
      __ brx(Assembler::negative, false, Assembler::pn, L_copy_8_bytes );
      __ delayed()->add(offset0, 8, offset8);

      // Copy by 16 bytes chunks
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_16_bytes);
      __ ldx(from, offset0, O3);
      __ ldx(from, offset8, G3);
      __ deccc(count, 2);
      __ stx(O3, to, offset0);
      __ inc(offset0, 16);
      __ stx(G3, to, offset8);
      __ brx(Assembler::greaterEqual, false, Assembler::pt, L_copy_16_bytes);
      __ delayed()->inc(offset8, 16);

      // Copy last 8 bytes
    __ BIND(L_copy_8_bytes);
      __ inccc(count, 2);
      __ brx(Assembler::zero, true, Assembler::pn, L_exit );
      __ delayed()->mov(offset0, offset8); // Set O5 used by other stubs
      __ ldx(from, offset0, O3);
      __ stx(O3, to, offset0);
    __ BIND(L_exit);
  }

  //
  //  Generate stub for disjoint long copy.
  //  "aligned" is ignored, because we must make the stronger
  //  assumption that both addresses are always 64-bit aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_disjoint_long_copy(bool aligned, address *entry, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    assert_clean_int(O2, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    generate_disjoint_long_copy_core(aligned);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jlong_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //
  //  Generate core code for conjoint long copy (and oop copy on 64-bit).
  //  "aligned" is ignored, because we must make the stronger
  //  assumption that both addresses are always 64-bit aligned.
  //
  // Arguments:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  void generate_conjoint_long_copy_core(bool aligned) {
    // Do reverse copy.
    Label L_copy_8_bytes, L_copy_16_bytes, L_exit;
    const Register from    = O0;  // source array address
    const Register to      = O1;  // destination array address
    const Register count   = O2;  // elements count
    const Register offset8 = O4;  // element offset
    const Register offset0 = O5;  // previous element offset

      __ subcc(count, 1, count);
      __ brx(Assembler::lessEqual, false, Assembler::pn, L_copy_8_bytes );
      __ delayed()->sllx(count, LogBytesPerLong, offset8);
      __ sub(offset8, 8, offset0);
      __ align(OptoLoopAlignment);
    __ BIND(L_copy_16_bytes);
      __ ldx(from, offset8, O2);
      __ ldx(from, offset0, O3);
      __ stx(O2, to, offset8);
      __ deccc(offset8, 16);      // use offset8 as counter
      __ stx(O3, to, offset0);
      __ brx(Assembler::greater, false, Assembler::pt, L_copy_16_bytes);
      __ delayed()->dec(offset0, 16);

    __ BIND(L_copy_8_bytes);
      __ brx(Assembler::negative, false, Assembler::pn, L_exit );
      __ delayed()->nop();
      __ ldx(from, 0, O3);
      __ stx(O3, to, 0);
    __ BIND(L_exit);
  }

  //  Generate stub for conjoint long copy.
  //  "aligned" is ignored, because we must make the stronger
  //  assumption that both addresses are always 64-bit aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_conjoint_long_copy(bool aligned, address nooverlap_target,
                                      address *entry, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    assert(aligned, "Should always be aligned");

    assert_clean_int(O2, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, 3);

    generate_conjoint_long_copy_core(aligned);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_jlong_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //  Generate stub for disjoint oop copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_disjoint_oop_copy(bool aligned, address *entry, const char *name,
                                     bool dest_uninitialized = false) {

    const Register from  = O0;  // source array address
    const Register to    = O1;  // destination array address
    const Register count = O2;  // elements count

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here
      BLOCK_COMMENT("Entry:");
    }

    DecoratorSet decorators = IN_HEAP | IS_ARRAY | ARRAYCOPY_DISJOINT;
    if (dest_uninitialized) {
      decorators |= IS_DEST_UNINITIALIZED;
    }
    if (aligned) {
      decorators |= ARRAYCOPY_ALIGNED;
    }

    BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
    bs->arraycopy_prologue(_masm, decorators, T_OBJECT, from, to, count);

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.
    if (UseCompressedOops) {
      generate_disjoint_int_copy_core(aligned);
    } else {
      generate_disjoint_long_copy_core(aligned);
    }

    bs->arraycopy_epilogue(_masm, decorators, T_OBJECT, from, to, count);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_oop_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }

  //  Generate stub for conjoint oop copy.  If "aligned" is true, the
  //  "from" and "to" addresses are assumed to be heapword aligned.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //
  address generate_conjoint_oop_copy(bool aligned, address nooverlap_target,
                                     address *entry, const char *name,
                                     bool dest_uninitialized = false) {

    const Register from  = O0;  // source array address
    const Register to    = O1;  // destination array address
    const Register count = O2;  // elements count

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    assert_clean_int(count, O3);     // Make sure 'count' is clean int.

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, LogBytesPerHeapOop);

    DecoratorSet decorators = IN_HEAP | IS_ARRAY;
    if (dest_uninitialized) {
      decorators |= IS_DEST_UNINITIALIZED;
    }
    if (aligned) {
      decorators |= ARRAYCOPY_ALIGNED;
    }

    BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
    bs->arraycopy_prologue(_masm, decorators, T_OBJECT, from, to, count);

    if (UseCompressedOops) {
      generate_conjoint_int_copy_core(aligned);
    } else {
      generate_conjoint_long_copy_core(aligned);
    }

    bs->arraycopy_epilogue(_masm, decorators, T_OBJECT, from, to, count);

    // O3, O4 are used as temp registers
    inc_counter_np(SharedRuntime::_oop_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->mov(G0, O0); // return 0
    return start;
  }


  // Helper for generating a dynamic type check.
  // Smashes only the given temp registers.
  void generate_type_check(Register sub_klass,
                           Register super_check_offset,
                           Register super_klass,
                           Register temp,
                           Label& L_success) {
    assert_different_registers(sub_klass, super_check_offset, super_klass, temp);

    BLOCK_COMMENT("type_check:");

    Label L_miss, L_pop_to_miss;

    assert_clean_int(super_check_offset, temp);

    __ check_klass_subtype_fast_path(sub_klass, super_klass, temp, noreg,
                                     &L_success, &L_miss, NULL,
                                     super_check_offset);

    BLOCK_COMMENT("type_check_slow_path:");
    __ save_frame(0);
    __ check_klass_subtype_slow_path(sub_klass->after_save(),
                                     super_klass->after_save(),
                                     L0, L1, L2, L4,
                                     NULL, &L_pop_to_miss);
    __ ba(L_success);
    __ delayed()->restore();

    __ bind(L_pop_to_miss);
    __ restore();

    // Fall through on failure!
    __ BIND(L_miss);
  }


  //  Generate stub for checked oop copy.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 treated as signed
  //      ckoff: O3 (super_check_offset)
  //      ckval: O4 (super_klass)
  //      ret:   O0 zero for success; (-1^K) where K is partial transfer count
  //
  address generate_checkcast_copy(const char *name, address *entry, bool dest_uninitialized = false) {

    const Register O0_from   = O0;      // source array address
    const Register O1_to     = O1;      // destination array address
    const Register O2_count  = O2;      // elements count
    const Register O3_ckoff  = O3;      // super_check_offset
    const Register O4_ckval  = O4;      // super_klass

    const Register O5_offset = O5;      // loop var, with stride wordSize
    const Register G1_remain = G1;      // loop var, with stride -1
    const Register G3_oop    = G3;      // actual oop copied
    const Register G4_klass  = G4;      // oop._klass
    const Register G5_super  = G5;      // oop._klass._primary_supers[ckval]

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

#ifdef ASSERT
    // We sometimes save a frame (see generate_type_check below).
    // If this will cause trouble, let's fail now instead of later.
    __ save_frame(0);
    __ restore();
#endif

    assert_clean_int(O2_count, G1);     // Make sure 'count' is clean int.

#ifdef ASSERT
    // caller guarantees that the arrays really are different
    // otherwise, we would have to make conjoint checks
    { Label L;
      __ mov(O3, G1);           // spill: overlap test smashes O3
      __ mov(O4, G4);           // spill: overlap test smashes O4
      array_overlap_test(L, LogBytesPerHeapOop);
      __ stop("checkcast_copy within a single array");
      __ bind(L);
      __ mov(G1, O3);
      __ mov(G4, O4);
    }
#endif //ASSERT

    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from generic stub)
      BLOCK_COMMENT("Entry:");
    }

    DecoratorSet decorators = IN_HEAP | IS_ARRAY | ARRAYCOPY_CHECKCAST;
    if (dest_uninitialized) {
      decorators |= IS_DEST_UNINITIALIZED;
    }

    BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
    bs->arraycopy_prologue(_masm, decorators, T_OBJECT, O0_from, O1_to, O2_count);

    Label load_element, store_element, do_epilogue, fail, done;
    __ addcc(O2_count, 0, G1_remain);   // initialize loop index, and test it
    __ brx(Assembler::notZero, false, Assembler::pt, load_element);
    __ delayed()->mov(G0, O5_offset);   // offset from start of arrays

    // Empty array:  Nothing to do.
    inc_counter_np(SharedRuntime::_checkcast_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->set(0, O0);           // return 0 on (trivial) success

    // ======== begin loop ========
    // (Loop is rotated; its entry is load_element.)
    // Loop variables:
    //   (O5 = 0; ; O5 += wordSize) --- offset from src, dest arrays
    //   (O2 = len; O2 != 0; O2--) --- number of oops *remaining*
    //   G3, G4, G5 --- current oop, oop.klass, oop.klass.super
    __ align(OptoLoopAlignment);

    __ BIND(store_element);
    __ deccc(G1_remain);                // decrement the count
    __ store_heap_oop(G3_oop, O1_to, O5_offset, noreg, AS_RAW); // store the oop
    __ inc(O5_offset, heapOopSize);     // step to next offset
    __ brx(Assembler::zero, true, Assembler::pt, do_epilogue);
    __ delayed()->set(0, O0);           // return -1 on success

    // ======== loop entry is here ========
    __ BIND(load_element);
    __ load_heap_oop(O0_from, O5_offset, G3_oop, noreg, AS_RAW);  // load the oop
    __ br_null_short(G3_oop, Assembler::pt, store_element);

    __ load_klass(G3_oop, G4_klass); // query the object klass

    generate_type_check(G4_klass, O3_ckoff, O4_ckval, G5_super,
                        // branch to this on success:
                        store_element);
    // ======== end loop ========

    // It was a real error; we must depend on the caller to finish the job.
    // Register G1 has number of *remaining* oops, O2 number of *total* oops.
    // Emit GC store barriers for the oops we have copied (O2 minus G1),
    // and report their number to the caller.
    __ BIND(fail);
    __ subcc(O2_count, G1_remain, O2_count);
    __ brx(Assembler::zero, false, Assembler::pt, done);
    __ delayed()->not1(O2_count, O0);   // report (-1^K) to caller

    __ BIND(do_epilogue);
    bs->arraycopy_epilogue(_masm, decorators, T_OBJECT, O0_from, O1_to, O2_count);

    __ BIND(done);
    inc_counter_np(SharedRuntime::_checkcast_array_copy_ctr, O3, O4);
    __ retl();
    __ delayed()->nop();             // return value in 00

    return start;
  }


  //  Generate 'unsafe' array copy stub
  //  Though just as safe as the other stubs, it takes an unscaled
  //  size_t argument instead of an element count.
  //
  // Arguments for generated stub:
  //      from:  O0
  //      to:    O1
  //      count: O2 byte count, treated as ssize_t, can be zero
  //
  // Examines the alignment of the operands and dispatches
  // to a long, int, short, or byte copy loop.
  //
  address generate_unsafe_copy(const char* name,
                               address byte_copy_entry,
                               address short_copy_entry,
                               address int_copy_entry,
                               address long_copy_entry) {

    const Register O0_from   = O0;      // source array address
    const Register O1_to     = O1;      // destination array address
    const Register O2_count  = O2;      // elements count

    const Register G1_bits   = G1;      // test copy of low bits

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    // bump this on entry, not on exit:
    inc_counter_np(SharedRuntime::_unsafe_array_copy_ctr, G1, G3);

    __ or3(O0_from, O1_to, G1_bits);
    __ or3(O2_count,       G1_bits, G1_bits);

    __ btst(BytesPerLong-1, G1_bits);
    __ br(Assembler::zero, true, Assembler::pt,
          long_copy_entry, relocInfo::runtime_call_type);
    // scale the count on the way out:
    __ delayed()->srax(O2_count, LogBytesPerLong, O2_count);

    __ btst(BytesPerInt-1, G1_bits);
    __ br(Assembler::zero, true, Assembler::pt,
          int_copy_entry, relocInfo::runtime_call_type);
    // scale the count on the way out:
    __ delayed()->srax(O2_count, LogBytesPerInt, O2_count);

    __ btst(BytesPerShort-1, G1_bits);
    __ br(Assembler::zero, true, Assembler::pt,
          short_copy_entry, relocInfo::runtime_call_type);
    // scale the count on the way out:
    __ delayed()->srax(O2_count, LogBytesPerShort, O2_count);

    __ br(Assembler::always, false, Assembler::pt,
          byte_copy_entry, relocInfo::runtime_call_type);
    __ delayed()->nop();

    return start;
  }


  // Perform range checks on the proposed arraycopy.
  // Kills the two temps, but nothing else.
  // Also, clean the sign bits of src_pos and dst_pos.
  void arraycopy_range_checks(Register src,     // source array oop (O0)
                              Register src_pos, // source position (O1)
                              Register dst,     // destination array oo (O2)
                              Register dst_pos, // destination position (O3)
                              Register length,  // length of copy (O4)
                              Register temp1, Register temp2,
                              Label& L_failed) {
    BLOCK_COMMENT("arraycopy_range_checks:");

    //  if (src_pos + length > arrayOop(src)->length() ) FAIL;

    const Register array_length = temp1;  // scratch
    const Register end_pos      = temp2;  // scratch

    // Note:  This next instruction may be in the delay slot of a branch:
    __ add(length, src_pos, end_pos);  // src_pos + length
    __ lduw(src, arrayOopDesc::length_offset_in_bytes(), array_length);
    __ cmp(end_pos, array_length);
    __ br(Assembler::greater, false, Assembler::pn, L_failed);

    //  if (dst_pos + length > arrayOop(dst)->length() ) FAIL;
    __ delayed()->add(length, dst_pos, end_pos); // dst_pos + length
    __ lduw(dst, arrayOopDesc::length_offset_in_bytes(), array_length);
    __ cmp(end_pos, array_length);
    __ br(Assembler::greater, false, Assembler::pn, L_failed);

    // Have to clean up high 32-bits of 'src_pos' and 'dst_pos'.
    // Move with sign extension can be used since they are positive.
    __ delayed()->signx(src_pos, src_pos);
    __ signx(dst_pos, dst_pos);

    BLOCK_COMMENT("arraycopy_range_checks done");
  }


  //
  //  Generate generic array copy stubs
  //
  //  Input:
  //    O0    -  src oop
  //    O1    -  src_pos
  //    O2    -  dst oop
  //    O3    -  dst_pos
  //    O4    -  element count
  //
  //  Output:
  //    O0 ==  0  -  success
  //    O0 == -1  -  need to call System.arraycopy
  //
  address generate_generic_copy(const char *name,
                                address entry_jbyte_arraycopy,
                                address entry_jshort_arraycopy,
                                address entry_jint_arraycopy,
                                address entry_oop_arraycopy,
                                address entry_jlong_arraycopy,
                                address entry_checkcast_arraycopy) {
    Label L_failed, L_objArray;

    // Input registers
    const Register src      = O0;  // source array oop
    const Register src_pos  = O1;  // source position
    const Register dst      = O2;  // destination array oop
    const Register dst_pos  = O3;  // destination position
    const Register length   = O4;  // elements count

    // registers used as temp
    const Register G3_src_klass = G3; // source array klass
    const Register G4_dst_klass = G4; // destination array klass
    const Register G5_lh        = G5; // layout handler
    const Register O5_temp      = O5;

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    // bump this on entry, not on exit:
    inc_counter_np(SharedRuntime::_generic_array_copy_ctr, G1, G3);

    // In principle, the int arguments could be dirty.
    //assert_clean_int(src_pos, G1);
    //assert_clean_int(dst_pos, G1);
    //assert_clean_int(length, G1);

    //-----------------------------------------------------------------------
    // Assembler stubs will be used for this call to arraycopy
    // if the following conditions are met:
    //
    // (1) src and dst must not be null.
    // (2) src_pos must not be negative.
    // (3) dst_pos must not be negative.
    // (4) length  must not be negative.
    // (5) src klass and dst klass should be the same and not NULL.
    // (6) src and dst should be arrays.
    // (7) src_pos + length must not exceed length of src.
    // (8) dst_pos + length must not exceed length of dst.
    BLOCK_COMMENT("arraycopy initial argument checks");

    //  if (src == NULL) return -1;
    __ br_null(src, false, Assembler::pn, L_failed);

    //  if (src_pos < 0) return -1;
    __ delayed()->tst(src_pos);
    __ br(Assembler::negative, false, Assembler::pn, L_failed);
    __ delayed()->nop();

    //  if (dst == NULL) return -1;
    __ br_null(dst, false, Assembler::pn, L_failed);

    //  if (dst_pos < 0) return -1;
    __ delayed()->tst(dst_pos);
    __ br(Assembler::negative, false, Assembler::pn, L_failed);

    //  if (length < 0) return -1;
    __ delayed()->tst(length);
    __ br(Assembler::negative, false, Assembler::pn, L_failed);

    BLOCK_COMMENT("arraycopy argument klass checks");
    //  get src->klass()
    if (UseCompressedClassPointers) {
      __ delayed()->nop(); // ??? not good
      __ load_klass(src, G3_src_klass);
    } else {
      __ delayed()->ld_ptr(src, oopDesc::klass_offset_in_bytes(), G3_src_klass);
    }

#ifdef ASSERT
    //  assert(src->klass() != NULL);
    BLOCK_COMMENT("assert klasses not null");
    { Label L_a, L_b;
      __ br_notnull_short(G3_src_klass, Assembler::pt, L_b); // it is broken if klass is NULL
      __ bind(L_a);
      __ stop("broken null klass");
      __ bind(L_b);
      __ load_klass(dst, G4_dst_klass);
      __ br_null(G4_dst_klass, false, Assembler::pn, L_a); // this would be broken also
      __ delayed()->mov(G0, G4_dst_klass);      // scribble the temp
      BLOCK_COMMENT("assert done");
    }
#endif

    // Load layout helper
    //
    //  |array_tag|     | header_size | element_type |     |log2_element_size|
    // 32        30    24            16              8     2                 0
    //
    //   array_tag: typeArray = 0x3, objArray = 0x2, non-array = 0x0
    //

    int lh_offset = in_bytes(Klass::layout_helper_offset());

    // Load 32-bits signed value. Use br() instruction with it to check icc.
    __ lduw(G3_src_klass, lh_offset, G5_lh);

    if (UseCompressedClassPointers) {
      __ load_klass(dst, G4_dst_klass);
    }
    // Handle objArrays completely differently...
    juint objArray_lh = Klass::array_layout_helper(T_OBJECT);
    __ set(objArray_lh, O5_temp);
    __ cmp(G5_lh,       O5_temp);
    __ br(Assembler::equal, false, Assembler::pt, L_objArray);
    if (UseCompressedClassPointers) {
      __ delayed()->nop();
    } else {
      __ delayed()->ld_ptr(dst, oopDesc::klass_offset_in_bytes(), G4_dst_klass);
    }

    //  if (src->klass() != dst->klass()) return -1;
    __ cmp_and_brx_short(G3_src_klass, G4_dst_klass, Assembler::notEqual, Assembler::pn, L_failed);

    //  if (!src->is_Array()) return -1;
    __ cmp(G5_lh, Klass::_lh_neutral_value); // < 0
    __ br(Assembler::greaterEqual, false, Assembler::pn, L_failed);

    // At this point, it is known to be a typeArray (array_tag 0x3).
#ifdef ASSERT
    __ delayed()->nop();
    { Label L;
      jint lh_prim_tag_in_place = (Klass::_lh_array_tag_type_value << Klass::_lh_array_tag_shift);
      __ set(lh_prim_tag_in_place, O5_temp);
      __ cmp(G5_lh,                O5_temp);
      __ br(Assembler::greaterEqual, false, Assembler::pt, L);
      __ delayed()->nop();
      __ stop("must be a primitive array");
      __ bind(L);
    }
#else
    __ delayed();                               // match next insn to prev branch
#endif

    arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
                           O5_temp, G4_dst_klass, L_failed);

    // TypeArrayKlass
    //
    // src_addr = (src + array_header_in_bytes()) + (src_pos << log2elemsize);
    // dst_addr = (dst + array_header_in_bytes()) + (dst_pos << log2elemsize);
    //

    const Register G4_offset = G4_dst_klass;    // array offset
    const Register G3_elsize = G3_src_klass;    // log2 element size

    __ srl(G5_lh, Klass::_lh_header_size_shift, G4_offset);
    __ and3(G4_offset, Klass::_lh_header_size_mask, G4_offset); // array_offset
    __ add(src, G4_offset, src);       // src array offset
    __ add(dst, G4_offset, dst);       // dst array offset
    __ and3(G5_lh, Klass::_lh_log2_element_size_mask, G3_elsize); // log2 element size

    // next registers should be set before the jump to corresponding stub
    const Register from     = O0;  // source array address
    const Register to       = O1;  // destination array address
    const Register count    = O2;  // elements count

    // 'from', 'to', 'count' registers should be set in this order
    // since they are the same as 'src', 'src_pos', 'dst'.

    BLOCK_COMMENT("scale indexes to element size");
    __ sll_ptr(src_pos, G3_elsize, src_pos);
    __ sll_ptr(dst_pos, G3_elsize, dst_pos);
    __ add(src, src_pos, from);       // src_addr
    __ add(dst, dst_pos, to);         // dst_addr

    BLOCK_COMMENT("choose copy loop based on element size");
    __ cmp(G3_elsize, 0);
    __ br(Assembler::equal, true, Assembler::pt, entry_jbyte_arraycopy);
    __ delayed()->signx(length, count); // length

    __ cmp(G3_elsize, LogBytesPerShort);
    __ br(Assembler::equal, true, Assembler::pt, entry_jshort_arraycopy);
    __ delayed()->signx(length, count); // length

    __ cmp(G3_elsize, LogBytesPerInt);
    __ br(Assembler::equal, true, Assembler::pt, entry_jint_arraycopy);
    __ delayed()->signx(length, count); // length
#ifdef ASSERT
    { Label L;
      __ cmp_and_br_short(G3_elsize, LogBytesPerLong, Assembler::equal, Assembler::pt, L);
      __ stop("must be long copy, but elsize is wrong");
      __ bind(L);
    }
#endif
    __ br(Assembler::always, false, Assembler::pt, entry_jlong_arraycopy);
    __ delayed()->signx(length, count); // length

    // ObjArrayKlass
  __ BIND(L_objArray);
    // live at this point:  G3_src_klass, G4_dst_klass, src[_pos], dst[_pos], length

    Label L_plain_copy, L_checkcast_copy;
    //  test array classes for subtyping
    __ cmp(G3_src_klass, G4_dst_klass);         // usual case is exact equality
    __ brx(Assembler::notEqual, true, Assembler::pn, L_checkcast_copy);
    __ delayed()->lduw(G4_dst_klass, lh_offset, O5_temp); // hoisted from below

    // Identically typed arrays can be copied without element-wise checks.
    arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
                           O5_temp, G5_lh, L_failed);

    __ add(src, arrayOopDesc::base_offset_in_bytes(T_OBJECT), src); //src offset
    __ add(dst, arrayOopDesc::base_offset_in_bytes(T_OBJECT), dst); //dst offset
    __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
    __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
    __ add(src, src_pos, from);       // src_addr
    __ add(dst, dst_pos, to);         // dst_addr
  __ BIND(L_plain_copy);
    __ br(Assembler::always, false, Assembler::pt, entry_oop_arraycopy);
    __ delayed()->signx(length, count); // length

  __ BIND(L_checkcast_copy);
    // live at this point:  G3_src_klass, G4_dst_klass
    {
      // Before looking at dst.length, make sure dst is also an objArray.
      // lduw(G4_dst_klass, lh_offset, O5_temp); // hoisted to delay slot
      __ cmp(G5_lh,                    O5_temp);
      __ br(Assembler::notEqual, false, Assembler::pn, L_failed);

      // It is safe to examine both src.length and dst.length.
      __ delayed();                             // match next insn to prev branch
      arraycopy_range_checks(src, src_pos, dst, dst_pos, length,
                             O5_temp, G5_lh, L_failed);

      // Marshal the base address arguments now, freeing registers.
      __ add(src, arrayOopDesc::base_offset_in_bytes(T_OBJECT), src); //src offset
      __ add(dst, arrayOopDesc::base_offset_in_bytes(T_OBJECT), dst); //dst offset
      __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
      __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
      __ add(src, src_pos, from);               // src_addr
      __ add(dst, dst_pos, to);                 // dst_addr
      __ signx(length, count);                  // length (reloaded)

      Register sco_temp = O3;                   // this register is free now
      assert_different_registers(from, to, count, sco_temp,
                                 G4_dst_klass, G3_src_klass);

      // Generate the type check.
      int sco_offset = in_bytes(Klass::super_check_offset_offset());
      __ lduw(G4_dst_klass, sco_offset, sco_temp);
      generate_type_check(G3_src_klass, sco_temp, G4_dst_klass,
                          O5_temp, L_plain_copy);

      // Fetch destination element klass from the ObjArrayKlass header.
      int ek_offset = in_bytes(ObjArrayKlass::element_klass_offset());

      // the checkcast_copy loop needs two extra arguments:
      __ ld_ptr(G4_dst_klass, ek_offset, O4);   // dest elem klass
      // lduw(O4, sco_offset, O3);              // sco of elem klass

      __ br(Assembler::always, false, Assembler::pt, entry_checkcast_arraycopy);
      __ delayed()->lduw(O4, sco_offset, O3);
    }

  __ BIND(L_failed);
    __ retl();
    __ delayed()->sub(G0, 1, O0); // return -1
    return start;
  }

  //
  //  Generate stub for heap zeroing.
  //  "to" address is aligned to jlong (8 bytes).
  //
  // Arguments for generated stub:
  //      to:    O0
  //      count: O1 treated as signed (count of HeapWord)
  //             count could be 0
  //
  address generate_zero_aligned_words(const char* name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    const Register to    = O0;   // source array address
    const Register count = O1;   // HeapWords count
    const Register temp  = O2;   // scratch

    Label Ldone;
    __ sllx(count, LogHeapWordSize, count); // to bytes count
    // Use BIS for zeroing
    __ bis_zeroing(to, count, temp, Ldone);
    __ bind(Ldone);
    __ retl();
    __ delayed()->nop();
    return start;
}

  void generate_arraycopy_stubs() {
    address entry;
    address entry_jbyte_arraycopy;
    address entry_jshort_arraycopy;
    address entry_jint_arraycopy;
    address entry_oop_arraycopy;
    address entry_jlong_arraycopy;
    address entry_checkcast_arraycopy;

    //*** jbyte
    // Always need aligned and unaligned versions
    StubRoutines::_jbyte_disjoint_arraycopy         = generate_disjoint_byte_copy(false, &entry,
                                                                                  "jbyte_disjoint_arraycopy");
    StubRoutines::_jbyte_arraycopy                  = generate_conjoint_byte_copy(false, entry,
                                                                                  &entry_jbyte_arraycopy,
                                                                                  "jbyte_arraycopy");
    StubRoutines::_arrayof_jbyte_disjoint_arraycopy = generate_disjoint_byte_copy(true, &entry,
                                                                                  "arrayof_jbyte_disjoint_arraycopy");
    StubRoutines::_arrayof_jbyte_arraycopy          = generate_conjoint_byte_copy(true, entry, NULL,
                                                                                  "arrayof_jbyte_arraycopy");

    //*** jshort
    // Always need aligned and unaligned versions
    StubRoutines::_jshort_disjoint_arraycopy         = generate_disjoint_short_copy(false, &entry,
                                                                                    "jshort_disjoint_arraycopy");
    StubRoutines::_jshort_arraycopy                  = generate_conjoint_short_copy(false, entry,
                                                                                    &entry_jshort_arraycopy,
                                                                                    "jshort_arraycopy");
    StubRoutines::_arrayof_jshort_disjoint_arraycopy = generate_disjoint_short_copy(true, &entry,
                                                                                    "arrayof_jshort_disjoint_arraycopy");
    StubRoutines::_arrayof_jshort_arraycopy          = generate_conjoint_short_copy(true, entry, NULL,
                                                                                    "arrayof_jshort_arraycopy");

    //*** jint
    // Aligned versions
    StubRoutines::_arrayof_jint_disjoint_arraycopy = generate_disjoint_int_copy(true, &entry,
                                                                                "arrayof_jint_disjoint_arraycopy");
    StubRoutines::_arrayof_jint_arraycopy          = generate_conjoint_int_copy(true, entry, &entry_jint_arraycopy,
                                                                                "arrayof_jint_arraycopy");
    // In 64 bit we need both aligned and unaligned versions of jint arraycopy.
    // entry_jint_arraycopy always points to the unaligned version (notice that we overwrite it).
    StubRoutines::_jint_disjoint_arraycopy         = generate_disjoint_int_copy(false, &entry,
                                                                                "jint_disjoint_arraycopy");
    StubRoutines::_jint_arraycopy                  = generate_conjoint_int_copy(false, entry,
                                                                                &entry_jint_arraycopy,
                                                                                "jint_arraycopy");

    //*** jlong
    // It is always aligned
    StubRoutines::_arrayof_jlong_disjoint_arraycopy = generate_disjoint_long_copy(true, &entry,
                                                                                  "arrayof_jlong_disjoint_arraycopy");
    StubRoutines::_arrayof_jlong_arraycopy          = generate_conjoint_long_copy(true, entry, &entry_jlong_arraycopy,
                                                                                  "arrayof_jlong_arraycopy");
    StubRoutines::_jlong_disjoint_arraycopy         = StubRoutines::_arrayof_jlong_disjoint_arraycopy;
    StubRoutines::_jlong_arraycopy                  = StubRoutines::_arrayof_jlong_arraycopy;


    //*** oops
    // Aligned versions
    StubRoutines::_arrayof_oop_disjoint_arraycopy        = generate_disjoint_oop_copy(true, &entry,
                                                                                      "arrayof_oop_disjoint_arraycopy");
    StubRoutines::_arrayof_oop_arraycopy                 = generate_conjoint_oop_copy(true, entry, &entry_oop_arraycopy,
                                                                                      "arrayof_oop_arraycopy");
    // Aligned versions without pre-barriers
    StubRoutines::_arrayof_oop_disjoint_arraycopy_uninit = generate_disjoint_oop_copy(true, &entry,
                                                                                      "arrayof_oop_disjoint_arraycopy_uninit",
                                                                                      /*dest_uninitialized*/true);
    StubRoutines::_arrayof_oop_arraycopy_uninit          = generate_conjoint_oop_copy(true, entry, NULL,
                                                                                      "arrayof_oop_arraycopy_uninit",
                                                                                      /*dest_uninitialized*/true);
    if (UseCompressedOops) {
      // With compressed oops we need unaligned versions, notice that we overwrite entry_oop_arraycopy.
      StubRoutines::_oop_disjoint_arraycopy            = generate_disjoint_oop_copy(false, &entry,
                                                                                    "oop_disjoint_arraycopy");
      StubRoutines::_oop_arraycopy                     = generate_conjoint_oop_copy(false, entry, &entry_oop_arraycopy,
                                                                                    "oop_arraycopy");
      // Unaligned versions without pre-barriers
      StubRoutines::_oop_disjoint_arraycopy_uninit     = generate_disjoint_oop_copy(false, &entry,
                                                                                    "oop_disjoint_arraycopy_uninit",
                                                                                    /*dest_uninitialized*/true);
      StubRoutines::_oop_arraycopy_uninit              = generate_conjoint_oop_copy(false, entry, NULL,
                                                                                    "oop_arraycopy_uninit",
                                                                                    /*dest_uninitialized*/true);
    } else {
      // oop arraycopy is always aligned on 32bit and 64bit without compressed oops
      StubRoutines::_oop_disjoint_arraycopy            = StubRoutines::_arrayof_oop_disjoint_arraycopy;
      StubRoutines::_oop_arraycopy                     = StubRoutines::_arrayof_oop_arraycopy;
      StubRoutines::_oop_disjoint_arraycopy_uninit     = StubRoutines::_arrayof_oop_disjoint_arraycopy_uninit;
      StubRoutines::_oop_arraycopy_uninit              = StubRoutines::_arrayof_oop_arraycopy_uninit;
    }

    StubRoutines::_checkcast_arraycopy        = generate_checkcast_copy("checkcast_arraycopy", &entry_checkcast_arraycopy);
    StubRoutines::_checkcast_arraycopy_uninit = generate_checkcast_copy("checkcast_arraycopy_uninit", NULL,
                                                                        /*dest_uninitialized*/true);

    StubRoutines::_unsafe_arraycopy    = generate_unsafe_copy("unsafe_arraycopy",
                                                              entry_jbyte_arraycopy,
                                                              entry_jshort_arraycopy,
                                                              entry_jint_arraycopy,
                                                              entry_jlong_arraycopy);
    StubRoutines::_generic_arraycopy   = generate_generic_copy("generic_arraycopy",
                                                               entry_jbyte_arraycopy,
                                                               entry_jshort_arraycopy,
                                                               entry_jint_arraycopy,
                                                               entry_oop_arraycopy,
                                                               entry_jlong_arraycopy,
                                                               entry_checkcast_arraycopy);

    StubRoutines::_jbyte_fill = generate_fill(T_BYTE, false, "jbyte_fill");
    StubRoutines::_jshort_fill = generate_fill(T_SHORT, false, "jshort_fill");
    StubRoutines::_jint_fill = generate_fill(T_INT, false, "jint_fill");
    StubRoutines::_arrayof_jbyte_fill = generate_fill(T_BYTE, true, "arrayof_jbyte_fill");
    StubRoutines::_arrayof_jshort_fill = generate_fill(T_SHORT, true, "arrayof_jshort_fill");
    StubRoutines::_arrayof_jint_fill = generate_fill(T_INT, true, "arrayof_jint_fill");

    if (UseBlockZeroing) {
      StubRoutines::_zero_aligned_words = generate_zero_aligned_words("zero_aligned_words");
    }
  }

  address generate_aescrypt_encryptBlock() {
    // required since we read expanded key 'int' array starting first element without alignment considerations
    assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
           "the following code assumes that first element of an int array is aligned to 8 bytes");
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "aescrypt_encryptBlock");
    Label L_load_misaligned_input, L_load_expanded_key, L_doLast128bit, L_storeOutput, L_store_misaligned_output;
    address start = __ pc();
    Register from = O0; // source byte array
    Register to = O1;   // destination byte array
    Register key = O2;  // expanded key array
    const Register keylen = O4; //reg for storing expanded key array length

    // read expanded key length
    __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);

    // Method to address arbitrary alignment for load instructions:
    // Check last 3 bits of 'from' address to see if it is aligned to 8-byte boundary
    // If zero/aligned then continue with double FP load instructions
    // If not zero/mis-aligned then alignaddr will set GSR.align with number of bytes to skip during faligndata
    // alignaddr will also convert arbitrary aligned 'from' address to nearest 8-byte aligned address
    // load 3 * 8-byte components (to read 16 bytes input) in 3 different FP regs starting at this aligned address
    // faligndata will then extract (based on GSR.align value) the appropriate 8 bytes from the 2 source regs

    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input);
    __ delayed()->alignaddr(from, G0, from);

    // aligned case: load input into F54-F56
    __ ldf(FloatRegisterImpl::D, from, 0, F54);
    __ ldf(FloatRegisterImpl::D, from, 8, F56);
    __ ba_short(L_load_expanded_key);

    __ BIND(L_load_misaligned_input);
    __ ldf(FloatRegisterImpl::D, from, 0, F54);
    __ ldf(FloatRegisterImpl::D, from, 8, F56);
    __ ldf(FloatRegisterImpl::D, from, 16, F58);
    __ faligndata(F54, F56, F54);
    __ faligndata(F56, F58, F56);

    __ BIND(L_load_expanded_key);
    // Since we load expanded key buffers starting first element, 8-byte alignment is guaranteed
    for ( int i = 0;  i <= 38; i += 2 ) {
      __ ldf(FloatRegisterImpl::D, key, i*4, as_FloatRegister(i));
    }

    // perform cipher transformation
    __ fxor(FloatRegisterImpl::D, F0, F54, F54);
    __ fxor(FloatRegisterImpl::D, F2, F56, F56);
    // rounds 1 through 8
    for ( int i = 4;  i <= 28; i += 8 ) {
      __ aes_eround01(as_FloatRegister(i), F54, F56, F58);
      __ aes_eround23(as_FloatRegister(i+2), F54, F56, F60);
      __ aes_eround01(as_FloatRegister(i+4), F58, F60, F54);
      __ aes_eround23(as_FloatRegister(i+6), F58, F60, F56);
    }
    __ aes_eround01(F36, F54, F56, F58); //round 9
    __ aes_eround23(F38, F54, F56, F60);

    // 128-bit original key size
    __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pt, L_doLast128bit);

    for ( int i = 40;  i <= 50; i += 2 ) {
      __ ldf(FloatRegisterImpl::D, key, i*4, as_FloatRegister(i) );
    }
    __ aes_eround01(F40, F58, F60, F54); //round 10
    __ aes_eround23(F42, F58, F60, F56);
    __ aes_eround01(F44, F54, F56, F58); //round 11
    __ aes_eround23(F46, F54, F56, F60);

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pt, L_storeOutput);

    __ ldf(FloatRegisterImpl::D, key, 208, F52);
    __ aes_eround01(F48, F58, F60, F54); //round 12
    __ aes_eround23(F50, F58, F60, F56);
    __ ldf(FloatRegisterImpl::D, key, 216, F46);
    __ ldf(FloatRegisterImpl::D, key, 224, F48);
    __ ldf(FloatRegisterImpl::D, key, 232, F50);
    __ aes_eround01(F52, F54, F56, F58); //round 13
    __ aes_eround23(F46, F54, F56, F60);
    __ ba_short(L_storeOutput);

    __ BIND(L_doLast128bit);
    __ ldf(FloatRegisterImpl::D, key, 160, F48);
    __ ldf(FloatRegisterImpl::D, key, 168, F50);

    __ BIND(L_storeOutput);
    // perform last round of encryption common for all key sizes
    __ aes_eround01_l(F48, F58, F60, F54); //last round
    __ aes_eround23_l(F50, F58, F60, F56);

    // Method to address arbitrary alignment for store instructions:
    // Check last 3 bits of 'dest' address to see if it is aligned to 8-byte boundary
    // If zero/aligned then continue with double FP store instructions
    // If not zero/mis-aligned then edge8n will generate edge mask in result reg (O3 in below case)
    // Example: If dest address is 0x07 and nearest 8-byte aligned address is 0x00 then edge mask will be 00000001
    // Compute (8-n) where n is # of bytes skipped by partial store(stpartialf) inst from edge mask, n=7 in this case
    // We get the value of n from the andcc that checks 'dest' alignment. n is available in O5 in below case.
    // Set GSR.align to (8-n) using alignaddr
    // Circular byte shift store values by n places so that the original bytes are at correct position for stpartialf
    // Set the arbitrarily aligned 'dest' address to nearest 8-byte aligned address
    // Store (partial) the original first (8-n) bytes starting at the original 'dest' address
    // Negate the edge mask so that the subsequent stpartialf can store the original (8-n-1)th through 8th bytes at appropriate address
    // We need to execute this process for both the 8-byte result values

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, O5);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output);
    __ delayed()->edge8n(to, G0, O3);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F54, to, 0);
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::D, F56, to, 8);

    __ BIND(L_store_misaligned_output);
    __ add(to, 8, O4);
    __ mov(8, O2);
    __ sub(O2, O5, O2);
    __ alignaddr(O2, G0, O2);
    __ faligndata(F54, F54, F54);
    __ faligndata(F56, F56, F56);
    __ and3(to, -8, to);
    __ and3(O4, -8, O4);
    __ stpartialf(to, O3, F54, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(O4, O3, F56, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(O4, 8, O4);
    __ orn(G0, O3, O3);
    __ stpartialf(to, O3, F54, Assembler::ASI_PST8_PRIMARY);
    __ retl();
    __ delayed()->stpartialf(O4, O3, F56, Assembler::ASI_PST8_PRIMARY);

    return start;
  }

  address generate_aescrypt_decryptBlock() {
    assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
           "the following code assumes that first element of an int array is aligned to 8 bytes");
    // required since we read original key 'byte' array as well in the decryption stubs
    assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
           "the following code assumes that first element of a byte array is aligned to 8 bytes");
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "aescrypt_decryptBlock");
    address start = __ pc();
    Label L_load_misaligned_input, L_load_original_key, L_expand192bit, L_expand256bit, L_reload_misaligned_input;
    Label L_256bit_transform, L_common_transform, L_store_misaligned_output;
    Register from = O0; // source byte array
    Register to = O1;   // destination byte array
    Register key = O2;  // expanded key array
    Register original_key = O3;  // original key array only required during decryption
    const Register keylen = O4;  // reg for storing expanded key array length

    // read expanded key array length
    __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);

    // save 'from' since we may need to recheck alignment in case of 256-bit decryption
    __ mov(from, G1);

    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input);
    __ delayed()->alignaddr(from, G0, from);

    // aligned case: load input into F52-F54
    __ ldf(FloatRegisterImpl::D, from, 0, F52);
    __ ldf(FloatRegisterImpl::D, from, 8, F54);
    __ ba_short(L_load_original_key);

    __ BIND(L_load_misaligned_input);
    __ ldf(FloatRegisterImpl::D, from, 0, F52);
    __ ldf(FloatRegisterImpl::D, from, 8, F54);
    __ ldf(FloatRegisterImpl::D, from, 16, F56);
    __ faligndata(F52, F54, F52);
    __ faligndata(F54, F56, F54);

    __ BIND(L_load_original_key);
    // load original key from SunJCE expanded decryption key
    // Since we load original key buffer starting first element, 8-byte alignment is guaranteed
    for ( int i = 0;  i <= 3; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // 256-bit original key size
    __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_expand256bit);

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_expand192bit);

    // 128-bit original key size
    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 36; i += 4 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+2), i/4, as_FloatRegister(i+4));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+4), as_FloatRegister(i+6));
    }

    // perform 128-bit key specific inverse cipher transformation
    __ fxor(FloatRegisterImpl::D, F42, F54, F54);
    __ fxor(FloatRegisterImpl::D, F40, F52, F52);
    __ ba_short(L_common_transform);

    __ BIND(L_expand192bit);

    // start loading rest of the 192-bit key
    __ ldf(FloatRegisterImpl::S, original_key, 16, F4);
    __ ldf(FloatRegisterImpl::S, original_key, 20, F5);

    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 36; i += 6 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+4), i/6, as_FloatRegister(i+6));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+6), as_FloatRegister(i+8));
      __ aes_kexpand2(as_FloatRegister(i+4), as_FloatRegister(i+8), as_FloatRegister(i+10));
    }
    __ aes_kexpand1(F42, F46, 7, F48);
    __ aes_kexpand2(F44, F48, F50);

    // perform 192-bit key specific inverse cipher transformation
    __ fxor(FloatRegisterImpl::D, F50, F54, F54);
    __ fxor(FloatRegisterImpl::D, F48, F52, F52);
    __ aes_dround23(F46, F52, F54, F58);
    __ aes_dround01(F44, F52, F54, F56);
    __ aes_dround23(F42, F56, F58, F54);
    __ aes_dround01(F40, F56, F58, F52);
    __ ba_short(L_common_transform);

    __ BIND(L_expand256bit);

    // load rest of the 256-bit key
    for ( int i = 4;  i <= 7; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 40; i += 8 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+6), i/8, as_FloatRegister(i+8));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+8), as_FloatRegister(i+10));
      __ aes_kexpand0(as_FloatRegister(i+4), as_FloatRegister(i+10), as_FloatRegister(i+12));
      __ aes_kexpand2(as_FloatRegister(i+6), as_FloatRegister(i+12), as_FloatRegister(i+14));
    }
    __ aes_kexpand1(F48, F54, 6, F56);
    __ aes_kexpand2(F50, F56, F58);

    for ( int i = 0;  i <= 6; i += 2 ) {
      __ fsrc2(FloatRegisterImpl::D, as_FloatRegister(58-i), as_FloatRegister(i));
    }

    // reload original 'from' address
    __ mov(G1, from);

    // re-check 8-byte alignment
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_reload_misaligned_input);
    __ delayed()->alignaddr(from, G0, from);

    // aligned case: load input into F52-F54
    __ ldf(FloatRegisterImpl::D, from, 0, F52);
    __ ldf(FloatRegisterImpl::D, from, 8, F54);
    __ ba_short(L_256bit_transform);

    __ BIND(L_reload_misaligned_input);
    __ ldf(FloatRegisterImpl::D, from, 0, F52);
    __ ldf(FloatRegisterImpl::D, from, 8, F54);
    __ ldf(FloatRegisterImpl::D, from, 16, F56);
    __ faligndata(F52, F54, F52);
    __ faligndata(F54, F56, F54);

    // perform 256-bit key specific inverse cipher transformation
    __ BIND(L_256bit_transform);
    __ fxor(FloatRegisterImpl::D, F0, F54, F54);
    __ fxor(FloatRegisterImpl::D, F2, F52, F52);
    __ aes_dround23(F4, F52, F54, F58);
    __ aes_dround01(F6, F52, F54, F56);
    __ aes_dround23(F50, F56, F58, F54);
    __ aes_dround01(F48, F56, F58, F52);
    __ aes_dround23(F46, F52, F54, F58);
    __ aes_dround01(F44, F52, F54, F56);
    __ aes_dround23(F42, F56, F58, F54);
    __ aes_dround01(F40, F56, F58, F52);

    for ( int i = 0;  i <= 7; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // perform inverse cipher transformations common for all key sizes
    __ BIND(L_common_transform);
    for ( int i = 38;  i >= 6; i -= 8 ) {
      __ aes_dround23(as_FloatRegister(i), F52, F54, F58);
      __ aes_dround01(as_FloatRegister(i-2), F52, F54, F56);
      if ( i != 6) {
        __ aes_dround23(as_FloatRegister(i-4), F56, F58, F54);
        __ aes_dround01(as_FloatRegister(i-6), F56, F58, F52);
      } else {
        __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F54);
        __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F52);
      }
    }

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, O5);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output);
    __ delayed()->edge8n(to, G0, O3);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F52, to, 0);
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::D, F54, to, 8);

    __ BIND(L_store_misaligned_output);
    __ add(to, 8, O4);
    __ mov(8, O2);
    __ sub(O2, O5, O2);
    __ alignaddr(O2, G0, O2);
    __ faligndata(F52, F52, F52);
    __ faligndata(F54, F54, F54);
    __ and3(to, -8, to);
    __ and3(O4, -8, O4);
    __ stpartialf(to, O3, F52, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(O4, O3, F54, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(O4, 8, O4);
    __ orn(G0, O3, O3);
    __ stpartialf(to, O3, F52, Assembler::ASI_PST8_PRIMARY);
    __ retl();
    __ delayed()->stpartialf(O4, O3, F54, Assembler::ASI_PST8_PRIMARY);

    return start;
  }

  address generate_cipherBlockChaining_encryptAESCrypt() {
    assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
           "the following code assumes that first element of an int array is aligned to 8 bytes");
    assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
           "the following code assumes that first element of a byte array is aligned to 8 bytes");
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "cipherBlockChaining_encryptAESCrypt");
    Label L_cbcenc128, L_load_misaligned_input_128bit, L_128bit_transform, L_store_misaligned_output_128bit;
    Label L_check_loop_end_128bit, L_cbcenc192, L_load_misaligned_input_192bit, L_192bit_transform;
    Label L_store_misaligned_output_192bit, L_check_loop_end_192bit, L_cbcenc256, L_load_misaligned_input_256bit;
    Label L_256bit_transform, L_store_misaligned_output_256bit, L_check_loop_end_256bit;
    address start = __ pc();
    Register from = I0; // source byte array
    Register to = I1;   // destination byte array
    Register key = I2;  // expanded key array
    Register rvec = I3; // init vector
    const Register len_reg = I4; // cipher length
    const Register keylen = I5;  // reg for storing expanded key array length

    __ save_frame(0);
    // save cipher len to return in the end
    __ mov(len_reg, L0);

    // read expanded key length
    __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);

    // load initial vector, 8-byte alignment is guranteed
    __ ldf(FloatRegisterImpl::D, rvec, 0, F60);
    __ ldf(FloatRegisterImpl::D, rvec, 8, F62);
    // load key, 8-byte alignment is guranteed
    __ ldx(key,0,G1);
    __ ldx(key,8,G5);

    // start loading expanded key, 8-byte alignment is guranteed
    for ( int i = 0, j = 16;  i <= 38; i += 2, j += 8 ) {
      __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
    }

    // 128-bit original key size
    __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pt, L_cbcenc128);

    for ( int i = 40, j = 176;  i <= 46; i += 2, j += 8 ) {
      __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
    }

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pt, L_cbcenc192);

    for ( int i = 48, j = 208;  i <= 54; i += 2, j += 8 ) {
      __ ldf(FloatRegisterImpl::D, key, j, as_FloatRegister(i));
    }

    // 256-bit original key size
    __ ba_short(L_cbcenc256);

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc128);
    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_128bit);
    __ delayed()->mov(from, L1); // save original 'from' address before alignaddr

    // aligned case: load input into G3 and G4
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ ba_short(L_128bit_transform);

    __ BIND(L_load_misaligned_input_128bit);
    // can clobber F48, F50 and F52 as they are not used in 128 and 192-bit key encryption
    __ alignaddr(from, G0, from);
    __ ldf(FloatRegisterImpl::D, from, 0, F48);
    __ ldf(FloatRegisterImpl::D, from, 8, F50);
    __ ldf(FloatRegisterImpl::D, from, 16, F52);
    __ faligndata(F48, F50, F48);
    __ faligndata(F50, F52, F50);
    __ movdtox(F48, G3);
    __ movdtox(F50, G4);
    __ mov(L1, from);

    __ BIND(L_128bit_transform);
    __ xor3(G1,G3,G3);
    __ xor3(G5,G4,G4);
    __ movxtod(G3,F56);
    __ movxtod(G4,F58);
    __ fxor(FloatRegisterImpl::D, F60, F56, F60);
    __ fxor(FloatRegisterImpl::D, F62, F58, F62);

    // TEN_EROUNDS
    for ( int i = 0;  i <= 32; i += 8 ) {
      __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
      __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
      if (i != 32 ) {
        __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
      } else {
        __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
      }
    }

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, L1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_128bit);
    __ delayed()->edge8n(to, G0, L2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ ba_short(L_check_loop_end_128bit);

    __ BIND(L_store_misaligned_output_128bit);
    __ add(to, 8, L3);
    __ mov(8, L4);
    __ sub(L4, L1, L4);
    __ alignaddr(L4, G0, L4);
    // save cipher text before circular right shift
    // as it needs to be stored as iv for next block (see code before next retl)
    __ movdtox(F60, L6);
    __ movdtox(F62, L7);
    __ faligndata(F60, F60, F60);
    __ faligndata(F62, F62, F62);
    __ mov(to, L5);
    __ and3(to, -8, to);
    __ and3(L3, -8, L3);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(L3, 8, L3);
    __ orn(G0, L2, L2);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ mov(L5, to);
    __ movxtod(L6, F60);
    __ movxtod(L7, F62);

    __ BIND(L_check_loop_end_128bit);
    __ add(from, 16, from);
    __ add(to, 16, to);
    __ subcc(len_reg, 16, len_reg);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc128);
    __ delayed()->nop();
    // re-init intial vector for next block, 8-byte alignment is guaranteed
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ mov(L0, I0);
    __ ret();
    __ delayed()->restore();

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc192);
    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_192bit);
    __ delayed()->mov(from, L1); // save original 'from' address before alignaddr

    // aligned case: load input into G3 and G4
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ ba_short(L_192bit_transform);

    __ BIND(L_load_misaligned_input_192bit);
    // can clobber F48, F50 and F52 as they are not used in 128 and 192-bit key encryption
    __ alignaddr(from, G0, from);
    __ ldf(FloatRegisterImpl::D, from, 0, F48);
    __ ldf(FloatRegisterImpl::D, from, 8, F50);
    __ ldf(FloatRegisterImpl::D, from, 16, F52);
    __ faligndata(F48, F50, F48);
    __ faligndata(F50, F52, F50);
    __ movdtox(F48, G3);
    __ movdtox(F50, G4);
    __ mov(L1, from);

    __ BIND(L_192bit_transform);
    __ xor3(G1,G3,G3);
    __ xor3(G5,G4,G4);
    __ movxtod(G3,F56);
    __ movxtod(G4,F58);
    __ fxor(FloatRegisterImpl::D, F60, F56, F60);
    __ fxor(FloatRegisterImpl::D, F62, F58, F62);

    // TWELEVE_EROUNDS
    for ( int i = 0;  i <= 40; i += 8 ) {
      __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
      __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
      if (i != 40 ) {
        __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
      } else {
        __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
      }
    }

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, L1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_192bit);
    __ delayed()->edge8n(to, G0, L2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ ba_short(L_check_loop_end_192bit);

    __ BIND(L_store_misaligned_output_192bit);
    __ add(to, 8, L3);
    __ mov(8, L4);
    __ sub(L4, L1, L4);
    __ alignaddr(L4, G0, L4);
    __ movdtox(F60, L6);
    __ movdtox(F62, L7);
    __ faligndata(F60, F60, F60);
    __ faligndata(F62, F62, F62);
    __ mov(to, L5);
    __ and3(to, -8, to);
    __ and3(L3, -8, L3);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(L3, 8, L3);
    __ orn(G0, L2, L2);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ mov(L5, to);
    __ movxtod(L6, F60);
    __ movxtod(L7, F62);

    __ BIND(L_check_loop_end_192bit);
    __ add(from, 16, from);
    __ subcc(len_reg, 16, len_reg);
    __ add(to, 16, to);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc192);
    __ delayed()->nop();
    // re-init intial vector for next block, 8-byte alignment is guaranteed
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ mov(L0, I0);
    __ ret();
    __ delayed()->restore();

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc256);
    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_256bit);
    __ delayed()->mov(from, L1); // save original 'from' address before alignaddr

    // aligned case: load input into G3 and G4
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ ba_short(L_256bit_transform);

    __ BIND(L_load_misaligned_input_256bit);
    // cannot clobber F48, F50 and F52. F56, F58 can be used though
    __ alignaddr(from, G0, from);
    __ movdtox(F60, L2); // save F60 before overwriting
    __ ldf(FloatRegisterImpl::D, from, 0, F56);
    __ ldf(FloatRegisterImpl::D, from, 8, F58);
    __ ldf(FloatRegisterImpl::D, from, 16, F60);
    __ faligndata(F56, F58, F56);
    __ faligndata(F58, F60, F58);
    __ movdtox(F56, G3);
    __ movdtox(F58, G4);
    __ mov(L1, from);
    __ movxtod(L2, F60);

    __ BIND(L_256bit_transform);
    __ xor3(G1,G3,G3);
    __ xor3(G5,G4,G4);
    __ movxtod(G3,F56);
    __ movxtod(G4,F58);
    __ fxor(FloatRegisterImpl::D, F60, F56, F60);
    __ fxor(FloatRegisterImpl::D, F62, F58, F62);

    // FOURTEEN_EROUNDS
    for ( int i = 0;  i <= 48; i += 8 ) {
      __ aes_eround01(as_FloatRegister(i), F60, F62, F56);
      __ aes_eround23(as_FloatRegister(i+2), F60, F62, F58);
      if (i != 48 ) {
        __ aes_eround01(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23(as_FloatRegister(i+6), F56, F58, F62);
      } else {
        __ aes_eround01_l(as_FloatRegister(i+4), F56, F58, F60);
        __ aes_eround23_l(as_FloatRegister(i+6), F56, F58, F62);
      }
    }

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, L1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_256bit);
    __ delayed()->edge8n(to, G0, L2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ ba_short(L_check_loop_end_256bit);

    __ BIND(L_store_misaligned_output_256bit);
    __ add(to, 8, L3);
    __ mov(8, L4);
    __ sub(L4, L1, L4);
    __ alignaddr(L4, G0, L4);
    __ movdtox(F60, L6);
    __ movdtox(F62, L7);
    __ faligndata(F60, F60, F60);
    __ faligndata(F62, F62, F62);
    __ mov(to, L5);
    __ and3(to, -8, to);
    __ and3(L3, -8, L3);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(L3, 8, L3);
    __ orn(G0, L2, L2);
    __ stpartialf(to, L2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(L3, L2, F62, Assembler::ASI_PST8_PRIMARY);
    __ mov(L5, to);
    __ movxtod(L6, F60);
    __ movxtod(L7, F62);

    __ BIND(L_check_loop_end_256bit);
    __ add(from, 16, from);
    __ subcc(len_reg, 16, len_reg);
    __ add(to, 16, to);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc256);
    __ delayed()->nop();
    // re-init intial vector for next block, 8-byte alignment is guaranteed
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ mov(L0, I0);
    __ ret();
    __ delayed()->restore();

    return start;
  }

  address generate_cipherBlockChaining_decryptAESCrypt_Parallel() {
    assert((arrayOopDesc::base_offset_in_bytes(T_INT) & 7) == 0,
           "the following code assumes that first element of an int array is aligned to 8 bytes");
    assert((arrayOopDesc::base_offset_in_bytes(T_BYTE) & 7) == 0,
           "the following code assumes that first element of a byte array is aligned to 8 bytes");
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "cipherBlockChaining_decryptAESCrypt");
    Label L_cbcdec_end, L_expand192bit, L_expand256bit, L_dec_first_block_start;
    Label L_dec_first_block128, L_dec_first_block192, L_dec_next2_blocks128, L_dec_next2_blocks192, L_dec_next2_blocks256;
    Label L_load_misaligned_input_first_block, L_transform_first_block, L_load_misaligned_next2_blocks128, L_transform_next2_blocks128;
    Label L_load_misaligned_next2_blocks192, L_transform_next2_blocks192, L_load_misaligned_next2_blocks256, L_transform_next2_blocks256;
    Label L_store_misaligned_output_first_block, L_check_decrypt_end, L_store_misaligned_output_next2_blocks128;
    Label L_check_decrypt_loop_end128, L_store_misaligned_output_next2_blocks192, L_check_decrypt_loop_end192;
    Label L_store_misaligned_output_next2_blocks256, L_check_decrypt_loop_end256;
    address start = __ pc();
    Register from = I0; // source byte array
    Register to = I1;   // destination byte array
    Register key = I2;  // expanded key array
    Register rvec = I3; // init vector
    const Register len_reg = I4; // cipher length
    const Register original_key = I5;  // original key array only required during decryption
    const Register keylen = L6;  // reg for storing expanded key array length

    __ save_frame(0); //args are read from I* registers since we save the frame in the beginning
    // save cipher len to return in the end
    __ mov(len_reg, L7);

    // load original key from SunJCE expanded decryption key
    // Since we load original key buffer starting first element, 8-byte alignment is guaranteed
    for ( int i = 0;  i <= 3; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // load initial vector, 8-byte alignment is guaranteed
    __ ldx(rvec,0,L0);
    __ ldx(rvec,8,L1);

    // read expanded key array length
    __ ldsw(Address(key, arrayOopDesc::length_offset_in_bytes() - arrayOopDesc::base_offset_in_bytes(T_INT)), keylen, 0);

    // 256-bit original key size
    __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_expand256bit);

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_expand192bit);

    // 128-bit original key size
    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 36; i += 4 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+2), i/4, as_FloatRegister(i+4));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+4), as_FloatRegister(i+6));
    }

    // load expanded key[last-1] and key[last] elements
    __ movdtox(F40,L2);
    __ movdtox(F42,L3);

    __ and3(len_reg, 16, L4);
    __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks128);
    __ nop();

    __ ba_short(L_dec_first_block_start);

    __ BIND(L_expand192bit);
    // load rest of the 192-bit key
    __ ldf(FloatRegisterImpl::S, original_key, 16, F4);
    __ ldf(FloatRegisterImpl::S, original_key, 20, F5);

    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 36; i += 6 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+4), i/6, as_FloatRegister(i+6));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+6), as_FloatRegister(i+8));
      __ aes_kexpand2(as_FloatRegister(i+4), as_FloatRegister(i+8), as_FloatRegister(i+10));
    }
    __ aes_kexpand1(F42, F46, 7, F48);
    __ aes_kexpand2(F44, F48, F50);

    // load expanded key[last-1] and key[last] elements
    __ movdtox(F48,L2);
    __ movdtox(F50,L3);

    __ and3(len_reg, 16, L4);
    __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks192);
    __ nop();

    __ ba_short(L_dec_first_block_start);

    __ BIND(L_expand256bit);
    // load rest of the 256-bit key
    for ( int i = 4;  i <= 7; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // perform key expansion since SunJCE decryption-key expansion is not compatible with SPARC crypto instructions
    for ( int i = 0;  i <= 40; i += 8 ) {
      __ aes_kexpand1(as_FloatRegister(i), as_FloatRegister(i+6), i/8, as_FloatRegister(i+8));
      __ aes_kexpand2(as_FloatRegister(i+2), as_FloatRegister(i+8), as_FloatRegister(i+10));
      __ aes_kexpand0(as_FloatRegister(i+4), as_FloatRegister(i+10), as_FloatRegister(i+12));
      __ aes_kexpand2(as_FloatRegister(i+6), as_FloatRegister(i+12), as_FloatRegister(i+14));
    }
    __ aes_kexpand1(F48, F54, 6, F56);
    __ aes_kexpand2(F50, F56, F58);

    // load expanded key[last-1] and key[last] elements
    __ movdtox(F56,L2);
    __ movdtox(F58,L3);

    __ and3(len_reg, 16, L4);
    __ br_null_short(L4, Assembler::pt, L_dec_next2_blocks256);

    __ BIND(L_dec_first_block_start);
    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_input_first_block);
    __ delayed()->mov(from, G1); // save original 'from' address before alignaddr

    // aligned case: load input into L4 and L5
    __ ldx(from,0,L4);
    __ ldx(from,8,L5);
    __ ba_short(L_transform_first_block);

    __ BIND(L_load_misaligned_input_first_block);
    __ alignaddr(from, G0, from);
    // F58, F60, F62 can be clobbered
    __ ldf(FloatRegisterImpl::D, from, 0, F58);
    __ ldf(FloatRegisterImpl::D, from, 8, F60);
    __ ldf(FloatRegisterImpl::D, from, 16, F62);
    __ faligndata(F58, F60, F58);
    __ faligndata(F60, F62, F60);
    __ movdtox(F58, L4);
    __ movdtox(F60, L5);
    __ mov(G1, from);

    __ BIND(L_transform_first_block);
    __ xor3(L2,L4,G1);
    __ movxtod(G1,F60);
    __ xor3(L3,L5,G1);
    __ movxtod(G1,F62);

    // 128-bit original key size
    __ cmp_and_brx_short(keylen, 44, Assembler::equal, Assembler::pn, L_dec_first_block128);

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_dec_first_block192);

    __ aes_dround23(F54, F60, F62, F58);
    __ aes_dround01(F52, F60, F62, F56);
    __ aes_dround23(F50, F56, F58, F62);
    __ aes_dround01(F48, F56, F58, F60);

    __ BIND(L_dec_first_block192);
    __ aes_dround23(F46, F60, F62, F58);
    __ aes_dround01(F44, F60, F62, F56);
    __ aes_dround23(F42, F56, F58, F62);
    __ aes_dround01(F40, F56, F58, F60);

    __ BIND(L_dec_first_block128);
    for ( int i = 38;  i >= 6; i -= 8 ) {
      __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
      __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
      if ( i != 6) {
        __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
      } else {
        __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
      }
    }

    __ movxtod(L0,F56);
    __ movxtod(L1,F58);
    __ mov(L4,L0);
    __ mov(L5,L1);
    __ fxor(FloatRegisterImpl::D, F56, F60, F60);
    __ fxor(FloatRegisterImpl::D, F58, F62, F62);

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, G1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_first_block);
    __ delayed()->edge8n(to, G0, G2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ ba_short(L_check_decrypt_end);

    __ BIND(L_store_misaligned_output_first_block);
    __ add(to, 8, G3);
    __ mov(8, G4);
    __ sub(G4, G1, G4);
    __ alignaddr(G4, G0, G4);
    __ faligndata(F60, F60, F60);
    __ faligndata(F62, F62, F62);
    __ mov(to, G1);
    __ and3(to, -8, to);
    __ and3(G3, -8, G3);
    __ stpartialf(to, G2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(G3, G2, F62, Assembler::ASI_PST8_PRIMARY);
    __ add(to, 8, to);
    __ add(G3, 8, G3);
    __ orn(G0, G2, G2);
    __ stpartialf(to, G2, F60, Assembler::ASI_PST8_PRIMARY);
    __ stpartialf(G3, G2, F62, Assembler::ASI_PST8_PRIMARY);
    __ mov(G1, to);

    __ BIND(L_check_decrypt_end);
    __ add(from, 16, from);
    __ add(to, 16, to);
    __ subcc(len_reg, 16, len_reg);
    __ br(Assembler::equal, false, Assembler::pt, L_cbcdec_end);
    __ delayed()->nop();

    // 256-bit original key size
    __ cmp_and_brx_short(keylen, 60, Assembler::equal, Assembler::pn, L_dec_next2_blocks256);

    // 192-bit original key size
    __ cmp_and_brx_short(keylen, 52, Assembler::equal, Assembler::pn, L_dec_next2_blocks192);

    __ align(OptoLoopAlignment);
    __ BIND(L_dec_next2_blocks128);
    __ nop();

    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks128);
    __ delayed()->mov(from, G1); // save original 'from' address before alignaddr

    // aligned case: load input into G4, G5, L4 and L5
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ ba_short(L_transform_next2_blocks128);

    __ BIND(L_load_misaligned_next2_blocks128);
    __ alignaddr(from, G0, from);
    // F40, F42, F58, F60, F62 can be clobbered
    __ ldf(FloatRegisterImpl::D, from, 0, F40);
    __ ldf(FloatRegisterImpl::D, from, 8, F42);
    __ ldf(FloatRegisterImpl::D, from, 16, F60);
    __ ldf(FloatRegisterImpl::D, from, 24, F62);
    __ ldf(FloatRegisterImpl::D, from, 32, F58);
    __ faligndata(F40, F42, F40);
    __ faligndata(F42, F60, F42);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F58, F62);
    __ movdtox(F40, G4);
    __ movdtox(F42, G5);
    __ movdtox(F60, L4);
    __ movdtox(F62, L5);
    __ mov(G1, from);

    __ BIND(L_transform_next2_blocks128);
    // F40:F42 used for first 16-bytes
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F40);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F42);

    // F60:F62 used for next 16-bytes
    __ xor3(L2,L4,G1);
    __ movxtod(G1,F60);
    __ xor3(L3,L5,G1);
    __ movxtod(G1,F62);

    for ( int i = 38;  i >= 6; i -= 8 ) {
      __ aes_dround23(as_FloatRegister(i), F40, F42, F44);
      __ aes_dround01(as_FloatRegister(i-2), F40, F42, F46);
      __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
      __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
      if (i != 6 ) {
        __ aes_dround23(as_FloatRegister(i-4), F46, F44, F42);
        __ aes_dround01(as_FloatRegister(i-6), F46, F44, F40);
        __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
      } else {
        __ aes_dround23_l(as_FloatRegister(i-4), F46, F44, F42);
        __ aes_dround01_l(as_FloatRegister(i-6), F46, F44, F40);
        __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
      }
    }

    __ movxtod(L0,F46);
    __ movxtod(L1,F44);
    __ fxor(FloatRegisterImpl::D, F46, F40, F40);
    __ fxor(FloatRegisterImpl::D, F44, F42, F42);

    __ movxtod(G4,F56);
    __ movxtod(G5,F58);
    __ mov(L4,L0);
    __ mov(L5,L1);
    __ fxor(FloatRegisterImpl::D, F56, F60, F60);
    __ fxor(FloatRegisterImpl::D, F58, F62, F62);

    // For mis-aligned store of 32 bytes of result we can do:
    // Circular right-shift all 4 FP registers so that 'head' and 'tail'
    // parts that need to be stored starting at mis-aligned address are in a FP reg
    // the other 3 FP regs can thus be stored using regular store
    // we then use the edge + partial-store mechanism to store the 'head' and 'tail' parts

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, G1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks128);
    __ delayed()->edge8n(to, G0, G2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F40, to, 0);
    __ stf(FloatRegisterImpl::D, F42, to, 8);
    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);
    __ ba_short(L_check_decrypt_loop_end128);

    __ BIND(L_store_misaligned_output_next2_blocks128);
    __ mov(8, G4);
    __ sub(G4, G1, G4);
    __ alignaddr(G4, G0, G4);
    __ faligndata(F40, F42, F56); // F56 can be clobbered
    __ faligndata(F42, F60, F42);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F40, F40);
    __ mov(to, G1);
    __ and3(to, -8, to);
    __ stpartialf(to, G2, F40, Assembler::ASI_PST8_PRIMARY);
    __ stf(FloatRegisterImpl::D, F56, to, 8);
    __ stf(FloatRegisterImpl::D, F42, to, 16);
    __ stf(FloatRegisterImpl::D, F60, to, 24);
    __ add(to, 32, to);
    __ orn(G0, G2, G2);
    __ stpartialf(to, G2, F40, Assembler::ASI_PST8_PRIMARY);
    __ mov(G1, to);

    __ BIND(L_check_decrypt_loop_end128);
    __ add(from, 32, from);
    __ add(to, 32, to);
    __ subcc(len_reg, 32, len_reg);
    __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks128);
    __ delayed()->nop();
    __ ba_short(L_cbcdec_end);

    __ align(OptoLoopAlignment);
    __ BIND(L_dec_next2_blocks192);
    __ nop();

    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks192);
    __ delayed()->mov(from, G1); // save original 'from' address before alignaddr

    // aligned case: load input into G4, G5, L4 and L5
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ ba_short(L_transform_next2_blocks192);

    __ BIND(L_load_misaligned_next2_blocks192);
    __ alignaddr(from, G0, from);
    // F48, F50, F52, F60, F62 can be clobbered
    __ ldf(FloatRegisterImpl::D, from, 0, F48);
    __ ldf(FloatRegisterImpl::D, from, 8, F50);
    __ ldf(FloatRegisterImpl::D, from, 16, F60);
    __ ldf(FloatRegisterImpl::D, from, 24, F62);
    __ ldf(FloatRegisterImpl::D, from, 32, F52);
    __ faligndata(F48, F50, F48);
    __ faligndata(F50, F60, F50);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F52, F62);
    __ movdtox(F48, G4);
    __ movdtox(F50, G5);
    __ movdtox(F60, L4);
    __ movdtox(F62, L5);
    __ mov(G1, from);

    __ BIND(L_transform_next2_blocks192);
    // F48:F50 used for first 16-bytes
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F48);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F50);

    // F60:F62 used for next 16-bytes
    __ xor3(L2,L4,G1);
    __ movxtod(G1,F60);
    __ xor3(L3,L5,G1);
    __ movxtod(G1,F62);

    for ( int i = 46;  i >= 6; i -= 8 ) {
      __ aes_dround23(as_FloatRegister(i), F48, F50, F52);
      __ aes_dround01(as_FloatRegister(i-2), F48, F50, F54);
      __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
      __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
      if (i != 6 ) {
        __ aes_dround23(as_FloatRegister(i-4), F54, F52, F50);
        __ aes_dround01(as_FloatRegister(i-6), F54, F52, F48);
        __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
      } else {
        __ aes_dround23_l(as_FloatRegister(i-4), F54, F52, F50);
        __ aes_dround01_l(as_FloatRegister(i-6), F54, F52, F48);
        __ aes_dround23_l(as_FloatRegister(i-4), F56, F58, F62);
        __ aes_dround01_l(as_FloatRegister(i-6), F56, F58, F60);
      }
    }

    __ movxtod(L0,F54);
    __ movxtod(L1,F52);
    __ fxor(FloatRegisterImpl::D, F54, F48, F48);
    __ fxor(FloatRegisterImpl::D, F52, F50, F50);

    __ movxtod(G4,F56);
    __ movxtod(G5,F58);
    __ mov(L4,L0);
    __ mov(L5,L1);
    __ fxor(FloatRegisterImpl::D, F56, F60, F60);
    __ fxor(FloatRegisterImpl::D, F58, F62, F62);

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, G1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks192);
    __ delayed()->edge8n(to, G0, G2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F48, to, 0);
    __ stf(FloatRegisterImpl::D, F50, to, 8);
    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);
    __ ba_short(L_check_decrypt_loop_end192);

    __ BIND(L_store_misaligned_output_next2_blocks192);
    __ mov(8, G4);
    __ sub(G4, G1, G4);
    __ alignaddr(G4, G0, G4);
    __ faligndata(F48, F50, F56); // F56 can be clobbered
    __ faligndata(F50, F60, F50);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F48, F48);
    __ mov(to, G1);
    __ and3(to, -8, to);
    __ stpartialf(to, G2, F48, Assembler::ASI_PST8_PRIMARY);
    __ stf(FloatRegisterImpl::D, F56, to, 8);
    __ stf(FloatRegisterImpl::D, F50, to, 16);
    __ stf(FloatRegisterImpl::D, F60, to, 24);
    __ add(to, 32, to);
    __ orn(G0, G2, G2);
    __ stpartialf(to, G2, F48, Assembler::ASI_PST8_PRIMARY);
    __ mov(G1, to);

    __ BIND(L_check_decrypt_loop_end192);
    __ add(from, 32, from);
    __ add(to, 32, to);
    __ subcc(len_reg, 32, len_reg);
    __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks192);
    __ delayed()->nop();
    __ ba_short(L_cbcdec_end);

    __ align(OptoLoopAlignment);
    __ BIND(L_dec_next2_blocks256);
    __ nop();

    // check for 8-byte alignment since source byte array may have an arbitrary alignment if offset mod 8 is non-zero
    __ andcc(from, 7, G0);
    __ br(Assembler::notZero, true, Assembler::pn, L_load_misaligned_next2_blocks256);
    __ delayed()->mov(from, G1); // save original 'from' address before alignaddr

    // aligned case: load input into G4, G5, L4 and L5
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ ba_short(L_transform_next2_blocks256);

    __ BIND(L_load_misaligned_next2_blocks256);
    __ alignaddr(from, G0, from);
    // F0, F2, F4, F60, F62 can be clobbered
    __ ldf(FloatRegisterImpl::D, from, 0, F0);
    __ ldf(FloatRegisterImpl::D, from, 8, F2);
    __ ldf(FloatRegisterImpl::D, from, 16, F60);
    __ ldf(FloatRegisterImpl::D, from, 24, F62);
    __ ldf(FloatRegisterImpl::D, from, 32, F4);
    __ faligndata(F0, F2, F0);
    __ faligndata(F2, F60, F2);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F4, F62);
    __ movdtox(F0, G4);
    __ movdtox(F2, G5);
    __ movdtox(F60, L4);
    __ movdtox(F62, L5);
    __ mov(G1, from);

    __ BIND(L_transform_next2_blocks256);
    // F0:F2 used for first 16-bytes
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F0);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F2);

    // F60:F62 used for next 16-bytes
    __ xor3(L2,L4,G1);
    __ movxtod(G1,F60);
    __ xor3(L3,L5,G1);
    __ movxtod(G1,F62);

    __ aes_dround23(F54, F0, F2, F4);
    __ aes_dround01(F52, F0, F2, F6);
    __ aes_dround23(F54, F60, F62, F58);
    __ aes_dround01(F52, F60, F62, F56);
    __ aes_dround23(F50, F6, F4, F2);
    __ aes_dround01(F48, F6, F4, F0);
    __ aes_dround23(F50, F56, F58, F62);
    __ aes_dround01(F48, F56, F58, F60);
    // save F48:F54 in temp registers
    __ movdtox(F54,G2);
    __ movdtox(F52,G3);
    __ movdtox(F50,L6);
    __ movdtox(F48,G1);
    for ( int i = 46;  i >= 14; i -= 8 ) {
      __ aes_dround23(as_FloatRegister(i), F0, F2, F4);
      __ aes_dround01(as_FloatRegister(i-2), F0, F2, F6);
      __ aes_dround23(as_FloatRegister(i), F60, F62, F58);
      __ aes_dround01(as_FloatRegister(i-2), F60, F62, F56);
      __ aes_dround23(as_FloatRegister(i-4), F6, F4, F2);
      __ aes_dround01(as_FloatRegister(i-6), F6, F4, F0);
      __ aes_dround23(as_FloatRegister(i-4), F56, F58, F62);
      __ aes_dround01(as_FloatRegister(i-6), F56, F58, F60);
    }
    // init F48:F54 with F0:F6 values (original key)
    __ ldf(FloatRegisterImpl::D, original_key, 0, F48);
    __ ldf(FloatRegisterImpl::D, original_key, 8, F50);
    __ ldf(FloatRegisterImpl::D, original_key, 16, F52);
    __ ldf(FloatRegisterImpl::D, original_key, 24, F54);
    __ aes_dround23(F54, F0, F2, F4);
    __ aes_dround01(F52, F0, F2, F6);
    __ aes_dround23(F54, F60, F62, F58);
    __ aes_dround01(F52, F60, F62, F56);
    __ aes_dround23_l(F50, F6, F4, F2);
    __ aes_dround01_l(F48, F6, F4, F0);
    __ aes_dround23_l(F50, F56, F58, F62);
    __ aes_dround01_l(F48, F56, F58, F60);
    // re-init F48:F54 with their original values
    __ movxtod(G2,F54);
    __ movxtod(G3,F52);
    __ movxtod(L6,F50);
    __ movxtod(G1,F48);

    __ movxtod(L0,F6);
    __ movxtod(L1,F4);
    __ fxor(FloatRegisterImpl::D, F6, F0, F0);
    __ fxor(FloatRegisterImpl::D, F4, F2, F2);

    __ movxtod(G4,F56);
    __ movxtod(G5,F58);
    __ mov(L4,L0);
    __ mov(L5,L1);
    __ fxor(FloatRegisterImpl::D, F56, F60, F60);
    __ fxor(FloatRegisterImpl::D, F58, F62, F62);

    // check for 8-byte alignment since dest byte array may have arbitrary alignment if offset mod 8 is non-zero
    __ andcc(to, 7, G1);
    __ br(Assembler::notZero, true, Assembler::pn, L_store_misaligned_output_next2_blocks256);
    __ delayed()->edge8n(to, G0, G2);

    // aligned case: store output into the destination array
    __ stf(FloatRegisterImpl::D, F0, to, 0);
    __ stf(FloatRegisterImpl::D, F2, to, 8);
    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);
    __ ba_short(L_check_decrypt_loop_end256);

    __ BIND(L_store_misaligned_output_next2_blocks256);
    __ mov(8, G4);
    __ sub(G4, G1, G4);
    __ alignaddr(G4, G0, G4);
    __ faligndata(F0, F2, F56); // F56 can be clobbered
    __ faligndata(F2, F60, F2);
    __ faligndata(F60, F62, F60);
    __ faligndata(F62, F0, F0);
    __ mov(to, G1);
    __ and3(to, -8, to);
    __ stpartialf(to, G2, F0, Assembler::ASI_PST8_PRIMARY);
    __ stf(FloatRegisterImpl::D, F56, to, 8);
    __ stf(FloatRegisterImpl::D, F2, to, 16);
    __ stf(FloatRegisterImpl::D, F60, to, 24);
    __ add(to, 32, to);
    __ orn(G0, G2, G2);
    __ stpartialf(to, G2, F0, Assembler::ASI_PST8_PRIMARY);
    __ mov(G1, to);

    __ BIND(L_check_decrypt_loop_end256);
    __ add(from, 32, from);
    __ add(to, 32, to);
    __ subcc(len_reg, 32, len_reg);
    __ br(Assembler::notEqual, false, Assembler::pt, L_dec_next2_blocks256);
    __ delayed()->nop();

    __ BIND(L_cbcdec_end);
    // re-init intial vector for next block, 8-byte alignment is guaranteed
    __ stx(L0, rvec, 0);
    __ stx(L1, rvec, 8);
    __ mov(L7, I0);
    __ ret();
    __ delayed()->restore();

    return start;
  }

  address generate_sha1_implCompress(bool multi_block, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_sha1_loop, L_sha1_unaligned_input, L_sha1_unaligned_input_loop;
    int i;

    Register buf   = O0; // byte[] source+offset
    Register state = O1; // int[]  SHA.state
    Register ofs   = O2; // int    offset
    Register limit = O3; // int    limit

    // load state into F0-F4
    for (i = 0; i < 5; i++) {
      __ ldf(FloatRegisterImpl::S, state, i*4, as_FloatRegister(i));
    }

    __ andcc(buf, 7, G0);
    __ br(Assembler::notZero, false, Assembler::pn, L_sha1_unaligned_input);
    __ delayed()->nop();

    __ BIND(L_sha1_loop);
    // load buf into F8-F22
    for (i = 0; i < 8; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
    }
    __ sha1();
    if (multi_block) {
      __ add(ofs, 64, ofs);
      __ add(buf, 64, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha1_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F4 into state and return
    for (i = 0; i < 4; i++) {
      __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F4, state, 0x10);

    __ BIND(L_sha1_unaligned_input);
    __ alignaddr(buf, G0, buf);

    __ BIND(L_sha1_unaligned_input_loop);
    // load buf into F8-F22
    for (i = 0; i < 9; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
    }
    for (i = 0; i < 8; i++) {
      __ faligndata(as_FloatRegister(i*2 + 8), as_FloatRegister(i*2 + 10), as_FloatRegister(i*2 + 8));
    }
    __ sha1();
    if (multi_block) {
      __ add(ofs, 64, ofs);
      __ add(buf, 64, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha1_unaligned_input_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F4 into state and return
    for (i = 0; i < 4; i++) {
      __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F4, state, 0x10);

    return start;
  }

  address generate_sha256_implCompress(bool multi_block, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_sha256_loop, L_sha256_unaligned_input, L_sha256_unaligned_input_loop;
    int i;

    Register buf   = O0; // byte[] source+offset
    Register state = O1; // int[]  SHA2.state
    Register ofs   = O2; // int    offset
    Register limit = O3; // int    limit

    // load state into F0-F7
    for (i = 0; i < 8; i++) {
      __ ldf(FloatRegisterImpl::S, state, i*4, as_FloatRegister(i));
    }

    __ andcc(buf, 7, G0);
    __ br(Assembler::notZero, false, Assembler::pn, L_sha256_unaligned_input);
    __ delayed()->nop();

    __ BIND(L_sha256_loop);
    // load buf into F8-F22
    for (i = 0; i < 8; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
    }
    __ sha256();
    if (multi_block) {
      __ add(ofs, 64, ofs);
      __ add(buf, 64, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha256_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F7 into state and return
    for (i = 0; i < 7; i++) {
      __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F7, state, 0x1c);

    __ BIND(L_sha256_unaligned_input);
    __ alignaddr(buf, G0, buf);

    __ BIND(L_sha256_unaligned_input_loop);
    // load buf into F8-F22
    for (i = 0; i < 9; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 8));
    }
    for (i = 0; i < 8; i++) {
      __ faligndata(as_FloatRegister(i*2 + 8), as_FloatRegister(i*2 + 10), as_FloatRegister(i*2 + 8));
    }
    __ sha256();
    if (multi_block) {
      __ add(ofs, 64, ofs);
      __ add(buf, 64, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha256_unaligned_input_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F7 into state and return
    for (i = 0; i < 7; i++) {
      __ stf(FloatRegisterImpl::S, as_FloatRegister(i), state, i*4);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F7, state, 0x1c);

    return start;
  }

  address generate_sha512_implCompress(bool multi_block, const char *name) {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

    Label L_sha512_loop, L_sha512_unaligned_input, L_sha512_unaligned_input_loop;
    int i;

    Register buf   = O0; // byte[] source+offset
    Register state = O1; // long[] SHA5.state
    Register ofs   = O2; // int    offset
    Register limit = O3; // int    limit

    // load state into F0-F14
    for (i = 0; i < 8; i++) {
      __ ldf(FloatRegisterImpl::D, state, i*8, as_FloatRegister(i*2));
    }

    __ andcc(buf, 7, G0);
    __ br(Assembler::notZero, false, Assembler::pn, L_sha512_unaligned_input);
    __ delayed()->nop();

    __ BIND(L_sha512_loop);
    // load buf into F16-F46
    for (i = 0; i < 16; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 16));
    }
    __ sha512();
    if (multi_block) {
      __ add(ofs, 128, ofs);
      __ add(buf, 128, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha512_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F14 into state and return
    for (i = 0; i < 7; i++) {
      __ stf(FloatRegisterImpl::D, as_FloatRegister(i*2), state, i*8);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::D, F14, state, 0x38);

    __ BIND(L_sha512_unaligned_input);
    __ alignaddr(buf, G0, buf);

    __ BIND(L_sha512_unaligned_input_loop);
    // load buf into F16-F46
    for (i = 0; i < 17; i++) {
      __ ldf(FloatRegisterImpl::D, buf, i*8, as_FloatRegister(i*2 + 16));
    }
    for (i = 0; i < 16; i++) {
      __ faligndata(as_FloatRegister(i*2 + 16), as_FloatRegister(i*2 + 18), as_FloatRegister(i*2 + 16));
    }
    __ sha512();
    if (multi_block) {
      __ add(ofs, 128, ofs);
      __ add(buf, 128, buf);
      __ cmp_and_brx_short(ofs, limit, Assembler::lessEqual, Assembler::pt, L_sha512_unaligned_input_loop);
      __ mov(ofs, O0); // to be returned
    }

    // store F0-F14 into state and return
    for (i = 0; i < 7; i++) {
      __ stf(FloatRegisterImpl::D, as_FloatRegister(i*2), state, i*8);
    }
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::D, F14, state, 0x38);

    return start;
  }

  /* Single and multi-block ghash operations */
  address generate_ghash_processBlocks() {
      __ align(CodeEntryAlignment);
      Label L_ghash_loop, L_aligned, L_main;
      StubCodeMark mark(this, "StubRoutines", "ghash_processBlocks");
      address start = __ pc();

      Register state = I0;
      Register subkeyH = I1;
      Register data = I2;
      Register len = I3;

      __ save_frame(0);

      __ ldx(state, 0, O0);
      __ ldx(state, 8, O1);

      // Loop label for multiblock operations
      __ BIND(L_ghash_loop);

      // Check if 'data' is unaligned
      __ andcc(data, 7, G1);
      __ br(Assembler::zero, false, Assembler::pt, L_aligned);
      __ delayed()->nop();

      Register left_shift = L1;
      Register right_shift = L2;
      Register data_ptr = L3;

      // Get left and right shift values in bits
      __ sll(G1, LogBitsPerByte, left_shift);
      __ mov(64, right_shift);
      __ sub(right_shift, left_shift, right_shift);

      // Align to read 'data'
      __ sub(data, G1, data_ptr);

      // Load first 8 bytes of 'data'
      __ ldx(data_ptr, 0, O4);
      __ sllx(O4, left_shift, O4);
      __ ldx(data_ptr, 8, O5);
      __ srlx(O5, right_shift, G4);
      __ bset(G4, O4);

      // Load second 8 bytes of 'data'
      __ sllx(O5, left_shift, O5);
      __ ldx(data_ptr, 16, G4);
      __ srlx(G4, right_shift, G4);
      __ ba(L_main);
      __ delayed()->bset(G4, O5);

      // If 'data' is aligned, load normally
      __ BIND(L_aligned);
      __ ldx(data, 0, O4);
      __ ldx(data, 8, O5);

      __ BIND(L_main);
      __ ldx(subkeyH, 0, O2);
      __ ldx(subkeyH, 8, O3);

      __ xor3(O0, O4, O0);
      __ xor3(O1, O5, O1);

      __ xmulxhi(O0, O3, G3);
      __ xmulx(O0, O2, O5);
      __ xmulxhi(O1, O2, G4);
      __ xmulxhi(O1, O3, G5);
      __ xmulx(O0, O3, G1);
      __ xmulx(O1, O3, G2);
      __ xmulx(O1, O2, O3);
      __ xmulxhi(O0, O2, O4);

      __ mov(0xE1, O0);
      __ sllx(O0, 56, O0);

      __ xor3(O5, G3, O5);
      __ xor3(O5, G4, O5);
      __ xor3(G5, G1, G1);
      __ xor3(G1, O3, G1);
      __ srlx(G2, 63, O1);
      __ srlx(G1, 63, G3);
      __ sllx(G2, 63, O3);
      __ sllx(G2, 58, O2);
      __ xor3(O3, O2, O2);

      __ sllx(G1, 1, G1);
      __ or3(G1, O1, G1);

      __ xor3(G1, O2, G1);

      __ sllx(G2, 1, G2);

      __ xmulxhi(G1, O0, O1);
      __ xmulx(G1, O0, O2);
      __ xmulxhi(G2, O0, O3);
      __ xmulx(G2, O0, G1);

      __ xor3(O4, O1, O4);
      __ xor3(O5, O2, O5);
      __ xor3(O5, O3, O5);

      __ sllx(O4, 1, O2);
      __ srlx(O5, 63, O3);

      __ or3(O2, O3, O0);

      __ sllx(O5, 1, O1);
      __ srlx(G1, 63, O2);
      __ or3(O1, O2, O1);
      __ xor3(O1, G3, O1);

      __ deccc(len);
      __ br(Assembler::notZero, true, Assembler::pt, L_ghash_loop);
      __ delayed()->add(data, 16, data);

      __ stx(O0, I0, 0);
      __ stx(O1, I0, 8);

      __ ret();
      __ delayed()->restore();

      return start;
  }

  /**
   *  Arguments:
   *
   * Inputs:
   *   O0   - int   crc
   *   O1   - byte* buf
   *   O2   - int   len
   *   O3   - int*  table
   *
   * Output:
   *   O0   - int crc result
   */
  address generate_updateBytesCRC32C() {
    assert(UseCRC32CIntrinsics, "need CRC32C instruction");

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "updateBytesCRC32C");
    address start = __ pc();

    const Register crc   = O0;  // crc
    const Register buf   = O1;  // source java byte array address
    const Register len   = O2;  // number of bytes
    const Register table = O3;  // byteTable

    __ kernel_crc32c(crc, buf, len, table);

    __ retl();
    __ delayed()->nop();

    return start;
  }

#define ADLER32_NUM_TEMPS 16

  /**
   *  Arguments:
   *
   * Inputs:
   *   O0   - int   adler
   *   O1   - byte* buff
   *   O2   - int   len
   *
   * Output:
   *   O0   - int adler result
   */
  address generate_updateBytesAdler32() {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "updateBytesAdler32");
    address start = __ pc();

    Label L_cleanup_loop, L_cleanup_loop_check;
    Label L_main_loop_check, L_main_loop, L_inner_loop, L_inner_loop_check;
    Label L_nmax_check_done;

    // Aliases
    Register s1     = O0;
    Register s2     = O3;
    Register buff   = O1;
    Register len    = O2;
    Register temp[ADLER32_NUM_TEMPS] = {L0, L1, L2, L3, L4, L5, L6, L7, I0, I1, I2, I3, I4, I5, G3, I7};

    // Max number of bytes we can process before having to take the mod
    // 0x15B0 is 5552 in decimal, the largest n such that 255n(n+1)/2 + (n+1)(BASE-1) <= 2^32-1
    unsigned long NMAX = 0x15B0;

    // Zero-out the upper bits of len
    __ clruwu(len);

    // Create the mask 0xFFFF
    __ set64(0x00FFFF, O4, O5); // O5 is the temp register

    // s1 is initialized to the lower 16 bits of adler
    // s2 is initialized to the upper 16 bits of adler
    __ srlx(O0, 16, O5); // adler >> 16
    __ and3(O0, O4, s1); // s1  = (adler & 0xFFFF)
    __ and3(O5, O4, s2); // s2  = ((adler >> 16) & 0xFFFF)

    // The pipelined loop needs at least 16 elements for 1 iteration
    // It does check this, but it is more effective to skip to the cleanup loop
    // Setup the constant for cutoff checking
    __ mov(15, O4);

    // Check if we are above the cutoff, if not go to the cleanup loop immediately
    __ cmp_and_br_short(len, O4, Assembler::lessEqualUnsigned, Assembler::pt, L_cleanup_loop_check);

    // Free up some registers for our use
    for (int i = 0; i < ADLER32_NUM_TEMPS; i++) {
      __ movxtod(temp[i], as_FloatRegister(2*i));
    }

    // Loop maintenance stuff is done at the end of the loop, so skip to there
    __ ba_short(L_main_loop_check);

    __ BIND(L_main_loop);

    // Prologue for inner loop
    __ ldub(buff, 0, L0);
    __ dec(O5);

    for (int i = 1; i < 8; i++) {
      __ ldub(buff, i, temp[i]);
    }

    __ inc(buff, 8);

    // Inner loop processes 16 elements at a time, might never execute if only 16 elements
    // to be processed by the outter loop
    __ ba_short(L_inner_loop_check);

    __ BIND(L_inner_loop);

    for (int i = 0; i < 8; i++) {
      __ ldub(buff, (2*i), temp[(8+(2*i)) % ADLER32_NUM_TEMPS]);
      __ add(s1, temp[i], s1);
      __ ldub(buff, (2*i)+1, temp[(8+(2*i)+1) % ADLER32_NUM_TEMPS]);
      __ add(s2, s1, s2);
    }

    // Original temp 0-7 used and new loads to temp 0-7 issued
    // temp 8-15 ready to be consumed
    __ add(s1, I0, s1);
    __ dec(O5);
    __ add(s2, s1, s2);
    __ add(s1, I1, s1);
    __ inc(buff, 16);
    __ add(s2, s1, s2);

    for (int i = 0; i < 6; i++) {
      __ add(s1, temp[10+i], s1);
      __ add(s2, s1, s2);
    }

    __ BIND(L_inner_loop_check);
    __ nop();
    __ cmp_and_br_short(O5, 0, Assembler::notEqual, Assembler::pt, L_inner_loop);

    // Epilogue
    for (int i = 0; i < 4; i++) {
      __ ldub(buff, (2*i), temp[8+(2*i)]);
      __ add(s1, temp[i], s1);
      __ ldub(buff, (2*i)+1, temp[8+(2*i)+1]);
      __ add(s2, s1, s2);
    }

    __ add(s1, temp[4], s1);
    __ inc(buff, 8);

    for (int i = 0; i < 11; i++) {
      __ add(s2, s1, s2);
      __ add(s1, temp[5+i], s1);
    }

    __ add(s2, s1, s2);

    // Take the mod for s1 and s2
    __ set64(0xFFF1, L0, L1);
    __ udivx(s1, L0, L1);
    __ udivx(s2, L0, L2);
    __ mulx(L0, L1, L1);
    __ mulx(L0, L2, L2);
    __ sub(s1, L1, s1);
    __ sub(s2, L2, s2);

    // Make sure there is something left to process
    __ BIND(L_main_loop_check);
    __ set64(NMAX, L0, L1);
    // k = len < NMAX ? len : NMAX
    __ cmp_and_br_short(len, L0, Assembler::greaterEqualUnsigned, Assembler::pt, L_nmax_check_done);
    __ andn(len, 0x0F, L0); // only loop a multiple of 16 times
    __ BIND(L_nmax_check_done);
    __ mov(L0, O5);
    __ sub(len, L0, len); // len -= k

    __ srlx(O5, 4, O5); // multiplies of 16
    __ cmp_and_br_short(O5, 0, Assembler::notEqual, Assembler::pt, L_main_loop);

    // Restore anything we used, take the mod one last time, combine and return
    // Restore any registers we saved
    for (int i = 0; i < ADLER32_NUM_TEMPS; i++) {
      __ movdtox(as_FloatRegister(2*i), temp[i]);
    }

    // There might be nothing left to process
    __ ba_short(L_cleanup_loop_check);

    __ BIND(L_cleanup_loop);
    __ ldub(buff, 0, O4); // load single byte form buffer
    __ inc(buff); // buff++
    __ add(s1, O4, s1); // s1 += *buff++;
    __ dec(len); // len--
    __ add(s1, s2, s2); // s2 += s1;
    __ BIND(L_cleanup_loop_check);
    __ nop();
    __ cmp_and_br_short(len, 0, Assembler::notEqual, Assembler::pt, L_cleanup_loop);

    // Take the mod one last time
    __ set64(0xFFF1, O1, O2);
    __ udivx(s1, O1, O2);
    __ udivx(s2, O1, O5);
    __ mulx(O1, O2, O2);
    __ mulx(O1, O5, O5);
    __ sub(s1, O2, s1);
    __ sub(s2, O5, s2);

    // Combine lower bits and higher bits
    __ sllx(s2, 16, s2); // s2 = s2 << 16
    __ or3(s1, s2, s1);  // adler = s2 | s1
    // Final return value is in O0
    __ retl();
    __ delayed()->nop();

    return start;
  }

  /**
   *  Arguments:
   *
   * Inputs:
   *   O0   - int   crc
   *   O1   - byte* buf
   *   O2   - int   len
   *   O3   - int*  table
   *
   * Output:
   *   O0   - int crc result
   */
  address generate_updateBytesCRC32() {
    assert(UseCRC32Intrinsics, "need VIS3 instructions");

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "updateBytesCRC32");
    address start = __ pc();

    const Register crc   = O0; // crc
    const Register buf   = O1; // source java byte array address
    const Register len   = O2; // length
    const Register table = O3; // crc_table address (reuse register)

    __ kernel_crc32(crc, buf, len, table);

    __ retl();
    __ delayed()->nop();

    return start;
  }

  /**
   * Arguments:
   *
   * Inputs:
   *   I0   - int* x-addr
   *   I1   - int  x-len
   *   I2   - int* y-addr
   *   I3   - int  y-len
   *   I4   - int* z-addr   (output vector)
   *   I5   - int  z-len
   */
  address generate_multiplyToLen() {
    assert(UseMultiplyToLenIntrinsic, "need VIS3 instructions");

    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "multiplyToLen");
    address start = __ pc();

    __ save_frame(0);

    const Register xptr = I0; // input address
    const Register xlen = I1; // ...and length in 32b-words
    const Register yptr = I2; //
    const Register ylen = I3; //
    const Register zptr = I4; // output address
    const Register zlen = I5; // ...and length in 32b-words

    /* The minimal "limb" representation suggest that odd length vectors are as
     * likely as even length dittos. This in turn suggests that we need to cope
     * with odd/even length arrays and data not aligned properly for 64-bit read
     * and write operations. We thus use a number of different kernels:
     *
     *   if (is_even(x.len) && is_even(y.len))
     *      if (is_align64(x) && is_align64(y) && is_align64(z))
     *         if (x.len == y.len && 16 <= x.len && x.len <= 64)
     *            memv_mult_mpmul(...)
     *         else
     *            memv_mult_64x64(...)
     *      else
     *         memv_mult_64x64u(...)
     *   else
     *      memv_mult_32x32(...)
     *
     * Here we assume VIS3 support (for 'umulxhi', 'addxc' and 'addxccc').
     * In case CBCOND instructions are supported, we will use 'cxbX'. If the
     * MPMUL instruction is supported, we will generate a kernel using 'mpmul'
     * (for vectors with proper characteristics).
     */
    const Register tmp0 = L0;
    const Register tmp1 = L1;

    Label L_mult_32x32;
    Label L_mult_64x64u;
    Label L_mult_64x64;
    Label L_exit;

    if_both_even(xlen, ylen, tmp0, false, L_mult_32x32);
    if_all3_aligned(xptr, yptr, zptr, tmp1, 64, false, L_mult_64x64u);

    if (UseMPMUL) {
      if_eq(xlen, ylen, false, L_mult_64x64);
      if_in_rng(xlen, 16, 64, tmp0, tmp1, false, L_mult_64x64);

      // 1. Multiply naturally aligned 64b-datums using a generic 'mpmul' kernel,
      //    operating on equal length vectors of size [16..64].
      gen_mult_mpmul(xlen, xptr, yptr, zptr, L_exit);
    }

    // 2. Multiply naturally aligned 64-bit datums (64x64).
    __ bind(L_mult_64x64);
    gen_mult_64x64(xptr, xlen, yptr, ylen, zptr, zlen, L_exit);

    // 3. Multiply unaligned 64-bit datums (64x64).
    __ bind(L_mult_64x64u);
    gen_mult_64x64_unaligned(xptr, xlen, yptr, ylen, zptr, zlen, L_exit);

    // 4. Multiply naturally aligned 32-bit datums (32x32).
    __ bind(L_mult_32x32);
    gen_mult_32x32(xptr, xlen, yptr, ylen, zptr, zlen, L_exit);

    __ bind(L_exit);
    __ ret();
    __ delayed()->restore();

    return start;
  }

  // Additional help functions used by multiplyToLen generation.

  void if_both_even(Register r1, Register r2, Register tmp, bool iseven, Label &L)
  {
    __ or3(r1, r2, tmp);
    __ andcc(tmp, 0x1, tmp);
    __ br_icc_zero(iseven, Assembler::pn, L);
  }

  void if_all3_aligned(Register r1, Register r2, Register r3,
                       Register tmp, uint align, bool isalign, Label &L)
  {
    __ or3(r1, r2, tmp);
    __ or3(r3, tmp, tmp);
    __ andcc(tmp, (align - 1), tmp);
    __ br_icc_zero(isalign, Assembler::pn, L);
  }

  void if_eq(Register x, Register y, bool iseq, Label &L)
  {
    Assembler::Condition cf = (iseq ? Assembler::equal : Assembler::notEqual);
    __ cmp_and_br_short(x, y, cf, Assembler::pt, L);
  }

  void if_in_rng(Register x, int lb, int ub, Register t1, Register t2, bool inrng, Label &L)
  {
    assert(Assembler::is_simm13(lb), "Small ints only!");
    assert(Assembler::is_simm13(ub), "Small ints only!");
    // Compute (x - lb) * (ub - x) >= 0
    // NOTE: With the local use of this routine, we rely on small integers to
    //       guarantee that we do not overflow in the multiplication.
    __ add(G0, ub, t2);
    __ sub(x, lb, t1);
    __ sub(t2, x, t2);
    __ mulx(t1, t2, t1);
    Assembler::Condition cf = (inrng ? Assembler::greaterEqual : Assembler::less);
    __ cmp_and_br_short(t1, G0, cf, Assembler::pt, L);
  }

  void ldd_entry(Register base, Register offs, FloatRegister dest)
  {
    __ ldd(base, offs, dest);
    __ inc(offs, 8);
  }

  void ldx_entry(Register base, Register offs, Register dest)
  {
    __ ldx(base, offs, dest);
    __ inc(offs, 8);
  }

  void mpmul_entry(int m, Label &next)
  {
    __ mpmul(m);
    __ cbcond(Assembler::equal, Assembler::icc, G0, G0, next);
  }

  void stx_entry(Label &L, Register r1, Register r2, Register base, Register offs)
  {
    __ bind(L);
    __ stx(r1, base, offs);
    __ inc(offs, 8);
    __ stx(r2, base, offs);
    __ inc(offs, 8);
  }

  void offs_entry(Label &Lbl0, Label &Lbl1)
  {
    assert(Lbl0.is_bound(), "must be");
    assert(Lbl1.is_bound(), "must be");

    int offset = Lbl0.loc_pos() - Lbl1.loc_pos();

    __ emit_data(offset);
  }

  /* Generate the actual multiplication kernels for BigInteger vectors:
   *
   *   1. gen_mult_mpmul(...)
   *
   *   2. gen_mult_64x64(...)
   *
   *   3. gen_mult_64x64_unaligned(...)
   *
   *   4. gen_mult_32x32(...)
   */
  void gen_mult_mpmul(Register len, Register xptr, Register yptr, Register zptr,
                      Label &L_exit)
  {
    const Register zero = G0;
    const Register gxp  = G1;   // Need to use global registers across RWs.
    const Register gyp  = G2;
    const Register gzp  = G3;
    const Register disp = G4;
    const Register offs = G5;

    __ mov(xptr, gxp);
    __ mov(yptr, gyp);
    __ mov(zptr, gzp);

    /* Compute jump vector entry:
     *
     *   1. mpmul input size (0..31) x 64b
     *   2. vector input size in 32b limbs (even number)
     *   3. branch entries in reverse order (31..0), using two
     *      instructions per entry (2 * 4 bytes).
     *
     *   displacement = byte_offset(bra_offset(len))
     *                = byte_offset((64 - len)/2)
     *                = 8 * (64 - len)/2
     *                = 4 * (64 - len)
     */
    Register temp = I5;         // Alright to use input regs. in first batch.

    __ sub(zero, len, temp);
    __ add(temp, 64, temp);
    __ sllx(temp, 2, disp);     // disp := (64 - len) << 2

    // Dispatch relative current PC, into instruction table below.
    __ rdpc(temp);
    __ add(temp, 16, temp);
    __ jmp(temp, disp);
    __ delayed()->clr(offs);

    ldd_entry(gxp, offs, F22);
    ldd_entry(gxp, offs, F20);
    ldd_entry(gxp, offs, F18);
    ldd_entry(gxp, offs, F16);
    ldd_entry(gxp, offs, F14);
    ldd_entry(gxp, offs, F12);
    ldd_entry(gxp, offs, F10);
    ldd_entry(gxp, offs, F8);
    ldd_entry(gxp, offs, F6);
    ldd_entry(gxp, offs, F4);
    ldx_entry(gxp, offs, I5);
    ldx_entry(gxp, offs, I4);
    ldx_entry(gxp, offs, I3);
    ldx_entry(gxp, offs, I2);
    ldx_entry(gxp, offs, I1);
    ldx_entry(gxp, offs, I0);
    ldx_entry(gxp, offs, L7);
    ldx_entry(gxp, offs, L6);
    ldx_entry(gxp, offs, L5);
    ldx_entry(gxp, offs, L4);
    ldx_entry(gxp, offs, L3);
    ldx_entry(gxp, offs, L2);
    ldx_entry(gxp, offs, L1);
    ldx_entry(gxp, offs, L0);
    ldd_entry(gxp, offs, F2);
    ldd_entry(gxp, offs, F0);
    ldx_entry(gxp, offs, O5);
    ldx_entry(gxp, offs, O4);
    ldx_entry(gxp, offs, O3);
    ldx_entry(gxp, offs, O2);
    ldx_entry(gxp, offs, O1);
    ldx_entry(gxp, offs, O0);

    __ save(SP, -176, SP);

    const Register addr = gxp;  // Alright to reuse 'gxp'.

    // Dispatch relative current PC, into instruction table below.
    __ rdpc(addr);
    __ add(addr, 16, addr);
    __ jmp(addr, disp);
    __ delayed()->clr(offs);

    ldd_entry(gyp, offs, F58);
    ldd_entry(gyp, offs, F56);
    ldd_entry(gyp, offs, F54);
    ldd_entry(gyp, offs, F52);
    ldd_entry(gyp, offs, F50);
    ldd_entry(gyp, offs, F48);
    ldd_entry(gyp, offs, F46);
    ldd_entry(gyp, offs, F44);
    ldd_entry(gyp, offs, F42);
    ldd_entry(gyp, offs, F40);
    ldd_entry(gyp, offs, F38);
    ldd_entry(gyp, offs, F36);
    ldd_entry(gyp, offs, F34);
    ldd_entry(gyp, offs, F32);
    ldd_entry(gyp, offs, F30);
    ldd_entry(gyp, offs, F28);
    ldd_entry(gyp, offs, F26);
    ldd_entry(gyp, offs, F24);
    ldx_entry(gyp, offs, O5);
    ldx_entry(gyp, offs, O4);
    ldx_entry(gyp, offs, O3);
    ldx_entry(gyp, offs, O2);
    ldx_entry(gyp, offs, O1);
    ldx_entry(gyp, offs, O0);
    ldx_entry(gyp, offs, L7);
    ldx_entry(gyp, offs, L6);
    ldx_entry(gyp, offs, L5);
    ldx_entry(gyp, offs, L4);
    ldx_entry(gyp, offs, L3);
    ldx_entry(gyp, offs, L2);
    ldx_entry(gyp, offs, L1);
    ldx_entry(gyp, offs, L0);

    __ save(SP, -176, SP);
    __ save(SP, -176, SP);
    __ save(SP, -176, SP);
    __ save(SP, -176, SP);
    __ save(SP, -176, SP);

    Label L_mpmul_restore_4, L_mpmul_restore_3, L_mpmul_restore_2;
    Label L_mpmul_restore_1, L_mpmul_restore_0;

    // Dispatch relative current PC, into instruction table below.
    __ rdpc(addr);
    __ add(addr, 16, addr);
    __ jmp(addr, disp);
    __ delayed()->clr(offs);

    mpmul_entry(31, L_mpmul_restore_0);
    mpmul_entry(30, L_mpmul_restore_0);
    mpmul_entry(29, L_mpmul_restore_0);
    mpmul_entry(28, L_mpmul_restore_0);
    mpmul_entry(27, L_mpmul_restore_1);
    mpmul_entry(26, L_mpmul_restore_1);
    mpmul_entry(25, L_mpmul_restore_1);
    mpmul_entry(24, L_mpmul_restore_1);
    mpmul_entry(23, L_mpmul_restore_1);
    mpmul_entry(22, L_mpmul_restore_1);
    mpmul_entry(21, L_mpmul_restore_1);
    mpmul_entry(20, L_mpmul_restore_2);
    mpmul_entry(19, L_mpmul_restore_2);
    mpmul_entry(18, L_mpmul_restore_2);
    mpmul_entry(17, L_mpmul_restore_2);
    mpmul_entry(16, L_mpmul_restore_2);
    mpmul_entry(15, L_mpmul_restore_2);
    mpmul_entry(14, L_mpmul_restore_2);
    mpmul_entry(13, L_mpmul_restore_3);
    mpmul_entry(12, L_mpmul_restore_3);
    mpmul_entry(11, L_mpmul_restore_3);
    mpmul_entry(10, L_mpmul_restore_3);
    mpmul_entry( 9, L_mpmul_restore_3);
    mpmul_entry( 8, L_mpmul_restore_3);
    mpmul_entry( 7, L_mpmul_restore_3);
    mpmul_entry( 6, L_mpmul_restore_4);
    mpmul_entry( 5, L_mpmul_restore_4);
    mpmul_entry( 4, L_mpmul_restore_4);
    mpmul_entry( 3, L_mpmul_restore_4);
    mpmul_entry( 2, L_mpmul_restore_4);
    mpmul_entry( 1, L_mpmul_restore_4);
    mpmul_entry( 0, L_mpmul_restore_4);

    Label L_z31, L_z30, L_z29, L_z28, L_z27, L_z26, L_z25, L_z24;
    Label L_z23, L_z22, L_z21, L_z20, L_z19, L_z18, L_z17, L_z16;
    Label L_z15, L_z14, L_z13, L_z12, L_z11, L_z10, L_z09, L_z08;
    Label L_z07, L_z06, L_z05, L_z04, L_z03, L_z02, L_z01, L_z00;

    Label L_zst_base;    // Store sequence base address.
    __ bind(L_zst_base);

    stx_entry(L_z31, L7, L6, gzp, offs);
    stx_entry(L_z30, L5, L4, gzp, offs);
    stx_entry(L_z29, L3, L2, gzp, offs);
    stx_entry(L_z28, L1, L0, gzp, offs);
    __ restore();
    stx_entry(L_z27, O5, O4, gzp, offs);
    stx_entry(L_z26, O3, O2, gzp, offs);
    stx_entry(L_z25, O1, O0, gzp, offs);
    stx_entry(L_z24, L7, L6, gzp, offs);
    stx_entry(L_z23, L5, L4, gzp, offs);
    stx_entry(L_z22, L3, L2, gzp, offs);
    stx_entry(L_z21, L1, L0, gzp, offs);
    __ restore();
    stx_entry(L_z20, O5, O4, gzp, offs);
    stx_entry(L_z19, O3, O2, gzp, offs);
    stx_entry(L_z18, O1, O0, gzp, offs);
    stx_entry(L_z17, L7, L6, gzp, offs);
    stx_entry(L_z16, L5, L4, gzp, offs);
    stx_entry(L_z15, L3, L2, gzp, offs);
    stx_entry(L_z14, L1, L0, gzp, offs);
    __ restore();
    stx_entry(L_z13, O5, O4, gzp, offs);
    stx_entry(L_z12, O3, O2, gzp, offs);
    stx_entry(L_z11, O1, O0, gzp, offs);
    stx_entry(L_z10, L7, L6, gzp, offs);
    stx_entry(L_z09, L5, L4, gzp, offs);
    stx_entry(L_z08, L3, L2, gzp, offs);
    stx_entry(L_z07, L1, L0, gzp, offs);
    __ restore();
    stx_entry(L_z06, O5, O4, gzp, offs);
    stx_entry(L_z05, O3, O2, gzp, offs);
    stx_entry(L_z04, O1, O0, gzp, offs);
    stx_entry(L_z03, L7, L6, gzp, offs);
    stx_entry(L_z02, L5, L4, gzp, offs);
    stx_entry(L_z01, L3, L2, gzp, offs);
    stx_entry(L_z00, L1, L0, gzp, offs);

    __ restore();
    __ restore();
    // Exit out of 'mpmul' routine, back to multiplyToLen.
    __ ba_short(L_exit);

    Label L_zst_offs;
    __ bind(L_zst_offs);

    offs_entry(L_z31, L_zst_base);  // index 31: 2048x2048
    offs_entry(L_z30, L_zst_base);
    offs_entry(L_z29, L_zst_base);
    offs_entry(L_z28, L_zst_base);
    offs_entry(L_z27, L_zst_base);
    offs_entry(L_z26, L_zst_base);
    offs_entry(L_z25, L_zst_base);
    offs_entry(L_z24, L_zst_base);
    offs_entry(L_z23, L_zst_base);
    offs_entry(L_z22, L_zst_base);
    offs_entry(L_z21, L_zst_base);
    offs_entry(L_z20, L_zst_base);
    offs_entry(L_z19, L_zst_base);
    offs_entry(L_z18, L_zst_base);
    offs_entry(L_z17, L_zst_base);
    offs_entry(L_z16, L_zst_base);
    offs_entry(L_z15, L_zst_base);
    offs_entry(L_z14, L_zst_base);
    offs_entry(L_z13, L_zst_base);
    offs_entry(L_z12, L_zst_base);
    offs_entry(L_z11, L_zst_base);
    offs_entry(L_z10, L_zst_base);
    offs_entry(L_z09, L_zst_base);
    offs_entry(L_z08, L_zst_base);
    offs_entry(L_z07, L_zst_base);
    offs_entry(L_z06, L_zst_base);
    offs_entry(L_z05, L_zst_base);
    offs_entry(L_z04, L_zst_base);
    offs_entry(L_z03, L_zst_base);
    offs_entry(L_z02, L_zst_base);
    offs_entry(L_z01, L_zst_base);
    offs_entry(L_z00, L_zst_base);  // index  0:   64x64

    __ bind(L_mpmul_restore_4);
    __ restore();
    __ bind(L_mpmul_restore_3);
    __ restore();
    __ bind(L_mpmul_restore_2);
    __ restore();
    __ bind(L_mpmul_restore_1);
    __ restore();
    __ bind(L_mpmul_restore_0);

    // Dispatch via offset vector entry, into z-store sequence.
    Label L_zst_rdpc;
    __ bind(L_zst_rdpc);

    assert(L_zst_base.is_bound(), "must be");
    assert(L_zst_offs.is_bound(), "must be");
    assert(L_zst_rdpc.is_bound(), "must be");

    int dbase = L_zst_rdpc.loc_pos() - L_zst_base.loc_pos();
    int doffs = L_zst_rdpc.loc_pos() - L_zst_offs.loc_pos();

    temp = gyp;   // Alright to reuse 'gyp'.

    __ rdpc(addr);
    __ sub(addr, doffs, temp);
    __ srlx(disp, 1, disp);
    __ lduw(temp, disp, offs);
    __ sub(addr, dbase, temp);
    __ jmp(temp, offs);
    __ delayed()->clr(offs);
  }

  void gen_mult_64x64(Register xp, Register xn,
                      Register yp, Register yn,
                      Register zp, Register zn, Label &L_exit)
  {
    // Assuming that a stack frame has already been created, i.e. local and
    // output registers are available for immediate use.

    const Register ri = L0;     // Outer loop index, xv[i]
    const Register rj = L1;     // Inner loop index, yv[j]
    const Register rk = L2;     // Output loop index, zv[k]
    const Register rx = L4;     // x-vector datum [i]
    const Register ry = L5;     // y-vector datum [j]
    const Register rz = L6;     // z-vector datum [k]
    const Register rc = L7;     // carry over (to z-vector datum [k-1])

    const Register lop = O0;    // lo-64b product
    const Register hip = O1;    // hi-64b product

    const Register zero = G0;

    Label L_loop_i,  L_exit_loop_i;
    Label L_loop_j;
    Label L_loop_i2, L_exit_loop_i2;

    __ srlx(xn, 1, xn);         // index for u32 to u64 ditto
    __ srlx(yn, 1, yn);         // index for u32 to u64 ditto
    __ srlx(zn, 1, zn);         // index for u32 to u64 ditto
    __ dec(xn);                 // Adjust [0..(N/2)-1]
    __ dec(yn);
    __ dec(zn);
    __ clr(rc);                 // u64 c = 0
    __ sllx(xn, 3, ri);         // int i = xn (byte offset i = 8*xn)
    __ sllx(yn, 3, rj);         // int j = yn (byte offset i = 8*xn)
    __ sllx(zn, 3, rk);         // int k = zn (byte offset k = 8*zn)
    __ ldx(yp, rj, ry);         // u64 y = yp[yn]

    // for (int i = xn; i >= 0; i--)
    __ bind(L_loop_i);

    __ cmp_and_br_short(ri, 0,  // i >= 0
                        Assembler::less, Assembler::pn, L_exit_loop_i);
    __ ldx(xp, ri, rx);         // x = xp[i]
    __ mulx(rx, ry, lop);       // lo-64b-part of result 64x64
    __ umulxhi(rx, ry, hip);    // hi-64b-part of result 64x64
    __ addcc(rc, lop, lop);     // Accumulate lower order bits (producing carry)
    __ addxc(hip, zero, rc);    // carry over to next datum [k-1]
    __ stx(lop, zp, rk);        // z[k] = lop
    __ dec(rk, 8);              // k--
    __ dec(ri, 8);              // i--
    __ ba_short(L_loop_i);

    __ bind(L_exit_loop_i);
    __ stx(rc, zp, rk);         // z[k] = c

    // for (int j = yn - 1; j >= 0; j--)
    __ sllx(yn, 3, rj);         // int j = yn - 1 (byte offset j = 8*yn)
    __ dec(rj, 8);

    __ bind(L_loop_j);

    __ cmp_and_br_short(rj, 0,  // j >= 0
                        Assembler::less, Assembler::pn, L_exit);
    __ clr(rc);                 // u64 c = 0
    __ ldx(yp, rj, ry);         // u64 y = yp[j]

    // for (int i = xn, k = --zn; i >= 0; i--)
    __ dec(zn);                 // --zn
    __ sllx(xn, 3, ri);         // int i = xn (byte offset i = 8*xn)
    __ sllx(zn, 3, rk);         // int k = zn (byte offset k = 8*zn)

    __ bind(L_loop_i2);

    __ cmp_and_br_short(ri, 0,  // i >= 0
                        Assembler::less, Assembler::pn, L_exit_loop_i2);
    __ ldx(xp, ri, rx);         // x = xp[i]
    __ ldx(zp, rk, rz);         // z = zp[k], accumulator
    __ mulx(rx, ry, lop);       // lo-64b-part of result 64x64
    __ umulxhi(rx, ry, hip);    // hi-64b-part of result 64x64
    __ addcc(rz, rc, rz);       // Accumulate lower order bits,
    __ addxc(hip, zero, rc);    // Accumulate higher order bits to carry
    __ addcc(rz, lop, rz);      //    z += lo(p) + c
    __ addxc(rc, zero, rc);
    __ stx(rz, zp, rk);         // zp[k] = z
    __ dec(rk, 8);              // k--
    __ dec(ri, 8);              // i--
    __ ba_short(L_loop_i2);

    __ bind(L_exit_loop_i2);
    __ stx(rc, zp, rk);         // z[k] = c
    __ dec(rj, 8);              // j--
    __ ba_short(L_loop_j);
  }

  void gen_mult_64x64_unaligned(Register xp, Register xn,
                                Register yp, Register yn,
                                Register zp, Register zn, Label &L_exit)
  {
    // Assuming that a stack frame has already been created, i.e. local and
    // output registers are available for use.

    const Register xpc = L0;    // Outer loop cursor, xp[i]
    const Register ypc = L1;    // Inner loop cursor, yp[j]
    const Register zpc = L2;    // Output loop cursor, zp[k]
    const Register rx  = L4;    // x-vector datum [i]
    const Register ry  = L5;    // y-vector datum [j]
    const Register rz  = L6;    // z-vector datum [k]
    const Register rc  = L7;    // carry over (to z-vector datum [k-1])
    const Register rt  = O2;

    const Register lop = O0;    // lo-64b product
    const Register hip = O1;    // hi-64b product

    const Register zero = G0;

    Label L_loop_i,  L_exit_loop_i;
    Label L_loop_j;
    Label L_loop_i2, L_exit_loop_i2;

    __ srlx(xn, 1, xn);         // index for u32 to u64 ditto
    __ srlx(yn, 1, yn);         // index for u32 to u64 ditto
    __ srlx(zn, 1, zn);         // index for u32 to u64 ditto
    __ dec(xn);                 // Adjust [0..(N/2)-1]
    __ dec(yn);
    __ dec(zn);
    __ clr(rc);                 // u64 c = 0
    __ sllx(xn, 3, xpc);        // u32* xpc = &xp[xn] (byte offset 8*xn)
    __ add(xp, xpc, xpc);
    __ sllx(yn, 3, ypc);        // u32* ypc = &yp[yn] (byte offset 8*yn)
    __ add(yp, ypc, ypc);
    __ sllx(zn, 3, zpc);        // u32* zpc = &zp[zn] (byte offset 8*zn)
    __ add(zp, zpc, zpc);
    __ lduw(ypc, 0, rt);        // u64 y = yp[yn]
    __ lduw(ypc, 4, ry);        //   ...
    __ sllx(rt, 32, rt);
    __ or3(rt, ry, ry);

    // for (int i = xn; i >= 0; i--)
    __ bind(L_loop_i);

    __ cmp_and_brx_short(xpc, xp,// i >= 0
                         Assembler::lessUnsigned, Assembler::pn, L_exit_loop_i);
    __ lduw(xpc, 0, rt);        // u64 x = xp[i]
    __ lduw(xpc, 4, rx);        //   ...
    __ sllx(rt, 32, rt);
    __ or3(rt, rx, rx);
    __ mulx(rx, ry, lop);       // lo-64b-part of result 64x64
    __ umulxhi(rx, ry, hip);    // hi-64b-part of result 64x64
    __ addcc(rc, lop, lop);     // Accumulate lower order bits (producing carry)
    __ addxc(hip, zero, rc);    // carry over to next datum [k-1]
    __ srlx(lop, 32, rt);
    __ stw(rt, zpc, 0);         // z[k] = lop
    __ stw(lop, zpc, 4);        //   ...
    __ dec(zpc, 8);             // k-- (zpc--)
    __ dec(xpc, 8);             // i-- (xpc--)
    __ ba_short(L_loop_i);

    __ bind(L_exit_loop_i);
    __ srlx(rc, 32, rt);
    __ stw(rt, zpc, 0);         // z[k] = c
    __ stw(rc, zpc, 4);

    // for (int j = yn - 1; j >= 0; j--)
    __ sllx(yn, 3, ypc);        // u32* ypc = &yp[yn] (byte offset 8*yn)
    __ add(yp, ypc, ypc);
    __ dec(ypc, 8);             // yn - 1 (ypc--)

    __ bind(L_loop_j);

    __ cmp_and_brx_short(ypc, yp,// j >= 0
                         Assembler::lessUnsigned, Assembler::pn, L_exit);
    __ clr(rc);                 // u64 c = 0
    __ lduw(ypc, 0, rt);        // u64 y = yp[j] (= *ypc)
    __ lduw(ypc, 4, ry);        //   ...
    __ sllx(rt, 32, rt);
    __ or3(rt, ry, ry);

    // for (int i = xn, k = --zn; i >= 0; i--)
    __ sllx(xn, 3, xpc);        // u32* xpc = &xp[xn] (byte offset 8*xn)
    __ add(xp, xpc, xpc);
    __ dec(zn);                 // --zn
    __ sllx(zn, 3, zpc);        // u32* zpc = &zp[zn] (byte offset 8*zn)
    __ add(zp, zpc, zpc);

    __ bind(L_loop_i2);

    __ cmp_and_brx_short(xpc, xp,// i >= 0
                         Assembler::lessUnsigned, Assembler::pn, L_exit_loop_i2);
    __ lduw(xpc, 0, rt);        // u64 x = xp[i] (= *xpc)
    __ lduw(xpc, 4, rx);        //   ...
    __ sllx(rt, 32, rt);
    __ or3(rt, rx, rx);

    __ lduw(zpc, 0, rt);        // u64 z = zp[k] (= *zpc)
    __ lduw(zpc, 4, rz);        //   ...
    __ sllx(rt, 32, rt);
    __ or3(rt, rz, rz);

    __ mulx(rx, ry, lop);       // lo-64b-part of result 64x64
    __ umulxhi(rx, ry, hip);    // hi-64b-part of result 64x64
    __ addcc(rz, rc, rz);       // Accumulate lower order bits...
    __ addxc(hip, zero, rc);    // Accumulate higher order bits to carry
    __ addcc(rz, lop, rz);      // ... z += lo(p) + c
    __ addxccc(rc, zero, rc);
    __ srlx(rz, 32, rt);
    __ stw(rt, zpc, 0);         // zp[k] = z    (*zpc = z)
    __ stw(rz, zpc, 4);
    __ dec(zpc, 8);             // k-- (zpc--)
    __ dec(xpc, 8);             // i-- (xpc--)
    __ ba_short(L_loop_i2);

    __ bind(L_exit_loop_i2);
    __ srlx(rc, 32, rt);
    __ stw(rt, zpc, 0);         // z[k] = c
    __ stw(rc, zpc, 4);
    __ dec(ypc, 8);             // j-- (ypc--)
    __ ba_short(L_loop_j);
  }

  void gen_mult_32x32(Register xp, Register xn,
                      Register yp, Register yn,
                      Register zp, Register zn, Label &L_exit)
  {
    // Assuming that a stack frame has already been created, i.e. local and
    // output registers are available for use.

    const Register ri = L0;     // Outer loop index, xv[i]
    const Register rj = L1;     // Inner loop index, yv[j]
    const Register rk = L2;     // Output loop index, zv[k]
    const Register rx = L4;     // x-vector datum [i]
    const Register ry = L5;     // y-vector datum [j]
    const Register rz = L6;     // z-vector datum [k]
    const Register rc = L7;     // carry over (to z-vector datum [k-1])

    const Register p64 = O0;    // 64b product
    const Register z65 = O1;    // carry+64b accumulator
    const Register c65 = O2;    // carry at bit 65
    const Register c33 = O2;    // carry at bit 33 (after shift)

    const Register zero = G0;

    Label L_loop_i,  L_exit_loop_i;
    Label L_loop_j;
    Label L_loop_i2, L_exit_loop_i2;

    __ dec(xn);                 // Adjust [0..N-1]
    __ dec(yn);
    __ dec(zn);
    __ clr(rc);                 // u32 c = 0
    __ sllx(xn, 2, ri);         // int i = xn (byte offset i = 4*xn)
    __ sllx(yn, 2, rj);         // int j = yn (byte offset i = 4*xn)
    __ sllx(zn, 2, rk);         // int k = zn (byte offset k = 4*zn)
    __ lduw(yp, rj, ry);        // u32 y = yp[yn]

    // for (int i = xn; i >= 0; i--)
    __ bind(L_loop_i);

    __ cmp_and_br_short(ri, 0,  // i >= 0
                        Assembler::less, Assembler::pn, L_exit_loop_i);
    __ lduw(xp, ri, rx);        // x = xp[i]
    __ mulx(rx, ry, p64);       // 64b result of 32x32
    __ addcc(rc, p64, z65);     // Accumulate to 65 bits (producing carry)
    __ addxc(zero, zero, c65);  // Materialise carry (in bit 65) into lsb,
    __ sllx(c65, 32, c33);      // and shift into bit 33
    __ srlx(z65, 32, rc);       // carry = c33 | hi(z65) >> 32
    __ add(c33, rc, rc);        // carry over to next datum [k-1]
    __ stw(z65, zp, rk);        // z[k] = lo(z65)
    __ dec(rk, 4);              // k--
    __ dec(ri, 4);              // i--
    __ ba_short(L_loop_i);

    __ bind(L_exit_loop_i);
    __ stw(rc, zp, rk);         // z[k] = c

    // for (int j = yn - 1; j >= 0; j--)
    __ sllx(yn, 2, rj);         // int j = yn - 1 (byte offset j = 4*yn)
    __ dec(rj, 4);

    __ bind(L_loop_j);

    __ cmp_and_br_short(rj, 0,  // j >= 0
                        Assembler::less, Assembler::pn, L_exit);
    __ clr(rc);                 // u32 c = 0
    __ lduw(yp, rj, ry);        // u32 y = yp[j]

    // for (int i = xn, k = --zn; i >= 0; i--)
    __ dec(zn);                 // --zn
    __ sllx(xn, 2, ri);         // int i = xn (byte offset i = 4*xn)
    __ sllx(zn, 2, rk);         // int k = zn (byte offset k = 4*zn)

    __ bind(L_loop_i2);

    __ cmp_and_br_short(ri, 0,  // i >= 0
                        Assembler::less, Assembler::pn, L_exit_loop_i2);
    __ lduw(xp, ri, rx);        // x = xp[i]
    __ lduw(zp, rk, rz);        // z = zp[k], accumulator
    __ mulx(rx, ry, p64);       // 64b result of 32x32
    __ add(rz, rc, rz);         // Accumulate lower order bits,
    __ addcc(rz, p64, z65);     //   z += lo(p64) + c
    __ addxc(zero, zero, c65);  // Materialise carry (in bit 65) into lsb,
    __ sllx(c65, 32, c33);      // and shift into bit 33
    __ srlx(z65, 32, rc);       // carry = c33 | hi(z65) >> 32
    __ add(c33, rc, rc);        // carry over to next datum [k-1]
    __ stw(z65, zp, rk);        // zp[k] = lo(z65)
    __ dec(rk, 4);              // k--
    __ dec(ri, 4);              // i--
    __ ba_short(L_loop_i2);

    __ bind(L_exit_loop_i2);
    __ stw(rc, zp, rk);         // z[k] = c
    __ dec(rj, 4);              // j--
    __ ba_short(L_loop_j);
  }


  void generate_initial() {
    // Generates all stubs and initializes the entry points

    //------------------------------------------------------------------------------------------------------------------------
    // entry points that exist in all platforms
    // Note: This is code that could be shared among different platforms - however the benefit seems to be smaller than
    //       the disadvantage of having a much more complicated generator structure. See also comment in stubRoutines.hpp.
    StubRoutines::_forward_exception_entry                 = generate_forward_exception();

    StubRoutines::_call_stub_entry                         = generate_call_stub(StubRoutines::_call_stub_return_address);
    StubRoutines::_catch_exception_entry                   = generate_catch_exception();

    //------------------------------------------------------------------------------------------------------------------------
    // entry points that are platform specific
    StubRoutines::Sparc::_test_stop_entry                  = generate_test_stop();

    StubRoutines::Sparc::_stop_subroutine_entry            = generate_stop_subroutine();
    StubRoutines::Sparc::_flush_callers_register_windows_entry = generate_flush_callers_register_windows();

    // Build this early so it's available for the interpreter.
    StubRoutines::_throw_StackOverflowError_entry =
            generate_throw_exception("StackOverflowError throw_exception",
            CAST_FROM_FN_PTR(address, SharedRuntime::throw_StackOverflowError));
    StubRoutines::_throw_delayed_StackOverflowError_entry =
            generate_throw_exception("delayed StackOverflowError throw_exception",
            CAST_FROM_FN_PTR(address, SharedRuntime::throw_delayed_StackOverflowError));

    if (UseCRC32Intrinsics) {
      // set table address before stub generation which use it
      StubRoutines::_crc_table_adr = (address)StubRoutines::Sparc::_crc_table;
      StubRoutines::_updateBytesCRC32 = generate_updateBytesCRC32();
    }

    if (UseCRC32CIntrinsics) {
      // set table address before stub generation which use it
      StubRoutines::_crc32c_table_addr = (address)StubRoutines::Sparc::_crc32c_table;
      StubRoutines::_updateBytesCRC32C = generate_updateBytesCRC32C();
    }
  }


  void generate_all() {
    // Generates all stubs and initializes the entry points

    // Generate partial_subtype_check first here since its code depends on
    // UseZeroBaseCompressedOops which is defined after heap initialization.
    StubRoutines::Sparc::_partial_subtype_check                = generate_partial_subtype_check();
    // These entry points require SharedInfo::stack0 to be set up in non-core builds
    StubRoutines::_throw_AbstractMethodError_entry         = generate_throw_exception("AbstractMethodError throw_exception",          CAST_FROM_FN_PTR(address, SharedRuntime::throw_AbstractMethodError));
    StubRoutines::_throw_IncompatibleClassChangeError_entry= generate_throw_exception("IncompatibleClassChangeError throw_exception", CAST_FROM_FN_PTR(address, SharedRuntime::throw_IncompatibleClassChangeError));
    StubRoutines::_throw_NullPointerException_at_call_entry= generate_throw_exception("NullPointerException at call throw_exception", CAST_FROM_FN_PTR(address, SharedRuntime::throw_NullPointerException_at_call));

    // support for verify_oop (must happen after universe_init)
    StubRoutines::_verify_oop_subroutine_entry     = generate_verify_oop_subroutine();

    // arraycopy stubs used by compilers
    generate_arraycopy_stubs();

    // Don't initialize the platform math functions since sparc
    // doesn't have intrinsics for these operations.

    // Safefetch stubs.
    generate_safefetch("SafeFetch32", sizeof(int),     &StubRoutines::_safefetch32_entry,
                                                       &StubRoutines::_safefetch32_fault_pc,
                                                       &StubRoutines::_safefetch32_continuation_pc);
    generate_safefetch("SafeFetchN", sizeof(intptr_t), &StubRoutines::_safefetchN_entry,
                                                       &StubRoutines::_safefetchN_fault_pc,
                                                       &StubRoutines::_safefetchN_continuation_pc);

    // generate AES intrinsics code
    if (UseAESIntrinsics) {
      StubRoutines::_aescrypt_encryptBlock = generate_aescrypt_encryptBlock();
      StubRoutines::_aescrypt_decryptBlock = generate_aescrypt_decryptBlock();
      StubRoutines::_cipherBlockChaining_encryptAESCrypt = generate_cipherBlockChaining_encryptAESCrypt();
      StubRoutines::_cipherBlockChaining_decryptAESCrypt = generate_cipherBlockChaining_decryptAESCrypt_Parallel();
    }
    // generate GHASH intrinsics code
    if (UseGHASHIntrinsics) {
      StubRoutines::_ghash_processBlocks = generate_ghash_processBlocks();
    }

    // generate SHA1/SHA256/SHA512 intrinsics code
    if (UseSHA1Intrinsics) {
      StubRoutines::_sha1_implCompress     = generate_sha1_implCompress(false,   "sha1_implCompress");
      StubRoutines::_sha1_implCompressMB   = generate_sha1_implCompress(true,    "sha1_implCompressMB");
    }
    if (UseSHA256Intrinsics) {
      StubRoutines::_sha256_implCompress   = generate_sha256_implCompress(false, "sha256_implCompress");
      StubRoutines::_sha256_implCompressMB = generate_sha256_implCompress(true,  "sha256_implCompressMB");
    }
    if (UseSHA512Intrinsics) {
      StubRoutines::_sha512_implCompress   = generate_sha512_implCompress(false, "sha512_implCompress");
      StubRoutines::_sha512_implCompressMB = generate_sha512_implCompress(true,  "sha512_implCompressMB");
    }
    // generate Adler32 intrinsics code
    if (UseAdler32Intrinsics) {
      StubRoutines::_updateBytesAdler32 = generate_updateBytesAdler32();
    }

#ifdef COMPILER2
    // Intrinsics supported by C2 only:
    if (UseMultiplyToLenIntrinsic) {
      StubRoutines::_multiplyToLen = generate_multiplyToLen();
    }
#endif // COMPILER2
  }

 public:
  StubGenerator(CodeBuffer* code, bool all) : StubCodeGenerator(code) {
    // replace the standard masm with a special one:
    _masm = new MacroAssembler(code);

    _stub_count = !all ? 0x100 : 0x200;
    if (all) {
      generate_all();
    } else {
      generate_initial();
    }

    // make sure this stub is available for all local calls
    if (_atomic_add_stub.is_unbound()) {
      // generate a second time, if necessary
      (void) generate_atomic_add();
    }
  }


 private:
  int _stub_count;
  void stub_prolog(StubCodeDesc* cdesc) {
    # ifdef ASSERT
      // put extra information in the stub code, to make it more readable
      // Write the high part of the address
      // [RGV] Check if there is a dependency on the size of this prolog
      __ emit_data((intptr_t)cdesc >> 32,    relocInfo::none);
      __ emit_data((intptr_t)cdesc,    relocInfo::none);
      __ emit_data(++_stub_count, relocInfo::none);
    # endif
    align(true);
  }

  void align(bool at_header = false) {
    // %%%%% move this constant somewhere else
    // UltraSPARC cache line size is 8 instructions:
    const unsigned int icache_line_size = 32;
    const unsigned int icache_half_line_size = 16;

    if (at_header) {
      while ((intptr_t)(__ pc()) % icache_line_size != 0) {
        __ emit_data(0, relocInfo::none);
      }
    } else {
      while ((intptr_t)(__ pc()) % icache_half_line_size != 0) {
        __ nop();
      }
    }
  }

}; // end class declaration

void StubGenerator_generate(CodeBuffer* code, bool all) {
  StubGenerator g(code, all);
}