stubGenerator_sparc.cpp 150.6 KB
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/*
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 * Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
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 * 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.
 *
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 * 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.
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 *
 */

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#include "precompiled.hpp"
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#include "asm/macroAssembler.inline.hpp"
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#include "interpreter/interpreter.hpp"
#include "nativeInst_sparc.hpp"
#include "oops/instanceOop.hpp"
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#include "oops/method.hpp"
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#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"
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#include "runtime/thread.inline.hpp"
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#include "utilities/top.hpp"
#ifdef COMPILER2
#include "opto/runtime.hpp"
#endif
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// 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

static address handle_unsafe_access() {
  JavaThread* thread = JavaThread::current();
  address pc  = thread->saved_exception_pc();
  address npc = thread->saved_exception_npc();
  // pc is the instruction which we must emulate
  // doing a no-op is fine:  return garbage from the load

  // request an async exception
  thread->set_pending_unsafe_access_error();

  // return address of next instruction to execute
  return npc;
}

class StubGenerator: public StubCodeGenerator {
 private:

#ifdef PRODUCT
#define inc_counter_np(a,b,c) (0)
#else
#define inc_counter_np(counter, t1, t2) \
  BLOCK_COMMENT("inc_counter " #counter); \
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  __ inc_counter(&counter, t1, t2);
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#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);
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    __ reinit_heapbase();
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#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);
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      __ br_null_short(t, Assembler::pt, L);
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      __ 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)
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      __ sll(t, Interpreter::logStackElementSize, t);           // compute number of bytes
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      __ 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 );
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      __ cmp_zero_and_br(Assembler::zero, cnt, exit);
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      __ 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);
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      __ st_ptr(tmp, dst, 0);
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      __ deccc(cnt);
      __ br(Assembler::greater, false, Assembler::pt, loop);
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      __ delayed()->sub(dst, Interpreter::stackElementSize, dst);
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      // 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)
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    __ sll(t, Interpreter::logStackElementSize, t);    // compute number of bytes
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    __ sub(FP, t, Gargs);                              // setup parameter pointer
#ifdef _LP64
    __ add( Gargs, STACK_BIAS, Gargs );                // Account for LP64 stack bias
#endif
    __ 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);
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      __ ba(exit);
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      __ delayed()->st_ptr(O0, addr, G0);

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

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

      __ BIND(is_long);
#ifdef _LP64
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      __ ba(exit);
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      __ delayed()->st_long(O0, addr, G0);      // store entire long
#else
#if defined(COMPILER2)
  // All return values are where we want them, except for Longs.  C2 returns
  // longs in G1 in the 32-bit build whereas the interpreter wants them in O0/O1.
  // Since the interpreter will return longs in G1 and O0/O1 in the 32bit
  // build we simply always use G1.
  // Note: I tried to make c2 return longs in O0/O1 and G1 so we wouldn't have to
  // do this here. Unfortunately if we did a rethrow we'd see an machepilog node
  // first which would move g1 -> O0/O1 and destroy the exception we were throwing.

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      __ ba(exit);
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      __ delayed()->stx(G1, addr, G0);  // store entire long
#else
      __ st(O1, addr, BytesPerInt);
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      __ ba(exit);
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      __ delayed()->st(O0, addr, G0);
#endif /* COMPILER2 */
#endif /* _LP64 */
     }
     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;
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    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   ());
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    // 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");

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    AddressLiteral stub_ret(StubRoutines::_call_stub_return_address);
    __ jump_to(stub_ret, temp_reg);
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    __ 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;

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    Address exception_addr(G2_thread, Thread::pending_exception_offset());
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#ifdef ASSERT
    // make sure that this code is only executed if there is a pending exception
    { Label L;
      __ ld_ptr(exception_addr, Gtemp);
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      __ br_notnull_short(Gtemp, Assembler::pt, L);
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      __ 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");
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    __ call_VM_leaf(L7_thread_cache, CAST_FROM_FN_PTR(address, SharedRuntime::exception_handler_for_return_address), G2_thread, Lscratch);
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    __ 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;
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      __ br_notnull_short(Oexception, Assembler::pt, L);
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      __ 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;
  }

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  // 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();
  }
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  //------------------------------------------------------------------------------------------------------------------------
  // 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->

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  address generate_throw_exception(const char* name, address runtime_entry,
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                                   Register arg1 = noreg, Register arg2 = noreg) {
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#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);
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    if (arg1 != noreg) {
      assert(arg2 != O1, "clobbered");
      __ mov(arg1, O1);
    }
    if (arg2 != noreg) {
      __ mov(arg2, O2);
    }
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    // 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;

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    Address exception_addr(G2_thread, Thread::pending_exception_offset());
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    Register scratch_reg = Gtemp;
    __ ld_ptr(exception_addr, scratch_reg);
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    __ br_notnull_short(scratch_reg, Assembler::pt, L);
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    __ 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();

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    __ flushw();
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    __ 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).
  //
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  // Arguments:
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  //
  //      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
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      __ cas(O1, O2, O3);
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      __ cmp_and_br_short(O2, O3, Assembler::notEqual, Assembler::pn, retry);
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      __ retl(false);
      __ delayed()->mov(O2, O0);  // report previous value to caller
    } else {
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      __ retl(false);
      __ delayed()->swap(O1, 0, O0);
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    }

    return start;
  }


  // Support for jint Atomic::cmpxchg(jint exchange_value, volatile jint* dest, jint compare_value)
  //
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  // Arguments:
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  //
  //      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)
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    __ cas(O1, O2, O0);
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    __ retl(false);
    __ delayed()->nop();

    return start;
  }

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

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    Label(retry);
    __ BIND(retry);
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    __ 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
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    return start;
  }
  Label _atomic_add_stub;  // called from other stubs


  //------------------------------------------------------------------------------------------------------------------------
  // The following routine generates a subroutine to throw an asynchronous
  // UnknownError when an unsafe access gets a fault that could not be
  // reasonably prevented by the programmer.  (Example: SIGBUS/OBJERR.)
  //
  // Arguments :
  //
  //      trapping PC:    O7
  //
  // Results:
  //     posts an asynchronous exception, skips the trapping instruction
  //

  address generate_handler_for_unsafe_access() {
    StubCodeMark mark(this, "StubRoutines", "handler_for_unsafe_access");
    address start = __ pc();

    const int preserve_register_words = (64 * 2);
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    Address preserve_addr(FP, (-preserve_register_words * wordSize) + STACK_BIAS);
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    Register Lthread = L7_thread_cache;
    int i;

    __ save_frame(0);
    __ mov(G1, L1);
    __ mov(G2, L2);
    __ mov(G3, L3);
    __ mov(G4, L4);
    __ mov(G5, L5);
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    for (i = 0; i < 64; i += 2) {
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      __ stf(FloatRegisterImpl::D, as_FloatRegister(i), preserve_addr, i * wordSize);
    }

    address entry_point = CAST_FROM_FN_PTR(address, handle_unsafe_access);
    BLOCK_COMMENT("call handle_unsafe_access");
    __ call(entry_point, relocInfo::runtime_call_type);
    __ delayed()->nop();

    __ mov(L1, G1);
    __ mov(L2, G2);
    __ mov(L3, G3);
    __ mov(L4, G4);
    __ mov(L5, G5);
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    for (i = 0; i < 64; i += 2) {
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      __ ldf(FloatRegisterImpl::D, preserve_addr, as_FloatRegister(i), i * wordSize);
    }

    __ verify_thread();

    __ jmp(O0, 0);
    __ delayed()->restore();

    return start;
  }


  // 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() {
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    __ align(CodeEntryAlignment);
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    StubCodeMark mark(this, "StubRoutines", "partial_subtype_check");
    address start = __ pc();
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    Label miss;
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#if defined(COMPILER2) && !defined(_LP64)
    // Do not use a 'save' because it blows the 64-bit O registers.
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    __ add(SP,-4*wordSize,SP);  // Make space for 4 temps (stack must be 2 words aligned)
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    __ st_ptr(L0,SP,(frame::register_save_words+0)*wordSize);
    __ st_ptr(L1,SP,(frame::register_save_words+1)*wordSize);
    __ st_ptr(L2,SP,(frame::register_save_words+2)*wordSize);
    __ st_ptr(L3,SP,(frame::register_save_words+3)*wordSize);
    Register Rret   = O0;
    Register Rsub   = O1;
    Register Rsuper = O2;
#else
    __ save_frame(0);
    Register Rret   = I0;
    Register Rsub   = I1;
    Register Rsuper = I2;
#endif

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

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    __ check_klass_subtype_slow_path(Rsub, Rsuper,
                                     L0, L1, L2, L3,
                                     NULL, &miss);
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    // Match falls through here.
    __ addcc(G0,0,Rret);        // set Z flags, Z result
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#if defined(COMPILER2) && !defined(_LP64)
    __ ld_ptr(SP,(frame::register_save_words+0)*wordSize,L0);
    __ ld_ptr(SP,(frame::register_save_words+1)*wordSize,L1);
    __ ld_ptr(SP,(frame::register_save_words+2)*wordSize,L2);
    __ ld_ptr(SP,(frame::register_save_words+3)*wordSize,L3);
    __ retl();                  // Result in Rret is zero; flags set to Z
    __ delayed()->add(SP,4*wordSize,SP);
#else
    __ ret();                   // Result in Rret is zero; flags set to Z
    __ delayed()->restore();
#endif

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

#if defined(COMPILER2) && !defined(_LP64)
    __ ld_ptr(SP,(frame::register_save_words+0)*wordSize,L0);
    __ ld_ptr(SP,(frame::register_save_words+1)*wordSize,L1);
    __ ld_ptr(SP,(frame::register_save_words+2)*wordSize,L2);
    __ ld_ptr(SP,(frame::register_save_words+3)*wordSize,L3);
    __ retl();                  // Result in Rret is != 0; flags set to NZ
    __ delayed()->add(SP,4*wordSize,SP);
#else
    __ ret();                   // Result in Rret is != 0; flags set to NZ
    __ delayed()->restore();
#endif

    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) && defined(_LP64)
    __ 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)
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        __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, no_overlap_target);
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      else
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        __ brx(Assembler::greaterEqualUnsigned, false, Assembler::pt, (*NOLp));
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      __ delayed()->nop();
  }

  //
  //  Generate pre-write barrier for array.
  //
  //  Input:
  //     addr     - register containing starting address
  //     count    - register containing element count
  //     tmp      - scratch register
  //
  //  The input registers are overwritten.
  //
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  void gen_write_ref_array_pre_barrier(Register addr, Register count, bool dest_uninitialized) {
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    BarrierSet* bs = Universe::heap()->barrier_set();
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    switch (bs->kind()) {
      case BarrierSet::G1SATBCT:
      case BarrierSet::G1SATBCTLogging:
        // With G1, don't generate the call if we statically know that the target in uninitialized
        if (!dest_uninitialized) {
          __ save_frame(0);
          // Save the necessary global regs... will be used after.
          if (addr->is_global()) {
            __ mov(addr, L0);
          }
          if (count->is_global()) {
            __ mov(count, L1);
          }
          __ mov(addr->after_save(), O0);
          // Get the count into O1
          __ call(CAST_FROM_FN_PTR(address, BarrierSet::static_write_ref_array_pre));
          __ delayed()->mov(count->after_save(), O1);
          if (addr->is_global()) {
            __ mov(L0, addr);
          }
          if (count->is_global()) {
            __ mov(L1, count);
          }
          __ restore();
        }
        break;
      case BarrierSet::CardTableModRef:
      case BarrierSet::CardTableExtension:
      case BarrierSet::ModRef:
        break;
      default:
        ShouldNotReachHere();
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    }
  }
  //
  //  Generate post-write barrier for array.
  //
  //  Input:
  //     addr     - register containing starting address
  //     count    - register containing element count
  //     tmp      - scratch register
  //
  //  The input registers are overwritten.
  //
  void gen_write_ref_array_post_barrier(Register addr, Register count,
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                                        Register tmp) {
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    BarrierSet* bs = Universe::heap()->barrier_set();

    switch (bs->kind()) {
      case BarrierSet::G1SATBCT:
      case BarrierSet::G1SATBCTLogging:
        {
          // Get some new fresh output registers.
          __ save_frame(0);
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          __ mov(addr->after_save(), O0);
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          __ call(CAST_FROM_FN_PTR(address, BarrierSet::static_write_ref_array_post));
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          __ delayed()->mov(count->after_save(), O1);
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          __ restore();
        }
        break;
      case BarrierSet::CardTableModRef:
      case BarrierSet::CardTableExtension:
        {
          CardTableModRefBS* ct = (CardTableModRefBS*)bs;
          assert(sizeof(*ct->byte_map_base) == sizeof(jbyte), "adjust this code");
          assert_different_registers(addr, count, tmp);

          Label L_loop;

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          __ sll_ptr(count, LogBytesPerHeapOop, count);
          __ sub(count, BytesPerHeapOop, count);
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          __ add(count, addr, count);
          // Use two shifts to clear out those low order two bits! (Cannot opt. into 1.)
          __ srl_ptr(addr, CardTableModRefBS::card_shift, addr);
          __ srl_ptr(count, CardTableModRefBS::card_shift, count);
          __ sub(count, addr, count);
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          AddressLiteral rs(ct->byte_map_base);
          __ set(rs, tmp);
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        __ BIND(L_loop);
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          __ stb(G0, tmp, addr);
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          __ subcc(count, 1, count);
          __ brx(Assembler::greaterEqual, false, Assembler::pt, L_loop);
          __ delayed()->add(addr, 1, addr);
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        }
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        break;
      case BarrierSet::ModRef:
        break;
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      default:
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        ShouldNotReachHere();
    }
  }

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  //
  // 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, 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, prefetch_count, count);

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

      Label L_copy_prefetch;
      (this->*copy_loop_func)(from, to, count, count_dec, L_copy_prefetch, true, false);
      __ add(count, prefetch_count, count); // restore 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);
  }
D
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  // 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,
1182 1183 1184 1185
                     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;
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    // if both arrays have the same alignment mod 8, do 8 bytes aligned copy
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    __ andcc(from, 7, G1); // misaligned bytes
    __ br(Assembler::zero, false, Assembler::pt, L_aligned_copy);
    __ delayed()->nop();
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    const Register left_shift  = G1; // left  shift bit counter
    const Register right_shift = G5; // right shift bit counter

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    __ sll(G1, LogBitsPerByte, left_shift);
    __ mov(64, right_shift);
    __ sub(right_shift, left_shift, right_shift);
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    //
    // Load 2 aligned 8-bytes chunks and use one from previous iteration
    // to form 2 aligned 8-bytes chunks to store.
    //
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    __ 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, 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);
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    __ BIND(L_copy_last_bytes);
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    __ 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
D
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    __ 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);
1264
      __ align(OptoLoopAlignment);
D
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    __ 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
  //
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  address generate_disjoint_byte_copy(bool aligned, address *entry, const char *name) {
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    __ 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.

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    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    // 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
      //
#ifndef _LP64
      // copy a 4-bytes word if necessary to align 'to' to 8 bytes
      __ andcc(to, 7, G0);
      __ br(Assembler::zero, false, Assembler::pn, L_skip_alignment);
      __ delayed()->ld(from, 0, O3);
      __ inc(from, 4);
      __ inc(to, 4);
      __ dec(count, 4);
      __ st(O3, to, -4);
    __ BIND(L_skip_alignment);
#endif
    } 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);
    }
#ifdef _LP64
    if (!aligned)
#endif
    {
      // 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.

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

    // 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);
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      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
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      __ align(OptoLoopAlignment);
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    __ 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
  //
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  address generate_conjoint_byte_copy(bool aligned, address nooverlap_target,
                                      address *entry, const char *name) {
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    // 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.

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    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    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);
    }
#ifdef _LP64
    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
#endif
    {
      // 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
1490
      __ align(OptoLoopAlignment);
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    __ 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);
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      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1505
      __ align(OptoLoopAlignment);
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    __ 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
  //
1531
  address generate_disjoint_short_copy(bool aligned, address *entry, const char * name) {
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    __ 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.

1547 1548 1549 1550 1551
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    // 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.
      //
#ifndef _LP64
      // copy a 2-elements word if necessary to align 'to' to 8 bytes
      __ 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, 2);
      __ st(O3, to, -4);
    __ BIND(L_skip_alignment);
#endif
    } 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);
    }
#ifdef _LP64
    if (!aligned)
#endif
    {
      // 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.

1610
      copy_16_bytes_forward_with_shift(from, to, count, 1, L_copy_2_bytes);
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    }

    // 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);
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      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
1622
      __ align(OptoLoopAlignment);
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    __ 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;
  }

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  //
  //  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;
N
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    Label L_fill_2_bytes, L_fill_elements, L_fill_32_bytes;
N
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    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
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      __ sllx(value, 48, value);
      __ srlx(value, 48, value);
N
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    }
    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
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1695 1696
    __ brx(Assembler::lessUnsigned, false, Assembler::pn, L_fill_elements); // use unsigned cmp
    __ delayed()->andcc(count, 1, G0);
N
never 已提交
1697 1698 1699 1700 1701 1702 1703 1704 1705 1706 1707 1708 1709 1710 1711 1712 1713 1714 1715 1716 1717 1718 1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741 1742

    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);
    }
#ifdef _LP64
    if (!aligned) {
#endif
    // 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);
#ifdef _LP64
    }
#endif

    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);
    }

1743 1744 1745 1746 1747 1748
    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();

N
never 已提交
1749
    Label L_fill_32_bytes_loop, L_fill_4_bytes;
N
never 已提交
1750 1751 1752 1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765 1766 1767 1768 1769 1770 1771 1772 1773 1774 1775 1776 1777 1778 1779 1780
    __ 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
N
never 已提交
1781 1782 1783
    if (t == T_INT) {
      __ BIND(L_fill_elements);
    }
N
never 已提交
1784 1785 1786 1787 1788 1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815
    __ 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();
N
never 已提交
1816 1817 1818 1819 1820 1821 1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857
    __ 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);
    }
N
never 已提交
1858 1859 1860
    return start;
  }

D
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  //
  //  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
  //
1870 1871
  address generate_conjoint_short_copy(bool aligned, address nooverlap_target,
                                       address *entry, const char *name) {
D
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    // 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.

1891 1892 1893 1894 1895
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    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);
    }
#ifdef _LP64
    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
#endif
    {
      // 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
1952
      __ align(OptoLoopAlignment);
D
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    __ 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);
K
kvn 已提交
1966
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
D
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1967 1968 1969 1970 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981 1982
    __ 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;
  }

1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014 2015 2016 2017 2018 2019 2020 2021
  //
  // 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);

  }

D
duke 已提交
2022 2023 2024 2025 2026 2027 2028 2029 2030 2031 2032 2033 2034
  //
  //  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;
2035
    Label L_copy_4_bytes, L_copy_4_bytes_loop, L_exit;
D
duke 已提交
2036 2037 2038 2039 2040 2041 2042 2043 2044 2045 2046 2047 2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061 2062 2063 2064 2065 2066 2067 2068 2069 2070 2071 2072 2073 2074 2075 2076 2077 2078 2079 2080 2081 2082 2083 2084 2085

    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.
    //
#ifdef _LP64
    if (!aligned)
#endif
    {
      // 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
2086
      __ sllx(O3, 32,  O3);
D
duke 已提交
2087

2088
      disjoint_copy_core(from, to, count, 2, 16, copy_16_bytes_loop);
D
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2089 2090 2091 2092 2093

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

    __ BIND(L_aligned_copy);
2094 2095
    } // !aligned

D
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    // 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);
K
kvn 已提交
2104
      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
D
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2105 2106 2107 2108 2109 2110 2111 2112 2113 2114 2115 2116 2117 2118 2119 2120 2121 2122
    __ 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
  //
2123
  address generate_disjoint_int_copy(bool aligned, address *entry, const char *name) {
D
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2124 2125 2126 2127 2128 2129 2130
    __ 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.

2131 2132 2133 2134 2135
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
duke 已提交
2136 2137 2138 2139 2140 2141 2142 2143 2144 2145 2146 2147 2148 2149 2150 2151 2152 2153 2154 2155 2156 2157 2158 2159 2160 2161 2162 2163 2164 2165 2166 2167 2168 2169 2170 2171 2172 2173 2174 2175 2176 2177 2178 2179 2180 2181 2182 2183 2184 2185 2186 2187 2188 2189 2190 2191 2192 2193 2194 2195 2196 2197 2198 2199

    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);
2200
      __ align(OptoLoopAlignment);
D
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    __ 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
2222
      __ align(OptoLoopAlignment);
D
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    __ 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);
K
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      __ cmp_and_br_short(count, 0, Assembler::equal, Assembler::pt, L_exit);
D
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    __ 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
  //
2256 2257
  address generate_conjoint_int_copy(bool aligned, address nooverlap_target,
                                     address *entry, const char *name) {
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    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

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

2264 2265 2266 2267 2268
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    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;
  }

2281 2282 2283 2284 2285 2286 2287 2288 2289 2290
  //
  // 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) {
2291
          __ prefetch(from, ArraycopySrcPrefetchDistance+off, Assembler::severalReads);
2292 2293
        }
        if (ArraycopyDstPrefetchDistance > 0) {
2294
          __ prefetch(to, ArraycopyDstPrefetchDistance+off, Assembler::severalWritesAndPossiblyReads);
2295 2296 2297 2298 2299 2300 2301 2302 2303 2304 2305 2306 2307 2308 2309 2310 2311 2312
        }
      }
      __ 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);
  }

D
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  //
  //  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
  //
2323 2324 2325 2326 2327 2328 2329 2330 2331 2332 2333 2334 2335 2336 2337 2338 2339 2340 2341 2342 2343
  // 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;
  // }
  //
D
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  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

2352 2353 2354 2355
    __ 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);
2356 2357

    // Copy by 64 bytes chunks
2358

2359 2360
    const Register from64 = O3;  // source address
    const Register to64   = G3;  // destination address
2361 2362 2363 2364 2365 2366 2367
    __ 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);
2368

2369
    disjoint_copy_core(from64, to64, count, 3, 64, copy_64_bytes_loop);
2370 2371 2372

      // Restore O4(offset0), O5(offset8)
      __ sub(from64, from, offset0);
2373
      __ inccc(count, 6); // restore count
2374 2375 2376 2377
      __ brx(Assembler::negative, false, Assembler::pn, L_copy_8_bytes );
      __ delayed()->add(offset0, 8, offset8);

      // Copy by 16 bytes chunks
2378
      __ align(OptoLoopAlignment);
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    __ 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);

2389
      // Copy last 8 bytes
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    __ 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
  //
2409
  address generate_disjoint_long_copy(bool aligned, address *entry, const char *name) {
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    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

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

2416 2417 2418 2419 2420
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
D
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    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);
2454
      __ align(OptoLoopAlignment);
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    __ 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
  //
2481 2482
  address generate_conjoint_long_copy(bool aligned, address nooverlap_target,
                                      address *entry, const char *name) {
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    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", name);
    address start = __ pc();

2487
    assert(aligned, "Should always be aligned");
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    assert_clean_int(O2, O3);     // Make sure 'count' is clean int.

2491 2492 2493 2494 2495
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from Unsafe.copyMemory)
      BLOCK_COMMENT("Entry:");
    }
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    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
  //
2516 2517
  address generate_disjoint_oop_copy(bool aligned, address *entry, const char *name,
                                     bool dest_uninitialized = false) {
D
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    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.

2529 2530 2531 2532 2533
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here
      BLOCK_COMMENT("Entry:");
    }
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    // save arguments for barrier generation
    __ mov(to, G1);
    __ mov(count, G5);
2538
    gen_write_ref_array_pre_barrier(G1, G5, dest_uninitialized);
D
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  #ifdef _LP64
2540 2541 2542 2543 2544 2545
    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);
    }
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  #else
    generate_disjoint_int_copy_core(aligned);
  #endif
    // O0 is used as temp register
    gen_write_ref_array_post_barrier(G1, G5, O0);

    // 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
  //
2567
  address generate_conjoint_oop_copy(bool aligned, address nooverlap_target,
2568 2569
                                     address *entry, const char *name,
                                     bool dest_uninitialized = false) {
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    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.

2581 2582 2583 2584 2585 2586 2587
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here
      BLOCK_COMMENT("Entry:");
    }

    array_overlap_test(nooverlap_target, LogBytesPerHeapOop);
D
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    // save arguments for barrier generation
    __ mov(to, G1);
    __ mov(count, G5);
2592
    gen_write_ref_array_pre_barrier(G1, G5, dest_uninitialized);
D
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  #ifdef _LP64
2595 2596 2597 2598 2599
    if (UseCompressedOops) {
      generate_conjoint_int_copy_core(aligned);
    } else {
      generate_conjoint_long_copy_core(aligned);
    }
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  #else
    generate_conjoint_int_copy_core(aligned);
  #endif

    // O0 is used as temp register
    gen_write_ref_array_post_barrier(G1, G5, O0);

    // 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,
2621
                           Label& L_success) {
D
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    assert_different_registers(sub_klass, super_check_offset, super_klass, temp);

    BLOCK_COMMENT("type_check:");

2626
    Label L_miss, L_pop_to_miss;
D
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    assert_clean_int(super_check_offset, temp);

2630 2631 2632
    __ check_klass_subtype_fast_path(sub_klass, super_klass, temp, noreg,
                                     &L_success, &L_miss, NULL,
                                     super_check_offset);
D
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2634
    BLOCK_COMMENT("type_check_slow_path:");
D
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2635
    __ save_frame(0);
2636 2637 2638 2639
    __ check_klass_subtype_slow_path(sub_klass->after_save(),
                                     super_klass->after_save(),
                                     L0, L1, L2, L4,
                                     NULL, &L_pop_to_miss);
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    __ ba(L_success);
2641
    __ delayed()->restore();
D
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2643 2644
    __ bind(L_pop_to_miss);
    __ restore();
D
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    // 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
  //
2661
  address generate_checkcast_copy(const char *name, address *entry, bool dest_uninitialized = false) {
D
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2662 2663 2664 2665 2666 2667 2668 2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679

    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
2680
    // We sometimes save a frame (see generate_type_check below).
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    // If this will cause trouble, let's fail now instead of later.
    __ save_frame(0);
    __ restore();
#endif

2686 2687
    assert_clean_int(O2_count, G1);     // Make sure 'count' is clean int.

D
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2688 2689 2690 2691 2692 2693
#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
2694
      array_overlap_test(L, LogBytesPerHeapOop);
D
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      __ stop("checkcast_copy within a single array");
      __ bind(L);
      __ mov(G1, O3);
      __ mov(G4, O4);
    }
#endif //ASSERT

2702 2703 2704 2705 2706
    if (entry != NULL) {
      *entry = __ pc();
      // caller can pass a 64-bit byte count here (from generic stub)
      BLOCK_COMMENT("Entry:");
    }
2707
    gen_write_ref_array_pre_barrier(O1_to, O2_count, dest_uninitialized);
D
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2708 2709 2710 2711 2712 2713 2714 2715 2716 2717 2718 2719 2720 2721 2722 2723 2724

    Label load_element, store_element, do_card_marks, 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
2725
    __ align(OptoLoopAlignment);
D
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2727 2728
    __ BIND(store_element);
    __ deccc(G1_remain);                // decrement the count
2729 2730
    __ store_heap_oop(G3_oop, O1_to, O5_offset); // store the oop
    __ inc(O5_offset, heapOopSize);     // step to next offset
D
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    __ brx(Assembler::zero, true, Assembler::pt, do_card_marks);
    __ delayed()->set(0, O0);           // return -1 on success

    // ======== loop entry is here ========
2735
    __ BIND(load_element);
2736
    __ load_heap_oop(O0_from, O5_offset, G3_oop);  // load the oop
K
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    __ br_null_short(G3_oop, Assembler::pt, store_element);
D
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2738

2739
    __ load_klass(G3_oop, G4_klass); // query the object klass
D
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    generate_type_check(G4_klass, O3_ckoff, O4_ckval, G5_super,
                        // branch to this on success:
2743
                        store_element);
D
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    // ======== 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.
2750
    __ BIND(fail);
D
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    __ subcc(O2_count, G1_remain, O2_count);
    __ brx(Assembler::zero, false, Assembler::pt, done);
    __ delayed()->not1(O2_count, O0);   // report (-1^K) to caller

2755
    __ BIND(do_card_marks);
D
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    gen_write_ref_array_post_barrier(O1_to, O2_count, O3);   // store check on O1[0..O2]

2758
    __ BIND(done);
D
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    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.
  //
2779 2780 2781 2782 2783
  address generate_unsafe_copy(const char* name,
                               address byte_copy_entry,
                               address short_copy_entry,
                               address int_copy_entry,
                               address long_copy_entry) {
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    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
  //
2879 2880 2881 2882 2883 2884 2885
  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) {
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    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()
2948
    if (UseCompressedClassPointers) {
2949 2950 2951 2952 2953
      __ delayed()->nop(); // ??? not good
      __ load_klass(src, G3_src_klass);
    } else {
      __ delayed()->ld_ptr(src, oopDesc::klass_offset_in_bytes(), G3_src_klass);
    }
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#ifdef ASSERT
    //  assert(src->klass() != NULL);
    BLOCK_COMMENT("assert klasses not null");
    { Label L_a, L_b;
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      __ br_notnull_short(G3_src_klass, Assembler::pt, L_b); // it is broken if klass is NULL
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      __ bind(L_a);
      __ stop("broken null klass");
      __ bind(L_b);
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      __ load_klass(dst, G4_dst_klass);
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      __ 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
    //

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

2983
    if (UseCompressedClassPointers) {
2984 2985
      __ load_klass(dst, G4_dst_klass);
    }
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    // 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);
2991
    if (UseCompressedClassPointers) {
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      __ delayed()->nop();
    } else {
      __ delayed()->ld_ptr(dst, oopDesc::klass_offset_in_bytes(), G4_dst_klass);
    }
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    //  if (src->klass() != dst->klass()) return -1;
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    __ cmp_and_brx_short(G3_src_klass, G4_dst_klass, Assembler::notEqual, Assembler::pn, L_failed);
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    //  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);

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    // TypeArrayKlass
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    //
    // 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);
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    __ br(Assembler::equal, true, Assembler::pt, entry_jbyte_arraycopy);
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    __ delayed()->signx(length, count); // length

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

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

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    // ObjArrayKlass
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  __ 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
3090 3091
    __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
    __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
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    __ add(src, src_pos, from);       // src_addr
    __ add(dst, dst_pos, to);         // dst_addr
  __ BIND(L_plain_copy);
3095
    __ br(Assembler::always, false, Assembler::pt, entry_oop_arraycopy);
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    __ 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
3114 3115
      __ sll_ptr(src_pos, LogBytesPerHeapOop, src_pos);
      __ sll_ptr(dst_pos, LogBytesPerHeapOop, dst_pos);
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      __ 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.
3125
      int sco_offset = in_bytes(Klass::super_check_offset_offset());
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      __ lduw(G4_dst_klass, sco_offset, sco_temp);
      generate_type_check(G3_src_klass, sco_temp, G4_dst_klass,
                          O5_temp, L_plain_copy);

3130 3131
      // Fetch destination element klass from the ObjArrayKlass header.
      int ek_offset = in_bytes(ObjArrayKlass::element_klass_offset());
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      // 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

3137
      __ br(Assembler::always, false, Assembler::pt, entry_checkcast_arraycopy);
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      __ delayed()->lduw(O4, sco_offset, O3);
    }

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

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  //
  //  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;
}

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  void generate_arraycopy_stubs() {
3176 3177 3178 3179 3180 3181 3182 3183
    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;

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    //*** 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");
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    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");

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    //*** 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");
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#ifdef _LP64
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    // 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");
#else
    // In 32 bit jints are always HeapWordSize aligned, so always use the aligned version
    // (in fact in 32bit we always have a pre-loop part even in the aligned version,
    //  because it uses 64-bit loads/stores, so the aligned flag is actually ignored).
    StubRoutines::_jint_disjoint_arraycopy = StubRoutines::_arrayof_jint_disjoint_arraycopy;
    StubRoutines::_jint_arraycopy          = StubRoutines::_arrayof_jint_arraycopy;
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#endif
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    //*** 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);
#ifdef _LP64
    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
#endif
    {
      // 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);
D
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3282 3283 3284 3285 3286 3287 3288 3289 3290 3291 3292 3293
    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);
N
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    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");
K
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    if (UseBlockZeroing) {
      StubRoutines::_zero_aligned_words = generate_zero_aligned_words("zero_aligned_words");
    }
D
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  }

K
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  address generate_aescrypt_encryptBlock() {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "aesencryptBlock");
    Label L_doLast128bit, L_storeOutput;
    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);

    // load input into F54-F56; F30-F31 used as temp
    __ ldf(FloatRegisterImpl::S, from, 0, F30);
    __ ldf(FloatRegisterImpl::S, from, 4, F31);
    __ fmov(FloatRegisterImpl::D, F30, F54);
    __ ldf(FloatRegisterImpl::S, from, 8, F30);
    __ ldf(FloatRegisterImpl::S, from, 12, F31);
    __ fmov(FloatRegisterImpl::D, F30, F56);

    // load expanded key
    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);
    __ br(Assembler::always, false, Assembler::pt, L_storeOutput);
    __ delayed()->nop();

    __ 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);

    // store output into the destination array, F0-F1 used as temp
    __ fmov(FloatRegisterImpl::D, F54, F0);
    __ stf(FloatRegisterImpl::S, F0, to, 0);
    __ stf(FloatRegisterImpl::S, F1, to, 4);
    __ fmov(FloatRegisterImpl::D, F56, F0);
    __ stf(FloatRegisterImpl::S, F0, to, 8);
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F1, to, 12);

    return start;
  }

  address generate_aescrypt_decryptBlock() {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "aesdecryptBlock");
    address start = __ pc();
    Label L_expand192bit, L_expand256bit, L_common_transform;
    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);

    // load input into F52-F54; F30,F31 used as temp
    __ ldf(FloatRegisterImpl::S, from, 0, F30);
    __ ldf(FloatRegisterImpl::S, from, 4, F31);
    __ fmov(FloatRegisterImpl::D, F30, F52);
    __ ldf(FloatRegisterImpl::S, from, 8, F30);
    __ ldf(FloatRegisterImpl::S, from, 12, F31);
    __ fmov(FloatRegisterImpl::D, F30, F54);

    // load original key from SunJCE expanded decryption key
    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);
    __ br(Assembler::always, false, Assembler::pt, L_common_transform);
    __ delayed()->nop();

    __ 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);
    __ br(Assembler::always, false, Assembler::pt, L_common_transform);
    __ delayed()->nop();

    __ 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 ) {
      __ fmov(FloatRegisterImpl::D, as_FloatRegister(58-i), as_FloatRegister(i));
    }

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

    // perform 256-bit key specific inverse cipher transformation
    __ 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);
      }
    }

    // store output to destination array, F0-F1 used as temp
    __ fmov(FloatRegisterImpl::D, F52, F0);
    __ stf(FloatRegisterImpl::S, F0, to, 0);
    __ stf(FloatRegisterImpl::S, F1, to, 4);
    __ fmov(FloatRegisterImpl::D, F54, F0);
    __ stf(FloatRegisterImpl::S, F0, to, 8);
    __ retl();
    __ delayed()->stf(FloatRegisterImpl::S, F1, to, 12);

    return start;
  }

  address generate_cipherBlockChaining_encryptAESCrypt() {
    __ align(CodeEntryAlignment);
    StubCodeMark mark(this, "StubRoutines", "cipherBlockChaining_encryptAESCrypt");
    Label L_cbcenc128, L_cbcenc192, L_cbcenc256;
    address start = __ pc();
    Register from = O0; // source byte array
    Register to = O1;   // destination byte array
    Register key = O2;  // expanded key array
    Register rvec = O3; // init vector
    const Register len_reg = O4; // cipher length
    const Register keylen = O5;  // reg for storing expanded key array length

    // save cipher len to return in the end
    __ mov(len_reg, L1);

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

    // load init vector
    __ ldf(FloatRegisterImpl::D, rvec, 0, F60);
    __ ldf(FloatRegisterImpl::D, rvec, 8, F62);
    __ ldx(key,0,G1);
    __ ldx(key,8,G2);

    // start loading expanded key
    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
    __ br(Assembler::always, false, Assembler::pt, L_cbcenc256);
    __ delayed()->nop();

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc128);
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ xor3(G1,G3,G3);
    __ xor3(G2,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);
      }
    }

    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ add(from, 16, from);
    __ add(to, 16, to);
    __ subcc(len_reg, 16, len_reg);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc128);
    __ delayed()->nop();
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ retl();
    __ delayed()->mov(L1, O0);

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc192);
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ xor3(G1,G3,G3);
    __ xor3(G2,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);
      }
    }

    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ add(from, 16, from);
    __ subcc(len_reg, 16, len_reg);
    __ add(to, 16, to);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc192);
    __ delayed()->nop();
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ retl();
    __ delayed()->mov(L1, O0);

    __ align(OptoLoopAlignment);
    __ BIND(L_cbcenc256);
    __ ldx(from,0,G3);
    __ ldx(from,8,G4);
    __ xor3(G1,G3,G3);
    __ xor3(G2,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);
      }
    }

    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);
    __ add(from, 16, from);
    __ subcc(len_reg, 16, len_reg);
    __ add(to, 16, to);
    __ br(Assembler::notEqual, false, Assembler::pt, L_cbcenc256);
    __ delayed()->nop();
    __ stf(FloatRegisterImpl::D, F60, rvec, 0);
    __ stf(FloatRegisterImpl::D, F62, rvec, 8);
    __ retl();
    __ delayed()->mov(L1, O0);

    return start;
  }

  address generate_cipherBlockChaining_decryptAESCrypt_Parallel() {
    __ 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;
    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 cipher len before save_frame, to return in the end
    __ mov(O4, L0);
    __ save_frame(0); //args are read from I* registers since we save the frame in the beginning

    // load original key from SunJCE expanded decryption key
    for ( int i = 0;  i <= 3; i++ ) {
      __ ldf(FloatRegisterImpl::S, original_key, i*4, as_FloatRegister(i));
    }

    // load initial vector
    __ 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(L4, false, Assembler::pt, L_dec_next2_blocks128);
    __ delayed()->nop();

    __ br(Assembler::always, false, Assembler::pt, L_dec_first_block_start);
    __ delayed()->nop();

    __ 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(L4, false, Assembler::pt, L_dec_next2_blocks192);
    __ delayed()->nop();

    __ br(Assembler::always, false, Assembler::pt, L_dec_first_block_start);
    __ delayed()->nop();

    __ 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(L4, false, Assembler::pt, L_dec_next2_blocks256);
    __ delayed()->nop();

    __ BIND(L_dec_first_block_start);
    __ ldx(from,0,L4);
    __ ldx(from,8,L5);
    __ 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);

    __ stf(FloatRegisterImpl::D, F60, to, 0);
    __ stf(FloatRegisterImpl::D, F62, to, 8);

    __ 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();

    // F40:F42 used for first 16-bytes
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F40);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F42);

    // F60:F62 used for next 16-bytes
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ 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);

    __ stf(FloatRegisterImpl::D, F40, to, 0);
    __ stf(FloatRegisterImpl::D, F42, to, 8);

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

    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);

    __ 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();
    __ br(Assembler::always, false, Assembler::pt, L_cbcdec_end);
    __ delayed()->nop();

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

    // F48:F50 used for first 16-bytes
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F48);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F50);

    // F60:F62 used for next 16-bytes
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ 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);

    __ stf(FloatRegisterImpl::D, F48, to, 0);
    __ stf(FloatRegisterImpl::D, F50, to, 8);

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

    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);

    __ 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();
    __ br(Assembler::always, false, Assembler::pt, L_cbcdec_end);
    __ delayed()->nop();

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

    // F0:F2 used for first 16-bytes
    __ ldx(from,0,G4);
    __ ldx(from,8,G5);
    __ xor3(L2,G4,G1);
    __ movxtod(G1,F0);
    __ xor3(L3,G5,G1);
    __ movxtod(G1,F2);

    // F60:F62 used for next 16-bytes
    __ ldx(from,16,L4);
    __ ldx(from,24,L5);
    __ 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,G6);
    __ 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(G6,F50);
    __ movxtod(G1,F48);

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

    __ stf(FloatRegisterImpl::D, F0, to, 0);
    __ stf(FloatRegisterImpl::D, F2, to, 8);

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

    __ stf(FloatRegisterImpl::D, F60, to, 16);
    __ stf(FloatRegisterImpl::D, F62, to, 24);

    __ 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);
    __ stx(L0, rvec, 0);
    __ stx(L1, rvec, 8);
    __ restore();
    __ mov(L0, O0);
    __ retl();
    __ delayed()->nop();

    return start;
  }

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  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();

#if !defined(COMPILER2) && !defined(_LP64)
    StubRoutines::_atomic_xchg_entry         = generate_atomic_xchg();
    StubRoutines::_atomic_cmpxchg_entry      = generate_atomic_cmpxchg();
    StubRoutines::_atomic_add_entry          = generate_atomic_add();
    StubRoutines::_atomic_xchg_ptr_entry     = StubRoutines::_atomic_xchg_entry;
    StubRoutines::_atomic_cmpxchg_ptr_entry  = StubRoutines::_atomic_cmpxchg_entry;
    StubRoutines::_atomic_cmpxchg_long_entry = generate_atomic_cmpxchg_long();
    StubRoutines::_atomic_add_ptr_entry      = StubRoutines::_atomic_add_entry;
#endif  // COMPILER2 !=> _LP64
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    // 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));
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  }


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

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    // 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();
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    // These entry points require SharedInfo::stack0 to be set up in non-core builds
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    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));
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    StubRoutines::_handler_for_unsafe_access_entry =
      generate_handler_for_unsafe_access();

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


 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
#ifdef _LP64
// 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);
#endif
      __ 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);
}