c1_LIRAssembler_x86.cpp 117.8 KB
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/*
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 * Copyright 2000-2009 Sun Microsystems, Inc.  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.
 *
 * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
 * CA 95054 USA or visit www.sun.com if you need additional information or
 * have any questions.
 *
 */

# include "incls/_precompiled.incl"
# include "incls/_c1_LIRAssembler_x86.cpp.incl"


// These masks are used to provide 128-bit aligned bitmasks to the XMM
// instructions, to allow sign-masking or sign-bit flipping.  They allow
// fast versions of NegF/NegD and AbsF/AbsD.

// Note: 'double' and 'long long' have 32-bits alignment on x86.
static jlong* double_quadword(jlong *adr, jlong lo, jlong hi) {
  // Use the expression (adr)&(~0xF) to provide 128-bits aligned address
  // of 128-bits operands for SSE instructions.
  jlong *operand = (jlong*)(((long)adr)&((long)(~0xF)));
  // Store the value to a 128-bits operand.
  operand[0] = lo;
  operand[1] = hi;
  return operand;
}

// Buffer for 128-bits masks used by SSE instructions.
static jlong fp_signmask_pool[(4+1)*2]; // 4*128bits(data) + 128bits(alignment)

// Static initialization during VM startup.
static jlong *float_signmask_pool  = double_quadword(&fp_signmask_pool[1*2], CONST64(0x7FFFFFFF7FFFFFFF), CONST64(0x7FFFFFFF7FFFFFFF));
static jlong *double_signmask_pool = double_quadword(&fp_signmask_pool[2*2], CONST64(0x7FFFFFFFFFFFFFFF), CONST64(0x7FFFFFFFFFFFFFFF));
static jlong *float_signflip_pool  = double_quadword(&fp_signmask_pool[3*2], CONST64(0x8000000080000000), CONST64(0x8000000080000000));
static jlong *double_signflip_pool = double_quadword(&fp_signmask_pool[4*2], CONST64(0x8000000000000000), CONST64(0x8000000000000000));



NEEDS_CLEANUP // remove this definitions ?
const Register IC_Klass    = rax;   // where the IC klass is cached
const Register SYNC_header = rax;   // synchronization header
const Register SHIFT_count = rcx;   // where count for shift operations must be

#define __ _masm->


static void select_different_registers(Register preserve,
                                       Register extra,
                                       Register &tmp1,
                                       Register &tmp2) {
  if (tmp1 == preserve) {
    assert_different_registers(tmp1, tmp2, extra);
    tmp1 = extra;
  } else if (tmp2 == preserve) {
    assert_different_registers(tmp1, tmp2, extra);
    tmp2 = extra;
  }
  assert_different_registers(preserve, tmp1, tmp2);
}



static void select_different_registers(Register preserve,
                                       Register extra,
                                       Register &tmp1,
                                       Register &tmp2,
                                       Register &tmp3) {
  if (tmp1 == preserve) {
    assert_different_registers(tmp1, tmp2, tmp3, extra);
    tmp1 = extra;
  } else if (tmp2 == preserve) {
    assert_different_registers(tmp1, tmp2, tmp3, extra);
    tmp2 = extra;
  } else if (tmp3 == preserve) {
    assert_different_registers(tmp1, tmp2, tmp3, extra);
    tmp3 = extra;
  }
  assert_different_registers(preserve, tmp1, tmp2, tmp3);
}



bool LIR_Assembler::is_small_constant(LIR_Opr opr) {
  if (opr->is_constant()) {
    LIR_Const* constant = opr->as_constant_ptr();
    switch (constant->type()) {
      case T_INT: {
        return true;
      }

      default:
        return false;
    }
  }
  return false;
}


LIR_Opr LIR_Assembler::receiverOpr() {
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  return FrameMap::receiver_opr;
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}

LIR_Opr LIR_Assembler::incomingReceiverOpr() {
  return receiverOpr();
}

LIR_Opr LIR_Assembler::osrBufferPointer() {
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  return FrameMap::as_pointer_opr(receiverOpr()->as_register());
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}

//--------------fpu register translations-----------------------


address LIR_Assembler::float_constant(float f) {
  address const_addr = __ float_constant(f);
  if (const_addr == NULL) {
    bailout("const section overflow");
    return __ code()->consts()->start();
  } else {
    return const_addr;
  }
}


address LIR_Assembler::double_constant(double d) {
  address const_addr = __ double_constant(d);
  if (const_addr == NULL) {
    bailout("const section overflow");
    return __ code()->consts()->start();
  } else {
    return const_addr;
  }
}


void LIR_Assembler::set_24bit_FPU() {
  __ fldcw(ExternalAddress(StubRoutines::addr_fpu_cntrl_wrd_24()));
}

void LIR_Assembler::reset_FPU() {
  __ fldcw(ExternalAddress(StubRoutines::addr_fpu_cntrl_wrd_std()));
}

void LIR_Assembler::fpop() {
  __ fpop();
}

void LIR_Assembler::fxch(int i) {
  __ fxch(i);
}

void LIR_Assembler::fld(int i) {
  __ fld_s(i);
}

void LIR_Assembler::ffree(int i) {
  __ ffree(i);
}

void LIR_Assembler::breakpoint() {
  __ int3();
}

void LIR_Assembler::push(LIR_Opr opr) {
  if (opr->is_single_cpu()) {
    __ push_reg(opr->as_register());
  } else if (opr->is_double_cpu()) {
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    NOT_LP64(__ push_reg(opr->as_register_hi()));
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    __ push_reg(opr->as_register_lo());
  } else if (opr->is_stack()) {
    __ push_addr(frame_map()->address_for_slot(opr->single_stack_ix()));
  } else if (opr->is_constant()) {
    LIR_Const* const_opr = opr->as_constant_ptr();
    if (const_opr->type() == T_OBJECT) {
      __ push_oop(const_opr->as_jobject());
    } else if (const_opr->type() == T_INT) {
      __ push_jint(const_opr->as_jint());
    } else {
      ShouldNotReachHere();
    }

  } else {
    ShouldNotReachHere();
  }
}

void LIR_Assembler::pop(LIR_Opr opr) {
  if (opr->is_single_cpu()) {
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    __ pop_reg(opr->as_register());
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  } else {
    ShouldNotReachHere();
  }
}

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bool LIR_Assembler::is_literal_address(LIR_Address* addr) {
  return addr->base()->is_illegal() && addr->index()->is_illegal();
}

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//-------------------------------------------
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Address LIR_Assembler::as_Address(LIR_Address* addr) {
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  return as_Address(addr, rscratch1);
}

Address LIR_Assembler::as_Address(LIR_Address* addr, Register tmp) {
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  if (addr->base()->is_illegal()) {
    assert(addr->index()->is_illegal(), "must be illegal too");
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    AddressLiteral laddr((address)addr->disp(), relocInfo::none);
    if (! __ reachable(laddr)) {
      __ movptr(tmp, laddr.addr());
      Address res(tmp, 0);
      return res;
    } else {
      return __ as_Address(laddr);
    }
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  }

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  Register base = addr->base()->as_pointer_register();
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  if (addr->index()->is_illegal()) {
    return Address( base, addr->disp());
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  } else if (addr->index()->is_cpu_register()) {
    Register index = addr->index()->as_pointer_register();
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    return Address(base, index, (Address::ScaleFactor) addr->scale(), addr->disp());
  } else if (addr->index()->is_constant()) {
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    intptr_t addr_offset = (addr->index()->as_constant_ptr()->as_jint() << addr->scale()) + addr->disp();
    assert(Assembler::is_simm32(addr_offset), "must be");
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    return Address(base, addr_offset);
  } else {
    Unimplemented();
    return Address();
  }
}


Address LIR_Assembler::as_Address_hi(LIR_Address* addr) {
  Address base = as_Address(addr);
  return Address(base._base, base._index, base._scale, base._disp + BytesPerWord);
}


Address LIR_Assembler::as_Address_lo(LIR_Address* addr) {
  return as_Address(addr);
}


void LIR_Assembler::osr_entry() {
  offsets()->set_value(CodeOffsets::OSR_Entry, code_offset());
  BlockBegin* osr_entry = compilation()->hir()->osr_entry();
  ValueStack* entry_state = osr_entry->state();
  int number_of_locks = entry_state->locks_size();

  // we jump here if osr happens with the interpreter
  // state set up to continue at the beginning of the
  // loop that triggered osr - in particular, we have
  // the following registers setup:
  //
  // rcx: osr buffer
  //

  // build frame
  ciMethod* m = compilation()->method();
  __ build_frame(initial_frame_size_in_bytes());

  // OSR buffer is
  //
  // locals[nlocals-1..0]
  // monitors[0..number_of_locks]
  //
  // locals is a direct copy of the interpreter frame so in the osr buffer
  // so first slot in the local array is the last local from the interpreter
  // and last slot is local[0] (receiver) from the interpreter
  //
  // Similarly with locks. The first lock slot in the osr buffer is the nth lock
  // from the interpreter frame, the nth lock slot in the osr buffer is 0th lock
  // in the interpreter frame (the method lock if a sync method)

  // Initialize monitors in the compiled activation.
  //   rcx: pointer to osr buffer
  //
  // All other registers are dead at this point and the locals will be
  // copied into place by code emitted in the IR.

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  Register OSR_buf = osrBufferPointer()->as_pointer_register();
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  { assert(frame::interpreter_frame_monitor_size() == BasicObjectLock::size(), "adjust code below");
    int monitor_offset = BytesPerWord * method()->max_locals() +
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      (2 * BytesPerWord) * (number_of_locks - 1);
    // SharedRuntime::OSR_migration_begin() packs BasicObjectLocks in
    // the OSR buffer using 2 word entries: first the lock and then
    // the oop.
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    for (int i = 0; i < number_of_locks; i++) {
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      int slot_offset = monitor_offset - ((i * 2) * BytesPerWord);
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#ifdef ASSERT
      // verify the interpreter's monitor has a non-null object
      {
        Label L;
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        __ cmpptr(Address(OSR_buf, slot_offset + 1*BytesPerWord), (int32_t)NULL_WORD);
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        __ jcc(Assembler::notZero, L);
        __ stop("locked object is NULL");
        __ bind(L);
      }
#endif
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      __ movptr(rbx, Address(OSR_buf, slot_offset + 0));
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      __ movptr(frame_map()->address_for_monitor_lock(i), rbx);
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      __ movptr(rbx, Address(OSR_buf, slot_offset + 1*BytesPerWord));
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      __ movptr(frame_map()->address_for_monitor_object(i), rbx);
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    }
  }
}


// inline cache check; done before the frame is built.
int LIR_Assembler::check_icache() {
  Register receiver = FrameMap::receiver_opr->as_register();
  Register ic_klass = IC_Klass;
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  const int ic_cmp_size = LP64_ONLY(10) NOT_LP64(9);
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  if (!VerifyOops) {
    // insert some nops so that the verified entry point is aligned on CodeEntryAlignment
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    while ((__ offset() + ic_cmp_size) % CodeEntryAlignment != 0) {
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      __ nop();
    }
  }
  int offset = __ offset();
  __ inline_cache_check(receiver, IC_Klass);
  assert(__ offset() % CodeEntryAlignment == 0 || VerifyOops, "alignment must be correct");
  if (VerifyOops) {
    // force alignment after the cache check.
    // It's been verified to be aligned if !VerifyOops
    __ align(CodeEntryAlignment);
  }
  return offset;
}


void LIR_Assembler::jobject2reg_with_patching(Register reg, CodeEmitInfo* info) {
  jobject o = NULL;
  PatchingStub* patch = new PatchingStub(_masm, PatchingStub::load_klass_id);
  __ movoop(reg, o);
  patching_epilog(patch, lir_patch_normal, reg, info);
}


void LIR_Assembler::monitorexit(LIR_Opr obj_opr, LIR_Opr lock_opr, Register new_hdr, int monitor_no, Register exception) {
  if (exception->is_valid()) {
    // preserve exception
    // note: the monitor_exit runtime call is a leaf routine
    //       and cannot block => no GC can happen
    // The slow case (MonitorAccessStub) uses the first two stack slots
    // ([esp+0] and [esp+4]), therefore we store the exception at [esp+8]
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    __ movptr (Address(rsp, 2*wordSize), exception);
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  }

  Register obj_reg  = obj_opr->as_register();
  Register lock_reg = lock_opr->as_register();

  // setup registers (lock_reg must be rax, for lock_object)
  assert(obj_reg != SYNC_header && lock_reg != SYNC_header, "rax, must be available here");
  Register hdr = lock_reg;
  assert(new_hdr == SYNC_header, "wrong register");
  lock_reg = new_hdr;
  // compute pointer to BasicLock
  Address lock_addr = frame_map()->address_for_monitor_lock(monitor_no);
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  __ lea(lock_reg, lock_addr);
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  // unlock object
  MonitorAccessStub* slow_case = new MonitorExitStub(lock_opr, true, monitor_no);
  // _slow_case_stubs->append(slow_case);
  // temporary fix: must be created after exceptionhandler, therefore as call stub
  _slow_case_stubs->append(slow_case);
  if (UseFastLocking) {
    // try inlined fast unlocking first, revert to slow locking if it fails
    // note: lock_reg points to the displaced header since the displaced header offset is 0!
    assert(BasicLock::displaced_header_offset_in_bytes() == 0, "lock_reg must point to the displaced header");
    __ unlock_object(hdr, obj_reg, lock_reg, *slow_case->entry());
  } else {
    // always do slow unlocking
    // note: the slow unlocking code could be inlined here, however if we use
    //       slow unlocking, speed doesn't matter anyway and this solution is
    //       simpler and requires less duplicated code - additionally, the
    //       slow unlocking code is the same in either case which simplifies
    //       debugging
    __ jmp(*slow_case->entry());
  }
  // done
  __ bind(*slow_case->continuation());

  if (exception->is_valid()) {
    // restore exception
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    __ movptr (exception, Address(rsp, 2 * wordSize));
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  }
}

// This specifies the rsp decrement needed to build the frame
int LIR_Assembler::initial_frame_size_in_bytes() {
  // if rounding, must let FrameMap know!
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  // The frame_map records size in slots (32bit word)

  // subtract two words to account for return address and link
  return (frame_map()->framesize() - (2*VMRegImpl::slots_per_word))  * VMRegImpl::stack_slot_size;
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}


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void LIR_Assembler::emit_exception_handler() {
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  // if the last instruction is a call (typically to do a throw which
  // is coming at the end after block reordering) the return address
  // must still point into the code area in order to avoid assertion
  // failures when searching for the corresponding bci => add a nop
  // (was bug 5/14/1999 - gri)
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  __ nop();

  // generate code for exception handler
  address handler_base = __ start_a_stub(exception_handler_size);
  if (handler_base == NULL) {
    // not enough space left for the handler
    bailout("exception handler overflow");
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    return;
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  }
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#ifdef ASSERT
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  int offset = code_offset();
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#endif // ASSERT

  compilation()->offsets()->set_value(CodeOffsets::Exceptions, code_offset());
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  // if the method does not have an exception handler, then there is
  // no reason to search for one
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  if (compilation()->has_exception_handlers() || compilation()->env()->jvmti_can_post_exceptions()) {
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    // the exception oop and pc are in rax, and rdx
    // no other registers need to be preserved, so invalidate them
    __ invalidate_registers(false, true, true, false, true, true);

    // check that there is really an exception
    __ verify_not_null_oop(rax);

    // search an exception handler (rax: exception oop, rdx: throwing pc)
    __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::handle_exception_nofpu_id)));

    // if the call returns here, then the exception handler for particular
    // exception doesn't exist -> unwind activation and forward exception to caller
  }

  // the exception oop is in rax,
  // no other registers need to be preserved, so invalidate them
  __ invalidate_registers(false, true, true, true, true, true);

  // check that there is really an exception
  __ verify_not_null_oop(rax);

  // unlock the receiver/klass if necessary
  // rax,: exception
  ciMethod* method = compilation()->method();
  if (method->is_synchronized() && GenerateSynchronizationCode) {
    monitorexit(FrameMap::rbx_oop_opr, FrameMap::rcx_opr, SYNC_header, 0, rax);
  }

  // unwind activation and forward exception to caller
  // rax,: exception
  __ jump(RuntimeAddress(Runtime1::entry_for(Runtime1::unwind_exception_id)));
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  assert(code_offset() - offset <= exception_handler_size, "overflow");
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  __ end_a_stub();
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}

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void LIR_Assembler::emit_deopt_handler() {
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  // if the last instruction is a call (typically to do a throw which
  // is coming at the end after block reordering) the return address
  // must still point into the code area in order to avoid assertion
  // failures when searching for the corresponding bci => add a nop
  // (was bug 5/14/1999 - gri)
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  __ nop();

  // generate code for exception handler
  address handler_base = __ start_a_stub(deopt_handler_size);
  if (handler_base == NULL) {
    // not enough space left for the handler
    bailout("deopt handler overflow");
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    return;
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  }
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#ifdef ASSERT
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  int offset = code_offset();
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#endif // ASSERT

  compilation()->offsets()->set_value(CodeOffsets::Deopt, code_offset());

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  InternalAddress here(__ pc());
  __ pushptr(here.addr());
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  __ jump(RuntimeAddress(SharedRuntime::deopt_blob()->unpack()));
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  assert(code_offset() - offset <= deopt_handler_size, "overflow");
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  __ end_a_stub();

}


// This is the fast version of java.lang.String.compare; it has not
// OSR-entry and therefore, we generate a slow version for OSR's
void LIR_Assembler::emit_string_compare(LIR_Opr arg0, LIR_Opr arg1, LIR_Opr dst, CodeEmitInfo* info) {
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  __ movptr (rbx, rcx); // receiver is in rcx
  __ movptr (rax, arg1->as_register());
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  // Get addresses of first characters from both Strings
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  __ movptr (rsi, Address(rax, java_lang_String::value_offset_in_bytes()));
  __ movptr (rcx, Address(rax, java_lang_String::offset_offset_in_bytes()));
  __ lea    (rsi, Address(rsi, rcx, Address::times_2, arrayOopDesc::base_offset_in_bytes(T_CHAR)));
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  // rbx, may be NULL
  add_debug_info_for_null_check_here(info);
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  __ movptr (rdi, Address(rbx, java_lang_String::value_offset_in_bytes()));
  __ movptr (rcx, Address(rbx, java_lang_String::offset_offset_in_bytes()));
  __ lea    (rdi, Address(rdi, rcx, Address::times_2, arrayOopDesc::base_offset_in_bytes(T_CHAR)));
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  // compute minimum length (in rax) and difference of lengths (on top of stack)
  if (VM_Version::supports_cmov()) {
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    __ movl     (rbx, Address(rbx, java_lang_String::count_offset_in_bytes()));
    __ movl     (rax, Address(rax, java_lang_String::count_offset_in_bytes()));
    __ mov      (rcx, rbx);
    __ subptr   (rbx, rax); // subtract lengths
    __ push     (rbx);      // result
    __ cmov     (Assembler::lessEqual, rax, rcx);
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  } else {
    Label L;
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    __ movl     (rbx, Address(rbx, java_lang_String::count_offset_in_bytes()));
    __ movl     (rcx, Address(rax, java_lang_String::count_offset_in_bytes()));
    __ mov      (rax, rbx);
    __ subptr   (rbx, rcx);
    __ push     (rbx);
    __ jcc      (Assembler::lessEqual, L);
    __ mov      (rax, rcx);
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    __ bind (L);
  }
  // is minimum length 0?
  Label noLoop, haveResult;
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  __ testptr (rax, rax);
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  __ jcc (Assembler::zero, noLoop);

  // compare first characters
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  __ load_unsigned_short(rcx, Address(rdi, 0));
  __ load_unsigned_short(rbx, Address(rsi, 0));
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  __ subl(rcx, rbx);
  __ jcc(Assembler::notZero, haveResult);
  // starting loop
  __ decrement(rax); // we already tested index: skip one
  __ jcc(Assembler::zero, noLoop);

  // set rsi.edi to the end of the arrays (arrays have same length)
  // negate the index

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  __ lea(rsi, Address(rsi, rax, Address::times_2, type2aelembytes(T_CHAR)));
  __ lea(rdi, Address(rdi, rax, Address::times_2, type2aelembytes(T_CHAR)));
  __ negptr(rax);
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  // compare the strings in a loop

  Label loop;
  __ align(wordSize);
  __ bind(loop);
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  __ load_unsigned_short(rcx, Address(rdi, rax, Address::times_2, 0));
  __ load_unsigned_short(rbx, Address(rsi, rax, Address::times_2, 0));
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  __ subl(rcx, rbx);
  __ jcc(Assembler::notZero, haveResult);
  __ increment(rax);
  __ jcc(Assembler::notZero, loop);

  // strings are equal up to min length

  __ bind(noLoop);
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  __ pop(rax);
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  return_op(LIR_OprFact::illegalOpr);

  __ bind(haveResult);
  // leave instruction is going to discard the TOS value
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  __ mov (rax, rcx); // result of call is in rax,
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}


void LIR_Assembler::return_op(LIR_Opr result) {
  assert(result->is_illegal() || !result->is_single_cpu() || result->as_register() == rax, "word returns are in rax,");
  if (!result->is_illegal() && result->is_float_kind() && !result->is_xmm_register()) {
    assert(result->fpu() == 0, "result must already be on TOS");
  }

  // Pop the stack before the safepoint code
  __ leave();

  bool result_is_oop = result->is_valid() ? result->is_oop() : false;

  // Note: we do not need to round double result; float result has the right precision
  // the poll sets the condition code, but no data registers
  AddressLiteral polling_page(os::get_polling_page() + (SafepointPollOffset % os::vm_page_size()),
                              relocInfo::poll_return_type);
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  // NOTE: the requires that the polling page be reachable else the reloc
  // goes to the movq that loads the address and not the faulting instruction
  // which breaks the signal handler code

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  __ test32(rax, polling_page);

  __ ret(0);
}


int LIR_Assembler::safepoint_poll(LIR_Opr tmp, CodeEmitInfo* info) {
  AddressLiteral polling_page(os::get_polling_page() + (SafepointPollOffset % os::vm_page_size()),
                              relocInfo::poll_type);

  if (info != NULL) {
    add_debug_info_for_branch(info);
  } else {
    ShouldNotReachHere();
  }

  int offset = __ offset();
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  // NOTE: the requires that the polling page be reachable else the reloc
  // goes to the movq that loads the address and not the faulting instruction
  // which breaks the signal handler code

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  __ test32(rax, polling_page);
  return offset;
}


void LIR_Assembler::move_regs(Register from_reg, Register to_reg) {
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  if (from_reg != to_reg) __ mov(to_reg, from_reg);
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}

void LIR_Assembler::swap_reg(Register a, Register b) {
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  __ xchgptr(a, b);
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}


void LIR_Assembler::const2reg(LIR_Opr src, LIR_Opr dest, LIR_PatchCode patch_code, CodeEmitInfo* info) {
  assert(src->is_constant(), "should not call otherwise");
  assert(dest->is_register(), "should not call otherwise");
  LIR_Const* c = src->as_constant_ptr();

  switch (c->type()) {
    case T_INT: {
      assert(patch_code == lir_patch_none, "no patching handled here");
      __ movl(dest->as_register(), c->as_jint());
      break;
    }

    case T_LONG: {
      assert(patch_code == lir_patch_none, "no patching handled here");
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#ifdef _LP64
      __ movptr(dest->as_register_lo(), (intptr_t)c->as_jlong());
#else
      __ movptr(dest->as_register_lo(), c->as_jint_lo());
      __ movptr(dest->as_register_hi(), c->as_jint_hi());
#endif // _LP64
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      break;
    }

    case T_OBJECT: {
      if (patch_code != lir_patch_none) {
        jobject2reg_with_patching(dest->as_register(), info);
      } else {
        __ movoop(dest->as_register(), c->as_jobject());
      }
      break;
    }

    case T_FLOAT: {
      if (dest->is_single_xmm()) {
        if (c->is_zero_float()) {
          __ xorps(dest->as_xmm_float_reg(), dest->as_xmm_float_reg());
        } else {
          __ movflt(dest->as_xmm_float_reg(),
                   InternalAddress(float_constant(c->as_jfloat())));
        }
      } else {
        assert(dest->is_single_fpu(), "must be");
        assert(dest->fpu_regnr() == 0, "dest must be TOS");
        if (c->is_zero_float()) {
          __ fldz();
        } else if (c->is_one_float()) {
          __ fld1();
        } else {
          __ fld_s (InternalAddress(float_constant(c->as_jfloat())));
        }
      }
      break;
    }

    case T_DOUBLE: {
      if (dest->is_double_xmm()) {
        if (c->is_zero_double()) {
          __ xorpd(dest->as_xmm_double_reg(), dest->as_xmm_double_reg());
        } else {
          __ movdbl(dest->as_xmm_double_reg(),
                    InternalAddress(double_constant(c->as_jdouble())));
        }
      } else {
        assert(dest->is_double_fpu(), "must be");
        assert(dest->fpu_regnrLo() == 0, "dest must be TOS");
        if (c->is_zero_double()) {
          __ fldz();
        } else if (c->is_one_double()) {
          __ fld1();
        } else {
          __ fld_d (InternalAddress(double_constant(c->as_jdouble())));
        }
      }
      break;
    }

    default:
      ShouldNotReachHere();
  }
}

void LIR_Assembler::const2stack(LIR_Opr src, LIR_Opr dest) {
  assert(src->is_constant(), "should not call otherwise");
  assert(dest->is_stack(), "should not call otherwise");
  LIR_Const* c = src->as_constant_ptr();

  switch (c->type()) {
    case T_INT:  // fall through
    case T_FLOAT:
      __ movl(frame_map()->address_for_slot(dest->single_stack_ix()), c->as_jint_bits());
      break;

    case T_OBJECT:
      __ movoop(frame_map()->address_for_slot(dest->single_stack_ix()), c->as_jobject());
      break;

    case T_LONG:  // fall through
    case T_DOUBLE:
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#ifdef _LP64
      __ movptr(frame_map()->address_for_slot(dest->double_stack_ix(),
                                            lo_word_offset_in_bytes), (intptr_t)c->as_jlong_bits());
#else
      __ movptr(frame_map()->address_for_slot(dest->double_stack_ix(),
                                              lo_word_offset_in_bytes), c->as_jint_lo_bits());
      __ movptr(frame_map()->address_for_slot(dest->double_stack_ix(),
                                              hi_word_offset_in_bytes), c->as_jint_hi_bits());
#endif // _LP64
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      break;

    default:
      ShouldNotReachHere();
  }
}

void LIR_Assembler::const2mem(LIR_Opr src, LIR_Opr dest, BasicType type, CodeEmitInfo* info ) {
  assert(src->is_constant(), "should not call otherwise");
  assert(dest->is_address(), "should not call otherwise");
  LIR_Const* c = src->as_constant_ptr();
  LIR_Address* addr = dest->as_address_ptr();

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  int null_check_here = code_offset();
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  switch (type) {
    case T_INT:    // fall through
    case T_FLOAT:
      __ movl(as_Address(addr), c->as_jint_bits());
      break;

    case T_OBJECT:  // fall through
    case T_ARRAY:
      if (c->as_jobject() == NULL) {
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        __ movptr(as_Address(addr), NULL_WORD);
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      } else {
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        if (is_literal_address(addr)) {
          ShouldNotReachHere();
          __ movoop(as_Address(addr, noreg), c->as_jobject());
        } else {
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#ifdef _LP64
          __ movoop(rscratch1, c->as_jobject());
          null_check_here = code_offset();
          __ movptr(as_Address_lo(addr), rscratch1);
#else
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          __ movoop(as_Address(addr), c->as_jobject());
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#endif
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        }
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      }
      break;

    case T_LONG:    // fall through
    case T_DOUBLE:
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#ifdef _LP64
      if (is_literal_address(addr)) {
        ShouldNotReachHere();
        __ movptr(as_Address(addr, r15_thread), (intptr_t)c->as_jlong_bits());
      } else {
        __ movptr(r10, (intptr_t)c->as_jlong_bits());
        null_check_here = code_offset();
        __ movptr(as_Address_lo(addr), r10);
      }
#else
      // Always reachable in 32bit so this doesn't produce useless move literal
      __ movptr(as_Address_hi(addr), c->as_jint_hi_bits());
      __ movptr(as_Address_lo(addr), c->as_jint_lo_bits());
#endif // _LP64
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      break;

    case T_BOOLEAN: // fall through
    case T_BYTE:
      __ movb(as_Address(addr), c->as_jint() & 0xFF);
      break;

    case T_CHAR:    // fall through
    case T_SHORT:
      __ movw(as_Address(addr), c->as_jint() & 0xFFFF);
      break;

    default:
      ShouldNotReachHere();
  };
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  if (info != NULL) {
    add_debug_info_for_null_check(null_check_here, info);
  }
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}


void LIR_Assembler::reg2reg(LIR_Opr src, LIR_Opr dest) {
  assert(src->is_register(), "should not call otherwise");
  assert(dest->is_register(), "should not call otherwise");

  // move between cpu-registers
  if (dest->is_single_cpu()) {
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#ifdef _LP64
    if (src->type() == T_LONG) {
      // Can do LONG -> OBJECT
      move_regs(src->as_register_lo(), dest->as_register());
      return;
    }
#endif
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    assert(src->is_single_cpu(), "must match");
    if (src->type() == T_OBJECT) {
      __ verify_oop(src->as_register());
    }
    move_regs(src->as_register(), dest->as_register());

  } else if (dest->is_double_cpu()) {
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#ifdef _LP64
    if (src->type() == T_OBJECT || src->type() == T_ARRAY) {
      // Surprising to me but we can see move of a long to t_object
      __ verify_oop(src->as_register());
      move_regs(src->as_register(), dest->as_register_lo());
      return;
    }
#endif
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    assert(src->is_double_cpu(), "must match");
    Register f_lo = src->as_register_lo();
    Register f_hi = src->as_register_hi();
    Register t_lo = dest->as_register_lo();
    Register t_hi = dest->as_register_hi();
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#ifdef _LP64
    assert(f_hi == f_lo, "must be same");
    assert(t_hi == t_lo, "must be same");
    move_regs(f_lo, t_lo);
#else
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    assert(f_lo != f_hi && t_lo != t_hi, "invalid register allocation");

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    if (f_lo == t_hi && f_hi == t_lo) {
      swap_reg(f_lo, f_hi);
    } else if (f_hi == t_lo) {
      assert(f_lo != t_hi, "overwriting register");
      move_regs(f_hi, t_hi);
      move_regs(f_lo, t_lo);
    } else {
      assert(f_hi != t_lo, "overwriting register");
      move_regs(f_lo, t_lo);
      move_regs(f_hi, t_hi);
    }
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#endif // LP64
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    // special moves from fpu-register to xmm-register
    // necessary for method results
  } else if (src->is_single_xmm() && !dest->is_single_xmm()) {
    __ movflt(Address(rsp, 0), src->as_xmm_float_reg());
    __ fld_s(Address(rsp, 0));
  } else if (src->is_double_xmm() && !dest->is_double_xmm()) {
    __ movdbl(Address(rsp, 0), src->as_xmm_double_reg());
    __ fld_d(Address(rsp, 0));
  } else if (dest->is_single_xmm() && !src->is_single_xmm()) {
    __ fstp_s(Address(rsp, 0));
    __ movflt(dest->as_xmm_float_reg(), Address(rsp, 0));
  } else if (dest->is_double_xmm() && !src->is_double_xmm()) {
    __ fstp_d(Address(rsp, 0));
    __ movdbl(dest->as_xmm_double_reg(), Address(rsp, 0));

    // move between xmm-registers
  } else if (dest->is_single_xmm()) {
    assert(src->is_single_xmm(), "must match");
    __ movflt(dest->as_xmm_float_reg(), src->as_xmm_float_reg());
  } else if (dest->is_double_xmm()) {
    assert(src->is_double_xmm(), "must match");
    __ movdbl(dest->as_xmm_double_reg(), src->as_xmm_double_reg());

    // move between fpu-registers (no instruction necessary because of fpu-stack)
  } else if (dest->is_single_fpu() || dest->is_double_fpu()) {
    assert(src->is_single_fpu() || src->is_double_fpu(), "must match");
    assert(src->fpu() == dest->fpu(), "currently should be nothing to do");
  } else {
    ShouldNotReachHere();
  }
}

void LIR_Assembler::reg2stack(LIR_Opr src, LIR_Opr dest, BasicType type, bool pop_fpu_stack) {
  assert(src->is_register(), "should not call otherwise");
  assert(dest->is_stack(), "should not call otherwise");

  if (src->is_single_cpu()) {
    Address dst = frame_map()->address_for_slot(dest->single_stack_ix());
    if (type == T_OBJECT || type == T_ARRAY) {
      __ verify_oop(src->as_register());
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      __ movptr (dst, src->as_register());
    } else {
      __ movl (dst, src->as_register());
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    }

  } else if (src->is_double_cpu()) {
    Address dstLO = frame_map()->address_for_slot(dest->double_stack_ix(), lo_word_offset_in_bytes);
    Address dstHI = frame_map()->address_for_slot(dest->double_stack_ix(), hi_word_offset_in_bytes);
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    __ movptr (dstLO, src->as_register_lo());
    NOT_LP64(__ movptr (dstHI, src->as_register_hi()));
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  } else if (src->is_single_xmm()) {
    Address dst_addr = frame_map()->address_for_slot(dest->single_stack_ix());
    __ movflt(dst_addr, src->as_xmm_float_reg());

  } else if (src->is_double_xmm()) {
    Address dst_addr = frame_map()->address_for_slot(dest->double_stack_ix());
    __ movdbl(dst_addr, src->as_xmm_double_reg());

  } else if (src->is_single_fpu()) {
    assert(src->fpu_regnr() == 0, "argument must be on TOS");
    Address dst_addr = frame_map()->address_for_slot(dest->single_stack_ix());
    if (pop_fpu_stack)     __ fstp_s (dst_addr);
    else                   __ fst_s  (dst_addr);

  } else if (src->is_double_fpu()) {
    assert(src->fpu_regnrLo() == 0, "argument must be on TOS");
    Address dst_addr = frame_map()->address_for_slot(dest->double_stack_ix());
    if (pop_fpu_stack)     __ fstp_d (dst_addr);
    else                   __ fst_d  (dst_addr);

  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::reg2mem(LIR_Opr src, LIR_Opr dest, BasicType type, LIR_PatchCode patch_code, CodeEmitInfo* info, bool pop_fpu_stack, bool /* unaligned */) {
  LIR_Address* to_addr = dest->as_address_ptr();
  PatchingStub* patch = NULL;

  if (type == T_ARRAY || type == T_OBJECT) {
    __ verify_oop(src->as_register());
  }
  if (patch_code != lir_patch_none) {
    patch = new PatchingStub(_masm, PatchingStub::access_field_id);
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    Address toa = as_Address(to_addr);
    assert(toa.disp() != 0, "must have");
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  }
  if (info != NULL) {
    add_debug_info_for_null_check_here(info);
  }

  switch (type) {
    case T_FLOAT: {
      if (src->is_single_xmm()) {
        __ movflt(as_Address(to_addr), src->as_xmm_float_reg());
      } else {
        assert(src->is_single_fpu(), "must be");
        assert(src->fpu_regnr() == 0, "argument must be on TOS");
        if (pop_fpu_stack)      __ fstp_s(as_Address(to_addr));
        else                    __ fst_s (as_Address(to_addr));
      }
      break;
    }

    case T_DOUBLE: {
      if (src->is_double_xmm()) {
        __ movdbl(as_Address(to_addr), src->as_xmm_double_reg());
      } else {
        assert(src->is_double_fpu(), "must be");
        assert(src->fpu_regnrLo() == 0, "argument must be on TOS");
        if (pop_fpu_stack)      __ fstp_d(as_Address(to_addr));
        else                    __ fst_d (as_Address(to_addr));
      }
      break;
    }

    case T_ADDRESS: // fall through
    case T_ARRAY:   // fall through
    case T_OBJECT:  // fall through
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#ifdef _LP64
      __ movptr(as_Address(to_addr), src->as_register());
      break;
#endif // _LP64
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    case T_INT:
      __ movl(as_Address(to_addr), src->as_register());
      break;

    case T_LONG: {
      Register from_lo = src->as_register_lo();
      Register from_hi = src->as_register_hi();
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#ifdef _LP64
      __ movptr(as_Address_lo(to_addr), from_lo);
#else
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      Register base = to_addr->base()->as_register();
      Register index = noreg;
      if (to_addr->index()->is_register()) {
        index = to_addr->index()->as_register();
      }
      if (base == from_lo || index == from_lo) {
        assert(base != from_hi, "can't be");
        assert(index == noreg || (index != base && index != from_hi), "can't handle this");
        __ movl(as_Address_hi(to_addr), from_hi);
        if (patch != NULL) {
          patching_epilog(patch, lir_patch_high, base, info);
          patch = new PatchingStub(_masm, PatchingStub::access_field_id);
          patch_code = lir_patch_low;
        }
        __ movl(as_Address_lo(to_addr), from_lo);
      } else {
        assert(index == noreg || (index != base && index != from_lo), "can't handle this");
        __ movl(as_Address_lo(to_addr), from_lo);
        if (patch != NULL) {
          patching_epilog(patch, lir_patch_low, base, info);
          patch = new PatchingStub(_masm, PatchingStub::access_field_id);
          patch_code = lir_patch_high;
        }
        __ movl(as_Address_hi(to_addr), from_hi);
      }
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#endif // _LP64
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      break;
    }

    case T_BYTE:    // fall through
    case T_BOOLEAN: {
      Register src_reg = src->as_register();
      Address dst_addr = as_Address(to_addr);
      assert(VM_Version::is_P6() || src_reg->has_byte_register(), "must use byte registers if not P6");
      __ movb(dst_addr, src_reg);
      break;
    }

    case T_CHAR:    // fall through
    case T_SHORT:
      __ movw(as_Address(to_addr), src->as_register());
      break;

    default:
      ShouldNotReachHere();
  }

  if (patch_code != lir_patch_none) {
    patching_epilog(patch, patch_code, to_addr->base()->as_register(), info);
  }
}


void LIR_Assembler::stack2reg(LIR_Opr src, LIR_Opr dest, BasicType type) {
  assert(src->is_stack(), "should not call otherwise");
  assert(dest->is_register(), "should not call otherwise");

  if (dest->is_single_cpu()) {
    if (type == T_ARRAY || type == T_OBJECT) {
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      __ movptr(dest->as_register(), frame_map()->address_for_slot(src->single_stack_ix()));
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      __ verify_oop(dest->as_register());
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    } else {
      __ movl(dest->as_register(), frame_map()->address_for_slot(src->single_stack_ix()));
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    }

  } else if (dest->is_double_cpu()) {
    Address src_addr_LO = frame_map()->address_for_slot(src->double_stack_ix(), lo_word_offset_in_bytes);
    Address src_addr_HI = frame_map()->address_for_slot(src->double_stack_ix(), hi_word_offset_in_bytes);
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    __ movptr(dest->as_register_lo(), src_addr_LO);
    NOT_LP64(__ movptr(dest->as_register_hi(), src_addr_HI));
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  } else if (dest->is_single_xmm()) {
    Address src_addr = frame_map()->address_for_slot(src->single_stack_ix());
    __ movflt(dest->as_xmm_float_reg(), src_addr);

  } else if (dest->is_double_xmm()) {
    Address src_addr = frame_map()->address_for_slot(src->double_stack_ix());
    __ movdbl(dest->as_xmm_double_reg(), src_addr);

  } else if (dest->is_single_fpu()) {
    assert(dest->fpu_regnr() == 0, "dest must be TOS");
    Address src_addr = frame_map()->address_for_slot(src->single_stack_ix());
    __ fld_s(src_addr);

  } else if (dest->is_double_fpu()) {
    assert(dest->fpu_regnrLo() == 0, "dest must be TOS");
    Address src_addr = frame_map()->address_for_slot(src->double_stack_ix());
    __ fld_d(src_addr);

  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::stack2stack(LIR_Opr src, LIR_Opr dest, BasicType type) {
  if (src->is_single_stack()) {
1126 1127 1128 1129
    if (type == T_OBJECT || type == T_ARRAY) {
      __ pushptr(frame_map()->address_for_slot(src ->single_stack_ix()));
      __ popptr (frame_map()->address_for_slot(dest->single_stack_ix()));
    } else {
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#ifndef _LP64
1131 1132
      __ pushl(frame_map()->address_for_slot(src ->single_stack_ix()));
      __ popl (frame_map()->address_for_slot(dest->single_stack_ix()));
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#else
      //no pushl on 64bits
      __ movl(rscratch1, frame_map()->address_for_slot(src ->single_stack_ix()));
      __ movl(frame_map()->address_for_slot(dest->single_stack_ix()), rscratch1);
#endif
1138
    }
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  } else if (src->is_double_stack()) {
1141 1142 1143 1144
#ifdef _LP64
    __ pushptr(frame_map()->address_for_slot(src ->double_stack_ix()));
    __ popptr (frame_map()->address_for_slot(dest->double_stack_ix()));
#else
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    __ pushl(frame_map()->address_for_slot(src ->double_stack_ix(), 0));
1146
    // push and pop the part at src + wordSize, adding wordSize for the previous push
1147 1148
    __ pushl(frame_map()->address_for_slot(src ->double_stack_ix(), 2 * wordSize));
    __ popl (frame_map()->address_for_slot(dest->double_stack_ix(), 2 * wordSize));
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    __ popl (frame_map()->address_for_slot(dest->double_stack_ix(), 0));
1150
#endif // _LP64
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  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::mem2reg(LIR_Opr src, LIR_Opr dest, BasicType type, LIR_PatchCode patch_code, CodeEmitInfo* info, bool /* unaligned */) {
  assert(src->is_address(), "should not call otherwise");
  assert(dest->is_register(), "should not call otherwise");

  LIR_Address* addr = src->as_address_ptr();
  Address from_addr = as_Address(addr);

  switch (type) {
    case T_BOOLEAN: // fall through
    case T_BYTE:    // fall through
    case T_CHAR:    // fall through
    case T_SHORT:
      if (!VM_Version::is_P6() && !from_addr.uses(dest->as_register())) {
        // on pre P6 processors we may get partial register stalls
        // so blow away the value of to_rinfo before loading a
        // partial word into it.  Do it here so that it precedes
        // the potential patch point below.
1175
        __ xorptr(dest->as_register(), dest->as_register());
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      }
      break;
  }

  PatchingStub* patch = NULL;
  if (patch_code != lir_patch_none) {
    patch = new PatchingStub(_masm, PatchingStub::access_field_id);
1183
    assert(from_addr.disp() != 0, "must have");
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  }
  if (info != NULL) {
    add_debug_info_for_null_check_here(info);
  }

  switch (type) {
    case T_FLOAT: {
      if (dest->is_single_xmm()) {
        __ movflt(dest->as_xmm_float_reg(), from_addr);
      } else {
        assert(dest->is_single_fpu(), "must be");
        assert(dest->fpu_regnr() == 0, "dest must be TOS");
        __ fld_s(from_addr);
      }
      break;
    }

    case T_DOUBLE: {
      if (dest->is_double_xmm()) {
        __ movdbl(dest->as_xmm_double_reg(), from_addr);
      } else {
        assert(dest->is_double_fpu(), "must be");
        assert(dest->fpu_regnrLo() == 0, "dest must be TOS");
        __ fld_d(from_addr);
      }
      break;
    }

    case T_ADDRESS: // fall through
    case T_OBJECT:  // fall through
    case T_ARRAY:   // fall through
1215 1216 1217 1218
#ifdef _LP64
      __ movptr(dest->as_register(), from_addr);
      break;
#endif // _L64
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    case T_INT:
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      // %%% could this be a movl? this is safer but longer instruction
      __ movl2ptr(dest->as_register(), from_addr);
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      break;

    case T_LONG: {
      Register to_lo = dest->as_register_lo();
      Register to_hi = dest->as_register_hi();
1227 1228 1229
#ifdef _LP64
      __ movptr(to_lo, as_Address_lo(addr));
#else
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      Register base = addr->base()->as_register();
      Register index = noreg;
      if (addr->index()->is_register()) {
        index = addr->index()->as_register();
      }
      if ((base == to_lo && index == to_hi) ||
          (base == to_hi && index == to_lo)) {
        // addresses with 2 registers are only formed as a result of
        // array access so this code will never have to deal with
        // patches or null checks.
        assert(info == NULL && patch == NULL, "must be");
1241
        __ lea(to_hi, as_Address(addr));
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        __ movl(to_lo, Address(to_hi, 0));
        __ movl(to_hi, Address(to_hi, BytesPerWord));
      } else if (base == to_lo || index == to_lo) {
        assert(base != to_hi, "can't be");
        assert(index == noreg || (index != base && index != to_hi), "can't handle this");
        __ movl(to_hi, as_Address_hi(addr));
        if (patch != NULL) {
          patching_epilog(patch, lir_patch_high, base, info);
          patch = new PatchingStub(_masm, PatchingStub::access_field_id);
          patch_code = lir_patch_low;
        }
        __ movl(to_lo, as_Address_lo(addr));
      } else {
        assert(index == noreg || (index != base && index != to_lo), "can't handle this");
        __ movl(to_lo, as_Address_lo(addr));
        if (patch != NULL) {
          patching_epilog(patch, lir_patch_low, base, info);
          patch = new PatchingStub(_masm, PatchingStub::access_field_id);
          patch_code = lir_patch_high;
        }
        __ movl(to_hi, as_Address_hi(addr));
      }
1264
#endif // _LP64
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      break;
    }

    case T_BOOLEAN: // fall through
    case T_BYTE: {
      Register dest_reg = dest->as_register();
      assert(VM_Version::is_P6() || dest_reg->has_byte_register(), "must use byte registers if not P6");
      if (VM_Version::is_P6() || from_addr.uses(dest_reg)) {
1273
        __ movsbl(dest_reg, from_addr);
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      } else {
        __ movb(dest_reg, from_addr);
        __ shll(dest_reg, 24);
        __ sarl(dest_reg, 24);
      }
1279
      // These are unsigned so the zero extension on 64bit is just what we need
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      break;
    }

    case T_CHAR: {
      Register dest_reg = dest->as_register();
      assert(VM_Version::is_P6() || dest_reg->has_byte_register(), "must use byte registers if not P6");
      if (VM_Version::is_P6() || from_addr.uses(dest_reg)) {
1287
        __ movzwl(dest_reg, from_addr);
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      } else {
        __ movw(dest_reg, from_addr);
      }
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      // This is unsigned so the zero extension on 64bit is just what we need
      // __ movl2ptr(dest_reg, dest_reg);
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      break;
    }

    case T_SHORT: {
      Register dest_reg = dest->as_register();
      if (VM_Version::is_P6() || from_addr.uses(dest_reg)) {
1299
        __ movswl(dest_reg, from_addr);
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      } else {
        __ movw(dest_reg, from_addr);
        __ shll(dest_reg, 16);
        __ sarl(dest_reg, 16);
      }
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      // Might not be needed in 64bit but certainly doesn't hurt (except for code size)
      __ movl2ptr(dest_reg, dest_reg);
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      break;
    }

    default:
      ShouldNotReachHere();
  }

  if (patch != NULL) {
    patching_epilog(patch, patch_code, addr->base()->as_register(), info);
  }

  if (type == T_ARRAY || type == T_OBJECT) {
    __ verify_oop(dest->as_register());
  }
}


void LIR_Assembler::prefetchr(LIR_Opr src) {
  LIR_Address* addr = src->as_address_ptr();
  Address from_addr = as_Address(addr);

  if (VM_Version::supports_sse()) {
    switch (ReadPrefetchInstr) {
      case 0:
        __ prefetchnta(from_addr); break;
      case 1:
        __ prefetcht0(from_addr); break;
      case 2:
        __ prefetcht2(from_addr); break;
      default:
        ShouldNotReachHere(); break;
    }
  } else if (VM_Version::supports_3dnow()) {
    __ prefetchr(from_addr);
  }
}


void LIR_Assembler::prefetchw(LIR_Opr src) {
  LIR_Address* addr = src->as_address_ptr();
  Address from_addr = as_Address(addr);

  if (VM_Version::supports_sse()) {
    switch (AllocatePrefetchInstr) {
      case 0:
        __ prefetchnta(from_addr); break;
      case 1:
        __ prefetcht0(from_addr); break;
      case 2:
        __ prefetcht2(from_addr); break;
      case 3:
        __ prefetchw(from_addr); break;
      default:
        ShouldNotReachHere(); break;
    }
  } else if (VM_Version::supports_3dnow()) {
    __ prefetchw(from_addr);
  }
}


NEEDS_CLEANUP; // This could be static?
Address::ScaleFactor LIR_Assembler::array_element_size(BasicType type) const {
1370
  int elem_size = type2aelembytes(type);
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  switch (elem_size) {
    case 1: return Address::times_1;
    case 2: return Address::times_2;
    case 4: return Address::times_4;
    case 8: return Address::times_8;
  }
  ShouldNotReachHere();
  return Address::no_scale;
}


void LIR_Assembler::emit_op3(LIR_Op3* op) {
  switch (op->code()) {
    case lir_idiv:
    case lir_irem:
      arithmetic_idiv(op->code(),
                      op->in_opr1(),
                      op->in_opr2(),
                      op->in_opr3(),
                      op->result_opr(),
                      op->info());
      break;
    default:      ShouldNotReachHere(); break;
  }
}

void LIR_Assembler::emit_opBranch(LIR_OpBranch* op) {
#ifdef ASSERT
  assert(op->block() == NULL || op->block()->label() == op->label(), "wrong label");
  if (op->block() != NULL)  _branch_target_blocks.append(op->block());
  if (op->ublock() != NULL) _branch_target_blocks.append(op->ublock());
#endif

  if (op->cond() == lir_cond_always) {
    if (op->info() != NULL) add_debug_info_for_branch(op->info());
    __ jmp (*(op->label()));
  } else {
    Assembler::Condition acond = Assembler::zero;
    if (op->code() == lir_cond_float_branch) {
      assert(op->ublock() != NULL, "must have unordered successor");
      __ jcc(Assembler::parity, *(op->ublock()->label()));
      switch(op->cond()) {
        case lir_cond_equal:        acond = Assembler::equal;      break;
        case lir_cond_notEqual:     acond = Assembler::notEqual;   break;
        case lir_cond_less:         acond = Assembler::below;      break;
        case lir_cond_lessEqual:    acond = Assembler::belowEqual; break;
        case lir_cond_greaterEqual: acond = Assembler::aboveEqual; break;
        case lir_cond_greater:      acond = Assembler::above;      break;
        default:                         ShouldNotReachHere();
      }
    } else {
      switch (op->cond()) {
        case lir_cond_equal:        acond = Assembler::equal;       break;
        case lir_cond_notEqual:     acond = Assembler::notEqual;    break;
        case lir_cond_less:         acond = Assembler::less;        break;
        case lir_cond_lessEqual:    acond = Assembler::lessEqual;   break;
        case lir_cond_greaterEqual: acond = Assembler::greaterEqual;break;
        case lir_cond_greater:      acond = Assembler::greater;     break;
        case lir_cond_belowEqual:   acond = Assembler::belowEqual;  break;
        case lir_cond_aboveEqual:   acond = Assembler::aboveEqual;  break;
        default:                         ShouldNotReachHere();
      }
    }
    __ jcc(acond,*(op->label()));
  }
}

void LIR_Assembler::emit_opConvert(LIR_OpConvert* op) {
  LIR_Opr src  = op->in_opr();
  LIR_Opr dest = op->result_opr();

  switch (op->bytecode()) {
    case Bytecodes::_i2l:
1444 1445 1446
#ifdef _LP64
      __ movl2ptr(dest->as_register_lo(), src->as_register());
#else
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      move_regs(src->as_register(), dest->as_register_lo());
      move_regs(src->as_register(), dest->as_register_hi());
      __ sarl(dest->as_register_hi(), 31);
1450
#endif // LP64
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      break;

    case Bytecodes::_l2i:
      move_regs(src->as_register_lo(), dest->as_register());
      break;

    case Bytecodes::_i2b:
      move_regs(src->as_register(), dest->as_register());
      __ sign_extend_byte(dest->as_register());
      break;

    case Bytecodes::_i2c:
      move_regs(src->as_register(), dest->as_register());
      __ andl(dest->as_register(), 0xFFFF);
      break;

    case Bytecodes::_i2s:
      move_regs(src->as_register(), dest->as_register());
      __ sign_extend_short(dest->as_register());
      break;


    case Bytecodes::_f2d:
    case Bytecodes::_d2f:
      if (dest->is_single_xmm()) {
        __ cvtsd2ss(dest->as_xmm_float_reg(), src->as_xmm_double_reg());
      } else if (dest->is_double_xmm()) {
        __ cvtss2sd(dest->as_xmm_double_reg(), src->as_xmm_float_reg());
      } else {
        assert(src->fpu() == dest->fpu(), "register must be equal");
        // do nothing (float result is rounded later through spilling)
      }
      break;

    case Bytecodes::_i2f:
    case Bytecodes::_i2d:
      if (dest->is_single_xmm()) {
1488
        __ cvtsi2ssl(dest->as_xmm_float_reg(), src->as_register());
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      } else if (dest->is_double_xmm()) {
1490
        __ cvtsi2sdl(dest->as_xmm_double_reg(), src->as_register());
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      } else {
        assert(dest->fpu() == 0, "result must be on TOS");
        __ movl(Address(rsp, 0), src->as_register());
        __ fild_s(Address(rsp, 0));
      }
      break;

    case Bytecodes::_f2i:
    case Bytecodes::_d2i:
      if (src->is_single_xmm()) {
1501
        __ cvttss2sil(dest->as_register(), src->as_xmm_float_reg());
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      } else if (src->is_double_xmm()) {
1503
        __ cvttsd2sil(dest->as_register(), src->as_xmm_double_reg());
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      } else {
        assert(src->fpu() == 0, "input must be on TOS");
        __ fldcw(ExternalAddress(StubRoutines::addr_fpu_cntrl_wrd_trunc()));
        __ fist_s(Address(rsp, 0));
        __ movl(dest->as_register(), Address(rsp, 0));
        __ fldcw(ExternalAddress(StubRoutines::addr_fpu_cntrl_wrd_std()));
      }

      // IA32 conversion instructions do not match JLS for overflow, underflow and NaN -> fixup in stub
      assert(op->stub() != NULL, "stub required");
      __ cmpl(dest->as_register(), 0x80000000);
      __ jcc(Assembler::equal, *op->stub()->entry());
      __ bind(*op->stub()->continuation());
      break;

    case Bytecodes::_l2f:
    case Bytecodes::_l2d:
      assert(!dest->is_xmm_register(), "result in xmm register not supported (no SSE instruction present)");
      assert(dest->fpu() == 0, "result must be on TOS");

1524 1525
      __ movptr(Address(rsp, 0),            src->as_register_lo());
      NOT_LP64(__ movl(Address(rsp, BytesPerWord), src->as_register_hi()));
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      __ fild_d(Address(rsp, 0));
      // float result is rounded later through spilling
      break;

    case Bytecodes::_f2l:
    case Bytecodes::_d2l:
      assert(!src->is_xmm_register(), "input in xmm register not supported (no SSE instruction present)");
      assert(src->fpu() == 0, "input must be on TOS");
1534
      assert(dest == FrameMap::long0_opr, "runtime stub places result in these registers");
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      // instruction sequence too long to inline it here
      {
        __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::fpu2long_stub_id)));
      }
      break;

    default: ShouldNotReachHere();
  }
}

void LIR_Assembler::emit_alloc_obj(LIR_OpAllocObj* op) {
  if (op->init_check()) {
    __ cmpl(Address(op->klass()->as_register(),
                    instanceKlass::init_state_offset_in_bytes() + sizeof(oopDesc)),
            instanceKlass::fully_initialized);
    add_debug_info_for_null_check_here(op->stub()->info());
    __ jcc(Assembler::notEqual, *op->stub()->entry());
  }
  __ allocate_object(op->obj()->as_register(),
                     op->tmp1()->as_register(),
                     op->tmp2()->as_register(),
                     op->header_size(),
                     op->object_size(),
                     op->klass()->as_register(),
                     *op->stub()->entry());
  __ bind(*op->stub()->continuation());
}

void LIR_Assembler::emit_alloc_array(LIR_OpAllocArray* op) {
  if (UseSlowPath ||
      (!UseFastNewObjectArray && (op->type() == T_OBJECT || op->type() == T_ARRAY)) ||
      (!UseFastNewTypeArray   && (op->type() != T_OBJECT && op->type() != T_ARRAY))) {
    __ jmp(*op->stub()->entry());
  } else {
    Register len =  op->len()->as_register();
    Register tmp1 = op->tmp1()->as_register();
    Register tmp2 = op->tmp2()->as_register();
    Register tmp3 = op->tmp3()->as_register();
    if (len == tmp1) {
      tmp1 = tmp3;
    } else if (len == tmp2) {
      tmp2 = tmp3;
    } else if (len == tmp3) {
      // everything is ok
    } else {
1581
      __ mov(tmp3, len);
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    }
    __ allocate_array(op->obj()->as_register(),
                      len,
                      tmp1,
                      tmp2,
                      arrayOopDesc::header_size(op->type()),
                      array_element_size(op->type()),
                      op->klass()->as_register(),
                      *op->stub()->entry());
  }
  __ bind(*op->stub()->continuation());
}



void LIR_Assembler::emit_opTypeCheck(LIR_OpTypeCheck* op) {
  LIR_Code code = op->code();
  if (code == lir_store_check) {
    Register value = op->object()->as_register();
    Register array = op->array()->as_register();
    Register k_RInfo = op->tmp1()->as_register();
    Register klass_RInfo = op->tmp2()->as_register();
    Register Rtmp1 = op->tmp3()->as_register();

    CodeStub* stub = op->stub();
    Label done;
1608
    __ cmpptr(value, (int32_t)NULL_WORD);
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    __ jcc(Assembler::equal, done);
    add_debug_info_for_null_check_here(op->info_for_exception());
1611 1612
    __ movptr(k_RInfo, Address(array, oopDesc::klass_offset_in_bytes()));
    __ movptr(klass_RInfo, Address(value, oopDesc::klass_offset_in_bytes()));
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    // get instance klass
1615
    __ movptr(k_RInfo, Address(k_RInfo, objArrayKlass::element_klass_offset_in_bytes() + sizeof(oopDesc)));
1616 1617 1618
    // perform the fast part of the checking logic
    __ check_klass_subtype_fast_path(klass_RInfo, k_RInfo, Rtmp1, &done, stub->entry(), NULL);
    // call out-of-line instance of __ check_klass_subtype_slow_path(...):
1619 1620
    __ push(klass_RInfo);
    __ push(k_RInfo);
D
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    __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::slow_subtype_check_id)));
1622 1623 1624
    __ pop(klass_RInfo);
    __ pop(k_RInfo);
    // result is a boolean
D
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1625 1626 1627 1628 1629 1630 1631 1632 1633 1634 1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 1649 1650 1651 1652 1653 1654
    __ cmpl(k_RInfo, 0);
    __ jcc(Assembler::equal, *stub->entry());
    __ bind(done);
  } else if (op->code() == lir_checkcast) {
    // we always need a stub for the failure case.
    CodeStub* stub = op->stub();
    Register obj = op->object()->as_register();
    Register k_RInfo = op->tmp1()->as_register();
    Register klass_RInfo = op->tmp2()->as_register();
    Register dst = op->result_opr()->as_register();
    ciKlass* k = op->klass();
    Register Rtmp1 = noreg;

    Label done;
    if (obj == k_RInfo) {
      k_RInfo = dst;
    } else if (obj == klass_RInfo) {
      klass_RInfo = dst;
    }
    if (k->is_loaded()) {
      select_different_registers(obj, dst, k_RInfo, klass_RInfo);
    } else {
      Rtmp1 = op->tmp3()->as_register();
      select_different_registers(obj, dst, k_RInfo, klass_RInfo, Rtmp1);
    }

    assert_different_registers(obj, k_RInfo, klass_RInfo);
    if (!k->is_loaded()) {
      jobject2reg_with_patching(k_RInfo, op->info_for_patch());
    } else {
1655
#ifdef _LP64
1656
      __ movoop(k_RInfo, k->constant_encoding());
1657
#else
D
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      k_RInfo = noreg;
1659
#endif // _LP64
D
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    }
    assert(obj != k_RInfo, "must be different");
1662
    __ cmpptr(obj, (int32_t)NULL_WORD);
D
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1663 1664 1665 1666 1667 1668 1669 1670 1671 1672 1673 1674 1675 1676 1677 1678
    if (op->profiled_method() != NULL) {
      ciMethod* method = op->profiled_method();
      int bci          = op->profiled_bci();

      Label profile_done;
      __ jcc(Assembler::notEqual, profile_done);
      // Object is null; update methodDataOop
      ciMethodData* md = method->method_data();
      if (md == NULL) {
        bailout("out of memory building methodDataOop");
        return;
      }
      ciProfileData* data = md->bci_to_data(bci);
      assert(data != NULL,       "need data for checkcast");
      assert(data->is_BitData(), "need BitData for checkcast");
      Register mdo  = klass_RInfo;
1679
      __ movoop(mdo, md->constant_encoding());
D
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      Address data_addr(mdo, md->byte_offset_of_slot(data, DataLayout::header_offset()));
      int header_bits = DataLayout::flag_mask_to_header_mask(BitData::null_seen_byte_constant());
      __ orl(data_addr, header_bits);
      __ jmp(done);
      __ bind(profile_done);
    } else {
      __ jcc(Assembler::equal, done);
    }
    __ verify_oop(obj);

    if (op->fast_check()) {
      // get object classo
      // not a safepoint as obj null check happens earlier
      if (k->is_loaded()) {
1694 1695 1696
#ifdef _LP64
        __ cmpptr(k_RInfo, Address(obj, oopDesc::klass_offset_in_bytes()));
#else
1697
        __ cmpoop(Address(obj, oopDesc::klass_offset_in_bytes()), k->constant_encoding());
1698
#endif // _LP64
D
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      } else {
1700
        __ cmpptr(k_RInfo, Address(obj, oopDesc::klass_offset_in_bytes()));
D
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      }
      __ jcc(Assembler::notEqual, *stub->entry());
      __ bind(done);
    } else {
      // get object class
      // not a safepoint as obj null check happens earlier
1708
      __ movptr(klass_RInfo, Address(obj, oopDesc::klass_offset_in_bytes()));
D
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      if (k->is_loaded()) {
        // See if we get an immediate positive hit
1711 1712 1713
#ifdef _LP64
        __ cmpptr(k_RInfo, Address(klass_RInfo, k->super_check_offset()));
#else
1714
        __ cmpoop(Address(klass_RInfo, k->super_check_offset()), k->constant_encoding());
1715
#endif // _LP64
D
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        if (sizeof(oopDesc) + Klass::secondary_super_cache_offset_in_bytes() != k->super_check_offset()) {
          __ jcc(Assembler::notEqual, *stub->entry());
        } else {
          // See if we get an immediate positive hit
          __ jcc(Assembler::equal, done);
          // check for self
1722 1723 1724
#ifdef _LP64
          __ cmpptr(klass_RInfo, k_RInfo);
#else
1725
          __ cmpoop(klass_RInfo, k->constant_encoding());
1726
#endif // _LP64
D
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          __ jcc(Assembler::equal, done);

1729 1730 1731 1732
          __ push(klass_RInfo);
#ifdef _LP64
          __ push(k_RInfo);
#else
1733
          __ pushoop(k->constant_encoding());
1734
#endif // _LP64
D
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          __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::slow_subtype_check_id)));
1736 1737 1738
          __ pop(klass_RInfo);
          __ pop(klass_RInfo);
          // result is a boolean
D
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          __ cmpl(klass_RInfo, 0);
          __ jcc(Assembler::equal, *stub->entry());
        }
        __ bind(done);
      } else {
1744 1745 1746
        // perform the fast part of the checking logic
        __ check_klass_subtype_fast_path(klass_RInfo, k_RInfo, Rtmp1, &done, stub->entry(), NULL);
        // call out-of-line instance of __ check_klass_subtype_slow_path(...):
1747 1748
        __ push(klass_RInfo);
        __ push(k_RInfo);
D
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        __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::slow_subtype_check_id)));
1750 1751 1752
        __ pop(klass_RInfo);
        __ pop(k_RInfo);
        // result is a boolean
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        __ cmpl(k_RInfo, 0);
        __ jcc(Assembler::equal, *stub->entry());
        __ bind(done);
      }

    }
    if (dst != obj) {
1760
      __ mov(dst, obj);
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    }
  } else if (code == lir_instanceof) {
    Register obj = op->object()->as_register();
    Register k_RInfo = op->tmp1()->as_register();
    Register klass_RInfo = op->tmp2()->as_register();
    Register dst = op->result_opr()->as_register();
    ciKlass* k = op->klass();

    Label done;
    Label zero;
    Label one;
    if (obj == k_RInfo) {
      k_RInfo = klass_RInfo;
      klass_RInfo = obj;
    }
    // patching may screw with our temporaries on sparc,
    // so let's do it before loading the class
    if (!k->is_loaded()) {
      jobject2reg_with_patching(k_RInfo, op->info_for_patch());
1780
    } else {
1781
      LP64_ONLY(__ movoop(k_RInfo, k->constant_encoding()));
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    }
    assert(obj != k_RInfo, "must be different");

    __ verify_oop(obj);
    if (op->fast_check()) {
1787
      __ cmpptr(obj, (int32_t)NULL_WORD);
D
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      __ jcc(Assembler::equal, zero);
      // get object class
      // not a safepoint as obj null check happens earlier
1791
      if (LP64_ONLY(false &&) k->is_loaded()) {
1792
        NOT_LP64(__ cmpoop(Address(obj, oopDesc::klass_offset_in_bytes()), k->constant_encoding()));
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        k_RInfo = noreg;
      } else {
1795
        __ cmpptr(k_RInfo, Address(obj, oopDesc::klass_offset_in_bytes()));
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      }
      __ jcc(Assembler::equal, one);
    } else {
      // get object class
      // not a safepoint as obj null check happens earlier
1802
      __ cmpptr(obj, (int32_t)NULL_WORD);
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      __ jcc(Assembler::equal, zero);
1804 1805 1806
      __ movptr(klass_RInfo, Address(obj, oopDesc::klass_offset_in_bytes()));

#ifndef _LP64
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      if (k->is_loaded()) {
        // See if we get an immediate positive hit
1809
        __ cmpoop(Address(klass_RInfo, k->super_check_offset()), k->constant_encoding());
D
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        __ jcc(Assembler::equal, one);
        if (sizeof(oopDesc) + Klass::secondary_super_cache_offset_in_bytes() == k->super_check_offset()) {
          // check for self
1813
          __ cmpoop(klass_RInfo, k->constant_encoding());
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          __ jcc(Assembler::equal, one);
1815
          __ push(klass_RInfo);
1816
          __ pushoop(k->constant_encoding());
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          __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::slow_subtype_check_id)));
1818 1819
          __ pop(klass_RInfo);
          __ pop(dst);
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          __ jmp(done);
        }
1822 1823
      }
        else // next block is unconditional if LP64:
1824
#endif // LP64
1825
      {
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        assert(dst != klass_RInfo && dst != k_RInfo, "need 3 registers");

1828 1829 1830
        // perform the fast part of the checking logic
        __ check_klass_subtype_fast_path(klass_RInfo, k_RInfo, dst, &one, &zero, NULL);
        // call out-of-line instance of __ check_klass_subtype_slow_path(...):
1831 1832
        __ push(klass_RInfo);
        __ push(k_RInfo);
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        __ call(RuntimeAddress(Runtime1::entry_for(Runtime1::slow_subtype_check_id)));
1834 1835
        __ pop(klass_RInfo);
        __ pop(dst);
D
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        __ jmp(done);
      }
    }
    __ bind(zero);
1840
    __ xorptr(dst, dst);
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    __ jmp(done);
    __ bind(one);
1843
    __ movptr(dst, 1);
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    __ bind(done);
  } else {
    ShouldNotReachHere();
  }

}


void LIR_Assembler::emit_compare_and_swap(LIR_OpCompareAndSwap* op) {
1853
  if (LP64_ONLY(false &&) op->code() == lir_cas_long && VM_Version::supports_cx8()) {
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    assert(op->cmp_value()->as_register_lo() == rax, "wrong register");
    assert(op->cmp_value()->as_register_hi() == rdx, "wrong register");
    assert(op->new_value()->as_register_lo() == rbx, "wrong register");
    assert(op->new_value()->as_register_hi() == rcx, "wrong register");
    Register addr = op->addr()->as_register();
    if (os::is_MP()) {
      __ lock();
    }
1862
    NOT_LP64(__ cmpxchg8(Address(addr, 0)));
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1864 1865 1866
  } else if (op->code() == lir_cas_int || op->code() == lir_cas_obj ) {
    NOT_LP64(assert(op->addr()->is_single_cpu(), "must be single");)
    Register addr = (op->addr()->is_single_cpu() ? op->addr()->as_register() : op->addr()->as_register_lo());
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    Register newval = op->new_value()->as_register();
    Register cmpval = op->cmp_value()->as_register();
    assert(cmpval == rax, "wrong register");
    assert(newval != NULL, "new val must be register");
    assert(cmpval != newval, "cmp and new values must be in different registers");
    assert(cmpval != addr, "cmp and addr must be in different registers");
    assert(newval != addr, "new value and addr must be in different registers");
    if (os::is_MP()) {
      __ lock();
    }
1877 1878 1879 1880 1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898
    if ( op->code() == lir_cas_obj) {
      __ cmpxchgptr(newval, Address(addr, 0));
    } else if (op->code() == lir_cas_int) {
      __ cmpxchgl(newval, Address(addr, 0));
    } else {
      LP64_ONLY(__ cmpxchgq(newval, Address(addr, 0)));
    }
#ifdef _LP64
  } else if (op->code() == lir_cas_long) {
    Register addr = (op->addr()->is_single_cpu() ? op->addr()->as_register() : op->addr()->as_register_lo());
    Register newval = op->new_value()->as_register_lo();
    Register cmpval = op->cmp_value()->as_register_lo();
    assert(cmpval == rax, "wrong register");
    assert(newval != NULL, "new val must be register");
    assert(cmpval != newval, "cmp and new values must be in different registers");
    assert(cmpval != addr, "cmp and addr must be in different registers");
    assert(newval != addr, "new value and addr must be in different registers");
    if (os::is_MP()) {
      __ lock();
    }
    __ cmpxchgq(newval, Address(addr, 0));
#endif // _LP64
D
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1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932
  } else {
    Unimplemented();
  }
}


void LIR_Assembler::cmove(LIR_Condition condition, LIR_Opr opr1, LIR_Opr opr2, LIR_Opr result) {
  Assembler::Condition acond, ncond;
  switch (condition) {
    case lir_cond_equal:        acond = Assembler::equal;        ncond = Assembler::notEqual;     break;
    case lir_cond_notEqual:     acond = Assembler::notEqual;     ncond = Assembler::equal;        break;
    case lir_cond_less:         acond = Assembler::less;         ncond = Assembler::greaterEqual; break;
    case lir_cond_lessEqual:    acond = Assembler::lessEqual;    ncond = Assembler::greater;      break;
    case lir_cond_greaterEqual: acond = Assembler::greaterEqual; ncond = Assembler::less;         break;
    case lir_cond_greater:      acond = Assembler::greater;      ncond = Assembler::lessEqual;    break;
    case lir_cond_belowEqual:   acond = Assembler::belowEqual;   ncond = Assembler::above;        break;
    case lir_cond_aboveEqual:   acond = Assembler::aboveEqual;   ncond = Assembler::below;        break;
    default:                    ShouldNotReachHere();
  }

  if (opr1->is_cpu_register()) {
    reg2reg(opr1, result);
  } else if (opr1->is_stack()) {
    stack2reg(opr1, result, result->type());
  } else if (opr1->is_constant()) {
    const2reg(opr1, result, lir_patch_none, NULL);
  } else {
    ShouldNotReachHere();
  }

  if (VM_Version::supports_cmov() && !opr2->is_constant()) {
    // optimized version that does not require a branch
    if (opr2->is_single_cpu()) {
      assert(opr2->cpu_regnr() != result->cpu_regnr(), "opr2 already overwritten by previous move");
1933
      __ cmov(ncond, result->as_register(), opr2->as_register());
D
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    } else if (opr2->is_double_cpu()) {
      assert(opr2->cpu_regnrLo() != result->cpu_regnrLo() && opr2->cpu_regnrLo() != result->cpu_regnrHi(), "opr2 already overwritten by previous move");
      assert(opr2->cpu_regnrHi() != result->cpu_regnrLo() && opr2->cpu_regnrHi() != result->cpu_regnrHi(), "opr2 already overwritten by previous move");
1937 1938
      __ cmovptr(ncond, result->as_register_lo(), opr2->as_register_lo());
      NOT_LP64(__ cmovptr(ncond, result->as_register_hi(), opr2->as_register_hi());)
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    } else if (opr2->is_single_stack()) {
      __ cmovl(ncond, result->as_register(), frame_map()->address_for_slot(opr2->single_stack_ix()));
    } else if (opr2->is_double_stack()) {
1942 1943
      __ cmovptr(ncond, result->as_register_lo(), frame_map()->address_for_slot(opr2->double_stack_ix(), lo_word_offset_in_bytes));
      NOT_LP64(__ cmovptr(ncond, result->as_register_hi(), frame_map()->address_for_slot(opr2->double_stack_ix(), hi_word_offset_in_bytes));)
D
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1944 1945 1946 1947 1948 1949 1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967 1968 1969 1970 1971 1972 1973 1974 1975 1976 1977 1978 1979 1980 1981 1982 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
    } else {
      ShouldNotReachHere();
    }

  } else {
    Label skip;
    __ jcc (acond, skip);
    if (opr2->is_cpu_register()) {
      reg2reg(opr2, result);
    } else if (opr2->is_stack()) {
      stack2reg(opr2, result, result->type());
    } else if (opr2->is_constant()) {
      const2reg(opr2, result, lir_patch_none, NULL);
    } else {
      ShouldNotReachHere();
    }
    __ bind(skip);
  }
}


void LIR_Assembler::arith_op(LIR_Code code, LIR_Opr left, LIR_Opr right, LIR_Opr dest, CodeEmitInfo* info, bool pop_fpu_stack) {
  assert(info == NULL, "should never be used, idiv/irem and ldiv/lrem not handled by this method");

  if (left->is_single_cpu()) {
    assert(left == dest, "left and dest must be equal");
    Register lreg = left->as_register();

    if (right->is_single_cpu()) {
      // cpu register - cpu register
      Register rreg = right->as_register();
      switch (code) {
        case lir_add: __ addl (lreg, rreg); break;
        case lir_sub: __ subl (lreg, rreg); break;
        case lir_mul: __ imull(lreg, rreg); break;
        default:      ShouldNotReachHere();
      }

    } else if (right->is_stack()) {
      // cpu register - stack
      Address raddr = frame_map()->address_for_slot(right->single_stack_ix());
      switch (code) {
        case lir_add: __ addl(lreg, raddr); break;
        case lir_sub: __ subl(lreg, raddr); break;
        default:      ShouldNotReachHere();
      }

    } else if (right->is_constant()) {
      // cpu register - constant
      jint c = right->as_constant_ptr()->as_jint();
      switch (code) {
        case lir_add: {
          __ increment(lreg, c);
          break;
        }
        case lir_sub: {
          __ decrement(lreg, c);
          break;
        }
        default: ShouldNotReachHere();
      }

    } else {
      ShouldNotReachHere();
    }

  } else if (left->is_double_cpu()) {
    assert(left == dest, "left and dest must be equal");
    Register lreg_lo = left->as_register_lo();
    Register lreg_hi = left->as_register_hi();

    if (right->is_double_cpu()) {
      // cpu register - cpu register
      Register rreg_lo = right->as_register_lo();
      Register rreg_hi = right->as_register_hi();
2019 2020
      NOT_LP64(assert_different_registers(lreg_lo, lreg_hi, rreg_lo, rreg_hi));
      LP64_ONLY(assert_different_registers(lreg_lo, rreg_lo));
D
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      switch (code) {
        case lir_add:
2023 2024
          __ addptr(lreg_lo, rreg_lo);
          NOT_LP64(__ adcl(lreg_hi, rreg_hi));
D
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          break;
        case lir_sub:
2027 2028
          __ subptr(lreg_lo, rreg_lo);
          NOT_LP64(__ sbbl(lreg_hi, rreg_hi));
D
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          break;
        case lir_mul:
2031 2032 2033
#ifdef _LP64
          __ imulq(lreg_lo, rreg_lo);
#else
D
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          assert(lreg_lo == rax && lreg_hi == rdx, "must be");
          __ imull(lreg_hi, rreg_lo);
          __ imull(rreg_hi, lreg_lo);
          __ addl (rreg_hi, lreg_hi);
          __ mull (rreg_lo);
          __ addl (lreg_hi, rreg_hi);
2040
#endif // _LP64
D
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          break;
        default:
          ShouldNotReachHere();
      }

    } else if (right->is_constant()) {
      // cpu register - constant
2048 2049 2050 2051 2052 2053 2054 2055 2056 2057 2058 2059 2060 2061
#ifdef _LP64
      jlong c = right->as_constant_ptr()->as_jlong_bits();
      __ movptr(r10, (intptr_t) c);
      switch (code) {
        case lir_add:
          __ addptr(lreg_lo, r10);
          break;
        case lir_sub:
          __ subptr(lreg_lo, r10);
          break;
        default:
          ShouldNotReachHere();
      }
#else
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      jint c_lo = right->as_constant_ptr()->as_jint_lo();
      jint c_hi = right->as_constant_ptr()->as_jint_hi();
      switch (code) {
        case lir_add:
2066
          __ addptr(lreg_lo, c_lo);
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          __ adcl(lreg_hi, c_hi);
          break;
        case lir_sub:
2070
          __ subptr(lreg_lo, c_lo);
D
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          __ sbbl(lreg_hi, c_hi);
          break;
        default:
          ShouldNotReachHere();
      }
2076
#endif // _LP64
D
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    } else {
      ShouldNotReachHere();
    }

  } else if (left->is_single_xmm()) {
    assert(left == dest, "left and dest must be equal");
    XMMRegister lreg = left->as_xmm_float_reg();

    if (right->is_single_xmm()) {
      XMMRegister rreg = right->as_xmm_float_reg();
      switch (code) {
        case lir_add: __ addss(lreg, rreg);  break;
        case lir_sub: __ subss(lreg, rreg);  break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ mulss(lreg, rreg);  break;
        case lir_div_strictfp: // fall through
        case lir_div: __ divss(lreg, rreg);  break;
        default: ShouldNotReachHere();
      }
    } else {
      Address raddr;
      if (right->is_single_stack()) {
        raddr = frame_map()->address_for_slot(right->single_stack_ix());
      } else if (right->is_constant()) {
        // hack for now
        raddr = __ as_Address(InternalAddress(float_constant(right->as_jfloat())));
      } else {
        ShouldNotReachHere();
      }
      switch (code) {
        case lir_add: __ addss(lreg, raddr);  break;
        case lir_sub: __ subss(lreg, raddr);  break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ mulss(lreg, raddr);  break;
        case lir_div_strictfp: // fall through
        case lir_div: __ divss(lreg, raddr);  break;
        default: ShouldNotReachHere();
      }
    }

  } else if (left->is_double_xmm()) {
    assert(left == dest, "left and dest must be equal");

    XMMRegister lreg = left->as_xmm_double_reg();
    if (right->is_double_xmm()) {
      XMMRegister rreg = right->as_xmm_double_reg();
      switch (code) {
        case lir_add: __ addsd(lreg, rreg);  break;
        case lir_sub: __ subsd(lreg, rreg);  break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ mulsd(lreg, rreg);  break;
        case lir_div_strictfp: // fall through
        case lir_div: __ divsd(lreg, rreg);  break;
        default: ShouldNotReachHere();
      }
    } else {
      Address raddr;
      if (right->is_double_stack()) {
        raddr = frame_map()->address_for_slot(right->double_stack_ix());
      } else if (right->is_constant()) {
        // hack for now
        raddr = __ as_Address(InternalAddress(double_constant(right->as_jdouble())));
      } else {
        ShouldNotReachHere();
      }
      switch (code) {
        case lir_add: __ addsd(lreg, raddr);  break;
        case lir_sub: __ subsd(lreg, raddr);  break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ mulsd(lreg, raddr);  break;
        case lir_div_strictfp: // fall through
        case lir_div: __ divsd(lreg, raddr);  break;
        default: ShouldNotReachHere();
      }
    }

  } else if (left->is_single_fpu()) {
    assert(dest->is_single_fpu(),  "fpu stack allocation required");

    if (right->is_single_fpu()) {
      arith_fpu_implementation(code, left->fpu_regnr(), right->fpu_regnr(), dest->fpu_regnr(), pop_fpu_stack);

    } else {
      assert(left->fpu_regnr() == 0, "left must be on TOS");
      assert(dest->fpu_regnr() == 0, "dest must be on TOS");

      Address raddr;
      if (right->is_single_stack()) {
        raddr = frame_map()->address_for_slot(right->single_stack_ix());
      } else if (right->is_constant()) {
        address const_addr = float_constant(right->as_jfloat());
        assert(const_addr != NULL, "incorrect float/double constant maintainance");
        // hack for now
        raddr = __ as_Address(InternalAddress(const_addr));
      } else {
        ShouldNotReachHere();
      }

      switch (code) {
        case lir_add: __ fadd_s(raddr); break;
        case lir_sub: __ fsub_s(raddr); break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ fmul_s(raddr); break;
        case lir_div_strictfp: // fall through
        case lir_div: __ fdiv_s(raddr); break;
        default:      ShouldNotReachHere();
      }
    }

  } else if (left->is_double_fpu()) {
    assert(dest->is_double_fpu(),  "fpu stack allocation required");

    if (code == lir_mul_strictfp || code == lir_div_strictfp) {
      // Double values require special handling for strictfp mul/div on x86
      __ fld_x(ExternalAddress(StubRoutines::addr_fpu_subnormal_bias1()));
      __ fmulp(left->fpu_regnrLo() + 1);
    }

    if (right->is_double_fpu()) {
      arith_fpu_implementation(code, left->fpu_regnrLo(), right->fpu_regnrLo(), dest->fpu_regnrLo(), pop_fpu_stack);

    } else {
      assert(left->fpu_regnrLo() == 0, "left must be on TOS");
      assert(dest->fpu_regnrLo() == 0, "dest must be on TOS");

      Address raddr;
      if (right->is_double_stack()) {
        raddr = frame_map()->address_for_slot(right->double_stack_ix());
      } else if (right->is_constant()) {
        // hack for now
        raddr = __ as_Address(InternalAddress(double_constant(right->as_jdouble())));
      } else {
        ShouldNotReachHere();
      }

      switch (code) {
        case lir_add: __ fadd_d(raddr); break;
        case lir_sub: __ fsub_d(raddr); break;
        case lir_mul_strictfp: // fall through
        case lir_mul: __ fmul_d(raddr); break;
        case lir_div_strictfp: // fall through
        case lir_div: __ fdiv_d(raddr); break;
        default: ShouldNotReachHere();
      }
    }

    if (code == lir_mul_strictfp || code == lir_div_strictfp) {
      // Double values require special handling for strictfp mul/div on x86
      __ fld_x(ExternalAddress(StubRoutines::addr_fpu_subnormal_bias2()));
      __ fmulp(dest->fpu_regnrLo() + 1);
    }

  } else if (left->is_single_stack() || left->is_address()) {
    assert(left == dest, "left and dest must be equal");

    Address laddr;
    if (left->is_single_stack()) {
      laddr = frame_map()->address_for_slot(left->single_stack_ix());
    } else if (left->is_address()) {
      laddr = as_Address(left->as_address_ptr());
    } else {
      ShouldNotReachHere();
    }

    if (right->is_single_cpu()) {
      Register rreg = right->as_register();
      switch (code) {
        case lir_add: __ addl(laddr, rreg); break;
        case lir_sub: __ subl(laddr, rreg); break;
        default:      ShouldNotReachHere();
      }
    } else if (right->is_constant()) {
      jint c = right->as_constant_ptr()->as_jint();
      switch (code) {
        case lir_add: {
2253
          __ incrementl(laddr, c);
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          break;
        }
        case lir_sub: {
2257
          __ decrementl(laddr, c);
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          break;
        }
        default: ShouldNotReachHere();
      }
    } else {
      ShouldNotReachHere();
    }

  } else {
    ShouldNotReachHere();
  }
}

void LIR_Assembler::arith_fpu_implementation(LIR_Code code, int left_index, int right_index, int dest_index, bool pop_fpu_stack) {
  assert(pop_fpu_stack  || (left_index     == dest_index || right_index     == dest_index), "invalid LIR");
  assert(!pop_fpu_stack || (left_index - 1 == dest_index || right_index - 1 == dest_index), "invalid LIR");
  assert(left_index == 0 || right_index == 0, "either must be on top of stack");

  bool left_is_tos = (left_index == 0);
  bool dest_is_tos = (dest_index == 0);
  int non_tos_index = (left_is_tos ? right_index : left_index);

  switch (code) {
    case lir_add:
      if (pop_fpu_stack)       __ faddp(non_tos_index);
      else if (dest_is_tos)    __ fadd (non_tos_index);
      else                     __ fadda(non_tos_index);
      break;

    case lir_sub:
      if (left_is_tos) {
        if (pop_fpu_stack)     __ fsubrp(non_tos_index);
        else if (dest_is_tos)  __ fsub  (non_tos_index);
        else                   __ fsubra(non_tos_index);
      } else {
        if (pop_fpu_stack)     __ fsubp (non_tos_index);
        else if (dest_is_tos)  __ fsubr (non_tos_index);
        else                   __ fsuba (non_tos_index);
      }
      break;

    case lir_mul_strictfp: // fall through
    case lir_mul:
      if (pop_fpu_stack)       __ fmulp(non_tos_index);
      else if (dest_is_tos)    __ fmul (non_tos_index);
      else                     __ fmula(non_tos_index);
      break;

    case lir_div_strictfp: // fall through
    case lir_div:
      if (left_is_tos) {
        if (pop_fpu_stack)     __ fdivrp(non_tos_index);
        else if (dest_is_tos)  __ fdiv  (non_tos_index);
        else                   __ fdivra(non_tos_index);
      } else {
        if (pop_fpu_stack)     __ fdivp (non_tos_index);
        else if (dest_is_tos)  __ fdivr (non_tos_index);
        else                   __ fdiva (non_tos_index);
      }
      break;

    case lir_rem:
      assert(left_is_tos && dest_is_tos && right_index == 1, "must be guaranteed by FPU stack allocation");
      __ fremr(noreg);
      break;

    default:
      ShouldNotReachHere();
  }
}


void LIR_Assembler::intrinsic_op(LIR_Code code, LIR_Opr value, LIR_Opr unused, LIR_Opr dest, LIR_Op* op) {
  if (value->is_double_xmm()) {
    switch(code) {
      case lir_abs :
        {
          if (dest->as_xmm_double_reg() != value->as_xmm_double_reg()) {
            __ movdbl(dest->as_xmm_double_reg(), value->as_xmm_double_reg());
          }
          __ andpd(dest->as_xmm_double_reg(),
                    ExternalAddress((address)double_signmask_pool));
        }
        break;

      case lir_sqrt: __ sqrtsd(dest->as_xmm_double_reg(), value->as_xmm_double_reg()); break;
      // all other intrinsics are not available in the SSE instruction set, so FPU is used
      default      : ShouldNotReachHere();
    }

  } else if (value->is_double_fpu()) {
    assert(value->fpu_regnrLo() == 0 && dest->fpu_regnrLo() == 0, "both must be on TOS");
    switch(code) {
      case lir_log   : __ flog() ; break;
      case lir_log10 : __ flog10() ; break;
      case lir_abs   : __ fabs() ; break;
      case lir_sqrt  : __ fsqrt(); break;
      case lir_sin   :
        // Should consider not saving rbx, if not necessary
        __ trigfunc('s', op->as_Op2()->fpu_stack_size());
        break;
      case lir_cos :
        // Should consider not saving rbx, if not necessary
        assert(op->as_Op2()->fpu_stack_size() <= 6, "sin and cos need two free stack slots");
        __ trigfunc('c', op->as_Op2()->fpu_stack_size());
        break;
      case lir_tan :
        // Should consider not saving rbx, if not necessary
        __ trigfunc('t', op->as_Op2()->fpu_stack_size());
        break;
      default      : ShouldNotReachHere();
    }
  } else {
    Unimplemented();
  }
}

void LIR_Assembler::logic_op(LIR_Code code, LIR_Opr left, LIR_Opr right, LIR_Opr dst) {
  // assert(left->destroys_register(), "check");
  if (left->is_single_cpu()) {
    Register reg = left->as_register();
    if (right->is_constant()) {
      int val = right->as_constant_ptr()->as_jint();
      switch (code) {
        case lir_logic_and: __ andl (reg, val); break;
        case lir_logic_or:  __ orl  (reg, val); break;
        case lir_logic_xor: __ xorl (reg, val); break;
        default: ShouldNotReachHere();
      }
    } else if (right->is_stack()) {
      // added support for stack operands
      Address raddr = frame_map()->address_for_slot(right->single_stack_ix());
      switch (code) {
        case lir_logic_and: __ andl (reg, raddr); break;
        case lir_logic_or:  __ orl  (reg, raddr); break;
        case lir_logic_xor: __ xorl (reg, raddr); break;
        default: ShouldNotReachHere();
      }
    } else {
      Register rright = right->as_register();
      switch (code) {
2399 2400 2401
        case lir_logic_and: __ andptr (reg, rright); break;
        case lir_logic_or : __ orptr  (reg, rright); break;
        case lir_logic_xor: __ xorptr (reg, rright); break;
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        default: ShouldNotReachHere();
      }
    }
    move_regs(reg, dst->as_register());
  } else {
    Register l_lo = left->as_register_lo();
    Register l_hi = left->as_register_hi();
    if (right->is_constant()) {
2410 2411 2412 2413 2414 2415 2416 2417 2418 2419 2420 2421 2422 2423 2424
#ifdef _LP64
      __ mov64(rscratch1, right->as_constant_ptr()->as_jlong());
      switch (code) {
        case lir_logic_and:
          __ andq(l_lo, rscratch1);
          break;
        case lir_logic_or:
          __ orq(l_lo, rscratch1);
          break;
        case lir_logic_xor:
          __ xorq(l_lo, rscratch1);
          break;
        default: ShouldNotReachHere();
      }
#else
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      int r_lo = right->as_constant_ptr()->as_jint_lo();
      int r_hi = right->as_constant_ptr()->as_jint_hi();
      switch (code) {
        case lir_logic_and:
          __ andl(l_lo, r_lo);
          __ andl(l_hi, r_hi);
          break;
        case lir_logic_or:
          __ orl(l_lo, r_lo);
          __ orl(l_hi, r_hi);
          break;
        case lir_logic_xor:
          __ xorl(l_lo, r_lo);
          __ xorl(l_hi, r_hi);
          break;
        default: ShouldNotReachHere();
      }
2442
#endif // _LP64
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    } else {
      Register r_lo = right->as_register_lo();
      Register r_hi = right->as_register_hi();
      assert(l_lo != r_hi, "overwriting registers");
      switch (code) {
        case lir_logic_and:
2449 2450
          __ andptr(l_lo, r_lo);
          NOT_LP64(__ andptr(l_hi, r_hi);)
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          break;
        case lir_logic_or:
2453 2454
          __ orptr(l_lo, r_lo);
          NOT_LP64(__ orptr(l_hi, r_hi);)
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          break;
        case lir_logic_xor:
2457 2458
          __ xorptr(l_lo, r_lo);
          NOT_LP64(__ xorptr(l_hi, r_hi);)
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          break;
        default: ShouldNotReachHere();
      }
    }

    Register dst_lo = dst->as_register_lo();
    Register dst_hi = dst->as_register_hi();

2467 2468 2469
#ifdef _LP64
    move_regs(l_lo, dst_lo);
#else
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    if (dst_lo == l_hi) {
      assert(dst_hi != l_lo, "overwriting registers");
      move_regs(l_hi, dst_hi);
      move_regs(l_lo, dst_lo);
    } else {
      assert(dst_lo != l_hi, "overwriting registers");
      move_regs(l_lo, dst_lo);
      move_regs(l_hi, dst_hi);
    }
2479
#endif // _LP64
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  }
}


// we assume that rax, and rdx can be overwritten
void LIR_Assembler::arithmetic_idiv(LIR_Code code, LIR_Opr left, LIR_Opr right, LIR_Opr temp, LIR_Opr result, CodeEmitInfo* info) {

  assert(left->is_single_cpu(),   "left must be register");
  assert(right->is_single_cpu() || right->is_constant(),  "right must be register or constant");
  assert(result->is_single_cpu(), "result must be register");

  //  assert(left->destroys_register(), "check");
  //  assert(right->destroys_register(), "check");

  Register lreg = left->as_register();
  Register dreg = result->as_register();

  if (right->is_constant()) {
    int divisor = right->as_constant_ptr()->as_jint();
    assert(divisor > 0 && is_power_of_2(divisor), "must be");
    if (code == lir_idiv) {
      assert(lreg == rax, "must be rax,");
      assert(temp->as_register() == rdx, "tmp register must be rdx");
      __ cdql(); // sign extend into rdx:rax
      if (divisor == 2) {
        __ subl(lreg, rdx);
      } else {
        __ andl(rdx, divisor - 1);
        __ addl(lreg, rdx);
      }
      __ sarl(lreg, log2_intptr(divisor));
      move_regs(lreg, dreg);
    } else if (code == lir_irem) {
      Label done;
2514
      __ mov(dreg, lreg);
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      __ andl(dreg, 0x80000000 | (divisor - 1));
      __ jcc(Assembler::positive, done);
      __ decrement(dreg);
      __ orl(dreg, ~(divisor - 1));
      __ increment(dreg);
      __ bind(done);
    } else {
      ShouldNotReachHere();
    }
  } else {
    Register rreg = right->as_register();
    assert(lreg == rax, "left register must be rax,");
    assert(rreg != rdx, "right register must not be rdx");
    assert(temp->as_register() == rdx, "tmp register must be rdx");

    move_regs(lreg, rax);

    int idivl_offset = __ corrected_idivl(rreg);
    add_debug_info_for_div0(idivl_offset, info);
    if (code == lir_irem) {
      move_regs(rdx, dreg); // result is in rdx
    } else {
      move_regs(rax, dreg);
    }
  }
}


void LIR_Assembler::comp_op(LIR_Condition condition, LIR_Opr opr1, LIR_Opr opr2, LIR_Op2* op) {
  if (opr1->is_single_cpu()) {
    Register reg1 = opr1->as_register();
    if (opr2->is_single_cpu()) {
      // cpu register - cpu register
2548 2549 2550 2551 2552 2553
      if (opr1->type() == T_OBJECT || opr1->type() == T_ARRAY) {
        __ cmpptr(reg1, opr2->as_register());
      } else {
        assert(opr2->type() != T_OBJECT && opr2->type() != T_ARRAY, "cmp int, oop?");
        __ cmpl(reg1, opr2->as_register());
      }
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    } else if (opr2->is_stack()) {
      // cpu register - stack
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      if (opr1->type() == T_OBJECT || opr1->type() == T_ARRAY) {
        __ cmpptr(reg1, frame_map()->address_for_slot(opr2->single_stack_ix()));
      } else {
        __ cmpl(reg1, frame_map()->address_for_slot(opr2->single_stack_ix()));
      }
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    } else if (opr2->is_constant()) {
      // cpu register - constant
      LIR_Const* c = opr2->as_constant_ptr();
      if (c->type() == T_INT) {
        __ cmpl(reg1, c->as_jint());
2566 2567
      } else if (c->type() == T_OBJECT || c->type() == T_ARRAY) {
        // In 64bit oops are single register
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        jobject o = c->as_jobject();
        if (o == NULL) {
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          __ cmpptr(reg1, (int32_t)NULL_WORD);
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        } else {
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#ifdef _LP64
          __ movoop(rscratch1, o);
          __ cmpptr(reg1, rscratch1);
#else
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          __ cmpoop(reg1, c->as_jobject());
2577
#endif // _LP64
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        }
      } else {
        ShouldNotReachHere();
      }
      // cpu register - address
    } else if (opr2->is_address()) {
      if (op->info() != NULL) {
        add_debug_info_for_null_check_here(op->info());
      }
      __ cmpl(reg1, as_Address(opr2->as_address_ptr()));
    } else {
      ShouldNotReachHere();
    }

  } else if(opr1->is_double_cpu()) {
    Register xlo = opr1->as_register_lo();
    Register xhi = opr1->as_register_hi();
    if (opr2->is_double_cpu()) {
2596 2597 2598
#ifdef _LP64
      __ cmpptr(xlo, opr2->as_register_lo());
#else
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      // cpu register - cpu register
      Register ylo = opr2->as_register_lo();
      Register yhi = opr2->as_register_hi();
      __ subl(xlo, ylo);
      __ sbbl(xhi, yhi);
      if (condition == lir_cond_equal || condition == lir_cond_notEqual) {
        __ orl(xhi, xlo);
      }
2607
#endif // _LP64
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    } else if (opr2->is_constant()) {
      // cpu register - constant 0
      assert(opr2->as_jlong() == (jlong)0, "only handles zero");
2611 2612 2613
#ifdef _LP64
      __ cmpptr(xlo, (int32_t)opr2->as_jlong());
#else
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      assert(condition == lir_cond_equal || condition == lir_cond_notEqual, "only handles equals case");
      __ orl(xhi, xlo);
2616
#endif // _LP64
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    } else {
      ShouldNotReachHere();
    }

  } else if (opr1->is_single_xmm()) {
    XMMRegister reg1 = opr1->as_xmm_float_reg();
    if (opr2->is_single_xmm()) {
      // xmm register - xmm register
      __ ucomiss(reg1, opr2->as_xmm_float_reg());
    } else if (opr2->is_stack()) {
      // xmm register - stack
      __ ucomiss(reg1, frame_map()->address_for_slot(opr2->single_stack_ix()));
    } else if (opr2->is_constant()) {
      // xmm register - constant
      __ ucomiss(reg1, InternalAddress(float_constant(opr2->as_jfloat())));
    } else if (opr2->is_address()) {
      // xmm register - address
      if (op->info() != NULL) {
        add_debug_info_for_null_check_here(op->info());
      }
      __ ucomiss(reg1, as_Address(opr2->as_address_ptr()));
    } else {
      ShouldNotReachHere();
    }

  } else if (opr1->is_double_xmm()) {
    XMMRegister reg1 = opr1->as_xmm_double_reg();
    if (opr2->is_double_xmm()) {
      // xmm register - xmm register
      __ ucomisd(reg1, opr2->as_xmm_double_reg());
    } else if (opr2->is_stack()) {
      // xmm register - stack
      __ ucomisd(reg1, frame_map()->address_for_slot(opr2->double_stack_ix()));
    } else if (opr2->is_constant()) {
      // xmm register - constant
      __ ucomisd(reg1, InternalAddress(double_constant(opr2->as_jdouble())));
    } else if (opr2->is_address()) {
      // xmm register - address
      if (op->info() != NULL) {
        add_debug_info_for_null_check_here(op->info());
      }
      __ ucomisd(reg1, as_Address(opr2->pointer()->as_address()));
    } else {
      ShouldNotReachHere();
    }

  } else if(opr1->is_single_fpu() || opr1->is_double_fpu()) {
    assert(opr1->is_fpu_register() && opr1->fpu() == 0, "currently left-hand side must be on TOS (relax this restriction)");
    assert(opr2->is_fpu_register(), "both must be registers");
    __ fcmp(noreg, opr2->fpu(), op->fpu_pop_count() > 0, op->fpu_pop_count() > 1);

  } else if (opr1->is_address() && opr2->is_constant()) {
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    LIR_Const* c = opr2->as_constant_ptr();
#ifdef _LP64
    if (c->type() == T_OBJECT || c->type() == T_ARRAY) {
      assert(condition == lir_cond_equal || condition == lir_cond_notEqual, "need to reverse");
      __ movoop(rscratch1, c->as_jobject());
    }
#endif // LP64
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    if (op->info() != NULL) {
      add_debug_info_for_null_check_here(op->info());
    }
    // special case: address - constant
    LIR_Address* addr = opr1->as_address_ptr();
    if (c->type() == T_INT) {
      __ cmpl(as_Address(addr), c->as_jint());
2683 2684 2685 2686 2687 2688
    } else if (c->type() == T_OBJECT || c->type() == T_ARRAY) {
#ifdef _LP64
      // %%% Make this explode if addr isn't reachable until we figure out a
      // better strategy by giving noreg as the temp for as_Address
      __ cmpptr(rscratch1, as_Address(addr, noreg));
#else
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      __ cmpoop(as_Address(addr), c->as_jobject());
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#endif // _LP64
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    } else {
      ShouldNotReachHere();
    }

  } else {
    ShouldNotReachHere();
  }
}

void LIR_Assembler::comp_fl2i(LIR_Code code, LIR_Opr left, LIR_Opr right, LIR_Opr dst, LIR_Op2* op) {
  if (code == lir_cmp_fd2i || code == lir_ucmp_fd2i) {
    if (left->is_single_xmm()) {
      assert(right->is_single_xmm(), "must match");
      __ cmpss2int(left->as_xmm_float_reg(), right->as_xmm_float_reg(), dst->as_register(), code == lir_ucmp_fd2i);
    } else if (left->is_double_xmm()) {
      assert(right->is_double_xmm(), "must match");
      __ cmpsd2int(left->as_xmm_double_reg(), right->as_xmm_double_reg(), dst->as_register(), code == lir_ucmp_fd2i);

    } else {
      assert(left->is_single_fpu() || left->is_double_fpu(), "must be");
      assert(right->is_single_fpu() || right->is_double_fpu(), "must match");

      assert(left->fpu() == 0, "left must be on TOS");
      __ fcmp2int(dst->as_register(), code == lir_ucmp_fd2i, right->fpu(),
                  op->fpu_pop_count() > 0, op->fpu_pop_count() > 1);
    }
  } else {
    assert(code == lir_cmp_l2i, "check");
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#ifdef _LP64
      Register dest = dst->as_register();
      __ xorptr(dest, dest);
      Label high, done;
      __ cmpptr(left->as_register_lo(), right->as_register_lo());
      __ jcc(Assembler::equal, done);
      __ jcc(Assembler::greater, high);
      __ decrement(dest);
      __ jmp(done);
      __ bind(high);
      __ increment(dest);

      __ bind(done);

#else
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    __ lcmp2int(left->as_register_hi(),
                left->as_register_lo(),
                right->as_register_hi(),
                right->as_register_lo());
    move_regs(left->as_register_hi(), dst->as_register());
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#endif // _LP64
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  }
}


void LIR_Assembler::align_call(LIR_Code code) {
  if (os::is_MP()) {
    // make sure that the displacement word of the call ends up word aligned
    int offset = __ offset();
    switch (code) {
      case lir_static_call:
      case lir_optvirtual_call:
        offset += NativeCall::displacement_offset;
        break;
      case lir_icvirtual_call:
        offset += NativeCall::displacement_offset + NativeMovConstReg::instruction_size;
      break;
      case lir_virtual_call:  // currently, sparc-specific for niagara
      default: ShouldNotReachHere();
    }
    while (offset++ % BytesPerWord != 0) {
      __ nop();
    }
  }
}


void LIR_Assembler::call(address entry, relocInfo::relocType rtype, CodeEmitInfo* info) {
  assert(!os::is_MP() || (__ offset() + NativeCall::displacement_offset) % BytesPerWord == 0,
         "must be aligned");
  __ call(AddressLiteral(entry, rtype));
  add_call_info(code_offset(), info);
}


void LIR_Assembler::ic_call(address entry, CodeEmitInfo* info) {
  RelocationHolder rh = virtual_call_Relocation::spec(pc());
  __ movoop(IC_Klass, (jobject)Universe::non_oop_word());
  assert(!os::is_MP() ||
         (__ offset() + NativeCall::displacement_offset) % BytesPerWord == 0,
         "must be aligned");
  __ call(AddressLiteral(entry, rh));
  add_call_info(code_offset(), info);
}


/* Currently, vtable-dispatch is only enabled for sparc platforms */
void LIR_Assembler::vtable_call(int vtable_offset, CodeEmitInfo* info) {
  ShouldNotReachHere();
}

void LIR_Assembler::emit_static_call_stub() {
  address call_pc = __ pc();
  address stub = __ start_a_stub(call_stub_size);
  if (stub == NULL) {
    bailout("static call stub overflow");
    return;
  }

  int start = __ offset();
  if (os::is_MP()) {
    // make sure that the displacement word of the call ends up word aligned
    int offset = __ offset() + NativeMovConstReg::instruction_size + NativeCall::displacement_offset;
    while (offset++ % BytesPerWord != 0) {
      __ nop();
    }
  }
  __ relocate(static_stub_Relocation::spec(call_pc));
  __ movoop(rbx, (jobject)NULL);
  // must be set to -1 at code generation time
  assert(!os::is_MP() || ((__ offset() + 1) % BytesPerWord) == 0, "must be aligned on MP");
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  // On 64bit this will die since it will take a movq & jmp, must be only a jmp
  __ jump(RuntimeAddress(__ pc()));
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  assert(__ offset() - start <= call_stub_size, "stub too big")
  __ end_a_stub();
}


void LIR_Assembler::throw_op(LIR_Opr exceptionPC, LIR_Opr exceptionOop, CodeEmitInfo* info, bool unwind) {
  assert(exceptionOop->as_register() == rax, "must match");
  assert(unwind || exceptionPC->as_register() == rdx, "must match");

  // exception object is not added to oop map by LinearScan
  // (LinearScan assumes that no oops are in fixed registers)
  info->add_register_oop(exceptionOop);
  Runtime1::StubID unwind_id;

  if (!unwind) {
    // get current pc information
    // pc is only needed if the method has an exception handler, the unwind code does not need it.
    int pc_for_athrow_offset = __ offset();
    InternalAddress pc_for_athrow(__ pc());
    __ lea(exceptionPC->as_register(), pc_for_athrow);
    add_call_info(pc_for_athrow_offset, info); // for exception handler

    __ verify_not_null_oop(rax);
    // search an exception handler (rax: exception oop, rdx: throwing pc)
    if (compilation()->has_fpu_code()) {
      unwind_id = Runtime1::handle_exception_id;
    } else {
      unwind_id = Runtime1::handle_exception_nofpu_id;
    }
  } else {
    unwind_id = Runtime1::unwind_exception_id;
  }
  __ call(RuntimeAddress(Runtime1::entry_for(unwind_id)));

  // enough room for two byte trap
  __ nop();
}


void LIR_Assembler::shift_op(LIR_Code code, LIR_Opr left, LIR_Opr count, LIR_Opr dest, LIR_Opr tmp) {

  // optimized version for linear scan:
  // * count must be already in ECX (guaranteed by LinearScan)
  // * left and dest must be equal
  // * tmp must be unused
  assert(count->as_register() == SHIFT_count, "count must be in ECX");
  assert(left == dest, "left and dest must be equal");
  assert(tmp->is_illegal(), "wasting a register if tmp is allocated");

  if (left->is_single_cpu()) {
    Register value = left->as_register();
    assert(value != SHIFT_count, "left cannot be ECX");

    switch (code) {
      case lir_shl:  __ shll(value); break;
      case lir_shr:  __ sarl(value); break;
      case lir_ushr: __ shrl(value); break;
      default: ShouldNotReachHere();
    }
  } else if (left->is_double_cpu()) {
    Register lo = left->as_register_lo();
    Register hi = left->as_register_hi();
    assert(lo != SHIFT_count && hi != SHIFT_count, "left cannot be ECX");
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#ifdef _LP64
    switch (code) {
      case lir_shl:  __ shlptr(lo);        break;
      case lir_shr:  __ sarptr(lo);        break;
      case lir_ushr: __ shrptr(lo);        break;
      default: ShouldNotReachHere();
    }
#else
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    switch (code) {
      case lir_shl:  __ lshl(hi, lo);        break;
      case lir_shr:  __ lshr(hi, lo, true);  break;
      case lir_ushr: __ lshr(hi, lo, false); break;
      default: ShouldNotReachHere();
    }
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#endif // LP64
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  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::shift_op(LIR_Code code, LIR_Opr left, jint count, LIR_Opr dest) {
  if (dest->is_single_cpu()) {
    // first move left into dest so that left is not destroyed by the shift
    Register value = dest->as_register();
    count = count & 0x1F; // Java spec

    move_regs(left->as_register(), value);
    switch (code) {
      case lir_shl:  __ shll(value, count); break;
      case lir_shr:  __ sarl(value, count); break;
      case lir_ushr: __ shrl(value, count); break;
      default: ShouldNotReachHere();
    }
  } else if (dest->is_double_cpu()) {
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#ifndef _LP64
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    Unimplemented();
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#else
    // first move left into dest so that left is not destroyed by the shift
    Register value = dest->as_register_lo();
    count = count & 0x1F; // Java spec

    move_regs(left->as_register_lo(), value);
    switch (code) {
      case lir_shl:  __ shlptr(value, count); break;
      case lir_shr:  __ sarptr(value, count); break;
      case lir_ushr: __ shrptr(value, count); break;
      default: ShouldNotReachHere();
    }
#endif // _LP64
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  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::store_parameter(Register r, int offset_from_rsp_in_words) {
  assert(offset_from_rsp_in_words >= 0, "invalid offset from rsp");
  int offset_from_rsp_in_bytes = offset_from_rsp_in_words * BytesPerWord;
  assert(offset_from_rsp_in_bytes < frame_map()->reserved_argument_area_size(), "invalid offset");
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  __ movptr (Address(rsp, offset_from_rsp_in_bytes), r);
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}


void LIR_Assembler::store_parameter(jint c,     int offset_from_rsp_in_words) {
  assert(offset_from_rsp_in_words >= 0, "invalid offset from rsp");
  int offset_from_rsp_in_bytes = offset_from_rsp_in_words * BytesPerWord;
  assert(offset_from_rsp_in_bytes < frame_map()->reserved_argument_area_size(), "invalid offset");
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  __ movptr (Address(rsp, offset_from_rsp_in_bytes), c);
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}


void LIR_Assembler::store_parameter(jobject o,  int offset_from_rsp_in_words) {
  assert(offset_from_rsp_in_words >= 0, "invalid offset from rsp");
  int offset_from_rsp_in_bytes = offset_from_rsp_in_words * BytesPerWord;
  assert(offset_from_rsp_in_bytes < frame_map()->reserved_argument_area_size(), "invalid offset");
  __ movoop (Address(rsp, offset_from_rsp_in_bytes), o);
}


// This code replaces a call to arraycopy; no exception may
// be thrown in this code, they must be thrown in the System.arraycopy
// activation frame; we could save some checks if this would not be the case
void LIR_Assembler::emit_arraycopy(LIR_OpArrayCopy* op) {
  ciArrayKlass* default_type = op->expected_type();
  Register src = op->src()->as_register();
  Register dst = op->dst()->as_register();
  Register src_pos = op->src_pos()->as_register();
  Register dst_pos = op->dst_pos()->as_register();
  Register length  = op->length()->as_register();
  Register tmp = op->tmp()->as_register();

  CodeStub* stub = op->stub();
  int flags = op->flags();
  BasicType basic_type = default_type != NULL ? default_type->element_type()->basic_type() : T_ILLEGAL;
  if (basic_type == T_ARRAY) basic_type = T_OBJECT;

  // if we don't know anything or it's an object array, just go through the generic arraycopy
  if (default_type == NULL) {
    Label done;
    // save outgoing arguments on stack in case call to System.arraycopy is needed
    // HACK ALERT. This code used to push the parameters in a hardwired fashion
    // for interpreter calling conventions. Now we have to do it in new style conventions.
    // For the moment until C1 gets the new register allocator I just force all the
    // args to the right place (except the register args) and then on the back side
    // reload the register args properly if we go slow path. Yuck

    // These are proper for the calling convention

    store_parameter(length, 2);
    store_parameter(dst_pos, 1);
    store_parameter(dst, 0);

    // these are just temporary placements until we need to reload
    store_parameter(src_pos, 3);
    store_parameter(src, 4);
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    NOT_LP64(assert(src == rcx && src_pos == rdx, "mismatch in calling convention");)
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    address entry = CAST_FROM_FN_PTR(address, Runtime1::arraycopy);
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    // pass arguments: may push as this is not a safepoint; SP must be fix at each safepoint
#ifdef _LP64
    // The arguments are in java calling convention so we can trivially shift them to C
    // convention
    assert_different_registers(c_rarg0, j_rarg1, j_rarg2, j_rarg3, j_rarg4);
    __ mov(c_rarg0, j_rarg0);
    assert_different_registers(c_rarg1, j_rarg2, j_rarg3, j_rarg4);
    __ mov(c_rarg1, j_rarg1);
    assert_different_registers(c_rarg2, j_rarg3, j_rarg4);
    __ mov(c_rarg2, j_rarg2);
    assert_different_registers(c_rarg3, j_rarg4);
    __ mov(c_rarg3, j_rarg3);
#ifdef _WIN64
    // Allocate abi space for args but be sure to keep stack aligned
    __ subptr(rsp, 6*wordSize);
    store_parameter(j_rarg4, 4);
    __ call(RuntimeAddress(entry));
    __ addptr(rsp, 6*wordSize);
#else
    __ mov(c_rarg4, j_rarg4);
    __ call(RuntimeAddress(entry));
#endif // _WIN64
#else
    __ push(length);
    __ push(dst_pos);
    __ push(dst);
    __ push(src_pos);
    __ push(src);
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    __ call_VM_leaf(entry, 5); // removes pushed parameter from the stack

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#endif // _LP64

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    __ cmpl(rax, 0);
    __ jcc(Assembler::equal, *stub->continuation());

    // Reload values from the stack so they are where the stub
    // expects them.
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    __ movptr   (dst,     Address(rsp, 0*BytesPerWord));
    __ movptr   (dst_pos, Address(rsp, 1*BytesPerWord));
    __ movptr   (length,  Address(rsp, 2*BytesPerWord));
    __ movptr   (src_pos, Address(rsp, 3*BytesPerWord));
    __ movptr   (src,     Address(rsp, 4*BytesPerWord));
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    __ jmp(*stub->entry());

    __ bind(*stub->continuation());
    return;
  }

  assert(default_type != NULL && default_type->is_array_klass() && default_type->is_loaded(), "must be true at this point");

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  int elem_size = type2aelembytes(basic_type);
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  int shift_amount;
  Address::ScaleFactor scale;

  switch (elem_size) {
    case 1 :
      shift_amount = 0;
      scale = Address::times_1;
      break;
    case 2 :
      shift_amount = 1;
      scale = Address::times_2;
      break;
    case 4 :
      shift_amount = 2;
      scale = Address::times_4;
      break;
    case 8 :
      shift_amount = 3;
      scale = Address::times_8;
      break;
    default:
      ShouldNotReachHere();
  }

  Address src_length_addr = Address(src, arrayOopDesc::length_offset_in_bytes());
  Address dst_length_addr = Address(dst, arrayOopDesc::length_offset_in_bytes());
  Address src_klass_addr = Address(src, oopDesc::klass_offset_in_bytes());
  Address dst_klass_addr = Address(dst, oopDesc::klass_offset_in_bytes());

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  // length and pos's are all sign extended at this point on 64bit

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  // test for NULL
  if (flags & LIR_OpArrayCopy::src_null_check) {
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    __ testptr(src, src);
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    __ jcc(Assembler::zero, *stub->entry());
  }
  if (flags & LIR_OpArrayCopy::dst_null_check) {
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    __ testptr(dst, dst);
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    __ jcc(Assembler::zero, *stub->entry());
  }

  // check if negative
  if (flags & LIR_OpArrayCopy::src_pos_positive_check) {
    __ testl(src_pos, src_pos);
    __ jcc(Assembler::less, *stub->entry());
  }
  if (flags & LIR_OpArrayCopy::dst_pos_positive_check) {
    __ testl(dst_pos, dst_pos);
    __ jcc(Assembler::less, *stub->entry());
  }
  if (flags & LIR_OpArrayCopy::length_positive_check) {
    __ testl(length, length);
    __ jcc(Assembler::less, *stub->entry());
  }

  if (flags & LIR_OpArrayCopy::src_range_check) {
3104
    __ lea(tmp, Address(src_pos, length, Address::times_1, 0));
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    __ cmpl(tmp, src_length_addr);
    __ jcc(Assembler::above, *stub->entry());
  }
  if (flags & LIR_OpArrayCopy::dst_range_check) {
3109
    __ lea(tmp, Address(dst_pos, length, Address::times_1, 0));
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    __ cmpl(tmp, dst_length_addr);
    __ jcc(Assembler::above, *stub->entry());
  }

  if (flags & LIR_OpArrayCopy::type_check) {
3115 3116
    __ movptr(tmp, src_klass_addr);
    __ cmpptr(tmp, dst_klass_addr);
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    __ jcc(Assembler::notEqual, *stub->entry());
  }

#ifdef ASSERT
  if (basic_type != T_OBJECT || !(flags & LIR_OpArrayCopy::type_check)) {
    // Sanity check the known type with the incoming class.  For the
    // primitive case the types must match exactly with src.klass and
    // dst.klass each exactly matching the default type.  For the
    // object array case, if no type check is needed then either the
    // dst type is exactly the expected type and the src type is a
    // subtype which we can't check or src is the same array as dst
    // but not necessarily exactly of type default_type.
    Label known_ok, halt;
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    __ movoop(tmp, default_type->constant_encoding());
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    if (basic_type != T_OBJECT) {
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      __ cmpptr(tmp, dst_klass_addr);
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      __ jcc(Assembler::notEqual, halt);
3134
      __ cmpptr(tmp, src_klass_addr);
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      __ jcc(Assembler::equal, known_ok);
    } else {
3137
      __ cmpptr(tmp, dst_klass_addr);
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      __ jcc(Assembler::equal, known_ok);
3139
      __ cmpptr(src, dst);
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3140 3141 3142 3143 3144 3145 3146 3147 3148
      __ jcc(Assembler::equal, known_ok);
    }
    __ bind(halt);
    __ stop("incorrect type information in arraycopy");
    __ bind(known_ok);
  }
#endif

  if (shift_amount > 0 && basic_type != T_OBJECT) {
3149
    __ shlptr(length, shift_amount);
D
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  }
3151 3152 3153

#ifdef _LP64
  assert_different_registers(c_rarg0, dst, dst_pos, length);
R
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  __ movl2ptr(src_pos, src_pos); //higher 32bits must be null
3155 3156
  __ lea(c_rarg0, Address(src, src_pos, scale, arrayOopDesc::base_offset_in_bytes(basic_type)));
  assert_different_registers(c_rarg1, length);
R
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3157
  __ movl2ptr(dst_pos, dst_pos); //higher 32bits must be null
3158 3159 3160 3161 3162 3163 3164 3165
  __ lea(c_rarg1, Address(dst, dst_pos, scale, arrayOopDesc::base_offset_in_bytes(basic_type)));
  __ mov(c_rarg2, length);

#else
  __ lea(tmp, Address(src, src_pos, scale, arrayOopDesc::base_offset_in_bytes(basic_type)));
  store_parameter(tmp, 0);
  __ lea(tmp, Address(dst, dst_pos, scale, arrayOopDesc::base_offset_in_bytes(basic_type)));
  store_parameter(tmp, 1);
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  store_parameter(length, 2);
3167
#endif // _LP64
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  if (basic_type == T_OBJECT) {
    __ call_VM_leaf(CAST_FROM_FN_PTR(address, Runtime1::oop_arraycopy), 0);
  } else {
    __ call_VM_leaf(CAST_FROM_FN_PTR(address, Runtime1::primitive_arraycopy), 0);
  }

  __ bind(*stub->continuation());
}


void LIR_Assembler::emit_lock(LIR_OpLock* op) {
  Register obj = op->obj_opr()->as_register();  // may not be an oop
  Register hdr = op->hdr_opr()->as_register();
  Register lock = op->lock_opr()->as_register();
  if (!UseFastLocking) {
    __ jmp(*op->stub()->entry());
  } else if (op->code() == lir_lock) {
    Register scratch = noreg;
    if (UseBiasedLocking) {
      scratch = op->scratch_opr()->as_register();
    }
    assert(BasicLock::displaced_header_offset_in_bytes() == 0, "lock_reg must point to the displaced header");
    // add debug info for NullPointerException only if one is possible
    int null_check_offset = __ lock_object(hdr, obj, lock, scratch, *op->stub()->entry());
    if (op->info() != NULL) {
      add_debug_info_for_null_check(null_check_offset, op->info());
    }
    // done
  } else if (op->code() == lir_unlock) {
    assert(BasicLock::displaced_header_offset_in_bytes() == 0, "lock_reg must point to the displaced header");
    __ unlock_object(hdr, obj, lock, *op->stub()->entry());
  } else {
    Unimplemented();
  }
  __ bind(*op->stub()->continuation());
}


void LIR_Assembler::emit_profile_call(LIR_OpProfileCall* op) {
  ciMethod* method = op->profiled_method();
  int bci          = op->profiled_bci();

  // Update counter for all call types
  ciMethodData* md = method->method_data();
  if (md == NULL) {
    bailout("out of memory building methodDataOop");
    return;
  }
  ciProfileData* data = md->bci_to_data(bci);
  assert(data->is_CounterData(), "need CounterData for calls");
  assert(op->mdo()->is_single_cpu(),  "mdo must be allocated");
  Register mdo  = op->mdo()->as_register();
3220
  __ movoop(mdo, md->constant_encoding());
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  Address counter_addr(mdo, md->byte_offset_of_slot(data, CounterData::count_offset()));
  __ addl(counter_addr, DataLayout::counter_increment);
  Bytecodes::Code bc = method->java_code_at_bci(bci);
  // Perform additional virtual call profiling for invokevirtual and
  // invokeinterface bytecodes
  if ((bc == Bytecodes::_invokevirtual || bc == Bytecodes::_invokeinterface) &&
      Tier1ProfileVirtualCalls) {
    assert(op->recv()->is_single_cpu(), "recv must be allocated");
    Register recv = op->recv()->as_register();
    assert_different_registers(mdo, recv);
    assert(data->is_VirtualCallData(), "need VirtualCallData for virtual calls");
    ciKlass* known_klass = op->known_holder();
    if (Tier1OptimizeVirtualCallProfiling && known_klass != NULL) {
      // We know the type that will be seen at this call site; we can
      // statically update the methodDataOop rather than needing to do
      // dynamic tests on the receiver type

      // NOTE: we should probably put a lock around this search to
      // avoid collisions by concurrent compilations
      ciVirtualCallData* vc_data = (ciVirtualCallData*) data;
      uint i;
      for (i = 0; i < VirtualCallData::row_limit(); i++) {
        ciKlass* receiver = vc_data->receiver(i);
        if (known_klass->equals(receiver)) {
          Address data_addr(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_count_offset(i)));
          __ addl(data_addr, DataLayout::counter_increment);
          return;
        }
      }

      // Receiver type not found in profile data; select an empty slot

      // Note that this is less efficient than it should be because it
      // always does a write to the receiver part of the
      // VirtualCallData rather than just the first time
      for (i = 0; i < VirtualCallData::row_limit(); i++) {
        ciKlass* receiver = vc_data->receiver(i);
        if (receiver == NULL) {
          Address recv_addr(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_offset(i)));
3260
          __ movoop(recv_addr, known_klass->constant_encoding());
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          Address data_addr(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_count_offset(i)));
          __ addl(data_addr, DataLayout::counter_increment);
          return;
        }
      }
    } else {
3267
      __ movptr(recv, Address(recv, oopDesc::klass_offset_in_bytes()));
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      Label update_done;
      uint i;
      for (i = 0; i < VirtualCallData::row_limit(); i++) {
        Label next_test;
        // See if the receiver is receiver[n].
3273
        __ cmpptr(recv, Address(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_offset(i))));
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        __ jcc(Assembler::notEqual, next_test);
        Address data_addr(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_count_offset(i)));
        __ addl(data_addr, DataLayout::counter_increment);
        __ jmp(update_done);
        __ bind(next_test);
      }

      // Didn't find receiver; find next empty slot and fill it in
      for (i = 0; i < VirtualCallData::row_limit(); i++) {
        Label next_test;
        Address recv_addr(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_offset(i)));
3285
        __ cmpptr(recv_addr, (int32_t)NULL_WORD);
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        __ jcc(Assembler::notEqual, next_test);
3287
        __ movptr(recv_addr, recv);
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        __ movl(Address(mdo, md->byte_offset_of_slot(data, VirtualCallData::receiver_count_offset(i))), DataLayout::counter_increment);
        if (i < (VirtualCallData::row_limit() - 1)) {
          __ jmp(update_done);
        }
        __ bind(next_test);
      }

      __ bind(update_done);
    }
  }
}


void LIR_Assembler::emit_delay(LIR_OpDelay*) {
  Unimplemented();
}


void LIR_Assembler::monitor_address(int monitor_no, LIR_Opr dst) {
3307
  __ lea(dst->as_register(), frame_map()->address_for_monitor_lock(monitor_no));
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}


void LIR_Assembler::align_backward_branch_target() {
  __ align(BytesPerWord);
}


void LIR_Assembler::negate(LIR_Opr left, LIR_Opr dest) {
  if (left->is_single_cpu()) {
    __ negl(left->as_register());
    move_regs(left->as_register(), dest->as_register());

  } else if (left->is_double_cpu()) {
    Register lo = left->as_register_lo();
3323 3324 3325 3326 3327
#ifdef _LP64
    Register dst = dest->as_register_lo();
    __ movptr(dst, lo);
    __ negptr(dst);
#else
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    Register hi = left->as_register_hi();
    __ lneg(hi, lo);
    if (dest->as_register_lo() == hi) {
      assert(dest->as_register_hi() != lo, "destroying register");
      move_regs(hi, dest->as_register_hi());
      move_regs(lo, dest->as_register_lo());
    } else {
      move_regs(lo, dest->as_register_lo());
      move_regs(hi, dest->as_register_hi());
    }
3338
#endif // _LP64
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  } else if (dest->is_single_xmm()) {
    if (left->as_xmm_float_reg() != dest->as_xmm_float_reg()) {
      __ movflt(dest->as_xmm_float_reg(), left->as_xmm_float_reg());
    }
    __ xorps(dest->as_xmm_float_reg(),
             ExternalAddress((address)float_signflip_pool));

  } else if (dest->is_double_xmm()) {
    if (left->as_xmm_double_reg() != dest->as_xmm_double_reg()) {
      __ movdbl(dest->as_xmm_double_reg(), left->as_xmm_double_reg());
    }
    __ xorpd(dest->as_xmm_double_reg(),
             ExternalAddress((address)double_signflip_pool));

  } else if (left->is_single_fpu() || left->is_double_fpu()) {
    assert(left->fpu() == 0, "arg must be on TOS");
    assert(dest->fpu() == 0, "dest must be TOS");
    __ fchs();

  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::leal(LIR_Opr addr, LIR_Opr dest) {
  assert(addr->is_address() && dest->is_register(), "check");
3367 3368 3369
  Register reg;
  reg = dest->as_pointer_register();
  __ lea(reg, as_Address(addr->as_address_ptr()));
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}



void LIR_Assembler::rt_call(LIR_Opr result, address dest, const LIR_OprList* args, LIR_Opr tmp, CodeEmitInfo* info) {
  assert(!tmp->is_valid(), "don't need temporary");
  __ call(RuntimeAddress(dest));
  if (info != NULL) {
    add_call_info_here(info);
  }
}


void LIR_Assembler::volatile_move_op(LIR_Opr src, LIR_Opr dest, BasicType type, CodeEmitInfo* info) {
  assert(type == T_LONG, "only for volatile long fields");

  if (info != NULL) {
    add_debug_info_for_null_check_here(info);
  }

  if (src->is_double_xmm()) {
    if (dest->is_double_cpu()) {
3392 3393 3394 3395
#ifdef _LP64
      __ movdq(dest->as_register_lo(), src->as_xmm_double_reg());
#else
      __ movdl(dest->as_register_lo(), src->as_xmm_double_reg());
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      __ psrlq(src->as_xmm_double_reg(), 32);
3397 3398
      __ movdl(dest->as_register_hi(), src->as_xmm_double_reg());
#endif // _LP64
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    } else if (dest->is_double_stack()) {
      __ movdbl(frame_map()->address_for_slot(dest->double_stack_ix()), src->as_xmm_double_reg());
    } else if (dest->is_address()) {
      __ movdbl(as_Address(dest->as_address_ptr()), src->as_xmm_double_reg());
    } else {
      ShouldNotReachHere();
    }

  } else if (dest->is_double_xmm()) {
    if (src->is_double_stack()) {
      __ movdbl(dest->as_xmm_double_reg(), frame_map()->address_for_slot(src->double_stack_ix()));
    } else if (src->is_address()) {
      __ movdbl(dest->as_xmm_double_reg(), as_Address(src->as_address_ptr()));
    } else {
      ShouldNotReachHere();
    }

  } else if (src->is_double_fpu()) {
    assert(src->fpu_regnrLo() == 0, "must be TOS");
    if (dest->is_double_stack()) {
      __ fistp_d(frame_map()->address_for_slot(dest->double_stack_ix()));
    } else if (dest->is_address()) {
      __ fistp_d(as_Address(dest->as_address_ptr()));
    } else {
      ShouldNotReachHere();
    }

  } else if (dest->is_double_fpu()) {
    assert(dest->fpu_regnrLo() == 0, "must be TOS");
    if (src->is_double_stack()) {
      __ fild_d(frame_map()->address_for_slot(src->double_stack_ix()));
    } else if (src->is_address()) {
      __ fild_d(as_Address(src->as_address_ptr()));
    } else {
      ShouldNotReachHere();
    }
  } else {
    ShouldNotReachHere();
  }
}


void LIR_Assembler::membar() {
3442 3443
  // QQQ sparc TSO uses this,
  __ membar( Assembler::Membar_mask_bits(Assembler::StoreLoad));
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}

void LIR_Assembler::membar_acquire() {
  // No x86 machines currently require load fences
  // __ load_fence();
}

void LIR_Assembler::membar_release() {
  // No x86 machines currently require store fences
  // __ store_fence();
}

void LIR_Assembler::get_thread(LIR_Opr result_reg) {
  assert(result_reg->is_register(), "check");
3458 3459 3460 3461
#ifdef _LP64
  // __ get_thread(result_reg->as_register_lo());
  __ mov(result_reg->as_register(), r15_thread);
#else
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  __ get_thread(result_reg->as_register());
3463
#endif // _LP64
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}


void LIR_Assembler::peephole(LIR_List*) {
  // do nothing for now
}


#undef __