src/cpu/x86/vm/c1_FrameMap_x86.cpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1999, 2013, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #include "precompiled.hpp"
 #include "c1/c1_FrameMap.hpp"
 #include "c1/c1_LIR.hpp"
 #include "runtime/sharedRuntime.hpp"
 #include "vmreg_x86.inline.hpp"

 const int FrameMap::pd_c_runtime_reserved_arg_size = 0;

 LIR_Opr FrameMap::map_to_opr(BasicType type, VMRegPair* reg, bool) {
   LIR_Opr opr = LIR_OprFact::illegalOpr;
   VMReg r_1 = reg->first();
   VMReg r_2 = reg->second();
   if (r_1->is_stack()) {
     // Convert stack slot to an SP offset
     // The calling convention does not count the SharedRuntime::out_preserve_stack_slots() value
     // so we must add it in here.
     int st_off = (r_1->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size;
     opr = LIR_OprFact::address(new LIR_Address(rsp_opr, st_off, type));
   } else if (r_1->is_Register()) {
     Register reg = r_1->as_Register();
     if (r_2->is_Register() && (type == T_LONG || type == T_DOUBLE)) {
       Register reg2 = r_2->as_Register();
 #ifdef _LP64
       assert(reg2 == reg, "must be same register");
       opr = as_long_opr(reg);
 #else
       opr = as_long_opr(reg2, reg);
 #endif // _LP64
     } else if (type == T_OBJECT || type == T_ARRAY) {
       opr = as_oop_opr(reg);
     } else if (type == T_METADATA) {
       opr = as_metadata_opr(reg);
     } else {
       opr = as_opr(reg);
     }
   } else if (r_1->is_FloatRegister()) {
     assert(type == T_DOUBLE || type == T_FLOAT, "wrong type");
     int num = r_1->as_FloatRegister()->encoding();
     if (type == T_FLOAT) {
       opr = LIR_OprFact::single_fpu(num);
     } else {
       opr = LIR_OprFact::double_fpu(num);
     }
   } else if (r_1->is_XMMRegister()) {
     assert(type == T_DOUBLE || type == T_FLOAT, "wrong type");
     int num = r_1->as_XMMRegister()->encoding();
     if (type == T_FLOAT) {
       opr = LIR_OprFact::single_xmm(num);
     } else {
       opr = LIR_OprFact::double_xmm(num);
     }
   } else {
     ShouldNotReachHere();
   }
   return opr;
 }


 LIR_Opr FrameMap::rsi_opr;
 LIR_Opr FrameMap::rdi_opr;
 LIR_Opr FrameMap::rbx_opr;
 LIR_Opr FrameMap::rax_opr;
 LIR_Opr FrameMap::rdx_opr;
 LIR_Opr FrameMap::rcx_opr;
 LIR_Opr FrameMap::rsp_opr;
 LIR_Opr FrameMap::rbp_opr;

 LIR_Opr FrameMap::receiver_opr;

 LIR_Opr FrameMap::rsi_oop_opr;
 LIR_Opr FrameMap::rdi_oop_opr;
 LIR_Opr FrameMap::rbx_oop_opr;
 LIR_Opr FrameMap::rax_oop_opr;
 LIR_Opr FrameMap::rdx_oop_opr;
 LIR_Opr FrameMap::rcx_oop_opr;

 LIR_Opr FrameMap::rsi_metadata_opr;
 LIR_Opr FrameMap::rdi_metadata_opr;
 LIR_Opr FrameMap::rbx_metadata_opr;
 LIR_Opr FrameMap::rax_metadata_opr;
 LIR_Opr FrameMap::rdx_metadata_opr;
 LIR_Opr FrameMap::rcx_metadata_opr;

 LIR_Opr FrameMap::long0_opr;
 LIR_Opr FrameMap::long1_opr;
 LIR_Opr FrameMap::fpu0_float_opr;
 LIR_Opr FrameMap::fpu0_double_opr;
 LIR_Opr FrameMap::xmm0_float_opr;
 LIR_Opr FrameMap::xmm0_double_opr;

 #ifdef _LP64

 LIR_Opr  FrameMap::r8_opr;
 LIR_Opr  FrameMap::r9_opr;
 LIR_Opr FrameMap::r10_opr;
 LIR_Opr FrameMap::r11_opr;
 LIR_Opr FrameMap::r12_opr;
 LIR_Opr FrameMap::r13_opr;
 LIR_Opr FrameMap::r14_opr;
 LIR_Opr FrameMap::r15_opr;

 // r10 and r15 can never contain oops since they aren't available to
 // the allocator
 LIR_Opr  FrameMap::r8_oop_opr;
 LIR_Opr  FrameMap::r9_oop_opr;
 LIR_Opr FrameMap::r11_oop_opr;
 LIR_Opr FrameMap::r12_oop_opr;
 LIR_Opr FrameMap::r13_oop_opr;
 LIR_Opr FrameMap::r14_oop_opr;

 LIR_Opr  FrameMap::r8_metadata_opr;
 LIR_Opr  FrameMap::r9_metadata_opr;
 LIR_Opr FrameMap::r11_metadata_opr;
 LIR_Opr FrameMap::r12_metadata_opr;
 LIR_Opr FrameMap::r13_metadata_opr;
 LIR_Opr FrameMap::r14_metadata_opr;
 #endif // _LP64

 LIR_Opr FrameMap::_caller_save_cpu_regs[] = { 0, };
 LIR_Opr FrameMap::_caller_save_fpu_regs[] = { 0, };
 LIR_Opr FrameMap::_caller_save_xmm_regs[] = { 0, };

 XMMRegister FrameMap::_xmm_regs [] = { 0, };

 XMMRegister FrameMap::nr2xmmreg(int rnr) {
   assert(_init_done, "tables not initialized");
   return _xmm_regs[rnr];
 }

 //--------------------------------------------------------
 //               FrameMap
 //--------------------------------------------------------

 void FrameMap::initialize() {
   assert(!_init_done, "once");

   assert(nof_cpu_regs == LP64_ONLY(16) NOT_LP64(8), "wrong number of CPU registers");
   map_register(0, rsi);  rsi_opr = LIR_OprFact::single_cpu(0);
   map_register(1, rdi);  rdi_opr = LIR_OprFact::single_cpu(1);
   map_register(2, rbx);  rbx_opr = LIR_OprFact::single_cpu(2);
   map_register(3, rax);  rax_opr = LIR_OprFact::single_cpu(3);
   map_register(4, rdx);  rdx_opr = LIR_OprFact::single_cpu(4);
   map_register(5, rcx);  rcx_opr = LIR_OprFact::single_cpu(5);

 #ifndef _LP64
   // The unallocatable registers are at the end
   map_register(6, rsp);
   map_register(7, rbp);
 #else
   map_register( 6, r8);    r8_opr = LIR_OprFact::single_cpu(6);
   map_register( 7, r9);    r9_opr = LIR_OprFact::single_cpu(7);
   map_register( 8, r11);  r11_opr = LIR_OprFact::single_cpu(8);
   map_register( 9, r13);  r13_opr = LIR_OprFact::single_cpu(9);
   map_register(10, r14);  r14_opr = LIR_OprFact::single_cpu(10);
   // r12 is allocated conditionally. With compressed oops it holds
   // the heapbase value and is not visible to the allocator.
   map_register(11, r12);  r12_opr = LIR_OprFact::single_cpu(11);
   // The unallocatable registers are at the end
   map_register(12, r10);  r10_opr = LIR_OprFact::single_cpu(12);
   map_register(13, r15);  r15_opr = LIR_OprFact::single_cpu(13);
   map_register(14, rsp);
   map_register(15, rbp);
 #endif // _LP64

 #ifdef _LP64
   long0_opr = LIR_OprFact::double_cpu(3 /*eax*/, 3 /*eax*/);
   long1_opr = LIR_OprFact::double_cpu(2 /*ebx*/, 2 /*ebx*/);
 #else
   long0_opr = LIR_OprFact::double_cpu(3 /*eax*/, 4 /*edx*/);
   long1_opr = LIR_OprFact::double_cpu(2 /*ebx*/, 5 /*ecx*/);
 #endif // _LP64
   fpu0_float_opr   = LIR_OprFact::single_fpu(0);
   fpu0_double_opr  = LIR_OprFact::double_fpu(0);
   xmm0_float_opr   = LIR_OprFact::single_xmm(0);
   xmm0_double_opr  = LIR_OprFact::double_xmm(0);

   _caller_save_cpu_regs[0] = rsi_opr;
   _caller_save_cpu_regs[1] = rdi_opr;
   _caller_save_cpu_regs[2] = rbx_opr;
   _caller_save_cpu_regs[3] = rax_opr;
   _caller_save_cpu_regs[4] = rdx_opr;
   _caller_save_cpu_regs[5] = rcx_opr;

 #ifdef _LP64
   _caller_save_cpu_regs[6]  = r8_opr;
   _caller_save_cpu_regs[7]  = r9_opr;
   _caller_save_cpu_regs[8]  = r11_opr;
   _caller_save_cpu_regs[9]  = r13_opr;
   _caller_save_cpu_regs[10] = r14_opr;
   _caller_save_cpu_regs[11] = r12_opr;
 #endif // _LP64


   _xmm_regs[0] = xmm0;
   _xmm_regs[1] = xmm1;
   _xmm_regs[2] = xmm2;
   _xmm_regs[3] = xmm3;
   _xmm_regs[4] = xmm4;
   _xmm_regs[5] = xmm5;
   _xmm_regs[6] = xmm6;
   _xmm_regs[7] = xmm7;

 #ifdef _LP64
   _xmm_regs[8]   = xmm8;
   _xmm_regs[9]   = xmm9;
   _xmm_regs[10]  = xmm10;
   _xmm_regs[11]  = xmm11;
   _xmm_regs[12]  = xmm12;
   _xmm_regs[13]  = xmm13;
   _xmm_regs[14]  = xmm14;
   _xmm_regs[15]  = xmm15;
 #endif // _LP64

   for (int i = 0; i < 8; i++) {
     _caller_save_fpu_regs[i] = LIR_OprFact::single_fpu(i);
   }

   for (int i = 0; i < nof_caller_save_xmm_regs ; i++) {
     _caller_save_xmm_regs[i] = LIR_OprFact::single_xmm(i);
   }

   _init_done = true;

   rsi_oop_opr = as_oop_opr(rsi);
   rdi_oop_opr = as_oop_opr(rdi);
   rbx_oop_opr = as_oop_opr(rbx);
   rax_oop_opr = as_oop_opr(rax);
   rdx_oop_opr = as_oop_opr(rdx);
   rcx_oop_opr = as_oop_opr(rcx);

   rsi_metadata_opr = as_metadata_opr(rsi);
   rdi_metadata_opr = as_metadata_opr(rdi);
   rbx_metadata_opr = as_metadata_opr(rbx);
   rax_metadata_opr = as_metadata_opr(rax);
   rdx_metadata_opr = as_metadata_opr(rdx);
   rcx_metadata_opr = as_metadata_opr(rcx);

   rsp_opr = as_pointer_opr(rsp);
   rbp_opr = as_pointer_opr(rbp);

 #ifdef _LP64
   r8_oop_opr = as_oop_opr(r8);
   r9_oop_opr = as_oop_opr(r9);
   r11_oop_opr = as_oop_opr(r11);
   r12_oop_opr = as_oop_opr(r12);
   r13_oop_opr = as_oop_opr(r13);
   r14_oop_opr = as_oop_opr(r14);

   r8_metadata_opr = as_metadata_opr(r8);
   r9_metadata_opr = as_metadata_opr(r9);
   r11_metadata_opr = as_metadata_opr(r11);
   r12_metadata_opr = as_metadata_opr(r12);
   r13_metadata_opr = as_metadata_opr(r13);
   r14_metadata_opr = as_metadata_opr(r14);
 #endif // _LP64

   VMRegPair regs;
   BasicType sig_bt = T_OBJECT;
   SharedRuntime::java_calling_convention(&sig_bt, &regs, 1, true);
   receiver_opr = as_oop_opr(regs.first()->as_Register());

 }


 Address FrameMap::make_new_address(ByteSize sp_offset) const {
   // for rbp, based address use this:
   // return Address(rbp, in_bytes(sp_offset) - (framesize() - 2) * 4);
   return Address(rsp, in_bytes(sp_offset));
 }


 // ----------------mapping-----------------------
 // all mapping is based on rbp, addressing, except for simple leaf methods where we access
 // the locals rsp based (and no frame is built)


 // Frame for simple leaf methods (quick entries)
 //
 //   +----------+
 //   | ret addr |   <- TOS
 //   +----------+
 //   | args     |
 //   | ......   |

 // Frame for standard methods
 //
 //   | .........|  <- TOS
 //   | locals   |
 //   +----------+
 //   | old rbp,  |  <- EBP
 //   +----------+
 //   | ret addr |
 //   +----------+
 //   |  args    |
 //   | .........|


 // For OopMaps, map a local variable or spill index to an VMRegImpl name.
 // This is the offset from sp() in the frame of the slot for the index,
 // skewed by VMRegImpl::stack0 to indicate a stack location (vs.a register.)
 //
 //           framesize +
 //           stack0         stack0          0  <- VMReg
 //             |              | <registers> |
 //  ...........|..............|.............|
 //      0 1 2 3 x x 4 5 6 ... |                <- local indices
 //      ^           ^        sp()                 ( x x indicate link
 //      |           |                               and return addr)
 //  arguments   non-argument locals


 VMReg FrameMap::fpu_regname (int n) {
   // Return the OptoReg name for the fpu stack slot "n"
   // A spilled fpu stack slot comprises to two single-word OptoReg's.
   return as_FloatRegister(n)->as_VMReg();
 }

 LIR_Opr FrameMap::stack_pointer() {
   return FrameMap::rsp_opr;
 }

 // JSR 292
 // On x86, there is no need to save the SP, because neither
 // method handle intrinsics, nor compiled lambda forms modify it.
 LIR_Opr FrameMap::method_handle_invoke_SP_save_opr() {
   return LIR_OprFact::illegalOpr;
 }

 bool FrameMap::validate_frame() {
   return true;
 }
	/*
	* Copyright (c) 1999, 2013, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#include "precompiled.hpp"
	#include "c1/c1_FrameMap.hpp"
	#include "c1/c1_LIR.hpp"
	#include "runtime/sharedRuntime.hpp"
	#include "vmreg_x86.inline.hpp"

	const int FrameMap::pd_c_runtime_reserved_arg_size = 0;

	LIR_Opr FrameMap::map_to_opr(BasicType type, VMRegPair* reg, bool) {
	LIR_Opr opr = LIR_OprFact::illegalOpr;
	VMReg r_1 = reg->first();
	VMReg r_2 = reg->second();
	if (r_1->is_stack()) {
	// Convert stack slot to an SP offset
	// The calling convention does not count the SharedRuntime::out_preserve_stack_slots() value
	// so we must add it in here.
	int st_off = (r_1->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size;
	opr = LIR_OprFact::address(new LIR_Address(rsp_opr, st_off, type));
	} else if (r_1->is_Register()) {
	Register reg = r_1->as_Register();
	if (r_2->is_Register() && (type == T_LONG \|\| type == T_DOUBLE)) {
	Register reg2 = r_2->as_Register();
	#ifdef _LP64
	assert(reg2 == reg, "must be same register");
	opr = as_long_opr(reg);
	#else
	opr = as_long_opr(reg2, reg);
	#endif // _LP64
	} else if (type == T_OBJECT \|\| type == T_ARRAY) {
	opr = as_oop_opr(reg);
	} else if (type == T_METADATA) {
	opr = as_metadata_opr(reg);
	} else {
	opr = as_opr(reg);
	}
	} else if (r_1->is_FloatRegister()) {
	assert(type == T_DOUBLE \|\| type == T_FLOAT, "wrong type");
	int num = r_1->as_FloatRegister()->encoding();
	if (type == T_FLOAT) {
	opr = LIR_OprFact::single_fpu(num);
	} else {
	opr = LIR_OprFact::double_fpu(num);
	}
	} else if (r_1->is_XMMRegister()) {
	assert(type == T_DOUBLE \|\| type == T_FLOAT, "wrong type");
	int num = r_1->as_XMMRegister()->encoding();
	if (type == T_FLOAT) {
	opr = LIR_OprFact::single_xmm(num);
	} else {
	opr = LIR_OprFact::double_xmm(num);
	}
	} else {
	ShouldNotReachHere();
	}
	return opr;
	}


	LIR_Opr FrameMap::rsi_opr;
	LIR_Opr FrameMap::rdi_opr;
	LIR_Opr FrameMap::rbx_opr;
	LIR_Opr FrameMap::rax_opr;
	LIR_Opr FrameMap::rdx_opr;
	LIR_Opr FrameMap::rcx_opr;
	LIR_Opr FrameMap::rsp_opr;
	LIR_Opr FrameMap::rbp_opr;

	LIR_Opr FrameMap::receiver_opr;

	LIR_Opr FrameMap::rsi_oop_opr;
	LIR_Opr FrameMap::rdi_oop_opr;
	LIR_Opr FrameMap::rbx_oop_opr;
	LIR_Opr FrameMap::rax_oop_opr;
	LIR_Opr FrameMap::rdx_oop_opr;
	LIR_Opr FrameMap::rcx_oop_opr;

	LIR_Opr FrameMap::rsi_metadata_opr;
	LIR_Opr FrameMap::rdi_metadata_opr;
	LIR_Opr FrameMap::rbx_metadata_opr;
	LIR_Opr FrameMap::rax_metadata_opr;
	LIR_Opr FrameMap::rdx_metadata_opr;
	LIR_Opr FrameMap::rcx_metadata_opr;

	LIR_Opr FrameMap::long0_opr;
	LIR_Opr FrameMap::long1_opr;
	LIR_Opr FrameMap::fpu0_float_opr;
	LIR_Opr FrameMap::fpu0_double_opr;
	LIR_Opr FrameMap::xmm0_float_opr;
	LIR_Opr FrameMap::xmm0_double_opr;

	#ifdef _LP64

	LIR_Opr FrameMap::r8_opr;
	LIR_Opr FrameMap::r9_opr;
	LIR_Opr FrameMap::r10_opr;
	LIR_Opr FrameMap::r11_opr;
	LIR_Opr FrameMap::r12_opr;
	LIR_Opr FrameMap::r13_opr;
	LIR_Opr FrameMap::r14_opr;
	LIR_Opr FrameMap::r15_opr;

	// r10 and r15 can never contain oops since they aren't available to
	// the allocator
	LIR_Opr FrameMap::r8_oop_opr;
	LIR_Opr FrameMap::r9_oop_opr;
	LIR_Opr FrameMap::r11_oop_opr;
	LIR_Opr FrameMap::r12_oop_opr;
	LIR_Opr FrameMap::r13_oop_opr;
	LIR_Opr FrameMap::r14_oop_opr;

	LIR_Opr FrameMap::r8_metadata_opr;
	LIR_Opr FrameMap::r9_metadata_opr;
	LIR_Opr FrameMap::r11_metadata_opr;
	LIR_Opr FrameMap::r12_metadata_opr;
	LIR_Opr FrameMap::r13_metadata_opr;
	LIR_Opr FrameMap::r14_metadata_opr;
	#endif // _LP64

	LIR_Opr FrameMap::_caller_save_cpu_regs[] = { 0, };
	LIR_Opr FrameMap::_caller_save_fpu_regs[] = { 0, };
	LIR_Opr FrameMap::_caller_save_xmm_regs[] = { 0, };

	XMMRegister FrameMap::_xmm_regs [] = { 0, };

	XMMRegister FrameMap::nr2xmmreg(int rnr) {
	assert(_init_done, "tables not initialized");
	return _xmm_regs[rnr];
	}

	//--------------------------------------------------------
	// FrameMap
	//--------------------------------------------------------

	void FrameMap::initialize() {
	assert(!_init_done, "once");

	assert(nof_cpu_regs == LP64_ONLY(16) NOT_LP64(8), "wrong number of CPU registers");
	map_register(0, rsi); rsi_opr = LIR_OprFact::single_cpu(0);
	map_register(1, rdi); rdi_opr = LIR_OprFact::single_cpu(1);
	map_register(2, rbx); rbx_opr = LIR_OprFact::single_cpu(2);
	map_register(3, rax); rax_opr = LIR_OprFact::single_cpu(3);
	map_register(4, rdx); rdx_opr = LIR_OprFact::single_cpu(4);
	map_register(5, rcx); rcx_opr = LIR_OprFact::single_cpu(5);

	#ifndef _LP64
	// The unallocatable registers are at the end
	map_register(6, rsp);
	map_register(7, rbp);
	#else
	map_register( 6, r8); r8_opr = LIR_OprFact::single_cpu(6);
	map_register( 7, r9); r9_opr = LIR_OprFact::single_cpu(7);
	map_register( 8, r11); r11_opr = LIR_OprFact::single_cpu(8);
	map_register( 9, r13); r13_opr = LIR_OprFact::single_cpu(9);
	map_register(10, r14); r14_opr = LIR_OprFact::single_cpu(10);
	// r12 is allocated conditionally. With compressed oops it holds
	// the heapbase value and is not visible to the allocator.
	map_register(11, r12); r12_opr = LIR_OprFact::single_cpu(11);
	// The unallocatable registers are at the end
	map_register(12, r10); r10_opr = LIR_OprFact::single_cpu(12);
	map_register(13, r15); r15_opr = LIR_OprFact::single_cpu(13);
	map_register(14, rsp);
	map_register(15, rbp);
	#endif // _LP64

	#ifdef _LP64
	long0_opr = LIR_OprFact::double_cpu(3 /eax/, 3 /eax/);
	long1_opr = LIR_OprFact::double_cpu(2 /ebx/, 2 /ebx/);
	#else
	long0_opr = LIR_OprFact::double_cpu(3 /eax/, 4 /edx/);
	long1_opr = LIR_OprFact::double_cpu(2 /ebx/, 5 /ecx/);
	#endif // _LP64
	fpu0_float_opr = LIR_OprFact::single_fpu(0);
	fpu0_double_opr = LIR_OprFact::double_fpu(0);
	xmm0_float_opr = LIR_OprFact::single_xmm(0);
	xmm0_double_opr = LIR_OprFact::double_xmm(0);

	_caller_save_cpu_regs[0] = rsi_opr;
	_caller_save_cpu_regs[1] = rdi_opr;
	_caller_save_cpu_regs[2] = rbx_opr;
	_caller_save_cpu_regs[3] = rax_opr;
	_caller_save_cpu_regs[4] = rdx_opr;
	_caller_save_cpu_regs[5] = rcx_opr;

	#ifdef _LP64
	_caller_save_cpu_regs[6] = r8_opr;
	_caller_save_cpu_regs[7] = r9_opr;
	_caller_save_cpu_regs[8] = r11_opr;
	_caller_save_cpu_regs[9] = r13_opr;
	_caller_save_cpu_regs[10] = r14_opr;
	_caller_save_cpu_regs[11] = r12_opr;
	#endif // _LP64


	_xmm_regs[0] = xmm0;
	_xmm_regs[1] = xmm1;
	_xmm_regs[2] = xmm2;
	_xmm_regs[3] = xmm3;
	_xmm_regs[4] = xmm4;
	_xmm_regs[5] = xmm5;
	_xmm_regs[6] = xmm6;
	_xmm_regs[7] = xmm7;

	#ifdef _LP64
	_xmm_regs[8] = xmm8;
	_xmm_regs[9] = xmm9;
	_xmm_regs[10] = xmm10;
	_xmm_regs[11] = xmm11;
	_xmm_regs[12] = xmm12;
	_xmm_regs[13] = xmm13;
	_xmm_regs[14] = xmm14;
	_xmm_regs[15] = xmm15;
	#endif // _LP64

	for (int i = 0; i < 8; i++) {
	_caller_save_fpu_regs[i] = LIR_OprFact::single_fpu(i);
	}

	for (int i = 0; i < nof_caller_save_xmm_regs ; i++) {
	_caller_save_xmm_regs[i] = LIR_OprFact::single_xmm(i);
	}

	_init_done = true;

	rsi_oop_opr = as_oop_opr(rsi);
	rdi_oop_opr = as_oop_opr(rdi);
	rbx_oop_opr = as_oop_opr(rbx);
	rax_oop_opr = as_oop_opr(rax);
	rdx_oop_opr = as_oop_opr(rdx);
	rcx_oop_opr = as_oop_opr(rcx);

	rsi_metadata_opr = as_metadata_opr(rsi);
	rdi_metadata_opr = as_metadata_opr(rdi);
	rbx_metadata_opr = as_metadata_opr(rbx);
	rax_metadata_opr = as_metadata_opr(rax);
	rdx_metadata_opr = as_metadata_opr(rdx);
	rcx_metadata_opr = as_metadata_opr(rcx);

	rsp_opr = as_pointer_opr(rsp);
	rbp_opr = as_pointer_opr(rbp);

	#ifdef _LP64
	r8_oop_opr = as_oop_opr(r8);
	r9_oop_opr = as_oop_opr(r9);
	r11_oop_opr = as_oop_opr(r11);
	r12_oop_opr = as_oop_opr(r12);
	r13_oop_opr = as_oop_opr(r13);
	r14_oop_opr = as_oop_opr(r14);

	r8_metadata_opr = as_metadata_opr(r8);
	r9_metadata_opr = as_metadata_opr(r9);
	r11_metadata_opr = as_metadata_opr(r11);
	r12_metadata_opr = as_metadata_opr(r12);
	r13_metadata_opr = as_metadata_opr(r13);
	r14_metadata_opr = as_metadata_opr(r14);
	#endif // _LP64

	VMRegPair regs;
	BasicType sig_bt = T_OBJECT;
	SharedRuntime::java_calling_convention(&sig_bt, &regs, 1, true);
	receiver_opr = as_oop_opr(regs.first()->as_Register());

	}


	Address FrameMap::make_new_address(ByteSize sp_offset) const {
	// for rbp, based address use this:
	// return Address(rbp, in_bytes(sp_offset) - (framesize() - 2) * 4);
	return Address(rsp, in_bytes(sp_offset));
	}


	// ----------------mapping-----------------------
	// all mapping is based on rbp, addressing, except for simple leaf methods where we access
	// the locals rsp based (and no frame is built)


	// Frame for simple leaf methods (quick entries)
	//
	// +----------+
	// \| ret addr \| <- TOS
	// +----------+
	// \| args \|
	// \| ...... \|

	// Frame for standard methods
	//
	// \| .........\| <- TOS
	// \| locals \|
	// +----------+
	// \| old rbp, \| <- EBP
	// +----------+
	// \| ret addr \|
	// +----------+
	// \| args \|
	// \| .........\|


	// For OopMaps, map a local variable or spill index to an VMRegImpl name.
	// This is the offset from sp() in the frame of the slot for the index,
	// skewed by VMRegImpl::stack0 to indicate a stack location (vs.a register.)
	//
	// framesize +
	// stack0 stack0 0 <- VMReg
	// \| \| <registers> \|
	// ...........\|..............\|.............\|
	// 0 1 2 3 x x 4 5 6 ... \| <- local indices
	// ^ ^ sp() ( x x indicate link
	// \| \| and return addr)
	// arguments non-argument locals


	VMReg FrameMap::fpu_regname (int n) {
	// Return the OptoReg name for the fpu stack slot "n"
	// A spilled fpu stack slot comprises to two single-word OptoReg's.
	return as_FloatRegister(n)->as_VMReg();
	}

	LIR_Opr FrameMap::stack_pointer() {
	return FrameMap::rsp_opr;
	}

	// JSR 292
	// On x86, there is no need to save the SP, because neither
	// method handle intrinsics, nor compiled lambda forms modify it.
	LIR_Opr FrameMap::method_handle_invoke_SP_save_opr() {
	return LIR_OprFact::illegalOpr;
	}

	bool FrameMap::validate_frame() {
	return true;
	}