src/hotspot/cpu/ppc/nativeInst_ppc.hpp - platform/libcore - Git at Google

 /*
  * Copyright (c) 2002, 2018, Oracle and/or its affiliates. All rights reserved.
  * Copyright (c) 2012, 2018 SAP SE. 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.
  *
  */

 #ifndef CPU_PPC_VM_NATIVEINST_PPC_HPP
 #define CPU_PPC_VM_NATIVEINST_PPC_HPP

 #include "asm/macroAssembler.hpp"
 #include "runtime/icache.hpp"
 #include "runtime/os.hpp"
 #include "runtime/safepointMechanism.hpp"

 // We have interfaces for the following instructions:
 //
 // - NativeInstruction
 //   - NativeCall
 //   - NativeFarCall
 //   - NativeMovConstReg
 //   - NativeJump
 //   - NativeIllegalInstruction
 //   - NativeConditionalFarBranch
 //   - NativeCallTrampolineStub

 // The base class for different kinds of native instruction abstractions.
 // It provides the primitive operations to manipulate code relative to this.
 class NativeInstruction {
   friend class Relocation;

  public:
   bool is_jump() { return Assembler::is_b(long_at(0)); } // See NativeGeneralJump.

   bool is_sigtrap_ic_miss_check() {
     assert(UseSIGTRAP, "precondition");
     return MacroAssembler::is_trap_ic_miss_check(long_at(0));
   }

   bool is_sigtrap_null_check() {
     assert(UseSIGTRAP && TrapBasedNullChecks, "precondition");
     return MacroAssembler::is_trap_null_check(long_at(0));
   }

   // We use a special trap for marking a method as not_entrant or zombie
   // iff UseSIGTRAP.
   bool is_sigtrap_zombie_not_entrant() {
     assert(UseSIGTRAP, "precondition");
     return MacroAssembler::is_trap_zombie_not_entrant(long_at(0));
   }

   // We use an illtrap for marking a method as not_entrant or zombie
   // iff !UseSIGTRAP.
   bool is_sigill_zombie_not_entrant() {
     assert(!UseSIGTRAP, "precondition");
     // Work around a C++ compiler bug which changes 'this'.
     return NativeInstruction::is_sigill_zombie_not_entrant_at(addr_at(0));
   }
   static bool is_sigill_zombie_not_entrant_at(address addr);

 #ifdef COMPILER2
   // SIGTRAP-based implicit range checks
   bool is_sigtrap_range_check() {
     assert(UseSIGTRAP && TrapBasedRangeChecks, "precondition");
     return MacroAssembler::is_trap_range_check(long_at(0));
   }
 #endif

   // 'should not reach here'.
   bool is_sigtrap_should_not_reach_here() {
     return MacroAssembler::is_trap_should_not_reach_here(long_at(0));
   }

   bool is_safepoint_poll() {
     // Is the current instruction a POTENTIAL read access to the polling page?
     // The current arguments of the instruction are not checked!
     if (SafepointMechanism::uses_thread_local_poll() && USE_POLL_BIT_ONLY) {
       int encoding = SafepointMechanism::poll_bit();
       return MacroAssembler::is_tdi(long_at(0), Assembler::traptoGreaterThanUnsigned | Assembler::traptoEqual,
                                     -1, encoding);
     }
     return MacroAssembler::is_load_from_polling_page(long_at(0), NULL);
   }

   bool is_memory_serialization(JavaThread *thread, void *ucontext) {
     // Is the current instruction a write access of thread to the
     // memory serialization page?
     return MacroAssembler::is_memory_serialization(long_at(0), thread, ucontext);
   }

   address get_stack_bang_address(void *ucontext) {
     // If long_at(0) is not a stack bang, return 0. Otherwise, return
     // banged address.
     return MacroAssembler::get_stack_bang_address(long_at(0), ucontext);
   }

  protected:
   address  addr_at(int offset) const    { return address(this) + offset; }
   int      long_at(int offset) const    { return *(int*)addr_at(offset); }

  public:
   void verify() NOT_DEBUG_RETURN;
 };

 inline NativeInstruction* nativeInstruction_at(address address) {
   NativeInstruction* inst = (NativeInstruction*)address;
   inst->verify();
   return inst;
 }

 // The NativeCall is an abstraction for accessing/manipulating call
 // instructions. It is used to manipulate inline caches, primitive &
 // dll calls, etc.
 //
 // Sparc distinguishes `NativeCall' and `NativeFarCall'. On PPC64,
 // at present, we provide a single class `NativeCall' representing the
 // sequence `load_const, mtctr, bctrl' or the sequence 'ld_from_toc,
 // mtctr, bctrl'.
 class NativeCall: public NativeInstruction {
  public:

   enum ppc_specific_constants {
     load_const_instruction_size                 = 28,
     load_const_from_method_toc_instruction_size = 16,
     instruction_size                            = 16 // Used in shared code for calls with reloc_info.
   };

   static bool is_call_at(address a) {
     return Assembler::is_bl(*(int*)(a));
   }

   static bool is_call_before(address return_address) {
     return NativeCall::is_call_at(return_address - 4);
   }

   address instruction_address() const {
     return addr_at(0);
   }

   address next_instruction_address() const {
     // We have only bl.
     assert(MacroAssembler::is_bl(*(int*)instruction_address()), "Should be bl instruction!");
     return addr_at(4);
   }

   address return_address() const {
     return next_instruction_address();
   }

   address destination() const;

   // The parameter assert_lock disables the assertion during code generation.
   void set_destination_mt_safe(address dest, bool assert_lock = true);

   address get_trampoline();

   void verify_alignment() {} // do nothing on ppc
   void verify() NOT_DEBUG_RETURN;
 };

 inline NativeCall* nativeCall_at(address instr) {
   NativeCall* call = (NativeCall*)instr;
   call->verify();
   return call;
 }

 inline NativeCall* nativeCall_before(address return_address) {
   NativeCall* call = NULL;
   if (MacroAssembler::is_bl(*(int*)(return_address - 4)))
     call = (NativeCall*)(return_address - 4);
   call->verify();
   return call;
 }

 // The NativeFarCall is an abstraction for accessing/manipulating native
 // call-anywhere instructions.
 // Used to call native methods which may be loaded anywhere in the address
 // space, possibly out of reach of a call instruction.
 class NativeFarCall: public NativeInstruction {
  public:
   // We use MacroAssembler::bl64_patchable() for implementing a
   // call-anywhere instruction.

   // Checks whether instr points at a NativeFarCall instruction.
   static bool is_far_call_at(address instr) {
     return MacroAssembler::is_bl64_patchable_at(instr);
   }

   // Does the NativeFarCall implementation use a pc-relative encoding
   // of the call destination?
   // Used when relocating code.
   bool is_pcrelative() {
     assert(MacroAssembler::is_bl64_patchable_at((address)this),
            "unexpected call type");
     return MacroAssembler::is_bl64_patchable_pcrelative_at((address)this);
   }

   // Returns the NativeFarCall's destination.
   address destination() const {
     assert(MacroAssembler::is_bl64_patchable_at((address)this),
            "unexpected call type");
     return MacroAssembler::get_dest_of_bl64_patchable_at((address)this);
   }

   // Sets the NativeCall's destination, not necessarily mt-safe.
   // Used when relocating code.
   void set_destination(address dest) {
     // Set new destination (implementation of call may change here).
     assert(MacroAssembler::is_bl64_patchable_at((address)this),
            "unexpected call type");
     MacroAssembler::set_dest_of_bl64_patchable_at((address)this, dest);
   }

   void verify() NOT_DEBUG_RETURN;
 };

 // Instantiates a NativeFarCall object starting at the given instruction
 // address and returns the NativeFarCall object.
 inline NativeFarCall* nativeFarCall_at(address instr) {
   NativeFarCall* call = (NativeFarCall*)instr;
   call->verify();
   return call;
 }

 // An interface for accessing/manipulating native set_oop imm, reg instructions
 // (used to manipulate inlined data references, etc.).
 class NativeMovConstReg: public NativeInstruction {
  public:

   enum ppc_specific_constants {
     load_const_instruction_size                 = 20,
     load_const_from_method_toc_instruction_size =  8,
     instruction_size                            =  8 // Used in shared code for calls with reloc_info.
   };

   address instruction_address() const {
     return addr_at(0);
   }

   address next_instruction_address() const;

   // (The [set_]data accessor respects oop_type relocs also.)
   intptr_t data() const;

   // Patch the code stream.
   address set_data_plain(intptr_t x, CodeBlob *code);
   // Patch the code stream and oop pool.
   void set_data(intptr_t x);

   // Patch narrow oop constants. Use this also for narrow klass.
   void set_narrow_oop(narrowOop data, CodeBlob *code = NULL);

   void verify() NOT_DEBUG_RETURN;
 };

 inline NativeMovConstReg* nativeMovConstReg_at(address address) {
   NativeMovConstReg* test = (NativeMovConstReg*)address;
   test->verify();
   return test;
 }

 // The NativeJump is an abstraction for accessing/manipulating native
 // jump-anywhere instructions.
 class NativeJump: public NativeInstruction {
  public:
   // We use MacroAssembler::b64_patchable() for implementing a
   // jump-anywhere instruction.

   enum ppc_specific_constants {
     instruction_size = MacroAssembler::b64_patchable_size
   };

   // Checks whether instr points at a NativeJump instruction.
   static bool is_jump_at(address instr) {
     return MacroAssembler::is_b64_patchable_at(instr)
       || (   MacroAssembler::is_load_const_from_method_toc_at(instr)
           && Assembler::is_mtctr(*(int*)(instr + 2 * 4))
           && Assembler::is_bctr(*(int*)(instr + 3 * 4)));
   }

   // Does the NativeJump implementation use a pc-relative encoding
   // of the call destination?
   // Used when relocating code or patching jumps.
   bool is_pcrelative() {
     return MacroAssembler::is_b64_patchable_pcrelative_at((address)this);
   }

   // Returns the NativeJump's destination.
   address jump_destination() const {
     if (MacroAssembler::is_b64_patchable_at((address)this)) {
       return MacroAssembler::get_dest_of_b64_patchable_at((address)this);
     } else if (MacroAssembler::is_load_const_from_method_toc_at((address)this)
                && Assembler::is_mtctr(*(int*)((address)this + 2 * 4))
                && Assembler::is_bctr(*(int*)((address)this + 3 * 4))) {
       return (address)((NativeMovConstReg *)this)->data();
     } else {
       ShouldNotReachHere();
       return NULL;
     }
   }

   // Sets the NativeJump's destination, not necessarily mt-safe.
   // Used when relocating code or patching jumps.
   void set_jump_destination(address dest) {
     // Set new destination (implementation of call may change here).
     if (MacroAssembler::is_b64_patchable_at((address)this)) {
       MacroAssembler::set_dest_of_b64_patchable_at((address)this, dest);
     } else if (MacroAssembler::is_load_const_from_method_toc_at((address)this)
                && Assembler::is_mtctr(*(int*)((address)this + 2 * 4))
                && Assembler::is_bctr(*(int*)((address)this + 3 * 4))) {
       ((NativeMovConstReg *)this)->set_data((intptr_t)dest);
     } else {
       ShouldNotReachHere();
     }
   }

   // MT-safe insertion of native jump at verified method entry
   static void patch_verified_entry(address entry, address verified_entry, address dest);

   void verify() NOT_DEBUG_RETURN;

   static void check_verified_entry_alignment(address entry, address verified_entry) {
     // We just patch one instruction on ppc64, so the jump doesn't have to
     // be aligned. Nothing to do here.
   }
 };

 // Instantiates a NativeJump object starting at the given instruction
 // address and returns the NativeJump object.
 inline NativeJump* nativeJump_at(address instr) {
   NativeJump* call = (NativeJump*)instr;
   call->verify();
   return call;
 }

 // NativeConditionalFarBranch is abstraction for accessing/manipulating
 // conditional far branches.
 class NativeConditionalFarBranch : public NativeInstruction {
  public:

   static bool is_conditional_far_branch_at(address instr) {
     return MacroAssembler::is_bc_far_at(instr);
   }

   address branch_destination() const {
     return MacroAssembler::get_dest_of_bc_far_at((address)this);
   }

   void set_branch_destination(address dest) {
     MacroAssembler::set_dest_of_bc_far_at((address)this, dest);
   }
 };

 inline NativeConditionalFarBranch* NativeConditionalFarBranch_at(address address) {
   assert(NativeConditionalFarBranch::is_conditional_far_branch_at(address),
          "must be a conditional far branch");
   return (NativeConditionalFarBranch*)address;
 }

 // Call trampoline stubs.
 class NativeCallTrampolineStub : public NativeInstruction {
  private:

   address encoded_destination_addr() const;

  public:

   address destination(nmethod *nm = NULL) const;
   int destination_toc_offset() const;

   void set_destination(address new_destination);
 };

 // Note: Other stubs must not begin with this pattern.
 inline bool is_NativeCallTrampolineStub_at(address address) {
   int first_instr = *(int*)address;
   // calculate_address_from_global_toc and long form of ld_largeoffset_unchecked begin with addis with target R12
   if (Assembler::is_addis(first_instr) &&
       (Register)(intptr_t)Assembler::inv_rt_field(first_instr) == R12_scratch2) return true;

   // short form of ld_largeoffset_unchecked is ld which is followed by mtctr
   int second_instr = *((int*)address + 1);
   if (Assembler::is_ld(first_instr) &&
       (Register)(intptr_t)Assembler::inv_rt_field(first_instr) == R12_scratch2 &&
       Assembler::is_mtctr(second_instr) &&
       (Register)(intptr_t)Assembler::inv_rs_field(second_instr) == R12_scratch2) return true;

   return false;
 }

 inline NativeCallTrampolineStub* NativeCallTrampolineStub_at(address address) {
   assert(is_NativeCallTrampolineStub_at(address), "no call trampoline found");
   return (NativeCallTrampolineStub*)address;
 }

 ///////////////////////////////////////////////////////////////////////////////////////////////////

 //-------------------------------------
 //  N a t i v e G e n e r a l J u m p
 //-------------------------------------

 // Despite the name, handles only simple branches.
 class NativeGeneralJump;
 inline NativeGeneralJump* nativeGeneralJump_at(address address);

 // Currently only implemented as single unconditional branch.
 class NativeGeneralJump: public NativeInstruction {
  public:

   enum PPC64_specific_constants {
     instruction_size = 4
   };

   address instruction_address() const { return addr_at(0); }

   // Creation.
   friend inline NativeGeneralJump* nativeGeneralJump_at(address addr) {
     NativeGeneralJump* jump = (NativeGeneralJump*)(addr);
     DEBUG_ONLY( jump->verify(); )
     return jump;
   }

   // Insertion of native general jump instruction.
   static void insert_unconditional(address code_pos, address entry);

   address jump_destination() const {
     DEBUG_ONLY( verify(); )
     return addr_at(0) + Assembler::inv_li_field(long_at(0));
   }

   void set_jump_destination(address dest) {
     DEBUG_ONLY( verify(); )
     insert_unconditional(addr_at(0), dest);
   }

   static void replace_mt_safe(address instr_addr, address code_buffer);

   void verify() const { guarantee(Assembler::is_b(long_at(0)), "invalid NativeGeneralJump"); }
 };

 // An interface for accessing/manipulating native load int (load_const32).
 class NativeMovRegMem;
 inline NativeMovRegMem* nativeMovRegMem_at(address address);
 class NativeMovRegMem: public NativeInstruction {
  public:

   enum PPC64_specific_constants {
     instruction_size = 8
   };

   address instruction_address() const { return addr_at(0); }

   int num_bytes_to_end_of_patch() const { return instruction_size; }

   intptr_t offset() const {
 #ifdef VM_LITTLE_ENDIAN
     short *hi_ptr = (short*)(addr_at(0));
     short *lo_ptr = (short*)(addr_at(4));
 #else
     short *hi_ptr = (short*)(addr_at(0) + 2);
     short *lo_ptr = (short*)(addr_at(4) + 2);
 #endif
     return ((*hi_ptr) << 16) | ((*lo_ptr) & 0xFFFF);
   }

   void set_offset(intptr_t x) {
 #ifdef VM_LITTLE_ENDIAN
     short *hi_ptr = (short*)(addr_at(0));
     short *lo_ptr = (short*)(addr_at(4));
 #else
     short *hi_ptr = (short*)(addr_at(0) + 2);
     short *lo_ptr = (short*)(addr_at(4) + 2);
 #endif
     *hi_ptr = x >> 16;
     *lo_ptr = x & 0xFFFF;
     ICache::ppc64_flush_icache_bytes(addr_at(0), NativeMovRegMem::instruction_size);
   }

   void add_offset_in_bytes(intptr_t radd_offset) {
     set_offset(offset() + radd_offset);
   }

   void verify() const {
     guarantee(Assembler::is_lis(long_at(0)), "load_const32 1st instr");
     guarantee(Assembler::is_ori(long_at(4)), "load_const32 2nd instr");
   }

  private:
   friend inline NativeMovRegMem* nativeMovRegMem_at(address address) {
     NativeMovRegMem* test = (NativeMovRegMem*)address;
     DEBUG_ONLY( test->verify(); )
     return test;
   }
 };

 #endif // CPU_PPC_VM_NATIVEINST_PPC_HPP
	/*
	* Copyright (c) 2002, 2018, Oracle and/or its affiliates. All rights reserved.
	* Copyright (c) 2012, 2018 SAP SE. 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.
	*
	*/

	#ifndef CPU_PPC_VM_NATIVEINST_PPC_HPP
	#define CPU_PPC_VM_NATIVEINST_PPC_HPP

	#include "asm/macroAssembler.hpp"
	#include "runtime/icache.hpp"
	#include "runtime/os.hpp"
	#include "runtime/safepointMechanism.hpp"

	// We have interfaces for the following instructions:
	//
	// - NativeInstruction
	// - NativeCall
	// - NativeFarCall
	// - NativeMovConstReg
	// - NativeJump
	// - NativeIllegalInstruction
	// - NativeConditionalFarBranch
	// - NativeCallTrampolineStub

	// The base class for different kinds of native instruction abstractions.
	// It provides the primitive operations to manipulate code relative to this.
	class NativeInstruction {
	friend class Relocation;

	public:
	bool is_jump() { return Assembler::is_b(long_at(0)); } // See NativeGeneralJump.

	bool is_sigtrap_ic_miss_check() {
	assert(UseSIGTRAP, "precondition");
	return MacroAssembler::is_trap_ic_miss_check(long_at(0));
	}

	bool is_sigtrap_null_check() {
	assert(UseSIGTRAP && TrapBasedNullChecks, "precondition");
	return MacroAssembler::is_trap_null_check(long_at(0));
	}

	// We use a special trap for marking a method as not_entrant or zombie
	// iff UseSIGTRAP.
	bool is_sigtrap_zombie_not_entrant() {
	assert(UseSIGTRAP, "precondition");
	return MacroAssembler::is_trap_zombie_not_entrant(long_at(0));
	}

	// We use an illtrap for marking a method as not_entrant or zombie
	// iff !UseSIGTRAP.
	bool is_sigill_zombie_not_entrant() {
	assert(!UseSIGTRAP, "precondition");
	// Work around a C++ compiler bug which changes 'this'.
	return NativeInstruction::is_sigill_zombie_not_entrant_at(addr_at(0));
	}
	static bool is_sigill_zombie_not_entrant_at(address addr);

	#ifdef COMPILER2
	// SIGTRAP-based implicit range checks
	bool is_sigtrap_range_check() {
	assert(UseSIGTRAP && TrapBasedRangeChecks, "precondition");
	return MacroAssembler::is_trap_range_check(long_at(0));
	}
	#endif

	// 'should not reach here'.
	bool is_sigtrap_should_not_reach_here() {
	return MacroAssembler::is_trap_should_not_reach_here(long_at(0));
	}

	bool is_safepoint_poll() {
	// Is the current instruction a POTENTIAL read access to the polling page?
	// The current arguments of the instruction are not checked!
	if (SafepointMechanism::uses_thread_local_poll() && USE_POLL_BIT_ONLY) {
	int encoding = SafepointMechanism::poll_bit();
	return MacroAssembler::is_tdi(long_at(0), Assembler::traptoGreaterThanUnsigned \| Assembler::traptoEqual,
	-1, encoding);
	}
	return MacroAssembler::is_load_from_polling_page(long_at(0), NULL);
	}

	bool is_memory_serialization(JavaThread thread, void ucontext) {
	// Is the current instruction a write access of thread to the
	// memory serialization page?
	return MacroAssembler::is_memory_serialization(long_at(0), thread, ucontext);
	}

	address get_stack_bang_address(void *ucontext) {
	// If long_at(0) is not a stack bang, return 0. Otherwise, return
	// banged address.
	return MacroAssembler::get_stack_bang_address(long_at(0), ucontext);
	}

	protected:
	address addr_at(int offset) const { return address(this) + offset; }
	int long_at(int offset) const { return (int)addr_at(offset); }

	public:
	void verify() NOT_DEBUG_RETURN;
	};

	inline NativeInstruction* nativeInstruction_at(address address) {
	NativeInstruction* inst = (NativeInstruction*)address;
	inst->verify();
	return inst;
	}

	// The NativeCall is an abstraction for accessing/manipulating call
	// instructions. It is used to manipulate inline caches, primitive &
	// dll calls, etc.
	//
	// Sparc distinguishes `NativeCall' and `NativeFarCall'. On PPC64,
	// at present, we provide a single class `NativeCall' representing the
	// sequence `load_const, mtctr, bctrl' or the sequence 'ld_from_toc,
	// mtctr, bctrl'.
	class NativeCall: public NativeInstruction {
	public:

	enum ppc_specific_constants {
	load_const_instruction_size = 28,
	load_const_from_method_toc_instruction_size = 16,
	instruction_size = 16 // Used in shared code for calls with reloc_info.
	};

	static bool is_call_at(address a) {
	return Assembler::is_bl((int)(a));
	}

	static bool is_call_before(address return_address) {
	return NativeCall::is_call_at(return_address - 4);
	}

	address instruction_address() const {
	return addr_at(0);
	}

	address next_instruction_address() const {
	// We have only bl.
	assert(MacroAssembler::is_bl((int)instruction_address()), "Should be bl instruction!");
	return addr_at(4);
	}

	address return_address() const {
	return next_instruction_address();
	}

	address destination() const;

	// The parameter assert_lock disables the assertion during code generation.
	void set_destination_mt_safe(address dest, bool assert_lock = true);

	address get_trampoline();

	void verify_alignment() {} // do nothing on ppc
	void verify() NOT_DEBUG_RETURN;
	};

	inline NativeCall* nativeCall_at(address instr) {
	NativeCall* call = (NativeCall*)instr;
	call->verify();
	return call;
	}

	inline NativeCall* nativeCall_before(address return_address) {
	NativeCall* call = NULL;
	if (MacroAssembler::is_bl((int)(return_address - 4)))
	call = (NativeCall*)(return_address - 4);
	call->verify();
	return call;
	}

	// The NativeFarCall is an abstraction for accessing/manipulating native
	// call-anywhere instructions.
	// Used to call native methods which may be loaded anywhere in the address
	// space, possibly out of reach of a call instruction.
	class NativeFarCall: public NativeInstruction {
	public:
	// We use MacroAssembler::bl64_patchable() for implementing a
	// call-anywhere instruction.

	// Checks whether instr points at a NativeFarCall instruction.
	static bool is_far_call_at(address instr) {
	return MacroAssembler::is_bl64_patchable_at(instr);
	}

	// Does the NativeFarCall implementation use a pc-relative encoding
	// of the call destination?
	// Used when relocating code.
	bool is_pcrelative() {
	assert(MacroAssembler::is_bl64_patchable_at((address)this),
	"unexpected call type");
	return MacroAssembler::is_bl64_patchable_pcrelative_at((address)this);
	}

	// Returns the NativeFarCall's destination.
	address destination() const {
	assert(MacroAssembler::is_bl64_patchable_at((address)this),
	"unexpected call type");
	return MacroAssembler::get_dest_of_bl64_patchable_at((address)this);
	}

	// Sets the NativeCall's destination, not necessarily mt-safe.
	// Used when relocating code.
	void set_destination(address dest) {
	// Set new destination (implementation of call may change here).
	assert(MacroAssembler::is_bl64_patchable_at((address)this),
	"unexpected call type");
	MacroAssembler::set_dest_of_bl64_patchable_at((address)this, dest);
	}

	void verify() NOT_DEBUG_RETURN;
	};

	// Instantiates a NativeFarCall object starting at the given instruction
	// address and returns the NativeFarCall object.
	inline NativeFarCall* nativeFarCall_at(address instr) {
	NativeFarCall* call = (NativeFarCall*)instr;
	call->verify();
	return call;
	}

	// An interface for accessing/manipulating native set_oop imm, reg instructions
	// (used to manipulate inlined data references, etc.).
	class NativeMovConstReg: public NativeInstruction {
	public:

	enum ppc_specific_constants {
	load_const_instruction_size = 20,
	load_const_from_method_toc_instruction_size = 8,
	instruction_size = 8 // Used in shared code for calls with reloc_info.
	};

	address instruction_address() const {
	return addr_at(0);
	}

	address next_instruction_address() const;

	// (The [set_]data accessor respects oop_type relocs also.)
	intptr_t data() const;

	// Patch the code stream.
	address set_data_plain(intptr_t x, CodeBlob *code);
	// Patch the code stream and oop pool.
	void set_data(intptr_t x);

	// Patch narrow oop constants. Use this also for narrow klass.
	void set_narrow_oop(narrowOop data, CodeBlob *code = NULL);

	void verify() NOT_DEBUG_RETURN;
	};

	inline NativeMovConstReg* nativeMovConstReg_at(address address) {
	NativeMovConstReg* test = (NativeMovConstReg*)address;
	test->verify();
	return test;
	}

	// The NativeJump is an abstraction for accessing/manipulating native
	// jump-anywhere instructions.
	class NativeJump: public NativeInstruction {
	public:
	// We use MacroAssembler::b64_patchable() for implementing a
	// jump-anywhere instruction.

	enum ppc_specific_constants {
	instruction_size = MacroAssembler::b64_patchable_size
	};

	// Checks whether instr points at a NativeJump instruction.
	static bool is_jump_at(address instr) {
	return MacroAssembler::is_b64_patchable_at(instr)
	\|\| ( MacroAssembler::is_load_const_from_method_toc_at(instr)
	&& Assembler::is_mtctr((int)(instr + 2 * 4))
	&& Assembler::is_bctr((int)(instr + 3 * 4)));
	}

	// Does the NativeJump implementation use a pc-relative encoding
	// of the call destination?
	// Used when relocating code or patching jumps.
	bool is_pcrelative() {
	return MacroAssembler::is_b64_patchable_pcrelative_at((address)this);
	}

	// Returns the NativeJump's destination.
	address jump_destination() const {
	if (MacroAssembler::is_b64_patchable_at((address)this)) {
	return MacroAssembler::get_dest_of_b64_patchable_at((address)this);
	} else if (MacroAssembler::is_load_const_from_method_toc_at((address)this)
	&& Assembler::is_mtctr((int)((address)this + 2 * 4))
	&& Assembler::is_bctr((int)((address)this + 3 * 4))) {
	return (address)((NativeMovConstReg *)this)->data();
	} else {
	ShouldNotReachHere();
	return NULL;
	}
	}

	// Sets the NativeJump's destination, not necessarily mt-safe.
	// Used when relocating code or patching jumps.
	void set_jump_destination(address dest) {
	// Set new destination (implementation of call may change here).
	if (MacroAssembler::is_b64_patchable_at((address)this)) {
	MacroAssembler::set_dest_of_b64_patchable_at((address)this, dest);
	} else if (MacroAssembler::is_load_const_from_method_toc_at((address)this)
	&& Assembler::is_mtctr((int)((address)this + 2 * 4))
	&& Assembler::is_bctr((int)((address)this + 3 * 4))) {
	((NativeMovConstReg *)this)->set_data((intptr_t)dest);
	} else {
	ShouldNotReachHere();
	}
	}

	// MT-safe insertion of native jump at verified method entry
	static void patch_verified_entry(address entry, address verified_entry, address dest);

	void verify() NOT_DEBUG_RETURN;

	static void check_verified_entry_alignment(address entry, address verified_entry) {
	// We just patch one instruction on ppc64, so the jump doesn't have to
	// be aligned. Nothing to do here.
	}
	};

	// Instantiates a NativeJump object starting at the given instruction
	// address and returns the NativeJump object.
	inline NativeJump* nativeJump_at(address instr) {
	NativeJump* call = (NativeJump*)instr;
	call->verify();
	return call;
	}

	// NativeConditionalFarBranch is abstraction for accessing/manipulating
	// conditional far branches.
	class NativeConditionalFarBranch : public NativeInstruction {
	public:

	static bool is_conditional_far_branch_at(address instr) {
	return MacroAssembler::is_bc_far_at(instr);
	}

	address branch_destination() const {
	return MacroAssembler::get_dest_of_bc_far_at((address)this);
	}

	void set_branch_destination(address dest) {
	MacroAssembler::set_dest_of_bc_far_at((address)this, dest);
	}
	};

	inline NativeConditionalFarBranch* NativeConditionalFarBranch_at(address address) {
	assert(NativeConditionalFarBranch::is_conditional_far_branch_at(address),
	"must be a conditional far branch");
	return (NativeConditionalFarBranch*)address;
	}

	// Call trampoline stubs.
	class NativeCallTrampolineStub : public NativeInstruction {
	private:

	address encoded_destination_addr() const;

	public:

	address destination(nmethod *nm = NULL) const;
	int destination_toc_offset() const;

	void set_destination(address new_destination);
	};

	// Note: Other stubs must not begin with this pattern.
	inline bool is_NativeCallTrampolineStub_at(address address) {
	int first_instr = (int)address;
	// calculate_address_from_global_toc and long form of ld_largeoffset_unchecked begin with addis with target R12
	if (Assembler::is_addis(first_instr) &&
	(Register)(intptr_t)Assembler::inv_rt_field(first_instr) == R12_scratch2) return true;

	// short form of ld_largeoffset_unchecked is ld which is followed by mtctr
	int second_instr = ((int)address + 1);
	if (Assembler::is_ld(first_instr) &&
	(Register)(intptr_t)Assembler::inv_rt_field(first_instr) == R12_scratch2 &&
	Assembler::is_mtctr(second_instr) &&
	(Register)(intptr_t)Assembler::inv_rs_field(second_instr) == R12_scratch2) return true;

	return false;
	}

	inline NativeCallTrampolineStub* NativeCallTrampolineStub_at(address address) {
	assert(is_NativeCallTrampolineStub_at(address), "no call trampoline found");
	return (NativeCallTrampolineStub*)address;
	}

	///////////////////////////////////////////////////////////////////////////////////////////////////

	//-------------------------------------
	// N a t i v e G e n e r a l J u m p
	//-------------------------------------

	// Despite the name, handles only simple branches.
	class NativeGeneralJump;
	inline NativeGeneralJump* nativeGeneralJump_at(address address);

	// Currently only implemented as single unconditional branch.
	class NativeGeneralJump: public NativeInstruction {
	public:

	enum PPC64_specific_constants {
	instruction_size = 4
	};

	address instruction_address() const { return addr_at(0); }

	// Creation.
	friend inline NativeGeneralJump* nativeGeneralJump_at(address addr) {
	NativeGeneralJump* jump = (NativeGeneralJump*)(addr);
	DEBUG_ONLY( jump->verify(); )
	return jump;
	}

	// Insertion of native general jump instruction.
	static void insert_unconditional(address code_pos, address entry);

	address jump_destination() const {
	DEBUG_ONLY( verify(); )
	return addr_at(0) + Assembler::inv_li_field(long_at(0));
	}

	void set_jump_destination(address dest) {
	DEBUG_ONLY( verify(); )
	insert_unconditional(addr_at(0), dest);
	}

	static void replace_mt_safe(address instr_addr, address code_buffer);

	void verify() const { guarantee(Assembler::is_b(long_at(0)), "invalid NativeGeneralJump"); }
	};

	// An interface for accessing/manipulating native load int (load_const32).
	class NativeMovRegMem;
	inline NativeMovRegMem* nativeMovRegMem_at(address address);
	class NativeMovRegMem: public NativeInstruction {
	public:

	enum PPC64_specific_constants {
	instruction_size = 8
	};

	address instruction_address() const { return addr_at(0); }

	int num_bytes_to_end_of_patch() const { return instruction_size; }

	intptr_t offset() const {
	#ifdef VM_LITTLE_ENDIAN
	short hi_ptr = (short)(addr_at(0));
	short lo_ptr = (short)(addr_at(4));
	#else
	short hi_ptr = (short)(addr_at(0) + 2);
	short lo_ptr = (short)(addr_at(4) + 2);
	#endif
	return ((hi_ptr) << 16) \| ((lo_ptr) & 0xFFFF);
	}

	void set_offset(intptr_t x) {
	#ifdef VM_LITTLE_ENDIAN
	short hi_ptr = (short)(addr_at(0));
	short lo_ptr = (short)(addr_at(4));
	#else
	short hi_ptr = (short)(addr_at(0) + 2);
	short lo_ptr = (short)(addr_at(4) + 2);
	#endif
	*hi_ptr = x >> 16;
	*lo_ptr = x & 0xFFFF;
	ICache::ppc64_flush_icache_bytes(addr_at(0), NativeMovRegMem::instruction_size);
	}

	void add_offset_in_bytes(intptr_t radd_offset) {
	set_offset(offset() + radd_offset);
	}

	void verify() const {
	guarantee(Assembler::is_lis(long_at(0)), "load_const32 1st instr");
	guarantee(Assembler::is_ori(long_at(4)), "load_const32 2nd instr");
	}

	private:
	friend inline NativeMovRegMem* nativeMovRegMem_at(address address) {
	NativeMovRegMem* test = (NativeMovRegMem*)address;
	DEBUG_ONLY( test->verify(); )
	return test;
	}
	};

	#endif // CPU_PPC_VM_NATIVEINST_PPC_HPP