src/share/vm/asm/assembler.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1997, 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.
  *
  */

 #ifndef SHARE_VM_ASM_ASSEMBLER_HPP
 #define SHARE_VM_ASM_ASSEMBLER_HPP

 #include "asm/codeBuffer.hpp"
 #include "code/oopRecorder.hpp"
 #include "code/relocInfo.hpp"
 #include "memory/allocation.hpp"
 #include "utilities/debug.hpp"
 #include "utilities/growableArray.hpp"
 #include "utilities/top.hpp"

 #ifdef TARGET_ARCH_x86
 # include "register_x86.hpp"
 # include "vm_version_x86.hpp"
 #endif
 #ifdef TARGET_ARCH_sparc
 # include "register_sparc.hpp"
 # include "vm_version_sparc.hpp"
 #endif
 #ifdef TARGET_ARCH_zero
 # include "register_zero.hpp"
 # include "vm_version_zero.hpp"
 #endif
 #ifdef TARGET_ARCH_arm
 # include "register_arm.hpp"
 # include "vm_version_arm.hpp"
 #endif
 #ifdef TARGET_ARCH_ppc
 # include "register_ppc.hpp"
 # include "vm_version_ppc.hpp"
 #endif

 // This file contains platform-independent assembler declarations.

 class MacroAssembler;
 class AbstractAssembler;
 class Label;

 /**
  * Labels represent destinations for control transfer instructions.  Such
  * instructions can accept a Label as their target argument.  A Label is
  * bound to the current location in the code stream by calling the
  * MacroAssembler's 'bind' method, which in turn calls the Label's 'bind'
  * method.  A Label may be referenced by an instruction before it's bound
  * (i.e., 'forward referenced').  'bind' stores the current code offset
  * in the Label object.
  *
  * If an instruction references a bound Label, the offset field(s) within
  * the instruction are immediately filled in based on the Label's code
  * offset.  If an instruction references an unbound label, that
  * instruction is put on a list of instructions that must be patched
  * (i.e., 'resolved') when the Label is bound.
  *
  * 'bind' will call the platform-specific 'patch_instruction' method to
  * fill in the offset field(s) for each unresolved instruction (if there
  * are any).  'patch_instruction' lives in one of the
  * cpu/<arch>/vm/assembler_<arch>* files.
  *
  * Instead of using a linked list of unresolved instructions, a Label has
  * an array of unresolved instruction code offsets.  _patch_index
  * contains the total number of forward references.  If the Label's array
  * overflows (i.e., _patch_index grows larger than the array size), a
  * GrowableArray is allocated to hold the remaining offsets.  (The cache
  * size is 4 for now, which handles over 99.5% of the cases)
  *
  * Labels may only be used within a single CodeSection.  If you need
  * to create references between code sections, use explicit relocations.
  */
 class Label VALUE_OBJ_CLASS_SPEC {
  private:
   enum { PatchCacheSize = 4 };

   // _loc encodes both the binding state (via its sign)
   // and the binding locator (via its value) of a label.
   //
   // _loc >= 0   bound label, loc() encodes the target (jump) position
   // _loc == -1  unbound label
   int _loc;

   // References to instructions that jump to this unresolved label.
   // These instructions need to be patched when the label is bound
   // using the platform-specific patchInstruction() method.
   //
   // To avoid having to allocate from the C-heap each time, we provide
   // a local cache and use the overflow only if we exceed the local cache
   int _patches[PatchCacheSize];
   int _patch_index;
   GrowableArray<int>* _patch_overflow;

   Label(const Label&) { ShouldNotReachHere(); }

  public:

   /**
    * After binding, be sure 'patch_instructions' is called later to link
    */
   void bind_loc(int loc) {
     assert(loc >= 0, "illegal locator");
     assert(_loc == -1, "already bound");
     _loc = loc;
   }
   void bind_loc(int pos, int sect) { bind_loc(CodeBuffer::locator(pos, sect)); }

 #ifndef PRODUCT
   // Iterates over all unresolved instructions for printing
   void print_instructions(MacroAssembler* masm) const;
 #endif // PRODUCT

   /**
    * Returns the position of the the Label in the code buffer
    * The position is a 'locator', which encodes both offset and section.
    */
   int loc() const {
     assert(_loc >= 0, "unbound label");
     return _loc;
   }
   int loc_pos()  const { return CodeBuffer::locator_pos(loc()); }
   int loc_sect() const { return CodeBuffer::locator_sect(loc()); }

   bool is_bound() const    { return _loc >=  0; }
   bool is_unbound() const  { return _loc == -1 && _patch_index > 0; }
   bool is_unused() const   { return _loc == -1 && _patch_index == 0; }

   /**
    * Adds a reference to an unresolved displacement instruction to
    * this unbound label
    *
    * @param cb         the code buffer being patched
    * @param branch_loc the locator of the branch instruction in the code buffer
    */
   void add_patch_at(CodeBuffer* cb, int branch_loc);

   /**
    * Iterate over the list of patches, resolving the instructions
    * Call patch_instruction on each 'branch_loc' value
    */
   void patch_instructions(MacroAssembler* masm);

   void init() {
     _loc = -1;
     _patch_index = 0;
     _patch_overflow = NULL;
   }

   Label() {
     init();
   }
 };

 // A union type for code which has to assemble both constant and
 // non-constant operands, when the distinction cannot be made
 // statically.
 class RegisterOrConstant VALUE_OBJ_CLASS_SPEC {
  private:
   Register _r;
   intptr_t _c;

  public:
   RegisterOrConstant(): _r(noreg), _c(0) {}
   RegisterOrConstant(Register r): _r(r), _c(0) {}
   RegisterOrConstant(intptr_t c): _r(noreg), _c(c) {}

   Register as_register() const { assert(is_register(),""); return _r; }
   intptr_t as_constant() const { assert(is_constant(),""); return _c; }

   Register register_or_noreg() const { return _r; }
   intptr_t constant_or_zero() const  { return _c; }

   bool is_register() const { return _r != noreg; }
   bool is_constant() const { return _r == noreg; }
 };

 // The Abstract Assembler: Pure assembler doing NO optimizations on the
 // instruction level; i.e., what you write is what you get.
 // The Assembler is generating code into a CodeBuffer.
 class AbstractAssembler : public ResourceObj  {
   friend class Label;

  protected:
   CodeSection* _code_section;          // section within the code buffer
   OopRecorder* _oop_recorder;          // support for relocInfo::oop_type

  public:
   // Code emission & accessing
   address addr_at(int pos) const { return code_section()->start() + pos; }

  protected:
   // This routine is called with a label is used for an address.
   // Labels and displacements truck in offsets, but target must return a PC.
   address target(Label& L)             { return code_section()->target(L, pc()); }

   bool is8bit(int x) const             { return -0x80 <= x && x < 0x80; }
   bool isByte(int x) const             { return 0 <= x && x < 0x100; }
   bool isShiftCount(int x) const       { return 0 <= x && x < 32; }

   // Instruction boundaries (required when emitting relocatable values).
   class InstructionMark: public StackObj {
    private:
     AbstractAssembler* _assm;

    public:
     InstructionMark(AbstractAssembler* assm) : _assm(assm) {
       assert(assm->inst_mark() == NULL, "overlapping instructions");
       _assm->set_inst_mark();
     }
     ~InstructionMark() {
       _assm->clear_inst_mark();
     }
   };
   friend class InstructionMark;
 #ifdef ASSERT
   // Make it return true on platforms which need to verify
   // instruction boundaries for some operations.
   static bool pd_check_instruction_mark();

   // Add delta to short branch distance to verify that it still fit into imm8.
   int _short_branch_delta;

   int  short_branch_delta() const { return _short_branch_delta; }
   void set_short_branch_delta()   { _short_branch_delta = 32; }
   void clear_short_branch_delta() { _short_branch_delta = 0; }

   class ShortBranchVerifier: public StackObj {
    private:
     AbstractAssembler* _assm;

    public:
     ShortBranchVerifier(AbstractAssembler* assm) : _assm(assm) {
       assert(assm->short_branch_delta() == 0, "overlapping instructions");
       _assm->set_short_branch_delta();
     }
     ~ShortBranchVerifier() {
       _assm->clear_short_branch_delta();
     }
   };
 #else
   // Dummy in product.
   class ShortBranchVerifier: public StackObj {
    public:
     ShortBranchVerifier(AbstractAssembler* assm) {}
   };
 #endif

  public:

   // Creation
   AbstractAssembler(CodeBuffer* code);

   // ensure buf contains all code (call this before using/copying the code)
   void flush();

   void emit_int8(   int8_t  x) { code_section()->emit_int8(   x); }
   void emit_int16(  int16_t x) { code_section()->emit_int16(  x); }
   void emit_int32(  int32_t x) { code_section()->emit_int32(  x); }
   void emit_int64(  int64_t x) { code_section()->emit_int64(  x); }

   void emit_float(  jfloat  x) { code_section()->emit_float(  x); }
   void emit_double( jdouble x) { code_section()->emit_double( x); }
   void emit_address(address x) { code_section()->emit_address(x); }

   // min and max values for signed immediate ranges
   static int min_simm(int nbits) { return -(intptr_t(1) << (nbits - 1))    ; }
   static int max_simm(int nbits) { return  (intptr_t(1) << (nbits - 1)) - 1; }

   // Define some:
   static int min_simm10() { return min_simm(10); }
   static int min_simm13() { return min_simm(13); }
   static int min_simm16() { return min_simm(16); }

   // Test if x is within signed immediate range for nbits
   static bool is_simm(intptr_t x, int nbits) { return min_simm(nbits) <= x && x <= max_simm(nbits); }

   // Define some:
   static bool is_simm5( intptr_t x) { return is_simm(x, 5 ); }
   static bool is_simm8( intptr_t x) { return is_simm(x, 8 ); }
   static bool is_simm10(intptr_t x) { return is_simm(x, 10); }
   static bool is_simm11(intptr_t x) { return is_simm(x, 11); }
   static bool is_simm12(intptr_t x) { return is_simm(x, 12); }
   static bool is_simm13(intptr_t x) { return is_simm(x, 13); }
   static bool is_simm16(intptr_t x) { return is_simm(x, 16); }
   static bool is_simm26(intptr_t x) { return is_simm(x, 26); }
   static bool is_simm32(intptr_t x) { return is_simm(x, 32); }

   // Accessors
   CodeSection*  code_section() const   { return _code_section; }
   CodeBuffer*   code()         const   { return code_section()->outer(); }
   int           sect()         const   { return code_section()->index(); }
   address       pc()           const   { return code_section()->end();   }
   int           offset()       const   { return code_section()->size();  }
   int           locator()      const   { return CodeBuffer::locator(offset(), sect()); }

   OopRecorder*  oop_recorder() const   { return _oop_recorder; }
   void      set_oop_recorder(OopRecorder* r) { _oop_recorder = r; }

   address       inst_mark() const { return code_section()->mark();       }
   void      set_inst_mark()       {        code_section()->set_mark();   }
   void    clear_inst_mark()       {        code_section()->clear_mark(); }

   // Constants in code
   void relocate(RelocationHolder const& rspec, int format = 0) {
     assert(!pd_check_instruction_mark()
         || inst_mark() == NULL || inst_mark() == code_section()->end(),
         "call relocate() between instructions");
     code_section()->relocate(code_section()->end(), rspec, format);
   }
   void relocate(   relocInfo::relocType rtype, int format = 0) {
     code_section()->relocate(code_section()->end(), rtype, format);
   }

   static int code_fill_byte();         // used to pad out odd-sized code buffers

   // Associate a comment with the current offset.  It will be printed
   // along with the disassembly when printing nmethods.  Currently
   // only supported in the instruction section of the code buffer.
   void block_comment(const char* comment);
   // Copy str to a buffer that has the same lifetime as the CodeBuffer
   const char* code_string(const char* str);

   // Label functions
   void bind(Label& L); // binds an unbound label L to the current code position

   // Move to a different section in the same code buffer.
   void set_code_section(CodeSection* cs);

   // Inform assembler when generating stub code and relocation info
   address    start_a_stub(int required_space);
   void       end_a_stub();
   // Ditto for constants.
   address    start_a_const(int required_space, int required_align = sizeof(double));
   void       end_a_const(CodeSection* cs);  // Pass the codesection to continue in (insts or stubs?).

   // constants support
   //
   // We must remember the code section (insts or stubs) in c1
   // so we can reset to the proper section in end_a_const().
   address long_constant(jlong c) {
     CodeSection* c1 = _code_section;
     address ptr = start_a_const(sizeof(c), sizeof(c));
     if (ptr != NULL) {
       emit_int64(c);
       end_a_const(c1);
     }
     return ptr;
   }
   address double_constant(jdouble c) {
     CodeSection* c1 = _code_section;
     address ptr = start_a_const(sizeof(c), sizeof(c));
     if (ptr != NULL) {
       emit_double(c);
       end_a_const(c1);
     }
     return ptr;
   }
   address float_constant(jfloat c) {
     CodeSection* c1 = _code_section;
     address ptr = start_a_const(sizeof(c), sizeof(c));
     if (ptr != NULL) {
       emit_float(c);
       end_a_const(c1);
     }
     return ptr;
   }
   address address_constant(address c) {
     CodeSection* c1 = _code_section;
     address ptr = start_a_const(sizeof(c), sizeof(c));
     if (ptr != NULL) {
       emit_address(c);
       end_a_const(c1);
     }
     return ptr;
   }
   address address_constant(address c, RelocationHolder const& rspec) {
     CodeSection* c1 = _code_section;
     address ptr = start_a_const(sizeof(c), sizeof(c));
     if (ptr != NULL) {
       relocate(rspec);
       emit_address(c);
       end_a_const(c1);
     }
     return ptr;
   }

   // Bootstrapping aid to cope with delayed determination of constants.
   // Returns a static address which will eventually contain the constant.
   // The value zero (NULL) stands instead of a constant which is still uncomputed.
   // Thus, the eventual value of the constant must not be zero.
   // This is fine, since this is designed for embedding object field
   // offsets in code which must be generated before the object class is loaded.
   // Field offsets are never zero, since an object's header (mark word)
   // is located at offset zero.
   RegisterOrConstant delayed_value(int(*value_fn)(), Register tmp, int offset = 0);
   RegisterOrConstant delayed_value(address(*value_fn)(), Register tmp, int offset = 0);
   virtual RegisterOrConstant delayed_value_impl(intptr_t* delayed_value_addr, Register tmp, int offset) = 0;
   // Last overloading is platform-dependent; look in assembler_<arch>.cpp.
   static intptr_t* delayed_value_addr(int(*constant_fn)());
   static intptr_t* delayed_value_addr(address(*constant_fn)());
   static void update_delayed_values();

   // Bang stack to trigger StackOverflowError at a safe location
   // implementation delegates to machine-specific bang_stack_with_offset
   void generate_stack_overflow_check( int frame_size_in_bytes );
   virtual void bang_stack_with_offset(int offset) = 0;


   /**
    * A platform-dependent method to patch a jump instruction that refers
    * to this label.
    *
    * @param branch the location of the instruction to patch
    * @param masm the assembler which generated the branch
    */
   void pd_patch_instruction(address branch, address target);

 };

 #ifdef TARGET_ARCH_x86
 # include "assembler_x86.hpp"
 #endif
 #ifdef TARGET_ARCH_sparc
 # include "assembler_sparc.hpp"
 #endif
 #ifdef TARGET_ARCH_zero
 # include "assembler_zero.hpp"
 #endif
 #ifdef TARGET_ARCH_arm
 # include "assembler_arm.hpp"
 #endif
 #ifdef TARGET_ARCH_ppc
 # include "assembler_ppc.hpp"
 #endif


 #endif // SHARE_VM_ASM_ASSEMBLER_HPP
	/*
	* Copyright (c) 1997, 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.
	*
	*/

	#ifndef SHARE_VM_ASM_ASSEMBLER_HPP
	#define SHARE_VM_ASM_ASSEMBLER_HPP

	#include "asm/codeBuffer.hpp"
	#include "code/oopRecorder.hpp"
	#include "code/relocInfo.hpp"
	#include "memory/allocation.hpp"
	#include "utilities/debug.hpp"
	#include "utilities/growableArray.hpp"
	#include "utilities/top.hpp"

	#ifdef TARGET_ARCH_x86
	# include "register_x86.hpp"
	# include "vm_version_x86.hpp"
	#endif
	#ifdef TARGET_ARCH_sparc
	# include "register_sparc.hpp"
	# include "vm_version_sparc.hpp"
	#endif
	#ifdef TARGET_ARCH_zero
	# include "register_zero.hpp"
	# include "vm_version_zero.hpp"
	#endif
	#ifdef TARGET_ARCH_arm
	# include "register_arm.hpp"
	# include "vm_version_arm.hpp"
	#endif
	#ifdef TARGET_ARCH_ppc
	# include "register_ppc.hpp"
	# include "vm_version_ppc.hpp"
	#endif

	// This file contains platform-independent assembler declarations.

	class MacroAssembler;
	class AbstractAssembler;
	class Label;

	/**
	* Labels represent destinations for control transfer instructions. Such
	* instructions can accept a Label as their target argument. A Label is
	* bound to the current location in the code stream by calling the
	* MacroAssembler's 'bind' method, which in turn calls the Label's 'bind'
	* method. A Label may be referenced by an instruction before it's bound
	* (i.e., 'forward referenced'). 'bind' stores the current code offset
	* in the Label object.
	*
	* If an instruction references a bound Label, the offset field(s) within
	* the instruction are immediately filled in based on the Label's code
	* offset. If an instruction references an unbound label, that
	* instruction is put on a list of instructions that must be patched
	* (i.e., 'resolved') when the Label is bound.
	*
	* 'bind' will call the platform-specific 'patch_instruction' method to
	* fill in the offset field(s) for each unresolved instruction (if there
	* are any). 'patch_instruction' lives in one of the
	* cpu/<arch>/vm/assembler_<arch>* files.
	*
	* Instead of using a linked list of unresolved instructions, a Label has
	* an array of unresolved instruction code offsets. _patch_index
	* contains the total number of forward references. If the Label's array
	* overflows (i.e., _patch_index grows larger than the array size), a
	* GrowableArray is allocated to hold the remaining offsets. (The cache
	* size is 4 for now, which handles over 99.5% of the cases)
	*
	* Labels may only be used within a single CodeSection. If you need
	* to create references between code sections, use explicit relocations.
	*/
	class Label VALUE_OBJ_CLASS_SPEC {
	private:
	enum { PatchCacheSize = 4 };

	// _loc encodes both the binding state (via its sign)
	// and the binding locator (via its value) of a label.
	//
	// _loc >= 0 bound label, loc() encodes the target (jump) position
	// _loc == -1 unbound label
	int _loc;

	// References to instructions that jump to this unresolved label.
	// These instructions need to be patched when the label is bound
	// using the platform-specific patchInstruction() method.
	//
	// To avoid having to allocate from the C-heap each time, we provide
	// a local cache and use the overflow only if we exceed the local cache
	int _patches[PatchCacheSize];
	int _patch_index;
	GrowableArray<int>* _patch_overflow;

	Label(const Label&) { ShouldNotReachHere(); }

	public:

	/**
	* After binding, be sure 'patch_instructions' is called later to link
	*/
	void bind_loc(int loc) {
	assert(loc >= 0, "illegal locator");
	assert(_loc == -1, "already bound");
	_loc = loc;
	}
	void bind_loc(int pos, int sect) { bind_loc(CodeBuffer::locator(pos, sect)); }

	#ifndef PRODUCT
	// Iterates over all unresolved instructions for printing
	void print_instructions(MacroAssembler* masm) const;
	#endif // PRODUCT

	/**
	* Returns the position of the the Label in the code buffer
	* The position is a 'locator', which encodes both offset and section.
	*/
	int loc() const {
	assert(_loc >= 0, "unbound label");
	return _loc;
	}
	int loc_pos() const { return CodeBuffer::locator_pos(loc()); }
	int loc_sect() const { return CodeBuffer::locator_sect(loc()); }

	bool is_bound() const { return _loc >= 0; }
	bool is_unbound() const { return _loc == -1 && _patch_index > 0; }
	bool is_unused() const { return _loc == -1 && _patch_index == 0; }

	/**
	* Adds a reference to an unresolved displacement instruction to
	* this unbound label
	*
	* @param cb the code buffer being patched
	* @param branch_loc the locator of the branch instruction in the code buffer
	*/
	void add_patch_at(CodeBuffer* cb, int branch_loc);

	/**
	* Iterate over the list of patches, resolving the instructions
	* Call patch_instruction on each 'branch_loc' value
	*/
	void patch_instructions(MacroAssembler* masm);

	void init() {
	_loc = -1;
	_patch_index = 0;
	_patch_overflow = NULL;
	}

	Label() {
	init();
	}
	};

	// A union type for code which has to assemble both constant and
	// non-constant operands, when the distinction cannot be made
	// statically.
	class RegisterOrConstant VALUE_OBJ_CLASS_SPEC {
	private:
	Register _r;
	intptr_t _c;

	public:
	RegisterOrConstant(): _r(noreg), _c(0) {}
	RegisterOrConstant(Register r): _r(r), _c(0) {}
	RegisterOrConstant(intptr_t c): _r(noreg), _c(c) {}

	Register as_register() const { assert(is_register(),""); return _r; }
	intptr_t as_constant() const { assert(is_constant(),""); return _c; }

	Register register_or_noreg() const { return _r; }
	intptr_t constant_or_zero() const { return _c; }

	bool is_register() const { return _r != noreg; }
	bool is_constant() const { return _r == noreg; }
	};

	// The Abstract Assembler: Pure assembler doing NO optimizations on the
	// instruction level; i.e., what you write is what you get.
	// The Assembler is generating code into a CodeBuffer.
	class AbstractAssembler : public ResourceObj {
	friend class Label;

	protected:
	CodeSection* _code_section; // section within the code buffer
	OopRecorder* _oop_recorder; // support for relocInfo::oop_type

	public:
	// Code emission & accessing
	address addr_at(int pos) const { return code_section()->start() + pos; }

	protected:
	// This routine is called with a label is used for an address.
	// Labels and displacements truck in offsets, but target must return a PC.
	address target(Label& L) { return code_section()->target(L, pc()); }

	bool is8bit(int x) const { return -0x80 <= x && x < 0x80; }
	bool isByte(int x) const { return 0 <= x && x < 0x100; }
	bool isShiftCount(int x) const { return 0 <= x && x < 32; }

	// Instruction boundaries (required when emitting relocatable values).
	class InstructionMark: public StackObj {
	private:
	AbstractAssembler* _assm;

	public:
	InstructionMark(AbstractAssembler* assm) : _assm(assm) {
	assert(assm->inst_mark() == NULL, "overlapping instructions");
	_assm->set_inst_mark();
	}
	~InstructionMark() {
	_assm->clear_inst_mark();
	}
	};
	friend class InstructionMark;
	#ifdef ASSERT
	// Make it return true on platforms which need to verify
	// instruction boundaries for some operations.
	static bool pd_check_instruction_mark();

	// Add delta to short branch distance to verify that it still fit into imm8.
	int _short_branch_delta;

	int short_branch_delta() const { return _short_branch_delta; }
	void set_short_branch_delta() { _short_branch_delta = 32; }
	void clear_short_branch_delta() { _short_branch_delta = 0; }

	class ShortBranchVerifier: public StackObj {
	private:
	AbstractAssembler* _assm;

	public:
	ShortBranchVerifier(AbstractAssembler* assm) : _assm(assm) {
	assert(assm->short_branch_delta() == 0, "overlapping instructions");
	_assm->set_short_branch_delta();
	}
	~ShortBranchVerifier() {
	_assm->clear_short_branch_delta();
	}
	};
	#else
	// Dummy in product.
	class ShortBranchVerifier: public StackObj {
	public:
	ShortBranchVerifier(AbstractAssembler* assm) {}
	};
	#endif

	public:

	// Creation
	AbstractAssembler(CodeBuffer* code);

	// ensure buf contains all code (call this before using/copying the code)
	void flush();

	void emit_int8( int8_t x) { code_section()->emit_int8( x); }
	void emit_int16( int16_t x) { code_section()->emit_int16( x); }
	void emit_int32( int32_t x) { code_section()->emit_int32( x); }
	void emit_int64( int64_t x) { code_section()->emit_int64( x); }

	void emit_float( jfloat x) { code_section()->emit_float( x); }
	void emit_double( jdouble x) { code_section()->emit_double( x); }
	void emit_address(address x) { code_section()->emit_address(x); }

	// min and max values for signed immediate ranges
	static int min_simm(int nbits) { return -(intptr_t(1) << (nbits - 1)) ; }
	static int max_simm(int nbits) { return (intptr_t(1) << (nbits - 1)) - 1; }

	// Define some:
	static int min_simm10() { return min_simm(10); }
	static int min_simm13() { return min_simm(13); }
	static int min_simm16() { return min_simm(16); }

	// Test if x is within signed immediate range for nbits
	static bool is_simm(intptr_t x, int nbits) { return min_simm(nbits) <= x && x <= max_simm(nbits); }

	// Define some:
	static bool is_simm5( intptr_t x) { return is_simm(x, 5 ); }
	static bool is_simm8( intptr_t x) { return is_simm(x, 8 ); }
	static bool is_simm10(intptr_t x) { return is_simm(x, 10); }
	static bool is_simm11(intptr_t x) { return is_simm(x, 11); }
	static bool is_simm12(intptr_t x) { return is_simm(x, 12); }
	static bool is_simm13(intptr_t x) { return is_simm(x, 13); }
	static bool is_simm16(intptr_t x) { return is_simm(x, 16); }
	static bool is_simm26(intptr_t x) { return is_simm(x, 26); }
	static bool is_simm32(intptr_t x) { return is_simm(x, 32); }

	// Accessors
	CodeSection* code_section() const { return _code_section; }
	CodeBuffer* code() const { return code_section()->outer(); }
	int sect() const { return code_section()->index(); }
	address pc() const { return code_section()->end(); }
	int offset() const { return code_section()->size(); }
	int locator() const { return CodeBuffer::locator(offset(), sect()); }

	OopRecorder* oop_recorder() const { return _oop_recorder; }
	void set_oop_recorder(OopRecorder* r) { _oop_recorder = r; }

	address inst_mark() const { return code_section()->mark(); }
	void set_inst_mark() { code_section()->set_mark(); }
	void clear_inst_mark() { code_section()->clear_mark(); }

	// Constants in code
	void relocate(RelocationHolder const& rspec, int format = 0) {
	assert(!pd_check_instruction_mark()
	\|\| inst_mark() == NULL \|\| inst_mark() == code_section()->end(),
	"call relocate() between instructions");
	code_section()->relocate(code_section()->end(), rspec, format);
	}
	void relocate( relocInfo::relocType rtype, int format = 0) {
	code_section()->relocate(code_section()->end(), rtype, format);
	}

	static int code_fill_byte(); // used to pad out odd-sized code buffers

	// Associate a comment with the current offset. It will be printed
	// along with the disassembly when printing nmethods. Currently
	// only supported in the instruction section of the code buffer.
	void block_comment(const char* comment);
	// Copy str to a buffer that has the same lifetime as the CodeBuffer
	const char* code_string(const char* str);

	// Label functions
	void bind(Label& L); // binds an unbound label L to the current code position

	// Move to a different section in the same code buffer.
	void set_code_section(CodeSection* cs);

	// Inform assembler when generating stub code and relocation info
	address start_a_stub(int required_space);
	void end_a_stub();
	// Ditto for constants.
	address start_a_const(int required_space, int required_align = sizeof(double));
	void end_a_const(CodeSection* cs); // Pass the codesection to continue in (insts or stubs?).

	// constants support
	//
	// We must remember the code section (insts or stubs) in c1
	// so we can reset to the proper section in end_a_const().
	address long_constant(jlong c) {
	CodeSection* c1 = _code_section;
	address ptr = start_a_const(sizeof(c), sizeof(c));
	if (ptr != NULL) {
	emit_int64(c);
	end_a_const(c1);
	}
	return ptr;
	}
	address double_constant(jdouble c) {
	CodeSection* c1 = _code_section;
	address ptr = start_a_const(sizeof(c), sizeof(c));
	if (ptr != NULL) {
	emit_double(c);
	end_a_const(c1);
	}
	return ptr;
	}
	address float_constant(jfloat c) {
	CodeSection* c1 = _code_section;
	address ptr = start_a_const(sizeof(c), sizeof(c));
	if (ptr != NULL) {
	emit_float(c);
	end_a_const(c1);
	}
	return ptr;
	}
	address address_constant(address c) {
	CodeSection* c1 = _code_section;
	address ptr = start_a_const(sizeof(c), sizeof(c));
	if (ptr != NULL) {
	emit_address(c);
	end_a_const(c1);
	}
	return ptr;
	}
	address address_constant(address c, RelocationHolder const& rspec) {
	CodeSection* c1 = _code_section;
	address ptr = start_a_const(sizeof(c), sizeof(c));
	if (ptr != NULL) {
	relocate(rspec);
	emit_address(c);
	end_a_const(c1);
	}
	return ptr;
	}

	// Bootstrapping aid to cope with delayed determination of constants.
	// Returns a static address which will eventually contain the constant.
	// The value zero (NULL) stands instead of a constant which is still uncomputed.
	// Thus, the eventual value of the constant must not be zero.
	// This is fine, since this is designed for embedding object field
	// offsets in code which must be generated before the object class is loaded.
	// Field offsets are never zero, since an object's header (mark word)
	// is located at offset zero.
	RegisterOrConstant delayed_value(int(*value_fn)(), Register tmp, int offset = 0);
	RegisterOrConstant delayed_value(address(*value_fn)(), Register tmp, int offset = 0);
	virtual RegisterOrConstant delayed_value_impl(intptr_t* delayed_value_addr, Register tmp, int offset) = 0;
	// Last overloading is platform-dependent; look in assembler_<arch>.cpp.
	static intptr_t* delayed_value_addr(int(*constant_fn)());
	static intptr_t* delayed_value_addr(address(*constant_fn)());
	static void update_delayed_values();

	// Bang stack to trigger StackOverflowError at a safe location
	// implementation delegates to machine-specific bang_stack_with_offset
	void generate_stack_overflow_check( int frame_size_in_bytes );
	virtual void bang_stack_with_offset(int offset) = 0;


	/**
	* A platform-dependent method to patch a jump instruction that refers
	* to this label.
	*
	* @param branch the location of the instruction to patch
	* @param masm the assembler which generated the branch
	*/
	void pd_patch_instruction(address branch, address target);

	};

	#ifdef TARGET_ARCH_x86
	# include "assembler_x86.hpp"
	#endif
	#ifdef TARGET_ARCH_sparc
	# include "assembler_sparc.hpp"
	#endif
	#ifdef TARGET_ARCH_zero
	# include "assembler_zero.hpp"
	#endif
	#ifdef TARGET_ARCH_arm
	# include "assembler_arm.hpp"
	#endif
	#ifdef TARGET_ARCH_ppc
	# include "assembler_ppc.hpp"
	#endif


	#endif // SHARE_VM_ASM_ASSEMBLER_HPP