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 /*

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  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.

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  * 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

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 #ifndef SHARE_VM_INTERPRETER_ABSTRACTINTERPRETER_HPP

 #define SHARE_VM_INTERPRETER_ABSTRACTINTERPRETER_HPP

 #include "code/stubs.hpp"

 #include "interpreter/bytecodes.hpp"

 #include "runtime/vmThread.hpp"

 #include "utilities/top.hpp"

 #ifdef TARGET_ARCH_MODEL_x86_32

 # include "interp_masm_x86_32.hpp"

 #endif

 #ifdef TARGET_ARCH_MODEL_x86_64

 # include "interp_masm_x86_64.hpp"

 #endif

 #ifdef TARGET_ARCH_MODEL_sparc

 # include "interp_masm_sparc.hpp"

 #endif

 #ifdef TARGET_ARCH_MODEL_zero

 # include "interp_masm_zero.hpp"

 #endif

 #ifdef TARGET_ARCH_MODEL_arm

 # include "interp_masm_arm.hpp"

 #endif

 #ifdef TARGET_ARCH_MODEL_ppc

 # include "interp_masm_ppc.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_linux

 # include "thread_linux.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_solaris

 # include "thread_solaris.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_windows

 # include "thread_windows.inline.hpp"

 #endif

 #ifdef TARGET_OS_FAMILY_bsd

 # include "thread_bsd.inline.hpp"

 #endif

 // This file contains the platform-independent parts

 // of the abstract interpreter and the abstract interpreter generator.

 // Organization of the interpreter(s). There exists two different interpreters in hotpot

 // an assembly language version (aka template interpreter) and a high level language version

 // (aka c++ interpreter). Th division of labor is as follows:

 // Template Interpreter          C++ Interpreter        Functionality

 //

 // templateTable*                bytecodeInterpreter*   actual interpretation of bytecodes

 //

 // templateInterpreter*          cppInterpreter*        generation of assembly code that creates

 //                                                      and manages interpreter runtime frames.

 //                                                      Also code for populating interpreter

 //                                                      frames created during deoptimization.

 //

 // For both template and c++ interpreter. There are common files for aspects of the interpreter

 // that are generic to both interpreters. This is the layout:

 //

 // abstractInterpreter.hpp: generic description of the interpreter.

 // interpreter*:            generic frame creation and handling.

 //

 //------------------------------------------------------------------------------------------------------------------------

 // The C++ interface to the bytecode interpreter(s).

 class AbstractInterpreter: AllStatic {

   friend class VMStructs;

   friend class Interpreter;

   friend class CppInterpreterGenerator;

  public:

   enum MethodKind {

     zerolocals,                                                 // method needs locals initialization

     zerolocals_synchronized,                                    // method needs locals initialization & is synchronized

     native,                                                     // native method

     native_synchronized,                                        // native method & is synchronized

     empty,                                                      // empty method (code: _return)

     accessor,                                                   // accessor method (code: _aload_0, _getfield, _(a|i)return)

     abstract,                                                   // abstract method (throws an AbstractMethodException)

     method_handle_invoke_FIRST,                                 // java.lang.invoke.MethodHandles::invokeExact, etc.

     method_handle_invoke_LAST                                   = (method_handle_invoke_FIRST

                                                                    + (vmIntrinsics::LAST_MH_SIG_POLY

                                                                       - vmIntrinsics::FIRST_MH_SIG_POLY)),

     java_lang_math_sin,                                         // implementation of java.lang.Math.sin   (x)

     java_lang_math_cos,                                         // implementation of java.lang.Math.cos   (x)

     java_lang_math_tan,                                         // implementation of java.lang.Math.tan   (x)

     java_lang_math_abs,                                         // implementation of java.lang.Math.abs   (x)

     java_lang_math_sqrt,                                        // implementation of java.lang.Math.sqrt  (x)

     java_lang_math_log,                                         // implementation of java.lang.Math.log   (x)

     java_lang_math_log10,                                       // implementation of java.lang.Math.log10 (x)

     java_lang_math_pow,                                         // implementation of java.lang.Math.pow   (x,y)

     java_lang_math_exp,                                         // implementation of java.lang.Math.exp   (x)

     java_lang_ref_reference_get,                                // implementation of java.lang.ref.Reference.get()

     number_of_method_entries,

     invalid = -1

   };

   // Conversion from the part of the above enum to vmIntrinsics::_invokeExact, etc.

   static vmIntrinsics::ID method_handle_intrinsic(MethodKind kind) {

     if (kind >= method_handle_invoke_FIRST && kind <= method_handle_invoke_LAST)

       return (vmIntrinsics::ID)( vmIntrinsics::FIRST_MH_SIG_POLY + (kind - method_handle_invoke_FIRST) );

     else

       return vmIntrinsics::_none;

   }

   enum SomeConstants {

     number_of_result_handlers = 10                              // number of result handlers for native calls

   };

  protected:

   static StubQueue* _code;                                      // the interpreter code (codelets)

   static bool       _notice_safepoints;                         // true if safepoints are activated

   static address    _native_entry_begin;                        // Region for native entry code

   static address    _native_entry_end;

   // method entry points

   static address    _entry_table[number_of_method_entries];     // entry points for a given method

   static address    _native_abi_to_tosca[number_of_result_handlers];  // for native method result handlers

   static address    _slow_signature_handler;                              // the native method generic (slow) signature handler

   static address    _rethrow_exception_entry;                   // rethrows an activation in previous frame

   friend class      AbstractInterpreterGenerator;

   friend class              InterpreterGenerator;

   friend class      InterpreterMacroAssembler;

  public:

   // Initialization/debugging

   static void       initialize();

   static StubQueue* code()                                      { return _code; }

   // Method activation

   static MethodKind method_kind(methodHandle m);

   static address    entry_for_kind(MethodKind k)                { assert(0 <= k && k < number_of_method_entries, "illegal kind"); return _entry_table[k]; }

   static address    entry_for_method(methodHandle m)            { return entry_for_kind(method_kind(m)); }

   // used for bootstrapping method handles:

   static void       set_entry_for_kind(MethodKind k, address e);

   static void       print_method_kind(MethodKind kind)          PRODUCT_RETURN;

   static bool       can_be_compiled(methodHandle m);

   // Runtime support

   // length = invoke bytecode length (to advance to next bytecode)

   static address    deopt_entry   (TosState state, int length) { ShouldNotReachHere(); return NULL; }

   static address    return_entry  (TosState state, int length) { ShouldNotReachHere(); return NULL; }

   static address    rethrow_exception_entry()                   { return _rethrow_exception_entry; }

   // Activation size in words for a method that is just being called.

   // Parameters haven't been pushed so count them too.

   static int        size_top_interpreter_activation(methodOop method);

   // Deoptimization support

   // Compute the entry address for continuation after

   static address deopt_continue_after_entry(methodOop method,

                                             address bcp,

                                             int callee_parameters,

                                             bool is_top_frame);

   // Compute the entry address for reexecution

   static address deopt_reexecute_entry(methodOop method, address bcp);

   // Deoptimization should reexecute this bytecode

   static bool    bytecode_should_reexecute(Bytecodes::Code code);

   // share implementation of size_activation and layout_activation:

   static int        size_activation(methodOop method,

                                     int temps,

                                     int popframe_args,

                                     int monitors,

                                     int caller_actual_parameters,

                                     int callee_params,

                                     int callee_locals,

                                     bool is_top_frame) {

     return layout_activation(method,

                              temps,

                              popframe_args,

                              monitors,

                              caller_actual_parameters,

                              callee_params,

                              callee_locals,

                              (frame*)NULL,

                              (frame*)NULL,

                              is_top_frame);

   }

   static int       layout_activation(methodOop method,

                                      int temps,

                                      int popframe_args,

                                      int monitors,

                                      int caller_actual_parameters,

                                      int callee_params,

                                      int callee_locals,

                                      frame* caller,

                                      frame* interpreter_frame,

                                      bool is_top_frame);

   // Runtime support

   static bool       is_not_reached(                       methodHandle method, int bci);

   // Safepoint support

   static void       notice_safepoints()                         { ShouldNotReachHere(); } // stops the thread when reaching a safepoint

   static void       ignore_safepoints()                         { ShouldNotReachHere(); } // ignores safepoints

   // Support for native calls

   static address    slow_signature_handler()                    { return _slow_signature_handler; }

   static address    result_handler(BasicType type)              { return _native_abi_to_tosca[BasicType_as_index(type)]; }

   static int        BasicType_as_index(BasicType type);         // computes index into result_handler_by_index table

   static bool       in_native_entry(address pc)                 { return _native_entry_begin <= pc && pc < _native_entry_end; }

   // Debugging/printing

   static void       print();                                    // prints the interpreter code

  public:

   // Interpreter helpers

   const static int stackElementWords   = 1;

   const static int stackElementSize    = stackElementWords * wordSize;

   const static int logStackElementSize = LogBytesPerWord;

   // Local values relative to locals[n]

   static int  local_offset_in_bytes(int n) {

     return ((frame::interpreter_frame_expression_stack_direction() * n) * stackElementSize);

   }

   // access to stacked values according to type:

   static oop* oop_addr_in_slot(intptr_t* slot_addr) {

     return (oop*) slot_addr;

   }

   static jint* int_addr_in_slot(intptr_t* slot_addr) {

     if ((int) sizeof(jint) < wordSize && !Bytes::is_Java_byte_ordering_different())

       // big-endian LP64

       return (jint*)(slot_addr + 1) - 1;

     else

       return (jint*) slot_addr;

   }

   static jlong long_in_slot(intptr_t* slot_addr) {

     if (sizeof(intptr_t) >= sizeof(jlong)) {

       return *(jlong*) slot_addr;

     } else {

       return Bytes::get_native_u8((address)slot_addr);

     }

   }

   static void set_long_in_slot(intptr_t* slot_addr, jlong value) {

     if (sizeof(intptr_t) >= sizeof(jlong)) {

       *(jlong*) slot_addr = value;

     } else {

       Bytes::put_native_u8((address)slot_addr, value);

     }

   }

   static void get_jvalue_in_slot(intptr_t* slot_addr, BasicType type, jvalue* value) {

     switch (type) {

     case T_BOOLEAN: value->z = *int_addr_in_slot(slot_addr);            break;

     case T_CHAR:    value->c = *int_addr_in_slot(slot_addr);            break;

     case T_BYTE:    value->b = *int_addr_in_slot(slot_addr);            break;

     case T_SHORT:   value->s = *int_addr_in_slot(slot_addr);            break;

     case T_INT:     value->i = *int_addr_in_slot(slot_addr);            break;

     case T_LONG:    value->j = long_in_slot(slot_addr);                 break;

     case T_FLOAT:   value->f = *(jfloat*)int_addr_in_slot(slot_addr);   break;

     case T_DOUBLE:  value->d = jdouble_cast(long_in_slot(slot_addr));   break;

     case T_OBJECT:  value->l = (jobject)*oop_addr_in_slot(slot_addr);   break;

     default:        ShouldNotReachHere();

     }

   }

   static void set_jvalue_in_slot(intptr_t* slot_addr, BasicType type, jvalue* value) {

     switch (type) {

     case T_BOOLEAN: *int_addr_in_slot(slot_addr) = (value->z != 0);     break;

     case T_CHAR:    *int_addr_in_slot(slot_addr) = value->c;            break;

     case T_BYTE:    *int_addr_in_slot(slot_addr) = value->b;            break;

     case T_SHORT:   *int_addr_in_slot(slot_addr) = value->s;            break;

     case T_INT:     *int_addr_in_slot(slot_addr) = value->i;            break;

     case T_LONG:    set_long_in_slot(slot_addr, value->j);              break;

     case T_FLOAT:   *(jfloat*)int_addr_in_slot(slot_addr) = value->f;   break;

     case T_DOUBLE:  set_long_in_slot(slot_addr, jlong_cast(value->d));  break;

     case T_OBJECT:  *oop_addr_in_slot(slot_addr) = (oop) value->l;      break;

     default:        ShouldNotReachHere();

     }

   }

 };

 //------------------------------------------------------------------------------------------------------------------------

 // The interpreter generator.

 class Template;

 class AbstractInterpreterGenerator: public StackObj {

  protected:

   InterpreterMacroAssembler* _masm;

   // shared code sequences

   // Converter for native abi result to tosca result

   address generate_result_handler_for(BasicType type);

   address generate_slow_signature_handler();

   // entry point generator

   address generate_method_entry(AbstractInterpreter::MethodKind kind);

   void bang_stack_shadow_pages(bool native_call);

   void generate_all();

  public:

   AbstractInterpreterGenerator(StubQueue* _code);

 };

 #endif // SHARE_VM_INTERPRETER_ABSTRACTINTERPRETER_HPP