src/share/vm/ci/ciStreams.hpp - 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.
  *
  */

 #ifndef SHARE_VM_CI_CISTREAMS_HPP
 #define SHARE_VM_CI_CISTREAMS_HPP

 #include "ci/ciClassList.hpp"
 #include "ci/ciExceptionHandler.hpp"
 #include "ci/ciInstanceKlass.hpp"
 #include "ci/ciMethod.hpp"
 #include "interpreter/bytecode.hpp"

 // ciBytecodeStream
 //
 // The class is used to iterate over the bytecodes of a method.
 // It hides the details of constant pool structure/access by
 // providing accessors for constant pool items.  It returns only pure
 // Java bytecodes; VM-internal _fast bytecodes are translated back to
 // their original form during iteration.
 class ciBytecodeStream : StackObj {
 private:
   // Handling for the weird bytecodes
   Bytecodes::Code next_wide_or_table(Bytecodes::Code); // Handle _wide & complicated inline table

   static Bytecodes::Code check_java(Bytecodes::Code c) {
     assert(Bytecodes::is_java_code(c), "should not return _fast bytecodes");
     return c;
   }

   static Bytecodes::Code check_defined(Bytecodes::Code c) {
     assert(Bytecodes::is_defined(c), "");
     return c;
   }

   ciMethod* _method;           // the method
   ciInstanceKlass* _holder;
   address _bc_start;            // Start of current bytecode for table
   address _was_wide;            // Address past last wide bytecode
   jint* _table_base;            // Aligned start of last table or switch

   address _start;                  // Start of bytecodes
   address _end;                    // Past end of bytecodes
   address _pc;                     // Current PC
   Bytecodes::Code _bc;             // Current bytecode
   Bytecodes::Code _raw_bc;         // Current bytecode, raw form

   void reset( address base, unsigned int size ) {
     _bc_start =_was_wide = 0;
     _start = _pc = base; _end = base + size;
   }

   void assert_wide(bool require_wide) const {
     if (require_wide)
          { assert(is_wide(),  "must be a wide instruction"); }
     else { assert(!is_wide(), "must not be a wide instruction"); }
   }

   Bytecode bytecode() const { return Bytecode(this, _bc_start); }
   Bytecode next_bytecode() const { return Bytecode(this, _pc); }

 public:
   // End-Of-Bytecodes
   static Bytecodes::Code EOBC() {
     return Bytecodes::_illegal;
   }

   ciBytecodeStream(ciMethod* m) {
     reset_to_method(m);
   }

   ciBytecodeStream() {
     reset_to_method(NULL);
   }

   ciMethod* method() const { return _method; }

   void reset_to_method(ciMethod* m) {
     _method = m;
     if (m == NULL) {
       _holder = NULL;
       reset(NULL, 0);
     } else {
       _holder = m->holder();
       reset(m->code(), m->code_size());
     }
   }

   void reset_to_bci( int bci );

   // Force the iterator to report a certain bci.
   void force_bci(int bci);

   void set_max_bci( int max ) {
     _end = _start + max;
   }

   address cur_bcp() const       { return _bc_start; }  // Returns bcp to current instruction
   int next_bci() const          { return _pc - _start; }
   int cur_bci() const           { return _bc_start - _start; }
   int instruction_size() const  { return _pc - _bc_start; }

   Bytecodes::Code cur_bc() const{ return check_java(_bc); }
   Bytecodes::Code cur_bc_raw() const { return check_defined(_raw_bc); }
   Bytecodes::Code next_bc()     { return Bytecodes::java_code((Bytecodes::Code)* _pc); }

   // Return current ByteCode and increment PC to next bytecode, skipping all
   // intermediate constants.  Returns EOBC at end.
   // Expected usage:
   //     ciBytecodeStream iter(m);
   //     while (iter.next() != ciBytecodeStream::EOBC()) { ... }
   Bytecodes::Code next() {
     _bc_start = _pc;                        // Capture start of bc
     if( _pc >= _end ) return EOBC();        // End-Of-Bytecodes

     // Fetch Java bytecode
     // All rewritten bytecodes maintain the size of original bytecode.
     _bc = Bytecodes::java_code(_raw_bc = (Bytecodes::Code)*_pc);
     int csize = Bytecodes::length_for(_bc); // Expected size
     _pc += csize;                           // Bump PC past bytecode
     if (csize == 0) {
       _bc = next_wide_or_table(_bc);
     }
     return check_java(_bc);
   }

   bool is_wide() const { return ( _pc == _was_wide ); }

   // Does this instruction contain an index which refes into the CP cache?
   bool has_cache_index() const { return Bytecodes::uses_cp_cache(cur_bc_raw()); }

   bool has_optional_appendix() { return Bytecodes::has_optional_appendix(cur_bc_raw()); }

   int get_index_u1() const {
     return bytecode().get_index_u1(cur_bc_raw());
   }

   int get_index_u1_cpcache() const {
     return bytecode().get_index_u1_cpcache(cur_bc_raw());
   }

   // Get a byte index following this bytecode.
   // If prefixed with a wide bytecode, get a wide index.
   int get_index() const {
     assert(!has_cache_index(), "else use cpcache variant");
     return (_pc == _was_wide)   // was widened?
       ? get_index_u2(true)      // yes, return wide index
       : get_index_u1();         // no, return narrow index
   }

   // Get 2-byte index (byte swapping depending on which bytecode)
   int get_index_u2(bool is_wide = false) const {
     return bytecode().get_index_u2(cur_bc_raw(), is_wide);
   }

   // Get 2-byte index in native byte order.  (Rewriter::rewrite makes these.)
   int get_index_u2_cpcache() const {
     return bytecode().get_index_u2_cpcache(cur_bc_raw());
   }

   // Get 4-byte index, for invokedynamic.
   int get_index_u4() const {
     return bytecode().get_index_u4(cur_bc_raw());
   }

   bool has_index_u4() const {
     return bytecode().has_index_u4(cur_bc_raw());
   }

   // Get dimensions byte (multinewarray)
   int get_dimensions() const { return *(unsigned char*)(_pc-1); }

   // Sign-extended index byte/short, no widening
   int get_constant_u1()                     const { return bytecode().get_constant_u1(instruction_size()-1, cur_bc_raw()); }
   int get_constant_u2(bool is_wide = false) const { return bytecode().get_constant_u2(instruction_size()-2, cur_bc_raw(), is_wide); }

   // Get a byte signed constant for "iinc".  Invalid for other bytecodes.
   // If prefixed with a wide bytecode, get a wide constant
   int get_iinc_con() const {return (_pc==_was_wide) ? (jshort) get_constant_u2(true) : (jbyte) get_constant_u1();}

   // 2-byte branch offset from current pc
   int get_dest() const {
     return cur_bci() + bytecode().get_offset_s2(cur_bc_raw());
   }

   // 2-byte branch offset from next pc
   int next_get_dest() const {
     assert(_pc < _end, "");
     return next_bci() + next_bytecode().get_offset_s2(Bytecodes::_ifeq);
   }

   // 4-byte branch offset from current pc
   int get_far_dest() const {
     return cur_bci() + bytecode().get_offset_s4(cur_bc_raw());
   }

   // For a lookup or switch table, return target destination
   int get_int_table( int index ) const {
     return Bytes::get_Java_u4((address)&_table_base[index]); }

   // For tableswitch - get length of offset part
   int get_tableswitch_length()  { return get_int_table(2)-get_int_table(1)+1; }

   int get_dest_table( int index ) const {
     return cur_bci() + get_int_table(index); }

   // --- Constant pool access ---
   int get_constant_raw_index() const;
   int get_constant_pool_index() const;
   int get_constant_cache_index() const;
   int get_field_index();
   int get_method_index();

   // If this bytecode is a new, newarray, multianewarray, instanceof,
   // or checkcast, get the referenced klass.
   ciKlass* get_klass(bool& will_link);
   int get_klass_index() const;

   // If this bytecode is one of the ldc variants, get the referenced
   // constant.  Do not attempt to resolve it, since that would require
   // execution of Java code.  If it is not resolved, return an unloaded
   // object (ciConstant.as_object()->is_loaded() == false).
   ciConstant get_constant();
   constantTag get_constant_pool_tag(int index) const;

   // True if the klass-using bytecode points to an unresolved klass
   bool is_unresolved_klass() const {
     constantTag tag = get_constant_pool_tag(get_klass_index());
     return tag.is_unresolved_klass();
   }

   // If this bytecode is one of get_field, get_static, put_field,
   // or put_static, get the referenced field.
   ciField* get_field(bool& will_link);

   ciInstanceKlass* get_declared_field_holder();
   int      get_field_holder_index();
   int      get_field_signature_index();

   ciMethod*     get_method(bool& will_link, ciSignature* *declared_signature_result);
   bool          has_appendix();
   ciObject*     get_appendix();
   bool          has_method_type();
   ciMethodType* get_method_type();
   ciKlass*      get_declared_method_holder();
   int           get_method_holder_index();
   int           get_method_signature_index();

   // Get the resolved references arrays from the constant pool
   ciObjArray* get_resolved_references();
 };


 // ciSignatureStream
 //
 // The class is used to iterate over the elements of a method signature.
 class ciSignatureStream : public StackObj {
 private:
   ciSignature* _sig;
   int          _pos;
   // holder is a method's holder
   ciKlass*     _holder;
 public:
   ciSignatureStream(ciSignature* signature, ciKlass* holder = NULL) {
     _sig = signature;
     _pos = 0;
     _holder = holder;
   }

   bool at_return_type() { return _pos == _sig->count(); }

   bool is_done() { return _pos > _sig->count(); }

   void next() {
     if (_pos <= _sig->count()) {
       _pos++;
     }
   }

   ciType* type() {
     if (at_return_type()) {
       return _sig->return_type();
     } else {
       return _sig->type_at(_pos);
     }
   }

   // next klass in the signature
   ciKlass* next_klass() {
     ciKlass* sig_k;
     if (_holder != NULL) {
       sig_k = _holder;
       _holder = NULL;
     } else {
       while (!type()->is_klass()) {
         next();
       }
       assert(!at_return_type(), "passed end of signature");
       sig_k = type()->as_klass();
       next();
     }
     return sig_k;
   }
 };


 // ciExceptionHandlerStream
 //
 // The class is used to iterate over the exception handlers of
 // a method.
 class ciExceptionHandlerStream : public StackObj {
 private:
   // The method whose handlers we are traversing
   ciMethod* _method;

   // Our current position in the list of handlers
   int        _pos;
   int        _end;

   ciInstanceKlass*  _exception_klass;
   int        _bci;
   bool       _is_exact;

 public:
   ciExceptionHandlerStream(ciMethod* method) {
     _method = method;

     // Force loading of method code and handlers.
     _method->code();

     _pos = 0;
     _end = _method->_handler_count;
     _exception_klass = NULL;
     _bci    = -1;
     _is_exact = false;
   }

   ciExceptionHandlerStream(ciMethod* method, int bci,
                            ciInstanceKlass* exception_klass = NULL,
                            bool is_exact = false) {
     _method = method;

     // Force loading of method code and handlers.
     _method->code();

     _pos = -1;
     _end = _method->_handler_count + 1; // include the rethrow handler
     _exception_klass = (exception_klass != NULL && exception_klass->is_loaded()
                           ? exception_klass
                           : NULL);
     _bci = bci;
     assert(_bci >= 0, "bci out of range");
     _is_exact = is_exact;
     next();
   }

   // These methods are currently implemented in an odd way.
   // Count the number of handlers the iterator has ever produced
   // or will ever produce.  Do not include the final rethrow handler.
   // That is, a trivial exception handler stream will have a count
   // of zero and produce just the rethrow handler.
   int count();

   // Count the number of handlers this stream will produce from now on.
   // Include the current handler, and the final rethrow handler.
   // The remaining count will be zero iff is_done() is true,
   int count_remaining();

   bool is_done() {
     return (_pos >= _end);
   }

   void next() {
     _pos++;
     if (_bci != -1) {
       // We are not iterating over all handlers...
       while (!is_done()) {
         ciExceptionHandler* handler = _method->_exception_handlers[_pos];
         if (handler->is_in_range(_bci)) {
           if (handler->is_catch_all()) {
             // Found final active catch block.
             _end = _pos+1;
             return;
           } else if (_exception_klass == NULL || !handler->catch_klass()->is_loaded()) {
             // We cannot do any type analysis here.  Must conservatively assume
             // catch block is reachable.
             return;
           } else if (_exception_klass->is_subtype_of(handler->catch_klass())) {
             // This catch clause will definitely catch the exception.
             // Final candidate.
             _end = _pos+1;
             return;
           } else if (!_is_exact &&
                      handler->catch_klass()->is_subtype_of(_exception_klass)) {
             // This catch block may be reachable.
             return;
           }
         }

         // The catch block was not pertinent.  Go on.
         _pos++;
       }
     } else {
       // This is an iteration over all handlers.
       return;
     }
   }

   ciExceptionHandler* handler() {
     return _method->_exception_handlers[_pos];
   }
 };


 // Implementation for declarations in bytecode.hpp
 Bytecode::Bytecode(const ciBytecodeStream* stream, address bcp): _bcp(bcp != NULL ? bcp : stream->cur_bcp()), _code(Bytecodes::code_at(NULL, addr_at(0))) {}
 Bytecode_lookupswitch::Bytecode_lookupswitch(const ciBytecodeStream* stream): Bytecode(stream) { verify(); }
 Bytecode_tableswitch::Bytecode_tableswitch(const ciBytecodeStream* stream): Bytecode(stream) { verify(); }

 #endif // SHARE_VM_CI_CISTREAMS_HPP
	/*
	* 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.
	*
	*/

	#ifndef SHARE_VM_CI_CISTREAMS_HPP
	#define SHARE_VM_CI_CISTREAMS_HPP

	#include "ci/ciClassList.hpp"
	#include "ci/ciExceptionHandler.hpp"
	#include "ci/ciInstanceKlass.hpp"
	#include "ci/ciMethod.hpp"
	#include "interpreter/bytecode.hpp"

	// ciBytecodeStream
	//
	// The class is used to iterate over the bytecodes of a method.
	// It hides the details of constant pool structure/access by
	// providing accessors for constant pool items. It returns only pure
	// Java bytecodes; VM-internal _fast bytecodes are translated back to
	// their original form during iteration.
	class ciBytecodeStream : StackObj {
	private:
	// Handling for the weird bytecodes
	Bytecodes::Code next_wide_or_table(Bytecodes::Code); // Handle _wide & complicated inline table

	static Bytecodes::Code check_java(Bytecodes::Code c) {
	assert(Bytecodes::is_java_code(c), "should not return _fast bytecodes");
	return c;
	}

	static Bytecodes::Code check_defined(Bytecodes::Code c) {
	assert(Bytecodes::is_defined(c), "");
	return c;
	}

	ciMethod* _method; // the method
	ciInstanceKlass* _holder;
	address _bc_start; // Start of current bytecode for table
	address _was_wide; // Address past last wide bytecode
	jint* _table_base; // Aligned start of last table or switch

	address _start; // Start of bytecodes
	address _end; // Past end of bytecodes
	address _pc; // Current PC
	Bytecodes::Code _bc; // Current bytecode
	Bytecodes::Code _raw_bc; // Current bytecode, raw form

	void reset( address base, unsigned int size ) {
	_bc_start =_was_wide = 0;
	_start = _pc = base; _end = base + size;
	}

	void assert_wide(bool require_wide) const {
	if (require_wide)
	{ assert(is_wide(), "must be a wide instruction"); }
	else { assert(!is_wide(), "must not be a wide instruction"); }
	}

	Bytecode bytecode() const { return Bytecode(this, _bc_start); }
	Bytecode next_bytecode() const { return Bytecode(this, _pc); }

	public:
	// End-Of-Bytecodes
	static Bytecodes::Code EOBC() {
	return Bytecodes::_illegal;
	}

	ciBytecodeStream(ciMethod* m) {
	reset_to_method(m);
	}

	ciBytecodeStream() {
	reset_to_method(NULL);
	}

	ciMethod* method() const { return _method; }

	void reset_to_method(ciMethod* m) {
	_method = m;
	if (m == NULL) {
	_holder = NULL;
	reset(NULL, 0);
	} else {
	_holder = m->holder();
	reset(m->code(), m->code_size());
	}
	}

	void reset_to_bci( int bci );

	// Force the iterator to report a certain bci.
	void force_bci(int bci);

	void set_max_bci( int max ) {
	_end = _start + max;
	}

	address cur_bcp() const { return _bc_start; } // Returns bcp to current instruction
	int next_bci() const { return _pc - _start; }
	int cur_bci() const { return _bc_start - _start; }
	int instruction_size() const { return _pc - _bc_start; }

	Bytecodes::Code cur_bc() const{ return check_java(_bc); }
	Bytecodes::Code cur_bc_raw() const { return check_defined(_raw_bc); }
	Bytecodes::Code next_bc() { return Bytecodes::java_code((Bytecodes::Code)* _pc); }

	// Return current ByteCode and increment PC to next bytecode, skipping all
	// intermediate constants. Returns EOBC at end.
	// Expected usage:
	// ciBytecodeStream iter(m);
	// while (iter.next() != ciBytecodeStream::EOBC()) { ... }
	Bytecodes::Code next() {
	_bc_start = _pc; // Capture start of bc
	if( _pc >= _end ) return EOBC(); // End-Of-Bytecodes

	// Fetch Java bytecode
	// All rewritten bytecodes maintain the size of original bytecode.
	_bc = Bytecodes::java_code(_raw_bc = (Bytecodes::Code)*_pc);
	int csize = Bytecodes::length_for(_bc); // Expected size
	_pc += csize; // Bump PC past bytecode
	if (csize == 0) {
	_bc = next_wide_or_table(_bc);
	}
	return check_java(_bc);
	}

	bool is_wide() const { return ( _pc == _was_wide ); }

	// Does this instruction contain an index which refes into the CP cache?
	bool has_cache_index() const { return Bytecodes::uses_cp_cache(cur_bc_raw()); }

	bool has_optional_appendix() { return Bytecodes::has_optional_appendix(cur_bc_raw()); }

	int get_index_u1() const {
	return bytecode().get_index_u1(cur_bc_raw());
	}

	int get_index_u1_cpcache() const {
	return bytecode().get_index_u1_cpcache(cur_bc_raw());
	}

	// Get a byte index following this bytecode.
	// If prefixed with a wide bytecode, get a wide index.
	int get_index() const {
	assert(!has_cache_index(), "else use cpcache variant");
	return (_pc == _was_wide) // was widened?
	? get_index_u2(true) // yes, return wide index
	: get_index_u1(); // no, return narrow index
	}

	// Get 2-byte index (byte swapping depending on which bytecode)
	int get_index_u2(bool is_wide = false) const {
	return bytecode().get_index_u2(cur_bc_raw(), is_wide);
	}

	// Get 2-byte index in native byte order. (Rewriter::rewrite makes these.)
	int get_index_u2_cpcache() const {
	return bytecode().get_index_u2_cpcache(cur_bc_raw());
	}

	// Get 4-byte index, for invokedynamic.
	int get_index_u4() const {
	return bytecode().get_index_u4(cur_bc_raw());
	}

	bool has_index_u4() const {
	return bytecode().has_index_u4(cur_bc_raw());
	}

	// Get dimensions byte (multinewarray)
	int get_dimensions() const { return (unsigned char)(_pc-1); }

	// Sign-extended index byte/short, no widening
	int get_constant_u1() const { return bytecode().get_constant_u1(instruction_size()-1, cur_bc_raw()); }
	int get_constant_u2(bool is_wide = false) const { return bytecode().get_constant_u2(instruction_size()-2, cur_bc_raw(), is_wide); }

	// Get a byte signed constant for "iinc". Invalid for other bytecodes.
	// If prefixed with a wide bytecode, get a wide constant
	int get_iinc_con() const {return (_pc==_was_wide) ? (jshort) get_constant_u2(true) : (jbyte) get_constant_u1();}

	// 2-byte branch offset from current pc
	int get_dest() const {
	return cur_bci() + bytecode().get_offset_s2(cur_bc_raw());
	}

	// 2-byte branch offset from next pc
	int next_get_dest() const {
	assert(_pc < _end, "");
	return next_bci() + next_bytecode().get_offset_s2(Bytecodes::_ifeq);
	}

	// 4-byte branch offset from current pc
	int get_far_dest() const {
	return cur_bci() + bytecode().get_offset_s4(cur_bc_raw());
	}

	// For a lookup or switch table, return target destination
	int get_int_table( int index ) const {
	return Bytes::get_Java_u4((address)&_table_base[index]); }

	// For tableswitch - get length of offset part
	int get_tableswitch_length() { return get_int_table(2)-get_int_table(1)+1; }

	int get_dest_table( int index ) const {
	return cur_bci() + get_int_table(index); }

	// --- Constant pool access ---
	int get_constant_raw_index() const;
	int get_constant_pool_index() const;
	int get_constant_cache_index() const;
	int get_field_index();
	int get_method_index();

	// If this bytecode is a new, newarray, multianewarray, instanceof,
	// or checkcast, get the referenced klass.
	ciKlass* get_klass(bool& will_link);
	int get_klass_index() const;

	// If this bytecode is one of the ldc variants, get the referenced
	// constant. Do not attempt to resolve it, since that would require
	// execution of Java code. If it is not resolved, return an unloaded
	// object (ciConstant.as_object()->is_loaded() == false).
	ciConstant get_constant();
	constantTag get_constant_pool_tag(int index) const;

	// True if the klass-using bytecode points to an unresolved klass
	bool is_unresolved_klass() const {
	constantTag tag = get_constant_pool_tag(get_klass_index());
	return tag.is_unresolved_klass();
	}

	// If this bytecode is one of get_field, get_static, put_field,
	// or put_static, get the referenced field.
	ciField* get_field(bool& will_link);

	ciInstanceKlass* get_declared_field_holder();
	int get_field_holder_index();
	int get_field_signature_index();

	ciMethod* get_method(bool& will_link, ciSignature* *declared_signature_result);
	bool has_appendix();
	ciObject* get_appendix();
	bool has_method_type();
	ciMethodType* get_method_type();
	ciKlass* get_declared_method_holder();
	int get_method_holder_index();
	int get_method_signature_index();

	// Get the resolved references arrays from the constant pool
	ciObjArray* get_resolved_references();
	};


	// ciSignatureStream
	//
	// The class is used to iterate over the elements of a method signature.
	class ciSignatureStream : public StackObj {
	private:
	ciSignature* _sig;
	int _pos;
	// holder is a method's holder
	ciKlass* _holder;
	public:
	ciSignatureStream(ciSignature* signature, ciKlass* holder = NULL) {
	_sig = signature;
	_pos = 0;
	_holder = holder;
	}

	bool at_return_type() { return _pos == _sig->count(); }

	bool is_done() { return _pos > _sig->count(); }

	void next() {
	if (_pos <= _sig->count()) {
	_pos++;
	}
	}

	ciType* type() {
	if (at_return_type()) {
	return _sig->return_type();
	} else {
	return _sig->type_at(_pos);
	}
	}

	// next klass in the signature
	ciKlass* next_klass() {
	ciKlass* sig_k;
	if (_holder != NULL) {
	sig_k = _holder;
	_holder = NULL;
	} else {
	while (!type()->is_klass()) {
	next();
	}
	assert(!at_return_type(), "passed end of signature");
	sig_k = type()->as_klass();
	next();
	}
	return sig_k;
	}
	};


	// ciExceptionHandlerStream
	//
	// The class is used to iterate over the exception handlers of
	// a method.
	class ciExceptionHandlerStream : public StackObj {
	private:
	// The method whose handlers we are traversing
	ciMethod* _method;

	// Our current position in the list of handlers
	int _pos;
	int _end;

	ciInstanceKlass* _exception_klass;
	int _bci;
	bool _is_exact;

	public:
	ciExceptionHandlerStream(ciMethod* method) {
	_method = method;

	// Force loading of method code and handlers.
	_method->code();

	_pos = 0;
	_end = _method->_handler_count;
	_exception_klass = NULL;
	_bci = -1;
	_is_exact = false;
	}

	ciExceptionHandlerStream(ciMethod* method, int bci,
	ciInstanceKlass* exception_klass = NULL,
	bool is_exact = false) {
	_method = method;

	// Force loading of method code and handlers.
	_method->code();

	_pos = -1;
	_end = _method->_handler_count + 1; // include the rethrow handler
	_exception_klass = (exception_klass != NULL && exception_klass->is_loaded()
	? exception_klass
	: NULL);
	_bci = bci;
	assert(_bci >= 0, "bci out of range");
	_is_exact = is_exact;
	next();
	}

	// These methods are currently implemented in an odd way.
	// Count the number of handlers the iterator has ever produced
	// or will ever produce. Do not include the final rethrow handler.
	// That is, a trivial exception handler stream will have a count
	// of zero and produce just the rethrow handler.
	int count();

	// Count the number of handlers this stream will produce from now on.
	// Include the current handler, and the final rethrow handler.
	// The remaining count will be zero iff is_done() is true,
	int count_remaining();

	bool is_done() {
	return (_pos >= _end);
	}

	void next() {
	_pos++;
	if (_bci != -1) {
	// We are not iterating over all handlers...
	while (!is_done()) {
	ciExceptionHandler* handler = _method->_exception_handlers[_pos];
	if (handler->is_in_range(_bci)) {
	if (handler->is_catch_all()) {
	// Found final active catch block.
	_end = _pos+1;
	return;
	} else if (_exception_klass == NULL \|\| !handler->catch_klass()->is_loaded()) {
	// We cannot do any type analysis here. Must conservatively assume
	// catch block is reachable.
	return;
	} else if (_exception_klass->is_subtype_of(handler->catch_klass())) {
	// This catch clause will definitely catch the exception.
	// Final candidate.
	_end = _pos+1;
	return;
	} else if (!_is_exact &&
	handler->catch_klass()->is_subtype_of(_exception_klass)) {
	// This catch block may be reachable.
	return;
	}
	}

	// The catch block was not pertinent. Go on.
	_pos++;
	}
	} else {
	// This is an iteration over all handlers.
	return;
	}
	}

	ciExceptionHandler* handler() {
	return _method->_exception_handlers[_pos];
	}
	};



	// Implementation for declarations in bytecode.hpp
	Bytecode::Bytecode(const ciBytecodeStream* stream, address bcp): _bcp(bcp != NULL ? bcp : stream->cur_bcp()), _code(Bytecodes::code_at(NULL, addr_at(0))) {}
	Bytecode_lookupswitch::Bytecode_lookupswitch(const ciBytecodeStream* stream): Bytecode(stream) { verify(); }
	Bytecode_tableswitch::Bytecode_tableswitch(const ciBytecodeStream* stream): Bytecode(stream) { verify(); }

	#endif // SHARE_VM_CI_CISTREAMS_HPP