src/share/vm/code/debugInfoRec.cpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 1998, 2013, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #include "precompiled.hpp"
 #include "code/debugInfoRec.hpp"
 #include "code/scopeDesc.hpp"
 #include "prims/jvmtiExport.hpp"

 // Private definition.
 // There is one DIR_Chunk for each scope and values array.
 // A chunk can potentially be used more than once.
 // We keep track of these chunks in order to detect
 // repetition and enable sharing.
 class DIR_Chunk {
   friend class DebugInformationRecorder;
   int  _offset; // location in the stream of this scope
   int  _length; // number of bytes in the stream
   int  _hash;   // hash of stream bytes (for quicker reuse)

   void* operator new(size_t ignore, DebugInformationRecorder* dir) throw() {
     assert(ignore == sizeof(DIR_Chunk), "");
     if (dir->_next_chunk >= dir->_next_chunk_limit) {
       const int CHUNK = 100;
       dir->_next_chunk = NEW_RESOURCE_ARRAY(DIR_Chunk, CHUNK);
       dir->_next_chunk_limit = dir->_next_chunk + CHUNK;
     }
     return dir->_next_chunk++;
   }

   DIR_Chunk(int offset, int length, DebugInformationRecorder* dir) {
     _offset = offset;
     _length = length;
     unsigned int hash = 0;
     address p = dir->stream()->buffer() + _offset;
     for (int i = 0; i < length; i++) {
       if (i == 6)  break;
       hash *= 127;
       hash += p[i];
     }
     _hash = hash;
   }

   DIR_Chunk* find_match(GrowableArray<DIR_Chunk*>* arr,
                         int start_index,
                         DebugInformationRecorder* dir) {
     int end_index = arr->length();
     int hash = this->_hash, length = this->_length;
     address buf = dir->stream()->buffer();
     for (int i = end_index; --i >= start_index; ) {
       DIR_Chunk* that = arr->at(i);
       if (hash   == that->_hash &&
           length == that->_length &&
           0 == memcmp(buf + this->_offset, buf + that->_offset, length)) {
         return that;
       }
     }
     return NULL;
   }
 };

 static inline bool compute_recording_non_safepoints() {
   if (JvmtiExport::should_post_compiled_method_load()
       && FLAG_IS_DEFAULT(DebugNonSafepoints)) {
     // The default value of this flag is taken to be true,
     // if JVMTI is looking at nmethod codes.
     // We anticipate that JVMTI may wish to participate in profiling.
     return true;
   }

   // If the flag is set manually, use it, whether true or false.
   // Otherwise, if JVMTI is not in the picture, use the default setting.
   // (This is true in debug, just for the exercise, false in product mode.)
   return DebugNonSafepoints;
 }

 DebugInformationRecorder::DebugInformationRecorder(OopRecorder* oop_recorder)
   : _recording_non_safepoints(compute_recording_non_safepoints())
 {
   _pcs_size   = 100;
   _pcs        = NEW_RESOURCE_ARRAY(PcDesc, _pcs_size);
   _pcs_length = 0;

   _prev_safepoint_pc = PcDesc::lower_offset_limit;

   _stream = new DebugInfoWriteStream(this, 10 * K);
   // make sure that there is no stream_decode_offset that is zero
   _stream->write_byte((jbyte)0xFF);

   // make sure that we can distinguish the value "serialized_null" from offsets
   assert(_stream->position() > serialized_null, "sanity");

   _oop_recorder = oop_recorder;

   _all_chunks    = new GrowableArray<DIR_Chunk*>(300);
   _shared_chunks = new GrowableArray<DIR_Chunk*>(30);
   _next_chunk = _next_chunk_limit = NULL;

   add_new_pc_offset(PcDesc::lower_offset_limit);  // sentinel record

   debug_only(_recording_state = rs_null);
 }


 void DebugInformationRecorder::add_oopmap(int pc_offset, OopMap* map) {
   // !!!!! Preserve old style handling of oopmaps for now
   _oopmaps->add_gc_map(pc_offset, map);
 }

 void DebugInformationRecorder::add_safepoint(int pc_offset, OopMap* map) {
   assert(!_oop_recorder->is_complete(), "not frozen yet");
   // Store the new safepoint

   // Add the oop map
   add_oopmap(pc_offset, map);

   add_new_pc_offset(pc_offset);

   assert(_recording_state == rs_null, "nesting of recording calls");
   debug_only(_recording_state = rs_safepoint);
 }

 void DebugInformationRecorder::add_non_safepoint(int pc_offset) {
   assert(!_oop_recorder->is_complete(), "not frozen yet");
   assert(_recording_non_safepoints, "must be recording non-safepoints");

   add_new_pc_offset(pc_offset);

   assert(_recording_state == rs_null, "nesting of recording calls");
   debug_only(_recording_state = rs_non_safepoint);
 }

 void DebugInformationRecorder::add_new_pc_offset(int pc_offset) {
   assert(_pcs_length == 0 || last_pc()->pc_offset() < pc_offset,
          "must specify a new, larger pc offset");

   // add the pcdesc
   if (_pcs_length == _pcs_size) {
     // Expand
     int     new_pcs_size = _pcs_size * 2;
     PcDesc* new_pcs      = NEW_RESOURCE_ARRAY(PcDesc, new_pcs_size);
     for (int index = 0; index < _pcs_length; index++) {
       new_pcs[index] = _pcs[index];
     }
     _pcs_size = new_pcs_size;
     _pcs      = new_pcs;
   }
   assert(_pcs_size > _pcs_length, "There must be room for after expanding");

   _pcs[_pcs_length++] = PcDesc(pc_offset, DebugInformationRecorder::serialized_null,
                                DebugInformationRecorder::serialized_null);
 }


 int DebugInformationRecorder::serialize_monitor_values(GrowableArray<MonitorValue*>* monitors) {
   if (monitors == NULL || monitors->is_empty()) return DebugInformationRecorder::serialized_null;
   assert(_recording_state == rs_safepoint, "must be recording a safepoint");
   int result = stream()->position();
   stream()->write_int(monitors->length());
   for (int index = 0; index < monitors->length(); index++) {
     monitors->at(index)->write_on(stream());
   }
   assert(result != serialized_null, "sanity");

   // (See comment below on DebugInformationRecorder::describe_scope.)
   int shared_result = find_sharable_decode_offset(result);
   if (shared_result != serialized_null) {
     stream()->set_position(result);
     result = shared_result;
   }

   return result;
 }


 int DebugInformationRecorder::serialize_scope_values(GrowableArray<ScopeValue*>* values) {
   if (values == NULL || values->is_empty()) return DebugInformationRecorder::serialized_null;
   assert(_recording_state == rs_safepoint, "must be recording a safepoint");
   int result = stream()->position();
   assert(result != serialized_null, "sanity");
   stream()->write_int(values->length());
   for (int index = 0; index < values->length(); index++) {
     values->at(index)->write_on(stream());
   }

   // (See comment below on DebugInformationRecorder::describe_scope.)
   int shared_result = find_sharable_decode_offset(result);
   if (shared_result != serialized_null) {
     stream()->set_position(result);
     result = shared_result;
   }

   return result;
 }


 #ifndef PRODUCT
 // These variables are put into one block to reduce relocations
 // and make it simpler to print from the debugger.
 static
 struct dir_stats_struct {
   int chunks_queried;
   int chunks_shared;
   int chunks_reshared;
   int chunks_elided;

   void print() {
     tty->print_cr("Debug Data Chunks: %d, shared %d+%d, non-SP's elided %d",
                   chunks_queried,
                   chunks_shared, chunks_reshared,
                   chunks_elided);
   }
 } dir_stats;
 #endif //PRODUCT


 int DebugInformationRecorder::find_sharable_decode_offset(int stream_offset) {
   // Only pull this trick if non-safepoint recording
   // is enabled, for now.
   if (!recording_non_safepoints())
     return serialized_null;

   NOT_PRODUCT(++dir_stats.chunks_queried);
   int stream_length = stream()->position() - stream_offset;
   assert(stream_offset != serialized_null, "should not be null");
   assert(stream_length != 0, "should not be empty");

   DIR_Chunk* ns = new(this) DIR_Chunk(stream_offset, stream_length, this);

   // Look in previously shared scopes first:
   DIR_Chunk* ms = ns->find_match(_shared_chunks, 0, this);
   if (ms != NULL) {
     NOT_PRODUCT(++dir_stats.chunks_reshared);
     assert(ns+1 == _next_chunk, "");
     _next_chunk = ns;
     return ms->_offset;
   }

   // Look in recently encountered scopes next:
   const int MAX_RECENT = 50;
   int start_index = _all_chunks->length() - MAX_RECENT;
   if (start_index < 0)  start_index = 0;
   ms = ns->find_match(_all_chunks, start_index, this);
   if (ms != NULL) {
     NOT_PRODUCT(++dir_stats.chunks_shared);
     // Searching in _all_chunks is limited to a window,
     // but searching in _shared_chunks is unlimited.
     _shared_chunks->append(ms);
     assert(ns+1 == _next_chunk, "");
     _next_chunk = ns;
     return ms->_offset;
   }

   // No match.  Add this guy to the list, in hopes of future shares.
   _all_chunks->append(ns);
   return serialized_null;
 }


 // must call add_safepoint before: it sets PcDesc and this routine uses
 // the last PcDesc set
 void DebugInformationRecorder::describe_scope(int         pc_offset,
                                               ciMethod*   method,
                                               int         bci,
                                               bool        reexecute,
                                               bool        is_method_handle_invoke,
                                               bool        return_oop,
                                               DebugToken* locals,
                                               DebugToken* expressions,
                                               DebugToken* monitors) {
   assert(_recording_state != rs_null, "nesting of recording calls");
   PcDesc* last_pd = last_pc();
   assert(last_pd->pc_offset() == pc_offset, "must be last pc");
   int sender_stream_offset = last_pd->scope_decode_offset();
   // update the stream offset of current pc desc
   int stream_offset = stream()->position();
   last_pd->set_scope_decode_offset(stream_offset);

   // Record flags into pcDesc.
   last_pd->set_should_reexecute(reexecute);
   last_pd->set_is_method_handle_invoke(is_method_handle_invoke);
   last_pd->set_return_oop(return_oop);

   // serialize sender stream offest
   stream()->write_int(sender_stream_offset);

   // serialize scope
   Metadata* method_enc = (method == NULL)? NULL: method->constant_encoding();
   stream()->write_int(oop_recorder()->find_index(method_enc));
   stream()->write_bci(bci);
   assert(method == NULL ||
          (method->is_native() && bci == 0) ||
          (!method->is_native() && 0 <= bci && bci < method->code_size()) ||
          (method->is_compiled_lambda_form() && bci == -99) ||  // this might happen in C1
          bci == -1, "illegal bci");

   // serialize the locals/expressions/monitors
   stream()->write_int((intptr_t) locals);
   stream()->write_int((intptr_t) expressions);
   stream()->write_int((intptr_t) monitors);

   // Here's a tricky bit.  We just wrote some bytes.
   // Wouldn't it be nice to find that we had already
   // written those same bytes somewhere else?
   // If we get lucky this way, reset the stream
   // and reuse the old bytes.  By the way, this
   // trick not only shares parent scopes, but also
   // compresses equivalent non-safepoint PcDescs.
   int shared_stream_offset = find_sharable_decode_offset(stream_offset);
   if (shared_stream_offset != serialized_null) {
     stream()->set_position(stream_offset);
     last_pd->set_scope_decode_offset(shared_stream_offset);
   }
 }

 void DebugInformationRecorder::dump_object_pool(GrowableArray<ScopeValue*>* objects) {
   guarantee( _pcs_length > 0, "safepoint must exist before describing scopes");
   PcDesc* last_pd = &_pcs[_pcs_length-1];
   if (objects != NULL) {
     for (int i = objects->length() - 1; i >= 0; i--) {
       ((ObjectValue*) objects->at(i))->set_visited(false);
     }
   }
   int offset = serialize_scope_values(objects);
   last_pd->set_obj_decode_offset(offset);
 }

 void DebugInformationRecorder::end_scopes(int pc_offset, bool is_safepoint) {
   assert(_recording_state == (is_safepoint? rs_safepoint: rs_non_safepoint),
          "nesting of recording calls");
   debug_only(_recording_state = rs_null);

   // Try to compress away an equivalent non-safepoint predecessor.
   // (This only works because we have previously recognized redundant
   // scope trees and made them use a common scope_decode_offset.)
   if (_pcs_length >= 2 && recording_non_safepoints()) {
     PcDesc* last = last_pc();
     PcDesc* prev = prev_pc();
     // If prev is (a) not a safepoint and (b) has the same
     // stream pointer, then it can be coalesced into the last.
     // This is valid because non-safepoints are only sought
     // with pc_desc_near, which (when it misses prev) will
     // search forward until it finds last.
     // In addition, it does not matter if the last PcDesc
     // is for a safepoint or not.
     if (_prev_safepoint_pc < prev->pc_offset() && prev->is_same_info(last)) {
       assert(prev == last-1, "sane");
       prev->set_pc_offset(pc_offset);
       _pcs_length -= 1;
       NOT_PRODUCT(++dir_stats.chunks_elided);
     }
   }

   // We have just recorded this safepoint.
   // Remember it in case the previous paragraph needs to know.
   if (is_safepoint) {
     _prev_safepoint_pc = pc_offset;
   }
 }

 #ifdef ASSERT
 bool DebugInformationRecorder::recorders_frozen() {
   return _oop_recorder->is_complete() || _oop_recorder->is_complete();
 }

 void DebugInformationRecorder::mark_recorders_frozen() {
   _oop_recorder->freeze();
 }
 #endif // PRODUCT

 DebugToken* DebugInformationRecorder::create_scope_values(GrowableArray<ScopeValue*>* values) {
   assert(!recorders_frozen(), "not frozen yet");
   return (DebugToken*) (intptr_t) serialize_scope_values(values);
 }


 DebugToken* DebugInformationRecorder::create_monitor_values(GrowableArray<MonitorValue*>* monitors) {
   assert(!recorders_frozen(), "not frozen yet");
   return (DebugToken*) (intptr_t) serialize_monitor_values(monitors);
 }


 int DebugInformationRecorder::data_size() {
   debug_only(mark_recorders_frozen());  // mark it "frozen" for asserts
   return _stream->position();
 }


 int DebugInformationRecorder::pcs_size() {
   debug_only(mark_recorders_frozen());  // mark it "frozen" for asserts
   if (last_pc()->pc_offset() != PcDesc::upper_offset_limit)
     add_new_pc_offset(PcDesc::upper_offset_limit);
   return _pcs_length * sizeof(PcDesc);
 }


 void DebugInformationRecorder::copy_to(nmethod* nm) {
   nm->copy_scopes_data(stream()->buffer(), stream()->position());
   nm->copy_scopes_pcs(_pcs, _pcs_length);
 }


 void DebugInformationRecorder::verify(const nmethod* code) {
   Unimplemented();
 }

 #ifndef PRODUCT
 void DebugInformationRecorder::print_statistics() {
   dir_stats.print();
 }
 #endif //PRODUCT
	/*
	* Copyright (c) 1998, 2013, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#include "precompiled.hpp"
	#include "code/debugInfoRec.hpp"
	#include "code/scopeDesc.hpp"
	#include "prims/jvmtiExport.hpp"

	// Private definition.
	// There is one DIR_Chunk for each scope and values array.
	// A chunk can potentially be used more than once.
	// We keep track of these chunks in order to detect
	// repetition and enable sharing.
	class DIR_Chunk {
	friend class DebugInformationRecorder;
	int _offset; // location in the stream of this scope
	int _length; // number of bytes in the stream
	int _hash; // hash of stream bytes (for quicker reuse)

	void* operator new(size_t ignore, DebugInformationRecorder* dir) throw() {
	assert(ignore == sizeof(DIR_Chunk), "");
	if (dir->_next_chunk >= dir->_next_chunk_limit) {
	const int CHUNK = 100;
	dir->_next_chunk = NEW_RESOURCE_ARRAY(DIR_Chunk, CHUNK);
	dir->_next_chunk_limit = dir->_next_chunk + CHUNK;
	}
	return dir->_next_chunk++;
	}

	DIR_Chunk(int offset, int length, DebugInformationRecorder* dir) {
	_offset = offset;
	_length = length;
	unsigned int hash = 0;
	address p = dir->stream()->buffer() + _offset;
	for (int i = 0; i < length; i++) {
	if (i == 6) break;
	hash *= 127;
	hash += p[i];
	}
	_hash = hash;
	}

	DIR_Chunk* find_match(GrowableArray<DIR_Chunk> arr,
	int start_index,
	DebugInformationRecorder* dir) {
	int end_index = arr->length();
	int hash = this->_hash, length = this->_length;
	address buf = dir->stream()->buffer();
	for (int i = end_index; --i >= start_index; ) {
	DIR_Chunk* that = arr->at(i);
	if (hash == that->_hash &&
	length == that->_length &&
	0 == memcmp(buf + this->_offset, buf + that->_offset, length)) {
	return that;
	}
	}
	return NULL;
	}
	};

	static inline bool compute_recording_non_safepoints() {
	if (JvmtiExport::should_post_compiled_method_load()
	&& FLAG_IS_DEFAULT(DebugNonSafepoints)) {
	// The default value of this flag is taken to be true,
	// if JVMTI is looking at nmethod codes.
	// We anticipate that JVMTI may wish to participate in profiling.
	return true;
	}

	// If the flag is set manually, use it, whether true or false.
	// Otherwise, if JVMTI is not in the picture, use the default setting.
	// (This is true in debug, just for the exercise, false in product mode.)
	return DebugNonSafepoints;
	}

	DebugInformationRecorder::DebugInformationRecorder(OopRecorder* oop_recorder)
	: _recording_non_safepoints(compute_recording_non_safepoints())
	{
	_pcs_size = 100;
	_pcs = NEW_RESOURCE_ARRAY(PcDesc, _pcs_size);
	_pcs_length = 0;

	_prev_safepoint_pc = PcDesc::lower_offset_limit;

	_stream = new DebugInfoWriteStream(this, 10 * K);
	// make sure that there is no stream_decode_offset that is zero
	_stream->write_byte((jbyte)0xFF);

	// make sure that we can distinguish the value "serialized_null" from offsets
	assert(_stream->position() > serialized_null, "sanity");

	_oop_recorder = oop_recorder;

	_all_chunks = new GrowableArray<DIR_Chunk*>(300);
	_shared_chunks = new GrowableArray<DIR_Chunk*>(30);
	_next_chunk = _next_chunk_limit = NULL;

	add_new_pc_offset(PcDesc::lower_offset_limit); // sentinel record

	debug_only(_recording_state = rs_null);
	}


	void DebugInformationRecorder::add_oopmap(int pc_offset, OopMap* map) {
	// !!!!! Preserve old style handling of oopmaps for now
	_oopmaps->add_gc_map(pc_offset, map);
	}

	void DebugInformationRecorder::add_safepoint(int pc_offset, OopMap* map) {
	assert(!_oop_recorder->is_complete(), "not frozen yet");
	// Store the new safepoint

	// Add the oop map
	add_oopmap(pc_offset, map);

	add_new_pc_offset(pc_offset);

	assert(_recording_state == rs_null, "nesting of recording calls");
	debug_only(_recording_state = rs_safepoint);
	}

	void DebugInformationRecorder::add_non_safepoint(int pc_offset) {
	assert(!_oop_recorder->is_complete(), "not frozen yet");
	assert(_recording_non_safepoints, "must be recording non-safepoints");

	add_new_pc_offset(pc_offset);

	assert(_recording_state == rs_null, "nesting of recording calls");
	debug_only(_recording_state = rs_non_safepoint);
	}

	void DebugInformationRecorder::add_new_pc_offset(int pc_offset) {
	assert(_pcs_length == 0 \|\| last_pc()->pc_offset() < pc_offset,
	"must specify a new, larger pc offset");

	// add the pcdesc
	if (_pcs_length == _pcs_size) {
	// Expand
	int new_pcs_size = _pcs_size * 2;
	PcDesc* new_pcs = NEW_RESOURCE_ARRAY(PcDesc, new_pcs_size);
	for (int index = 0; index < _pcs_length; index++) {
	new_pcs[index] = _pcs[index];
	}
	_pcs_size = new_pcs_size;
	_pcs = new_pcs;
	}
	assert(_pcs_size > _pcs_length, "There must be room for after expanding");

	_pcs[_pcs_length++] = PcDesc(pc_offset, DebugInformationRecorder::serialized_null,
	DebugInformationRecorder::serialized_null);
	}


	int DebugInformationRecorder::serialize_monitor_values(GrowableArray<MonitorValue> monitors) {
	if (monitors == NULL \|\| monitors->is_empty()) return DebugInformationRecorder::serialized_null;
	assert(_recording_state == rs_safepoint, "must be recording a safepoint");
	int result = stream()->position();
	stream()->write_int(monitors->length());
	for (int index = 0; index < monitors->length(); index++) {
	monitors->at(index)->write_on(stream());
	}
	assert(result != serialized_null, "sanity");

	// (See comment below on DebugInformationRecorder::describe_scope.)
	int shared_result = find_sharable_decode_offset(result);
	if (shared_result != serialized_null) {
	stream()->set_position(result);
	result = shared_result;
	}

	return result;
	}


	int DebugInformationRecorder::serialize_scope_values(GrowableArray<ScopeValue> values) {
	if (values == NULL \|\| values->is_empty()) return DebugInformationRecorder::serialized_null;
	assert(_recording_state == rs_safepoint, "must be recording a safepoint");
	int result = stream()->position();
	assert(result != serialized_null, "sanity");
	stream()->write_int(values->length());
	for (int index = 0; index < values->length(); index++) {
	values->at(index)->write_on(stream());
	}

	// (See comment below on DebugInformationRecorder::describe_scope.)
	int shared_result = find_sharable_decode_offset(result);
	if (shared_result != serialized_null) {
	stream()->set_position(result);
	result = shared_result;
	}

	return result;
	}


	#ifndef PRODUCT
	// These variables are put into one block to reduce relocations
	// and make it simpler to print from the debugger.
	static
	struct dir_stats_struct {
	int chunks_queried;
	int chunks_shared;
	int chunks_reshared;
	int chunks_elided;

	void print() {
	tty->print_cr("Debug Data Chunks: %d, shared %d+%d, non-SP's elided %d",
	chunks_queried,
	chunks_shared, chunks_reshared,
	chunks_elided);
	}
	} dir_stats;
	#endif //PRODUCT


	int DebugInformationRecorder::find_sharable_decode_offset(int stream_offset) {
	// Only pull this trick if non-safepoint recording
	// is enabled, for now.
	if (!recording_non_safepoints())
	return serialized_null;

	NOT_PRODUCT(++dir_stats.chunks_queried);
	int stream_length = stream()->position() - stream_offset;
	assert(stream_offset != serialized_null, "should not be null");
	assert(stream_length != 0, "should not be empty");

	DIR_Chunk* ns = new(this) DIR_Chunk(stream_offset, stream_length, this);

	// Look in previously shared scopes first:
	DIR_Chunk* ms = ns->find_match(_shared_chunks, 0, this);
	if (ms != NULL) {
	NOT_PRODUCT(++dir_stats.chunks_reshared);
	assert(ns+1 == _next_chunk, "");
	_next_chunk = ns;
	return ms->_offset;
	}

	// Look in recently encountered scopes next:
	const int MAX_RECENT = 50;
	int start_index = _all_chunks->length() - MAX_RECENT;
	if (start_index < 0) start_index = 0;
	ms = ns->find_match(_all_chunks, start_index, this);
	if (ms != NULL) {
	NOT_PRODUCT(++dir_stats.chunks_shared);
	// Searching in _all_chunks is limited to a window,
	// but searching in _shared_chunks is unlimited.
	_shared_chunks->append(ms);
	assert(ns+1 == _next_chunk, "");
	_next_chunk = ns;
	return ms->_offset;
	}

	// No match. Add this guy to the list, in hopes of future shares.
	_all_chunks->append(ns);
	return serialized_null;
	}


	// must call add_safepoint before: it sets PcDesc and this routine uses
	// the last PcDesc set
	void DebugInformationRecorder::describe_scope(int pc_offset,
	ciMethod* method,
	int bci,
	bool reexecute,
	bool is_method_handle_invoke,
	bool return_oop,
	DebugToken* locals,
	DebugToken* expressions,
	DebugToken* monitors) {
	assert(_recording_state != rs_null, "nesting of recording calls");
	PcDesc* last_pd = last_pc();
	assert(last_pd->pc_offset() == pc_offset, "must be last pc");
	int sender_stream_offset = last_pd->scope_decode_offset();
	// update the stream offset of current pc desc
	int stream_offset = stream()->position();
	last_pd->set_scope_decode_offset(stream_offset);

	// Record flags into pcDesc.
	last_pd->set_should_reexecute(reexecute);
	last_pd->set_is_method_handle_invoke(is_method_handle_invoke);
	last_pd->set_return_oop(return_oop);

	// serialize sender stream offest
	stream()->write_int(sender_stream_offset);

	// serialize scope
	Metadata* method_enc = (method == NULL)? NULL: method->constant_encoding();
	stream()->write_int(oop_recorder()->find_index(method_enc));
	stream()->write_bci(bci);
	assert(method == NULL \|\|
	(method->is_native() && bci == 0) \|\|
	(!method->is_native() && 0 <= bci && bci < method->code_size()) \|\|
	(method->is_compiled_lambda_form() && bci == -99) \|\| // this might happen in C1
	bci == -1, "illegal bci");

	// serialize the locals/expressions/monitors
	stream()->write_int((intptr_t) locals);
	stream()->write_int((intptr_t) expressions);
	stream()->write_int((intptr_t) monitors);

	// Here's a tricky bit. We just wrote some bytes.
	// Wouldn't it be nice to find that we had already
	// written those same bytes somewhere else?
	// If we get lucky this way, reset the stream
	// and reuse the old bytes. By the way, this
	// trick not only shares parent scopes, but also
	// compresses equivalent non-safepoint PcDescs.
	int shared_stream_offset = find_sharable_decode_offset(stream_offset);
	if (shared_stream_offset != serialized_null) {
	stream()->set_position(stream_offset);
	last_pd->set_scope_decode_offset(shared_stream_offset);
	}
	}

	void DebugInformationRecorder::dump_object_pool(GrowableArray<ScopeValue> objects) {
	guarantee( _pcs_length > 0, "safepoint must exist before describing scopes");
	PcDesc* last_pd = &_pcs[_pcs_length-1];
	if (objects != NULL) {
	for (int i = objects->length() - 1; i >= 0; i--) {
	((ObjectValue*) objects->at(i))->set_visited(false);
	}
	}
	int offset = serialize_scope_values(objects);
	last_pd->set_obj_decode_offset(offset);
	}

	void DebugInformationRecorder::end_scopes(int pc_offset, bool is_safepoint) {
	assert(_recording_state == (is_safepoint? rs_safepoint: rs_non_safepoint),
	"nesting of recording calls");
	debug_only(_recording_state = rs_null);

	// Try to compress away an equivalent non-safepoint predecessor.
	// (This only works because we have previously recognized redundant
	// scope trees and made them use a common scope_decode_offset.)
	if (_pcs_length >= 2 && recording_non_safepoints()) {
	PcDesc* last = last_pc();
	PcDesc* prev = prev_pc();
	// If prev is (a) not a safepoint and (b) has the same
	// stream pointer, then it can be coalesced into the last.
	// This is valid because non-safepoints are only sought
	// with pc_desc_near, which (when it misses prev) will
	// search forward until it finds last.
	// In addition, it does not matter if the last PcDesc
	// is for a safepoint or not.
	if (_prev_safepoint_pc < prev->pc_offset() && prev->is_same_info(last)) {
	assert(prev == last-1, "sane");
	prev->set_pc_offset(pc_offset);
	_pcs_length -= 1;
	NOT_PRODUCT(++dir_stats.chunks_elided);
	}
	}

	// We have just recorded this safepoint.
	// Remember it in case the previous paragraph needs to know.
	if (is_safepoint) {
	_prev_safepoint_pc = pc_offset;
	}
	}

	#ifdef ASSERT
	bool DebugInformationRecorder::recorders_frozen() {
	return _oop_recorder->is_complete() \|\| _oop_recorder->is_complete();
	}

	void DebugInformationRecorder::mark_recorders_frozen() {
	_oop_recorder->freeze();
	}
	#endif // PRODUCT

	DebugToken* DebugInformationRecorder::create_scope_values(GrowableArray<ScopeValue> values) {
	assert(!recorders_frozen(), "not frozen yet");
	return (DebugToken*) (intptr_t) serialize_scope_values(values);
	}


	DebugToken* DebugInformationRecorder::create_monitor_values(GrowableArray<MonitorValue> monitors) {
	assert(!recorders_frozen(), "not frozen yet");
	return (DebugToken*) (intptr_t) serialize_monitor_values(monitors);
	}


	int DebugInformationRecorder::data_size() {
	debug_only(mark_recorders_frozen()); // mark it "frozen" for asserts
	return _stream->position();
	}


	int DebugInformationRecorder::pcs_size() {
	debug_only(mark_recorders_frozen()); // mark it "frozen" for asserts
	if (last_pc()->pc_offset() != PcDesc::upper_offset_limit)
	add_new_pc_offset(PcDesc::upper_offset_limit);
	return _pcs_length * sizeof(PcDesc);
	}


	void DebugInformationRecorder::copy_to(nmethod* nm) {
	nm->copy_scopes_data(stream()->buffer(), stream()->position());
	nm->copy_scopes_pcs(_pcs, _pcs_length);
	}


	void DebugInformationRecorder::verify(const nmethod* code) {
	Unimplemented();
	}

	#ifndef PRODUCT
	void DebugInformationRecorder::print_statistics() {
	dir_stats.print();
	}
	#endif //PRODUCT