oprofile-0.9.7/libpp/callgraph_container.cpp - nest-learning-thermostat/5.0.2/oprofile - Git at Google

 /**
  * @file callgraph_container.cpp
  * Container associating symbols and caller/caller symbols
  *
  * @remark Copyright 2004 OProfile authors
  * @remark Read the file COPYING
  *
  * @author Philippe Elie
  * @author John Levon
  */

 #include <cstdlib>

 #include <map>
 #include <set>
 #include <algorithm>
 #include <iterator>
 #include <string>
 #include <iostream>
 #include <numeric>

 #include "callgraph_container.h"
 #include "cverb.h"
 #include "parse_filename.h"
 #include "profile_container.h"
 #include "arrange_profiles.h"
 #include "populate.h"
 #include "string_filter.h"
 #include "op_bfd.h"
 #include "op_sample_file.h"
 #include "locate_images.h"

 using namespace std;

 namespace {

 bool operator==(cg_symbol const & lhs, cg_symbol const & rhs)
 {
 	less_symbol cmp_symb;
 	return !cmp_symb(lhs, rhs) && !cmp_symb(rhs, lhs);
 }


 // we store {caller,callee} inside a single u64
 odb_key_t caller_to_key(u32 value)
 {
 	return odb_key_t(value) << 32;
 }


 u32 key_to_callee(odb_key_t key)
 {
 	return key & 0xffffffff;
 }


 bool compare_by_callee_vma(pair<odb_key_t, count_type> const & lhs,
                            pair<odb_key_t, count_type> const & rhs)
 {
 	return (key_to_callee(lhs.first)) < (key_to_callee(rhs.first));
 }


 /*
  * We need 2 comparators for callgraph to get the desired output:
  *
  *	caller_with_few_samples
  *	caller_with_many_samples
  * function_with_many_samples
  *	callee_with_many_samples
  *	callee_with_few_samples
  */

 bool
 compare_arc_count(symbol_entry const & lhs, symbol_entry const & rhs)
 {
 	return lhs.sample.counts[0] < rhs.sample.counts[0];
 }


 bool
 compare_arc_count_reverse(symbol_entry const & lhs, symbol_entry const & rhs)
 {
 	return rhs.sample.counts[0] < lhs.sample.counts[0];
 }


 // find the nearest bfd symbol for the given file offset and check it's
 // in range
 op_bfd_symbol const *
 get_symbol_by_filepos(op_bfd const & bfd, u32 bfd_offset,
                       vma_t offset, symbol_index_t & i)
 {
 	offset += bfd_offset;
 	op_bfd_symbol tmpsym(offset, 0, string());

 	// sorted by filepos so this will find the nearest
 	vector<op_bfd_symbol>::const_iterator it =
 		upper_bound(bfd.syms.begin(), bfd.syms.end(), tmpsym);

 	if (it != bfd.syms.begin())
 		--it;

 	if (it == bfd.syms.end()) {
 		cerr << "get_symbol_by_filepos: no symbols at all?" << endl;
 		abort();
 	}

 	// if the offset is past the end of the symbol, we didn't find one
 	u32 const end_offset = it->size() + it->filepos();

 	if (offset >= end_offset) {
 		// let's be verbose for now
 		cerr << "warning: dropping hyperspace sample at offset "
 		     << hex << offset << " >= " << end_offset
 		     << " for binary " << bfd.get_filename() << dec << endl;
 		return NULL;
 	}

 	i = distance(bfd.syms.begin(), it);
 	return &(*it);
 }


 /// temporary caller and callee data held during processing
 class call_data {
 public:
 	call_data(profile_container const & p, profile_t const & pr,
 	          op_bfd const & bfd, u32 boff, image_name_id iid,
 	          image_name_id aid, bool debug_info)
 		: pc(p), profile(pr), b(bfd), boffset(boff), image(iid),
 		  app(aid), debug(debug_info) {}

 	/// point to a caller symbol
 	void caller_sym(symbol_index_t i) {
 		sym = symbol_entry();

 		unsigned long long start;
 		unsigned long long end;
 		b.get_symbol_range(i, start, end);

 		samples.clear();

 		// see profile_t::samples_range() for why we need this check
 		if (start > boffset) {
 			profile_t::iterator_pair p_it = profile.samples_range(
 				caller_to_key(start - boffset),
 				caller_to_key(end - boffset));

 			// Our odb_key_t contain (from_eip << 32 | to_eip),
 			// the range of keys we selected above contains one
 			// caller but different callees, and due to the
 			// ordering callee offsets are not consecutive: so
 			// we must sort them first.

 			for (; p_it.first != p_it.second; ++p_it.first) {
 				samples.push_back(make_pair(p_it.first.vma(),
 					p_it.first.count()));
 			}

 			sort(samples.begin(), samples.end(),
 			     compare_by_callee_vma);
 		}

 		sym.size = end - start;
 		sym.name = symbol_names.create(b.syms[i].name());
 		sym.sample.vma = b.syms[i].vma();

 		finish_sym(i, start);

 		if (cverb << vdebug) {
 			cverb << vdebug << hex << "Caller sym: "
 			      << b.syms[i].name() << " filepos " << start
 			      << "-" << end << dec << endl;
 		}
 	}

 	/// point to a callee symbol
 	bool callee_sym(u32 off) {
 		sym = symbol_entry();

 		symbol_index_t i = 0;
 		op_bfd_symbol const * bfdsym =
 			get_symbol_by_filepos(b, boffset, off, i);

 		if (!bfdsym)
 			return false;

 		callee_end = bfdsym->size() + bfdsym->filepos() - boffset;

 		sym.size = bfdsym->size();
 		sym.name = symbol_names.create(bfdsym->name());
 		sym.sample.vma = bfdsym->vma();

 		finish_sym(i, bfdsym->filepos());

 		if (cverb << vdebug) {
 			cverb << vdebug << hex << "Callee sym: "
 			      << bfdsym->name() << " filepos "
 			      << bfdsym->filepos() << "-"
 			      << (bfdsym->filepos() + bfdsym->size())
 			      << dec << endl;
 		}
 		return true;
 	}

 	void verbose_bfd(string const & prefix) const {
 		cverb << vdebug << prefix << " " << b.get_filename()
 		      << " offset " << boffset << " app "
 		      << image_names.name(app) << endl;
 	}

 	typedef vector<pair<odb_key_t, count_type> > samples_t;

 	typedef samples_t::const_iterator const_iterator;

 	samples_t samples;
 	symbol_entry sym;
 	u32 callee_end;

 private:
 	/// fill in the rest of the sym
 	void finish_sym(symbol_index_t i, unsigned long start) {
 		sym.image_name = image;
 		sym.app_name = app;
 		symbol_entry const * self = pc.find(sym);
 		if (self)
 			sym.sample.counts = self->sample.counts;

 		if (debug) {
 			string filename;
 			file_location & loc = sym.sample.file_loc;
 			if (b.get_linenr(i, start, filename, loc.linenr))
 				loc.filename = debug_names.create(filename);
 		}
 	}

 	profile_container const & pc;
 	profile_t const & profile;
 	op_bfd const & b;
 	u32 boffset;
 	image_name_id image;
 	image_name_id app;
 	bool debug;
 };


 /// accumulate all samples for a given caller/callee pair
 count_type
 accumulate_callee(call_data::const_iterator & it, call_data::const_iterator end,
                   u32 callee_end)
 {
 	count_type count = 0;
 	call_data::const_iterator const start = it;

 	while (it != end) {
 		u32 offset = key_to_callee(it->first);

 		if (cverb << (vdebug & vlevel1)) {
 			cverb << (vdebug & vlevel1) << hex << "offset: "
 			      << offset << dec << endl;
 		}

 		// stop if we pass the end of the callee
 		if (offset >= callee_end)
 			break;

 		count += it->second;
 		++it;
 	}

 	// If we haven't advanced at all, then we'll get
 	// an infinite loop, so we must abort.
 	if (it == start) {
 		cerr << "failure to advance iterator\n";
 		abort();
 	}

 	return count;
 }


 } // anonymous namespace


 void arc_recorder::
 add(symbol_entry const & caller, symbol_entry const * callee,
     count_array_t const & arc_count)
 {
 	cg_data & data = sym_map[caller];

 	// If we have a callee, add it to the caller's list, then
 	// add the caller to the callee's list.
 	if (callee) {
 		data.callees[*callee] += arc_count;

 		cg_data & callee_data = sym_map[*callee];

 		callee_data.callers[caller] += arc_count;
 	}
 }


 void arc_recorder::process_children(cg_symbol & sym, double threshold)
 {
 	// generate the synthetic self entry for the symbol
 	symbol_entry self = sym;

 	self.name = symbol_names.create(symbol_names.demangle(self.name)
 	                                + " [self]");

 	sym.total_callee_count += self.sample.counts;
 	sym.callees.push_back(self);

 	sort(sym.callers.begin(), sym.callers.end(), compare_arc_count);
 	sort(sym.callees.begin(), sym.callees.end(), compare_arc_count_reverse);

 	// FIXME: this relies on sort always being sample count

 	cg_symbol::children::iterator cit = sym.callers.begin();
 	cg_symbol::children::iterator cend = sym.callers.end();

 	while (cit != cend && op_ratio(cit->sample.counts[0],
 	       sym.total_caller_count[0]) < threshold)
 		++cit;

 	if (cit != cend)
 		sym.callers.erase(sym.callers.begin(), cit);

 	cit = sym.callees.begin();
 	cend = sym.callees.end();

 	while (cit != cend && op_ratio(cit->sample.counts[0],
 	       sym.total_callee_count[0]) >= threshold)
 		++cit;

 	if (cit != cend)
 		sym.callees.erase(cit, sym.callees.end());
 }


 void arc_recorder::
 process(count_array_t total, double threshold,
         string_filter const & sym_filter)
 {
 	map_t::const_iterator it;
 	map_t::const_iterator end = sym_map.end();

 	for (it = sym_map.begin(); it != end; ++it) {
 		cg_symbol sym((*it).first);
 		cg_data const & data = (*it).second;

 		// threshold out the main symbol if needed
 		if (op_ratio(sym.sample.counts[0], total[0]) < threshold)
 			continue;

 		// FIXME: slow?
 		if (!sym_filter.match(symbol_names.demangle(sym.name)))
 			continue;

 		cg_data::children::const_iterator cit;
 		cg_data::children::const_iterator cend = data.callers.end();

 		for (cit = data.callers.begin(); cit != cend; ++cit) {
 			symbol_entry csym = cit->first;
 			csym.sample.counts = cit->second;
 			sym.callers.push_back(csym);
 			sym.total_caller_count += cit->second;
 		}

 		cend = data.callees.end();

 		for (cit = data.callees.begin(); cit != cend; ++cit) {
 			symbol_entry csym = cit->first;
 			csym.sample.counts = cit->second;
 			sym.callees.push_back(csym);
 			sym.total_callee_count += cit->second;
 		}

 		process_children(sym, threshold);

 		// insert sym into cg_syms_objs
 		// then store pointer to sym in cg_syms
 		cg_syms.push_back(&(*cg_syms_objs.insert(cg_syms_objs.end(), sym)));
 	}
 }


 symbol_collection const & arc_recorder::get_symbols() const
 {
 	return cg_syms;
 }


 void callgraph_container::populate(list<inverted_profile> const & iprofiles,
    extra_images const & extra, bool debug_info, double threshold,
    bool merge_lib, string_filter const & sym_filter)
 {
 	this->extra_found_images = extra;
 	// non callgraph samples container, we record sample at symbol level
 	// not at vma level.
 	profile_container pc(debug_info, false, extra_found_images);

 	list<inverted_profile>::const_iterator it;
 	list<inverted_profile>::const_iterator const end = iprofiles.end();
 	for (it = iprofiles.begin(); it != end; ++it) {
 		// populate_caller_image take care about empty sample filename
 		populate_for_image(pc, *it, sym_filter, 0);
 	}

 	add_symbols(pc);

 	total_count = pc.samples_count();

 	for (it = iprofiles.begin(); it != end; ++it) {
 		for (size_t i = 0; i < it->groups.size(); ++i) {
 			populate(it->groups[i], it->image,
 				i, pc, debug_info, merge_lib);
 		}
 	}

 	recorder.process(total_count, threshold / 100.0, sym_filter);
 }


 void callgraph_container::populate(list<image_set> const & lset,
 	string const & app_image, size_t pclass,
 	profile_container const & pc, bool debug_info, bool merge_lib)
 {
 	list<image_set>::const_iterator lit;
 	list<image_set>::const_iterator const lend = lset.end();
 	for (lit = lset.begin(); lit != lend; ++lit) {
 		list<profile_sample_files>::const_iterator pit;
 		list<profile_sample_files>::const_iterator pend
 			= lit->files.end();
 		for (pit = lit->files.begin(); pit != pend; ++pit) {
 			populate(pit->cg_files, app_image,
 				 pclass, pc, debug_info, merge_lib);
 		}
 	}
 }


 void callgraph_container::populate(list<string> const & cg_files,
 	string const & app_image, size_t pclass,
 	profile_container const & pc, bool debug_info, bool merge_lib)
 {
 	list<string>::const_iterator it;
 	list<string>::const_iterator const end = cg_files.end();
 	for (it = cg_files.begin(); it != end; ++it) {
 		cverb << vdebug << "samples file : " << *it << endl;

 		parsed_filename caller_file =
 			parse_filename(*it, extra_found_images);
 		string const app_name = caller_file.image;

 		image_error error;
 		extra_found_images.find_image_path(caller_file.lib_image,
 				error, false);

 		if (error != image_ok)
 			report_image_error(caller_file.lib_image,
 					   error, false, extra_found_images);

 		bool caller_bfd_ok = true;
 		op_bfd caller_bfd(caller_file.lib_image,
 			string_filter(), extra_found_images, caller_bfd_ok);
 		if (!caller_bfd_ok)
 			report_image_error(caller_file.lib_image,
 			                   image_format_failure, false,
 					   extra_found_images);

 		parsed_filename callee_file =
 			parse_filename(*it, extra_found_images);

 		extra_found_images.find_image_path(callee_file.cg_image,
 				error, false);
 		if (error != image_ok)
 			report_image_error(callee_file.cg_image,
 					   error, false, extra_found_images);

 		bool callee_bfd_ok = true;
 		op_bfd callee_bfd(callee_file.cg_image,
 			string_filter(), extra_found_images, callee_bfd_ok);
 		if (!callee_bfd_ok)
 			report_image_error(callee_file.cg_image,
 		                           image_format_failure, false,
 					   extra_found_images);

 		profile_t profile;
 		// We can't use start_offset support in profile_t, give
 		// it a zero offset and we will fix that in add()
 		profile.add_sample_file(*it);
 		add(profile, caller_bfd, caller_bfd_ok, callee_bfd,
 		    merge_lib ? app_image : app_name, pc,
 		    debug_info, pclass);
 	}
 }


 void callgraph_container::
 add(profile_t const & profile, op_bfd const & caller_bfd, bool caller_bfd_ok,
    op_bfd const & callee_bfd, string const & app_name,
    profile_container const & pc, bool debug_info, size_t pclass)
 {
 	string const image_name = caller_bfd.get_filename();

 	opd_header const & header = profile.get_header();

 	// We can't use kernel sample file w/o the binary else we will
 	// use it with a zero offset, the code below will abort because
 	// we will get incorrect callee sub-range and out of range
 	// callee vma. FIXME
 	if (header.is_kernel && !caller_bfd_ok)
 		return;

 	// We must handle start_offset, this offset can be different for the
 	// caller and the callee: kernel sample traversing the syscall barrier.
 	u32 caller_offset;
 	if (header.is_kernel)
 		caller_offset = caller_bfd.get_start_offset(0);
 	else
 		caller_offset = header.anon_start;

 	u32 callee_offset;
 	if (header.cg_to_is_kernel)
 		callee_offset = callee_bfd.get_start_offset(0);
 	else
 		callee_offset = header.cg_to_anon_start;

 	image_name_id image_id = image_names.create(image_name);
 	image_name_id callee_image_id = image_names.create(callee_bfd.get_filename());
 	image_name_id app_id = image_names.create(app_name);

 	call_data caller(pc, profile, caller_bfd, caller_offset, image_id,
 	                   app_id, debug_info);
 	call_data callee(pc, profile, callee_bfd, callee_offset,
 	                   callee_image_id, app_id, debug_info);

 	if (cverb << vdebug) {
 		caller.verbose_bfd("Caller:");
 		callee.verbose_bfd("Callee:");
 	}

 	// For each symbol in the caller bfd, process all arcs to
 	// callee bfd symbols

 	for (symbol_index_t i = 0; i < caller_bfd.syms.size(); ++i) {

 		caller.caller_sym(i);

 		call_data::const_iterator dit = caller.samples.begin();
 		call_data::const_iterator dend = caller.samples.end();
 		while (dit != dend) {
 			// if we can't find the callee, skip an arc
 			if (!callee.callee_sym(key_to_callee(dit->first))) {
 				++dit;
 				continue;
 			}

 			count_array_t arc_count;
 			arc_count[pclass] =
 				accumulate_callee(dit, dend, callee.callee_end);

 			recorder.add(caller.sym, &callee.sym, arc_count);
 		}
 	}
 }


 void callgraph_container::add_symbols(profile_container const & pc)
 {
 	symbol_container::symbols_t::iterator it;
 	symbol_container::symbols_t::iterator const end = pc.end_symbol();

 	for (it = pc.begin_symbol(); it != end; ++it)
 		recorder.add(*it, 0, count_array_t());
 }


 column_flags callgraph_container::output_hint() const
 {
 	column_flags output_hints = cf_none;

 	// FIXME: costly: must we access directly recorder map ?
 	symbol_collection syms = recorder.get_symbols();

 	symbol_collection::iterator it;
 	symbol_collection::iterator const end = syms.end();
 	for (it = syms.begin(); it != end; ++it)
 		output_hints = (*it)->output_hint(output_hints);

 	return output_hints;
 }


 count_array_t callgraph_container::samples_count() const
 {
 	return total_count;
 }


 symbol_collection const & callgraph_container::get_symbols() const
 {
 	return recorder.get_symbols();
 }
	/**
	* @file callgraph_container.cpp
	* Container associating symbols and caller/caller symbols
	*
	* @remark Copyright 2004 OProfile authors
	* @remark Read the file COPYING
	*
	* @author Philippe Elie
	* @author John Levon
	*/

	#include <cstdlib>

	#include <map>
	#include <set>
	#include <algorithm>
	#include <iterator>
	#include <string>
	#include <iostream>
	#include <numeric>

	#include "callgraph_container.h"
	#include "cverb.h"
	#include "parse_filename.h"
	#include "profile_container.h"
	#include "arrange_profiles.h"
	#include "populate.h"
	#include "string_filter.h"
	#include "op_bfd.h"
	#include "op_sample_file.h"
	#include "locate_images.h"

	using namespace std;

	namespace {

	bool operator==(cg_symbol const & lhs, cg_symbol const & rhs)
	{
	less_symbol cmp_symb;
	return !cmp_symb(lhs, rhs) && !cmp_symb(rhs, lhs);
	}


	// we store {caller,callee} inside a single u64
	odb_key_t caller_to_key(u32 value)
	{
	return odb_key_t(value) << 32;
	}


	u32 key_to_callee(odb_key_t key)
	{
	return key & 0xffffffff;
	}


	bool compare_by_callee_vma(pair<odb_key_t, count_type> const & lhs,
	pair<odb_key_t, count_type> const & rhs)
	{
	return (key_to_callee(lhs.first)) < (key_to_callee(rhs.first));
	}


	/*
	* We need 2 comparators for callgraph to get the desired output:
	*
	* caller_with_few_samples
	* caller_with_many_samples
	* function_with_many_samples
	* callee_with_many_samples
	* callee_with_few_samples
	*/

	bool
	compare_arc_count(symbol_entry const & lhs, symbol_entry const & rhs)
	{
	return lhs.sample.counts[0] < rhs.sample.counts[0];
	}


	bool
	compare_arc_count_reverse(symbol_entry const & lhs, symbol_entry const & rhs)
	{
	return rhs.sample.counts[0] < lhs.sample.counts[0];
	}


	// find the nearest bfd symbol for the given file offset and check it's
	// in range
	op_bfd_symbol const *
	get_symbol_by_filepos(op_bfd const & bfd, u32 bfd_offset,
	vma_t offset, symbol_index_t & i)
	{
	offset += bfd_offset;
	op_bfd_symbol tmpsym(offset, 0, string());

	// sorted by filepos so this will find the nearest
	vector<op_bfd_symbol>::const_iterator it =
	upper_bound(bfd.syms.begin(), bfd.syms.end(), tmpsym);

	if (it != bfd.syms.begin())
	--it;

	if (it == bfd.syms.end()) {
	cerr << "get_symbol_by_filepos: no symbols at all?" << endl;
	abort();
	}

	// if the offset is past the end of the symbol, we didn't find one
	u32 const end_offset = it->size() + it->filepos();

	if (offset >= end_offset) {
	// let's be verbose for now
	cerr << "warning: dropping hyperspace sample at offset "
	<< hex << offset << " >= " << end_offset
	<< " for binary " << bfd.get_filename() << dec << endl;
	return NULL;
	}

	i = distance(bfd.syms.begin(), it);
	return &(*it);
	}


	/// temporary caller and callee data held during processing
	class call_data {
	public:
	call_data(profile_container const & p, profile_t const & pr,
	op_bfd const & bfd, u32 boff, image_name_id iid,
	image_name_id aid, bool debug_info)
	: pc(p), profile(pr), b(bfd), boffset(boff), image(iid),
	app(aid), debug(debug_info) {}

	/// point to a caller symbol
	void caller_sym(symbol_index_t i) {
	sym = symbol_entry();

	unsigned long long start;
	unsigned long long end;
	b.get_symbol_range(i, start, end);

	samples.clear();

	// see profile_t::samples_range() for why we need this check
	if (start > boffset) {
	profile_t::iterator_pair p_it = profile.samples_range(
	caller_to_key(start - boffset),
	caller_to_key(end - boffset));

	// Our odb_key_t contain (from_eip << 32 \| to_eip),
	// the range of keys we selected above contains one
	// caller but different callees, and due to the
	// ordering callee offsets are not consecutive: so
	// we must sort them first.

	for (; p_it.first != p_it.second; ++p_it.first) {
	samples.push_back(make_pair(p_it.first.vma(),
	p_it.first.count()));
	}

	sort(samples.begin(), samples.end(),
	compare_by_callee_vma);
	}

	sym.size = end - start;
	sym.name = symbol_names.create(b.syms[i].name());
	sym.sample.vma = b.syms[i].vma();

	finish_sym(i, start);

	if (cverb << vdebug) {
	cverb << vdebug << hex << "Caller sym: "
	<< b.syms[i].name() << " filepos " << start
	<< "-" << end << dec << endl;
	}
	}

	/// point to a callee symbol
	bool callee_sym(u32 off) {
	sym = symbol_entry();

	symbol_index_t i = 0;
	op_bfd_symbol const * bfdsym =
	get_symbol_by_filepos(b, boffset, off, i);

	if (!bfdsym)
	return false;

	callee_end = bfdsym->size() + bfdsym->filepos() - boffset;

	sym.size = bfdsym->size();
	sym.name = symbol_names.create(bfdsym->name());
	sym.sample.vma = bfdsym->vma();

	finish_sym(i, bfdsym->filepos());

	if (cverb << vdebug) {
	cverb << vdebug << hex << "Callee sym: "
	<< bfdsym->name() << " filepos "
	<< bfdsym->filepos() << "-"
	<< (bfdsym->filepos() + bfdsym->size())
	<< dec << endl;
	}
	return true;
	}

	void verbose_bfd(string const & prefix) const {
	cverb << vdebug << prefix << " " << b.get_filename()
	<< " offset " << boffset << " app "
	<< image_names.name(app) << endl;
	}

	typedef vector<pair<odb_key_t, count_type> > samples_t;

	typedef samples_t::const_iterator const_iterator;

	samples_t samples;
	symbol_entry sym;
	u32 callee_end;

	private:
	/// fill in the rest of the sym
	void finish_sym(symbol_index_t i, unsigned long start) {
	sym.image_name = image;
	sym.app_name = app;
	symbol_entry const * self = pc.find(sym);
	if (self)
	sym.sample.counts = self->sample.counts;

	if (debug) {
	string filename;
	file_location & loc = sym.sample.file_loc;
	if (b.get_linenr(i, start, filename, loc.linenr))
	loc.filename = debug_names.create(filename);
	}
	}

	profile_container const & pc;
	profile_t const & profile;
	op_bfd const & b;
	u32 boffset;
	image_name_id image;
	image_name_id app;
	bool debug;
	};


	/// accumulate all samples for a given caller/callee pair
	count_type
	accumulate_callee(call_data::const_iterator & it, call_data::const_iterator end,
	u32 callee_end)
	{
	count_type count = 0;
	call_data::const_iterator const start = it;

	while (it != end) {
	u32 offset = key_to_callee(it->first);

	if (cverb << (vdebug & vlevel1)) {
	cverb << (vdebug & vlevel1) << hex << "offset: "
	<< offset << dec << endl;
	}

	// stop if we pass the end of the callee
	if (offset >= callee_end)
	break;

	count += it->second;
	++it;
	}

	// If we haven't advanced at all, then we'll get
	// an infinite loop, so we must abort.
	if (it == start) {
	cerr << "failure to advance iterator\n";
	abort();
	}

	return count;
	}


	} // anonymous namespace


	void arc_recorder::
	add(symbol_entry const & caller, symbol_entry const * callee,
	count_array_t const & arc_count)
	{
	cg_data & data = sym_map[caller];

	// If we have a callee, add it to the caller's list, then
	// add the caller to the callee's list.
	if (callee) {
	data.callees[*callee] += arc_count;

	cg_data & callee_data = sym_map[*callee];

	callee_data.callers[caller] += arc_count;
	}
	}


	void arc_recorder::process_children(cg_symbol & sym, double threshold)
	{
	// generate the synthetic self entry for the symbol
	symbol_entry self = sym;

	self.name = symbol_names.create(symbol_names.demangle(self.name)
	+ " [self]");

	sym.total_callee_count += self.sample.counts;
	sym.callees.push_back(self);

	sort(sym.callers.begin(), sym.callers.end(), compare_arc_count);
	sort(sym.callees.begin(), sym.callees.end(), compare_arc_count_reverse);

	// FIXME: this relies on sort always being sample count

	cg_symbol::children::iterator cit = sym.callers.begin();
	cg_symbol::children::iterator cend = sym.callers.end();

	while (cit != cend && op_ratio(cit->sample.counts[0],
	sym.total_caller_count[0]) < threshold)
	++cit;

	if (cit != cend)
	sym.callers.erase(sym.callers.begin(), cit);

	cit = sym.callees.begin();
	cend = sym.callees.end();

	while (cit != cend && op_ratio(cit->sample.counts[0],
	sym.total_callee_count[0]) >= threshold)
	++cit;

	if (cit != cend)
	sym.callees.erase(cit, sym.callees.end());
	}


	void arc_recorder::
	process(count_array_t total, double threshold,
	string_filter const & sym_filter)
	{
	map_t::const_iterator it;
	map_t::const_iterator end = sym_map.end();

	for (it = sym_map.begin(); it != end; ++it) {
	cg_symbol sym((*it).first);
	cg_data const & data = (*it).second;

	// threshold out the main symbol if needed
	if (op_ratio(sym.sample.counts[0], total[0]) < threshold)
	continue;

	// FIXME: slow?
	if (!sym_filter.match(symbol_names.demangle(sym.name)))
	continue;

	cg_data::children::const_iterator cit;
	cg_data::children::const_iterator cend = data.callers.end();

	for (cit = data.callers.begin(); cit != cend; ++cit) {
	symbol_entry csym = cit->first;
	csym.sample.counts = cit->second;
	sym.callers.push_back(csym);
	sym.total_caller_count += cit->second;
	}

	cend = data.callees.end();

	for (cit = data.callees.begin(); cit != cend; ++cit) {
	symbol_entry csym = cit->first;
	csym.sample.counts = cit->second;
	sym.callees.push_back(csym);
	sym.total_callee_count += cit->second;
	}

	process_children(sym, threshold);

	// insert sym into cg_syms_objs
	// then store pointer to sym in cg_syms
	cg_syms.push_back(&(*cg_syms_objs.insert(cg_syms_objs.end(), sym)));
	}
	}


	symbol_collection const & arc_recorder::get_symbols() const
	{
	return cg_syms;
	}


	void callgraph_container::populate(list<inverted_profile> const & iprofiles,
	extra_images const & extra, bool debug_info, double threshold,
	bool merge_lib, string_filter const & sym_filter)
	{
	this->extra_found_images = extra;
	// non callgraph samples container, we record sample at symbol level
	// not at vma level.
	profile_container pc(debug_info, false, extra_found_images);

	list<inverted_profile>::const_iterator it;
	list<inverted_profile>::const_iterator const end = iprofiles.end();
	for (it = iprofiles.begin(); it != end; ++it) {
	// populate_caller_image take care about empty sample filename
	populate_for_image(pc, *it, sym_filter, 0);
	}

	add_symbols(pc);

	total_count = pc.samples_count();

	for (it = iprofiles.begin(); it != end; ++it) {
	for (size_t i = 0; i < it->groups.size(); ++i) {
	populate(it->groups[i], it->image,
	i, pc, debug_info, merge_lib);
	}
	}

	recorder.process(total_count, threshold / 100.0, sym_filter);
	}


	void callgraph_container::populate(list<image_set> const & lset,
	string const & app_image, size_t pclass,
	profile_container const & pc, bool debug_info, bool merge_lib)
	{
	list<image_set>::const_iterator lit;
	list<image_set>::const_iterator const lend = lset.end();
	for (lit = lset.begin(); lit != lend; ++lit) {
	list<profile_sample_files>::const_iterator pit;
	list<profile_sample_files>::const_iterator pend
	= lit->files.end();
	for (pit = lit->files.begin(); pit != pend; ++pit) {
	populate(pit->cg_files, app_image,
	pclass, pc, debug_info, merge_lib);
	}
	}
	}


	void callgraph_container::populate(list<string> const & cg_files,
	string const & app_image, size_t pclass,
	profile_container const & pc, bool debug_info, bool merge_lib)
	{
	list<string>::const_iterator it;
	list<string>::const_iterator const end = cg_files.end();
	for (it = cg_files.begin(); it != end; ++it) {
	cverb << vdebug << "samples file : " << *it << endl;

	parsed_filename caller_file =
	parse_filename(*it, extra_found_images);
	string const app_name = caller_file.image;

	image_error error;
	extra_found_images.find_image_path(caller_file.lib_image,
	error, false);

	if (error != image_ok)
	report_image_error(caller_file.lib_image,
	error, false, extra_found_images);

	bool caller_bfd_ok = true;
	op_bfd caller_bfd(caller_file.lib_image,
	string_filter(), extra_found_images, caller_bfd_ok);
	if (!caller_bfd_ok)
	report_image_error(caller_file.lib_image,
	image_format_failure, false,
	extra_found_images);

	parsed_filename callee_file =
	parse_filename(*it, extra_found_images);

	extra_found_images.find_image_path(callee_file.cg_image,
	error, false);
	if (error != image_ok)
	report_image_error(callee_file.cg_image,
	error, false, extra_found_images);

	bool callee_bfd_ok = true;
	op_bfd callee_bfd(callee_file.cg_image,
	string_filter(), extra_found_images, callee_bfd_ok);
	if (!callee_bfd_ok)
	report_image_error(callee_file.cg_image,
	image_format_failure, false,
	extra_found_images);

	profile_t profile;
	// We can't use start_offset support in profile_t, give
	// it a zero offset and we will fix that in add()
	profile.add_sample_file(*it);
	add(profile, caller_bfd, caller_bfd_ok, callee_bfd,
	merge_lib ? app_image : app_name, pc,
	debug_info, pclass);
	}
	}


	void callgraph_container::
	add(profile_t const & profile, op_bfd const & caller_bfd, bool caller_bfd_ok,
	op_bfd const & callee_bfd, string const & app_name,
	profile_container const & pc, bool debug_info, size_t pclass)
	{
	string const image_name = caller_bfd.get_filename();

	opd_header const & header = profile.get_header();

	// We can't use kernel sample file w/o the binary else we will
	// use it with a zero offset, the code below will abort because
	// we will get incorrect callee sub-range and out of range
	// callee vma. FIXME
	if (header.is_kernel && !caller_bfd_ok)
	return;

	// We must handle start_offset, this offset can be different for the
	// caller and the callee: kernel sample traversing the syscall barrier.
	u32 caller_offset;
	if (header.is_kernel)
	caller_offset = caller_bfd.get_start_offset(0);
	else
	caller_offset = header.anon_start;

	u32 callee_offset;
	if (header.cg_to_is_kernel)
	callee_offset = callee_bfd.get_start_offset(0);
	else
	callee_offset = header.cg_to_anon_start;

	image_name_id image_id = image_names.create(image_name);
	image_name_id callee_image_id = image_names.create(callee_bfd.get_filename());
	image_name_id app_id = image_names.create(app_name);

	call_data caller(pc, profile, caller_bfd, caller_offset, image_id,
	app_id, debug_info);
	call_data callee(pc, profile, callee_bfd, callee_offset,
	callee_image_id, app_id, debug_info);

	if (cverb << vdebug) {
	caller.verbose_bfd("Caller:");
	callee.verbose_bfd("Callee:");
	}

	// For each symbol in the caller bfd, process all arcs to
	// callee bfd symbols

	for (symbol_index_t i = 0; i < caller_bfd.syms.size(); ++i) {

	caller.caller_sym(i);

	call_data::const_iterator dit = caller.samples.begin();
	call_data::const_iterator dend = caller.samples.end();
	while (dit != dend) {
	// if we can't find the callee, skip an arc
	if (!callee.callee_sym(key_to_callee(dit->first))) {
	++dit;
	continue;
	}

	count_array_t arc_count;
	arc_count[pclass] =
	accumulate_callee(dit, dend, callee.callee_end);

	recorder.add(caller.sym, &callee.sym, arc_count);
	}
	}
	}


	void callgraph_container::add_symbols(profile_container const & pc)
	{
	symbol_container::symbols_t::iterator it;
	symbol_container::symbols_t::iterator const end = pc.end_symbol();

	for (it = pc.begin_symbol(); it != end; ++it)
	recorder.add(*it, 0, count_array_t());
	}


	column_flags callgraph_container::output_hint() const
	{
	column_flags output_hints = cf_none;

	// FIXME: costly: must we access directly recorder map ?
	symbol_collection syms = recorder.get_symbols();

	symbol_collection::iterator it;
	symbol_collection::iterator const end = syms.end();
	for (it = syms.begin(); it != end; ++it)
	output_hints = (*it)->output_hint(output_hints);

	return output_hints;
	}


	count_array_t callgraph_container::samples_count() const
	{
	return total_count;
	}


	symbol_collection const & callgraph_container::get_symbols() const
	{
	return recorder.get_symbols();
	}