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

 /**
  * @file libpp/populate_for_spu.cpp
  * Fill up a profile_container from inverted profiles for
  * a Cell BE SPU profile
  *
  * @remark Copyright 2007 OProfile authors
  * @remark Read the file COPYING
  *
  * @author Maynard Johnson
  * (C) Copyright IBM Corporation 2007
  */

 #include "profile.h"
 #include "profile_container.h"
 #include "arrange_profiles.h"
 #include "op_bfd.h"
 #include "op_header.h"
 #include "populate.h"
 #include "populate_for_spu.h"

 #include "image_errors.h"

 #include <iostream>

 using namespace std;

 namespace {

 static int spu_profile = unknown_profile;

 /*
  * On Cell Broadband Engine, an application executing on an SPE may
  * have been loaded from a separate SPU executable binary file or may
  * have been loaded from an embedded section of a PPE application or
  * shared library.  In the embedded case, the embedding file may actually
  * contain multiple SPU images, resulting in different SPU images being loaded
  * onto different SPUs.  Thus, the SPUs may be executing different code, even
  * though the application of the parent PPE process is the same.  Therefore,
  * we must be sure to create a separate op_bfd object for each SPU.  When doing
  * so below, we examine header.embedded_offset.  If embedded_offset is > 0, it's
  * interpreted as the offset of an SPU image embedded in the containing file,
  * so the filename to do the check_mtime on is the containing file, ip.image;
  * otherwise, the filename to do the check_mtime on is the separate backing
  * file of the SPU image, abfd->filename.
  */
 void
 populate_spu_profile_from_files(list<profile_sample_files> const & files,
 				string const app_image,
 				profile_container & samples,
 				inverted_profile const & ip,
 				string_filter const & symbol_filter,
 				size_t ip_grp_num, bool * has_debug_info)
 {
 	string archive_path = samples.extra_found_images.get_archive_path();
 	bool ok = ip.error == image_ok;
 	op_bfd * abfd = NULL;
 	string fname_to_check;
 	list<profile_sample_files>::const_iterator it = files.begin();
 	list<profile_sample_files>::const_iterator const end = files.end();
 	for (; it != end; ++it) {
 		profile_t profile;
 		if (it->sample_filename.empty())
 			continue;

 		profile.add_sample_file(it->sample_filename);
 		opd_header header = profile.get_header();
 		if (header.embedded_offset) {
 			abfd = new op_bfd(header.embedded_offset,
 					  ip.image,
 					  symbol_filter,
 					  samples.extra_found_images,
 					  ok);
 			fname_to_check = ip.image;
 		} else {
 			abfd = new op_bfd(ip.image,
 					  symbol_filter,
 					  samples.extra_found_images,
 					  ok);
 			fname_to_check = abfd->get_filename();
 		}
 		profile.set_offset(*abfd);
 		if (!ok && ip.error == image_ok)
 			ip.error = image_format_failure;

 		if (ip.error == image_format_failure)
 			report_image_error(ip, false,
 					   samples.extra_found_images);

 		samples.add(profile, *abfd, app_image, ip_grp_num);
 		if (ip.error == image_ok) {
 			image_error error;
 			string filename =
 				samples.extra_found_images.find_image_path(
 					fname_to_check, error, true);
 			check_mtime(filename, profile.get_header());
 		}

 		if (has_debug_info && !*has_debug_info)
 			*has_debug_info = abfd->has_debug_info();
 		delete abfd;
 	}
 }
 }  // anon namespace

 void
 populate_for_spu_image(profile_container & samples,
 		       inverted_profile const & ip,
 		       string_filter const & symbol_filter,
 		       bool * has_debug_info)
 {

 	for (size_t i = 0; i < ip.groups.size(); ++i) {
 		list < image_set >::const_iterator it=
 			ip.groups[i].begin();
 		list < image_set >::const_iterator const end
 			= ip.groups[i].end();

 		for (; it != end; ++it)
 			populate_spu_profile_from_files(it->files,
 				it->app_image, samples, ip,
 				symbol_filter, i, has_debug_info);
 	}
 }

 bool is_spu_profile(inverted_profile const & ip)
 {
 	bool retval = false;
 	string sfname = "";
 	if (spu_profile != unknown_profile)
 		return spu_profile;

 	if (!ip.groups.size())
 		return false;

 	for (size_t i = 0; i < ip.groups.size(); ++i) {
 		list<image_set>::const_iterator grp_it
 			= ip.groups[i].begin();
 		list<image_set>::const_iterator const grp_end
 			= ip.groups[i].end();

 		for (; grp_it != grp_end; ++grp_it) {
 			list<profile_sample_files>::const_iterator sfiles_it =
 				grp_it->files.begin();
 			list<profile_sample_files>::const_iterator sfiles_end =
 				grp_it->files.end();
 			for (; sfiles_it != sfiles_end; ++sfiles_it) {
 				if (!sfiles_it->sample_filename.empty()) {
 					sfname = sfiles_it->sample_filename;
 					goto do_check;
 				}
 			}
 		}
 	}
 	goto out;

 do_check:
 	spu_profile = profile_t::is_spu_sample_file(sfname);

 	if (spu_profile == cell_spu_profile)
 		retval = true;

 out:
 	return retval;
 }
	/**
	* @file libpp/populate_for_spu.cpp
	* Fill up a profile_container from inverted profiles for
	* a Cell BE SPU profile
	*
	* @remark Copyright 2007 OProfile authors
	* @remark Read the file COPYING
	*
	* @author Maynard Johnson
	* (C) Copyright IBM Corporation 2007
	*/

	#include "profile.h"
	#include "profile_container.h"
	#include "arrange_profiles.h"
	#include "op_bfd.h"
	#include "op_header.h"
	#include "populate.h"
	#include "populate_for_spu.h"

	#include "image_errors.h"

	#include <iostream>

	using namespace std;

	namespace {

	static int spu_profile = unknown_profile;

	/*
	* On Cell Broadband Engine, an application executing on an SPE may
	* have been loaded from a separate SPU executable binary file or may
	* have been loaded from an embedded section of a PPE application or
	* shared library. In the embedded case, the embedding file may actually
	* contain multiple SPU images, resulting in different SPU images being loaded
	* onto different SPUs. Thus, the SPUs may be executing different code, even
	* though the application of the parent PPE process is the same. Therefore,
	* we must be sure to create a separate op_bfd object for each SPU. When doing
	* so below, we examine header.embedded_offset. If embedded_offset is > 0, it's
	* interpreted as the offset of an SPU image embedded in the containing file,
	* so the filename to do the check_mtime on is the containing file, ip.image;
	* otherwise, the filename to do the check_mtime on is the separate backing
	* file of the SPU image, abfd->filename.
	*/
	void
	populate_spu_profile_from_files(list<profile_sample_files> const & files,
	string const app_image,
	profile_container & samples,
	inverted_profile const & ip,
	string_filter const & symbol_filter,
	size_t ip_grp_num, bool * has_debug_info)
	{
	string archive_path = samples.extra_found_images.get_archive_path();
	bool ok = ip.error == image_ok;
	op_bfd * abfd = NULL;
	string fname_to_check;
	list<profile_sample_files>::const_iterator it = files.begin();
	list<profile_sample_files>::const_iterator const end = files.end();
	for (; it != end; ++it) {
	profile_t profile;
	if (it->sample_filename.empty())
	continue;

	profile.add_sample_file(it->sample_filename);
	opd_header header = profile.get_header();
	if (header.embedded_offset) {
	abfd = new op_bfd(header.embedded_offset,
	ip.image,
	symbol_filter,
	samples.extra_found_images,
	ok);
	fname_to_check = ip.image;
	} else {
	abfd = new op_bfd(ip.image,
	symbol_filter,
	samples.extra_found_images,
	ok);
	fname_to_check = abfd->get_filename();
	}
	profile.set_offset(*abfd);
	if (!ok && ip.error == image_ok)
	ip.error = image_format_failure;

	if (ip.error == image_format_failure)
	report_image_error(ip, false,
	samples.extra_found_images);

	samples.add(profile, *abfd, app_image, ip_grp_num);
	if (ip.error == image_ok) {
	image_error error;
	string filename =
	samples.extra_found_images.find_image_path(
	fname_to_check, error, true);
	check_mtime(filename, profile.get_header());
	}

	if (has_debug_info && !*has_debug_info)
	*has_debug_info = abfd->has_debug_info();
	delete abfd;
	}
	}
	} // anon namespace

	void
	populate_for_spu_image(profile_container & samples,
	inverted_profile const & ip,
	string_filter const & symbol_filter,
	bool * has_debug_info)
	{

	for (size_t i = 0; i < ip.groups.size(); ++i) {
	list < image_set >::const_iterator it=
	ip.groups[i].begin();
	list < image_set >::const_iterator const end
	= ip.groups[i].end();

	for (; it != end; ++it)
	populate_spu_profile_from_files(it->files,
	it->app_image, samples, ip,
	symbol_filter, i, has_debug_info);
	}
	}

	bool is_spu_profile(inverted_profile const & ip)
	{
	bool retval = false;
	string sfname = "";
	if (spu_profile != unknown_profile)
	return spu_profile;

	if (!ip.groups.size())
	return false;

	for (size_t i = 0; i < ip.groups.size(); ++i) {
	list<image_set>::const_iterator grp_it
	= ip.groups[i].begin();
	list<image_set>::const_iterator const grp_end
	= ip.groups[i].end();

	for (; grp_it != grp_end; ++grp_it) {
	list<profile_sample_files>::const_iterator sfiles_it =
	grp_it->files.begin();
	list<profile_sample_files>::const_iterator sfiles_end =
	grp_it->files.end();
	for (; sfiles_it != sfiles_end; ++sfiles_it) {
	if (!sfiles_it->sample_filename.empty()) {
	sfname = sfiles_it->sample_filename;
	goto do_check;
	}
	}
	}
	}
	goto out;

	do_check:
	spu_profile = profile_t::is_spu_sample_file(sfname);

	if (spu_profile == cell_spu_profile)
	retval = true;

	out:
	return retval;
	}