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[/] [altor32/] [trunk/] [gcc-x64/] [or1knd-elf/] [or1knd-elf/] [include/] [c++/] [4.8.0/] [profile/] [impl/] [profiler_trace.h] - Rev 35
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// -*- C++ -*- // // Copyright (C) 2009, 2010 Free Software Foundation, Inc. // // This file is part of the GNU ISO C++ Library. This library is free // software; you can redistribute it and/or modify it under the // terms of the GNU General Public License as published by the // Free Software Foundation; either version 3, or (at your option) // any later version. // // This library 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 for more details. // Under Section 7 of GPL version 3, you are granted additional // permissions described in the GCC Runtime Library Exception, version // 3.1, as published by the Free Software Foundation. // You should have received a copy of the GNU General Public License along // with this library; see the file COPYING3. If not see // <http://www.gnu.org/licenses/>. /** @file profile/impl/profiler_trace.h * @brief Data structures to represent profiling traces. */ // Written by Lixia Liu and Silvius Rus. #ifndef _GLIBCXX_PROFILE_PROFILER_TRACE_H #define _GLIBCXX_PROFILE_PROFILER_TRACE_H 1 #include <cstdio> // fopen, fclose, fprintf, FILE #include <cerrno> #include <cstdlib> // atof, atoi, strtol, getenv, atexit, abort #if __cplusplus >= 201103L #define _GLIBCXX_IMPL_UNORDERED_MAP std::_GLIBCXX_STD_C::unordered_map #include <unordered_map> #else #include <tr1/unordered_map> #define _GLIBCXX_IMPL_UNORDERED_MAP std::tr1::unordered_map #endif #include <ext/concurrence.h> #include <fstream> #include <string> #include <utility> #include <vector> #include "profile/impl/profiler_algos.h" #include "profile/impl/profiler_state.h" #include "profile/impl/profiler_node.h" namespace __gnu_profile { /** @brief Internal environment. Values can be set one of two ways: 1. In config file "var = value". The default config file path is libstdcxx-profile.conf. 2. By setting process environment variables. For instance, in a Bash shell you can set the unit cost of iterating through a map like this: export __map_iterate_cost_factor=5.0. If a value is set both in the input file and through an environment variable, the environment value takes precedence. */ typedef _GLIBCXX_IMPL_UNORDERED_MAP<std::string, std::string> __env_t; _GLIBCXX_PROFILE_DEFINE_UNINIT_DATA(__env_t, __env); /** @brief Master lock. */ _GLIBCXX_PROFILE_DEFINE_UNINIT_DATA(__gnu_cxx::__mutex, __global_lock); /** @brief Representation of a warning. */ struct __warning_data { float __magnitude; __stack_t __context; const char* __warning_id; std::string __warning_message; __warning_data() : __magnitude(0.0), __context(0), __warning_id(0) { } __warning_data(float __m, __stack_t __c, const char* __id, const std::string& __msg) : __magnitude(__m), __context(__c), __warning_id(__id), __warning_message(__msg) { } bool operator<(const __warning_data& __other) const { return __magnitude < __other.__magnitude; } }; typedef std::_GLIBCXX_STD_C::vector<__warning_data> __warning_vector_t; // Defined in profiler_<diagnostic name>.h. class __trace_hash_func; class __trace_hashtable_size; class __trace_map2umap; class __trace_vector_size; class __trace_vector_to_list; class __trace_list_to_slist; class __trace_list_to_vector; void __trace_vector_size_init(); void __trace_hashtable_size_init(); void __trace_hash_func_init(); void __trace_vector_to_list_init(); void __trace_list_to_slist_init(); void __trace_list_to_vector_init(); void __trace_map_to_unordered_map_init(); void __trace_vector_size_report(FILE*, __warning_vector_t&); void __trace_hashtable_size_report(FILE*, __warning_vector_t&); void __trace_hash_func_report(FILE*, __warning_vector_t&); void __trace_vector_to_list_report(FILE*, __warning_vector_t&); void __trace_list_to_slist_report(FILE*, __warning_vector_t&); void __trace_list_to_vector_report(FILE*, __warning_vector_t&); void __trace_map_to_unordered_map_report(FILE*, __warning_vector_t&); struct __cost_factor { const char* __env_var; float __value; }; typedef std::_GLIBCXX_STD_C::vector<__cost_factor*> __cost_factor_vector; _GLIBCXX_PROFILE_DEFINE_DATA(__trace_hash_func*, _S_hash_func, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_hashtable_size*, _S_hashtable_size, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_map2umap*, _S_map2umap, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_vector_size*, _S_vector_size, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_vector_to_list*, _S_vector_to_list, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_list_to_slist*, _S_list_to_slist, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__trace_list_to_vector*, _S_list_to_vector, 0); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __vector_shift_cost_factor, {"__vector_shift_cost_factor", 1.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __vector_iterate_cost_factor, {"__vector_iterate_cost_factor", 1.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __vector_resize_cost_factor, {"__vector_resize_cost_factor", 1.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __list_shift_cost_factor, {"__list_shift_cost_factor", 0.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __list_iterate_cost_factor, {"__list_iterate_cost_factor", 10.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __list_resize_cost_factor, {"__list_resize_cost_factor", 0.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __map_insert_cost_factor, {"__map_insert_cost_factor", 1.5}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __map_erase_cost_factor, {"__map_erase_cost_factor", 1.5}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __map_find_cost_factor, {"__map_find_cost_factor", 1}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __map_iterate_cost_factor, {"__map_iterate_cost_factor", 2.3}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __umap_insert_cost_factor, {"__umap_insert_cost_factor", 12.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __umap_erase_cost_factor, {"__umap_erase_cost_factor", 12.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __umap_find_cost_factor, {"__umap_find_cost_factor", 10.0}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor, __umap_iterate_cost_factor, {"__umap_iterate_cost_factor", 1.7}); _GLIBCXX_PROFILE_DEFINE_DATA(__cost_factor_vector*, __cost_factors, 0); _GLIBCXX_PROFILE_DEFINE_DATA(const char*, _S_trace_file_name, _GLIBCXX_PROFILE_TRACE_PATH_ROOT); _GLIBCXX_PROFILE_DEFINE_DATA(std::size_t, _S_max_warn_count, _GLIBCXX_PROFILE_MAX_WARN_COUNT); _GLIBCXX_PROFILE_DEFINE_DATA(std::size_t, _S_max_stack_depth, _GLIBCXX_PROFILE_MAX_STACK_DEPTH); _GLIBCXX_PROFILE_DEFINE_DATA(std::size_t, _S_max_mem, _GLIBCXX_PROFILE_MEM_PER_DIAGNOSTIC); inline std::size_t __stack_max_depth() { return _GLIBCXX_PROFILE_DATA(_S_max_stack_depth); } inline std::size_t __max_mem() { return _GLIBCXX_PROFILE_DATA(_S_max_mem); } /** @brief Base class for all trace producers. */ template<typename __object_info, typename __stack_info> class __trace_base { public: // Do not pick the initial size too large, as we don't know which // diagnostics are more active. __trace_base() : __object_table(10000), __stack_table(10000), __stack_table_byte_size(0), __id(0) { } virtual ~__trace_base() { } void __add_object(__object_t object, __object_info __info); __object_info* __get_object_info(__object_t __object); void __retire_object(__object_t __object); void __write(FILE* __f); void __collect_warnings(__warning_vector_t& __warnings); private: __gnu_cxx::__mutex __object_table_lock; __gnu_cxx::__mutex __stack_table_lock; typedef _GLIBCXX_IMPL_UNORDERED_MAP<__object_t, __object_info> __object_table_t; typedef _GLIBCXX_IMPL_UNORDERED_MAP<__stack_t, __stack_info, __stack_hash, __stack_hash> __stack_table_t; __object_table_t __object_table; __stack_table_t __stack_table; std::size_t __stack_table_byte_size; protected: const char* __id; }; template<typename __object_info, typename __stack_info> void __trace_base<__object_info, __stack_info>:: __collect_warnings(__warning_vector_t& __warnings) { for (typename __stack_table_t::iterator __it = __stack_table.begin(); __it != __stack_table.end(); ++__it) __warnings.push_back(__warning_data((*__it).second.__magnitude(), (*__it).first, __id, (*__it).second.__advice())); } template<typename __object_info, typename __stack_info> void __trace_base<__object_info, __stack_info>:: __add_object(__object_t __object, __object_info __info) { if (__max_mem() == 0 || __object_table.size() * sizeof(__object_info) <= __max_mem()) { this->__object_table_lock.lock(); __object_table.insert(typename __object_table_t:: value_type(__object, __info)); this->__object_table_lock.unlock(); } } template<typename __object_info, typename __stack_info> __object_info* __trace_base<__object_info, __stack_info>:: __get_object_info(__object_t __object) { // XXX: Revisit this to see if we can decrease mutex spans. // Without this mutex, the object table could be rehashed during an // insertion on another thread, which could result in a segfault. this->__object_table_lock.lock(); typename __object_table_t::iterator __object_it = __object_table.find(__object); if (__object_it == __object_table.end()) { this->__object_table_lock.unlock(); return 0; } else { this->__object_table_lock.unlock(); return &__object_it->second; } } template<typename __object_info, typename __stack_info> void __trace_base<__object_info, __stack_info>:: __retire_object(__object_t __object) { this->__object_table_lock.lock(); this->__stack_table_lock.lock(); typename __object_table_t::iterator __object_it = __object_table.find(__object); if (__object_it != __object_table.end()) { const __object_info& __info = __object_it->second; const __stack_t& __stack = __info.__stack(); typename __stack_table_t::iterator __stack_it = __stack_table.find(__stack); if (__stack_it == __stack_table.end()) { // First occurence of this call context. if (__max_mem() == 0 || __stack_table_byte_size < __max_mem()) { __stack_table_byte_size += (sizeof(__instruction_address_t) * __size(__stack) + sizeof(__stack) + sizeof(__stack_info)); __stack_table.insert(make_pair(__stack, __stack_info(__info))); } } else { // Merge object info into info summary for this call context. __stack_it->second.__merge(__info); delete __stack; } __object_table.erase(__object); } this->__object_table_lock.unlock(); this->__stack_table_lock.unlock(); } template<typename __object_info, typename __stack_info> void __trace_base<__object_info, __stack_info>:: __write(FILE* __f) { for (typename __stack_table_t::iterator __it = __stack_table.begin(); __it != __stack_table.end(); ++__it) if (__it->second.__is_valid()) { std::fprintf(__f, __id); std::fprintf(__f, "|"); __gnu_profile::__write(__f, __it->first); std::fprintf(__f, "|"); __it->second.__write(__f); } } inline std::size_t __env_to_size_t(const char* __env_var, std::size_t __default_value) { char* __env_value = std::getenv(__env_var); if (__env_value) { errno = 0; long __converted_value = std::strtol(__env_value, 0, 10); if (errno || __converted_value < 0) { std::fprintf(stderr, "Bad value for environment variable '%s'.\n", __env_var); std::abort(); } else return static_cast<std::size_t>(__converted_value); } else return __default_value; } inline void __set_max_stack_trace_depth() { _GLIBCXX_PROFILE_DATA(_S_max_stack_depth) = __env_to_size_t(_GLIBCXX_PROFILE_MAX_STACK_DEPTH_ENV_VAR, _GLIBCXX_PROFILE_DATA(_S_max_stack_depth)); } inline void __set_max_mem() { _GLIBCXX_PROFILE_DATA(_S_max_mem) = __env_to_size_t(_GLIBCXX_PROFILE_MEM_PER_DIAGNOSTIC_ENV_VAR, _GLIBCXX_PROFILE_DATA(_S_max_mem)); } inline int __log_magnitude(float __f) { const float __log_base = 10.0; int __result = 0; int __sign = 1; if (__f < 0) { __f = -__f; __sign = -1; } while (__f > __log_base) { ++__result; __f /= 10.0; } return __sign * __result; } inline FILE* __open_output_file(const char* __extension) { // The path is made of _S_trace_file_name + "." + extension. std::size_t __root_len = __builtin_strlen(_GLIBCXX_PROFILE_DATA(_S_trace_file_name)); std::size_t __ext_len = __builtin_strlen(__extension); char* __file_name = new char[__root_len + 1 + __ext_len + 1]; __builtin_memcpy(__file_name, _GLIBCXX_PROFILE_DATA(_S_trace_file_name), __root_len); *(__file_name + __root_len) = '.'; __builtin_memcpy(__file_name + __root_len + 1, __extension, __ext_len + 1); FILE* __out_file = std::fopen(__file_name, "w"); if (!__out_file) { std::fprintf(stderr, "Could not open trace file '%s'.\n", __file_name); std::abort(); } delete[] __file_name; return __out_file; } struct __warn { FILE* __file; __warn(FILE* __f) { __file = __f; } void operator()(const __warning_data& __info) { std::fprintf(__file, __info.__warning_id); std::fprintf(__file, ": improvement = %d", __log_magnitude(__info.__magnitude)); std::fprintf(__file, ": call stack = "); __gnu_profile::__write(__file, __info.__context); std::fprintf(__file, ": advice = %s\n", __info.__warning_message.c_str()); } }; /** @brief Final report method, registered with @b atexit. * * This can also be called directly by user code, including signal handlers. * It is protected against deadlocks by the reentrance guard in profiler.h. * However, when called from a signal handler that triggers while within * __gnu_profile (under the guarded zone), no output will be produced. */ inline void __report(void) { _GLIBCXX_PROFILE_DATA(__global_lock).lock(); __warning_vector_t __warnings, __top_warnings; FILE* __raw_file = __open_output_file("raw"); __trace_vector_size_report(__raw_file, __warnings); __trace_hashtable_size_report(__raw_file, __warnings); __trace_hash_func_report(__raw_file, __warnings); __trace_vector_to_list_report(__raw_file, __warnings); __trace_list_to_slist_report(__raw_file, __warnings); __trace_list_to_vector_report(__raw_file, __warnings); __trace_map_to_unordered_map_report(__raw_file, __warnings); std::fclose(__raw_file); // Sort data by magnitude, keeping just top N. std::size_t __cutoff = std::min(_GLIBCXX_PROFILE_DATA(_S_max_warn_count), __warnings.size()); __top_n(__warnings, __top_warnings, __cutoff); FILE* __warn_file = __open_output_file("txt"); __for_each(__top_warnings.begin(), __top_warnings.end(), __warn(__warn_file)); std::fclose(__warn_file); _GLIBCXX_PROFILE_DATA(__global_lock).unlock(); } inline void __set_trace_path() { char* __env_trace_file_name = std::getenv(_GLIBCXX_PROFILE_TRACE_ENV_VAR); if (__env_trace_file_name) _GLIBCXX_PROFILE_DATA(_S_trace_file_name) = __env_trace_file_name; // Make sure early that we can create the trace file. std::fclose(__open_output_file("txt")); } inline void __set_max_warn_count() { char* __env_max_warn_count_str = std::getenv(_GLIBCXX_PROFILE_MAX_WARN_COUNT_ENV_VAR); if (__env_max_warn_count_str) _GLIBCXX_PROFILE_DATA(_S_max_warn_count) = static_cast<std::size_t>(std::atoi(__env_max_warn_count_str)); } inline void __read_cost_factors() { std::string __conf_file_name(_GLIBCXX_PROFILE_DATA(_S_trace_file_name)); __conf_file_name += ".conf"; std::ifstream __conf_file(__conf_file_name.c_str()); if (__conf_file.is_open()) { std::string __line; while (std::getline(__conf_file, __line)) { std::string::size_type __i = __line.find_first_not_of(" \t\n\v"); if (__line.length() <= 0 || __line[__i] == '#') // Skip empty lines or comments. continue; } // Trim. __line.erase(__remove(__line.begin(), __line.end(), ' '), __line.end()); std::string::size_type __pos = __line.find("="); std::string __factor_name = __line.substr(0, __pos); std::string::size_type __end = __line.find_first_of(";\n"); std::string __factor_value = __line.substr(__pos + 1, __end - __pos); _GLIBCXX_PROFILE_DATA(__env)[__factor_name] = __factor_value; } } struct __cost_factor_writer { FILE* __file; __cost_factor_writer(FILE* __f) : __file(__f) { } void operator() (const __cost_factor* __factor) { std::fprintf(__file, "%s = %f\n", __factor->__env_var, __factor->__value); } }; inline void __write_cost_factors() { FILE* __file = __open_output_file("conf.out"); __for_each(_GLIBCXX_PROFILE_DATA(__cost_factors)->begin(), _GLIBCXX_PROFILE_DATA(__cost_factors)->end(), __cost_factor_writer(__file)); std::fclose(__file); } struct __cost_factor_setter { void operator()(__cost_factor* __factor) { // Look it up in the process environment first. const char* __env_value = std::getenv(__factor->__env_var); if (!__env_value) { // Look it up in the config file. __env_t::iterator __it = _GLIBCXX_PROFILE_DATA(__env).find(__factor->__env_var); if (__it != _GLIBCXX_PROFILE_DATA(__env).end()) __env_value = (*__it).second.c_str(); } if (__env_value) __factor->__value = std::atof(__env_value); } }; inline void __set_cost_factors() { _GLIBCXX_PROFILE_DATA(__cost_factors) = new __cost_factor_vector; _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__vector_shift_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__vector_iterate_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__vector_resize_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__list_shift_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__list_iterate_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__list_resize_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__map_insert_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__map_erase_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__map_find_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__map_iterate_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__umap_insert_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__umap_erase_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__umap_find_cost_factor)); _GLIBCXX_PROFILE_DATA(__cost_factors)-> push_back(&_GLIBCXX_PROFILE_DATA(__umap_iterate_cost_factor)); __for_each(_GLIBCXX_PROFILE_DATA(__cost_factors)->begin(), _GLIBCXX_PROFILE_DATA(__cost_factors)->end(), __cost_factor_setter()); } inline void __profcxx_init_unconditional() { _GLIBCXX_PROFILE_DATA(__global_lock).lock(); if (__is_invalid()) { __set_max_warn_count(); if (_GLIBCXX_PROFILE_DATA(_S_max_warn_count) == 0) __turn_off(); else { __set_max_stack_trace_depth(); __set_max_mem(); __set_trace_path(); __read_cost_factors(); __set_cost_factors(); __write_cost_factors(); __trace_vector_size_init(); __trace_hashtable_size_init(); __trace_hash_func_init(); __trace_vector_to_list_init(); __trace_list_to_slist_init(); __trace_list_to_vector_init(); __trace_map_to_unordered_map_init(); std::atexit(__report); __turn_on(); } } _GLIBCXX_PROFILE_DATA(__global_lock).unlock(); } /** @brief This function must be called by each instrumentation point. * * The common path is inlined fully. */ inline bool __profcxx_init() { if (__is_invalid()) __profcxx_init_unconditional(); return __is_on(); } } // namespace __gnu_profile #endif /* _GLIBCXX_PROFILE_PROFILER_TRACE_H */