Files
rocm-systems/source/lib/omnitrace/library/cpu_freq.cpp
T
Jonathan R. Madsen e7d3125459 restructure libomnitrace + tasking and omnitrace-causal updates (#237)
* restructured libomnitrace

- this is necessary to incorporate some of the binary analysis capabilities into omnitrace exe
- created libomnitrace-core (static)
- created libomnitrace-binary (static)
- created libomnitrace (static)
- omnitrace-avail links to libomnitrace.a
- omnitrace-critical-trace links to libomnitrace.a
- tweaked the testing
  - reduced verbosity on some of MPI tests
  - excluded trace-time-window from tests on Ubuntu 18.04
  - reduced causal e2e iterations
- minor tweak to tasking
  - manually create `PTL::UserTaskQueue` instance instead of relying on `PTL::ThreadPool` to create it

* Update formatting workflow

- source formatting uses ubuntu-22.04
- check-includes doesn't generate false positive for 'include "timemory.hpp"'

* omnitrace-causal --generate-configs

- fix config generation in omnitrace causal
- add test for omnitrace-causal + generating configs

* Fix omnitrace-object-library build

- accidentally included rocm sources in non-rocm builds

* Fix rocm compilation w/o rocprofiler

* update timemory submodule with mpi_get warning messages

* sampling offload file updates

- more verbose messages
- disable offload before stopping

* testing updates

- increase causal e2e iterations to 12
- increase lock_environment verbose to 2 (for sampling offload messages)
- fix return for omnitrace_add_validation_test
2023-02-04 10:59:50 -06:00

255 lines
9.0 KiB
C++

// MIT License
//
// Copyright (c) 2022 Advanced Micro Devices, Inc. All Rights Reserved.
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
#include "library/cpu_freq.hpp"
#include "core/common.hpp"
#include "core/components/fwd.hpp"
#include "core/config.hpp"
#include "core/debug.hpp"
#include "core/defines.hpp"
#include "core/perfetto.hpp"
#include "core/timemory.hpp"
#include "library/components/cpu_freq.hpp"
#include "library/thread_data.hpp"
#include "library/thread_info.hpp"
#include <timemory/components/rusage/backends.hpp>
#include <timemory/mpl/types.hpp>
#include <timemory/units.hpp>
#include <timemory/utility/procfs/cpuinfo.hpp>
#include <timemory/utility/type_list.hpp>
#include <cstddef>
#include <cstdlib>
#include <string>
#include <sys/resource.h>
#include <tuple>
#include <utility>
#include <vector>
namespace omnitrace
{
namespace cpu_freq
{
template <typename... Tp>
using type_list = tim::type_list<Tp...>;
namespace
{
using cpu_data_tuple_t = std::tuple<size_t, int64_t, int64_t, int64_t, int64_t, int64_t,
int64_t, int64_t, component::cpu_freq>;
std::deque<cpu_data_tuple_t> data = {};
template <typename... Types>
void init_perfetto_counter_tracks(type_list<Types...>)
{
(perfetto_counter_track<Types>::init(), ...);
}
} // namespace
} // namespace cpu_freq
} // namespace omnitrace
namespace omnitrace
{
namespace cpu_freq
{
void
setup()
{
init_perfetto_counter_tracks(
type_list<category::cpu_freq, category::process_page, category::process_virt,
category::process_peak, category::process_context_switch,
category::process_page_fault, category::process_user_mode_time,
category::process_kernel_mode_time>{});
}
void
config()
{
component::cpu_freq::configure();
}
void
sample()
{
auto _ts = tim::get_clock_real_now<size_t, std::nano>();
auto _rcache = tim::rusage_cache{ RUSAGE_SELF };
auto _freqs = component::cpu_freq{}.sample();
// user and kernel mode times are in microseconds
data.emplace_back(
_ts, tim::get_page_rss(), tim::get_virt_mem(), _rcache.get_peak_rss(),
_rcache.get_num_priority_context_switch() +
_rcache.get_num_voluntary_context_switch(),
_rcache.get_num_major_page_faults() + _rcache.get_num_minor_page_faults(),
_rcache.get_user_mode_time() * 1000, _rcache.get_kernel_mode_time() * 1000,
std::move(_freqs));
}
void
shutdown()
{}
namespace
{
template <typename... Types, size_t N = sizeof...(Types)>
void
config_perfetto_counter_tracks(type_list<Types...>, std::array<const char*, N> _labels,
std::array<const char*, N> _units)
{
static_assert(sizeof...(Types) == N,
"Error! Number of types != number of labels/units");
auto _config = [&](auto _t) {
using type = std::decay_t<decltype(_t)>;
using track = perfetto_counter_track<type>;
constexpr auto _idx = tim::index_of<type, type_list<Types...>>::value;
if(!track::exists(0))
{
auto addendum = [&](const char* _v) { return JOIN(" ", "CPU", _v, "(S)"); };
track::emplace(0, addendum(_labels.at(_idx)), _units.at(_idx));
}
};
(_config(Types{}), ...);
}
struct index
{
size_t value = 0;
};
template <typename Tp, typename... Args>
void
write_perfetto_counter_track(Args... _args)
{
using track = perfetto_counter_track<Tp>;
TRACE_COUNTER(trait::name<Tp>::value, track::at(0, 0), _args...);
}
template <typename Tp, typename... Args>
void
write_perfetto_counter_track(index&& _idx, Args... _args)
{
using track = perfetto_counter_track<Tp>;
TRACE_COUNTER(trait::name<Tp>::value, track::at(_idx.value, 0), _args...);
}
} // namespace
void
post_process()
{
OMNITRACE_VERBOSE(1,
"Post-processing %zu cpu frequency and memory usage entries...\n",
data.size());
auto _process_frequencies = [](size_t _idx, size_t _offset) {
using freq_track = perfetto_counter_track<category::cpu_freq>;
const auto& _thread_info = thread_info::get(0, InternalTID);
OMNITRACE_CI_THROW(!_thread_info, "Missing thread info for thread 0");
if(!_thread_info) return;
if(!freq_track::exists(_idx))
{
auto addendum = [&](const char* _v) {
return JOIN(" ", "CPU", _v, JOIN("", '[', _idx, ']'), "(S)");
};
freq_track::emplace(_idx, addendum("Frequency"), "MHz");
}
for(auto& itr : data)
{
uint64_t _ts = std::get<0>(itr);
double _freq = std::get<8>(itr).at(_offset);
if(!_thread_info->is_valid_time(_ts)) continue;
write_perfetto_counter_track<category::cpu_freq>(index{ _idx }, _ts, _freq);
}
auto _end_ts = _thread_info->get_stop();
write_perfetto_counter_track<category::cpu_freq>(index{ _idx }, _end_ts, 0);
};
auto _process_cpu_rusage = []() {
config_perfetto_counter_tracks(
type_list<category::process_page, category::process_virt,
category::process_peak, category::process_context_switch,
category::process_page_fault, category::process_user_mode_time,
category::process_kernel_mode_time>{},
{ "Memory Usage", "Virtual Memory Usage", "Peak Memory", "Context Switches",
"Page Faults", "User Time", "Kernel Time" },
{ "MB", "MB", "MB", "", "", "sec", "sec" });
const auto& _thread_info = thread_info::get(0, InternalTID);
OMNITRACE_CI_THROW(!_thread_info, "Missing thread info for thread 0");
if(!_thread_info) return;
for(auto& itr : data)
{
uint64_t _ts = std::get<0>(itr);
if(!_thread_info->is_valid_time(_ts)) continue;
double _page = std::get<1>(itr);
double _virt = std::get<2>(itr);
double _peak = std::get<3>(itr);
uint64_t _cntx = std::get<4>(itr);
uint64_t _flts = std::get<5>(itr);
double _user = std::get<6>(itr);
double _kern = std::get<7>(itr);
write_perfetto_counter_track<category::process_page>(_ts,
_page / units::megabyte);
write_perfetto_counter_track<category::process_virt>(_ts,
_virt / units::megabyte);
write_perfetto_counter_track<category::process_peak>(_ts,
_peak / units::megabyte);
write_perfetto_counter_track<category::process_context_switch>(_ts, _cntx);
write_perfetto_counter_track<category::process_page_fault>(_ts, _flts);
write_perfetto_counter_track<category::process_user_mode_time>(
_ts, _user / units::sec);
write_perfetto_counter_track<category::process_kernel_mode_time>(
_ts, _kern / units::sec);
}
auto _end_ts = _thread_info->get_stop();
write_perfetto_counter_track<category::process_page>(_end_ts, 0.0);
write_perfetto_counter_track<category::process_virt>(_end_ts, 0.0);
write_perfetto_counter_track<category::process_peak>(_end_ts, 0.0);
write_perfetto_counter_track<category::process_context_switch>(_end_ts, 0);
write_perfetto_counter_track<category::process_page_fault>(_end_ts, 0);
write_perfetto_counter_track<category::process_user_mode_time>(_end_ts, 0.0);
write_perfetto_counter_track<category::process_kernel_mode_time>(_end_ts, 0.0);
};
_process_cpu_rusage();
auto& enabled_cpu_freqs = component::cpu_freq::get_enabled_cpus();
for(auto itr = enabled_cpu_freqs.begin(); itr != enabled_cpu_freqs.end(); ++itr)
{
auto _idx = *itr;
auto _offset = std::distance(enabled_cpu_freqs.begin(), itr);
_process_frequencies(_idx, _offset);
}
enabled_cpu_freqs.clear();
}
} // namespace cpu_freq
} // namespace omnitrace