Files
rocm-systems/source/lib/omnitrace/library/thread_data.hpp
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

618 wiersze
20 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.
#pragma once
#include "api.hpp"
#include "core/common.hpp"
#include "core/concepts.hpp"
#include "core/config.hpp"
#include "core/containers/stable_vector.hpp"
#include "core/defines.hpp"
#include "core/state.hpp"
#include "core/timemory.hpp"
#include "core/utility.hpp"
#include "library/thread_deleter.hpp"
#include <timemory/utility/macros.hpp>
#include <timemory/utility/types.hpp>
#include <array>
#include <cstdint>
#include <cstdlib>
#include <memory>
#include <optional>
#include <type_traits>
#include <vector>
namespace omnitrace
{
// bundle of components used in instrumentation
using instrumentation_bundle_t =
tim::component_bundle<project::omnitrace, comp::wall_clock*,
comp::user_global_bundle*>;
// allocator for instrumentation_bundle_t
using bundle_allocator_t = tim::data::ring_buffer_allocator<instrumentation_bundle_t>;
using grow_functor_t = int64_t (*)(int64_t);
inline auto&
grow_functors()
{
static auto _v = container::stable_vector<grow_functor_t>{};
return _v;
}
template <typename Tp>
struct base_thread_data
{
base_thread_data()
{
auto _func = [](int64_t _sz) -> int64_t {
auto& _v = Tp::instance();
if(_v && _v->capacity() < static_cast<size_t>(_sz + 1))
{
_v->reserve(_v->capacity() + 1);
_v->resize(_v->capacity());
}
return (_v) ? _v->capacity() : 0;
};
grow_functors().emplace_back(std::move(_func));
}
};
template <typename Tp, typename Tag = void, size_t MaxThreads = max_supported_threads>
struct thread_data
{
using value_type = unique_ptr_t<Tp>;
using instance_array_t = std::array<value_type, MaxThreads>;
template <typename... Args>
static void construct(construct_on_thread&&, Args&&...);
static value_type& instance();
static instance_array_t& instances();
template <typename... Args>
static value_type& instance(construct_on_thread&&, Args&&...);
template <typename... Args>
static instance_array_t& instances(construct_on_init, Args&&...);
template <typename... Args>
static void construct(Args&&... args)
{
construct(construct_on_thread{}, std::forward<Args>(args)...);
}
template <typename... Args>
static value_type& instance(Args&&... args)
{
return instance(construct_on_thread{}, std::forward<Args>(args)...);
}
static constexpr size_t size() { return MaxThreads; }
decltype(auto) begin() { return instances().begin(); }
decltype(auto) end() { return instances().end(); }
decltype(auto) begin() const { return instances().begin(); }
decltype(auto) end() const { return instances().end(); }
};
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
void
thread_data<Tp, Tag, MaxThreads>::construct(construct_on_thread&& _t, Args&&... _args)
{
// construct outside of lambda to prevent data-race
static auto& _instances = instances();
if(!_instances.at(_t.index))
_instances.at(_t.index) =
utility::generate<value_type>{}(std::forward<Args>(_args)...);
}
template <typename Tp, typename Tag, size_t MaxThreads>
unique_ptr_t<Tp>&
thread_data<Tp, Tag, MaxThreads>::instance()
{
return instances().at(threading::get_id());
}
template <typename Tp, typename Tag, size_t MaxThreads>
typename thread_data<Tp, Tag, MaxThreads>::instance_array_t&
thread_data<Tp, Tag, MaxThreads>::instances()
{
static auto _v = instance_array_t{};
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
unique_ptr_t<Tp>&
thread_data<Tp, Tag, MaxThreads>::instance(construct_on_thread&& _t, Args&&... _args)
{
construct(construct_on_thread{ _t }, std::forward<Args>(_args)...);
return instances().at(_t.index);
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
typename thread_data<Tp, Tag, MaxThreads>::instance_array_t&
thread_data<Tp, Tag, MaxThreads>::instances(construct_on_init, Args&&... _args)
{
static auto& _v = [&]() -> instance_array_t& {
auto& _internal = instances();
for(size_t i = 0; i < MaxThreads; ++i)
_internal.at(i) =
utility::generate<value_type>{}(std::forward<Args>(_args)...);
return _internal;
}();
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
struct use_placement_new_when_generating_unique_ptr<
thread_data<std::optional<Tp>, Tag, MaxThreads>> : std::true_type
{};
template <typename Tp, typename Tag, size_t MaxThreads>
struct use_placement_new_when_generating_unique_ptr<
thread_data<identity<Tp>, Tag, MaxThreads>> : std::true_type
{};
//--------------------------------------------------------------------------------------//
//
// thread_data with std::optional
//
//--------------------------------------------------------------------------------------//
template <typename Tp, typename Tag, size_t MaxThreads>
struct thread_data<std::optional<Tp>, Tag, MaxThreads>
: base_thread_data<thread_data<std::optional<Tp>, Tag, MaxThreads>>
{
using this_type = thread_data<std::optional<Tp>, Tag, MaxThreads>;
using value_type = std::optional<Tp>;
using array_type = container::stable_vector<value_type, MaxThreads>;
using functor_type = std::function<value_type()>;
thread_data() = default;
~thread_data() = default;
explicit thread_data(functor_type&& _init)
: m_init{ std::move(_init) }
{}
thread_data(const thread_data&) = default;
thread_data(thread_data&&) noexcept = default;
thread_data& operator=(const thread_data&) = default;
thread_data& operator=(thread_data&&) noexcept = default;
static unique_ptr_t<this_type>& instance();
template <typename... Args>
static unique_ptr_t<this_type>& instance(construct_on_init, Args&&...);
template <typename... Args>
static value_type& instance(construct_on_thread&&, Args&&...);
template <typename... Args>
static unique_ptr_t<this_type>& construct(construct_on_init, Args&&...);
template <typename... Args>
static value_type& construct(construct_on_thread&&, Args&&...);
size_t size() { return m_data.size(); }
decltype(auto) data() { return m_data; }
decltype(auto) data() const { return m_data; }
decltype(auto) begin() { return m_data.begin(); }
decltype(auto) end() { return m_data.end(); }
decltype(auto) begin() const { return m_data.begin(); }
decltype(auto) end() const { return m_data.end(); }
decltype(auto) at(size_t _idx) { return m_data.at(_idx); }
decltype(auto) at(size_t _idx) const { return m_data.at(_idx); }
decltype(auto) operator[](size_t _idx) { return m_data[_idx]; }
decltype(auto) operator[](size_t _idx) const { return m_data[_idx]; }
decltype(auto) reserve(size_t _n) { return m_data.reserve(_n); }
decltype(auto) capacity() const { return m_data.capacity(); }
decltype(auto) empty() const { return m_data.empty(); }
void resize(size_t _n) { container::resize(m_data, _n, m_init()); }
template <typename Up>
void resize(size_t _n, Up&& _v)
{
static_assert(std::is_assignable<value_type, Up>::value,
"value is not assignable to optional<Tp>");
container::resize(m_data, _n, std::forward<Up>(_v));
}
private:
array_type m_data = {};
functor_type m_init = []() { return value_type{}; };
};
template <typename Tp, typename Tag, size_t MaxThreads>
unique_ptr_t<thread_data<std::optional<Tp>, Tag, MaxThreads>>&
thread_data<std::optional<Tp>, Tag, MaxThreads>::instance()
{
static auto _v = unique_ptr_t<this_type>{};
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
unique_ptr_t<thread_data<std::optional<Tp>, Tag, MaxThreads>>&
thread_data<std::optional<Tp>, Tag, MaxThreads>::instance(construct_on_init,
Args&&... _args)
{
static auto& _v = [&]() -> unique_ptr_t<this_type>& {
auto& _ref = instance();
if(!_ref)
_ref = utility::generate<unique_ptr_t<this_type>>{}(
std::forward<Args>(_args)...);
if(_ref->size() < MaxThreads) _ref->resize(MaxThreads);
return _ref;
}();
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
unique_ptr_t<thread_data<std::optional<Tp>, Tag, MaxThreads>>&
thread_data<std::optional<Tp>, Tag, MaxThreads>::construct(construct_on_init,
Args&&... _args)
{
// construct outside of lambda to prevent data-race
static auto& _ref = instance(construct_on_init{});
static auto _v = [&]() {
if(_ref)
{
for(auto& itr : *_ref)
itr = utility::generate<value_type>{}(std::forward<Args>(_args)...);
}
return (_ref != nullptr);
}();
return _ref;
(void) _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
std::optional<Tp>&
thread_data<std::optional<Tp>, Tag, MaxThreads>::construct(construct_on_thread&& _t,
Args&&... _args)
{
// construct outside of lambda to prevent data-race
static auto& _instance = instance(construct_on_init{});
static auto _constructed = container::stable_vector<bool, MaxThreads>{};
static auto _grow = []() {
container::resize(_constructed, MaxThreads, false);
grow_functors().emplace_back([](int64_t _n) -> int64_t {
if(static_cast<size_t>(_n) >= _constructed.size())
{
_constructed.reserve(_constructed.capacity() + 1);
container::resize(_constructed, _constructed.capacity(), false);
}
return _constructed.size();
});
return true;
}();
if(!_constructed.at(_t.index))
_constructed.at(_t.index) =
(_instance->at(_t.index) =
utility::generate<value_type>{}(std::forward<Args>(_args)...),
true);
return _instance->at(_t.index);
(void) _grow;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
std::optional<Tp>&
thread_data<std::optional<Tp>, Tag, MaxThreads>::instance(construct_on_thread&& _t,
Args&&... _args)
{
construct(construct_on_thread{ _t }, std::forward<Args>(_args)...);
return instance()->at(_t.index);
}
//--------------------------------------------------------------------------------------//
//
// thread_data with raw data (no pointer)
//
//--------------------------------------------------------------------------------------//
template <typename Tp, typename Tag, size_t MaxThreads>
struct thread_data<identity<Tp>, Tag, MaxThreads>
: base_thread_data<thread_data<identity<Tp>, Tag, MaxThreads>>
{
using this_type = thread_data<identity<Tp>, Tag, MaxThreads>;
using value_type = Tp;
using array_type = container::stable_vector<value_type, MaxThreads>;
using functor_type = std::function<value_type()>;
thread_data() = default;
~thread_data() = default;
explicit thread_data(functor_type&& _init)
: m_init{ std::move(_init) }
{}
thread_data(const thread_data&) = default;
thread_data(thread_data&&) noexcept = default;
thread_data& operator=(const thread_data&) = default;
thread_data& operator=(thread_data&&) noexcept = default;
static unique_ptr_t<this_type>& instance();
template <typename... Args>
static unique_ptr_t<this_type>& instance(construct_on_init, Args&&...);
template <typename... Args>
static value_type& instance(construct_on_thread&&, Args&&...);
template <typename... Args>
static unique_ptr_t<this_type>& construct(construct_on_init, Args&&...);
template <typename... Args>
static value_type& construct(construct_on_thread&&, Args&&...);
size_t size() { return m_data.size(); }
decltype(auto) data() { return m_data; }
decltype(auto) data() const { return m_data; }
decltype(auto) begin() { return m_data.begin(); }
decltype(auto) end() { return m_data.end(); }
decltype(auto) begin() const { return m_data.begin(); }
decltype(auto) end() const { return m_data.end(); }
decltype(auto) at(size_t _idx) { return m_data.at(_idx); }
decltype(auto) at(size_t _idx) const { return m_data.at(_idx); }
decltype(auto) operator[](size_t _idx) { return m_data[_idx]; }
decltype(auto) operator[](size_t _idx) const { return m_data[_idx]; }
decltype(auto) reserve(size_t _n) { return m_data.reserve(_n); }
decltype(auto) capacity() const { return m_data.capacity(); }
decltype(auto) empty() const { return m_data.empty(); }
void resize(size_t _n) { container::resize(m_data, _n, m_init()); }
void resize(size_t _n, value_type&& _v) { container::resize(m_data, _n, _v); }
void fill(value_type _v)
{
for(auto& itr : m_data)
itr = _v;
}
private:
array_type m_data = {};
functor_type m_init = []() { return value_type{}; };
};
template <typename Tp, typename Tag, size_t MaxThreads>
unique_ptr_t<thread_data<identity<Tp>, Tag, MaxThreads>>&
thread_data<identity<Tp>, Tag, MaxThreads>::instance()
{
static auto _v = unique_ptr_t<this_type>{};
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
unique_ptr_t<thread_data<identity<Tp>, Tag, MaxThreads>>&
thread_data<identity<Tp>, Tag, MaxThreads>::instance(construct_on_init, Args&&... _args)
{
static auto& _v = [&]() -> unique_ptr_t<this_type>& {
auto& _ref = instance();
if(!_ref)
_ref = utility::generate<unique_ptr_t<this_type>>{}(
std::forward<Args>(_args)...);
if(_ref->size() < MaxThreads) _ref->resize(MaxThreads);
return _ref;
}();
return _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
unique_ptr_t<thread_data<identity<Tp>, Tag, MaxThreads>>&
thread_data<identity<Tp>, Tag, MaxThreads>::construct(construct_on_init, Args&&... _args)
{
// construct outside of lambda to prevent data-race
static auto& _ref = instance(construct_on_init{});
static auto _v = [&]() {
if(_ref)
{
for(auto& itr : *_ref)
itr = utility::generate<value_type>{}(std::forward<Args>(_args)...);
}
return (_ref != nullptr);
}();
return _ref;
(void) _v;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
Tp&
thread_data<identity<Tp>, Tag, MaxThreads>::construct(construct_on_thread&& _t,
Args&&... _args)
{
// construct outside of lambda to prevent data-race
static auto& _instance = instance(construct_on_init{});
static auto _constructed = container::stable_vector<bool, MaxThreads>{};
static auto _grow = []() {
container::resize(_constructed, MaxThreads, false);
grow_functors().emplace_back([](int64_t _n) -> int64_t {
if(static_cast<size_t>(_n) >= _constructed.size())
{
_constructed.reserve(_constructed.capacity() + 1);
container::resize(_constructed, _constructed.capacity(), false);
}
return _constructed.size();
});
return true;
}();
if(!_constructed.at(_t.index))
_constructed.at(_t.index) =
(_instance->at(_t.index) =
utility::generate<value_type>{}(std::forward<Args>(_args)...),
true);
return _instance->at(_t.index);
(void) _grow;
}
template <typename Tp, typename Tag, size_t MaxThreads>
template <typename... Args>
Tp&
thread_data<identity<Tp>, Tag, MaxThreads>::instance(construct_on_thread&& _t,
Args&&... _args)
{
construct(construct_on_thread{ _t }, std::forward<Args>(_args)...);
return instance()->at(_t.index);
}
//--------------------------------------------------------------------------------------//
// there are currently some strange things that happen with
// vector<instrumentation_bundle_t> so using vector<instrumentation_bundle_t*> and
// timemory's ring_buffer_allocator to create contiguous memory-page aligned instances of
// the bundle
template <typename... Tp>
struct component_bundle_cache
{
using bundle_type = tim::component_bundle<project::omnitrace, Tp...>;
using this_type = component_bundle_cache<Tp...>;
using allocator_type = tim::data::ring_buffer_allocator<bundle_type>;
using instance_type =
std::array<component_bundle_cache<Tp...>, max_supported_threads>;
using iterator = typename std::vector<bundle_type*>::iterator;
using const_iterator = typename std::vector<bundle_type*>::const_iterator;
using reverse_iterator = typename std::vector<bundle_type*>::reverse_iterator;
allocator_type allocator = {};
std::vector<bundle_type*> bundles = {};
bool empty() const { return bundles.empty(); }
auto& front() { return bundles.front(); }
auto& front() const { return bundles.front(); }
auto& back() { return bundles.back(); }
auto& back() const { return bundles.back(); }
auto begin() { return bundles.begin(); }
auto end() { return bundles.end(); }
auto rbegin() { return bundles.rbegin(); }
auto rend() { return bundles.rend(); }
auto begin() const { return bundles.begin(); }
auto end() const { return bundles.end(); }
auto size() const { return bundles.size(); }
auto& at(size_t _idx) { return bundles.at(_idx); }
const auto& at(size_t _idx) const { return bundles.at(_idx); }
static auto& instances()
{
static auto _v = instance_type{};
return _v;
}
static auto& instance(int64_t _tid) { return instances().at(_tid); }
template <typename... Args>
bundle_type* construct(Args&&... args)
{
bundle_type* _v = allocator.allocate(1);
allocator.construct(_v, std::forward<Args>(args)...);
return bundles.emplace_back(_v);
}
void destroy(bundle_type* _v, size_t _idx)
{
allocator.destroy(_v);
allocator.deallocate(_v, 1);
bundles.erase(bundles.begin() + _idx);
}
void pop_back()
{
bundle_type* _v = bundles.back();
allocator.destroy(_v);
allocator.deallocate(_v, 1);
bundles.pop_back();
}
template <typename IterT>
void destroy(IterT _v)
{
iterator itr = begin();
if constexpr(std::is_same<IterT, reverse_iterator>::value)
{
if(_v == rend()) return;
std::advance(itr, std::distance(rbegin(), _v));
}
else
{
if(_v == end()) return;
itr = _v;
}
allocator.destroy(*itr);
allocator.deallocate(*itr, 1);
bundles.erase(itr);
}
};
template <typename... Tp>
struct component_bundle_cache<tim::component_bundle<project::omnitrace, Tp...>>
: component_bundle_cache<Tp...>
{
using base_type = component_bundle_cache<Tp...>;
using base_type::allocator;
using base_type::bundles;
using base_type::instances;
};
using instrumentation_bundles = component_bundle_cache<instrumentation_bundle_t>;
extern template struct component_bundle_cache<instrumentation_bundle_t>;
} // namespace omnitrace