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rocm-systems/samples/pc_sampling/pcs.cpp
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Vladimir Indic 0f89f0449d PC sampling: chiplet id + integration test fix (#983)
* PCS: show chiplet; cover loading/unloading in integration test

* Use (code_object_id, pc_addr) pair as instruction id.
2024-07-22 16:00:59 +05:30

353 linhas
14 KiB
C++

// MIT License
//
// Copyright (c) 2023 ROCm Developer Tools
//
// 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.
// undefine NDEBUG so asserts are implemented
#ifdef NDEBUG
# undef NDEBUG
#endif
#include "pcs.hpp"
#include "utils.hpp"
#include "common/defines.hpp"
#include <cassert>
#include <cstdio>
#include <iomanip>
#include <memory>
#include <sstream>
namespace client
{
namespace pcs
{
// TODO: Since this is used only within the `tool_init`,
// we are safe using static constructor.
// It would be nice to make this consistent with the `buffer_ids`.
tool_agent_info_vec_t gpu_agents;
// The reason for using raw pointers is the following.
// Sometimes, statically created objects of the client::pcs
// namespace might be freed prior to the `tool_fini`,
// meaning `buffer_ids` become unusable inside `tool_fini`.
// Instead, use raw pointers to control objects deallocation time.
// TODO: The approach with exporting raw pointers outside of the
// `pcs` namespace is a temporary solution.
// Instead, it would be better to encapsulate `buffer_ids` inside the
// `pcs` namespace and export functions for registering/flushing/destroying buffers.
pc_sampling_buffer_id_vec_t* buffer_ids = nullptr;
void
init()
{
buffer_ids = new pc_sampling_buffer_id_vec_t();
}
void
fini()
{
// Clear the data
buffer_ids->clear();
delete buffer_ids;
}
pc_sampling_buffer_id_vec_t*
get_pc_sampling_buffer_ids()
{
return buffer_ids;
}
rocprofiler_status_t
find_all_gpu_agents_supporting_pc_sampling_impl(rocprofiler_agent_version_t version,
const void** agents,
size_t num_agents,
void* user_data)
{
assert(version == ROCPROFILER_AGENT_INFO_VERSION_0);
// user_data represent the pointer to the array where gpu_agent will be stored
if(!user_data) return ROCPROFILER_STATUS_ERROR;
std::stringstream ss;
auto* _out_agents = static_cast<tool_agent_info_vec_t*>(user_data);
auto* _agents = reinterpret_cast<const rocprofiler_agent_t**>(agents);
for(size_t i = 0; i < num_agents; i++)
{
if(_agents[i]->type == ROCPROFILER_AGENT_TYPE_GPU)
{
// Instantiate the tool_agent_info.
// Store pointer to the rocprofiler_agent_t and instatiate a vector of
// available configurations.
// Move the ownership to the _out_agents
auto tool_gpu_agent = std::make_unique<tool_agent_info>();
tool_gpu_agent->agent_id = _agents[i]->id;
tool_gpu_agent->avail_configs = std::make_unique<avail_configs_vec_t>();
tool_gpu_agent->agent = _agents[i];
// Check if the GPU agent supports PC sampling. If so, add it to the
// output list `_out_agents`.
if(query_avail_configs_for_agent(tool_gpu_agent.get()))
_out_agents->push_back(std::move(tool_gpu_agent));
}
ss << "[" << __FUNCTION__ << "] " << _agents[i]->name << " :: "
<< "id=" << _agents[i]->id.handle << ", "
<< "type=" << _agents[i]->type << "\n";
}
*utils::get_output_stream() << ss.str() << std::endl;
return ROCPROFILER_STATUS_SUCCESS;
}
void
find_all_gpu_agents_supporting_pc_sampling()
{
// This function returns the all gpu agents supporting some kind of PC sampling
ROCPROFILER_CHECK(
rocprofiler_query_available_agents(ROCPROFILER_AGENT_INFO_VERSION_0,
&find_all_gpu_agents_supporting_pc_sampling_impl,
sizeof(rocprofiler_agent_t),
static_cast<void*>(&gpu_agents)));
}
/**
* @brief The function queries available PC sampling configurations.
* If there is at least one available configuration, it returns true.
* Otherwise, this function returns false to indicate the agent does
* not support PC sampling.
*/
bool
query_avail_configs_for_agent(tool_agent_info* agent_info)
{
// Clear the available configurations vector
agent_info->avail_configs->clear();
auto cb = [](const rocprofiler_pc_sampling_configuration_t* configs,
size_t num_config,
void* user_data) {
auto* avail_configs = static_cast<avail_configs_vec_t*>(user_data);
for(size_t i = 0; i < num_config; i++)
{
avail_configs->emplace_back(configs[i]);
}
return ROCPROFILER_STATUS_SUCCESS;
};
auto status = rocprofiler_query_pc_sampling_agent_configurations(
agent_info->agent_id, cb, agent_info->avail_configs.get());
std::stringstream ss;
if(status != ROCPROFILER_STATUS_SUCCESS)
{
// The query operation failed, so consider the PC sampling is unsupported at the agent.
// This can happen if the PC sampling service is invoked within the ROCgdb.
ss << "Querying PC sampling capabilities failed with status=" << status
<< " :: " << rocprofiler_get_status_string(status) << std::endl;
*utils::get_output_stream() << ss.str() << std::endl;
return false;
}
else if(agent_info->avail_configs->empty())
{
// No available configuration at the moment, so mark the PC sampling as unsupported.
return false;
}
ss << "The agent with the id: " << agent_info->agent_id.handle << " supports the "
<< agent_info->avail_configs->size() << " configurations: " << std::endl;
size_t ind = 0;
for(auto& cfg : *agent_info->avail_configs)
{
ss << "(" << ++ind << ".) "
<< "method: " << cfg.method << ", "
<< "unit: " << cfg.unit << ", "
<< "min_interval: " << cfg.min_interval << ", "
<< "max_interval: " << cfg.max_interval << ", "
<< "flags: " << std::hex << cfg.flags << std::dec << std::endl;
}
*utils::get_output_stream() << ss.str() << std::flush;
return true;
}
void
configure_pc_sampling_prefer_stochastic(tool_agent_info* agent_info,
rocprofiler_context_id_t context_id,
rocprofiler_buffer_id_t buffer_id)
{
int failures = 10;
size_t interval = 0;
do
{
// Update the list of available configurations
auto success = query_avail_configs_for_agent(agent_info);
if(!success)
{
// An error occured while querying PC sampling capabilities,
// so avoid trying configuring PC sampling service.
// Instead return false to indicated a failure.
ROCPROFILER_CHECK(ROCPROFILER_STATUS_ERROR);
}
const rocprofiler_pc_sampling_configuration_t* first_host_trap_config = nullptr;
const rocprofiler_pc_sampling_configuration_t* first_stochastic_config = nullptr;
// Search until encountering on the stochastic configuration, if any.
// Otherwise, use the host trap config
for(auto const& cfg : *agent_info->avail_configs)
{
if(cfg.method == ROCPROFILER_PC_SAMPLING_METHOD_STOCHASTIC)
{
first_stochastic_config = &cfg;
break;
}
else if(!first_host_trap_config &&
cfg.method == ROCPROFILER_PC_SAMPLING_METHOD_HOST_TRAP)
{
first_host_trap_config = &cfg;
}
}
// Check if the stochastic config is found. Use host trap config otherwise.
const rocprofiler_pc_sampling_configuration_t* picked_cfg =
(first_stochastic_config != nullptr) ? first_stochastic_config : first_host_trap_config;
if(picked_cfg->min_interval == picked_cfg->max_interval)
{
// Another process already configured PC sampling, so use the intreval it set up.
interval = picked_cfg->min_interval;
}
else
{
interval = 10000;
}
auto status = rocprofiler_configure_pc_sampling_service(context_id,
agent_info->agent_id,
picked_cfg->method,
picked_cfg->unit,
interval,
buffer_id);
if(status == ROCPROFILER_STATUS_SUCCESS)
{
*utils::get_output_stream()
<< ">>> We chose PC sampling interval: " << interval
<< " on the agent: " << agent_info->agent->id.handle << std::endl;
return;
}
else if(status != ROCPROFILER_STATUS_ERROR_NOT_AVAILABLE)
{
ROCPROFILER_CHECK(status);
}
// status == ROCPROFILER_STATUS_ERROR_NOT_AVAILABLE
// means another process P2 already configured PC sampling.
// Query available configurations again and receive the configurations picked by P2.
// However, if P2 destroys PC sampling service after query function finished,
// but before the `rocprofiler_configure_pc_sampling_service` is called,
// then the `rocprofiler_configure_pc_sampling_service` will fail again.
// The process P1 executing this loop can spin wait (starve) if it is unlucky enough
// to always be interuppted by some other process P2 that creates/destroys
// PC sampling service on the same device while P1 is executing the code
// after the `query_avail_configs_for_agent` and
// before the `rocprofiler_configure_pc_sampling_service`.
// This should happen very rarely, but just to be sure, we introduce a counter `failures`
// that will allow certain amount of failures to process P1.
} while(--failures);
// The process failed too many times configuring PC sampling,
// report this to user;
ROCPROFILER_CHECK(ROCPROFILER_STATUS_ERROR);
}
void
rocprofiler_pc_sampling_callback(rocprofiler_context_id_t /*context_id*/,
rocprofiler_buffer_id_t /*buffer_id*/,
rocprofiler_record_header_t** headers,
size_t num_headers,
void* /*data*/,
uint64_t drop_count)
{
std::stringstream ss;
ss << "The number of delivered samples is: " << num_headers << ", "
<< "while the number of dropped samples is: " << drop_count << std::endl;
for(size_t i = 0; i < num_headers; i++)
{
auto* cur_header = headers[i];
if(cur_header == nullptr)
{
throw std::runtime_error{
"rocprofiler provided a null pointer to header. this should never happen"};
}
else if(cur_header->hash !=
rocprofiler_record_header_compute_hash(cur_header->category, cur_header->kind))
{
throw std::runtime_error{"rocprofiler_record_header_t (category | kind) != hash"};
}
else if(cur_header->category == ROCPROFILER_BUFFER_CATEGORY_PC_SAMPLING)
{
if(cur_header->kind == ROCPROFILER_PC_SAMPLING_RECORD_SAMPLE)
{
auto* pc_sample =
static_cast<rocprofiler_pc_sampling_record_t*>(cur_header->payload);
ss << "pc: " << std::hex << pc_sample->pc << ", "
<< "timestamp: " << std::dec << pc_sample->timestamp << ", "
<< "exec: " << std::hex << std::setw(16) << pc_sample->exec_mask << ", "
<< "workgroup_id_(x=" << std::dec << std::setw(5) << pc_sample->workgroup_id.x
<< ", "
<< "y=" << std::setw(5) << pc_sample->workgroup_id.y << ", "
<< "z=" << std::setw(5) << pc_sample->workgroup_id.z << "), "
<< "wave_id: " << std::setw(2) << static_cast<unsigned int>(pc_sample->wave_id)
<< ", "
<< "chiplet: " << std::setw(2) << static_cast<unsigned int>(pc_sample->chiplet)
<< ", "
<< "cu_id: " << pc_sample->hw_id << ", "
<< "correlation: {internal=" << std::setw(7)
<< pc_sample->correlation_id.internal << ", "
<< "external=" << std::setw(5) << pc_sample->correlation_id.external.value << "}"
<< std::endl;
}
else if(cur_header->kind == ROCPROFILER_PC_SAMPLING_RECORD_CODE_OBJECT_LOAD_MARKER)
{
auto* marker = static_cast<rocprofiler_pc_sampling_code_object_load_marker_t*>(
cur_header->payload);
ss << "code object loading: " << marker->code_object_id << std::endl;
}
else if(cur_header->kind == ROCPROFILER_PC_SAMPLING_RECORD_CODE_OBJECT_UNLOAD_MARKER)
{
auto* marker = static_cast<rocprofiler_pc_sampling_code_object_unload_marker_t*>(
cur_header->payload);
ss << "code object unloading: " << marker->code_object_id << std::endl;
}
}
else
{
throw std::runtime_error{"unexpected rocprofiler_record_header_t category + kind"};
}
}
*utils::get_output_stream() << ss.str() << std::endl;
}
} // namespace pcs
} // namespace client