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rocm-systems/source/lib/rocprofiler-sdk/counters/device_counting.cpp
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Rawat, Swati 97b7a6315d update copyright date to 2025 (#102)
* Update LICENSE

* Update conf.py

* Update copyright year

* [fix] Update copyright year

* Update copyright year "ROCm Developer Tools"

* Add license headers to c++ files

* Add license to *.py

* Update licenses in rocdecode sources

---------

Co-authored-by: srawat <120587655+SwRaw@users.noreply.github.com>
Co-authored-by: Mythreya <mythreya.kuricheti@amd.com>
Co-authored-by: Jonathan R. Madsen <jonathanrmadsen@gmail.com>
2025-01-22 19:11:20 -06:00

601 строка
24 KiB
C++

// MIT License
//
// Copyright (c) 2023-2025 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 "lib/rocprofiler-sdk/counters/device_counting.hpp"
#include "lib/common/logging.hpp"
#include "lib/rocprofiler-sdk/buffer.hpp"
#include "lib/rocprofiler-sdk/context/context.hpp"
#include "lib/rocprofiler-sdk/counters/controller.hpp"
#include "lib/rocprofiler-sdk/counters/core.hpp"
#include "lib/rocprofiler-sdk/counters/id_decode.hpp"
#include "lib/rocprofiler-sdk/hsa/agent_cache.hpp"
#include "lib/rocprofiler-sdk/hsa/hsa.hpp"
#include "lib/rocprofiler-sdk/hsa/queue_controller.hpp"
#include "lib/rocprofiler-sdk/hsa/rocprofiler_packet.hpp"
#include <rocprofiler-sdk/fwd.h>
#include <chrono>
#include <cstdint>
#include <unordered_map>
namespace rocprofiler
{
namespace counters
{
std::atomic<bool>&
hsa_inited()
{
static std::atomic<bool> inited{false};
return inited;
}
uint64_t
submitPacket(hsa_queue_t* queue, const void* packet)
{
const uint32_t pkt_size = 0x40;
// advance command queue
const uint64_t write_idx =
hsa::get_core_table()->hsa_queue_add_write_index_scacq_screl_fn(queue, 1);
while((write_idx - hsa::get_core_table()->hsa_queue_load_read_index_relaxed_fn(queue)) >=
queue->size)
{
sched_yield();
}
const uint32_t slot_idx = (uint32_t)(write_idx % queue->size);
// NOLINTBEGIN(performance-no-int-to-ptr)
uint32_t* queue_slot =
reinterpret_cast<uint32_t*>((uintptr_t)(queue->base_address) + (slot_idx * pkt_size));
// NOLINTEND(performance-no-int-to-ptr)
const uint32_t* slot_data = reinterpret_cast<const uint32_t*>(packet);
// Copy buffered commands into the queue slot.
// Overwrite the AQL invalid header (first dword) last.
// This prevents the slot from being read until it's fully written.
memcpy(&queue_slot[1], &slot_data[1], pkt_size - sizeof(uint32_t));
std::atomic<uint32_t>* header_atomic_ptr =
reinterpret_cast<std::atomic<uint32_t>*>(&queue_slot[0]);
header_atomic_ptr->store(slot_data[0], std::memory_order_release);
// ringdoor bell
hsa::get_core_table()->hsa_signal_store_relaxed_fn(queue->doorbell_signal, write_idx);
return write_idx;
}
namespace
{
uint16_t
header_pkt(hsa_packet_type_t type)
{
uint16_t header = type << HSA_PACKET_HEADER_TYPE;
header |= 1 << HSA_PACKET_HEADER_BARRIER;
header |= HSA_FENCE_SCOPE_SYSTEM << HSA_PACKET_HEADER_SCACQUIRE_FENCE_SCOPE;
header |= HSA_FENCE_SCOPE_SYSTEM << HSA_PACKET_HEADER_SCRELEASE_FENCE_SCOPE;
return header;
}
std::unique_ptr<hsa::CounterAQLPacket>
construct_aql_pkt(std::shared_ptr<profile_config>& profile)
{
if(counter_callback_info::setup_profile_config(profile) != ROCPROFILER_STATUS_SUCCESS)
{
return nullptr;
}
auto pkts = profile->pkt_generator->construct_packet(
CHECK_NOTNULL(hsa::get_queue_controller())->get_core_table(),
CHECK_NOTNULL(hsa::get_queue_controller())->get_ext_table());
pkts->packets.start_packet.header = header_pkt(HSA_PACKET_TYPE_VENDOR_SPECIFIC);
pkts->packets.stop_packet.header = header_pkt(HSA_PACKET_TYPE_VENDOR_SPECIFIC);
pkts->packets.read_packet.header = header_pkt(HSA_PACKET_TYPE_VENDOR_SPECIFIC);
pkts->packets.start_packet.completion_signal.handle = 0;
return pkts;
}
bool
agent_async_handler(hsa_signal_value_t /*signal_v*/, void* data)
{
if(!data) return false;
const auto& callback_data = *static_cast<rocprofiler::counters::agent_callback_data*>(data);
const auto& prof_config = callback_data.profile;
// Decode the AQL packet data
auto decoded_pkt =
EvaluateAST::read_pkt(prof_config->pkt_generator.get(), *callback_data.packet);
EvaluateAST::read_special_counters(
*prof_config->agent, prof_config->required_special_counters, decoded_pkt);
auto* buf = buffer::get_buffer(callback_data.buffer.handle);
if(!buf)
{
ROCP_FATAL << fmt::format("Buffer {} destroyed before record was written",
callback_data.buffer.handle);
return false;
}
if(decoded_pkt.empty())
{
// reset the signal to allow another sample to start
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.completion, 1);
return true;
}
// Write out the AQL data to the buffer
for(auto& ast : prof_config->asts)
{
std::vector<std::unique_ptr<std::vector<rocprofiler_record_counter_t>>> cache;
auto* ret = CHECK_NOTNULL(ast.evaluate(decoded_pkt, cache));
ast.set_out_id(*ret);
for(auto& val : *ret)
{
val.user_data = callback_data.user_data;
val.agent_id = prof_config->agent->id;
if(callback_data.cached_counters)
{
callback_data.cached_counters->push_back(val);
}
buf->emplace(
ROCPROFILER_BUFFER_CATEGORY_COUNTERS, ROCPROFILER_COUNTER_RECORD_VALUE, val);
}
}
// reset the signal to allow another sample to start
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.completion, 1);
return true;
}
/**
* Setup the agent for handling profiling. This includes setting up the AQL packet,
* setting up the async handler, and (if this is the first time profiling) setting
* the profiling register on the queue. This function should only be called when
* the context is in the LOCKED status.
*/
void
init_callback_data(rocprofiler::counters::agent_callback_data& callback_data,
const hsa::AgentCache& agent)
{
// we have already setup this ctx
if(callback_data.packet) return;
callback_data.packet = construct_aql_pkt(callback_data.profile);
callback_data.queue = agent.profile_queue();
if(callback_data.completion.handle != 0) return;
CHECK(hsa::get_core_table() != nullptr);
CHECK(hsa::get_amd_ext_table() != nullptr);
CHECK(hsa::get_core_table()->hsa_signal_create_fn != nullptr);
CHECK(hsa::get_core_table()->hsa_signal_wait_relaxed_fn != nullptr);
CHECK(hsa::get_core_table()->hsa_signal_store_relaxed_fn != nullptr);
CHECK(hsa::get_amd_ext_table()->hsa_amd_signal_async_handler_fn != nullptr);
// Tri-state signal
// 1: allow next sample to start
// 0: sample in progress
// -1: sample complete
CHECK_EQ(hsa::get_core_table()->hsa_signal_create_fn(1, 0, nullptr, &callback_data.completion),
HSA_STATUS_SUCCESS);
// Signal to manage the startup of the context. Allows us to ensure that
// the AQL packet we inject with start_context() completes before returning
CHECK_EQ(
hsa::get_core_table()->hsa_signal_create_fn(1, 0, nullptr, &callback_data.start_signal),
HSA_STATUS_SUCCESS);
// Setup callback
// NOLINTBEGIN(performance-no-int-to-ptr)
CHECK_EQ(hsa::get_amd_ext_table()->hsa_amd_signal_async_handler_fn(callback_data.completion,
HSA_SIGNAL_CONDITION_LT,
0,
agent_async_handler,
&callback_data),
HSA_STATUS_SUCCESS);
// NOLINTEND(performance-no-int-to-ptr)
// If we do not have a completion handle, this is our first time profiling this agent.
// Setup our shared data structures.
static std::unordered_set<hsa_queue_t*> queues_init;
if(queues_init.find(callback_data.queue) != queues_init.end()) return;
queues_init.insert(callback_data.queue);
// Set state of the queue to allow profiling (may not be needed since AQL
// may do this in the future).
CHECK(agent.cpu_pool().handle != 0);
CHECK(agent.get_hsa_agent().handle != 0);
aql::set_profiler_active_on_queue(
agent.cpu_pool(), agent.get_hsa_agent(), [&](hsa::rocprofiler_packet pkt) {
pkt.ext_amd_aql_pm4.completion_signal = callback_data.completion;
submitPacket(callback_data.queue, (void*) &pkt);
constexpr auto timeout_hint =
std::chrono::duration_cast<std::chrono::nanoseconds>(std::chrono::seconds{1});
if(hsa::get_core_table()->hsa_signal_wait_relaxed_fn(callback_data.completion,
HSA_SIGNAL_CONDITION_EQ,
0,
timeout_hint.count(),
HSA_WAIT_STATE_ACTIVE) != 0)
{
ROCP_FATAL << "Could not set agent to be profiled";
}
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.completion, 1);
});
}
} // namespace
/**
* Read the previously started profiling registers for each agent. Injects both the read packet
* and the stop packet (a sidestep to the AQL issues) into the queue and optionally waits for the
* return. A small note here is that this function should avoid allocations to be signal safe.
*
* Special Case: If the counters the user requests are purely constants, skip packet injection
* and trigger the async handler manually.
*/
rocprofiler_status_t
read_agent_ctx(const context::context* ctx,
rocprofiler_user_data_t user_data,
rocprofiler_counter_flag_t flags,
std::vector<rocprofiler_record_counter_t>* out_counters)
{
rocprofiler_status_t status = ROCPROFILER_STATUS_SUCCESS;
if(!ctx->device_counter_collection)
{
ROCP_ERROR << fmt::format("Context {} has no agent counter collection", ctx->context_idx);
return ROCPROFILER_STATUS_ERROR_CONTEXT_INVALID;
}
auto& agent_ctx = *ctx->device_counter_collection;
// If we have not initiualized HSA yet, nothing to read, return;
if(hsa_inited().load() == false)
{
return ROCPROFILER_STATUS_ERROR;
}
// Set the state to LOCKED to prevent other calls to start/stop/read.
auto expected = rocprofiler::context::device_counting_service::state::ENABLED;
if(!agent_ctx.status.compare_exchange_strong(
expected, rocprofiler::context::device_counting_service::state::LOCKED))
{
return ROCPROFILER_STATUS_ERROR_CONTEXT_ERROR;
}
for(auto& callback_data : agent_ctx.agent_data)
{
auto wait_if_sync = [&]() {
if((flags & ROCPROFILER_COUNTER_FLAG_ASYNC) == 0)
{
// Wait for any inprogress samples to complete before returning
hsa::get_core_table()->hsa_signal_wait_relaxed_fn(callback_data.completion,
HSA_SIGNAL_CONDITION_EQ,
1,
UINT64_MAX,
HSA_WAIT_STATE_ACTIVE);
}
};
if(!callback_data.profile || !callback_data.set_profile) continue;
const auto* agent = agent::get_agent_cache(callback_data.profile->agent);
// If the agent no longer exists or we don't have a profile queue, reading is an error
if(!agent || !agent->profile_queue())
{
status = ROCPROFILER_STATUS_ERROR;
break;
}
// No AQL packet, nothing to do here.
if(!callback_data.packet) continue;
wait_if_sync();
if((flags & ROCPROFILER_COUNTER_FLAG_ASYNC) == 0)
callback_data.cached_counters = out_counters;
// If we have no hardware counters but a packet. The caller is expecting
// non-hardware based counter values to be returned. We can skip packet injection
// and trigger the async handler directly
if(callback_data.profile->reqired_hw_counters.empty())
{
callback_data.user_data = user_data;
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.completion, -1);
wait_if_sync();
continue;
}
ROCP_TRACE << fmt::format("Agent Info for Running Counter: Name = {}, XCC = {}, "
"SE = {}, CU = {}, SIMD = {}",
agent->get_rocp_agent()->name,
agent->get_rocp_agent()->num_xcc,
agent->get_rocp_agent()->num_shader_banks,
agent->get_rocp_agent()->cu_count,
agent->get_rocp_agent()->simd_arrays_per_engine);
// Submit the read packet to the queue
submitPacket(agent->profile_queue(), &callback_data.packet->packets.read_packet);
// Submit a barrier packet. This is needed to flush hardware caches. Without this
// the read packet may not have the correct data.
rocprofiler::hsa::rocprofiler_packet barrier{};
barrier.barrier_and.header = header_pkt(HSA_PACKET_TYPE_BARRIER_AND);
barrier.barrier_and.completion_signal = callback_data.completion;
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.completion, 0);
callback_data.user_data = user_data;
submitPacket(agent->profile_queue(), &barrier.barrier_and);
wait_if_sync();
if((flags & ROCPROFILER_COUNTER_FLAG_ASYNC) == 0) callback_data.cached_counters = nullptr;
}
agent_ctx.status.exchange(rocprofiler::context::device_counting_service::state::ENABLED);
return status;
}
/**
* Start the agent profiling for the context. For each agent that this context is
* enabled for, we will call the tool to get the profile config. This config will
* will then be used to generate the AQL packet (if it differs from the previous
* profile used). init_callback_data does this initialization. If a tool does not
* supply a profile, we skip this agent. We then submit the start packet to the
* profile queue. This call is synchronous.
*
* Special Case: if constants are the only counters being collected, we skip
* packet injection.
*/
rocprofiler_status_t
start_agent_ctx(const context::context* ctx)
{
auto status = ROCPROFILER_STATUS_SUCCESS;
if(!ctx->device_counter_collection)
{
return status;
}
auto& agent_ctx = *ctx->device_counter_collection;
if(hsa_inited().load() == false)
{
return ROCPROFILER_STATUS_SUCCESS;
}
// Set the state to LOCKED to prevent other calls to start/stop/read.
auto expected = rocprofiler::context::device_counting_service::state::DISABLED;
if(!agent_ctx.status.compare_exchange_strong(
expected, rocprofiler::context::device_counting_service::state::LOCKED))
{
return ROCPROFILER_STATUS_ERROR_SERVICE_ALREADY_CONFIGURED;
}
for(auto& callback_data : agent_ctx.agent_data)
{
const auto* agent = agent::get_agent_cache(agent::get_agent(callback_data.agent_id));
if(!agent)
{
ROCP_ERROR << "No agent found for context: " << ctx->context_idx;
status = ROCPROFILER_STATUS_ERROR;
break;
}
// But if we have an agent cache, we need a profile queue.
if(!agent->profile_queue())
{
ROCP_ERROR << "No profile queue found for context: " << ctx->context_idx;
status = ROCPROFILER_STATUS_ERROR_NO_PROFILE_QUEUE;
break;
}
callback_data.set_profile = false;
// Ask the tool what profile we should use for this agent
callback_data.cb(
{.handle = ctx->context_idx},
callback_data.agent_id,
[](rocprofiler_context_id_t context_id,
rocprofiler_profile_config_id_t config_id) -> rocprofiler_status_t {
auto* cb_ctx = rocprofiler::context::get_mutable_registered_context(context_id);
if(!cb_ctx) return ROCPROFILER_STATUS_ERROR_CONTEXT_INVALID;
auto config = rocprofiler::counters::get_profile_config(config_id);
if(!config) return ROCPROFILER_STATUS_ERROR_PROFILE_NOT_FOUND;
if(!cb_ctx->device_counter_collection)
{
return ROCPROFILER_STATUS_ERROR_CONTEXT_INVALID;
}
// Only allow profiles to be set in the locked state
if(cb_ctx->device_counter_collection->status.load() !=
rocprofiler::context::device_counting_service::state::LOCKED)
{
return ROCPROFILER_STATUS_ERROR_CONFIGURATION_LOCKED;
}
for(auto& agent_data : cb_ctx->device_counter_collection->agent_data)
{
// Find the agent that this profile is for and set it.
if(agent_data.agent_id.handle == config->agent->id.handle)
{
// If the profile config has changed, reset the packet
// and swap the profile.
if(agent_data.profile != config)
{
agent_data.profile = config;
agent_data.packet.reset();
}
// A flag to state that we set a profile
agent_data.set_profile = true;
return ROCPROFILER_STATUS_SUCCESS;
}
}
return ROCPROFILER_STATUS_ERROR_AGENT_MISMATCH;
},
callback_data.callback_data.ptr);
// If we did not set a profile, we have nothing to do.
if(!callback_data.set_profile)
{
callback_data.packet.reset();
continue;
}
CHECK(callback_data.profile);
// Generate necessary structures in the context (packet gen, etc) to process
// this packet.
init_callback_data(callback_data, *agent);
// No hardware counters were actually asked for (i.e. all constants)
if(callback_data.profile->reqired_hw_counters.empty())
{
continue;
}
callback_data.packet->packets.start_packet.completion_signal = callback_data.start_signal;
hsa::get_core_table()->hsa_signal_store_relaxed_fn(callback_data.start_signal, 1);
submitPacket(agent->profile_queue(), &callback_data.packet->packets.start_packet);
// Wait for startup to finish before continuing
hsa::get_core_table()->hsa_signal_wait_relaxed_fn(callback_data.start_signal,
HSA_SIGNAL_CONDITION_EQ,
0,
UINT64_MAX,
HSA_WAIT_STATE_ACTIVE);
}
agent_ctx.status.exchange(rocprofiler::context::device_counting_service::state::ENABLED);
return status;
}
/**
* Issue the stop packet for all active agents in this context. This call is
* synchronous.
*
* Special Case: if no hardware counters are being collected, skip issuing the
* stop packet.
*/
rocprofiler_status_t
stop_agent_ctx(const context::context* ctx)
{
auto status = ROCPROFILER_STATUS_SUCCESS;
if(!ctx->device_counter_collection)
{
return status;
}
auto& agent_ctx = *ctx->device_counter_collection;
if(hsa_inited().load() == false)
{
return ROCPROFILER_STATUS_SUCCESS;
}
auto expected = rocprofiler::context::device_counting_service::state::ENABLED;
if(!agent_ctx.status.compare_exchange_strong(
expected, rocprofiler::context::device_counting_service::state::LOCKED))
{
// Status is already stopped or being enabled elsewhere.
return ROCPROFILER_STATUS_SUCCESS;
}
for(auto& callback_data : agent_ctx.agent_data)
{
if(!callback_data.packet) continue;
const auto* agent = agent::get_agent_cache(callback_data.profile->agent);
if(!agent || !agent->profile_queue()) continue;
if(!callback_data.profile->reqired_hw_counters.empty())
{
// Remove when AQL is updated to not require stop to be called first
submitPacket(agent->profile_queue(), &callback_data.packet->packets.stop_packet);
}
// Wait for the stop packet to complete
hsa::get_core_table()->hsa_signal_wait_relaxed_fn(callback_data.completion,
HSA_SIGNAL_CONDITION_EQ,
1,
UINT64_MAX,
HSA_WAIT_STATE_ACTIVE);
}
agent_ctx.status.exchange(rocprofiler::context::device_counting_service::state::DISABLED);
return status;
}
// Stop all contexts and prevent any further requests to start/stop/read.
// Waits until any current operation is complete before exiting.
rocprofiler_status_t
device_counting_service_finalize()
{
for(auto& ctx : context::get_registered_contexts())
{
std::vector<rocprofiler::context::device_counting_service::state> expected = {
rocprofiler::context::device_counting_service::state::DISABLED,
rocprofiler::context::device_counting_service::state::ENABLED,
rocprofiler::context::device_counting_service::state::EXIT};
if(!ctx->device_counter_collection) continue;
while(!ctx->device_counter_collection->status.compare_exchange_strong(
expected[0], rocprofiler::context::device_counting_service::state::EXIT) &&
!ctx->device_counter_collection->status.compare_exchange_strong(
expected[1], rocprofiler::context::device_counting_service::state::EXIT) &&
!ctx->device_counter_collection->status.compare_exchange_strong(
expected[2], rocprofiler::context::device_counting_service::state::EXIT))
{
// Note: Compare Exchange can modify expected even if the exchange fails
expected = {rocprofiler::context::device_counting_service::state::DISABLED,
rocprofiler::context::device_counting_service::state::ENABLED,
rocprofiler::context::device_counting_service::state::EXIT};
};
}
return ROCPROFILER_STATUS_SUCCESS;
}
// If we have ctx's that were started before HSA was initialized, we need to
// actually start those contexts now that we have an HSA instance.
rocprofiler_status_t
device_counting_service_hsa_registration()
{
hsa_inited().store(true);
for(auto& ctx : context::get_active_contexts())
{
if(!ctx->device_counter_collection) continue;
start_agent_ctx(ctx);
}
return ROCPROFILER_STATUS_SUCCESS;
}
agent_callback_data::~agent_callback_data()
{
if(completion.handle != 0) hsa::get_core_table()->hsa_signal_destroy_fn(completion);
}
} // namespace counters
} // namespace rocprofiler