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net_async_base.h
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net_async_base.h
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#ifndef CAFFE2_CORE_NET_ASYNC_BASE_H_
#define CAFFE2_CORE_NET_ASYNC_BASE_H_
#include "c10/util/Registry.h"
#include "caffe2/core/common.h"
#include "caffe2/core/net.h"
#include "caffe2/core/net_dag_utils.h"
#include "caffe2/core/prof_dag_counters.h"
#include "caffe2/core/stats.h"
#include "caffe2/core/timer.h"
#include "caffe2/core/workspace.h"
#include "caffe2/proto/caffe2_pb.h"
#include "caffe2/proto/prof_dag.pb.h"
#include "caffe2/utils/proto_utils.h"
#include "caffe2/utils/thread_pool.h"
C10_DECLARE_int(caffe2_streams_per_gpu);
C10_DECLARE_int(caffe2_net_async_max_gpus);
C10_DECLARE_int(caffe2_net_async_max_numa_nodes);
C10_DECLARE_int(caffe2_net_async_thread_pool_size);
C10_DECLARE_bool(caffe2_net_async_check_stream_status);
C10_DECLARE_bool(caffe2_net_async_use_single_pool);
C10_DECLARE_bool(caffe2_net_async_use_per_net_pools);
C10_DECLARE_bool(caffe2_net_async_run_root_tasks_inline);
namespace caffe2 {
class AsyncNetExecutorHelper;
namespace tracing {
class Tracer;
}
struct ExecutionOptions {
explicit ExecutionOptions(const std::shared_ptr<const NetDef>& net_def);
// number of gpu streams per gpu per cpu thread
int streams_per_gpu_ = 1;
// ops synchronization options
bool finish_chain_ = false;
bool always_schedule_child_ = false;
// try to pick gpu stream that is not busy
bool check_stream_status_ = false;
// use single thread pool for all devices
bool use_single_pool_ = false;
// use per net instances thread pools instead of global ones
bool use_per_net_pools_ = false;
// whether RunAsync is blocking
bool is_blocking_ = false;
// prof_dag counters reporting
bool report_stats_ = false;
// immediately run children tasks inline whenever possible
bool use_dfs_scheduling_ = false;
// run net's root tasks in RunAsync thread instead of in thread pool
bool run_root_tasks_inline_ = false;
};
class CAFFE2_API AsyncNetBase : public NetBase {
public:
AsyncNetBase(const std::shared_ptr<const NetDef>& net_def, Workspace* ws);
~AsyncNetBase() override;
bool SupportsAsync() override {
return true;
}
vector<OperatorBase*> GetOperators() const override {
return operators_;
}
bool RunAsync() override;
const dag_utils::ExecutionChains& TEST_execution_chains() const {
return execution_chains_;
}
ProfDAGProtos GetOperatorStats() const;
ProfDAGProtos GetPerOperatorCost() const;
ProfDAGReport GetProfReport() const;
protected:
bool canSchedule(
int chain_id,
const std::vector<EventStatus>* status = nullptr,
bool* parent_failed = nullptr);
bool canSchedule(int parent_id, int child_id);
int tasksNum() const;
Event& event(int task_id) const;
EventStatus query(int task_id) const;
const std::vector<int>& children(int task_id) const;
const std::vector<int>& parents(int task_id) const;
int updateParentCount(int child_id);
int getParentCount(int child_id);
bool testAndSetScheduled(int task_id);
int numOps(int task_id) const;
int firstTaskOpId(int task_id) const;
int lastTaskOpId(int task_id) const;
const OperatorBase* firstTaskOp(int task_id) const;
const OperatorBase* lastTaskOp(int task_id) const;
OperatorBase* firstTaskOp(int task_id);
OperatorBase* lastTaskOp(int task_id);
void asyncWait(
int task_id,
int stream_id,
const std::vector<int>& wait_task_ids) const;
bool run(int task_id, int stream_id);
int stream(int task_id);
TaskThreadPoolBase* pool(const DeviceOption& device_option);
TaskThreadPoolBase* pool();
void finishTasks(const std::unordered_set<int>& task_ids);
void finalizeEvents();
bool isStreamFree(int task_id, int stream_id) const;
virtual void reset();
bool handleRunError() override;
// Operator/task graph
std::vector<OperatorBase*> operators_;
std::vector<dag_utils::OperatorNode> operator_nodes_;
std::vector<std::vector<int>> chains_;
std::vector<dag_utils::OpGraphNode> chain_nodes_; // chains' parents/children
dag_utils::ExecutionChains execution_chains_; // for testing
// Pools and streams
std::mutex pools_mutex_;
// first int key - device id, second - pool size, one pool per (device, size)
typedef std::unordered_map<
int,
std::unordered_map<int, std::shared_ptr<TaskThreadPoolBase>>>
PoolsMap;
PoolsMap cpu_pools_;
PoolsMap gpu_pools_;
static std::vector<int>& getStreamCounters();
int num_workers_;
// Exception/error handling
void handleChainError(
int task_id,
OperatorBase* op,
const char* err_msg,
bool save_exception = false);
std::atomic<bool> success_;
// Tracing
std::shared_ptr<tracing::Tracer> tracer_;
// execution mode flags
ExecutionOptions options_;
ProfDAGCounters counters_;
C10_DISABLE_COPY_AND_ASSIGN(AsyncNetBase);
private:
TaskThreadPoolBase*
poolGetter(PoolsMap& pools, int device_type, int device_id, int pool_size);
std::unique_ptr<AsyncNetExecutorHelper> helper_;
friend class AsyncNetExecutorHelper;
friend class tracing::Tracer;
};
C10_DECLARE_SHARED_REGISTRY(
ThreadPoolRegistry,
TaskThreadPoolBase,
int,
int,
bool);
class AsyncNetExecutorHelper : public ExecutorHelper {
public:
explicit AsyncNetExecutorHelper(AsyncNetBase* net) : net_(net) {}
TaskThreadPoolBase* GetPool(const DeviceOption& option) const override {
return net_->pool(option);
}
private:
AsyncNetBase* net_;
};
template <class TaskThreadPoolImpl, int device_type>
std::shared_ptr<TaskThreadPoolBase>
GetAsyncNetThreadPool(int device_id, int pool_size, bool create_new) {
static std::unordered_map<
int,
std::unordered_map<int, std::weak_ptr<TaskThreadPoolBase>>>
pools;
static std::mutex pool_mutex;
const auto& device_type_name = DeviceTypeName(device_type);
if (pool_size <= 0) {
if (FLAGS_caffe2_net_async_thread_pool_size > 0) {
pool_size = FLAGS_caffe2_net_async_thread_pool_size;
LOG(INFO) << "Using default " << device_type_name
<< " pool size: " << pool_size << "; device id: " << device_id;
} else {
auto num_cores = std::thread::hardware_concurrency();
CAFFE_ENFORCE(num_cores > 0, "Failed to get number of CPU cores");
LOG(INFO) << "Using estimated " << device_type_name
<< " pool size: " << num_cores << "; device id: " << device_id;
pool_size = num_cores;
}
} else {
LOG(INFO) << "Using specified " << device_type_name
<< " pool size: " << pool_size << "; device id: " << device_id;
}
if (create_new) {
LOG(INFO) << "Created new " << device_type_name
<< " pool, size: " << pool_size << "; device id: " << device_id;
return std::make_shared<TaskThreadPoolImpl>(pool_size, device_id);
} else {
std::lock_guard<std::mutex> lock(pool_mutex);
auto shared_pool = pools[device_id][pool_size].lock();
if (!shared_pool) {
LOG(INFO) << "Created shared " << device_type_name
<< " pool, size: " << pool_size << "; device id: " << device_id;
shared_pool = std::make_shared<TaskThreadPoolImpl>(pool_size, device_id);
pools[device_id][pool_size] = shared_pool;
}
return shared_pool;
}
}
} // namespace caffe2
#endif // CAFFE2_CORE_NET_ASYNC_BASE_H_