engine.cpp

#include <torch/csrc/autograd/engine.h>

#include <torch/csrc/autograd/autograd.h>
#include <torch/csrc/autograd/function.h>
#include <torch/csrc/autograd/functions/basic_ops.h>
#include <torch/csrc/autograd/grad_mode.h>
#include <torch/csrc/autograd/anomaly_mode.h>
#include <torch/csrc/autograd/variable.h>
#include <torch/csrc/utils/memory.h>

#include <ATen/DeviceGuard.h>
#include <ATen/ExpandUtils.h>
#include <ATen/Parallel.h>
#include <c10/util/Exception.h>
#include <c10/core/Stream.h>
#include <c10/core/Event.h>
#include <c10/core/DeviceGuard.h>
#include <c10/util/Optional.h>
#include <c10/core/StreamGuard.h>

#include <atomic>
#include <condition_variable>
#include <cstdint>
#include <functional>
#include <iostream>
#include <memory>
#include <mutex>
#include <set>
#include <string>
#include <thread>
#include <unordered_set>
#include <typeinfo>
#include <sstream>
#include <queue>
#include <TH/TH.h>

namespace torch { namespace autograd {

namespace {
static bool in_bad_autograd_fork =
    false; // True for children forked after engine's thread pool init

// Called in the forked child if engine's thread pool has already been
// initialized
static void forked_autograd_child() { in_bad_autograd_fork = true; }

// Should be called before unsafe for forks (thread pool) calls
static void track_bad_autograd_forks() {
#ifndef WIN32
  static std::once_flag flag;
  std::call_once(
      flag, [&] { pthread_atfork(nullptr, nullptr, forked_autograd_child); });
#endif
}
}

// Threads spawned by the engine are assigned a 'worker_device' specifying
// what device they process work for. This variable is initialized at:
// 1. thread creation time for CUDA, XLA device threads, as they are
//    spinning threads waiting for works on their device.
// 2. before the graph task execution for CPU threads, as for each
//    backward call we use the caller thread to drive engine execution.
// This is used when handling reentrant backwards calls;
// See Note [Reentrant backwards]
static thread_local int worker_device = NO_DEVICE;

// This variable is true if ALL invocations in the stack of re-entrant engine
// invocations are imperative backwards. This special variable is needed for the
// gradient checkpointing feature only.
static thread_local bool checkpoint_valid = true;

// Number of nested reentrant backwards calls currently on this thread
static thread_local int current_depth = 0;

// For all device threads (i.e. CUDA, XLA), total_depth represents the total nested
//   reentrant backwards depths over all device threads.
// For CPU devices, it is the total depth associated with the original backward call.
static thread_local int total_depth = 0;

// The current GraphTask being executed by this thread. This helps
// queue_callback() to find the target GraphTask to append final callbacks.
static thread_local std::shared_ptr<GraphTask> current_graph_task = nullptr;

// Every autograd worker thread is associated with a ready queue, which specifies
// the stream of work of this thread to do. This shared_ptr is a thread_local
// pointer to each thread's ready_queue, and it should be initialized via the
// Engine::init_local_ready_queue() call in each corresponding thread before execution.
//
// The CUDA, XLA threads are shared among all invocations of backwards via
// device_ready_queues_, while CPU threads are dedicated to processing CPU work for
// the backward they invoked. So any given graph task maintains its own cpu_ready_queue_
// where you should send work for it to be done
//
// For reentrant backward calls, if we spawn new thread from the current thread
// because we reached the maximum depth, the new thread will just reuse the same
// ReadyQueue with the parent thread for performance improvement.
// see Note [Reentrant backwards] for more details.
static thread_local std::shared_ptr<ReadyQueue> local_ready_queue = nullptr;

// Note [Reentrant backwards]
// ~~~~~~~~~~~~~~~~~~~~~~~~~~
// To understand the reentrant backwards problem, we have to notice two
// aspects of how the autograd engine is implemented today:
//
//  1. When you call Engine::execute(), you want to block until
//  differentiation finishes so that you can get the final result variables
//  of the backwards pass.
//
//  2. The engine operates by having a single worker thread per work queue,
//  and every work queue is pinned to a specific device where the
//  operation is executed.
//
// The problem is, suppose that you call backward() inside of a worker
// thread.  By property (1), we're supposed to block until the nested task
// finishes.  However, by property (2), this worker thread is on the
// hook for processing the tasks assigned to it; we better not block,
// because then all of our backward executions (including the one we
// just started) will deadlock!
//
// We maintain a pool of threads waiting for work to do
// When a reentrant backwards call occurs, the current thread blocks
// and a thread from the pool is woken up to complete the blocking tasks and an
// any other tasks that would have been assigned to that worker. If there are no
// threads available, a new thread is spawned. The new thread will continue
// processing tasks from the same ReadyQueue as the parent worker
//
// When the GraphTask is finished, the parent worker thread that is waiting on
// the task is notified and the current thread returns to the pool.

// Note [Streaming backwards]
// ~~~~~~~~~~~~~~~~~~~~~~~~~~
// On CUDA devices the autograd engine's device operations are run on the
// same stream that ran them in forward. This requires automatically
// syncing the streams so that function A finishes producing its
// output before function B consumes it.
//
// This synchronization occurs when outputs are placed into input buffers.
// The functions corresponding to input buffer positions have metadata
// recording their streams from forward, and during backward this
// data is used to sync the producer's stream with the consumer's.
//
// When a CUDA function is run either all its inputs were accumulated on the
// stream used to run the function OR the inputs are on different devices
// and the function is responsible for properly acquiring them.
//
// Historically, the autograd engine ran all CUDA operations on their
// device's DEFAULT stream. This meant that syncing (implicitly or
// explicitly) with the default streams was required before and after
// calling backward(). It also meant, however, that syncing with
// the default streams after backward() was sufficient to ensure
// that backward() had finished running. To preserve this historic
// behavior the engine records "leaf streams," the streams of the
// leaf variables, and syncs them with their device's default stream
// at the end of backward. All other streams are already synchronized
// to happen before at least one leaf stream (per the above), so syncing
// the leaf streams with the default streams is sufficient to implement
// the historic behavior.

int NodeTask::getReentrantDepth() const {
  std::shared_ptr<GraphTask> graph_task = base_.lock();
  if (graph_task) {
    return graph_task->reentrant_depth_;
  } else {
    // The graph task is no longer valid indicating an error. As a result, we
    // try to move this to the front of the queue to ensure the autograd
    // engine threads pick up this error soon.
    return std::numeric_limits<int>::max();
  }
}

auto ReadyQueue::push(NodeTask item, bool incrementOutstandingTasks) -> void {
  {
    // Lock mutex for writing to heap_
    std::lock_guard<std::mutex> lock(mutex_);
    if (incrementOutstandingTasks) {
      std::shared_ptr<GraphTask> graph_task = item.base_.lock();
      TORCH_INTERNAL_ASSERT(graph_task, "GraphTask is no longer valid!");
      ++graph_task->outstanding_tasks_;
    }
    heap_.push(std::move(item));
  }
  not_empty_.notify_one();
}

auto ReadyQueue::pushShutdownTask() -> void {
  {
    std::lock_guard<std::mutex> lock(mutex_);
    heap_.push(NodeTask({}, nullptr, InputBuffer(0), true));
  }
  not_empty_.notify_one();
}

size_t ReadyQueue::size() const {
  // Lock mutex for accesses to heap_
  std::unique_lock<std::mutex> lock(mutex_);
  return heap_.size();
}

auto ReadyQueue::pop() -> NodeTask {
  // Lock mutex for accesses to heap_
  std::unique_lock<std::mutex> lock(mutex_);
  not_empty_.wait(lock, [this]{ return !heap_.empty(); });
  // NOLINTNEXTLINE(cppcoreguidelines-pro-type-const-cast)
  auto task = std::move(const_cast<NodeTask&>(heap_.top())); heap_.pop();
  return task;
}

bool ReadyQueue::empty() const {
  // Lock mutex for accesses to heap_
  std::unique_lock<std::mutex> lock(mutex_);
  return heap_.empty();
}

Engine::Engine() : max_recursion_depth_(MAX_DEPTH), non_reentrant_device_thread_count_(0) {}

// Send shutdown tasks to all device_ready_queues_ if no backward tasks are running
// Even though readyQueue should be empty, shutdown tasks have the highest priority
Engine::~Engine() {
  bool noBackward = true;
  for (auto& queue: device_ready_queues_) {
    noBackward =  noBackward && queue->empty();
  }
  if (noBackward) {
    for (auto& queue : device_ready_queues_) {
     queue->pushShutdownTask();
    }
    // Do not wait for termination of global threads on Windows
    // Because CRT terminates DLL threads before calling
    // global object destructors
#if !defined(_WIN32) || defined(C10_USE_MSVC_STATIC_RUNTIME)
    std::unique_lock<std::mutex> lk(non_reentrant_device_thread_mutex_);
    while(non_reentrant_device_thread_count_.load() != 0) {
      non_reentrant_device_thread_condvar_.wait(lk);
    }
#endif
  }
  // Otherwise threads are leaked
}

void Engine::release_workers() {
  std::unique_lock<std::mutex> lk(non_reentrant_device_thread_mutex_);
  non_reentrant_device_thread_count_.store(0);
  non_reentrant_device_thread_condvar_.notify_one();
}

void Engine::increment_non_reentrant_thread_count() {
  std::unique_lock<std::mutex> lk(non_reentrant_device_thread_mutex_);
  non_reentrant_device_thread_count_.fetch_add(1);
  non_reentrant_device_thread_condvar_.notify_one();
}

void Engine::decrement_non_reentrant_thread_count() {
  std::unique_lock<std::mutex> lk(non_reentrant_device_thread_mutex_);
  non_reentrant_device_thread_count_.fetch_sub(1);
  non_reentrant_device_thread_condvar_.notify_one();
}

void Engine::thread_init(int device, const std::shared_ptr<ReadyQueue>& ready_queue, bool should_increment) {
  if (should_increment) {
    increment_non_reentrant_thread_count();
  }

  at::init_num_threads();

  // Note [Allocating GPUs to autograd threads]
  // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
  // What's our strategy here?  Originally, the autograd engine was written
  // with only CUDA in mind.  We allocate one thread to handle all CPU
  // operations, and a thread per CUDA device.
  //
  // But what if we have OTHER devices?  There are two plausible
  // strategies:
  //
  //  - We can allocate threads equal to max(num_cuda_devices, num_xla_devices,
  //    ...) and colocate cuda device 0 with xla device 0
  //  - We can allocate threads equal to sum(num_cuda_devices, num_xla_devices,
  //    ...) keeping everyone separate.
  //
  // We don't have any good reason to prefer one or the other, so we've
  // arbitrarily picked to colocate devices.  Maybe the other approach is
  // better.
  set_device(device);

  // initialize each device thread's thread local ready queue with the ready queue
  // that is created before the thread initialization
  init_local_ready_queue(ready_queue);

  std::shared_ptr<GraphTask> graph_task = nullptr;
  thread_main(graph_task);
  if (should_increment) {
    // Decrement the count during shutdown if we incremented earlier.
    decrement_non_reentrant_thread_count();
  }
}

GraphTaskGuard::GraphTaskGuard(std::shared_ptr<GraphTask> graph_task) {
  last_graph_task_ = std::move(current_graph_task);
  current_graph_task = std::move(graph_task);
}
GraphTaskGuard::~GraphTaskGuard() {
  restore_current_graph_task();
}

void GraphTaskGuard::restore_current_graph_task() {
  current_graph_task = std::move(last_graph_task_);
}

// NOTE: graph_tasks do not necessarily form a stack. Imagine this
// case:
//
//    +----> Eval1
//  Root
//    +----> Eval2
//
// Once Root is executed, both Eval1 and Eval2 are added to the ready queue.
// Next, Eval1 is run and this causes the worker to enter thread_main again.
// Then, it pops the next task from the queue, but at this point it is Eval2.
// It enters thread_main once again, but now with graph_task of Eval2, which is
// completely unrelated to that of Eval1 (it's not a recursive call).
// It's all ok and is handled right now, but it should be accounted for
// in case this code is to be changed.
//
// thread_main is used by:
// 1). autograd threads for devices (i.e. CUDA, XLA)
// 2). the caller/owning thread of the backward call on CPU (sync mode)
// 3). Renetrant backward that invoked by either 1) or 2)
// The exit conditions are different for the above three cases.
// For 1), we are spinning on running the thread_main on device autograd
//         threads throughout the Engine lifetime, thread_main will get
//         terminated during Engine destruction by pushing shutdown tasks
// For 2), the owning thread of the backward call drives the thread_main
//         synchronously until the graph_task of that owning thread is
//         completed and exit the thread_main to continue executing the
//         result of caller's code.
// For 3), the reentrant backward that invokes
//         thread_main, either from 1) or 2), will not spin and will exit as
//         long as graph_task is completed and notify the owning thread as
//         needed.
auto Engine::thread_main(const std::shared_ptr<GraphTask>& graph_task) -> void {
  // When graph_task is nullptr, this is a long running thread that processes
  // tasks (ex: device threads). When graph_task is non-null (ex: reentrant
  // backwards, user thread), this function is expected to exit once that
  // graph_task complete.

  // local_ready_queue should already been initialized when we get into thread_main
  TORCH_INTERNAL_ASSERT(local_ready_queue != nullptr);
  while (graph_task == nullptr || !graph_task->future_result_->completed()) {
    // local_graph_task represents the graph_task we retrieve from the queue.
    // The outer graph_task represents the overall graph_task we need to execute
    // for reentrant execution.
    std::shared_ptr<GraphTask> local_graph_task;
    {
      // Scope this block of execution since NodeTask is not needed after this
      // block and can be deallocated (release any references to grad tensors
      // as part of inputs_).
      NodeTask task = local_ready_queue->pop();
      // This will only work if the worker is running a non backward task
      // TODO Needs to be fixed this to work in all cases
      if (task.isShutdownTask_) {
        C10_LOG_API_USAGE_ONCE("torch.autograd.thread_shutdown");
        break;
      }

      if (!(local_graph_task = task.base_.lock())) {
        // GraphTask for function is no longer valid, skipping further
        // execution.
        continue;
      }

      if (task.fn_ && !local_graph_task->has_error_.load()) {
        AutoGradMode grad_mode(local_graph_task->grad_mode_);
        try {
          // The guard sets the thread_local current_graph_task on construction
          // and restores it on exit. The current_graph_task variable helps
          // queue_callback() to find the target GraphTask to append final
          // callbacks.
          GraphTaskGuard guard(local_graph_task);
          NodeGuard ndguard(task.fn_);
          evaluate_function(local_graph_task, task.fn_.get(), task.inputs_, local_graph_task->cpu_ready_queue_);
        } catch (std::exception& e) {
          thread_on_exception(local_graph_task, task.fn_, e);
        }
      }
    }

    // Decrement the outstanding tasks.
    --local_graph_task->outstanding_tasks_;

    // Check if we've completed execution.
    if (local_graph_task->completed()) {
      local_graph_task->mark_as_completed_and_run_post_processing();

      auto base_owner = local_graph_task->owner_;
      // The current worker thread finish the graph_task, but the owning thread
      // of the graph_task might be sleeping on pop() if it does not have work.
      // So we need to send a dummy function task to the owning thread just to
      // ensure that it's not sleeping, so that we can exit the thread_main.
      // If it has work, it might see that graph_task->outstanding_tasks_ == 0
      // before it gets to the task, but it's a no-op anyway.
      //
      // NB: This is not necessary if the current thread is the owning thread.
      if (worker_device != base_owner) {
        // Synchronize outstanding_tasks_ with queue mutex
        std::atomic_thread_fence(std::memory_order_release);
        ready_queue_by_index(local_graph_task->cpu_ready_queue_, base_owner)
            ->push(NodeTask(local_graph_task, nullptr, InputBuffer(0)));
      }
    }
  }
}

// Reentrant call will re-use the graph_task's owner thread ready_queue for
// queueing tasks (NOTE: this is not true in the async_mode of the engine).
// While we can create separate ready queue for each new reentrant
// thread, but sharing the same cpu_ready_queue with parent thread is a
// performance improvement and cuda thread still have to do the same thing.
void Engine::reentrant_thread_init() {
  at::init_num_threads();
  auto tp_shared = thread_pool_shared_;
  while(true) {
    std::unique_lock<std::mutex> lk(tp_shared->mutex_);
    ++thread_pool_shared_->num_workers_;
    tp_shared->work_.wait(lk, [&tp_shared]{ return !tp_shared->graphtasks_queue_.empty();});
    --thread_pool_shared_->num_workers_;
    auto task = tp_shared->graphtasks_queue_.front();
    tp_shared->graphtasks_queue_.pop();
    lk.unlock();
    std::shared_ptr<GraphTask> graph_task;
    if (!(graph_task = task.lock())) {
      LOG(INFO) << "GraphTask has expired, skipping reentrant execution";
      continue;
    }
    set_device(graph_task->owner_);
    // set the local_ready_queue to the ready queue on the graph_task->owner_ device
    local_ready_queue = ready_queue_by_index(graph_task->cpu_ready_queue_, graph_task->owner_);
    total_depth = graph_task->reentrant_depth_;
    thread_main(graph_task);
  }
}

void Engine::thread_on_exception(
    std::shared_ptr<GraphTask> graph_task,
    const std::shared_ptr<Node>& fn,
    std::exception& e) {
  graph_task->set_exception(std::current_exception(), fn);
}

bool GraphTask::completed() {
  return outstanding_tasks_.load() == 0 ||
      (exit_on_error_ && has_error_.load());
}

void GraphTask::mark_as_completed_and_run_post_processing() {
  // Allow only one thread one attempt to process this logic.
  if (future_completed_.exchange(true)) {
    // Future is already marked complete, or being marked as such.
    // In case the marking complete is only in progress, we add a
    // wait() to guarantee the future is marked complete on exit.
    future_result_->wait();
    return;
  }

  try {
    // Run post processing, before marking the future as complete.
    // Drop lock prior to completing, to avoid holding across callbacks.
    std::unique_lock<std::mutex> lock(mutex_);

    exec_post_processing();
    std::vector<Variable> vars = std::move(captured_vars_);

    // Need to unlock before we call markCompleted to avoid holding locks
    // when the callbacks are called.
    lock.unlock();
    future_result_->markCompleted(std::move(vars));
  } catch (std::exception& e) {
    future_result_->setErrorIfNeeded(std::current_exception());
  }
}

void GraphTask::exec_post_processing() {
  if (!not_ready_.empty()) {
    throw std::runtime_error("could not compute gradients for some functions");
  }

  // set the thread_local current_graph_task_ as more callbacks can be installed
  // by existing final callbacks.
  GraphTaskGuard guard(shared_from_this());
  // Lock mutex during each iteration for accessing final_callbacks.size()
  // Unlocking is necessary, because the callback can register
  // more callbacks (or they can be registered from other threads
  // while it's waiting.
  std::unique_lock<std::mutex> cb_lock(final_callbacks_lock_);
  // WARNING: Don't use a range-for loop here because more callbacks may be
  // added in between callback calls, so iterators may become invalidated.
  // NOLINTNEXTLINE(modernize-loop-convert)
  for (size_t i = 0; i < final_callbacks_.size(); ++i) {
    cb_lock.unlock();
    final_callbacks_[i]();
    cb_lock.lock();
  }

  // Syncs leaf streams with default streams (if necessary)
  // See note "Streaming backwards"
  for (const auto& leaf_stream : leaf_streams) {
    const auto guard = c10::impl::VirtualGuardImpl{c10::DeviceType::CUDA};
    const auto default_stream = guard.getDefaultStream(leaf_stream.device());
    if (leaf_stream != default_stream) {
      auto event = c10::Event{c10::DeviceType::CUDA};
      event.record(leaf_stream);
      default_stream.wait(event);
    }
  }
}

void GraphTask::set_exception_without_signal(const std::shared_ptr<Node>& fn) {
  if (!has_error_.exchange(true)) {
    if (AnomalyMode::is_enabled() && fn) {
      fn->metadata()->print_stack(fn->name());
    }
  }
}

void GraphTask::set_exception(
    std::exception_ptr eptr,
    const std::shared_ptr<Node>& fn) {
  set_exception_without_signal(fn);
  if (!future_completed_.exchange(true)) {
    future_result_->setError(std::move(eptr));
  }
}

static variable_list call_pre_hooks(Node& fn, variable_list inputs) {
  for (const auto& hook : fn.pre_hooks()) {
    inputs = (*hook)(inputs);
  }
  return inputs;
}

static variable_list call_post_hooks(Node& fn, variable_list outputs, const variable_list& inputs) {
  for (const auto& hook : fn.post_hooks()) {
    outputs = (*hook)(outputs, inputs);
  }
  return outputs;
}

static bool is_compatible_type(const at::TensorOptions& expected, const at::TensorOptions& actual) {
  // Types are compatible if they exactly match or if the gradient is a sparse
  // version of the expected type.
  return expected.type_equal(actual) || (actual.is_sparse() && expected.device().type() == actual.device().type());
}

void set_device(int device) {
  // NB: We MUST NOT construct the guard for device CPU,
  // as in some settings we compile with cuda, but
  // have lazy stubs for CUDA functionality (so actually
  // attempting to setup a guard(CPU_DEVICE) will cause an
  // error, because it will still query cudaGetDevice).
  //
  // Don't use DeviceGuard here because its destructor may be called before the
  // device is reset. This is fine because the device is thread local.
  if (device != CPU_DEVICE) {
    for (size_t i = 0; i < static_cast<size_t>(c10::DeviceType::COMPILE_TIME_MAX_DEVICE_TYPES); i++) {
      auto* impl = c10::impl::device_guard_impl_registry[i].load();
      if (impl && device < impl->deviceCount()) {
        impl->setDevice(at::Device(static_cast<c10::DeviceType>(i), device));
      }
    }
  }
  worker_device = device;
}

void validate_outputs(
    const edge_list& edges,
    variable_list& grads,
    const std::function<std::string(const std::string&)>& format_error) {
  if (grads.size() != edges.size()) {
    std::stringstream ss;
    ss << "invalid number of gradients - expected ";
    ss << edges.size() << ", but got " << grads.size();
    AT_ERROR(format_error(ss.str()));
  }
  for (size_t i = 0; i < grads.size(); i++) {
    const auto& edge = edges[i];
    if (!edge.is_valid()) continue;

    const auto& metadata = edge.function->input_metadata(edge.input_nr);
    auto& grad = grads[i];
    if (!grad.defined()) {
      // FIXME: TestJit.test_ge_optimized fails this assertion.
      // std::stringstream ss;
      // ss << "undefined gradient at index " << i;
      // AT_ERROR(format_error(ss.str()));
      continue;
    }
    if (!grad.sizes().equals(metadata.shape())) {
      if (!at::is_expandable_to(metadata.shape(), grad.sizes())) {
        std::stringstream ss;
        ss << "invalid gradient at index " << i << " - got ";
        ss << grad.sizes() << " but expected shape compatible with ";
        ss << metadata.shape();
        AT_ERROR(format_error(ss.str()));
      }
      grad = at::sum_to(std::move(grad), metadata.shape());
    }

    bool input_is_complex = isComplexType(c10::typeMetaToScalarType(metadata.options().dtype()));
    bool grad_is_complex = isComplexType(grad.scalar_type());

    TORCH_CHECK(isFloatingType(grad.scalar_type()) || (input_is_complex == grad_is_complex));
    if (c10::typeMetaToScalarType(metadata.options().dtype()) != grad.scalar_type()) {
      grad = grad.to(c10::typeMetaToScalarType(metadata.options().dtype()));
    }
    if (grad.device() != metadata.device() &&
        grad.dim() == 0) {
      grad = grad.to(metadata.device());
    }
    if (!is_compatible_type(metadata.options(), grad.options())) {
       std::stringstream ss;
       ss << "invalid gradient at index " << i << " - expected type ";
       ss << metadata.options() << " but got " << grad.options();
       AT_ERROR(format_error(ss.str()));
    }
    auto grad_device = grad.device();
    if (grad_device != metadata.device()) {
      std::stringstream ss;
      ss << "invalid gradient at index " << i << " - expected device ";
      ss << metadata.device() << " but got " << grad_device;
      AT_ERROR(format_error(ss.str()));
    }
    // We should not build graph for Tensors that are not differentiable
    TORCH_INTERNAL_ASSERT(isDifferentiableType(grad.scalar_type()));
  }
}

static variable_list call_function(
    std::shared_ptr<GraphTask>& graph_task,
    Node* func,
    InputBuffer& inputBuffer) {
  bool prev_checkpoint_valid_state = checkpoint_valid;
  checkpoint_valid =
      graph_task->can_checkpoint() && prev_checkpoint_valid_state;
  auto& fn = *func;
  auto inputs =
      call_pre_hooks(fn, InputBuffer::variables(std::move(inputBuffer)));

  if (!graph_task->keep_graph_) {
    fn.will_release_variables();
  }

  const auto has_post_hooks = !fn.post_hooks().empty();
  variable_list outputs;

  {
    at::ThreadLocalStateGuard guard(graph_task->thread_locals_);
    if (has_post_hooks) {
      // In functions/accumulate_grad.cpp, there is some logic to check the
      // conditions under which the incoming gradient can be stolen directly
      // (which elides a deep copy) instead of cloned. One of these conditions
      // is that the incoming gradient's refcount must be 1 (nothing else is
      // referencing the same data).  Stashing inputs_copy here bumps the
      // refcount, so if post hooks are employed, it's actually still ok for
      // accumulate_grad.cpp to steal the gradient if the refcount is 2.
      //
      // "new_grad.use_count() <= 1 + !post_hooks().empty()" in
      // accumulate_grad.cpp accounts for this, but also creates a silent
      // dependency between engine.cpp (ie, this particular engine
      // implementation) and accumulate_grad.cpp.
      //
      // If you change the logic here, make sure it's compatible with
      // accumulate_grad.cpp.
      auto inputs_copy = inputs;
      outputs = fn(std::move(inputs_copy));
    } else {
      outputs = fn(std::move(inputs));
    }
  }

  validate_outputs(fn.next_edges(), outputs, [&](const std::string& msg) {
    std::ostringstream ss;
    ss << "Function "  << fn.name() << " returned an " << msg;
    return ss.str();
  });
  checkpoint_valid = prev_checkpoint_valid_state;

  if(has_post_hooks){
    // NOLINTNEXTLINE(bugprone-use-after-move)
    return call_post_hooks(fn, std::move(outputs), inputs);
  }
  return outputs;
}

void Engine::evaluate_function(
    std::shared_ptr<GraphTask>& graph_task,
    Node* func,
    InputBuffer& inputs,
    const std::shared_ptr<ReadyQueue>& cpu_ready_queue) {
  // If exec_info_ is not empty, we have to instrument the execution
  auto& exec_info_ = graph_task->exec_info_;
  if (!exec_info_.empty()) {
    auto& fn_info = exec_info_.at(func);
    if (auto* capture_vec = fn_info.captures_.get()) {
      // Lock mutex for writing to graph_task->captured_vars_.
      std::lock_guard<std::mutex> lock(graph_task->mutex_);
      for (const auto& capture : *capture_vec) {
        auto& captured_grad = graph_task->captured_vars_[capture.output_idx_];
        captured_grad = inputs[capture.input_idx_];
        for (auto& hook : capture.hooks_) {
          captured_grad = (*hook)(captured_grad);
        }
      }
    }
    if (!fn_info.needed_) {
      // Skip execution if we don't need to execute the function.
      return;
    }
  }

  // Switches to a function's CUDA stream (if applicable) before calling it
  const auto opt_parent_stream = (*func).stream(c10::DeviceType::CUDA);
  c10::OptionalStreamGuard parent_stream_guard{opt_parent_stream};

  auto outputs = call_function(graph_task, func, inputs);

  auto& fn = *func;
  if (!graph_task->keep_graph_) {
    fn.release_variables();
  }

  int num_outputs = outputs.size();
  if (num_outputs == 0) { // Note: doesn't acquire the mutex
    // Records leaf stream (if applicable)
    // See note "Streaming backwards"
    if (opt_parent_stream) {
      std::lock_guard<std::mutex> lock(graph_task->mutex_);
      graph_task->leaf_streams.emplace(*opt_parent_stream);
    }
    return;
  }

  if (AnomalyMode::is_enabled()) {
    AutoGradMode grad_mode(false);
    for (int i = 0; i < num_outputs; ++i) {
      auto& output = outputs[i];
      at::OptionalDeviceGuard guard(device_of(output));
      if (output.defined() && isnan(output).any().item<uint8_t>()) {
        std::stringstream ss;
        ss << "Function '" << fn.name() << "' returned nan values in its " << i << "th output.";
        throw std::runtime_error(ss.str());
      }
    }
  }

  // Lock mutex for the accesses to GraphTask dependencies_, not_ready_ and cpu_ready_queue_ below
  std::lock_guard<std::mutex> lock(graph_task->mutex_);
  for (int i = 0; i < num_outputs; ++i) {
    auto& output = outputs[i];
    const auto& next = fn.next_edge(i);

    if (!next.is_valid()) continue;

    // Check if the next function is ready to be computed
    bool is_ready = false;
    auto& dependencies = graph_task->dependencies_;
    auto it = dependencies.find(next.function.get());

    if (it == dependencies.end()) {
      auto name = next.function->name();
      throw std::runtime_error(std::string("dependency not found for ") + name);
    } else if (--it->second == 0) {
      dependencies.erase(it);
      is_ready = true;
    }

    auto& not_ready = graph_task->not_ready_;
    auto not_ready_it = not_ready.find(next.function.get());
    if (not_ready_it == not_ready.end()) {
      // Skip functions that aren't supposed to be executed
      if (!exec_info_.empty()) {
        auto it = exec_info_.find(next.function.get());
        if (it == exec_info_.end() || !it->second.should_execute()) {
          continue;
        }
      }
      // No buffers have been allocated for the function
      InputBuffer input_buffer(next.function->num_inputs());

      // Accumulates into buffer
      const auto opt_next_stream = next.function->stream(c10::DeviceType::CUDA);
      input_buffer.add(next.input_nr,
                       std::move(output),
                       opt_parent_stream,
                       opt_next_stream);

      if (is_ready) {
        auto queue = ready_queue(cpu_ready_queue, input_buffer.device());
        queue->push(
            NodeTask(graph_task, next.function, std::move(input_buffer)));
      } else {
        not_ready.emplace(next.function.get(), std::move(input_buffer));
      }
    } else {
      // The function already has a buffer
      auto &input_buffer = not_ready_it->second;

      // Accumulates into buffer
      const auto opt_next_stream = next.function->stream(c10::DeviceType::CUDA);
      input_buffer.add(next.input_nr,
                       std::move(output),
                       opt_parent_stream,
                       opt_next_stream);
      if (is_ready) {
        auto queue = ready_queue(cpu_ready_queue, input_buffer.device());
        queue->push(
            NodeTask(graph_task, next.function, std::move(input_buffer)));
        not_ready.erase(not_ready_it);
      }
    }
  }
}

/* Computes the number of dependencies for each function which requires grad */
auto Engine::compute_dependencies(Node* root, GraphTask& task) -> void {
  // Just to make sure that they will never be added to the queue again
  std::unordered_set<Node*> seen;
  std::vector<Node*> queue { root };

  // Queue contains all nodes that will start propagating gradients.
  // We no longer have to expand functions that don't require grad.
  auto& dependencies = task.dependencies_;
  while (!queue.empty()) {
    auto fn = queue.back(); queue.pop_back();
    for (const auto& edge : fn->next_edges()) {
      if (auto next_ptr = edge.function.get()) {
        dependencies[next_ptr] += 1;
        const bool was_inserted = seen.insert(next_ptr).second;
        if (was_inserted) queue.push_back(next_ptr);
      }
    }
  }
}

auto Engine::execute(const edge_list& roots,
                     const variable_list& inputs,
                     bool keep_graph,
                     bool create_graph,
                     bool accumulate_grad,
                     const edge_list& outputs) -> variable_list {
  // NOLINTNEXTLINE(cppcoreguidelines-pro-type-const-cast)
  validate_outputs(roots, const_cast<variable_list&>(inputs), [](const std::string& msg) {
    return msg;
  });

  // A frech first time Engine::execute call should start on the CPU device, initialize
  // a new thread local ready queue on CPU or reuse the existing one (if there is one
  // allocated already, i.e. consecutive backward calls, re-entrant backward calls),
  // then memoize the local_ready_queue in GraphTask
  init_local_ready_queue();
  bool not_reentrant_backward_call = worker_device == NO_DEVICE;

  auto graph_task = std::make_shared<GraphTask>(
      /* keep_graph */ keep_graph,
      /* create_graph */ create_graph,
      /* depth */ not_reentrant_backward_call ? 0 : total_depth + 1,
      /* cpu_ready_queue */ local_ready_queue);

  // If we receive a single root, skip creating extra root node
  bool skip_dummy_node = roots.size() == 1;
  auto graph_root = skip_dummy_node ?
    roots.at(0).function :
    std::make_shared<GraphRoot>(roots, inputs);

  // Now compute the dependencies for all executable functions and queue the root
  compute_dependencies(graph_root.get(), *graph_task);

  if (!outputs.empty()) {
    graph_task->init_to_execute(*graph_root, outputs, accumulate_grad);
  }

  if (skip_dummy_node) {
    InputBuffer input_buffer(roots.at(0).function->num_inputs());
    auto input = inputs.at(0);

    const auto input_stream = InputMetadata(input).stream();
    const auto opt_next_stream = roots.at(0).function->stream(c10::DeviceType::CUDA);
    input_buffer.add(roots.at(0).input_nr,
                      std::move(input),
                      input_stream,
                      opt_next_stream);

    execute_with_graph_task(graph_task, graph_root, std::move(input_buffer));
  } else {
    execute_with_graph_task(graph_task, graph_root, InputBuffer(variable_list()));
  }
  // Avoid a refcount bump for the Future, since we check for refcount in
  // DistEngine (see TORCH_INTERNAL_ASSERT(futureGrads.use_count() == 1)
  // in dist_engine.cpp).
  auto& fut = graph_task->future_result_;
  fut->wait();
  return fut->value().toTensorVector();
}

void Engine::initialize_device_threads_pool() {
  track_bad_autograd_forks();
  TORCH_CHECK(!in_bad_autograd_fork,
              "Unable to handle autograd's threading in combination with fork-based multiprocessing. "
              "See https://github.com/pytorch/pytorch/wiki/Autograd-and-Fork");
  std::call_once(start_device_threads_flag_, &Engine::start_device_threads, this);
}

std::shared_ptr<at::ivalue::Future> Engine::execute_with_graph_task(
    const std::shared_ptr<GraphTask>& graph_task,
    std::shared_ptr<Node> graph_root,
    InputBuffer&& input_buffer) {
  initialize_device_threads_pool();
  // Lock mutex for GraphTask.
  std::unique_lock<std::mutex> lock(graph_task->mutex_);

  auto queue = ready_queue(graph_task->cpu_ready_queue_, input_buffer.device());

  // worker_device == NO_DEVICE it's a CPU thread and it's trying to drive the
  // autograd engine with corresponding GraphTask, and its NOT a re-entrant call
  if (worker_device == NO_DEVICE) {
    // We set the worker_device to CPU_DEVICE only if worker_device was previously
    // NO_DEVICE. Setting it to CPU afterwards allow us to detect whether this is
    // a re-entrant call or not.
    set_device(CPU_DEVICE);

    // set the graph_task owner to the current device
    graph_task->owner_ = worker_device;

    // Now that all the non-thread safe fields of the graph_task have been populated,
    // we can enqueue it.
    queue->push(NodeTask(graph_task, std::move(graph_root), std::move(input_buffer)));

    // The owning thread start to drive the engine execution for any CPU task that
    // was just pushed or will be added later from other worker threads
    lock.unlock();
    thread_main(graph_task);
    TORCH_INTERNAL_ASSERT(graph_task->future_result_->completed());
    // reset the worker_device after the completion of the graph_task, this is so
    // that the initial state of the engine remains the same across every backward()
    // or grad() call, we don't need to reset local_ready_queue as we could possibly
    // reuse it for new backward calls.
    worker_device = NO_DEVICE;
  } else {
    // If worker_device is any devices (i.e. CPU, CUDA): this is a re-entrant
    //    backward call from that device.
    graph_task->owner_ = worker_device;

    // Now that all the non-thread safe fields of the graph_task have been populated,
    // we can enqueue it.
    queue->push(NodeTask(graph_task, std::move(graph_root), std::move(input_buffer)));

    if (current_depth >= max_recursion_depth_) {
      // See Note [Reentrant backwards]
      // If reached the max depth, switch to a different thread
      add_thread_pool_task(graph_task);
    } else {
      // Total depth needs to be updated only in this codepath, since it is
      // not used in the block above (when we call add_thread_pool_task).
      // In the codepath above, GraphTask.reentrant_depth_ is used to
      // bootstrap total_depth in the other thread.
      ++total_depth;

      // Get back to work while we wait for our new graph_task to
      // complete!
      ++current_depth;
      lock.unlock();
      thread_main(graph_task);
      --current_depth;
      --total_depth;

      // The graph task should have completed and the associated future should
      // be marked completed as well since 'thread_main' above is a call
      // blocking an autograd engine thread.
      TORCH_INTERNAL_ASSERT(graph_task->future_result_->completed());
    }
  }
  // graph_task_exec_post_processing is done when the Future is marked as
  // completed in mark_as_completed_and_run_post_processing.
  return graph_task->future_result_;
}

// note that when python is present, this base engine will be overriden
// with a PythonEngine. Because this typically happens before get_default_engine
// is called, this base engine will never be created.
Engine& Engine::get_base_engine() {
  static Engine engine;
  return engine;
}

std::atomic<EngineStub> engine_stub(Engine::get_base_engine);

void set_default_engine_stub(EngineStub stub) {
  engine_stub.store(stub);
}


Engine& Engine::get_default_engine() {
  return engine_stub.load()();
}

void Engine::queue_callback(std::function<void()> callback) {
  TORCH_CHECK(
      current_graph_task,
      "Final callbacks can only be installed during backward pass.");

  std::lock_guard<std::mutex> lock(current_graph_task->final_callbacks_lock_);
  current_graph_task->final_callbacks_.emplace_back(std::move(callback));
}

bool Engine::is_checkpoint_valid() {
  return checkpoint_valid;
}

void Engine::init_local_ready_queue(std::shared_ptr<ReadyQueue> ready_queue) {
  if (ready_queue) {
    // if ready_queue provided in the caller, use the caller's ready_queue to initialize local_ready_queue
    local_ready_queue = std::move(ready_queue);
  } else if (!local_ready_queue){
    // otherwise if local_ready_queue not allocated, allocate a new ready_queue
    local_ready_queue = std::make_shared<ReadyQueue>();
  }
}

size_t Engine::ready_queue_size(const std::shared_ptr<GraphTask>& graph_task, at::Device device) {
  if (device_ready_queues_.empty()) {
    // The vector device_ready_queues_ is initialized in start_device_threads, but this method
    // can be called before start_device_threads. Adding this check to avoid index
    // out of bound error.
    return 0;
  }
  return ready_queue(graph_task->cpu_ready_queue_, device)->size();
}

// CPU ready queue is per GraphTask, but CUDA device ready queues are shared across all graph tasks
auto Engine::ready_queue(std::shared_ptr<ReadyQueue> cpu_ready_queue, at::Device device) -> std::shared_ptr<ReadyQueue>{
  if (device.type() == at::kCPU) {
    // return the cpu ready queue passed in
    TORCH_INTERNAL_ASSERT(cpu_ready_queue);
    return cpu_ready_queue;
  } else {
    // See Note [Allocating GPUs to autograd threads]
    return device_ready_queues_.at(device.index());
  }
}

auto Engine::ready_queue_by_index(std::shared_ptr<ReadyQueue> cpu_ready_queue, int device_index) -> std::shared_ptr<ReadyQueue> {
  if (device_index == CPU_DEVICE) {
    // return the cpu ready queue passed in
    TORCH_INTERNAL_ASSERT(cpu_ready_queue);
    return cpu_ready_queue;
  } else {
    // Static cast is ok here as the number of device should never overflow an int.
    TORCH_INTERNAL_ASSERT(0 <= device_index && device_index < static_cast<int>(device_ready_queues_.size()));
    // See Note [Allocating GPUs to autograd threads]
    // NB: This function would become obsolete if we truly allocated a CPU thread
    // per device, rather than colocate.
    return device_ready_queues_.at(device_index);
  }
}

auto Engine::start_device_threads() -> void {
  // See Note [Allocating GPUs to autograd threads]
  c10::DeviceIndex num_devices = 0;
  for (const auto& impl_atomic : c10::impl::device_guard_impl_registry) {
    auto* impl = impl_atomic.load();
    if (impl) {
      num_devices = std::max(num_devices, impl->deviceCount());
    }
  }

  // allocate one thread for every GPU device (but colocate GPUs of different
  // types), and pre-allocate the device_ready_queues_ to ensure safe reading on it.
  device_ready_queues_ = std::vector<std::shared_ptr<ReadyQueue>>(num_devices);
  for (auto& queue : device_ready_queues_)    {
    queue.reset(new ReadyQueue());
  }

  thread_pool_shared_ = std::make_shared<ThreadPoolShared>();

  for (int i = 0; i < num_devices; ++i) {
    std::thread t(&Engine::thread_init, this, i, device_ready_queues_[i], true);
    t.detach();
  }
  // Wait for the threads to start
  {
    std::unique_lock<std::mutex> lk(non_reentrant_device_thread_mutex_);
    while(non_reentrant_device_thread_count_.load() != num_devices) {
      non_reentrant_device_thread_condvar_.wait(lk);
    }
  }
}

void Engine::add_thread_pool_task(const std::weak_ptr<GraphTask>& graph_task) {
  std::unique_lock<std::mutex> lck(thread_pool_shared_->mutex_);
  // There may already be some items on the graphtasks_queue_ added by other
  // threads but not enough workers to get to the new task that will be
  // added
  bool create_thread = (thread_pool_shared_->num_workers_ <= thread_pool_shared_->graphtasks_queue_.size());
  thread_pool_shared_->graphtasks_queue_.push(graph_task);
  // Don't need to be holding the lock while actually creating the thread
  lck.unlock();
  if (create_thread) {
    std::thread t(&Engine::reentrant_thread_init, this);
    t.detach();
  }
  // This works even if new thread is created because wait() will test the
  // predicate before waiting
  thread_pool_shared_->work_.notify_one();
}

void GraphTask::init_to_execute(Node& graph_root, const edge_list& outputs, bool accumulate_grad) {
  exec_info_[&graph_root].needed_ = true;
  int output_idx = 0;
  for (auto & output_edge : outputs) {
    Node *output = output_edge.function.get();
    auto & info = exec_info_[output];
    if (accumulate_grad) {
      info.needed_ = true;
    } else {
      if (!info.captures_) {
        info.captures_ = make_unique<std::vector<ExecInfo::Capture>>();
      }
      info.captures_->emplace_back(output_edge.input_nr, output_idx++);
    }
  }
  captured_vars_.resize(output_idx);

  // NB: this is an uglier version (recursion replaced with iteration) of the following code:
  // is_needed = {}
  // def compute_is_needed(fn):
  //   if fn not in is_needed:
  //     is_needed[fn] = any(compute_is_needed(next_edge)
  //                         for next_edge in fn.next_edges)
  //   return is_needed[fn]
  struct Frame {
    Frame (Node *fn) : fn_(fn), next_next_fn_(0) {}
    Node *fn_;
    size_t next_next_fn_;

    Node* get_next_fn() {
      const auto & next = fn_->next_edges();
      auto num_next = next.size();
      while (next_next_fn_ < num_next) {
        auto fn = next[next_next_fn_++].function.get();
        if (fn) return fn;
      }
      return nullptr;
    }
  };
  std::vector<Frame> stack;
  std::unordered_set<Node*> seen;
  for (const auto & input : graph_root.next_edges()) {
    if (!input.function.get()) continue;
    if (seen.count(input.function.get()) > 0) continue;
    stack.emplace_back(input.function.get());
    while (!stack.empty()) {
      auto &frame = stack.back();
      if (Node *next_fn = frame.get_next_fn()) {
        if (/* bool unseen = */ seen.emplace(next_fn).second) {
          stack.emplace_back(next_fn);
          continue; // recurse
        }
      } else {
        // NB: if we were using real recursion we could have saved some lookups
        // using a return value from recursive call. It would make this manually unrolled
        // version a lot more complicated, so I skipped that.
        const auto & next_edges = frame.fn_->next_edges();
        const bool needed = std::any_of(
            next_edges.begin(), next_edges.end(), [&](const Edge& edge) {
              auto it = exec_info_.find(edge.function.get());
              return it != exec_info_.end() && it->second.should_execute();
            });
        exec_info_[frame.fn_].needed_ |= needed;
        stack.pop_back();
      }
    }
  }
}

}} // namespace torch::autograd