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#pragma once

#ifdef __GNUC__
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wunused-parameter"
#endif

//===- llvm/Support/Parallel.h - Parallel algorithms ----------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//

#ifndef LLVM_SUPPORT_PARALLEL_H
#define LLVM_SUPPORT_PARALLEL_H

#include "llvm/ADT/STLExtras.h"
#include "llvm/Config/llvm-config.h"
#include "llvm/Support/Error.h" 
#include "llvm/Support/MathExtras.h"
#include "llvm/Support/Threading.h"

#include <algorithm>
#include <condition_variable>
#include <functional>
#include <mutex>

namespace llvm {

namespace parallel {

// Strategy for the default executor used by the parallel routines provided by
// this file. It defaults to using all hardware threads and should be
// initialized before the first use of parallel routines.
extern ThreadPoolStrategy strategy;

namespace detail {

#if LLVM_ENABLE_THREADS

class Latch {
  uint32_t Count;
  mutable std::mutex Mutex;
  mutable std::condition_variable Cond;

public:
  explicit Latch(uint32_t Count = 0) : Count(Count) {}
  ~Latch() { sync(); }

  void inc() {
    std::lock_guard<std::mutex> lock(Mutex);
    ++Count;
  }

  void dec() {
    std::lock_guard<std::mutex> lock(Mutex);
    if (--Count == 0)
      Cond.notify_all();
  }

  void sync() const {
    std::unique_lock<std::mutex> lock(Mutex);
    Cond.wait(lock, [&] { return Count == 0; });
  }
};

class TaskGroup {
  Latch L;
  bool Parallel;

public:
  TaskGroup();
  ~TaskGroup();

  void spawn(std::function<void()> f);

  void sync() const { L.sync(); }
};

const ptrdiff_t MinParallelSize = 1024;

/// Inclusive median.
template <class RandomAccessIterator, class Comparator>
RandomAccessIterator medianOf3(RandomAccessIterator Start,
                               RandomAccessIterator End,
                               const Comparator &Comp) {
  RandomAccessIterator Mid = Start + (std::distance(Start, End) / 2);
  return Comp(*Start, *(End - 1))
             ? (Comp(*Mid, *(End - 1)) ? (Comp(*Start, *Mid) ? Mid : Start)
                                       : End - 1)
             : (Comp(*Mid, *Start) ? (Comp(*(End - 1), *Mid) ? Mid : End - 1)
                                   : Start);
}

template <class RandomAccessIterator, class Comparator>
void parallel_quick_sort(RandomAccessIterator Start, RandomAccessIterator End,
                         const Comparator &Comp, TaskGroup &TG, size_t Depth) {
  // Do a sequential sort for small inputs.
  if (std::distance(Start, End) < detail::MinParallelSize || Depth == 0) {
    llvm::sort(Start, End, Comp);
    return;
  }

  // Partition.
  auto Pivot = medianOf3(Start, End, Comp);
  // Move Pivot to End.
  std::swap(*(End - 1), *Pivot);
  Pivot = std::partition(Start, End - 1, [&Comp, End](decltype(*Start) V) {
    return Comp(V, *(End - 1));
  });
  // Move Pivot to middle of partition.
  std::swap(*Pivot, *(End - 1));

  // Recurse.
  TG.spawn([=, &Comp, &TG] {
    parallel_quick_sort(Start, Pivot, Comp, TG, Depth - 1);
  });
  parallel_quick_sort(Pivot + 1, End, Comp, TG, Depth - 1);
}

template <class RandomAccessIterator, class Comparator>
void parallel_sort(RandomAccessIterator Start, RandomAccessIterator End,
                   const Comparator &Comp) {
  TaskGroup TG;
  parallel_quick_sort(Start, End, Comp, TG,
                      llvm::Log2_64(std::distance(Start, End)) + 1);
}

// TaskGroup has a relatively high overhead, so we want to reduce 
// the number of spawn() calls. We'll create up to 1024 tasks here. 
// (Note that 1024 is an arbitrary number. This code probably needs 
// improving to take the number of available cores into account.) 
enum { MaxTasksPerGroup = 1024 }; 
 
template <class IterTy, class FuncTy>
void parallel_for_each(IterTy Begin, IterTy End, FuncTy Fn) {
  // Limit the number of tasks to MaxTasksPerGroup to limit job scheduling 
  // overhead on large inputs. 
  ptrdiff_t TaskSize = std::distance(Begin, End) / MaxTasksPerGroup; 
  if (TaskSize == 0)
    TaskSize = 1;

  TaskGroup TG;
  while (TaskSize < std::distance(Begin, End)) {
    TG.spawn([=, &Fn] { std::for_each(Begin, Begin + TaskSize, Fn); });
    Begin += TaskSize;
  }
  std::for_each(Begin, End, Fn);
}

template <class IndexTy, class FuncTy>
void parallel_for_each_n(IndexTy Begin, IndexTy End, FuncTy Fn) {
  // Limit the number of tasks to MaxTasksPerGroup to limit job scheduling 
  // overhead on large inputs. 
  ptrdiff_t TaskSize = (End - Begin) / MaxTasksPerGroup; 
  if (TaskSize == 0)
    TaskSize = 1;

  TaskGroup TG;
  IndexTy I = Begin;
  for (; I + TaskSize < End; I += TaskSize) {
    TG.spawn([=, &Fn] {
      for (IndexTy J = I, E = I + TaskSize; J != E; ++J)
        Fn(J);
    });
  }
  for (IndexTy J = I; J < End; ++J)
    Fn(J);
}

template <class IterTy, class ResultTy, class ReduceFuncTy, 
          class TransformFuncTy> 
ResultTy parallel_transform_reduce(IterTy Begin, IterTy End, ResultTy Init, 
                                   ReduceFuncTy Reduce, 
                                   TransformFuncTy Transform) { 
  // Limit the number of tasks to MaxTasksPerGroup to limit job scheduling 
  // overhead on large inputs. 
  size_t NumInputs = std::distance(Begin, End); 
  if (NumInputs == 0) 
    return std::move(Init); 
  size_t NumTasks = std::min(static_cast<size_t>(MaxTasksPerGroup), NumInputs); 
  std::vector<ResultTy> Results(NumTasks, Init); 
  { 
    // Each task processes either TaskSize or TaskSize+1 inputs. Any inputs 
    // remaining after dividing them equally amongst tasks are distributed as 
    // one extra input over the first tasks. 
    TaskGroup TG; 
    size_t TaskSize = NumInputs / NumTasks; 
    size_t RemainingInputs = NumInputs % NumTasks; 
    IterTy TBegin = Begin; 
    for (size_t TaskId = 0; TaskId < NumTasks; ++TaskId) { 
      IterTy TEnd = TBegin + TaskSize + (TaskId < RemainingInputs ? 1 : 0); 
      TG.spawn([=, &Transform, &Reduce, &Results] { 
        // Reduce the result of transformation eagerly within each task. 
        ResultTy R = Init; 
        for (IterTy It = TBegin; It != TEnd; ++It) 
          R = Reduce(R, Transform(*It)); 
        Results[TaskId] = R; 
      }); 
      TBegin = TEnd; 
    } 
    assert(TBegin == End); 
  } 
 
  // Do a final reduction. There are at most 1024 tasks, so this only adds 
  // constant single-threaded overhead for large inputs. Hopefully most 
  // reductions are cheaper than the transformation. 
  ResultTy FinalResult = std::move(Results.front()); 
  for (ResultTy &PartialResult : 
       makeMutableArrayRef(Results.data() + 1, Results.size() - 1)) 
    FinalResult = Reduce(FinalResult, std::move(PartialResult)); 
  return std::move(FinalResult); 
} 
 
#endif

} // namespace detail
} // namespace parallel

template <class RandomAccessIterator,
          class Comparator = std::less<
              typename std::iterator_traits<RandomAccessIterator>::value_type>>
void parallelSort(RandomAccessIterator Start, RandomAccessIterator End,
                  const Comparator &Comp = Comparator()) {
#if LLVM_ENABLE_THREADS
  if (parallel::strategy.ThreadsRequested != 1) {
    parallel::detail::parallel_sort(Start, End, Comp);
    return;
  }
#endif
  llvm::sort(Start, End, Comp);
}

template <class IterTy, class FuncTy>
void parallelForEach(IterTy Begin, IterTy End, FuncTy Fn) {
#if LLVM_ENABLE_THREADS
  if (parallel::strategy.ThreadsRequested != 1) {
    parallel::detail::parallel_for_each(Begin, End, Fn);
    return;
  }
#endif
  std::for_each(Begin, End, Fn);
}

template <class FuncTy>
void parallelForEachN(size_t Begin, size_t End, FuncTy Fn) {
#if LLVM_ENABLE_THREADS
  if (parallel::strategy.ThreadsRequested != 1) {
    parallel::detail::parallel_for_each_n(Begin, End, Fn);
    return;
  }
#endif
  for (size_t I = Begin; I != End; ++I)
    Fn(I);
}

template <class IterTy, class ResultTy, class ReduceFuncTy, 
          class TransformFuncTy> 
ResultTy parallelTransformReduce(IterTy Begin, IterTy End, ResultTy Init, 
                                 ReduceFuncTy Reduce, 
                                 TransformFuncTy Transform) { 
#if LLVM_ENABLE_THREADS 
  if (parallel::strategy.ThreadsRequested != 1) { 
    return parallel::detail::parallel_transform_reduce(Begin, End, Init, Reduce, 
                                                       Transform); 
  } 
#endif 
  for (IterTy I = Begin; I != End; ++I) 
    Init = Reduce(std::move(Init), Transform(*I)); 
  return std::move(Init); 
} 
 
// Range wrappers.
template <class RangeTy,
          class Comparator = std::less<decltype(*std::begin(RangeTy()))>>
void parallelSort(RangeTy &&R, const Comparator &Comp = Comparator()) {
  parallelSort(std::begin(R), std::end(R), Comp);
}

template <class RangeTy, class FuncTy>
void parallelForEach(RangeTy &&R, FuncTy Fn) {
  parallelForEach(std::begin(R), std::end(R), Fn);
}

template <class RangeTy, class ResultTy, class ReduceFuncTy, 
          class TransformFuncTy> 
ResultTy parallelTransformReduce(RangeTy &&R, ResultTy Init, 
                                 ReduceFuncTy Reduce, 
                                 TransformFuncTy Transform) { 
  return parallelTransformReduce(std::begin(R), std::end(R), Init, Reduce, 
                                 Transform); 
} 
 
// Parallel for-each, but with error handling. 
template <class RangeTy, class FuncTy> 
Error parallelForEachError(RangeTy &&R, FuncTy Fn) { 
  // The transform_reduce algorithm requires that the initial value be copyable. 
  // Error objects are uncopyable. We only need to copy initial success values, 
  // so work around this mismatch via the C API. The C API represents success 
  // values with a null pointer. The joinErrors discards null values and joins 
  // multiple errors into an ErrorList. 
  return unwrap(parallelTransformReduce( 
      std::begin(R), std::end(R), wrap(Error::success()), 
      [](LLVMErrorRef Lhs, LLVMErrorRef Rhs) { 
        return wrap(joinErrors(unwrap(Lhs), unwrap(Rhs))); 
      }, 
      [&Fn](auto &&V) { return wrap(Fn(V)); })); 
} 
 
} // namespace llvm

#endif // LLVM_SUPPORT_PARALLEL_H

#ifdef __GNUC__
#pragma GCC diagnostic pop
#endif