File: numeric_impl.h

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// -*- C++ -*-
//===----------------------------------------------------------------------===//
//
// 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 _PSTL_NUMERIC_IMPL_H
#define _PSTL_NUMERIC_IMPL_H

#include <__assert>
#include <__config>
#include <iterator>
#include <type_traits>
#include <numeric>

#include "parallel_backend.h"
#include "execution_impl.h"
#include "unseq_backend_simd.h"
#include "algorithm_fwd.h"

namespace __pstl {
namespace __internal {

//------------------------------------------------------------------------
// transform_exclusive_scan
//
// walk3 evaluates f(x,y,z) for (x,y,z) drawn from [first1,last1), [first2,...), [first3,...)
//------------------------------------------------------------------------

// Exclusive form
template <class _ForwardIterator, class _OutputIterator, class _UnaryOperation, class _Tp, class _BinaryOperation>
std::pair<_OutputIterator, _Tp> __brick_transform_scan(
    _ForwardIterator __first,
    _ForwardIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    /*Inclusive*/ std::false_type,
    /*is_vector=*/std::false_type) noexcept {
  for (; __first != __last; ++__first, ++__result) {
    *__result = __init;
    __init = __binary_op(__init, __unary_op(*__first));
  }
  return std::make_pair(__result, __init);
}

// Inclusive form
template <class _RandomAccessIterator, class _OutputIterator, class _UnaryOperation, class _Tp, class _BinaryOperation>
std::pair<_OutputIterator, _Tp> __brick_transform_scan(
    _RandomAccessIterator __first,
    _RandomAccessIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    /*Inclusive*/ std::true_type,
    /*is_vector=*/std::false_type) noexcept {
  for (; __first != __last; ++__first, ++__result) {
    __init    = __binary_op(__init, __unary_op(*__first));
    *__result = __init;
  }
  return std::make_pair(__result, __init);
}

// type is arithmetic and binary operation is a user defined operation.
template <typename _Tp, typename _BinaryOperation>
using is_arithmetic_udop =
    std::integral_constant<bool,
                           std::is_arithmetic<_Tp>::value && !std::is_same<_BinaryOperation, std::plus<_Tp>>::value>;

// [restriction] - T shall be DefaultConstructible.
// [violation] - default ctor of T shall set the identity value for binary_op.
template <class _RandomAccessIterator,
          class _OutputIterator,
          class _UnaryOperation,
          class _Tp,
          class _BinaryOperation,
          class _Inclusive>
typename std::enable_if<!is_arithmetic_udop<_Tp, _BinaryOperation>::value, std::pair<_OutputIterator, _Tp>>::type
__brick_transform_scan(
    _RandomAccessIterator __first,
    _RandomAccessIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    _Inclusive,
    /*is_vector=*/std::true_type) noexcept {
#if defined(_PSTL_UDS_PRESENT)
  return __unseq_backend::__simd_scan(
      __first, __last - __first, __result, __unary_op, __init, __binary_op, _Inclusive());
#else
  // We need to call serial brick here to call function for inclusive and exclusive scan that depends on _Inclusive()
  // value
  return __internal::__brick_transform_scan(
      __first,
      __last,
      __result,
      __unary_op,
      __init,
      __binary_op,
      _Inclusive(),
      /*is_vector=*/std::false_type());
#endif
}

template <class _RandomAccessIterator,
          class _OutputIterator,
          class _UnaryOperation,
          class _Tp,
          class _BinaryOperation,
          class _Inclusive>
typename std::enable_if<is_arithmetic_udop<_Tp, _BinaryOperation>::value, std::pair<_OutputIterator, _Tp>>::type
__brick_transform_scan(
    _RandomAccessIterator __first,
    _RandomAccessIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    _Inclusive,
    /*is_vector=*/std::true_type) noexcept {
  return __internal::__brick_transform_scan(
      __first,
      __last,
      __result,
      __unary_op,
      __init,
      __binary_op,
      _Inclusive(),
      /*is_vector=*/std::false_type());
}

template <class _Tag,
          class _ExecutionPolicy,
          class _ForwardIterator,
          class _OutputIterator,
          class _UnaryOperation,
          class _Tp,
          class _BinaryOperation,
          class _Inclusive>
_OutputIterator __pattern_transform_scan(
    _Tag,
    _ExecutionPolicy&&,
    _ForwardIterator __first,
    _ForwardIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    _Inclusive) noexcept {
  return __internal::__brick_transform_scan(
             __first, __last, __result, __unary_op, __init, __binary_op, _Inclusive(), typename _Tag::__is_vector{})
      .first;
}

template <class _IsVector,
          class _ExecutionPolicy,
          class _RandomAccessIterator,
          class _OutputIterator,
          class _UnaryOperation,
          class _Tp,
          class _BinaryOperation,
          class _Inclusive>
typename std::enable_if<!std::is_floating_point<_Tp>::value, _OutputIterator>::type __pattern_transform_scan(
    __parallel_tag<_IsVector> __tag,
    _ExecutionPolicy&& __exec,
    _RandomAccessIterator __first,
    _RandomAccessIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    _Inclusive) {
  using __backend_tag = typename decltype(__tag)::__backend_tag;

  typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type _DifferenceType;

  return __internal::__except_handler([&]() {
    __par_backend::__parallel_transform_scan(
        __backend_tag{},
        std::forward<_ExecutionPolicy>(__exec),
        __last - __first,
        [__first, __unary_op](_DifferenceType __i) mutable { return __unary_op(__first[__i]); },
        __init,
        __binary_op,
        [__first, __unary_op, __binary_op](_DifferenceType __i, _DifferenceType __j, _Tp __init) {
          // Execute serial __brick_transform_reduce, due to the explicit SIMD vectorization (reduction) requires a
          // commutative operation for the guarantee of correct scan.
          return __internal::__brick_transform_reduce(
              __first + __i,
              __first + __j,
              __init,
              __binary_op,
              __unary_op,
              /*__is_vector*/ std::false_type());
        },
        [__first, __unary_op, __binary_op, __result](_DifferenceType __i, _DifferenceType __j, _Tp __init) {
          return __internal::__brick_transform_scan(
                     __first + __i,
                     __first + __j,
                     __result + __i,
                     __unary_op,
                     __init,
                     __binary_op,
                     _Inclusive(),
                     _IsVector{})
              .second;
        });
    return __result + (__last - __first);
  });
}

template <class _IsVector,
          class _ExecutionPolicy,
          class _RandomAccessIterator,
          class _OutputIterator,
          class _UnaryOperation,
          class _Tp,
          class _BinaryOperation,
          class _Inclusive>
typename std::enable_if<std::is_floating_point<_Tp>::value, _OutputIterator>::type __pattern_transform_scan(
    __parallel_tag<_IsVector> __tag,
    _ExecutionPolicy&& __exec,
    _RandomAccessIterator __first,
    _RandomAccessIterator __last,
    _OutputIterator __result,
    _UnaryOperation __unary_op,
    _Tp __init,
    _BinaryOperation __binary_op,
    _Inclusive) {
  using __backend_tag = typename decltype(__tag)::__backend_tag;

  typedef typename std::iterator_traits<_RandomAccessIterator>::difference_type _DifferenceType;
  _DifferenceType __n = __last - __first;

  if (__n <= 0) {
    return __result;
  }
  return __internal::__except_handler([&]() {
    __par_backend::__parallel_strict_scan(
        __backend_tag{},
        std::forward<_ExecutionPolicy>(__exec),
        __n,
        __init,
        [__first, __unary_op, __binary_op, __result](_DifferenceType __i, _DifferenceType __len) {
          return __internal::__brick_transform_scan(
                     __first + __i,
                     __first + (__i + __len),
                     __result + __i,
                     __unary_op,
                     _Tp{},
                     __binary_op,
                     _Inclusive(),
                     _IsVector{})
              .second;
        },
        __binary_op,
        [__result, &__binary_op](_DifferenceType __i, _DifferenceType __len, _Tp __initial) {
          return *(std::transform(__result + __i,
                                  __result + __i + __len,
                                  __result + __i,
                                  [&__initial, &__binary_op](const _Tp& __x) {
                                    return __binary_op(__initial, __x);
                                  }) -
                   1);
        },
        [](_Tp) {});
    return __result + (__last - __first);
  });
}

//------------------------------------------------------------------------
// adjacent_difference
//------------------------------------------------------------------------

template <class _ForwardIterator, class _OutputIterator, class _BinaryOperation>
_OutputIterator __brick_adjacent_difference(
    _ForwardIterator __first,
    _ForwardIterator __last,
    _OutputIterator __d_first,
    _BinaryOperation __op,
    /*is_vector*/ std::false_type) noexcept {
  return std::adjacent_difference(__first, __last, __d_first, __op);
}

template <class _RandomAccessIterator1, class _RandomAccessIterator2, class BinaryOperation>
_RandomAccessIterator2 __brick_adjacent_difference(
    _RandomAccessIterator1 __first,
    _RandomAccessIterator1 __last,
    _RandomAccessIterator2 __d_first,
    BinaryOperation __op,
    /*is_vector=*/std::true_type) noexcept {
  _LIBCPP_ASSERT_UNCATEGORIZED(__first != __last, "Range cannot be empty");

  typedef typename std::iterator_traits<_RandomAccessIterator1>::reference _ReferenceType1;
  typedef typename std::iterator_traits<_RandomAccessIterator2>::reference _ReferenceType2;

  auto __n   = __last - __first;
  *__d_first = *__first;
  return __unseq_backend::__simd_walk_3(
      __first + 1,
      __n - 1,
      __first,
      __d_first + 1,
      [&__op](_ReferenceType1 __x, _ReferenceType1 __y, _ReferenceType2 __z) { __z = __op(__x, __y); });
}

template <class _Tag, class _ExecutionPolicy, class _ForwardIterator, class _OutputIterator, class _BinaryOperation>
_OutputIterator __pattern_adjacent_difference(
    _Tag,
    _ExecutionPolicy&&,
    _ForwardIterator __first,
    _ForwardIterator __last,
    _OutputIterator __d_first,
    _BinaryOperation __op) noexcept {
  return __internal::__brick_adjacent_difference(__first, __last, __d_first, __op, typename _Tag::__is_vector{});
}

template <class _IsVector,
          class _ExecutionPolicy,
          class _RandomAccessIterator1,
          class _RandomAccessIterator2,
          class _BinaryOperation>
_RandomAccessIterator2 __pattern_adjacent_difference(
    __parallel_tag<_IsVector> __tag,
    _ExecutionPolicy&& __exec,
    _RandomAccessIterator1 __first,
    _RandomAccessIterator1 __last,
    _RandomAccessIterator2 __d_first,
    _BinaryOperation __op) {
  _LIBCPP_ASSERT_UNCATEGORIZED(__first != __last, "range cannot be empty");
  typedef typename std::iterator_traits<_RandomAccessIterator1>::reference _ReferenceType1;
  typedef typename std::iterator_traits<_RandomAccessIterator2>::reference _ReferenceType2;

  using __backend_tag = typename decltype(__tag)::__backend_tag;

  *__d_first = *__first;
  __par_backend::__parallel_for(
      __backend_tag{},
      std::forward<_ExecutionPolicy>(__exec),
      __first,
      __last - 1,
      [&__op, __d_first, __first](_RandomAccessIterator1 __b, _RandomAccessIterator1 __e) {
        _RandomAccessIterator2 __d_b = __d_first + (__b - __first);
        __internal::__brick_walk3(
            __b,
            __e,
            __b + 1,
            __d_b + 1,
            [&__op](_ReferenceType1 __x, _ReferenceType1 __y, _ReferenceType2 __z) { __z = __op(__y, __x); },
            _IsVector{});
      });
  return __d_first + (__last - __first);
}

} // namespace __internal
} // namespace __pstl

#endif /* _PSTL_NUMERIC_IMPL_H */