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hpc_array_vector.hpp
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hpc_array_vector.hpp
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#pragma once
#include <hpc_array_traits.hpp>
#include <hpc_matrix.hpp>
#include <iterator>
#include <type_traits>
namespace hpc {
namespace impl {
template <class T, layout L, class O>
class array_vector_reference
{
public:
using array_value_type = typename ::hpc::array_traits<T>::value_type;
using array_size_type = typename ::hpc::array_traits<T>::size_type;
using iterator_type = ::hpc::impl::inner_iterator<
::hpc::pointer_iterator<array_value_type, decltype(O() * array_size_type())>,
L,
O,
array_size_type>;
private:
iterator_type m_iterator;
public:
HPC_ALWAYS_INLINE HPC_HOST_DEVICE
array_vector_reference(iterator_type iterator_in) noexcept
: m_iterator(iterator_in)
{
}
// movable
HPC_ALWAYS_INLINE
array_vector_reference(array_vector_reference&&) = default;
HPC_ALWAYS_INLINE array_vector_reference&
operator=(array_vector_reference&&) = default;
// not copyable
HPC_HOST_DEVICE
array_vector_reference(array_vector_reference const&) = delete;
HPC_ALWAYS_INLINE HPC_HOST_DEVICE explicit operator T() const noexcept
{
return ::hpc::array_traits<T>::load(m_iterator);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE void
operator=(T const& value) const noexcept
{
::hpc::array_traits<T>::store(m_iterator, value);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE T
load() const noexcept
{
return ::hpc::array_traits<T>::load(m_iterator);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE void
store(T const& value) const noexcept
{
::hpc::array_traits<T>::store(m_iterator, value);
}
template <class T2, layout L2, class O2>
HPC_ALWAYS_INLINE HPC_HOST_DEVICE void
operator=(array_vector_reference<T2, L2, O2> const& ref) const noexcept
{
::hpc::array_traits<T>::store(m_iterator, ref.load());
}
};
template <class T, layout L, class O>
class array_vector_reference<T const, L, O>
{
public:
using array_value_type = typename ::hpc::array_traits<T>::value_type;
using array_size_type = typename ::hpc::array_traits<T>::size_type;
using iterator_type = ::hpc::impl::inner_iterator<
::hpc::pointer_iterator<array_value_type const, decltype(O() * array_size_type())>,
L,
O,
array_size_type>;
private:
iterator_type m_iterator;
public:
HPC_ALWAYS_INLINE HPC_HOST_DEVICE explicit array_vector_reference(iterator_type iterator_in) noexcept
: m_iterator(iterator_in)
{
}
// movable
HPC_ALWAYS_INLINE
array_vector_reference(array_vector_reference&&) = default;
HPC_ALWAYS_INLINE array_vector_reference&
operator=(array_vector_reference&&) = default;
// not copyable
HPC_HOST_DEVICE
array_vector_reference(array_vector_reference const&) = delete;
HPC_HOST_DEVICE array_vector_reference&
operator=(array_vector_reference const&) = delete;
HPC_ALWAYS_INLINE HPC_HOST_DEVICE explicit operator T() const noexcept
{
return ::hpc::array_traits<T>::load(m_iterator);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE T
load() const noexcept
{
return ::hpc::array_traits<T>::load(m_iterator);
}
};
} // namespace impl
template <class T, layout L, class O>
class array_vector_iterator
{
public:
using value_type = std::remove_const_t<T>;
using array_value_type = typename ::hpc::array_traits<value_type>::value_type;
using array_size_type = typename ::hpc::array_traits<value_type>::size_type;
using qualified_array_value_type =
typename std::conditional<std::is_const<T>::value, array_value_type const, array_value_type>::type;
using iterator = ::hpc::impl::outer_iterator<
::hpc::pointer_iterator<qualified_array_value_type, decltype(O() * array_size_type())>,
L,
O,
array_size_type>;
private:
iterator m_iterator;
public:
using difference_type = O;
using reference = ::hpc::impl::array_vector_reference<T, L, O>;
using pointer = T*;
using iterator_category = typename iterator::iterator_category;
HPC_ALWAYS_INLINE HPC_HOST_DEVICE explicit constexpr array_vector_iterator(iterator iterator_in) noexcept
: m_iterator(iterator_in)
{
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator==(array_vector_iterator const& other) const noexcept
{
return m_iterator == other.m_iterator;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator!=(array_vector_iterator const& other) const noexcept
{
return m_iterator != other.m_iterator;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr reference
operator*() const noexcept
{
auto const inner_range = *m_iterator;
return reference(inner_range.begin());
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator&
operator++() noexcept
{
++m_iterator;
return *this;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator
operator++(int) noexcept
{
auto ret = *this;
++m_iterator;
return ret;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator&
operator--() noexcept
{
--m_iterator;
return *this;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator
operator--(int) noexcept
{
auto ret = *this;
--m_iterator;
return ret;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator&
operator+=(difference_type const n) noexcept
{
m_iterator += n;
return *this;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE array_vector_iterator&
operator-=(difference_type const n) noexcept
{
m_iterator -= n;
return *this;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr array_vector_iterator
operator+(difference_type const n) const noexcept
{
return array_vector_iterator(m_iterator + n);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr array_vector_iterator
operator-(difference_type const n) const noexcept
{
return array_vector_iterator(m_iterator - n);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr difference_type
operator-(array_vector_iterator const& other) const noexcept
{
return difference_type(m_iterator - other.m_iterator);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr reference
operator[](difference_type const i) const noexcept
{
return *((*this) + i);
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator<(array_vector_iterator const& other) const noexcept
{
return m_iterator < other.m_iterator;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator>(array_vector_iterator const& other) const noexcept
{
return m_iterator > other.m_iterator;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator<=(array_vector_iterator const& other) const noexcept
{
return m_iterator <= other.m_iterator;
}
HPC_ALWAYS_INLINE HPC_HOST_DEVICE constexpr bool
operator>=(array_vector_iterator const& other) const noexcept
{
return m_iterator >= other.m_iterator;
}
};
template <
class T,
layout L = ::hpc::host_layout,
class Allocator = std::allocator<T>,
class ExecutionPolicy = ::hpc::serial_policy,
class Index = std::ptrdiff_t>
class array_vector
{
public:
using array_value_type = typename ::hpc::array_traits<T>::value_type;
using array_size_type = typename ::hpc::array_traits<T>::size_type;
static constexpr array_size_type
array_size() noexcept
{
return ::hpc::array_traits<T>::size();
}
private:
using matrix_allocator_type = typename std::allocator_traits<Allocator>::template rebind_alloc<array_value_type>;
using matrix_type =
::hpc::matrix<array_value_type, L, matrix_allocator_type, ExecutionPolicy, Index, array_size_type>;
matrix_type m_matrix;
public:
using value_type = T;
using allocator_type = Allocator;
using execution_policy = ExecutionPolicy;
using size_type = Index;
using difference_type = typename matrix_type::difference_type;
using reference = ::hpc::impl::array_vector_reference<value_type, L, Index>;
using const_reference = ::hpc::impl::array_vector_reference<value_type const, L, Index>;
using pointer = T*;
using const_pointer = T const*;
using iterator = ::hpc::array_vector_iterator<T, L, Index>;
using const_iterator = ::hpc::array_vector_iterator<T const, L, Index>;
constexpr array_vector() noexcept = default;
array_vector(size_type count) : m_matrix(count, array_size())
{
}
array_vector(allocator_type const& allocator_in, execution_policy const& exec_in) noexcept
: m_matrix(allocator_in, exec_in)
{
}
array_vector(size_type count, allocator_type const& allocator_in, execution_policy const& exec_in)
: m_matrix(count, array_size(), allocator_in, exec_in)
{
}
array_vector(array_vector&&) noexcept = default;
array_vector(array_vector const&) = delete;
array_vector&
operator=(array_vector&&) = default;
array_vector&
operator=(array_vector const&) = delete;
iterator
begin() noexcept
{
return iterator(m_matrix.begin());
}
const_iterator
begin() const noexcept
{
return const_iterator(m_matrix.begin());
}
const_iterator
cbegin() const noexcept
{
return const_iterator(m_matrix.begin());
}
iterator
end() noexcept
{
return iterator(m_matrix.end());
}
const_iterator
end() const noexcept
{
return const_iterator(m_matrix.end());
}
const_iterator
cend() const noexcept
{
return const_iterator(m_matrix.end());
}
bool
empty() const noexcept
{
return m_matrix.empty();
}
size_type
size() const noexcept
{
return size_type(m_matrix.size());
}
void
clear()
{
m_matrix.clear();
}
void
resize(size_type count)
{
m_matrix.resize(count, array_size());
}
constexpr allocator_type
get_allocator() const noexcept
{
return m_matrix.get_allocator();
}
constexpr execution_policy
get_execution_policy() const noexcept
{
return m_matrix.get_execution_policy();
}
constexpr reference
operator[](size_type i) noexcept
{
return begin()[i];
}
constexpr const_reference
operator[](size_type i) const noexcept
{
return begin()[i];
}
array_value_type*
data() noexcept
{
return m_matrix.data();
}
array_value_type const*
data() const noexcept
{
return m_matrix.data();
}
};
template <class T, class Index = std::ptrdiff_t>
using host_array_vector = array_vector<T, ::hpc::host_layout, ::hpc::host_allocator<T>, ::hpc::host_policy, Index>;
template <class T, class Index = std::ptrdiff_t>
using device_array_vector =
array_vector<T, ::hpc::device_layout, ::hpc::device_allocator<T>, ::hpc::device_policy, Index>;
template <class T, class Index = std::ptrdiff_t>
using pinned_array_vector =
array_vector<T, ::hpc::device_layout, ::hpc::pinned_allocator<T>, ::hpc::host_policy, Index>;
template <class T, layout L, class A, class P, class I>
void
copy(array_vector<T, L, A, P, I> const& from, array_vector<T, L, A, P, I>& to)
{
hpc::copy(from.get_execution_policy(), from, to);
}
#ifdef HPC_CUDA
template <class T, class Index>
void
copy(pinned_array_vector<T, Index> const& from, device_array_vector<T, Index>& to)
{
assert(from.size() == to.size());
auto const num_arrays = from.size();
auto const array_size = from.array_size();
auto const size = std::size_t(num_arrays * array_size);
auto const from_ptr = from.data();
auto const to_ptr = to.data();
using array_value_type = typename pinned_array_vector<T, Index>::array_value_type;
#ifndef NDEBUG
auto err =
#endif
cudaDeviceSynchronize();
assert(cudaSuccess == err);
#ifndef NDEBUG
err =
#endif
cudaMemcpy(to_ptr, from_ptr, size * sizeof(array_value_type), cudaMemcpyHostToDevice);
assert(cudaSuccess == err);
#ifndef NDEBUG
err =
#endif
cudaDeviceSynchronize();
assert(cudaSuccess == err);
}
template <class T, class Index>
void
copy(device_array_vector<T, Index> const& from, pinned_array_vector<T, Index>& to)
{
assert(from.size() == to.size());
auto const num_arrays = from.size();
auto const array_size = from.array_size();
auto const size = std::size_t(num_arrays * array_size);
auto const from_ptr = from.data();
auto const to_ptr = to.data();
using array_value_type = typename pinned_array_vector<T, Index>::array_value_type;
#ifndef NDEBUG
auto err =
#endif
cudaDeviceSynchronize();
assert(cudaSuccess == err);
#ifndef NDEBUG
err =
#endif
cudaMemcpy(to_ptr, from_ptr, size * sizeof(array_value_type), cudaMemcpyDeviceToHost);
assert(cudaSuccess == err);
#ifndef NDEBUG
err =
#endif
cudaDeviceSynchronize();
assert(cudaSuccess == err);
}
#endif
} // namespace hpc