include/pybind11/numpy.h - platform/external/python/pybind11 - Gitiles

 /*
     pybind11/numpy.h: Basic NumPy support, vectorize() wrapper

     Copyright (c) 2016 Wenzel Jakob <wenzel.jakob@epfl.ch>

     All rights reserved. Use of this source code is governed by a
     BSD-style license that can be found in the LICENSE file.
 */

 #pragma once

 #include "pybind11.h"
 #include "complex.h"
 #include <numeric>
 #include <algorithm>
 #include <cstdlib>
 #include <cstring>
 #include <initializer_list>

 #if defined(_MSC_VER)
 #pragma warning(push)
 #pragma warning(disable: 4127) // warning C4127: Conditional expression is constant
 #endif

 NAMESPACE_BEGIN(pybind11)
 namespace detail { template <typename type, typename SFINAE = void> struct npy_format_descriptor { }; }

 class array : public buffer {
 public:
     struct API {
         enum Entries {
             API_PyArray_Type = 2,
             API_PyArray_DescrFromType = 45,
             API_PyArray_FromAny = 69,
             API_PyArray_NewCopy = 85,
             API_PyArray_NewFromDescr = 94,
             API_PyArray_DescrConverter = 174,
             API_PyArray_GetArrayParamsFromObject = 278,

             NPY_C_CONTIGUOUS_ = 0x0001,
             NPY_F_CONTIGUOUS_ = 0x0002,
             NPY_ARRAY_FORCECAST_ = 0x0010,
             NPY_ENSURE_ARRAY_ = 0x0040,
             NPY_BOOL_ = 0,
             NPY_BYTE_, NPY_UBYTE_,
             NPY_SHORT_, NPY_USHORT_,
             NPY_INT_, NPY_UINT_,
             NPY_LONG_, NPY_ULONG_,
             NPY_LONGLONG_, NPY_ULONGLONG_,
             NPY_FLOAT_, NPY_DOUBLE_, NPY_LONGDOUBLE_,
             NPY_CFLOAT_, NPY_CDOUBLE_, NPY_CLONGDOUBLE_
         };

         static API lookup() {
             module m = module::import("numpy.core.multiarray");
             object c = (object) m.attr("_ARRAY_API");
 #if PY_MAJOR_VERSION >= 3
             void **api_ptr = (void **) (c ? PyCapsule_GetPointer(c.ptr(), NULL) : nullptr);
 #else
             void **api_ptr = (void **) (c ? PyCObject_AsVoidPtr(c.ptr()) : nullptr);
 #endif
             API api;
 #define DECL_NPY_API(Func) api.Func##_ = (decltype(api.Func##_)) api_ptr[API_##Func];
             DECL_NPY_API(PyArray_Type);
             DECL_NPY_API(PyArray_DescrFromType);
             DECL_NPY_API(PyArray_FromAny);
             DECL_NPY_API(PyArray_NewCopy);
             DECL_NPY_API(PyArray_NewFromDescr);
             DECL_NPY_API(PyArray_DescrConverter);
             DECL_NPY_API(PyArray_GetArrayParamsFromObject);
 #undef DECL_NPY_API
             return api;
         }

         bool PyArray_Check_(PyObject *obj) const { return (bool) PyObject_TypeCheck(obj, PyArray_Type_); }

         PyObject *(*PyArray_DescrFromType_)(int);
         PyObject *(*PyArray_NewFromDescr_)
             (PyTypeObject *, PyObject *, int, Py_intptr_t *,
              Py_intptr_t *, void *, int, PyObject *);
         PyObject *(*PyArray_NewCopy_)(PyObject *, int);
         PyTypeObject *PyArray_Type_;
         PyObject *(*PyArray_FromAny_) (PyObject *, PyObject *, int, int, int, PyObject *);
         int (*PyArray_DescrConverter_) (PyObject *, PyObject **);
         int (*PyArray_GetArrayParamsFromObject_)(PyObject *, PyObject *, char, PyObject **, int *,
                                                  Py_ssize_t *, PyObject **, PyObject *);
     };

     PYBIND11_OBJECT_DEFAULT(array, buffer, lookup_api().PyArray_Check_)

     enum {
         c_style = API::NPY_C_CONTIGUOUS_,
         f_style = API::NPY_F_CONTIGUOUS_,
         forcecast = API::NPY_ARRAY_FORCECAST_
     };

     template <typename Type> array(size_t size, const Type *ptr) {
         API& api = lookup_api();
         PyObject *descr = detail::npy_format_descriptor<Type>::descr();
         Py_intptr_t shape = (Py_intptr_t) size;
         object tmp = object(api.PyArray_NewFromDescr_(
             api.PyArray_Type_, descr, 1, &shape, nullptr, (void *) ptr, 0, nullptr), false);
         if (ptr && tmp)
             tmp = object(api.PyArray_NewCopy_(tmp.ptr(), -1 /* any order */), false);
         if (!tmp)
             pybind11_fail("NumPy: unable to create array!");
         m_ptr = tmp.release().ptr();
     }

     array(const buffer_info &info) {
         PyObject *arr = nullptr, *descr = nullptr;
         int ndim = 0;
         Py_ssize_t dims[32];

         // allocate zeroed memory if it hasn't been provided
         auto buf_info = info;
         if (!buf_info.ptr)
             buf_info.ptr = std::calloc(info.size, info.itemsize);
         auto view = py::memoryview(buf_info);

         API& api = lookup_api();
         auto res = api.PyArray_GetArrayParamsFromObject_(view.ptr(), nullptr, 1, &descr,
                                                          &ndim, dims, &arr, nullptr);
         if (res < 0 || !arr || descr)
             pybind11_fail("NumPy: unable to convert buffer to an array");
         m_ptr = arr;
     }

 protected:
     static API &lookup_api() {
         static API api = API::lookup();
         return api;
     }

     template <typename T, typename SFINAE> friend struct detail::npy_format_descriptor;
 };

 template <typename T, int ExtraFlags = array::forcecast> class array_t : public array {
 public:
     PYBIND11_OBJECT_CVT(array_t, array, is_non_null, m_ptr = ensure(m_ptr));
     array_t() : array() { }
     array_t(const buffer_info& info) : array(info) {}
     static bool is_non_null(PyObject *ptr) { return ptr != nullptr; }
     static PyObject *ensure(PyObject *ptr) {
         if (ptr == nullptr)
             return nullptr;
         API &api = lookup_api();
         PyObject *descr = detail::npy_format_descriptor<T>::descr();
         PyObject *result = api.PyArray_FromAny_(ptr, descr, 0, 0, API::NPY_ENSURE_ARRAY_ | ExtraFlags, nullptr);
         if (!result)
             PyErr_Clear();
         Py_DECREF(ptr);
         return result;
     }
 };

 template <typename T> struct format_descriptor
 <T, typename std::enable_if<std::is_pod<T>::value &&
                             !std::is_integral<T>::value &&
                             !std::is_same<T, float>::value &&
                             !std::is_same<T, bool>::value &&
                             !std::is_same<T, std::complex<float>>::value &&
                             !std::is_same<T, std::complex<double>>::value>::type>
 {
     static const char *value() {
         return detail::npy_format_descriptor<T>::format_str();
     }
 };

 NAMESPACE_BEGIN(detail)

 template <typename T> struct npy_format_descriptor<T, typename std::enable_if<std::is_integral<T>::value>::type> {
 private:
     constexpr static const int values[8] = {
         array::API::NPY_BYTE_, array::API::NPY_UBYTE_, array::API::NPY_SHORT_,    array::API::NPY_USHORT_,
         array::API::NPY_INT_,  array::API::NPY_UINT_,  array::API::NPY_LONGLONG_, array::API::NPY_ULONGLONG_ };
 public:
     static int typenum() { return values[detail::log2(sizeof(T)) * 2 + (std::is_unsigned<T>::value ? 1 : 0)]; }
     static PyObject* descr() {
         if (auto obj = array::lookup_api().PyArray_DescrFromType_(typenum())) return obj;
         else pybind11_fail("Unsupported buffer format!");
     }
     template <typename T2 = T, typename std::enable_if<std::is_signed<T2>::value, int>::type = 0>
     static PYBIND11_DESCR name() { return _("int") + _<sizeof(T)*8>(); }
     template <typename T2 = T, typename std::enable_if<!std::is_signed<T2>::value, int>::type = 0>
     static PYBIND11_DESCR name() { return _("uint") + _<sizeof(T)*8>(); }
 };
 template <typename T> constexpr const int npy_format_descriptor<
     T, typename std::enable_if<std::is_integral<T>::value>::type>::values[8];

 #define DECL_FMT(Type, NumPyName, Name) template<> struct npy_format_descriptor<Type> { \
     static int typenum() { return array::API::NumPyName; } \
     static PyObject* descr() { \
         if (auto obj = array::lookup_api().PyArray_DescrFromType_(typenum())) return obj; \
         else pybind11_fail("Unsupported buffer format!"); \
     } \
     static PYBIND11_DESCR name() { return _(Name); } }
 DECL_FMT(float, NPY_FLOAT_, "float32");
 DECL_FMT(double, NPY_DOUBLE_, "float64");
 DECL_FMT(bool, NPY_BOOL_, "bool");
 DECL_FMT(std::complex<float>, NPY_CFLOAT_, "complex64");
 DECL_FMT(std::complex<double>, NPY_CDOUBLE_, "complex128");
 #undef DECL_FMT

 struct field_descriptor {
     const char *name;
     int offset;
     PyObject *descr;
 };

 template <typename T> struct npy_format_descriptor
 <T, typename std::enable_if<std::is_pod<T>::value && // offsetof only works correctly for POD types
                             !std::is_integral<T>::value &&
                             !std::is_same<T, float>::value &&
                             !std::is_same<T, bool>::value &&
                             !std::is_same<T, std::complex<float>>::value &&
                             !std::is_same<T, std::complex<double>>::value>::type>
 {
     static PYBIND11_DESCR name() { return _("user-defined"); }

     static PyObject* descr() {
         if (!descr_())
             pybind11_fail("NumPy: unsupported buffer format!");
         return descr_();
     }

     static const char* format_str() {
         return format_str_();
     }

     static void register_dtype(std::initializer_list<field_descriptor> fields) {
         array::API& api = array::lookup_api();
         auto args = py::dict();
         py::list names { }, offsets { }, formats { };
         std::vector<py::object> dtypes;
         for (auto field : fields) {
             names.append(py::str(field.name));
             offsets.append(py::int_(field.offset));
             if (!field.descr)
                 pybind11_fail("NumPy: unsupported field dtype");
             dtypes.emplace_back(field.descr, false);
             formats.append(dtypes.back());
         }
         args["names"] = names;
         args["offsets"] = offsets;
         args["formats"] = formats;
         if (!api.PyArray_DescrConverter_(args.release().ptr(), &descr_()) || !descr_())
             pybind11_fail("NumPy: failed to create structured dtype");
         auto np = module::import("numpy");
         auto empty = (object) np.attr("empty");
         if (auto arr = (object) empty(py::int_(0), object(descr(), true)))
             if (auto view = PyMemoryView_FromObject(arr.ptr()))
                 if (auto info = PyMemoryView_GET_BUFFER(view)) {
                     std::strncpy(format_str_(), info->format, 4096);
                     return;
                 }
         pybind11_fail("NumPy: failed to extract buffer format");
     }

 private:
     static inline PyObject*& descr_() { static PyObject *ptr = nullptr; return ptr; }
     static inline char* format_str_() { static char s[4096]; return s; }
 };

 #define FIELD_DESCRIPTOR(Type, Field) \
     ::pybind11::detail::field_descriptor { \
         #Field, offsetof(Type, Field), \
         ::pybind11::detail::npy_format_descriptor<decltype(static_cast<Type*>(0)->Field)>::descr() }

 // The main idea of this macro is borrowed from https://github.com/swansontec/map-macro
 // (C) William Swanson, Paul Fultz
 #define EVAL0(...) __VA_ARGS__
 #define EVAL1(...) EVAL0 (EVAL0 (EVAL0 (__VA_ARGS__)))
 #define EVAL2(...) EVAL1 (EVAL1 (EVAL1 (__VA_ARGS__)))
 #define EVAL3(...) EVAL2 (EVAL2 (EVAL2 (__VA_ARGS__)))
 #define EVAL4(...) EVAL3 (EVAL3 (EVAL3 (__VA_ARGS__)))
 #define EVAL(...)  EVAL4 (EVAL4 (EVAL4 (__VA_ARGS__)))
 #define MAP_END(...)
 #define MAP_OUT
 #define MAP_COMMA ,
 #define MAP_GET_END() 0, MAP_END
 #define MAP_NEXT0(test, next, ...) next MAP_OUT
 #define MAP_NEXT1(test, next) MAP_NEXT0 (test, next, 0)
 #define MAP_NEXT(test, next)  MAP_NEXT1 (MAP_GET_END test, next)
 #define MAP_LIST_NEXT1(test, next) MAP_NEXT0 (test, MAP_COMMA next, 0)
 #define MAP_LIST_NEXT(test, next)  MAP_LIST_NEXT1 (MAP_GET_END test, next)
 #define MAP_LIST0(f, t, x, peek, ...) f(t, x) MAP_LIST_NEXT (peek, MAP_LIST1) (f, t, peek, __VA_ARGS__)
 #define MAP_LIST1(f, t, x, peek, ...) f(t, x) MAP_LIST_NEXT (peek, MAP_LIST0) (f, t, peek, __VA_ARGS__)
 #define MAP_LIST(f, t, ...) EVAL (MAP_LIST1 (f, t, __VA_ARGS__, (), 0))

 #define PYBIND11_DTYPE(Type, ...) \
     ::pybind11::detail::npy_format_descriptor<Type>::register_dtype({MAP_LIST(FIELD_DESCRIPTOR, Type, __VA_ARGS__)})

 template  <class T>
 using array_iterator = typename std::add_pointer<T>::type;

 template <class T>
 array_iterator<T> array_begin(const buffer_info& buffer) {
     return array_iterator<T>(reinterpret_cast<T*>(buffer.ptr));
 }

 template <class T>
 array_iterator<T> array_end(const buffer_info& buffer) {
     return array_iterator<T>(reinterpret_cast<T*>(buffer.ptr) + buffer.size);
 }

 class common_iterator {
 public:
     using container_type = std::vector<size_t>;
     using value_type = container_type::value_type;
     using size_type = container_type::size_type;

     common_iterator() : p_ptr(0), m_strides() {}

     common_iterator(void* ptr, const container_type& strides, const std::vector<size_t>& shape)
         : p_ptr(reinterpret_cast<char*>(ptr)), m_strides(strides.size()) {
         m_strides.back() = static_cast<value_type>(strides.back());
         for (size_type i = m_strides.size() - 1; i != 0; --i) {
             size_type j = i - 1;
             value_type s = static_cast<value_type>(shape[i]);
             m_strides[j] = strides[j] + m_strides[i] - strides[i] * s;
         }
     }

     void increment(size_type dim) {
         p_ptr += m_strides[dim];
     }

     void* data() const {
         return p_ptr;
     }

 private:
     char* p_ptr;
     container_type m_strides;
 };

 template <size_t N> class multi_array_iterator {
 public:
     using container_type = std::vector<size_t>;

     multi_array_iterator(const std::array<buffer_info, N> &buffers,
                          const std::vector<size_t> &shape)
         : m_shape(shape.size()), m_index(shape.size(), 0),
           m_common_iterator() {

         // Manual copy to avoid conversion warning if using std::copy
         for (size_t i = 0; i < shape.size(); ++i)
             m_shape[i] = static_cast<container_type::value_type>(shape[i]);

         container_type strides(shape.size());
         for (size_t i = 0; i < N; ++i)
             init_common_iterator(buffers[i], shape, m_common_iterator[i], strides);
     }

     multi_array_iterator& operator++() {
         for (size_t j = m_index.size(); j != 0; --j) {
             size_t i = j - 1;
             if (++m_index[i] != m_shape[i]) {
                 increment_common_iterator(i);
                 break;
             } else {
                 m_index[i] = 0;
             }
         }
         return *this;
     }

     template <size_t K, class T> const T& data() const {
         return *reinterpret_cast<T*>(m_common_iterator[K].data());
     }

 private:

     using common_iter = common_iterator;

     void init_common_iterator(const buffer_info &buffer,
                               const std::vector<size_t> &shape,
                               common_iter &iterator, container_type &strides) {
         auto buffer_shape_iter = buffer.shape.rbegin();
         auto buffer_strides_iter = buffer.strides.rbegin();
         auto shape_iter = shape.rbegin();
         auto strides_iter = strides.rbegin();

         while (buffer_shape_iter != buffer.shape.rend()) {
             if (*shape_iter == *buffer_shape_iter)
                 *strides_iter = static_cast<size_t>(*buffer_strides_iter);
             else
                 *strides_iter = 0;

             ++buffer_shape_iter;
             ++buffer_strides_iter;
             ++shape_iter;
             ++strides_iter;
         }

         std::fill(strides_iter, strides.rend(), 0);
         iterator = common_iter(buffer.ptr, strides, shape);
     }

     void increment_common_iterator(size_t dim) {
         for (auto &iter : m_common_iterator)
             iter.increment(dim);
     }

     container_type m_shape;
     container_type m_index;
     std::array<common_iter, N> m_common_iterator;
 };

 template <size_t N>
 bool broadcast(const std::array<buffer_info, N>& buffers, size_t& ndim, std::vector<size_t>& shape) {
     ndim = std::accumulate(buffers.begin(), buffers.end(), size_t(0), [](size_t res, const buffer_info& buf) {
         return std::max(res, buf.ndim);
     });

     shape = std::vector<size_t>(ndim, 1);
     bool trivial_broadcast = true;
     for (size_t i = 0; i < N; ++i) {
         auto res_iter = shape.rbegin();
         bool i_trivial_broadcast = (buffers[i].size == 1) || (buffers[i].ndim == ndim);
         for (auto shape_iter = buffers[i].shape.rbegin();
              shape_iter != buffers[i].shape.rend(); ++shape_iter, ++res_iter) {

             if (*res_iter == 1)
                 *res_iter = *shape_iter;
             else if ((*shape_iter != 1) && (*res_iter != *shape_iter))
                 pybind11_fail("pybind11::vectorize: incompatible size/dimension of inputs!");

             i_trivial_broadcast = i_trivial_broadcast && (*res_iter == *shape_iter);
         }
         trivial_broadcast = trivial_broadcast && i_trivial_broadcast;
     }
     return trivial_broadcast;
 }

 template <typename Func, typename Return, typename... Args>
 struct vectorize_helper {
     typename std::remove_reference<Func>::type f;

     template <typename T>
     vectorize_helper(T&&f) : f(std::forward<T>(f)) { }

     object operator()(array_t<Args, array::c_style | array::forcecast>... args) {
         return run(args..., typename make_index_sequence<sizeof...(Args)>::type());
     }

     template <size_t ... Index> object run(array_t<Args, array::c_style | array::forcecast>&... args, index_sequence<Index...> index) {
         /* Request buffers from all parameters */
         const size_t N = sizeof...(Args);

         std::array<buffer_info, N> buffers {{ args.request()... }};

         /* Determine dimensions parameters of output array */
         size_t ndim = 0;
         std::vector<size_t> shape(0);
         bool trivial_broadcast = broadcast(buffers, ndim, shape);

         size_t size = 1;
         std::vector<size_t> strides(ndim);
         if (ndim > 0) {
             strides[ndim-1] = sizeof(Return);
             for (size_t i = ndim - 1; i > 0; --i) {
                 strides[i - 1] = strides[i] * shape[i];
                 size *= shape[i];
             }
             size *= shape[0];
         }

         if (size == 1)
             return cast(f(*((Args *) buffers[Index].ptr)...));

         array result(buffer_info(nullptr, sizeof(Return),
                      format_descriptor<Return>::value(),
             ndim, shape, strides));

         buffer_info buf = result.request();
         Return *output = (Return *) buf.ptr;

         if (trivial_broadcast) {
             /* Call the function */
             for (size_t i=0; i<size; ++i) {
                 output[i] = f((buffers[Index].size == 1
                                ? *((Args *) buffers[Index].ptr)
                                : ((Args *) buffers[Index].ptr)[i])...);
             }
         } else {
             apply_broadcast<N, Index...>(buffers, buf, index);
         }

         return result;
     }

     template <size_t N, size_t... Index>
     void apply_broadcast(const std::array<buffer_info, N> &buffers,
                          buffer_info &output, index_sequence<Index...>) {
         using input_iterator = multi_array_iterator<N>;
         using output_iterator = array_iterator<Return>;

         input_iterator input_iter(buffers, output.shape);
         output_iterator output_end = array_end<Return>(output);

         for (output_iterator iter = array_begin<Return>(output);
              iter != output_end; ++iter, ++input_iter) {
             *iter = f((input_iter.template data<Index, Args>())...);
         }
     }
 };

 template <typename T, int Flags> struct handle_type_name<array_t<T, Flags>> {
     static PYBIND11_DESCR name() { return _("numpy.ndarray[") + type_caster<T>::name() + _("]"); }
 };

 NAMESPACE_END(detail)

 template <typename Func, typename Return, typename... Args>
 detail::vectorize_helper<Func, Return, Args...> vectorize(const Func &f, Return (*) (Args ...)) {
     return detail::vectorize_helper<Func, Return, Args...>(f);
 }

 template <typename Return, typename... Args>
 detail::vectorize_helper<Return (*) (Args ...), Return, Args...> vectorize(Return (*f) (Args ...)) {
     return vectorize<Return (*) (Args ...), Return, Args...>(f, f);
 }

 template <typename func> auto vectorize(func &&f) -> decltype(
         vectorize(std::forward<func>(f), (typename detail::remove_class<decltype(&std::remove_reference<func>::type::operator())>::type *) nullptr)) {
     return vectorize(std::forward<func>(f), (typename detail::remove_class<decltype(
                    &std::remove_reference<func>::type::operator())>::type *) nullptr);
 }

 NAMESPACE_END(pybind11)

 #if defined(_MSC_VER)
 #pragma warning(pop)
 #endif
	/*
	pybind11/numpy.h: Basic NumPy support, vectorize() wrapper

	Copyright (c) 2016 Wenzel Jakob <wenzel.jakob@epfl.ch>

	All rights reserved. Use of this source code is governed by a
	BSD-style license that can be found in the LICENSE file.
	*/

	#pragma once

	#include "pybind11.h"
	#include "complex.h"
	#include <numeric>
	#include <algorithm>
	#include <cstdlib>
	#include <cstring>
	#include <initializer_list>

	#if defined(_MSC_VER)
	#pragma warning(push)
	#pragma warning(disable: 4127) // warning C4127: Conditional expression is constant
	#endif

	NAMESPACE_BEGIN(pybind11)
	namespace detail { template <typename type, typename SFINAE = void> struct npy_format_descriptor { }; }

	class array : public buffer {
	public:
	struct API {
	enum Entries {
	API_PyArray_Type = 2,
	API_PyArray_DescrFromType = 45,
	API_PyArray_FromAny = 69,
	API_PyArray_NewCopy = 85,
	API_PyArray_NewFromDescr = 94,
	API_PyArray_DescrConverter = 174,
	API_PyArray_GetArrayParamsFromObject = 278,

	NPY_C_CONTIGUOUS_ = 0x0001,
	NPY_F_CONTIGUOUS_ = 0x0002,
	NPY_ARRAY_FORCECAST_ = 0x0010,
	NPY_ENSURE_ARRAY_ = 0x0040,
	NPY_BOOL_ = 0,
	NPY_BYTE_, NPY_UBYTE_,
	NPY_SHORT_, NPY_USHORT_,
	NPY_INT_, NPY_UINT_,
	NPY_LONG_, NPY_ULONG_,
	NPY_LONGLONG_, NPY_ULONGLONG_,
	NPY_FLOAT_, NPY_DOUBLE_, NPY_LONGDOUBLE_,
	NPY_CFLOAT_, NPY_CDOUBLE_, NPY_CLONGDOUBLE_
	};

	static API lookup() {
	module m = module::import("numpy.core.multiarray");
	object c = (object) m.attr("_ARRAY_API");
	#if PY_MAJOR_VERSION >= 3
	void api_ptr = (void ) (c ? PyCapsule_GetPointer(c.ptr(), NULL) : nullptr);
	#else
	void api_ptr = (void ) (c ? PyCObject_AsVoidPtr(c.ptr()) : nullptr);
	#endif
	API api;
	#define DECL_NPY_API(Func) api.Func##_ = (decltype(api.Func##_)) api_ptr[API_##Func];
	DECL_NPY_API(PyArray_Type);
	DECL_NPY_API(PyArray_DescrFromType);
	DECL_NPY_API(PyArray_FromAny);
	DECL_NPY_API(PyArray_NewCopy);
	DECL_NPY_API(PyArray_NewFromDescr);
	DECL_NPY_API(PyArray_DescrConverter);
	DECL_NPY_API(PyArray_GetArrayParamsFromObject);
	#undef DECL_NPY_API
	return api;
	}

	bool PyArray_Check_(PyObject *obj) const { return (bool) PyObject_TypeCheck(obj, PyArray_Type_); }

	PyObject (PyArray_DescrFromType_)(int);
	PyObject (PyArray_NewFromDescr_)
	(PyTypeObject , PyObject , int, Py_intptr_t *,
	Py_intptr_t , void , int, PyObject *);
	PyObject (PyArray_NewCopy_)(PyObject *, int);
	PyTypeObject *PyArray_Type_;
	PyObject (PyArray_FromAny_) (PyObject , PyObject , int, int, int, PyObject *);
	int (PyArray_DescrConverter_) (PyObject , PyObject **);
	int (PyArray_GetArrayParamsFromObject_)(PyObject , PyObject , char, PyObject , int ,
	Py_ssize_t , PyObject , PyObject );
	};

	PYBIND11_OBJECT_DEFAULT(array, buffer, lookup_api().PyArray_Check_)

	enum {
	c_style = API::NPY_C_CONTIGUOUS_,
	f_style = API::NPY_F_CONTIGUOUS_,
	forcecast = API::NPY_ARRAY_FORCECAST_
	};

	template <typename Type> array(size_t size, const Type *ptr) {
	API& api = lookup_api();
	PyObject *descr = detail::npy_format_descriptor<Type>::descr();
	Py_intptr_t shape = (Py_intptr_t) size;
	object tmp = object(api.PyArray_NewFromDescr_(
	api.PyArray_Type_, descr, 1, &shape, nullptr, (void *) ptr, 0, nullptr), false);
	if (ptr && tmp)
	tmp = object(api.PyArray_NewCopy_(tmp.ptr(), -1 /* any order */), false);
	if (!tmp)
	pybind11_fail("NumPy: unable to create array!");
	m_ptr = tmp.release().ptr();
	}

	array(const buffer_info &info) {
	PyObject arr = nullptr, descr = nullptr;
	int ndim = 0;
	Py_ssize_t dims[32];

	// allocate zeroed memory if it hasn't been provided
	auto buf_info = info;
	if (!buf_info.ptr)
	buf_info.ptr = std::calloc(info.size, info.itemsize);
	auto view = py::memoryview(buf_info);

	API& api = lookup_api();
	auto res = api.PyArray_GetArrayParamsFromObject_(view.ptr(), nullptr, 1, &descr,
	&ndim, dims, &arr, nullptr);
	if (res < 0 \|\| !arr \|\| descr)
	pybind11_fail("NumPy: unable to convert buffer to an array");
	m_ptr = arr;
	}

	protected:
	static API &lookup_api() {
	static API api = API::lookup();
	return api;
	}

	template <typename T, typename SFINAE> friend struct detail::npy_format_descriptor;
	};

	template <typename T, int ExtraFlags = array::forcecast> class array_t : public array {
	public:
	PYBIND11_OBJECT_CVT(array_t, array, is_non_null, m_ptr = ensure(m_ptr));
	array_t() : array() { }
	array_t(const buffer_info& info) : array(info) {}
	static bool is_non_null(PyObject *ptr) { return ptr != nullptr; }
	static PyObject ensure(PyObject ptr) {
	if (ptr == nullptr)
	return nullptr;
	API &api = lookup_api();
	PyObject *descr = detail::npy_format_descriptor<T>::descr();
	PyObject *result = api.PyArray_FromAny_(ptr, descr, 0, 0, API::NPY_ENSURE_ARRAY_ \| ExtraFlags, nullptr);
	if (!result)
	PyErr_Clear();
	Py_DECREF(ptr);
	return result;
	}
	};

	template <typename T> struct format_descriptor
	<T, typename std::enable_if<std::is_pod<T>::value &&
	!std::is_integral<T>::value &&
	!std::is_same<T, float>::value &&
	!std::is_same<T, bool>::value &&
	!std::is_same<T, std::complex<float>>::value &&
	!std::is_same<T, std::complex<double>>::value>::type>
	{
	static const char *value() {
	return detail::npy_format_descriptor<T>::format_str();
	}
	};

	NAMESPACE_BEGIN(detail)

	template <typename T> struct npy_format_descriptor<T, typename std::enable_if<std::is_integral<T>::value>::type> {
	private:
	constexpr static const int values[8] = {
	array::API::NPY_BYTE_, array::API::NPY_UBYTE_, array::API::NPY_SHORT_, array::API::NPY_USHORT_,
	array::API::NPY_INT_, array::API::NPY_UINT_, array::API::NPY_LONGLONG_, array::API::NPY_ULONGLONG_ };
	public:
	static int typenum() { return values[detail::log2(sizeof(T)) * 2 + (std::is_unsigned<T>::value ? 1 : 0)]; }
	static PyObject* descr() {
	if (auto obj = array::lookup_api().PyArray_DescrFromType_(typenum())) return obj;
	else pybind11_fail("Unsupported buffer format!");
	}
	template <typename T2 = T, typename std::enable_if<std::is_signed<T2>::value, int>::type = 0>
	static PYBIND11_DESCR name() { return _("int") + _<sizeof(T)*8>(); }
	template <typename T2 = T, typename std::enable_if<!std::is_signed<T2>::value, int>::type = 0>
	static PYBIND11_DESCR name() { return _("uint") + _<sizeof(T)*8>(); }
	};
	template <typename T> constexpr const int npy_format_descriptor<
	T, typename std::enable_if<std::is_integral<T>::value>::type>::values[8];

	#define DECL_FMT(Type, NumPyName, Name) template<> struct npy_format_descriptor<Type> { \
	static int typenum() { return array::API::NumPyName; } \
	static PyObject* descr() { \
	if (auto obj = array::lookup_api().PyArray_DescrFromType_(typenum())) return obj; \
	else pybind11_fail("Unsupported buffer format!"); \
	} \
	static PYBIND11_DESCR name() { return _(Name); } }
	DECL_FMT(float, NPY_FLOAT_, "float32");
	DECL_FMT(double, NPY_DOUBLE_, "float64");
	DECL_FMT(bool, NPY_BOOL_, "bool");
	DECL_FMT(std::complex<float>, NPY_CFLOAT_, "complex64");
	DECL_FMT(std::complex<double>, NPY_CDOUBLE_, "complex128");
	#undef DECL_FMT

	struct field_descriptor {
	const char *name;
	int offset;
	PyObject *descr;
	};

	template <typename T> struct npy_format_descriptor
	<T, typename std::enable_if<std::is_pod<T>::value && // offsetof only works correctly for POD types
	!std::is_integral<T>::value &&
	!std::is_same<T, float>::value &&
	!std::is_same<T, bool>::value &&
	!std::is_same<T, std::complex<float>>::value &&
	!std::is_same<T, std::complex<double>>::value>::type>
	{
	static PYBIND11_DESCR name() { return _("user-defined"); }

	static PyObject* descr() {
	if (!descr_())
	pybind11_fail("NumPy: unsupported buffer format!");
	return descr_();
	}

	static const char* format_str() {
	return format_str_();
	}

	static void register_dtype(std::initializer_list<field_descriptor> fields) {
	array::API& api = array::lookup_api();
	auto args = py::dict();
	py::list names { }, offsets { }, formats { };
	std::vector<py::object> dtypes;
	for (auto field : fields) {
	names.append(py::str(field.name));
	offsets.append(py::int_(field.offset));
	if (!field.descr)
	pybind11_fail("NumPy: unsupported field dtype");
	dtypes.emplace_back(field.descr, false);
	formats.append(dtypes.back());
	}
	args["names"] = names;
	args["offsets"] = offsets;
	args["formats"] = formats;
	if (!api.PyArray_DescrConverter_(args.release().ptr(), &descr_()) \|\| !descr_())
	pybind11_fail("NumPy: failed to create structured dtype");
	auto np = module::import("numpy");
	auto empty = (object) np.attr("empty");
	if (auto arr = (object) empty(py::int_(0), object(descr(), true)))
	if (auto view = PyMemoryView_FromObject(arr.ptr()))
	if (auto info = PyMemoryView_GET_BUFFER(view)) {
	std::strncpy(format_str_(), info->format, 4096);
	return;
	}
	pybind11_fail("NumPy: failed to extract buffer format");
	}

	private:
	static inline PyObject& descr_() { static PyObject ptr = nullptr; return ptr; }
	static inline char* format_str_() { static char s[4096]; return s; }
	};

	#define FIELD_DESCRIPTOR(Type, Field) \
	::pybind11::detail::field_descriptor { \
	#Field, offsetof(Type, Field), \
	::pybind11::detail::npy_format_descriptor<decltype(static_cast<Type*>(0)->Field)>::descr() }

	// The main idea of this macro is borrowed from https://github.com/swansontec/map-macro
	// (C) William Swanson, Paul Fultz
	#define EVAL0(...) __VA_ARGS__
	#define EVAL1(...) EVAL0 (EVAL0 (EVAL0 (__VA_ARGS__)))
	#define EVAL2(...) EVAL1 (EVAL1 (EVAL1 (__VA_ARGS__)))
	#define EVAL3(...) EVAL2 (EVAL2 (EVAL2 (__VA_ARGS__)))
	#define EVAL4(...) EVAL3 (EVAL3 (EVAL3 (__VA_ARGS__)))
	#define EVAL(...) EVAL4 (EVAL4 (EVAL4 (__VA_ARGS__)))
	#define MAP_END(...)
	#define MAP_OUT
	#define MAP_COMMA ,
	#define MAP_GET_END() 0, MAP_END
	#define MAP_NEXT0(test, next, ...) next MAP_OUT
	#define MAP_NEXT1(test, next) MAP_NEXT0 (test, next, 0)
	#define MAP_NEXT(test, next) MAP_NEXT1 (MAP_GET_END test, next)
	#define MAP_LIST_NEXT1(test, next) MAP_NEXT0 (test, MAP_COMMA next, 0)
	#define MAP_LIST_NEXT(test, next) MAP_LIST_NEXT1 (MAP_GET_END test, next)
	#define MAP_LIST0(f, t, x, peek, ...) f(t, x) MAP_LIST_NEXT (peek, MAP_LIST1) (f, t, peek, __VA_ARGS__)
	#define MAP_LIST1(f, t, x, peek, ...) f(t, x) MAP_LIST_NEXT (peek, MAP_LIST0) (f, t, peek, __VA_ARGS__)
	#define MAP_LIST(f, t, ...) EVAL (MAP_LIST1 (f, t, __VA_ARGS__, (), 0))

	#define PYBIND11_DTYPE(Type, ...) \
	::pybind11::detail::npy_format_descriptor<Type>::register_dtype({MAP_LIST(FIELD_DESCRIPTOR, Type, __VA_ARGS__)})

	template <class T>
	using array_iterator = typename std::add_pointer<T>::type;

	template <class T>
	array_iterator<T> array_begin(const buffer_info& buffer) {
	return array_iterator<T>(reinterpret_cast<T*>(buffer.ptr));
	}

	template <class T>
	array_iterator<T> array_end(const buffer_info& buffer) {
	return array_iterator<T>(reinterpret_cast<T*>(buffer.ptr) + buffer.size);
	}

	class common_iterator {
	public:
	using container_type = std::vector<size_t>;
	using value_type = container_type::value_type;
	using size_type = container_type::size_type;

	common_iterator() : p_ptr(0), m_strides() {}

	common_iterator(void* ptr, const container_type& strides, const std::vector<size_t>& shape)
	: p_ptr(reinterpret_cast<char*>(ptr)), m_strides(strides.size()) {
	m_strides.back() = static_cast<value_type>(strides.back());
	for (size_type i = m_strides.size() - 1; i != 0; --i) {
	size_type j = i - 1;
	value_type s = static_cast<value_type>(shape[i]);
	m_strides[j] = strides[j] + m_strides[i] - strides[i] * s;
	}
	}

	void increment(size_type dim) {
	p_ptr += m_strides[dim];
	}

	void* data() const {
	return p_ptr;
	}

	private:
	char* p_ptr;
	container_type m_strides;
	};

	template <size_t N> class multi_array_iterator {
	public:
	using container_type = std::vector<size_t>;

	multi_array_iterator(const std::array<buffer_info, N> &buffers,
	const std::vector<size_t> &shape)
	: m_shape(shape.size()), m_index(shape.size(), 0),
	m_common_iterator() {

	// Manual copy to avoid conversion warning if using std::copy
	for (size_t i = 0; i < shape.size(); ++i)
	m_shape[i] = static_cast<container_type::value_type>(shape[i]);

	container_type strides(shape.size());
	for (size_t i = 0; i < N; ++i)
	init_common_iterator(buffers[i], shape, m_common_iterator[i], strides);
	}

	multi_array_iterator& operator++() {
	for (size_t j = m_index.size(); j != 0; --j) {
	size_t i = j - 1;
	if (++m_index[i] != m_shape[i]) {
	increment_common_iterator(i);
	break;
	} else {
	m_index[i] = 0;
	}
	}
	return *this;
	}

	template <size_t K, class T> const T& data() const {
	return reinterpret_cast<T>(m_common_iterator[K].data());
	}

	private:

	using common_iter = common_iterator;

	void init_common_iterator(const buffer_info &buffer,
	const std::vector<size_t> &shape,
	common_iter &iterator, container_type &strides) {
	auto buffer_shape_iter = buffer.shape.rbegin();
	auto buffer_strides_iter = buffer.strides.rbegin();
	auto shape_iter = shape.rbegin();
	auto strides_iter = strides.rbegin();

	while (buffer_shape_iter != buffer.shape.rend()) {
	if (shape_iter == buffer_shape_iter)
	strides_iter = static_cast<size_t>(buffer_strides_iter);
	else
	*strides_iter = 0;

	++buffer_shape_iter;
	++buffer_strides_iter;
	++shape_iter;
	++strides_iter;
	}

	std::fill(strides_iter, strides.rend(), 0);
	iterator = common_iter(buffer.ptr, strides, shape);
	}

	void increment_common_iterator(size_t dim) {
	for (auto &iter : m_common_iterator)
	iter.increment(dim);
	}

	container_type m_shape;
	container_type m_index;
	std::array<common_iter, N> m_common_iterator;
	};

	template <size_t N>
	bool broadcast(const std::array<buffer_info, N>& buffers, size_t& ndim, std::vector<size_t>& shape) {
	ndim = std::accumulate(buffers.begin(), buffers.end(), size_t(0), [](size_t res, const buffer_info& buf) {
	return std::max(res, buf.ndim);
	});

	shape = std::vector<size_t>(ndim, 1);
	bool trivial_broadcast = true;
	for (size_t i = 0; i < N; ++i) {
	auto res_iter = shape.rbegin();
	bool i_trivial_broadcast = (buffers[i].size == 1) \|\| (buffers[i].ndim == ndim);
	for (auto shape_iter = buffers[i].shape.rbegin();
	shape_iter != buffers[i].shape.rend(); ++shape_iter, ++res_iter) {

	if (*res_iter == 1)
	res_iter = shape_iter;
	else if ((shape_iter != 1) && (res_iter != *shape_iter))
	pybind11_fail("pybind11::vectorize: incompatible size/dimension of inputs!");

	i_trivial_broadcast = i_trivial_broadcast && (res_iter == shape_iter);
	}
	trivial_broadcast = trivial_broadcast && i_trivial_broadcast;
	}
	return trivial_broadcast;
	}

	template <typename Func, typename Return, typename... Args>
	struct vectorize_helper {
	typename std::remove_reference<Func>::type f;

	template <typename T>
	vectorize_helper(T&&f) : f(std::forward<T>(f)) { }

	object operator()(array_t<Args, array::c_style \| array::forcecast>... args) {
	return run(args..., typename make_index_sequence<sizeof...(Args)>::type());
	}

	template <size_t ... Index> object run(array_t<Args, array::c_style \| array::forcecast>&... args, index_sequence<Index...> index) {
	/* Request buffers from all parameters */
	const size_t N = sizeof...(Args);

	std::array<buffer_info, N> buffers {{ args.request()... }};

	/* Determine dimensions parameters of output array */
	size_t ndim = 0;
	std::vector<size_t> shape(0);
	bool trivial_broadcast = broadcast(buffers, ndim, shape);

	size_t size = 1;
	std::vector<size_t> strides(ndim);
	if (ndim > 0) {
	strides[ndim-1] = sizeof(Return);
	for (size_t i = ndim - 1; i > 0; --i) {
	strides[i - 1] = strides[i] * shape[i];
	size *= shape[i];
	}
	size *= shape[0];
	}

	if (size == 1)
	return cast(f(((Args ) buffers[Index].ptr)...));

	array result(buffer_info(nullptr, sizeof(Return),
	format_descriptor<Return>::value(),
	ndim, shape, strides));

	buffer_info buf = result.request();
	Return output = (Return ) buf.ptr;

	if (trivial_broadcast) {
	/* Call the function */
	for (size_t i=0; i<size; ++i) {
	output[i] = f((buffers[Index].size == 1
	? ((Args ) buffers[Index].ptr)
	: ((Args *) buffers[Index].ptr)[i])...);
	}
	} else {
	apply_broadcast<N, Index...>(buffers, buf, index);
	}

	return result;
	}

	template <size_t N, size_t... Index>
	void apply_broadcast(const std::array<buffer_info, N> &buffers,
	buffer_info &output, index_sequence<Index...>) {
	using input_iterator = multi_array_iterator<N>;
	using output_iterator = array_iterator<Return>;

	input_iterator input_iter(buffers, output.shape);
	output_iterator output_end = array_end<Return>(output);

	for (output_iterator iter = array_begin<Return>(output);
	iter != output_end; ++iter, ++input_iter) {
	*iter = f((input_iter.template data<Index, Args>())...);
	}
	}
	};

	template <typename T, int Flags> struct handle_type_name<array_t<T, Flags>> {
	static PYBIND11_DESCR name() { return _("numpy.ndarray[") + type_caster<T>::name() + _("]"); }
	};

	NAMESPACE_END(detail)

	template <typename Func, typename Return, typename... Args>
	detail::vectorize_helper<Func, Return, Args...> vectorize(const Func &f, Return (*) (Args ...)) {
	return detail::vectorize_helper<Func, Return, Args...>(f);
	}

	template <typename Return, typename... Args>
	detail::vectorize_helper<Return () (Args ...), Return, Args...> vectorize(Return (f) (Args ...)) {
	return vectorize<Return (*) (Args ...), Return, Args...>(f, f);
	}

	template <typename func> auto vectorize(func &&f) -> decltype(
	vectorize(std::forward<func>(f), (typename detail::remove_class<decltype(&std::remove_reference<func>::type::operator())>::type *) nullptr)) {
	return vectorize(std::forward<func>(f), (typename detail::remove_class<decltype(
	&std::remove_reference<func>::type::operator())>::type *) nullptr);
	}

	NAMESPACE_END(pybind11)

	#if defined(_MSC_VER)
	#pragma warning(pop)
	#endif