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

 /*
     pybind/numpy.h: Basic NumPy support, auto-vectorization support

     Copyright (c) 2015 Wenzel Jakob <wenzel@inf.ethz.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 <pybind/pybind.h>
 #include <pybind/complex.h>

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

 NAMESPACE_BEGIN(pybind)

 template <typename type> 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,
             NPY_C_CONTIGUOUS = 0x0001,
             NPY_F_CONTIGUOUS = 0x0002,
             NPY_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() {
             PyObject *numpy = PyImport_ImportModule("numpy.core.multiarray");
             PyObject *capsule = numpy ? PyObject_GetAttrString(numpy, "_ARRAY_API") : nullptr;
 #if PY_MAJOR_VERSION >= 3
             void **api_ptr = (void **) (capsule ? PyCapsule_GetPointer(capsule, NULL) : nullptr);
 #else
             void **api_ptr = (void **) (capsule ? PyCObject_AsVoidPtr(capsule) : nullptr);
 #endif
             Py_XDECREF(capsule);
             Py_XDECREF(numpy);
             if (api_ptr == nullptr)
                 throw std::runtime_error("Could not acquire pointer to NumPy API!");
             API api;
             api.PyArray_Type          = (decltype(api.PyArray_Type))          api_ptr[API_PyArray_Type];
             api.PyArray_DescrFromType = (decltype(api.PyArray_DescrFromType)) api_ptr[API_PyArray_DescrFromType];
             api.PyArray_FromAny       = (decltype(api.PyArray_FromAny))       api_ptr[API_PyArray_FromAny];
             api.PyArray_NewCopy       = (decltype(api.PyArray_NewCopy))       api_ptr[API_PyArray_NewCopy];
             api.PyArray_NewFromDescr  = (decltype(api.PyArray_NewFromDescr))  api_ptr[API_PyArray_NewFromDescr];
             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 *);
     };

     PYBIND_OBJECT_DEFAULT(array, buffer, lookup_api().PyArray_Check)

     template <typename Type> array(size_t size, const Type *ptr) {
         API& api = lookup_api();
         PyObject *descr = api.PyArray_DescrFromType(npy_format_descriptor<Type>::value);
         if (descr == nullptr)
             throw std::runtime_error("NumPy: unsupported buffer format!");
         Py_intptr_t shape = (Py_intptr_t) size;
         PyObject *tmp = api.PyArray_NewFromDescr(
             api.PyArray_Type, descr, 1, &shape, nullptr, (void *) ptr, 0, nullptr);
         if (tmp == nullptr)
             throw std::runtime_error("NumPy: unable to create array!");
         m_ptr = api.PyArray_NewCopy(tmp, -1 /* any order */);
         Py_DECREF(tmp);
         if (m_ptr == nullptr)
             throw std::runtime_error("NumPy: unable to copy array!");
     }

     array(const buffer_info &info) {
         API& api = lookup_api();
         if (info.format.size() != 1)
             throw std::runtime_error("Unsupported buffer format!");
         int fmt = (int) info.format[0];
         if (info.format == "Zd")
             fmt = API::NPY_CDOUBLE;
         else if (info.format == "Zf")
             fmt = API::NPY_CFLOAT;
         PyObject *descr = api.PyArray_DescrFromType(fmt);
         if (descr == nullptr)
             throw std::runtime_error("NumPy: unsupported buffer format '" + info.format + "'!");
         PyObject *tmp = api.PyArray_NewFromDescr(
             api.PyArray_Type, descr, info.ndim, (Py_intptr_t *) &info.shape[0],
             (Py_intptr_t *) &info.strides[0], info.ptr, 0, nullptr);
         if (tmp == nullptr)
             throw std::runtime_error("NumPy: unable to create array!");
         m_ptr = api.PyArray_NewCopy(tmp, -1 /* any order */);
         Py_DECREF(tmp);
         if (m_ptr == nullptr)
             throw std::runtime_error("NumPy: unable to copy array!");
     }

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

 template <typename T> class array_t : public array {
 public:
     PYBIND_OBJECT_CVT(array_t, array, is_non_null, m_ptr = ensure(m_ptr));
     array_t() : array() { }
     static bool is_non_null(PyObject *ptr) { return ptr != nullptr; }
     PyObject *ensure(PyObject *ptr) {
         if (ptr == nullptr)
             return nullptr;
         API &api = lookup_api();
         PyObject *descr = api.PyArray_DescrFromType(npy_format_descriptor<T>::value);
         return api.PyArray_FromAny(ptr, descr, 0, 0,
                                    API::NPY_C_CONTIGUOUS | API::NPY_ENSURE_ARRAY |
                                    API::NPY_NPY_ARRAY_FORCECAST, nullptr);
     }
 };

 #define DECL_FMT(t, n) template<> struct npy_format_descriptor<t> { enum { value = array::API::n }; }
 DECL_FMT(int8_t, NPY_BYTE);  DECL_FMT(uint8_t, NPY_UBYTE); DECL_FMT(int16_t, NPY_SHORT);
 DECL_FMT(uint16_t, NPY_USHORT); DECL_FMT(int32_t, NPY_INT); DECL_FMT(uint32_t, NPY_UINT);
 DECL_FMT(int64_t, NPY_LONGLONG); DECL_FMT(uint64_t, NPY_ULONGLONG); DECL_FMT(float, NPY_FLOAT);
 DECL_FMT(double, NPY_DOUBLE); DECL_FMT(bool, NPY_BOOL); DECL_FMT(std::complex<float>, NPY_CFLOAT);
 DECL_FMT(std::complex<double>, NPY_CDOUBLE);
 #undef DECL_FMT


 NAMESPACE_BEGIN(detail)
 PYBIND_TYPE_CASTER_PYTYPE(array)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<int8_t>)  PYBIND_TYPE_CASTER_PYTYPE(array_t<uint8_t>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<int16_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint16_t>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<int32_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint32_t>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<int64_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint64_t>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<float>)   PYBIND_TYPE_CASTER_PYTYPE(array_t<double>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<std::complex<float>>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<std::complex<double>>)
 PYBIND_TYPE_CASTER_PYTYPE(array_t<bool>)

 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>... args) {
         return run(args..., typename make_index_sequence<sizeof...(Args)>::type());
     }

     template <size_t ... Index> object run(array_t<Args>&... args, index_sequence<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 */
         int ndim = 0; size_t count = 0;
         std::vector<size_t> shape;
         for (size_t i=0; i<N; ++i) {
             if (buffers[i].count > count) {
                 ndim = buffers[i].ndim;
                 shape = buffers[i].shape;
                 count = buffers[i].count;
             }
         }
         std::vector<size_t> strides(ndim);
         if (ndim > 0) {
             strides[ndim-1] = sizeof(Return);
             for (int i=ndim-1; i>0; --i)
                 strides[i-1] = strides[i] * shape[i];
         }

         /* Check if the parameters are actually compatible */
         for (size_t i=0; i<N; ++i) {
             if (buffers[i].count != 1 && (buffers[i].ndim != ndim || buffers[i].shape != shape))
                 throw std::runtime_error("pybind::vectorize: incompatible size/dimension of inputs!");
         }

         /* Call the function */
         std::vector<Return> result(count);
         for (size_t i=0; i<count; ++i)
             result[i] = f((buffers[Index].count == 1
                                ? *((Args *) buffers[Index].ptr)
                                :  ((Args *) buffers[Index].ptr)[i])...);

         if (count == 1)
             return cast(result[0]);

         /* Return the result */
         return array(buffer_info(result.data(), sizeof(Return),
             format_descriptor<Return>::value(),
             ndim, shape, strides));
     }
 };

 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(pybind)

 #if defined(_MSC_VER)
 #pragma warning(pop)
 #endif
	/*
	pybind/numpy.h: Basic NumPy support, auto-vectorization support

	Copyright (c) 2015 Wenzel Jakob <wenzel@inf.ethz.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 <pybind/pybind.h>
	#include <pybind/complex.h>

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

	NAMESPACE_BEGIN(pybind)

	template <typename type> 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,
	NPY_C_CONTIGUOUS = 0x0001,
	NPY_F_CONTIGUOUS = 0x0002,
	NPY_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() {
	PyObject *numpy = PyImport_ImportModule("numpy.core.multiarray");
	PyObject *capsule = numpy ? PyObject_GetAttrString(numpy, "_ARRAY_API") : nullptr;
	#if PY_MAJOR_VERSION >= 3
	void api_ptr = (void ) (capsule ? PyCapsule_GetPointer(capsule, NULL) : nullptr);
	#else
	void api_ptr = (void ) (capsule ? PyCObject_AsVoidPtr(capsule) : nullptr);
	#endif
	Py_XDECREF(capsule);
	Py_XDECREF(numpy);
	if (api_ptr == nullptr)
	throw std::runtime_error("Could not acquire pointer to NumPy API!");
	API api;
	api.PyArray_Type = (decltype(api.PyArray_Type)) api_ptr[API_PyArray_Type];
	api.PyArray_DescrFromType = (decltype(api.PyArray_DescrFromType)) api_ptr[API_PyArray_DescrFromType];
	api.PyArray_FromAny = (decltype(api.PyArray_FromAny)) api_ptr[API_PyArray_FromAny];
	api.PyArray_NewCopy = (decltype(api.PyArray_NewCopy)) api_ptr[API_PyArray_NewCopy];
	api.PyArray_NewFromDescr = (decltype(api.PyArray_NewFromDescr)) api_ptr[API_PyArray_NewFromDescr];
	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 *);
	};

	PYBIND_OBJECT_DEFAULT(array, buffer, lookup_api().PyArray_Check)

	template <typename Type> array(size_t size, const Type *ptr) {
	API& api = lookup_api();
	PyObject *descr = api.PyArray_DescrFromType(npy_format_descriptor<Type>::value);
	if (descr == nullptr)
	throw std::runtime_error("NumPy: unsupported buffer format!");
	Py_intptr_t shape = (Py_intptr_t) size;
	PyObject *tmp = api.PyArray_NewFromDescr(
	api.PyArray_Type, descr, 1, &shape, nullptr, (void *) ptr, 0, nullptr);
	if (tmp == nullptr)
	throw std::runtime_error("NumPy: unable to create array!");
	m_ptr = api.PyArray_NewCopy(tmp, -1 /* any order */);
	Py_DECREF(tmp);
	if (m_ptr == nullptr)
	throw std::runtime_error("NumPy: unable to copy array!");
	}

	array(const buffer_info &info) {
	API& api = lookup_api();
	if (info.format.size() != 1)
	throw std::runtime_error("Unsupported buffer format!");
	int fmt = (int) info.format[0];
	if (info.format == "Zd")
	fmt = API::NPY_CDOUBLE;
	else if (info.format == "Zf")
	fmt = API::NPY_CFLOAT;
	PyObject *descr = api.PyArray_DescrFromType(fmt);
	if (descr == nullptr)
	throw std::runtime_error("NumPy: unsupported buffer format '" + info.format + "'!");
	PyObject *tmp = api.PyArray_NewFromDescr(
	api.PyArray_Type, descr, info.ndim, (Py_intptr_t *) &info.shape[0],
	(Py_intptr_t *) &info.strides[0], info.ptr, 0, nullptr);
	if (tmp == nullptr)
	throw std::runtime_error("NumPy: unable to create array!");
	m_ptr = api.PyArray_NewCopy(tmp, -1 /* any order */);
	Py_DECREF(tmp);
	if (m_ptr == nullptr)
	throw std::runtime_error("NumPy: unable to copy array!");
	}

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

	template <typename T> class array_t : public array {
	public:
	PYBIND_OBJECT_CVT(array_t, array, is_non_null, m_ptr = ensure(m_ptr));
	array_t() : array() { }
	static bool is_non_null(PyObject *ptr) { return ptr != nullptr; }
	PyObject ensure(PyObject ptr) {
	if (ptr == nullptr)
	return nullptr;
	API &api = lookup_api();
	PyObject *descr = api.PyArray_DescrFromType(npy_format_descriptor<T>::value);
	return api.PyArray_FromAny(ptr, descr, 0, 0,
	API::NPY_C_CONTIGUOUS \| API::NPY_ENSURE_ARRAY \|
	API::NPY_NPY_ARRAY_FORCECAST, nullptr);
	}
	};

	#define DECL_FMT(t, n) template<> struct npy_format_descriptor<t> { enum { value = array::API::n }; }
	DECL_FMT(int8_t, NPY_BYTE); DECL_FMT(uint8_t, NPY_UBYTE); DECL_FMT(int16_t, NPY_SHORT);
	DECL_FMT(uint16_t, NPY_USHORT); DECL_FMT(int32_t, NPY_INT); DECL_FMT(uint32_t, NPY_UINT);
	DECL_FMT(int64_t, NPY_LONGLONG); DECL_FMT(uint64_t, NPY_ULONGLONG); DECL_FMT(float, NPY_FLOAT);
	DECL_FMT(double, NPY_DOUBLE); DECL_FMT(bool, NPY_BOOL); DECL_FMT(std::complex<float>, NPY_CFLOAT);
	DECL_FMT(std::complex<double>, NPY_CDOUBLE);
	#undef DECL_FMT


	NAMESPACE_BEGIN(detail)
	PYBIND_TYPE_CASTER_PYTYPE(array)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<int8_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint8_t>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<int16_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint16_t>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<int32_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint32_t>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<int64_t>) PYBIND_TYPE_CASTER_PYTYPE(array_t<uint64_t>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<float>) PYBIND_TYPE_CASTER_PYTYPE(array_t<double>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<std::complex<float>>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<std::complex<double>>)
	PYBIND_TYPE_CASTER_PYTYPE(array_t<bool>)

	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>... args) {
	return run(args..., typename make_index_sequence<sizeof...(Args)>::type());
	}

	template <size_t ... Index> object run(array_t<Args>&... args, index_sequence<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 */
	int ndim = 0; size_t count = 0;
	std::vector<size_t> shape;
	for (size_t i=0; i<N; ++i) {
	if (buffers[i].count > count) {
	ndim = buffers[i].ndim;
	shape = buffers[i].shape;
	count = buffers[i].count;
	}
	}
	std::vector<size_t> strides(ndim);
	if (ndim > 0) {
	strides[ndim-1] = sizeof(Return);
	for (int i=ndim-1; i>0; --i)
	strides[i-1] = strides[i] * shape[i];
	}

	/* Check if the parameters are actually compatible */
	for (size_t i=0; i<N; ++i) {
	if (buffers[i].count != 1 && (buffers[i].ndim != ndim \|\| buffers[i].shape != shape))
	throw std::runtime_error("pybind::vectorize: incompatible size/dimension of inputs!");
	}

	/* Call the function */
	std::vector<Return> result(count);
	for (size_t i=0; i<count; ++i)
	result[i] = f((buffers[Index].count == 1
	? ((Args ) buffers[Index].ptr)
	: ((Args *) buffers[Index].ptr)[i])...);

	if (count == 1)
	return cast(result[0]);

	/* Return the result */
	return array(buffer_info(result.data(), sizeof(Return),
	format_descriptor<Return>::value(),
	ndim, shape, strides));
	}
	};

	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(pybind)

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