diff --git a/Wrapping/Python/MITKWRAP.i b/Wrapping/Python/MITKWRAP.i index 695bac0fb9..0ec67c3e37 100644 --- a/Wrapping/Python/MITKWRAP.i +++ b/Wrapping/Python/MITKWRAP.i @@ -1,25 +1,125 @@ %begin %{ #ifdef _MSC_VER #define SWIG_PYTHON_INTERPRETER_NO_DEBUG #endif +#define SWIG_FILE_WITH_INIT %} %module pyMITK +%include "numpy.i" +%naturalvar; // All non-primitive types will use const reference typemaps +%include #define MITKCORE_EXPORT %{ - -#include +//#include +#include +#include +#include #include +#include +// using mitk::DataStorage; +// using mitk::IFileReader; +// using mitk::IFileWriter; +// using mitk::Operation; +// using mitk::BaseProperty; +// using mitk::BaseGeometry; +// using mitk::TimeGeometry; +// using mitk::PropertyList; +// using mitk::Point3D; +// using itk::DataObject; + +struct TypeDefinitions +{ + static const int ComponentTypeUInt8 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeInt8 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeUInt16 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeInt16 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeUInt32 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeInt32 = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeFloat = (int)mitk::MapPixelType::value>::IOComponentType; + static const int ComponentTypeDouble = (int)mitk::MapPixelType::value>::IOComponentType; +}; -using mitk::Operation; -using mitk::BaseProperty; -using mitk::BaseGeometry; -using mitk::TimeGeometry; -using mitk::PropertyList; -using mitk::Point3D; -using itk::DataObject; +NPY_TYPES MakePixelTypeFromTypeID(int componentTypeID) +{ + switch (componentTypeID) + { + case TypeDefinitions::ComponentTypeUInt8 : + return NPY_USHORT; + case TypeDefinitions::ComponentTypeInt8 : + return NPY_SHORT; + case TypeDefinitions::ComponentTypeUInt16 : + return NPY_USHORT; + case TypeDefinitions::ComponentTypeInt16 : + return NPY_SHORT; + case TypeDefinitions::ComponentTypeUInt32 : + return NPY_UINT; + case TypeDefinitions::ComponentTypeInt32 : + return NPY_INT; + case TypeDefinitions::ComponentTypeFloat : + return NPY_FLOAT; + case TypeDefinitions::ComponentTypeDouble : + return NPY_DOUBLE; + default: + return NPY_DOUBLE; + } +} + +%} +%init %{ + import_array(); %} -%include +%typemap(out) std::vector { + size_t dims = $1.size(); + $result = PyArray_SimpleNewFromData(1, (npy_intp*) &(dims), NPY_DOUBLE, (void*)$1.data()); + PyArray_ENABLEFLAGS((PyArrayObject*)$result, NPY_ARRAY_OWNDATA); +} + +%typemap(out) mitk::Image::Pointer { + unsigned int dim = $1->GetDimension(); + std::cout << "dim: " << dim << std::endl; + auto* writeAccess = new mitk::ImageWriteAccessor($1); + void* mitkBufferPtr = writeAccess->GetData(); + std::cout << "pixel type: " << $1->GetPixelType().GetComponentTypeAsString()<< std::endl; + std::cout << "pixel component: " << $1->GetPixelType().GetComponentType()<< std::endl; + std::cout << "numpy type: "<< MakePixelTypeFromTypeID((int)$1->GetPixelType().GetComponentType())<< std::endl;; + std::vector size; + for (int i = 0; i < dim; ++i) + { + size.push_back($1->GetDimension(i)); + } + // if the image is a vector just treat is as another dimension + if ($1->GetPixelType().GetNumberOfComponents() > 1) + { + size.push_back( $1->GetPixelType().GetNumberOfComponents() ); + } + std::reverse(size.begin(), size.end()); + npy_intp shape[size.size()];//= {112, 122}; + for(int i = 0; i < size.size(); ++i ) + shape[i] = size.data()[i]; + + $result = PyArray_SimpleNewFromData(dim, shape, + MakePixelTypeFromTypeID((int)$1->GetPixelType().GetComponentType()), + mitkBufferPtr); + //PyArray_ENABLEFLAGS((PyArrayObject*)$result, NPY_ARRAY_OWNDATA); + //delete writeAccess; Don't delete write access! +} + +%inline +{ + mitk::Image::Pointer GetImageAsNumpy(std::string filename) + { + auto mitkImage = mitk::IOUtil::Load(filename); + return mitkImage; + } +} + +//%include +//%include %include +%pythoncode %{ +def GetName(): + return 'pyMITK' +%} \ No newline at end of file diff --git a/Wrapping/Python/numpy.i b/Wrapping/Python/numpy.i new file mode 100644 index 0000000000..c8c26cbcd3 --- /dev/null +++ b/Wrapping/Python/numpy.i @@ -0,0 +1,2970 @@ +/* -*- C -*- (not really, but good for syntax highlighting) */ + +/* + * Copyright (c) 2005-2015, NumPy Developers. + * All rights reserved. + * + * Redistribution and use in source and binary forms, with or without + * modification, are permitted provided that the following conditions are + * met: + * + * * Redistributions of source code must retain the above copyright + * notice, this list of conditions and the following disclaimer. + * + * * Redistributions in binary form must reproduce the above + * copyright notice, this list of conditions and the following + * disclaimer in the documentation and/or other materials provided + * with the distribution. + * + * * Neither the name of the NumPy Developers nor the names of any + * contributors may be used to endorse or promote products derived + * from this software without specific prior written permission. + * + * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS + * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT + * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR + * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT + * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, + * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT + * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, + * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY + * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT + * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE + * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + */ + +#ifdef SWIGPYTHON + +%{ +#ifndef SWIG_FILE_WITH_INIT +#define NO_IMPORT_ARRAY +#endif +#include "stdio.h" +#define NPY_NO_DEPRECATED_API NPY_1_7_API_VERSION +#include +%} + +/**********************************************************************/ + +%fragment("NumPy_Backward_Compatibility", "header") +{ +%#if NPY_API_VERSION < NPY_1_7_API_VERSION +%#define NPY_ARRAY_DEFAULT NPY_DEFAULT +%#define NPY_ARRAY_FARRAY NPY_FARRAY +%#define NPY_FORTRANORDER NPY_FORTRAN +%#endif +} + +/**********************************************************************/ + +/* The following code originally appeared in + * enthought/kiva/agg/src/numeric.i written by Eric Jones. It was + * translated from C++ to C by John Hunter. Bill Spotz has modified + * it to fix some minor bugs, upgrade from Numeric to numpy (all + * versions), add some comments and functionality, and convert from + * direct code insertion to SWIG fragments. + */ + +%fragment("NumPy_Macros", "header") +{ +/* Macros to extract array attributes. + */ +%#if NPY_API_VERSION < NPY_1_7_API_VERSION +%#define is_array(a) ((a) && PyArray_Check((PyArrayObject*)a)) +%#define array_type(a) (int)(PyArray_TYPE((PyArrayObject*)a)) +%#define array_numdims(a) (((PyArrayObject*)a)->nd) +%#define array_dimensions(a) (((PyArrayObject*)a)->dimensions) +%#define array_size(a,i) (((PyArrayObject*)a)->dimensions[i]) +%#define array_strides(a) (((PyArrayObject*)a)->strides) +%#define array_stride(a,i) (((PyArrayObject*)a)->strides[i]) +%#define array_data(a) (((PyArrayObject*)a)->data) +%#define array_descr(a) (((PyArrayObject*)a)->descr) +%#define array_flags(a) (((PyArrayObject*)a)->flags) +%#define array_clearflags(a,f) (((PyArrayObject*)a)->flags) &= ~f +%#define array_enableflags(a,f) (((PyArrayObject*)a)->flags) = f +%#define array_is_fortran(a) (PyArray_ISFORTRAN((PyArrayObject*)a)) +%#else +%#define is_array(a) ((a) && PyArray_Check(a)) +%#define array_type(a) PyArray_TYPE((PyArrayObject*)a) +%#define array_numdims(a) PyArray_NDIM((PyArrayObject*)a) +%#define array_dimensions(a) PyArray_DIMS((PyArrayObject*)a) +%#define array_strides(a) PyArray_STRIDES((PyArrayObject*)a) +%#define array_stride(a,i) PyArray_STRIDE((PyArrayObject*)a,i) +%#define array_size(a,i) PyArray_DIM((PyArrayObject*)a,i) +%#define array_data(a) PyArray_DATA((PyArrayObject*)a) +%#define array_descr(a) PyArray_DESCR((PyArrayObject*)a) +%#define array_flags(a) PyArray_FLAGS((PyArrayObject*)a) +%#define array_enableflags(a,f) PyArray_ENABLEFLAGS((PyArrayObject*)a,f) +%#define array_clearflags(a,f) PyArray_CLEARFLAGS((PyArrayObject*)a,f) +%#define array_is_fortran(a) (PyArray_IS_F_CONTIGUOUS((PyArrayObject*)a)) +%#endif +%#define array_is_contiguous(a) (PyArray_ISCONTIGUOUS((PyArrayObject*)a)) +%#define array_is_native(a) (PyArray_ISNOTSWAPPED((PyArrayObject*)a)) +} + +/**********************************************************************/ + +%fragment("NumPy_Utilities", + "header") +{ + /* Given a PyObject, return a string describing its type. + */ + const char* pytype_string(PyObject* py_obj) + { + if (py_obj == NULL ) return "C NULL value"; + if (py_obj == Py_None ) return "Python None" ; + if (PyCallable_Check(py_obj)) return "callable" ; + if (PyBytes_Check( py_obj)) return "string" ; + if (PyLong_Check( py_obj)) return "int" ; + if (PyFloat_Check( py_obj)) return "float" ; + if (PyDict_Check( py_obj)) return "dict" ; + if (PyList_Check( py_obj)) return "list" ; + if (PyTuple_Check( py_obj)) return "tuple" ; + + return "unknown type"; + } + + /* Given a NumPy typecode, return a string describing the type. + */ + const char* typecode_string(int typecode) + { + static const char* type_names[25] = {"bool", + "byte", + "unsigned byte", + "short", + "unsigned short", + "int", + "unsigned int", + "long", + "unsigned long", + "long long", + "unsigned long long", + "float", + "double", + "long double", + "complex float", + "complex double", + "complex long double", + "object", + "string", + "unicode", + "void", + "ntypes", + "notype", + "char", + "unknown"}; + return typecode < 24 ? type_names[typecode] : type_names[24]; + } + + /* Make sure input has correct numpy type. This now just calls + PyArray_EquivTypenums(). + */ + int type_match(int actual_type, + int desired_type) + { + return PyArray_EquivTypenums(actual_type, desired_type); + } + +void free_cap(PyObject * cap) + { + void* array = (void*) PyCapsule_GetPointer(cap,SWIGPY_CAPSULE_NAME); + if (array != NULL) free(array); + } + + +} + +/**********************************************************************/ + +%fragment("NumPy_Object_to_Array", + "header", + fragment="NumPy_Backward_Compatibility", + fragment="NumPy_Macros", + fragment="NumPy_Utilities") +{ + /* Given a PyObject pointer, cast it to a PyArrayObject pointer if + * legal. If not, set the python error string appropriately and + * return NULL. + */ + PyArrayObject* obj_to_array_no_conversion(PyObject* input, + int typecode) + { + PyArrayObject* ary = NULL; + if (is_array(input) && (typecode == NPY_NOTYPE || + PyArray_EquivTypenums(array_type(input), typecode))) + { + ary = (PyArrayObject*) input; + } + else if is_array(input) + { + const char* desired_type = typecode_string(typecode); + const char* actual_type = typecode_string(array_type(input)); + PyErr_Format(PyExc_TypeError, + "Array of type '%s' required. Array of type '%s' given", + desired_type, actual_type); + ary = NULL; + } + else + { + const char* desired_type = typecode_string(typecode); + const char* actual_type = pytype_string(input); + PyErr_Format(PyExc_TypeError, + "Array of type '%s' required. A '%s' was given", + desired_type, + actual_type); + ary = NULL; + } + return ary; + } + + /* Convert the given PyObject to a NumPy array with the given + * typecode. On success, return a valid PyArrayObject* with the + * correct type. On failure, the python error string will be set and + * the routine returns NULL. + */ + PyArrayObject* obj_to_array_allow_conversion(PyObject* input, + int typecode, + int* is_new_object) + { + PyArrayObject* ary = NULL; + PyObject* py_obj; + if (is_array(input) && (typecode == NPY_NOTYPE || + PyArray_EquivTypenums(array_type(input),typecode))) + { + ary = (PyArrayObject*) input; + *is_new_object = 0; + } + else + { + py_obj = PyArray_FROMANY(input, typecode, 0, 0, NPY_ARRAY_DEFAULT); + /* If NULL, PyArray_FromObject will have set python error value.*/ + ary = (PyArrayObject*) py_obj; + *is_new_object = 1; + } + return ary; + } + + /* Given a PyArrayObject, check to see if it is contiguous. If so, + * return the input pointer and flag it as not a new object. If it is + * not contiguous, create a new PyArrayObject using the original data, + * flag it as a new object and return the pointer. + */ + PyArrayObject* make_contiguous(PyArrayObject* ary, + int* is_new_object, + int min_dims, + int max_dims) + { + PyArrayObject* result; + if (array_is_contiguous(ary)) + { + result = ary; + *is_new_object = 0; + } + else + { + result = (PyArrayObject*) PyArray_ContiguousFromObject((PyObject*)ary, + array_type(ary), + min_dims, + max_dims); + *is_new_object = 1; + } + return result; + } + + /* Given a PyArrayObject, check to see if it is Fortran-contiguous. + * If so, return the input pointer, but do not flag it as not a new + * object. If it is not Fortran-contiguous, create a new + * PyArrayObject using the original data, flag it as a new object + * and return the pointer. + */ + PyArrayObject* make_fortran(PyArrayObject* ary, + int* is_new_object) + { + PyArrayObject* result; + if (array_is_fortran(ary)) + { + result = ary; + *is_new_object = 0; + } + else + { + Py_INCREF(array_descr(ary)); + result = (PyArrayObject*) PyArray_FromArray(ary, + array_descr(ary), +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + NPY_FORTRANORDER); +%#else + NPY_ARRAY_F_CONTIGUOUS); +%#endif + *is_new_object = 1; + } + return result; + } + + /* Convert a given PyObject to a contiguous PyArrayObject of the + * specified type. If the input object is not a contiguous + * PyArrayObject, a new one will be created and the new object flag + * will be set. + */ + PyArrayObject* obj_to_array_contiguous_allow_conversion(PyObject* input, + int typecode, + int* is_new_object) + { + int is_new1 = 0; + int is_new2 = 0; + PyArrayObject* ary2; + PyArrayObject* ary1 = obj_to_array_allow_conversion(input, + typecode, + &is_new1); + if (ary1) + { + ary2 = make_contiguous(ary1, &is_new2, 0, 0); + if ( is_new1 && is_new2) + { + Py_DECREF(ary1); + } + ary1 = ary2; + } + *is_new_object = is_new1 || is_new2; + return ary1; + } + + /* Convert a given PyObject to a Fortran-ordered PyArrayObject of the + * specified type. If the input object is not a Fortran-ordered + * PyArrayObject, a new one will be created and the new object flag + * will be set. + */ + PyArrayObject* obj_to_array_fortran_allow_conversion(PyObject* input, + int typecode, + int* is_new_object) + { + int is_new1 = 0; + int is_new2 = 0; + PyArrayObject* ary2; + PyArrayObject* ary1 = obj_to_array_allow_conversion(input, + typecode, + &is_new1); + if (ary1) + { + ary2 = make_fortran(ary1, &is_new2); + if (is_new1 && is_new2) + { + Py_DECREF(ary1); + } + ary1 = ary2; + } + *is_new_object = is_new1 || is_new2; + return ary1; + } +} /* end fragment */ + +/**********************************************************************/ + +%fragment("NumPy_Array_Requirements", + "header", + fragment="NumPy_Backward_Compatibility", + fragment="NumPy_Macros") +{ + /* Test whether a python object is contiguous. If array is + * contiguous, return 1. Otherwise, set the python error string and + * return 0. + */ + int require_contiguous(PyArrayObject* ary) + { + int contiguous = 1; + if (!array_is_contiguous(ary)) + { + PyErr_SetString(PyExc_TypeError, + "Array must be contiguous. A non-contiguous array was given"); + contiguous = 0; + } + return contiguous; + } + + /* Test whether a python object is (C_ or F_) contiguous. If array is + * contiguous, return 1. Otherwise, set the python error string and + * return 0. + */ + int require_c_or_f_contiguous(PyArrayObject* ary) + { + int contiguous = 1; + if (!(array_is_contiguous(ary) || array_is_fortran(ary))) + { + PyErr_SetString(PyExc_TypeError, + "Array must be contiguous (C_ or F_). A non-contiguous array was given"); + contiguous = 0; + } + return contiguous; + } + + /* Require that a numpy array is not byte-swapped. If the array is + * not byte-swapped, return 1. Otherwise, set the python error string + * and return 0. + */ + int require_native(PyArrayObject* ary) + { + int native = 1; + if (!array_is_native(ary)) + { + PyErr_SetString(PyExc_TypeError, + "Array must have native byteorder. " + "A byte-swapped array was given"); + native = 0; + } + return native; + } + + /* Require the given PyArrayObject to have a specified number of + * dimensions. If the array has the specified number of dimensions, + * return 1. Otherwise, set the python error string and return 0. + */ + int require_dimensions(PyArrayObject* ary, + int exact_dimensions) + { + int success = 1; + if (array_numdims(ary) != exact_dimensions) + { + PyErr_Format(PyExc_TypeError, + "Array must have %d dimensions. Given array has %d dimensions", + exact_dimensions, + array_numdims(ary)); + success = 0; + } + return success; + } + + /* Require the given PyArrayObject to have one of a list of specified + * number of dimensions. If the array has one of the specified number + * of dimensions, return 1. Otherwise, set the python error string + * and return 0. + */ + int require_dimensions_n(PyArrayObject* ary, + int* exact_dimensions, + int n) + { + int success = 0; + int i; + char dims_str[255] = ""; + char s[255]; + for (i = 0; i < n && !success; i++) + { + if (array_numdims(ary) == exact_dimensions[i]) + { + success = 1; + } + } + if (!success) + { + for (i = 0; i < n-1; i++) + { + sprintf(s, "%d, ", exact_dimensions[i]); + strcat(dims_str,s); + } + sprintf(s, " or %d", exact_dimensions[n-1]); + strcat(dims_str,s); + PyErr_Format(PyExc_TypeError, + "Array must have %s dimensions. Given array has %d dimensions", + dims_str, + array_numdims(ary)); + } + return success; + } + + /* Require the given PyArrayObject to have a specified shape. If the + * array has the specified shape, return 1. Otherwise, set the python + * error string and return 0. + */ + int require_size(PyArrayObject* ary, + npy_intp* size, + int n) + { + int i; + int success = 1; + size_t len; + char desired_dims[255] = "["; + char s[255]; + char actual_dims[255] = "["; + for(i=0; i < n;i++) + { + if (size[i] != -1 && size[i] != array_size(ary,i)) + { + success = 0; + } + } + if (!success) + { + for (i = 0; i < n; i++) + { + if (size[i] == -1) + { + sprintf(s, "*,"); + } + else + { + sprintf(s, "%ld,", (long int)size[i]); + } + strcat(desired_dims,s); + } + len = strlen(desired_dims); + desired_dims[len-1] = ']'; + for (i = 0; i < n; i++) + { + sprintf(s, "%ld,", (long int)array_size(ary,i)); + strcat(actual_dims,s); + } + len = strlen(actual_dims); + actual_dims[len-1] = ']'; + PyErr_Format(PyExc_TypeError, + "Array must have shape of %s. Given array has shape of %s", + desired_dims, + actual_dims); + } + return success; + } + + /* Require the given PyArrayObject to be Fortran ordered. If the + * the PyArrayObject is already Fortran ordered, do nothing. Else, + * set the Fortran ordering flag and recompute the strides. + */ + int require_fortran(PyArrayObject* ary) + { + int success = 1; + int nd = array_numdims(ary); + int i; + npy_intp * strides = array_strides(ary); + if (array_is_fortran(ary)) return success; + int n_non_one = 0; + /* Set the Fortran ordered flag */ + const npy_intp *dims = array_dimensions(ary); + for (i=0; i < nd; ++i) + n_non_one += (dims[i] != 1) ? 1 : 0; + if (n_non_one > 1) + array_clearflags(ary,NPY_ARRAY_CARRAY); + array_enableflags(ary,NPY_ARRAY_FARRAY); + /* Recompute the strides */ + strides[0] = strides[nd-1]; + for (i=1; i < nd; ++i) + strides[i] = strides[i-1] * array_size(ary,i-1); + return success; + } +} + +/* Combine all NumPy fragments into one for convenience */ +%fragment("NumPy_Fragments", + "header", + fragment="NumPy_Backward_Compatibility", + fragment="NumPy_Macros", + fragment="NumPy_Utilities", + fragment="NumPy_Object_to_Array", + fragment="NumPy_Array_Requirements") +{ +} + +/* End John Hunter translation (with modifications by Bill Spotz) + */ + +/* %numpy_typemaps() macro + * + * This macro defines a family of 75 typemaps that allow C arguments + * of the form + * + * 1. (DATA_TYPE IN_ARRAY1[ANY]) + * 2. (DATA_TYPE* IN_ARRAY1, DIM_TYPE DIM1) + * 3. (DIM_TYPE DIM1, DATA_TYPE* IN_ARRAY1) + * + * 4. (DATA_TYPE IN_ARRAY2[ANY][ANY]) + * 5. (DATA_TYPE* IN_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + * 6. (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_ARRAY2) + * 7. (DATA_TYPE* IN_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + * 8. (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_FARRAY2) + * + * 9. (DATA_TYPE IN_ARRAY3[ANY][ANY][ANY]) + * 10. (DATA_TYPE* IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 11. (DATA_TYPE** IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 12. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_ARRAY3) + * 13. (DATA_TYPE* IN_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 14. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_FARRAY3) + * + * 15. (DATA_TYPE IN_ARRAY4[ANY][ANY][ANY][ANY]) + * 16. (DATA_TYPE* IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 17. (DATA_TYPE** IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 18. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, , DIM_TYPE DIM4, DATA_TYPE* IN_ARRAY4) + * 19. (DATA_TYPE* IN_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 20. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_FARRAY4) + * + * 21. (DATA_TYPE INPLACE_ARRAY1[ANY]) + * 22. (DATA_TYPE* INPLACE_ARRAY1, DIM_TYPE DIM1) + * 23. (DIM_TYPE DIM1, DATA_TYPE* INPLACE_ARRAY1) + * + * 24. (DATA_TYPE INPLACE_ARRAY2[ANY][ANY]) + * 25. (DATA_TYPE* INPLACE_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + * 26. (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_ARRAY2) + * 27. (DATA_TYPE* INPLACE_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + * 28. (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_FARRAY2) + * + * 29. (DATA_TYPE INPLACE_ARRAY3[ANY][ANY][ANY]) + * 30. (DATA_TYPE* INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 31. (DATA_TYPE** INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 32. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_ARRAY3) + * 33. (DATA_TYPE* INPLACE_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + * 34. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_FARRAY3) + * + * 35. (DATA_TYPE INPLACE_ARRAY4[ANY][ANY][ANY][ANY]) + * 36. (DATA_TYPE* INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 37. (DATA_TYPE** INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 38. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_ARRAY4) + * 39. (DATA_TYPE* INPLACE_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + * 40. (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_FARRAY4) + * + * 41. (DATA_TYPE ARGOUT_ARRAY1[ANY]) + * 42. (DATA_TYPE* ARGOUT_ARRAY1, DIM_TYPE DIM1) + * 43. (DIM_TYPE DIM1, DATA_TYPE* ARGOUT_ARRAY1) + * + * 44. (DATA_TYPE ARGOUT_ARRAY2[ANY][ANY]) + * + * 45. (DATA_TYPE ARGOUT_ARRAY3[ANY][ANY][ANY]) + * + * 46. (DATA_TYPE ARGOUT_ARRAY4[ANY][ANY][ANY][ANY]) + * + * 47. (DATA_TYPE** ARGOUTVIEW_ARRAY1, DIM_TYPE* DIM1) + * 48. (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEW_ARRAY1) + * + * 49. (DATA_TYPE** ARGOUTVIEW_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + * 50. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_ARRAY2) + * 51. (DATA_TYPE** ARGOUTVIEW_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + * 52. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_FARRAY2) + * + * 53. (DATA_TYPE** ARGOUTVIEW_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) + * 54. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEW_ARRAY3) + * 55. (DATA_TYPE** ARGOUTVIEW_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) + * 56. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEW_FARRAY3) + * + * 57. (DATA_TYPE** ARGOUTVIEW_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) + * 58. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEW_ARRAY4) + * 59. (DATA_TYPE** ARGOUTVIEW_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) + * 60. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEW_FARRAY4) + * + * 61. (DATA_TYPE** ARGOUTVIEWM_ARRAY1, DIM_TYPE* DIM1) + * 62. (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEWM_ARRAY1) + * + * 63. (DATA_TYPE** ARGOUTVIEWM_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + * 64. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_ARRAY2) + * 65. (DATA_TYPE** ARGOUTVIEWM_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + * 66. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_FARRAY2) + * + * 67. (DATA_TYPE** ARGOUTVIEWM_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) + * 68. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEWM_ARRAY3) + * 69. (DATA_TYPE** ARGOUTVIEWM_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) + * 70. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEWM_FARRAY3) + * + * 71. (DATA_TYPE** ARGOUTVIEWM_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) + * 72. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEWM_ARRAY4) + * 73. (DATA_TYPE** ARGOUTVIEWM_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) + * 74. (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEWM_FARRAY4) + * + * 75. (DATA_TYPE* INPLACE_ARRAY_FLAT, DIM_TYPE DIM_FLAT) + * + * where "DATA_TYPE" is any type supported by the NumPy module, and + * "DIM_TYPE" is any int-like type suitable for specifying dimensions. + * The difference between "ARRAY" typemaps and "FARRAY" typemaps is + * that the "FARRAY" typemaps expect Fortran ordering of + * multidimensional arrays. In python, the dimensions will not need + * to be specified (except for the "DATA_TYPE* ARGOUT_ARRAY1" + * typemaps). The IN_ARRAYs can be a numpy array or any sequence that + * can be converted to a numpy array of the specified type. The + * INPLACE_ARRAYs must be numpy arrays of the appropriate type. The + * ARGOUT_ARRAYs will be returned as new numpy arrays of the + * appropriate type. + * + * These typemaps can be applied to existing functions using the + * %apply directive. For example: + * + * %apply (double* IN_ARRAY1, int DIM1) {(double* series, int length)}; + * double prod(double* series, int length); + * + * %apply (int DIM1, int DIM2, double* INPLACE_ARRAY2) + * {(int rows, int cols, double* matrix )}; + * void floor(int rows, int cols, double* matrix, double f); + * + * %apply (double IN_ARRAY3[ANY][ANY][ANY]) + * {(double tensor[2][2][2] )}; + * %apply (double ARGOUT_ARRAY3[ANY][ANY][ANY]) + * {(double low[2][2][2] )}; + * %apply (double ARGOUT_ARRAY3[ANY][ANY][ANY]) + * {(double upp[2][2][2] )}; + * void luSplit(double tensor[2][2][2], + * double low[2][2][2], + * double upp[2][2][2] ); + * + * or directly with + * + * double prod(double* IN_ARRAY1, int DIM1); + * + * void floor(int DIM1, int DIM2, double* INPLACE_ARRAY2, double f); + * + * void luSplit(double IN_ARRAY3[ANY][ANY][ANY], + * double ARGOUT_ARRAY3[ANY][ANY][ANY], + * double ARGOUT_ARRAY3[ANY][ANY][ANY]); + */ + +%define %numpy_typemaps(DATA_TYPE, DATA_TYPECODE, DIM_TYPE) + +/************************/ +/* Input Array Typemaps */ +/************************/ + +/* Typemap suite for (DATA_TYPE IN_ARRAY1[ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE IN_ARRAY1[ANY]) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE IN_ARRAY1[ANY]) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[1] = { $1_dim0 }; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 1) || + !require_size(array, size, 1)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(freearg) + (DATA_TYPE IN_ARRAY1[ANY]) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_ARRAY1, DIM_TYPE DIM1) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_ARRAY1, DIM_TYPE DIM1) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_ARRAY1, DIM_TYPE DIM1) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[1] = { -1 }; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 1) || + !require_size(array, size, 1)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); +} +%typemap(freearg) + (DATA_TYPE* IN_ARRAY1, DIM_TYPE DIM1) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DIM_TYPE DIM1, DATA_TYPE* IN_ARRAY1) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DATA_TYPE* IN_ARRAY1) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DATA_TYPE* IN_ARRAY1) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[1] = {-1}; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 1) || + !require_size(array, size, 1)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DATA_TYPE* IN_ARRAY1) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE IN_ARRAY2[ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE IN_ARRAY2[ANY][ANY]) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE IN_ARRAY2[ANY][ANY]) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[2] = { $1_dim0, $1_dim1 }; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 2) || + !require_size(array, size, 2)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(freearg) + (DATA_TYPE IN_ARRAY2[ANY][ANY]) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[2] = { -1, -1 }; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 2) || + !require_size(array, size, 2)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); +} +%typemap(freearg) + (DATA_TYPE* IN_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_ARRAY2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_ARRAY2) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_ARRAY2) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[2] = { -1, -1 }; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 2) || + !require_size(array, size, 2)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_ARRAY2) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[2] = { -1, -1 }; + array = obj_to_array_fortran_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 2) || + !require_size(array, size, 2) || !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); +} +%typemap(freearg) + (DATA_TYPE* IN_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_FARRAY2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_FARRAY2) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_FARRAY2) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[2] = { -1, -1 }; + array = obj_to_array_fortran_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 2) || + !require_size(array, size, 2) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* IN_FARRAY2) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE IN_ARRAY3[ANY][ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE IN_ARRAY3[ANY][ANY][ANY]) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE IN_ARRAY3[ANY][ANY][ANY]) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[3] = { $1_dim0, $1_dim1, $1_dim2 }; + array = obj_to_array_contiguous_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 3) || + !require_size(array, size, 3)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(freearg) + (DATA_TYPE IN_ARRAY3[ANY][ANY][ANY]) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[3] = { -1, -1, -1 }; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 3) || + !require_size(array, size, 3)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); +} +%typemap(freearg) + (DATA_TYPE* IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE** IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE** IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + /* for now, only concerned with lists */ + $1 = PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE** IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (DATA_TYPE** array=NULL, PyArrayObject** object_array=NULL, int* is_new_object_array=NULL) +{ + npy_intp size[2] = { -1, -1 }; + PyArrayObject* temp_array; + Py_ssize_t i; + int is_new_object; + + /* length of the list */ + $2 = PyList_Size($input); + + /* the arrays */ + array = (DATA_TYPE **)malloc($2*sizeof(DATA_TYPE *)); + object_array = (PyArrayObject **)calloc($2,sizeof(PyArrayObject *)); + is_new_object_array = (int *)calloc($2,sizeof(int)); + + if (array == NULL || object_array == NULL || is_new_object_array == NULL) + { + SWIG_fail; + } + + for (i=0; i<$2; i++) + { + temp_array = obj_to_array_contiguous_allow_conversion(PySequence_GetItem($input,i), DATA_TYPECODE, &is_new_object); + + /* the new array must be stored so that it can be destroyed in freearg */ + object_array[i] = temp_array; + is_new_object_array[i] = is_new_object; + + if (!temp_array || !require_dimensions(temp_array, 2)) SWIG_fail; + + /* store the size of the first array in the list, then use that for comparison. */ + if (i == 0) + { + size[0] = array_size(temp_array,0); + size[1] = array_size(temp_array,1); + } + + if (!require_size(temp_array, size, 2)) SWIG_fail; + + array[i] = (DATA_TYPE*) array_data(temp_array); + } + + $1 = (DATA_TYPE**) array; + $3 = (DIM_TYPE) size[0]; + $4 = (DIM_TYPE) size[1]; +} +%typemap(freearg) + (DATA_TYPE** IN_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + Py_ssize_t i; + + if (array$argnum!=NULL) free(array$argnum); + + /*freeing the individual arrays if needed */ + if (object_array$argnum!=NULL) + { + if (is_new_object_array$argnum!=NULL) + { + for (i=0; i<$2; i++) + { + if (object_array$argnum[i] != NULL && is_new_object_array$argnum[i]) + { Py_DECREF(object_array$argnum[i]); } + } + free(is_new_object_array$argnum); + } + free(object_array$argnum); + } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, + * DATA_TYPE* IN_ARRAY3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_ARRAY3) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_ARRAY3) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[3] = { -1, -1, -1 }; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 3) || + !require_size(array, size, 3)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_ARRAY3) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[3] = { -1, -1, -1 }; + array = obj_to_array_fortran_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 3) || + !require_size(array, size, 3) | !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); +} +%typemap(freearg) + (DATA_TYPE* IN_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, + * DATA_TYPE* IN_FARRAY3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_FARRAY3) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_FARRAY3) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[3] = { -1, -1, -1 }; + array = obj_to_array_fortran_allow_conversion($input, + DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 3) || + !require_size(array, size, 3) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* IN_FARRAY3) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE IN_ARRAY4[ANY][ANY][ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE IN_ARRAY4[ANY][ANY][ANY][ANY]) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE IN_ARRAY4[ANY][ANY][ANY][ANY]) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[4] = { $1_dim0, $1_dim1, $1_dim2 , $1_dim3}; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 4) || + !require_size(array, size, 4)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(freearg) + (DATA_TYPE IN_ARRAY4[ANY][ANY][ANY][ANY]) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[4] = { -1, -1, -1, -1 }; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 4) || + !require_size(array, size, 4)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); + $5 = (DIM_TYPE) array_size(array,3); +} +%typemap(freearg) + (DATA_TYPE* IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE** IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE** IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + /* for now, only concerned with lists */ + $1 = PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE** IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (DATA_TYPE** array=NULL, PyArrayObject** object_array=NULL, int* is_new_object_array=NULL) +{ + npy_intp size[3] = { -1, -1, -1 }; + PyArrayObject* temp_array; + Py_ssize_t i; + int is_new_object; + + /* length of the list */ + $2 = PyList_Size($input); + + /* the arrays */ + array = (DATA_TYPE **)malloc($2*sizeof(DATA_TYPE *)); + object_array = (PyArrayObject **)calloc($2,sizeof(PyArrayObject *)); + is_new_object_array = (int *)calloc($2,sizeof(int)); + + if (array == NULL || object_array == NULL || is_new_object_array == NULL) + { + SWIG_fail; + } + + for (i=0; i<$2; i++) + { + temp_array = obj_to_array_contiguous_allow_conversion(PySequence_GetItem($input,i), DATA_TYPECODE, &is_new_object); + + /* the new array must be stored so that it can be destroyed in freearg */ + object_array[i] = temp_array; + is_new_object_array[i] = is_new_object; + + if (!temp_array || !require_dimensions(temp_array, 3)) SWIG_fail; + + /* store the size of the first array in the list, then use that for comparison. */ + if (i == 0) + { + size[0] = array_size(temp_array,0); + size[1] = array_size(temp_array,1); + size[2] = array_size(temp_array,2); + } + + if (!require_size(temp_array, size, 3)) SWIG_fail; + + array[i] = (DATA_TYPE*) array_data(temp_array); + } + + $1 = (DATA_TYPE**) array; + $3 = (DIM_TYPE) size[0]; + $4 = (DIM_TYPE) size[1]; + $5 = (DIM_TYPE) size[2]; +} +%typemap(freearg) + (DATA_TYPE** IN_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + Py_ssize_t i; + + if (array$argnum!=NULL) free(array$argnum); + + /*freeing the individual arrays if needed */ + if (object_array$argnum!=NULL) + { + if (is_new_object_array$argnum!=NULL) + { + for (i=0; i<$2; i++) + { + if (object_array$argnum[i] != NULL && is_new_object_array$argnum[i]) + { Py_DECREF(object_array$argnum[i]); } + } + free(is_new_object_array$argnum); + } + free(object_array$argnum); + } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, + * DATA_TYPE* IN_ARRAY4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_ARRAY4) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_ARRAY4) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[4] = { -1, -1, -1 , -1}; + array = obj_to_array_contiguous_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 4) || + !require_size(array, size, 4)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DIM_TYPE) array_size(array,3); + $5 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_ARRAY4) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DATA_TYPE* IN_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* IN_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* IN_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[4] = { -1, -1, -1, -1 }; + array = obj_to_array_fortran_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 4) || + !require_size(array, size, 4) | !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); + $5 = (DIM_TYPE) array_size(array,3); +} +%typemap(freearg) + (DATA_TYPE* IN_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, + * DATA_TYPE* IN_FARRAY4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_FARRAY4) +{ + $1 = is_array($input) || PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_FARRAY4) + (PyArrayObject* array=NULL, int is_new_object=0) +{ + npy_intp size[4] = { -1, -1, -1 , -1 }; + array = obj_to_array_fortran_allow_conversion($input, DATA_TYPECODE, + &is_new_object); + if (!array || !require_dimensions(array, 4) || + !require_size(array, size, 4) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DIM_TYPE) array_size(array,3); + $5 = (DATA_TYPE*) array_data(array); +} +%typemap(freearg) + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* IN_FARRAY4) +{ + if (is_new_object$argnum && array$argnum) + { Py_DECREF(array$argnum); } +} + +/***************************/ +/* In-Place Array Typemaps */ +/***************************/ + +/* Typemap suite for (DATA_TYPE INPLACE_ARRAY1[ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE INPLACE_ARRAY1[ANY]) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE INPLACE_ARRAY1[ANY]) + (PyArrayObject* array=NULL) +{ + npy_intp size[1] = { $1_dim0 }; + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,1) || !require_size(array, size, 1) || + !require_contiguous(array) || !require_native(array)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_ARRAY1, DIM_TYPE DIM1) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_ARRAY1, DIM_TYPE DIM1) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_ARRAY1, DIM_TYPE DIM1) + (PyArrayObject* array=NULL, int i=1) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,1) || !require_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = 1; + for (i=0; i < array_numdims(array); ++i) $2 *= array_size(array,i); +} + +/* Typemap suite for (DIM_TYPE DIM1, DATA_TYPE* INPLACE_ARRAY1) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DATA_TYPE* INPLACE_ARRAY1) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DATA_TYPE* INPLACE_ARRAY1) + (PyArrayObject* array=NULL, int i=0) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,1) || !require_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = 1; + for (i=0; i < array_numdims(array); ++i) $1 *= array_size(array,i); + $2 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE INPLACE_ARRAY2[ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE INPLACE_ARRAY2[ANY][ANY]) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE INPLACE_ARRAY2[ANY][ANY]) + (PyArrayObject* array=NULL) +{ + npy_intp size[2] = { $1_dim0, $1_dim1 }; + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,2) || !require_size(array, size, 2) || + !require_contiguous(array) || !require_native(array)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_ARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,2) || !require_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_ARRAY2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_ARRAY2) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_ARRAY2) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,2) || !require_contiguous(array) || + !require_native(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_FARRAY2, DIM_TYPE DIM1, DIM_TYPE DIM2) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,2) || !require_contiguous(array) + || !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_FARRAY2) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_FARRAY2) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DATA_TYPE* INPLACE_FARRAY2) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,2) || !require_contiguous(array) || + !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE INPLACE_ARRAY3[ANY][ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE INPLACE_ARRAY3[ANY][ANY][ANY]) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE INPLACE_ARRAY3[ANY][ANY][ANY]) + (PyArrayObject* array=NULL) +{ + npy_intp size[3] = { $1_dim0, $1_dim1, $1_dim2 }; + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,3) || !require_size(array, size, 3) || + !require_contiguous(array) || !require_native(array)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,3) || !require_contiguous(array) || + !require_native(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); +} + +/* Typemap suite for (DATA_TYPE** INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE** INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + $1 = PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE** INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (DATA_TYPE** array=NULL, PyArrayObject** object_array=NULL) +{ + npy_intp size[2] = { -1, -1 }; + PyArrayObject* temp_array; + Py_ssize_t i; + + /* length of the list */ + $2 = PyList_Size($input); + + /* the arrays */ + array = (DATA_TYPE **)malloc($2*sizeof(DATA_TYPE *)); + object_array = (PyArrayObject **)calloc($2,sizeof(PyArrayObject *)); + + if (array == NULL || object_array == NULL) + { + SWIG_fail; + } + + for (i=0; i<$2; i++) + { + temp_array = obj_to_array_no_conversion(PySequence_GetItem($input,i), DATA_TYPECODE); + + /* the new array must be stored so that it can be destroyed in freearg */ + object_array[i] = temp_array; + + if ( !temp_array || !require_dimensions(temp_array, 2) || + !require_contiguous(temp_array) || + !require_native(temp_array) || + !PyArray_EquivTypenums(array_type(temp_array), DATA_TYPECODE) + ) SWIG_fail; + + /* store the size of the first array in the list, then use that for comparison. */ + if (i == 0) + { + size[0] = array_size(temp_array,0); + size[1] = array_size(temp_array,1); + } + + if (!require_size(temp_array, size, 2)) SWIG_fail; + + array[i] = (DATA_TYPE*) array_data(temp_array); + } + + $1 = (DATA_TYPE**) array; + $3 = (DIM_TYPE) size[0]; + $4 = (DIM_TYPE) size[1]; +} +%typemap(freearg) + (DATA_TYPE** INPLACE_ARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + if (array$argnum!=NULL) free(array$argnum); + if (object_array$argnum!=NULL) free(object_array$argnum); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, + * DATA_TYPE* INPLACE_ARRAY3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_ARRAY3) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_ARRAY3) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,3) || !require_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_FARRAY3, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,3) || !require_contiguous(array) || + !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, + * DATA_TYPE* INPLACE_FARRAY3) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_FARRAY3) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DATA_TYPE* INPLACE_FARRAY3) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,3) || !require_contiguous(array) + || !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE INPLACE_ARRAY4[ANY][ANY][ANY][ANY]) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE INPLACE_ARRAY4[ANY][ANY][ANY][ANY]) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE INPLACE_ARRAY4[ANY][ANY][ANY][ANY]) + (PyArrayObject* array=NULL) +{ + npy_intp size[4] = { $1_dim0, $1_dim1, $1_dim2 , $1_dim3 }; + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,4) || !require_size(array, size, 4) || + !require_contiguous(array) || !require_native(array)) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,4) || !require_contiguous(array) || + !require_native(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); + $5 = (DIM_TYPE) array_size(array,3); +} + +/* Typemap suite for (DATA_TYPE** INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE** INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + $1 = PySequence_Check($input); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE** INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (DATA_TYPE** array=NULL, PyArrayObject** object_array=NULL) +{ + npy_intp size[3] = { -1, -1, -1 }; + PyArrayObject* temp_array; + Py_ssize_t i; + + /* length of the list */ + $2 = PyList_Size($input); + + /* the arrays */ + array = (DATA_TYPE **)malloc($2*sizeof(DATA_TYPE *)); + object_array = (PyArrayObject **)calloc($2,sizeof(PyArrayObject *)); + + if (array == NULL || object_array == NULL) + { + SWIG_fail; + } + + for (i=0; i<$2; i++) + { + temp_array = obj_to_array_no_conversion(PySequence_GetItem($input,i), DATA_TYPECODE); + + /* the new array must be stored so that it can be destroyed in freearg */ + object_array[i] = temp_array; + + if ( !temp_array || !require_dimensions(temp_array, 3) || + !require_contiguous(temp_array) || + !require_native(temp_array) || + !PyArray_EquivTypenums(array_type(temp_array), DATA_TYPECODE) + ) SWIG_fail; + + /* store the size of the first array in the list, then use that for comparison. */ + if (i == 0) + { + size[0] = array_size(temp_array,0); + size[1] = array_size(temp_array,1); + size[2] = array_size(temp_array,2); + } + + if (!require_size(temp_array, size, 3)) SWIG_fail; + + array[i] = (DATA_TYPE*) array_data(temp_array); + } + + $1 = (DATA_TYPE**) array; + $3 = (DIM_TYPE) size[0]; + $4 = (DIM_TYPE) size[1]; + $5 = (DIM_TYPE) size[2]; +} +%typemap(freearg) + (DATA_TYPE** INPLACE_ARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + if (array$argnum!=NULL) free(array$argnum); + if (object_array$argnum!=NULL) free(object_array$argnum); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, + * DATA_TYPE* INPLACE_ARRAY4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_ARRAY4) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_ARRAY4) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,4) || !require_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DIM_TYPE) array_size(array,3); + $5 = (DATA_TYPE*) array_data(array); +} + +/* Typemap suite for (DATA_TYPE* INPLACE_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, + * DIM_TYPE DIM3, DIM_TYPE DIM4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_FARRAY4, DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,4) || !require_contiguous(array) || + !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = (DIM_TYPE) array_size(array,0); + $3 = (DIM_TYPE) array_size(array,1); + $4 = (DIM_TYPE) array_size(array,2); + $5 = (DIM_TYPE) array_size(array,3); +} + +/* Typemap suite for (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, + * DATA_TYPE* INPLACE_FARRAY4) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_FARRAY4) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DIM_TYPE DIM2, DIM_TYPE DIM3, DIM_TYPE DIM4, DATA_TYPE* INPLACE_FARRAY4) + (PyArrayObject* array=NULL) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_dimensions(array,4) || !require_contiguous(array) + || !require_native(array) || !require_fortran(array)) SWIG_fail; + $1 = (DIM_TYPE) array_size(array,0); + $2 = (DIM_TYPE) array_size(array,1); + $3 = (DIM_TYPE) array_size(array,2); + $4 = (DIM_TYPE) array_size(array,3); + $5 = (DATA_TYPE*) array_data(array); +} + +/*************************/ +/* Argout Array Typemaps */ +/*************************/ + +/* Typemap suite for (DATA_TYPE ARGOUT_ARRAY1[ANY]) + */ +%typemap(in,numinputs=0, + fragment="NumPy_Backward_Compatibility,NumPy_Macros") + (DATA_TYPE ARGOUT_ARRAY1[ANY]) + (PyObject* array = NULL) +{ + npy_intp dims[1] = { $1_dim0 }; + array = PyArray_SimpleNew(1, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(argout) + (DATA_TYPE ARGOUT_ARRAY1[ANY]) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/* Typemap suite for (DATA_TYPE* ARGOUT_ARRAY1, DIM_TYPE DIM1) + */ +%typemap(in,numinputs=1, + fragment="NumPy_Fragments") + (DATA_TYPE* ARGOUT_ARRAY1, DIM_TYPE DIM1) + (PyObject* array = NULL) +{ + npy_intp dims[1]; + if (!PyLong_Check($input)) + { + const char* typestring = pytype_string($input); + PyErr_Format(PyExc_TypeError, + "Int dimension expected. '%s' given.", + typestring); + SWIG_fail; + } + $2 = (DIM_TYPE) PyLong_AsSsize_t($input); + if ($2 == -1 && PyErr_Occurred()) SWIG_fail; + dims[0] = (npy_intp) $2; + array = PyArray_SimpleNew(1, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); +} +%typemap(argout) + (DATA_TYPE* ARGOUT_ARRAY1, DIM_TYPE DIM1) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/* Typemap suite for (DIM_TYPE DIM1, DATA_TYPE* ARGOUT_ARRAY1) + */ +%typemap(in,numinputs=1, + fragment="NumPy_Fragments") + (DIM_TYPE DIM1, DATA_TYPE* ARGOUT_ARRAY1) + (PyObject* array = NULL) +{ + npy_intp dims[1]; + if (!PyLong_Check($input)) + { + const char* typestring = pytype_string($input); + PyErr_Format(PyExc_TypeError, + "Int dimension expected. '%s' given.", + typestring); + SWIG_fail; + } + $1 = (DIM_TYPE) PyLong_AsSsize_t($input); + if ($1 == -1 && PyErr_Occurred()) SWIG_fail; + dims[0] = (npy_intp) $1; + array = PyArray_SimpleNew(1, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $2 = (DATA_TYPE*) array_data(array); +} +%typemap(argout) + (DIM_TYPE DIM1, DATA_TYPE* ARGOUT_ARRAY1) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/* Typemap suite for (DATA_TYPE ARGOUT_ARRAY2[ANY][ANY]) + */ +%typemap(in,numinputs=0, + fragment="NumPy_Backward_Compatibility,NumPy_Macros") + (DATA_TYPE ARGOUT_ARRAY2[ANY][ANY]) + (PyObject* array = NULL) +{ + npy_intp dims[2] = { $1_dim0, $1_dim1 }; + array = PyArray_SimpleNew(2, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(argout) + (DATA_TYPE ARGOUT_ARRAY2[ANY][ANY]) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/* Typemap suite for (DATA_TYPE ARGOUT_ARRAY3[ANY][ANY][ANY]) + */ +%typemap(in,numinputs=0, + fragment="NumPy_Backward_Compatibility,NumPy_Macros") + (DATA_TYPE ARGOUT_ARRAY3[ANY][ANY][ANY]) + (PyObject* array = NULL) +{ + npy_intp dims[3] = { $1_dim0, $1_dim1, $1_dim2 }; + array = PyArray_SimpleNew(3, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(argout) + (DATA_TYPE ARGOUT_ARRAY3[ANY][ANY][ANY]) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/* Typemap suite for (DATA_TYPE ARGOUT_ARRAY4[ANY][ANY][ANY][ANY]) + */ +%typemap(in,numinputs=0, + fragment="NumPy_Backward_Compatibility,NumPy_Macros") + (DATA_TYPE ARGOUT_ARRAY4[ANY][ANY][ANY][ANY]) + (PyObject* array = NULL) +{ + npy_intp dims[4] = { $1_dim0, $1_dim1, $1_dim2, $1_dim3 }; + array = PyArray_SimpleNew(4, dims, DATA_TYPECODE); + if (!array) SWIG_fail; + $1 = ($1_ltype) array_data(array); +} +%typemap(argout) + (DATA_TYPE ARGOUT_ARRAY4[ANY][ANY][ANY][ANY]) +{ + $result = SWIG_Python_AppendOutput($result,(PyObject*)array$argnum); +} + +/*****************************/ +/* Argoutview Array Typemaps */ +/*****************************/ + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_ARRAY1, DIM_TYPE* DIM1) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_ARRAY1, DIM_TYPE* DIM1 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim_temp) +{ + $1 = &data_temp; + $2 = &dim_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DATA_TYPE** ARGOUTVIEW_ARRAY1, DIM_TYPE* DIM1) +{ + npy_intp dims[1] = { *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(1, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEW_ARRAY1) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DATA_TYPE** ARGOUTVIEW_ARRAY1) + (DIM_TYPE dim_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim_temp; + $2 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEW_ARRAY1) +{ + npy_intp dims[1] = { *$1 }; + PyObject* obj = PyArray_SimpleNewFromData(1, dims, DATA_TYPECODE, (void*)(*$2)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_ARRAY2, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DATA_TYPE** ARGOUTVIEW_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) +{ + npy_intp dims[2] = { *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_ARRAY2) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DATA_TYPE** ARGOUTVIEW_ARRAY2) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_ARRAY2) +{ + npy_intp dims[2] = { *$1, *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$3)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_FARRAY2, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DATA_TYPE** ARGOUTVIEW_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) +{ + npy_intp dims[2] = { *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_FARRAY2) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DATA_TYPE** ARGOUTVIEW_FARRAY2) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEW_FARRAY2) +{ + npy_intp dims[2] = { *$1, *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$3)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_ARRAY3, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DATA_TYPE** ARGOUTVIEW_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) +{ + npy_intp dims[3] = { *$2, *$3, *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, + DATA_TYPE** ARGOUTVIEW_ARRAY3) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEW_ARRAY3) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DATA_TYPE* data_temp = NULL) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEW_ARRAY3) +{ + npy_intp dims[3] = { *$1, *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$4)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_FARRAY3, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DATA_TYPE** ARGOUTVIEW_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) +{ + npy_intp dims[3] = { *$2, *$3, *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, + DATA_TYPE** ARGOUTVIEW_FARRAY3) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DATA_TYPE** ARGOUTVIEW_FARRAY3) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEW_FARRAY3) +{ + npy_intp dims[3] = { *$1, *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$4)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3, DIM_TYPE* DIM4) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_ARRAY4, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; + $5 = &dim4_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DATA_TYPE** ARGOUTVIEW_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) +{ + npy_intp dims[4] = { *$2, *$3, *$4 , *$5 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, + DATA_TYPE** ARGOUTVIEW_ARRAY4) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 , DATA_TYPE** ARGOUTVIEW_ARRAY4) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &dim4_temp; + $5 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEW_ARRAY4) +{ + npy_intp dims[4] = { *$1, *$2, *$3 , *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$5)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEW_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3, DIM_TYPE* DIM4) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEW_FARRAY4, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; + $5 = &dim4_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DATA_TYPE** ARGOUTVIEW_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) +{ + npy_intp dims[4] = { *$2, *$3, *$4 , *$5 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, + DATA_TYPE** ARGOUTVIEW_FARRAY4) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 , DATA_TYPE** ARGOUTVIEW_FARRAY4) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &dim4_temp; + $5 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEW_FARRAY4) +{ + npy_intp dims[4] = { *$1, *$2, *$3 , *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$5)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + $result = SWIG_Python_AppendOutput($result,obj); +} + +/*************************************/ +/* Managed Argoutview Array Typemaps */ +/*************************************/ + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_ARRAY1, DIM_TYPE* DIM1) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_ARRAY1, DIM_TYPE* DIM1 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim_temp) +{ + $1 = &data_temp; + $2 = &dim_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_ARRAY1, DIM_TYPE* DIM1) +{ + npy_intp dims[1] = { *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(1, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEWM_ARRAY1) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DATA_TYPE** ARGOUTVIEWM_ARRAY1) + (DIM_TYPE dim_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim_temp; + $2 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DIM_TYPE* DIM1, DATA_TYPE** ARGOUTVIEWM_ARRAY1) +{ + npy_intp dims[1] = { *$1 }; + PyObject* obj = PyArray_SimpleNewFromData(1, dims, DATA_TYPECODE, (void*)(*$2)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$2), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_ARRAY2, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_ARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) +{ + npy_intp dims[2] = { *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_ARRAY2) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DATA_TYPE** ARGOUTVIEWM_ARRAY2) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_ARRAY2) +{ + npy_intp dims[2] = { *$1, *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$3)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$3), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_FARRAY2, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_FARRAY2, DIM_TYPE* DIM1, DIM_TYPE* DIM2) +{ + npy_intp dims[2] = { *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_FARRAY2) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DATA_TYPE** ARGOUTVIEWM_FARRAY2) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DATA_TYPE** ARGOUTVIEWM_FARRAY2) +{ + npy_intp dims[2] = { *$1, *$2 }; + PyObject* obj = PyArray_SimpleNewFromData(2, dims, DATA_TYPECODE, (void*)(*$3)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$3), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_ARRAY3, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_ARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) +{ + npy_intp dims[3] = { *$2, *$3, *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, + DATA_TYPE** ARGOUTVIEWM_ARRAY3) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DATA_TYPE** ARGOUTVIEWM_ARRAY3) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEWM_ARRAY3) +{ + npy_intp dims[3] = { *$1, *$2, *$3 }; + PyObject* obj= PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$4)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$4), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_FARRAY3, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_FARRAY3, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3) +{ + npy_intp dims[3] = { *$2, *$3, *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, + DATA_TYPE** ARGOUTVIEWM_FARRAY3) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DATA_TYPE** ARGOUTVIEWM_FARRAY3) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DATA_TYPE** ARGOUTVIEWM_FARRAY3) +{ + npy_intp dims[3] = { *$1, *$2, *$3 }; + PyObject* obj = PyArray_SimpleNewFromData(3, dims, DATA_TYPECODE, (void*)(*$4)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$4), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3, DIM_TYPE* DIM4) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_ARRAY4, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; + $5 = &dim4_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_ARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) +{ + npy_intp dims[4] = { *$2, *$3, *$4 , *$5 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, + DATA_TYPE** ARGOUTVIEWM_ARRAY4) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 , DATA_TYPE** ARGOUTVIEWM_ARRAY4) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &dim4_temp; + $5 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEWM_ARRAY4) +{ + npy_intp dims[4] = { *$1, *$2, *$3 , *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$5)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$5), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DATA_TYPE** ARGOUTVIEWM_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, + DIM_TYPE* DIM3, DIM_TYPE* DIM4) + */ +%typemap(in,numinputs=0) + (DATA_TYPE** ARGOUTVIEWM_FARRAY4, DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 ) + (DATA_TYPE* data_temp = NULL , DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp) +{ + $1 = &data_temp; + $2 = &dim1_temp; + $3 = &dim2_temp; + $4 = &dim3_temp; + $5 = &dim4_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DATA_TYPE** ARGOUTVIEWM_FARRAY4, DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4) +{ + npy_intp dims[4] = { *$2, *$3, *$4 , *$5 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$1)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$1), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/* Typemap suite for (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, + DATA_TYPE** ARGOUTVIEWM_FARRAY4) + */ +%typemap(in,numinputs=0) + (DIM_TYPE* DIM1 , DIM_TYPE* DIM2 , DIM_TYPE* DIM3 , DIM_TYPE* DIM4 , DATA_TYPE** ARGOUTVIEWM_FARRAY4) + (DIM_TYPE dim1_temp, DIM_TYPE dim2_temp, DIM_TYPE dim3_temp, DIM_TYPE dim4_temp, DATA_TYPE* data_temp = NULL ) +{ + $1 = &dim1_temp; + $2 = &dim2_temp; + $3 = &dim3_temp; + $4 = &dim4_temp; + $5 = &data_temp; +} +%typemap(argout, + fragment="NumPy_Backward_Compatibility,NumPy_Array_Requirements,NumPy_Utilities") + (DIM_TYPE* DIM1, DIM_TYPE* DIM2, DIM_TYPE* DIM3, DIM_TYPE* DIM4, DATA_TYPE** ARGOUTVIEWM_FARRAY4) +{ + npy_intp dims[4] = { *$1, *$2, *$3 , *$4 }; + PyObject* obj = PyArray_SimpleNewFromData(4, dims, DATA_TYPECODE, (void*)(*$5)); + PyArrayObject* array = (PyArrayObject*) obj; + + if (!array || !require_fortran(array)) SWIG_fail; + +PyObject* cap = PyCapsule_New((void*)(*$5), SWIGPY_CAPSULE_NAME, free_cap); + +%#if NPY_API_VERSION < NPY_1_7_API_VERSION + PyArray_BASE(array) = cap; +%#else + PyArray_SetBaseObject(array,cap); +%#endif + + $result = SWIG_Python_AppendOutput($result,obj); +} + +/**************************************/ +/* In-Place Array Typemap - flattened */ +/**************************************/ + +/* Typemap suite for (DATA_TYPE* INPLACE_ARRAY_FLAT, DIM_TYPE DIM_FLAT) + */ +%typecheck(SWIG_TYPECHECK_DOUBLE_ARRAY, + fragment="NumPy_Macros") + (DATA_TYPE* INPLACE_ARRAY_FLAT, DIM_TYPE DIM_FLAT) +{ + $1 = is_array($input) && PyArray_EquivTypenums(array_type($input), + DATA_TYPECODE); +} +%typemap(in, + fragment="NumPy_Fragments") + (DATA_TYPE* INPLACE_ARRAY_FLAT, DIM_TYPE DIM_FLAT) + (PyArrayObject* array=NULL, int i=1) +{ + array = obj_to_array_no_conversion($input, DATA_TYPECODE); + if (!array || !require_c_or_f_contiguous(array) + || !require_native(array)) SWIG_fail; + $1 = (DATA_TYPE*) array_data(array); + $2 = 1; + for (i=0; i < array_numdims(array); ++i) $2 *= array_size(array,i); +} + +%enddef /* %numpy_typemaps() macro */ +/* *************************************************************** */ + +/* Concrete instances of the %numpy_typemaps() macro: Each invocation + * below applies all of the typemaps above to the specified data type. + */ +%numpy_typemaps(signed char , NPY_BYTE , int) +%numpy_typemaps(unsigned char , NPY_UBYTE , int) +%numpy_typemaps(short , NPY_SHORT , int) +%numpy_typemaps(unsigned short , NPY_USHORT , int) +%numpy_typemaps(int , NPY_INT , int) +%numpy_typemaps(unsigned int , NPY_UINT , int) +%numpy_typemaps(long , NPY_LONG , int) +%numpy_typemaps(unsigned long , NPY_ULONG , int) +%numpy_typemaps(long long , NPY_LONGLONG , int) +%numpy_typemaps(unsigned long long, NPY_ULONGLONG, int) +%numpy_typemaps(float , NPY_FLOAT , int) +%numpy_typemaps(double , NPY_DOUBLE , int) +%numpy_typemaps(int8_t , NPY_INT8 , int) +%numpy_typemaps(int16_t , NPY_INT16 , int) +%numpy_typemaps(int32_t , NPY_INT32 , int) +%numpy_typemaps(int64_t , NPY_INT64 , int) +%numpy_typemaps(uint8_t , NPY_UINT8 , int) +%numpy_typemaps(uint16_t , NPY_UINT16 , int) +%numpy_typemaps(uint32_t , NPY_UINT32 , int) +%numpy_typemaps(uint64_t , NPY_UINT64 , int) + + +/* *************************************************************** + * The follow macro expansion does not work, because C++ bool is 4 + * bytes and NPY_BOOL is 1 byte + * + * %numpy_typemaps(bool, NPY_BOOL, int) + */ + +/* *************************************************************** + * On my Mac, I get the following warning for this macro expansion: + * 'swig/python detected a memory leak of type 'long double *', no destructor found.' + * + * %numpy_typemaps(long double, NPY_LONGDOUBLE, int) + */ + +#ifdef __cplusplus + +%include + +%numpy_typemaps(std::complex, NPY_CFLOAT , int) +%numpy_typemaps(std::complex, NPY_CDOUBLE, int) + +#endif + +#endif /* SWIGPYTHON */