/** * @license Apache-2.0 * * Copyright (c) 2018 The Stdlib Authors. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "stdlib/ndarray/base/ind2sub.h" #include "stdlib/ndarray/index_modes.h" #include "stdlib/ndarray/orders.h" #include #include /** * Converts a linear index to an array of subscripts. * * ## Notes * * - When provided a stride array containing negative strides, if an `offset` is greater than `0`, the function interprets the linear index as an index into the underlying data buffer for the array, thus returning subscripts from the perspective of that buffer. If an `offset` is equal to `0`, the function treats the linear index as an index into an array view, thus returning subscripts from the perspective of that view. In short, from the perspective of a view, view data is always ordered. * * - In "error" mode, the function returns `-1` if an index is out-of-bounds. * * @param ndims number of dimensions * @param shape array shape (dimensions) * @param strides array strides * @param offset location of the first indexed value **based** on the stride array * @param order specifies whether an array is row-major (C-style) or column-major (Fortran-style) * @param idx linear index in an array view * @param mode specifies how to handle a linear index which exceeds array dimensions * @param out output array * @return status code * * @example * #include "stdlib/ndarray/base/ind2sub.h" * #include "stdlib/ndarray/index_modes.h" * #include "stdlib/ndarray/orders.h" * #include * * int64_t ndims = 2; * int64_t shape[] = { 3, 3 }; * int64_t strides[] = { -3, 1 }; * int64_t offset = 6; * * int64_t out[ 2 ]; * * int8_t status = stdlib_ndarray_ind2sub( ndims, shape, strides, offset, STDLIB_NDARRAY_ROW_MAJOR, 7, STDLIB_NDARRAY_INDEX_ERROR, out ); * if ( status == -1 ) { * // Handle error... * } */ int8_t stdlib_ndarray_ind2sub( int64_t ndims, int64_t *shape, int64_t *strides, int64_t offset, enum STDLIB_NDARRAY_ORDER order, int64_t idx, enum STDLIB_NDARRAY_INDEX_MODE mode, int64_t *out ) { int64_t len; int64_t s; int64_t k; int64_t i; len = 1; for ( i = 0; i < ndims; i++ ) { len *= shape[ i ]; } if ( mode == STDLIB_NDARRAY_INDEX_CLAMP ) { if ( idx < 0 ) { idx = 0; } else if ( idx >= len ) { idx = len - 1; } } else if ( mode == STDLIB_NDARRAY_INDEX_WRAP ) { if ( idx < 0 ) { idx += len; // slight optimization to avoid modulo arithmetic when |idx| <= len if ( idx < 0 ) { idx -= len*( (int64_t)( idx/len ) ); // this is equivalent to `idx mod len`, where the result has same sign as dividend (i.e., `idx`); cannot use `%` as the sign of the result is implementation defined in C if ( idx != 0 ) { idx += len; } } } else if ( idx >= len ) { idx -= len; // slight optimization to avoid modulo arithmetic when len < idx <= 2*len if ( idx >= len ) { idx %= len; } } } else if ( idx < 0 || idx >= len ) { // mode == 'error' return -1; } if ( offset == 0 ) { if ( order == STDLIB_NDARRAY_COLUMN_MAJOR ) { for ( i = 0; i < ndims; i++ ) { s = idx % shape[ i ]; idx -= s; idx /= shape[ i ]; out[ i ] = s; } return 0; } // Case: row-major for ( i = ndims-1; i >= 0; i-- ) { s = idx % shape[ i ]; idx -= s; idx /= shape[ i ]; out[ i ] = s; } return 0; } if ( order == STDLIB_NDARRAY_COLUMN_MAJOR ) { for ( i = ndims-1; i >= 0; i-- ) { s = strides[ i ]; if ( s < 0 ) { k = idx / s; // truncates idx -= k * s; out[ i ] = shape[ i ] - 1 + k; } else { k = idx / s; // cppcheck-suppress zerodivcond // truncates idx -= k * s; out[ i ] = k; } } return 0; } // Case: row-major for ( i = 0; i < ndims; i++ ) { s = strides[ i ]; if ( s < 0 ) { k = idx / s; // truncates idx -= k * s; out[ i ] = shape[ i ] - 1 + k; } else { k = idx / s; // cppcheck-suppress zerodivcond // truncates idx -= k * s; out[ i ] = k; } } return 0; }