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* Copyright (c) 2014, ArrayFire
* All rights reserved.
*
* This file is distributed under 3-clause BSD license.
* The complete license agreement can be obtained at:
* http://arrayfire.com/licenses/BSD-3-Clause
********************************************************/
#pragma once
#include <af/defines.h>
#ifdef __cplusplus
namespace af
{
class array;
/**
C++ Interface for sum of elements in an array
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\return result of sum all values along dimension \p dim
\ingroup reduce_func_sum
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
*/
AFAPI array sum(const array &in, const int dim = -1);
#if AF_API_VERSION >= 31
/**
C++ Interface for sum of elements in an array while replacing nan values
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\param[in] nanval Replace nans with the value passed to this function
\return result of sum all values along dimension \p dim
\ingroup reduce_func_sum
*/
AFAPI array sum(const array &in, const int dim, const double nanval);
#endif
/**
C++ Interface for product of elements in an array
\param[in] in is the input array
\param[in] dim The dimension along which the multiply operation occurs
\return result of product all values along dimension \p dim
\ingroup reduce_func_product
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
*/
AFAPI array product(const array &in, const int dim = -1);
#if AF_API_VERSION >= 31
/**
C++ Interface for product of elements in an array while replacing nan values
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\param[in] nanval Replace nans with the value passed to this function
\return result of product all values along dimension \p dim
\ingroup reduce_func_product
*/
AFAPI array product(const array &in, const int dim, const double nanval);
#endif
/**
C++ Interface for minimum values in an array
\param[in] in is the input array
\param[in] dim The dimension along which the minimum value needs to be extracted
\return result of minimum all values along dimension \p dim
\ingroup reduce_func_min
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI array min(const array &in, const int dim = -1);
/**
C++ Interface for maximum values in an array
\param[in] in is the input array
\param[in] dim The dimension along which the maximum value needs to be extracted
\return result of maximum all values along dimension \p dim
\ingroup reduce_func_max
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI array max(const array &in, const int dim = -1);
/**
C++ Interface for checking all true values in an array
\param[in] in is the input array
\param[in] dim The dimension along which the values are checked to be all true
\return result of checking if values along dimension \p dim are all true
\ingroup reduce_func_all_true
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI array allTrue(const array &in, const int dim = -1);
/**
C++ Interface for checking any true values in an array
\param[in] in is the input array
\param[in] dim The dimension along which the values are checked to be any true
\return result of checking if values along dimension \p dim are any true
\ingroup reduce_func_any_true
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI array anyTrue(const array &in, const int dim = -1);
/**
C++ Interface for counting non-zero values in an array
\param[in] in is the input array
\param[in] dim The dimension along which the the number of non-zero values are counted
\return the number of non-zero values along dimension \p dim
\ingroup reduce_func_count
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are treated as non zero.
*/
AFAPI array count(const array &in, const int dim = -1);
/**
C++ Interface for sum of all elements in an array
\param[in] in is the input array
\return the sum of all values of \p in
\ingroup reduce_func_sum
*/
template<typename T> T sum(const array &in);
#if AF_API_VERSION >= 31
/**
C++ Interface for sum of all elements in an array while replacing nan values
\param[in] in is the input array
\param[in] nanval Replace nans with the value passed to this function
\return the sum of all values of \p in
\ingroup reduce_func_sum
*/
template<typename T> T sum(const array &in, double nanval);
#endif
/**
C++ Interface for product of all elements in an array
\param[in] in is the input array
\return the product of all values of \p in
\ingroup reduce_func_product
*/
template<typename T> T product(const array &in);
#if AF_API_VERSION >= 31
/**
C++ Interface for product of all elements in an array while replacing nan values
\param[in] in is the input array
\param[in] nanval Replace nans with the value passed to this function
\return the product of all values of \p in
\ingroup reduce_func_product
*/
template<typename T> T product(const array &in, double nanval);
#endif
/**
C++ Interface for getting minimum value of an array
\param[in] in is the input array
\return the minimum of all values of \p in
\ingroup reduce_func_min
\note NaN values are ignored
*/
template<typename T> T min(const array &in);
/**
C++ Interface for getting maximum value of an array
\param[in] in is the input array
\return the maximum of all values of \p in
\ingroup reduce_func_max
\note NaN values are ignored
*/
template<typename T> T max(const array &in);
/**
C++ Interface for checking if all values in an array are true
\param[in] in is the input array
\return true if all values of \p in are true, false otherwise
\ingroup reduce_func_all_true
\note NaN values are ignored
*/
template<typename T> T allTrue(const array &in);
/**
C++ Interface for checking if any values in an array are true
\param[in] in is the input array
\return true if any values of \p in are true, false otherwise
\ingroup reduce_func_any_true
\note NaN values are ignored
*/
template<typename T> T anyTrue(const array &in);
/**
C++ Interface for counting total number of non-zero values in an array
\param[in] in is the input array
\return the number of non-zero values in \p in
\ingroup reduce_func_count
\note NaN values are treated as non zero
*/
template<typename T> T count(const array &in);
/**
C++ Interface for getting minimum values and their locations in an array
\param[out] val will contain the minimum values along dimension \p dim
\param[out] idx will contain the locations of minimum all values along dimension \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the minimum value needs to be extracted
\ingroup reduce_func_min
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI void min(array &val, array &idx, const array &in, const int dim = -1);
/**
C++ Interface for getting maximum values and their locations in an array
\param[out] val will contain the maximum values along dimension \p dim
\param[out] idx will contain the locations of maximum all values along dimension \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the maximum value needs to be extracted
\ingroup reduce_func_max
\note \p dim is -1 by default. -1 denotes the first non-singleton dimension.
\note NaN values are ignored
*/
AFAPI void max(array &val, array &idx, const array &in, const int dim = -1);
/**
C++ Interface for getting minimum value and its location from the entire array
\param[out] val will contain the minimum values in the input
\param[out] idx will contain the locations of minimum all values in the input
\param[in] in is the input array
\ingroup reduce_func_min
\note NaN values are ignored
*/
template<typename T> void min(T *val, unsigned *idx, const array &in);
/**
C++ Interface for getting maximum value and its location from the entire array
\param[out] val contains the maximum values in the input
\param[out] idx contains the locations of maximum all values in the input
\param[in] in is the input array
\ingroup reduce_func_max
\note NaN values are ignored
*/
template<typename T> void max(T *val, unsigned *idx, const array &in);
/**
C++ Interface exclusive sum (cumulative sum) of an array
\param[in] in is the input array
\param[in] dim The dimension along which exclusive sum is performed
\return the output containing exclusive sums of the input
\ingroup scan_func_accum
*/
AFAPI array accum(const array &in, const int dim = 0);
/**
C++ Interface for finding the locations of non-zero values in an array
\param[in] in is the input array.
\return linear indices where \p in is non-zero
\ingroup scan_func_where
*/
AFAPI array where(const array &in);
/**
C++ Interface for calculating first order differences in an array
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\return array of first order numerical difference
\ingroup calc_func_diff1
*/
AFAPI array diff1(const array &in, const int dim = 0);
/**
C++ Interface for calculating second order differences in an array
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\return array of second order numerical difference
\ingroup calc_func_diff2
*/
AFAPI array diff2(const array &in, const int dim = 0);
/**
C++ Interface for sorting an array
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\return the sorted output
\ingroup sort_func_sort
\note \p dim is currently restricted to 0.
*/
AFAPI array sort(const array &in, const unsigned dim = 0, const bool isAscending = true);
/**
C++ Interface for sorting an array and getting original indices
\param[out] out will contain the sorted output
\param[out] indices will contain the indices in the original input
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\ingroup sort_func_sort_index
\note \p dim is currently restricted to 0.
*/
AFAPI void sort(array &out, array &indices, const array &in, const unsigned dim = 0,
const bool isAscending = true);
/**
C++ Interface for sorting an array based on keys
\param[out] out_keys will contain the keys based on sorted values
\param[out] out_values will contain the sorted values
\param[in] keys is the input array
\param[in] values The dimension along which numerical difference is performed
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\ingroup sort_func_sort_keys
\note \p dim is currently restricted to 0.
*/
AFAPI void sort(array &out_keys, array &out_values, const array &keys, const array &values,
const unsigned dim = 0, const bool isAscending = true);
/**
C++ Interface for getting unique values
\param[in] in is the input array
\param[in] is_sorted if true, skips the sorting steps internally
\return the unique values from \p in
\ingroup set_func_unique
*/
AFAPI array setUnique(const array &in, const bool is_sorted=false);
/**
C++ Interface for performing union of two arrays
\param[in] first is the first array
\param[in] second is the second array
\param[in] is_unique if true, skips calling unique internally
\return the union of \p first and \p second
\ingroup set_func_union
*/
AFAPI array setUnion(const array &first, const array &second, const bool is_unique=false);
/**
C++ Interface for performing intersect of two arrays
\param[in] first is the first array
\param[in] second is the second array
\param[in] is_unique if true, skips calling unique internally
\return the intersection of \p first and \p second
\ingroup set_func_intersect
*/
AFAPI array setIntersect(const array &first, const array &second, const bool is_unique=false);
}
#endif
#ifdef __cplusplus
extern "C" {
#endif
/**
C Interface for sum of elements in an array
\param[out] out will contain the sum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_sum
*/
AFAPI af_err af_sum(af_array *out, const af_array in, const int dim);
#if AF_API_VERSION >= 31
/**
C Interface for sum of elements in an array while replacing nans
\param[out] out will contain the sum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\param[in] nanval Replace nans with the value passed to this function
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_sum
*/
AFAPI af_err af_sum_nan(af_array *out, const af_array in, const int dim, const double nanval);
#endif
/**
C Interface for product of elements in an array
\param[out] out will contain the product of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the multiply operation occurs
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_product
*/
AFAPI af_err af_product(af_array *out, const af_array in, const int dim);
#if AF_API_VERSION >= 31
/**
C Interface for product of elements in an array while replacing nans
\param[out] out will contain the product of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the add operation occurs
\param[in] nanval Replace nans with the value passed to this function
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_product
*/
AFAPI af_err af_product_nan(af_array *out, const af_array in, const int dim, const double nanval);
#endif
/**
C Interface for minimum values in an array
\param[out] out will contain the minimum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the minimum value is extracted
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_min
*/
AFAPI af_err af_min(af_array *out, const af_array in, const int dim);
/**
C Interface for maximum values in an array
\param[out] out will contain the maximum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the maximum value is extracted
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_max
*/
AFAPI af_err af_max(af_array *out, const af_array in, const int dim);
/**
C Interface for checking all true values in an array
\param[out] out will contain the result of "and" operation all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the "and" operation occurs
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_all_true
*/
AFAPI af_err af_all_true(af_array *out, const af_array in, const int dim);
/**
C Interface for checking any true values in an array
\param[out] out will contain the result of "or" operation all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the "or" operation occurs
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_any_true
*/
AFAPI af_err af_any_true(af_array *out, const af_array in, const int dim);
/**
C Interface for counting non-zero values in an array
\param[out] out will contain the number of non-zero values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the non-zero values are counted
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_count
*/
AFAPI af_err af_count(af_array *out, const af_array in, const int dim);
/**
C Interface for sum of all elements in an array
\param[out] real will contain the real part of adding all elements in input \p in
\param[out] imag will contain the imaginary part of adding all elements in input \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real
\ingroup reduce_func_sum
*/
AFAPI af_err af_sum_all(double *real, double *imag, const af_array in);
#if AF_API_VERSION >= 31
/**
C Interface for sum of all elements in an array while replacing nans
\param[out] real will contain the real part of adding all elements in input \p in
\param[out] imag will contain the imaginary part of adding all elements in input \p in
\param[in] in is the input array
\param[in] nanval is the value which replaces nan
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real
\ingroup reduce_func_sum
*/
AFAPI af_err af_sum_nan_all(double *real, double *imag, const af_array in, const double nanval);
#endif
/**
C Interface for product of all elements in an array
\param[out] real will contain the real part of multiplying all elements in input \p in
\param[out] imag will contain the imaginary part of multiplying all elements in input \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real
\ingroup reduce_func_product
*/
AFAPI af_err af_product_all(double *real, double *imag, const af_array in);
#if AF_API_VERSION >= 31
/**
C Interface for product of all elements in an array while replacing nans
\param[out] real will contain the real part of adding all elements in input \p in
\param[out] imag will contain the imaginary part of adding all elements in input \p in
\param[in] in is the input array
\param[in] nanval is the value which replaces nan
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real
\ingroup reduce_func_product
*/
AFAPI af_err af_product_nan_all(double *real, double *imag, const af_array in, const double nanval);
#endif
/**
C Interface for getting minimum value of an array
\param[out] real will contain the real part of minimum value of all elements in input \p in
\param[out] imag will contain the imaginary part of minimum value of all elements in input \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real.
\ingroup reduce_func_min
*/
AFAPI af_err af_min_all(double *real, double *imag, const af_array in);
/**
C Interface for getting maximum value of an array
\param[out] real will contain the real part of maximum value of all elements in input \p in
\param[out] imag will contain the imaginary part of maximum value of all elements in input \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real.
\ingroup reduce_func_max
*/
AFAPI af_err af_max_all(double *real, double *imag, const af_array in);
/**
C Interface for checking if all values in an array are true
\param[out] real is 1 if all values of input \p in are true, 0 otherwise.
\param[out] imag is always set to 0.
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0.
\ingroup reduce_func_all_true
*/
AFAPI af_err af_all_true_all(double *real, double *imag, const af_array in);
/**
C Interface for checking if any values in an array are true
\param[out] real is 1 if any value of input \p in is true, 0 otherwise.
\param[out] imag is always set to 0.
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0.
\ingroup reduce_func_any_true
*/
AFAPI af_err af_any_true_all(double *real, double *imag, const af_array in);
/**
C Interface for counting total number of non-zero values in an array
\param[out] real will contain the number of non-zero values in \p in.
\param[out] imag is always set to 0.
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0.
\ingroup reduce_func_count
*/
AFAPI af_err af_count_all(double *real, double *imag, const af_array in);
/**
C Interface for getting minimum values and their locations in an array
\param[out] out will contain the minimum of all values in \p in along \p dim
\param[out] idx will contain the location of minimum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the minimum value is extracted
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_min
*/
AFAPI af_err af_imin(af_array *out, af_array *idx, const af_array in, const int dim);
/**
C Interface for getting maximum values and their locations in an array
\param[out] out will contain the maximum of all values in \p in along \p dim
\param[out] idx will contain the location of maximum of all values in \p in along \p dim
\param[in] in is the input array
\param[in] dim The dimension along which the maximum value is extracted
\return \ref AF_SUCCESS if the execution completes properly
\ingroup reduce_func_max
*/
AFAPI af_err af_imax(af_array *out, af_array *idx, const af_array in, const int dim);
/**
C Interface for getting minimum value and its location from the entire array
\param[out] real will contain the real part of minimum value of all elements in input \p in
\param[out] imag will contain the imaginary part of minimum value of all elements in input \p in
\param[out] idx will contain the location of minimum of all values in \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real.
\ingroup reduce_func_min
*/
AFAPI af_err af_imin_all(double *real, double *imag, unsigned *idx, const af_array in);
/**
C Interface for getting maximum value and it's location from the entire array
\param[out] real will contain the real part of maximum value of all elements in input \p in
\param[out] imag will contain the imaginary part of maximum value of all elements in input \p in
\param[out] idx will contain the location of maximum of all values in \p in
\param[in] in is the input array
\return \ref AF_SUCCESS if the execution completes properly
\note \p imag is always set to 0 when \p in is real.
\ingroup reduce_func_max
*/
AFAPI af_err af_imax_all(double *real, double *imag, unsigned *idx, const af_array in);
/**
C Interface exclusive sum (cumulative sum) of an array
\param[out] out will contain exclusive sums of the input
\param[in] in is the input array
\param[in] dim The dimension along which exclusive sum is performed
\return \ref AF_SUCCESS if the execution completes properly
\ingroup scan_func_accum
*/
AFAPI af_err af_accum(af_array *out, const af_array in, const int dim);
/**
C Interface for finding the locations of non-zero values in an array
\param[out] idx will contain indices where \p in is non-zero
\param[in] in is the input array.
\return \ref AF_SUCCESS if the execution completes properly
\ingroup scan_func_where
*/
AFAPI af_err af_where(af_array *idx, const af_array in);
/**
C Interface for calculating first order differences in an array
\param[out] out will contain the first order numerical differences of \p in
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\return \ref AF_SUCCESS if the execution completes properly
\ingroup calc_func_diff1
*/
AFAPI af_err af_diff1(af_array *out, const af_array in, const int dim);
/**
C Interface for calculating second order differences in an array
\param[out] out will contain the second order numerical differences of \p in
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\return \ref AF_SUCCESS if the execution completes properly
\ingroup calc_func_diff2
*/
AFAPI af_err af_diff2(af_array *out, const af_array in, const int dim);
/**
C Interface for sorting an array
\param[out] out will contain the sorted output
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\return \ref AF_SUCCESS if the execution completes properly
\ingroup sort_func_sort
\note \p dim is currently restricted to 0.
*/
AFAPI af_err af_sort(af_array *out, const af_array in, const unsigned dim, const bool isAscending);
/**
C Interface for sorting an array and getting original indices
\param[out] out will contain the sorted output
\param[out] indices will contain the indices in the original input
\param[in] in is the input array
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\return \ref AF_SUCCESS if the execution completes properly
\ingroup sort_func_sort_index
\note \p dim is currently restricted to 0.
*/
AFAPI af_err af_sort_index(af_array *out, af_array *indices, const af_array in,
const unsigned dim, const bool isAscending);
/**
C Interface for sorting an array based on keys
\param[out] out_keys will contain the keys based on sorted values
\param[out] out_values will contain the sorted values
\param[in] keys is the input array
\param[in] values The dimension along which numerical difference is performed
\param[in] dim The dimension along which numerical difference is performed
\param[in] isAscending specifies the sorting order
\return \ref AF_SUCCESS if the execution completes properly
\ingroup sort_func_sort_keys
\note \p dim is currently restricted to 0.
*/
AFAPI af_err af_sort_by_key(af_array *out_keys, af_array *out_values,
const af_array keys, const af_array values,
const unsigned dim, const bool isAscending);
/**
C Interface for getting unique values
\param[out] out will contain the unique values from \p in
\param[in] in is the input array
\param[in] is_sorted if true, skips the sorting steps internally
\return \ref AF_SUCCESS if the execution completes properly
\ingroup set_func_unique
*/
AFAPI af_err af_set_unique(af_array *out, const af_array in, const bool is_sorted);
/**
C Interface for performing union of two arrays
\param[out] out will contain the union of \p first and \p second
\param[in] first is the first array
\param[in] second is the second array
\param[in] is_unique if true, skips calling unique internally
\return \ref AF_SUCCESS if the execution completes properly
\ingroup set_func_union
*/
AFAPI af_err af_set_union(af_array *out, const af_array first, const af_array second, const bool is_unique);
/**
C Interface for performing intersect of two arrays
\param[out] out will contain the intersection of \p first and \p second
\param[in] first is the first array
\param[in] second is the second array
\param[in] is_unique if true, skips calling unique internally
\return \ref AF_SUCCESS if the execution completes properly
\ingroup set_func_intersect
*/
AFAPI af_err af_set_intersect(af_array *out, const af_array first, const af_array second, const bool is_unique);
#ifdef __cplusplus
}
#endif
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