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algorithm.cpp
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184 lines (149 loc) · 6.48 KB
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/*******************************************************
* Copyright (c) 2015, 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
********************************************************/
#include <af/algorithm.h>
#include <af/array.h>
#include "symbol_manager.hpp"
#define ALGO_HAPI_DEF(af_func) \
af_err af_func(af_array *out, const af_array in, const int dim) { \
CHECK_ARRAYS(in); \
CALL(af_func, out, in, dim); \
}
ALGO_HAPI_DEF(af_sum)
ALGO_HAPI_DEF(af_product)
ALGO_HAPI_DEF(af_min)
ALGO_HAPI_DEF(af_max)
ALGO_HAPI_DEF(af_all_true)
ALGO_HAPI_DEF(af_any_true)
ALGO_HAPI_DEF(af_count)
ALGO_HAPI_DEF(af_accum)
ALGO_HAPI_DEF(af_diff1)
ALGO_HAPI_DEF(af_diff2)
#undef ALGO_HAPI_DEF
#define ALGO_HAPI_DEF_BYKEY(af_func) \
af_err af_func(af_array *keys_out, af_array *vals_out, \
const af_array keys, const af_array vals, const int dim) { \
CHECK_ARRAYS(keys, vals); \
CALL(af_func, keys_out, vals_out, keys, vals, dim); \
}
ALGO_HAPI_DEF_BYKEY(af_sum_by_key)
ALGO_HAPI_DEF_BYKEY(af_product_by_key)
ALGO_HAPI_DEF_BYKEY(af_min_by_key)
ALGO_HAPI_DEF_BYKEY(af_max_by_key)
ALGO_HAPI_DEF_BYKEY(af_all_true_by_key)
ALGO_HAPI_DEF_BYKEY(af_any_true_by_key)
ALGO_HAPI_DEF_BYKEY(af_count_by_key)
#undef ALGO_HAPI_DEF_BYKEY
#define ALGO_HAPI_DEF(af_func_nan) \
af_err af_func_nan(af_array *out, const af_array in, const int dim, \
const double nanval) { \
CHECK_ARRAYS(in); \
CALL(af_func_nan, out, in, dim, nanval); \
}
ALGO_HAPI_DEF(af_sum_nan)
ALGO_HAPI_DEF(af_product_nan)
#undef ALGO_HAPI_DEF
#define ALGO_HAPI_DEF_BYKEY(af_func_nan) \
af_err af_func_nan(af_array *keys_out, af_array *vals_out, \
const af_array keys, const af_array vals, \
const int dim, const double nanval) { \
CHECK_ARRAYS(keys, vals); \
CALL(af_func_nan, keys_out, vals_out, keys, vals, dim, nanval); \
}
ALGO_HAPI_DEF_BYKEY(af_sum_by_key_nan)
ALGO_HAPI_DEF_BYKEY(af_product_by_key_nan)
#undef ALGO_HAPI_DEF_BYKEY
#define ALGO_HAPI_DEF(af_func_all) \
af_err af_func_all(double *real, double *imag, const af_array in) { \
CHECK_ARRAYS(in); \
CALL(af_func_all, real, imag, in); \
}
ALGO_HAPI_DEF(af_sum_all)
ALGO_HAPI_DEF(af_product_all)
ALGO_HAPI_DEF(af_min_all)
ALGO_HAPI_DEF(af_max_all)
ALGO_HAPI_DEF(af_all_true_all)
ALGO_HAPI_DEF(af_any_true_all)
ALGO_HAPI_DEF(af_count_all)
#undef ALGO_HAPI_DEF
#define ALGO_HAPI_DEF(af_func_nan_all) \
af_err af_func_nan_all(double *real, double *imag, const af_array in, \
const double nanval) { \
CHECK_ARRAYS(in); \
CALL(af_func_nan_all, real, imag, in, nanval); \
}
ALGO_HAPI_DEF(af_sum_nan_all)
ALGO_HAPI_DEF(af_product_nan_all)
#undef ALGO_HAPI_DEF
#define ALGO_HAPI_DEF(af_ifunc) \
af_err af_ifunc(af_array *out, af_array *idx, const af_array in, \
const int dim) { \
CHECK_ARRAYS(in); \
CALL(af_ifunc, out, idx, in, dim); \
}
ALGO_HAPI_DEF(af_imin)
ALGO_HAPI_DEF(af_imax)
#undef ALGO_HAPI_DEF
#define ALGO_HAPI_DEF(af_ifunc_all) \
af_err af_ifunc_all(double *real, double *imag, unsigned *idx, \
const af_array in) { \
CHECK_ARRAYS(in); \
CALL(af_ifunc_all, real, imag, idx, in); \
}
ALGO_HAPI_DEF(af_imin_all)
ALGO_HAPI_DEF(af_imax_all)
#undef ALGO_HAPI_DEF
af_err af_where(af_array *idx, const af_array in) {
CHECK_ARRAYS(in);
CALL(af_where, idx, in);
}
af_err af_scan(af_array *out, const af_array in, const int dim, af_binary_op op,
bool inclusive_scan) {
CHECK_ARRAYS(in);
CALL(af_scan, out, in, dim, op, inclusive_scan);
}
af_err af_scan_by_key(af_array *out, const af_array key, const af_array in,
const int dim, af_binary_op op, bool inclusive_scan) {
CHECK_ARRAYS(in, key);
CALL(af_scan_by_key, out, key, in, dim, op, inclusive_scan);
}
af_err af_sort(af_array *out, const af_array in, const unsigned dim,
const bool isAscending) {
CHECK_ARRAYS(in);
CALL(af_sort, out, in, dim, isAscending);
}
af_err af_sort_index(af_array *out, af_array *indices, const af_array in,
const unsigned dim, const bool isAscending) {
CHECK_ARRAYS(in);
CALL(af_sort_index, out, indices, in, dim, isAscending);
}
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) {
CHECK_ARRAYS(keys, values);
CALL(af_sort_by_key, out_keys, out_values, keys, values, dim, isAscending);
}
af_err af_set_unique(af_array *out, const af_array in, const bool is_sorted) {
CHECK_ARRAYS(in);
CALL(af_set_unique, out, in, is_sorted);
}
af_err af_set_union(af_array *out, const af_array first, const af_array second,
const bool is_unique) {
CHECK_ARRAYS(first, second);
CALL(af_set_union, out, first, second, is_unique);
}
af_err af_set_intersect(af_array *out, const af_array first,
const af_array second, const bool is_unique) {
CHECK_ARRAYS(first, second);
CALL(af_set_intersect, out, first, second, is_unique);
}
af_err af_max_ragged(af_array *vals, af_array *idx, const af_array in,
const af_array ragged_len, const int dim) {
CHECK_ARRAYS(in, ragged_len);
CALL(af_max_ragged, vals, idx, in, ragged_len, dim);
}