/*******************************************************

* 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

********************************************************/

#include <af/algorithm.h>

#include <af/array.h>

#include <af/compatible.h>

#include "common.hpp"

#include "error.hpp"

namespace af {

array sum(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_sum(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

array sum(const array &in, const int dim, const double nanval) {

af_array out = 0;

AF_THROW(af_sum_nan(&out, in.get(), dim, nanval));

return array(out);

}

void sumByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_sum_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

void sumByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim, const double nanval) {

af_array okeys, ovals;

AF_THROW(

af_sum_by_key_nan(&okeys, &ovals, keys.get(), vals.get(), dim, nanval));

keys_out = array(okeys);

vals_out = array(ovals);

}

array product(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_product(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

array product(const array &in, const int dim, const double nanval) {

af_array out = 0;

AF_THROW(af_product_nan(&out, in.get(), dim, nanval));

return array(out);

}

void productByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_product_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

void productByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim, const double nanval) {

af_array okeys, ovals;

AF_THROW(af_product_by_key_nan(&okeys, &ovals, keys.get(), vals.get(), dim,

nanval));

keys_out = array(okeys);

vals_out = array(ovals);

}

array mul(const array &in, const int dim) { return product(in, dim); }

array min(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_min(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

void minByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_min_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

array max(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_max(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

void maxByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_max_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

void max(array &val, array &idx, const array &in, const array &ragged_len,

const int dim) {

af_array oval, oidx;

AF_THROW(af_max_ragged(&oval, &oidx, in.get(), ragged_len.get(), dim));

val = array(oval);

idx = array(oidx);

}

// 2.1 compatibility

array alltrue(const array &in, const int dim) { return allTrue(in, dim); }

array allTrue(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_all_true(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

void allTrueByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_all_true_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

// 2.1 compatibility

array anytrue(const array &in, const int dim) { return anyTrue(in, dim); }

array anyTrue(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_any_true(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

void anyTrueByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_any_true_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

array count(const array &in, const int dim) {

af_array out = 0;

AF_THROW(af_count(&out, in.get(), getFNSD(dim, in.dims())));

return array(out);

}

void countByKey(array &keys_out, array &vals_out, const array &keys,

const array &vals, const int dim) {

af_array okeys, ovals;

AF_THROW(af_count_by_key(&okeys, &ovals, keys.get(), vals.get(),

getFNSD(dim, vals.dims())));

keys_out = array(okeys);

vals_out = array(ovals);

}

void min(array &val, array &idx, const array &in, const int dim) {

af_array out = 0;

af_array loc = 0;

AF_THROW(af_imin(&out, &loc, in.get(), getFNSD(dim, in.dims())));

val = array(out);

idx = array(loc);

}

void max(array &val, array &idx, const array &in, const int dim) {

af_array out = 0;

af_array loc = 0;

AF_THROW(af_imax(&out, &loc, in.get(), getFNSD(dim, in.dims())));

val = array(out);

idx = array(loc);

}

#define INSTANTIATE(fnC, fnCPP) \

INSTANTIATE_REAL(fnC, fnCPP, float) \

INSTANTIATE_REAL(fnC, fnCPP, double) \

INSTANTIATE_REAL(fnC, fnCPP, int) \

INSTANTIATE_REAL(fnC, fnCPP, unsigned) \

INSTANTIATE_REAL(fnC, fnCPP, long) \

INSTANTIATE_REAL(fnC, fnCPP, unsigned long) \

INSTANTIATE_REAL(fnC, fnCPP, long long) \

INSTANTIATE_REAL(fnC, fnCPP, unsigned long long) \

INSTANTIATE_REAL(fnC, fnCPP, short) \

INSTANTIATE_REAL(fnC, fnCPP, unsigned short) \

INSTANTIATE_REAL(fnC, fnCPP, char) \

INSTANTIATE_REAL(fnC, fnCPP, signed char) \

INSTANTIATE_REAL(fnC, fnCPP, unsigned char) \

INSTANTIATE_CPLX(fnC, fnCPP, af_cfloat, float) \

INSTANTIATE_CPLX(fnC, fnCPP, af_cdouble, double)

#define INSTANTIATE_REAL(fnC, fnCPP, T) \

template<> \

AFAPI T fnCPP(const array &in) { \

double rval, ival; \

AF_THROW(af_##fnC##_all(&rval, &ival, in.get())); \

return (T)(rval); \

}

#define INSTANTIATE_CPLX(fnC, fnCPP, T, Tr) \

template<> \

AFAPI T fnCPP(const array &in) { \

double rval, ival; \

AF_THROW(af_##fnC##_all(&rval, &ival, in.get())); \

T out((Tr)rval, (Tr)ival); \

return out; \

}

#define INSTANTIATE_ARRAY(fnC, fnCPP) \

template<> \

AFAPI af::array fnCPP(const array &in) { \

af_array out = 0; \

AF_THROW(af_##fnC##_all_array(&out, in.get())); \

return array(out); \

}

INSTANTIATE(sum, sum)

INSTANTIATE(product, product)

INSTANTIATE(min, min)

INSTANTIATE(max, max)

INSTANTIATE(all_true, allTrue)

INSTANTIATE(any_true, anyTrue)

INSTANTIATE(count, count)

INSTANTIATE_REAL(all_true, allTrue, bool);

INSTANTIATE_REAL(any_true, anyTrue, bool);

INSTANTIATE_ARRAY(sum, sum)

INSTANTIATE_ARRAY(product, product)

INSTANTIATE_ARRAY(min, min)

INSTANTIATE_ARRAY(max, max)

INSTANTIATE_ARRAY(all_true, allTrue)

INSTANTIATE_ARRAY(any_true, anyTrue)

INSTANTIATE_ARRAY(count, count)

#undef INSTANTIATE_REAL

#undef INSTANTIATE_CPLX

#undef INSTANTIATE_ARRAY

#define INSTANTIATE_REAL(fnC, fnCPP, T) \

template<> \

AFAPI T fnCPP(const array &in, const double nanval) { \

double rval, ival; \

AF_THROW(af_##fnC##_all(&rval, &ival, in.get(), nanval)); \

return (T)(rval); \

}

#define INSTANTIATE_CPLX(fnC, fnCPP, T, Tr) \

template<> \

AFAPI T fnCPP(const array &in, const double nanval) { \

double rval, ival; \

AF_THROW(af_##fnC##_all(&rval, &ival, in.get(), nanval)); \

T out((Tr)rval, (Tr)ival); \

return out; \

}

#define INSTANTIATE_ARRAY(fnC, fnCPP) \

template<> \

AFAPI af::array fnCPP(const array &in, const double nanval) { \

af_array out = 0; \

AF_THROW(af_##fnC##_all_array(&out, in.get(), nanval)); \

return array(out); \

}

INSTANTIATE_ARRAY(sum_nan, sum)

INSTANTIATE_ARRAY(product_nan, product)

INSTANTIATE(sum_nan, sum)

INSTANTIATE(product_nan, product)

#undef INSTANTIATE_REAL

#undef INSTANTIATE_CPLX

#undef INSTANTIATE

#undef INSTANTIATE_ARRAY

#define INSTANTIATE_COMPAT(fnCPP, fnCompat, T) \

template<> \

AFAPI T fnCompat(const array &in) { \

return fnCPP<T>(in); \

}

#define INSTANTIATE(fnCPP, fnCompat) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, float) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, double) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, int) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, unsigned) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, long) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, unsigned long) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, long long) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, unsigned long long) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, char) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, signed char) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, unsigned char) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, af_cfloat) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, af_cdouble) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, short) \

INSTANTIATE_COMPAT(fnCPP, fnCompat, unsigned short)

INSTANTIATE(product, mul)

INSTANTIATE(allTrue, alltrue)

INSTANTIATE(anyTrue, anytrue)

INSTANTIATE_COMPAT(allTrue, alltrue, bool)

INSTANTIATE_COMPAT(anyTrue, anytrue, bool)

#undef INSTANTIATE

#undef INSTANTIATE_COMPAT

#define INSTANTIATE_REAL(fn, T) \

template<> \

AFAPI void fn(T *val, unsigned *idx, const array &in) { \

double rval, ival; \

AF_THROW(af_i##fn##_all(&rval, &ival, idx, in.get())); \

*val = (T)(rval); \

}

#define INSTANTIATE_CPLX(fn, T, Tr) \

template<> \

AFAPI void fn(T *val, unsigned *idx, const array &in) { \

double rval, ival; \

AF_THROW(af_i##fn##_all(&rval, &ival, idx, in.get())); \

*val = T((Tr)rval, (Tr)ival); \

}

#define INSTANTIATE(fn) \

INSTANTIATE_REAL(fn, float) \

INSTANTIATE_REAL(fn, double) \

INSTANTIATE_REAL(fn, int) \

INSTANTIATE_REAL(fn, unsigned) \

INSTANTIATE_REAL(fn, char) \

INSTANTIATE_REAL(fn, signed char) \

INSTANTIATE_REAL(fn, unsigned char) \

INSTANTIATE_REAL(fn, short) \

INSTANTIATE_REAL(fn, unsigned short) \

INSTANTIATE_CPLX(fn, af_cfloat, float) \

INSTANTIATE_CPLX(fn, af_cdouble, double)

INSTANTIATE(min)

INSTANTIATE(max)

} // namespace af