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{-# LANGUAGE TypeApplications #-}

{-# LANGUAGE ScopedTypeVariables #-}

module ArrayFire.Arith where

import Foreign.Marshal

import Foreign.Storable

import Foreign.C.String

import Data.Proxy

import Data.Coerce

import ArrayFire.Exception

import ArrayFire.Types

import ArrayFire.FFI

import ArrayFire.Internal.Arith

import ArrayFire.Internal.Defines

add

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

add x y batch =

x `op2` y $ \arr arr1 arr2 ->

af_add arr arr1 arr2 batch

sub

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

sub x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_add arr arr1 arr2 batch

mul

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

mul x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_mul arr arr1 arr2 batch

div

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

div x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_div arr arr1 arr2 batch

lt

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

lt x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_lt arr arr1 arr2 batch

gt

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

gt x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_gt arr arr1 arr2 batch

le

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

le x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_le arr arr1 arr2 batch

ge

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

ge x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_ge arr arr1 arr2 batch

eq

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

eq x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_eq arr arr1 arr2 batch

neq

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

neq x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_neq arr arr1 arr2 batch

and

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

and x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_and arr arr1 arr2 batch

or

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

or x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_or arr arr1 arr2 batch

not

:: AFType a

=> Array a

-> Array a

not = flip op1 af_not

bitAnd

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

bitAnd x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_bitand arr arr1 arr2 batch

bitOr

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

bitOr x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_bitor arr arr1 arr2 batch

bitXor

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

bitXor x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_bitxor arr arr1 arr2 batch

bitShiftL

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

bitShiftL x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_bitshiftl arr arr1 arr2 batch

bitShiftR

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

bitShiftR x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_bitshiftr arr arr1 arr2 batch

cast

:: forall a b . (AFType a, AFType b)

=> Array a

-> Array b

cast afArr =

coerce $ afArr `op1` (\x y -> af_cast x y dtyp)

where

dtyp = afType (Proxy @ b)

minOf

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

minOf x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_minof arr arr1 arr2 batch

maxOf

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

maxOf x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_maxof arr arr1 arr2 batch

clamp

:: Array a

-> Array a

-> Array a

-> Batch

-> Array a

clamp a b c batch =

op3 a b c $ \arr arr1 arr2 arr3 ->

af_clamp arr arr1 arr2 arr3 batch

rem

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

rem x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_rem arr arr1 arr2 batch

mod

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

mod x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_mod arr arr1 arr2 batch

abs

:: AFType a

=> Array a

-> Array a

abs = flip op1 af_abs

arg

:: AFType a

=> Array a

-> Array a

arg = flip op1 af_arg

sign

:: AFType a

=> Array a

-> Array a

sign = flip op1 af_sign

round

:: AFType a

=> Array a

-> Array a

round = flip op1 af_round

trunc

:: AFType a

=> Array a

-> Array a

trunc = flip op1 af_trunc

floor

:: AFType a

=> Array a

-> Array a

floor = flip op1 af_floor

ceil

:: AFType a

=> Array a

-> Array a

ceil = flip op1 af_ceil

sin

:: AFType a

=> Array a

-> Array a

sin = flip op1 af_sin

cos

:: AFType a

=> Array a

-> Array a

cos = flip op1 af_cos

tan

:: AFType a

=> Array a

-> Array a

tan = flip op1 af_tan

asin

:: AFType a

=> Array a

-> Array a

asin = flip op1 af_asin

acos

:: AFType a

=> Array a

-> Array a

acos = flip op1 af_acos

atan

:: AFType a

=> Array a

-> Array a

atan = flip op1 af_atan

atan2

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

atan2 x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_atan2 arr arr1 arr2 batch

cplx2

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

cplx2 x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_cplx2 arr arr1 arr2 batch

cplx

:: AFType a

=> Array a

-> Array a

cplx = flip op1 af_cplx

real

:: AFType a

=> Array a

-> Array a

real = flip op1 af_real

imag

:: AFType a

=> Array a

-> Array a

imag = flip op1 af_imag

conjg

:: AFType a

=> Array a

-> Array a

conjg = flip op1 af_conjg

sinh

:: AFType a

=> Array a

-> Array a

sinh = flip op1 af_sinh

cosh

:: AFType a

=> Array a

-> Array a

cosh = flip op1 af_cosh

tanh

:: AFType a

=> Array a

-> Array a

tanh = flip op1 af_tanh

root

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

root x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_root arr arr1 arr2 batch

pow

:: AFType a

=> Array a

-> Array a

-> Batch

-> Array a

pow x y batch = do

x `op2` y $ \arr arr1 arr2 ->

af_pow arr arr1 arr2 batch

pow2

:: AFType a

=> Array a

-> Array a

pow2 = flip op1 af_pow2

exp

:: AFType a

=> Array a

-> Array a

exp = flip op1 af_exp

sigmoid

:: AFType a

=> Array a

-> Array a

sigmoid = flip op1 af_sigmoid

expm1

:: AFType a

=> Array a

-> Array a

expm1 = flip op1 af_expm1

erf

:: AFType a

=> Array a

-> Array a

erf = flip op1 af_erf

erfc

:: AFType a

=> Array a

-> Array a

erfc = flip op1 af_erfc

log

:: AFType a

=> Array a

-> Array a

log = flip op1 af_log

log1p

:: AFType a

=> Array a

-> Array a

log1p = flip op1 af_log1p

log10

:: AFType a

=> Array a

-> Array a

log10 = flip op1 af_log10

log2

:: AFType a

=> Array a

-> Array a

log2 = flip op1 af_log2

sqrt

:: AFType a

=> Array a

-> Array a

sqrt = flip op1 af_sqrt

cbrt

:: AFType a

=> Array a

-> Array a

cbrt = flip op1 af_cbrt

factorial

:: AFType a

=> Array a

-> Array a

factorial = flip op1 af_factorial

tgamma

:: AFType a

=> Array a

-> Array a

tgamma = flip op1 af_tgamma

lgamma

:: AFType a

=> Array a

-> Array a

lgamma = flip op1 af_lgamma

isZero

:: AFType a

=> Array a

-> Array a

isZero = flip op1 af_iszero

isInf

:: AFType a

=> Array a

-> Array a

isInf = flip op1 af_isinf

isNan

:: AFType a

=> Array a

-> Array a

isNan = flip op1 af_isnan