ref: 74d91a0021de012908cfdb35fb61a1473a376130
dir: /lib/math/fpmath.myr/
use std
use "impls"
pkg math =
trait fpmath @f =
/* atan-impl */
atan : (x : @f -> @f)
atan2 : (y : @f, x : @f -> @f)
/* exp-impl */
exp : (x : @f -> @f)
expm1 : (x : @f -> @f)
/* fma-impl */
fma : (x : @f, y : @f, z : @f -> @f)
/* log-impl */
log : (x : @f -> @f)
log1p : (x : @f -> @f)
/* poly-impl */
horner_poly : (x : @f, a : @f[:] -> @f)
horner_polyu : (x : @f, a : @u[:] -> @f)
/* pown-impl */
pown : (x : @f, n : @i -> @f)
rootn : (x : @f, n : @u -> @f)
/* powr-impl */
powr : (x : @f, y : @f -> @f)
/* scale2-impl */
scale2 : (x : @f, m : @i -> @f)
/* sin-impl */
sin : (x : @f -> @f)
cos : (x : @f -> @f)
sincos : (x : @f -> (@f, @f))
/* sqrt-impl */
sqrt : (x : @f -> @f)
/* sum-impl */
kahan_sum : (a : @f[:] -> @f)
priest_sum : (a : @f[:] -> @f)
/* tan-impl */
tan : (x : @f -> @f)
cot : (x : @f -> @f)
/* trunc-impl */
trunc : (x : @f -> @f)
ceil : (x : @f -> @f)
floor : (x : @f -> @f)
;;
trait roundable @f -> @i =
/* round-impl */
rn : (x : @f -> @i)
;;
impl std.equatable flt32
impl std.equatable flt64
impl roundable flt64 -> int64
impl roundable flt32 -> int32
impl fpmath flt32
impl fpmath flt64
;;
/*
We consider two floating-point numbers equal if their bits are
equal. This does not treat NaNs specially: two distinct NaNs may
compare equal, or they may compare distinct (if they arise from
different bit patterns).
Additionally, +0.0 and -0.0 compare differently.
*/
impl std.equatable flt32 =
eq = {a : flt32, b : flt32; -> std.flt32bits(a) == std.flt32bits(b)}
;;
impl std.equatable flt64 =
eq = {a : flt64, b : flt64; -> std.flt64bits(a) == std.flt64bits(b)}
;;
impl roundable flt32 -> int32 =
rn = {x : flt32; -> rn32(x) }
;;
impl roundable flt64 -> int64 =
rn = {x : flt64; -> rn64(x) }
;;
impl fpmath flt32 =
atan = {x; -> atan32(x)}
atan2 = {y, x; -> atan232(y, x)}
fma = {x, y, z; -> fma32(x, y, z)}
exp = {x; -> exp32(x)}
expm1 = {x; -> expm132(x)}
log = {x; -> log32(x)}
log1p = {x; -> log1p32(x)}
horner_poly = {x, a; -> horner_poly32(x, a)}
horner_polyu = {x, a; -> horner_polyu32(x, a)}
pown = {x, n; -> pown32(x, n)}
rootn = {x, q; -> rootn32(x, q)}
powr = {x, y; -> powr32(x, y)}
scale2 = {x, m; -> scale232(x, m)}
sin = {x; -> sin32(x)}
cos = {x; -> cos32(x)}
sincos = {x; -> sincos32(x)}
sqrt = {x; -> sqrt32(x)}
kahan_sum = {l; -> kahan_sum32(l) }
priest_sum = {l; -> priest_sum32(l) }
tan = {x; -> tan32(x)}
cot = {x; -> cot32(x)}
trunc = {x; -> trunc32(x)}
floor = {x; -> floor32(x)}
ceil = {x; -> ceil32(x)}
;;
impl fpmath flt64 =
atan = {x; -> atan64(x)}
atan2 = {y, x; -> atan264(y, x)}
fma = {x, y, z; -> fma64(x, y, z)}
exp = {x; -> exp64(x)}
expm1 = {x; -> expm164(x)}
log = {x; -> log64(x)}
log1p = {x; -> log1p64(x)}
horner_poly = {x, a; -> horner_poly64(x, a)}
horner_polyu = {x, a; -> horner_polyu64(x, a)}
pown = {x, n; -> pown64(x, n)}
rootn = {x, q; -> rootn64(x, q)}
powr = {x, y; -> powr64(x, y)}
scale2 = {x, m; -> scale264(x, m)}
sin = {x; -> sin64(x)}
cos = {x; -> cos64(x)}
sincos = {x; -> sincos64(x)}
sqrt = {x; -> sqrt64(x)}
kahan_sum = {l; -> kahan_sum64(l) }
priest_sum = {l; -> priest_sum64(l) }
tan = {x; -> tan64(x)}
cot = {x; -> cot64(x)}
trunc = {x; -> trunc64(x)}
floor = {x; -> floor64(x)}
ceil = {x; -> ceil64(x)}
;;