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181 Commits
sqrt ... master

Author SHA1 Message Date
c5fb915a6d div_euclid 2024-10-12 10:01:06 -07:00
a274b6d232 not that important 2024-10-03 12:31:41 -07:00
218a7fbf0f more general PartialEq + PartialOrd 2024-10-03 12:27:38 -07:00
64e44846aa v0.1.1 from float 2024-10-02 14:40:39 -07:00
0d05540a6b from float + tests 2024-10-01 15:01:30 -07:00
9b3dde66bd change to float tests 2024-10-01 15:00:06 -07:00
a65eef3609 fix to float 2024-10-01 14:59:33 -07:00
c4a2778af1 explicitly implement From for specific types 2024-09-30 17:08:46 -07:00
46bb2bac4e deconstruct array instead of indexing 2024-09-30 17:08:12 -07:00
c6b4cc29b8 all dependencies must have a version specified 2024-09-30 10:21:59 -07:00
9a7ebb0f0a licensing and registration 2024-09-30 10:18:25 -07:00
438d0ec6ec test zeroes 2024-09-26 18:08:33 -07:00
94e23b7f0f idk what I'm doing 2024-09-26 18:08:20 -07:00
e6cd239dcb fix zeroes 2024-09-26 15:26:18 -07:00
8d97ffba92 column major 2024-09-26 15:06:05 -07:00
e46f4fb900 save a copy in sqrt using epic bnum 0.12 feature (pulled by yours truly) 2024-09-26 15:06:05 -07:00
2b58204cb9 update bnum 2024-09-26 15:06:05 -07:00
b91f061797 implement same-size wide mul more efficiently 2024-09-25 09:46:56 -07:00
102ea607ab Ratio Parity trait 2024-09-23 11:30:35 -07:00
ba357ee99b efficient fixed mul 2024-09-21 15:42:29 -07:00
546a4aa8c7 test negative 2024-09-18 11:50:34 -07:00
94cd23fe4b add ratio tests 2024-09-18 10:44:18 -07:00
bc773f7d45 test fix better 2024-09-17 15:10:11 -07:00
934475b959 fix fix 2024-09-17 15:10:07 -07:00
665d528b87 remove debug from float builder 2024-09-17 14:48:21 -07:00
865d7a7886 float tests 2024-09-17 14:47:18 -07:00
031cd6e771 float builder (debug version) 2024-09-17 14:47:14 -07:00
6dbe96fca2 Fixed<1,_>::to_raw() 2024-09-16 15:48:52 -07:00
655a6da251 cheese extrapolate div 2024-09-16 15:02:43 -07:00
a100f182e1 Fix trait 2024-09-16 15:02:31 -07:00
0734122e75 ratio: ord methods 2024-09-16 11:46:05 -07:00
4e284311e1 this depends on that 2024-09-15 20:30:09 -07:00
0cd28e402e fixed: special case for convenience 2024-09-13 14:00:40 -07:00
260ed0fd5c ratio: PartialEq, Eq, PartialOrd, Ord 2024-09-13 14:00:13 -07:00
ec82745c6d matrix: from_rows 2024-09-12 12:16:58 -07:00
10e56fb0b9 default numba (use with care) 2024-09-12 12:16:58 -07:00
5646bd3b5a fixed width specific impls 2024-09-12 10:52:57 -07:00
6cb639317c const helpers 2024-09-11 15:15:06 -07:00
db5c37c2fb implement 'fix' function that changes the fixed point 2024-09-11 14:06:34 -07:00
a73a32f2ad Divide trait 2024-09-11 13:29:13 -07:00
44ac6fe4be fixed_wide: no default features 2024-09-11 12:59:22 -07:00
1a24de3cd9 deferred division for vector + matrix 2024-09-11 12:20:17 -07:00
9f77531995 implement Debug + Display 2024-09-11 12:06:58 -07:00
7b78338c76 fix tests :/ 2024-09-10 14:50:35 -07:00
021d7f9d1f implement mul + div only for scalars (otherwise conflicting implementations) 2024-09-10 14:20:07 -07:00
338669b60f implement shift operators 2024-09-10 13:45:12 -07:00
085d9185a9 ratio operators 2024-09-10 13:22:49 -07:00
1fd7a6eafd fixed: inline functions Q_Q 2024-09-10 13:05:10 -07:00
91b96e4b5d move ratio to own crate (again) 2024-09-10 12:09:58 -07:00
fc65d0f1f4 rename fixed_wide_vectors to linear_ops 2024-09-10 11:57:18 -07:00
4eaf8794f6 fix compile without named fields 2024-09-10 11:36:48 -07:00
fa8614891d zeroes function uses type transformation, drops direct ratio dep from zeroes 2024-09-10 11:36:48 -07:00
c20a0a4a89 compare with From types 2024-09-10 11:36:48 -07:00
e66a245c78 delete fixed-wide 2024-09-10 11:36:48 -07:00
eb7eb30814 impl det + adjugate with trait bounds 2024-09-09 19:54:00 -07:00
57c3f2dd9e write m*v test 2024-09-09 19:54:00 -07:00
b772647137 impl Mat*Vec 2024-09-09 19:54:00 -07:00
dd2140d1d2 forgotten inlines 2024-09-09 19:54:00 -07:00
6cbd3446e5 impl matrix multiplication with Mul 2024-09-09 19:54:00 -07:00
b6d260bf2c update tests to use new ideas 2024-09-09 19:54:00 -07:00
53bb1522eb impl dot + cross + length_squared with trait bounds 2024-09-09 19:54:00 -07:00
206e219467 wide-mul crate feature 2024-09-09 19:54:00 -07:00
8ee6204a42 invent wide_div + test 2024-09-09 15:24:49 -07:00
803f1bea9e extract trait impls into named functions + fix spelling 2024-09-09 15:24:49 -07:00
62419e94e1 consistency 2024-09-09 14:14:48 -07:00
d3c4d530b6 refactor macros, move things around 2024-09-09 14:14:48 -07:00
898407a0e9 matrix and vector extend functions 2024-09-06 13:24:03 -07:00
66186c7354 doc 2024-09-06 13:03:55 -07:00
36c769346c use inline const constructor because it's a little bit prettier 2024-09-06 11:44:43 -07:00
5f2bec75f5 enable matrix mul test 2024-09-06 11:38:29 -07:00
7a9aaf9fe0 matrix mul 2024-09-06 11:38:22 -07:00
9ad90cea2e fix tests 2024-09-06 11:25:51 -07:00
f2fec0b3b9 implement a bunch of fixed wide stuff 2024-09-06 11:25:46 -07:00
dae72d73d5 convert to row-major 2024-09-06 10:52:17 -07:00
4a1eff40da matrix multiplication ascii art 2024-09-06 10:44:30 -07:00
d5bd82761a fix dot test 2024-09-06 10:36:34 -07:00
5cad8637cd tweak dot 2024-09-06 10:36:24 -07:00
607706ee2a nope 2024-09-05 17:56:09 -07:00
2312ee27b7 test vector and matrix (TODO: Debug trait) 2024-09-05 17:56:09 -07:00
4d2aa0b2c8 is this better? 2024-09-05 17:44:44 -07:00
34450d6a13 matrix multiplication 2024-09-05 17:37:38 -07:00
1a6ece1312 epic const generic array transpose
verified that this loop unrolls on compiler explorer
2024-09-05 17:36:45 -07:00
e95f675e91 test named fields 2024-09-05 16:56:59 -07:00
504ff37c47 write a test 2024-09-05 16:45:44 -07:00
41cdd03b1b wip fixed wide 2024-09-05 16:32:19 -07:00
e375173625 keep generic operators and only implement i64 convenience operator 2024-09-05 16:18:13 -07:00
488a6b6496 fix vector bool code 2024-09-05 16:08:53 -07:00
5cdd2c3ee1 must be less generic to avoid conflict with convenience operators 2024-09-05 16:05:47 -07:00
a0da6873c1 vector operators 2024-09-05 15:56:44 -07:00
345d5737a2 more generic Neg operator 2024-09-05 15:56:35 -07:00
f4d28dd3c3 use derive macros 2024-09-05 15:43:26 -07:00
c362081003 implement a bunch of stuff 2024-09-05 15:43:26 -07:00
990a923463 fixup tests 2024-09-05 13:53:03 -07:00
56b781fcb8 we build 2024-09-05 13:52:54 -07:00
e026f6efed wip 2024-09-05 13:36:38 -07:00
e475da5fb4 put that back 2024-09-05 13:16:02 -07:00
c3026c67e9 delete everything and start over 2024-09-05 12:49:20 -07:00
103697fbdd matrix: test det + adjugate 2024-09-04 13:55:11 -07:00
cf17460b77 special case 3d vectors and matrices 2024-09-04 13:47:50 -07:00
823a05c101 matrix: directly implement dot product to avoid a copy 2024-09-04 12:11:52 -07:00
e5f95b97ce matrix: macro mat mul 2024-09-04 12:11:52 -07:00
176eb762e3 name macros better 2024-09-03 12:51:19 -07:00
15bd78c0e1 matrix wide dot test 2024-09-03 10:59:47 -07:00
0f9d0c8c39 matrix wide dot 2024-09-03 10:59:18 -07:00
eefbdafc16 move more impls to common 2024-09-03 10:40:43 -07:00
b0ecfeb294 the matrix super macro 2024-09-03 10:10:46 -07:00
48a8271b99 transpose macro_repeated 2024-09-03 10:10:30 -07:00
1604888254 macro macro 2024-09-03 10:01:22 -07:00
4017f33447 delete comment 2024-09-03 09:40:49 -07:00
f0527714db move macro to mod 2024-09-03 09:40:46 -07:00
27d96f9b19 delete tuple impls 2024-09-03 09:30:13 -07:00
a5094fe873 common impls between matrix and vector 2024-09-02 18:54:50 -07:00
1bd45283a9 delete unused test 2024-09-02 18:36:05 -07:00
a6dc0c37ba MACRO MACRO MACRO 2024-09-02 18:35:37 -07:00
83434a89c7 wide_dot 2024-09-02 18:25:21 -07:00
b14c84bdad MACRO MACRO MACRO 2024-09-02 18:19:35 -07:00
e98744871b narrow paste scope 2024-09-02 18:19:35 -07:00
c26ce93fc8 paste 2024-09-02 18:19:35 -07:00
c856509759 remove old comment 2024-09-02 18:19:35 -07:00
5cb98ee29f vectors: no traits 2024-09-02 18:19:35 -07:00
bc29cd9848 move tests 2024-09-02 17:44:04 -07:00
502ab7f33f named function 2024-09-02 17:09:37 -07:00
e0dba8840e ruin everything successfully 2024-09-02 17:03:01 -07:00
4d13b4ada7 paste (this sucks) 2024-09-02 16:35:01 -07:00
2a2e729f59 wip 2024-09-02 16:15:17 -07:00
63cf94499b rewrite transpose 2024-08-30 14:49:56 -07:00
83a39468d5 matrix extend 2024-08-30 13:49:23 -07:00
9aba811cd0 delete spam doc tests 2024-08-30 13:30:01 -07:00
e413409f9f remove parentheses from macro 2024-08-30 13:30:01 -07:00
e6a28fbb70 test doesn't compile yet 2024-08-30 13:30:01 -07:00
88acec5659 matrix test to pass 2024-08-30 13:07:56 -07:00
0f0d7f7a9a initial matrix type 2024-08-30 13:02:48 -07:00
263f0d35d4 test reason why matrix needs its own type 2024-08-30 12:52:54 -07:00
d713b96ad3 vectors: extend 2024-08-30 12:41:25 -07:00
20285f0f98 delete affine 2024-08-30 12:31:20 -07:00
f103c247b8 transpose too easy 2024-08-30 12:20:54 -07:00
8e1807b4b7 VECTOR IS MATRIX 2024-08-30 12:07:12 -07:00
f531e8d8ee move vector2 macro code 2024-08-30 12:07:12 -07:00
78f860c672 inline const functions 2024-08-29 20:11:33 -07:00
0924518922 eviscerate PhantomData 2024-08-29 20:10:22 -07:00
46d89619bd use from_bits function for consts 2024-08-29 20:03:56 -07:00
540749e4f1 there is a poorly named function for this 2024-08-29 19:52:00 -07:00
3c5f01da89 describe algorithm 2024-08-29 19:08:55 -07:00
70a79a8d25 remove old kludge 2024-08-29 18:55:05 -07:00
0483c9eb27 fast 2024-08-29 18:38:29 -07:00
61aad93f8d sqrt: closed loop over bit shift 2024-08-29 18:29:04 -07:00
cd1aa26293 prevent 50 headaches 2024-08-29 17:22:45 -07:00
b656371142 pass zero test 2024-08-29 17:03:25 -07:00
9266edbf92 forgot to test zero... 2024-08-29 16:20:10 -07:00
6335b1da47 todo 2024-08-29 15:35:33 -07:00
8d5fc1ae48 test max 2024-08-29 15:27:48 -07:00
67c30b8535 save one shr operation 2024-08-29 15:21:10 -07:00
95651d7091 use wide_mul for more precise sqrt 2024-08-29 14:50:22 -07:00
91b378aa43 use tabs 2024-08-29 14:28:40 -07:00
ac7d9f5c3b test more 2024-08-29 13:30:48 -07:00
b45d93a7dc more sqrt tests 2024-08-29 13:16:09 -07:00
6549305c9f use import 2024-08-29 13:16:02 -07:00
6ea9eff844 further sqrt improvements 2024-08-29 13:15:17 -07:00
e684fb421e tests 2024-08-29 12:13:45 -07:00
8ba76c7a00 smarter sqrt 2024-08-29 12:13:45 -07:00
3d3eb966a4 multiply and divide was straight up wrong, and bruh this needs const generics so bad 2024-08-29 11:16:38 -07:00
491de52f17 improve failure mode 2024-08-29 10:43:14 -07:00
69da2c52a4 use tabs 2024-08-29 10:43:14 -07:00
9f6dffafda cordic sqrt 2024-08-29 10:43:14 -07:00
446de71c30 uh oh 2024-08-28 16:15:54 -07:00
d47eaa423e write some ratio tests 2024-08-28 15:46:49 -07:00
e604ce83e9 macro up wide traits 2024-08-28 15:33:10 -07:00
ac250e9d84 ratio operators 2024-08-28 15:28:48 -07:00
617952c1e3 split tests 2024-08-28 13:36:17 -07:00
9f9e8c793b probably need this to make compiling with no wide work 2024-08-28 13:33:45 -07:00
1f6594468d bvec 2024-08-28 13:29:29 -07:00
cc3cb35309 cant do it man 2024-08-28 13:04:35 -07:00
a923a6b5d1 consistency 2024-08-28 12:23:33 -07:00
68d1c23cfa allow simple ops (why did this not work before?) 2024-08-28 12:23:33 -07:00
8aa7da6be7 add tests 2024-08-28 12:17:00 -07:00
0be0dd5c6f fixed: more constants 2024-08-28 11:47:40 -07:00
f4ab9403a4 oh my god use tabs 2024-08-28 10:47:30 -07:00
67ac4cf7ff todo: drop affine 2024-08-28 10:14:49 -07:00
002d3d9eac why intermediate 2024-08-28 10:05:08 -07:00
e1368962c1 holy wide dot batman 2024-08-28 10:04:58 -07:00
4ae391e9fd trait constructor doesn't work because trait bounds (and is also bad) 2024-08-28 09:06:16 -07:00
54 changed files with 2961 additions and 903 deletions

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@ -1,11 +0,0 @@
[package]
name = "deferred_division"
version = "0.1.0"
edition = "2021"
[features]
default=["fixed_wide_traits"]
fixed_wide_traits=["dep:fixed_wide_traits"]
[dependencies]
fixed_wide_traits = { version = "0.1.0", path = "../fixed_wide_traits", optional = true }

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@ -1,8 +0,0 @@
pub mod ratio;
#[cfg(feature="fixed_wide_traits")]
mod wide;
#[cfg(test)]
mod tests;

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@ -1,10 +0,0 @@
#[derive(Clone,Copy,Debug,Hash)]
pub struct Ratio<Num,Den>{
pub(crate)num:Num,
pub(crate)den:Den,
}
//this trait is like a constructor for Ratio
pub trait DeferredDiv<Rhs=Self>{
type Output;
fn deferred_div(self,rhs:Rhs)->Self::Output;
}

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@ -1,51 +0,0 @@
use std::ops::{Add,Mul};
use crate::ratio::Ratio;
use fixed_wide_traits::wide::{WideMul,WideDiv};
impl<Num,Den:Copy> Ratio<Num,Den>
{
pub fn rational_add<T>(self,rhs:T)->Ratio<<Num as Add<<Den as Mul<T>>::Output>>::Output,Den>
where
Den:Mul<T>,
Num:Add<<Den as Mul<T>>::Output>,
{
Ratio{
num:self.num+self.den.mul(rhs),
den:self.den,
}
}
pub fn wide_rational_add<T>(self,rhs:T)->Ratio<<Num as Add<<Den as WideMul<T>>::Output>>::Output,Den>
where
Den:WideMul<T>,
Num:Add<<Den as WideMul<T>>::Output>,
{
Ratio{
num:self.num+self.den.wide_mul(rhs),
den:self.den,
}
}
}
impl<Num,Den,T> WideMul<T> for Ratio<Num,Den>
where
Num:WideMul<T>,
{
type Output=Ratio<<Num as WideMul<T>>::Output,Den>;
fn wide_mul(self,rhs:T)->Ratio<<Num as WideMul<T>>::Output,Den>{
Ratio{
num:self.num.wide_mul(rhs),
den:self.den,
}
}
}
impl<Num,Den,T> WideDiv<T> for Ratio<Num,Den>
where
Den:WideMul<T>,
{
type Output=Ratio<Num,<Den as WideMul<T>>::Output>;
fn wide_div(self,rhs:T)->Ratio<Num,<Den as WideMul<T>>::Output>{
Ratio{
num:self.num,
den:self.den.wide_mul(rhs),
}
}
}

31
fixed_wide/Cargo.lock generated
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@ -3,26 +3,33 @@
version = 3 version = 3
[[package]] [[package]]
name = "bnum" name = "arrayvec"
version = "0.11.0" version = "0.7.6"
source = "registry+https://github.com/rust-lang/crates.io-index" source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "3e31ea183f6ee62ac8b8a8cf7feddd766317adfb13ff469de57ce033efd6a790" checksum = "7c02d123df017efcdfbd739ef81735b36c5ba83ec3c59c80a9d7ecc718f92e50"
[[package]]
name = "bnum"
version = "0.12.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "50202def95bf36cb7d1d7a7962cea1c36a3f8ad42425e5d2b71d7acb8041b5b8"
[[package]] [[package]]
name = "fixed_wide" name = "fixed_wide"
version = "0.1.0" version = "0.1.1"
dependencies = [ dependencies = [
"arrayvec",
"bnum", "bnum",
"fixed_wide_traits", "paste",
"typenum", "ratio_ops",
] ]
[[package]] [[package]]
name = "fixed_wide_traits" name = "paste"
version = "0.1.0" version = "1.0.15"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "57c0d7b74b563b49d38dae00a0c37d4d6de9b432382b2892f0574ddcae73fd0a"
[[package]] [[package]]
name = "typenum" name = "ratio_ops"
version = "1.17.0" version = "0.1.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "42ff0bf0c66b8238c6f3b578df37d0b7848e55df8577b3f74f92a69acceeb825"

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@ -1,13 +1,20 @@
[package] [package]
name = "fixed_wide" name = "fixed_wide"
version = "0.1.0" version = "0.1.1"
edition = "2021" edition = "2021"
repository = "https://git.itzana.me/StrafesNET/fixed_wide_vectors"
license = "MIT OR Apache-2.0"
description = "Fixed point numbers with optional widening Mul operator."
authors = ["Rhys Lloyd <krakow20@gmail.com>"]
[features] [features]
default=["fixed_wide_traits"] default=[]
fixed_wide_traits=["dep:fixed_wide_traits"] deferred-division=["dep:ratio_ops"]
wide-mul=[]
zeroes=["dep:arrayvec"]
[dependencies] [dependencies]
bnum = "0.11.0" bnum = "0.12.0"
typenum = "1.17.0" arrayvec = { version = "0.7.6", optional = true }
fixed_wide_traits = { version = "0.1.0", path = "../fixed_wide_traits", optional = true } paste = "1.0.15"
ratio_ops = { version = "0.1.0", path = "../ratio_ops", registry = "strafesnet", optional = true }

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@ -1,120 +1,533 @@
use bnum::BInt; use bnum::{BInt,cast::As};
use typenum::Unsigned;
use std::marker::PhantomData;
#[derive(Clone,Copy,Debug,Hash)] #[derive(Clone,Copy,Debug,Default,Hash)]
pub struct Fixed<const CHUNKS:usize,Frac>{ /// A Fixed point number for which multiply operations widen the bits in the output. (when the wide-mul feature is enabled)
pub(crate)bits:BInt<{CHUNKS}>, /// N is the number of u64s to use
pub(crate)frac:PhantomData<Frac>, /// F is the number of fractional bits (always N*32 lol)
pub struct Fixed<const N:usize,const F:usize>{
pub(crate)bits:BInt<{N}>,
} }
impl<const CHUNKS:usize,Frac:Unsigned> Fixed<CHUNKS,Frac>{ impl<const N:usize,const F:usize> Fixed<N,F>{
pub const ZERO:Self=Self{bits:BInt::<CHUNKS>::ZERO,frac:PhantomData}; pub const MAX:Self=Self::from_bits(BInt::<N>::MAX);
pub const ONE:Self=Self{bits:BInt::<CHUNKS>::ONE.shl(Frac::U32),frac:PhantomData}; pub const MIN:Self=Self::from_bits(BInt::<N>::MIN);
pub const NEG_ONE:Self=Self{bits:BInt::<CHUNKS>::NEG_ONE.shl(Frac::U32),frac:PhantomData}; pub const ZERO:Self=Self::from_bits(BInt::<N>::ZERO);
pub const EPSILON:Self=Self::from_bits(BInt::<N>::ONE);
pub const NEG_EPSILON:Self=Self::from_bits(BInt::<N>::NEG_ONE);
pub const ONE:Self=Self::from_bits(BInt::<N>::ONE.shl(F as u32));
pub const TWO:Self=Self::from_bits(BInt::<N>::TWO.shl(F as u32));
pub const HALF:Self=Self::from_bits(BInt::<N>::ONE.shl(F as u32-1));
pub const NEG_ONE:Self=Self::from_bits(BInt::<N>::NEG_ONE.shl(F as u32));
pub const NEG_TWO:Self=Self::from_bits(BInt::<N>::NEG_TWO.shl(F as u32));
pub const NEG_HALF:Self=Self::from_bits(BInt::<N>::NEG_ONE.shl(F as u32-1));
} }
impl<const N:usize,const F:usize> Fixed<N,F>{
impl<const CHUNKS:usize,FracDst:Unsigned,T> From<T> for Fixed<CHUNKS,FracDst> #[inline]
where pub const fn from_bits(bits:BInt::<N>)->Self{
BInt<CHUNKS>:From<T>
{
fn from(value:T)->Self{
Self{ Self{
bits:BInt::<{CHUNKS}>::from(value)<<FracDst::U32, bits,
frac:PhantomData,
} }
} }
#[inline]
pub const fn to_bits(self)->BInt<N>{
self.bits
}
#[inline]
pub const fn raw_digit(value:i64)->Self{
let mut digits=[0u64;N];
digits[0]=value.abs() as u64;
//sign bit
digits[N-1]|=(value&i64::MIN) as u64;
Self::from_bits(BInt::from_bits(bnum::BUint::from_digits(digits)))
}
#[inline]
pub const fn is_zero(self)->bool{
self.bits.is_zero()
}
#[inline]
pub const fn is_negative(self)->bool{
self.bits.is_negative()
}
#[inline]
pub const fn is_positive(self)->bool{
self.bits.is_positive()
}
#[inline]
pub const fn abs(self)->Self{
Self::from_bits(self.bits.abs())
}
}
impl<const F:usize> Fixed<1,F>{
/// My old code called this function everywhere so let's provide it
#[inline]
pub const fn raw(value:i64)->Self{
Self::from_bits(BInt::from_bits(bnum::BUint::from_digit(value as u64)))
}
#[inline]
pub const fn to_raw(self)->i64{
let &[digit]=self.to_bits().to_bits().digits();
digit as i64
}
} }
impl<const CHUNKS:usize,Frac> PartialEq for Fixed<CHUNKS,Frac>{ macro_rules! impl_from {
($($from:ty),*)=>{
$(
impl<const N:usize,const F:usize> From<$from> for Fixed<N,F>{
#[inline]
fn from(value:$from)->Self{
Self::from_bits(BInt::<{N}>::from(value)<<F as u32)
}
}
)*
};
}
impl_from!(
u8,u16,u32,u64,u128,usize,
i8,i16,i32,i64,i128,isize
);
impl<const N:usize,const F:usize> PartialEq for Fixed<N,F>{
#[inline]
fn eq(&self,other:&Self)->bool{ fn eq(&self,other:&Self)->bool{
self.bits.eq(&other.bits) self.bits.eq(&other.bits)
} }
} }
impl<const CHUNKS:usize,Frac> Eq for Fixed<CHUNKS,Frac>{} impl<const N:usize,const F:usize,T> PartialEq<T> for Fixed<N,F>
where
T:Copy,
BInt::<N>:From<T>,
{
#[inline]
fn eq(&self,&other:&T)->bool{
self.bits.eq(&other.into())
}
}
impl<const N:usize,const F:usize> Eq for Fixed<N,F>{}
impl<const CHUNKS:usize,Frac> PartialOrd for Fixed<CHUNKS,Frac>{ impl<const N:usize,const F:usize> PartialOrd for Fixed<N,F>{
#[inline]
fn partial_cmp(&self,other:&Self)->Option<std::cmp::Ordering>{ fn partial_cmp(&self,other:&Self)->Option<std::cmp::Ordering>{
self.bits.partial_cmp(&other.bits) self.bits.partial_cmp(&other.bits)
} }
} }
impl<const CHUNKS:usize,Frac> Ord for Fixed<CHUNKS,Frac>{ impl<const N:usize,const F:usize,T> PartialOrd<T> for Fixed<N,F>
where
T:Copy,
BInt::<N>:From<T>,
{
#[inline]
fn partial_cmp(&self,&other:&T)->Option<std::cmp::Ordering>{
self.bits.partial_cmp(&other.into())
}
}
impl<const N:usize,const F:usize> Ord for Fixed<N,F>{
#[inline]
fn cmp(&self,other:&Self)->std::cmp::Ordering{ fn cmp(&self,other:&Self)->std::cmp::Ordering{
self.bits.cmp(&other.bits) self.bits.cmp(&other.bits)
} }
} }
impl<const CHUNKS:usize,Frac> std::ops::Neg for Fixed<CHUNKS,Frac>{ impl<const N:usize,const F:usize> std::ops::Neg for Fixed<N,F>{
type Output=Self; type Output=Self;
#[inline]
fn neg(self)->Self{ fn neg(self)->Self{
Self{ Self::from_bits(self.bits.neg())
bits:self.bits.neg(),
frac:PhantomData,
} }
}
impl<const N:usize,const F:usize> std::iter::Sum for Fixed<N,F>{
#[inline]
fn sum<I:Iterator<Item=Self>>(iter:I)->Self{
let mut sum=Self::ZERO;
for elem in iter{
sum+=elem;
}
sum
} }
} }
macro_rules! impl_operator { const fn signed_shift(lhs:u64,rhs:i32)->u64{
( $struct: ident, $trait: ident, $method: ident, $output: ty ) => { if rhs.is_negative(){
impl<const CHUNKS:usize,Frac> core::ops::$trait for $struct<CHUNKS,Frac>{ lhs>>-rhs
type Output = $output; }else{
lhs<<rhs
fn $method(self, other: Self) -> Self::Output {
Self {
bits:self.bits.$method(other.bits),
frac:PhantomData,
} }
}
macro_rules! impl_into_float {
( $output: ty, $unsigned:ty, $exponent_bits:expr, $mantissa_bits:expr ) => {
impl<const N:usize,const F:usize> Into<$output> for Fixed<N,F>{
#[inline]
fn into(self)->$output{
const DIGIT_SHIFT:u32=6;//Log2[64]
// SBBB BBBB
// 1001 1110 0000 0000
let sign=if self.bits.is_negative(){(1 as $unsigned)<<(<$unsigned>::BITS-1)}else{0};
let unsigned=self.bits.unsigned_abs();
let most_significant_bit=unsigned.bits();
let exp=if unsigned.is_zero(){
0
}else{
let msb=most_significant_bit as $unsigned;
let _127=((1 as $unsigned)<<($exponent_bits-1))-1;
let msb_offset=msb+_127-1-F as $unsigned;
msb_offset<<($mantissa_bits-1)
};
let digits=unsigned.digits();
let digit_index=most_significant_bit.saturating_sub(1)>>DIGIT_SHIFT;
let digit=digits[digit_index as usize];
//How many bits does the mantissa take from this digit
let take_bits=most_significant_bit-(digit_index<<DIGIT_SHIFT);
let rest_of_mantissa=$mantissa_bits as i32-(take_bits as i32);
let mut unmasked_mant=signed_shift(digit,rest_of_mantissa) as $unsigned;
if 0<rest_of_mantissa&&digit_index!=0{
//take the next digit down and shove some of its bits onto the bottom of the mantissa
let digit=digits[digit_index as usize-1];
let take_bits=most_significant_bit-((digit_index-1)<<DIGIT_SHIFT);
let rest_of_mantissa=$mantissa_bits as i32-(take_bits as i32);
let unmasked_mant2=signed_shift(digit,rest_of_mantissa) as $unsigned;
unmasked_mant|=unmasked_mant2;
}
let mant=unmasked_mant&((1 as $unsigned)<<($mantissa_bits-1))-1;
let bits=sign|exp|mant;
<$output>::from_bits(bits)
}
}
}
}
impl_into_float!(f32,u32,8,24);
impl_into_float!(f64,u64,11,53);
#[inline]
fn integer_decode_f32(f: f32) -> (u64, i16, bool) {
let bits: u32 = f.to_bits();
let sign: bool = bits & (1<<31) != 0;
let mut exponent: i16 = ((bits >> 23) & 0xff) as i16;
let mantissa = if exponent == 0 {
(bits & 0x7fffff) << 1
} else {
(bits & 0x7fffff) | 0x800000
};
// Exponent bias + mantissa shift
exponent -= 127 + 23;
(mantissa as u64, exponent, sign)
}
#[inline]
fn integer_decode_f64(f: f64) -> (u64, i16, bool) {
let bits: u64 = f.to_bits();
let sign: bool = bits & (1u64<<63) != 0;
let mut exponent: i16 = ((bits >> 52) & 0x7ff) as i16;
let mantissa = if exponent == 0 {
(bits & 0xfffffffffffff) << 1
} else {
(bits & 0xfffffffffffff) | 0x10000000000000
};
// Exponent bias + mantissa shift
exponent -= 1023 + 52;
(mantissa, exponent, sign)
}
#[derive(Debug,Eq,PartialEq)]
pub enum FixedFromFloatError{
Nan,
Infinite,
Overflow,
Underflow,
}
impl FixedFromFloatError{
pub fn underflow_to_zero<const N:usize,const F:usize>(self)->Result<Fixed<N,F>,Self>{
match self{
FixedFromFloatError::Underflow=>Ok(Fixed::ZERO),
_=>Err(self),
}
}
}
macro_rules! impl_from_float {
( $decode:ident, $input: ty, $mantissa_bits:expr ) => {
impl<const N:usize,const F:usize> TryFrom<$input> for Fixed<N,F>{
type Error=FixedFromFloatError;
#[inline]
fn try_from(value:$input)->Result<Self,Self::Error>{
const DIGIT_SHIFT:u32=6;
match value.classify(){
std::num::FpCategory::Nan=>Err(FixedFromFloatError::Nan),
std::num::FpCategory::Infinite=>Err(FixedFromFloatError::Infinite),
std::num::FpCategory::Zero=>Ok(Self::ZERO),
std::num::FpCategory::Subnormal
|std::num::FpCategory::Normal
=>{
let (m,e,s)=$decode(value);
let mut digits=[0u64;N];
let most_significant_bit=e as i32+$mantissa_bits as i32+F as i32;
if most_significant_bit<0{
return Err(FixedFromFloatError::Underflow);
}
let digit_index=most_significant_bit>>DIGIT_SHIFT;
let digit=digits.get_mut(digit_index as usize).ok_or(FixedFromFloatError::Overflow)?;
let take_bits=most_significant_bit-(digit_index<<DIGIT_SHIFT);
let rest_of_mantissa=-($mantissa_bits as i32-(take_bits as i32));
*digit=signed_shift(m,rest_of_mantissa);
if rest_of_mantissa<0&&digit_index!=0{
//we don't care if some float bits are partially truncated
if let Some(digit)=digits.get_mut((digit_index-1) as usize){
let take_bits=most_significant_bit-((digit_index-1)<<DIGIT_SHIFT);
let rest_of_mantissa=-($mantissa_bits as i32-(take_bits as i32));
*digit=signed_shift(m,rest_of_mantissa);
}
}
let bits=BInt::from_bits(bnum::BUint::from_digits(digits));
Ok(if s{
Self::from_bits(bits.overflowing_neg().0)
}else{
Self::from_bits(bits)
})
},
}
}
}
}
}
impl_from_float!(integer_decode_f32,f32,24);
impl_from_float!(integer_decode_f64,f64,53);
impl<const N:usize,const F:usize> core::fmt::Display for Fixed<N,F>{
#[inline]
fn fmt(&self,f:&mut core::fmt::Formatter)->Result<(),core::fmt::Error>{
let float:f32=(*self).into();
core::write!(f,"{:.3}",float)
}
}
macro_rules! impl_additive_operator {
( $struct: ident, $trait: ident, $method: ident, $output: ty ) => {
impl<const N:usize,const F:usize> $struct<N,F>{
#[inline]
pub const fn $method(self, other: Self) -> Self {
Self::from_bits(self.bits.$method(other.bits))
}
}
impl<const N:usize,const F:usize> core::ops::$trait for $struct<N,F>{
type Output = $output;
#[inline]
fn $method(self, other: Self) -> Self::Output {
self.$method(other)
}
}
impl<const N:usize,const F:usize,U> core::ops::$trait<U> for $struct<N,F>
where
BInt::<N>:From<U>,
{
type Output = $output;
#[inline]
fn $method(self, other: U) -> Self::Output {
Self::from_bits(self.bits.$method(BInt::<N>::from(other).shl(F as u32)))
} }
} }
}; };
} }
macro_rules! impl_assign_operator { macro_rules! impl_additive_assign_operator {
( $struct: ident, $trait: ident, $method: ident ) => { ( $struct: ident, $trait: ident, $method: ident ) => {
impl<const CHUNKS:usize,Frac> core::ops::$trait for $struct<CHUNKS,Frac>{ impl<const N:usize,const F:usize> core::ops::$trait for $struct<N,F>{
#[inline]
fn $method(&mut self, other: Self) { fn $method(&mut self, other: Self) {
self.bits.$method(other.bits); self.bits.$method(other.bits);
} }
} }
impl<const N:usize,const F:usize,U> core::ops::$trait<U> for $struct<N,F>
where
BInt::<N>:From<U>,
{
#[inline]
fn $method(&mut self, other: U) {
self.bits.$method(BInt::<N>::from(other).shl(F as u32));
}
}
}; };
} }
// Impl arithmetic pperators // Impl arithmetic pperators
impl_assign_operator!( Fixed, AddAssign, add_assign ); impl_additive_assign_operator!( Fixed, AddAssign, add_assign );
impl_operator!( Fixed, Add, add, Self ); impl_additive_operator!( Fixed, Add, add, Self );
impl_assign_operator!( Fixed, SubAssign, sub_assign ); impl_additive_assign_operator!( Fixed, SubAssign, sub_assign );
impl_operator!( Fixed, Sub, sub, Self ); impl_additive_operator!( Fixed, Sub, sub, Self );
impl_assign_operator!( Fixed, MulAssign, mul_assign ); impl_additive_assign_operator!( Fixed, RemAssign, rem_assign );
impl_operator!( Fixed, Mul, mul, Self ); impl_additive_operator!( Fixed, Rem, rem, Self );
impl_assign_operator!( Fixed, DivAssign, div_assign );
impl_operator!( Fixed, Div, div, Self );
impl_assign_operator!( Fixed, RemAssign, rem_assign );
impl_operator!( Fixed, Rem, rem, Self );
// Impl bitwise operators // Impl bitwise operators
impl_assign_operator!( Fixed, BitAndAssign, bitand_assign ); impl_additive_assign_operator!( Fixed, BitAndAssign, bitand_assign );
impl_operator!( Fixed, BitAnd, bitand, Self ); impl_additive_operator!( Fixed, BitAnd, bitand, Self );
impl_assign_operator!( Fixed, BitOrAssign, bitor_assign ); impl_additive_assign_operator!( Fixed, BitOrAssign, bitor_assign );
impl_operator!( Fixed, BitOr, bitor, Self ); impl_additive_operator!( Fixed, BitOr, bitor, Self );
impl_assign_operator!( Fixed, BitXorAssign, bitxor_assign ); impl_additive_assign_operator!( Fixed, BitXorAssign, bitxor_assign );
impl_operator!( Fixed, BitXor, bitxor, Self ); impl_additive_operator!( Fixed, BitXor, bitxor, Self );
// non-wide operators. The result is the same width as the inputs.
// This macro is not used in the default configuration.
#[allow(unused_macros)]
macro_rules! impl_multiplicative_operator_not_const_generic {
( ($struct: ident, $trait: ident, $method: ident, $output: ty ), $width:expr ) => {
impl<const F:usize> core::ops::$trait for $struct<$width,F>{
type Output = $output;
#[inline]
fn $method(self, other: Self) -> Self::Output {
paste::item!{
self.[<fixed_ $method>](other)
}
}
}
};
}
macro_rules! impl_multiplicative_assign_operator_not_const_generic {
( ($struct: ident, $trait: ident, $method: ident, $non_assign_method: ident ), $width:expr ) => {
impl<const F:usize> core::ops::$trait for $struct<$width,F>{
#[inline]
fn $method(&mut self, other: Self) {
paste::item!{
*self=self.[<fixed_ $non_assign_method>](other);
}
}
}
};
}
macro_rules! impl_multiply_operator_not_const_generic {
( ($struct: ident, $trait: ident, $method: ident, $output: ty ), $width:expr ) => {
impl<const F:usize> $struct<$width,F>{
paste::item!{
#[inline]
pub fn [<fixed_ $method>](self, rhs: Self) -> Self {
let (low,high)=self.bits.unsigned_abs().widening_mul(rhs.bits.unsigned_abs());
let out:BInt::<{$width*2}>=unsafe{core::mem::transmute([low,high])};
if self.is_negative()==rhs.is_negative(){
Self::from_bits(out.shr(F as u32).as_())
}else{
-Self::from_bits(out.shr(F as u32).as_())
}
}
}
}
#[cfg(not(feature="wide-mul"))]
impl_multiplicative_operator_not_const_generic!(($struct, $trait, $method, $output ), $width);
#[cfg(feature="deferred-division")]
impl ratio_ops::ratio::Divide<i64> for Fixed<$width,{$width*32}>{
type Output=Self;
#[inline]
fn divide(self, other: i64)->Self::Output{
Self::from_bits(self.bits.div_euclid(BInt::from(other)))
}
}
}
}
macro_rules! impl_divide_operator_not_const_generic {
( ($struct: ident, $trait: ident, $method: ident, $output: ty ), $width:expr ) => {
impl<const F:usize> $struct<$width,F>{
paste::item!{
#[inline]
pub fn [<fixed_ $method>](self,other:Self)->Self{
//this only needs to be $width+F as u32/64+1 but MUH CONST GENERICS!!!!!
let lhs=self.bits.as_::<BInt::<{$width*2}>>().shl(F as u32);
let rhs=other.bits.as_::<BInt::<{$width*2}>>();
Self::from_bits(lhs.div_euclid(rhs).as_())
}
}
}
#[cfg(all(not(feature="wide-mul"),not(feature="deferred-division")))]
impl_multiplicative_operator_not_const_generic!(($struct, $trait, $method, $output ), $width);
#[cfg(all(not(feature="wide-mul"),feature="deferred-division"))]
impl<const F:usize> ratio_ops::ratio::Divide for $struct<$width,F>{
type Output = $output;
#[inline]
fn divide(self, other: Self) -> Self::Output {
paste::item!{
self.[<fixed_ $method>](other)
}
}
}
};
}
macro_rules! impl_multiplicative_operator {
( $struct: ident, $trait: ident, $method: ident, $inner_method: ident, $output: ty ) => {
impl<const N:usize,const F:usize,U> core::ops::$trait<U> for $struct<N,F>
where
BInt::<N>:From<U>+core::ops::$trait,
{
type Output = $output;
#[inline]
fn $method(self,other:U)->Self::Output{
Self::from_bits(self.bits.$inner_method(BInt::<N>::from(other)))
}
}
};
}
macro_rules! impl_multiplicative_assign_operator {
( $struct: ident, $trait: ident, $method: ident, $not_assign_method: ident ) => {
impl<const N:usize,const F:usize,U> core::ops::$trait<U> for $struct<N,F>
where
BInt::<N>:From<U>+core::ops::$trait,
{
#[inline]
fn $method(&mut self,other:U){
self.bits=self.bits.$not_assign_method(BInt::<N>::from(other));
}
}
};
}
macro_rules! macro_repeated{
(
$macro:ident,
$any:tt,
$($repeated:tt),*
)=>{
$(
$macro!($any, $repeated);
)*
};
}
macro_rules! macro_16 {
( $macro: ident, $any:tt ) => {
macro_repeated!($macro,$any,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16);
}
}
macro_16!( impl_multiplicative_assign_operator_not_const_generic, (Fixed, MulAssign, mul_assign, mul) );
macro_16!( impl_multiply_operator_not_const_generic, (Fixed, Mul, mul, Self) );
macro_16!( impl_multiplicative_assign_operator_not_const_generic, (Fixed, DivAssign, div_assign, div) );
macro_16!( impl_divide_operator_not_const_generic, (Fixed, Div, div, Self) );
impl_multiplicative_assign_operator!( Fixed, MulAssign, mul_assign, mul );
impl_multiplicative_operator!( Fixed, Mul, mul, mul, Self );
impl_multiplicative_assign_operator!( Fixed, DivAssign, div_assign, div_euclid );
impl_multiplicative_operator!( Fixed, Div, div, div_euclid, Self );
#[cfg(feature="deferred-division")]
impl<const LHS_N:usize,const LHS_F:usize,const RHS_N:usize,const RHS_F:usize> core::ops::Div<Fixed<RHS_N,RHS_F>> for Fixed<LHS_N,LHS_F>{
type Output=ratio_ops::ratio::Ratio<Fixed<LHS_N,LHS_F>,Fixed<RHS_N,RHS_F>>;
#[inline]
fn div(self, other: Fixed<RHS_N,RHS_F>)->Self::Output{
ratio_ops::ratio::Ratio::new(self,other)
}
}
#[cfg(feature="deferred-division")]
impl<const N:usize,const F:usize> ratio_ops::ratio::Parity for Fixed<N,F>{
fn parity(&self)->bool{
self.is_negative()
}
}
macro_rules! impl_shift_operator { macro_rules! impl_shift_operator {
( $struct: ident, $trait: ident, $method: ident, $output: ty ) => { ( $struct: ident, $trait: ident, $method: ident, $output: ty ) => {
impl<const CHUNKS:usize,Frac> core::ops::$trait<u32> for $struct<CHUNKS,Frac>{ impl<const N:usize,const F:usize> core::ops::$trait<u32> for $struct<N,F>{
type Output = $output; type Output = $output;
#[inline]
fn $method(self, other: u32) -> Self::Output { fn $method(self, other: u32) -> Self::Output {
Self { Self::from_bits(self.bits.$method(other))
bits:self.bits.$method(other),
frac:PhantomData,
}
} }
} }
}; };
} }
macro_rules! impl_shift_assign_operator { macro_rules! impl_shift_assign_operator {
( $struct: ident, $trait: ident, $method: ident ) => { ( $struct: ident, $trait: ident, $method: ident ) => {
impl<const CHUNKS:usize,Frac> core::ops::$trait<u32> for $struct<CHUNKS,Frac>{ impl<const N:usize,const F:usize> core::ops::$trait<u32> for $struct<N,F>{
#[inline]
fn $method(&mut self, other: u32) { fn $method(&mut self, other: u32) {
self.bits.$method(other); self.bits.$method(other);
} }
@ -125,3 +538,311 @@ impl_shift_assign_operator!( Fixed, ShlAssign, shl_assign );
impl_shift_operator!( Fixed, Shl, shl, Self ); impl_shift_operator!( Fixed, Shl, shl, Self );
impl_shift_assign_operator!( Fixed, ShrAssign, shr_assign ); impl_shift_assign_operator!( Fixed, ShrAssign, shr_assign );
impl_shift_operator!( Fixed, Shr, shr, Self ); impl_shift_operator!( Fixed, Shr, shr, Self );
// wide operators. The result width is the sum of the input widths, i.e. none of the multiplication
#[allow(unused_macros)]
macro_rules! impl_wide_operators{
($lhs:expr,$rhs:expr)=>{
impl core::ops::Mul<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
type Output=Fixed<{$lhs+$rhs},{($lhs+$rhs)*32}>;
#[inline]
fn mul(self, other: Fixed<$rhs,{$rhs*32}>)->Self::Output{
paste::item!{
self.[<wide_mul_ $lhs _ $rhs>](other)
}
}
}
#[cfg(not(feature="deferred-division"))]
impl core::ops::Div<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
type Output=Fixed<{$lhs+$rhs},{($lhs+$rhs)*32}>;
#[inline]
fn div(self, other: Fixed<$rhs,{$rhs*32}>)->Self::Output{
paste::item!{
self.[<wide_div_ $lhs _ $rhs>](other)
}
}
}
#[cfg(feature="deferred-division")]
impl ratio_ops::ratio::Divide<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
type Output=Fixed<{$lhs+$rhs},{($lhs+$rhs)*32}>;
#[inline]
fn divide(self, other: Fixed<$rhs,{$rhs*32}>)->Self::Output{
paste::item!{
self.[<wide_div_ $lhs _ $rhs>](other)
}
}
}
}
}
// WIDE MUL: multiply into a wider type
// let a = I32F32::ONE;
// let b:I64F64 = a.wide_mul(a);
macro_rules! impl_wide_not_const_generic{
(
(),
($lhs:expr,$rhs:expr)
)=>{
impl Fixed<$lhs,{$lhs*32}>
{
paste::item!{
#[inline]
pub fn [<wide_mul_ $lhs _ $rhs>](self,rhs:Fixed<$rhs,{$rhs*32}>)->Fixed<{$lhs+$rhs},{($lhs+$rhs)*32}>{
let lhs=self.bits.as_::<BInt<{$lhs+$rhs}>>();
let rhs=rhs.bits.as_::<BInt<{$lhs+$rhs}>>();
Fixed::from_bits(lhs*rhs)
}
/// This operation cannot represent the fraction exactly,
/// but it shapes the output to have precision for the
/// largest and smallest possible fractions.
#[inline]
pub fn [<wide_div_ $lhs _ $rhs>](self,rhs:Fixed<$rhs,{$rhs*32}>)->Fixed<{$lhs+$rhs},{($lhs+$rhs)*32}>{
// (lhs/2^LHS_FRAC)/(rhs/2^RHS_FRAC)
let lhs=self.bits.as_::<BInt<{$lhs+$rhs}>>().shl($rhs*64);
let rhs=rhs.bits.as_::<BInt<{$lhs+$rhs}>>();
Fixed::from_bits(lhs/rhs)
}
}
}
#[cfg(feature="wide-mul")]
impl_wide_operators!($lhs,$rhs);
};
}
macro_rules! impl_wide_same_size_not_const_generic{
(
(),
$width:expr
)=>{
impl Fixed<$width,{$width*32}>
{
paste::item!{
#[inline]
pub fn [<wide_mul_ $width _ $width>](self,rhs:Fixed<$width,{$width*32}>)->Fixed<{$width*2},{$width*2*32}>{
let (low,high)=self.bits.unsigned_abs().widening_mul(rhs.bits.unsigned_abs());
let out:BInt::<{$width*2}>=unsafe{core::mem::transmute([low,high])};
if self.is_negative()==rhs.is_negative(){
Fixed::from_bits(out)
}else{
// Normal neg is the cheapest negation operation
// And the inputs cannot reach the point where it matters
Fixed::from_bits(out.neg())
}
}
/// This operation cannot represent the fraction exactly,
/// but it shapes the output to have precision for the
/// largest and smallest possible fractions.
#[inline]
pub fn [<wide_div_ $width _ $width>](self,rhs:Fixed<$width,{$width*32}>)->Fixed<{$width*2},{$width*2*32}>{
// (lhs/2^LHS_FRAC)/(rhs/2^RHS_FRAC)
let lhs=self.bits.as_::<BInt<{$width*2}>>().shl($width*64);
let rhs=rhs.bits.as_::<BInt<{$width*2}>>();
Fixed::from_bits(lhs/rhs)
}
}
}
#[cfg(feature="wide-mul")]
impl_wide_operators!($width,$width);
};
}
//const generics sidestepped wahoo
macro_repeated!(
impl_wide_not_const_generic,(),
(2,1),(3,1),(4,1),(5,1),(6,1),(7,1),(8,1),(9,1),(10,1),(11,1),(12,1),(13,1),(14,1),(15,1),
(1,2), (3,2),(4,2),(5,2),(6,2),(7,2),(8,2),(9,2),(10,2),(11,2),(12,2),(13,2),(14,2),
(1,3),(2,3), (4,3),(5,3),(6,3),(7,3),(8,3),(9,3),(10,3),(11,3),(12,3),(13,3),
(1,4),(2,4),(3,4), (5,4),(6,4),(7,4),(8,4),(9,4),(10,4),(11,4),(12,4),
(1,5),(2,5),(3,5),(4,5), (6,5),(7,5),(8,5),(9,5),(10,5),(11,5),
(1,6),(2,6),(3,6),(4,6),(5,6), (7,6),(8,6),(9,6),(10,6),
(1,7),(2,7),(3,7),(4,7),(5,7),(6,7), (8,7),(9,7),
(1,8),(2,8),(3,8),(4,8),(5,8),(6,8),(7,8), (9,8),
(1,9),(2,9),(3,9),(4,9),(5,9),(6,9),(7,9),
(1,10),(2,10),(3,10),(4,10),(5,10),(6,10),
(1,11),(2,11),(3,11),(4,11),(5,11),
(1,12),(2,12),(3,12),(4,12),
(1,13),(2,13),(3,13),
(1,14),(2,14),
(1,15)
);
macro_repeated!(
impl_wide_same_size_not_const_generic,(),
1,2,3,4,5,6,7,8
);
pub trait Fix<Out>{
fn fix(self)->Out;
}
macro_rules! impl_fix_rhs_lt_lhs_not_const_generic{
(
(),
($lhs:expr,$rhs:expr)
)=>{
impl Fixed<$lhs,{$lhs*32}>
{
paste::item!{
#[inline]
pub fn [<fix_ $rhs>](self)->Fixed<$rhs,{$rhs*32}>{
Fixed::from_bits(bnum::cast::As::as_::<BInt::<$rhs>>(self.bits.shr(($lhs-$rhs)*32)))
}
}
}
impl Fix<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
fn fix(self)->Fixed<$rhs,{$rhs*32}>{
paste::item!{
self.[<fix_ $rhs>]()
}
}
}
}
}
macro_rules! impl_fix_lhs_lt_rhs_not_const_generic{
(
(),
($lhs:expr,$rhs:expr)
)=>{
impl Fixed<$lhs,{$lhs*32}>
{
paste::item!{
#[inline]
pub fn [<fix_ $rhs>](self)->Fixed<$rhs,{$rhs*32}>{
Fixed::from_bits(bnum::cast::As::as_::<BInt::<$rhs>>(self.bits).shl(($rhs-$lhs)*32))
}
}
}
impl Fix<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
fn fix(self)->Fixed<$rhs,{$rhs*32}>{
paste::item!{
self.[<fix_ $rhs>]()
}
}
}
}
}
macro_rules! impl_fix_lhs_eq_rhs_not_const_generic{
(
(),
($lhs:expr,$rhs:expr)
)=>{
impl Fixed<$lhs,{$lhs*32}>
{
paste::item!{
#[inline]
pub fn [<fix_ $rhs>](self)->Fixed<$rhs,{$rhs*32}>{
self
}
}
}
impl Fix<Fixed<$rhs,{$rhs*32}>> for Fixed<$lhs,{$lhs*32}>{
fn fix(self)->Fixed<$rhs,{$rhs*32}>{
paste::item!{
self.[<fix_ $rhs>]()
}
}
}
}
}
// I LOVE NOT BEING ABLE TO USE CONST GENERICS
macro_repeated!(
impl_fix_rhs_lt_lhs_not_const_generic,(),
(2,1),(3,1),(4,1),(5,1),(6,1),(7,1),(8,1),(9,1),(10,1),(11,1),(12,1),(13,1),(14,1),(15,1),(16,1),(17,1),
(3,2),(4,2),(5,2),(6,2),(7,2),(8,2),(9,2),(10,2),(11,2),(12,2),(13,2),(14,2),(15,2),(16,2),
(4,3),(5,3),(6,3),(7,3),(8,3),(9,3),(10,3),(11,3),(12,3),(13,3),(14,3),(15,3),(16,3),
(5,4),(6,4),(7,4),(8,4),(9,4),(10,4),(11,4),(12,4),(13,4),(14,4),(15,4),(16,4),
(6,5),(7,5),(8,5),(9,5),(10,5),(11,5),(12,5),(13,5),(14,5),(15,5),(16,5),
(7,6),(8,6),(9,6),(10,6),(11,6),(12,6),(13,6),(14,6),(15,6),(16,6),
(8,7),(9,7),(10,7),(11,7),(12,7),(13,7),(14,7),(15,7),(16,7),
(9,8),(10,8),(11,8),(12,8),(13,8),(14,8),(15,8),(16,8),
(10,9),(11,9),(12,9),(13,9),(14,9),(15,9),(16,9),
(11,10),(12,10),(13,10),(14,10),(15,10),(16,10),
(12,11),(13,11),(14,11),(15,11),(16,11),
(13,12),(14,12),(15,12),(16,12),
(14,13),(15,13),(16,13),
(15,14),(16,14),
(16,15)
);
macro_repeated!(
impl_fix_lhs_lt_rhs_not_const_generic,(),
(1,2),
(1,3),(2,3),
(1,4),(2,4),(3,4),
(1,5),(2,5),(3,5),(4,5),
(1,6),(2,6),(3,6),(4,6),(5,6),
(1,7),(2,7),(3,7),(4,7),(5,7),(6,7),
(1,8),(2,8),(3,8),(4,8),(5,8),(6,8),(7,8),
(1,9),(2,9),(3,9),(4,9),(5,9),(6,9),(7,9),(8,9),
(1,10),(2,10),(3,10),(4,10),(5,10),(6,10),(7,10),(8,10),(9,10),
(1,11),(2,11),(3,11),(4,11),(5,11),(6,11),(7,11),(8,11),(9,11),(10,11),
(1,12),(2,12),(3,12),(4,12),(5,12),(6,12),(7,12),(8,12),(9,12),(10,12),(11,12),
(1,13),(2,13),(3,13),(4,13),(5,13),(6,13),(7,13),(8,13),(9,13),(10,13),(11,13),(12,13),
(1,14),(2,14),(3,14),(4,14),(5,14),(6,14),(7,14),(8,14),(9,14),(10,14),(11,14),(12,14),(13,14),
(1,15),(2,15),(3,15),(4,15),(5,15),(6,15),(7,15),(8,15),(9,15),(10,15),(11,15),(12,15),(13,15),(14,15),
(1,16),(2,16),(3,16),(4,16),(5,16),(6,16),(7,16),(8,16),(9,16),(10,16),(11,16),(12,16),(13,16),(14,16),(15,16)
);
macro_repeated!(
impl_fix_lhs_eq_rhs_not_const_generic,(),
(1,1),(2,2),(3,3),(4,4),(5,5),(6,6),(7,7),(8,8),(9,9),(10,10),(11,11),(12,12),(13,13),(14,14),(15,15),(16,16)
);
macro_rules! impl_not_const_generic{
($n:expr,$_2n:expr)=>{
impl Fixed<$n,{$n*32}>{
paste::item!{
#[inline]
pub fn sqrt_unchecked(self)->Self{
//1<<max_shift must be the minimum power of two which when squared is greater than self
//calculating max_shift:
//1. count "used" bits to the left of the decimal, not including the sign bit (so -1)
//2. divide by 2 via >>1 (sqrt-ish)
//3. add on fractional offset
//Voila
let used_bits=self.bits.bits() as i32-1-($n*32) as i32;
let max_shift=((used_bits>>1)+($n*32) as i32) as u32;
let mut result=Self::ZERO;
//resize self to match the wide mul output
let wide_self=self.[<fix_ $_2n>]();
//descend down the bits and check if flipping each bit would push the square over the input value
for shift in (0..=max_shift).rev(){
let new_result={
let mut bits=result.to_bits().to_bits();
bits.set_bit(shift,true);
Self::from_bits(BInt::from_bits(bits))
};
if new_result.[<wide_mul_ $n _ $n>](new_result)<=wide_self{
result=new_result;
}
}
result
}
}
#[inline]
pub fn sqrt(self)->Self{
if self<Self::ZERO{
panic!("Square root less than zero")
}else{
self.sqrt_unchecked()
}
}
#[inline]
pub fn sqrt_checked(self)->Option<Self>{
if self<Self::ZERO{
None
}else{
Some(self.sqrt_unchecked())
}
}
}
}
}
impl_not_const_generic!(1,2);
impl_not_const_generic!(2,4);
impl_not_const_generic!(3,6);
impl_not_const_generic!(4,8);
impl_not_const_generic!(5,10);
impl_not_const_generic!(6,12);
impl_not_const_generic!(7,14);
impl_not_const_generic!(8,16);

View File

@ -1,44 +0,0 @@
use bnum::BInt;
use bnum::cast::As;
use typenum::{Sum,Unsigned};
use crate::fixed::Fixed;
use fixed_wide_traits::wide::WideMul;
use std::marker::PhantomData;
macro_rules! impl_wide_mul {
($lhs: expr,$rhs: expr) => {
impl<A,B> WideMul<Fixed<$rhs,B>> for Fixed<$lhs,A>
where
A:std::ops::Add<B>,
B:Unsigned,
{
type Output=Fixed<{$lhs+$rhs},Sum<A,B>>;
fn wide_mul(self,rhs:Fixed<$rhs,B>)->Self::Output{
Fixed{
bits:self.bits.as_::<BInt<{$lhs+$rhs}>>()*rhs.bits.as_::<BInt<{$lhs+$rhs}>>(),
frac:PhantomData,
}
}
}
};
}
macro_rules! impl_wide_mul_all {
($(($x:expr, $y:expr)),*) => {
$(
impl_wide_mul!($x, $y);
)*
};
}
//const generics sidestepped wahoo
impl_wide_mul_all!(
(1,1),(2,1),(3,1),(4,1),(5,1),(6,1),(7,1),(8,1),
(1,2),(2,2),(3,2),(4,2),(5,2),(6,2),(7,2),(8,2),
(1,3),(2,3),(3,3),(4,3),(5,3),(6,3),(7,3),(8,3),
(1,4),(2,4),(3,4),(4,4),(5,4),(6,4),(7,4),(8,4),
(1,5),(2,5),(3,5),(4,5),(5,5),(6,5),(7,5),(8,5),
(1,6),(2,6),(3,6),(4,6),(5,6),(6,6),(7,6),(8,6),
(1,7),(2,7),(3,7),(4,7),(5,7),(6,7),(7,7),(8,7),
(1,8),(2,8),(3,8),(4,8),(5,8),(6,8),(7,8),(8,8)
);

View File

@ -1,11 +1,8 @@
pub mod fixed; pub mod fixed;
pub mod types; pub mod types;
pub mod typenum{ #[cfg(feature="zeroes")]
pub use typenum::Unsigned; pub mod zeroes;
}
#[cfg(feature="fixed_wide_traits")] #[cfg(test)]
mod fixed_wide_traits; mod tests;
#[cfg(feature="fixed_wide_traits")]
pub use ::fixed_wide_traits::wide;

218
fixed_wide/src/tests.rs Normal file
View File

@ -0,0 +1,218 @@
use crate::types::I32F32;
use crate::types::I256F256;
#[test]
fn you_can_add_numbers(){
let a=I256F256::from((3i128*2).pow(4));
assert_eq!(a+a,I256F256::from((3i128*2).pow(4)*2));
}
#[test]
fn to_f32(){
let a=I256F256::from(1)>>2;
let f:f32=a.into();
assert_eq!(f,0.25f32);
let f:f32=(-a).into();
assert_eq!(f,-0.25f32);
let a=I256F256::from(0);
let f:f32=(-a).into();
assert_eq!(f,0f32);
let a=I256F256::from(237946589723468975i64)<<16;
let f:f32=a.into();
assert_eq!(f,237946589723468975f32*2.0f32.powi(16));
}
#[test]
fn to_f64(){
let a=I256F256::from(1)>>2;
let f:f64=a.into();
assert_eq!(f,0.25f64);
let f:f64=(-a).into();
assert_eq!(f,-0.25f64);
let a=I256F256::from(0);
let f:f64=(-a).into();
assert_eq!(f,0f64);
let a=I256F256::from(237946589723468975i64)<<16;
let f:f64=a.into();
assert_eq!(f,237946589723468975f64*2.0f64.powi(16));
}
#[test]
fn from_f32(){
let a=I256F256::from(1)>>2;
let b:Result<I256F256,_>=0.25f32.try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(-1)>>2;
let b:Result<I256F256,_>=(-0.25f32).try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(0);
let b:Result<I256F256,_>=0.try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(0b101011110101001010101010000000000000000000000000000i64)<<16;
let b:Result<I256F256,_>=(0b101011110101001010101010000000000000000000000000000u64 as f32*2.0f32.powi(16)).try_into();
assert_eq!(b,Ok(a));
//I32F32::MAX into f32 is truncated into this value
let a=I32F32::raw(0b111111111111111111111111000000000000000000000000000000000000000i64);
let b:Result<I32F32,_>=Into::<f32>::into(I32F32::MAX).try_into();
assert_eq!(b,Ok(a));
//I32F32::MIN hits a special case since it's not representable as a positive signed integer
//TODO: don't return an overflow because this is technically possible
let a=I32F32::MIN;
let b:Result<I32F32,_>=Into::<f32>::into(I32F32::MIN).try_into();
assert_eq!(b,Err(crate::fixed::FixedFromFloatError::Overflow));
//16 is within the 24 bits of float precision
let b:Result<I32F32,_>=Into::<f32>::into(-I32F32::MIN.fix_2()).try_into();
assert_eq!(b,Err(crate::fixed::FixedFromFloatError::Overflow));
let b:Result<I32F32,_>=f32::MIN_POSITIVE.try_into();
assert_eq!(b,Err(crate::fixed::FixedFromFloatError::Underflow));
//test many cases
for i in 0..64{
let a=crate::fixed::Fixed::<2,64>::raw_digit(0b111111111111111111111111000000000000000000000000000000000000000i64)<<i;
let f:f32=a.into();
let b:Result<crate::fixed::Fixed<2,64>,_>=f.try_into();
assert_eq!(b,Ok(a));
}
}
#[test]
fn from_f64(){
let a=I256F256::from(1)>>2;
let b:Result<I256F256,_>=0.25f64.try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(-1)>>2;
let b:Result<I256F256,_>=(-0.25f64).try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(0);
let b:Result<I256F256,_>=0.try_into();
assert_eq!(b,Ok(a));
let a=I256F256::from(0b101011110101001010101010000000000000000000000000000i64)<<16;
let b:Result<I256F256,_>=(0b101011110101001010101010000000000000000000000000000u64 as f64*2.0f64.powi(16)).try_into();
assert_eq!(b,Ok(a));
}
#[test]
fn you_can_shr_numbers(){
let a=I32F32::from(4);
assert_eq!(a>>1,I32F32::from(2));
}
#[test]
fn test_wide_mul(){
let a=I32F32::ONE;
let aa=a.wide_mul_1_1(a);
assert_eq!(aa,crate::types::I64F64::ONE);
}
#[test]
fn test_wide_div(){
let a=I32F32::ONE*4;
let b=I32F32::ONE*2;
let wide_a=a.wide_mul_1_1(I32F32::ONE);
let wide_b=b.wide_mul_1_1(I32F32::ONE);
let ab=a.wide_div_1_1(b);
assert_eq!(ab,crate::types::I64F64::ONE*2);
let wab=wide_a.wide_div_2_1(b);
assert_eq!(wab,crate::fixed::Fixed::<3,96>::ONE*2);
let awb=a.wide_div_1_2(wide_b);
assert_eq!(awb,crate::fixed::Fixed::<3,96>::ONE*2);
}
#[test]
fn test_wide_mul_repeated() {
let a=I32F32::from(2);
let b=I32F32::from(3);
let w1=a.wide_mul_1_1(b);
let w2=w1.wide_mul_2_2(w1);
let w3=w2.wide_mul_4_4(w2);
assert_eq!(w3,I256F256::from((3i128*2).pow(4)));
}
#[test]
fn test_bint(){
let a=I32F32::ONE;
assert_eq!(a*2,I32F32::from(2));
}
#[test]
fn test_fix(){
assert_eq!(I32F32::ONE.fix_8(),I256F256::ONE);
assert_eq!(I32F32::ONE,I256F256::ONE.fix_1());
assert_eq!(I32F32::NEG_ONE.fix_8(),I256F256::NEG_ONE);
assert_eq!(I32F32::NEG_ONE,I256F256::NEG_ONE.fix_1());
}
#[test]
fn test_sqrt(){
let a=I32F32::ONE*4;
assert_eq!(a.sqrt(),I32F32::from(2));
}
#[test]
fn test_sqrt_zero(){
let a=I32F32::ZERO;
assert_eq!(a.sqrt(),I32F32::ZERO);
}
#[test]
fn test_sqrt_low(){
let a=I32F32::HALF;
let b=a.fixed_mul(a);
assert_eq!(b.sqrt(),a);
}
fn find_equiv_sqrt_via_f64(n:I32F32)->I32F32{
//GIMME THEM BITS BOY
let &[bits]=n.to_bits().to_bits().digits();
let ibits=bits as i64;
let f=(ibits as f64)/((1u64<<32) as f64);
let f_ans=f.sqrt();
let i=(f_ans*((1u64<<32) as f64)) as i64;
let r=I32F32::from_bits(bnum::BInt::<1>::from(i));
//mimic the behaviour of the algorithm,
//return the result if it truncates to the exact answer
if (r+I32F32::EPSILON).wide_mul_1_1(r+I32F32::EPSILON)==n.wide_mul_1_1(I32F32::ONE){
return r+I32F32::EPSILON;
}
if (r-I32F32::EPSILON).wide_mul_1_1(r-I32F32::EPSILON)==n.wide_mul_1_1(I32F32::ONE){
return r-I32F32::EPSILON;
}
return r;
}
fn test_exact(n:I32F32){
assert_eq!(n.sqrt(),find_equiv_sqrt_via_f64(n));
}
#[test]
fn test_sqrt_exact(){
//43
for i in 0..((i64::MAX as f32).ln() as u32){
let n=I32F32::from_bits(bnum::BInt::<1>::from((i as f32).exp() as i64));
test_exact(n);
}
}
#[test]
fn test_sqrt_max(){
let a=I32F32::MAX;
test_exact(a);
}
#[test]
#[cfg(all(feature="zeroes",not(feature="deferred-division")))]
fn test_zeroes_normal(){
// (x-1)*(x+1)
// x^2-1
let zeroes=I32F32::zeroes2(I32F32::NEG_ONE,I32F32::ZERO,I32F32::ONE);
assert_eq!(zeroes,arrayvec::ArrayVec::from_iter([I32F32::NEG_ONE,I32F32::ONE]));
let zeroes=I32F32::zeroes2(I32F32::NEG_ONE*3,I32F32::ONE*2,I32F32::ONE);
assert_eq!(zeroes,arrayvec::ArrayVec::from_iter([I32F32::NEG_ONE*3,I32F32::ONE]));
}
#[test]
#[cfg(all(feature="zeroes",feature="deferred-division"))]
fn test_zeroes_deferred_division(){
// (x-1)*(x+1)
// x^2-1
let zeroes=I32F32::zeroes2(I32F32::NEG_ONE,I32F32::ZERO,I32F32::ONE);
assert_eq!(
zeroes,
arrayvec::ArrayVec::from_iter([
ratio_ops::ratio::Ratio::new(I32F32::ONE*2,I32F32::NEG_ONE*2),
ratio_ops::ratio::Ratio::new(I32F32::ONE*2,I32F32::ONE*2),
])
);
}

View File

@ -1,4 +1,4 @@
pub type I32F32=crate::fixed::Fixed<1,typenum::consts::U32>; pub type I32F32=crate::fixed::Fixed<1,32>;
pub type I64F64=crate::fixed::Fixed<2,typenum::consts::U64>; pub type I64F64=crate::fixed::Fixed<2,64>;
pub type I128F128=crate::fixed::Fixed<4,typenum::consts::U128>; pub type I128F128=crate::fixed::Fixed<4,128>;
pub type I256F256=crate::fixed::Fixed<8,typenum::consts::U256>; pub type I256F256=crate::fixed::Fixed<8,256>;

53
fixed_wide/src/zeroes.rs Normal file
View File

@ -0,0 +1,53 @@
use crate::fixed::Fixed;
use arrayvec::ArrayVec;
use std::cmp::Ordering;
macro_rules! impl_zeroes{
($n:expr)=>{
impl Fixed<$n,{$n*32}>{
#[inline]
pub fn zeroes2(a0:Self,a1:Self,a2:Self)->ArrayVec<<Self as core::ops::Div>::Output,2>{
let a2pos=match a2.cmp(&Self::ZERO){
Ordering::Greater=>true,
Ordering::Equal=>return ArrayVec::from_iter(Self::zeroes1(a0,a1).into_iter()),
Ordering::Less=>false,
};
let radicand=a1*a1-a2*a0*4;
match radicand.cmp(&<Self as core::ops::Mul>::Output::ZERO){
Ordering::Greater=>{
paste::item!{
let planar_radicand=radicand.sqrt().[<fix_ $n>]();
}
//sort roots ascending and avoid taking the difference of large numbers
let zeroes=match (a2pos,Self::ZERO<a1){
(true, true )=>[(-a1-planar_radicand)/(a2*2),(a0*2)/(-a1-planar_radicand)],
(true, false)=>[(a0*2)/(-a1+planar_radicand),(-a1+planar_radicand)/(a2*2)],
(false,true )=>[(a0*2)/(-a1-planar_radicand),(-a1-planar_radicand)/(a2*2)],
(false,false)=>[(-a1+planar_radicand)/(a2*2),(a0*2)/(-a1+planar_radicand)],
};
ArrayVec::from_iter(zeroes)
},
Ordering::Equal=>ArrayVec::from_iter([(a1)/(a2*-2)]),
Ordering::Less=>ArrayVec::new_const(),
}
}
#[inline]
pub fn zeroes1(a0:Self,a1:Self)->ArrayVec<<Self as core::ops::Div>::Output,1>{
if a1==Self::ZERO{
ArrayVec::new_const()
}else{
ArrayVec::from_iter([(-a0)/(a1)])
}
}
}
};
}
impl_zeroes!(1);
impl_zeroes!(2);
impl_zeroes!(3);
impl_zeroes!(4);
//sqrt doubles twice!
//impl_zeroes!(5);
//impl_zeroes!(6);
//impl_zeroes!(7);
//impl_zeroes!(8);

View File

@ -1,63 +0,0 @@
# This file is automatically @generated by Cargo.
# It is not intended for manual editing.
version = 3
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name = "az"
version = "1.2.1"
source = "registry+https://github.com/rust-lang/crates.io-index"
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dependencies = [
"az",
"bytemuck",
"half",
"typenum",
]
[[package]]
name = "fixed_wide_traits"
version = "0.1.0"
dependencies = [
"fixed",
"typenum",
]
[[package]]
name = "half"
version = "2.4.1"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "6dd08c532ae367adf81c312a4580bc67f1d0fe8bc9c460520283f4c0ff277888"
dependencies = [
"cfg-if",
"crunchy",
]
[[package]]
name = "typenum"
version = "1.17.0"
source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "42ff0bf0c66b8238c6f3b578df37d0b7848e55df8577b3f74f92a69acceeb825"

View File

@ -1,10 +0,0 @@
[package]
name = "fixed_wide_traits"
version = "0.1.0"
edition = "2021"
[dependencies]
[dev-dependencies]
fixed = "1.28.0"
typenum = "1.17.0"

View File

@ -1,2 +0,0 @@
pub mod wide;
pub mod narrow;

View File

@ -1,57 +0,0 @@
pub trait Narrow{
type Output;
fn narrow(self)->Self::Output;
}
#[derive(Debug)]
pub enum Error{
Overflow,
Underflow,
}
impl std::fmt::Display for Error{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{self:?}")
}
}
impl std::error::Error for Error{}
pub trait TryNarrow{
type Output;
fn try_narrow(self)->Result<Self::Output,Error>;
}
#[cfg(test)]
mod tests {
use super::*;
//TODO: use num_traits to do a blanket implementation (self<T::MIN as U)
impl TryNarrow for i16{
type Output=i8;
fn try_narrow(self)->Result<Self::Output,Error>{
if self<i8::MIN as i16{
return Err(Error::Underflow);
}
if (i8::MAX as i16)<self{
return Err(Error::Overflow);
}
Ok(self as i8)
}
}
#[test]
fn test_i16_i8(){
assert!(matches!(257i16.try_narrow(),Err(Error::Overflow)));
assert!(matches!(64i16.try_narrow(),Ok(64i8)));
assert!(matches!((-257i16).try_narrow(),Err(Error::Underflow)));
}
impl Narrow for fixed::FixedI16<typenum::consts::U8>{
type Output=i8;
fn narrow(self)->Self::Output{
(self.to_bits()>>8) as i8
}
}
#[test]
fn test_fixed_i16_i8(){
let a=fixed::FixedI16::<typenum::consts::U8>::from(5)/2;
assert_eq!(a.narrow(),2);
}
}

View File

@ -1,16 +0,0 @@
pub trait WideMul<Rhs=Self>{
type Output;
fn wide_mul(self,rhs:Rhs)->Self::Output;
}
pub trait WideDiv<Rhs=Self>{
type Output;
fn wide_div(self,rhs:Rhs)->Self::Output;
}
pub trait WideDot<Rhs=Self>{
type Output;
fn wide_dot(self,rhs:Rhs)->Self::Output;
}
pub trait WideCross<Rhs=Self>{
type Output;
fn wide_cross(self,rhs:Rhs)->Self::Output;
}

View File

@ -1 +0,0 @@
/target

View File

@ -1,14 +0,0 @@
[package]
name = "fixed_wide_vectors"
version = "0.1.0"
edition = "2021"
[features]
default=["fixed_wide_traits"]
fixed_wide_traits=["dep:fixed_wide_traits"]
[dependencies]
fixed_wide_traits = { version = "0.1.0", path = "../fixed_wide_traits", optional = true }
[dev-dependencies]
fixed_wide = { version = "0.1.0", path = "../fixed_wide" }

View File

@ -1,17 +0,0 @@
use std::ops::Add;
use fixed_wide_traits::wide::WideDot;
pub struct Affine<M,T>{
pub matrix:M,
pub offset:T,
}
impl<M:Copy,T:Copy> Affine<M,T>{
pub fn wide_transform<X>(&self,input:X)-><<M as WideDot<X>>::Output as Add<T>>::Output
where
M:WideDot<X>,
<M as WideDot<X>>::Output:Add<T>,
{
self.matrix.wide_dot(input)+self.offset
}
}

View File

@ -1,12 +0,0 @@
mod macros;
mod vector;
#[cfg(feature="fixed_wide_traits")]
pub mod affine;
pub use vector::Vector2;
pub use vector::Vector3;
pub use vector::Vector4;
#[cfg(test)]
mod tests;

View File

@ -1,281 +0,0 @@
#[cfg(feature="fixed_wide_traits")]
pub mod wide;
// Stolen from https://github.com/c1m50c/fixed-vectors (MIT license)
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector {
( $struct: ident { $($field: ident), + }, ( $($generic: ident), + ), $size: expr ) => {
impl<T> $struct<T> {
/// Constructs a new vector with the specified values for each field.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let vec2 = Vector2::new(0, 0);
///
/// assert_eq!(vec2.x, 0);
/// assert_eq!(vec2.y, 0);
/// ```
#[inline(always)]
pub const fn new( $($field: T), + ) -> Self {
Self {
$( $field ), +
}
}
/// Consumes the vector and returns its values as an array.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let vec2 = Vector2::new(0, 0);
/// let array = vec2.to_array();
///
/// assert_eq!(array, [0, 0]);
/// ```
#[inline(always)]
pub fn to_array(self) -> [T; $size] {
[ $(self.$field), + ]
}
/// Consumes the vector and returns its values as a tuple.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let vec2 = Vector2::new(0, 0);
/// let tuple = vec2.to_tuple();
///
/// assert_eq!(tuple, (0, 0));
/// ```
#[inline(always)]
pub fn to_tuple(self) -> ( $($generic), + ) {
( $(self.$field), + )
}
/// Consumes the vector and returns a new vector with the given function applied on each field.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let vec2 = Vector2::new(1, 2)
/// .map(|i| i * 2);
///
/// assert_eq!(vec2, Vector2::new(2, 4));
/// ```
#[inline]
pub fn map<F, U>(self, f: F) -> $struct<U>
where
F: Fn(T) -> U
{
$struct {
$( $field: f(self.$field) ), +
}
}
}
impl<T: Copy> $struct<T> {
/// Constructs a vector using the given `value` as the value for all of its fields.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let vec2 = Vector2::from_value(0);
///
/// assert_eq!(vec2, Vector2::new(0, 0));
/// ```
#[inline(always)]
pub const fn from_value(value: T) -> Self {
Self {
$( $field: value ), +
}
}
}
impl<T> From<[T; $size]> for $struct<T> {
fn from(from: [T; $size]) -> Self {
let mut iterator = from.into_iter();
Self {
// SAFETY: We know the size of `from` so `iterator.next()` is always `Some(..)`
$( $field: unsafe { iterator.next().unwrap_unchecked() } ), +
}
}
}
impl<T> From<($($generic), +)> for $struct<T> {
fn from(from: ($($generic), +)) -> Self {
let ( $($field), + ) = from;
Self {
$( $field ), +
}
}
}
impl<T: core::fmt::Debug> core::fmt::Debug for $struct<T> {
fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result {
let identifier = core::stringify!($struct);
f.debug_struct(identifier)
$( .field( core::stringify!($field), &self.$field ) ) +
.finish()
}
}
impl<T: PartialEq> PartialEq for $struct<T> {
fn eq(&self, other: &Self) -> bool {
$( self.$field == other.$field ) && +
}
}
impl<T: Eq> Eq for $struct<T> { }
impl<T: core::hash::Hash> core::hash::Hash for $struct<T> {
fn hash<H: core::hash::Hasher>(&self, state: &mut H) {
$( self.$field.hash(state); ) +
}
}
impl<T: Clone> Clone for $struct<T> {
fn clone(&self) -> Self {
Self {
$( $field: self.$field.clone() ), +
}
}
}
impl<T: Copy> Copy for $struct<T> { }
impl<T: Default> Default for $struct<T> {
fn default() -> Self {
Self {
$( $field: T::default() ), +
}
}
}
impl<T: Ord> $struct<T> {
pub fn min(self, rhs: Self) -> $struct<T> {
$struct{
$( $field: self.$field.min(rhs.$field) ), +
}
}
pub fn max(self, rhs: Self) -> $struct<T> {
$struct{
$( $field: self.$field.max(rhs.$field) ), +
}
}
pub fn cmp(self, rhs: Self) -> $struct<core::cmp::Ordering> {
$struct{
$( $field: self.$field.cmp(&rhs.$field) ), +
}
}
pub fn lt(self, rhs: Self) -> $struct<bool> {
$struct{
$( $field: self.$field.lt(&rhs.$field) ), +
}
}
pub fn gt(self, rhs: Self) -> $struct<bool> {
$struct{
$( $field: self.$field.gt(&rhs.$field) ), +
}
}
pub fn ge(self, rhs: Self) -> $struct<bool> {
$struct{
$( $field: self.$field.ge(&rhs.$field) ), +
}
}
pub fn le(self, rhs: Self) -> $struct<bool> {
$struct{
$( $field: self.$field.le(&rhs.$field) ), +
}
}
}
impl<T: core::ops::Neg<Output = T>> core::ops::Neg for $struct<T> {
type Output = Self;
fn neg(self) -> Self::Output {
Self {
$( $field: -self.$field ), +
}
}
}
// Impl arithmetic pperators
$crate::impl_operator!( $struct { $($field), + }, AddAssign, add_assign );
$crate::impl_operator!( $struct { $($field), + }, Add, add, Self );
$crate::impl_operator!( $struct { $($field), + }, SubAssign, sub_assign );
$crate::impl_operator!( $struct { $($field), + }, Sub, sub, Self );
$crate::impl_operator!( $struct { $($field), + }, MulAssign, mul_assign );
$crate::impl_operator!( $struct { $($field), + }, Mul, mul, Self );
$crate::impl_operator!( $struct { $($field), + }, DivAssign, div_assign );
$crate::impl_operator!( $struct { $($field), + }, Div, div, Self );
$crate::impl_operator!( $struct { $($field), + }, RemAssign, rem_assign );
$crate::impl_operator!( $struct { $($field), + }, Rem, rem, Self );
// Impl bitwise operators
$crate::impl_operator!( $struct { $($field), + }, BitAndAssign, bitand_assign );
$crate::impl_operator!( $struct { $($field), + }, BitAnd, bitand, Self );
$crate::impl_operator!( $struct { $($field), + }, BitOrAssign, bitor_assign );
$crate::impl_operator!( $struct { $($field), + }, BitOr, bitor, Self );
$crate::impl_operator!( $struct { $($field), + }, BitXorAssign, bitxor_assign );
$crate::impl_operator!( $struct { $($field), + }, BitXor, bitxor, Self );
// Impl floating-point based methods
$crate::impl_wide_operations!( $struct { $($field), + }, $size );
};
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_operator {
( $struct: ident { $($field: ident), + }, $trait: ident, $method: ident, $output: ty ) => {
impl<T: core::ops::$trait<Output = T>> core::ops::$trait<Self> for $struct<T> {
type Output = $output;
fn $method(self, other: Self) -> Self::Output {
Self {
$( $field: self.$field.$method(other.$field) ), +
}
}
}
impl<T: core::ops::$trait<Output = T> + Copy> core::ops::$trait<T> for $struct<T> {
type Output = $output;
fn $method(self, other: T) -> Self::Output {
Self {
$( $field: self.$field.$method(other) ), +
}
}
}
};
( $struct: ident { $($field: ident), + }, $trait: ident, $method: ident ) => {
impl<T: core::ops::$trait> core::ops::$trait for $struct<T> {
fn $method(&mut self, other: Self) {
$( self.$field.$method(other.$field) ); +
}
}
impl<T: core::ops::$trait + Copy> core::ops::$trait<T> for $struct<T> {
fn $method(&mut self, other: T) {
$( self.$field.$method(other) ); +
}
}
};
}

View File

@ -1,43 +0,0 @@
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_wide_operations {
( $struct: ident { $($field: ident), + }, $size: expr ) => {
impl<U,T:Copy+fixed_wide_traits::wide::WideMul<Output=U>> fixed_wide_traits::wide::WideMul for $struct<T> {
type Output=$struct<U>;
#[inline]
fn wide_mul(self, rhs: Self) -> Self::Output {
$struct{
$( $field: self.$field.wide_mul(rhs.$field) ), +
}
}
}
impl<U:std::ops::Add<Output=U>,T:Copy+fixed_wide_traits::wide::WideMul<Output=U>> $struct<T> {
#[inline]
pub fn wide_dot(self, other: Self) -> U {
$crate::sum_repeating!(
$( + (self.$field.wide_mul(other.$field)) ) +
)
}
pub fn wide_length_squared(&self) -> U {
let squared = $struct {
$( $field: self.$field.wide_mul(self.$field) ), +
};
$crate::sum_repeating!(
$( + squared.$field ) +
)
}
}
};
}
// HACK: Allows us to sum repeating tokens in macros.
// See: https://stackoverflow.com/a/60187870/17452730
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! sum_repeating {
( + $($item: tt) * ) => {
$($item) *
};
}

View File

@ -1,62 +0,0 @@
use fixed_wide_traits::wide::WideMul;
use crate::Vector3;
type Planar64=fixed_wide::types::I32F32;
//type Planar64Wide1=fixed::types::I64F64;
//type Planar64Wide2=fixed_wide::types::I128F128;
type Planar64Wide3=fixed_wide::types::I256F256;
#[test]
fn wide_int64() {
let a=Planar64::from(2);
let b=Planar64::from(3);
let w1=a.wide_mul(b);
let w2=w1.wide_mul(w1);
let w3=w2.wide_mul(w2);
assert_eq!(w3,Planar64Wide3::from((3i128*2).pow(4)));
}
#[test]
fn you_can_add_numbers(){
let a=Planar64Wide3::from((3i128*2).pow(4));
assert_eq!(a+a,Planar64Wide3::from((3i128*2).pow(4)*2))
}
#[test]
fn you_can_shr_numbers(){
let a=Planar64::from(4);
assert_eq!(a>>1,Planar64::from(2))
}
#[test]
fn wide_vec3(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v.wide_mul(v);
let v2=v1.wide_mul(v1);
let v3=v2.wide_mul(v2);
assert_eq!(v3,Vector3::from_value(Planar64Wide3::from(3i128.pow(8))));
}
#[test]
fn wide_vec3_dot(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v.wide_mul(v);
let v2=v1.wide_mul(v1);
let v3=v2.wide_dot(v2);
assert_eq!(v3,Planar64Wide3::from(3i128.pow(8)*3));
}
#[test]
fn wide_vec3_length_squared(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v.wide_mul(v);
let v2=v1.wide_mul(v1);
let v3=v2.wide_length_squared();
assert_eq!(v3,Planar64Wide3::from(3i128.pow(8)*3));
}

View File

@ -1,68 +0,0 @@
// Stolen from https://github.com/c1m50c/fixed-vectors (MIT license)
/// Vector for holding two-dimensional values.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector2;
///
/// let mut vec2 = Vector2::new(1, 2);
/// vec2 += Vector2::new(1, 2);
///
/// assert_eq!(vec2.x, 2);
/// assert_eq!(vec2.y, 4);
/// ```
pub struct Vector2<T> {
pub x: T,
pub y: T,
}
/// Vector for holding three-dimensional values.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector3;
///
/// let mut vec3 = Vector3::new(1, 2, 3);
/// vec3 += Vector3::new(1, 2, 3);
///
/// assert_eq!(vec3.x, 2);
/// assert_eq!(vec3.y, 4);
/// assert_eq!(vec3.z, 6);
/// ```
pub struct Vector3<T> {
pub x: T,
pub y: T,
pub z: T,
}
/// Vector for holding four-dimensional values.
///
/// # Example
///
/// ```
/// use fixed_wide_vectors::Vector4;
///
/// let mut vec4 = Vector4::new(1, 2, 3, 4);
/// vec4 += Vector4::new(1, 2, 3, 4);
///
/// assert_eq!(vec4.x, 2);
/// assert_eq!(vec4.y, 4);
/// assert_eq!(vec4.z, 6);
/// assert_eq!(vec4.w, 8);
/// ```
pub struct Vector4<T> {
pub x: T,
pub y: T,
pub z: T,
pub w: T,
}
crate::impl_vector!(Vector2 { x, y }, (T, T), 2);
crate::impl_vector!(Vector3 { x, y, z }, (T, T, T), 3);
crate::impl_vector!(Vector4 { x, y, z, w }, (T, T, T, T), 4);

View File

@ -4,33 +4,33 @@ version = 3
[[package]] [[package]]
name = "bnum" name = "bnum"
version = "0.11.0" version = "0.12.0"
source = "registry+https://github.com/rust-lang/crates.io-index" source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "3e31ea183f6ee62ac8b8a8cf7feddd766317adfb13ff469de57ce033efd6a790" checksum = "50202def95bf36cb7d1d7a7962cea1c36a3f8ad42425e5d2b71d7acb8041b5b8"
[[package]] [[package]]
name = "fixed_wide" name = "fixed_wide"
version = "0.1.0" version = "0.1.1"
dependencies = [ dependencies = [
"bnum", "bnum",
"fixed_wide_traits", "paste",
"typenum",
] ]
[[package]] [[package]]
name = "fixed_wide_traits" name = "linear_ops"
version = "0.1.0"
[[package]]
name = "fixed_wide_vectors"
version = "0.1.0" version = "0.1.0"
dependencies = [ dependencies = [
"fixed_wide", "fixed_wide",
"fixed_wide_traits", "paste",
"ratio_ops",
] ]
[[package]] [[package]]
name = "typenum" name = "paste"
version = "1.17.0" version = "1.0.15"
source = "registry+https://github.com/rust-lang/crates.io-index" source = "registry+https://github.com/rust-lang/crates.io-index"
checksum = "42ff0bf0c66b8238c6f3b578df37d0b7848e55df8577b3f74f92a69acceeb825" checksum = "57c0d7b74b563b49d38dae00a0c37d4d6de9b432382b2892f0574ddcae73fd0a"
[[package]]
name = "ratio_ops"
version = "0.1.0"

22
linear_ops/Cargo.toml Normal file
View File

@ -0,0 +1,22 @@
[package]
name = "linear_ops"
version = "0.1.0"
edition = "2021"
repository = "https://git.itzana.me/StrafesNET/fixed_wide_vectors"
license = "MIT OR Apache-2.0"
description = "Vector/Matrix operations using trait bounds."
authors = ["Rhys Lloyd <krakow20@gmail.com>"]
[features]
default=["named-fields","fixed-wide"]
named-fields=[]
fixed-wide=["dep:fixed_wide","dep:paste"]
deferred-division=["dep:ratio_ops"]
[dependencies]
ratio_ops = { version = "0.1.0", path = "../ratio_ops", registry = "strafesnet", optional = true }
fixed_wide = { version = "0.1.0", path = "../fixed_wide", registry = "strafesnet", optional = true }
paste = { version = "1.0.15", optional = true }
[dev-dependencies]
fixed_wide = { version = "0.1.0", path = "../fixed_wide", registry = "strafesnet", features = ["wide-mul"] }

176
linear_ops/LICENSE-APACHE Normal file
View File

@ -0,0 +1,176 @@
Apache License
Version 2.0, January 2004
http://www.apache.org/licenses/
TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
1. Definitions.
"License" shall mean the terms and conditions for use, reproduction,
and distribution as defined by Sections 1 through 9 of this document.
"Licensor" shall mean the copyright owner or entity authorized by
the copyright owner that is granting the License.
"Legal Entity" shall mean the union of the acting entity and all
other entities that control, are controlled by, or are under common
control with that entity. For the purposes of this definition,
"control" means (i) the power, direct or indirect, to cause the
direction or management of such entity, whether by contract or
otherwise, or (ii) ownership of fifty percent (50%) or more of the
outstanding shares, or (iii) beneficial ownership of such entity.
"You" (or "Your") shall mean an individual or Legal Entity
exercising permissions granted by this License.
"Source" form shall mean the preferred form for making modifications,
including but not limited to software source code, documentation
source, and configuration files.
"Object" form shall mean any form resulting from mechanical
transformation or translation of a Source form, including but
not limited to compiled object code, generated documentation,
and conversions to other media types.
"Work" shall mean the work of authorship, whether in Source or
Object form, made available under the License, as indicated by a
copyright notice that is included in or attached to the work
(an example is provided in the Appendix below).
"Derivative Works" shall mean any work, whether in Source or Object
form, that is based on (or derived from) the Work and for which the
editorial revisions, annotations, elaborations, or other modifications
represent, as a whole, an original work of authorship. For the purposes
of this License, Derivative Works shall not include works that remain
separable from, or merely link (or bind by name) to the interfaces of,
the Work and Derivative Works thereof.
"Contribution" shall mean any work of authorship, including
the original version of the Work and any modifications or additions
to that Work or Derivative Works thereof, that is intentionally
submitted to Licensor for inclusion in the Work by the copyright owner
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risks associated with Your exercise of permissions under this License.
8. Limitation of Liability. In no event and under no legal theory,
whether in tort (including negligence), contract, or otherwise,
unless required by applicable law (such as deliberate and grossly
negligent acts) or agreed to in writing, shall any Contributor be
liable to You for damages, including any direct, indirect, special,
incidental, or consequential damages of any character arising as a
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work stoppage, computer failure or malfunction, or any and all
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9. Accepting Warranty or Additional Liability. While redistributing
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END OF TERMS AND CONDITIONS

23
linear_ops/LICENSE-MIT Normal file
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@ -0,0 +1,23 @@
Permission is hereby granted, free of charge, to any
person obtaining a copy of this software and associated
documentation files (the "Software"), to deal in the
Software without restriction, including without
limitation the rights to use, copy, modify, merge,
publish, distribute, sublicense, and/or sell copies of
the Software, and to permit persons to whom the Software
is furnished to do so, subject to the following
conditions:
The above copyright notice and this permission notice
shall be included in all copies or substantial portions
of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF
ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED
TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A
PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT
SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR
IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.

10
linear_ops/src/lib.rs Normal file
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@ -0,0 +1,10 @@
mod macros;
pub mod types;
pub mod vector;
pub mod matrix;
#[cfg(feature="named-fields")]
mod named;
#[cfg(test)]
mod tests;

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@ -0,0 +1 @@

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@ -0,0 +1,79 @@
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_fixed_wide_vector_not_const_generic {
(
(),
$n:expr
) => {
impl<const N:usize> Vector<N,fixed_wide::fixed::Fixed<$n,{$n*32}>>{
#[inline]
pub fn length(self)-><fixed_wide::fixed::Fixed::<$n,{$n*32}> as core::ops::Mul>::Output{
self.length_squared().sqrt_unchecked()
}
#[inline]
pub fn with_length<U,V>(self,length:U)-><Vector<N,V> as core::ops::Div<<fixed_wide::fixed::Fixed::<$n,{$n*32}> as core::ops::Mul>::Output>>::Output
where
fixed_wide::fixed::Fixed<$n,{$n*32}>:core::ops::Mul<U,Output=V>,
U:Copy,
V:core::ops::Div<<fixed_wide::fixed::Fixed::<$n,{$n*32}> as core::ops::Mul>::Output>,
{
self*length/self.length()
}
}
};
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! macro_4 {
( $macro: ident, $any:tt ) => {
$crate::macro_repeated!($macro,$any,1,2,3,4);
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_fixed_wide_vector {
() => {
$crate::macro_4!(impl_fixed_wide_vector_not_const_generic,());
// I LOVE NOT BEING ABLE TO USE CONST GENERICS
$crate::macro_repeated!(
impl_fix_not_const_generic,(),
(1,1),(2,1),(3,1),(4,1),(5,1),(6,1),(7,1),(8,1),(9,1),(10,1),(11,1),(12,1),(13,1),(14,1),(15,1),(16,1),
(1,2),(2,2),(3,2),(4,2),(5,2),(6,2),(7,2),(8,2),(9,2),(10,2),(11,2),(12,2),(13,2),(14,2),(15,2),(16,2),
(1,3),(2,3),(3,3),(4,3),(5,3),(6,3),(7,3),(8,3),(9,3),(10,3),(11,3),(12,3),(13,3),(14,3),(15,3),(16,3),
(1,4),(2,4),(3,4),(4,4),(5,4),(6,4),(7,4),(8,4),(9,4),(10,4),(11,4),(12,4),(13,4),(14,4),(15,4),(16,4),
(1,5),(2,5),(3,5),(4,5),(5,5),(6,5),(7,5),(8,5),(9,5),(10,5),(11,5),(12,5),(13,5),(14,5),(15,5),(16,5),
(1,6),(2,6),(3,6),(4,6),(5,6),(6,6),(7,6),(8,6),(9,6),(10,6),(11,6),(12,6),(13,6),(14,6),(15,6),(16,6),
(1,7),(2,7),(3,7),(4,7),(5,7),(6,7),(7,7),(8,7),(9,7),(10,7),(11,7),(12,7),(13,7),(14,7),(15,7),(16,7),
(1,8),(2,8),(3,8),(4,8),(5,8),(6,8),(7,8),(8,8),(9,8),(10,8),(11,8),(12,8),(13,8),(14,8),(15,8),(16,8),
(1,9),(2,9),(3,9),(4,9),(5,9),(6,9),(7,9),(8,9),(9,9),(10,9),(11,9),(12,9),(13,9),(14,9),(15,9),(16,9),
(1,10),(2,10),(3,10),(4,10),(5,10),(6,10),(7,10),(8,10),(9,10),(10,10),(11,10),(12,10),(13,10),(14,10),(15,10),(16,10),
(1,11),(2,11),(3,11),(4,11),(5,11),(6,11),(7,11),(8,11),(9,11),(10,11),(11,11),(12,11),(13,11),(14,11),(15,11),(16,11),
(1,12),(2,12),(3,12),(4,12),(5,12),(6,12),(7,12),(8,12),(9,12),(10,12),(11,12),(12,12),(13,12),(14,12),(15,12),(16,12),
(1,13),(2,13),(3,13),(4,13),(5,13),(6,13),(7,13),(8,13),(9,13),(10,13),(11,13),(12,13),(13,13),(14,13),(15,13),(16,13),
(1,14),(2,14),(3,14),(4,14),(5,14),(6,14),(7,14),(8,14),(9,14),(10,14),(11,14),(12,14),(13,14),(14,14),(15,14),(16,14),
(1,15),(2,15),(3,15),(4,15),(5,15),(6,15),(7,15),(8,15),(9,15),(10,15),(11,15),(12,15),(13,15),(14,15),(15,15),(16,15),
(1,16),(2,16),(3,16),(4,16),(5,16),(6,16),(7,16),(8,16),(9,16),(10,16),(11,16),(12,16),(13,16),(14,16),(15,16),(16,16)
);
};
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_fix_not_const_generic{
(
(),
($lhs:expr,$rhs:expr)
)=>{
impl<const N:usize> Vector<N,fixed_wide::fixed::Fixed<$lhs,{$lhs*32}>>
{
paste::item!{
#[inline]
pub fn [<fix_ $rhs>](self)->Vector<N,fixed_wide::fixed::Fixed<$rhs,{$rhs*32}>>{
self.map(|t|t.[<fix_ $rhs>]())
}
}
}
}
}

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@ -0,0 +1,272 @@
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix {
() => {
impl<const X:usize,const Y:usize,T> Matrix<X,Y,T>{
#[inline(always)]
pub const fn new(array:[[T;Y];X])->Self{
Self{array}
}
#[inline(always)]
pub fn to_array(self)->[[T;Y];X]{
self.array
}
#[inline]
pub fn from_cols(cols:[Vector<Y,T>;X])->Self
{
Matrix::new(
cols.map(|col|col.array),
)
}
#[inline]
pub fn map<F,U>(self,f:F)->Matrix<X,Y,U>
where
F:Fn(T)->U
{
Matrix::new(
self.array.map(|inner|inner.map(&f)),
)
}
#[inline]
pub fn transpose(self)->Matrix<Y,X,T>{
//how did I think of this
let mut array_of_iterators=self.array.map(|axis|axis.into_iter());
Matrix::new(
core::array::from_fn(|_|
array_of_iterators.each_mut().map(|iter|
iter.next().unwrap()
)
)
)
}
#[inline]
// old (list of rows) MatY<VecX>.MatX<VecZ> = MatY<VecZ>
// new (list of columns) MatX<VecY>.MatZ<VecX> = MatZ<VecY>
pub fn dot<const Z:usize,U,V>(self,rhs:Matrix<Z,X,U>)->Matrix<Z,Y,V>
where
T:core::ops::Mul<U,Output=V>+Copy,
V:core::iter::Sum,
U:Copy,
{
let mut array_of_iterators=self.array.map(|axis|axis.into_iter().cycle());
Matrix{
array:rhs.array.map(|rhs_axis|
core::array::from_fn(|_|
array_of_iterators
.iter_mut()
.zip(rhs_axis.iter())
.map(|(lhs_iter,&rhs_value)|
lhs_iter.next().unwrap()*rhs_value
).sum()
)
)
}
}
#[inline]
// MatX<VecY>.VecY = VecX
pub fn transform_vector<U,V>(self,rhs:Vector<X,U>)->Vector<Y,V>
where
T:core::ops::Mul<U,Output=V>,
V:core::iter::Sum,
U:Copy,
{
let mut array_of_iterators=self.array.map(|axis|axis.into_iter());
Vector::new(
core::array::from_fn(|_|
array_of_iterators
.iter_mut()
.zip(rhs.array.iter())
.map(|(lhs_iter,&rhs_value)|
lhs_iter.next().unwrap()*rhs_value
).sum()
)
)
}
}
impl<const X:usize,const Y:usize,T> Matrix<X,Y,T>
where
T:Copy
{
#[inline(always)]
pub const fn from_value(value:T)->Self{
Self::new([[value;Y];X])
}
}
impl<const X:usize,const Y:usize,T:Default> Default for Matrix<X,Y,T>{
#[inline]
fn default()->Self{
Self::new(
core::array::from_fn(|_|core::array::from_fn(|_|Default::default()))
)
}
}
impl<const X:usize,const Y:usize,T:core::fmt::Display> core::fmt::Display for Matrix<X,Y,T>{
#[inline]
fn fmt(&self,f:&mut core::fmt::Formatter)->Result<(),core::fmt::Error>{
for col in &self.array[0..X]{
core::write!(f,"\n")?;
for elem in &col[0..Y-1]{
core::write!(f,"{}, ",elem)?;
}
// assume we will be using matrices of size 1x1 or greater
core::write!(f,"{}",col.last().unwrap())?;
}
Ok(())
}
}
impl<const X:usize,const Y:usize,const Z:usize,T,U,V> core::ops::Mul<Matrix<Z,X,U>> for Matrix<X,Y,T>
where
T:core::ops::Mul<U,Output=V>+Copy,
V:core::iter::Sum,
U:Copy,
{
type Output=Matrix<Z,Y,V>;
#[inline]
fn mul(self,rhs:Matrix<Z,X,U>)->Self::Output{
self.dot(rhs)
}
}
impl<const X:usize,const Y:usize,T,U,V> core::ops::Mul<Vector<X,U>> for Matrix<X,Y,T>
where
T:core::ops::Mul<U,Output=V>,
V:core::iter::Sum,
U:Copy,
{
type Output=Vector<Y,V>;
#[inline]
fn mul(self,rhs:Vector<X,U>)->Self::Output{
self.transform_vector(rhs)
}
}
#[cfg(feature="deferred-division")]
$crate::impl_matrix_deferred_division!();
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_deferred_division {
() => {
impl<const X:usize,const Y:usize,T:ratio_ops::ratio::Divide<U,Output=V>,U:Copy,V> ratio_ops::ratio::Divide<U> for Matrix<X,Y,T>{
type Output=Matrix<X,Y,V>;
#[inline]
fn divide(self,rhs:U)->Self::Output{
self.map(|t|t.divide(rhs))
}
}
impl<const X:usize,const Y:usize,T,U> core::ops::Div<U> for Matrix<X,Y,T>{
type Output=ratio_ops::ratio::Ratio<Matrix<X,Y,T>,U>;
#[inline]
fn div(self,rhs:U)->Self::Output{
ratio_ops::ratio::Ratio::new(self,rhs)
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_extend {
( $x: expr, $y: expr ) => {
impl<T> Matrix<$x,$y,T>{
#[inline]
pub fn extend_column(self,value:Vector<$y,T>)->Matrix<{$x+1},$y,T>{
let mut iter=self.array.into_iter().chain(core::iter::once(value.array));
Matrix::new(
core::array::from_fn(|_|iter.next().unwrap()),
)
}
#[inline]
pub fn extend_row(self,value:Vector<$x,T>)->Matrix<$x,{$y+1},T>{
let mut iter_rows=value.array.into_iter();
Matrix::new(
self.array.map(|axis|{
let mut elements_iter=axis.into_iter().chain(core::iter::once(iter_rows.next().unwrap()));
core::array::from_fn(|_|elements_iter.next().unwrap())
})
)
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_named_fields_shape {
(
($struct_outer:ident, $size_outer: expr),
($size_inner: expr)
) => {
impl<T> core::ops::Deref for Matrix<$size_outer,$size_inner,T>{
type Target=$struct_outer<Vector<$size_inner,T>>;
#[inline]
fn deref(&self)->&Self::Target{
unsafe{core::mem::transmute(&self.array)}
}
}
impl<T> core::ops::DerefMut for Matrix<$size_outer,$size_inner,T>{
#[inline]
fn deref_mut(&mut self)->&mut Self::Target{
unsafe{core::mem::transmute(&mut self.array)}
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_named_fields_shape_shim {
(
($($vector_info:tt),+),
$matrix_info:tt
) => {
$crate::macro_repeated!(impl_matrix_named_fields_shape,$matrix_info,$($vector_info),+);
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_named_fields {
(
($($matrix_info:tt),+),
$vector_infos:tt
) => {
$crate::macro_repeated!(impl_matrix_named_fields_shape_shim,$vector_infos,$($matrix_info),+);
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_matrix_3x3 {
()=>{
impl<T,T2,T3> Matrix<3,3,T>
where
//cross
T:core::ops::Mul<T,Output=T2>+Copy,
T2:core::ops::Sub,
//dot
T:core::ops::Mul<<T2 as core::ops::Sub>::Output,Output=T3>,
T3:core::iter::Sum,
{
pub fn det(self)->T3{
self.x_axis.dot(self.y_axis.cross(self.z_axis))
}
}
impl<T,T2> Matrix<3,3,T>
where
T:core::ops::Mul<T,Output=T2>+Copy,
T2:core::ops::Sub,
{
pub fn adjugate(self)->Matrix<3,3,<T2 as core::ops::Sub>::Output>{
Matrix::new([
[self.y_axis.y*self.z_axis.z-self.y_axis.z*self.z_axis.y,self.x_axis.z*self.z_axis.y-self.x_axis.y*self.z_axis.z,self.x_axis.y*self.y_axis.z-self.x_axis.z*self.y_axis.y],
[self.y_axis.z*self.z_axis.x-self.y_axis.x*self.z_axis.z,self.x_axis.x*self.z_axis.z-self.x_axis.z*self.z_axis.x,self.x_axis.z*self.y_axis.x-self.x_axis.x*self.y_axis.z],
[self.y_axis.x*self.z_axis.y-self.y_axis.y*self.z_axis.x,self.x_axis.y*self.z_axis.x-self.x_axis.x*self.z_axis.y,self.x_axis.x*self.y_axis.y-self.x_axis.y*self.y_axis.x],
])
}
}
}
}

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@ -0,0 +1,20 @@
pub mod common;
pub mod vector;
pub mod matrix;
#[cfg(feature="fixed-wide")]
pub mod fixed_wide;
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! macro_repeated{
(
$macro:ident,
$any:tt,
$($repeated:tt),*
)=>{
$(
$crate::$macro!($any, $repeated);
)*
};
}

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@ -0,0 +1,357 @@
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector {
() => {
impl<const N:usize,T> Vector<N,T>{
#[inline(always)]
pub const fn new(array:[T;N])->Self{
Self{array}
}
#[inline(always)]
pub fn to_array(self)->[T;N]{
self.array
}
#[inline]
pub fn map<F,U>(self,f:F)->Vector<N,U>
where
F:Fn(T)->U
{
Vector::new(
self.array.map(f)
)
}
#[inline]
pub fn map_zip<F,U,V>(self,other:Vector<N,U>,f:F)->Vector<N,V>
where
F:Fn((T,U))->V,
{
let mut iter=self.array.into_iter().zip(other.array);
Vector::new(
core::array::from_fn(|_|f(iter.next().unwrap())),
)
}
}
impl<const N:usize,T:Copy> Vector<N,T>{
#[inline(always)]
pub const fn from_value(value:T)->Self{
Self::new([value;N])
}
}
impl<const N:usize,T:Default> Default for Vector<N,T>{
#[inline]
fn default()->Self{
Self::new(
core::array::from_fn(|_|Default::default())
)
}
}
impl<const N:usize,T:core::fmt::Display> core::fmt::Display for Vector<N,T>{
#[inline]
fn fmt(&self,f:&mut core::fmt::Formatter)->Result<(),core::fmt::Error>{
for elem in &self.array[0..N-1]{
core::write!(f,"{}, ",elem)?;
}
// assume we will be using vectors of length 1 or greater
core::write!(f,"{}",self.array.last().unwrap())
}
}
impl<const N:usize,T:Ord> Vector<N,T>{
#[inline]
pub fn min(self,rhs:Self)->Self{
self.map_zip(rhs,|(a,b)|a.min(b))
}
#[inline]
pub fn max(self,rhs:Self)->Self{
self.map_zip(rhs,|(a,b)|a.max(b))
}
#[inline]
pub fn cmp(self,rhs:Self)->Vector<N,core::cmp::Ordering>{
self.map_zip(rhs,|(a,b)|a.cmp(&b))
}
#[inline]
pub fn lt(self,rhs:Self)->Vector<N,bool>{
self.map_zip(rhs,|(a,b)|a.lt(&b))
}
#[inline]
pub fn gt(self,rhs:Self)->Vector<N,bool>{
self.map_zip(rhs,|(a,b)|a.gt(&b))
}
#[inline]
pub fn ge(self,rhs:Self)->Vector<N,bool>{
self.map_zip(rhs,|(a,b)|a.ge(&b))
}
#[inline]
pub fn le(self,rhs:Self)->Vector<N,bool>{
self.map_zip(rhs,|(a,b)|a.le(&b))
}
}
impl<const N:usize> Vector<N,bool>{
#[inline]
pub fn all(&self)->bool{
self.array==[true;N]
}
#[inline]
pub fn any(&self)->bool{
self.array!=[false;N]
}
}
impl<const N:usize,T:core::ops::Neg<Output=V>,V> core::ops::Neg for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn neg(self)->Self::Output{
Vector::new(
self.array.map(|t|-t)
)
}
}
impl<const N:usize,T> Vector<N,T>
{
#[inline]
pub fn dot<U,V>(self,rhs:Vector<N,U>)->V
where
T:core::ops::Mul<U,Output=V>,
V:core::iter::Sum,
{
self.array.into_iter().zip(rhs.array).map(|(a,b)|a*b).sum()
}
}
impl<const N:usize,T,V> Vector<N,T>
where
T:core::ops::Mul<Output=V>+Copy,
V:core::iter::Sum,
{
#[inline]
pub fn length_squared(self)->V{
self.array.into_iter().map(|t|t*t).sum()
}
}
// Impl arithmetic operators
$crate::impl_vector_assign_operator!(AddAssign, add_assign );
$crate::impl_vector_operator!(Add, add );
$crate::impl_vector_assign_operator!(SubAssign, sub_assign );
$crate::impl_vector_operator!(Sub, sub );
$crate::impl_vector_assign_operator!(RemAssign, rem_assign );
$crate::impl_vector_operator!(Rem, rem );
// mul and div are special, usually you multiply by a scalar
// and implementing both vec*vec and vec*scalar is conflicting implementations Q_Q
$crate::impl_vector_assign_operator_scalar!(MulAssign, mul_assign );
$crate::impl_vector_operator_scalar!(Mul, mul );
$crate::impl_vector_assign_operator_scalar!(DivAssign, div_assign );
#[cfg(not(feature="deferred-division"))]
$crate::impl_vector_operator_scalar!(Div, div );
#[cfg(feature="deferred-division")]
$crate::impl_vector_deferred_division!();
// Impl bitwise operators
$crate::impl_vector_assign_operator!(BitAndAssign, bitand_assign );
$crate::impl_vector_operator!(BitAnd, bitand );
$crate::impl_vector_assign_operator!(BitOrAssign, bitor_assign );
$crate::impl_vector_operator!(BitOr, bitor );
$crate::impl_vector_assign_operator!(BitXorAssign, bitxor_assign );
$crate::impl_vector_operator!(BitXor, bitxor );
// Impl shift operators
$crate::impl_vector_shift_assign_operator!(ShlAssign, shl_assign);
$crate::impl_vector_shift_operator!(Shl, shl);
$crate::impl_vector_shift_assign_operator!(ShrAssign, shr_assign);
$crate::impl_vector_shift_operator!(Shr, shr);
// dedicated methods for this type
#[cfg(feature="fixed-wide")]
$crate::impl_fixed_wide_vector!();
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_deferred_division {
() => {
impl<const N:usize,T:ratio_ops::ratio::Divide<U,Output=V>,U:Copy,V> ratio_ops::ratio::Divide<U> for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn divide(self,rhs:U)->Self::Output{
self.map(|t|t.divide(rhs))
}
}
impl<const N:usize,T,U> core::ops::Div<U> for Vector<N,T>{
type Output=ratio_ops::ratio::Ratio<Vector<N,T>,U>;
#[inline]
fn div(self,rhs:U)->Self::Output{
ratio_ops::ratio::Ratio::new(self,rhs)
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_operator_scalar {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U,Output=V>,U:Copy,V> core::ops::$trait<U> for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn $method(self,rhs:U)->Self::Output{
self.map(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_operator {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U,Output=V>,U,V> core::ops::$trait<Vector<N,U>> for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn $method(self,rhs:Vector<N,U>)->Self::Output{
self.map_zip(rhs,|(a,b)|a.$method(b))
}
}
impl<const N:usize,T:core::ops::$trait<i64,Output=T>> core::ops::$trait<i64> for Vector<N,T>{
type Output=Self;
#[inline]
fn $method(self,rhs:i64)->Self::Output{
self.map(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_assign_operator_scalar {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U>,U:Copy> core::ops::$trait<U> for Vector<N,T>{
#[inline]
fn $method(&mut self,rhs:U){
self.array.iter_mut()
.for_each(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_assign_operator {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U>,U> core::ops::$trait<Vector<N,U>> for Vector<N,T>{
#[inline]
fn $method(&mut self,rhs:Vector<N,U>){
self.array.iter_mut().zip(rhs.array)
.for_each(|(a,b)|a.$method(b))
}
}
impl<const N:usize,T:core::ops::$trait<i64>> core::ops::$trait<i64> for Vector<N,T>{
#[inline]
fn $method(&mut self,rhs:i64){
self.array.iter_mut()
.for_each(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_shift_operator {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U,Output=V>,U,V> core::ops::$trait<Vector<N,U>> for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn $method(self,rhs:Vector<N,U>)->Self::Output{
self.map_zip(rhs,|(a,b)|a.$method(b))
}
}
impl<const N:usize,T:core::ops::$trait<u32,Output=V>,V> core::ops::$trait<u32> for Vector<N,T>{
type Output=Vector<N,V>;
#[inline]
fn $method(self,rhs:u32)->Self::Output{
self.map(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_shift_assign_operator {
($trait: ident, $method: ident ) => {
impl<const N:usize,T:core::ops::$trait<U>,U> core::ops::$trait<Vector<N,U>> for Vector<N,T>{
#[inline]
fn $method(&mut self,rhs:Vector<N,U>){
self.array.iter_mut().zip(rhs.array)
.for_each(|(a,b)|a.$method(b))
}
}
impl<const N:usize,T:core::ops::$trait<u32>> core::ops::$trait<u32> for Vector<N,T>{
#[inline]
fn $method(&mut self,rhs:u32){
self.array.iter_mut()
.for_each(|t|t.$method(rhs))
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_extend {
( $size: expr ) => {
impl<T> Vector<$size,T>{
#[inline]
pub fn extend(self,value:T)->Vector<{$size+1},T>{
let mut iter=self.array.into_iter().chain(core::iter::once(value));
Vector::new(
core::array::from_fn(|_|iter.next().unwrap()),
)
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_named_fields {
( $struct:ident, $size: expr ) => {
impl<T> core::ops::Deref for Vector<$size,T>{
type Target=$struct<T>;
#[inline]
fn deref(&self)->&Self::Target{
unsafe{core::mem::transmute(&self.array)}
}
}
impl<T> core::ops::DerefMut for Vector<$size,T>{
#[inline]
fn deref_mut(&mut self)->&mut Self::Target{
unsafe{core::mem::transmute(&mut self.array)}
}
}
}
}
#[doc(hidden)]
#[macro_export(local_inner_macros)]
macro_rules! impl_vector_3 {
()=>{
impl<T> Vector<3,T>
{
#[inline]
pub fn cross<U,V>(self,rhs:Vector<3,U>)->Vector<3,<V as core::ops::Sub>::Output>
where
T:core::ops::Mul<U,Output=V>+Copy,
U:Copy,
V:core::ops::Sub,
{
Vector::new([
self.y*rhs.z-self.z*rhs.y,
self.z*rhs.x-self.x*rhs.z,
self.x*rhs.y-self.y*rhs.x,
])
}
}
}
}

17
linear_ops/src/matrix.rs Normal file
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@ -0,0 +1,17 @@
use crate::vector::Vector;
#[derive(Clone,Copy,Debug,Hash,Eq,PartialEq)]
pub struct Matrix<const X:usize,const Y:usize,T>{
pub(crate) array:[[T;Y];X],
}
crate::impl_matrix!();
crate::impl_matrix_extend!(2,2);
crate::impl_matrix_extend!(2,3);
crate::impl_matrix_extend!(3,2);
crate::impl_matrix_extend!(3,3);
//Special case 3x3 matrix operations because I cba to write macros for the arbitrary cases
#[cfg(feature="named-fields")]
crate::impl_matrix_3x3!();

59
linear_ops/src/named.rs Normal file
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@ -0,0 +1,59 @@
use crate::vector::Vector;
use crate::matrix::Matrix;
#[repr(C)]
pub struct Vector2<T> {
pub x: T,
pub y: T,
}
#[repr(C)]
pub struct Vector3<T> {
pub x: T,
pub y: T,
pub z: T,
}
#[repr(C)]
pub struct Vector4<T> {
pub x: T,
pub y: T,
pub z: T,
pub w: T,
}
crate::impl_vector_named_fields!(Vector2, 2);
crate::impl_vector_named_fields!(Vector3, 3);
crate::impl_vector_named_fields!(Vector4, 4);
#[repr(C)]
pub struct Matrix2<T> {
pub x_axis: T,
pub y_axis: T,
}
#[repr(C)]
pub struct Matrix3<T> {
pub x_axis: T,
pub y_axis: T,
pub z_axis: T,
}
#[repr(C)]
pub struct Matrix4<T> {
pub x_axis: T,
pub y_axis: T,
pub z_axis: T,
pub w_axis: T,
}
crate::impl_matrix_named_fields!(
//outer struct
(
(Matrix2, 2),
(Matrix3, 3),
(Matrix4, 4)
),
//inner struct
(
(2),
(3),
(4)
)
);

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@ -0,0 +1,96 @@
use crate::types::{Matrix3,Matrix3x2,Matrix3x4,Matrix4x2,Vector3};
type Planar64=fixed_wide::types::I32F32;
type Planar64Wide1=fixed_wide::types::I64F64;
//type Planar64Wide2=fixed_wide::types::I128F128;
type Planar64Wide3=fixed_wide::types::I256F256;
#[test]
fn wide_vec3(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v*v.x;
let v2=v1*v1.y;
let v3=v2*v2.z;
assert_eq!(v3.array,Vector3::from_value(Planar64Wide3::from(3i128.pow(8))).array);
}
#[test]
fn wide_vec3_dot(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v*v.x;
let v2=v1*v1.y;
let v3=v2.dot(v2);
assert_eq!(v3,Planar64Wide3::from(3i128.pow(8)*3));
}
#[test]
fn wide_vec3_length_squared(){
let v=Vector3::from_value(Planar64::from(3));
let v1=v*v.x;
let v2=v1*v1.y;
let v3=v2.length_squared();
assert_eq!(v3,Planar64Wide3::from(3i128.pow(8)*3));
}
#[test]
fn wide_matrix_dot(){
let lhs=Matrix3x4::new([
[Planar64::from(1),Planar64::from(2),Planar64::from(3),Planar64::from(4)],
[Planar64::from(5),Planar64::from(6),Planar64::from(7),Planar64::from(8)],
[Planar64::from(9),Planar64::from(10),Planar64::from(11),Planar64::from(12)],
]).transpose();
let rhs=Matrix4x2::new([
[Planar64::from(1),Planar64::from(2)],
[Planar64::from(3),Planar64::from(4)],
[Planar64::from(5),Planar64::from(6)],
[Planar64::from(7),Planar64::from(8)],
]).transpose();
// Mat3<Vec4>.dot(Mat4<Vec2>) -> Mat3<Vec2>
let m_dot=lhs*rhs;
//In[1]:= {{1, 2, 3, 4}, {5, 6, 7, 8}, {9, 10, 11, 12}} . {{1, 2}, {3, 4}, {5, 6}, {7, 8}}
//Out[1]= {{50, 60}, {114, 140}, {178, 220}}
assert_eq!(
m_dot.array,
Matrix3x2::new([
[Planar64Wide1::from(50),Planar64Wide1::from(60)],
[Planar64Wide1::from(114),Planar64Wide1::from(140)],
[Planar64Wide1::from(178),Planar64Wide1::from(220)],
]).transpose().array
);
}
#[test]
#[cfg(feature="named-fields")]
fn wide_matrix_det(){
let m=Matrix3::new([
[Planar64::from(1),Planar64::from(2),Planar64::from(3)],
[Planar64::from(4),Planar64::from(5),Planar64::from(7)],
[Planar64::from(6),Planar64::from(8),Planar64::from(9)],
]);
// In[2]:= Det[{{1, 2, 3}, {4, 5, 7}, {6, 8, 9}}]
// Out[2]= 7
assert_eq!(m.det(),fixed_wide::fixed::Fixed::<3,96>::from(7));
}
#[test]
#[cfg(feature="named-fields")]
fn wide_matrix_adjugate(){
let m=Matrix3::new([
[Planar64::from(1),Planar64::from(2),Planar64::from(3)],
[Planar64::from(4),Planar64::from(5),Planar64::from(7)],
[Planar64::from(6),Planar64::from(8),Planar64::from(9)],
]);
// In[6]:= Adjugate[{{1, 2, 3}, {4, 5, 7}, {6, 8, 9}}]
// Out[6]= {{-11, 6, -1}, {6, -9, 5}, {2, 4, -3}}
assert_eq!(
m.adjugate().array,
Matrix3::new([
[Planar64Wide1::from(-11),Planar64Wide1::from(6),Planar64Wide1::from(-1)],
[Planar64Wide1::from(6),Planar64Wide1::from(-9),Planar64Wide1::from(5)],
[Planar64Wide1::from(2),Planar64Wide1::from(4),Planar64Wide1::from(-3)],
]).array
);
}

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@ -0,0 +1,6 @@
mod tests;
#[cfg(feature="named-fields")]
mod named;
mod fixed_wide;

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@ -0,0 +1,30 @@
use crate::types::{Vector3,Matrix3};
#[test]
fn test_vector(){
let mut v=Vector3::new([1,2,3]);
assert_eq!(v.x,1);
assert_eq!(v.y,2);
assert_eq!(v.z,3);
v.x=5;
assert_eq!(v.x,5);
v.y*=v.x;
assert_eq!(v.y,10);
}
#[test]
fn test_matrix(){
let mut v=Matrix3::from_value(2);
assert_eq!(v.x_axis.x,2);
assert_eq!(v.y_axis.y,2);
assert_eq!(v.z_axis.z,2);
v.x_axis.x=5;
assert_eq!(v.x_axis.x,5);
v.y_axis.z*=v.x_axis.x;
assert_eq!(v.y_axis.z,10);
}

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@ -0,0 +1,59 @@
use crate::types::{Vector2,Vector3,Matrix3x4,Matrix4x2,Matrix3x2,Matrix2x3};
#[test]
fn test_bool(){
assert_eq!(Vector3::new([false,false,false]).any(),false);
assert_eq!(Vector3::new([false,false,true]).any(),true);
assert_eq!(Vector3::new([false,false,true]).all(),false);
assert_eq!(Vector3::new([true,true,true]).all(),true);
}
#[test]
fn test_length_squared(){
assert_eq!(Vector3::new([1,2,3]).length_squared(),14);
}
#[test]
fn test_arithmetic(){
let a=Vector3::new([1,2,3]);
assert_eq!((a+a*2).array,Vector3::new([1*3,2*3,3*3]).array);
}
#[test]
fn matrix_transform_vector(){
let m=Matrix2x3::new([
[1,2,3],
[4,5,6],
]).transpose();
let v=Vector3::new([1,2,3]);
let transformed=m*v;
assert_eq!(transformed.array,Vector2::new([14,32]).array);
}
#[test]
fn matrix_dot(){
// All this code was written row major and I converted the lib to colum major
let rhs=Matrix4x2::new([
[ 1.0, 2.0],
[ 3.0, 4.0],
[ 5.0, 6.0],
[ 7.0, 8.0],
]).transpose(); // | | |
let lhs=Matrix3x4::new([ // | | |
[1.0, 2.0, 3.0, 4.0],// [ 50.0, 60.0],
[5.0, 6.0, 7.0, 8.0],// [114.0,140.0],
[9.0,10.0,11.0,12.0],// [178.0,220.0],
]).transpose();
// Mat3<Vec4>.dot(Mat4<Vec2>) -> Mat3<Vec2>
let m_dot=lhs*rhs;
//In[1]:= {{1, 2, 3, 4}, {5, 6, 7, 8}, {9, 10, 11, 12}} . {{1, 2}, {3, 4}, {5, 6}, {7, 8}}
//Out[1]= {{50, 60}, {114, 140}, {178, 220}}
assert_eq!(
m_dot.array,
Matrix3x2::new([
[50.0,60.0],
[114.0,140.0],
[178.0,220.0],
]).transpose().array
);
}

18
linear_ops/src/types.rs Normal file
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@ -0,0 +1,18 @@
use crate::vector::Vector;
use crate::matrix::Matrix;
pub type Vector2<T>=Vector<2,T>;
pub type Vector3<T>=Vector<3,T>;
pub type Vector4<T>=Vector<4,T>;
pub type Matrix2<T>=Matrix<2,2,T>;
pub type Matrix2x3<T>=Matrix<2,3,T>;
pub type Matrix2x4<T>=Matrix<2,4,T>;
pub type Matrix3x2<T>=Matrix<3,2,T>;
pub type Matrix3<T>=Matrix<3,3,T>;
pub type Matrix3x4<T>=Matrix<3,4,T>;
pub type Matrix4x2<T>=Matrix<4,2,T>;
pub type Matrix4x3<T>=Matrix<4,3,T>;
pub type Matrix4<T>=Matrix<4,4,T>;

19
linear_ops/src/vector.rs Normal file
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@ -0,0 +1,19 @@
/// An array-backed vector type. Named fields are made accessible via the Deref/DerefMut traits which are implmented for 2-4 dimensions.
/// let mut v = Vector::new([1.0,2.0,3.0]);
/// v.x += v.z;
/// println!("v.x={}",v.x);
#[derive(Clone,Copy,Debug,Hash,Eq,PartialEq)]
pub struct Vector<const N:usize,T>{
pub(crate) array:[T;N],
}
crate::impl_vector!();
// Needs const generics for generic case
crate::impl_vector_extend!(2);
crate::impl_vector_extend!(3);
//cross product
#[cfg(feature="named-fields")]
crate::impl_vector_3!();

View File

@ -3,12 +3,5 @@
version = 3 version = 3
[[package]] [[package]]
name = "deferred_division" name = "ratio_ops"
version = "0.1.0"
dependencies = [
"fixed_wide_traits",
]
[[package]]
name = "fixed_wide_traits"
version = "0.1.0" version = "0.1.0"

10
ratio_ops/Cargo.toml Normal file
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@ -0,0 +1,10 @@
[package]
name = "ratio_ops"
version = "0.1.0"
edition = "2021"
repository = "https://git.itzana.me/StrafesNET/fixed_wide_vectors"
license = "MIT OR Apache-2.0"
description = "Ratio operations using trait bounds for avoiding division like the plague."
authors = ["Rhys Lloyd <krakow20@gmail.com>"]
[dependencies]

176
ratio_ops/LICENSE-APACHE Normal file
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@ -0,0 +1,176 @@
Apache License
Version 2.0, January 2004
http://www.apache.org/licenses/
TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
1. Definitions.
"License" shall mean the terms and conditions for use, reproduction,
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otherwise, or (ii) ownership of fifty percent (50%) or more of the
outstanding shares, or (iii) beneficial ownership of such entity.
"You" (or "Your") shall mean an individual or Legal Entity
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8. Limitation of Liability. In no event and under no legal theory,
whether in tort (including negligence), contract, or otherwise,
unless required by applicable law (such as deliberate and grossly
negligent acts) or agreed to in writing, shall any Contributor be
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9. Accepting Warranty or Additional Liability. While redistributing
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23
ratio_ops/LICENSE-MIT Normal file
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Permission is hereby granted, free of charge, to any
person obtaining a copy of this software and associated
documentation files (the "Software"), to deal in the
Software without restriction, including without
limitation the rights to use, copy, modify, merge,
publish, distribute, sublicense, and/or sell copies of
the Software, and to permit persons to whom the Software
is furnished to do so, subject to the following
conditions:
The above copyright notice and this permission notice
shall be included in all copies or substantial portions
of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF
ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED
TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A
PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT
SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR
IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
DEALINGS IN THE SOFTWARE.

4
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pub mod ratio;
#[cfg(test)]
mod tests;

297
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#[derive(Clone,Copy,Debug,Hash)]
pub struct Ratio<Num,Den>{
pub num:Num,
pub den:Den,
}
impl<Num,Den> Ratio<Num,Den>{
#[inline(always)]
pub const fn new(num:Num,den:Den)->Self{
Self{num,den}
}
}
/// The actual divide implementation, Div is replaced with a Ratio constructor
pub trait Divide<Rhs=Self>{
type Output;
fn divide(self,rhs:Rhs)->Self::Output;
}
impl<Num,Den> Ratio<Num,Den>
where
Num:Divide<Den>,
{
#[inline]
pub fn divide(self)-><Num as Divide<Den>>::Output{
self.num.divide(self.den)
}
}
//take care to use the ratio methods to avoid nested ratios
impl<LhsNum,LhsDen> Ratio<LhsNum,LhsDen>{
#[inline]
pub fn mul_ratio<RhsNum,RhsDen>(self,rhs:Ratio<RhsNum,RhsDen>)->Ratio<<LhsNum as core::ops::Mul<RhsNum>>::Output,<LhsDen as core::ops::Mul<RhsDen>>::Output>
where
LhsNum:core::ops::Mul<RhsNum>,
LhsDen:core::ops::Mul<RhsDen>,
{
Ratio::new(self.num*rhs.num,self.den*rhs.den)
}
#[inline]
pub fn div_ratio<RhsNum,RhsDen>(self,rhs:Ratio<RhsNum,RhsDen>)->Ratio<<LhsNum as core::ops::Mul<RhsDen>>::Output,<LhsDen as core::ops::Mul<RhsNum>>::Output>
where
LhsNum:core::ops::Mul<RhsDen>,
LhsDen:core::ops::Mul<RhsNum>,
{
Ratio::new(self.num*rhs.den,self.den*rhs.num)
}
}
macro_rules! impl_ratio_method {
($trait:ident, $method:ident, $ratio_method:ident) => {
impl<LhsNum,LhsDen> Ratio<LhsNum,LhsDen>{
#[inline]
pub fn $ratio_method<RhsNum,RhsDen,LhsCrossMul,RhsCrossMul>(self,rhs:Ratio<RhsNum,RhsDen>)->Ratio<<LhsCrossMul as core::ops::$trait<RhsCrossMul>>::Output,<LhsDen as core::ops::Mul<RhsDen>>::Output>
where
LhsNum:core::ops::Mul<RhsDen,Output=LhsCrossMul>,
LhsDen:core::ops::Mul<RhsNum,Output=RhsCrossMul>,
LhsDen:core::ops::Mul<RhsDen>,
LhsDen:Copy,
RhsDen:Copy,
LhsCrossMul:core::ops::$trait<RhsCrossMul>,
{
Ratio::new((self.num*rhs.den).$method(self.den*rhs.num),self.den*rhs.den)
}
}
};
}
impl_ratio_method!(Add,add,add_ratio);
impl_ratio_method!(Sub,sub,sub_ratio);
impl_ratio_method!(Rem,rem,rem_ratio);
/// Comparing two ratios needs to know the parity of the denominators
/// For signed integers this can be implemented with is_negative()
pub trait Parity{
fn parity(&self)->bool;
}
macro_rules! impl_parity_unsigned{
($($type:ty),*)=>{
$(
impl Parity for $type{
fn parity(&self)->bool{
false
}
}
)*
};
}
macro_rules! impl_parity_signed{
($($type:ty),*)=>{
$(
impl Parity for $type{
fn parity(&self)->bool{
self.is_negative()
}
}
)*
};
}
macro_rules! impl_parity_float{
($($type:ty),*)=>{
$(
impl Parity for $type{
fn parity(&self)->bool{
self.is_sign_negative()
}
}
)*
};
}
impl_parity_unsigned!(u8,u16,u32,u64,u128,usize);
impl_parity_signed!(i8,i16,i32,i64,i128,isize);
impl_parity_float!(f32,f64);
macro_rules! impl_ratio_ord_method{
($method:ident, $ratio_method:ident, $output:ty)=>{
impl<LhsNum,LhsDen:Parity> Ratio<LhsNum,LhsDen>{
#[inline]
pub fn $ratio_method<RhsNum,RhsDen:Parity,T>(self,rhs:Ratio<RhsNum,RhsDen>)->$output
where
LhsNum:core::ops::Mul<RhsDen,Output=T>,
LhsDen:core::ops::Mul<RhsNum,Output=T>,
T:Ord,
{
match self.den.parity()^rhs.den.parity(){
true=>(self.den*rhs.num).$method(&(self.num*rhs.den)),
false=>(self.num*rhs.den).$method(&(self.den*rhs.num)),
}
}
}
}
}
//PartialEq
impl_ratio_ord_method!(eq,eq_ratio,bool);
//PartialOrd
impl_ratio_ord_method!(lt,lt_ratio,bool);
impl_ratio_ord_method!(gt,gt_ratio,bool);
impl_ratio_ord_method!(le,le_ratio,bool);
impl_ratio_ord_method!(ge,ge_ratio,bool);
impl_ratio_ord_method!(partial_cmp,partial_cmp_ratio,Option<core::cmp::Ordering>);
//Ord
impl_ratio_ord_method!(cmp,cmp_ratio,core::cmp::Ordering);
/* generic rhs mul is not possible!
impl<Lhs,RhsNum,RhsDen> core::ops::Mul<Ratio<RhsNum,RhsDen>> for Lhs
where
Lhs:core::ops::Mul<RhsNum>,
{
type Output=Ratio<<Lhs as core::ops::Mul<RhsNum>>::Output,RhsDen>;
#[inline]
fn mul(self,rhs:Ratio<RhsNum,RhsDen>)->Self::Output{
Ratio::new(self*rhs.num,rhs.den)
}
}
*/
//operators
impl<LhsNum,LhsDen> core::ops::Neg for Ratio<LhsNum,LhsDen>
where
LhsNum:core::ops::Neg,
{
type Output=Ratio<<LhsNum as core::ops::Neg>::Output,LhsDen>;
#[inline]
fn neg(self)->Self::Output{
Ratio::new(-self.num,self.den)
}
}
impl<LhsNum,LhsDen,Rhs> core::ops::Mul<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsNum:core::ops::Mul<Rhs>,
{
type Output=Ratio<<LhsNum as core::ops::Mul<Rhs>>::Output,LhsDen>;
#[inline]
fn mul(self,rhs:Rhs)->Self::Output{
Ratio::new(self.num*rhs,self.den)
}
}
impl<LhsNum,LhsDen,Rhs> core::ops::Div<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsDen:core::ops::Mul<Rhs>,
{
type Output=Ratio<LhsNum,<LhsDen as core::ops::Mul<Rhs>>::Output>;
#[inline]
fn div(self,rhs:Rhs)->Self::Output{
Ratio::new(self.num,self.den*rhs)
}
}
macro_rules! impl_ratio_operator {
($trait:ident, $method:ident) => {
impl<LhsNum,LhsDen,Rhs,Intermediate> core::ops::$trait<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsNum:core::ops::$trait<Intermediate>,
LhsDen:Copy,
Rhs:core::ops::Mul<LhsDen,Output=Intermediate>,
{
type Output=Ratio<<LhsNum as core::ops::$trait<Intermediate>>::Output,LhsDen>;
#[inline]
fn $method(self,rhs:Rhs)->Self::Output{
Ratio::new(self.num.$method(rhs*self.den),self.den)
}
}
};
}
impl_ratio_operator!(Add,add);
impl_ratio_operator!(Sub,sub);
impl_ratio_operator!(Rem,rem);
//assign operators
impl<LhsNum,LhsDen,Rhs> core::ops::MulAssign<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsNum:core::ops::MulAssign<Rhs>,
{
#[inline]
fn mul_assign(&mut self,rhs:Rhs){
self.num*=rhs;
}
}
impl<LhsNum,LhsDen,Rhs> core::ops::DivAssign<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsDen:core::ops::MulAssign<Rhs>,
{
#[inline]
fn div_assign(&mut self,rhs:Rhs){
self.den*=rhs;
}
}
macro_rules! impl_ratio_assign_operator {
($trait:ident, $method:ident) => {
impl<LhsNum,LhsDen,Rhs> core::ops::$trait<Rhs> for Ratio<LhsNum,LhsDen>
where
LhsNum:core::ops::$trait,
LhsDen:Copy,
Rhs:core::ops::Mul<LhsDen,Output=LhsNum>,
{
#[inline]
fn $method(&mut self,rhs:Rhs){
self.num.$method(rhs*self.den)
}
}
};
}
impl_ratio_assign_operator!(AddAssign,add_assign);
impl_ratio_assign_operator!(SubAssign,sub_assign);
impl_ratio_assign_operator!(RemAssign,rem_assign);
// Only implement PartialEq<Self>
// Rust's operators aren't actually that good
impl<LhsNum,LhsDen,RhsNum,RhsDen,T,U> PartialEq<Ratio<RhsNum,RhsDen>> for Ratio<LhsNum,LhsDen>
where
LhsNum:Copy,
LhsDen:Copy,
RhsNum:Copy,
RhsDen:Copy,
LhsNum:core::ops::Mul<RhsDen,Output=T>,
RhsNum:core::ops::Mul<LhsDen,Output=U>,
T:PartialEq<U>,
{
#[inline]
fn eq(&self,other:&Ratio<RhsNum,RhsDen>)->bool{
(self.num*other.den).eq(&(other.num*self.den))
}
}
impl<Num,Den> Eq for Ratio<Num,Den> where Self:PartialEq{}
impl<LhsNum,LhsDen,RhsNum,RhsDen,T,U> PartialOrd<Ratio<RhsNum,RhsDen>> for Ratio<LhsNum,LhsDen>
where
LhsNum:Copy,
LhsDen:Copy,
RhsNum:Copy,
RhsDen:Copy,
LhsNum:core::ops::Mul<RhsDen,Output=T>,
RhsNum:core::ops::Mul<LhsDen,Output=U>,
T:PartialOrd<U>,
{
#[inline]
fn partial_cmp(&self,other:&Ratio<RhsNum,RhsDen>)->Option<core::cmp::Ordering>{
(self.num*other.den).partial_cmp(&(other.num*self.den))
}
}
impl<Num,Den,T> Ord for Ratio<Num,Den>
where
Num:Copy,
Den:Copy,
Num:core::ops::Mul<Den,Output=T>,
T:Ord,
{
#[inline]
fn cmp(&self,other:&Self)->std::cmp::Ordering{
(self.num*other.den).cmp(&(other.num*self.den))
}
}

58
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use crate::ratio::Ratio;
macro_rules! test_op{
($ratio_op:ident,$op:ident,$a:expr,$b:expr,$c:expr,$d:expr)=>{
assert_eq!(
Ratio::new($a,$b).$ratio_op(Ratio::new($c,$d)),
(($a as f32)/($b as f32)).$op(&(($c as f32)/($d as f32)))
);
};
}
macro_rules! test_many_ops{
($ratio_op:ident,$op:ident)=>{
test_op!($ratio_op,$op,1,2,3,4);
test_op!($ratio_op,$op,1,2,-3,4);
test_op!($ratio_op,$op,-1,2,-3,4);
test_op!($ratio_op,$op,-1,-2,-3,4);
test_op!($ratio_op,$op,2,1,6,3);
test_op!($ratio_op,$op,-2,1,6,3);
test_op!($ratio_op,$op,2,-1,-6,3);
test_op!($ratio_op,$op,2,1,6,-3);
};
}
#[test]
fn test_lt(){
test_many_ops!(lt_ratio,lt);
}
#[test]
fn test_gt(){
test_many_ops!(gt_ratio,gt);
}
#[test]
fn test_le(){
test_many_ops!(le_ratio,le);
}
#[test]
fn test_ge(){
test_many_ops!(ge_ratio,ge);
}
#[test]
fn test_eq(){
test_many_ops!(eq_ratio,eq);
}
#[test]
fn test_partial_cmp(){
test_many_ops!(partial_cmp_ratio,partial_cmp);
}
// #[test]
// fn test_cmp(){
// test_many_ops!(cmp_ratio,cmp);
// }