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169 Commits

Author SHA1 Message Date
a67aa71fb0 update rbx_loader 2024-10-04 19:42:25 -07:00
7cc0fd59c8 simplify double map into single map 2024-10-04 12:47:52 -07:00
bded9fccdf update rbx_loader 2024-10-03 20:33:10 -07:00
4cd0114567 v0.10.5 update roblox + source loaders 2024-10-01 17:11:23 -07:00
991e01d530 update deps 2024-10-01 17:11:23 -07:00
e2bd9ba692 maybe multiply smaller den faster (this operation sucks) 2024-09-30 21:09:45 -07:00
383df8637f update deps 2024-09-30 17:05:27 -07:00
1a6831cf8b fixed wide vectors 2024-09-30 10:36:37 -07:00
ccae1a45e1 up the date 2024-09-21 15:41:02 -07:00
1e299b7b9c update rbx_loader 2024-09-21 12:42:29 -07:00
f3d4d8dbda v0.10.4 roblox scripts 2024-09-20 11:50:44 -07:00
b2a84e3be1 update common 2024-08-21 14:20:09 -07:00
0468484788 make physics-graphics communication a bit less insane 2024-08-21 14:20:09 -07:00
b9dc97053f graphics: spaces 2024-08-21 14:20:09 -07:00
40ed173b60 physics: unused field 2024-08-21 14:20:09 -07:00
fd5a813357 graphics: bundle FrameState into struct 2024-08-21 14:20:09 -07:00
50726199b9 todo 2024-08-21 14:20:09 -07:00
0676007430 graphics: drop model_buf after upload 2024-08-21 14:20:09 -07:00
97c49c9351 graphics: unused struct 2024-08-21 14:20:09 -07:00
10689784be graphics_worker: untab 2024-08-21 14:20:09 -07:00
2eff5dda9e graphics_worker: tweaks (rust master) 2024-08-21 14:20:09 -07:00
93b04f4f1f physics: recalculate touching parts in set_position 2024-08-21 14:20:09 -07:00
c616e82c47 use const 2024-08-19 17:04:53 -07:00
d3f84c2dbd physics: refactor models and attributes with type safety
make invalid states unrepresentable!!!
2024-08-09 14:47:04 -07:00
5e45753756 update deps 2024-08-09 14:46:54 -07:00
cfee6f119f pull out collision handlers into functions 2024-08-08 15:54:23 -07:00
b9e34f53c3 do not set time on idle 2024-08-08 13:18:28 -07:00
394f1f1dc2 v0.10.3 physics updates + pause game + fix boosters 2024-08-07 19:48:09 -07:00
05ec7ea5d8 physics: rework jumping and boosters 2024-08-07 18:48:57 -07:00
7996df532e remove a source of non-determinism 2024-08-06 14:15:57 -07:00
b4b85b7da4 refactor physics_worker 2024-08-06 11:26:27 -07:00
3a98eaff7c move physics instruction to common 2024-08-06 11:10:43 -07:00
4b5b7dc2fb update deps 2024-08-06 11:02:49 -07:00
8a13640c55 time travel warning 2024-08-02 10:42:10 -07:00
85ba12ff92 pause on focus 2024-08-02 10:42:10 -07:00
4f492d73b0 update deps 2024-08-02 10:42:10 -07:00
a8d54fdd7c minor tweak to loading map from arg 2024-08-02 09:20:34 -07:00
34ac541260 ignore ReachWalkTargetVelocity 2024-08-02 08:03:16 -07:00
099788b746 this is wrong, even when velocity is zero 2024-08-02 08:03:16 -07:00
305017c6c8 iso shortcut 2024-08-02 08:03:16 -07:00
e47d152af2 make a distinction between restart and spawning 2024-08-02 08:03:16 -07:00
755adeaefd refactor physics instruction processing
This is an important engine upgrade: idle events do not donate their timestamp to engine objects and pollute the timeline with unnecessary game ticks that can be represented as analytic continuations of previous game ticks.  This means that all "render" tick updates can be dropped from bot timelines.  In other words, progressing the physics simulation is invariant to differing subdivisions of an overall time advancement with no external input.
2024-08-02 08:03:16 -07:00
e04e754abb v0.10.2 run timer 2024-08-01 09:39:16 -07:00
5c1f69628d update deps 2024-08-01 09:36:11 -07:00
44031c8b83 simple run timer 2024-08-01 09:29:13 -07:00
d6470ee81b denormalize zone data on load 2024-08-01 09:29:09 -07:00
a7c7088c1f model is supposed to be guaranteed to exist 2024-07-31 12:08:57 -07:00
dd6acbfc2f use mem::replace where it is needed 2024-07-31 12:08:57 -07:00
3fea6ec5a2 put imports together 2024-07-30 13:34:34 -07:00
38df41e043 mouse interpolator abstraction 2024-07-30 13:01:42 -07:00
171cd8f2e4 cross compile with all features 2024-07-30 12:02:28 -07:00
914b5da897 switch over tooling to snfm 2024-07-30 12:02:28 -07:00
52e92bfa5a no more textures 2024-07-30 11:37:26 -07:00
938500e39b update deps (don't panic on corrupted files) 2024-07-29 18:24:57 -07:00
d82dfc2bc2 build smaller 2024-07-29 17:41:46 -07:00
c59f40892a snf optional as well because why not 2024-07-29 17:41:46 -07:00
4863605af7 source and roblox map loading feature flags 2024-07-29 17:11:40 -07:00
685e74575a v0.10.1 snf 2024-07-29 16:53:04 -07:00
d1aca4519b change textures path on my pc 2024-07-29 16:51:36 -07:00
4a4ede36ed read snf map 2024-07-29 16:51:36 -07:00
33cc2e1a45 update common 2024-07-25 13:53:45 -07:00
9982a52af5 update deps 2024-07-22 13:52:27 -07:00
34939db8ef v0.10.0 style redesign + mesh loader 2024-07-22 13:23:19 -07:00
b61088195a update deps (aggressive) 2024-07-22 13:21:47 -07:00
19ab098be0 wgpu 22.0.0 2024-07-22 13:21:47 -07:00
bf1fad9fc4 use strafesnet registry 2024-07-22 13:21:47 -07:00
62b5ba2b33 pretty polygon fanning from vbsp code 2024-07-22 13:21:47 -07:00
f2a7b44884 print texture load error 2024-07-22 13:21:47 -07:00
c054b6aab3 update deps 2024-07-22 13:21:47 -07:00
7caec210ce include meshes symbolic link 2024-07-22 13:21:47 -07:00
5fdcf9047c implement roblox mesh loading 2024-07-22 13:21:47 -07:00
3756af9638 update strafesnet deps 2024-07-22 13:21:47 -07:00
8424fea634 redesign style data structures + fly 2024-07-22 13:21:47 -07:00
46c73b80c6 fix missing bsp_loader commit 2024-03-15 19:24:52 -07:00
0ac1c1aa6b adjust clipping planes 2024-02-18 00:23:27 -08:00
0a75e78c90 update deferred_loader 2024-02-17 22:08:06 -08:00
ecc8d2395b update bsp_loader 2024-02-17 20:32:03 -08:00
e2bd8b4038 v0.9.5 fix graphical bug 2024-02-16 20:03:15 -08:00
4a53040011 use .entry().or_insert_with() pattern everywhere 2024-02-16 06:04:24 -08:00
b1d860edf1 fix invisible walls 2024-02-16 04:11:42 -08:00
db6e1e43c1 file is probably gonna be here a long time 2024-02-16 00:18:16 -08:00
03970edeb8 update bsp_loader 2024-02-15 01:47:18 -08:00
e2da41ec99 update rbx_loader 2024-02-15 00:59:37 -08:00
ae4d539ab1 too much spam 2024-02-15 00:22:11 -08:00
9de60a8e19 v0.9.4 valve mesh loading 2024-02-15 00:22:11 -08:00
df8189b874 implement valve mesh loading 2024-02-15 00:22:11 -08:00
b25bcc627d asref path 2024-02-14 23:33:10 -08:00
977069c4eb v0.9.3 bsp legacy texture loader 2024-02-14 23:33:10 -08:00
63655ef931 enable source_legacy style texture loading 2024-02-14 23:33:10 -08:00
39924db94d change PhysicsMesh::from to PhysicsMesh::try_from 2024-02-14 23:33:10 -08:00
3b3ccefebb fix panic when no modes 2024-02-13 23:16:11 -08:00
ae6e4ee6aa v0.9.2 bsp_loader (no props or textures) 2024-02-13 22:36:12 -08:00
746d3eb7ee bsp_loader 2024-02-13 22:34:13 -08:00
7be93d2114 refactor loaders + file loading 2024-02-13 22:14:26 -08:00
e7f01eff80 print instead of panic 2024-02-13 06:08:03 -08:00
f58a17adba v0.9.1 data structure rewrite 2024-02-13 06:08:03 -08:00
3be9730b52 allow texture loading failure 2024-02-13 06:08:03 -08:00
93eeb3354f rewrite data structures, implement texture_loader 2024-02-13 06:08:03 -08:00
69bab269db stop clone 2024-02-13 00:07:30 -08:00
3bad427f61 shrink code 2024-02-07 21:11:50 -08:00
90cca51e6e patch arcane 2024-02-07 19:50:03 -08:00
480cd0e3be commonize 2024-01-29 22:37:48 -08:00
515ca20fb5 this is now a multi year project 2024-01-29 16:19:57 -08:00
6dff6a2c33 update dependencies 2024-01-29 16:19:57 -08:00
ae9fc15320 update wgpu and slap lifetimes on everything until it works 2024-01-19 20:11:58 -08:00
6ae058d834 make room for missing texture print 2024-01-18 13:05:54 -08:00
517c4914ac load_bsp module 2024-01-18 13:05:26 -08:00
6ce057ac64 add vbsp dep 2024-01-18 13:00:08 -08:00
c86824bdc1 skip objects with zero determinant 2023-12-30 10:36:03 -08:00
a7f7edef00 update deps 2023-12-24 13:10:12 -08:00
5b8e5c8899 we're not using floats anymore 2023-12-12 15:47:31 -08:00
14000c016e multiply and check instead of doing bithacks 2023-12-12 15:30:09 -08:00
1c4191cfc9 convert recursion to stack 2023-12-12 14:47:20 -08:00
b2f067e0b4 stop erroring on subnormals, it's not really an issue 2023-12-04 08:55:21 -08:00
aec82358ee comment about conceptual failure case 2023-12-02 03:06:13 -08:00
5da5006027 attempt to fix the bug 2023-12-02 03:06:13 -08:00
97a1b57b65 TODO: relative d value 2023-12-02 02:02:51 -08:00
a359650ff8 use relative position to avoid overflow 2023-12-02 01:58:18 -08:00
1790390055 don't mess with casts, wtf 2023-12-02 01:31:47 -08:00
49e077996d overflow detect 2023-12-02 01:31:47 -08:00
9bfcf0b083 use det to make numbers smaller 2023-12-01 20:59:04 -08:00
82b3201b0a optimize face_nd: precalculate det 2023-12-01 20:50:38 -08:00
513414d4bd fix a near overflow bug 2023-12-01 18:28:05 -08:00
5c4bd4c3c7 wrong air accel limit 2023-12-01 05:01:13 -08:00
92ec137f33 v0.9.0 Face Crawler + Integer Physics + Threading Rewrite + Config File 2023-12-01 05:01:13 -08:00
5cedf91709 Face Crawler™ 2023-12-01 04:41:28 -08:00
c201a1a626 improve zeroes precision 2023-12-01 04:41:11 -08:00
fbae4d9f80 delete sweep 2023-12-01 04:41:11 -08:00
9374e93801 face crawler prerequisites 2023-12-01 04:41:11 -08:00
0585cfe6f1 fix test 2023-11-30 01:45:55 -08:00
3d96517213 update deps 2023-11-30 01:45:54 -08:00
eeb1561c3d utopia preset 2023-11-10 19:12:19 -08:00
19e602544a anisotropic filtering 2023-11-10 19:08:33 -08:00
444c3cbad9 remove cybertruck model from default map 2023-11-09 19:21:04 -08:00
2006f81804 surf maps link 2023-11-08 19:41:26 -08:00
de7b7ba7be defer resize to next frame render 2023-11-08 18:20:19 -08:00
008c66e052 TrussPart 2023-11-07 20:54:49 -08:00
ba250277bd textures for spheres and cylinders 2023-11-07 20:45:05 -08:00
085d4e7912 use cubes instead of teapots and monkeys 2023-11-07 16:54:44 -08:00
dd6b5bed24 implement primitive FaceDescriptions with fixed size arrays instead of hashmaps 2023-11-07 13:26:24 -08:00
9d4cadda30 demo zipping script 2023-11-06 00:32:31 -08:00
242b4ab470 style modifiers in mode 2023-11-01 16:06:48 -07:00
eaef3d3fd5 dedicated arcane loader 2023-10-31 16:14:21 -07:00
9d726c5419 StrafeSettings 2023-10-31 14:32:54 -07:00
9592f82c4e move camera_offset to StyleModifiers & PhysicsOutputState 2023-10-30 22:29:01 -07:00
873c6ab935 panic when u32::MAX verts 2023-10-30 22:12:17 -07:00
7ba94c1b30 enable compat_worker interop with real workers 2023-10-30 19:42:02 -07:00
8fc6a7fb8f comment on intersection test location 2023-10-30 19:16:48 -07:00
a3340143db use enum for bvh node content + wrap every model in aabb 2023-10-30 18:59:51 -07:00
9fc7884270 rename Model{Graphics|Physics} for consistency 2023-10-30 18:27:52 -07:00
953b17bc69 change model index_format based on number of vertices 2023-10-30 17:58:21 -07:00
8fcb4e5c6c as works here 2023-10-30 16:40:56 -07:00
073a076fe8 already u32 2023-10-30 16:23:58 -07:00
9848d66001 tabs 2023-10-30 16:13:57 -07:00
6474ddcbd1 update winit 2023-10-28 23:08:09 -07:00
c4cd73e914 toc script 2023-10-28 17:30:37 -07:00
bbb1857377 attributes: checkpoints, jump count 2023-10-28 17:04:30 -07:00
883be0bc01 disable vsync for funsies 2023-10-28 17:04:30 -07:00
5885036f8f put build/run tools in git because I just lost them 2023-10-28 17:04:30 -07:00
076dab23cf delete some dead code 2023-10-27 00:24:11 -07:00
c1001d6f37 update wgpu to 0.18.0 2023-10-26 23:58:27 -07:00
08d4e7d997 back face culling 2023-10-26 19:07:44 -07:00
e1f4f6e535 update everything except wgpu because it crashes 2023-10-25 16:30:02 -07:00
3a4c4ef9fe silence many compiler warnings 2023-10-25 16:07:12 -07:00
41dd155c50 styling 2023-10-25 15:58:10 -07:00
5fd6ca219b roblox_rocket style 2023-10-25 15:45:25 -07:00
1c22f4a3c3 implement rocket_force 2023-10-25 15:45:25 -07:00
1e6c489750 optional strafing + optional rocket force 2023-10-25 15:45:25 -07:00
9f62f5f2fd graphics thread + refactor everything + drop deps + update winit 2023-10-25 15:41:35 -07:00
41 changed files with 6425 additions and 5895 deletions

2
.cargo/config.toml Normal file
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[registries.strafesnet]
index = "sparse+https://git.itzana.me/api/packages/strafesnet/cargo/"

1
.gitignore vendored
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/target
/textures

2352
Cargo.lock generated

File diff suppressed because it is too large Load Diff

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[package]
name = "strafe-client"
version = "0.8.0"
version = "0.10.5"
edition = "2021"
repository = "https://git.itzana.me/StrafesNET/strafe-client"
license = "Custom"
description = "StrafesNET game client for bhop and surf."
authors = ["Rhys Lloyd <krakow20@gmail.com>"]
# See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
[features]
default = ["snf"]
snf = ["dep:strafesnet_snf"]
source = ["dep:strafesnet_deferred_loader", "dep:strafesnet_bsp_loader"]
roblox = ["dep:strafesnet_deferred_loader", "dep:strafesnet_rbx_loader"]
[dependencies]
bytemuck = { version = "1.13.1", features = ["derive"] }
configparser = "3.0.2"
ddsfile = "0.5.1"
glam = "0.24.1"
lazy-regex = "3.0.2"
obj = "0.10.2"
glam = "0.29.0"
id = { version = "0.1.0", registry = "strafesnet" }
parking_lot = "0.12.1"
pollster = "0.3.0"
rbx_binary = "0.7.1"
rbx_dom_weak = "2.5.0"
rbx_reflection_database = "0.2.7"
rbx_xml = "0.13.1"
wgpu = "0.17.0"
winit = "0.28.6"
strafesnet_bsp_loader = { version = "0.2.1", registry = "strafesnet", optional = true }
strafesnet_common = { version = "0.5.2", registry = "strafesnet" }
strafesnet_deferred_loader = { version = "0.4.0", features = ["legacy"], registry = "strafesnet", optional = true }
strafesnet_rbx_loader = { version = "0.5.1", registry = "strafesnet", optional = true }
strafesnet_snf = { version = "0.2.0", registry = "strafesnet", optional = true }
wgpu = "22.1.0"
winit = "0.30.5"
#[profile.release]
[profile.release]
#lto = true
#strip = true
#codegen-units = 1
strip = true
codegen-units = 1

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/*******************************************************
* Copyright (C) 2023 Rhys Lloyd <krakow20@gmail.com>
* Copyright (C) 2023-2024 Rhys Lloyd <krakow20@gmail.com>
*
* This file is part of the StrafesNET bhop/surf client.
*

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use crate::integer::Planar64Vec3;
#[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
pub enum AabbFace{
Right,//+X
Top,
Back,
Left,
Bottom,
Front,
}
#[derive(Clone)]
pub struct Aabb{
pub min:Planar64Vec3,
pub max:Planar64Vec3,
}
impl Default for Aabb {
fn default()->Self {
Self{min:Planar64Vec3::MAX,max:Planar64Vec3::MIN}
}
}
impl Aabb{
const VERTEX_DATA:[Planar64Vec3;8]=[
Planar64Vec3::int( 1,-1,-1),
Planar64Vec3::int( 1, 1,-1),
Planar64Vec3::int( 1, 1, 1),
Planar64Vec3::int( 1,-1, 1),
Planar64Vec3::int(-1,-1, 1),
Planar64Vec3::int(-1, 1, 1),
Planar64Vec3::int(-1, 1,-1),
Planar64Vec3::int(-1,-1,-1),
];
pub fn grow(&mut self,point:Planar64Vec3){
self.min=self.min.min(point);
self.max=self.max.max(point);
}
pub fn join(&mut self,aabb:&Aabb){
self.min=self.min.min(aabb.min);
self.max=self.max.max(aabb.max);
}
pub fn inflate(&mut self,hs:Planar64Vec3){
self.min-=hs;
self.max+=hs;
}
pub fn intersects(&self,aabb:&Aabb)->bool{
(self.min.cmplt(aabb.max)&aabb.min.cmplt(self.max)).all()
}
pub fn normal(face:AabbFace)->Planar64Vec3{
match face {
AabbFace::Right=>Planar64Vec3::int(1,0,0),
AabbFace::Top=>Planar64Vec3::int(0,1,0),
AabbFace::Back=>Planar64Vec3::int(0,0,1),
AabbFace::Left=>Planar64Vec3::int(-1,0,0),
AabbFace::Bottom=>Planar64Vec3::int(0,-1,0),
AabbFace::Front=>Planar64Vec3::int(0,0,-1),
}
}
pub fn unit_vertices()->[Planar64Vec3;8] {
return Self::VERTEX_DATA;
}
// pub fn face(&self,face:AabbFace)->Aabb {
// let mut aabb=self.clone();
// //in this implementation face = worldspace aabb face
// match face {
// AabbFace::Right => aabb.min.x=aabb.max.x,
// AabbFace::Top => aabb.min.y=aabb.max.y,
// AabbFace::Back => aabb.min.z=aabb.max.z,
// AabbFace::Left => aabb.max.x=aabb.min.x,
// AabbFace::Bottom => aabb.max.y=aabb.min.y,
// AabbFace::Front => aabb.max.z=aabb.min.z,
// }
// return aabb;
// }
pub fn center(&self)->Planar64Vec3{
return self.min.midpoint(self.max)
}
//probably use floats for area & volume because we don't care about precision
// pub fn area_weight(&self)->f32{
// let d=self.max-self.min;
// d.x*d.y+d.y*d.z+d.z*d.x
// }
// pub fn volume(&self)->f32{
// let d=self.max-self.min;
// d.x*d.y*d.z
// }
}

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use crate::aabb::Aabb;
//da algaritum
//lista boxens
//sort by {minx,maxx,miny,maxy,minz,maxz} (6 lists)
//find the sets that minimizes the sum of surface areas
//splitting is done when the minimum split sum of surface areas is larger than the node's own surface area
//start with bisection into octrees because a bad bvh is still 1000x better than no bvh
//sort the centerpoints on each axis (3 lists)
//bv is put into octant based on whether it is upper or lower in each list
#[derive(Default)]
pub struct BvhNode{
children:Vec<Self>,
models:Vec<usize>,
aabb:Aabb,
}
impl BvhNode{
pub fn the_tester<F:FnMut(usize)>(&self,aabb:&Aabb,f:&mut F){
for &model in &self.models{
f(model);
}
for child in &self.children{
if aabb.intersects(&child.aabb){
child.the_tester(aabb,f);
}
}
}
}
pub fn generate_bvh(boxen:Vec<Aabb>)->BvhNode{
generate_bvh_node(boxen.into_iter().enumerate().collect())
}
fn generate_bvh_node(boxen:Vec<(usize,Aabb)>)->BvhNode{
let n=boxen.len();
if n<20{
let mut aabb=Aabb::default();
let models=boxen.into_iter().map(|b|{aabb.join(&b.1);b.0}).collect();
BvhNode{
children:Vec::new(),
models,
aabb,
}
}else{
let mut octant=std::collections::HashMap::with_capacity(n);//this ids which octant the boxen is put in
let mut sort_x=Vec::with_capacity(n);
let mut sort_y=Vec::with_capacity(n);
let mut sort_z=Vec::with_capacity(n);
for (i,aabb) in boxen.iter(){
let center=aabb.center();
octant.insert(*i,0);
sort_x.push((*i,center.x()));
sort_y.push((*i,center.y()));
sort_z.push((*i,center.z()));
}
sort_x.sort_by(|tup0,tup1|tup0.1.partial_cmp(&tup1.1).unwrap());
sort_y.sort_by(|tup0,tup1|tup0.1.partial_cmp(&tup1.1).unwrap());
sort_z.sort_by(|tup0,tup1|tup0.1.partial_cmp(&tup1.1).unwrap());
let h=n/2;
let median_x=sort_x[h].1;
let median_y=sort_y[h].1;
let median_z=sort_z[h].1;
for (i,c) in sort_x{
if median_x<c{
octant.insert(i,octant[&i]+1<<0);
}
}
for (i,c) in sort_y{
if median_y<c{
octant.insert(i,octant[&i]+1<<1);
}
}
for (i,c) in sort_z{
if median_z<c{
octant.insert(i,octant[&i]+1<<2);
}
}
//generate lists for unique octant values
let mut list_list=Vec::with_capacity(8);
let mut octant_list=Vec::with_capacity(8);
for (i,aabb) in boxen.into_iter(){
let octant_id=octant[&i];
let list_id=if let Some(list_id)=octant_list.iter().position(|&id|id==octant_id){
list_id
}else{
let list_id=list_list.len();
octant_list.push(octant_id);
list_list.push(Vec::new());
list_id
};
list_list[list_id].push((i,aabb));
}
let mut aabb=Aabb::default();
let children=list_list.into_iter().map(|b|{
let node=generate_bvh_node(b);
aabb.join(&node.aabb);
node
}).collect();
BvhNode{
children,
models:Vec::new(),
aabb,
}
}
}

21
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pub type QNWorker<'a,Task>=CompatNWorker<'a,Task>;
pub type INWorker<'a,Task>=CompatNWorker<'a,Task>;
pub struct CompatNWorker<'a,Task>{
data:std::marker::PhantomData<Task>,
f:Box<dyn FnMut(Task)+Send+'a>,
}
impl<'a,Task> CompatNWorker<'a,Task>{
pub fn new(f:impl FnMut(Task)+Send+'a)->CompatNWorker<'a,Task>{
Self{
data:std::marker::PhantomData,
f:Box::new(f),
}
}
pub fn send(&mut self,task:Task)->Result<(),()>{
(self.f)(task);
Ok(())
}
}

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use crate::physics::Body;
use crate::model_physics::{GigaTime,FEV,MeshQuery,DirectedEdge,MinkowskiMesh,MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert};
use strafesnet_common::integer::{Time,Fixed,Ratio};
#[derive(Debug)]
enum Transition<F,E:DirectedEdge,V>{
Miss,
Next(FEV<F,E,V>,GigaTime),
Hit(F,GigaTime),
}
type MinkowskiFEV=FEV<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>;
type MinkowskiTransition=Transition<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>;
fn next_transition(fev:&MinkowskiFEV,body_time:GigaTime,mesh:&MinkowskiMesh,body:&Body,mut best_time:GigaTime)->MinkowskiTransition{
//conflicting derivative means it crosses in the wrong direction.
//if the transition time is equal to an already tested transition, do not replace the current best.
let mut best_transition=MinkowskiTransition::Miss;
match fev{
&MinkowskiFEV::Face(face_id)=>{
//test own face collision time, ignoring roots with zero or conflicting derivative
//n=face.normal d=face.dot
//n.a t^2+n.v t+n.p-d==0
let (n,d)=mesh.face_nd(face_id);
//TODO: use higher precision d value?
//use the mesh transform translation instead of baking it into the d value.
for dt in Fixed::<4,128>::zeroes2((n.dot(body.position)-d)*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
if body_time.le_ratio(dt)&&dt.lt_ratio(best_time)&&n.dot(body.extrapolated_velocity_ratio_dt(dt)).is_negative(){
best_time=dt;
best_transition=MinkowskiTransition::Hit(face_id,dt);
break;
}
}
//test each edge collision time, ignoring roots with zero or conflicting derivative
for &directed_edge_id in mesh.face_edges(face_id).iter(){
let edge_n=mesh.directed_edge_n(directed_edge_id);
let n=n.cross(edge_n);
let verts=mesh.edge_verts(directed_edge_id.as_undirected());
//WARNING: d is moved out of the *2 block because of adding two vertices!
//WARNING: precision is swept under the rug!
for dt in Fixed::<4,128>::zeroes2(n.dot(body.position*2-(mesh.vert(verts[0])+mesh.vert(verts[1]))).fix_4(),n.dot(body.velocity).fix_4()*2,n.dot(body.acceleration).fix_4()){
if body_time.le_ratio(dt)&&dt.lt_ratio(best_time)&&n.dot(body.extrapolated_velocity_ratio_dt(dt)).is_negative(){
best_time=dt;
best_transition=MinkowskiTransition::Next(MinkowskiFEV::Edge(directed_edge_id.as_undirected()),dt);
break;
}
}
}
//if none:
},
&MinkowskiFEV::Edge(edge_id)=>{
//test each face collision time, ignoring roots with zero or conflicting derivative
let edge_n=mesh.edge_n(edge_id);
let edge_verts=mesh.edge_verts(edge_id);
let delta_pos=body.position*2-(mesh.vert(edge_verts[0])+mesh.vert(edge_verts[1]));
for (i,&edge_face_id) in mesh.edge_faces(edge_id).iter().enumerate(){
let face_n=mesh.face_nd(edge_face_id).0;
//edge_n gets parity from the order of edge_faces
let n=face_n.cross(edge_n)*((i as i64)*2-1);
//WARNING yada yada d *2
for dt in Fixed::<4,128>::zeroes2(n.dot(delta_pos).fix_4(),n.dot(body.velocity).fix_4()*2,n.dot(body.acceleration).fix_4()){
if body_time.le_ratio(dt)&&dt.lt_ratio(best_time)&&n.dot(body.extrapolated_velocity_ratio_dt(dt)).is_negative(){
best_time=dt;
best_transition=MinkowskiTransition::Next(MinkowskiFEV::Face(edge_face_id),dt);
break;
}
}
}
//test each vertex collision time, ignoring roots with zero or conflicting derivative
for (i,&vert_id) in edge_verts.iter().enumerate(){
//vertex normal gets parity from vert index
let n=edge_n*(1-2*(i as i64));
for dt in Fixed::<2,64>::zeroes2((n.dot(body.position-mesh.vert(vert_id)))*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
if body_time.le_ratio(dt)&&dt.lt_ratio(best_time)&&n.dot(body.extrapolated_velocity_ratio_dt(dt)).is_negative(){
let dt=Ratio::new(dt.num.fix_4(),dt.den.fix_4());
best_time=dt;
best_transition=MinkowskiTransition::Next(MinkowskiFEV::Vert(vert_id),dt);
break;
}
}
}
//if none:
},
&MinkowskiFEV::Vert(vert_id)=>{
//test each edge collision time, ignoring roots with zero or conflicting derivative
for &directed_edge_id in mesh.vert_edges(vert_id).iter(){
//edge is directed away from vertex, but we want the dot product to turn out negative
let n=-mesh.directed_edge_n(directed_edge_id);
for dt in Fixed::<2,64>::zeroes2((n.dot(body.position-mesh.vert(vert_id)))*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
if body_time.le_ratio(dt)&&dt.lt_ratio(best_time)&&n.dot(body.extrapolated_velocity_ratio_dt(dt)).is_negative(){
let dt=Ratio::new(dt.num.fix_4(),dt.den.fix_4());
best_time=dt;
best_transition=MinkowskiTransition::Next(MinkowskiFEV::Edge(directed_edge_id.as_undirected()),dt);
break;
}
}
}
//if none:
},
}
best_transition
}
pub enum CrawlResult<F,E:DirectedEdge,V>{
Miss(FEV<F,E,V>),
Hit(F,GigaTime),
}
type MinkowskiCrawlResult=CrawlResult<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>;
pub fn crawl_fev(mut fev:MinkowskiFEV,mesh:&MinkowskiMesh,relative_body:&Body,start_time:Time,time_limit:Time)->MinkowskiCrawlResult{
let mut body_time={
let r=(start_time-relative_body.time).to_ratio();
Ratio::new(r.num.fix_4(),r.den.fix_4())
};
let time_limit={
let r=(time_limit-relative_body.time).to_ratio();
Ratio::new(r.num.fix_4(),r.den.fix_4())
};
for _ in 0..20{
match next_transition(&fev,body_time,mesh,relative_body,time_limit){
Transition::Miss=>return CrawlResult::Miss(fev),
Transition::Next(next_fev,next_time)=>(fev,body_time)=(next_fev,next_time),
Transition::Hit(face,time)=>return CrawlResult::Hit(face,time),
}
}
//TODO: fix all bugs
//println!("Too many iterations! Using default behaviour instead of crashing...");
CrawlResult::Miss(fev)
}

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use std::io::Read;
#[derive(Debug)]
pub enum ReadError{
#[cfg(feature="roblox")]
Roblox(strafesnet_rbx_loader::ReadError),
#[cfg(feature="source")]
Source(strafesnet_bsp_loader::ReadError),
#[cfg(feature="snf")]
StrafesNET(strafesnet_snf::Error),
#[cfg(feature="snf")]
StrafesNETMap(strafesnet_snf::map::Error),
Io(std::io::Error),
UnknownFileFormat,
}
impl std::fmt::Display for ReadError{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{self:?}")
}
}
impl std::error::Error for ReadError{}
pub enum DataStructure{
#[cfg(feature="roblox")]
Roblox(strafesnet_rbx_loader::Model),
#[cfg(feature="source")]
Source(strafesnet_bsp_loader::Bsp),
#[cfg(feature="snf")]
StrafesNET(strafesnet_common::map::CompleteMap),
}
pub fn read<R:Read+std::io::Seek>(input:R)->Result<DataStructure,ReadError>{
let mut buf=std::io::BufReader::new(input);
let peek=std::io::BufRead::fill_buf(&mut buf).map_err(ReadError::Io)?;
match &peek[0..4]{
#[cfg(feature="roblox")]
b"<rob"=>Ok(DataStructure::Roblox(strafesnet_rbx_loader::read(buf).map_err(ReadError::Roblox)?)),
#[cfg(feature="source")]
b"VBSP"=>Ok(DataStructure::Source(strafesnet_bsp_loader::read(buf).map_err(ReadError::Source)?)),
#[cfg(feature="snf")]
b"SNFM"=>Ok(DataStructure::StrafesNET(
strafesnet_snf::read_map(buf).map_err(ReadError::StrafesNET)?
.into_complete_map().map_err(ReadError::StrafesNETMap)?
)),
_=>Err(ReadError::UnknownFileFormat),
}
}
#[derive(Debug)]
pub enum LoadError{
ReadError(ReadError),
File(std::io::Error),
Io(std::io::Error),
}
impl std::fmt::Display for LoadError{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{self:?}")
}
}
impl std::error::Error for LoadError{}
pub fn load<P:AsRef<std::path::Path>>(path:P)->Result<strafesnet_common::map::CompleteMap,LoadError>{
//blocking because it's simpler...
let file=std::fs::File::open(path).map_err(LoadError::File)?;
match read(file).map_err(LoadError::ReadError)?{
#[cfg(feature="snf")]
DataStructure::StrafesNET(map)=>Ok(map),
#[cfg(feature="roblox")]
DataStructure::Roblox(model)=>{
let mut place=model.into_place();
place.run_scripts();
let mut loader=strafesnet_deferred_loader::roblox_legacy();
let (texture_loader,mesh_loader)=loader.get_inner_mut();
let map_step1=strafesnet_rbx_loader::convert(
&place,
|name|texture_loader.acquire_render_config_id(name),
|name|mesh_loader.acquire_mesh_id(name),
);
let meshpart_meshes=mesh_loader.load_meshes().map_err(LoadError::Io)?;
let map_step2=map_step1.add_meshpart_meshes_and_calculate_attributes(
meshpart_meshes.into_iter().map(|(mesh_id,loader_model)|
(mesh_id,strafesnet_rbx_loader::data::RobloxMeshBytes::new(loader_model.get()))
)
);
let (textures,render_configs)=loader.into_render_configs().map_err(LoadError::Io)?.consume();
let map=map_step2.add_render_configs_and_textures(
render_configs.into_iter(),
textures.into_iter().map(|(texture_id,texture)|
(texture_id,match texture{
strafesnet_deferred_loader::texture::Texture::ImageDDS(data)=>data,
})
)
);
Ok(map)
},
#[cfg(feature="source")]
DataStructure::Source(bsp)=>{
let mut loader=strafesnet_deferred_loader::source_legacy();
let (texture_loader,mesh_loader)=loader.get_inner_mut();
let map_step1=strafesnet_bsp_loader::convert(
&bsp,
|name|texture_loader.acquire_render_config_id(name),
|name|mesh_loader.acquire_mesh_id(name),
);
let prop_meshes=mesh_loader.load_meshes(bsp.as_ref());
let map_step2=map_step1.add_prop_meshes(
//the type conflagulator 9000
prop_meshes.into_iter().map(|(mesh_id,loader_model)|
(mesh_id,strafesnet_bsp_loader::data::ModelData{
mdl:strafesnet_bsp_loader::data::MdlData::new(loader_model.mdl.get()),
vtx:strafesnet_bsp_loader::data::VtxData::new(loader_model.vtx.get()),
vvd:strafesnet_bsp_loader::data::VvdData::new(loader_model.vvd.get()),
})
),
|name|texture_loader.acquire_render_config_id(name),
);
let (textures,render_configs)=loader.into_render_configs().map_err(LoadError::Io)?.consume();
let map=map_step2.add_render_configs_and_textures(
render_configs.into_iter(),
textures.into_iter().map(|(texture_id,texture)|
(texture_id,match texture{
strafesnet_deferred_loader::texture::Texture::ImageDDS(data)=>data,
})
),
);
Ok(map)
},
}
}

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@ -1,315 +0,0 @@
fn optional_features() -> wgpu::Features {
wgpu::Features::empty()
}
fn required_features() -> wgpu::Features {
wgpu::Features::empty()
}
fn required_downlevel_capabilities() -> wgpu::DownlevelCapabilities {
wgpu::DownlevelCapabilities {
flags: wgpu::DownlevelFlags::empty(),
shader_model: wgpu::ShaderModel::Sm5,
..wgpu::DownlevelCapabilities::default()
}
}
pub fn required_limits() -> wgpu::Limits {
wgpu::Limits::downlevel_webgl2_defaults() // These downlevel limits will allow the code to run on all possible hardware
}
struct GraphicsContextPartial1{
backends:wgpu::Backends,
instance:wgpu::Instance,
}
fn create_instance()->GraphicsContextPartial1{
let backends=wgpu::util::backend_bits_from_env().unwrap_or_else(wgpu::Backends::all);
let dx12_shader_compiler=wgpu::util::dx12_shader_compiler_from_env().unwrap_or_default();
GraphicsContextPartial1{
backends,
instance:wgpu::Instance::new(wgpu::InstanceDescriptor{
backends,
dx12_shader_compiler,
}),
}
}
impl GraphicsContextPartial1{
fn create_surface(self,window:&winit::window::Window)->Result<GraphicsContextPartial2,wgpu::CreateSurfaceError>{
Ok(GraphicsContextPartial2{
backends:self.backends,
instance:self.instance,
surface:unsafe{self.instance.create_surface(window)}?
})
}
}
struct GraphicsContextPartial2{
backends:wgpu::Backends,
instance:wgpu::Instance,
surface:wgpu::Surface,
}
impl GraphicsContextPartial2{
fn pick_adapter(self)->GraphicsContextPartial3{
let adapter;
let optional_features=optional_features();
let required_features=required_features();
//no helper function smh gotta write it myself
let adapters=self.instance.enumerate_adapters(self.backends);
let mut chosen_adapter=None;
let mut chosen_adapter_score=0;
for adapter in adapters {
if !adapter.is_surface_supported(&self.surface) {
continue;
}
let score=match adapter.get_info().device_type{
wgpu::DeviceType::IntegratedGpu=>3,
wgpu::DeviceType::DiscreteGpu=>4,
wgpu::DeviceType::VirtualGpu=>2,
wgpu::DeviceType::Other|wgpu::DeviceType::Cpu=>1,
};
let adapter_features=adapter.features();
if chosen_adapter_score<score&&adapter_features.contains(required_features) {
chosen_adapter_score=score;
chosen_adapter=Some(adapter);
}
}
if let Some(maybe_chosen_adapter)=chosen_adapter{
adapter=maybe_chosen_adapter;
}else{
panic!("No suitable GPU adapters found on the system!");
}
let adapter_info=adapter.get_info();
println!("Using {} ({:?})", adapter_info.name, adapter_info.backend);
let required_downlevel_capabilities=required_downlevel_capabilities();
let downlevel_capabilities=adapter.get_downlevel_capabilities();
assert!(
downlevel_capabilities.shader_model >= required_downlevel_capabilities.shader_model,
"Adapter does not support the minimum shader model required to run this example: {:?}",
required_downlevel_capabilities.shader_model
);
assert!(
downlevel_capabilities
.flags
.contains(required_downlevel_capabilities.flags),
"Adapter does not support the downlevel capabilities required to run this example: {:?}",
required_downlevel_capabilities.flags - downlevel_capabilities.flags
);
GraphicsContextPartial3{
instance:self.instance,
surface:self.surface,
adapter,
}
}
}
struct GraphicsContextPartial3{
instance:wgpu::Instance,
surface:wgpu::Surface,
adapter:wgpu::Adapter,
}
impl GraphicsContextPartial3{
fn request_device(self)->GraphicsContextPartial4{
let optional_features=optional_features();
let required_features=required_features();
// Make sure we use the texture resolution limits from the adapter, so we can support images the size of the surface.
let needed_limits=required_limits().using_resolution(self.adapter.limits());
let trace_dir=std::env::var("WGPU_TRACE");
let (device, queue)=pollster::block_on(self.adapter
.request_device(
&wgpu::DeviceDescriptor {
label: None,
features: (optional_features & self.adapter.features()) | required_features,
limits: needed_limits,
},
trace_dir.ok().as_ref().map(std::path::Path::new),
))
.expect("Unable to find a suitable GPU adapter!");
GraphicsContextPartial4{
instance:self.instance,
surface:self.surface,
adapter:self.adapter,
device,
queue,
}
}
}
struct GraphicsContextPartial4{
instance:wgpu::Instance,
surface:wgpu::Surface,
adapter:wgpu::Adapter,
device:wgpu::Device,
queue:wgpu::Queue,
}
impl GraphicsContextPartial4{
fn configure_surface(self,size:&winit::dpi::PhysicalSize<u32>)->GraphicsContext{
let mut config=self.surface
.get_default_config(&self.adapter, size.width, size.height)
.expect("Surface isn't supported by the adapter.");
let surface_view_format=config.format.add_srgb_suffix();
config.view_formats.push(surface_view_format);
self.surface.configure(&self.device, &config);
GraphicsContext{
instance:self.instance,
surface:self.surface,
adapter:self.adapter,
device:self.device,
queue:self.queue,
config,
}
}
}
pub struct GraphicsContext{
pub instance:wgpu::Instance,
pub surface:wgpu::Surface,
pub adapter:wgpu::Adapter,
pub device:wgpu::Device,
pub queue:wgpu::Queue,
pub config:wgpu::SurfaceConfiguration,
}
pub fn setup(title:&str)->GraphicsContextSetup{
let event_loop=winit::event_loop::EventLoop::new();
let window=crate::window::WindowState::create_window(title,&event_loop).unwrap();
println!("Initializing the surface...");
let partial_1=create_instance();
let partial_2=partial_1.create_surface(&window).unwrap();
let partial_3=partial_2.pick_adapter();
let partial_4=partial_3.request_device();
GraphicsContextSetup{
window,
event_loop,
partial_graphics_context:partial_4,
}
}
struct GraphicsContextSetup{
window:winit::window::Window,
event_loop:winit::event_loop::EventLoop<()>,
partial_graphics_context:GraphicsContextPartial4,
}
impl GraphicsContextSetup{
fn into_split(self)->(winit::window::Window,winit::event_loop::EventLoop<()>,GraphicsContext){
let size=self.window.inner_size();
//Steal values and drop self
(
self.window,
self.event_loop,
self.partial_graphics_context.configure_surface(&size),
)
}
pub fn start(self,mut global_state:crate::GlobalState){
let (window,event_loop,graphics_context)=self.into_split();
println!("Entering render loop...");
event_loop.run(move |event,_,control_flow|{
*control_flow=if cfg!(feature="metal-auto-capture"){
winit::event_loop::ControlFlow::Exit
}else{
winit::event_loop::ControlFlow::Poll
};
match event{
winit::event::Event::RedrawEventsCleared=>{
window.request_redraw();
}
winit::event::Event::WindowEvent {
event:
winit::event::WindowEvent::Resized(size)
| winit::event::WindowEvent::ScaleFactorChanged {
new_inner_size:&mut size,
..
},
..
} => {
// Once winit is fixed, the detection conditions here can be removed.
// https://github.com/rust-windowing/winit/issues/2876
// this has been fixed if I update winit (remove the if statement and only use the else case)
//drop adapter when you delete this
let max_dimension=graphics_context.adapter.limits().max_texture_dimension_2d;
if max_dimension<size.width||max_dimension<size.height{
println!(
"The resizing size {:?} exceeds the limit of {}.",
size,
max_dimension
);
}else{
println!("Resizing to {:?}",size);
graphics_context.config.width=size.width.max(1);
graphics_context.config.height=size.height.max(1);
window.resize(&graphics_context);
graphics_context.surface.configure(&graphics_context.device,&graphics_context.config);
}
}
winit::event::Event::WindowEvent{event,..}=>match event{
winit::event::WindowEvent::KeyboardInput{
input:
winit::event::KeyboardInput{
virtual_keycode:Some(winit::event::VirtualKeyCode::Escape),
state: winit::event::ElementState::Pressed,
..
},
..
}
|winit::event::WindowEvent::CloseRequested=>{
*control_flow=winit::event_loop::ControlFlow::Exit;
}
winit::event::WindowEvent::KeyboardInput{
input:
winit::event::KeyboardInput{
virtual_keycode:Some(winit::event::VirtualKeyCode::Scroll),
state: winit::event::ElementState::Pressed,
..
},
..
}=>{
println!("{:#?}",graphics_context.instance.generate_report());
}
_=>{
global_state.update(event);
}
},
winit::event::Event::DeviceEvent{
event,
..
} => {
global_state.device_event(event);
},
winit::event::Event::RedrawRequested(_)=>{
let frame=match graphics_context.surface.get_current_texture(){
Ok(frame)=>frame,
Err(_)=>{
graphics_context.surface.configure(&graphics_context.device,&graphics_context.config);
graphics_context.surface
.get_current_texture()
.expect("Failed to acquire next surface texture!")
}
};
let view=frame.texture.create_view(&wgpu::TextureViewDescriptor{
format:Some(graphics_context.config.view_formats[0]),
..wgpu::TextureViewDescriptor::default()
});
graphics.render(&view,&graphics_context.device,&graphics_context.queue);
frame.present();
}
_=>{}
}
});
}
}

65
src/graphics_worker.rs Normal file
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@ -0,0 +1,65 @@
pub enum Instruction{
Render(crate::graphics::FrameState),
//UpdateModel(crate::graphics::GraphicsModelUpdate),
Resize(winit::dpi::PhysicalSize<u32>,crate::settings::UserSettings),
ChangeMap(strafesnet_common::map::CompleteMap),
}
//Ideally the graphics thread worker description is:
/*
WorkerDescription{
input:Immediate,
output:Realtime(PoolOrdering::Ordered(3)),
}
*/
//up to three frames in flight, dropping new frame requests when all three are busy, and dropping output frames when one renders out of order
pub fn new<'a>(
mut graphics:crate::graphics::GraphicsState,
mut config:wgpu::SurfaceConfiguration,
surface:wgpu::Surface<'a>,
device:wgpu::Device,
queue:wgpu::Queue,
)->crate::compat_worker::INWorker<'a,Instruction>{
let mut resize=None;
crate::compat_worker::INWorker::new(move |ins:Instruction|{
match ins{
Instruction::ChangeMap(map)=>{
graphics.clear();
graphics.generate_models(&device,&queue,&map);
},
Instruction::Resize(size,user_settings)=>{
resize=Some((size,user_settings));
}
Instruction::Render(frame_state)=>{
if let Some((size,user_settings))=resize.take(){
println!("Resizing to {:?}",size);
let t0=std::time::Instant::now();
config.width=size.width.max(1);
config.height=size.height.max(1);
surface.configure(&device,&config);
graphics.resize(&device,&config,&user_settings);
println!("Resize took {:?}",t0.elapsed());
}
//this has to go deeper somehow
let frame=match surface.get_current_texture(){
Ok(frame)=>frame,
Err(_)=>{
surface.configure(&device,&config);
surface
.get_current_texture()
.expect("Failed to acquire next surface texture!")
}
};
let view=frame.texture.create_view(&wgpu::TextureViewDescriptor{
format:Some(config.view_formats[0]),
..wgpu::TextureViewDescriptor::default()
});
graphics.render(&view,&device,&queue,frame_state);
frame.present();
}
}
})
}

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@ -1,50 +0,0 @@
use crate::integer::Time;
#[derive(Debug)]
pub struct TimedInstruction<I>{
pub time:Time,
pub instruction:I,
}
pub trait InstructionEmitter<I>{
fn next_instruction(&self,time_limit:Time)->Option<TimedInstruction<I>>;
}
pub trait InstructionConsumer<I>{
fn process_instruction(&mut self, instruction:TimedInstruction<I>);
}
//PROPER PRIVATE FIELDS!!!
pub struct InstructionCollector<I>{
time:Time,
instruction:Option<I>,
}
impl<I> InstructionCollector<I>{
pub fn new(time:Time)->Self{
Self{
time,
instruction:None
}
}
pub fn collect(&mut self,instruction:Option<TimedInstruction<I>>){
match instruction{
Some(unwrap_instruction)=>{
if unwrap_instruction.time<self.time {
self.time=unwrap_instruction.time;
self.instruction=Some(unwrap_instruction.instruction);
}
},
None=>(),
}
}
pub fn instruction(self)->Option<TimedInstruction<I>>{
//STEAL INSTRUCTION AND DESTROY INSTRUCTIONCOLLECTOR
match self.instruction{
Some(instruction)=>Some(TimedInstruction{
time:self.time,
instruction
}),
None=>None,
}
}
}

View File

@ -1,953 +0,0 @@
//integer units
#[derive(Clone,Copy,Hash,PartialEq,PartialOrd,Debug)]
pub struct Time(i64);
impl Time{
pub const ZERO:Self=Self(0);
pub const ONE_SECOND:Self=Self(1_000_000_000);
pub const ONE_MILLISECOND:Self=Self(1_000_000);
pub const ONE_MICROSECOND:Self=Self(1_000);
pub const ONE_NANOSECOND:Self=Self(1);
#[inline]
pub fn from_secs(num:i64)->Self{
Self(Self::ONE_SECOND.0*num)
}
#[inline]
pub fn from_millis(num:i64)->Self{
Self(Self::ONE_MILLISECOND.0*num)
}
#[inline]
pub fn from_micros(num:i64)->Self{
Self(Self::ONE_MICROSECOND.0*num)
}
#[inline]
pub fn from_nanos(num:i64)->Self{
Self(Self::ONE_NANOSECOND.0*num)
}
//should I have checked subtraction? force all time variables to be positive?
#[inline]
pub fn nanos(&self)->i64{
self.0
}
}
impl From<Planar64> for Time{
#[inline]
fn from(value:Planar64)->Self{
Time((((value.0 as i128)*1_000_000_000)>>32) as i64)
}
}
impl std::fmt::Display for Time{
#[inline]
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{}s+{:09}ns",self.0/Self::ONE_SECOND.0,self.0%Self::ONE_SECOND.0)
}
}
impl std::ops::Neg for Time{
type Output=Time;
#[inline]
fn neg(self)->Self::Output {
Time(-self.0)
}
}
impl std::ops::Add<Time> for Time{
type Output=Time;
#[inline]
fn add(self,rhs:Self)->Self::Output {
Time(self.0+rhs.0)
}
}
impl std::ops::Sub<Time> for Time{
type Output=Time;
#[inline]
fn sub(self,rhs:Self)->Self::Output {
Time(self.0-rhs.0)
}
}
impl std::ops::Mul<Time> for Time{
type Output=Time;
#[inline]
fn mul(self,rhs:Time)->Self::Output{
Self((((self.0 as i128)*(rhs.0 as i128))/1_000_000_000) as i64)
}
}
impl std::ops::Div<i64> for Time{
type Output=Time;
#[inline]
fn div(self,rhs:i64)->Self::Output {
Time(self.0/rhs)
}
}
#[inline]
const fn gcd(mut a:u64,mut b:u64)->u64{
while b!=0{
(a,b)=(b,a.rem_euclid(b));
};
a
}
#[derive(Clone,Hash)]
pub struct Ratio64{
num:i64,
den:u64,
}
impl Ratio64{
pub const ZERO:Self=Ratio64{num:0,den:1};
pub const ONE:Self=Ratio64{num:1,den:1};
#[inline]
pub const fn new(num:i64,den:u64)->Option<Ratio64>{
if den==0{
None
}else{
let d=gcd(num.unsigned_abs(),den);
Some(Self{num:num/d as i64,den:den/d})
}
}
#[inline]
pub fn mul_int(&self,rhs:i64)->i64{
rhs*self.num/self.den as i64
}
#[inline]
pub fn rhs_div_int(&self,rhs:i64)->i64{
rhs*self.den as i64/self.num
}
#[inline]
pub fn mul_ref(&self,rhs:&Ratio64)->Ratio64{
let (num,den)=(self.num*rhs.num,self.den*rhs.den);
let d=gcd(num.unsigned_abs(),den);
Self{
num:num/d as i64,
den:den/d,
}
}
}
//from num_traits crate
#[inline]
fn integer_decode_f32(f: f32) -> (u64, i16, i8) {
let bits: u32 = f.to_bits();
let sign: i8 = if bits >> 31 == 0 { 1 } else { -1 };
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, i8) {
let bits: u64 = f.to_bits();
let sign: i8 = if bits >> 63 == 0 { 1 } else { -1 };
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)]
pub enum Ratio64TryFromFloatError{
Nan,
Infinite,
Subnormal,
HighlyNegativeExponent(i16),
HighlyPositiveExponent(i16),
}
const MAX_DENOMINATOR:u128=u64::MAX as u128;
#[inline]
fn ratio64_from_mes((m,e,s):(u64,i16,i8))->Result<Ratio64,Ratio64TryFromFloatError>{
if e< -127{
//this can also just be zero
Err(Ratio64TryFromFloatError::HighlyNegativeExponent(e))
}else if e< -63{
//approximate input ratio within denominator limit
let mut target_num=m as u128;
let mut target_den=1u128<<-e;
let mut num=1;
let mut den=0;
let mut prev_num=0;
let mut prev_den=1;
while target_den!=0{
let whole=target_num/target_den;
(target_num,target_den)=(target_den,target_num-whole*target_den);
let new_num=whole*num+prev_num;
let new_den=whole*den+prev_den;
if MAX_DENOMINATOR<new_den{
break;
}else{
(prev_num,prev_den)=(num,den);
(num,den)=(new_num,new_den);
}
}
Ok(Ratio64::new(num as i64,den as u64).unwrap())
}else if e<0{
Ok(Ratio64::new((m as i64)*(s as i64),1<<-e).unwrap())
}else if (64-m.leading_zeros() as i16)+e<64{
Ok(Ratio64::new((m as i64)*(s as i64)*(1<<e),1).unwrap())
}else{
Err(Ratio64TryFromFloatError::HighlyPositiveExponent(e))
}
}
impl TryFrom<f32> for Ratio64{
type Error=Ratio64TryFromFloatError;
#[inline]
fn try_from(value:f32)->Result<Self,Self::Error>{
match value.classify(){
std::num::FpCategory::Nan=>Err(Self::Error::Nan),
std::num::FpCategory::Infinite=>Err(Self::Error::Infinite),
std::num::FpCategory::Zero=>Ok(Self::ZERO),
std::num::FpCategory::Subnormal=>Err(Self::Error::Subnormal),
std::num::FpCategory::Normal=>ratio64_from_mes(integer_decode_f32(value)),
}
}
}
impl TryFrom<f64> for Ratio64{
type Error=Ratio64TryFromFloatError;
#[inline]
fn try_from(value:f64)->Result<Self,Self::Error>{
match value.classify(){
std::num::FpCategory::Nan=>Err(Self::Error::Nan),
std::num::FpCategory::Infinite=>Err(Self::Error::Infinite),
std::num::FpCategory::Zero=>Ok(Self::ZERO),
std::num::FpCategory::Subnormal=>Err(Self::Error::Subnormal),
std::num::FpCategory::Normal=>ratio64_from_mes(integer_decode_f64(value)),
}
}
}
impl std::ops::Mul<Ratio64> for Ratio64{
type Output=Ratio64;
#[inline]
fn mul(self,rhs:Ratio64)->Self::Output{
let (num,den)=(self.num*rhs.num,self.den*rhs.den);
let d=gcd(num.unsigned_abs(),den);
Self{
num:num/d as i64,
den:den/d,
}
}
}
impl std::ops::Mul<i64> for Ratio64{
type Output=Ratio64;
#[inline]
fn mul(self,rhs:i64)->Self::Output {
Self{
num:self.num*rhs,
den:self.den,
}
}
}
impl std::ops::Div<u64> for Ratio64{
type Output=Ratio64;
#[inline]
fn div(self,rhs:u64)->Self::Output {
Self{
num:self.num,
den:self.den*rhs,
}
}
}
#[derive(Clone,Hash)]
pub struct Ratio64Vec2{
pub x:Ratio64,
pub y:Ratio64,
}
impl Ratio64Vec2{
pub const ONE:Self=Self{x:Ratio64::ONE,y:Ratio64::ONE};
#[inline]
pub fn new(x:Ratio64,y:Ratio64)->Self{
Self{x,y}
}
#[inline]
pub fn mul_int(&self,rhs:glam::I64Vec2)->glam::I64Vec2{
glam::i64vec2(
self.x.mul_int(rhs.x),
self.y.mul_int(rhs.y),
)
}
}
impl std::ops::Mul<i64> for Ratio64Vec2{
type Output=Ratio64Vec2;
#[inline]
fn mul(self,rhs:i64)->Self::Output {
Self{
x:self.x*rhs,
y:self.y*rhs,
}
}
}
///[-pi,pi) = [-2^31,2^31-1]
#[derive(Clone,Copy,Hash)]
pub struct Angle32(i32);
impl Angle32{
pub const FRAC_PI_2:Self=Self(1<<30);
pub const PI:Self=Self(-1<<31);
#[inline]
pub fn wrap_from_i64(theta:i64)->Self{
//take lower bits
//note: this was checked on compiler explorer and compiles to 1 instruction!
Self(i32::from_ne_bytes(((theta&((1<<32)-1)) as u32).to_ne_bytes()))
}
#[inline]
pub fn clamp_from_i64(theta:i64)->Self{
//the assembly is a bit confusing for this, I thought it was checking the same thing twice
//but it's just checking and then overwriting the value for both upper and lower bounds.
Self(theta.clamp(i32::MIN as i64,i32::MAX as i64) as i32)
}
#[inline]
pub fn get(&self)->i32{
self.0
}
/// Clamps the value towards the midpoint of the range.
/// Note that theta_min can be larger than theta_max and it will wrap clamp the other way around
#[inline]
pub fn clamp(&self,theta_min:Self,theta_max:Self)->Self{
//((max-min as u32)/2 as i32)+min
let midpoint=((
u32::from_ne_bytes(theta_max.0.to_ne_bytes())
.wrapping_sub(u32::from_ne_bytes(theta_min.0.to_ne_bytes()))
/2
) as i32)//(u32::MAX/2) as i32 ALWAYS works
.wrapping_add(theta_min.0);
//(theta-mid).clamp(max-mid,min-mid)+mid
Self(
self.0.wrapping_sub(midpoint)
.max(theta_min.0.wrapping_sub(midpoint))
.min(theta_max.0.wrapping_sub(midpoint))
.wrapping_add(midpoint)
)
}
/*
#[inline]
pub fn cos(&self)->Unit32{
//TODO: fix this rounding towards 0
Unit32(unsafe{((self.0 as f64*ANGLE32_TO_FLOAT64_RADIANS).cos()*UNIT32_ONE_FLOAT64).to_int_unchecked()})
}
#[inline]
pub fn sin(&self)->Unit32{
//TODO: fix this rounding towards 0
Unit32(unsafe{((self.0 as f64*ANGLE32_TO_FLOAT64_RADIANS).sin()*UNIT32_ONE_FLOAT64).to_int_unchecked()})
}
*/
}
const ANGLE32_TO_FLOAT64_RADIANS:f64=std::f64::consts::PI/((1i64<<31) as f64);
impl Into<f32> for Angle32{
#[inline]
fn into(self)->f32{
(self.0 as f64*ANGLE32_TO_FLOAT64_RADIANS) as f32
}
}
impl std::ops::Neg for Angle32{
type Output=Angle32;
#[inline]
fn neg(self)->Self::Output{
Angle32(self.0.wrapping_neg())
}
}
impl std::ops::Add<Angle32> for Angle32{
type Output=Angle32;
#[inline]
fn add(self,rhs:Self)->Self::Output {
Angle32(self.0.wrapping_add(rhs.0))
}
}
impl std::ops::Sub<Angle32> for Angle32{
type Output=Angle32;
#[inline]
fn sub(self,rhs:Self)->Self::Output {
Angle32(self.0.wrapping_sub(rhs.0))
}
}
impl std::ops::Mul<i32> for Angle32{
type Output=Angle32;
#[inline]
fn mul(self,rhs:i32)->Self::Output {
Angle32(self.0.wrapping_mul(rhs))
}
}
impl std::ops::Mul<Angle32> for Angle32{
type Output=Angle32;
#[inline]
fn mul(self,rhs:Self)->Self::Output {
Angle32(self.0.wrapping_mul(rhs.0))
}
}
/* Unit type unused for now, may revive it for map files
///[-1.0,1.0] = [-2^30,2^30]
pub struct Unit32(i32);
impl Unit32{
#[inline]
pub fn as_planar64(&self) -> Planar64{
Planar64(4*(self.0 as i64))
}
}
const UNIT32_ONE_FLOAT64=((1<<30) as f64);
///[-1.0,1.0] = [-2^30,2^30]
pub struct Unit32Vec3(glam::IVec3);
impl TryFrom<[f32;3]> for Unit32Vec3{
type Error=Unit32TryFromFloatError;
fn try_from(value:[f32;3])->Result<Self,Self::Error>{
Ok(Self(glam::ivec3(
Unit32::try_from(Planar64::try_from(value[0])?)?.0,
Unit32::try_from(Planar64::try_from(value[1])?)?.0,
Unit32::try_from(Planar64::try_from(value[2])?)?.0,
)))
}
}
*/
///[-1.0,1.0] = [-2^32,2^32]
#[derive(Clone,Copy,Hash,Eq,Ord,PartialEq,PartialOrd)]
pub struct Planar64(i64);
impl Planar64{
pub const ZERO:Self=Self(0);
pub const ONE:Self=Self(1<<32);
#[inline]
pub const fn int(num:i32)->Self{
Self(Self::ONE.0*num as i64)
}
#[inline]
pub const fn raw(num:i64)->Self{
Self(num)
}
#[inline]
pub const fn get(&self)->i64{
self.0
}
pub fn sqrt(&self)->Self{
Planar64(unsafe{(((self.0 as i128)<<32) as f64).sqrt().to_int_unchecked()})
}
}
const PLANAR64_ONE_FLOAT32:f32=(1u64<<32) as f32;
const PLANAR64_CONVERT_TO_FLOAT32:f32=1.0/PLANAR64_ONE_FLOAT32;
const PLANAR64_ONE_FLOAT64:f64=(1u64<<32) as f64;
impl Into<f32> for Planar64{
#[inline]
fn into(self)->f32{
self.0 as f32*PLANAR64_CONVERT_TO_FLOAT32
}
}
impl From<Ratio64> for Planar64{
#[inline]
fn from(ratio:Ratio64)->Self{
Self((((ratio.num as i128)<<32)/ratio.den as i128) as i64)
}
}
#[derive(Debug)]
pub enum Planar64TryFromFloatError{
Nan,
Infinite,
Subnormal,
HighlyNegativeExponent(i16),
HighlyPositiveExponent(i16),
}
#[inline]
fn planar64_from_mes((m,e,s):(u64,i16,i8))->Result<Planar64,Planar64TryFromFloatError>{
let e32=e+32;
if e32<0&&(m>>-e32)==0{//shifting m will underflow to 0
Ok(Planar64::ZERO)
// println!("m{} e{} s{}",m,e,s);
// println!("f={}",(m as f64)*(2.0f64.powf(e as f64))*(s as f64));
// Err(Planar64TryFromFloatError::HighlyNegativeExponent(e))
}else if (64-m.leading_zeros() as i16)+e32<64{//shifting m will not overflow
if e32<0{
Ok(Planar64((m as i64)*(s as i64)>>-e32))
}else{
Ok(Planar64((m as i64)*(s as i64)<<e32))
}
}else{//if shifting m will overflow (prev check failed)
Err(Planar64TryFromFloatError::HighlyPositiveExponent(e))
}
}
impl TryFrom<f32> for Planar64{
type Error=Planar64TryFromFloatError;
#[inline]
fn try_from(value:f32)->Result<Self,Self::Error>{
match value.classify(){
std::num::FpCategory::Nan=>Err(Self::Error::Nan),
std::num::FpCategory::Infinite=>Err(Self::Error::Infinite),
std::num::FpCategory::Zero=>Ok(Self::ZERO),
std::num::FpCategory::Subnormal=>Err(Self::Error::Subnormal),
std::num::FpCategory::Normal=>planar64_from_mes(integer_decode_f32(value)),
}
}
}
impl TryFrom<f64> for Planar64{
type Error=Planar64TryFromFloatError;
#[inline]
fn try_from(value:f64)->Result<Self,Self::Error>{
match value.classify(){
std::num::FpCategory::Nan=>Err(Self::Error::Nan),
std::num::FpCategory::Infinite=>Err(Self::Error::Infinite),
std::num::FpCategory::Zero=>Ok(Self::ZERO),
std::num::FpCategory::Subnormal=>Err(Self::Error::Subnormal),
std::num::FpCategory::Normal=>planar64_from_mes(integer_decode_f64(value)),
}
}
}
impl std::fmt::Display for Planar64{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{:.3}",
Into::<f32>::into(*self),
)
}
}
impl std::ops::Neg for Planar64{
type Output=Planar64;
#[inline]
fn neg(self)->Self::Output{
Planar64(-self.0)
}
}
impl std::ops::Add<Planar64> for Planar64{
type Output=Planar64;
#[inline]
fn add(self, rhs: Self) -> Self::Output {
Planar64(self.0+rhs.0)
}
}
impl std::ops::Sub<Planar64> for Planar64{
type Output=Planar64;
#[inline]
fn sub(self, rhs: Self) -> Self::Output {
Planar64(self.0-rhs.0)
}
}
impl std::ops::Mul<i64> for Planar64{
type Output=Planar64;
#[inline]
fn mul(self, rhs: i64) -> Self::Output {
Planar64(self.0*rhs)
}
}
impl std::ops::Mul<Planar64> for Planar64{
type Output=Planar64;
#[inline]
fn mul(self, rhs: Self) -> Self::Output {
Planar64(((self.0 as i128*rhs.0 as i128)>>32) as i64)
}
}
impl std::ops::Mul<Time> for Planar64{
type Output=Planar64;
#[inline]
fn mul(self,rhs:Time)->Self::Output{
Planar64(((self.0 as i128*rhs.0 as i128)/1_000_000_000) as i64)
}
}
impl std::ops::Div<i64> for Planar64{
type Output=Planar64;
#[inline]
fn div(self, rhs: i64) -> Self::Output {
Planar64(self.0/rhs)
}
}
impl std::ops::Div<Planar64> for Planar64{
type Output=Planar64;
#[inline]
fn div(self, rhs: Planar64) -> Self::Output {
Planar64((((self.0 as i128)<<32)/rhs.0 as i128) as i64)
}
}
// impl PartialOrd<i64> for Planar64{
// fn partial_cmp(&self, other: &i64) -> Option<std::cmp::Ordering> {
// self.0.partial_cmp(other)
// }
// }
///[-1.0,1.0] = [-2^32,2^32]
#[derive(Clone,Copy,Default,Hash,Eq,PartialEq)]
pub struct Planar64Vec3(glam::I64Vec3);
impl Planar64Vec3{
pub const ZERO:Self=Planar64Vec3(glam::I64Vec3::ZERO);
pub const ONE:Self=Self::int(1,1,1);
pub const X:Self=Self::int(1,0,0);
pub const Y:Self=Self::int(0,1,0);
pub const Z:Self=Self::int(0,0,1);
pub const NEG_X:Self=Self::int(-1,0,0);
pub const NEG_Y:Self=Self::int(0,-1,0);
pub const NEG_Z:Self=Self::int(0,0,-1);
pub const MIN:Self=Planar64Vec3(glam::I64Vec3::MIN);
pub const MAX:Self=Planar64Vec3(glam::I64Vec3::MAX);
#[inline]
pub const fn int(x:i32,y:i32,z:i32)->Self{
Self(glam::i64vec3((x as i64)<<32,(y as i64)<<32,(z as i64)<<32))
}
#[inline]
pub const fn raw(x:i64,y:i64,z:i64)->Self{
Self(glam::i64vec3(x,y,z))
}
#[inline]
pub fn x(&self)->Planar64{
Planar64(self.0.x)
}
#[inline]
pub fn y(&self)->Planar64{
Planar64(self.0.y)
}
#[inline]
pub fn z(&self)->Planar64{
Planar64(self.0.z)
}
#[inline]
pub fn min(&self,rhs:Self)->Self{
Self(glam::i64vec3(
self.0.x.min(rhs.0.x),
self.0.y.min(rhs.0.y),
self.0.z.min(rhs.0.z),
))
}
#[inline]
pub fn max(&self,rhs:Self)->Self{
Self(glam::i64vec3(
self.0.x.max(rhs.0.x),
self.0.y.max(rhs.0.y),
self.0.z.max(rhs.0.z),
))
}
#[inline]
pub fn midpoint(&self,rhs:Self)->Self{
Self((self.0+rhs.0)/2)
}
#[inline]
pub fn cmplt(&self,rhs:Self)->glam::BVec3{
self.0.cmplt(rhs.0)
}
#[inline]
pub fn dot(&self,rhs:Self)->Planar64{
Planar64(((
(self.0.x as i128)*(rhs.0.x as i128)+
(self.0.y as i128)*(rhs.0.y as i128)+
(self.0.z as i128)*(rhs.0.z as i128)
)>>32) as i64)
}
#[inline]
pub fn length(&self)->Planar64{
let radicand=(self.0.x as i128)*(self.0.x as i128)+(self.0.y as i128)*(self.0.y as i128)+(self.0.z as i128)*(self.0.z as i128);
Planar64(unsafe{(radicand as f64).sqrt().to_int_unchecked()})
}
#[inline]
pub fn with_length(&self,length:Planar64)->Self{
let radicand=(self.0.x as i128)*(self.0.x as i128)+(self.0.y as i128)*(self.0.y as i128)+(self.0.z as i128)*(self.0.z as i128);
let self_length:i128=unsafe{(radicand as f64).sqrt().to_int_unchecked()};
//self.0*length/self_length
Planar64Vec3(
glam::i64vec3(
((self.0.x as i128)*(length.0 as i128)/self_length) as i64,
((self.0.y as i128)*(length.0 as i128)/self_length) as i64,
((self.0.z as i128)*(length.0 as i128)/self_length) as i64,
)
)
}
}
impl Into<glam::Vec3> for Planar64Vec3{
#[inline]
fn into(self)->glam::Vec3{
glam::vec3(
self.0.x as f32,
self.0.y as f32,
self.0.z as f32,
)*PLANAR64_CONVERT_TO_FLOAT32
}
}
impl TryFrom<[f32;3]> for Planar64Vec3{
type Error=Planar64TryFromFloatError;
#[inline]
fn try_from(value:[f32;3])->Result<Self,Self::Error>{
Ok(Self(glam::i64vec3(
Planar64::try_from(value[0])?.0,
Planar64::try_from(value[1])?.0,
Planar64::try_from(value[2])?.0,
)))
}
}
impl TryFrom<glam::Vec3A> for Planar64Vec3{
type Error=Planar64TryFromFloatError;
#[inline]
fn try_from(value:glam::Vec3A)->Result<Self,Self::Error>{
Ok(Self(glam::i64vec3(
Planar64::try_from(value.x)?.0,
Planar64::try_from(value.y)?.0,
Planar64::try_from(value.z)?.0,
)))
}
}
impl std::fmt::Display for Planar64Vec3{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"{:.3},{:.3},{:.3}",
Into::<f32>::into(self.x()),Into::<f32>::into(self.y()),Into::<f32>::into(self.z()),
)
}
}
impl std::ops::Neg for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn neg(self)->Self::Output{
Planar64Vec3(-self.0)
}
}
impl std::ops::Add<Planar64Vec3> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn add(self,rhs:Planar64Vec3) -> Self::Output {
Planar64Vec3(self.0+rhs.0)
}
}
impl std::ops::AddAssign<Planar64Vec3> for Planar64Vec3{
#[inline]
fn add_assign(&mut self,rhs:Planar64Vec3){
*self=*self+rhs
}
}
impl std::ops::Sub<Planar64Vec3> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn sub(self,rhs:Planar64Vec3) -> Self::Output {
Planar64Vec3(self.0-rhs.0)
}
}
impl std::ops::SubAssign<Planar64Vec3> for Planar64Vec3{
#[inline]
fn sub_assign(&mut self,rhs:Planar64Vec3){
*self=*self-rhs
}
}
impl std::ops::Mul<Planar64Vec3> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn mul(self, rhs: Planar64Vec3) -> Self::Output {
Planar64Vec3(glam::i64vec3(
(((self.0.x as i128)*(rhs.0.x as i128))>>32) as i64,
(((self.0.y as i128)*(rhs.0.y as i128))>>32) as i64,
(((self.0.z as i128)*(rhs.0.z as i128))>>32) as i64
))
}
}
impl std::ops::Mul<Planar64> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn mul(self, rhs: Planar64) -> Self::Output {
Planar64Vec3(glam::i64vec3(
(((self.0.x as i128)*(rhs.0 as i128))>>32) as i64,
(((self.0.y as i128)*(rhs.0 as i128))>>32) as i64,
(((self.0.z as i128)*(rhs.0 as i128))>>32) as i64
))
}
}
impl std::ops::Mul<i64> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn mul(self,rhs:i64)->Self::Output {
Planar64Vec3(glam::i64vec3(
self.0.x*rhs,
self.0.y*rhs,
self.0.z*rhs
))
}
}
impl std::ops::Mul<Time> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn mul(self,rhs:Time)->Self::Output{
Planar64Vec3(glam::i64vec3(
(((self.0.x as i128)*(rhs.0 as i128))/1_000_000_000) as i64,
(((self.0.y as i128)*(rhs.0 as i128))/1_000_000_000) as i64,
(((self.0.z as i128)*(rhs.0 as i128))/1_000_000_000) as i64
))
}
}
impl std::ops::Div<i64> for Planar64Vec3{
type Output=Planar64Vec3;
#[inline]
fn div(self,rhs:i64)->Self::Output{
Planar64Vec3(glam::i64vec3(
self.0.x/rhs,
self.0.y/rhs,
self.0.z/rhs,
))
}
}
///[-1.0,1.0] = [-2^32,2^32]
#[derive(Clone,Copy)]
pub struct Planar64Mat3{
x_axis:Planar64Vec3,
y_axis:Planar64Vec3,
z_axis:Planar64Vec3,
}
impl Default for Planar64Mat3{
#[inline]
fn default() -> Self {
Self{
x_axis:Planar64Vec3::X,
y_axis:Planar64Vec3::Y,
z_axis:Planar64Vec3::Z,
}
}
}
impl std::ops::Mul<Planar64Vec3> for Planar64Mat3{
type Output=Planar64Vec3;
#[inline]
fn mul(self,rhs:Planar64Vec3) -> Self::Output {
self.x_axis*rhs.x()
+self.y_axis*rhs.y()
+self.z_axis*rhs.z()
}
}
impl Planar64Mat3{
#[inline]
pub fn from_cols(x_axis:Planar64Vec3,y_axis:Planar64Vec3,z_axis:Planar64Vec3)->Self{
Self{
x_axis,
y_axis,
z_axis,
}
}
pub const fn int_from_cols_array(array:[i32;9])->Self{
Self{
x_axis:Planar64Vec3::int(array[0],array[1],array[2]),
y_axis:Planar64Vec3::int(array[3],array[4],array[5]),
z_axis:Planar64Vec3::int(array[6],array[7],array[8]),
}
}
#[inline]
pub fn from_rotation_yx(yaw:Angle32,pitch:Angle32)->Self{
let xtheta=yaw.0 as f64*ANGLE32_TO_FLOAT64_RADIANS;
let (xs,xc)=xtheta.sin_cos();
let (xc,xs)=(xc*PLANAR64_ONE_FLOAT64,xs*PLANAR64_ONE_FLOAT64);
let ytheta=pitch.0 as f64*ANGLE32_TO_FLOAT64_RADIANS;
let (ys,yc)=ytheta.sin_cos();
let (yc,ys)=(yc*PLANAR64_ONE_FLOAT64,ys*PLANAR64_ONE_FLOAT64);
//TODO: fix this rounding towards 0
let (xc,xs):(i64,i64)=(unsafe{xc.to_int_unchecked()},unsafe{xs.to_int_unchecked()});
let (yc,ys):(i64,i64)=(unsafe{yc.to_int_unchecked()},unsafe{ys.to_int_unchecked()});
Self::from_cols(
Planar64Vec3(glam::i64vec3(xc,0,-xs)),
Planar64Vec3(glam::i64vec3(((xs as i128*ys as i128)>>32) as i64,yc,((xc as i128*ys as i128)>>32) as i64)),
Planar64Vec3(glam::i64vec3(((xs as i128*yc as i128)>>32) as i64,-ys,((xc as i128*yc as i128)>>32) as i64)),
)
}
#[inline]
pub fn from_rotation_y(angle:Angle32)->Self{
let theta=angle.0 as f64*ANGLE32_TO_FLOAT64_RADIANS;
let (s,c)=theta.sin_cos();
let (c,s)=(c*PLANAR64_ONE_FLOAT64,s*PLANAR64_ONE_FLOAT64);
//TODO: fix this rounding towards 0
let (c,s):(i64,i64)=(unsafe{c.to_int_unchecked()},unsafe{s.to_int_unchecked()});
Self::from_cols(
Planar64Vec3(glam::i64vec3(c,0,-s)),
Planar64Vec3::Y,
Planar64Vec3(glam::i64vec3(s,0,c)),
)
}
}
impl Into<glam::Mat3> for Planar64Mat3{
#[inline]
fn into(self)->glam::Mat3{
glam::Mat3::from_cols(
self.x_axis.into(),
self.y_axis.into(),
self.z_axis.into(),
)
}
}
impl TryFrom<glam::Mat3A> for Planar64Mat3{
type Error=Planar64TryFromFloatError;
#[inline]
fn try_from(value:glam::Mat3A)->Result<Self,Self::Error>{
Ok(Self{
x_axis:Planar64Vec3::try_from(value.x_axis)?,
y_axis:Planar64Vec3::try_from(value.y_axis)?,
z_axis:Planar64Vec3::try_from(value.z_axis)?,
})
}
}
impl std::fmt::Display for Planar64Mat3{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"\n{:.3},{:.3},{:.3}\n{:.3},{:.3},{:.3}\n{:.3},{:.3},{:.3}",
Into::<f32>::into(self.x_axis.x()),Into::<f32>::into(self.x_axis.y()),Into::<f32>::into(self.x_axis.z()),
Into::<f32>::into(self.y_axis.x()),Into::<f32>::into(self.y_axis.y()),Into::<f32>::into(self.y_axis.z()),
Into::<f32>::into(self.z_axis.x()),Into::<f32>::into(self.z_axis.y()),Into::<f32>::into(self.z_axis.z()),
)
}
}
impl std::ops::Div<i64> for Planar64Mat3{
type Output=Planar64Mat3;
#[inline]
fn div(self,rhs:i64)->Self::Output{
Planar64Mat3{
x_axis:self.x_axis/rhs,
y_axis:self.y_axis/rhs,
z_axis:self.z_axis/rhs,
}
}
}
///[-1.0,1.0] = [-2^32,2^32]
#[derive(Clone,Copy,Default)]
pub struct Planar64Affine3{
pub matrix3:Planar64Mat3,//includes scale above 1
pub translation:Planar64Vec3,
}
impl Planar64Affine3{
#[inline]
pub fn new(matrix3:Planar64Mat3,translation:Planar64Vec3)->Self{
Self{matrix3,translation}
}
#[inline]
pub fn transform_point3(&self,point:Planar64Vec3) -> Planar64Vec3{
Planar64Vec3(
self.translation.0
+(self.matrix3.x_axis*point.x()).0
+(self.matrix3.y_axis*point.y()).0
+(self.matrix3.z_axis*point.z()).0
)
}
}
impl Into<glam::Mat4> for Planar64Affine3{
#[inline]
fn into(self)->glam::Mat4{
glam::Mat4::from_cols_array(&[
self.matrix3.x_axis.0.x as f32,self.matrix3.x_axis.0.y as f32,self.matrix3.x_axis.0.z as f32,0.0,
self.matrix3.y_axis.0.x as f32,self.matrix3.y_axis.0.y as f32,self.matrix3.y_axis.0.z as f32,0.0,
self.matrix3.z_axis.0.x as f32,self.matrix3.z_axis.0.y as f32,self.matrix3.z_axis.0.z as f32,0.0,
self.translation.0.x as f32,self.translation.0.y as f32,self.translation.0.z as f32,PLANAR64_ONE_FLOAT32
])*PLANAR64_CONVERT_TO_FLOAT32
}
}
impl TryFrom<glam::Affine3A> for Planar64Affine3{
type Error=Planar64TryFromFloatError;
fn try_from(value: glam::Affine3A)->Result<Self, Self::Error> {
Ok(Self{
matrix3:Planar64Mat3::try_from(value.matrix3)?,
translation:Planar64Vec3::try_from(value.translation)?
})
}
}
impl std::fmt::Display for Planar64Affine3{
fn fmt(&self,f:&mut std::fmt::Formatter<'_>)->std::fmt::Result{
write!(f,"translation: {:.3},{:.3},{:.3}\nmatrix3:\n{:.3},{:.3},{:.3}\n{:.3},{:.3},{:.3}\n{:.3},{:.3},{:.3}",
Into::<f32>::into(self.translation.x()),Into::<f32>::into(self.translation.y()),Into::<f32>::into(self.translation.z()),
Into::<f32>::into(self.matrix3.x_axis.x()),Into::<f32>::into(self.matrix3.x_axis.y()),Into::<f32>::into(self.matrix3.x_axis.z()),
Into::<f32>::into(self.matrix3.y_axis.x()),Into::<f32>::into(self.matrix3.y_axis.y()),Into::<f32>::into(self.matrix3.y_axis.z()),
Into::<f32>::into(self.matrix3.z_axis.x()),Into::<f32>::into(self.matrix3.z_axis.y()),Into::<f32>::into(self.matrix3.z_axis.z()),
)
}
}
#[test]
fn test_sqrt(){
let r=Planar64::int(400);
println!("r{}",r.get());
let s=r.sqrt();
println!("s{}",s.get());
}

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@ -1,504 +0,0 @@
use crate::primitives;
use crate::integer::{Planar64,Planar64Vec3,Planar64Mat3,Planar64Affine3};
fn class_is_a(class: &str, superclass: &str) -> bool {
if class==superclass {
return true
}
let class_descriptor=rbx_reflection_database::get().classes.get(class);
if let Some(descriptor) = &class_descriptor {
if let Some(class_super) = &descriptor.superclass {
return class_is_a(&class_super, superclass)
}
}
return false
}
fn recursive_collect_superclass(objects: &mut std::vec::Vec<rbx_dom_weak::types::Ref>,dom: &rbx_dom_weak::WeakDom, instance: &rbx_dom_weak::Instance, superclass: &str){
for &referent in instance.children() {
if let Some(c) = dom.get_by_ref(referent) {
if class_is_a(c.class.as_str(), superclass) {
objects.push(c.referent());//copy ref
}
recursive_collect_superclass(objects,dom,c,superclass);
}
}
}
fn get_texture_refs(dom:&rbx_dom_weak::WeakDom) -> Vec<rbx_dom_weak::types::Ref>{
let mut objects = std::vec::Vec::new();
recursive_collect_superclass(&mut objects, dom, dom.root(),"Decal");
//get ids
//clear vec
//next class
objects
}
fn planar64_affine3_from_roblox(cf:&rbx_dom_weak::types::CFrame,size:&rbx_dom_weak::types::Vector3)->Planar64Affine3{
Planar64Affine3::new(
Planar64Mat3::from_cols(
Planar64Vec3::try_from([cf.orientation.x.x,cf.orientation.y.x,cf.orientation.z.x]).unwrap()
*Planar64::try_from(size.x/2.0).unwrap(),
Planar64Vec3::try_from([cf.orientation.x.y,cf.orientation.y.y,cf.orientation.z.y]).unwrap()
*Planar64::try_from(size.y/2.0).unwrap(),
Planar64Vec3::try_from([cf.orientation.x.z,cf.orientation.y.z,cf.orientation.z.z]).unwrap()
*Planar64::try_from(size.z/2.0).unwrap(),
),
Planar64Vec3::try_from([cf.position.x,cf.position.y,cf.position.z]).unwrap()
)
}
fn get_attributes(name:&str,can_collide:bool,velocity:Planar64Vec3,force_intersecting:bool)->crate::model::CollisionAttributes{
let mut general=crate::model::GameMechanicAttributes::default();
let mut intersecting=crate::model::IntersectingAttributes::default();
let mut contacting=crate::model::ContactingAttributes::default();
let mut force_can_collide=can_collide;
match name{
"Water"=>{
force_can_collide=false;
//TODO: read stupid CustomPhysicalProperties
intersecting.water=Some(crate::model::IntersectingWater{density:Planar64::ONE,viscosity:Planar64::ONE/10,current:velocity});
},
"Accelerator"=>{
//although the new game supports collidable accelerators, this is a roblox compatability map loader
force_can_collide=false;
general.accelerator=Some(crate::model::GameMechanicAccelerator{acceleration:velocity});
},
"SetVelocity"=>general.trajectory=Some(crate::model::GameMechanicSetTrajectory::Velocity(velocity)),
"MapFinish"=>{force_can_collide=false;general.zone=Some(crate::model::GameMechanicZone{mode_id:0,behaviour:crate::model::ZoneBehaviour::Finish})},
"MapAnticheat"=>{force_can_collide=false;general.zone=Some(crate::model::GameMechanicZone{mode_id:0,behaviour:crate::model::ZoneBehaviour::Anitcheat})},
"Platform"=>general.teleport_behaviour=Some(crate::model::TeleportBehaviour::StageElement(crate::model::GameMechanicStageElement{
mode_id:0,
stage_id:0,
force:false,
behaviour:crate::model::StageElementBehaviour::Platform,
})),
other=>{
if let Some(captures)=lazy_regex::regex!(r"^(Force)?(Spawn|SpawnAt|Trigger|Teleport|Platform)(\d+)$")
.captures(other){
general.teleport_behaviour=Some(crate::model::TeleportBehaviour::StageElement(crate::model::GameMechanicStageElement{
mode_id:0,
stage_id:captures[3].parse::<u32>().unwrap(),
force:match captures.get(1){
Some(m)=>m.as_str()=="Force",
None=>false,
},
behaviour:match &captures[2]{
"Spawn"|"SpawnAt"=>crate::model::StageElementBehaviour::SpawnAt,
//cancollide false so you don't hit the side
//NOT a decoration
"Trigger"=>{force_can_collide=false;crate::model::StageElementBehaviour::Trigger},
"Teleport"=>{force_can_collide=false;crate::model::StageElementBehaviour::Teleport},
"Platform"=>crate::model::StageElementBehaviour::Platform,
_=>panic!("regex1[2] messed up bad"),
}
}));
}else if let Some(captures)=lazy_regex::regex!(r"^(Force)?(Jump)(\d+)$")
.captures(other){
general.teleport_behaviour=Some(crate::model::TeleportBehaviour::StageElement(crate::model::GameMechanicStageElement{
mode_id:0,
stage_id:0,
force:match captures.get(1){
Some(m)=>m.as_str()=="Force",
None=>false,
},
behaviour:match &captures[2]{
"Jump"=>crate::model::StageElementBehaviour::JumpLimit(captures[3].parse::<u32>().unwrap()),
_=>panic!("regex4[1] messed up bad"),
}
}));
}else if let Some(captures)=lazy_regex::regex!(r"^Bonus(Finish|Anticheat)(\d+)$")
.captures(other){
force_can_collide=false;
match &captures[1]{
"Finish"=>general.zone=Some(crate::model::GameMechanicZone{mode_id:captures[2].parse::<u32>().unwrap(),behaviour:crate::model::ZoneBehaviour::Finish}),
"Anticheat"=>general.zone=Some(crate::model::GameMechanicZone{mode_id:captures[2].parse::<u32>().unwrap(),behaviour:crate::model::ZoneBehaviour::Anitcheat}),
_=>panic!("regex2[1] messed up bad"),
}
}else if let Some(captures)=lazy_regex::regex!(r"^(WormholeIn)(\d+)$")
.captures(other){
force_can_collide=false;
match &captures[1]{
"WormholeIn"=>general.teleport_behaviour=Some(crate::model::TeleportBehaviour::Wormhole(crate::model::GameMechanicWormhole{destination_model_id:captures[2].parse::<u32>().unwrap()})),
_=>panic!("regex3[1] messed up bad"),
}
}
}
}
//need some way to skip this
if velocity!=Planar64Vec3::ZERO{
general.booster=Some(crate::model::GameMechanicBooster::Velocity(velocity));
}
match force_can_collide{
true=>{
match name{
"Bounce"=>contacting.contact_behaviour=Some(crate::model::ContactingBehaviour::Elastic(u32::MAX)),
"Surf"=>contacting.contact_behaviour=Some(crate::model::ContactingBehaviour::Surf),
"Ladder"=>contacting.contact_behaviour=Some(crate::model::ContactingBehaviour::Ladder(crate::model::ContactingLadder{sticky:true})),
_=>(),
}
crate::model::CollisionAttributes::Contact{contacting,general}
},
false=>if force_intersecting
||general.any()
||intersecting.any()
{
crate::model::CollisionAttributes::Intersect{intersecting,general}
}else{
crate::model::CollisionAttributes::Decoration
},
}
}
struct RobloxAssetId(u64);
struct RobloxAssetIdParseErr;
impl std::str::FromStr for RobloxAssetId {
type Err=RobloxAssetIdParseErr;
fn from_str(s: &str) -> Result<Self, Self::Err>{
let regman=lazy_regex::regex!(r"(\d+)$");
if let Some(captures) = regman.captures(s) {
if captures.len()==2{//captures[0] is all captures concatenated, and then each individual capture
if let Ok(id) = captures[0].parse::<u64>() {
return Ok(Self(id));
}
}
}
Err(RobloxAssetIdParseErr)
}
}
#[derive(Clone,Copy,PartialEq)]
struct RobloxTextureTransform{
offset_u:f32,
offset_v:f32,
scale_u:f32,
scale_v:f32,
}
impl std::cmp::Eq for RobloxTextureTransform{}//????
impl std::default::Default for RobloxTextureTransform{
fn default() -> Self {
Self{offset_u:0.0,offset_v:0.0,scale_u:1.0,scale_v:1.0}
}
}
impl std::hash::Hash for RobloxTextureTransform {
fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
self.offset_u.to_ne_bytes().hash(state);
self.offset_v.to_ne_bytes().hash(state);
self.scale_u.to_ne_bytes().hash(state);
self.scale_v.to_ne_bytes().hash(state);
}
}
#[derive(Clone,PartialEq)]
struct RobloxFaceTextureDescription{
texture:u32,
color:glam::Vec4,
transform:RobloxTextureTransform,
}
impl std::cmp::Eq for RobloxFaceTextureDescription{}//????
impl std::hash::Hash for RobloxFaceTextureDescription {
fn hash<H: std::hash::Hasher>(&self, state: &mut H) {
self.texture.hash(state);
self.transform.hash(state);
for &el in self.color.as_ref().iter() {
el.to_ne_bytes().hash(state);
}
}
}
impl RobloxFaceTextureDescription{
fn to_face_description(&self)->primitives::FaceDescription{
primitives::FaceDescription{
texture:Some(self.texture),
transform:glam::Affine2::from_translation(
glam::vec2(self.transform.offset_u,self.transform.offset_v)
)
*glam::Affine2::from_scale(
glam::vec2(self.transform.scale_u,self.transform.scale_v)
),
color:self.color,
}
}
}
type RobloxPartDescription=[Option<RobloxFaceTextureDescription>;6];
type RobloxWedgeDescription=[Option<RobloxFaceTextureDescription>;5];
type RobloxCornerWedgeDescription=[Option<RobloxFaceTextureDescription>;5];
#[derive(Clone,Eq,Hash,PartialEq)]
enum RobloxBasePartDescription{
Sphere,
Part(RobloxPartDescription),
Cylinder,
Wedge(RobloxWedgeDescription),
CornerWedge(RobloxCornerWedgeDescription),
}
pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::IndexedModelInstances{
//IndexedModelInstances includes textures
let mut spawn_point=Planar64Vec3::ZERO;
let mut indexed_models=Vec::new();
let mut model_id_from_description=std::collections::HashMap::<RobloxBasePartDescription,usize>::new();
let mut texture_id_from_asset_id=std::collections::HashMap::<u64,u32>::new();
let mut asset_id_from_texture_id=Vec::new();
let mut object_refs=Vec::new();
let mut temp_objects=Vec::new();
recursive_collect_superclass(&mut object_refs, &dom, dom.root(),"BasePart");
for object_ref in object_refs {
if let Some(object)=dom.get_by_ref(object_ref){
if let (
Some(rbx_dom_weak::types::Variant::CFrame(cf)),
Some(rbx_dom_weak::types::Variant::Vector3(size)),
Some(rbx_dom_weak::types::Variant::Vector3(velocity)),
Some(rbx_dom_weak::types::Variant::Float32(transparency)),
Some(rbx_dom_weak::types::Variant::Color3uint8(color3)),
Some(rbx_dom_weak::types::Variant::Bool(can_collide)),
) = (
object.properties.get("CFrame"),
object.properties.get("Size"),
object.properties.get("Velocity"),
object.properties.get("Transparency"),
object.properties.get("Color"),
object.properties.get("CanCollide"),
)
{
let model_transform=planar64_affine3_from_roblox(cf,size);
//push TempIndexedAttributes
let mut force_intersecting=false;
let mut temp_indexing_attributes=Vec::new();
if let Some(attr)=match &object.name[..]{
"MapStart"=>{
spawn_point=model_transform.transform_point3(Planar64Vec3::ZERO)+Planar64Vec3::Y*5/2;
Some(crate::model::TempIndexedAttributes::Start(crate::model::TempAttrStart{mode_id:0}))
},
"UnorderedCheckpoint"=>Some(crate::model::TempIndexedAttributes::UnorderedCheckpoint(crate::model::TempAttrUnorderedCheckpoint{mode_id:0})),
other=>{
let regman=lazy_regex::regex!(r"^(BonusStart|Spawn|ForceSpawn|OrderedCheckpoint|WormholeOut)(\d+)$");
if let Some(captures) = regman.captures(other) {
match &captures[1]{
"BonusStart"=>Some(crate::model::TempIndexedAttributes::Start(crate::model::TempAttrStart{mode_id:captures[2].parse::<u32>().unwrap()})),
"Spawn"|"ForceSpawn"=>Some(crate::model::TempIndexedAttributes::Spawn(crate::model::TempAttrSpawn{mode_id:0,stage_id:captures[2].parse::<u32>().unwrap()})),
"OrderedCheckpoint"=>Some(crate::model::TempIndexedAttributes::OrderedCheckpoint(crate::model::TempAttrOrderedCheckpoint{mode_id:0,checkpoint_id:captures[2].parse::<u32>().unwrap()})),
"WormholeOut"=>Some(crate::model::TempIndexedAttributes::Wormhole(crate::model::TempAttrWormhole{wormhole_id:captures[2].parse::<u32>().unwrap()})),
_=>None,
}
}else{
None
}
}
}{
force_intersecting=true;
temp_indexing_attributes.push(attr);
}
//TODO: also detect "CylinderMesh" etc here
let shape=match &object.class[..]{
"Part"=>{
if let Some(rbx_dom_weak::types::Variant::Enum(shape))=object.properties.get("Shape"){
match shape.to_u32(){
0=>primitives::Primitives::Sphere,
1=>primitives::Primitives::Cube,
2=>primitives::Primitives::Cylinder,
3=>primitives::Primitives::Wedge,
4=>primitives::Primitives::CornerWedge,
_=>panic!("Funky roblox PartType={};",shape.to_u32()),
}
}else{
panic!("Part has no Shape!");
}
},
"WedgePart"=>primitives::Primitives::Wedge,
"CornerWedgePart"=>primitives::Primitives::CornerWedge,
_=>{
println!("Unsupported BasePart ClassName={}; defaulting to cube",object.class);
primitives::Primitives::Cube
}
};
//use the biggest one and cut it down later...
let mut part_texture_description:RobloxPartDescription=[None,None,None,None,None,None];
temp_objects.clear();
recursive_collect_superclass(&mut temp_objects, &dom, object,"Decal");
for &decal_ref in &temp_objects{
if let Some(decal)=dom.get_by_ref(decal_ref){
if let (
Some(rbx_dom_weak::types::Variant::Content(content)),
Some(rbx_dom_weak::types::Variant::Enum(normalid)),
Some(rbx_dom_weak::types::Variant::Color3(decal_color3)),
Some(rbx_dom_weak::types::Variant::Float32(decal_transparency)),
) = (
decal.properties.get("Texture"),
decal.properties.get("Face"),
decal.properties.get("Color3"),
decal.properties.get("Transparency"),
) {
if let Ok(asset_id)=content.clone().into_string().parse::<RobloxAssetId>(){
let texture_id=if let Some(&texture_id)=texture_id_from_asset_id.get(&asset_id.0){
texture_id
}else{
let texture_id=asset_id_from_texture_id.len() as u32;
texture_id_from_asset_id.insert(asset_id.0,texture_id);
asset_id_from_texture_id.push(asset_id.0);
texture_id
};
let normal_id=normalid.to_u32();
if normal_id<6{
let (roblox_texture_color,roblox_texture_transform)=if decal.class=="Texture"{
//generate tranform
if let (
Some(rbx_dom_weak::types::Variant::Float32(ox)),
Some(rbx_dom_weak::types::Variant::Float32(oy)),
Some(rbx_dom_weak::types::Variant::Float32(sx)),
Some(rbx_dom_weak::types::Variant::Float32(sy)),
) = (
decal.properties.get("OffsetStudsU"),
decal.properties.get("OffsetStudsV"),
decal.properties.get("StudsPerTileU"),
decal.properties.get("StudsPerTileV"),
)
{
let (size_u,size_v)=match normal_id{
0=>(size.z,size.y),//right
1=>(size.x,size.z),//top
2=>(size.x,size.y),//back
3=>(size.z,size.y),//left
4=>(size.x,size.z),//bottom
5=>(size.x,size.y),//front
_=>panic!("unreachable"),
};
(
glam::vec4(decal_color3.r,decal_color3.g,decal_color3.b,1.0-*decal_transparency),
RobloxTextureTransform{
offset_u:*ox/(*sx),offset_v:*oy/(*sy),
scale_u:size_u/(*sx),scale_v:size_v/(*sy),
}
)
}else{
(glam::Vec4::ONE,RobloxTextureTransform::default())
}
}else{
(glam::Vec4::ONE,RobloxTextureTransform::default())
};
part_texture_description[normal_id as usize]=Some(RobloxFaceTextureDescription{
texture:texture_id,
color:roblox_texture_color,
transform:roblox_texture_transform,
});
}else{
println!("NormalId={} unsupported for shape={:?}",normal_id,shape);
}
}
}
}
}
//obscure rust syntax "slice pattern"
let [
f0,//Cube::Right
f1,//Cube::Top
f2,//Cube::Back
f3,//Cube::Left
f4,//Cube::Bottom
f5,//Cube::Front
]=part_texture_description;
let basepart_texture_description=match shape{
primitives::Primitives::Sphere=>RobloxBasePartDescription::Sphere,
primitives::Primitives::Cube=>RobloxBasePartDescription::Part([f0,f1,f2,f3,f4,f5]),
primitives::Primitives::Cylinder=>RobloxBasePartDescription::Cylinder,
//use front face texture first and use top face texture as a fallback
primitives::Primitives::Wedge=>RobloxBasePartDescription::Wedge([
f0,//Cube::Right->Wedge::Right
if f5.is_some(){f5}else{f1},//Cube::Front|Cube::Top->Wedge::TopFront
f2,//Cube::Back->Wedge::Back
f3,//Cube::Left->Wedge::Left
f4,//Cube::Bottom->Wedge::Bottom
]),
//TODO: fix Left+Back texture coordinates to match roblox when not overwridden by Top
primitives::Primitives::CornerWedge=>RobloxBasePartDescription::CornerWedge([
f0,//Cube::Right->CornerWedge::Right
if f2.is_some(){f2}else{f1.clone()},//Cube::Back|Cube::Top->CornerWedge::TopBack
if f3.is_some(){f3}else{f1},//Cube::Left|Cube::Top->CornerWedge::TopLeft
f4,//Cube::Bottom->CornerWedge::Bottom
f5,//Cube::Front->CornerWedge::Front
]),
};
//make new model if unit cube has not been created before
let model_id=if let Some(&model_id)=model_id_from_description.get(&basepart_texture_description){
//push to existing texture model
model_id
}else{
let model_id=indexed_models.len();
model_id_from_description.insert(basepart_texture_description.clone(),model_id);//borrow checker going crazy
indexed_models.push(match basepart_texture_description{
RobloxBasePartDescription::Sphere=>primitives::unit_sphere(),
RobloxBasePartDescription::Part(part_texture_description)=>{
let mut cube_face_description=primitives::CubeFaceDescription::new();
for (face_id,roblox_face_description) in part_texture_description.iter().enumerate(){
cube_face_description.insert(
match face_id{
0=>primitives::CubeFace::Right,
1=>primitives::CubeFace::Top,
2=>primitives::CubeFace::Back,
3=>primitives::CubeFace::Left,
4=>primitives::CubeFace::Bottom,
5=>primitives::CubeFace::Front,
_=>panic!("unreachable"),
},
match roblox_face_description{
Some(roblox_texture_transform)=>roblox_texture_transform.to_face_description(),
None=>primitives::FaceDescription::default(),
});
}
primitives::generate_partial_unit_cube(cube_face_description)
},
RobloxBasePartDescription::Cylinder=>primitives::unit_cylinder(),
RobloxBasePartDescription::Wedge(wedge_texture_description)=>{
let mut wedge_face_description=primitives::WedgeFaceDescription::new();
for (face_id,roblox_face_description) in wedge_texture_description.iter().enumerate(){
wedge_face_description.insert(
match face_id{
0=>primitives::WedgeFace::Right,
1=>primitives::WedgeFace::TopFront,
2=>primitives::WedgeFace::Back,
3=>primitives::WedgeFace::Left,
4=>primitives::WedgeFace::Bottom,
_=>panic!("unreachable"),
},
match roblox_face_description{
Some(roblox_texture_transform)=>roblox_texture_transform.to_face_description(),
None=>primitives::FaceDescription::default(),
});
}
primitives::generate_partial_unit_wedge(wedge_face_description)
},
RobloxBasePartDescription::CornerWedge(cornerwedge_texture_description)=>{
let mut cornerwedge_face_description=primitives::CornerWedgeFaceDescription::new();
for (face_id,roblox_face_description) in cornerwedge_texture_description.iter().enumerate(){
cornerwedge_face_description.insert(
match face_id{
0=>primitives::CornerWedgeFace::Right,
1=>primitives::CornerWedgeFace::TopBack,
2=>primitives::CornerWedgeFace::TopLeft,
3=>primitives::CornerWedgeFace::Bottom,
4=>primitives::CornerWedgeFace::Front,
_=>panic!("unreachable"),
},
match roblox_face_description{
Some(roblox_texture_transform)=>roblox_texture_transform.to_face_description(),
None=>primitives::FaceDescription::default(),
});
}
primitives::generate_partial_unit_cornerwedge(cornerwedge_face_description)
},
});
model_id
};
indexed_models[model_id].instances.push(crate::model::ModelInstance {
transform:model_transform,
color:glam::vec4(color3.r as f32/255f32, color3.g as f32/255f32, color3.b as f32/255f32, 1.0-*transparency),
attributes:get_attributes(&object.name,*can_collide,Planar64Vec3::try_from([velocity.x,velocity.y,velocity.z]).unwrap(),force_intersecting),
temp_indexing:temp_indexing_attributes,
});
}
}
}
crate::model::IndexedModelInstances{
textures:asset_id_from_texture_id.iter().map(|t|t.to_string()).collect(),
models:indexed_models,
spawn_point,
modes:Vec::new(),
}
}

View File

@ -1,187 +1,17 @@
use std::time::Instant;
use physics::PhysicsInstruction;
use render_thread::InputInstruction;
use instruction::{TimedInstruction, InstructionConsumer};
mod bvh;
mod aabb;
mod model;
mod file;
mod setup;
mod window;
mod worker;
mod zeroes;
mod integer;
mod physics;
mod graphics;
mod settings;
mod primitives;
mod instruction;
mod load_roblox;
mod render_thread;
mod face_crawler;
mod compat_worker;
mod model_physics;
mod model_graphics;
mod graphics_context;
pub struct GlobalState{
start_time: std::time::Instant,
manual_mouse_lock:bool,
mouse:std::sync::Arc<std::sync::Mutex<physics::MouseState>>,
user_settings:settings::UserSettings,
//Ideally the graphics thread worker description is:
/*
WorkerDescription{
input:Immediate,
output:Realtime(PoolOrdering::Ordered(3)),
}
*/
//up to three frames in flight, dropping new frame requests when all three are busy, and dropping output frames when one renders out of order
graphics_thread:worker::INWorker<graphics::GraphicsInstruction>,
physics_thread:worker::QNWorker<TimedInstruction<InputInstruction>>,
}
fn load_file(path: std::path::PathBuf)->Option<model::IndexedModelInstances>{
println!("Loading file: {:?}", &path);
//oh boy! let's load the map!
if let Ok(file)=std::fs::File::open(path){
let mut input = std::io::BufReader::new(file);
let mut first_8=[0u8;8];
//.rbxm roblox binary = "<roblox!"
//.rbxmx roblox xml = "<roblox "
//.bsp = "VBSP"
//.vmf =
//.snf = "SNMF"
//.snf = "SNBF"
if let (Ok(()),Ok(()))=(std::io::Read::read_exact(&mut input, &mut first_8),std::io::Seek::rewind(&mut input)){
match &first_8[0..4]{
b"<rob"=>{
match match &first_8[4..8]{
b"lox!"=>rbx_binary::from_reader(input).map_err(|e|format!("{:?}",e)),
b"lox "=>rbx_xml::from_reader(input,rbx_xml::DecodeOptions::default()).map_err(|e|format!("{:?}",e)),
other=>Err(format!("Unknown Roblox file type {:?}",other)),
}{
Ok(dom)=>Some(load_roblox::generate_indexed_models(dom)),
Err(e)=>{
println!("Error loading roblox file:{:?}",e);
None
},
}
},
//b"VBSP"=>Some(load_bsp::generate_indexed_models(input)),
//b"SNFM"=>Some(sniffer::generate_indexed_models(input)),
//b"SNFB"=>Some(sniffer::load_bot(input)),
other=>{
println!("loser file {:?}",other);
None
},
}
}else{
println!("Failed to read first 8 bytes and seek back to beginning of file.");
None
}
}else{
println!("Could not open file");
None
}
}
fn default_models()->model::IndexedModelInstances{
let mut indexed_models = Vec::new();
indexed_models.append(&mut model::generate_indexed_model_list_from_obj(obj::ObjData::load_buf(&include_bytes!("../models/teslacyberv3.0.obj")[..]).unwrap(),glam::Vec4::ONE));
indexed_models.push(primitives::unit_sphere());
indexed_models.push(primitives::unit_cylinder());
indexed_models.push(primitives::unit_cube());
println!("models.len = {:?}", indexed_models.len());
indexed_models[0].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(10.,0.,-10.))).unwrap(),
..Default::default()
});
//quad monkeys
indexed_models[1].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(10.,5.,10.))).unwrap(),
..Default::default()
});
indexed_models[1].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(20.,5.,10.))).unwrap(),
color:glam::vec4(1.0,0.0,0.0,1.0),
..Default::default()
});
indexed_models[1].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(10.,5.,20.))).unwrap(),
color:glam::vec4(0.0,1.0,0.0,1.0),
..Default::default()
});
indexed_models[1].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(20.,5.,20.))).unwrap(),
color:glam::vec4(0.0,0.0,1.0,1.0),
..Default::default()
});
//decorative monkey
indexed_models[1].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(15.,10.,15.))).unwrap(),
color:glam::vec4(0.5,0.5,0.5,0.5),
attributes:model::CollisionAttributes::Decoration,
..Default::default()
});
//teapot
indexed_models[2].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_scale_rotation_translation(glam::vec3(0.5, 1.0, 0.2),glam::quat(-0.22248298016985793,-0.839457167990537,-0.05603504040830783,-0.49261857546227916),glam::vec3(-10.,7.,10.))).unwrap(),
..Default::default()
});
//ground
indexed_models[3].instances.push(model::ModelInstance{
transform:integer::Planar64Affine3::try_from(glam::Affine3A::from_translation(glam::vec3(0.,0.,0.))*glam::Affine3A::from_scale(glam::vec3(160.0, 1.0, 160.0))).unwrap(),
..Default::default()
});
model::IndexedModelInstances{
textures:Vec::new(),
models:indexed_models,
spawn_point:integer::Planar64Vec3::Y*50,
modes:Vec::new(),
}
}
impl GlobalState {
fn init() -> Self {
//wee
let user_settings=settings::read_user_settings();
let mut graphics=GraphicsState::new();
graphics.load_user_settings(&user_settings);
//how to multithread
//1. build
physics.generate_models(&indexed_model_instances);
//2. move
let physics_thread=physics.into_worker();
//3. forget
let mut state=GlobalState{
start_time:Instant::now(),
manual_mouse_lock:false,
mouse:physics::MouseState::default(),
user_settings,
graphics,
physics_thread,
};
state.generate_model_graphics(&device,&queue,indexed_model_instances);
let args:Vec<String>=std::env::args().collect();
if args.len()==2{
let indexed_model_instances=load_file(std::path::PathBuf::from(&args[1]));
state.render_thread=RenderThread::new(user_settings,indexed_model_instances);
}
return state;
}
}
mod physics_worker;
mod graphics_worker;
fn main(){
let title=format!("Strafe Client v{}",env!("CARGO_PKG_VERSION")).as_str();
let context=graphics_context::setup(title);
let global_state=GlobalState::init();//new
global_state.replace_models(&context,default_models());
context.start(global_state);
setup::setup_and_start(format!("Strafe Client v{}",env!("CARGO_PKG_VERSION")));
}

View File

@ -1,294 +0,0 @@
use crate::integer::{Time,Planar64,Planar64Vec3,Planar64Affine3};
pub type TextureCoordinate=glam::Vec2;
pub type Color4=glam::Vec4;
#[derive(Clone,Hash,PartialEq,Eq)]
pub struct IndexedVertex{
pub pos:u32,
pub tex:u32,
pub normal:u32,
pub color:u32,
}
pub struct IndexedPolygon{
pub vertices:Vec<u32>,
}
pub struct IndexedGroup{
pub texture:Option<u32>,//RenderPattern? material/texture/shader/flat color
pub polys:Vec<IndexedPolygon>,
}
pub struct IndexedModel{
pub unique_pos:Vec<Planar64Vec3>,
pub unique_normal:Vec<Planar64Vec3>,
pub unique_tex:Vec<TextureCoordinate>,
pub unique_color:Vec<Color4>,
pub unique_vertices:Vec<IndexedVertex>,
pub groups: Vec<IndexedGroup>,
pub instances:Vec<ModelInstance>,
}
pub struct ModelInstance{
//pub id:u64,//this does not actually help with map fixes resimulating bots, they must always be resimulated
pub transform:Planar64Affine3,
pub color:Color4,//transparency is in here
pub attributes:CollisionAttributes,
pub temp_indexing:Vec<TempIndexedAttributes>,
}
impl std::default::Default for ModelInstance{
fn default() -> Self {
Self{
color:Color4::ONE,
transform:Default::default(),
attributes:Default::default(),
temp_indexing:Default::default(),
}
}
}
pub struct IndexedModelInstances{
pub textures:Vec<String>,//RenderPattern
pub models:Vec<IndexedModel>,
//may make this into an object later.
pub modes:Vec<ModeDescription>,
pub spawn_point:Planar64Vec3,
}
//stage description referencing flattened ids is spooky, but the map loading is meant to be deterministic.
pub struct ModeDescription{
pub start:usize,//start=model_id
pub spawns:Vec<usize>,//spawns[spawn_id]=model_id
pub ordered_checkpoints:Vec<usize>,//ordered_checkpoints[checkpoint_id]=model_id
pub unordered_checkpoints:Vec<usize>,//unordered_checkpoints[checkpoint_id]=model_id
pub spawn_from_stage_id:std::collections::HashMap::<u32,usize>,
pub ordered_checkpoint_from_checkpoint_id:std::collections::HashMap::<u32,usize>,
}
impl ModeDescription{
pub fn get_spawn_model_id(&self,stage_id:u32)->Option<&usize>{
self.spawns.get(*self.spawn_from_stage_id.get(&stage_id)?)
}
pub fn get_ordered_checkpoint_model_id(&self,checkpoint_id:u32)->Option<&usize>{
self.ordered_checkpoints.get(*self.ordered_checkpoint_from_checkpoint_id.get(&checkpoint_id)?)
}
}
//I don't want this code to exist!
#[derive(Clone)]
pub struct TempAttrStart{
pub mode_id:u32,
}
#[derive(Clone)]
pub struct TempAttrSpawn{
pub mode_id:u32,
pub stage_id:u32,
}
#[derive(Clone)]
pub struct TempAttrOrderedCheckpoint{
pub mode_id:u32,
pub checkpoint_id:u32,
}
#[derive(Clone)]
pub struct TempAttrUnorderedCheckpoint{
pub mode_id:u32,
}
#[derive(Clone)]
pub struct TempAttrWormhole{
pub wormhole_id:u32,
}
pub enum TempIndexedAttributes{
Start(TempAttrStart),
Spawn(TempAttrSpawn),
OrderedCheckpoint(TempAttrOrderedCheckpoint),
UnorderedCheckpoint(TempAttrUnorderedCheckpoint),
Wormhole(TempAttrWormhole),
}
//you have this effect while in contact
#[derive(Clone)]
pub struct ContactingLadder{
pub sticky:bool
}
#[derive(Clone)]
pub enum ContactingBehaviour{
Surf,
Ladder(ContactingLadder),
Elastic(u32),//[1/2^32,1] 0=None (elasticity+1)/2^32
}
//you have this effect while intersecting
#[derive(Clone)]
pub struct IntersectingWater{
pub viscosity:Planar64,
pub density:Planar64,
pub current:Planar64Vec3,
}
//All models can be given these attributes
#[derive(Clone)]
pub struct GameMechanicAccelerator{
pub acceleration:Planar64Vec3
}
#[derive(Clone)]
pub enum GameMechanicBooster{
Affine(Planar64Affine3),//capable of SetVelocity,DotVelocity,normal booster,bouncy part,redirect velocity, and much more
Velocity(Planar64Vec3),//straight up boost velocity adds to your current velocity
Energy{direction:Planar64Vec3,energy:Planar64},//increase energy in direction
}
#[derive(Clone)]
pub enum TrajectoryChoice{
HighArcLongDuration,//underhand lob at target: less horizontal speed and more air time
LowArcShortDuration,//overhand throw at target: more horizontal speed and less air time
}
#[derive(Clone)]
pub enum GameMechanicSetTrajectory{
AirTime(Time),//air time (relative to gravity direction) is invariant across mass and gravity changes
Height(Planar64),//boost height (relative to gravity direction) is invariant across mass and gravity changes
TargetPointTime{//launch on a trajectory that will land at a target point in a set amount of time
target_point:Planar64Vec3,
time:Time,//short time = fast and direct, long time = launch high in the air, negative time = wrong way
},
TrajectoryTargetPoint{//launch at a fixed speed and land at a target point
target_point:Planar64Vec3,
speed:Planar64,//if speed is too low this will fail to reach the target. The closest-passing trajectory will be chosen instead
trajectory_choice:TrajectoryChoice,
},
Velocity(Planar64Vec3),//SetVelocity
DotVelocity{direction:Planar64Vec3,dot:Planar64},//set your velocity in a specific direction without touching other directions
}
#[derive(Clone)]
pub enum ZoneBehaviour{
//Start is indexed
//Checkpoints are indexed
Finish,
Anitcheat,
}
#[derive(Clone)]
pub struct GameMechanicZone{
pub mode_id:u32,
pub behaviour:ZoneBehaviour,
}
// enum TrapCondition{
// FasterThan(Planar64),
// SlowerThan(Planar64),
// InRange(Planar64,Planar64),
// OutsideRange(Planar64,Planar64),
// }
#[derive(Clone)]
pub enum StageElementBehaviour{
//Spawn,//The behaviour of stepping on a spawn setting the spawnid
SpawnAt,
Trigger,
Teleport,
Platform,
JumpLimit(u32),
//Speedtrap(TrapCondition),//Acts as a trigger with a speed condition
}
#[derive(Clone)]
pub struct GameMechanicStageElement{
pub mode_id:u32,
pub stage_id:u32,//which spawn to send to
pub force:bool,//allow setting to lower spawn id i.e. 7->3
pub behaviour:StageElementBehaviour
}
#[derive(Clone)]
pub struct GameMechanicWormhole{
//destination does not need to be another wormhole
//this defines a one way portal to a destination model transform
//two of these can create a two way wormhole
pub destination_model_id:u32,
//(position,angles)*=origin.transform.inverse()*destination.transform
}
#[derive(Clone)]
pub enum TeleportBehaviour{
StageElement(GameMechanicStageElement),
Wormhole(GameMechanicWormhole),
}
//attributes listed in order of handling
#[derive(Default,Clone)]
pub struct GameMechanicAttributes{
pub zone:Option<GameMechanicZone>,
pub booster:Option<GameMechanicBooster>,
pub trajectory:Option<GameMechanicSetTrajectory>,
pub teleport_behaviour:Option<TeleportBehaviour>,
pub accelerator:Option<GameMechanicAccelerator>,
}
impl GameMechanicAttributes{
pub fn any(&self)->bool{
self.booster.is_some()
||self.trajectory.is_some()
||self.zone.is_some()
||self.teleport_behaviour.is_some()
||self.accelerator.is_some()
}
}
#[derive(Default,Clone)]
pub struct ContactingAttributes{
//friction?
pub contact_behaviour:Option<ContactingBehaviour>,
}
impl ContactingAttributes{
pub fn any(&self)->bool{
self.contact_behaviour.is_some()
}
}
#[derive(Default,Clone)]
pub struct IntersectingAttributes{
pub water:Option<IntersectingWater>,
}
impl IntersectingAttributes{
pub fn any(&self)->bool{
self.water.is_some()
}
}
//Spawn(u32) NO! spawns are indexed in the map header instead of marked with attibutes
pub enum CollisionAttributes{
Decoration,//visual only
Contact{//track whether you are contacting the object
contacting:ContactingAttributes,
general:GameMechanicAttributes,
},
Intersect{//track whether you are intersecting the object
intersecting:IntersectingAttributes,
general:GameMechanicAttributes,
},
}
impl std::default::Default for CollisionAttributes{
fn default() -> Self {
Self::Contact{
contacting:ContactingAttributes::default(),
general:GameMechanicAttributes::default()
}
}
}
pub fn generate_indexed_model_list_from_obj(data:obj::ObjData,color:Color4)->Vec<IndexedModel>{
let mut unique_vertex_index = std::collections::HashMap::<obj::IndexTuple,u32>::new();
return data.objects.iter().map(|object|{
unique_vertex_index.clear();
let mut unique_vertices = Vec::new();
let groups = object.groups.iter().map(|group|{
IndexedGroup{
texture:None,
polys:group.polys.iter().map(|poly|{
IndexedPolygon{
vertices:poly.0.iter().map(|&tup|{
if let Some(&i)=unique_vertex_index.get(&tup){
i
}else{
let i=unique_vertices.len() as u32;
unique_vertices.push(IndexedVertex{
pos: tup.0 as u32,
tex: tup.1.unwrap() as u32,
normal: tup.2.unwrap() as u32,
color: 0,
});
unique_vertex_index.insert(tup,i);
i
}
}).collect()
}
}).collect()
}
}).collect();
IndexedModel{
unique_pos: data.position.iter().map(|&v|Planar64Vec3::try_from(v).unwrap()).collect(),
unique_tex: data.texture.iter().map(|&v|TextureCoordinate::from_array(v)).collect(),
unique_normal: data.normal.iter().map(|&v|Planar64Vec3::try_from(v).unwrap()).collect(),
unique_color: vec![color],
unique_vertices,
groups,
instances:Vec::new(),
}
}).collect()
}

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@ -1,55 +1,48 @@
use bytemuck::{Pod, Zeroable};
use crate::model::{IndexedVertex,IndexedPolygon};
#[derive(Clone, Copy, Pod, Zeroable)]
use bytemuck::{Pod,Zeroable};
use strafesnet_common::model::{IndexedVertex,PolygonGroup,RenderConfigId};
#[derive(Clone,Copy,Pod,Zeroable)]
#[repr(C)]
pub struct GraphicsVertex {
pub pos: [f32; 3],
pub tex: [f32; 2],
pub normal: [f32; 3],
pub color: [f32; 4],
pub struct GraphicsVertex{
pub pos:[f32;3],
pub tex:[f32;2],
pub normal:[f32;3],
pub color:[f32;4],
}
pub struct IndexedGroupFixedTexture{
pub polys:Vec<IndexedPolygon>,
}
pub struct IndexedModelGraphicsSingleTexture{
pub unique_pos:Vec<[f32; 3]>,
pub unique_tex:Vec<[f32; 2]>,
pub unique_normal:Vec<[f32; 3]>,
pub unique_color:Vec<[f32; 4]>,
#[derive(Clone,Copy,id::Id)]
pub struct IndexedGraphicsMeshOwnedRenderConfigId(u32);
pub struct IndexedGraphicsMeshOwnedRenderConfig{
pub unique_pos:Vec<[f32;3]>,
pub unique_tex:Vec<[f32;2]>,
pub unique_normal:Vec<[f32;3]>,
pub unique_color:Vec<[f32;4]>,
pub unique_vertices:Vec<IndexedVertex>,
pub texture:Option<u32>,//RenderPattern? material/texture/shader/flat color
pub groups: Vec<IndexedGroupFixedTexture>,
pub instances:Vec<ModelGraphicsInstance>,
pub render_config:RenderConfigId,
pub polys:PolygonGroup,
pub instances:Vec<GraphicsModelOwned>,
}
pub struct ModelGraphicsSingleTexture{
pub instances: Vec<ModelGraphicsInstance>,
pub vertices: Vec<GraphicsVertex>,
pub entities: Vec<Vec<u16>>,
pub texture: Option<u32>,
pub enum Indices{
U32(Vec<u32>),
U16(Vec<u16>),
}
#[derive(Clone,PartialEq)]
pub struct ModelGraphicsColor4(glam::Vec4);
impl ModelGraphicsColor4{
pub const fn get(&self)->glam::Vec4{
self.0
}
pub struct GraphicsMeshOwnedRenderConfig{
pub vertices:Vec<GraphicsVertex>,
pub indices:Indices,
pub render_config:RenderConfigId,
pub instances:Vec<GraphicsModelOwned>,
}
impl From<glam::Vec4> for ModelGraphicsColor4{
fn from(value:glam::Vec4)->Self{
Self(value)
}
}
impl std::hash::Hash for ModelGraphicsColor4{
fn hash<H: std::hash::Hasher>(&self,state:&mut H) {
#[derive(Clone,Copy,PartialEq,id::Id)]
pub struct GraphicsModelColor4(glam::Vec4);
impl std::hash::Hash for GraphicsModelColor4{
fn hash<H:std::hash::Hasher>(&self,state:&mut H) {
for &f in self.0.as_ref(){
bytemuck::cast::<f32,u32>(f).hash(state);
}
}
}
impl Eq for ModelGraphicsColor4{}
impl Eq for GraphicsModelColor4{}
#[derive(Clone)]
pub struct ModelGraphicsInstance{
pub struct GraphicsModelOwned{
pub transform:glam::Mat4,
pub normal_transform:glam::Mat3,
pub color:ModelGraphicsColor4,
pub color:GraphicsModelColor4,
}

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src/physics_worker.rs Normal file
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@ -0,0 +1,242 @@
use strafesnet_common::mouse::MouseState;
use strafesnet_common::physics::Instruction as PhysicsInputInstruction;
use strafesnet_common::integer::Time;
use strafesnet_common::instruction::TimedInstruction;
use strafesnet_common::timer::{Scaled,Timer,TimerState};
use mouse_interpolator::MouseInterpolator;
#[derive(Debug)]
pub enum InputInstruction{
MoveMouse(glam::IVec2),
MoveRight(bool),
MoveUp(bool),
MoveBack(bool),
MoveLeft(bool),
MoveDown(bool),
MoveForward(bool),
Jump(bool),
Zoom(bool),
ResetAndRestart,
ResetAndSpawn(strafesnet_common::gameplay_modes::ModeId,strafesnet_common::gameplay_modes::StageId),
PracticeFly,
}
pub enum Instruction{
Input(InputInstruction),
Render,
Resize(winit::dpi::PhysicalSize<u32>),
ChangeMap(strafesnet_common::map::CompleteMap),
//SetPaused is not an InputInstruction: the physics doesn't know that it's paused.
SetPaused(bool),
//Graphics(crate::graphics_worker::Instruction),
}
mod mouse_interpolator{
use super::*;
//TODO: move this or tab
pub struct MouseInterpolator{
//"PlayerController"
user_settings:crate::settings::UserSettings,
//"MouseInterpolator"
timeline:std::collections::VecDeque<TimedInstruction<PhysicsInputInstruction>>,
last_mouse_time:Time,//this value is pre-transformed to simulation time
mouse_blocking:bool,
//"Simulation"
timer:Timer<Scaled>,
physics:crate::physics::PhysicsContext,
}
impl MouseInterpolator{
pub fn new(
physics:crate::physics::PhysicsContext,
user_settings:crate::settings::UserSettings,
)->MouseInterpolator{
MouseInterpolator{
mouse_blocking:true,
last_mouse_time:physics.get_next_mouse().time,
timeline:std::collections::VecDeque::new(),
timer:Timer::from_state(Scaled::identity(),false),
physics,
user_settings,
}
}
fn push_mouse_instruction(&mut self,ins:&TimedInstruction<Instruction>,m:glam::IVec2){
if self.mouse_blocking{
//tell the game state which is living in the past about its future
self.timeline.push_front(TimedInstruction{
time:self.last_mouse_time,
instruction:PhysicsInputInstruction::SetNextMouse(MouseState{time:self.timer.time(ins.time),pos:m}),
});
}else{
//mouse has just started moving again after being still for longer than 10ms.
//replace the entire mouse interpolation state to avoid an intermediate state with identical m0.t m1.t timestamps which will divide by zero
self.timeline.push_front(TimedInstruction{
time:self.last_mouse_time,
instruction:PhysicsInputInstruction::ReplaceMouse(
MouseState{time:self.last_mouse_time,pos:self.physics.get_next_mouse().pos},
MouseState{time:self.timer.time(ins.time),pos:m}
),
});
//delay physics execution until we have an interpolation target
self.mouse_blocking=true;
}
self.last_mouse_time=self.timer.time(ins.time);
}
fn push(&mut self,time:Time,phys_input:PhysicsInputInstruction){
//This is always a non-mouse event
self.timeline.push_back(TimedInstruction{
time:self.timer.time(time),
instruction:phys_input,
});
}
/// returns should_empty_queue
/// may or may not mutate internal state XD!
fn map_instruction(&mut self,ins:&TimedInstruction<Instruction>)->bool{
let mut update_mouse_blocking=true;
match &ins.instruction{
Instruction::Input(input_instruction)=>match input_instruction{
&InputInstruction::MoveMouse(m)=>{
if !self.timer.is_paused(){
self.push_mouse_instruction(ins,m);
}
update_mouse_blocking=false;
},
&InputInstruction::MoveForward(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveForward(s)),
&InputInstruction::MoveLeft(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveLeft(s)),
&InputInstruction::MoveBack(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveBack(s)),
&InputInstruction::MoveRight(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveRight(s)),
&InputInstruction::MoveUp(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveUp(s)),
&InputInstruction::MoveDown(s)=>self.push(ins.time,PhysicsInputInstruction::SetMoveDown(s)),
&InputInstruction::Jump(s)=>self.push(ins.time,PhysicsInputInstruction::SetJump(s)),
&InputInstruction::Zoom(s)=>self.push(ins.time,PhysicsInputInstruction::SetZoom(s)),
&InputInstruction::ResetAndSpawn(mode_id,stage_id)=>{
self.push(ins.time,PhysicsInputInstruction::Reset);
self.push(ins.time,PhysicsInputInstruction::SetSensitivity(self.user_settings.calculate_sensitivity()));
self.push(ins.time,PhysicsInputInstruction::Spawn(mode_id,stage_id));
},
InputInstruction::ResetAndRestart=>{
self.push(ins.time,PhysicsInputInstruction::Reset);
self.push(ins.time,PhysicsInputInstruction::SetSensitivity(self.user_settings.calculate_sensitivity()));
self.push(ins.time,PhysicsInputInstruction::Restart);
},
InputInstruction::PracticeFly=>self.push(ins.time,PhysicsInputInstruction::PracticeFly),
},
//do these really need to idle the physics?
//sending None dumps the instruction queue
Instruction::ChangeMap(_)=>self.push(ins.time,PhysicsInputInstruction::Idle),
Instruction::Resize(_)=>self.push(ins.time,PhysicsInputInstruction::Idle),
Instruction::Render=>self.push(ins.time,PhysicsInputInstruction::Idle),
&Instruction::SetPaused(paused)=>{
if let Err(e)=self.timer.set_paused(ins.time,paused){
println!("Cannot pause: {e}");
}
self.push(ins.time,PhysicsInputInstruction::Idle);
},
}
if update_mouse_blocking{
//this returns the bool for us
self.update_mouse_blocking(ins.time)
}else{
//do flush that queue
true
}
}
/// must check if self.mouse_blocking==true before calling!
fn unblock_mouse(&mut self,time:Time){
//push an event to extrapolate no movement from
self.timeline.push_front(TimedInstruction{
time:self.last_mouse_time,
instruction:PhysicsInputInstruction::SetNextMouse(MouseState{time:self.timer.time(time),pos:self.physics.get_next_mouse().pos}),
});
self.last_mouse_time=self.timer.time(time);
//stop blocking. the mouse is not moving so the physics does not need to live in the past and wait for interpolation targets.
self.mouse_blocking=false;
}
fn update_mouse_blocking(&mut self,time:Time)->bool{
if self.mouse_blocking{
//assume the mouse has stopped moving after 10ms.
//shitty mice are 125Hz which is 8ms so this should cover that.
//setting this to 100us still doesn't print even though it's 10x lower than the polling rate,
//so mouse events are probably not handled separately from drawing and fire right before it :(
if Time::from_millis(10)<self.timer.time(time)-self.physics.get_next_mouse().time{
self.unblock_mouse(time);
true
}else{
false
}
}else{
//keep this up to date so that it can be used as a known-timestamp
//that the mouse was not moving when the mouse starts moving again
self.last_mouse_time=self.timer.time(time);
true
}
}
fn empty_queue(&mut self){
while let Some(instruction)=self.timeline.pop_front(){
self.physics.run_input_instruction(instruction);
}
}
pub fn handle_instruction(&mut self,ins:&TimedInstruction<Instruction>){
let should_empty_queue=self.map_instruction(ins);
if should_empty_queue{
self.empty_queue();
}
}
pub fn get_frame_state(&self,time:Time)->crate::graphics::FrameState{
crate::graphics::FrameState{
body:self.physics.camera_body(),
camera:self.physics.camera(),
time:self.timer.time(time),
}
}
pub fn change_map(&mut self,time:Time,map:&strafesnet_common::map::CompleteMap){
//dump any pending interpolation state
if self.mouse_blocking{
self.unblock_mouse(time);
}
self.empty_queue();
//doing it like this to avoid doing PhysicsInstruction::ChangeMap(Rc<CompleteMap>)
self.physics.generate_models(&map);
//use the standard input interface so the instructions are written out to bots
self.handle_instruction(&TimedInstruction{
time:self.timer.time(time),
instruction:Instruction::Input(InputInstruction::ResetAndSpawn(
strafesnet_common::gameplay_modes::ModeId::MAIN,
strafesnet_common::gameplay_modes::StageId::FIRST,
)),
});
}
pub const fn user_settings(&self)->&crate::settings::UserSettings{
&self.user_settings
}
}
}
pub fn new<'a>(
mut graphics_worker:crate::compat_worker::INWorker<'a,crate::graphics_worker::Instruction>,
user_settings:crate::settings::UserSettings,
)->crate::compat_worker::QNWorker<'a,TimedInstruction<Instruction>>{
let physics=crate::physics::PhysicsContext::default();
let mut interpolator=MouseInterpolator::new(
physics,
user_settings
);
crate::compat_worker::QNWorker::new(move |ins:TimedInstruction<Instruction>|{
interpolator.handle_instruction(&ins);
match ins.instruction{
Instruction::Render=>{
let frame_state=interpolator.get_frame_state(ins.time);
graphics_worker.send(crate::graphics_worker::Instruction::Render(frame_state)).unwrap();
},
Instruction::Resize(size)=>{
graphics_worker.send(crate::graphics_worker::Instruction::Resize(size,interpolator.user_settings().clone())).unwrap();
},
Instruction::ChangeMap(map)=>{
interpolator.change_map(ins.time,&map);
graphics_worker.send(crate::graphics_worker::Instruction::ChangeMap(map)).unwrap();
},
Instruction::Input(_)=>(),
Instruction::SetPaused(_)=>(),
}
})
}

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@ -1,510 +0,0 @@
use crate::model::{Color4,TextureCoordinate,IndexedModel,IndexedPolygon,IndexedGroup,IndexedVertex};
use crate::integer::Planar64Vec3;
#[derive(Debug)]
pub enum Primitives{
Sphere,
Cube,
Cylinder,
Wedge,
CornerWedge,
}
#[derive(Hash,PartialEq,Eq)]
pub enum CubeFace{
Right,
Top,
Back,
Left,
Bottom,
Front,
}
const CUBE_DEFAULT_TEXTURE_COORDS:[TextureCoordinate;4]=[
TextureCoordinate::new(0.0,0.0),
TextureCoordinate::new(1.0,0.0),
TextureCoordinate::new(1.0,1.0),
TextureCoordinate::new(0.0,1.0),
];
const CUBE_DEFAULT_VERTICES:[Planar64Vec3;8]=[
Planar64Vec3::int(-1,-1, 1),//0 left bottom back
Planar64Vec3::int( 1,-1, 1),//1 right bottom back
Planar64Vec3::int( 1, 1, 1),//2 right top back
Planar64Vec3::int(-1, 1, 1),//3 left top back
Planar64Vec3::int(-1, 1,-1),//4 left top front
Planar64Vec3::int( 1, 1,-1),//5 right top front
Planar64Vec3::int( 1,-1,-1),//6 right bottom front
Planar64Vec3::int(-1,-1,-1),//7 left bottom front
];
const CUBE_DEFAULT_NORMALS:[Planar64Vec3;6]=[
Planar64Vec3::int( 1, 0, 0),//CubeFace::Right
Planar64Vec3::int( 0, 1, 0),//CubeFace::Top
Planar64Vec3::int( 0, 0, 1),//CubeFace::Back
Planar64Vec3::int(-1, 0, 0),//CubeFace::Left
Planar64Vec3::int( 0,-1, 0),//CubeFace::Bottom
Planar64Vec3::int( 0, 0,-1),//CubeFace::Front
];
const CUBE_DEFAULT_POLYS:[[[u32;3];4];6]=[
// right (1, 0, 0)
[
[6,2,0],//[vertex,tex,norm]
[5,1,0],
[2,0,0],
[1,3,0],
],
// top (0, 1, 0)
[
[5,3,1],
[4,2,1],
[3,1,1],
[2,0,1],
],
// back (0, 0, 1)
[
[0,3,2],
[1,2,2],
[2,1,2],
[3,0,2],
],
// left (-1, 0, 0)
[
[0,2,3],
[3,1,3],
[4,0,3],
[7,3,3],
],
// bottom (0,-1, 0)
[
[1,1,4],
[0,0,4],
[7,3,4],
[6,2,4],
],
// front (0, 0,-1)
[
[4,1,5],
[5,0,5],
[6,3,5],
[7,2,5],
],
];
#[derive(Hash,PartialEq,Eq)]
pub enum WedgeFace{
Right,
TopFront,
Back,
Left,
Bottom,
}
const WEDGE_DEFAULT_NORMALS:[Planar64Vec3;5]=[
Planar64Vec3::int( 1, 0, 0),//Wedge::Right
Planar64Vec3::int( 0, 1,-1),//Wedge::TopFront
Planar64Vec3::int( 0, 0, 1),//Wedge::Back
Planar64Vec3::int(-1, 0, 0),//Wedge::Left
Planar64Vec3::int( 0,-1, 0),//Wedge::Bottom
];
/*
local cornerWedgeVerticies = {
Vector3.new(-1/2,-1/2,-1/2),7
Vector3.new(-1/2,-1/2, 1/2),0
Vector3.new( 1/2,-1/2,-1/2),6
Vector3.new( 1/2,-1/2, 1/2),1
Vector3.new( 1/2, 1/2,-1/2),5
}
*/
#[derive(Hash,PartialEq,Eq)]
pub enum CornerWedgeFace{
Right,
TopBack,
TopLeft,
Bottom,
Front,
}
const CORNERWEDGE_DEFAULT_NORMALS:[Planar64Vec3;5]=[
Planar64Vec3::int( 1, 0, 0),//CornerWedge::Right
Planar64Vec3::int( 0, 1, 1),//CornerWedge::BackTop
Planar64Vec3::int(-1, 1, 0),//CornerWedge::LeftTop
Planar64Vec3::int( 0,-1, 0),//CornerWedge::Bottom
Planar64Vec3::int( 0, 0,-1),//CornerWedge::Front
];
//HashMap fits this use case perfectly but feels like using a sledgehammer to drive a nail
pub fn unit_sphere()->crate::model::IndexedModel{
let mut indexed_model=crate::model::generate_indexed_model_list_from_obj(obj::ObjData::load_buf(&include_bytes!("../models/suzanne.obj")[..]).unwrap(),Color4::ONE).remove(0);
for pos in indexed_model.unique_pos.iter_mut(){
*pos=*pos/2;
}
indexed_model
}
pub type CubeFaceDescription=std::collections::HashMap::<CubeFace,FaceDescription>;
pub fn unit_cube()->crate::model::IndexedModel{
let mut t=CubeFaceDescription::new();
t.insert(CubeFace::Right,FaceDescription::default());
t.insert(CubeFace::Top,FaceDescription::default());
t.insert(CubeFace::Back,FaceDescription::default());
t.insert(CubeFace::Left,FaceDescription::default());
t.insert(CubeFace::Bottom,FaceDescription::default());
t.insert(CubeFace::Front,FaceDescription::default());
generate_partial_unit_cube(t)
}
const TEAPOT_TRANSFORM:crate::integer::Planar64Mat3=crate::integer::Planar64Mat3::int_from_cols_array([0,1,0, -1,0,0, 0,0,1]);
pub fn unit_cylinder()->crate::model::IndexedModel{
let mut indexed_model=crate::model::generate_indexed_model_list_from_obj(obj::ObjData::load_buf(&include_bytes!("../models/teapot.obj")[..]).unwrap(),Color4::ONE).remove(0);
for pos in indexed_model.unique_pos.iter_mut(){
*pos=TEAPOT_TRANSFORM*(*pos)/10;
}
indexed_model
}
pub type WedgeFaceDescription=std::collections::HashMap::<WedgeFace,FaceDescription>;
pub fn unit_wedge()->crate::model::IndexedModel{
let mut t=WedgeFaceDescription::new();
t.insert(WedgeFace::Right,FaceDescription::default());
t.insert(WedgeFace::TopFront,FaceDescription::default());
t.insert(WedgeFace::Back,FaceDescription::default());
t.insert(WedgeFace::Left,FaceDescription::default());
t.insert(WedgeFace::Bottom,FaceDescription::default());
generate_partial_unit_wedge(t)
}
pub type CornerWedgeFaceDescription=std::collections::HashMap::<CornerWedgeFace,FaceDescription>;
pub fn unit_cornerwedge()->crate::model::IndexedModel{
let mut t=CornerWedgeFaceDescription::new();
t.insert(CornerWedgeFace::Right,FaceDescription::default());
t.insert(CornerWedgeFace::TopBack,FaceDescription::default());
t.insert(CornerWedgeFace::TopLeft,FaceDescription::default());
t.insert(CornerWedgeFace::Bottom,FaceDescription::default());
t.insert(CornerWedgeFace::Front,FaceDescription::default());
generate_partial_unit_cornerwedge(t)
}
#[derive(Clone)]
pub struct FaceDescription{
pub texture:Option<u32>,
pub transform:glam::Affine2,
pub color:Color4,
}
impl std::default::Default for FaceDescription{
fn default()->Self {
Self{
texture:None,
transform:glam::Affine2::IDENTITY,
color:Color4::new(1.0,1.0,1.0,0.0),//zero alpha to hide the default texture
}
}
}
impl FaceDescription{
pub fn new(texture:u32,transform:glam::Affine2,color:Color4)->Self{
Self{texture:Some(texture),transform,color}
}
pub fn from_texture(texture:u32)->Self{
Self{
texture:Some(texture),
transform:glam::Affine2::IDENTITY,
color:Color4::ONE,
}
}
}
//TODO: it's probably better to use a shared vertex buffer between all primitives and use indexed rendering instead of generating a unique vertex buffer for each primitive.
//implementation: put all roblox primitives into one model.groups <- this won't work but I forget why
pub fn generate_partial_unit_cube(face_descriptions:CubeFaceDescription)->crate::model::IndexedModel{
let mut generated_pos=Vec::new();
let mut generated_tex=Vec::new();
let mut generated_normal=Vec::new();
let mut generated_color=Vec::new();
let mut generated_vertices=Vec::new();
let mut groups=Vec::new();
let mut transforms=Vec::new();
//note that on a cube every vertex is guaranteed to be unique, so there's no need to hash them against existing vertices.
for (face,face_description) in face_descriptions.into_iter(){
//assume that scanning short lists is faster than hashing.
let transform_index=if let Some(transform_index)=transforms.iter().position(|&transform|transform==face_description.transform){
transform_index
}else{
//create new transform_index
let transform_index=transforms.len();
transforms.push(face_description.transform);
for tex in CUBE_DEFAULT_TEXTURE_COORDS{
generated_tex.push(face_description.transform.transform_point2(tex));
}
transform_index
} as u32;
let color_index=if let Some(color_index)=generated_color.iter().position(|&color|color==face_description.color){
color_index
}else{
//create new color_index
let color_index=generated_color.len();
generated_color.push(face_description.color);
color_index
} as u32;
let face_id=match face{
CubeFace::Right => 0,
CubeFace::Top => 1,
CubeFace::Back => 2,
CubeFace::Left => 3,
CubeFace::Bottom => 4,
CubeFace::Front => 5,
};
//always push normal
let normal_index=generated_normal.len() as u32;
generated_normal.push(CUBE_DEFAULT_NORMALS[face_id]);
//push vertices as they are needed
groups.push(IndexedGroup{
texture:face_description.texture,
polys:vec![IndexedPolygon{
vertices:CUBE_DEFAULT_POLYS[face_id].map(|tup|{
let pos=CUBE_DEFAULT_VERTICES[tup[0] as usize];
let pos_index=if let Some(pos_index)=generated_pos.iter().position(|&p|p==pos){
pos_index
}else{
//create new pos_index
let pos_index=generated_pos.len();
generated_pos.push(pos);
pos_index
} as u32;
//always push vertex
let vertex=IndexedVertex{
pos:pos_index,
tex:tup[1]+4*transform_index,
normal:normal_index,
color:color_index,
};
let vert_index=generated_vertices.len();
generated_vertices.push(vertex);
vert_index as u32
}).to_vec(),
}],
});
}
IndexedModel{
unique_pos:generated_pos,
unique_tex:generated_tex,
unique_normal:generated_normal,
unique_color:generated_color,
unique_vertices:generated_vertices,
groups,
instances:Vec::new(),
}
}
//don't think too hard about the copy paste because this is all going into the map tool eventually...
pub fn generate_partial_unit_wedge(face_descriptions:WedgeFaceDescription)->crate::model::IndexedModel{
let wedge_default_polys=vec![
// right (1, 0, 0)
vec![
[6,2,0],//[vertex,tex,norm]
[2,0,0],
[1,3,0],
],
// FrontTop (0, 1, -1)
vec![
[3,1,1],
[2,0,1],
[6,3,1],
[7,2,1],
],
// back (0, 0, 1)
vec![
[0,3,2],
[1,2,2],
[2,1,2],
[3,0,2],
],
// left (-1, 0, 0)
vec![
[0,2,3],
[3,1,3],
[7,3,3],
],
// bottom (0,-1, 0)
vec![
[1,1,4],
[0,0,4],
[7,3,4],
[6,2,4],
],
];
let mut generated_pos=Vec::new();
let mut generated_tex=Vec::new();
let mut generated_normal=Vec::new();
let mut generated_color=Vec::new();
let mut generated_vertices=Vec::new();
let mut groups=Vec::new();
let mut transforms=Vec::new();
//note that on a cube every vertex is guaranteed to be unique, so there's no need to hash them against existing vertices.
for (face,face_description) in face_descriptions.into_iter(){
//assume that scanning short lists is faster than hashing.
let transform_index=if let Some(transform_index)=transforms.iter().position(|&transform|transform==face_description.transform){
transform_index
}else{
//create new transform_index
let transform_index=transforms.len();
transforms.push(face_description.transform);
for tex in CUBE_DEFAULT_TEXTURE_COORDS{
generated_tex.push(face_description.transform.transform_point2(tex));
}
transform_index
} as u32;
let color_index=if let Some(color_index)=generated_color.iter().position(|&color|color==face_description.color){
color_index
}else{
//create new color_index
let color_index=generated_color.len();
generated_color.push(face_description.color);
color_index
} as u32;
let face_id=match face{
WedgeFace::Right => 0,
WedgeFace::TopFront => 1,
WedgeFace::Back => 2,
WedgeFace::Left => 3,
WedgeFace::Bottom => 4,
};
//always push normal
let normal_index=generated_normal.len() as u32;
generated_normal.push(WEDGE_DEFAULT_NORMALS[face_id]);
//push vertices as they are needed
groups.push(IndexedGroup{
texture:face_description.texture,
polys:vec![IndexedPolygon{
vertices:wedge_default_polys[face_id].iter().map(|tup|{
let pos=CUBE_DEFAULT_VERTICES[tup[0] as usize];
let pos_index=if let Some(pos_index)=generated_pos.iter().position(|&p|p==pos){
pos_index
}else{
//create new pos_index
let pos_index=generated_pos.len();
generated_pos.push(pos);
pos_index
} as u32;
//always push vertex
let vertex=IndexedVertex{
pos:pos_index,
tex:tup[1]+4*transform_index,
normal:normal_index,
color:color_index,
};
let vert_index=generated_vertices.len();
generated_vertices.push(vertex);
vert_index as u32
}).collect(),
}],
});
}
IndexedModel{
unique_pos:generated_pos,
unique_tex:generated_tex,
unique_normal:generated_normal,
unique_color:generated_color,
unique_vertices:generated_vertices,
groups,
instances:Vec::new(),
}
}
pub fn generate_partial_unit_cornerwedge(face_descriptions:CornerWedgeFaceDescription)->crate::model::IndexedModel{
let cornerwedge_default_polys=vec![
// right (1, 0, 0)
vec![
[6,2,0],//[vertex,tex,norm]
[5,1,0],
[1,3,0],
],
// BackTop (0, 1, 1)
vec![
[5,3,1],
[0,1,1],
[1,0,1],
],
// LeftTop (-1, 1, 0)
vec![
[5,3,2],
[7,2,2],
[0,1,2],
],
// bottom (0,-1, 0)
vec![
[1,1,3],
[0,0,3],
[7,3,3],
[6,2,3],
],
// front (0, 0,-1)
vec![
[5,0,4],
[6,3,4],
[7,2,4],
],
];
let mut generated_pos=Vec::new();
let mut generated_tex=Vec::new();
let mut generated_normal=Vec::new();
let mut generated_color=Vec::new();
let mut generated_vertices=Vec::new();
let mut groups=Vec::new();
let mut transforms=Vec::new();
//note that on a cube every vertex is guaranteed to be unique, so there's no need to hash them against existing vertices.
for (face,face_description) in face_descriptions.into_iter(){
//assume that scanning short lists is faster than hashing.
let transform_index=if let Some(transform_index)=transforms.iter().position(|&transform|transform==face_description.transform){
transform_index
}else{
//create new transform_index
let transform_index=transforms.len();
transforms.push(face_description.transform);
for tex in CUBE_DEFAULT_TEXTURE_COORDS{
generated_tex.push(face_description.transform.transform_point2(tex));
}
transform_index
} as u32;
let color_index=if let Some(color_index)=generated_color.iter().position(|&color|color==face_description.color){
color_index
}else{
//create new color_index
let color_index=generated_color.len();
generated_color.push(face_description.color);
color_index
} as u32;
let face_id=match face{
CornerWedgeFace::Right => 0,
CornerWedgeFace::TopBack => 1,
CornerWedgeFace::TopLeft => 2,
CornerWedgeFace::Bottom => 3,
CornerWedgeFace::Front => 4,
};
//always push normal
let normal_index=generated_normal.len() as u32;
generated_normal.push(CORNERWEDGE_DEFAULT_NORMALS[face_id]);
//push vertices as they are needed
groups.push(IndexedGroup{
texture:face_description.texture,
polys:vec![IndexedPolygon{
vertices:cornerwedge_default_polys[face_id].iter().map(|tup|{
let pos=CUBE_DEFAULT_VERTICES[tup[0] as usize];
let pos_index=if let Some(pos_index)=generated_pos.iter().position(|&p|p==pos){
pos_index
}else{
//create new pos_index
let pos_index=generated_pos.len();
generated_pos.push(pos);
pos_index
} as u32;
//always push vertex
let vertex=IndexedVertex{
pos:pos_index,
tex:tup[1]+4*transform_index,
normal:normal_index,
color:color_index,
};
let vert_index=generated_vertices.len();
generated_vertices.push(vertex);
vert_index as u32
}).collect(),
}],
});
}
IndexedModel{
unique_pos:generated_pos,
unique_tex:generated_tex,
unique_normal:generated_normal,
unique_color:generated_color,
unique_vertices:generated_vertices,
groups,
instances:Vec::new(),
}
}

View File

@ -1,129 +0,0 @@
use crate::integer::Time;
use crate::physics::{MouseState,PhysicsInputInstruction};
use crate::instruction::{TimedInstruction,InstructionConsumer};
#[derive(Debug)]
pub enum InputInstruction {
MoveMouse(glam::IVec2),
MoveRight(bool),
MoveUp(bool),
MoveBack(bool),
MoveLeft(bool),
MoveDown(bool),
MoveForward(bool),
Jump(bool),
Zoom(bool),
Reset,
Render,
//Idle: there were no input events, but the simulation is safe to advance to this timestep
//for interpolation / networking / playback reasons, most playback heads will always want
//to be 1 instruction ahead to generate the next state for interpolation.
}
pub struct RenderState{
physics:crate::physics::PhysicsState,
graphics:crate::graphics::GraphicsState,
}
impl RenderState{
pub fn new(user_settings:&crate::settings::UserSettings,indexed_model_instances:crate::model::IndexedModelInstances){
let mut physics=crate::physics::PhysicsState::default();
physics.spawn(indexed_model_instances.spawn_point);
physics.load_user_settings(user_settings);
physics.generate_models(&indexed_model_instances);
let mut graphics=Self::new_graphics_state();
graphics.load_user_settings(user_settings);
graphics.generate_models(indexed_model_instances);
//manual reset
}
pub fn into_worker(mut self)->crate::worker::CNWorker<TimedInstruction<InputInstruction>>{
let mut mouse_blocking=true;
let mut last_mouse_time=self.physics.next_mouse.time;
let mut timeline=std::collections::VecDeque::new();
crate::worker::CNWorker::new(move |ins:TimedInstruction<InputInstruction>|{
let mut render=false;
if if let Some(phys_input)=match ins.instruction{
InputInstruction::MoveMouse(m)=>{
if mouse_blocking{
//tell the game state which is living in the past about its future
timeline.push_front(TimedInstruction{
time:last_mouse_time,
instruction:PhysicsInputInstruction::SetNextMouse(MouseState{time:ins.time,pos:m}),
});
}else{
//mouse has just started moving again after being still for longer than 10ms.
//replace the entire mouse interpolation state to avoid an intermediate state with identical m0.t m1.t timestamps which will divide by zero
timeline.push_front(TimedInstruction{
time:last_mouse_time,
instruction:PhysicsInputInstruction::ReplaceMouse(
MouseState{time:last_mouse_time,pos:self.physics.next_mouse.pos},
MouseState{time:ins.time,pos:m}
),
});
//delay physics execution until we have an interpolation target
mouse_blocking=true;
}
last_mouse_time=ins.time;
None
},
InputInstruction::MoveForward(s)=>Some(PhysicsInputInstruction::SetMoveForward(s)),
InputInstruction::MoveLeft(s)=>Some(PhysicsInputInstruction::SetMoveLeft(s)),
InputInstruction::MoveBack(s)=>Some(PhysicsInputInstruction::SetMoveBack(s)),
InputInstruction::MoveRight(s)=>Some(PhysicsInputInstruction::SetMoveRight(s)),
InputInstruction::MoveUp(s)=>Some(PhysicsInputInstruction::SetMoveUp(s)),
InputInstruction::MoveDown(s)=>Some(PhysicsInputInstruction::SetMoveDown(s)),
InputInstruction::Jump(s)=>Some(PhysicsInputInstruction::SetJump(s)),
InputInstruction::Zoom(s)=>Some(PhysicsInputInstruction::SetZoom(s)),
InputInstruction::Reset=>Some(PhysicsInputInstruction::Reset),
InputInstruction::Render=>{render=true;Some(PhysicsInputInstruction::Idle)},
}{
//non-mouse event
timeline.push_back(TimedInstruction{
time:ins.time,
instruction:phys_input,
});
if mouse_blocking{
//assume the mouse has stopped moving after 10ms.
//shitty mice are 125Hz which is 8ms so this should cover that.
//setting this to 100us still doesn't print even though it's 10x lower than the polling rate,
//so mouse events are probably not handled separately from drawing and fire right before it :(
if Time::from_millis(10)<ins.time-self.physics.next_mouse.time{
//push an event to extrapolate no movement from
timeline.push_front(TimedInstruction{
time:last_mouse_time,
instruction:PhysicsInputInstruction::SetNextMouse(MouseState{time:ins.time,pos:self.physics.next_mouse.pos}),
});
last_mouse_time=ins.time;
//stop blocking. the mouse is not moving so the physics does not need to live in the past and wait for interpolation targets.
mouse_blocking=false;
true
}else{
false
}
}else{
//keep this up to date so that it can be used as a known-timestamp
//that the mouse was not moving when the mouse starts moving again
last_mouse_time=ins.time;
true
}
}else{
//mouse event
true
}{
//empty queue
while let Some(instruction)=timeline.pop_front(){
self.physics.run(instruction.time);
self.physics.process_instruction(TimedInstruction{
time:instruction.time,
instruction:crate::physics::PhysicsInstruction::Input(instruction.instruction),
});
}
}
if render{
self.graphics.render();
}
})
}
}

View File

@ -1,11 +1,14 @@
use crate::integer::{Ratio64,Ratio64Vec2};
use strafesnet_common::integer::{Ratio64,Ratio64Vec2};
#[derive(Clone)]
struct Ratio{
ratio:f64,
}
#[derive(Clone)]
enum DerivedFov{
FromScreenAspect,
FromAspect(Ratio),
}
#[derive(Clone)]
enum Fov{
Exactly{x:f64,y:f64},
SpecifyXDeriveY{x:f64,y:DerivedFov},
@ -16,9 +19,11 @@ impl Default for Fov{
Fov::SpecifyYDeriveX{x:DerivedFov::FromScreenAspect,y:1.0}
}
}
#[derive(Clone)]
enum DerivedSensitivity{
FromRatio(Ratio64),
}
#[derive(Clone)]
enum Sensitivity{
Exactly{x:Ratio64,y:Ratio64},
SpecifyXDeriveY{x:Ratio64,y:DerivedSensitivity},
@ -30,7 +35,7 @@ impl Default for Sensitivity{
}
}
#[derive(Default)]
#[derive(Default,Clone)]
pub struct UserSettings{
fov:Fov,
sensitivity:Sensitivity,

292
src/setup.rs Normal file
View File

@ -0,0 +1,292 @@
use crate::window::WindowInstruction;
use strafesnet_common::instruction::TimedInstruction;
use strafesnet_common::integer;
fn optional_features()->wgpu::Features{
wgpu::Features::TEXTURE_COMPRESSION_ASTC
|wgpu::Features::TEXTURE_COMPRESSION_ETC2
}
fn required_features()->wgpu::Features{
wgpu::Features::TEXTURE_COMPRESSION_BC
}
fn required_downlevel_capabilities()->wgpu::DownlevelCapabilities{
wgpu::DownlevelCapabilities{
flags:wgpu::DownlevelFlags::empty(),
shader_model:wgpu::ShaderModel::Sm5,
..wgpu::DownlevelCapabilities::default()
}
}
pub fn required_limits()->wgpu::Limits{
wgpu::Limits::default()
}
struct SetupContextPartial1{
backends:wgpu::Backends,
instance:wgpu::Instance,
}
fn create_window(title:&str,event_loop:&winit::event_loop::EventLoop<()>)->Result<winit::window::Window,winit::error::OsError>{
let mut attr=winit::window::WindowAttributes::default();
attr=attr.with_title(title);
#[cfg(windows_OFF)] // TODO
{
use winit::platform::windows::WindowBuilderExtWindows;
builder=builder.with_no_redirection_bitmap(true);
}
event_loop.create_window(attr)
}
fn create_instance()->SetupContextPartial1{
let backends=wgpu::util::backend_bits_from_env().unwrap_or_else(wgpu::Backends::all);
let dx12_shader_compiler=wgpu::util::dx12_shader_compiler_from_env().unwrap_or_default();
SetupContextPartial1{
backends,
instance:wgpu::Instance::new(wgpu::InstanceDescriptor{
backends,
dx12_shader_compiler,
..Default::default()
}),
}
}
impl SetupContextPartial1{
fn create_surface<'a>(self,window:&'a winit::window::Window)->Result<SetupContextPartial2<'a>,wgpu::CreateSurfaceError>{
Ok(SetupContextPartial2{
backends:self.backends,
surface:self.instance.create_surface(window)?,
instance:self.instance,
})
}
}
struct SetupContextPartial2<'a>{
backends:wgpu::Backends,
instance:wgpu::Instance,
surface:wgpu::Surface<'a>,
}
impl<'a> SetupContextPartial2<'a>{
fn pick_adapter(self)->SetupContextPartial3<'a>{
let adapter;
//TODO: prefer adapter that implements optional features
//let optional_features=optional_features();
let required_features=required_features();
//no helper function smh gotta write it myself
let adapters=self.instance.enumerate_adapters(self.backends);
let mut chosen_adapter=None;
let mut chosen_adapter_score=0;
for adapter in adapters {
if !adapter.is_surface_supported(&self.surface) {
continue;
}
let score=match adapter.get_info().device_type{
wgpu::DeviceType::IntegratedGpu=>3,
wgpu::DeviceType::DiscreteGpu=>4,
wgpu::DeviceType::VirtualGpu=>2,
wgpu::DeviceType::Other|wgpu::DeviceType::Cpu=>1,
};
let adapter_features=adapter.features();
if chosen_adapter_score<score&&adapter_features.contains(required_features) {
chosen_adapter_score=score;
chosen_adapter=Some(adapter);
}
}
if let Some(maybe_chosen_adapter)=chosen_adapter{
adapter=maybe_chosen_adapter;
}else{
panic!("No suitable GPU adapters found on the system!");
}
let adapter_info=adapter.get_info();
println!("Using {} ({:?})", adapter_info.name, adapter_info.backend);
let required_downlevel_capabilities=required_downlevel_capabilities();
let downlevel_capabilities=adapter.get_downlevel_capabilities();
assert!(
downlevel_capabilities.shader_model >= required_downlevel_capabilities.shader_model,
"Adapter does not support the minimum shader model required to run this example: {:?}",
required_downlevel_capabilities.shader_model
);
assert!(
downlevel_capabilities
.flags
.contains(required_downlevel_capabilities.flags),
"Adapter does not support the downlevel capabilities required to run this example: {:?}",
required_downlevel_capabilities.flags - downlevel_capabilities.flags
);
SetupContextPartial3{
instance:self.instance,
surface:self.surface,
adapter,
}
}
}
struct SetupContextPartial3<'a>{
instance:wgpu::Instance,
surface:wgpu::Surface<'a>,
adapter:wgpu::Adapter,
}
impl<'a> SetupContextPartial3<'a>{
fn request_device(self)->SetupContextPartial4<'a>{
let optional_features=optional_features();
let required_features=required_features();
// Make sure we use the texture resolution limits from the adapter, so we can support images the size of the surface.
let needed_limits=required_limits().using_resolution(self.adapter.limits());
let trace_dir=std::env::var("WGPU_TRACE");
let (device, queue)=pollster::block_on(self.adapter
.request_device(
&wgpu::DeviceDescriptor {
label: None,
required_features: (optional_features & self.adapter.features()) | required_features,
required_limits: needed_limits,
memory_hints:wgpu::MemoryHints::Performance,
},
trace_dir.ok().as_ref().map(std::path::Path::new),
))
.expect("Unable to find a suitable GPU adapter!");
SetupContextPartial4{
instance:self.instance,
surface:self.surface,
adapter:self.adapter,
device,
queue,
}
}
}
struct SetupContextPartial4<'a>{
instance:wgpu::Instance,
surface:wgpu::Surface<'a>,
adapter:wgpu::Adapter,
device:wgpu::Device,
queue:wgpu::Queue,
}
impl<'a> SetupContextPartial4<'a>{
fn configure_surface(self,size:&'a winit::dpi::PhysicalSize<u32>)->SetupContext<'a>{
let mut config=self.surface
.get_default_config(&self.adapter, size.width, size.height)
.expect("Surface isn't supported by the adapter.");
let surface_view_format=config.format.add_srgb_suffix();
config.view_formats.push(surface_view_format);
config.present_mode=wgpu::PresentMode::AutoNoVsync;
self.surface.configure(&self.device, &config);
SetupContext{
instance:self.instance,
surface:self.surface,
device:self.device,
queue:self.queue,
config,
}
}
}
pub struct SetupContext<'a>{
pub instance:wgpu::Instance,
pub surface:wgpu::Surface<'a>,
pub device:wgpu::Device,
pub queue:wgpu::Queue,
pub config:wgpu::SurfaceConfiguration,
}
pub fn setup_and_start(title:String){
let event_loop=winit::event_loop::EventLoop::new().unwrap();
println!("Initializing the surface...");
let partial_1=create_instance();
let window=create_window(title.as_str(),&event_loop).unwrap();
let partial_2=partial_1.create_surface(&window).unwrap();
let partial_3=partial_2.pick_adapter();
let partial_4=partial_3.request_device();
let size=window.inner_size();
let setup_context=partial_4.configure_surface(&size);
//dedicated thread to ping request redraw back and resize the window doesn't seem logical
//the thread that spawns the physics thread
let mut window_thread=crate::window::worker(
&window,
setup_context,
);
if let Some(arg)=std::env::args().nth(1){
let path=std::path::PathBuf::from(arg);
window_thread.send(TimedInstruction{
time:integer::Time::ZERO,
instruction:WindowInstruction::WindowEvent(winit::event::WindowEvent::DroppedFile(path)),
}).unwrap();
};
println!("Entering event loop...");
let root_time=std::time::Instant::now();
run_event_loop(event_loop,window_thread,root_time).unwrap();
}
fn run_event_loop(
event_loop:winit::event_loop::EventLoop<()>,
mut window_thread:crate::compat_worker::QNWorker<TimedInstruction<WindowInstruction>>,
root_time:std::time::Instant
)->Result<(),winit::error::EventLoopError>{
event_loop.run(move |event,elwt|{
let time=integer::Time::from_nanos(root_time.elapsed().as_nanos() as i64);
// *control_flow=if cfg!(feature="metal-auto-capture"){
// winit::event_loop::ControlFlow::Exit
// }else{
// winit::event_loop::ControlFlow::Poll
// };
match event{
winit::event::Event::AboutToWait=>{
window_thread.send(TimedInstruction{time,instruction:WindowInstruction::RequestRedraw}).unwrap();
}
winit::event::Event::WindowEvent {
event:
// WindowEvent::Resized(size)
// | WindowEvent::ScaleFactorChanged {
// new_inner_size: &mut size,
// ..
// },
winit::event::WindowEvent::Resized(size),//ignoring scale factor changed for now because mutex bruh
window_id:_,
} => {
window_thread.send(TimedInstruction{time,instruction:WindowInstruction::Resize(size)}).unwrap();
}
winit::event::Event::WindowEvent{event,..}=>match event{
winit::event::WindowEvent::KeyboardInput{
event:
winit::event::KeyEvent {
logical_key: winit::keyboard::Key::Named(winit::keyboard::NamedKey::Escape),
state: winit::event::ElementState::Pressed,
..
},
..
}
|winit::event::WindowEvent::CloseRequested=>{
elwt.exit();
}
winit::event::WindowEvent::RedrawRequested=>{
window_thread.send(TimedInstruction{time,instruction:WindowInstruction::Render}).unwrap();
}
_=>{
window_thread.send(TimedInstruction{time,instruction:WindowInstruction::WindowEvent(event)}).unwrap();
}
},
winit::event::Event::DeviceEvent{
event,
..
} => {
window_thread.send(TimedInstruction{time,instruction:WindowInstruction::DeviceEvent(event)}).unwrap();
},
_=>{}
}
})
}

View File

@ -48,7 +48,7 @@ struct ModelInstance{
//my fancy idea is to create a megatexture for each model that includes all the textures each intance will need
//the texture transform then maps the texture coordinates to the location of the specific texture
//group 1 is the model
const MAX_MODEL_INSTANCES=4096;
const MAX_MODEL_INSTANCES=512;
@group(2)
@binding(0)
var<uniform> model_instances: array<ModelInstance, MAX_MODEL_INSTANCES>;

View File

@ -1,8 +0,0 @@
//something that implements body + hitbox + transform can predict collision
impl crate::sweep::PredictCollision for Model {
fn predict_collision(&self,other:&Model) -> Option<crate::event::EventStruct> {
//math!
None
}
}

View File

@ -1,50 +1,71 @@
pub struct WindowState{
//ok
}
impl WindowState{
fn resize(&mut self);
fn render(&self);
use crate::physics_worker::InputInstruction;
use strafesnet_common::integer;
use strafesnet_common::instruction::TimedInstruction;
fn update(&mut self, window: &winit::window::Window, event: winit::event::WindowEvent) {
let time=integer::Time::from_nanos(self.start_time.elapsed().as_nanos() as i64);
pub enum WindowInstruction{
Resize(winit::dpi::PhysicalSize<u32>),
WindowEvent(winit::event::WindowEvent),
DeviceEvent(winit::event::DeviceEvent),
RequestRedraw,
Render,
}
//holds thread handles to dispatch to
struct WindowContext<'a>{
manual_mouse_lock:bool,
mouse:strafesnet_common::mouse::MouseState,//std::sync::Arc<std::sync::Mutex<>>
screen_size:glam::UVec2,
window:&'a winit::window::Window,
physics_thread:crate::compat_worker::QNWorker<'a, TimedInstruction<crate::physics_worker::Instruction>>,
}
impl WindowContext<'_>{
fn get_middle_of_screen(&self)->winit::dpi::PhysicalPosition<f32>{
winit::dpi::PhysicalPosition::new(self.screen_size.x as f32/2.0,self.screen_size.y as f32/2.0)
}
fn window_event(&mut self,time:integer::Time,event: winit::event::WindowEvent) {
match event {
winit::event::WindowEvent::DroppedFile(path)=>{
std::thread::spawn(move ||{
let indexed_model_instances=load_file(path);
self.render_thread.send(Instruction::Die(indexed_model_instances));
});
match crate::file::load(path.as_path()){
Ok(map)=>self.physics_thread.send(TimedInstruction{time,instruction:crate::physics_worker::Instruction::ChangeMap(map)}).unwrap(),
Err(e)=>println!("Failed to load map: {e}"),
}
},
winit::event::WindowEvent::Focused(state)=>{
//pause unpause
self.physics_thread.send(TimedInstruction{
time,
instruction:crate::physics_worker::Instruction::SetPaused(!state),
}).unwrap();
//recalculate pressed keys on focus
},
winit::event::WindowEvent::KeyboardInput {
input:winit::event::KeyboardInput{state, virtual_keycode,..},
winit::event::WindowEvent::KeyboardInput{
event:winit::event::KeyEvent{state,logical_key,repeat:false,..},
..
}=>{
let s=match state {
winit::event::ElementState::Pressed => true,
winit::event::ElementState::Released => false,
let s=match state{
winit::event::ElementState::Pressed=>true,
winit::event::ElementState::Released=>false,
};
match virtual_keycode{
Some(winit::event::VirtualKeyCode::Tab)=>{
match logical_key{
winit::keyboard::Key::Named(winit::keyboard::NamedKey::Tab)=>{
if s{
self.manual_mouse_lock=false;
match window.set_cursor_position(winit::dpi::PhysicalPosition::new(self.graphics.camera.screen_size.x as f32/2.0, self.graphics.camera.screen_size.y as f32/2.0)){
match self.window.set_cursor_position(self.get_middle_of_screen()){
Ok(())=>(),
Err(e)=>println!("Could not set cursor position: {:?}",e),
}
match window.set_cursor_grab(winit::window::CursorGrabMode::None){
match self.window.set_cursor_grab(winit::window::CursorGrabMode::None){
Ok(())=>(),
Err(e)=>println!("Could not release cursor: {:?}",e),
}
}else{
//if cursor is outside window don't lock but apparently there's no get pos function
//let pos=window.get_cursor_pos();
match window.set_cursor_grab(winit::window::CursorGrabMode::Locked){
match self.window.set_cursor_grab(winit::window::CursorGrabMode::Locked){
Ok(())=>(),
Err(_)=>{
match window.set_cursor_grab(winit::window::CursorGrabMode::Confined){
match self.window.set_cursor_grab(winit::window::CursorGrabMode::Confined){
Ok(())=>(),
Err(e)=>{
self.manual_mouse_lock=true;
@ -54,62 +75,67 @@ impl WindowState{
}
}
}
window.set_cursor_visible(s);
self.window.set_cursor_visible(s);
},
Some(winit::event::VirtualKeyCode::F11)=>{
winit::keyboard::Key::Named(winit::keyboard::NamedKey::F11)=>{
if s{
if window.fullscreen().is_some(){
window.set_fullscreen(None);
if self.window.fullscreen().is_some(){
self.window.set_fullscreen(None);
}else{
window.set_fullscreen(Some(winit::window::Fullscreen::Borderless(None)));
self.window.set_fullscreen(Some(winit::window::Fullscreen::Borderless(None)));
}
}
},
Some(winit::event::VirtualKeyCode::Escape)=>{
winit::keyboard::Key::Named(winit::keyboard::NamedKey::Escape)=>{
if s{
self.manual_mouse_lock=false;
match window.set_cursor_grab(winit::window::CursorGrabMode::None){
match self.window.set_cursor_grab(winit::window::CursorGrabMode::None){
Ok(())=>(),
Err(e)=>println!("Could not release cursor: {:?}",e),
}
window.set_cursor_visible(true);
self.window.set_cursor_visible(true);
}
},
Some(keycode)=>{
if let Some(input_instruction)=match keycode {
winit::event::VirtualKeyCode::W => Some(InputInstruction::MoveForward(s)),
winit::event::VirtualKeyCode::A => Some(InputInstruction::MoveLeft(s)),
winit::event::VirtualKeyCode::S => Some(InputInstruction::MoveBack(s)),
winit::event::VirtualKeyCode::D => Some(InputInstruction::MoveRight(s)),
winit::event::VirtualKeyCode::E => Some(InputInstruction::MoveUp(s)),
winit::event::VirtualKeyCode::Q => Some(InputInstruction::MoveDown(s)),
winit::event::VirtualKeyCode::Space => Some(InputInstruction::Jump(s)),
winit::event::VirtualKeyCode::Z => Some(InputInstruction::Zoom(s)),
winit::event::VirtualKeyCode::R => if s{Some(InputInstruction::Reset)}else{None},
_ => None,
keycode=>{
if let Some(input_instruction)=match keycode{
winit::keyboard::Key::Named(winit::keyboard::NamedKey::Space)=>Some(InputInstruction::Jump(s)),
winit::keyboard::Key::Character(key)=>match key.as_str(){
"w"=>Some(InputInstruction::MoveForward(s)),
"a"=>Some(InputInstruction::MoveLeft(s)),
"s"=>Some(InputInstruction::MoveBack(s)),
"d"=>Some(InputInstruction::MoveRight(s)),
"e"=>Some(InputInstruction::MoveUp(s)),
"q"=>Some(InputInstruction::MoveDown(s)),
"z"=>Some(InputInstruction::Zoom(s)),
"r"=>if s{
//mouse needs to be reset since the position is absolute
self.mouse=strafesnet_common::mouse::MouseState::default();
Some(InputInstruction::ResetAndRestart)
}else{None},
"f"=>if s{Some(InputInstruction::PracticeFly)}else{None},
_=>None,
},
_=>None,
}{
self.physics_thread.send(TimedInstruction{
time,
instruction:input_instruction,
instruction:crate::physics_worker::Instruction::Input(input_instruction),
}).unwrap();
}
},
_=>(),
}
},
_=>(),
}
}
fn device_event(&mut self, window: &winit::window::Window, event: winit::event::DeviceEvent) {
//there's no way this is the best way get a timestamp.
let time=integer::Time::from_nanos(self.start_time.elapsed().as_nanos() as i64);
fn device_event(&mut self,time:integer::Time,event: winit::event::DeviceEvent) {
match event {
winit::event::DeviceEvent::MouseMotion {
delta,//these (f64,f64) are integers on my machine
} => {
if self.manual_mouse_lock{
match window.set_cursor_position(winit::dpi::PhysicalPosition::new(self.graphics.camera.screen_size.x as f32/2.0, self.graphics.camera.screen_size.y as f32/2.0)){
match self.window.set_cursor_position(self.get_middle_of_screen()){
Ok(())=>(),
Err(e)=>println!("Could not set cursor position: {:?}",e),
}
@ -121,7 +147,7 @@ impl WindowState{
self.mouse.pos+=delta;
self.physics_thread.send(TimedInstruction{
time,
instruction:InputInstruction::MoveMouse(self.mouse.pos),
instruction:crate::physics_worker::Instruction::Input(InputInstruction::MoveMouse(self.mouse.pos)),
}).unwrap();
},
winit::event::DeviceEvent::MouseWheel {
@ -131,22 +157,67 @@ impl WindowState{
if false{//self.physics.style.use_scroll{
self.physics_thread.send(TimedInstruction{
time,
instruction:InputInstruction::Jump(true),//activates the immediate jump path, but the style modifier prevents controls&CONTROL_JUMP bit from being set to auto jump
instruction:crate::physics_worker::Instruction::Input(InputInstruction::Jump(true)),//activates the immediate jump path, but the style modifier prevents controls&CONTROL_JUMP bit from being set to auto jump
}).unwrap();
}
}
_=>(),
}
}
pub fn create_window(title:&str,event_loop:&winit::event_loop::EventLoop<()>)->Result<winit::window::Window,winit::error::OsError>{
let mut builder = winit::window::WindowBuilder::new();
builder = builder.with_title(title);
#[cfg(windows_OFF)] // TODO
{
use winit::platform::windows::WindowBuilderExtWindows;
builder = builder.with_no_redirection_bitmap(true);
}
builder.build(event_loop)
}
}
pub fn worker<'a>(
window:&'a winit::window::Window,
setup_context:crate::setup::SetupContext<'a>,
)->crate::compat_worker::QNWorker<'a,TimedInstruction<WindowInstruction>>{
// WindowContextSetup::new
let user_settings=crate::settings::read_user_settings();
let mut graphics=crate::graphics::GraphicsState::new(&setup_context.device,&setup_context.queue,&setup_context.config);
graphics.load_user_settings(&user_settings);
//WindowContextSetup::into_context
let screen_size=glam::uvec2(setup_context.config.width,setup_context.config.height);
let graphics_thread=crate::graphics_worker::new(graphics,setup_context.config,setup_context.surface,setup_context.device,setup_context.queue);
let mut window_context=WindowContext{
manual_mouse_lock:false,
mouse:strafesnet_common::mouse::MouseState::default(),
//make sure to update this!!!!!
screen_size,
window,
physics_thread:crate::physics_worker::new(
graphics_thread,
user_settings,
),
};
//WindowContextSetup::into_worker
crate::compat_worker::QNWorker::new(move |ins:TimedInstruction<WindowInstruction>|{
match ins.instruction{
WindowInstruction::RequestRedraw=>{
window_context.window.request_redraw();
}
WindowInstruction::WindowEvent(window_event)=>{
window_context.window_event(ins.time,window_event);
},
WindowInstruction::DeviceEvent(device_event)=>{
window_context.device_event(ins.time,device_event);
},
WindowInstruction::Resize(size)=>{
window_context.physics_thread.send(
TimedInstruction{
time:ins.time,
instruction:crate::physics_worker::Instruction::Resize(size)
}
).unwrap();
}
WindowInstruction::Render=>{
window_context.physics_thread.send(
TimedInstruction{
time:ins.time,
instruction:crate::physics_worker::Instruction::Render
}
).unwrap();
}
}
})
}

View File

@ -1,6 +1,6 @@
use std::thread;
use std::sync::{mpsc,Arc};
use parking_lot::{Mutex,Condvar};
use parking_lot::Mutex;
//WorkerPool
struct Pool(u32);
@ -104,17 +104,15 @@ QN = WorkerDescription{
}
*/
//None Output Worker does all its work internally from the perspective of the work submitter
pub struct QNWorker<Task:Send> {
pub struct QNWorker<'a,Task:Send>{
sender: mpsc::Sender<Task>,
handle:thread::ScopedJoinHandle<'a,()>,
}
impl<Task:Send+'static> QNWorker<Task>{
pub fn new<F:FnMut(Task)+Send+'static>(mut f:F)->Self{
impl<'a,Task:Send+'a> QNWorker<'a,Task>{
pub fn new<F:FnMut(Task)+Send+'a>(scope:&'a thread::Scope<'a,'_>,mut f:F)->QNWorker<'a,Task>{
let (sender,receiver)=mpsc::channel::<Task>();
let ret=Self {
sender,
};
thread::spawn(move ||{
let handle=scope.spawn(move ||{
loop {
match receiver.recv() {
Ok(task)=>f(task),
@ -125,7 +123,10 @@ impl<Task:Send+'static> QNWorker<Task>{
}
}
});
ret
Self{
sender,
handle,
}
}
pub fn send(&self,task:Task)->Result<(),mpsc::SendError<Task>>{
self.sender.send(task)
@ -139,120 +140,57 @@ IN = WorkerDescription{
}
*/
//Inputs are dropped if the worker is busy
pub struct INWorker<Task:Clone>{
input:Arc<(Mutex<Task>,Condvar)>,
pub struct INWorker<'a,Task:Send>{
sender: mpsc::SyncSender<Task>,
handle:thread::ScopedJoinHandle<'a,()>,
}
impl<Task:Clone+Send+'static> INWorker<Task>{
pub fn new<F:FnMut(Task)+Send+'static>(task:Task,mut f:F)->Self{
let ret=Self {
input:Arc::new((Mutex::new(task),Condvar::new())),
};
let input=ret.input.clone();
thread::spawn(move ||{
impl<'a,Task:Send+'a> INWorker<'a,Task>{
pub fn new<F:FnMut(Task)+Send+'a>(scope:&'a thread::Scope<'a,'_>,mut f:F)->INWorker<'a,Task>{
let (sender,receiver)=mpsc::sync_channel::<Task>(1);
let handle=scope.spawn(move ||{
loop {
input.1.wait(&mut input.0.lock());
f(input.0.lock().clone());
}
});
ret
}
pub fn send(&self,task:Task){
*self.input.0.lock()=task;
self.input.1.notify_one();
}
}
//worker pools work by cloning a mpsc and passing it into the thread, the thread sends its results through that
//worker pools have a master thread that manages the pool so that the work submission thread does not need to implement async
pub struct QQWorkerPool<Task:Send,Value:Send>{
sender:mpsc::Sender<Task>,
queue:Arc<Mutex<std::collections::VecDeque<Value>>>,
}
impl<Task:Send+'static,Value:Send+'static> QQWorkerPool<Task,Value>{
pub fn new<F:Fn(Task)->Value+Send+'static>(pool_size:usize,f:F)->Self{
let (task_sender,task_receiver)=mpsc::channel::<Task>();
let (value_sender,value_receiver)=mpsc::channel::<Value>();
let ret=Self{
sender:task_sender,
queue:Arc::new(Mutex::new(std::collections::VecDeque::new())),
};
let mut queue_collect=ret.queue.clone();
let mut worker_senders=Vec::with_capacity(pool_size);
let mut active_workers_collect=Arc::new(Mutex::new(0usize));
let mut active_workers_dispatch=active_workers_collect.clone();
let mut condvar_collect=Arc::new(Condvar::new());
let mut condvar_dispatch=condvar_collect.clone();
//task dispatch thread
thread::spawn(move ||{
loop{
//block if no workers are available, value collection thread will notify
let n=*active_workers_dispatch.lock();
if n==pool_size{
//wait for notifiy
condvar_dispatch.wait(&mut active_workers_dispatch.lock());
}
match task_receiver.recv(){
Ok(task)=>{
*active_workers_dispatch.lock()+=1;
//workers are never full here
//else if workers busy: spawn a new worker
//else: send task to an available worker
}
match receiver.recv() {
Ok(task)=>f(task),
Err(_)=>{
println!("Dispatch stopping.",);
println!("Worker stopping.",);
break;
}
}
}
});
//value collection thread (bad idea, put this logic in each thread)
thread::spawn(move ||{
loop{
match value_receiver.recv(){
Ok(value)=>{
//maybe I can be smart with this as a signal that a worker finished a task
let n=*active_workers_collect.lock();
*active_workers_collect.lock()-=1;
if n==pool_size{
condvar_collect.notify_one();
}
(*queue_collect.lock()).push_front(value);
}
Err(_)=>{
println!("Collection stopping.",);
break;
Self{
sender,
handle,
}
}
}
});
ret
}
pub fn send(&self,task:Task)->Result<(),mpsc::SendError<Task>>{
//blocking!
pub fn blocking_send(&self,task:Task)->Result<(), mpsc::SendError<Task>>{
self.sender.send(task)
}
pub fn get(&self)->Option<Value>{
(*self.queue.lock()).pop_back()
pub fn send(&self,task:Task)->Result<(), mpsc::TrySendError<Task>>{
self.sender.try_send(task)
}
}
#[test]//How to run this test with printing: cargo test --release -- --nocapture
fn test_worker() {
println!("hiiiii");
#[cfg(test)]
mod test{
use super::{thread,QRWorker};
use crate::physics;
use strafesnet_common::{integer,instruction};
#[test]//How to run this test with printing: cargo test --release -- --nocapture
fn test_worker() {
// Create the worker thread
let worker=QRWorker::new(crate::physics::Body::with_pva(crate::integer::Planar64Vec3::ZERO,crate::integer::Planar64Vec3::ZERO,crate::integer::Planar64Vec3::ZERO),
|_|crate::physics::Body::with_pva(crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE)
let test_body=physics::Body::new(integer::vec3::ONE,integer::vec3::ONE,integer::vec3::ONE,integer::Time::ZERO);
let worker=QRWorker::new(physics::Body::ZERO,
|_|physics::Body::new(integer::vec3::ONE,integer::vec3::ONE,integer::vec3::ONE,integer::Time::ZERO)
);
// Send tasks to the worker
for _ in 0..5 {
let task = crate::instruction::TimedInstruction{
time:crate::integer::Time::ZERO,
instruction:crate::physics::PhysicsInstruction::StrafeTick,
let task = instruction::TimedInstruction{
time:integer::Time::ZERO,
instruction:strafesnet_common::physics::Instruction::Idle,
};
worker.send(task).unwrap();
}
@ -261,17 +199,18 @@ fn test_worker() {
// sender.send("STOP".to_string()).unwrap();
// Sleep to allow the worker thread to finish processing
thread::sleep(std::time::Duration::from_secs(2));
thread::sleep(std::time::Duration::from_millis(10));
// Send a new task
let task = crate::instruction::TimedInstruction{
time:crate::integer::Time::ZERO,
instruction:crate::physics::PhysicsInstruction::StrafeTick,
let task = instruction::TimedInstruction{
time:integer::Time::ZERO,
instruction:strafesnet_common::physics::Instruction::Idle,
};
worker.send(task).unwrap();
println!("value={}",worker.grab_clone());
//assert_eq!(test_body,worker.grab_clone());
// wait long enough to see print from final task
thread::sleep(std::time::Duration::from_secs(1));
thread::sleep(std::time::Duration::from_millis(10));
}
}

View File

@ -1,32 +0,0 @@
//find roots of polynomials
use crate::integer::Planar64;
#[inline]
pub fn zeroes2(a0:Planar64,a1:Planar64,a2:Planar64) -> Vec<Planar64>{
if a2==Planar64::ZERO{
return zeroes1(a0, a1);
}
let radicand=a1.get() as i128*a1.get() as i128-a2.get() as i128*a0.get() as i128*4;
if 0<radicand {
//start with f64 sqrt
let planar_radicand=Planar64::raw(unsafe{(radicand as f64).sqrt().to_int_unchecked()});
//TODO: one or two newtons
if Planar64::ZERO<a2 {
return vec![(-a1-planar_radicand)/(a2*2),(-a1+planar_radicand)/(a2*2)];
} else {
return vec![(-a1+planar_radicand)/(a2*2),(-a1-planar_radicand)/(a2*2)];
}
} else if radicand==0 {
return vec![a1/(a2*-2)];
} else {
return vec![];
}
}
#[inline]
pub fn zeroes1(a0:Planar64,a1:Planar64) -> Vec<Planar64> {
if a1==Planar64::ZERO{
return vec![];
} else {
return vec![-a0/a1];
}
}

1
tools/arcane Executable file
View File

@ -0,0 +1 @@
mangohud ../target/release/strafe-client bhop_maps/5692113331.snfm

1
tools/bhop_maps Symbolic link
View File

@ -0,0 +1 @@
/run/media/quat/Files/Documents/map-files/verify-scripts/maps/bhop_snfm

1
tools/cross-compile.sh Executable file
View File

@ -0,0 +1 @@
cargo build --release --target x86_64-pc-windows-gnu --all-features

1
tools/iso Executable file
View File

@ -0,0 +1 @@
mangohud ../target/release/strafe-client bhop_maps/5692124338.snfm

4
tools/make-demo.sh Executable file
View File

@ -0,0 +1,4 @@
mkdir -p ../target/demo
mv ../target/x86_64-pc-windows-gnu/release/strafe-client.exe ../target/demo/strafe-client.exe
rm ../target/demo.7z
7z a -t7z -mx=9 -mfb=273 -ms -md=31 -myx=9 -mtm=- -mmt -mmtf -md=1536m -mmf=bt3 -mmc=10000 -mpb=0 -mlc=0 ../target/demo.7z ../target/demo

1
tools/run Executable file
View File

@ -0,0 +1 @@
mangohud ../target/release/strafe-client "$1"

4
tools/settings.conf Normal file
View File

@ -0,0 +1,4 @@
[camera]
sensitivity_x=98384
fov_y=1.0
#fov_x_from_y_ratio=1.33333333333333333333333333333333

1
tools/surf_maps Symbolic link
View File

@ -0,0 +1 @@
/run/media/quat/Files/Documents/map-files/verify-scripts/maps/surf_snfm

1
tools/toc Executable file
View File

@ -0,0 +1 @@
mangohud ../target/release/strafe-client bhop_maps/5692152916.snfm

1
tools/utopia Executable file
View File

@ -0,0 +1 @@
mangohud ../target/release/strafe-client surf_maps/5692145408.snfm