Print Only Horizontal Velocity

The Speed function is unnecessary I forgot to remove it
Something idk
2024-02-11 22:26:34 +00:00 · 2024-02-11 22:24:40 +00:00 · 2024-02-07 21:11:50 -08:00 · 2024-02-07 19:50:03 -08:00 · 2024-01-29 22:37:48 -08:00 · 2024-01-29 16:19:57 -08:00
37 changed files with 6250 additions and 5594 deletions
--- a/Cargo.lock
+++ b/Cargo.lock
--- a/Cargo.toml
+++ b/Cargo.toml
@ -1,19 +1,16 @@
 [package]
 name = "strafe-client"
-version = "0.8.0"
+version = "0.9.0"
 edition = "2021"
 # See more keys and their definitions at https://doc.rust-lang.org/cargo/reference/manifest.html
 [dependencies]
 async-executor = "1.5.1"
 bytemuck = { version = "1.13.1", features = ["derive"] }
 configparser = "3.0.2"
 ddsfile = "0.5.1"
-env_logger = "0.10.0"
+glam = "0.25.0"
 glam = "0.24.1"
 lazy-regex = "3.0.2"
 log = "0.4.20"
 obj = "0.10.2"
 parking_lot = "0.12.1"
 pollster = "0.3.0"
@ -21,8 +18,11 @@ 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"
+strafesnet_common = { git = "https://git.itzana.me/StrafesNET/common", rev = "434ca29aef7e3015c9ca1ed45de8fef42e33fdfb" }
-winit = "0.28.6"
+vbsp = "0.5.0"
 vmdl = "0.1.1"
 wgpu = "0.19.0"
 winit = "0.29.2"
 #[profile.release]
 #lto = true
--- a/2
+++ b/2
@ -1,5 +1,5 @@
 /*******************************************************
-* 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.
 *
--- a/src/aabb.rs
+++ b/src/aabb.rs
@ -1,89 +0,0 @@
 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
 	// }
 }
--- a/src/bvh.rs
+++ b/src/bvh.rs
@ -1,107 +0,0 @@
 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<u32>,
 	aabb:Aabb,
 }
 impl BvhNode{
 	pub fn the_tester<F:FnMut(u32)>(&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 as u32}).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,
 		}
 	}
 }
--- a/src/compat_worker.rs
+++ b/src/compat_worker.rs
@ -0,0 +1,21 @@
 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(())
 	}
 }
--- a/src/face_crawler.rs
+++ b/src/face_crawler.rs
@ -0,0 +1,119 @@
 use crate::physics::Body;
 use crate::model_physics::{FEV,MeshQuery,DirectedEdge};
 use strafesnet_common::integer::{Time,Planar64};
 use strafesnet_common::zeroes::zeroes2;
 enum Transition<F,E:DirectedEdge,V>{
 	Miss,
 	Next(FEV<F,E,V>,Time),
 	Hit(F,Time),
 }
 	fn next_transition<F:Copy,E:Copy+DirectedEdge,V:Copy>(fev:&FEV<F,E,V>,time:Time,mesh:&impl MeshQuery<F,E,V>,body:&Body,time_limit:Time)->Transition<F,E,V>{
 		//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_time=time_limit;
 		let mut best_transtition=Transition::Miss;
 		match fev{
 			&FEV::<F,E,V>::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 t in zeroes2((n.dot(body.position)-d)*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
 					let t=body.time+Time::from(t);
 					if time<=t&&t<best_time&&n.dot(body.extrapolated_velocity(t))<Planar64::ZERO{
 						best_time=t;
 						best_transtition=Transition::Hit(face_id,t);
 						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!
 					for t in zeroes2(n.dot(body.position*2-(mesh.vert(verts[0])+mesh.vert(verts[1]))),n.dot(body.velocity)*2,n.dot(body.acceleration)){
 						let t=body.time+Time::from(t);
 						if time<=t&&t<best_time&&n.dot(body.extrapolated_velocity(t))<Planar64::ZERO{
 							best_time=t;
 							best_transtition=Transition::Next(FEV::<F,E,V>::Edge(directed_edge_id.as_undirected()),t);
 							break;
 						}
 					}
 				}
 				//if none:
 			},
 			&FEV::<F,E,V>::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 t in zeroes2(n.dot(delta_pos),n.dot(body.velocity)*2,n.dot(body.acceleration)){
 						let t=body.time+Time::from(t);
 						if time<=t&&t<best_time&&n.dot(body.extrapolated_velocity(t))<Planar64::ZERO{
 							best_time=t;
 							best_transtition=Transition::Next(FEV::<F,E,V>::Face(edge_face_id),t);
 							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 t in zeroes2((n.dot(body.position-mesh.vert(vert_id)))*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
 						let t=body.time+Time::from(t);
 						if time<=t&&t<best_time&&n.dot(body.extrapolated_velocity(t))<Planar64::ZERO{
 							best_time=t;
 							best_transtition=Transition::Next(FEV::<F,E,V>::Vert(vert_id),t);
 							break;
 						}
 					}
 				}
 				//if none:
 			},
 			&FEV::<F,E,V>::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 t in zeroes2((n.dot(body.position-mesh.vert(vert_id)))*2,n.dot(body.velocity)*2,n.dot(body.acceleration)){
 						let t=body.time+Time::from(t);
 						if time<=t&&t<best_time&&n.dot(body.extrapolated_velocity(t))<Planar64::ZERO{
 							best_time=t;
 							best_transtition=Transition::Next(FEV::<F,E,V>::Edge(directed_edge_id.as_undirected()),t);
 							break;
 						}
 					}
 				}
 				//if none:
 			},
 		}
 		best_transtition
 	}
 pub enum CrawlResult<F,E:DirectedEdge,V>{
 	Miss(FEV<F,E,V>),
 	Hit(F,Time),
 }
 pub fn crawl_fev<F:Copy,E:Copy+DirectedEdge,V:Copy>(mut fev:FEV<F,E,V>,mesh:&impl MeshQuery<F,E,V>,relative_body:&Body,start_time:Time,time_limit:Time)->CrawlResult<F,E,V>{	
 	let mut time=start_time;
 	for _ in 0..20{
 		match next_transition(&fev,time,mesh,relative_body,time_limit){
 			Transition::Miss=>return CrawlResult::Miss(fev),
 			Transition::Next(next_fev,next_time)=>(fev,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)
 }
--- a/src/framework.rs
+++ b/src/framework.rs
@ -1,516 +0,0 @@
 use std::future::Future;
 #[cfg(target_arch = "wasm32")]
 use std::str::FromStr;
 #[cfg(target_arch = "wasm32")]
 use web_sys::{ImageBitmapRenderingContext, OffscreenCanvas};
 use winit::{
 	event::{self, WindowEvent, DeviceEvent},
 	event_loop::{ControlFlow, EventLoop},
 };
 #[allow(dead_code)]
 pub fn cast_slice<T>(data: &[T]) -> &[u8] {
 	use std::{mem::size_of, slice::from_raw_parts};
 	unsafe { from_raw_parts(data.as_ptr() as *const u8, data.len() * size_of::<T>()) }
 }
 #[allow(dead_code)]
 pub enum ShaderStage {
 	Vertex,
 	Fragment,
 	Compute,
 }
 pub trait Example: 'static + Sized {
 	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()
 		}
 	}
 	fn required_limits() -> wgpu::Limits {
 		wgpu::Limits::downlevel_webgl2_defaults() // These downlevel limits will allow the code to run on all possible hardware
 	}
 	fn init(
 		config: &wgpu::SurfaceConfiguration,
 		adapter: &wgpu::Adapter,
 		device: &wgpu::Device,
 		queue: &wgpu::Queue,
 	) -> Self;
 	fn resize(
 		&mut self,
 		config: &wgpu::SurfaceConfiguration,
 		device: &wgpu::Device,
 		queue: &wgpu::Queue,
 	);
 	fn update(&mut self, window: &winit::window::Window, device: &wgpu::Device, queue: &wgpu::Queue, event: WindowEvent);
 	fn device_event(&mut self, window: &winit::window::Window, event: DeviceEvent);
 	fn load_file(&mut self, path:std::path::PathBuf, device: &wgpu::Device, queue: &wgpu::Queue);
 	fn render(
 		&mut self,
 		view: &wgpu::TextureView,
 		device: &wgpu::Device,
 		queue: &wgpu::Queue,
 		spawner: &Spawner,
 	);
 }
 struct Setup {
 	window: winit::window::Window,
 	event_loop: EventLoop<()>,
 	instance: wgpu::Instance,
 	size: winit::dpi::PhysicalSize<u32>,
 	surface: wgpu::Surface,
 	adapter: wgpu::Adapter,
 	device: wgpu::Device,
 	queue: wgpu::Queue,
 	#[cfg(target_arch = "wasm32")]
 	offscreen_canvas_setup: Option<OffscreenCanvasSetup>,
 }
 #[cfg(target_arch = "wasm32")]
 struct OffscreenCanvasSetup {
 	offscreen_canvas: OffscreenCanvas,
 	bitmap_renderer: ImageBitmapRenderingContext,
 }
 async fn setup<E: Example>(title: &str) -> Setup {
 	#[cfg(not(target_arch = "wasm32"))]
 	{
 		env_logger::init();
 	};
 	let event_loop = EventLoop::new();
 	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);
 	}
 	let window = builder.build(&event_loop).unwrap();
 	#[cfg(target_arch = "wasm32")]
 	{
 		use winit::platform::web::WindowExtWebSys;
 		let query_string = web_sys::window().unwrap().location().search().unwrap();
 		let level: log::Level = parse_url_query_string(&query_string, "RUST_LOG")
 			.and_then(|x| x.parse().ok())
 			.unwrap_or(log::Level::Error);
 		console_log::init_with_level(level).expect("could not initialize logger");
 		std::panic::set_hook(Box::new(console_error_panic_hook::hook));
 		// On wasm, append the canvas to the document body
 		web_sys::window()
 			.and_then(|win| win.document())
 			.and_then(|doc| doc.body())
 			.and_then(|body| {
 				body.append_child(&web_sys::Element::from(window.canvas()))
 					.ok()
 			})
 			.expect("couldn't append canvas to document body");
 	}
 	#[cfg(target_arch = "wasm32")]
 	let mut offscreen_canvas_setup: Option<OffscreenCanvasSetup> = None;
 	#[cfg(target_arch = "wasm32")]
 	{
 		use wasm_bindgen::JsCast;
 		use winit::platform::web::WindowExtWebSys;
 		let query_string = web_sys::window().unwrap().location().search().unwrap();
 		if let Some(offscreen_canvas_param) =
 			parse_url_query_string(&query_string, "offscreen_canvas")
 		{
 			if FromStr::from_str(offscreen_canvas_param) == Ok(true) {
 				log::info!("Creating OffscreenCanvasSetup");
 				let offscreen_canvas =
 					OffscreenCanvas::new(1024, 768).expect("couldn't create OffscreenCanvas");
 				let bitmap_renderer = window
 					.canvas()
 					.get_context("bitmaprenderer")
 					.expect("couldn't create ImageBitmapRenderingContext (Result)")
 					.expect("couldn't create ImageBitmapRenderingContext (Option)")
 					.dyn_into::<ImageBitmapRenderingContext>()
 					.expect("couldn't convert into ImageBitmapRenderingContext");
 				offscreen_canvas_setup = Some(OffscreenCanvasSetup {
 					offscreen_canvas,
 					bitmap_renderer,
 				})
 			}
 		}
 	};
 	log::info!("Initializing the surface...");
 	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();
 	let instance = wgpu::Instance::new(wgpu::InstanceDescriptor {
 		backends,
 		dx12_shader_compiler,
 	});
 	let (size, surface) = unsafe {
 		let size = window.inner_size();
 		#[cfg(any(not(target_arch = "wasm32"), target_os = "emscripten"))]
 		let surface = instance.create_surface(&window).unwrap();
 		#[cfg(all(target_arch = "wasm32", not(target_os = "emscripten")))]
 		let surface = {
 			if let Some(offscreen_canvas_setup) = &offscreen_canvas_setup {
 				log::info!("Creating surface from OffscreenCanvas");
 				instance.create_surface_from_offscreen_canvas(
 					offscreen_canvas_setup.offscreen_canvas.clone(),
 				)
 			} else {
 				instance.create_surface(&window)
 			}
 		}
 		.unwrap();
 		(size, surface)
 	};
 	let adapter;
 	let optional_features = E::optional_features();
 	let required_features = E::required_features();
 	//no helper function smh gotta write it myself
 	let adapters = instance.enumerate_adapters(backends);
 	let mut chosen_adapter = None;
 	let mut chosen_adapter_score=0;
 	for adapter in adapters {
 		if !adapter.is_surface_supported(&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!");
 	}
 	#[cfg(not(target_arch = "wasm32"))]
 	{
 		let adapter_info = adapter.get_info();
 		println!("Using {} ({:?})", adapter_info.name, adapter_info.backend);
 	}
 	let required_downlevel_capabilities = E::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
 	);
 	// Make sure we use the texture resolution limits from the adapter, so we can support images the size of the surface.
 	let needed_limits = E::required_limits().using_resolution(adapter.limits());
 	let trace_dir = std::env::var("WGPU_TRACE");
 	let (device, queue) = adapter
 		.request_device(
 			&wgpu::DeviceDescriptor {
 				label: None,
 				features: (optional_features & adapter.features()) | required_features,
 				limits: needed_limits,
 			},
 			trace_dir.ok().as_ref().map(std::path::Path::new),
 		)
 		.await
 		.expect("Unable to find a suitable GPU adapter!");
 	Setup {
 		window,
 		event_loop,
 		instance,
 		size,
 		surface,
 		adapter,
 		device,
 		queue,
 		#[cfg(target_arch = "wasm32")]
 		offscreen_canvas_setup,
 	}
 }
 fn start<E: Example>(
 	#[cfg(not(target_arch = "wasm32"))] Setup {
 		window,
 		event_loop,
 		instance,
 		size,
 		surface,
 		adapter,
 		device,
 		queue,
 	}: Setup,
 	#[cfg(target_arch = "wasm32")] Setup {
 		window,
 		event_loop,
 		instance,
 		size,
 		surface,
 		adapter,
 		device,
 		queue,
 		offscreen_canvas_setup,
 	}: Setup,
 ) {
 	let spawner = Spawner::new();
 	let mut config = surface
 		.get_default_config(&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);
 	surface.configure(&device, &config);
 	log::info!("Initializing the example...");
 	let mut example = E::init(&config, &adapter, &device, &queue);
 	log::info!("Entering render loop...");
 	event_loop.run(move |event, _, control_flow| {
 		let _ = (&instance, &adapter); // force ownership by the closure
 		*control_flow = if cfg!(feature = "metal-auto-capture") {
 			ControlFlow::Exit
 		} else {
 			ControlFlow::Poll
 		};
 		match event {
 			event::Event::RedrawEventsCleared => {
 				#[cfg(not(target_arch = "wasm32"))]
 				spawner.run_until_stalled();
 				window.request_redraw();
 			}
 			event::Event::WindowEvent {
 				event:
 					WindowEvent::Resized(size)
 					| 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
 				let max_dimension = adapter.limits().max_texture_dimension_2d;
 				if size.width > max_dimension || size.height > max_dimension {
 					log::warn!(
 						"The resizing size {:?} exceeds the limit of {}.",
 						size,
 						max_dimension
 					);
 				} else {
 					log::info!("Resizing to {:?}", size);
 					config.width = size.width.max(1);
 					config.height = size.height.max(1);
 					example.resize(&config, &device, &queue);
 					surface.configure(&device, &config);
 				}
 			}
 			event::Event::WindowEvent { event, .. } => match event {
 				WindowEvent::KeyboardInput {
 					input:
 						event::KeyboardInput {
 							virtual_keycode: Some(event::VirtualKeyCode::Escape),
 							state: event::ElementState::Pressed,
 							..
 						},
 					..
 				}
 				| WindowEvent::CloseRequested => {
 					*control_flow = ControlFlow::Exit;
 				}
 				#[cfg(not(target_arch = "wasm32"))]
 				WindowEvent::KeyboardInput {
 					input:
 						event::KeyboardInput {
 							virtual_keycode: Some(event::VirtualKeyCode::Scroll),
 							state: event::ElementState::Pressed,
 							..
 						},
 					..
 				} => {
 					println!("{:#?}", instance.generate_report());
 				}
 				_ => {
 					example.update(&window,&device,&queue,event);
 				}
 			},
 			event::Event::DeviceEvent {
 				event,
 				..
 			} => {
 				example.device_event(&window,event);
 			},
 			event::Event::RedrawRequested(_) => {
 				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(surface_view_format),
 					..wgpu::TextureViewDescriptor::default()
 				});
 				example.render(&view, &device, &queue, &spawner);
 				frame.present();
 				#[cfg(target_arch = "wasm32")]
 				{
 					if let Some(offscreen_canvas_setup) = &offscreen_canvas_setup {
 						let image_bitmap = offscreen_canvas_setup
 							.offscreen_canvas
 							.transfer_to_image_bitmap()
 							.expect("couldn't transfer offscreen canvas to image bitmap.");
 						offscreen_canvas_setup
 							.bitmap_renderer
 							.transfer_from_image_bitmap(&image_bitmap);
 						log::info!("Transferring OffscreenCanvas to ImageBitmapRenderer");
 					}
 				}
 			}
 			_ => {}
 		}
 	});
 }
 #[cfg(not(target_arch = "wasm32"))]
 pub struct Spawner<'a> {
 	executor: async_executor::LocalExecutor<'a>,
 }
 #[cfg(not(target_arch = "wasm32"))]
 impl<'a> Spawner<'a> {
 	fn new() -> Self {
 		Self {
 			executor: async_executor::LocalExecutor::new(),
 		}
 	}
 	#[allow(dead_code)]
 	pub fn spawn_local(&self, future: impl Future<Output = ()> + 'a) {
 		self.executor.spawn(future).detach();
 	}
 	fn run_until_stalled(&self) {
 		while self.executor.try_tick() {}
 	}
 }
 #[cfg(target_arch = "wasm32")]
 pub struct Spawner {}
 #[cfg(target_arch = "wasm32")]
 impl Spawner {
 	fn new() -> Self {
 		Self {}
 	}
 	#[allow(dead_code)]
 	pub fn spawn_local(&self, future: impl Future<Output = ()> + 'static) {
 		wasm_bindgen_futures::spawn_local(future);
 	}
 }
 #[cfg(not(target_arch = "wasm32"))]
 pub fn run<E: Example>(title: &str) {
 	let setup = pollster::block_on(setup::<E>(title));
 	start::<E>(setup);
 }
 #[cfg(target_arch = "wasm32")]
 pub fn run<E: Example>(title: &str) {
 	use wasm_bindgen::prelude::*;
 	let title = title.to_owned();
 	wasm_bindgen_futures::spawn_local(async move {
 		let setup = setup::<E>(&title).await;
 		let start_closure = Closure::once_into_js(move || start::<E>(setup));
 		// make sure to handle JS exceptions thrown inside start.
 		// Otherwise wasm_bindgen_futures Queue would break and never handle any tasks again.
 		// This is required, because winit uses JS exception for control flow to escape from `run`.
 		if let Err(error) = call_catch(&start_closure) {
 			let is_control_flow_exception = error.dyn_ref::<js_sys::Error>().map_or(false, |e| {
 				e.message().includes("Using exceptions for control flow", 0)
 			});
 			if !is_control_flow_exception {
 				web_sys::console::error_1(&error);
 			}
 		}
 		#[wasm_bindgen]
 		extern "C" {
 			#[wasm_bindgen(catch, js_namespace = Function, js_name = "prototype.call.call")]
 			fn call_catch(this: &JsValue) -> Result<(), JsValue>;
 		}
 	});
 }
 #[cfg(target_arch = "wasm32")]
 /// Parse the query string as returned by `web_sys::window()?.location().search()?` and get a
 /// specific key out of it.
 pub fn parse_url_query_string<'a>(query: &'a str, search_key: &str) -> Option<&'a str> {
 	let query_string = query.strip_prefix('?')?;
 	for pair in query_string.split('&') {
 		let mut pair = pair.split('=');
 		let key = pair.next()?;
 		let value = pair.next()?;
 		if key == search_key {
 			return Some(value);
 		}
 	}
 	None
 }
 // This allows treating the framework as a standalone example,
 // thus avoiding listing the example names in `Cargo.toml`.
 #[allow(dead_code)]
 fn main() {}
--- a/src/graphics.rs
+++ b/src/graphics.rs
--- a/src/graphics_worker.rs
+++ b/src/graphics_worker.rs
@ -0,0 +1,72 @@
 use strafesnet_common::integer;
 pub enum Instruction{
 	Render(crate::physics::PhysicsOutputState,integer::Time,glam::IVec2),
 	//UpdateModel(crate::graphics::GraphicsModelUpdate),
 	Resize(winit::dpi::PhysicalSize<u32>,crate::settings::UserSettings),
 	GenerateModels(crate::model::IndexedModelInstances),
 	ClearModels,
 }
 //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::GenerateModels(indexed_model_instances)=>{
 				graphics.generate_models(&device,&queue,indexed_model_instances);
 			},
 			Instruction::ClearModels=>{
 				graphics.clear();
 			},
 			Instruction::Resize(size,user_settings)=>{
 				resize=Some((size,user_settings));
 			}
 			Instruction::Render(physics_output,predicted_time,mouse_pos)=>{
 				if let Some((size,user_settings))=&resize{
 					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());
 				}
 				//clear every time w/e
 				resize=None;
 				//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,physics_output,predicted_time,mouse_pos);
 				frame.present();
 			}
 		}
 	})
 }
--- a/src/instruction.rs
+++ b/src/instruction.rs
@ -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,
 		}
 	}
 }
--- a/src/integer.rs
+++ b/src/integer.rs
@ -1,962 +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,Debug,Hash,Eq,Ord,PartialEq,PartialOrd)]
 pub struct Planar64(i64);
 impl Planar64{
 	pub const ZERO:Self=Self(0);
 	pub const ONE:Self=Self(1<<32);
 	pub const FRAC_1_SQRT2:Self=Self(3_037_000_500);
 	#[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,Debug,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 cross(&self,rhs:Self)->Planar64Vec3{
 		Planar64Vec3(((
 			(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());
 }
--- a/src/load_bsp.rs
+++ b/src/load_bsp.rs
@ -0,0 +1,232 @@
 use strafesnet_common::integer;
 const VALVE_SCALE:f32=1.0/16.0;
 fn valve_transform(v:[f32;3])->integer::Planar64Vec3{
 	integer::Planar64Vec3::try_from([v[0]*VALVE_SCALE,v[2]*VALVE_SCALE,-v[1]*VALVE_SCALE]).unwrap()
 }
 pub fn generate_indexed_models<R:std::io::Read+std::io::Seek>(input:&mut R)->Result<crate::model::IndexedModelInstances,vbsp::BspError>{
 	let mut s=Vec::new();
 	match input.read_to_end(&mut s){
 		Ok(_)=>(),
 		Err(e)=>println!("load_bsp::generate_indexed_models read_to_end failed: {:?}",e),
 	}
 	match vbsp::Bsp::read(s.as_slice()){
 		Ok(bsp)=>{
 			let mut spawn_point=integer::Planar64Vec3::ZERO;
 			let mut name_from_texture_id=Vec::new();
 			let mut texture_id_from_name=std::collections::HashMap::new();
 			let mut models=bsp.models().map(|world_model|{
 				//non-deduplicated
 				let mut spam_pos=Vec::new();
 				let mut spam_tex=Vec::new();
 				let mut spam_normal=Vec::new();
 				let mut spam_vertices=Vec::new();
 				let groups=world_model.faces()
 				.filter(|face| face.is_visible())//TODO: look at this
 				.map(|face|{
 					let face_texture=face.texture();
 					let face_texture_data=face_texture.texture_data();
 					let (texture_u,texture_v)=(glam::Vec3A::from_slice(&face_texture.texture_transforms_u[0..3]),glam::Vec3A::from_slice(&face_texture.texture_transforms_v[0..3]));
 					let texture_offset=glam::vec2(face_texture.texture_transforms_u[3],face_texture.texture_transforms_v[3]);
 					let texture_size=glam::vec2(face_texture_data.width as f32,face_texture_data.height as f32);
 					//texture
 					let texture_id=if let Some(&texture_id)=texture_id_from_name.get(face_texture_data.name()){
 						texture_id
 					}else{
 						let texture_id=name_from_texture_id.len() as u32;
 						texture_id_from_name.insert(face_texture_data.name().to_string(),texture_id);
 						name_from_texture_id.push(face_texture_data.name().to_string());
 						texture_id
 					};
 					//normal
 					let normal=face.normal();
 					let normal_idx=spam_normal.len() as u32;
 					spam_normal.push(valve_transform(<[f32;3]>::from(normal)));
 					let mut vertices:Vec<u32>=face.vertex_positions().map(|vertex_pos|{
 						let vertex_xyz=<[f32;3]>::from(vertex_pos);
 						let pos=glam::Vec3A::from_array(vertex_xyz);
 						let pos_idx=spam_pos.len();
 						spam_pos.push(valve_transform(vertex_xyz));
 						//calculate texture coordinates
 						let tex=(glam::vec2(pos.dot(texture_u),pos.dot(texture_v))+texture_offset)/texture_size;
 						let tex_idx=spam_tex.len() as u32;
 						spam_tex.push(tex);
 						let i=spam_vertices.len() as u32;
 						spam_vertices.push(crate::model::IndexedVertex{
 							pos: pos_idx as u32,
 							tex: tex_idx as u32,
 							normal: normal_idx,
 							color: 0,
 						});
 						i
 					}).collect();
 					vertices.reverse();
 					crate::model::IndexedGroup{
 						texture:Some(texture_id),
 						polys:vec![crate::model::IndexedPolygon{vertices}],
 					}
 				}).collect();
 				crate::model::IndexedModel{
 					unique_pos:spam_pos,
 					unique_tex:spam_tex,
 					unique_normal:spam_normal,
 					unique_color:vec![glam::Vec4::ONE],
 					unique_vertices:spam_vertices,
 					groups,
 					instances:vec![crate::model::ModelInstance{
 						attributes:crate::model::CollisionAttributes::Decoration,
 						transform:integer::Planar64Affine3::new(
 							integer::Planar64Mat3::default(),
 							valve_transform(<[f32;3]>::from(world_model.origin))
 						),
 						..Default::default()
 					}],
 				}
 			}).collect();
 			//dedupe prop models
 			let mut model_dedupe=std::collections::HashSet::new();
 			for prop in bsp.static_props(){
 				model_dedupe.insert(prop.model());
 			}
 			//generate unique meshes
 			let mut model_map=std::collections::HashMap::with_capacity(model_dedupe.len());
 			let mut prop_models=Vec::new();
 			for model_name in model_dedupe{
 				let model_name_lower=model_name.to_lowercase();
 				//.mdl, .vvd, .dx90.vtx
 				let mut path=std::path::PathBuf::from(model_name_lower.as_str());
 				let file_name=std::path::PathBuf::from(path.file_stem().unwrap());
 				path.pop();
 				path.push(file_name);
 				let mut vvd_path=path.clone();
 				let mut vtx_path=path.clone();
 				vvd_path.set_extension("vvd");
 				vtx_path.set_extension("dx90.vtx");
 				match (bsp.pack.get(model_name_lower.as_str()),bsp.pack.get(vvd_path.as_os_str().to_str().unwrap()),bsp.pack.get(vtx_path.as_os_str().to_str().unwrap())){
 					(Ok(Some(mdl_file)),Ok(Some(vvd_file)),Ok(Some(vtx_file)))=>{
 						match (vmdl::mdl::Mdl::read(mdl_file.as_ref()),vmdl::vvd::Vvd::read(vvd_file.as_ref()),vmdl::vtx::Vtx::read(vtx_file.as_ref())){
 							(Ok(mdl),Ok(vvd),Ok(vtx))=>{
 								let model=vmdl::Model::from_parts(mdl,vtx,vvd);
 								let texture_paths=model.texture_directories();
 								if texture_paths.len()!=1{
 									println!("WARNING: multiple texture paths");
 								}
 								let skin=model.skin_tables().nth(0).unwrap();
 								let mut spam_pos=Vec::with_capacity(model.vertices().len());
 								let mut spam_normal=Vec::with_capacity(model.vertices().len());
 								let mut spam_tex=Vec::with_capacity(model.vertices().len());
 								let mut spam_vertices=Vec::with_capacity(model.vertices().len());
 								for (i,vertex) in model.vertices().iter().enumerate(){
 									spam_pos.push(valve_transform(<[f32;3]>::from(vertex.position)));
 									spam_normal.push(valve_transform(<[f32;3]>::from(vertex.normal)));
 									spam_tex.push(glam::Vec2::from_array(vertex.texture_coordinates));
 									spam_vertices.push(crate::model::IndexedVertex{
 										pos:i as u32,
 										tex:i as u32,
 										normal:i as u32,
 										color:0,
 									});
 								}
 								let model_id=prop_models.len();
 								model_map.insert(model_name,model_id);
 								prop_models.push(crate::model::IndexedModel{
 									unique_pos:spam_pos,
 									unique_normal:spam_normal,
 									unique_tex:spam_tex,
 									unique_color:vec![glam::Vec4::ONE],
 									unique_vertices:spam_vertices,
 									groups:model.meshes().map(|mesh|{
 										let texture=if let (Some(texture_path),Some(texture_name))=(texture_paths.get(0),skin.texture(mesh.material_index())){
 											let mut path=std::path::PathBuf::from(texture_path.as_str());
 											path.push(texture_name);
 											let texture_location=path.as_os_str().to_str().unwrap();
 											let texture_id=if let Some(&texture_id)=texture_id_from_name.get(texture_location){
 												texture_id
 											}else{
 												println!("texture! {}",texture_location);
 												let texture_id=name_from_texture_id.len() as u32;
 												texture_id_from_name.insert(texture_location.to_string(),texture_id);
 												name_from_texture_id.push(texture_location.to_string());
 												texture_id
 											};
 											Some(texture_id)
 										}else{
 											None
 										};
 										crate::model::IndexedGroup{
 											texture,
 											polys:{
 												//looking at the code, it would seem that the strips are pre-deindexed into triangle lists when calling this function
 												mesh.vertex_strip_indices().map(|strip|{
 													strip.collect::<Vec<usize>>().chunks(3).map(|tri|{
 														crate::model::IndexedPolygon{vertices:vec![tri[0] as u32,tri[1] as u32,tri[2] as u32]}
 													}).collect::<Vec<crate::model::IndexedPolygon>>()
 												}).flatten().collect()
 											},
 										}
 									}).collect(),
 									instances:Vec::new(),
 								});
 							},
 							_=>println!("model_name={} error",model_name),
 						}
 					},
 					_=>println!("no model name={}",model_name),
 				}
 			}
 			//generate model instances
 			for prop in bsp.static_props(){
 				let placement=prop.as_prop_placement();
 				if let Some(&model_index)=model_map.get(placement.model){
 					prop_models[model_index].instances.push(crate::model::ModelInstance{
 						transform:integer::Planar64Affine3::new(
 							integer::Planar64Mat3::try_from(
 								glam::Mat3A::from_diagonal(glam::Vec3::splat(placement.scale))
 								//TODO: figure this out
 								*glam::Mat3A::from_quat(glam::Quat::from_xyzw(
 									placement.rotation.v.x,//b
 									placement.rotation.v.y,//c
 									placement.rotation.v.z,//d
 									placement.rotation.s,//a
 								))
 							).unwrap(),
 							valve_transform(<[f32;3]>::from(placement.origin)),
 						),
 						attributes:crate::model::CollisionAttributes::Decoration,
 						..Default::default()
 					});
 				}else{
 					//println!("model not found {}",placement.model);
 				}
 			}
 			//actually add the prop models
 			prop_models.append(&mut models);
 			Ok(crate::model::IndexedModelInstances{
 				textures:name_from_texture_id,
 				models:prop_models,
 				spawn_point,
 				modes:Vec::new(),
 			})
 		},
 		Err(e)=>{
 			println!("rotten {:?}",e);
 			Err(e)
 		},
 	}
 }
--- a/src/load_roblox.rs
+++ b/src/load_roblox.rs
@ -1,5 +1,5 @@
 use crate::primitives;
-use crate::integer::{Planar64,Planar64Vec3,Planar64Mat3,Planar64Affine3};
+use strafesnet_common::integer::{Planar64,Planar64Vec3,Planar64Mat3,Planar64Affine3};
 fn class_is_a(class: &str, superclass: &str) -> bool {
 	if class==superclass {
@ -14,22 +14,17 @@ fn class_is_a(class: &str, superclass: &str) -> bool {
 	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() {
+	let mut stack=vec![instance];
-		if let Some(c) = dom.get_by_ref(referent) {
+	while let Some(item)=stack.pop(){
-			if class_is_a(c.class.as_str(), superclass) {
+		for &referent in item.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);
+				stack.push(c);
 			}
 		}
 	}
 }
 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(
@ -49,18 +44,23 @@ fn get_attributes(name:&str,can_collide:bool,velocity:Planar64Vec3,force_interse
 	let mut intersecting=crate::model::IntersectingAttributes::default();
 	let mut contacting=crate::model::ContactingAttributes::default();
 	let mut force_can_collide=can_collide;
 	const GRAVITY:Planar64Vec3=Planar64Vec3::int(0,-100,0);
 	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});
+			intersecting.water=Some(crate::model::IntersectingWater{density:Planar64::ONE,viscosity:Planar64::ONE/10,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});
 		},
 		// "UnorderedCheckpoint"=>general.teleport_behaviour=Some(crate::model::TeleportBehaviour::StageElement(crate::model::GameMechanicStageElement{
 		// 	mode_id:0,
 		// 	stage_id:0,
 		// 	force:false,
 		// 	behaviour:crate::model::StageElementBehaviour::Unordered
 		// })),
 		"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})},
@ -120,24 +120,18 @@ fn get_attributes(name:&str,can_collide:bool,velocity:Planar64Vec3,force_interse
 					_=>panic!("regex3[1] messed up bad"),
 				}
 			}
 			// else if let Some(captures)=lazy_regex::regex!(r"^(OrderedCheckpoint)(\d+)$")
 			// .captures(other){
 			// 	match &captures[1]{
 			// 		"OrderedCheckpoint"=>general.checkpoint=Some(crate::model::GameMechanicCheckpoint::Ordered{mode_id:0,checkpoint_id:captures[2].parse::<u32>().unwrap()}),
 			// 		_=>panic!("regex3[1] messed up bad"),
 			// 	}
 			// }
 		}
 	}
 	//need some way to skip this
 	if velocity!=Planar64Vec3::ZERO{
 		//assume all vertical boosters are targetting a height
 		let vg=velocity.dot(GRAVITY);
 		if Planar64::ZERO<=vg{
 			//weird down booster
 		general.booster=Some(crate::model::GameMechanicBooster::Velocity(velocity));
 		}else{
 			println!("set attr");
 			let gg=GRAVITY.dot(GRAVITY);
 			let height=-vg*gg.sqrt().sqrt()*Planar64::FRAC_1_SQRT2/gg;//vi/sqrt(-2*a)=d
 			let v=velocity-GRAVITY*(vg/gg);
 			//if we are adding zero SO BE IT, the check to see if the vectors are parallel is too sensitive
 			general.booster=Some(crate::model::GameMechanicBooster::Velocity(v));
 			general.trajectory=Some(crate::model::GameMechanicSetTrajectory::Height(height));
 		}
 	}
 	match force_can_collide{
 		true=>{
@ -232,9 +226,9 @@ type RobloxWedgeDescription=[Option<RobloxFaceTextureDescription>;5];
 type RobloxCornerWedgeDescription=[Option<RobloxFaceTextureDescription>;5];
 #[derive(Clone,Eq,Hash,PartialEq)]
 enum RobloxBasePartDescription{
-	Sphere,
+	Sphere(RobloxPartDescription),
 	Part(RobloxPartDescription),
-	Cylinder,
+	Cylinder(RobloxPartDescription),
 	Wedge(RobloxWedgeDescription),
 	CornerWedge(RobloxCornerWedgeDescription),
 }
@ -271,22 +265,33 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 			{
 				let model_transform=planar64_affine3_from_roblox(cf,size);
 				if model_transform.matrix3.determinant()==Planar64::ZERO{
 					let mut parent_ref=object.parent();
 					let mut full_path=object.name.clone();
 					while let Some(parent)=dom.get_by_ref(parent_ref){
 						full_path=format!("{}.{}",parent.name,full_path);
 						parent_ref=parent.parent();
 					}
 					println!("Zero determinant CFrame at location {}",full_path);
 					println!("matrix3:{}",model_transform.matrix3);
 					continue;
 				}
 				//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{mode_id:0})
+						Some(crate::model::TempIndexedAttributes::Start(crate::model::TempAttrStart{mode_id:0}))
 					},
 					"UnorderedCheckpoint"=>Some(crate::model::TempIndexedAttributes::UnorderedCheckpoint{mode_id:0}),
 					other=>{
-						let regman=lazy_regex::regex!(r"^(BonusStart|Spawn|ForceSpawn|OrderedCheckpoint)(\d+)$");
+						let regman=lazy_regex::regex!(r"^(BonusStart|Spawn|ForceSpawn|WormholeOut)(\d+)$");
 						if let Some(captures) = regman.captures(other) {
 							match &captures[1]{
-								"BonusStart"=>Some(crate::model::TempIndexedAttributes::Start{mode_id:captures[2].parse::<u32>().unwrap()}),
+								"BonusStart"=>Some(crate::model::TempIndexedAttributes::Start(crate::model::TempAttrStart{mode_id:captures[2].parse::<u32>().unwrap()})),
-								"Spawn"|"ForceSpawn"=>Some(crate::model::TempIndexedAttributes::Spawn{mode_id:0,stage_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{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{
@ -314,6 +319,7 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 							panic!("Part has no Shape!");
 						}
 					},
 					"TrussPart"=>primitives::Primitives::Cube,
 					"WedgePart"=>primitives::Primitives::Wedge,
 					"CornerWedgePart"=>primitives::Primitives::CornerWedge,
 					_=>{
@ -408,9 +414,9 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 					f5,//Cube::Front
 				]=part_texture_description;
 				let basepart_texture_description=match shape{
-					primitives::Primitives::Sphere=>RobloxBasePartDescription::Sphere,
+					primitives::Primitives::Sphere=>RobloxBasePartDescription::Sphere([f0,f1,f2,f3,f4,f5]),
 					primitives::Primitives::Cube=>RobloxBasePartDescription::Part([f0,f1,f2,f3,f4,f5]),
-					primitives::Primitives::Cylinder=>RobloxBasePartDescription::Cylinder,
+					primitives::Primitives::Cylinder=>RobloxBasePartDescription::Cylinder([f0,f1,f2,f3,f4,f5]),
 					//use front face texture first and use top face texture as a fallback
 					primitives::Primitives::Wedge=>RobloxBasePartDescription::Wedge([
 						f0,//Cube::Right->Wedge::Right
@ -436,9 +442,10 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 					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::Sphere(part_texture_description)
-						RobloxBasePartDescription::Part(part_texture_description)=>{
+						|RobloxBasePartDescription::Cylinder(part_texture_description)
-							let mut cube_face_description=primitives::CubeFaceDescription::new();
+						|RobloxBasePartDescription::Part(part_texture_description)=>{
 							let mut cube_face_description=primitives::CubeFaceDescription::default();
 							for (face_id,roblox_face_description) in part_texture_description.iter().enumerate(){
 								cube_face_description.insert(
 								match face_id{
@ -457,9 +464,8 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 							}
 							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();
+							let mut wedge_face_description=primitives::WedgeFaceDescription::default();
 							for (face_id,roblox_face_description) in wedge_texture_description.iter().enumerate(){
 								wedge_face_description.insert(
 								match face_id{
@ -478,7 +484,7 @@ pub fn generate_indexed_models(dom:rbx_dom_weak::WeakDom) -> crate::model::Index
 							primitives::generate_partial_unit_wedge(wedge_face_description)
 						},
 						RobloxBasePartDescription::CornerWedge(cornerwedge_texture_description)=>{
-							let mut cornerwedge_face_description=primitives::CornerWedgeFaceDescription::new();
+							let mut cornerwedge_face_description=primitives::CornerWedgeFaceDescription::default();
 							for (face_id,roblox_face_description) in cornerwedge_texture_description.iter().enumerate(){
 								cornerwedge_face_description.insert(
 								match face_id{
--- a/src/main.rs
+++ b/src/main.rs
--- a/src/model.rs
+++ b/src/model.rs
@ -1,4 +1,4 @@
-use crate::integer::{Time,Planar64,Planar64Vec3,Planar64Affine3};
+use strafesnet_common::integer::{Time,Planar64,Planar64Vec3,Planar64Affine3};
 pub type TextureCoordinate=glam::Vec2;
 pub type Color4=glam::Vec4;
 #[derive(Clone,Hash,PartialEq,Eq)]
@ -50,104 +50,111 @@ pub struct IndexedModelInstances{
 }
 //stage description referencing flattened ids is spooky, but the map loading is meant to be deterministic.
 pub struct ModeDescription{
-	pub start:u32,//start=model_id
+	//TODO: put "default" style modifiers in mode
-	pub spawns:Vec<u32>,//spawns[spawn_id]=model_id
+	//pub style:StyleModifiers,
-	pub ordered_checkpoints:Vec<u32>,//ordered_checkpoints[checkpoint_id]=model_id
+	pub start:usize,//start=model_id
-	pub unordered_checkpoints:Vec<u32>,//unordered_checkpoints[checkpoint_id]=model_id
+	pub spawns:Vec<usize>,//spawns[spawn_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<&u32>{
+	pub fn get_spawn_model_id(&self,stage_id:u32)->Option<&usize>{
-		if let Some(&spawn)=self.spawn_from_stage_id.get(&stage_id){
+		self.spawns.get(*self.spawn_from_stage_id.get(&stage_id)?)
 			self.spawns.get(spawn)
 		}else{
 			None
 		}
 	}
 	pub fn get_ordered_checkpoint_model_id(&self,checkpoint_id:u32)->Option<&u32>{
 		if let Some(&checkpoint)=self.ordered_checkpoint_from_checkpoint_id.get(&checkpoint_id){
 			self.ordered_checkpoints.get(checkpoint)
 		}else{
 			None
 		}
 	}
 }
 //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 TempAttrWormhole{
 	pub wormhole_id:u32,
 }
 pub enum TempIndexedAttributes{
-	Start{
+	Start(TempAttrStart),
-		mode_id:u32,
+	Spawn(TempAttrSpawn),
-	},
+	Wormhole(TempAttrWormhole),
 	Spawn{
 		mode_id:u32,
 		stage_id:u32,
 	},
 	OrderedCheckpoint{
 		mode_id:u32,
 		checkpoint_id:u32,
 	},
 	UnorderedCheckpoint{
 		mode_id:u32,
 	},
 }
 //you have this effect while in contact
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub struct ContactingLadder{
 	pub sticky:bool
 }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub enum ContactingBehaviour{
 	Surf,
 	Cling,//usable as a zipline, or other weird and wonderful things
 	Ladder(ContactingLadder),
 	Elastic(u32),//[1/2^32,1] 0=None (elasticity+1)/2^32
 }
 //you have this effect while intersecting
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub struct IntersectingWater{
 	pub viscosity:Planar64,
 	pub density:Planar64,
-	pub current:Planar64Vec3,
+	pub velocity:Planar64Vec3,
 }
 //All models can be given these attributes
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub struct GameMechanicAccelerator{
 	pub acceleration:Planar64Vec3
 }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 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,Debug)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 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,Debug)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub enum GameMechanicSetTrajectory{
 	//Speed-type SetTrajectory
 	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
 	DotVelocity{direction:Planar64Vec3,dot:Planar64},//set your velocity in a specific direction without touching other directions
 	//Velocity-type SetTrajectory
 	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
+	TargetPointSpeed{//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)]
+impl GameMechanicSetTrajectory{
 	fn is_velocity(&self)->bool{
 		match self{
 			GameMechanicSetTrajectory::AirTime(_)
 			|GameMechanicSetTrajectory::Height(_)
 			|GameMechanicSetTrajectory::DotVelocity{direction:_,dot:_}=>false,
 			GameMechanicSetTrajectory::TargetPointTime{target_point:_,time:_}
 			|GameMechanicSetTrajectory::TargetPointSpeed{target_point:_,speed:_,trajectory_choice:_}
 			|GameMechanicSetTrajectory::Velocity(_)=>true,
 		}
 	}
 }
 #[derive(Clone,Hash,Eq,PartialEq)]
 pub enum ZoneBehaviour{
 	//Start is indexed
 	//Checkpoints are indexed
 	Finish,
 	Anitcheat,
 }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub struct GameMechanicZone{
 	pub mode_id:u32,
 	pub behaviour:ZoneBehaviour,
@ -158,24 +165,36 @@ pub struct GameMechanicZone{
 // 	InRange(Planar64,Planar64),
 // 	OutsideRange(Planar64,Planar64),
 // }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub enum StageElementBehaviour{
 	//Spawn,//The behaviour of stepping on a spawn setting the spawnid
- 	SpawnAt,
+	SpawnAt,//must be standing on top to get effect. except cancollide false
 	Trigger,
 	Teleport,
 	Platform,
 	//Checkpoint acts like a trigger if you haven't hit all the checkpoints yet.
 	//Note that all stage elements act like this for the next stage.
 	Checkpoint,
 	//OrderedCheckpoint. You must pass through all of these in ascending order.
 	//If you hit them out of order it acts like a trigger.
 	//Do not support backtracking at all for now.
 	Ordered{
 		checkpoint_id:u32,
 	},
 	//UnorderedCheckpoint. You must pass through all of these in any order.
 	Unordered,
 	//If you get reset by a jump limit
 	JumpLimit(u32),
 	//Speedtrap(TrapCondition),//Acts as a trigger with a speed condition
 }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 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)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub struct GameMechanicWormhole{
 	//destination does not need to be another wormhole
 	//this defines a one way portal to a destination model transform
@ -183,13 +202,13 @@ pub struct GameMechanicWormhole{
 	pub destination_model_id:u32,
 	//(position,angles)*=origin.transform.inverse()*destination.transform
 }
-#[derive(Clone)]
+#[derive(Clone,Hash,Eq,PartialEq)]
 pub enum TeleportBehaviour{
 	StageElement(GameMechanicStageElement),
 	Wormhole(GameMechanicWormhole),
 }
 //attributes listed in order of handling
-#[derive(Default,Clone)]
+#[derive(Default,Clone,Hash,Eq,PartialEq)]
 pub struct GameMechanicAttributes{
 	pub zone:Option<GameMechanicZone>,
 	pub booster:Option<GameMechanicBooster>,
@ -199,14 +218,28 @@ pub struct GameMechanicAttributes{
 }
 impl GameMechanicAttributes{
 	pub fn any(&self)->bool{
-		self.booster.is_some()
+		self.zone.is_some()
 		||self.booster.is_some()
 		||self.trajectory.is_some()
 		||self.zone.is_some()
 		||self.teleport_behaviour.is_some()
 		||self.accelerator.is_some()
 	}
 	pub fn is_wrcp(&self,current_mode_id:u32)->bool{
 		self.trajectory.as_ref().map_or(false,|t|t.is_velocity())
 		&&match &self.teleport_behaviour{
 			Some(TeleportBehaviour::StageElement(
 				GameMechanicStageElement{
 					mode_id,
 					stage_id:_,
 					force:true,
 					behaviour:StageElementBehaviour::Trigger|StageElementBehaviour::Teleport
 				}
 			))=>current_mode_id==*mode_id,
 			_=>false,
 		}
 	}
 }
-#[derive(Default,Clone)]
+#[derive(Default,Clone,Hash,Eq,PartialEq)]
 pub struct ContactingAttributes{
 	//friction?
 	pub contact_behaviour:Option<ContactingBehaviour>,
@ -216,7 +249,7 @@ impl ContactingAttributes{
 		self.contact_behaviour.is_some()
 	}
 }
-#[derive(Default,Clone)]
+#[derive(Default,Clone,Hash,Eq,PartialEq)]
 pub struct IntersectingAttributes{
 	pub water:Option<IntersectingWater>,
 }
--- a/src/model_graphics.rs
+++ b/src/model_graphics.rs
@ -11,7 +11,7 @@ pub struct GraphicsVertex {
 pub struct IndexedGroupFixedTexture{
 	pub polys:Vec<IndexedPolygon>,
 }
-pub struct IndexedModelGraphicsSingleTexture{
+pub struct IndexedGraphicsModelSingleTexture{
 	pub unique_pos:Vec<[f32; 3]>,
 	pub unique_tex:Vec<[f32; 2]>,
 	pub unique_normal:Vec<[f32; 3]>,
@ -19,37 +19,41 @@ pub struct IndexedModelGraphicsSingleTexture{
 	pub unique_vertices:Vec<IndexedVertex>,
 	pub texture:Option<u32>,//RenderPattern? material/texture/shader/flat color
 	pub groups: Vec<IndexedGroupFixedTexture>,
-	pub instances:Vec<ModelGraphicsInstance>,
+	pub instances:Vec<GraphicsModelInstance>,
 }
-pub struct ModelGraphicsSingleTexture{
+pub enum Entities{
-	pub instances: Vec<ModelGraphicsInstance>,
+	U32(Vec<Vec<u32>>),
-	pub vertices: Vec<GraphicsVertex>,
+	U16(Vec<Vec<u16>>),
-	pub entities: Vec<Vec<u16>>,
+}
-	pub texture: Option<u32>,
+pub struct GraphicsModelSingleTexture{
 	pub instances:Vec<GraphicsModelInstance>,
 	pub vertices:Vec<GraphicsVertex>,
 	pub entities:Entities,
 	pub texture:Option<u32>,
 }
 #[derive(Clone,PartialEq)]
-pub struct ModelGraphicsColor4(glam::Vec4);
+pub struct GraphicsModelColor4(glam::Vec4);
-impl ModelGraphicsColor4{
+impl GraphicsModelColor4{
 	pub const fn get(&self)->glam::Vec4{
 		self.0
 	}
 }
-impl From<glam::Vec4> for ModelGraphicsColor4{
+impl From<glam::Vec4> for GraphicsModelColor4{
 	fn from(value:glam::Vec4)->Self{
 		Self(value)
 	}
 }
-impl std::hash::Hash for ModelGraphicsColor4{
+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 GraphicsModelInstance{
 	pub transform:glam::Mat4,
 	pub normal_transform:glam::Mat3,
-	pub color:ModelGraphicsColor4,
+	pub color:GraphicsModelColor4,
 }
--- a/src/model_physics.rs
+++ b/src/model_physics.rs
@ -1 +1,745 @@
-//
+use std::borrow::{Borrow,Cow};
 use strafesnet_common::zeroes;
 use strafesnet_common::integer::{self,Planar64,Planar64Vec3};
 #[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
 pub struct VertId(usize);
 #[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
 pub struct EdgeId(usize);
 pub trait UndirectedEdge{
 	type DirectedEdge:Copy+DirectedEdge;
 	fn as_directed(&self,parity:bool)->Self::DirectedEdge;
 }
 impl UndirectedEdge for EdgeId{
 	type DirectedEdge=DirectedEdgeId;
 	fn as_directed(&self,parity:bool)->DirectedEdgeId{
 		DirectedEdgeId(self.0|((parity as usize)<<(usize::BITS-1)))
 	}
 }
 pub trait DirectedEdge{
 	type UndirectedEdge:Copy+UndirectedEdge;
 	fn as_undirected(&self)->Self::UndirectedEdge;
 	fn parity(&self)->bool;
 	//this is stupid but may work fine
 	fn reverse(&self)-><<Self as DirectedEdge>::UndirectedEdge as UndirectedEdge>::DirectedEdge{
 		self.as_undirected().as_directed(!self.parity())
 	}
 }
 /// DirectedEdgeId refers to an EdgeId when undirected.
 #[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
 pub struct DirectedEdgeId(usize);
 impl DirectedEdge for DirectedEdgeId{
 	type UndirectedEdge=EdgeId;
 	fn as_undirected(&self)->EdgeId{
 		EdgeId(self.0&!(1<<(usize::BITS-1)))
 	}
 	fn parity(&self)->bool{
 		self.0&(1<<(usize::BITS-1))!=0
 	}
 }
 #[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
 pub struct FaceId(usize);
 //Vertex <-> Edge <-> Face -> Collide
 pub enum FEV<F,E:DirectedEdge,V>{
 	Face(F),
 	Edge(E::UndirectedEdge),
 	Vert(V),
 }
 //use Unit32 #[repr(C)] for map files
 struct Face{
 	normal:Planar64Vec3,
 	dot:Planar64,
 }
 struct Vert(Planar64Vec3);
 pub trait MeshQuery<FACE:Clone,EDGE:Clone+DirectedEdge,VERT:Clone>{
 	fn edge_n(&self,edge_id:EDGE::UndirectedEdge)->Planar64Vec3{
 		let verts=self.edge_verts(edge_id);
 		self.vert(verts[1].clone())-self.vert(verts[0].clone())
 	}
 	fn directed_edge_n(&self,directed_edge_id:EDGE)->Planar64Vec3{
 		let verts=self.edge_verts(directed_edge_id.as_undirected());
 		(self.vert(verts[1].clone())-self.vert(verts[0].clone()))*((directed_edge_id.parity() as i64)*2-1)
 	}
 	fn vert(&self,vert_id:VERT)->Planar64Vec3;
 	fn face_nd(&self,face_id:FACE)->(Planar64Vec3,Planar64);
 	fn face_edges(&self,face_id:FACE)->Cow<Vec<EDGE>>;
 	fn edge_faces(&self,edge_id:EDGE::UndirectedEdge)->Cow<[FACE;2]>;
 	fn edge_verts(&self,edge_id:EDGE::UndirectedEdge)->Cow<[VERT;2]>;
 	fn vert_edges(&self,vert_id:VERT)->Cow<Vec<EDGE>>;
 	fn vert_faces(&self,vert_id:VERT)->Cow<Vec<FACE>>;
 }
 struct FaceRefs{
 	edges:Vec<DirectedEdgeId>,
 	//verts:Vec<VertId>,
 }
 struct EdgeRefs{
 	faces:[FaceId;2],//left, right
 	verts:[VertId;2],//bottom, top
 }
 struct VertRefs{
 	faces:Vec<FaceId>,
 	edges:Vec<DirectedEdgeId>,
 }
 pub struct PhysicsMesh{
 	faces:Vec<Face>,
 	verts:Vec<Vert>,
 	face_topology:Vec<FaceRefs>,
 	edge_topology:Vec<EdgeRefs>,
 	vert_topology:Vec<VertRefs>,
 }
 #[derive(Default,Clone)]
 struct VertRefGuy{
 	edges:std::collections::HashSet<DirectedEdgeId>,
 	faces:std::collections::HashSet<FaceId>,
 }
 #[derive(Clone,Hash,Eq,PartialEq)]
 struct EdgeRefVerts([VertId;2]);
 impl EdgeRefVerts{
 	fn new(v0:VertId,v1:VertId)->(Self,bool){
 		(if v0.0<v1.0{
 			Self([v0,v1])
 		}else{
 			Self([v1,v0])
 		},v0.0<v1.0)
 	}
 }
 struct EdgeRefFaces([FaceId;2]);
 impl EdgeRefFaces{
 	fn new()->Self{
 		Self([FaceId(0);2])
 	}
 	fn push(&mut self,i:usize,face_id:FaceId){
 		self.0[i]=face_id;
 	}
 }
 struct FaceRefEdges(Vec<DirectedEdgeId>);
 #[derive(Default)]
 struct EdgePool{
 	edge_guys:Vec<(EdgeRefVerts,EdgeRefFaces)>,
 	edge_id_from_guy:std::collections::HashMap<EdgeRefVerts,usize>,
 }
 impl EdgePool{
 	fn push(&mut self,edge_ref_verts:EdgeRefVerts)->(&mut EdgeRefFaces,EdgeId){
 		let edge_id=if let Some(&edge_id)=self.edge_id_from_guy.get(&edge_ref_verts){
 			edge_id
 		}else{
 			let edge_id=self.edge_guys.len();
 			self.edge_guys.push((edge_ref_verts.clone(),EdgeRefFaces::new()));
 			self.edge_id_from_guy.insert(edge_ref_verts,edge_id);
 			edge_id
 		};
 		(&mut unsafe{self.edge_guys.get_unchecked_mut(edge_id)}.1,EdgeId(edge_id))
 	}
 }
 impl From<&crate::model::IndexedModel> for PhysicsMesh{
 	fn from(indexed_model:&crate::model::IndexedModel)->Self{
 		assert!(indexed_model.unique_pos.len()!=0,"Mesh cannot have 0 vertices");
 		let verts=indexed_model.unique_pos.iter().map(|v|Vert(v.clone())).collect();
 		let mut vert_ref_guys=vec![VertRefGuy::default();indexed_model.unique_pos.len()];
 		let mut edge_pool=EdgePool::default();
 		let mut face_i=0;
 		let mut faces=Vec::new();
 		let mut face_ref_guys=Vec::new();
 		for group in indexed_model.groups.iter(){for poly in group.polys.iter(){
 			let face_id=FaceId(face_i);
 			//one face per poly
 			let mut normal=Planar64Vec3::ZERO;
 			let len=poly.vertices.len();
 			let face_edges=poly.vertices.iter().enumerate().map(|(i,&vert_id)|{
 				let vert0_id=indexed_model.unique_vertices[vert_id as usize].pos as usize;
 				let vert1_id=indexed_model.unique_vertices[poly.vertices[(i+1)%len] as usize].pos as usize;
 				//https://www.khronos.org/opengl/wiki/Calculating_a_Surface_Normal (Newell's Method)
 				let v0=indexed_model.unique_pos[vert0_id];
 				let v1=indexed_model.unique_pos[vert1_id];
 				normal+=Planar64Vec3::new(
 					(v0.y()-v1.y())*(v0.z()+v1.z()),
 					(v0.z()-v1.z())*(v0.x()+v1.x()),
 					(v0.x()-v1.x())*(v0.y()+v1.y()),
 				);
 				//get/create edge and push face into it
 				let (edge_ref_verts,is_sorted)=EdgeRefVerts::new(VertId(vert0_id),VertId(vert1_id));
 				let (edge_ref_faces,edge_id)=edge_pool.push(edge_ref_verts);
 				//polygon vertices as assumed to be listed clockwise
 				//populate the edge face on the left or right depending on how the edge vertices got sorted
 				edge_ref_faces.push(!is_sorted as usize,face_id);
 				//index edges & face into vertices
 				{
 					let vert_ref_guy=unsafe{vert_ref_guys.get_unchecked_mut(vert0_id)};
 					vert_ref_guy.edges.insert(edge_id.as_directed(is_sorted));
 					vert_ref_guy.faces.insert(face_id);
 					unsafe{vert_ref_guys.get_unchecked_mut(vert1_id)}.edges.insert(edge_id.as_directed(!is_sorted));
 				}
 				//return directed_edge_id
 				edge_id.as_directed(is_sorted)
 			}).collect();
 			//choose precision loss randomly idk
 			normal=normal/len as i64;
 			let mut dot=Planar64::ZERO;
 			for &v in poly.vertices.iter(){
 				dot+=normal.dot(indexed_model.unique_pos[indexed_model.unique_vertices[v as usize].pos as usize]);
 			}
 			faces.push(Face{normal,dot:dot/len as i64});
 			face_ref_guys.push(FaceRefEdges(face_edges));
 			face_i+=1;
 		}}
 		//conceivably faces, edges, and vertices exist now
 		Self{
 			faces,
 			verts,
 			face_topology:face_ref_guys.into_iter().map(|face_ref_guy|{
 				FaceRefs{edges:face_ref_guy.0}
 			}).collect(),
 			edge_topology:edge_pool.edge_guys.into_iter().map(|(edge_ref_verts,edge_ref_faces)|
 				EdgeRefs{faces:edge_ref_faces.0,verts:edge_ref_verts.0}
 			).collect(),
 			vert_topology:vert_ref_guys.into_iter().map(|vert_ref_guy|
 				VertRefs{
 					edges:vert_ref_guy.edges.into_iter().collect(),
 					faces:vert_ref_guy.faces.into_iter().collect(),
 				}
 			).collect(),
 		}
 	}
 }
 impl PhysicsMesh{
 	pub fn verts<'a>(&'a self)->impl Iterator<Item=Planar64Vec3>+'a{
 		self.verts.iter().map(|Vert(pos)|*pos)
 	}
 }
 impl MeshQuery<FaceId,DirectedEdgeId,VertId> for PhysicsMesh{
 	fn face_nd(&self,face_id:FaceId)->(Planar64Vec3,Planar64){
 		(self.faces[face_id.0].normal,self.faces[face_id.0].dot)
 	}
 	//ideally I never calculate the vertex position, but I have to for the graphical meshes...
 	fn vert(&self,vert_id:VertId)->Planar64Vec3{
 		self.verts[vert_id.0].0
 	}
 	fn face_edges(&self,face_id:FaceId)->Cow<Vec<DirectedEdgeId>>{
 		Cow::Borrowed(&self.face_topology[face_id.0].edges)
 	}
 	fn edge_faces(&self,edge_id:EdgeId)->Cow<[FaceId;2]>{
 		Cow::Borrowed(&self.edge_topology[edge_id.0].faces)
 	}
 	fn edge_verts(&self,edge_id:EdgeId)->Cow<[VertId;2]>{
 		Cow::Borrowed(&self.edge_topology[edge_id.0].verts)
 	}
 	fn vert_edges(&self,vert_id:VertId)->Cow<Vec<DirectedEdgeId>>{
 		Cow::Borrowed(&self.vert_topology[vert_id.0].edges)
 	}
 	fn vert_faces(&self,vert_id:VertId)->Cow<Vec<FaceId>>{
 		Cow::Borrowed(&self.vert_topology[vert_id.0].faces)
 	}
 }
 pub struct TransformedMesh<'a>{
 	mesh:&'a PhysicsMesh,
 	transform:&'a integer::Planar64Affine3,
 	normal_transform:&'a integer::Planar64Mat3,
 	transform_det:Planar64,
 }
 impl TransformedMesh<'_>{
 	pub fn new<'a>(
 		mesh:&'a PhysicsMesh,
 		transform:&'a integer::Planar64Affine3,
 		normal_transform:&'a integer::Planar64Mat3,
 		transform_det:Planar64,
 		)->TransformedMesh<'a>{
 		TransformedMesh{
 			mesh,
 			transform,
 			normal_transform,
 			transform_det,
 		}
 	}
 	fn farthest_vert(&self,dir:Planar64Vec3)->VertId{
 		let mut best_dot=Planar64::MIN;
 		let mut best_vert=VertId(0);
 		for (i,vert) in self.mesh.verts.iter().enumerate(){
 			let p=self.transform.transform_point3(vert.0);
 			let d=dir.dot(p);
 			if best_dot<d{
 				best_dot=d;
 				best_vert=VertId(i);
 			}
 		}
 		best_vert
 	}
 }
 impl MeshQuery<FaceId,DirectedEdgeId,VertId> for TransformedMesh<'_>{
 	fn face_nd(&self,face_id:FaceId)->(Planar64Vec3,Planar64){
 		let (n,d)=self.mesh.face_nd(face_id);
 		let transformed_n=*self.normal_transform*n;
 		let transformed_d=d+transformed_n.dot(self.transform.translation)/self.transform_det;
 		(transformed_n/self.transform_det,transformed_d)
 	}
 	fn vert(&self,vert_id:VertId)->Planar64Vec3{
 		self.transform.transform_point3(self.mesh.vert(vert_id))
 	}
 	#[inline]
 	fn face_edges(&self,face_id:FaceId)->Cow<Vec<DirectedEdgeId>>{
 		self.mesh.face_edges(face_id)
 	}
 	#[inline]
 	fn edge_faces(&self,edge_id:EdgeId)->Cow<[FaceId;2]>{
 		self.mesh.edge_faces(edge_id)
 	}
 	#[inline]
 	fn edge_verts(&self,edge_id:EdgeId)->Cow<[VertId;2]>{
 		self.mesh.edge_verts(edge_id)
 	}
 	#[inline]
 	fn vert_edges(&self,vert_id:VertId)->Cow<Vec<DirectedEdgeId>>{
 		self.mesh.vert_edges(vert_id)
 	}
 	#[inline]
 	fn vert_faces(&self,vert_id:VertId)->Cow<Vec<FaceId>>{
 		self.mesh.vert_faces(vert_id)
 	}
 }
 //Note that a face on a minkowski mesh refers to a pair of fevs on the meshes it's summed from
 //(face,vertex)
 //(edge,edge)
 //(vertex,face)
 #[derive(Clone,Copy)]
 pub enum MinkowskiVert{
 	VertVert(VertId,VertId),
 }
 #[derive(Clone,Copy)]
 pub enum MinkowskiEdge{
 	VertEdge(VertId,EdgeId),
 	EdgeVert(EdgeId,VertId),
 	//EdgeEdge when edges are parallel
 }
 impl UndirectedEdge for MinkowskiEdge{
 	type DirectedEdge=MinkowskiDirectedEdge;
 	fn as_directed(&self,parity:bool)->Self::DirectedEdge{
 		match self{
 			MinkowskiEdge::VertEdge(v0,e1)=>MinkowskiDirectedEdge::VertEdge(*v0,e1.as_directed(parity)),
 			MinkowskiEdge::EdgeVert(e0,v1)=>MinkowskiDirectedEdge::EdgeVert(e0.as_directed(parity),*v1),
 		}
 	}
 }
 #[derive(Clone,Copy)]
 pub enum MinkowskiDirectedEdge{
 	VertEdge(VertId,DirectedEdgeId),
 	EdgeVert(DirectedEdgeId,VertId),
 	//EdgeEdge when edges are parallel
 }
 impl DirectedEdge for MinkowskiDirectedEdge{
 	type UndirectedEdge=MinkowskiEdge;
 	fn as_undirected(&self)->Self::UndirectedEdge{
 		match self{
 			MinkowskiDirectedEdge::VertEdge(v0,e1)=>MinkowskiEdge::VertEdge(*v0,e1.as_undirected()),
 			MinkowskiDirectedEdge::EdgeVert(e0,v1)=>MinkowskiEdge::EdgeVert(e0.as_undirected(),*v1),
 		}
 	}
 	fn parity(&self)->bool{
 		match self{
 			MinkowskiDirectedEdge::VertEdge(_,e)
 			|MinkowskiDirectedEdge::EdgeVert(e,_)=>e.parity(),
 		}
 	}
 }
 #[derive(Debug,Clone,Copy,Hash,Eq,PartialEq)]
 pub enum MinkowskiFace{
 	VertFace(VertId,FaceId),
 	EdgeEdge(EdgeId,EdgeId,bool),
 	FaceVert(FaceId,VertId),
 	//EdgeFace
 	//FaceEdge
 	//FaceFace
 }
 pub struct MinkowskiMesh<'a>{
 	mesh0:&'a TransformedMesh<'a>,
 	mesh1:&'a TransformedMesh<'a>,
 }
 //infinity fev algorithm state transition
 enum Transition{
 	Done,//found closest vert, no edges are better
 	Vert(MinkowskiVert),//transition to vert
 }
 enum EV{
 	Vert(MinkowskiVert),
 	Edge(MinkowskiEdge),
 }
 impl MinkowskiMesh<'_>{
 	pub fn minkowski_sum<'a>(mesh0:&'a TransformedMesh,mesh1:&'a TransformedMesh)->MinkowskiMesh<'a>{
 		MinkowskiMesh{
 			mesh0,
 			mesh1,
 		}
 	}
 	fn farthest_vert(&self,dir:Planar64Vec3)->MinkowskiVert{
 		MinkowskiVert::VertVert(self.mesh0.farthest_vert(dir),self.mesh1.farthest_vert(-dir))
 	}
 	fn next_transition_vert(&self,vert_id:MinkowskiVert,best_distance_squared:&mut Planar64,infinity_dir:Planar64Vec3,point:Planar64Vec3)->Transition{
 		let mut best_transition=Transition::Done;
 		for &directed_edge_id in self.vert_edges(vert_id).iter(){
 			let edge_n=self.directed_edge_n(directed_edge_id);
 			//is boundary uncrossable by a crawl from infinity
 			let edge_verts=self.edge_verts(directed_edge_id.as_undirected());
 			//select opposite vertex
 			let test_vert_id=edge_verts[directed_edge_id.parity() as usize];
 			//test if it's closer
 			let diff=point-self.vert(test_vert_id);
 			if zeroes::zeroes1(edge_n.dot(diff),edge_n.dot(infinity_dir)).len()==0{
 				let distance_squared=diff.dot(diff);
 				if distance_squared<*best_distance_squared{
 					best_transition=Transition::Vert(test_vert_id);
 					*best_distance_squared=distance_squared;
 				}
 			}
 		}
 		best_transition
 	}
 	fn final_ev(&self,vert_id:MinkowskiVert,best_distance_squared:&mut Planar64,infinity_dir:Planar64Vec3,point:Planar64Vec3)->EV{
 		let mut best_transition=EV::Vert(vert_id);
 		let diff=point-self.vert(vert_id);
 		for &directed_edge_id in self.vert_edges(vert_id).iter(){
 			let edge_n=self.directed_edge_n(directed_edge_id);
 			//is boundary uncrossable by a crawl from infinity
 			//check if time of collision is outside Time::MIN..Time::MAX
 			let d=edge_n.dot(diff);
 			if zeroes::zeroes1(d,edge_n.dot(infinity_dir)).len()==0{
 				//test the edge
 				let edge_nn=edge_n.dot(edge_n);
 				if Planar64::ZERO<=d&&d<=edge_nn{
 					let distance_squared={
 						let c=diff.cross(edge_n);
 						c.dot(c)/edge_nn
 					};
 					if distance_squared<=*best_distance_squared{
 						best_transition=EV::Edge(directed_edge_id.as_undirected());
 						*best_distance_squared=distance_squared;
 					}
 				}
 			}
 		}
 		best_transition
 	}
 	fn crawl_boundaries(&self,mut vert_id:MinkowskiVert,infinity_dir:Planar64Vec3,point:Planar64Vec3)->EV{
 		let mut best_distance_squared={
 			let diff=point-self.vert(vert_id);
 			diff.dot(diff)
 		};
 		loop{
 			match self.next_transition_vert(vert_id,&mut best_distance_squared,infinity_dir,point){
 				Transition::Done=>return self.final_ev(vert_id,&mut best_distance_squared,infinity_dir,point),
 				Transition::Vert(new_vert_id)=>vert_id=new_vert_id,
 			}
 		}
 	}
 	/// This function drops a vertex down to an edge or a face if the path from infinity did not cross any vertex-edge boundaries but the point is supposed to have already crossed a boundary down from a vertex
 	fn infinity_fev(&self,infinity_dir:Planar64Vec3,point:Planar64Vec3)->FEV::<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>{
 		//start on any vertex
 		//cross uncrossable vertex-edge boundaries until you find the closest vertex or edge
 		//cross edge-face boundary if it's uncrossable
 		match self.crawl_boundaries(self.farthest_vert(infinity_dir),infinity_dir,point){
 			//if a vert is returned, it is the closest point to the infinity point
 			EV::Vert(vert_id)=>FEV::<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>::Vert(vert_id),
 			EV::Edge(edge_id)=>{
 				//cross to face if the boundary is not crossable and we are on the wrong side
 				let edge_n=self.edge_n(edge_id);
 				// point is multiplied by two because vert_sum sums two vertices.
 				let delta_pos=point*2-{
 					let &[v0,v1]=self.edge_verts(edge_id).borrow();
 					self.vert(v0)+self.vert(v1)
 				};
 				for (i,&face_id) in self.edge_faces(edge_id).iter().enumerate(){
 					let face_n=self.face_nd(face_id).0;
 					//edge-face boundary nd, n facing out of the face towards the edge
 					let boundary_n=face_n.cross(edge_n)*(i as i64*2-1);
 					let boundary_d=boundary_n.dot(delta_pos);
 					//check if time of collision is outside Time::MIN..Time::MAX
 					//infinity_dir can always be treated as a velocity
 					if (boundary_d)<=Planar64::ZERO&&zeroes::zeroes1(boundary_d,boundary_n.dot(infinity_dir)*2).len()==0{
 						//both faces cannot pass this condition, return early if one does.
 						return FEV::<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>::Face(face_id);
 					}
 				}
 				FEV::<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>::Edge(edge_id)
 			},
 		}
 	}
 	fn closest_fev_not_inside(&self,mut infinity_body:crate::physics::Body)->Option<FEV::<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert>>{
 		infinity_body.infinity_dir().map_or(None,|dir|{
 			let infinity_fev=self.infinity_fev(-dir,infinity_body.position);
 			//a line is simpler to solve than a parabola
 			infinity_body.velocity=dir;
 			infinity_body.acceleration=Planar64Vec3::ZERO;
 			//crawl in from negative infinity along a tangent line to get the closest fev
 			match crate::face_crawler::crawl_fev(infinity_fev,self,&infinity_body,integer::Time::MIN,infinity_body.time){
 				crate::face_crawler::CrawlResult::Miss(fev)=>Some(fev),
 				crate::face_crawler::CrawlResult::Hit(_,_)=>None,
 			}
 		})
 	}
 	pub fn predict_collision_in(&self,relative_body:&crate::physics::Body,time_limit:integer::Time)->Option<(MinkowskiFace,integer::Time)>{
 		self.closest_fev_not_inside(relative_body.clone()).map_or(None,|fev|{
 			//continue forwards along the body parabola
 			match crate::face_crawler::crawl_fev(fev,self,relative_body,relative_body.time,time_limit){
 				crate::face_crawler::CrawlResult::Miss(_)=>None,
 				crate::face_crawler::CrawlResult::Hit(face,time)=>Some((face,time)),
 			}
 		})
 	}
 	pub fn predict_collision_out(&self,relative_body:&crate::physics::Body,time_limit:integer::Time)->Option<(MinkowskiFace,integer::Time)>{
 		//create an extrapolated body at time_limit
 		let infinity_body=crate::physics::Body::new(
 			relative_body.extrapolated_position(time_limit),
 			-relative_body.extrapolated_velocity(time_limit),
 			relative_body.acceleration,
 			-time_limit,
 		);
 		self.closest_fev_not_inside(infinity_body).map_or(None,|fev|{
 			//continue backwards along the body parabola
 			match crate::face_crawler::crawl_fev(fev,self,&-relative_body.clone(),-time_limit,-relative_body.time){
 				crate::face_crawler::CrawlResult::Miss(_)=>None,
 				crate::face_crawler::CrawlResult::Hit(face,time)=>Some((face,-time)),//no need to test -time<time_limit because of the first step
 			}
 		})
 	}
 	pub fn predict_collision_face_out(&self,relative_body:&crate::physics::Body,time_limit:integer::Time,contact_face_id:MinkowskiFace)->Option<(MinkowskiEdge,integer::Time)>{
 		//no algorithm needed, there is only one state and two cases (Edge,None)
 		//determine when it passes an edge ("sliding off" case)
 		let mut best_time=time_limit;
 		let mut best_edge=None;
 		let face_n=self.face_nd(contact_face_id).0;
 		for &directed_edge_id in self.face_edges(contact_face_id).iter(){
 			let edge_n=self.directed_edge_n(directed_edge_id);
 			//f x e points in
 			let n=face_n.cross(edge_n);
 			let verts=self.edge_verts(directed_edge_id.as_undirected());
 			let d=n.dot(self.vert(verts[0])+self.vert(verts[1]));
 			//WARNING! d outside of *2
 			for t in zeroes::zeroes2((n.dot(relative_body.position))*2-d,n.dot(relative_body.velocity)*2,n.dot(relative_body.acceleration)){
 				let t=relative_body.time+integer::Time::from(t);
 				if relative_body.time<t&&t<best_time&&n.dot(relative_body.extrapolated_velocity(t))<Planar64::ZERO{
 					best_time=t;
 					best_edge=Some(directed_edge_id);
 					break;
 				}
 			}
 		}
 		best_edge.map(|e|(e.as_undirected(),best_time))
 	}
 }
 impl MeshQuery<MinkowskiFace,MinkowskiDirectedEdge,MinkowskiVert> for MinkowskiMesh<'_>{
 	fn face_nd(&self,face_id:MinkowskiFace)->(Planar64Vec3,Planar64){
 		match face_id{
 			MinkowskiFace::VertFace(v0,f1)=>{
 				let (n,d)=self.mesh1.face_nd(f1);
 				(-n,d-n.dot(self.mesh0.vert(v0)))
 			},
 			MinkowskiFace::EdgeEdge(e0,e1,parity)=>{
 				let edge0_n=self.mesh0.edge_n(e0);
 				let edge1_n=self.mesh1.edge_n(e1);
 				let &[e0v0,e0v1]=self.mesh0.edge_verts(e0).borrow();
 				let &[e1v0,e1v1]=self.mesh1.edge_verts(e1).borrow();
 				let n=edge0_n.cross(edge1_n);
 				let e0d=n.dot(self.mesh0.vert(e0v0)+self.mesh0.vert(e0v1));
 				let e1d=n.dot(self.mesh1.vert(e1v0)+self.mesh1.vert(e1v1));
 				(n*(parity as i64*4-2),(e0d-e1d)*(parity as i64*2-1))
 			},
 			MinkowskiFace::FaceVert(f0,v1)=>{
 				let (n,d)=self.mesh0.face_nd(f0);
 				(n,d-n.dot(self.mesh1.vert(v1)))
 			},
 		}
 	}
 	fn vert(&self,vert_id:MinkowskiVert)->Planar64Vec3{
 		match vert_id{
 			MinkowskiVert::VertVert(v0,v1)=>{
 				self.mesh0.vert(v0)-self.mesh1.vert(v1)
 			},
 		}
 	}
 	fn face_edges(&self,face_id:MinkowskiFace)->Cow<Vec<MinkowskiDirectedEdge>>{
 		match face_id{
 			MinkowskiFace::VertFace(v0,f1)=>{
 				Cow::Owned(self.mesh1.face_edges(f1).iter().map(|&edge_id1|{
 					MinkowskiDirectedEdge::VertEdge(v0,edge_id1.reverse())
 				}).collect())
 			},
 			MinkowskiFace::EdgeEdge(e0,e1,parity)=>{
 				let e0v=self.mesh0.edge_verts(e0);
 				let e1v=self.mesh1.edge_verts(e1);
 				//could sort this if ordered edges are needed
 				//probably just need to reverse this list according to parity
 				Cow::Owned(vec![
 					MinkowskiDirectedEdge::VertEdge(e0v[0],e1.as_directed(parity)),
 					MinkowskiDirectedEdge::EdgeVert(e0.as_directed(!parity),e1v[0]),
 					MinkowskiDirectedEdge::VertEdge(e0v[1],e1.as_directed(!parity)),
 					MinkowskiDirectedEdge::EdgeVert(e0.as_directed(parity),e1v[1]),
 				])
 			},
 			MinkowskiFace::FaceVert(f0,v1)=>{
 				Cow::Owned(self.mesh0.face_edges(f0).iter().map(|&edge_id0|{
 					MinkowskiDirectedEdge::EdgeVert(edge_id0,v1)
 				}).collect())
 			},
 		}
 	}
 	fn edge_faces(&self,edge_id:MinkowskiEdge)->Cow<[MinkowskiFace;2]>{
 		match edge_id{
 			MinkowskiEdge::VertEdge(v0,e1)=>{
 				//faces are listed backwards from the minkowski mesh
 				let v0e=self.mesh0.vert_edges(v0);
 				let &[e1f0,e1f1]=self.mesh1.edge_faces(e1).borrow();
 				Cow::Owned([(e1f1,false),(e1f0,true)].map(|(edge_face_id1,face_parity)|{
 					let mut best_edge=None;
 					let mut best_d=Planar64::ZERO;
 					let edge_face1_n=self.mesh1.face_nd(edge_face_id1).0;
 					let edge_face1_nn=edge_face1_n.dot(edge_face1_n);
 					for &directed_edge_id0 in v0e.iter(){
 						let edge0_n=self.mesh0.directed_edge_n(directed_edge_id0);
 						//must be behind other face.
 						let d=edge_face1_n.dot(edge0_n);
 						if d<Planar64::ZERO{
 							let edge0_nn=edge0_n.dot(edge0_n);
 							//divide by zero???
 							let dd=d*d/(edge_face1_nn*edge0_nn);
 							if best_d<dd{
 								best_d=dd;
 								best_edge=Some(directed_edge_id0);
 							}
 						}
 					}
 					best_edge.map_or(
 						MinkowskiFace::VertFace(v0,edge_face_id1),
 						|directed_edge_id0|MinkowskiFace::EdgeEdge(directed_edge_id0.as_undirected(),e1,directed_edge_id0.parity()^face_parity)
 					)
 				}))
 			},
 			MinkowskiEdge::EdgeVert(e0,v1)=>{
 				//tracking index with an external variable because .enumerate() is not available
 				let v1e=self.mesh1.vert_edges(v1);
 				let &[e0f0,e0f1]=self.mesh0.edge_faces(e0).borrow();
 				Cow::Owned([(e0f0,true),(e0f1,false)].map(|(edge_face_id0,face_parity)|{
 					let mut best_edge=None;
 					let mut best_d=Planar64::ZERO;
 					let edge_face0_n=self.mesh0.face_nd(edge_face_id0).0;
 					let edge_face0_nn=edge_face0_n.dot(edge_face0_n);
 					for &directed_edge_id1 in v1e.iter(){
 						let edge1_n=self.mesh1.directed_edge_n(directed_edge_id1);
 						let d=edge_face0_n.dot(edge1_n);
 						if d<Planar64::ZERO{
 							let edge1_nn=edge1_n.dot(edge1_n);
 							let dd=d*d/(edge_face0_nn*edge1_nn);
 							if best_d<dd{
 								best_d=dd;
 								best_edge=Some(directed_edge_id1);
 							}
 						}
 					}
 					best_edge.map_or(
 						MinkowskiFace::FaceVert(edge_face_id0,v1),
 						|directed_edge_id1|MinkowskiFace::EdgeEdge(e0,directed_edge_id1.as_undirected(),directed_edge_id1.parity()^face_parity)
 					)
 				}))
 			},
 		}
 	}
 	fn edge_verts(&self,edge_id:MinkowskiEdge)->Cow<[MinkowskiVert;2]>{
 		match edge_id{
 			MinkowskiEdge::VertEdge(v0,e1)=>{
 				Cow::Owned(self.mesh1.edge_verts(e1).map(|vert_id1|{
 					MinkowskiVert::VertVert(v0,vert_id1)
 				}))
 			},
 			MinkowskiEdge::EdgeVert(e0,v1)=>{
 				Cow::Owned(self.mesh0.edge_verts(e0).map(|vert_id0|{
 					MinkowskiVert::VertVert(vert_id0,v1)
 				}))
 			},
 		}
 	}
 	fn vert_edges(&self,vert_id:MinkowskiVert)->Cow<Vec<MinkowskiDirectedEdge>>{
 		match vert_id{
 			MinkowskiVert::VertVert(v0,v1)=>{
 				let mut edges=Vec::new();
 				//detect shared volume when the other mesh is mirrored along a test edge dir
 				let v0f=self.mesh0.vert_faces(v0);
 				let v1f=self.mesh1.vert_faces(v1);
 				let v0f_n:Vec<Planar64Vec3>=v0f.iter().map(|&face_id|self.mesh0.face_nd(face_id).0).collect();
 				let v1f_n:Vec<Planar64Vec3>=v1f.iter().map(|&face_id|self.mesh1.face_nd(face_id).0).collect();
 				let the_len=v0f.len()+v1f.len();
 				for &directed_edge_id in self.mesh0.vert_edges(v0).iter(){
 					let n=self.mesh0.directed_edge_n(directed_edge_id);
 					let nn=n.dot(n);
 					//make a set of faces
 					let mut face_normals=Vec::with_capacity(the_len);
 					//add mesh0 faces as-is
 					face_normals.clone_from(&v0f_n);
 					for face_n in &v1f_n{
 						//add reflected mesh1 faces
 						face_normals.push(*face_n-n*(face_n.dot(n)*2/nn));
 					}
 					if is_empty_volume(face_normals){
 						edges.push(MinkowskiDirectedEdge::EdgeVert(directed_edge_id,v1));
 					}
 				}
 				for &directed_edge_id in self.mesh1.vert_edges(v1).iter(){
 					let n=self.mesh1.directed_edge_n(directed_edge_id);
 					let nn=n.dot(n);
 					let mut face_normals=Vec::with_capacity(the_len);
 					face_normals.clone_from(&v1f_n);
 					for face_n in &v0f_n{
 						face_normals.push(*face_n-n*(face_n.dot(n)*2/nn));
 					}
 					if is_empty_volume(face_normals){
 						edges.push(MinkowskiDirectedEdge::VertEdge(v0,directed_edge_id));
 					}
 				}
 				Cow::Owned(edges)
 			},
 		}
 	}
 	fn vert_faces(&self,_vert_id:MinkowskiVert)->Cow<Vec<MinkowskiFace>>{
 		unimplemented!()
 	}
 }
 fn is_empty_volume(normals:Vec<Planar64Vec3>)->bool{
 	let len=normals.len();
 	for i in 0..len-1{
 		for j in i+1..len{
 			let n=normals[i].cross(normals[j]);
 			let mut d_comp=None;
 			for k in 0..len{
 				if k!=i&&k!=j{
 					let d=n.dot(normals[k]);
 					if let Some(comp)=&d_comp{
 						if *comp*d<Planar64::ZERO{
 							return true;
 						}
 					}else{
 						d_comp=Some(d);
 					}
 				}
 			}
 		}
 	}
 	return false;
 }
 #[test]
 fn test_is_empty_volume(){
 	assert!(!is_empty_volume([Planar64Vec3::X,Planar64Vec3::Y,Planar64Vec3::Z].to_vec()));
 	assert!(is_empty_volume([Planar64Vec3::X,Planar64Vec3::Y,Planar64Vec3::Z,Planar64Vec3::NEG_X].to_vec()));
 }
 #[test]
 fn build_me_a_cube(){
 	let unit_cube=crate::primitives::unit_cube();
 	let mesh=PhysicsMesh::from(&unit_cube);
 	//println!("mesh={:?}",mesh);
 }
--- a/src/physics.rs
+++ b/src/physics.rs
--- a/src/physics_worker.rs
+++ b/src/physics_worker.rs
@ -0,0 +1,165 @@
 use crate::physics::{MouseState,PhysicsInputInstruction};
 use strafesnet_common::integer::Time;
 use strafesnet_common::instruction::{TimedInstruction,InstructionConsumer};
 use strafesnet_common::integer::{self,Planar64,Planar64Vec3,Planar64Mat3,Angle32,Ratio64,Ratio64Vec2};
 #[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,
 }
 pub enum Instruction{
 	Input(InputInstruction),
 	Render,
 	Resize(winit::dpi::PhysicalSize<u32>,crate::settings::UserSettings),
 	GenerateModels(crate::model::IndexedModelInstances),
 	ClearModels,
 	//Graphics(crate::graphics_worker::Instruction),
 }
 pub struct Speed{
 	pub player_vel:Planar64Vec3,
 	pub time:Time
 }
 impl std::ops::Neg for Speed{
 	type Output=Self;
 	fn neg(self)->Self::Output{
 		Self{
 			player_vel:self.player_vel,
 			time:self.time
 		}
 	}
 }
 impl  Speed{
 	pub fn new(player_vel:Planar64Vec3,time:Time)->Self{
 		Self{
 			player_vel,
 			time,
 		}
 	}
 }
 	pub fn new(mut physics:crate::physics::PhysicsState,mut graphics_worker:crate::compat_worker::INWorker<crate::graphics_worker::Instruction>)->crate::compat_worker::QNWorker<TimedInstruction<Instruction>>{
 		let mut mouse_blocking=true;
 		let mut last_mouse_time=physics.next_mouse.time;
 		let mut timeline=std::collections::VecDeque::new();
 		let mut next_velocity_print=std::time::Instant::now();
 		let mut player_vel = physics.body.velocity.length();
 		crate::compat_worker::QNWorker::new(move |ins:TimedInstruction<Instruction>|{
 			if if let Some(phys_input)=match &ins.instruction{
 				Instruction::Input(input_instruction)=>match input_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: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),
 				},
 				Instruction::GenerateModels(_)=>Some(PhysicsInputInstruction::Idle),
 				Instruction::ClearModels=>Some(PhysicsInputInstruction::Idle),
 				Instruction::Resize(_,_)=>Some(PhysicsInputInstruction::Idle),
 				Instruction::Render=>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-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: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(){
 					physics.run(instruction.time);
 					physics.process_instruction(TimedInstruction{
 						time:instruction.time,
 						instruction:crate::physics::PhysicsInstruction::Input(instruction.instruction),
 					});
 				}
 				//some random print stuff
 				if 3.0/5.0<next_velocity_print.elapsed().as_secs_f64(){
 					next_velocity_print=next_velocity_print+std::time::Duration::from_secs_f64(1.0/30.0);
 					println!("velocity: {} u/s", (Planar64Vec3::new(physics.body.velocity.x(), Planar64::int(0), physics.body.velocity.z())).length()*(Planar64::int(130)/9));
 				}
 			}
 			match ins.instruction{
 				Instruction::Render=>{
 					graphics_worker.send(crate::graphics_worker::Instruction::Render(physics.output(),ins.time,physics.next_mouse.pos)).unwrap();
 				},
 				Instruction::Resize(size,user_settings)=>{
 					graphics_worker.send(crate::graphics_worker::Instruction::Resize(size,user_settings)).unwrap();
 				},
 				Instruction::GenerateModels(indexed_model_instances)=>{
 					physics.generate_models(&indexed_model_instances);
 					physics.spawn(indexed_model_instances.spawn_point);
 					graphics_worker.send(crate::graphics_worker::Instruction::GenerateModels(indexed_model_instances)).unwrap();
 				},
 				Instruction::ClearModels=>{
 					physics.clear();
 					graphics_worker.send(crate::graphics_worker::Instruction::ClearModels).unwrap();
 				},
 				_=>(),
 			}
 		})
 	}
--- a/src/primitives.rs
+++ b/src/primitives.rs
@ -1,5 +1,5 @@
 use crate::model::{Color4,TextureCoordinate,IndexedModel,IndexedPolygon,IndexedGroup,IndexedVertex};
-use crate::integer::Planar64Vec3;
+use strafesnet_common::integer::Planar64Vec3;
 #[derive(Debug)]
 pub enum Primitives{
@ -126,17 +126,21 @@ const CORNERWEDGE_DEFAULT_NORMALS:[Planar64Vec3;5]=[
 	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);
+	unit_cube()
-	for pos in indexed_model.unique_pos.iter_mut(){
+}
-		*pos=*pos/2;
+#[derive(Default)]
-	}
+pub struct CubeFaceDescription([Option<FaceDescription>;6]);
-	indexed_model
+impl CubeFaceDescription{
 	pub fn insert(&mut self,index:CubeFace,value:FaceDescription){
 		self.0[index as usize]=Some(value);
 	}
 	pub fn pairs(self)->std::iter::FilterMap<std::iter::Enumerate<std::array::IntoIter<Option<FaceDescription>,6>>,impl FnMut((usize,Option<FaceDescription>))->Option<(usize,FaceDescription)>>{
 		self.0.into_iter().enumerate().filter_map(|v|v.1.map(|u|(v.0,u)))
 	}
 }
 pub type CubeFaceDescription=std::collections::HashMap::<CubeFace,FaceDescription>;
 pub fn unit_cube()->crate::model::IndexedModel{
-	let mut t=CubeFaceDescription::new();
+	let mut t=CubeFaceDescription::default();
 	t.insert(CubeFace::Right,FaceDescription::default());
 	t.insert(CubeFace::Top,FaceDescription::default());
 	t.insert(CubeFace::Back,FaceDescription::default());
@ -145,17 +149,21 @@ pub fn unit_cube()->crate::model::IndexedModel{
 	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);
+	unit_cube()
-	for pos in indexed_model.unique_pos.iter_mut(){
+}
-		*pos=TEAPOT_TRANSFORM*(*pos)/10;
+#[derive(Default)]
-	}
+pub struct WedgeFaceDescription([Option<FaceDescription>;5]);
-	indexed_model
+impl WedgeFaceDescription{
 	pub fn insert(&mut self,index:WedgeFace,value:FaceDescription){
 		self.0[index as usize]=Some(value);
 	}
 	pub fn pairs(self)->std::iter::FilterMap<std::iter::Enumerate<std::array::IntoIter<Option<FaceDescription>,5>>,impl FnMut((usize,Option<FaceDescription>))->Option<(usize,FaceDescription)>>{
 		self.0.into_iter().enumerate().filter_map(|v|v.1.map(|u|(v.0,u)))
 	}
 }
 pub type WedgeFaceDescription=std::collections::HashMap::<WedgeFace,FaceDescription>;
 pub fn unit_wedge()->crate::model::IndexedModel{
-	let mut t=WedgeFaceDescription::new();
+	let mut t=WedgeFaceDescription::default();
 	t.insert(WedgeFace::Right,FaceDescription::default());
 	t.insert(WedgeFace::TopFront,FaceDescription::default());
 	t.insert(WedgeFace::Back,FaceDescription::default());
@ -163,9 +171,18 @@ pub fn unit_wedge()->crate::model::IndexedModel{
 	t.insert(WedgeFace::Bottom,FaceDescription::default());
 	generate_partial_unit_wedge(t)
 }
-pub type CornerWedgeFaceDescription=std::collections::HashMap::<CornerWedgeFace,FaceDescription>;
+#[derive(Default)]
 pub struct CornerWedgeFaceDescription([Option<FaceDescription>;5]);
 impl CornerWedgeFaceDescription{
 	pub fn insert(&mut self,index:CornerWedgeFace,value:FaceDescription){
 		self.0[index as usize]=Some(value);
 	}
 	pub fn pairs(self)->std::iter::FilterMap<std::iter::Enumerate<std::array::IntoIter<Option<FaceDescription>,5>>,impl FnMut((usize,Option<FaceDescription>))->Option<(usize,FaceDescription)>>{
 		self.0.into_iter().enumerate().filter_map(|v|v.1.map(|u|(v.0,u)))
 	}
 }
 pub fn unit_cornerwedge()->crate::model::IndexedModel{
-	let mut t=CornerWedgeFaceDescription::new();
+	let mut t=CornerWedgeFaceDescription::default();
 	t.insert(CornerWedgeFace::Right,FaceDescription::default());
 	t.insert(CornerWedgeFace::TopBack,FaceDescription::default());
 	t.insert(CornerWedgeFace::TopLeft,FaceDescription::default());
@ -189,18 +206,6 @@ impl std::default::Default for FaceDescription{
 		}
 	}
 }
 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{
@ -212,7 +217,7 @@ pub fn generate_partial_unit_cube(face_descriptions:CubeFaceDescription)->crate:
 	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(){
+	for (face_id,face_description) in face_descriptions.pairs(){
 		//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
@ -233,14 +238,6 @@ pub fn generate_partial_unit_cube(face_descriptions:CubeFaceDescription)->crate:
 			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]);
@ -327,7 +324,7 @@ pub fn generate_partial_unit_wedge(face_descriptions:WedgeFaceDescription)->crat
 	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(){
+	for (face_id,face_description) in face_descriptions.pairs(){
 		//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
@ -348,13 +345,6 @@ pub fn generate_partial_unit_wedge(face_descriptions:WedgeFaceDescription)->crat
 			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]);
@ -439,7 +429,7 @@ pub fn generate_partial_unit_cornerwedge(face_descriptions:CornerWedgeFaceDescri
 	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(){
+	for (face_id,face_description) in face_descriptions.pairs(){
 		//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
@ -460,13 +450,6 @@ pub fn generate_partial_unit_cornerwedge(face_descriptions:CornerWedgeFaceDescri
 			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]);
--- a/src/settings.rs
+++ b/src/settings.rs
@ -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,
--- a/src/setup.rs
+++ b/src/setup.rs
@ -0,0 +1,281 @@
 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 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)
 }
 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,
 				},
 				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
 	let window=crate::window::WindowContextSetup::new(&setup_context,&window);
 	//the thread that spawns the physics thread
 	let window_thread=window.into_worker(setup_context);
 	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();
 				},
 				_=>{}
 			}
 		})
 }
--- a/src/sweep.rs
+++ b/src/sweep.rs
@ -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
 	}
 }
--- a/src/window.rs
+++ b/src/window.rs
@ -0,0 +1,244 @@
 use crate::physics_worker::InputInstruction;
 use strafesnet_common::integer;
 use strafesnet_common::instruction::TimedInstruction;
 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:crate::physics::MouseState,//std::sync::Arc<std::sync::Mutex<>>
 	screen_size:glam::UVec2,
 	user_settings:crate::settings::UserSettings,
 	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)=>{
 				//blocking because it's simpler...
 				if let Some(indexed_model_instances)=crate::load_file(path){
 					self.physics_thread.send(TimedInstruction{time,instruction:crate::physics_worker::Instruction::ClearModels}).unwrap();
 					self.physics_thread.send(TimedInstruction{time,instruction:crate::physics_worker::Instruction::GenerateModels(indexed_model_instances)}).unwrap();
 				}
 			},
 			winit::event::WindowEvent::Focused(_state)=>{
 				//pause unpause
 				//recalculate pressed keys on focus
 			},
 			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,
 				};
 				match logical_key{
 					winit::keyboard::Key::Named(winit::keyboard::NamedKey::Tab)=>{
 						if s{
 							self.manual_mouse_lock=false;
 							match self.window.set_cursor_position(self.get_middle_of_screen()){
 								Ok(())=>(),
 								Err(e)=>println!("Could not set cursor position: {:?}",e),
 							}
 							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 self.window.set_cursor_grab(winit::window::CursorGrabMode::Locked){
 								Ok(())=>(),
 								Err(_)=>{
 									match self.window.set_cursor_grab(winit::window::CursorGrabMode::Confined){
 										Ok(())=>(),
 										Err(e)=>{
 											self.manual_mouse_lock=true;
 											println!("Could not confine cursor: {:?}",e)
 										},
 									}
 								}
 							}
 						}
 						self.window.set_cursor_visible(s);
 					},
 					winit::keyboard::Key::Named(winit::keyboard::NamedKey::F11)=>{
 						if s{
 							if self.window.fullscreen().is_some(){
 								self.window.set_fullscreen(None);
 							}else{
 								self.window.set_fullscreen(Some(winit::window::Fullscreen::Borderless(None)));
 							}
 						}
 					},
 					winit::keyboard::Key::Named(winit::keyboard::NamedKey::Escape)=>{
 						if s{
 							self.manual_mouse_lock=false;
 							match self.window.set_cursor_grab(winit::window::CursorGrabMode::None){
 								Ok(())=>(),
 								Err(e)=>println!("Could not release cursor: {:?}",e),
 							}
 							self.window.set_cursor_visible(true);
 						}
 					},
 					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{Some(InputInstruction::Reset)}else{None},
 								_=>None,
 							},
 							_=>None,
 						}{
 							self.physics_thread.send(TimedInstruction{
 								time,
 								instruction:crate::physics_worker::Instruction::Input(input_instruction),
 							}).unwrap();
 						}
 					},
 				}
 			},
 			_=>(),
 		}
 	}
 	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 self.window.set_cursor_position(self.get_middle_of_screen()){
 						Ok(())=>(),
 						Err(e)=>println!("Could not set cursor position: {:?}",e),
 					}
 				}
 				//do not step the physics because the mouse polling rate is higher than the physics can run.
 				//essentially the previous input will be overwritten until a true step runs
 				//which is fine because they run all the time.
 				let delta=glam::ivec2(delta.0 as i32,delta.1 as i32);
 				self.mouse.pos+=delta;
 				self.physics_thread.send(TimedInstruction{
 					time,
 					instruction:crate::physics_worker::Instruction::Input(InputInstruction::MoveMouse(self.mouse.pos)),
 				}).unwrap();
 			},
 			winit::event::DeviceEvent::MouseWheel {
 			    delta,
 			} => {
 				println!("mousewheel {:?}",delta);
 				if false{//self.physics.style.use_scroll{
 					self.physics_thread.send(TimedInstruction{
 						time,
 						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 struct WindowContextSetup<'a>{
 	user_settings:crate::settings::UserSettings,
 	window:&'a winit::window::Window,
 	physics:crate::physics::PhysicsState,
 	graphics:crate::graphics::GraphicsState,
 }
 impl<'a> WindowContextSetup<'a>{
 	pub fn new(context:&crate::setup::SetupContext,window:&'a winit::window::Window)->Self{
 		//wee
 		let user_settings=crate::settings::read_user_settings();
 		let args:Vec<String>=std::env::args().collect();
 		let indexed_model_instances=if args.len()==2{
 			crate::load_file(std::path::PathBuf::from(&args[1]))
 		}else{
 			None
 		}.unwrap_or(crate::default_models());
 		let mut physics=crate::physics::PhysicsState::default();
 		physics.load_user_settings(&user_settings);
 		physics.generate_models(&indexed_model_instances);
 		physics.spawn(indexed_model_instances.spawn_point);
 		let mut graphics=crate::graphics::GraphicsState::new(&context.device,&context.queue,&context.config);
 		graphics.load_user_settings(&user_settings);
 		graphics.generate_models(&context.device,&context.queue,indexed_model_instances);
 		Self{
 			user_settings,
 			window,
 			graphics,
 			physics,
 		}
 	}
 	fn into_context(self,setup_context:crate::setup::SetupContext<'a>)->WindowContext<'a>{
 		let screen_size=glam::uvec2(setup_context.config.width,setup_context.config.height);
 		let graphics_thread=crate::graphics_worker::new(self.graphics,setup_context.config,setup_context.surface,setup_context.device,setup_context.queue);
 		WindowContext{
 			manual_mouse_lock:false,
 			mouse:crate::physics::MouseState::default(),
 			//make sure to update this!!!!!
 			screen_size,
 			user_settings:self.user_settings,
 			window:self.window,
 			physics_thread:crate::physics_worker::new(self.physics,graphics_thread),
 		}
 	}
 	pub fn into_worker(self,setup_context:crate::setup::SetupContext<'a>)->crate::compat_worker::QNWorker<'a,TimedInstruction<WindowInstruction>>{
 		let mut window_context=self.into_context(setup_context);
 		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,window_context.user_settings.clone())
 						}
 					).unwrap();
 				}
 				WindowInstruction::Render=>{
 					window_context.physics_thread.send(
 						TimedInstruction{
 							time:ins.time,
 							instruction:crate::physics_worker::Instruction::Render
 						}
 					).unwrap();
 				}
 			}
 		})
 	}
 }
--- a/src/worker.rs
+++ b/src/worker.rs
@ -2,16 +2,68 @@ use std::thread;
 use std::sync::{mpsc,Arc};
 use parking_lot::Mutex;
 //WorkerPool
 struct Pool(u32);
 enum PoolOrdering{
 	Single,//single thread cannot get out of order
 	Ordered(u32),//order matters and should be buffered/dropped according to ControlFlow
 	Unordered(u32),//order does not matter
 }
 //WorkerInput
 enum Input{
 	//no input, workers have everything needed at creation
 	None,
 	//Immediate input to any available worker, dropped if they are overflowing (all workers are busy)
 	Immediate,
 	//Queued input is ordered, but serial jobs that mutate state (such as running physics) can only be done with a single worker
 	Queued,//"Fifo"
 	//Query a function to get next input when a thread becomes available
 	//worker stops querying when Query function returns None and dies after all threads complete
 	//lifetimes sound crazy on this one
 	Query,
 	//Queue of length one, the input is replaced if it is submitted twice before the current work finishes
 	Mailbox,
 }
 //WorkerOutput
 enum Output{
 	None(Pool),
 	Realtime(PoolOrdering),//outputs are dropped if they are out of order and order is demanded
 	Buffered(PoolOrdering),//outputs are held back internally if they are out of order and order is demanded
 }
 //It would be possible to implement all variants
 //with a query input function and callback output function but I'm not sure if that's worth it.
 //Immediate = Condvar
 //Queued = receiver.recv()
 //a callback function would need to use an async runtime!
 //realtime output is an arc mutex of the output value that is assigned every time a worker completes a job
 //buffered output produces a receiver object that can be passed to the creation of another worker
 //when ordering is requested, output is ordered by the order each thread is run
 //which is the same as the order that the input data is processed except for Input::None which has no input data
 //WorkerDescription
 struct Description{
 	input:Input,
 	output:Output,
 }
 //The goal here is to have a worker thread that parks itself when it runs out of work.
 //The worker thread publishes the result of its work back to the worker object for every item in the work queue.
 //Previous values do not matter as soon as a new value is produced, which is why it's called "Realtime"
 //The physics (target use case) knows when it has not changed the body, so not updating the value is also an option.
-pub struct Worker<Task:Send,Value:Clone> {
+/*
 QR = WorkerDescription{
 	input:Queued,
 	output:Realtime(Single),
 }
 */
 pub struct QRWorker<Task:Send,Value:Clone>{
 	sender: mpsc::Sender<Task>,
 	value:Arc<Mutex<Value>>,
 }
-impl<Task:Send+'static,Value:Clone+Send+'static> Worker<Task,Value> {
+impl<Task:Send+'static,Value:Clone+Send+'static> QRWorker<Task,Value>{
 	pub fn new<F:FnMut(Task)->Value+Send+'static>(value:Value,mut f:F) -> Self {
 		let (sender, receiver) = mpsc::channel::<Task>();
 		let ret=Self {
@ -45,43 +97,94 @@ impl<Task:Send+'static,Value:Clone+Send+'static> Worker<Task,Value> {
 	}
 }
-pub struct CompatWorker<Task,Value:Clone,F>{
+/*
-	data:std::marker::PhantomData<Task>,
+QN = WorkerDescription{
-	f:F,
+	input:Queued,
-	value:Value,
+	output:None(Single),
 }
 */
 //None Output Worker does all its work internally from the perspective of the work submitter
 pub struct QNWorker<'a,Task:Send>{
 	sender: mpsc::Sender<Task>,
 	handle:thread::ScopedJoinHandle<'a,()>,
 }
-impl<Task,Value:Clone,F:FnMut(Task)->Value> CompatWorker<Task,Value,F> {
+impl<'a,Task:Send+'a> QNWorker<'a,Task>{
-	pub fn new(value:Value,f:F) -> Self {
+	pub fn new<F:FnMut(Task)+Send+'a>(scope:&'a thread::Scope<'a,'_>,mut f:F)->QNWorker<'a,Task>{
-		Self {
+		let (sender,receiver)=mpsc::channel::<Task>();
-			f,
+		let handle=scope.spawn(move ||{
-			value,
+			loop {
-			data:std::marker::PhantomData,
+				match receiver.recv() {
 					Ok(task)=>f(task),
 					Err(_)=>{
 						println!("Worker stopping.",);
 						break;
 					}
 				}
 			}
 		});
 		Self{
 			sender,
 			handle,
 		}
 	}
 	pub fn send(&self,task:Task)->Result<(),mpsc::SendError<Task>>{
 		self.sender.send(task)
 	}
 }
-	pub fn send(&mut self,task:Task)->Result<(),()>{
+/*
-		self.value=(self.f)(task);
+IN = WorkerDescription{
-		Ok(())
+	input:Immediate,
-	}
+	output:None(Single),
 }
 */
 //Inputs are dropped if the worker is busy
 pub struct INWorker<'a,Task:Send>{
 	sender: mpsc::SyncSender<Task>,
 	handle:thread::ScopedJoinHandle<'a,()>,
 }
-	pub fn grab_clone(&self)->Value{
+impl<'a,Task:Send+'a> INWorker<'a,Task>{
-		self.value.clone()
+	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 {
 				match receiver.recv() {
 					Ok(task)=>f(task),
 					Err(_)=>{
 						println!("Worker stopping.",);
 						break;
 					}
 				}
 			}
 		});
 		Self{
 			sender,
 			handle,
 		}
 	}
 	//blocking!
 	pub fn blocking_send(&self,task:Task)->Result<(), mpsc::SendError<Task>>{
 		self.sender.send(task)
 	}
 	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");
 	// Create the worker thread
-	let worker = Worker::new(crate::physics::Body::with_pva(crate::integer::Planar64Vec3::ZERO,crate::integer::Planar64Vec3::ZERO,crate::integer::Planar64Vec3::ZERO),
+	let test_body=crate::physics::Body::new(crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Time::ZERO);
-		|_|crate::physics::Body::with_pva(crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE)
+	let worker=QRWorker::new(crate::physics::Body::default(),
 		|_|crate::physics::Body::new(crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Planar64Vec3::ONE,crate::integer::Time::ZERO)
 	);
 	// Send tasks to the worker
 	for _ in 0..5 {
-		let task = crate::instruction::TimedInstruction{
+		let task = strafesnet_common::instruction::TimedInstruction{
-			time:crate::integer::Time::ZERO,
+			time:strafesnet_common::integer::Time::ZERO,
 			instruction:crate::physics::PhysicsInstruction::StrafeTick,
 		};
 		worker.send(task).unwrap();
@ -91,17 +194,17 @@ 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{
+	let task = strafesnet_common::instruction::TimedInstruction{
-		time:crate::integer::Time::ZERO,
+		time:strafesnet_common::integer::Time::ZERO,
 		instruction:crate::physics::PhysicsInstruction::StrafeTick,
 	};
 	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));
 }
--- a/src/zeroes.rs
+++ b/src/zeroes.rs
@ -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 mut 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];
 	}
 }
--- a/tools/arcane
+++ b/tools/arcane
@ -0,0 +1 @@
 mangohud ../target/release/strafe-client bhop_maps/5692113331.rbxm
--- a/tools/bhop_maps
+++ b/tools/bhop_maps
@ -0,0 +1 @@
 /run/media/quat/Files/Documents/map-files/verify-scripts/maps/bhop_all/
--- a/tools/cross-compile.sh
+++ b/tools/cross-compile.sh
@ -0,0 +1 @@
 cargo build --release --target x86_64-pc-windows-gnu
--- a/tools/make-demo.sh
+++ b/tools/make-demo.sh
@ -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
--- a/tools/run
+++ b/tools/run
@ -0,0 +1 @@
 mangohud ../target/release/strafe-client "$1"
--- a/tools/settings.conf
+++ b/tools/settings.conf
@ -0,0 +1,4 @@
 [camera]
 sensitivity_x=98384
 fov_y=1.0
 #fov_x_from_y_ratio=1.33333333333333333333333333333333
--- a/tools/surf_maps
+++ b/tools/surf_maps
@ -0,0 +1 @@
 /run/media/quat/Files/Documents/map-files/verify-scripts/maps/surf_all/
--- a/tools/textures
+++ b/tools/textures
@ -0,0 +1 @@
 /run/media/quat/Files/Documents/map-files/verify-scripts/textures/dds/
--- a/tools/toc
+++ b/tools/toc
@ -0,0 +1 @@
 mangohud ../target/release/strafe-client bhop_maps/5692152916.rbxm
--- a/tools/utopia
+++ b/tools/utopia
@ -0,0 +1 @@
 mangohud ../target/release/strafe-client surf_maps/5692145408.rbxm
Author	SHA1	Message	Date
Royiex	f07d9f968e	Print Only Horizontal Velocity The Speed function is unnecessary I forgot to remove it	2024-02-11 22:26:34 +00:00
Royiex	2cef79da1d	Something idk	2024-02-11 22:24:40 +00:00
Quaternions	3bad427f61	shrink code	2024-02-07 21:11:50 -08:00
Quaternions	90cca51e6e	patch arcane	2024-02-07 19:50:03 -08:00
Quaternions	480cd0e3be	commonize	2024-01-29 22:37:48 -08:00
Quaternions	515ca20fb5	this is now a multi year project	2024-01-29 16:19:57 -08:00
Quaternions	6dff6a2c33	update dependencies	2024-01-29 16:19:57 -08:00
Quaternions	ae9fc15320	update wgpu and slap lifetimes on everything until it works	2024-01-19 20:11:58 -08:00
Quaternions	6ae058d834	make room for missing texture print	2024-01-18 13:05:54 -08:00
Quaternions	517c4914ac	load_bsp module	2024-01-18 13:05:26 -08:00
Quaternions	6ce057ac64	add vbsp dep	2024-01-18 13:00:08 -08:00
Quaternions	c86824bdc1	skip objects with zero determinant	2023-12-30 10:36:03 -08:00
Quaternions	a7f7edef00	update deps	2023-12-24 13:10:12 -08:00
Quaternions	5b8e5c8899	we're not using floats anymore	2023-12-12 15:47:31 -08:00
Quaternions	14000c016e	multiply and check instead of doing bithacks	2023-12-12 15:30:09 -08:00
Quaternions	1c4191cfc9	convert recursion to stack	2023-12-12 14:47:20 -08:00
Quaternions	b2f067e0b4	stop erroring on subnormals, it's not really an issue	2023-12-04 08:55:21 -08:00
Quaternions	aec82358ee	comment about conceptual failure case	2023-12-02 03:06:13 -08:00
Quaternions	5da5006027	attempt to fix the bug	2023-12-02 03:06:13 -08:00
Quaternions	97a1b57b65	TODO: relative d value	2023-12-02 02:02:51 -08:00
Quaternions	a359650ff8	use relative position to avoid overflow	2023-12-02 01:58:18 -08:00
Quaternions	1790390055	don't mess with casts, wtf	2023-12-02 01:31:47 -08:00
Quaternions	49e077996d	overflow detect	2023-12-02 01:31:47 -08:00
Quaternions	9bfcf0b083	use det to make numbers smaller	2023-12-01 20:59:04 -08:00
Quaternions	82b3201b0a	optimize face_nd: precalculate det	2023-12-01 20:50:38 -08:00
Quaternions	513414d4bd	fix a near overflow bug	2023-12-01 18:28:05 -08:00
Quaternions	5c4bd4c3c7	wrong air accel limit	2023-12-01 05:01:13 -08:00
Quaternions	92ec137f33	v0.9.0 Face Crawler + Integer Physics + Threading Rewrite + Config File	2023-12-01 05:01:13 -08:00
Quaternions	5cedf91709	Face Crawler™	2023-12-01 04:41:28 -08:00
Quaternions	c201a1a626	improve zeroes precision	2023-12-01 04:41:11 -08:00
Quaternions	fbae4d9f80	delete sweep	2023-12-01 04:41:11 -08:00
Quaternions	9374e93801	face crawler prerequisites	2023-12-01 04:41:11 -08:00
Quaternions	0585cfe6f1	fix test	2023-11-30 01:45:55 -08:00
Quaternions	3d96517213	update deps	2023-11-30 01:45:54 -08:00
Quaternions	eeb1561c3d	utopia preset	2023-11-10 19:12:19 -08:00
Quaternions	19e602544a	anisotropic filtering	2023-11-10 19:08:33 -08:00
Quaternions	444c3cbad9	remove cybertruck model from default map	2023-11-09 19:21:04 -08:00
Quaternions	2006f81804	surf maps link	2023-11-08 19:41:26 -08:00
Quaternions	de7b7ba7be	defer resize to next frame render	2023-11-08 18:20:19 -08:00
Quaternions	008c66e052	TrussPart	2023-11-07 20:54:49 -08:00
Quaternions	ba250277bd	textures for spheres and cylinders	2023-11-07 20:45:05 -08:00
Quaternions	085d4e7912	use cubes instead of teapots and monkeys	2023-11-07 16:54:44 -08:00
Quaternions	dd6b5bed24	implement primitive FaceDescriptions with fixed size arrays instead of hashmaps	2023-11-07 13:26:24 -08:00
Quaternions	9d4cadda30	demo zipping script	2023-11-06 00:32:31 -08:00
Quaternions	242b4ab470	style modifiers in mode	2023-11-01 16:06:48 -07:00
Quaternions	eaef3d3fd5	dedicated arcane loader	2023-10-31 16:14:21 -07:00
Quaternions	9d726c5419	StrafeSettings	2023-10-31 14:32:54 -07:00
Quaternions	9592f82c4e	move camera_offset to StyleModifiers & PhysicsOutputState	2023-10-30 22:29:01 -07:00
Quaternions	873c6ab935	panic when u32::MAX verts	2023-10-30 22:12:17 -07:00
Quaternions	7ba94c1b30	enable compat_worker interop with real workers	2023-10-30 19:42:02 -07:00
Quaternions	8fc6a7fb8f	comment on intersection test location	2023-10-30 19:16:48 -07:00
Quaternions	a3340143db	use enum for bvh node content + wrap every model in aabb	2023-10-30 18:59:51 -07:00
Quaternions	9fc7884270	rename Model{Graphics\|Physics} for consistency	2023-10-30 18:27:52 -07:00
Quaternions	953b17bc69	change model index_format based on number of vertices	2023-10-30 17:58:21 -07:00
Quaternions	8fcb4e5c6c	as works here	2023-10-30 16:40:56 -07:00
Quaternions	073a076fe8	already u32	2023-10-30 16:23:58 -07:00
Quaternions	9848d66001	tabs	2023-10-30 16:13:57 -07:00
Quaternions	6474ddcbd1	update winit	2023-10-28 23:08:09 -07:00
Quaternions	c4cd73e914	toc script	2023-10-28 17:30:37 -07:00
Quaternions	bbb1857377	attributes: checkpoints, jump count	2023-10-28 17:04:30 -07:00
Quaternions	883be0bc01	disable vsync for funsies	2023-10-28 17:04:30 -07:00
Quaternions	5885036f8f	put build/run tools in git because I just lost them	2023-10-28 17:04:30 -07:00
Quaternions	076dab23cf	delete some dead code	2023-10-27 00:24:11 -07:00
Quaternions	c1001d6f37	update wgpu to 0.18.0	2023-10-26 23:58:27 -07:00
Quaternions	08d4e7d997	back face culling	2023-10-26 19:07:44 -07:00
Quaternions	e1f4f6e535	update everything except wgpu because it crashes	2023-10-25 16:30:02 -07:00
Quaternions	3a4c4ef9fe	silence many compiler warnings	2023-10-25 16:07:12 -07:00
Quaternions	41dd155c50	styling	2023-10-25 15:58:10 -07:00
Quaternions	5fd6ca219b	roblox_rocket style	2023-10-25 15:45:25 -07:00
Quaternions	1c22f4a3c3	implement rocket_force	2023-10-25 15:45:25 -07:00
Quaternions	1e6c489750	optional strafing + optional rocket force	2023-10-25 15:45:25 -07:00
Quaternions	9f62f5f2fd	graphics thread + refactor everything + drop deps + update winit	2023-10-25 15:41:35 -07:00
Quaternions	7be7d2c0df	literally into_worker	2023-10-18 18:21:11 -07:00
Quaternions	cb6b0acd44	TODO: need real functions	2023-10-18 18:21:11 -07:00
Quaternions	cbcf047c3f	basic wormholes (no velocity or camera transformation)	2023-10-18 18:21:11 -07:00
Quaternions	6e5de4aa46	overhaul TempIndexedAttributes + add Wormhole indexing	2023-10-18 18:21:11 -07:00
Quaternions	cc776e7cb4	model_id is usize + PhysicsModels struct	2023-10-18 18:21:11 -07:00
Quaternions	5a66ac46b9	functionate that damn code block	2023-10-18 18:21:11 -07:00
Quaternions	38f6e1df3f	overhaul attributes	2023-10-18 18:21:11 -07:00
Quaternions	849dcf98f7	overhaul StyleModifiers	2023-10-18 18:21:11 -07:00
Quaternions	d04d1be27e	overhaul WalkState + implement ladders	2023-10-18 18:21:11 -07:00
Quaternions	35bfd1d366	implement simulate_move_rotation	2023-10-18 18:21:11 -07:00
Quaternions	586bf8ce89	unpub a bunch of physics stuff	2023-10-18 18:21:11 -07:00
Quaternions	127b205401	implement MoveState + TouchingState	2023-10-18 18:21:11 -07:00
Quaternions	4f596ca5d7	unneeded mut	2023-10-18 16:30:02 -07:00
		`@ -0,0 +1 @@`
							`mangohud ../target/release/strafe-client bhop_maps/5692113331.rbxm`
		`@ -0,0 +1 @@`
							`/run/media/quat/Files/Documents/map-files/verify-scripts/maps/bhop_all/`
		`@ -0,0 +1 @@`
							`cargo build --release --target x86_64-pc-windows-gnu`