move controller to separate module

This commit is contained in:
Michael Sippel 2024-08-03 22:50:04 +02:00
parent 783631182c
commit 1e3a92000a
Signed by: senvas
GPG key ID: 060F22F65102F95C
15 changed files with 293 additions and 204 deletions

92
src/controller.rs Normal file
View file

@ -0,0 +1,92 @@
use {
std::time::{Instant, Duration},
crate::waveform::Waveform,
};
pub struct Controller {
pub tbegin: Instant,
pub transition_begin: Instant,
pub last_tap: Instant
}
impl Controller {
pub fn new() -> Self {
Controller {
tbegin: Instant::now(),
transition_begin: Instant::now(),
last_tap: Instant::now()
}
}
pub fn handle_key(
&mut self,
event: winit::event::KeyEvent,
inputs: &mut crate::inputs::Inputs,
) {
if event.state == winit::event::ElementState::Pressed {
match event.logical_key {
winit::keyboard::Key::Character(c) => {
eprintln!("pressed {}", c);
if c.is_ascii() {
match &c[0..1] {
"x" => {
// tap tempo
let old_tap = self.last_tap;
self.last_tap = std::time::Instant::now();
if (self.last_tap - old_tap) < Duration::from_millis(20000) {
inputs.cycle_len = self.last_tap - old_tap;
}
}
"q" => {
// sync
inputs.t = Duration::from_millis(0);
self.tbegin = std::time::Instant::now();
},
"0"|"1"|"2"|"3"|"4"|"5"|"6"|"7"|"8"|"9" => {
let idx = c.chars().nth(0).unwrap().to_digit(10).unwrap() as u32;
inputs.scene_select = idx as usize;
self.transition_begin = std::time::Instant::now();
}
"r" => { inputs.master_wave = match inputs.master_wave {
None => Some(Waveform::Sine),
Some(Waveform::Sine) => Some(Waveform::Triangle),
Some(Waveform::Triangle) => Some(Waveform::Square),
Some(Waveform::Square) => Some(Waveform::Sawtooth),
Some(Waveform::Sawtooth) => None
}
}
"," => { inputs.master_wave = None; }
"n" => { inputs.master_intensity += 0.1; }
"m" => { inputs.master_intensity -= 0.1; }
"s" => { inputs.master_subdivision +=1; }
"b" => { inputs.master_subdivision -=1; }
"o" => { inputs.wheel +=1; }
"z" => { inputs.wheel -=1; }
"e" => { inputs.wheel2 += 1; }
"p"=> { inputs.wheel2 -= 1; }
"-" => { inputs.master_intensity *= -1.0; }
"." => {
if inputs.active {
eprintln!("DEACTIVATED");
inputs.active = false;
} else {
inputs.active = true;
eprintln!("ACTIVATED");
}
}
_=>{}
}
eprintln!("--------------");
eprintln!("updated inputs:\n {:?}", inputs);
eprintln!("--------------");
}
}
_ => {}
}
}
}
}

View file

@ -70,7 +70,7 @@ impl Fixture {
self.position + centered_pixpos * self.scale
}
pub fn update_buffer(&mut self, view: &Box<dyn ColorGrid>) {
pub fn update_buffer(&mut self, view: &dyn crate::view::Animation) {
for xi in 0 .. self.resolution.x {
for yi in 0 ..self.resolution.y {
let gpos = self.get_global_pos(&Vector2::new(xi, yi));

View file

@ -19,6 +19,29 @@ pub struct Inputs {
pub master_intensity: f32,
pub wheel: i32,
pub wheel2: i32,
pub active: bool,
}
impl Default for Inputs {
fn default() -> Inputs {
Inputs {
t: Duration::from_millis(0),
transition_time: Duration::from_millis(0),
cycle_len: Duration::from_millis(300),
wave_peak: 0.5,
scene_select: 0,
master_wave: None,
master_subdivision: 0,
master_intensity: 1.0,
wheel: 0,
wheel2: 0,
active: false,
}
}
}

View file

@ -21,6 +21,7 @@ mod view;
mod stripe_driver;
mod jack;
mod waveform;
mod controller;
mod patterns;
mod scene_library;
@ -50,22 +51,7 @@ async fn main() {
socket.write().unwrap().set_read_timeout(Some(std::time::Duration::from_millis(1)));
socket.write().unwrap().set_write_timeout(Some(std::time::Duration::from_millis(1)));
let inputs = Arc::new(RwLock::new(
Inputs {
t: Duration::from_millis(0),
transition_time: Duration::from_millis(0),
cycle_len: Duration::from_millis(300),
wave_peak: 0.5,
scene_select: 0,
master_wave: None,
master_subdivision: 0,
master_intensity: 1.0,
wheel: 0,
wheel2: 0
}
));
let mut inputs = Inputs::default();
let mut lighting_setup = LightingSetup::new(
vec![
@ -89,25 +75,28 @@ async fn main() {
.offset(Vector2::new(0.5, 0.0))
],
Box::new( SceneLibrary::new(inputs.clone()) )
Box::new( SceneLibrary::new() )
);
let mut tbegin = std::time::Instant::now();
let mut transition_begin = std::time::Instant::now();
let mut last_tap = std::time::Instant::now();
let mut z = 0;
let mut controller = controller::Controller::new();
let mut frame_count = 0;
let mut fps_sum_window = std::time::Instant::now();
let mut active = false;
lighting_setup.advance( &inputs );
for i in 0..5 {
lighting_setup.sync_fixture(i);
}
event_loop.run(move |event, elwt| {
let tcur = std::time::Instant::now();
elwt.set_control_flow(
ControlFlow::WaitUntil(
tcur + Duration::from_millis(25)
));
// FPS statistics
if (tcur - fps_sum_window).as_millis() > 5000 {
let avg_fps = (1000.0 * frame_count as f32) / ((tcur - fps_sum_window).as_millis() as f32);
eprintln!("avg fps: {}", avg_fps);
@ -117,15 +106,13 @@ async fn main() {
frame_count += 1;
}
elwt.set_control_flow(ControlFlow::
WaitUntil(
tcur + Duration::from_millis(25)
));
inputs.write().unwrap().t = tcur - tbegin;
inputs.write().unwrap().transition_time = tcur - transition_begin;
lighting_setup.update_buffers();
// update animation
inputs.t = tcur - controller.tbegin;
inputs.transition_time = tcur - controller.transition_begin;
lighting_setup.advance( &inputs );
if active {
// refresh fixture outputs
if inputs.active {
// sync
let mut rbuf = [0 as u8; 8];
@ -171,76 +158,12 @@ async fn main() {
window_id: _,
event: winit::event::WindowEvent::KeyboardInput{ device_id, event, is_synthetic }
} => {
if event.state == winit::event::ElementState::Pressed {
match event.logical_key {
winit::keyboard::Key::Character(c) => {
eprintln!("pressed {}", c);
controller.handle_key(
event, &mut inputs
);
}
let mut inputs = inputs.write().unwrap();
if c.is_ascii() {
match &c[0..1] {
"x" => {
// tap tempo
let old_tap = last_tap;
last_tap = std::time::Instant::now();
if (last_tap - old_tap) < Duration::from_millis(20000) {
inputs.cycle_len = last_tap - old_tap;
}
}
"q" => {
// sync
inputs.t = Duration::from_millis(0);
tbegin = std::time::Instant::now();
},
"0"|"1"|"2"|"3"|"4"|"5"|"6"|"7"|"8"|"9" => {
let idx = c.chars().nth(0).unwrap().to_digit(10).unwrap() as u32;
inputs.scene_select = idx as usize;
transition_begin = std::time::Instant::now();
}
"r" => { inputs.master_wave = match inputs.master_wave {
None => Some(Waveform::Sine),
Some(Waveform::Sine) => Some(Waveform::Triangle),
Some(Waveform::Triangle) => Some(Waveform::Square),
Some(Waveform::Square) => Some(Waveform::Sawtooth),
Some(Waveform::Sawtooth) => None
}
}
"," => { inputs.master_wave = None; }
"n" => { inputs.master_intensity += 0.1; }
"m" => { inputs.master_intensity -= 0.1; }
"s" => { inputs.master_subdivision +=1; }
"b" => { inputs.master_subdivision -=1; }
"o" => { inputs.wheel +=1; }
"z" => { inputs.wheel -=1; }
"e" => { inputs.wheel2 += 1; }
"p"=> { inputs.wheel2 -= 1; }
"-" => { inputs.master_intensity *= -1.0; }
"." => {
if active {
eprintln!("DEACTIVATED");
active = false;
} else {
active = true;
eprintln!("ACTIVATED");
}
}
_=>{}
}
eprintln!("--------------");
eprintln!("updated inputs:\n {:?}", inputs);
eprintln!("--------------");
}
}
_ => {}
}
}
}
_ => {}
_ => {}
}
let (width, height) = *dim.lock().unwrap();

View file

@ -10,22 +10,27 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid}
crate::{Inputs, view::{ColorGrid, Animation}}
};
#[derive(Default)]
pub struct Alternate {
pub inputs: Arc<RwLock< Inputs >>,
pub inputs: Inputs,
}
impl Animation for Alternate {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for Alternate {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let switch = 0;
let t = (inputs.wheel as f32 * inputs.t.as_millis() as f32 / inputs.cycle_len.as_millis() as f32) % 1.0;
let t = (self.inputs.wheel as f32 * self.inputs.t.as_millis() as f32 / self.inputs.cycle_len.as_millis() as f32) % 1.0;
if ((50.0+p.y*128.0) / inputs.wheel as f32) as u32 % 2 == 0 {
if ((50.0+p.y*128.0) / self.inputs.wheel as f32) as u32 % 2 == 0 {
if t < 0.5 {
Rgb::new(0.5, 0.2, 0.2)
} else {
@ -38,9 +43,6 @@ impl ColorGrid for Alternate {
Rgb::new(0.0, 0.0, 0.6)
}
}
}
}

View file

@ -10,15 +10,21 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid}
crate::{Inputs, view::{ColorGrid, Animation}}
};
pub struct ArcticRain { pub inputs: Arc<RwLock< Inputs >> }
#[derive(Default)]
pub struct ArcticRain { pub inputs: Inputs }
impl Animation for ArcticRain {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for ArcticRain {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let i = ( inputs.t.as_millis() as f32 / (4.0*inputs.cycle_len.as_millis() as f32) ) % 1.0;
let i = ( self.inputs.t.as_millis() as f32 / (4.0*self.inputs.cycle_len.as_millis() as f32) ) % 1.0;
let pi2 = 2.0 * 3.1415926;
@ -26,7 +32,7 @@ impl ColorGrid for ArcticRain {
Rgb::from_color(
&Hsv::<f32, Turns<f32>>::new(
// Turns( 0.65 + 0.3*(inputs.wheel%10) as f32*0.1 ),
Turns( (inputs.wheel.abs() % 256) as f32 / 256.0 ),
Turns( (self.inputs.wheel.abs() % 256) as f32 / 256.0 ),
0.9,
1.0 - ((i + (2.0-p.y/4.0)) * 12.0) % 1.0,
// (f32::sin(-p.y+i) * 12.0) % 1.0,

View file

@ -9,17 +9,25 @@ use {
cgmath::{Point2, Vector2},
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid, util::get_angle}
crate::{
Inputs,
view::{ColorGrid, Animation},
util::get_angle
}
};
#[derive(Default)]
pub struct Breathing { pub inputs: Inputs }
impl Animation for Breathing {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
pub struct Breathing { pub inputs: Arc<RwLock< Inputs >> }
impl ColorGrid for Breathing {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let millis = inputs.t.as_millis();
let millis = self.inputs.t.as_millis();
let p1 = p + Vector2::new(0.0,0.5);
let r2 = p1.x*p1.x + p1.y*p1.y;
@ -32,8 +40,8 @@ impl ColorGrid for Breathing {
mirrorphi *
(
0.5+ 0.5*f32::sin(
inputs.t.as_millis() as f32
/ inputs.cycle_len.as_millis() as f32
self.inputs.t.as_millis() as f32
/ self.inputs.cycle_len.as_millis() as f32
)
)
) % 1.0;
@ -42,7 +50,7 @@ impl ColorGrid for Breathing {
&Hsv::<f32, Turns<f32>>::new(
Turns( 0.25+0.25*f32::sin(millis as f32/8000.0) + gamma*0.5 ),
0.5 + r2 * 0.5,
inputs.wave_peak,
self.inputs.wave_peak,
)
)
}

View file

@ -10,15 +10,21 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid, util::get_angle}
crate::{Inputs, view::{ColorGrid, Animation}, util::get_angle}
};
pub struct PastelFade { pub inputs: Arc<RwLock< Inputs >> }
#[derive(Default)]
pub struct PastelFade { pub inputs: Inputs }
impl Animation for PastelFade {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for PastelFade {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let i = ( 5.0 + 0.7 * inputs.t.as_millis() as f32 / (16.0*inputs.cycle_len.as_millis() as f32) ) % 1.0;
let i = ( 5.0 + 0.7 * self.inputs.t.as_millis() as f32 / (16.0*self.inputs.cycle_len.as_millis() as f32) ) % 1.0;
Rgb::from_color(
&Hsv::<f32, Turns<f32>>::new(

View file

@ -10,18 +10,23 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid}
crate::{Inputs, view::{ColorGrid, Animation}}
};
#[derive(Default)]
pub struct Strobe {
pub inputs: Arc<RwLock< Inputs >>,
pub inputs: Inputs,
}
impl Animation for Strobe {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for Strobe {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let t = (inputs.wheel as f32 * inputs.t.as_millis() as f32 / inputs.cycle_len.as_millis() as f32) % 1.0;
let t = (self.inputs.wheel as f32 * self.inputs.t.as_millis() as f32 / self.inputs.cycle_len.as_millis() as f32) % 1.0;
if t < 0.6 {
Rgb::new(0.3, 0.3, 0.3)

View file

@ -10,16 +10,21 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid}
crate::{Inputs, view::{ColorGrid, Animation}}
};
pub struct UbootPrüfstandFade { pub inputs: Arc<RwLock< Inputs >> }
#[derive(Default)]
pub struct UbootPrüfstandFade { pub inputs: Inputs }
impl Animation for UbootPrüfstandFade {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for UbootPrüfstandFade {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
// let millis = self
let i = ( inputs.t.as_millis() as f32 / (4.0*inputs.cycle_len.as_millis() as f32) ) % 1.0;
let i = ( self.inputs.t.as_millis() as f32 / (4.0*self.inputs.cycle_len.as_millis() as f32) ) % 1.0;
let pi2 = 2.0 * 3.1415926;
@ -34,7 +39,7 @@ impl ColorGrid for UbootPrüfstandFade {
let col2 = Rgb::new(0.8, 0.0, 0.0);
let p = ( inputs.t.as_millis() as f32 / (32.0*inputs.cycle_len.as_millis() as f32)) % 1.0;
let p = ( self.inputs.t.as_millis() as f32 / (32.0*self.inputs.cycle_len.as_millis() as f32)) % 1.0;
if p >= 0.7 {
col2
} else {

View file

@ -10,21 +10,25 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid, util::get_angle, waveform::Waveform}
crate::{Inputs, view::{ColorGrid, Animation}, util::get_angle, waveform::Waveform}
};
pub struct WaveFade { pub inputs: Arc<RwLock< Inputs >>,
pub struct WaveFade { pub inputs: Inputs,
pub hue: f32,
}
impl Animation for WaveFade {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
impl ColorGrid for WaveFade {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let nt = ( inputs.t.as_millis() as f32 / inputs.cycle_len.as_millis() as f32 );
let nt = ( self.inputs.t.as_millis() as f32 / self.inputs.cycle_len.as_millis() as f32 );
let i =
match inputs.wheel % 4 {
match self.inputs.wheel % 4 {
0 => Waveform::Sine{}.get_norm(nt),
1 => Waveform::Triangle{}.get_norm(nt),
2 => Waveform::Sawtooth{}.get_norm(nt),

View file

@ -10,16 +10,21 @@ use {
std::time::Duration,
angle::Turns,
crate::{Inputs, view::ColorGrid, util::get_angle}
crate::{Inputs, view::{ColorGrid, Animation}, util::get_angle}
};
#[derive(Default)]
pub struct Wheel { pub inputs: Inputs }
impl Animation for Wheel {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
}
}
pub struct Wheel { pub inputs: Arc<RwLock< Inputs >> }
impl ColorGrid for Wheel {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let millis = inputs.t.as_millis();
let millis = self.inputs.t.as_millis();
let p1 = p + Vector2::new(0.0,0.5);
let r2 = p1.x*p1.x + p1.y*p1.y;
@ -31,8 +36,8 @@ impl ColorGrid for Wheel {
(5.0) *
mirrorphi *
(
inputs.t.as_millis() as f32
/ (inputs.cycle_len.as_millis() as f32 * (1.0 + (inputs.wheel as f32).abs()))
self.inputs.t.as_millis() as f32
/ (self.inputs.cycle_len.as_millis() as f32 * (1.0 + (self.inputs.wheel as f32).abs()))
)
);
@ -40,7 +45,7 @@ impl ColorGrid for Wheel {
&Hsv::<f32, Turns<f32>>::new(
Turns( gamma*0.5 ),
0.5 + r2 * 0.5,
(inputs.wheel as f32 / 16.0),
(self.inputs.wheel as f32 / 16.0),
)
)
}

View file

@ -11,56 +11,67 @@ use {
angle::Turns,
crate::Inputs,
crate::view::ColorGrid,
crate::view::{ColorGrid, Animation},
crate::patterns::*
};
pub struct SceneLibrary {
library: Vec< Box<dyn ColorGrid> >,
current_scene: RwLock<usize>,
inputs: Arc<RwLock< Inputs >>,
library: Vec< Box<dyn Animation> >,
current_scene: usize,
inputs: Inputs,
transition_length: Duration,
// transition_curve: enum { Constant, Linear, Sigmoid, Sinus }
}
impl SceneLibrary {
pub fn new( inputs: Arc<RwLock<Inputs>> ) -> Self {
pub fn new() -> Self {
SceneLibrary {
library: vec![
// 0
Box::new( Breathing{ inputs: inputs.clone() } ),
Box::new( Breathing::default() ),
// 1
Box::new( Strobe{ inputs: inputs.clone() } ),
Box::new( Strobe::default() ),
// 2
Box::new( WaveFade{ inputs: inputs.clone(), hue: 0.5 } ),
// Box::new( WaveFade{ inputs: inputs.clone(), hue: 0.5 } ),
// 3
Box::new( UbootPrüfstandFade{ inputs: inputs.clone() } ),
Box::new( UbootPrüfstandFade::default() ),
//4
Box::new( ArcticRain{ inputs: inputs.clone() } ),
Box::new( ArcticRain::default() ),
//5
Box::new( Wheel{ inputs: inputs.clone() } ),
Box::new( Wheel::default() ),
//6
Box::new( Alternate{ inputs: inputs.clone() } ),
Box::new( Alternate::default() ),
//7
Box::new( PastelFade{ inputs: inputs.clone() } ),
Box::new( PastelFade::default() ),
//8
Box::new( OneShotMan::default() )
],
current_scene: RwLock::new(0),
inputs,
current_scene: 0,
inputs: Inputs::default(),
transition_length: Duration::from_millis(200),
}
}
}
impl Animation for SceneLibrary {
fn advance(&mut self, inputs: &Inputs) {
self.inputs = inputs.clone();
if self.inputs.transition_time.as_millis() as f32 > self.transition_length.as_millis() as f32 {
// change own state:
self.current_scene = self.inputs.scene_select;
}
if let Some(a) = self.library.get_mut(self.current_scene) {
a.advance( inputs );
}
}
}
impl ColorGrid for SceneLibrary {
fn get(&self, p: &Vector2<f32>) -> Rgb<f32> {
let inputs = self.inputs.read().unwrap().clone();
let sc = *self.current_scene.read().unwrap();
let mut intensity: f32 = inputs.master_intensity;
let mut intensity: f32 = self.inputs.master_intensity;
if intensity > 1.0 {
intensity = 1.0;
}
@ -68,20 +79,19 @@ impl ColorGrid for SceneLibrary {
intensity = -1.0;
}
if let Some(w) = inputs.master_wave {
if let Some(w) = self.inputs.master_wave.clone() {
intensity *= w.get_doub(
inputs.t.as_millis() as f32
/ inputs.cycle_len.as_millis() as f32
self.inputs.t.as_millis() as f32
/ self.inputs.cycle_len.as_millis() as f32
);
}
if inputs.scene_select < self.library.len() {
if self.inputs.scene_select < self.library.len() {
if inputs.scene_select == sc {
if self.inputs.scene_select == self.current_scene {
// display only one animation
let mut hsv = Hsv::from_color(
&self.library[ sc ].get(p)
&self.library[ self.current_scene ].get(p)
);
hsv = Hsv::<f32>::new(
@ -93,24 +103,18 @@ impl ColorGrid for SceneLibrary {
Rgb::from_color(&hsv)
} else {
// display transition
let cur_scene = &self.library[ sc ];
let nxt_scene = &self.library[ inputs.scene_select ];
let cur_scene = &self.library[ self.current_scene ];
let nxt_scene = &self.library[ self.inputs.scene_select ];
// crossfade param
let w = ( inputs.transition_time.as_millis() as f32 / self.transition_length.as_millis() as f32 );
if w >= 1.0 {
// change own state:
*self.current_scene.write().unwrap() = inputs.scene_select;
}
let w = ( self.inputs.transition_time.as_millis() as f32 / self.transition_length.as_millis() as f32 );
cur_scene.get(p)
.lerp(
&nxt_scene.get(p),
w
)
}
}
} else {
Rgb::new(0.0, 0.0, 0.0)
}

View file

@ -1,7 +1,8 @@
use {
crate::{
fixture::Fixture,
view::ColorGrid
inputs::Inputs,
view::{ColorGrid, Animation}
},
cgmath::Vector2,
std::time::Duration,
@ -12,22 +13,22 @@ pub struct LightingSetup {
fixtures: Vec<Fixture>,
t: Arc<RwLock<Duration>>,
view: Box<dyn ColorGrid>
animation: Box<dyn Animation>
}
impl LightingSetup {
pub fn new(fixtures: Vec<Fixture>, view: Box<dyn ColorGrid>) -> Self {
pub fn new(fixtures: Vec<Fixture>, animation: Box<dyn Animation>) -> Self {
let t = Arc::new(RwLock::new(Duration::from_millis(0)));
LightingSetup {
fixtures,
t: t.clone(),
view
animation
}
}
pub fn update_buffers(&mut self) {
for fixture in self.fixtures.iter_mut() {
fixture.update_buffer( &self.view );
fixture.update_buffer( self.animation.as_ref() );
}
}
@ -46,6 +47,11 @@ impl LightingSetup {
}
}
pub fn advance(&mut self, inputs: &Inputs) {
self.animation.advance(inputs);
self.update_buffers();
}
pub fn draw_preview(
&self,
buffer: &mut softbuffer::Buffer<'_, Arc<winit::window::Window>, Arc<winit::window::Window>>,
@ -65,7 +71,7 @@ impl LightingSetup {
let xf = (x as f32 - width as f32/2.0) / mindim as f32;
let yf = -(y as f32 - height as f32/2.0) / mindim as f32;
let color = self.view.get(&Vector2::new(xf, yf));
let color = self.animation.get(&Vector2::new(xf, yf));
let red = (color.red() * 16.0) as u32;

View file

@ -8,8 +8,8 @@ use {
pub trait ColorGrid {
fn get(&self, pos: &Vector2<f32>) -> Rgb<f32>;
}
pub trait Animation {
fn advance(&mut self, inputs: Inputs);
pub trait Animation : ColorGrid {
fn advance(&mut self, inputs: &Inputs);
}