hypoloop/examples/pixelstest.rs

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Rust
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2021-08-12 16:53:36 -06:00
#![deny(clippy::all)]
#![forbid(unsafe_code)]
use hypoloop::core::{State, Loop};
use log::error;
use pixels::{Error, Pixels, SurfaceTexture};
use winit::dpi::LogicalSize;
use winit::event::{Event, VirtualKeyCode};
use winit::event_loop::{ControlFlow, EventLoop};
use winit::window::WindowBuilder;
use winit_input_helper::WinitInputHelper;
const WIDTH: u32 = 320;
const HEIGHT: u32 = 240;
const BOX_SIZE: i16 = 64;
/// Representation of the application state. In this example, a box will bounce around the screen.
struct World {
box_x: i16,
box_y: i16,
velocity_x: i16,
velocity_y: i16,
}
fn main() -> Result<(), Error> {
env_logger::init();
let event_loop = EventLoop::new();
let mut input = WinitInputHelper::new();
let window = {
let size = LogicalSize::new(WIDTH as f64, HEIGHT as f64);
WindowBuilder::new()
.with_title("Hello Pixels")
.with_inner_size(size)
.with_min_inner_size(size)
.build(&event_loop)
.unwrap()
};
let mut pixels = {
let window_size = window.inner_size();
let surface_texture = SurfaceTexture::new(window_size.width, window_size.height, &window);
Pixels::new(WIDTH, HEIGHT, surface_texture)?
};
let mut world = World::new();
// create sim with default configuration
let mut sim = Loop::new();
sim.set_update_interval(10);
let mut update_logic = move |state: &mut State| {
// print information about the current tick's timings
state.debug_time();
world.update(state.get_delta_time(), state.get_timescale());
world.draw(pixels.get_frame());
if pixels
.render()
.map_err(|e| error!("pixels.render() failed: {}", e))
.is_err()
{
state.pause();
return;
}
};
// create a closure containing your display logic
let mut display_logic = move |state: &mut State| {
// Draw the current frame
window.request_redraw();
};
sim.init();
event_loop.run(move |event, _, control_flow| {
// Handle input events
if input.update(&event) {
// Close events
if input.key_pressed(VirtualKeyCode::Escape) || input.quit() {
*control_flow = ControlFlow::Exit;
return;
}
}
// step the sim forward
sim.step(&mut update_logic, &mut display_logic);
});
}
impl World {
/// Create a new `World` instance that can draw a moving box.
fn new() -> Self {
Self {
box_x: 24,
box_y: 16,
velocity_x: 100,
velocity_y: 100,
}
}
/// Update the `World` internal state; bounce the box around the screen.
fn update(&mut self, delta_time: u32, timescale: f32) {
let timestep: f32 = delta_time as f32 / 1000.0 * timescale;
if self.box_x <= 0 || self.box_x + BOX_SIZE > WIDTH as i16 {
self.velocity_x *= -1;
}
if self.box_y <= 0 || self.box_y + BOX_SIZE > HEIGHT as i16 {
self.velocity_y *= -1;
}
self.box_x += (self.velocity_x as f32 * timestep) as i16;
self.box_y += (self.velocity_y as f32 * timestep) as i16;
}
/// Draw the `World` state to the frame buffer.
///
/// Assumes the default texture format: `wgpu::TextureFormat::Rgba8UnormSrgb`
fn draw(&self, frame: &mut [u8]) {
for (i, pixel) in frame.chunks_exact_mut(4).enumerate() {
let x = (i % WIDTH as usize) as i16;
let y = (i / WIDTH as usize) as i16;
let inside_the_box = x >= self.box_x
&& x < self.box_x + BOX_SIZE
&& y >= self.box_y
&& y < self.box_y + BOX_SIZE;
let rgba = if inside_the_box {
[0x5e, 0x48, 0xe8, 0xff]
} else {
[0x48, 0xb2, 0xe8, 0xff]
};
pixel.copy_from_slice(&rgba);
}
}
}