Force actix-web to differentiate between canvases

[litoprism.git] / src / main.rs

use std::convert::From;
use std::io::Cursor;
use std::fmt::Display;
use std::fmt;
use std::borrow::BorrowMut;
use std::sync::{Arc, Mutex};
use num_traits::Zero;
use num_traits::cast::AsPrimitive;
use percent_encoding::percent_decode_str;
use actix_web::{get, web, App, HttpServer, HttpRequest, HttpResponse, Responder, ResponseError, Result};
use actix_web::body::BoxBody;
use actix_web::http::StatusCode;
use image::{ImageBuffer, ColorType, Rgb, RgbImage, write_buffer_with_format};
use image::ImageOutputFormat::Png;
use image::imageops::{FilterType, resize};
use image::error::{LimitError, LimitErrorKind};


#[derive(Debug)]
struct ImageError(image::ImageError);

impl ImageError {
    fn dimension_error() -> ImageError {
        ImageError(image::ImageError::Limits(LimitError::from_kind(LimitErrorKind::DimensionError)))
    }
}

impl Display for ImageError {
    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
        write!(f, "{}", &self.0)
    }
}

impl ResponseError for ImageError {
    fn status_code(&self) -> StatusCode {
        StatusCode::INTERNAL_SERVER_ERROR
    }

    fn error_response(&self) -> HttpResponse<BoxBody> {
        HttpResponse::InternalServerError().body(format!("{}\n", &self))
    }
}

#[derive(Debug)]
enum CanvasError {
    NotExists,
    DimensionMismatch,
    ImageError(ImageError)
}

impl Display for CanvasError {
    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
        write!(f, "Canvas Error: see error_response() for more details")
    }
}

impl ResponseError for CanvasError {
    fn status_code(&self) -> StatusCode {
        match &self {
            CanvasError::NotExists => StatusCode::NOT_FOUND,
            CanvasError::DimensionMismatch => StatusCode::BAD_REQUEST,
            CanvasError::ImageError(e) => e.status_code()
        }
    }

    fn error_response(&self) -> HttpResponse<BoxBody> {
        match &self {
            CanvasError::NotExists => HttpResponse::NotFound().body("Canvas does not exist."),
            CanvasError::DimensionMismatch => HttpResponse::BadRequest().body("Supplied dimensions don't much the dimensions of existing canvas."),
            CanvasError::ImageError(e) => e.error_response()
        }
    }
}

impl From<ImageError> for CanvasError {
    fn from(e: ImageError) -> CanvasError {
        CanvasError::ImageError(e)
    }
}

struct ToRgbIter<'a, T> where T: AsPrimitive<u8> {
    iter: Box<&'a mut dyn Iterator<Item = T>>
}

impl<'a, T: AsPrimitive<u8>> ToRgbIter<'a, T> {
    fn new(data: &'a mut (dyn Iterator<Item = T>)) -> ToRgbIter<T> {
        ToRgbIter { iter: Box::new(data) }
    }
}

impl<T: AsPrimitive<u8> + Zero> Iterator for ToRgbIter<'_, T> {
    type Item = Rgb<u8>;
    fn next(&mut self) -> Option<Rgb<u8>> {
        if let Some(r) = self.iter.next() {
            let g = self.iter.next().unwrap_or(T::zero());
            let b = self.iter.next().unwrap_or(T::zero());
            Some(Rgb([r.as_(), g.as_(), b.as_()]))
        }
        else {
            None
        }
    }
}

fn to_imageresult<T> (result: Result<T, image::ImageError>) -> Result<T, ImageError> {
    match result {
        Ok(v) => Ok(v),
        Err(e) => Err(ImageError(e))
    }
}

fn to_canvasresult<T: std::fmt::Debug> (result: Result<T, ImageError>) -> Result<T, CanvasError> {
    println!("Converting to canvasresult: {:?}", result);
    match result {
        Ok(v) => Ok(v),
        Err(e) => Err(CanvasError::ImageError(e))
    }
}

#[derive(Debug)]
struct Canvas {
    pen: usize,
    img: RgbImage
}

impl Canvas {
    fn new(width: u32, height: u32) -> Canvas {
        Canvas { pen: 0, img: ImageBuffer::new(width, height) }
    }

    fn from_image(img: RgbImage) -> Canvas {
        Canvas { pen: 0, img }
    }

    /*fn replace(&self, img: RgbImage, pen: usize) -> Canvas {
        self.img = img;
        self.pen = pen;
        self
    }*/

    fn advance_pen(mut self, offset: usize) -> Canvas {
        //Canvas { pen: self.pen + offset, img: self.img }
        self.pen += offset;
        self.pen %= self.img.width() as usize * self.img.height() as usize;
        self
    }
}

struct Canvas0(Option<Canvas>);
struct Canvas1(Option<Canvas>);

#[get("/hello/{name}")]
async fn greet(name: web::Path<String>, req: HttpRequest) -> impl Responder {
    println!("{:?}", req);
    format!("Hello {name}!")
}

fn rgb_encode_to_canvas(mut canvas: Canvas, data: &mut dyn Iterator<Item = u8>) -> Result<Canvas, ImageError> {
    let mut pixels = canvas.img.pixels_mut().skip(canvas.pen);
    let mut counter = 0;

    for sp in ToRgbIter::new(data) {
        let mut dp = match pixels.next() {
            Some(pixel) => pixel,
            None => {
                pixels = canvas.img.pixels_mut().skip(0);
                pixels.next().ok_or(ImageError::dimension_error())?
            }
        };
        println!("{:?}", sp);
        dp.0 = sp.0;
        counter += 1;
    }

    Ok(canvas.advance_pen(counter))
}

fn rgb_encode(img: RgbImage, data: &mut dyn Iterator<Item = u8>) -> Result<RgbImage, ImageError> {
    Ok(rgb_encode_to_canvas(Canvas::from_image(img), data)?.img)
}

fn apply_to_canvas<'a, F>(f: F, canvas_option: &'a mut Option<Canvas>, dimensions: Option<(u32, u32)>, data: &str) -> Result<&'a mut Canvas, CanvasError>
    where F: Fn(Canvas, &mut dyn Iterator<Item = u8>) -> Result<Canvas, CanvasError>
{
    let canvas = match canvas_option.take() {
        Some(canvas) => match dimensions {
            Some(dimensions) => {
                if dimensions == canvas.img.dimensions() {
                    Ok(canvas)
                }
                else {
                    _ = canvas_option.insert(canvas);
                    Err(CanvasError::DimensionMismatch)
                }
            },
            None =>
                Ok(canvas)
        },
        None => match dimensions {
            Some((dim_x, dim_y)) =>
                Ok(Canvas::new(dim_x, dim_y)),
            None =>
                Err(CanvasError::NotExists)
        }
    }?;

    Ok(canvas_option.insert(f(canvas, percent_decode_str(&data).into_iter().borrow_mut())?))
}

fn make_png(dim_x: u32, dim_y: u32, scale: u32, data: &mut dyn Iterator<Item = u8>) -> Result<Cursor<Vec<u8>>, ImageError> {
    // Image must not be larger than 1 megapixel
    if dim_x * dim_y * scale > 1048576 {
        return Err(ImageError::dimension_error())
    }

    let img: RgbImage = rgb_encode(ImageBuffer::new(dim_x, dim_y), data)?;

    let tdim_x = dim_x * scale;
    let tdim_y = dim_y * scale;
    let img = resize(&img, tdim_x, tdim_y, FilterType::Nearest);
    let mut cursor = Cursor::new(Vec::new());
    to_imageresult(write_buffer_with_format(&mut cursor, &img, tdim_x, tdim_y, ColorType::Rgb8, Png))?;
    Ok(cursor)
}

#[get("/gen/0/{data}")]
async fn img_gen0(req: HttpRequest) -> Result<impl Responder> {
    let data = req.uri().path().split("/").skip(3).next().unwrap();
    let cursor = make_png(32, 32, 16, percent_decode_str(&data).into_iter().borrow_mut())?;
    Ok(HttpResponse::build(StatusCode::OK)
       .content_type("image/png")
       .body(cursor.into_inner()))
}

#[get("/gen/1/{dim_x}/{dim_y}/{scale}/{data}")]
async fn img_gen1(req: HttpRequest, path: web::Path<(u32, u32, u32)>) -> Result<impl Responder> {
    let (dim_x, dim_y, scale) = path.into_inner();
    let data = req.uri().path().split("/").skip(6).next().unwrap();
    let cursor = make_png(dim_x, dim_y, scale, percent_decode_str(&data).into_iter().borrow_mut())?;
    Ok(HttpResponse::build(StatusCode::OK)
       .content_type("image/png")
       .body(cursor.into_inner()))
}

#[get("/pgen/0/{data}")]
async fn img_pgen0(req: HttpRequest, canvas0: web::Data<Arc<Mutex<Canvas0>>>) -> Result<impl Responder> {
    let data = req.uri().path().split("/").skip(3).next().unwrap();
    let mut cursor = Cursor::new(Vec::new());
    let scale = 16;
    let img: RgbImage = ({
        let canvas_option = &mut *canvas0.lock().unwrap();
        Ok(apply_to_canvas( |c, d| to_canvasresult(rgb_encode_to_canvas(c, d)), &mut canvas_option.0, None, data)?.img.clone())
    } as Result<RgbImage, CanvasError>)?;
    let (tdim_x, tdim_y) = img.dimensions();
    let (tdim_x, tdim_y) = (tdim_x * scale, tdim_y * scale);
    let img = resize(&img, tdim_x, tdim_y, FilterType::Nearest);
    to_imageresult(write_buffer_with_format(&mut cursor, &img, tdim_x, tdim_y, ColorType::Rgb8, Png))?;
    Ok(HttpResponse::build(StatusCode::OK)
       .content_type("image/png")
       .body(cursor.into_inner()))
}

#[get("/pgen/1/{dim_x}/{dim_y}/{scale}/{data}")]
async fn img_pgen1(req: HttpRequest, path: web::Path<(u32, u32, u32)>, canvas1: web::Data<Arc<Mutex<Canvas1>>>) -> Result<impl Responder> {
    let (dim_x, dim_y, scale) = path.into_inner();
    let data = req.uri().path().split("/").skip(6).next().unwrap();
    let img: RgbImage = ({
        let canvas_option = &mut *canvas1.lock().unwrap();
        Ok(apply_to_canvas( |c, d| to_canvasresult(rgb_encode_to_canvas(c, d)), &mut canvas_option.0, Some((dim_x, dim_y)), data)?.img.clone())
    } as Result<RgbImage, CanvasError>)?;
    let (tdim_x, tdim_y) = img.dimensions();
    let (tdim_x, tdim_y) = (tdim_x * scale, tdim_y * scale);
    let img = resize(&img, tdim_x, tdim_y, FilterType::Nearest);
    let mut cursor = Cursor::new(Vec::new());
    to_imageresult(write_buffer_with_format(&mut cursor, &img, tdim_x, tdim_y, ColorType::Rgb8, Png))?;
    Ok(HttpResponse::build(StatusCode::OK)
       .content_type("image/png")
       .body(cursor.into_inner()))
}


#[actix_web::main] // or #[tokio::main]
async fn main() -> std::io::Result<()> {
    env_logger::init();
    let canvas0 = Arc::new(Mutex::new(Canvas0(Some(Canvas::new(32, 32)))));
    let canvas1 = Arc::new(Mutex::new(Canvas1(None)));
    HttpServer::new(move || {
        App::new()
            .service(greet)
            .service(img_gen0)
            .service(img_gen1)
            .service(img_pgen0)
            .service(img_pgen1)
            .app_data(web::Data::new(canvas0.clone()))
            .app_data(web::Data::new(canvas1.clone()))
    })
    .bind(("127.0.0.1", 8080))?
    .run()
    .await
}