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//! Image support for embedded-graphics //! //! The two main types used to draw images are [`ImageDrawable`] and [`Image`]. //! //! [`ImageDrawable`] is implemented to add support for different image formats. This crate includes //! an implementation for [raw pixel data]. Additional implementations for other image formats are //! provided by external crates like [tinybmp] and [tinytga]. //! //! The [`Image`] object is used to specify the location at which an [`ImageDrawable`] is drawn. //! Images are drawn relative to their top-left corner. //! //! # Examples //! //! ## Display an RGB565 raw data image //! //! This example displays a small image created from a raw data array. The image is RGB565 encoded, //! so it uses the `Rgb565` color type. //! //! ```rust //! use embedded_graphics::{ //! image::{Image, ImageRaw, ImageRawBE}, //! pixelcolor::Rgb565, //! prelude::*, //! }; //! # use embedded_graphics::mock_display::MockDisplay as Display; //! //! let mut display: Display<Rgb565> = Display::default(); //! //! // Raw big endian image data for demonstration purposes. A real image would likely be much //! // larger. //! let data = [ //! 0x00, 0x00, 0xF8, 0x00, 0x07, 0xE0, 0xFF, 0xE0, // //! 0x00, 0x1F, 0x07, 0xFF, 0xF8, 0x1F, 0xFF, 0xFF, // //! ]; //! //! // Create a raw image instance. Other image formats will require different code to load them. //! // All code after loading is the same for any image format. //! let raw: ImageRawBE<Rgb565> = ImageRaw::new(&data, 4); //! //! // Create an `Image` object to position the image at `Point::zero()`. //! let image = Image::new(&raw, Point::zero()); //! //! // Draw the image to the display. //! image.draw(&mut display)?; //! //! # Ok::<(), core::convert::Infallible>(()) //! ``` //! //! ## Sub images //! //! [`SubImage`]s are used to split a larger image drawables into multiple parts, e.g. to draw a //! single sprite from a sprite atlas as in this example. Use the [`sub_image`] method provided by //! [`ImageDrawableExt`] to get a sub image from an image drawable. [`ImageDrawableExt`] is included //! in the [`prelude`], which this example takes advantage of. //! //! ```rust //! use embedded_graphics::{ //! image::{Image, ImageRaw, ImageRawBE}, //! pixelcolor::Rgb565, //! prelude::*, //! primitives::Rectangle, //! }; //! # use embedded_graphics::mock_display::MockDisplay as Display; //! //! let mut display: Display<Rgb565> = Display::default(); //! //! let data = [ 0xF8, 0x00, 0x07, 0xE0, 0xFF, 0xE0, /* ... */ ]; //! // or: let data = include_bytes!("sprite_atlas.raw"); //! //! # let data = [0u8; 32 * 16 * 2]; //! let sprite_atlas: ImageRawBE<Rgb565> = ImageRaw::new(&data, 32); //! //! // Create individual sub images for each sprite in the sprite atlas. //! // The position and size of the sub images is defined by a `Rectangle`. //! let sprite_1 = sprite_atlas.sub_image(&Rectangle::new(Point::new(0, 0), Size::new(16, 16))); //! let sprite_2 = sprite_atlas.sub_image(&Rectangle::new(Point::new(16, 0), Size::new(16, 16))); //! //! // Create `Image` objects to draw the sprites at different positions on the display. //! Image::new(&sprite_1, Point::new(10, 10)).draw(&mut display)?; //! Image::new(&sprite_2, Point::new(40, 30)).draw(&mut display)?; //! //! # Ok::<(), core::convert::Infallible>(()) //! ``` //! //! # Implementing new image formats //! //! To add embedded-graphics support for an new image format the [`ImageDrawable`] and //! [`OriginDimensions`] traits must be implemented. See the [`ImageDrawable`] documentation //! for more information. //! //! [tinytga]: https://crates.io/crates/tinytga //! [tinybmp]: https://crates.io/crates/tinybmp //! [raw pixel data]: struct.ImageRaw.html //! [`ImageDrawable`]: trait.ImageDrawable.html //! [`ImageDrawableExt`]: trait.ImageDrawableExt.html //! [`sub_image`]: trait.ImageDrawableExt.html#tymethod.sub_image //! [`OriginDimensions`]: ../geometry/trait.OriginDimensions.html //! [`Image`]: ./struct.Image.html //! [`SubImage`]: struct.SubImage.html //! [`prelude`]: ../prelude/index.html mod image_drawable_ext; mod image_raw; mod sub_image; pub use embedded_graphics_core::image::ImageDrawable; pub use image_drawable_ext::ImageDrawableExt; pub use image_raw::{ImageRaw, ImageRawBE, ImageRawLE}; pub use sub_image::SubImage; use crate::{ draw_target::{DrawTarget, DrawTargetExt}, geometry::{Dimensions, OriginDimensions, Point}, primitives::Rectangle, transform::Transform, Drawable, }; use core::fmt::Debug; /// Image object. /// /// The `Image` struct serves as a wrapper around an [`ImageDrawable`] that provides support for /// an image format (raw bytes, BMP, TGA, etc). It allows an image to be repositioned using /// [`Transform::translate`] or [`Transform::translate_mut`] and drawn to a display that /// implements the [`DrawTarget`] trait. /// /// Refer to the [module documentation] for examples. /// /// [module documentation]: ./index.html /// [`Transform::translate`]: ../transform/trait.Transform.html#tymethod.translate /// [`Transform::translate_mut`]: ../transform/trait.Transform.html#tymethod.translate_mut /// [`DrawTarget`]: ../draw_target/trait.DrawTarget.html /// [`ImageDrawable`]: trait.ImageDrawable.html #[derive(Debug, Clone, Copy)] pub struct Image<'a, T> { image_drawable: &'a T, offset: Point, } impl<'a, T> Image<'a, T> where T: ImageDrawable, { /// Creates a new `Image`. pub fn new(image_drawable: &'a T, position: Point) -> Self { Self { image_drawable, offset: position, } } } impl<T> Transform for Image<'_, T> { /// Translate the image by a given delta, returning a new image /// /// # Examples /// /// ## Move an image around /// /// This examples moves a 4x4 black and white image by `(10, 20)` pixels without mutating the /// original image /// /// ```rust /// use embedded_graphics::{ /// geometry::Point, /// image::{Image, ImageRaw}, /// pixelcolor::BinaryColor, /// prelude::*, /// }; /// /// let image: ImageRaw<BinaryColor> = ImageRaw::new(&[0xff, 0x00, 0xff, 0x00], 4); /// /// let image = Image::new(&image, Point::zero()); /// /// let image_moved = image.translate(Point::new(10, 20)); /// /// assert_eq!(image.bounding_box().top_left, Point::zero()); /// assert_eq!(image_moved.bounding_box().top_left, Point::new(10, 20)); /// ``` fn translate(&self, by: Point) -> Self { Self { image_drawable: self.image_drawable, offset: self.offset + by, } } /// Translate the image by a given delta, modifying the original object /// /// # Examples /// /// ## Move an image around /// /// This examples moves a 4x4 black and white image by `(10, 20)` pixels by mutating the /// original image /// /// ```rust /// use embedded_graphics::{ /// geometry::Point, /// image::{Image, ImageRaw}, /// pixelcolor::BinaryColor, /// prelude::*, /// }; /// /// let image: ImageRaw<BinaryColor> = ImageRaw::new(&[0xff, 0x00, 0xff, 0x00], 4); /// /// let mut image = Image::new(&image, Point::zero()); /// /// image.translate_mut(Point::new(10, 20)); /// /// assert_eq!(image.bounding_box().top_left, Point::new(10, 20)); /// ``` fn translate_mut(&mut self, by: Point) -> &mut Self { self.offset += by; self } } impl<'a, T> Drawable for Image<'a, T> where T: ImageDrawable, { type Color = T::Color; type Output = (); fn draw<D>(&self, display: &mut D) -> Result<Self::Output, D::Error> where D: DrawTarget<Color = Self::Color>, { self.image_drawable .draw(&mut display.translated(self.offset)) } } impl<'a, T> Dimensions for Image<'a, T> where T: OriginDimensions, { fn bounding_box(&self) -> Rectangle { self.image_drawable.bounding_box().translate(self.offset) } } #[cfg(test)] mod tests { use super::*; use crate::{geometry::Size, mock_display::MockDisplay, pixelcolor::BinaryColor}; #[test] fn negative_top_left() { let image: ImageRaw<BinaryColor> = ImageRaw::new(&[0xff, 0x00, 0xff, 0x00], 4); let image = Image::new(&image, Point::zero()).translate(Point::new(-1, -1)); assert_eq!( image.bounding_box(), Rectangle::new(Point::new(-1, -1), Size::new(4, 4)) ); } #[test] fn dimensions() { let image: ImageRaw<BinaryColor> = ImageRaw::new(&[0xff, 0x00, 0xFF, 0x00], 4); let image = Image::new(&image, Point::zero()).translate(Point::new(100, 200)); assert_eq!( image.bounding_box(), Rectangle::new(Point::new(100, 200), Size::new(4, 4)) ); } #[test] fn position() { let image_raw: ImageRaw<BinaryColor> = ImageRaw::new(&[0xAA, 0x55, 0xAA, 0x55], 4); let mut display = MockDisplay::new(); Image::new(&image_raw, Point::new(1, 2)) .draw(&mut display) .unwrap(); display.assert_pattern(&[ " ", // " ", // " #.#.", // " .#.#", // " #.#.", // " .#.#", // ]); } }