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use super::index_for_pixel::index_for_pixel;
use super::ImageSize;
use std::fmt;
/// Tiny 2D grid with 8 bits per pixel.
///
/// The max size is 255x255 pixels.
///
/// The smallest image size is 0x0 pixels.
#[derive(Clone, Hash, Eq, Ord, PartialEq, PartialOrd)]
pub struct Image {
width: u8,
height: u8,
pixels: Vec<u8>,
}
impl Image {
pub fn empty() -> Self {
Self { width: 0, height: 0, pixels: vec!() }
}
/// Create an `Image` instance, filled with `color`
pub fn color(width: u8, height: u8, color: u8) -> Self {
let len: usize = (width as usize) * (height as usize);
if len == 0 {
return Self::empty();
}
let pixels: Vec<u8> = vec![color; len];
Self { width, height, pixels }
}
/// Create an `Image` instance, filled with zeroes
pub fn zero(width: u8, height: u8) -> Self {
Self::color(width, height, 0)
}
/// Create an `Image` instance filled with a specific color.
///
/// Returns an `Image` with the same size as the current image.
#[allow(dead_code)]
pub fn clone_color(&self, color: u8) -> Self {
Self::color(self.width, self.height, color)
}
/// Create an `Image` instance filled with zeroes.
///
/// Returns an `Image` with the same size as the current image.
#[allow(dead_code)]
pub fn clone_zero(&self) -> Self {
self.clone_color(0)
}
/// Create an `Image` instance filled with ones.
///
/// Returns an `Image` with the same size as the current image.
#[allow(dead_code)]
pub fn clone_one(&self) -> Self {
self.clone_color(1)
}
/// Create a `Image` instance without any checks of the data
///
/// It's up to the caller to ensure:
/// - Make sure that the pixels.len() is the same as width x height.
/// - Make sure that when width=0, that height is not greater than 0.
/// - Make sure that when height=0, that width is not greater than 0.
pub fn create_raw(width: u8, height: u8, pixels: Vec<u8>) -> Self {
Self { width, height, pixels }
}
pub fn is_empty(&self) -> bool {
self.width == 0 || self.height == 0
}
pub fn width(&self) -> u8 {
self.width
}
pub fn height(&self) -> u8 {
self.height
}
/// The size of the image
pub fn size(&self) -> ImageSize {
ImageSize {
width: self.width,
height: self.height,
}
}
pub fn pixels(&self) -> &Vec<u8> {
&self.pixels
}
pub fn index_for_pixel(&self, x: i32, y: i32) -> Option<usize> {
index_for_pixel(x, y, self.width, self.height)
}
/// Get pixel value at coordinate (x, y). No wrap around.
///
/// Idea for simplification. I rarely act on the `None` value.
///
/// from this: `image.get(x as i32, y as i32).unwrap_or(255);`
///
/// to this: `image.get(x, y)` and use `Color::Invalid` when getting outside the image.
pub fn get(&self, x: i32, y: i32) -> Option<u8> {
let index: usize = self.index_for_pixel(x, y)?;
if index >= self.pixels.len() {
return None;
}
Some(self.pixels[index])
}
/// Get pixel value with coordinate (x, y) wrapped around.
///
/// Returns `None` when the image is empty.
///
/// When the coordinate is outside the image, it will wrap around.
#[allow(dead_code)]
pub fn get_wrap(&self, x: i32, y: i32) -> Option<u8> {
if self.is_empty() {
return None;
}
let mut x_wrap: i32 = x % (self.width as i32);
if x_wrap < 0 {
x_wrap += self.width as i32;
}
let mut y_wrap: i32 = y % (self.height as i32);
if y_wrap < 0 {
y_wrap += self.height as i32;
}
self.get(x_wrap, y_wrap)
}
/// Set pixel value at coordinate (x, y).
pub fn set(&mut self, x: i32, y: i32, value: u8) -> Option<()> {
let index: usize = self.index_for_pixel(x, y)?;
if index >= self.pixels.len() {
return None;
}
self.pixels[index] = value;
Some(())
}
/// Replace content
pub fn set_image(&mut self, other: Image) {
self.width = other.width;
self.height = other.height;
self.pixels = other.pixels;
}
/// Get the lowest and highest pixel values in the image.
///
/// If the image is empty, it returns `None`.
pub fn minmax(&self) -> Option<(u8,u8)> {
if self.is_empty() {
return None;
}
let mut min_value: u8 = u8::MAX;
let mut max_value: u8 = 0;
for y in 0..self.height {
for x in 0..self.width {
let pixel_value: u8 = self.get(x as i32, y as i32).unwrap_or(255);
min_value = min_value.min(pixel_value);
max_value = max_value.max(pixel_value);
}
}
Some((min_value, max_value))
}
/// Formatting of the pixels that is easy for a human to read.
pub fn human_readable(&self) -> String {
let mut s = String::new();
for y in 0..self.height {
if y > 0 {
s += "\n";
}
for x in 0..self.width {
let pixel_value: u8 = self.get(x as i32, y as i32).unwrap_or(255);
if x > 0 {
s += " ";
}
s += &format!("{:X?}", pixel_value);
}
}
s
}
}
impl fmt::Debug for Image {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "Image {}x{}\n{}", self.width, self.height, self.human_readable())
}
}
#[cfg(test)]
mod tests {
use super::*;
use std::collections::HashSet;
#[test]
fn test_10000_init_empty() {
let bm = Image::empty();
assert_eq!(bm.width(), 0);
assert_eq!(bm.height(), 0);
assert_eq!(bm.pixels().is_empty(), true);
assert_eq!(bm.is_empty(), true);
}
#[test]
fn test_10001_init_color() {
let bm = Image::color(4, 3, 1);
assert_eq!(bm.width(), 4);
assert_eq!(bm.height(), 3);
assert_eq!(bm.pixels().len(), 4 * 3);
assert_eq!(bm.is_empty(), false);
let mut sum: usize = 0;
for pixel in bm.pixels() {
sum += *pixel as usize;
}
assert_eq!(sum, 12);
}
#[test]
fn test_10002_init_color_empty() {
{
let image = Image::color(0, 3, 1);
assert_eq!(image, Image::empty());
}
{
let image = Image::color(3, 0, 1);
assert_eq!(image, Image::empty());
}
}
#[test]
fn test_10003_init_zero() {
let bm = Image::zero(4, 3);
assert_eq!(bm.width(), 4);
assert_eq!(bm.height(), 3);
assert_eq!(bm.pixels().len(), 4 * 3);
assert_eq!(bm.is_empty(), false);
let mut sum: usize = 0;
for pixel in bm.pixels() {
sum += *pixel as usize;
}
assert_eq!(sum, 0);
}
#[test]
fn test_20000_get_set_pixel_value_ok() {
let mut bm = Image::zero(3, 2);
bm.set(0, 0, 1).expect("ok");
bm.set(1, 0, 2).expect("ok");
bm.set(2, 0, 3).expect("ok");
bm.set(0, 1, 4).expect("ok");
bm.set(1, 1, 5).expect("ok");
bm.set(2, 1, 6).expect("ok");
assert_eq!(bm.get(0, 0), Some(1));
assert_eq!(bm.get(1, 0), Some(2));
assert_eq!(bm.get(2, 0), Some(3));
assert_eq!(bm.get(0, 1), Some(4));
assert_eq!(bm.get(1, 1), Some(5));
assert_eq!(bm.get(2, 1), Some(6));
}
#[test]
fn test_20001_get_set_pixel_value_ok() {
let mut bm = Image::zero(3, 1);
bm.set(0, 0, 253).expect("ok");
bm.set(1, 0, 254).expect("ok");
bm.set(2, 0, 255).expect("ok");
assert_eq!(bm.get(0, 0), Some(253));
assert_eq!(bm.get(1, 0), Some(254));
assert_eq!(bm.get(2, 0), Some(255));
}
#[test]
fn test_20002_set_pixel_value_error() {
let mut bm = Image::zero(3, 2);
// negative coordinates
assert_eq!(bm.set(-1, 0, 0), None);
assert_eq!(bm.set(0, -1, 0), None);
// beyond width or height
assert_eq!(bm.set(3, 0, 0), None);
assert_eq!(bm.set(0, 2, 0), None);
}
#[test]
fn test_20003_get_wrap() {
// Arrange
let pixels: Vec<u8> = vec![
11, 21, 31,
12, 22, 32,
13, 23, 33,
14, 24, 34,
];
let image: Image = Image::create_raw(3, 4, pixels);
// Act & Assert
{
// negative x coordinate
assert_eq!(image.get_wrap(-1, 0), Some(31));
assert_eq!(image.get_wrap(-4, 0), Some(31));
assert_eq!(image.get_wrap(-7, 0), Some(31));
}
{
// negative y coordinate
assert_eq!(image.get_wrap(0, -1), Some(14));
assert_eq!(image.get_wrap(0, -5), Some(14));
assert_eq!(image.get_wrap(0, -9), Some(14));
}
{
// x coordinate beyond width
assert_eq!(image.get_wrap(3, 0), Some(11));
assert_eq!(image.get_wrap(6, 0), Some(11));
assert_eq!(image.get_wrap(9, 0), Some(11));
}
{
// y coordinate beyond height
assert_eq!(image.get_wrap(0, 4), Some(11));
assert_eq!(image.get_wrap(0, 8), Some(11));
assert_eq!(image.get_wrap(0, 12), Some(11));
}
}
#[test]
fn test_30000_compare() {
{
let mut bm0 = Image::zero(3, 2);
bm0.set(0, 0, 255).expect("ok");
bm0.set(2, 1, 255).expect("ok");
let bm1 = Image::create_raw(3, 2, vec![255, 0, 0, 0, 0, 255]);
assert_eq!(bm0, bm1);
}
{
let mut bm0 = Image::zero(3, 2);
bm0.set(0, 0, 255).expect("ok");
bm0.set(2, 1, 254).expect("ok");
let bm1 = Image::create_raw(3, 2, vec![255, 0, 0, 0, 0, 255]);
assert_ne!(bm0, bm1);
}
{
let mut bm0 = Image::create_raw(3, 2, vec![255, 0, 0, 0, 0, 255]);
bm0.set(0, 0, 0).expect("ok");
bm0.set(2, 1, 0).expect("ok");
let bm1 = Image::zero(3, 2);
assert_eq!(bm0, bm1);
}
}
#[test]
fn test_40000_equal() {
{
let image0 = Image::create_raw(2, 2, vec![1, 2, 3, 4]);
let image1 = Image::create_raw(2, 2, vec![1, 2, 3, 4]);
assert_eq!(image0, image1);
}
{
let image0 = Image::empty();
let image1 = Image::empty();
assert_eq!(image0, image1);
}
{
let image0 = Image::create_raw(1, 4, vec![1, 2, 3, 4]);
let image1 = Image::create_raw(4, 1, vec![1, 2, 3, 4]);
assert_ne!(image0, image1);
}
{
let image0 = Image::empty();
let image1 = Image::create_raw(4, 1, vec![1, 2, 3, 4]);
assert_ne!(image0, image1);
}
}
fn mock_hashset() -> HashSet<Image> {
let mut images: HashSet<Image> = HashSet::<Image>::new();
{
let image = Image::create_raw(2, 2, vec![1, 2, 3, 4]);
images.insert(image);
}
{
let image = Image::create_raw(1, 1, vec![9]);
images.insert(image);
}
images
}
#[test]
fn test_50000_hash() {
let images: HashSet<Image> = mock_hashset();
assert_eq!(images.len(), 2);
}
#[test]
fn test_50001_hash_insert_identical_image_does_not_affect_size() {
let mut images: HashSet<Image> = mock_hashset();
{
let image = Image::create_raw(1, 1, vec![9]);
images.insert(image);
}
assert_eq!(images.len(), 2);
}
#[test]
fn test_50002_hash_remove_image() {
let mut images: HashSet<Image> = mock_hashset();
{
let image = Image::create_raw(1, 1, vec![9]);
images.remove(&image);
}
assert_eq!(images.len(), 1);
}
#[test]
fn test_60000_set_image() {
// Arrange
let mut image = Image::empty();
let new_image = Image::color(3, 2, 9);
// Act
image.set_image(new_image);
// Assert
assert_eq!(image.width(), 3);
assert_eq!(image.height(), 2);
let expected_pixels: Vec<u8> = vec![9, 9, 9, 9, 9, 9];
assert_eq!(*image.pixels(), expected_pixels);
}
#[test]
fn test_70000_sort_same_sizes_different_colors() {
// Arrange
let image0 = Image::color(1, 1, 0);
let image1 = Image::color(1, 1, 1);
let image2 = Image::color(1, 1, 2);
let image3 = Image::color(1, 1, 3);
let mut shuffled_images: Vec<Image> = vec![image3.clone(), image1.clone(), image0.clone(), image2.clone()];
// Act
shuffled_images.sort();
// Assert
let expected_images: Vec<Image> = vec![image0, image1, image2, image3];
assert_eq!(expected_images, shuffled_images);
}
#[test]
fn test_70001_sort_different_sizes_same_color() {
// Arrange
let image0 = Image::color(1, 1, 0);
let image1 = Image::color(1, 2, 0);
let image2 = Image::color(2, 1, 0);
let image3 = Image::color(2, 2, 0);
let mut shuffled_images: Vec<Image> = vec![image3.clone(), image1.clone(), image0.clone(), image2.clone()];
// Act
shuffled_images.sort();
// Assert
let expected_images: Vec<Image> = vec![image0, image1, image2, image3];
assert_eq!(expected_images, shuffled_images);
}
#[test]
fn test_80000_clone_color() {
// Arrange
let mut input = Image::zero(5, 3);
_ = input.set(2, 1, 1);
// Act
let actual: Image = input.clone_color(1);
// Assert
let expected = Image::color(5, 3, 1);
assert_eq!(expected, actual);
}
#[test]
fn test_90000_minmax() {
{
let image = Image::create_raw(2, 3, vec![5, 4, 9, 5, 42, 9]);
assert_eq!(image.minmax(), Some((4, 42)));
}
{
let image = Image::empty();
assert_eq!(image.minmax(), None);
}
}
}
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