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2f228ff2cf
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@ -1,69 +1,94 @@
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use std::collections::HashMap;
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#[derive(Debug, Clone, Serialize, Deserialize)]
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enum FeatureResult {
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/// A boolean. Just a boolean
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Bool(bool),
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/// Signed 32-bit integer
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I32(i32),
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/// 32-bit single precision floating point
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/// can be used for aspect ratio or luminance
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F32(f32),
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/// Vector for nested multidimensional
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Vec(Vec<FeatureResult>),
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/// Standard RGBA color
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RGBA(f32, f32, f32, f32),
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/// Indices intended for the usage in historgrams
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Indices(Vec<u64>)
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}
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fn extract_color_distribution(image_data: &[u8]) -> HashMap<u32, f32> {
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let mut color_distribution: HashMap<u32, f32> = HashMap::new();
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let total_pixels = image_data.len() as f32 / 4.0;//für 4 Werte
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impl Default for FeatureResult {
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fn default() -> Self {
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FeatureResult::Bool(false)
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}
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}
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for pixel in image_data.chunks_exact(4) {
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let r = pixel[0] as u32;
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let g = pixel[1] as u32;
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let b = pixel[2] as u32;
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let a = pixel[3] as u32;
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let rgba = (r << 24) | (g << 16) | (b << 8) | a;
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/// For some feature return type we want to implement a custom compare function
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/// for example: historgrams are compared with cosine similarity
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impl PartialEq for FeatureResult {
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fn eq(&self, other: &Self) -> bool {
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match (self, other) {
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(Self::Bool(l0), Self::Bool(r0)) => l0 == r0,
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(Self::I32(l0), Self::I32(r0)) => l0 == r0,
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(Self::F32(l0), Self::F32(r0)) => l0 == r0,
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(Self::Vec(l0), Self::Vec(r0)) => l0 == r0,
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(Self::RGBA(l0, l1, l2, l3), Self::RGBA(r0, r1, r2, r3)) => l0 == r0 && l1 == r1 && l2 == r2 && l3 == r3,
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(Self::Indices(_), Self::Indices(_)) => todo!("implement cosine similarity"),
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_ => false,
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}
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}
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}
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*color_distribution.entry(rgba).or_insert(0.0) += 1.0;
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type FeatureGenerator = Box<dyn Fn(crate::Image<f32>) -> (String, FeatureResult)>;
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#[derive(Serialize, Deserialize, Default)]
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struct Database {
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images: HashMap<String, HashMap<String, FeatureResult>>,
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/// keep feature generator for the case when we add a new image
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/// this field is not serialized and needs to be wrapped in an option
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#[serde(skip)]
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generators: Option<Vec<FeatureGenerator>>
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}
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impl Database {
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pub fn add_feature(&mut self, feature: FeatureGenerator) {
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for (path, features) in self.images.iter_mut() {
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// compute feature for every image
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todo!("run this as a closure parallel with a thread pool");
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let (name, res) = feature(todo!("load image from disk"));
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features.insert(name, res);
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}
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for (_, count) in &mut color_distribution {
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*count /= total_pixels;
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if let Some(generators) = self.generators.as_mut() {
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generators.push(feature);
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} else {
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self.generators = Some(vec![feature])
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}
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}
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color_distribution
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}
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fn extract_average_brightness(image: &[u8]) -> u8 {
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let mut sum: u32 = 0;
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let mut count: u32 = 0;
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for i in (0..image.len()).step_by(4) {
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let r = image[i] as u32;
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let g = image[i + 1] as u32;
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let b = image[i + 2] as u32;
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// (0.299 * R) + (0.587 * G) + (0.114 * B)
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let brightness = ((0.299 * r as f32) + (0.587 * g as f32) + (0.114 * b as f32)).round() as u32;
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sum += brightness;
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count += 1;
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pub fn add_image(&mut self, path: String) {
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let image = todo!("load image from disk");
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let mut features = HashMap::new();
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if let Some(generators) = self.generators {
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for generator in generators.iter() {
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let (name, res) = generator(image);
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features.insert(name, res);
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}
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}
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self.images.insert(path, features);
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}
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let average_brightness = (sum / count) as u8;
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average_brightness
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}
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fn main() {
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test2();
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/// example feature implementation
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fn average_luminance(image: Image<f32>) -> (String, FeatureResult) {
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(String::from("average-brightness"), FeatureResult::F32(0.0))
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}
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fn test2(){
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#[test]
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fn test() {
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let mut data = Database::default();
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let image_data: Vec<(u8, u8, u8, u8)> = vec![
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(255, 0, 0, 255), // Red
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(0, 255, 0, 255), // Green
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(0, 0, 255, 255), // Blue
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];
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//convert image data to useable &u8 slice
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let byte_slice: &[u8] = unsafe {
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std::slice::from_raw_parts(
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image_data.as_ptr() as *const u8,
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image_data.len() * 4,
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)
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};
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let color_distribution = extract_color_distribution(&byte_slice);
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let color_distribution_vec: Vec<f32> = color_distribution.values().cloned().collect();
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let average_brightness = extract_average_brightness(&byte_slice);
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println!("{:?}", average_brightness);
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println!("{:?}", color_distribution_vec);
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data.add_feature(Box::new(average_luminance));
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let _as_json = serde_json::to_string(&data);
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}
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