wallswitch 0.60.5

//! Julia Set fractal generator overlay.
//!
//! This module provides the implementation of the Julia Set fractal renderer,
//! using pre-programmed coordinate presets. It generates mathematical overlays
//! dynamically fitted to the display dimensions and blends them using high-contrast
//! dual-tone chromatic borders and 3D shadow depth offsets.

use crate::effects::{
    FractalPreset, MAX_ITERATIONS, MIN_ITERATIONS, ProceduralEffect, Viewport, ViewportSpecs,
    blend_and_vignette_pixel, calculate_distance_estimator, calculate_smooth_potential,
    compute_escape_iterations, get_rotation_steps, partition_rows, rotate_point,
};
use crate::{
    Complex, ImageEffect, NEON_PALETTES, NeonColor, WallSwitchError, WallSwitchResult,
    get_random_integer, smoothstep,
};
use image::RgbImage;
use std::{io::Error, path::Path, thread};

/// Implementation of the [`ImageEffect`] trait for rendering Julia Set fractals.
impl ImageEffect for JuliaGenerator {
    /// Applies the Julia Set procedural overlay onto an in-memory image buffer.
    fn apply(&self, rgb_img: &mut RgbImage) {
        self.apply_effect_in_memory(rgb_img);
    }

    /// Returns formatting diagnostic information about the active generator.
    fn info(&self) -> String {
        format!(
            "fractal [{}]\n\
            f(z) = z² + c, where c = {:8.5} {} {:7.5}i (iter = {:4}, zoom = {:.2}), color: {}",
            self.preset.fractal_name,
            self.preset.center.re,
            if self.preset.center.im >= 0.0 {
                "+"
            } else {
                "-"
            },
            self.preset.center.im.abs(),
            self.scan_iterations,
            self.zoom,
            self.color_palette
        )
    }
}

/// A procedural generator for rendering Julia Set fractals onto desktop backgrounds.
///
/// Combines mathematical coordinate presets with viewport fitting, lighting shaders,
/// and color interpolation to produce high-definition digital art overlays.
pub struct JuliaGenerator {
    /// The active coordinate preset, enclosing the center points and metadata.
    pub preset: FractalPreset,
    /// The maximum iteration limit for escape-time calculations.
    pub scan_iterations: u32,
    /// The base color palette selected for the neon glow.
    pub color_palette: NeonColor,
    /// The viewport zoom level.
    pub zoom: f64,
    /// The cosine of the rotation angle.
    pub cos_angle: f64,
    /// The sine of the rotation angle.
    pub sin_angle: f64,
}

impl Default for JuliaGenerator {
    /// Returns the default fallback instance of the Julia Set generator.
    fn default() -> Self {
        Self {
            preset: FractalPreset {
                center: Complex::new(-0.7, 0.27015),
                fractal_name: "Classic dendrite",
                effect_name: ProceduralEffect::JuliaSet,
            },
            scan_iterations: get_random_integer(MIN_ITERATIONS, MAX_ITERATIONS),
            color_palette: NEON_PALETTES[5],
            zoom: 3.0,
            cos_angle: 1.0,
            sin_angle: 0.0,
        }
    }
}

impl JuliaGenerator {
    /// Generates a randomized Julia Set configuration fitted to the target aspect ratio.
    ///
    /// Selects one of the built-in coordinate presets, assigns a neon color palette,
    /// rotates the coordinate system randomly, and optimizes the viewport fit.
    pub fn random(monitor: &crate::Monitor) -> Self {
        let width = monitor.resolution.width as u32;
        let height = monitor.resolution.height as u32;

        let presets = [
            FractalPreset {
                center: Complex::new(-0.4, 0.6),
                fractal_name: "Classic cloud swirls",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.8, 0.156),
                fractal_name: "Detailed spirals",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.7269, 0.1889),
                fractal_name: "Lace structures",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.75, 0.11),
                fractal_name: "Feathery branches",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.1, 0.651),
                fractal_name: "Cosmic dust style",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.70176, -0.3842),
                fractal_name: "Dragon-like curves",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(0.355, 0.355),
                fractal_name: "Spiral galaxy arms",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.4, -0.59),
                fractal_name: "Swirling vortexes",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.54, 0.54),
                fractal_name: "Ornamental lace borders",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.74543, 0.11301),
                fractal_name: "Dense filigree patterns",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.835, -0.2321),
                fractal_name: "Lightning rods",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.77269, 0.12428),
                fractal_name: "Coral reefs",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.51251, 0.5213),
                fractal_name: "Fine lace filaments",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.55, 0.55),
                fractal_name: "Intricate leaf outlines",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.624, 0.435),
                fractal_name: "Crystalline snowflake patterns",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.12, 0.85),
                fractal_name: "Flowing plasma plumes",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.742, 0.1345),
                fractal_name: "Intricate branching nodes",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.391, -0.587),
                fractal_name: "Swirling storm clouds",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(0.0, 0.8),
                fractal_name: "Classic symmetric dendritic structure",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.73, 0.21),
                fractal_name: "Feathery dendritic lace",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.81, 0.2),
                fractal_name: "Spiral galaxy filaments",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.68, 0.34),
                fractal_name: "Delicate coral spirals",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.76, 0.08),
                fractal_name: "Lightning tree branches",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.72, 0.22),
                fractal_name: "Dendritic pine branches",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(0.285, 0.01),
                fractal_name: "Cosmic galaxy vortex swirls",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.743643, 0.13182),
                fractal_name: "Highly intricate Seahorse Valley filaments",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.8, 0.17),
                fractal_name: "Spidery lace denderites",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.7269, -0.1889),
                fractal_name: "Conjugate lace structures",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.835, 0.2321),
                fractal_name: "Conjugate lightning rods",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.75, 0.05),
                fractal_name: "Dense branching coral reef",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.70176, 0.3842),
                fractal_name: "Conjugate dragon-like curves",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.74543, -0.11301),
                fractal_name: "Dense conjugate filigree",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.8, 0.16),
                fractal_name: "Deep sea coral spirals",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.722, 0.246),
                fractal_name: "Dendritic pine branch variation",
                effect_name: ProceduralEffect::JuliaSet,
            },
            FractalPreset {
                center: Complex::new(-0.2, 0.65),
                fractal_name: "Soft flame plasma plumes",
                effect_name: ProceduralEffect::JuliaSet,
            },
        ];

        let p_idx: usize = get_random_integer(0, NEON_PALETTES.len() - 1);
        let color_palette = NEON_PALETTES[p_idx];

        let angle_degrees: f64 = get_random_integer(0, 359);
        let radians = angle_degrees.to_radians();

        let preset_idx: usize = get_random_integer(0, presets.len() - 1);
        let selected_preset = presets[preset_idx];

        let mut julia = Self {
            preset: selected_preset,
            scan_iterations: get_random_integer(MIN_ITERATIONS, MAX_ITERATIONS),
            color_palette,
            zoom: 3.0,
            cos_angle: radians.cos(),
            sin_angle: radians.sin(),
        };

        julia.optimize_fit(width, height);
        julia
    }

    /// Optimizes the viewport boundaries by scanning complex boundaries and finding a balanced zoom.
    pub fn optimize_fit(&mut self, width: u32, height: u32) {
        let w_f = width as f64;
        let h_f = height as f64;
        let min_dim = w_f.min(h_f);

        let c_abs = self.preset.center.norm_sq().sqrt();
        let r_bound = (1.0 + (1.0 + 4.0 * c_abs).sqrt()) / 2.0;
        let search_limit = r_bound * 1.2;

        let steps = 128;
        let inv_steps_minus_1 = 1.0 / (steps - 1) as f64;
        let range = 2.0 * search_limit;

        let scan_iterations = self.scan_iterations;
        let mut active_points = Vec::with_capacity(steps * steps / 2);

        for step_y in 0..steps {
            let ry = -search_limit + (step_y as f64 * inv_steps_minus_1) * range;
            for step_x in 0..steps {
                let rx = -search_limit + (step_x as f64 * inv_steps_minus_1) * range;

                let (i, _, _) = compute_escape_iterations(
                    ProceduralEffect::JuliaSet,
                    Complex::new(rx, ry),
                    self.preset.center,
                    scan_iterations,
                );

                if i > 3 && i < scan_iterations {
                    active_points.push((rx, ry));
                }
            }
        }

        if !active_points.is_empty() {
            let mut best_zoom = f64::MAX;
            let mut best_cos = self.cos_angle;
            let mut best_sin = self.sin_angle;

            for (_rad, cos_t, sin_t) in get_rotation_steps() {
                let mut max_cx_abs = 0.0_f64;
                let mut max_cy_abs = 0.0_f64;

                for &(rx, ry) in &active_points {
                    let (cx, cy) = rotate_point(rx, ry, cos_t, sin_t);
                    max_cx_abs = max_cx_abs.max(cx.abs());
                    max_cy_abs = max_cy_abs.max(cy.abs());
                }

                let zoom_x = 2.0 * max_cx_abs * min_dim / w_f;
                let zoom_y = 2.0 * max_cy_abs * min_dim / h_f;
                let required_zoom = zoom_x.max(zoom_y);

                if required_zoom < best_zoom {
                    best_zoom = required_zoom;
                    best_cos = cos_t;
                    best_sin = sin_t;
                }
            }

            self.zoom = best_zoom * 1.10;
            self.cos_angle = best_cos;
            self.sin_angle = best_sin;
        } else {
            self.zoom = 2.0 * r_bound * 1.10;
        }
    }

    /// Renders the Julia Set in-place over the active background memory buffer.
    pub fn apply_effect_in_memory(&self, rgb_img: &mut RgbImage) {
        let (width, height) = rgb_img.dimensions();
        let w_f = width as f64;
        let h_f = height as f64;

        let specs = ViewportSpecs {
            center: self.preset.center,
            zoom: self.zoom,
            cos_angle: self.cos_angle,
            sin_angle: self.sin_angle,
            is_julia: true,
        };
        let viewport = Viewport::new(w_f, h_f, &specs);

        let scan_iterations = self.scan_iterations;
        let center = self.preset.center;
        let (mut rows, width_usize) = partition_rows(rgb_img);

        let cores = thread::available_parallelism()
            .map(|n| n.get())
            .unwrap_or(4);
        let chunk_size = (rows.len() / cores).max(1);

        let min_dim = w_f.min(h_f);
        let scale = self.zoom / min_dim;

        thread::scope(|scope| {
            let viewport_ref = &viewport;
            let color_palette = self.color_palette.to_array();
            for chunk in rows.chunks_mut(chunk_size) {
                scope.spawn(move || {
                    for (y, row_data) in chunk.iter_mut() {
                        let y_f = *y as f64;
                        for x in 0..width_usize {
                            let x_f = x as f64;
                            let z_init = viewport_ref.map(x_f, y_f);

                            let (i, z, dz) = compute_escape_iterations(
                                ProceduralEffect::JuliaSet,
                                z_init,
                                center,
                                scan_iterations,
                            );

                            let t = calculate_smooth_potential(i, scan_iterations, z);

                            let (fractal_rgb, alpha, s_alpha) = if t > 0.005 && i < scan_iterations
                            {
                                let dist_complex =
                                    calculate_distance_estimator(i, scan_iterations, z, dz);
                                let dist_pixels = (dist_complex / scale) as f32;

                                let thickness = 2.5_f32;
                                let max_radius = thickness * 2.0;
                                let shadow_radius = max_radius * 1.5;

                                if dist_pixels < shadow_radius {
                                    let norm_dist = dist_pixels / max_radius;

                                    let core = if dist_pixels < 1.2 {
                                        1.0 - (dist_pixels / 1.2)
                                    } else {
                                        0.0
                                    };

                                    let ripple_freq = 12.0_f32;
                                    let ripple_wave =
                                        (t * std::f32::consts::PI * ripple_freq).sin().abs();
                                    let nested_detail = (1.0
                                        - smoothstep(0.0, 0.4, 1.0 - ripple_wave))
                                        * (1.0 - norm_dist);

                                    let glow = if dist_pixels < max_radius {
                                        (1.0 - norm_dist * norm_dist).powi(6) * 0.45
                                    } else {
                                        0.0
                                    };

                                    let profile = core * 0.65 + nested_detail * 0.20 + glow * 0.15;

                                    let norm_shadow = dist_pixels / shadow_radius;
                                    let shadow_profile =
                                        (1.0 - norm_shadow * norm_shadow).powi(2) * 0.35;

                                    let angle = z.im.atan2(z.re) as f32;
                                    let light = 0.65_f32 + 0.35_f32 * (angle * 4.0).cos().abs();

                                    let t_cycled = (t * 2.0) % 1.0;
                                    let secondary_color =
                                        [color_palette[1], color_palette[2], color_palette[0]];

                                    let r_grad = if t_cycled < 0.5 {
                                        let factor = t_cycled * 2.0;
                                        color_palette[0] * (1.0 - factor)
                                            + secondary_color[0] * factor
                                    } else {
                                        let factor = (t_cycled - 0.5) * 2.0;
                                        secondary_color[0] * (1.0 - factor)
                                            + color_palette[0] * factor
                                    };
                                    let g_grad = if t_cycled < 0.5 {
                                        let factor = t_cycled * 2.0;
                                        color_palette[1] * (1.0 - factor)
                                            + secondary_color[1] * factor
                                    } else {
                                        let factor = (t_cycled - 0.5) * 2.0;
                                        secondary_color[1] * (1.0 - factor)
                                            + color_palette[1] * factor
                                    };
                                    let b_grad = if t_cycled < 0.5 {
                                        let factor = t_cycled * 2.0;
                                        color_palette[2] * (1.0 - factor)
                                            + secondary_color[2] * factor
                                    } else {
                                        let factor = (t_cycled - 0.5) * 2.0;
                                        secondary_color[2] * (1.0 - factor)
                                            + color_palette[2] * factor
                                    };

                                    let core_color = [r_grad, g_grad, b_grad];

                                    let mut border_color =
                                        [1.0 - r_grad, 1.0 - g_grad, 1.0 - b_grad];
                                    let max_val =
                                        border_color[0].max(border_color[1]).max(border_color[2]);
                                    if max_val > 0.0 {
                                        border_color[0] /= max_val;
                                        border_color[1] /= max_val;
                                        border_color[2] /= max_val;
                                    }

                                    let color_blend = norm_dist.powi(2);

                                    let r_blended = core_color[0] * (1.0 - color_blend)
                                        + border_color[0] * color_blend;
                                    let g_blended = core_color[1] * (1.0 - color_blend)
                                        + border_color[1] * color_blend;
                                    let b_blended = core_color[2] * (1.0 - color_blend)
                                        + border_color[2] * color_blend;

                                    let brightness_boost = 1.20_f32;

                                    let rgb = [
                                        (r_blended * light * brightness_boost).clamp(0.0, 1.0),
                                        (g_blended * light * brightness_boost).clamp(0.0, 1.0),
                                        (b_blended * light * brightness_boost).clamp(0.0, 1.0),
                                    ];

                                    let iteration_fade =
                                        if i < 16 { (i as f32 - 3.0) / 13.0 } else { 1.0 };

                                    (
                                        rgb,
                                        profile * 0.95 * iteration_fade,
                                        shadow_profile * iteration_fade,
                                    )
                                } else {
                                    ([0.0, 0.0, 0.0], 0.0, 0.0)
                                }
                            } else {
                                ([0.0, 0.0, 0.0], 0.0, 0.0)
                            };

                            let idx = x * 3;
                            blend_and_vignette_pixel(row_data, idx, fractal_rgb, alpha, s_alpha);
                        }
                    }
                });
            }
        });
    }

    /// Helper to process, render, and write output files directly to system storage.
    pub fn apply_effect<P: AsRef<Path>>(
        &self,
        input_path: P,
        output_path: P,
    ) -> WallSwitchResult<()> {
        let img = image::open(&input_path)
            .map_err(|e| WallSwitchError::UnableToFind(format!("Failed to open image: {e}")))?;

        let mut rgb_img = img.to_rgb8();
        self.apply_effect_in_memory(&mut rgb_img);

        rgb_img
            .save(&output_path)
            .map_err(|e| WallSwitchError::Io(Error::other(e)))?;

        Ok(())
    }
}