2026-05-25 21:02:10 -04:00
2 changed files with 286 additions and 11 deletions
@@ -0,0 +1,124 @@
 # WGPU/egui Interactive App Architecture Spike
 > Goal: introduce an interactive OpenVistaPro app without destabilizing the existing CLI, importer pipeline, or deterministic CPU reference renderer.
 ## Decision
 Keep the repository as a single Rust crate for now.
 The current boundary set is still moving, but it is already useful:
 - `src/terrain.rs`, `src/terrain_gen.rs`, `src/import.rs`, `src/scene.rs`, `src/scene_file.rs`, `src/script.rs`, `src/script_exec.rs`, `src/path.rs`, `src/render.rs`, and `src/colormap.rs` are the clean-room core.
 - `src/cli.rs` and `src/main.rs` are the command-line adapter.
 - `src/app_state.rs`, `src/ui_shell.rs`, `src/app.rs`, and `src/bin/openvistapro_app.rs` are the optional interactive shell.
 A workspace split into `openvistapro-core`, `openvistapro-cli`, and `openvistapro-app` would add maintenance overhead before there is a second renderer/backend boundary that truly justifies it. The better near-term move is to keep a monolith and enforce boundaries with modules, feature flags, and tests.
 Revisit a workspace split only when at least one of these becomes true:
 1. the GPU renderer needs materially different dependencies from the CLI/reference renderer,
 2. the core API stabilizes enough that the app shell can depend on it as a published internal crate boundary, or
 3. build times / dependency fanout make the single-crate layout painful.
 ## Integration recommendation
 Use egui as the interactive shell now, and treat WGPU as the rendering backend that arrives later behind a narrow viewport abstraction.
 Recommended path:
 1. Keep `eframe` for the windowing / egui host while the shell is still mostly controls and state.
 2. Keep the current CPU renderer as the canonical reference output for tests and CLI smoke runs.
 3. Introduce a tiny viewport trait or adapter boundary before any full GPU renderer lands.
 4. Add a WGPU-backed viewport only once the render pipeline actually needs GPU surfaces, textures, and custom passes.
 Why this order:
 - `eframe` already gives a working egui host with the least glue.
 - CLI builds stay GPU-free because the app stays behind the `app` feature.
 - The CPU renderer remains the reference implementation for determinism and testability.
 - WGPU can then become an implementation detail of the viewport, not a rewrite of the app state model.
 ## Module boundaries
 Keep the following responsibilities separate:
 ### Core domain
 - `terrain.rs`: immutable height grid and sampling rules.
 - `terrain_gen.rs`: deterministic procedural generation inputs and output grid creation.
 - `import.rs`: import boundary and source metadata.
 - `scene.rs`: camera, lighting, hydrology, and palette-linked scene state.
 - `scene_file.rs`: `.ovp.toml` persistence.
 - `script.rs` / `script_exec.rs`: project-owned script language and executor.
 - `path.rs`: MakePath-style camera path generation.
 - `render.rs`: deterministic CPU render outputs.
 - `colormap.rs`: palette / band mapping.
 ### CLI adapter
 - `cli.rs` should stay focused on argument parsing and orchestration.
 - Keep it thin enough that the same core operations can be called from future automation or from the app shell.
 ### Interactive shell state
 - `app_state.rs` should remain pure state plus reducers / actions.
 - `ui_shell.rs` should own section ordering, labels, and placeholder metadata.
 - Avoid leaking egui types into either file.
 ### egui view/controller
 - `app.rs` should remain the presentation layer that turns `AppData` into panels, menus, and a preview texture.
 - The shell should consume state snapshots and call backend actions, not embed render or import logic inline.
 ### Future GPU viewport
 - Introduce a narrow backend boundary for viewport rendering before the first custom WGPU renderer lands.
 - Keep surface creation, texture upload, and draw passes out of `AppData`.
 - Prefer a dedicated GPU adapter module over scattering WGPU setup across the UI code.
 ## Minimal first app shell
 The smallest durable shell is:
 - a stable top command bar,
 - a left or right dock for section-specific controls,
 - a central viewport that can show the CPU preview now and a GPU surface later,
 - a status bar for file paths, script status, and render feedback,
 - a tiny about/help dialog for orientation.
 That is already enough to validate layout, interaction, and state management without pretending the GPU renderer exists yet.
 ## Testing strategy
 Keep the test surface split the same way as the code.
 ### Unit tests
 - `AppData` reducers and state transitions.
 - `UiShellState` navigation order and section metadata.
 - render-mode selection and preview-state plumbing.
 - scene / script / path / importer behavior.
 ### Smoke commands
 Use existing CLI and app entry points as smoke tests for the architecture:
 - `cargo run -- info`
 - `cargo run -- render --preset fractal --seed 1337 --width 64 --height 64 --output /tmp/openvistapro-fractal.png`
 - `cargo run --features app --bin openvistapro_app` when a display is available
 ### Later integration tests
 Once the GPU viewport exists, add lightweight screenshot or frame-smoke coverage around the viewport adapter rather than baking WGPU assumptions into the core state model.
 ## Next tasks
 1. Add a small viewport abstraction so the egui shell can switch between CPU preview and a future GPU backend without changing `AppData`.
 2. Keep the CPU renderer as the reference implementation for deterministic validation.
 3. Add a dedicated GPU adapter module only when the WGPU surface truly exists.
 4. Revisit a workspace split after the GPU path forces a second hard boundary.
 5. Keep `docs/knowledgebase/architecture-notes.md` and `docs/knowledgebase/ui-panel-map.md` aligned with any later shell or viewport changes.
 ## Recommendation summary
 Stay monolithic now, keep egui as the host shell, and treat WGPU as a future viewport backend rather than the reason to split the crate today. That gives OpenVistaPro the fastest path to a usable interactive app while protecting the CLI and deterministic renderer from churn.
@@ -1,29 +1,104 @@
 use crate::terrain::{HeightGrid, TerrainError};
-const OCTAVE_COUNT: usize = 4;
+const DEFAULT_OCTAVE_COUNT: usize = 4;
-const BASE_FREQUENCY: f32 = 2.0;
+const DEFAULT_BASE_FREQUENCY: f32 = 2.0;
-const LACUNARITY: f32 = 2.0;
+const DEFAULT_LACUNARITY: f32 = 2.0;
-const GAIN: f32 = 0.5;
+const DEFAULT_GAIN: f32 = 0.5;
 const LATTICE_SEED_STEP: u64 = 0x9E37_79B9_7F4A_7C15;
 const LATTICE_X_MUL: u64 = 0x9E37_79B9_7F4A_7C15;
 const LATTICE_Y_MUL: u64 = 0xC2B2_AE3D_27D4_EB4F;
 const FINALIZER_MUL1: u64 = 0xBF58_476D_1CE4_E5B9;
 const FINALIZER_MUL2: u64 = 0x94D0_49BB_1331_11EB;
 fn sanitize_positive(value: f32, fallback: f32) -> f32 {
    if value.is_finite() && value > 0.0 {
        value
    } else {
        fallback
    }
 }
 fn sanitize_gain(value: f32) -> f32 {
    if value.is_finite() {
        value.clamp(0.0, 1.0)
    } else {
        DEFAULT_GAIN
    }
 }
 /// Tunable fractal-noise controls for procedural terrain generation.
 #[derive(Debug, Clone, Copy, PartialEq)]
 pub struct TerrainGenerationSettings {
    octave_count: usize,
    base_frequency: f32,
    lacunarity: f32,
    gain: f32,
 }
 impl TerrainGenerationSettings {
    /// Build a settings bundle, normalizing obviously invalid inputs.
    pub fn new(octave_count: usize, base_frequency: f32, lacunarity: f32, gain: f32) -> Self {
        Self {
            octave_count: octave_count.max(1),
            base_frequency: sanitize_positive(base_frequency, DEFAULT_BASE_FREQUENCY),
            lacunarity: sanitize_positive(lacunarity, DEFAULT_LACUNARITY),
            gain: sanitize_gain(gain),
        }
    }
    pub fn octave_count(&self) -> usize {
        self.octave_count
    }
    pub fn base_frequency(&self) -> f32 {
        self.base_frequency
    }
    pub fn lacunarity(&self) -> f32 {
        self.lacunarity
    }
    pub fn gain(&self) -> f32 {
        self.gain
    }
 }
 impl Default for TerrainGenerationSettings {
    fn default() -> Self {
        Self::new(
            DEFAULT_OCTAVE_COUNT,
            DEFAULT_BASE_FREQUENCY,
            DEFAULT_LACUNARITY,
            DEFAULT_GAIN,
        )
    }
 }
 /// Describes a terrain generation request.
 ///
 /// Specs are immutable once constructed; identical specs always yield
 /// identical [`HeightGrid`]s from a given [`TerrainGenerator`].
-#[derive(Debug, Clone, Copy, PartialEq, Eq)]
+#[derive(Debug, Clone, Copy, PartialEq)]
 pub struct TerrainGenerationSpec {
    seed: u64,
    width: u32,
    height: u32,
    settings: TerrainGenerationSettings,
 }
 impl TerrainGenerationSpec {
    /// Creates a spec, rejecting zero-sized grids with [`TerrainError::ZeroDimension`].
    pub fn new(seed: u64, width: u32, height: u32) -> Result<Self, TerrainError> {
        Self::with_settings(seed, width, height, TerrainGenerationSettings::default())
    }
    /// Creates a spec with explicit fractal settings.
    pub fn with_settings(
        seed: u64,
        width: u32,
        height: u32,
        settings: TerrainGenerationSettings,
    ) -> Result<Self, TerrainError> {
        if width == 0 || height == 0 {
            return Err(TerrainError::ZeroDimension);
        }
@@ -31,9 +106,28 @@ impl TerrainGenerationSpec {
            seed,
            width,
            height,
            settings,
        })
    }
    /// Convenience constructor for callers that want to override the default settings inline.
    pub fn with_parameters(
        seed: u64,
        width: u32,
        height: u32,
        octave_count: usize,
        base_frequency: f32,
        lacunarity: f32,
        gain: f32,
    ) -> Result<Self, TerrainError> {
        Self::with_settings(
            seed,
            width,
            height,
            TerrainGenerationSettings::new(octave_count, base_frequency, lacunarity, gain),
        )
    }
    pub fn seed(&self) -> u64 {
        self.seed
    }
@@ -45,6 +139,10 @@ impl TerrainGenerationSpec {
    pub fn height(&self) -> u32 {
        self.height
    }
    pub fn settings(&self) -> TerrainGenerationSettings {
        self.settings
    }
 }
 /// Produces a [`HeightGrid`] from a [`TerrainGenerationSpec`].
@@ -116,18 +214,18 @@ fn value_noise(seed: u64, x: f32, y: f32) -> f32 {
 }
 #[inline]
-fn fbm_height(seed: u64, x: f32, y: f32) -> f32 {
+fn fbm_height(seed: u64, x: f32, y: f32, settings: TerrainGenerationSettings) -> f32 {
    let mut total = 0.0;
    let mut amplitude = 1.0;
-    let mut frequency = BASE_FREQUENCY;
+    let mut frequency = settings.base_frequency();
    let mut amplitude_sum = 0.0;
-    for octave in 0..OCTAVE_COUNT {
+    for octave in 0..settings.octave_count() {
        let octave_seed = seed.wrapping_add((octave as u64).wrapping_mul(LATTICE_SEED_STEP));
        total += amplitude * value_noise(octave_seed, x * frequency, y * frequency);
        amplitude_sum += amplitude;
-        amplitude *= GAIN;
+        amplitude *= settings.gain();
-        frequency *= LACUNARITY;
+        frequency *= settings.lacunarity();
    }
    total / amplitude_sum
@@ -142,7 +240,7 @@ impl TerrainGenerator for DeterministicTerrainGenerator {
            let ny = normalized_coord(y, height);
            for x in 0..width {
                let nx = normalized_coord(x, width);
-                samples.push(fbm_height(spec.seed(), nx, ny));
+                samples.push(fbm_height(spec.seed(), nx, ny, spec.settings()));
            }
        }
        HeightGrid::new(width, height, samples)
@@ -165,6 +263,28 @@ mod tests {
        );
    }
    #[test]
    fn settings_normalize_invalid_inputs() {
        let settings = TerrainGenerationSettings::new(0, -1.0, 0.0, 2.0);
        assert_eq!(settings.octave_count(), 1);
        assert_eq!(settings.base_frequency(), DEFAULT_BASE_FREQUENCY);
        assert_eq!(settings.lacunarity(), DEFAULT_LACUNARITY);
        assert_eq!(settings.gain(), 1.0);
    }
    #[test]
    fn with_parameters_exposes_custom_settings() {
        let spec = TerrainGenerationSpec::with_parameters(7, 8, 6, 2, 1.5, 3.0, 0.25).unwrap();
        let settings = spec.settings();
        assert_eq!(spec.seed(), 7);
        assert_eq!(spec.width(), 8);
        assert_eq!(spec.height(), 6);
        assert_eq!(settings.octave_count(), 2);
        assert_eq!(settings.base_frequency(), 1.5);
        assert_eq!(settings.lacunarity(), 3.0);
        assert_eq!(settings.gain(), 0.25);
    }
    #[test]
    fn generate_matches_spec_dimensions() {
        let spec = TerrainGenerationSpec::new(99, 8, 5).unwrap();
@@ -185,4 +305,35 @@ mod tests {
            .unwrap();
        assert_ne!(a.sample(0, 0), b.sample(0, 0));
    }
    #[test]
    fn generate_is_bounded_and_deterministic_for_exact_samples() {
        let spec = TerrainGenerationSpec::new(1337, 4, 4).unwrap();
        let generator = DeterministicTerrainGenerator::new();
        let first = generator.generate(&spec).unwrap();
        let second = generator.generate(&spec).unwrap();
        let expected = [
            [0.706_783_f32, 0.390_681, 0.571_295, 0.454_375],
            [0.667_478, 0.549_327, 0.476_506, 0.335_594],
            [0.603_516, 0.451_503, 0.516_397, 0.357_081],
            [0.308_838, 0.295_558, 0.570_510, 0.666_683],
        ];
        for y in 0..4 {
            for x in 0..4 {
                let sample = first.sample(x, y).unwrap();
                assert!((0.0..=1.0).contains(&sample));
                assert_eq!(sample, second.sample(x, y).unwrap());
                assert!(
                    (sample - expected[y as usize][x as usize]).abs() < 1e-6,
                    "mismatch at ({x}, {y})"
                );
            }
        }
        let (min, max) = first.min_max().unwrap();
        assert!(min >= 0.0);
        assert!(max <= 1.0);
    }
 }