* fix(viewer): tune shadow biases to stop acne without detaching shadows normalBias 0.02 was too small a texel offset for the building-fit 1024 shadow map and brought back self-shadowing acne. Settle on normalBias 0.08 (0.07 and below acnes, 0.1 reads detached) plus depth bias -0.0005 to suppress the residual acne that a normal bias alone couldn't clear. Also adds a `?debug=shadowcamera` diagnostic that draws a CameraHelper for each shadow camera so the fitted frustum can be inspected while tuning. Co-Authored-By: Claude Fable 5 <noreply@anthropic.com> * feat(editor): polygon editor handle UX — focus, cursors, visibility - vertex/midpoint cylinders ignore scene depth like the edge arrows so they stay visible through walls and slabs; vertex radius 0.1 -> 0.08, midpoint 0.06 -> 0.05, midpoints use the brighter arrow shade at rest - during any drag only the active handle stays mounted (other arrows, vertices, edge bars and the cross disappear) so the gesture reads clearly - handles set pointer cursors: move for vertices/midpoints/cross, and a screen-space direction-aware resize cursor for the edge arrows Co-Authored-By: Claude Fable 5 <noreply@anthropic.com> * fix(editor): keep ceiling affordances quiet during any interaction The ceiling corner brackets' hit boxes caught drag-time hover (spatial events keep firing during host drags by design), set hoveredId to the ceiling and flashed the ceiling grid mid-gesture — e.g. while dragging a slab polygon vertex. Unmount the brackets while ANY interaction scope is active, and gate CeilingSystem's hover-driven grid reveal on idle scope + no inputDragging as a second layer. Co-Authored-By: Claude Fable 5 <noreply@anthropic.com> * fix(core): stop room detection resurrecting deleted slabs on load Two holes in the wall-driven auto slab sync: - initSpaceDetectionSync started with an empty baseline, so scene hydration (one atomic setScene) read as 'every wall changed' and ran a full detection pass on every load, recreating auto slabs the user had deleted. Seed the baseline from the store at init and treat a level's first snapshot as baseline — detection now only reacts to in-session wall edits. - matchesManualFootprint required mutual coverage, so a single manual slab spanning multiple rooms never suppressed those rooms' auto slabs (only a fraction of it lies inside each room). Suppression now only asks whether the ROOM is substantially covered by the union of manual slabs. Co-Authored-By: Claude Fable 5 <noreply@anthropic.com> --------- Co-authored-by: Claude Fable 5 <noreply@anthropic.com>
Pascal Editor
A 3D building editor built with React Three Fiber and WebGPU.
https://github.com/user-attachments/assets/8b50e7cf-cebe-4579-9cf3-8786b35f7b6b
Repository Architecture
This is a Turborepo monorepo with three main packages:
editor/
├── apps/
│ └── editor/ # Next.js application
├── packages/
│ ├── core/ # Schema definitions, state management, systems
│ ├── viewer/ # 3D rendering components
│ └── ui/ # Shared UI components
Separation of Concerns
| Package | Responsibility |
|---|---|
| @pascal-app/core | Node schemas, scene state (Zustand), systems (geometry generation), spatial queries, event bus |
| @pascal-app/viewer | 3D rendering via React Three Fiber, default camera/controls, post-processing |
| apps/editor | UI components, tools, custom behaviors, editor-specific systems |
The viewer renders the scene with sensible defaults. The editor extends it with interactive tools, selection management, and editing capabilities.
Stores
Each package has its own Zustand store for managing state:
| Store | Package | Responsibility |
|---|---|---|
useScene |
@pascal-app/core |
Scene data: nodes, root IDs, dirty nodes, CRUD operations. Persisted to IndexedDB with undo/redo via Zundo. |
useViewer |
@pascal-app/viewer |
Viewer state: current selection (building/level/zone IDs), level display mode (stacked/exploded/solo), camera mode. |
useEditor |
apps/editor |
Editor state: active tool, structure layer visibility, panel states, editor-specific preferences. |
Access patterns:
// Subscribe to state changes (React component)
const nodes = useScene((state) => state.nodes)
const levelId = useViewer((state) => state.selection.levelId)
const activeTool = useEditor((state) => state.tool)
// Access state outside React (callbacks, systems)
const node = useScene.getState().nodes[id]
useViewer.getState().setSelection({ levelId: 'level_123' })
Core Concepts
Nodes
Nodes are the data primitives that describe the 3D scene. All nodes extend BaseNode:
BaseNode {
id: string // Auto-generated with type prefix (e.g., "wall_abc123")
type: string // Discriminator for type-safe handling
parentId: string | null // Parent node reference
visible: boolean
camera?: Camera // Optional saved camera position
metadata?: JSON // Arbitrary metadata (e.g., { isTransient: true })
}
Node Hierarchy:
Site
└── Building
└── Level
├── Wall → Item (doors, windows)
├── Slab
├── Ceiling → Item (lights)
├── Roof
├── Zone
├── Scan (3D reference)
└── Guide (2D reference)
Nodes are stored in a flat dictionary (Record<id, Node>), not a nested tree. Parent-child relationships are defined via parentId and children arrays.
Scene State (Zustand Store)
The scene is managed by a Zustand store in @pascal-app/core:
useScene.getState() = {
nodes: Record<id, AnyNode>, // All nodes
rootNodeIds: string[], // Top-level nodes (sites)
dirtyNodes: Set<string>, // Nodes pending system updates
createNode(node, parentId),
updateNode(id, updates),
deleteNode(id),
}
Middleware:
- Persist - Saves to IndexedDB (excludes transient nodes)
- Temporal (Zundo) - Undo/redo with 50-step history
Scene Registry
The registry maps node IDs to their Three.js objects for fast lookup:
sceneRegistry = {
nodes: Map<id, Object3D>, // ID → 3D object
byType: {
wall: Set<id>,
item: Set<id>,
zone: Set<id>,
// ...
}
}
Renderers register their refs using the useRegistry hook:
const ref = useRef<Mesh>(null!)
useRegistry(node.id, 'wall', ref)
This allows systems to access 3D objects directly without traversing the scene graph.
Node Renderers
Renderers are React components that create Three.js objects for each node type:
SceneRenderer
└── NodeRenderer (dispatches by type)
├── BuildingRenderer
├── LevelRenderer
├── WallRenderer
├── SlabRenderer
├── ZoneRenderer
├── ItemRenderer
└── ...
Pattern:
- Renderer creates a placeholder mesh/group
- Registers it with
useRegistry - Systems update geometry based on node data
Example (simplified):
const WallRenderer = ({ node }) => {
const ref = useRef<Mesh>(null!)
useRegistry(node.id, 'wall', ref)
return (
<mesh ref={ref}>
<boxGeometry args={[0, 0, 0]} /> {/* Replaced by WallSystem */}
<meshStandardMaterial />
{node.children.map(id => <NodeRenderer key={id} nodeId={id} />)}
</mesh>
)
}
Systems
Systems are React components that run in the render loop (useFrame) to update geometry and transforms. They process dirty nodes marked by the store.
Core Systems (in @pascal-app/core):
| System | Responsibility |
|---|---|
WallSystem |
Generates wall geometry with mitering and CSG cutouts for doors/windows |
SlabSystem |
Generates floor geometry from polygons |
CeilingSystem |
Generates ceiling geometry |
RoofSystem |
Generates roof geometry |
ItemSystem |
Positions items on walls, ceilings, or floors (slab elevation) |
Viewer Systems (in @pascal-app/viewer):
| System | Responsibility |
|---|---|
LevelSystem |
Handles level visibility and vertical positioning (stacked/exploded/solo modes) |
ScanSystem |
Controls 3D scan visibility |
GuideSystem |
Controls guide image visibility |
Processing Pattern:
useFrame(() => {
for (const id of dirtyNodes) {
const obj = sceneRegistry.nodes.get(id)
const node = useScene.getState().nodes[id]
// Update geometry, transforms, etc.
updateGeometry(obj, node)
dirtyNodes.delete(id)
}
})
Dirty Nodes
When a node changes, it's marked as dirty in useScene.getState().dirtyNodes. Systems check this set each frame and only recompute geometry for dirty nodes.
// Automatic: createNode, updateNode, deleteNode mark nodes dirty
useScene.getState().updateNode(wallId, { thickness: 0.2 })
// → wallId added to dirtyNodes
// → WallSystem regenerates geometry next frame
// → wallId removed from dirtyNodes
Manual marking:
useScene.getState().dirtyNodes.add(wallId)
Event Bus
Inter-component communication uses a typed event emitter (mitt):
// Node events
emitter.on('wall:click', (event) => { ... })
emitter.on('item:enter', (event) => { ... })
emitter.on('zone:context-menu', (event) => { ... })
// Grid events (background)
emitter.on('grid:click', (event) => { ... })
// Event payload
NodeEvent {
node: AnyNode
position: [x, y, z]
localPosition: [x, y, z]
normal?: [x, y, z]
stopPropagation: () => void
}
Spatial Grid Manager
Handles collision detection and placement validation:
spatialGridManager.canPlaceOnFloor(levelId, position, dimensions, rotation)
spatialGridManager.canPlaceOnWall(wallId, t, height, dimensions)
spatialGridManager.getSlabElevationAt(levelId, x, z)
Used by item placement tools to validate positions and calculate slab elevations.
Editor Architecture
The editor extends the viewer with:
Tools
Tools are activated via the toolbar and handle user input for specific operations:
- SelectTool - Selection and manipulation
- WallTool - Draw walls
- ZoneTool - Create zones
- ItemTool - Place furniture/fixtures
- SlabTool - Create floor slabs
Selection Manager
The editor uses a custom selection manager with hierarchical navigation:
Site → Building → Level → Zone → Items
Each depth level has its own selection strategy for hover/click behavior.
Editor-Specific Systems
ZoneSystem- Controls zone visibility based on level mode- Custom camera controls with node focusing
Data Flow
User Action (click, drag)
↓
Tool Handler
↓
useScene.createNode() / updateNode()
↓
Node added/updated in store
Node marked dirty
↓
React re-renders NodeRenderer
useRegistry() registers 3D object
↓
System detects dirty node (useFrame)
Updates geometry via sceneRegistry
Clears dirty flag
Building a Plugin
The editor is extensible: a plugin ships node kinds (schema, 3D/2D rendering, placement tools, inspector parametrics) and left-rail panels through the same Plugin manifest the built-ins use — there is no separate internal API.
- Developer guide — Create a plugin: the
Pluginshape, panel contributions, discovery, lifecycle, and what's in/out of v1. - Worked example —
pascalorg/plugin-trees: a standalone plugin with procedural trees, flowers, grass, and a presets panel. Clone it as a starting point.
Technology Stack
- React 19 + Next.js 16
- Three.js (WebGPU renderer)
- React Three Fiber + Drei
- Zustand (state management)
- Zod (schema validation)
- Zundo (undo/redo)
- three-bvh-csg (Boolean geometry operations)
- Turborepo (monorepo management)
- Bun (package manager)
Getting Started
Development
Run the development server from the root directory to enable hot reload for all packages:
# Install dependencies
bun install
# Run development server (builds packages + starts editor with watch mode)
bun dev
# This will:
# 1. Build @pascal-app/core and @pascal-app/viewer
# 2. Start watching both packages for changes
# 3. Start the Next.js editor dev server
# Open http://localhost:3000
Important: Always run bun dev from the root directory to ensure the package watchers are running. This enables hot reload when you edit files in packages/core/src/ or packages/viewer/src/.
Building for Production
# Build all packages
turbo build
# Build specific package
turbo build --filter=@pascal-app/core
Publishing Packages
# Build packages
turbo build --filter=@pascal-app/core --filter=@pascal-app/viewer
# Publish to npm
npm publish --workspace=@pascal-app/core --access public
npm publish --workspace=@pascal-app/viewer --access public
Key Files
| Path | Description |
|---|---|
packages/core/src/schema/ |
Node type definitions (Zod schemas) |
packages/core/src/store/use-scene.ts |
Scene state store |
packages/core/src/hooks/scene-registry/ |
3D object registry |
packages/core/src/systems/ |
Geometry generation systems |
packages/viewer/src/components/renderers/ |
Node renderers |
packages/viewer/src/components/viewer/ |
Main Viewer component |
apps/editor/components/tools/ |
Editor tools |
apps/editor/store/ |
Editor-specific state |