"use client"; import { useCallback, useEffect, useLayoutEffect, useMemo, useRef, useState, type MouseEvent as ReactMouseEvent, } from "react"; import { useTheme } from "next-themes"; import { ReactFlow, ReactFlowProvider, Background, Controls, MiniMap, applyNodeChanges, applyEdgeChanges, useReactFlow, type Node as RFNode, type Edge as RFEdge, type NodeChange, type EdgeChange, type Connection, type OnConnectEnd, BackgroundVariant, } from "@xyflow/react"; import { cn } from "@/lib/utils"; import "@xyflow/react/dist/style.css"; import { toast } from "@/lib/toast"; import { msg } from "@/lib/toast-messages"; import { enqueueCanvasOp, readCanvasSnapshot, resolveCanvasOp, writeCanvasSnapshot, } from "@/lib/canvas-local-persistence"; import { useConvexAuth, useMutation, useQuery } from "convex/react"; import { api } from "@/convex/_generated/api"; import type { Doc, Id } from "@/convex/_generated/dataModel"; import { authClient } from "@/lib/auth-client"; import { nodeTypes } from "./node-types"; import { convexNodeDocWithMergedStorageUrl, convexNodeToRF, convexEdgeToRF, convexEdgeToRFWithSourceGlow, NODE_DEFAULTS, NODE_HANDLE_MAP, } from "@/lib/canvas-utils"; import CanvasToolbar, { type CanvasNavTool, } from "@/components/canvas/canvas-toolbar"; import { CanvasAppMenu } from "@/components/canvas/canvas-app-menu"; import { CanvasCommandPalette } from "@/components/canvas/canvas-command-palette"; import { CanvasConnectionDropMenu, type ConnectionDropMenuState, } from "@/components/canvas/canvas-connection-drop-menu"; import { CanvasPlacementProvider } from "@/components/canvas/canvas-placement-context"; import { AssetBrowserTargetContext, type AssetBrowserTargetApi, } from "@/components/canvas/asset-browser-panel"; import CustomConnectionLine from "@/components/canvas/custom-connection-line"; import type { CanvasNodeTemplate } from "@/lib/canvas-node-templates"; import { applyPinnedNodePositions, applyPinnedNodePositionsReadOnly, CANVAS_MIN_ZOOM, clientRequestIdFromOptimisticEdgeId, clientRequestIdFromOptimisticNodeId, createCanvasOpId, DEFAULT_EDGE_OPTIONS, EDGE_INTERSECTION_HIGHLIGHT_STYLE, getConnectEndClientPoint, getMiniMapNodeColor, getMiniMapNodeStrokeColor, getNodeCenterClientPosition, getIntersectedEdgeId, getPendingMovePinsFromLocalOps, hasHandleKey, inferPendingConnectionNodeHandoff, isEditableKeyboardTarget, isOptimisticEdgeId, isOptimisticNodeId, mergeNodesPreservingLocalState, normalizeHandle, OPTIMISTIC_EDGE_PREFIX, OPTIMISTIC_NODE_PREFIX, positionsMatchPin, type PendingEdgeSplit, rfEdgeConnectionSignature, withResolvedCompareData, } from "./canvas-helpers"; import { adjustNodeDimensionChanges } from "./canvas-node-change-helpers"; import { useGenerationFailureWarnings } from "./canvas-generation-failures"; import { useCanvasDeleteHandlers } from "./canvas-delete-handlers"; import { getImageDimensions } from "./canvas-media-utils"; import { useCanvasReconnectHandlers } from "./canvas-reconnect"; import { useCanvasScissors } from "./canvas-scissors"; interface CanvasInnerProps { canvasId: Id<"canvases">; } function CanvasInner({ canvasId }: CanvasInnerProps) { const { screenToFlowPosition } = useReactFlow(); const { resolvedTheme } = useTheme(); const { data: session, isPending: isSessionPending } = authClient.useSession(); const { isLoading: isAuthLoading, isAuthenticated } = useConvexAuth(); const shouldSkipCanvasQueries = isSessionPending || isAuthLoading || !isAuthenticated; const convexAuthUserProbe = useQuery( api.auth.safeGetAuthUser, shouldSkipCanvasQueries ? "skip" : {}, ); useEffect(() => { if (process.env.NODE_ENV === "production") return; if (!isAuthLoading && !isAuthenticated) { console.warn("[Canvas debug] mounted without Convex auth", { canvasId }); } }, [canvasId, isAuthLoading, isAuthenticated]); useEffect(() => { if (process.env.NODE_ENV === "production") return; if (isAuthLoading || isSessionPending) return; console.info("[Canvas auth state]", { canvasId, convex: { isAuthenticated, shouldSkipCanvasQueries, probeUserId: convexAuthUserProbe?.userId ?? null, probeRecordId: convexAuthUserProbe?._id ?? null, }, session: { hasUser: Boolean(session?.user), email: session?.user?.email ?? null, }, }); }, [ canvasId, convexAuthUserProbe?._id, convexAuthUserProbe?.userId, isAuthLoading, isAuthenticated, isSessionPending, session?.user, shouldSkipCanvasQueries, ]); // ─── Convex Realtime Queries ─────────────────────────────────── const convexNodes = useQuery( api.nodes.list, shouldSkipCanvasQueries ? "skip" : { canvasId }, ); const convexEdges = useQuery( api.edges.list, shouldSkipCanvasQueries ? "skip" : { canvasId }, ); const storageUrlsById = useQuery( api.storage.batchGetUrlsForCanvas, shouldSkipCanvasQueries ? "skip" : { canvasId }, ); const canvas = useQuery( api.canvases.get, shouldSkipCanvasQueries ? "skip" : { canvasId }, ); // ─── Convex Mutations (exakte Signaturen aus nodes.ts / edges.ts) ── const moveNode = useMutation(api.nodes.move); const resizeNode = useMutation(api.nodes.resize); const generateUploadUrl = useMutation(api.storage.generateUploadUrl); const batchMoveNodes = useMutation(api.nodes.batchMove); const pendingMoveAfterCreateRef = useRef( new Map(), ); const resolvedRealIdByClientRequestRef = useRef(new Map>()); const pendingEdgeSplitByClientRequestRef = useRef( new Map(), ); /** Connection-Drop → neue Node: erlaubt Carry-over der Kante in der Rollback-Lücke (ohne Phantom nach Fehler). */ const pendingConnectionCreatesRef = useRef(new Set()); /** Nach create+drag: Convex liefert oft noch Erstellkoordinaten, bis `moveNode` committed — bis dahin Position pinnen. */ const pendingLocalPositionUntilConvexMatchesRef = useRef( new Map(), ); /** Vorheriger Stand von api.nodes.list-IDs — um genau die neu eingetretene Node-ID vor Mutation-.then zu erkennen. */ const convexNodeIdsSnapshotForEdgeCarryRef = useRef(new Set()); const createNode = useMutation(api.nodes.create).withOptimisticUpdate( (localStore, args) => { const current = localStore.getQuery(api.nodes.list, { canvasId: args.canvasId, }); if (current === undefined) return; const tempId = ( args.clientRequestId ? `${OPTIMISTIC_NODE_PREFIX}${args.clientRequestId}` : `${OPTIMISTIC_NODE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` ) as Id<"nodes">; const synthetic: Doc<"nodes"> = { _id: tempId, _creationTime: Date.now(), canvasId: args.canvasId, type: args.type as Doc<"nodes">["type"], positionX: args.positionX, positionY: args.positionY, width: args.width, height: args.height, status: "idle", retryCount: 0, data: args.data, parentId: args.parentId, zIndex: args.zIndex, }; localStore.setQuery( api.nodes.list, { canvasId: args.canvasId }, [...current, synthetic], ); }, ); const createNodeWithEdgeFromSource = useMutation( api.nodes.createWithEdgeFromSource, ).withOptimisticUpdate((localStore, args) => { const nodeList = localStore.getQuery(api.nodes.list, { canvasId: args.canvasId, }); const edgeList = localStore.getQuery(api.edges.list, { canvasId: args.canvasId, }); if (nodeList === undefined || edgeList === undefined) return; const tempNodeId = ( args.clientRequestId ? `${OPTIMISTIC_NODE_PREFIX}${args.clientRequestId}` : `${OPTIMISTIC_NODE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` ) as Id<"nodes">; const tempEdgeId = ( args.clientRequestId ? `${OPTIMISTIC_EDGE_PREFIX}${args.clientRequestId}` : `${OPTIMISTIC_EDGE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` ) as Id<"edges">; const syntheticNode: Doc<"nodes"> = { _id: tempNodeId, _creationTime: Date.now(), canvasId: args.canvasId, type: args.type as Doc<"nodes">["type"], positionX: args.positionX, positionY: args.positionY, width: args.width, height: args.height, status: "idle", retryCount: 0, data: args.data, parentId: args.parentId, zIndex: args.zIndex, }; const syntheticEdge: Doc<"edges"> = { _id: tempEdgeId, _creationTime: Date.now(), canvasId: args.canvasId, sourceNodeId: args.sourceNodeId, targetNodeId: tempNodeId, sourceHandle: args.sourceHandle, targetHandle: args.targetHandle, }; localStore.setQuery(api.nodes.list, { canvasId: args.canvasId }, [ ...nodeList, syntheticNode, ]); localStore.setQuery(api.edges.list, { canvasId: args.canvasId }, [ ...edgeList, syntheticEdge, ]); }); const createNodeWithEdgeToTarget = useMutation( api.nodes.createWithEdgeToTarget, ).withOptimisticUpdate((localStore, args) => { const nodeList = localStore.getQuery(api.nodes.list, { canvasId: args.canvasId, }); const edgeList = localStore.getQuery(api.edges.list, { canvasId: args.canvasId, }); if (nodeList === undefined || edgeList === undefined) return; const tempNodeId = ( args.clientRequestId ? `${OPTIMISTIC_NODE_PREFIX}${args.clientRequestId}` : `${OPTIMISTIC_NODE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` ) as Id<"nodes">; const tempEdgeId = ( args.clientRequestId ? `${OPTIMISTIC_EDGE_PREFIX}${args.clientRequestId}` : `${OPTIMISTIC_EDGE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` ) as Id<"edges">; const syntheticNode: Doc<"nodes"> = { _id: tempNodeId, _creationTime: Date.now(), canvasId: args.canvasId, type: args.type as Doc<"nodes">["type"], positionX: args.positionX, positionY: args.positionY, width: args.width, height: args.height, status: "idle", retryCount: 0, data: args.data, parentId: args.parentId, zIndex: args.zIndex, }; const syntheticEdge: Doc<"edges"> = { _id: tempEdgeId, _creationTime: Date.now(), canvasId: args.canvasId, sourceNodeId: tempNodeId, targetNodeId: args.targetNodeId, sourceHandle: args.sourceHandle, targetHandle: args.targetHandle, }; localStore.setQuery(api.nodes.list, { canvasId: args.canvasId }, [ ...nodeList, syntheticNode, ]); localStore.setQuery(api.edges.list, { canvasId: args.canvasId }, [ ...edgeList, syntheticEdge, ]); }); const createNodeWithEdgeSplit = useMutation(api.nodes.createWithEdgeSplit); const batchRemoveNodes = useMutation(api.nodes.batchRemove).withOptimisticUpdate( (localStore, args) => { const nodeList = localStore.getQuery(api.nodes.list, { canvasId }); const edgeList = localStore.getQuery(api.edges.list, { canvasId }); if (nodeList === undefined || edgeList === undefined) return; const removeSet = new Set(args.nodeIds.map((id) => id as string)); localStore.setQuery( api.nodes.list, { canvasId }, nodeList.filter((n) => !removeSet.has(n._id)), ); localStore.setQuery( api.edges.list, { canvasId }, edgeList.filter( (e) => !removeSet.has(e.sourceNodeId) && !removeSet.has(e.targetNodeId), ), ); }, ); const createEdge = useMutation(api.edges.create).withOptimisticUpdate( (localStore, args) => { const edgeList = localStore.getQuery(api.edges.list, { canvasId: args.canvasId, }); if (edgeList === undefined) return; const tempId = `${OPTIMISTIC_EDGE_PREFIX}${Date.now()}_${Math.random().toString(36).slice(2, 11)}` as Id<"edges">; const synthetic: Doc<"edges"> = { _id: tempId, _creationTime: Date.now(), canvasId: args.canvasId, sourceNodeId: args.sourceNodeId, targetNodeId: args.targetNodeId, sourceHandle: args.sourceHandle, targetHandle: args.targetHandle, }; localStore.setQuery( api.edges.list, { canvasId: args.canvasId }, [...edgeList, synthetic], ); }, ); const removeEdge = useMutation(api.edges.remove).withOptimisticUpdate( (localStore, args) => { const edgeList = localStore.getQuery(api.edges.list, { canvasId }); if (edgeList === undefined) return; localStore.setQuery( api.edges.list, { canvasId }, edgeList.filter((e) => e._id !== args.edgeId), ); }, ); const runMoveNodeMutation = useCallback( async (args: { nodeId: Id<"nodes">; positionX: number; positionY: number }) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "moveNode", payload: args }); try { return await moveNode(args); } finally { resolveCanvasOp(canvasId, opId); } }, [canvasId, moveNode], ); const runBatchMoveNodesMutation = useCallback( async (args: Parameters[0]) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "batchMoveNodes", payload: args }); try { return await batchMoveNodes(args); } finally { resolveCanvasOp(canvasId, opId); } }, [batchMoveNodes, canvasId], ); const runResizeNodeMutation = useCallback( async (args: { nodeId: Id<"nodes">; width: number; height: number }) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "resizeNode", payload: args }); try { return await resizeNode(args); } finally { resolveCanvasOp(canvasId, opId); } }, [canvasId, resizeNode], ); const runBatchRemoveNodesMutation = useCallback( async (args: Parameters[0]) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "batchRemoveNodes", payload: args }); try { return await batchRemoveNodes(args); } finally { resolveCanvasOp(canvasId, opId); } }, [batchRemoveNodes, canvasId], ); const runCreateEdgeMutation = useCallback( async (args: Parameters[0]) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "createEdge", payload: args }); try { return await createEdge(args); } finally { resolveCanvasOp(canvasId, opId); } }, [canvasId, createEdge], ); const runRemoveEdgeMutation = useCallback( async (args: Parameters[0]) => { const opId = createCanvasOpId(); enqueueCanvasOp(canvasId, { id: opId, type: "removeEdge", payload: args }); try { return await removeEdge(args); } finally { resolveCanvasOp(canvasId, opId); } }, [canvasId, removeEdge], ); const splitEdgeAtExistingNodeMut = useMutation( api.nodes.splitEdgeAtExistingNode, ).withOptimisticUpdate((localStore, args) => { const edgeList = localStore.getQuery(api.edges.list, { canvasId: args.canvasId, }); const nodeList = localStore.getQuery(api.nodes.list, { canvasId: args.canvasId, }); if (edgeList === undefined || nodeList === undefined) return; const removed = edgeList.find((e) => e._id === args.splitEdgeId); if (!removed) return; const t1 = `${OPTIMISTIC_EDGE_PREFIX}s1_${Date.now()}_${Math.random().toString(36).slice(2, 10)}` as Id<"edges">; const t2 = `${OPTIMISTIC_EDGE_PREFIX}s2_${Date.now()}_${Math.random().toString(36).slice(2, 10)}` as Id<"edges">; const now = Date.now(); const nextEdges = edgeList.filter((e) => e._id !== args.splitEdgeId); nextEdges.push( { _id: t1, _creationTime: now, canvasId: args.canvasId, sourceNodeId: removed.sourceNodeId, targetNodeId: args.middleNodeId, sourceHandle: args.splitSourceHandle, targetHandle: args.newNodeTargetHandle, }, { _id: t2, _creationTime: now, canvasId: args.canvasId, sourceNodeId: args.middleNodeId, targetNodeId: removed.targetNodeId, sourceHandle: args.newNodeSourceHandle, targetHandle: args.splitTargetHandle, }, ); localStore.setQuery(api.edges.list, { canvasId: args.canvasId }, nextEdges); if (args.positionX !== undefined && args.positionY !== undefined) { const px = args.positionX; const py = args.positionY; localStore.setQuery( api.nodes.list, { canvasId: args.canvasId }, nodeList.map((n) => n._id === args.middleNodeId ? { ...n, positionX: px, positionY: py, } : n, ), ); } }); /** Freepik-Panel: State canvas-weit, damit es den optimistic_… → Real-ID-Wechsel überlebt. */ const [assetBrowserTargetNodeId, setAssetBrowserTargetNodeId] = useState< string | null >(null); const assetBrowserTargetApi: AssetBrowserTargetApi = useMemo( () => ({ targetNodeId: assetBrowserTargetNodeId, openForNode: (nodeId: string) => setAssetBrowserTargetNodeId(nodeId), close: () => setAssetBrowserTargetNodeId(null), }), [assetBrowserTargetNodeId], ); /** Pairing: create kann vor oder nach Drag-Ende fertig sein. Kanten-Split + Position in einem Convex-Roundtrip wenn split ansteht. */ const syncPendingMoveForClientRequest = useCallback( async ( clientRequestId: string | undefined, realId?: Id<"nodes">, ): Promise => { if (!clientRequestId) return; if (realId !== undefined) { const optimisticNodeId = `${OPTIMISTIC_NODE_PREFIX}${clientRequestId}`; setAssetBrowserTargetNodeId((current) => current === optimisticNodeId ? (realId as string) : current, ); const pendingMove = pendingMoveAfterCreateRef.current.get(clientRequestId); const splitPayload = pendingEdgeSplitByClientRequestRef.current.get(clientRequestId); if (splitPayload) { pendingEdgeSplitByClientRequestRef.current.delete(clientRequestId); if (pendingMove) { pendingMoveAfterCreateRef.current.delete(clientRequestId); } resolvedRealIdByClientRequestRef.current.delete(clientRequestId); try { await splitEdgeAtExistingNodeMut({ canvasId, splitEdgeId: splitPayload.intersectedEdgeId, middleNodeId: realId, splitSourceHandle: splitPayload.intersectedSourceHandle, splitTargetHandle: splitPayload.intersectedTargetHandle, newNodeSourceHandle: splitPayload.middleSourceHandle, newNodeTargetHandle: splitPayload.middleTargetHandle, positionX: pendingMove?.positionX ?? splitPayload.positionX, positionY: pendingMove?.positionY ?? splitPayload.positionY, }); } catch (error: unknown) { console.error("[Canvas pending edge split failed]", { clientRequestId, realId, error: String(error), }); } return; } if (pendingMove) { pendingMoveAfterCreateRef.current.delete(clientRequestId); // Ref bewusst NICHT löschen: Edge-Sync braucht clientRequestId→realId für // Remap/Carry-over, solange convexNodes/convexEdges nach Mutation kurz auseinanderlaufen. resolvedRealIdByClientRequestRef.current.set(clientRequestId, realId); pendingLocalPositionUntilConvexMatchesRef.current.set( realId as string, { x: pendingMove.positionX, y: pendingMove.positionY, }, ); await runMoveNodeMutation({ nodeId: realId, positionX: pendingMove.positionX, positionY: pendingMove.positionY, }); return; } resolvedRealIdByClientRequestRef.current.set(clientRequestId, realId); return; } const r = resolvedRealIdByClientRequestRef.current.get(clientRequestId); const p = pendingMoveAfterCreateRef.current.get(clientRequestId); if (!r || !p) return; pendingMoveAfterCreateRef.current.delete(clientRequestId); resolvedRealIdByClientRequestRef.current.delete(clientRequestId); const splitPayload = pendingEdgeSplitByClientRequestRef.current.get(clientRequestId); if (splitPayload) { pendingEdgeSplitByClientRequestRef.current.delete(clientRequestId); try { await splitEdgeAtExistingNodeMut({ canvasId, splitEdgeId: splitPayload.intersectedEdgeId, middleNodeId: r, splitSourceHandle: splitPayload.intersectedSourceHandle, splitTargetHandle: splitPayload.intersectedTargetHandle, newNodeSourceHandle: splitPayload.middleSourceHandle, newNodeTargetHandle: splitPayload.middleTargetHandle, positionX: splitPayload.positionX ?? p.positionX, positionY: splitPayload.positionY ?? p.positionY, }); } catch (error: unknown) { console.error("[Canvas pending edge split failed]", { clientRequestId, realId: r, error: String(error), }); } } else { pendingLocalPositionUntilConvexMatchesRef.current.set(r as string, { x: p.positionX, y: p.positionY, }); await runMoveNodeMutation({ nodeId: r, positionX: p.positionX, positionY: p.positionY, }); } }, [canvasId, runMoveNodeMutation, splitEdgeAtExistingNodeMut], ); // ─── Lokaler State (für flüssiges Dragging) ─────────────────── const [nodes, setNodes] = useState([]); const [edges, setEdges] = useState([]); const [hasHydratedLocalSnapshot, setHasHydratedLocalSnapshot] = useState(false); /** Erzwingt Edge-Merge nach Mutation, falls clientRequestId→realId-Ref erst im Promise gesetzt wird. */ const [edgeSyncNonce, setEdgeSyncNonce] = useState(0); const [connectionDropMenu, setConnectionDropMenu] = useState(null); const connectionDropMenuRef = useRef(null); connectionDropMenuRef.current = connectionDropMenu; const [scissorsMode, setScissorsMode] = useState(false); const [scissorStrokePreview, setScissorStrokePreview] = useState< { x: number; y: number }[] | null >(null); const [navTool, setNavTool] = useState("select"); useEffect(() => { const snapshot = readCanvasSnapshot(canvasId as string); if (snapshot) { setNodes(snapshot.nodes); setEdges(snapshot.edges); } setHasHydratedLocalSnapshot(true); }, [canvasId]); useEffect(() => { if (!hasHydratedLocalSnapshot) return; writeCanvasSnapshot(canvasId as string, { nodes, edges }); }, [canvasId, edges, hasHydratedLocalSnapshot, nodes]); const handleNavToolChange = useCallback((tool: CanvasNavTool) => { if (tool === "scissor") { setScissorsMode(true); setNavTool("scissor"); return; } setScissorsMode(false); setNavTool(tool); }, []); // Auswahl (V) / Hand (H) — ergänzt die Leertaste (Standard: panActivationKeyCode Space beim Ziehen) useEffect(() => { const onKeyDown = (e: KeyboardEvent) => { if (e.metaKey || e.ctrlKey || e.altKey) return; if (isEditableKeyboardTarget(e.target)) return; const key = e.key.length === 1 ? e.key.toLowerCase() : ""; if (key === "v") { e.preventDefault(); handleNavToolChange("select"); return; } if (key === "h") { e.preventDefault(); handleNavToolChange("hand"); return; } }; document.addEventListener("keydown", onKeyDown); return () => document.removeEventListener("keydown", onKeyDown); }, [handleNavToolChange]); const { flowPanOnDrag, flowSelectionOnDrag } = useMemo(() => { const panMiddleRight: number[] = [1, 2]; if (scissorsMode) { return { flowPanOnDrag: panMiddleRight, flowSelectionOnDrag: false }; } if (navTool === "hand") { return { flowPanOnDrag: true, flowSelectionOnDrag: false }; } if (navTool === "comment") { return { flowPanOnDrag: panMiddleRight, flowSelectionOnDrag: true }; } return { flowPanOnDrag: panMiddleRight, flowSelectionOnDrag: true }; }, [scissorsMode, navTool]); const edgesRef = useRef(edges); edgesRef.current = edges; const scissorsModeRef = useRef(scissorsMode); scissorsModeRef.current = scissorsMode; // Drag-Lock: während des Drags kein Convex-Override const isDragging = useRef(false); /** Convex-Merge: Position nicht mit veraltetem Snapshot überschreiben (RF-`dragging` kommt oft verzögert). */ const preferLocalPositionNodeIdsRef = useRef(new Set()); // Resize-Lock: kein Convex→lokal während aktiver Größenänderung (veraltete Maße überschreiben sonst den Resize) const isResizing = useRef(false); // Delete-Lock: Nodes die gerade gelöscht werden, nicht aus Convex-Sync wiederherstellen const deletingNodeIds = useRef>(new Set()); // Delete Edge on Drop const edgeReconnectSuccessful = useRef(true); const isReconnectDragActiveRef = useRef(false); const overlappedEdgeRef = useRef(null); const highlightedEdgeRef = useRef(null); const highlightedEdgeOriginalStyleRef = useRef( undefined, ); useGenerationFailureWarnings(convexNodes); const { onEdgeClickScissors, onScissorsFlowPointerDownCapture } = useCanvasScissors({ scissorsMode, scissorsModeRef, edgesRef, setScissorsMode, setNavTool, setScissorStrokePreview, runRemoveEdgeMutation, }); const { onBeforeDelete, onNodesDelete, onEdgesDelete } = useCanvasDeleteHandlers({ canvasId, nodes, edges, deletingNodeIds, setAssetBrowserTargetNodeId, runBatchRemoveNodesMutation, runCreateEdgeMutation, runRemoveEdgeMutation, }); const { onReconnectStart, onReconnect, onReconnectEnd } = useCanvasReconnectHandlers({ edgeReconnectSuccessful, isReconnectDragActiveRef, setEdges, runRemoveEdgeMutation, }); // ─── Convex → Lokaler State Sync ────────────────────────────── /** * 1) Kanten: Carry/Inferenz setzt ggf. `resolvedRealIdByClientRequestRef` (auch bevor Mutation-.then läuft). * 2) Nodes: gleicher Commit, vor Paint — echte Node-IDs passen zu Kanten-Endpunkten (verhindert „reißende“ Kanten). * Während Drag (`isDraggingRef` oder `node.dragging`): nur optimistic→real-Handoff. */ useLayoutEffect(() => { if (!convexEdges) return; setEdges((prev) => { const prevConvexSnap = convexNodeIdsSnapshotForEdgeCarryRef.current; const currentConvexIdList = convexNodes !== undefined ? convexNodes.map((n) => n._id as string) : []; const currentConvexIdSet = new Set(currentConvexIdList); const newlyAppearedIds: string[] = []; for (const id of currentConvexIdList) { if (!prevConvexSnap.has(id)) newlyAppearedIds.push(id); } const tempEdges = prev.filter((e) => e.className === "temp"); const sourceTypeByNodeId = convexNodes !== undefined ? new Map(convexNodes.map((n) => [n._id, n.type])) : undefined; const glowMode = resolvedTheme === "dark" ? "dark" : "light"; const mapped = convexEdges.map((edge) => sourceTypeByNodeId ? convexEdgeToRFWithSourceGlow( edge, sourceTypeByNodeId.get(edge.sourceNodeId), glowMode, ) : convexEdgeToRF(edge), ); const mappedSignatures = new Set(mapped.map(rfEdgeConnectionSignature)); const convexNodeIds = convexNodes !== undefined ? new Set(convexNodes.map((n) => n._id as string)) : null; const realIdByClientRequest = resolvedRealIdByClientRequestRef.current; const resolveEndpoint = (nodeId: string): string => { if (!isOptimisticNodeId(nodeId)) return nodeId; const cr = clientRequestIdFromOptimisticNodeId(nodeId); if (!cr) return nodeId; const real = realIdByClientRequest.get(cr); return real !== undefined ? (real as string) : nodeId; }; /** Wenn Mutation-.then noch nicht lief: echte ID aus Delta (eine neue Node) + gleiche clientRequestId wie Kante. */ const resolveEndpointWithInference = ( nodeId: string, edge: RFEdge, ): string => { const base = resolveEndpoint(nodeId); if (!isOptimisticNodeId(base)) return base; const nodeCr = clientRequestIdFromOptimisticNodeId(base); if (nodeCr === null) return base; const edgeCr = clientRequestIdFromOptimisticEdgeId(edge.id); if (edgeCr === null || edgeCr !== nodeCr) return base; if (!pendingConnectionCreatesRef.current.has(nodeCr)) return base; if (newlyAppearedIds.length !== 1) return base; const inferred = newlyAppearedIds[0]; resolvedRealIdByClientRequestRef.current.set( nodeCr, inferred as Id<"nodes">, ); return inferred; }; const endpointUsable = (nodeId: string): boolean => { const resolved = resolveEndpoint(nodeId); if (convexNodeIds?.has(resolved)) return true; if (convexNodeIds?.has(nodeId)) return true; return false; }; const optimisticEndpointHasPendingCreate = (nodeId: string): boolean => { if (!isOptimisticNodeId(nodeId)) return false; const cr = clientRequestIdFromOptimisticNodeId(nodeId); return ( cr !== null && pendingConnectionCreatesRef.current.has(cr) ); }; const shouldCarryOptimisticEdge = ( original: RFEdge, remapped: RFEdge, ): boolean => { if (mappedSignatures.has(rfEdgeConnectionSignature(remapped))) { return false; } const sourceOk = endpointUsable(remapped.source); const targetOk = endpointUsable(remapped.target); if (sourceOk && targetOk) return true; if (!pendingConnectionCreatesRef.current.size) { return false; } if ( sourceOk && optimisticEndpointHasPendingCreate(original.target) ) { return true; } if ( targetOk && optimisticEndpointHasPendingCreate(original.source) ) { return true; } return false; }; const carriedOptimistic: RFEdge[] = []; for (const e of prev) { if (e.className === "temp") continue; if (!isOptimisticEdgeId(e.id)) continue; const remapped: RFEdge = { ...e, source: resolveEndpointWithInference(e.source, e), target: resolveEndpointWithInference(e.target, e), }; if (!shouldCarryOptimisticEdge(e, remapped)) continue; carriedOptimistic.push(remapped); } if (convexNodes !== undefined) { convexNodeIdsSnapshotForEdgeCarryRef.current = currentConvexIdSet; } /** Erst löschen, wenn Convex die neue Kante geliefert hat — sonst kurzes Fenster: pending=0, Kanten-Query noch alt, Carry schlägt fehl. */ for (const cr of [...pendingConnectionCreatesRef.current]) { const realId = resolvedRealIdByClientRequestRef.current.get(cr); if (realId === undefined) continue; const nodePresent = convexNodes !== undefined && convexNodes.some((n) => n._id === realId); const edgeTouchesNewNode = convexEdges.some( (e) => e.sourceNodeId === realId || e.targetNodeId === realId, ); if (nodePresent && edgeTouchesNewNode) { pendingConnectionCreatesRef.current.delete(cr); } } return [...mapped, ...carriedOptimistic, ...tempEdges]; }); }, [convexEdges, convexNodes, resolvedTheme, edgeSyncNonce]); useLayoutEffect(() => { if (!convexNodes || isResizing.current) return; setNodes((previousNodes) => { inferPendingConnectionNodeHandoff( previousNodes, convexNodes, pendingConnectionCreatesRef.current, resolvedRealIdByClientRequestRef.current, ); /** RF setzt `node.dragging` + Position oft bevor `onNodeDragStart` `isDraggingRef` setzt — ohne diese Zeile zieht useLayoutEffect Convex-Stand darüber („Kleben“). */ const anyRfNodeDragging = previousNodes.some((n) => Boolean((n as { dragging?: boolean }).dragging), ); if (isDragging.current || anyRfNodeDragging) { const needsOptimisticHandoff = previousNodes.some((n) => { const cr = clientRequestIdFromOptimisticNodeId(n.id); return ( cr !== null && resolvedRealIdByClientRequestRef.current.has(cr) ); }); if (!needsOptimisticHandoff) { return previousNodes; } } const prevDataById = new Map( previousNodes.map((node) => [node.id, node.data as Record]), ); const enriched = convexNodes.map((node) => convexNodeDocWithMergedStorageUrl( node, storageUrlsById, prevDataById, ), ); const incomingNodes = withResolvedCompareData( enriched.map(convexNodeToRF), edges, ); // Nodes, die gerade optimistisch gelöscht werden, nicht wiederherstellen const filteredIncoming = deletingNodeIds.current.size > 0 ? incomingNodes.filter((node) => !deletingNodeIds.current.has(node.id)) : incomingNodes; const merged = applyPinnedNodePositions( mergeNodesPreservingLocalState( previousNodes, filteredIncoming, resolvedRealIdByClientRequestRef.current, preferLocalPositionNodeIdsRef.current, ), pendingLocalPositionUntilConvexMatchesRef.current, ); const mergedWithOpPins = applyPinnedNodePositionsReadOnly( merged, getPendingMovePinsFromLocalOps(canvasId as string), ); /** Nicht am Drag-Ende leeren (moveNode läuft oft async): solange Convex alt ist, Eintrag behalten und erst bei übereinstimmendem Snapshot entfernen. */ const incomingById = new Map( filteredIncoming.map((n) => [n.id, n]), ); for (const n of mergedWithOpPins) { if (!preferLocalPositionNodeIdsRef.current.has(n.id)) continue; const inc = incomingById.get(n.id); if (!inc) continue; if ( positionsMatchPin(n.position, { x: inc.position.x, y: inc.position.y, }) ) { preferLocalPositionNodeIdsRef.current.delete(n.id); } } return mergedWithOpPins; }); }, [canvasId, convexNodes, edges, storageUrlsById]); useEffect(() => { if (isDragging.current) return; setNodes((nds) => withResolvedCompareData(nds, edges)); }, [edges]); // ─── Node Changes (Drag, Select, Remove) ───────────────────── const onNodesChange = useCallback( (changes: NodeChange[]) => { for (const c of changes) { if (c.type === "dimensions") { if (c.resizing === true) { isResizing.current = true; } else if (c.resizing === false) { isResizing.current = false; } } } const removedIds = new Set(); for (const c of changes) { if (c.type === "remove") { removedIds.add(c.id); } } setNodes((nds) => { for (const c of changes) { if (c.type === "position" && "id" in c) { pendingLocalPositionUntilConvexMatchesRef.current.delete(c.id); preferLocalPositionNodeIdsRef.current.add(c.id); } } const adjustedChanges = adjustNodeDimensionChanges(changes, nds); const nextNodes = applyNodeChanges(adjustedChanges, nds); for (const change of adjustedChanges) { if (change.type !== "dimensions") continue; if (!change.dimensions) continue; if (removedIds.has(change.id)) continue; const prevNode = nds.find((node) => node.id === change.id); const nextNode = nextNodes.find((node) => node.id === change.id); void prevNode; void nextNode; if (change.resizing !== false) continue; void runResizeNodeMutation({ nodeId: change.id as Id<"nodes">, width: change.dimensions.width, height: change.dimensions.height, }).catch((error: unknown) => { if (process.env.NODE_ENV !== "production") { console.warn("[Canvas] resizeNode failed", error); } }); } return nextNodes; }); }, [runResizeNodeMutation], ); const onEdgesChange = useCallback((changes: EdgeChange[]) => { setEdges((eds) => applyEdgeChanges(changes, eds)); }, []); const onFlowError = useCallback((id: string, error: string) => { if (process.env.NODE_ENV === "production") return; console.error("[ReactFlow error]", { canvasId, id, error }); }, [canvasId]); const setHighlightedIntersectionEdge = useCallback((edgeId: string | null) => { const previousHighlightedEdgeId = highlightedEdgeRef.current; if (previousHighlightedEdgeId === edgeId) { return; } setEdges((currentEdges) => { let nextEdges = currentEdges; if (previousHighlightedEdgeId) { nextEdges = nextEdges.map((edge) => edge.id === previousHighlightedEdgeId ? { ...edge, style: highlightedEdgeOriginalStyleRef.current, } : edge, ); } if (!edgeId) { highlightedEdgeOriginalStyleRef.current = undefined; return nextEdges; } const edgeToHighlight = nextEdges.find((edge) => edge.id === edgeId); if (!edgeToHighlight || edgeToHighlight.className === "temp") { highlightedEdgeOriginalStyleRef.current = undefined; return nextEdges; } highlightedEdgeOriginalStyleRef.current = edgeToHighlight.style; return nextEdges.map((edge) => edge.id === edgeId ? { ...edge, style: { ...(edge.style ?? {}), ...EDGE_INTERSECTION_HIGHLIGHT_STYLE, }, } : edge, ); }); highlightedEdgeRef.current = edgeId; }, []); const onNodeDrag = useCallback( (_event: React.MouseEvent, node: RFNode) => { const nodeCenter = getNodeCenterClientPosition(node.id); if (!nodeCenter) { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); return; } const intersectedEdgeId = getIntersectedEdgeId(nodeCenter); if (!intersectedEdgeId) { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); return; } const intersectedEdge = edges.find( (edge) => edge.id === intersectedEdgeId && edge.className !== "temp", ); if (!intersectedEdge) { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); return; } if ( intersectedEdge.source === node.id || intersectedEdge.target === node.id ) { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); return; } const handles = NODE_HANDLE_MAP[node.type ?? ""]; if (!hasHandleKey(handles, "source") || !hasHandleKey(handles, "target")) { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); return; } overlappedEdgeRef.current = intersectedEdge.id; setHighlightedIntersectionEdge(intersectedEdge.id); }, [edges, setHighlightedIntersectionEdge], ); // ─── Drag Start → Lock ──────────────────────────────────────── const onNodeDragStart = useCallback( (_event: ReactMouseEvent, _node: RFNode, draggedNodes: RFNode[]) => { isDragging.current = true; overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); for (const n of draggedNodes) { pendingLocalPositionUntilConvexMatchesRef.current.delete(n.id); } }, [setHighlightedIntersectionEdge], ); // ─── Drag Stop → Commit zu Convex ───────────────────────────── const onNodeDragStop = useCallback( (_: React.MouseEvent, node: RFNode, draggedNodes: RFNode[]) => { const intersectedEdgeId = overlappedEdgeRef.current; void (async () => { try { const intersectedEdge = intersectedEdgeId ? edges.find( (edge) => edge.id === intersectedEdgeId && edge.className !== "temp", ) : undefined; const splitHandles = NODE_HANDLE_MAP[node.type ?? ""]; const splitEligible = intersectedEdge !== undefined && splitHandles !== undefined && intersectedEdge.source !== node.id && intersectedEdge.target !== node.id && hasHandleKey(splitHandles, "source") && hasHandleKey(splitHandles, "target"); if (draggedNodes.length > 1) { for (const n of draggedNodes) { const cid = clientRequestIdFromOptimisticNodeId(n.id); if (cid) { pendingMoveAfterCreateRef.current.set(cid, { positionX: n.position.x, positionY: n.position.y, }); await syncPendingMoveForClientRequest(cid); } } const realMoves = draggedNodes.filter((n) => !isOptimisticNodeId(n.id)); if (realMoves.length > 0) { await runBatchMoveNodesMutation({ moves: realMoves.map((n) => ({ nodeId: n.id as Id<"nodes">, positionX: n.position.x, positionY: n.position.y, })), }); } if (!splitEligible || !intersectedEdge) { return; } const multiCid = clientRequestIdFromOptimisticNodeId(node.id); let middleId = node.id as Id<"nodes">; if (multiCid) { const r = resolvedRealIdByClientRequestRef.current.get(multiCid); if (!r) { pendingEdgeSplitByClientRequestRef.current.set(multiCid, { intersectedEdgeId: intersectedEdge.id as Id<"edges">, sourceNodeId: intersectedEdge.source as Id<"nodes">, targetNodeId: intersectedEdge.target as Id<"nodes">, intersectedSourceHandle: normalizeHandle( intersectedEdge.sourceHandle, ), intersectedTargetHandle: normalizeHandle( intersectedEdge.targetHandle, ), middleSourceHandle: normalizeHandle(splitHandles.source), middleTargetHandle: normalizeHandle(splitHandles.target), positionX: node.position.x, positionY: node.position.y, }); return; } middleId = r; } await splitEdgeAtExistingNodeMut({ canvasId, splitEdgeId: intersectedEdge.id as Id<"edges">, middleNodeId: middleId, splitSourceHandle: normalizeHandle(intersectedEdge.sourceHandle), splitTargetHandle: normalizeHandle(intersectedEdge.targetHandle), newNodeSourceHandle: normalizeHandle(splitHandles.source), newNodeTargetHandle: normalizeHandle(splitHandles.target), }); return; } if (!splitEligible || !intersectedEdge) { const cidSingle = clientRequestIdFromOptimisticNodeId(node.id); if (cidSingle) { pendingMoveAfterCreateRef.current.set(cidSingle, { positionX: node.position.x, positionY: node.position.y, }); await syncPendingMoveForClientRequest(cidSingle); } else { await runMoveNodeMutation({ nodeId: node.id as Id<"nodes">, positionX: node.position.x, positionY: node.position.y, }); } return; } const singleCid = clientRequestIdFromOptimisticNodeId(node.id); if (singleCid) { const resolvedSingle = resolvedRealIdByClientRequestRef.current.get(singleCid); if (!resolvedSingle) { pendingMoveAfterCreateRef.current.set(singleCid, { positionX: node.position.x, positionY: node.position.y, }); pendingEdgeSplitByClientRequestRef.current.set(singleCid, { intersectedEdgeId: intersectedEdge.id as Id<"edges">, sourceNodeId: intersectedEdge.source as Id<"nodes">, targetNodeId: intersectedEdge.target as Id<"nodes">, intersectedSourceHandle: normalizeHandle( intersectedEdge.sourceHandle, ), intersectedTargetHandle: normalizeHandle( intersectedEdge.targetHandle, ), middleSourceHandle: normalizeHandle(splitHandles.source), middleTargetHandle: normalizeHandle(splitHandles.target), positionX: node.position.x, positionY: node.position.y, }); await syncPendingMoveForClientRequest(singleCid); return; } await splitEdgeAtExistingNodeMut({ canvasId, splitEdgeId: intersectedEdge.id as Id<"edges">, middleNodeId: resolvedSingle, splitSourceHandle: normalizeHandle(intersectedEdge.sourceHandle), splitTargetHandle: normalizeHandle(intersectedEdge.targetHandle), newNodeSourceHandle: normalizeHandle(splitHandles.source), newNodeTargetHandle: normalizeHandle(splitHandles.target), positionX: node.position.x, positionY: node.position.y, }); pendingMoveAfterCreateRef.current.delete(singleCid); return; } await splitEdgeAtExistingNodeMut({ canvasId, splitEdgeId: intersectedEdge.id as Id<"edges">, middleNodeId: node.id as Id<"nodes">, splitSourceHandle: normalizeHandle(intersectedEdge.sourceHandle), splitTargetHandle: normalizeHandle(intersectedEdge.targetHandle), newNodeSourceHandle: normalizeHandle(splitHandles.source), newNodeTargetHandle: normalizeHandle(splitHandles.target), positionX: node.position.x, positionY: node.position.y, }); } catch (error) { console.error("[Canvas edge intersection split failed]", { canvasId, nodeId: node.id, nodeType: node.type, intersectedEdgeId, error: String(error), }); } finally { overlappedEdgeRef.current = null; setHighlightedIntersectionEdge(null); isDragging.current = false; } })(); }, [ canvasId, edges, runBatchMoveNodesMutation, runMoveNodeMutation, setHighlightedIntersectionEdge, splitEdgeAtExistingNodeMut, syncPendingMoveForClientRequest, ], ); // ─── Neue Verbindung → Convex Edge ──────────────────────────── const onConnect = useCallback( (connection: Connection) => { if (connection.source && connection.target) { void runCreateEdgeMutation({ canvasId, sourceNodeId: connection.source as Id<"nodes">, targetNodeId: connection.target as Id<"nodes">, sourceHandle: connection.sourceHandle ?? undefined, targetHandle: connection.targetHandle ?? undefined, }); } }, [canvasId, runCreateEdgeMutation], ); const onConnectEnd = useCallback( (event, connectionState) => { if (isReconnectDragActiveRef.current) return; if (connectionState.isValid === true) return; const fromNode = connectionState.fromNode; const fromHandle = connectionState.fromHandle; if (!fromNode || !fromHandle) return; const pt = getConnectEndClientPoint(event); if (!pt) return; const flow = screenToFlowPosition({ x: pt.x, y: pt.y }); setConnectionDropMenu({ screenX: pt.x, screenY: pt.y, flowX: flow.x, flowY: flow.y, fromNodeId: fromNode.id as Id<"nodes">, fromHandleId: fromHandle.id ?? undefined, fromHandleType: fromHandle.type, }); }, [screenToFlowPosition], ); const handleConnectionDropPick = useCallback( (template: CanvasNodeTemplate) => { const ctx = connectionDropMenuRef.current; if (!ctx) return; const defaults = NODE_DEFAULTS[template.type] ?? { width: 200, height: 100, data: {}, }; const clientRequestId = crypto.randomUUID(); pendingConnectionCreatesRef.current.add(clientRequestId); const handles = NODE_HANDLE_MAP[template.type]; const width = template.width ?? defaults.width; const height = template.height ?? defaults.height; const data = { ...defaults.data, ...(template.defaultData as Record), canvasId, }; const base = { canvasId, type: template.type, positionX: ctx.flowX, positionY: ctx.flowY, width, height, data, clientRequestId, }; const settle = (realId: Id<"nodes">) => { void syncPendingMoveForClientRequest(clientRequestId, realId).catch( (error: unknown) => { console.error("[Canvas] settle syncPendingMove failed", error); }, ); }; if (ctx.fromHandleType === "source") { void createNodeWithEdgeFromSource({ ...base, sourceNodeId: ctx.fromNodeId, sourceHandle: ctx.fromHandleId, targetHandle: handles?.target ?? undefined, }) .then((realId) => { resolvedRealIdByClientRequestRef.current.set( clientRequestId, realId, ); settle(realId); setEdgeSyncNonce((n) => n + 1); }) .catch((error) => { pendingConnectionCreatesRef.current.delete(clientRequestId); console.error("[Canvas] createNodeWithEdgeFromSource failed", error); }); } else { void createNodeWithEdgeToTarget({ ...base, targetNodeId: ctx.fromNodeId, sourceHandle: handles?.source ?? undefined, targetHandle: ctx.fromHandleId, }) .then((realId) => { resolvedRealIdByClientRequestRef.current.set( clientRequestId, realId, ); settle(realId); setEdgeSyncNonce((n) => n + 1); }) .catch((error) => { pendingConnectionCreatesRef.current.delete(clientRequestId); console.error("[Canvas] createNodeWithEdgeToTarget failed", error); }); } }, [ canvasId, createNodeWithEdgeFromSource, createNodeWithEdgeToTarget, syncPendingMoveForClientRequest, ], ); const onDragOver = useCallback((event: React.DragEvent) => { event.preventDefault(); const hasFiles = event.dataTransfer.types.includes("Files"); event.dataTransfer.dropEffect = hasFiles ? "copy" : "move"; }, []); const onDrop = useCallback( async (event: React.DragEvent) => { event.preventDefault(); const rawData = event.dataTransfer.getData( "application/lemonspace-node-type", ); if (!rawData) { const hasFiles = event.dataTransfer.files && event.dataTransfer.files.length > 0; if (hasFiles) { const file = event.dataTransfer.files[0]; if (file.type.startsWith("image/")) { try { let dimensions: { width: number; height: number } | undefined; try { dimensions = await getImageDimensions(file); } catch { dimensions = undefined; } const uploadUrl = await generateUploadUrl(); const result = await fetch(uploadUrl, { method: "POST", headers: { "Content-Type": file.type }, body: file, }); if (!result.ok) { throw new Error("Upload failed"); } const { storageId } = (await result.json()) as { storageId: string }; const position = screenToFlowPosition({ x: event.clientX, y: event.clientY }); const clientRequestId = crypto.randomUUID(); void createNode({ canvasId, type: "image", positionX: position.x, positionY: position.y, width: NODE_DEFAULTS.image.width, height: NODE_DEFAULTS.image.height, data: { storageId, filename: file.name, mimeType: file.type, ...(dimensions ? { width: dimensions.width, height: dimensions.height } : {}), canvasId, }, clientRequestId, }).then((realId) => { void syncPendingMoveForClientRequest( clientRequestId, realId, ).catch((error: unknown) => { console.error( "[Canvas] drop createNode syncPendingMove failed", error, ); }); }); } catch (err) { console.error("Failed to upload dropped file:", err); toast.error(msg.canvas.uploadFailed.title, err instanceof Error ? err.message : undefined); } return; } } return; } // Support both plain type string (sidebar) and JSON payload (browser panels) let nodeType: string; let payloadData: Record | undefined; try { const parsed = JSON.parse(rawData); if (typeof parsed === "object" && parsed.type) { nodeType = parsed.type; payloadData = parsed.data; } else { nodeType = rawData; } } catch { nodeType = rawData; } const position = screenToFlowPosition({ x: event.clientX, y: event.clientY, }); const defaults = NODE_DEFAULTS[nodeType] ?? { width: 200, height: 100, data: {}, }; const clientRequestId = crypto.randomUUID(); void createNode({ canvasId, type: nodeType, positionX: position.x, positionY: position.y, width: defaults.width, height: defaults.height, data: { ...defaults.data, ...payloadData, canvasId }, clientRequestId, }).then((realId) => { void syncPendingMoveForClientRequest(clientRequestId, realId).catch( (error: unknown) => { console.error( "[Canvas] createNode syncPendingMove failed", error, ); }, ); }); }, [screenToFlowPosition, createNode, canvasId, syncPendingMoveForClientRequest, generateUploadUrl], ); // ─── Loading State ──────────────────────────────────────────── if (convexNodes === undefined || convexEdges === undefined) { return (
Canvas lädt…
); } return ( { void syncPendingMoveForClientRequest(clientRequestId, realId).catch( (error: unknown) => { console.error( "[Canvas] onCreateNodeSettled syncPendingMove failed", error, ); }, ); }} >
setConnectionDropMenu(null)} onPick={handleConnectionDropPick} /> {scissorsMode ? (
Scherenmodus — Kante anklicken oder ziehen zum Durchtrennen ·{" "} Esc oder K beenden · Mitte/Rechtsklick zum Verschieben
) : null} {scissorStrokePreview && scissorStrokePreview.length > 1 ? ( `${p.x},${p.y}`) .join(" ")} /> ) : null}
); } interface CanvasProps { canvasId: Id<"canvases">; } export default function Canvas({ canvasId }: CanvasProps) { return ( ); }