grapheditor enhanced para set for ai

2026-04-19 01:31:57 +02:00 · 2026-04-19 01:31:57 +02:00 · 1ffe521ad8
commit 1ffe521ad8
parent 7d27ddf6b5
2 changed files with 317 additions and 17 deletions
--- a/modules/features/graphicalEditor/routeFeatureGraphicalEditor.py
+++ b/modules/features/graphicalEditor/routeFeatureGraphicalEditor.py
@ -757,12 +757,31 @@ async def _runEditorAgent(
            "for the user — you must NEVER execute the workflow or any of its actions. "
            "Even when the user says 'create a workflow that sends an email', you build the "
            "graph (e.g. add an email node, connect it) — you do NOT actually send an email. "
-            "Use these workflow tools to mutate the graph: "
+            "\n\nGraph-mutating tools: readWorkflowGraph, listAvailableNodeTypes, "
-            "readWorkflowGraph, listAvailableNodeTypes, addNode, removeNode, connectNodes, "
+            "describeNodeType, addNode, removeNode, connectNodes, setNodeParameter, "
-            "setNodeParameter, validateGraph. "
+            "autoLayoutWorkflow, validateGraph. "
-            "Always read the current graph and list available node types first, then plan the "
+            "Connection discovery (for parameters of frontendType='userConnection'): listConnections."
-            "smallest set of mutations, then apply them. Respond concisely in the user's "
+            "\n\nMandatory build sequence:"
-            "language and confirm what you changed in the graph."
+            "\n1. readWorkflowGraph — understand current state."
            "\n2. listAvailableNodeTypes — find candidate node ids."
            "\n3. For EACH node type you plan to add: call describeNodeType(nodeType=...) "
            "to learn its requiredParameters, allowedValues and ports. Never skip this "
            "step — guessing parameters leaves the user with empty config cards."
            "\n4. If any required parameter has frontendType='userConnection' (e.g. "
            "email.checkEmail.connectionReference), call listConnections and pick the "
            "connectionId that matches the user's intent (or ask the user if none clearly fits)."
            "\n5. addNode with parameters={...} containing AT LEAST every requiredParameter "
            "filled with a sensible value (use the user's request, the parameter "
            "description, sane defaults, or — for required user-connection fields — "
            "an actual connectionId). Do NOT pass position; the layout step handles it."
            "\n6. connectNodes — wire the nodes consistent with port schemas from describeNodeType."
            "\n7. autoLayoutWorkflow — call exactly once as the LAST graph-mutating step so the "
            "canvas shows a readable top-down layout instead of overlapping boxes."
            "\n8. validateGraph — sanity check, then answer the user."
            "\n\nIf a required parameter cannot be filled from the user's request and has "
            "no safe default, ask the user once for that specific value (e.g. recipient "
            "address, target language, prompt text) instead of leaving the field blank. "
            "Respond concisely in the user's language and list what you changed in the graph."
        )
        editorConfig = AgentConfig(
--- a/modules/serviceCenter/services/serviceAgent/workflowTools.py
+++ b/modules/serviceCenter/services/serviceAgent/workflowTools.py
@ -3,7 +3,8 @@
 """
 Workflow Toolbox - AI-assisted graph manipulation tools for the GraphicalEditor.
 Tools: readWorkflowGraph, addNode, removeNode, connectNodes, setNodeParameter,
-       listAvailableNodeTypes, validateGraph, listWorkflowHistory, readWorkflowMessages.
+       listAvailableNodeTypes, describeNodeType, autoLayoutWorkflow,
       validateGraph, listWorkflowHistory, readWorkflowMessages.
 Conventions enforced here (matches coreTools / actionToolAdapter):
  - Every ``ToolResult(...)`` provides ``toolCallId`` and ``toolName`` (pydantic
@ -144,14 +145,32 @@ async def _addNode(params: Dict[str, Any], context: Any) -> ToolResult:
        nodeId = params.get("nodeId") or str(uuid.uuid4())[:8]
        title = params.get("title", "")
        nodeParams = params.get("parameters", {}) or {}
-        position = params.get("position") or {"x": len(nodes) * 200, "y": 100}
+
        # Frontend stores positions as TOP-LEVEL ``x`` / ``y`` on the node
        # (see ``fromApiGraph`` / ``toApiGraph``). Accept either explicit
        # ``x`` / ``y`` or a ``position={x,y}`` shape from the model and
        # always persist as top-level ``x`` / ``y``. Fallback puts new
        # nodes in a horizontal stripe so the user sees them even before
        # ``autoLayoutWorkflow`` runs.
        position = params.get("position") or {}
        x = params.get("x")
        if x is None:
            x = position.get("x") if isinstance(position, dict) else None
        if x is None:
            x = 40 + len(nodes) * 260
        y = params.get("y")
        if y is None:
            y = position.get("y") if isinstance(position, dict) else None
        if y is None:
            y = 40
        newNode = {
            "id": nodeId,
            "type": nodeType,
            "title": title,
            "parameters": nodeParams,
-            "position": position,
+            "x": x,
            "y": y,
        }
        nodes.append(newNode)
        graph["nodes"] = nodes
@ -287,8 +306,55 @@ def _coerceLabel(rawLabel: Any, fallback: str) -> str:
    return fallback
 def _summarizeNodeForCatalog(n: Dict[str, Any]) -> Dict[str, Any]:
    """Compact summary used in ``listAvailableNodeTypes`` — small but
    informative enough that the model can pick the right type and knows
    whether ``describeNodeType`` is worth a follow-up call."""
    nodeId = n.get("id") or ""
    paramsList = n.get("parameters") or []
    requiredCount = sum(1 for p in paramsList if isinstance(p, dict) and p.get("required"))
    return {
        "id": nodeId,
        "category": n.get("category"),
        "label": _coerceLabel(n.get("label"), nodeId),
        "description": _coerceLabel(n.get("description"), ""),
        "paramCount": len(paramsList),
        "requiredParamCount": requiredCount,
        "usesAi": bool(((n.get("meta") or {}).get("usesAi"))),
    }
 def _summarizeParameter(p: Dict[str, Any]) -> Dict[str, Any]:
    """Reduce a node parameter spec to just what the AI needs to fill it."""
    out: Dict[str, Any] = {
        "name": p.get("name"),
        "type": p.get("type"),
        "required": bool(p.get("required")),
        "frontendType": p.get("frontendType"),
        "description": _coerceLabel(p.get("description"), ""),
    }
    if "default" in p:
        out["default"] = p.get("default")
    feOpts = p.get("frontendOptions")
    if isinstance(feOpts, dict):
        # Expose enum-style choices ("options") so the model sticks to allowed values.
        if isinstance(feOpts.get("options"), list):
            out["allowedValues"] = feOpts.get("options")
    if p.get("frontendType") == "userConnection":
        out["hint"] = (
            "Call listConnections to discover available connections; pass the "
            "connectionId here. Required before this node can run."
        )
    return out
 async def _listAvailableNodeTypes(params: Dict[str, Any], context: Any) -> ToolResult:
-    """List all available node types for the flow builder."""
+    """List all available node types for the flow builder (compact catalog).
    Returns ``id``, ``category``, ``label``, short ``description``, and the
    parameter counts. To learn HOW to fill a node's parameters use
    ``describeNodeType(nodeType=...)`` — that returns the full schema.
    """
    name = "listAvailableNodeTypes"
    try:
        from modules.features.graphicalEditor.nodeDefinitions import STATIC_NODE_TYPES
@ -296,18 +362,188 @@ async def _listAvailableNodeTypes(params: Dict[str, Any], context: Any) -> ToolR
        for n in STATIC_NODE_TYPES:
            if not isinstance(n, dict):
                continue
-            nodeId = n.get("id") or ""
+            nodeTypes.append(_summarizeNodeForCatalog(n))
            nodeTypes.append({
                "id": nodeId,
                "category": n.get("category"),
                "label": _coerceLabel(n.get("label"), nodeId),
            })
        return _ok(name, {"nodeTypes": nodeTypes, "count": len(nodeTypes)})
    except Exception as e:
        logger.exception("listAvailableNodeTypes failed: %s", e)
        return _err(name, str(e))
 async def _describeNodeType(params: Dict[str, Any], context: Any) -> ToolResult:
    """Return the full schema for a single node type so the AI can fill
    ``addNode.parameters`` correctly (which fields are required, what types,
    default values, allowed enum values, what each port expects/produces).
    This is the canonical way to discover required parameters before
    calling ``addNode`` — without it the model guesses ``parameters={}``
    and the user gets empty configuration cards.
    """
    name = "describeNodeType"
    try:
        nodeType = params.get("nodeType") or params.get("id")
        if not nodeType:
            return _err(name, "nodeType required")
        from modules.features.graphicalEditor.nodeDefinitions import STATIC_NODE_TYPES
        target: Dict[str, Any] = {}
        for n in STATIC_NODE_TYPES:
            if isinstance(n, dict) and n.get("id") == nodeType:
                target = n
                break
        if not target:
            return _err(name, f"Unknown nodeType '{nodeType}' — call listAvailableNodeTypes first")
        rawParams = target.get("parameters") or []
        parameters = [
            _summarizeParameter(p) for p in rawParams if isinstance(p, dict)
        ]
        def _portList(portsDict: Any) -> List[Dict[str, Any]]:
            if not isinstance(portsDict, dict):
                return []
            out: List[Dict[str, Any]] = []
            for idx, spec in sorted(portsDict.items(), key=lambda kv: int(kv[0]) if str(kv[0]).isdigit() else 0):
                if not isinstance(spec, dict):
                    continue
                entry: Dict[str, Any] = {"index": int(idx) if str(idx).isdigit() else idx}
                if "schema" in spec:
                    entry["schema"] = spec.get("schema")
                if "accepts" in spec:
                    entry["accepts"] = spec.get("accepts")
                out.append(entry)
            return out
        meta = target.get("meta") or {}
        return _ok(name, {
            "id": target.get("id"),
            "category": target.get("category"),
            "label": _coerceLabel(target.get("label"), target.get("id") or ""),
            "description": _coerceLabel(target.get("description"), ""),
            "usesAi": bool(meta.get("usesAi")),
            "inputs": int(target.get("inputs") or 0),
            "outputs": int(target.get("outputs") or 0),
            "inputPorts": _portList(target.get("inputPorts")),
            "outputPorts": _portList(target.get("outputPorts")),
            "parameters": parameters,
            "requiredParameters": [p["name"] for p in parameters if p.get("required")],
        })
    except Exception as e:
        logger.exception("describeNodeType failed: %s", e)
        return _err(name, str(e))
 # Geometry constants — MUST match the frontend (FlowCanvas.tsx) so the
 # server-side auto-layout produces the exact same coordinates the user
 # would get by clicking "Arrange" in the UI.
 _NODE_WIDTH = 200
 _NODE_HEIGHT = 72
 _LAYOUT_V_GAP = 80
 _LAYOUT_H_GAP = 60
 _LAYOUT_START_X = 40
 _LAYOUT_START_Y = 40
 def _computeAutoLayout(
    nodes: List[Dict[str, Any]],
    connections: List[Dict[str, Any]],
 ) -> List[Dict[str, Any]]:
    """Topological-layer layout — port of ``computeAutoLayout`` in FlowCanvas.tsx.
    Arranges nodes top-to-bottom in layers (one layer per BFS step from the
    sources). Disconnected nodes are appended as extra single-node layers,
    same as the frontend. Returns a NEW node list with updated top-level
    ``x``/``y``; legacy ``position`` keys are stripped to avoid two
    competing sources of truth.
    """
    if not nodes:
        return nodes
    nodeIds = {n.get("id") for n in nodes if n.get("id")}
    inDegree: Dict[str, int] = {nid: 0 for nid in nodeIds if nid}
    children: Dict[str, List[str]] = {nid: [] for nid in nodeIds if nid}
    for c in connections or []:
        src = c.get("source")
        tgt = c.get("target")
        if src in inDegree and tgt in inDegree:
            inDegree[tgt] = inDegree[tgt] + 1
            children[src].append(tgt)
    layers: List[List[str]] = []
    layerOf: Dict[str, int] = {}
    queue: List[str] = [nid for nid, deg in inDegree.items() if deg == 0]
    while queue:
        batch = list(queue)
        queue = []
        layerIdx = len(layers)
        layers.append(batch)
        for nid in batch:
            layerOf[nid] = layerIdx
            for childId in children.get(nid, []):
                inDegree[childId] = inDegree[childId] - 1
                if inDegree[childId] == 0:
                    queue.append(childId)
    # Cycles: append remaining nodes as their own layers (matches frontend).
    for n in nodes:
        nid = n.get("id")
        if nid and nid not in layerOf:
            layerIdx = len(layers)
            layers.append([nid])
            layerOf[nid] = layerIdx
    out: List[Dict[str, Any]] = []
    for n in nodes:
        nid = n.get("id")
        layer = layerOf.get(nid, 0) if nid else 0
        siblings = layers[layer] if 0 <= layer < len(layers) else [nid]
        idxInLayer = siblings.index(nid) if nid in siblings else 0
        new = dict(n)
        new["x"] = _LAYOUT_START_X + idxInLayer * (_NODE_WIDTH + _LAYOUT_H_GAP)
        new["y"] = _LAYOUT_START_Y + layer * (_NODE_HEIGHT + _LAYOUT_V_GAP)
        # Strip legacy ``position`` so frontend never sees two coordinates.
        new.pop("position", None)
        out.append(new)
    return out
 async def _autoLayoutWorkflow(params: Dict[str, Any], context: Any) -> ToolResult:
    """Re-arrange all nodes of the workflow into a clean top-down layered layout.
    Same algorithm as the editor's "Arrange" button — call this after you
    finished adding/connecting nodes so the user doesn't see an unreadable
    pile of overlapping boxes.
    """
    name = "autoLayoutWorkflow"
    try:
        workflowId, instanceId = _resolveIds(params, context)
        if not workflowId or not instanceId:
            return _err(name, "workflowId and instanceId required (and not present in agent context)")
        iface = _getInterface(context, instanceId)
        wf = iface.getWorkflow(workflowId)
        if not wf:
            return _err(name, f"Workflow {workflowId} not found")
        graph = dict(wf.get("graph", {}) or {})
        nodes = list(graph.get("nodes", []) or [])
        connections = list(graph.get("connections", []) or [])
        if not nodes:
            return _ok(name, {"message": "No nodes to layout", "nodeCount": 0})
        graph["nodes"] = _computeAutoLayout(nodes, connections)
        iface.updateWorkflow(workflowId, {"graph": graph})
        return _ok(name, {
            "message": f"Auto-layout applied to {len(nodes)} nodes",
            "nodeCount": len(nodes),
            "layerCount": max((c.get("y", 0) for c in graph["nodes"]), default=_LAYOUT_START_Y) // (_NODE_HEIGHT + _LAYOUT_V_GAP) + 1,
        })
    except Exception as e:
        logger.exception("autoLayoutWorkflow failed: %s", e)
        return _err(name, str(e))
 async def _validateGraph(params: Dict[str, Any], context: Any) -> ToolResult:
    """Validate a workflow graph for common issues."""
    name = "validateGraph"
@ -507,11 +743,56 @@ def getWorkflowToolDefinitions() -> List[Dict[str, Any]]:
        {
            "name": "listAvailableNodeTypes",
            "handler": _listAvailableNodeTypes,
-            "description": "List all available node types for the flow builder. Call this once to discover ids before using addNode.",
+            "description": (
                "List all available node types (compact catalog: id, label, "
                "description, paramCount, requiredParamCount, usesAi). Call this "
                "once to discover ids; then call describeNodeType for each type "
                "you intend to add to learn the parameter schema."
            ),
            "parameters": {"type": "object", "properties": {}},
            "readOnly": True,
            "toolSet": TOOLBOX_ID,
        },
        {
            "name": "describeNodeType",
            "handler": _describeNodeType,
            "description": (
                "Return the FULL parameter schema for a single node type "
                "(name, type, required, default, allowedValues, description) "
                "plus input/output ports. ALWAYS call this before addNode for "
                "any node type that has requiredParamCount > 0, and pass all "
                "required parameters into addNode — otherwise the user sees an "
                "empty configuration card. For parameters with "
                "frontendType='userConnection' call listConnections to obtain "
                "a connectionId."
            ),
            "parameters": {
                "type": "object",
                "properties": {
                    "nodeType": {"type": "string", "description": "Node type id from listAvailableNodeTypes (e.g. 'email.checkEmail', 'ai.prompt')"},
                },
                "required": ["nodeType"],
            },
            "readOnly": True,
            "toolSet": TOOLBOX_ID,
        },
        {
            "name": "autoLayoutWorkflow",
            "handler": _autoLayoutWorkflow,
            "description": (
                "Re-arrange ALL nodes into a clean top-down layered layout "
                "(same algorithm as the editor's 'Arrange' button). Call this "
                "AFTER you finished adding nodes and connections, otherwise the "
                "user sees a pile of overlapping boxes. Idempotent — safe to "
                "call multiple times."
            ),
            "parameters": {
                "type": "object",
                "properties": {**_idFields},
                "required": [],
            },
            "toolSet": TOOLBOX_ID,
        },
        {
            "name": "validateGraph",
            "handler": _validateGraph,