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coze-studio/backend/domain/workflow/internal/canvas/validate/canvas_validate.go

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/*
* Copyright 2025 coze-dev Authors
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package validate
import (
"context"
"fmt"
"regexp"
"strconv"
"github.com/coze-dev/coze-studio/backend/domain/workflow"
"github.com/coze-dev/coze-studio/backend/domain/workflow/entity"
"github.com/coze-dev/coze-studio/backend/domain/workflow/entity/vo"
"github.com/coze-dev/coze-studio/backend/domain/workflow/internal/canvas/convert"
"github.com/coze-dev/coze-studio/backend/domain/workflow/internal/nodes"
"github.com/coze-dev/coze-studio/backend/domain/workflow/internal/schema"
"github.com/coze-dev/coze-studio/backend/domain/workflow/variable"
"github.com/coze-dev/coze-studio/backend/pkg/sonic"
"github.com/coze-dev/coze-studio/backend/types/errno"
)
type Issue struct {
NodeErr *NodeErr
PathErr *PathErr
Message string
}
type NodeErr struct {
NodeID string `json:"nodeID"`
NodeName string `json:"nodeName"`
}
type PathErr struct {
StartNode string `json:"start"`
EndNode string `json:"end"`
}
type reachability struct {
reachableNodes map[string]*vo.Node
nestedReachability map[string]*reachability
}
type Config struct {
Canvas *vo.Canvas
AppID *int64
AgentID *int64
VariablesMetaGetter variable.VariablesMetaGetter
}
type CanvasValidator struct {
cfg *Config
reachability *reachability
}
func NewCanvasValidator(_ context.Context, cfg *Config) (*CanvasValidator, error) {
if cfg == nil {
return nil, fmt.Errorf("config is required")
}
if cfg.Canvas == nil {
return nil, fmt.Errorf("canvas is required")
}
reachability, err := analyzeCanvasReachability(cfg.Canvas)
if err != nil {
return nil, err
}
return &CanvasValidator{reachability: reachability, cfg: cfg}, nil
}
func (cv *CanvasValidator) DetectCycles(_ context.Context) (issues []*Issue, err error) {
issues = make([]*Issue, 0)
nodeIDs := make([]string, 0)
for _, node := range cv.cfg.Canvas.Nodes {
nodeIDs = append(nodeIDs, node.ID)
}
controlSuccessors := map[string][]string{}
for _, e := range cv.cfg.Canvas.Edges {
controlSuccessors[e.TargetNodeID] = append(controlSuccessors[e.TargetNodeID], e.SourceNodeID)
}
cycles := detectCycles(nodeIDs, controlSuccessors)
if len(cycles) == 0 {
return issues, nil
}
for _, cycle := range cycles {
n := len(cycle)
for i := 0; i < n; i++ {
if cycle[i] == cycle[(i+1)%n] {
continue
}
issues = append(issues, &Issue{
PathErr: &PathErr{
StartNode: cycle[i],
EndNode: cycle[(i+1)%n],
},
Message: "line connections do not allow parallel lines to intersect and form loops with each other",
})
}
}
return issues, nil
}
func (cv *CanvasValidator) ValidateConnections(ctx context.Context) (issues []*Issue, err error) {
issues, err = validateConnections(ctx, cv.cfg.Canvas)
if err != nil {
return issues, err
}
return issues, nil
}
func (cv *CanvasValidator) CheckRefVariable(_ context.Context) (issues []*Issue, err error) {
issues = make([]*Issue, 0)
var checkRefVariable func(reachability *reachability, reachableNodes map[string]bool) error
checkRefVariable = func(reachability *reachability, parentReachableNodes map[string]bool) error {
currentReachableNodes := make(map[string]bool)
combinedReachable := make(map[string]bool)
for _, node := range reachability.reachableNodes {
currentReachableNodes[node.ID] = true
combinedReachable[node.ID] = true
}
if parentReachableNodes != nil {
for id := range parentReachableNodes {
combinedReachable[id] = true
}
}
var inputBlockVerify func(node *vo.Node, ref *vo.BlockInput) error
inputBlockVerify = func(node *vo.Node, inputBlock *vo.BlockInput) error {
if inputBlock.Value.Type != vo.BlockInputValueTypeRef {
return nil
}
ref, err := parseBlockInputRef(inputBlock.Value.Content)
if err != nil {
return err
}
if ref.Source == vo.RefSourceTypeGlobalApp || ref.Source == vo.RefSourceTypeGlobalSystem || ref.Source == vo.RefSourceTypeGlobalUser {
return nil
}
if ref.Source == vo.RefSourceTypeBlockOutput && ref.BlockID == "" {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: node.Data.Meta.Title,
},
Message: `ref block error,[blockID] is empty`,
})
return nil
}
if _, exists := combinedReachable[ref.BlockID]; !exists {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: node.Data.Meta.Title,
},
Message: fmt.Sprintf(`the node id "%s" on which node id "%s" depends does not exist`, node.ID, ref.BlockID),
})
}
return nil
}
for nodeID, node := range reachability.reachableNodes {
if node.Data != nil && node.Data.Inputs != nil && node.Data.Inputs.InputParameters != nil { // only validate InputParameters
parameters := node.Data.Inputs.InputParameters
for _, p := range parameters {
if p.Input != nil {
valid := validateInputParameterName(p.Name)
if !valid {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: nodeID,
NodeName: node.Data.Meta.Title,
},
Message: fmt.Sprintf(`parameter name only allows number or alphabet, and must begin with alphabet, but it's "%s"`, p.Name),
})
}
err = inputBlockVerify(node, p.Input)
if err != nil {
return err
}
}
if p.Left != nil {
err = inputBlockVerify(node, p.Left)
if err != nil {
return err
}
}
if p.Right != nil {
err = inputBlockVerify(node, p.Right)
if err != nil {
return err
}
}
}
}
}
for _, r := range reachability.nestedReachability {
err := checkRefVariable(r, currentReachableNodes)
if err != nil {
return err
}
}
return nil
}
err = checkRefVariable(cv.reachability, nil)
if err != nil {
return nil, err
}
return issues, nil
}
func (cv *CanvasValidator) ValidateNestedFlows(_ context.Context) (issues []*Issue, err error) {
issues = make([]*Issue, 0)
for nodeID, node := range cv.reachability.reachableNodes {
if nestedReachableNodes, ok := cv.reachability.nestedReachability[nodeID]; ok && len(nestedReachableNodes.nestedReachability) > 0 {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: nodeID,
NodeName: node.Data.Meta.Title,
},
Message: "composite nodes such as batch/loop cannot be nested",
})
}
}
return issues, nil
}
func (cv *CanvasValidator) CheckGlobalVariables(ctx context.Context) (issues []*Issue, err error) {
if cv.cfg.AppID == nil && cv.cfg.AgentID == nil {
return issues, nil
}
type nodeVars struct {
node *vo.Node
vars map[string]*vo.TypeInfo
}
nVars := make([]*nodeVars, 0)
for _, node := range cv.cfg.Canvas.Nodes {
if node.Type == entity.NodeTypeComment.IDStr() {
continue
}
if node.Type == entity.NodeTypeVariableAssigner.IDStr() {
v := &nodeVars{node: node, vars: make(map[string]*vo.TypeInfo)}
for _, p := range node.Data.Inputs.InputParameters {
v.vars[p.Name], err = convert.CanvasBlockInputToTypeInfo(p.Left)
if err != nil {
return nil, err
}
}
nVars = append(nVars, v)
}
}
if len(nVars) == 0 {
return issues, nil
}
var varsMeta map[string]*vo.TypeInfo
if cv.cfg.AppID != nil {
varsMeta, err = cv.cfg.VariablesMetaGetter.GetAppVariablesMeta(ctx, strconv.FormatInt(*cv.cfg.AppID, 10), "")
} else {
varsMeta, err = cv.cfg.VariablesMetaGetter.GetAgentVariablesMeta(ctx, *cv.cfg.AgentID, "")
}
for _, nodeVar := range nVars {
nodeName := nodeVar.node.Data.Meta.Title
nodeID := nodeVar.node.ID
for v, info := range nodeVar.vars {
vInfo, ok := varsMeta[v]
if !ok {
continue
}
if vInfo.Type != info.Type {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: nodeID,
NodeName: nodeName,
},
Message: fmt.Sprintf("node name %v,param [%s], type mismatch", nodeName, v),
})
}
if vInfo.Type == vo.DataTypeArray && info.Type == vo.DataTypeArray {
if vInfo.ElemTypeInfo.Type != info.ElemTypeInfo.Type {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: nodeID,
NodeName: nodeName,
},
Message: fmt.Sprintf("node name %v, param [%s], array element type mismatch", nodeName, v),
})
}
}
}
}
return issues, nil
}
func (cv *CanvasValidator) CheckSubWorkFlowTerminatePlanType(ctx context.Context) (issues []*Issue, err error) {
issues = make([]*Issue, 0)
subWfMap := make([]*vo.Node, 0)
var (
draftIDs []int64
subID2SubVersion = map[int64]string{}
)
var collectSubWorkFlowNodes func(nodes []*vo.Node)
collectSubWorkFlowNodes = func(nodes []*vo.Node) {
for _, n := range nodes {
if n.Type == entity.NodeTypeSubWorkflow.IDStr() {
subWfMap = append(subWfMap, n)
wID, err := strconv.ParseInt(n.Data.Inputs.WorkflowID, 10, 64)
if err != nil {
return
}
if len(n.Data.Inputs.WorkflowVersion) > 0 {
subID2SubVersion[wID] = n.Data.Inputs.WorkflowVersion
} else {
draftIDs = append(draftIDs, wID)
}
}
if len(n.Blocks) > 0 {
collectSubWorkFlowNodes(n.Blocks)
}
}
}
collectSubWorkFlowNodes(cv.cfg.Canvas.Nodes)
if len(subWfMap) == 0 {
return issues, nil
}
wfID2Canvas := make(map[int64]*vo.Canvas)
if len(draftIDs) > 0 {
wfs, _, err := workflow.GetRepository().MGetDrafts(ctx, &vo.MGetPolicy{
MetaQuery: vo.MetaQuery{
IDs: draftIDs,
},
})
if err != nil {
return nil, err
}
for _, draft := range wfs {
var canvas vo.Canvas
if err = sonic.UnmarshalString(draft.Canvas, &canvas); err != nil {
return nil, err
}
wfID2Canvas[draft.ID] = &canvas
}
}
if len(subID2SubVersion) > 0 {
for id, version := range subID2SubVersion {
v, err := workflow.GetRepository().GetVersion(ctx, id, version)
if err != nil {
return nil, err
}
var canvas vo.Canvas
if err = sonic.UnmarshalString(v.Canvas, &canvas); err != nil {
return nil, err
}
wfID2Canvas[id] = &canvas
}
}
for _, node := range subWfMap {
wfID, err := strconv.ParseInt(node.Data.Inputs.WorkflowID, 10, 64)
if err != nil {
return nil, err
}
if c, ok := wfID2Canvas[wfID]; !ok {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: node.Data.Meta.Title,
},
Message: "sub workflow has been modified, please refresh the page",
})
} else {
_, endNode, err := findStartAndEndNodes(c.Nodes)
if err != nil {
return nil, err
}
if endNode != nil {
if string(*endNode.Data.Inputs.TerminatePlan) != toTerminatePlan(node.Data.Inputs.TerminationType) {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: node.Data.Meta.Title,
},
Message: "sub workflow has been modified, please refresh the page",
})
}
}
}
}
return issues, nil
}
func validateConnections(ctx context.Context, c *vo.Canvas) (issues []*Issue, err error) {
issues = make([]*Issue, 0)
nodeMap := buildNodeMap(c)
for _, node := range nodeMap {
if len(node.Blocks) > 0 && len(node.Edges) > 0 {
n := &vo.Node{
ID: node.ID,
Type: node.Type,
Data: node.Data,
}
nestedCanvas := &vo.Canvas{
Nodes: append(node.Blocks, n),
Edges: node.Edges,
}
is, err := validateConnections(ctx, nestedCanvas)
if err != nil {
return nil, err
}
issues = append(issues, is...)
}
}
outDegree := make(map[string]int)
selectorPorts := make(map[string]map[string]bool)
for nodeID, node := range nodeMap {
if node.Data.Inputs != nil && node.Data.Inputs.SettingOnError != nil &&
node.Data.Inputs.SettingOnError.ProcessType != nil &&
*node.Data.Inputs.SettingOnError.ProcessType == vo.ErrorProcessTypeExceptionBranch {
if _, exists := selectorPorts[nodeID]; !exists {
selectorPorts[nodeID] = make(map[string]bool)
}
selectorPorts[nodeID][schema.PortBranchError] = true
selectorPorts[nodeID][schema.PortDefault] = true
}
ba, ok := nodes.GetBranchAdaptor(entity.IDStrToNodeType(node.Type))
if ok {
expects := ba.ExpectPorts(ctx, node)
if len(expects) > 0 {
if _, exists := selectorPorts[nodeID]; !exists {
selectorPorts[nodeID] = make(map[string]bool)
}
for _, e := range expects {
selectorPorts[nodeID][e] = true
}
}
}
}
for _, edge := range c.Edges {
outDegree[edge.SourceNodeID]++
}
portOutDegree := make(map[string]map[string]int) // Node ID - > Port - > Outgoing
for _, edge := range c.Edges {
if _, ok := selectorPorts[edge.SourceNodeID]; !ok {
continue
}
if _, exists := portOutDegree[edge.SourceNodeID]; !exists {
portOutDegree[edge.SourceNodeID] = make(map[string]int)
}
portOutDegree[edge.SourceNodeID][edge.SourcePortID]++
}
for nodeID, node := range nodeMap {
nodeName := node.Data.Meta.Title
switch et := entity.IDStrToNodeType(node.Type); et {
case entity.NodeTypeEntry:
if outDegree[nodeID] == 0 {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: nodeID,
NodeName: nodeName,
},
Message: `node "start" not connected`,
})
}
case entity.NodeTypeExit:
default:
if ports, isSelector := selectorPorts[nodeID]; isSelector {
message := ""
for port := range ports {
if portOutDegree[nodeID][port] == 0 {
message += fmt.Sprintf(`node "%v"'s port "%v" not connected;`, nodeName, port)
}
}
if len(message) > 0 {
selectorIssues := &Issue{NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: nodeName,
}, Message: message}
issues = append(issues, selectorIssues)
}
} else {
// Break, continue without checking out degrees
if et == entity.NodeTypeBreak || et == entity.NodeTypeContinue {
continue
}
if outDegree[nodeID] == 0 {
issues = append(issues, &Issue{
NodeErr: &NodeErr{
NodeID: node.ID,
NodeName: nodeName,
},
Message: fmt.Sprintf(`node "%v" not connected`, nodeName),
})
}
}
}
}
return issues, nil
}
func analyzeCanvasReachability(c *vo.Canvas) (*reachability, error) {
nodeMap := buildNodeMap(c)
reachable := &reachability{}
if err := processNestedReachability(c, reachable); err != nil {
return nil, err
}
startNode, _, err := findStartAndEndNodes(c.Nodes)
if err != nil {
return nil, err
}
edgeMap := make(map[string][]string)
for _, edge := range c.Edges {
edgeMap[edge.SourceNodeID] = append(edgeMap[edge.SourceNodeID], edge.TargetNodeID)
}
reachable.reachableNodes, err = performReachabilityAnalysis(nodeMap, edgeMap, startNode)
if err != nil {
return nil, err
}
return reachable, nil
}
func buildNodeMap(c *vo.Canvas) map[string]*vo.Node {
nodeMap := make(map[string]*vo.Node, len(c.Nodes))
for _, node := range c.Nodes {
nodeMap[node.ID] = node
}
return nodeMap
}
func processNestedReachability(c *vo.Canvas, r *reachability) error {
for _, node := range c.Nodes {
if len(node.Blocks) > 0 && len(node.Edges) > 0 {
nestedCanvas := &vo.Canvas{
Nodes: append([]*vo.Node{
{
ID: node.ID,
Type: entity.NodeTypeEntry.IDStr(),
Data: node.Data,
},
{
ID: node.ID,
Type: entity.NodeTypeExit.IDStr(),
},
}, node.Blocks...),
Edges: node.Edges,
}
nestedReachable, err := analyzeCanvasReachability(nestedCanvas)
if err != nil {
return fmt.Errorf("processing nested canvas for node %s: %w", node.ID, err)
}
if r.nestedReachability == nil {
r.nestedReachability = make(map[string]*reachability)
}
r.nestedReachability[node.ID] = nestedReachable
}
}
return nil
}
func findStartAndEndNodes(nodes []*vo.Node) (*vo.Node, *vo.Node, error) {
var startNode, endNode *vo.Node
for _, node := range nodes {
switch node.Type {
case entity.NodeTypeEntry.IDStr():
startNode = node
case entity.NodeTypeExit.IDStr():
endNode = node
}
}
if startNode == nil {
return nil, nil, fmt.Errorf("start node not found")
}
if endNode == nil {
return nil, nil, fmt.Errorf("end node not found")
}
return startNode, endNode, nil
}
func performReachabilityAnalysis(nodeMap map[string]*vo.Node, edgeMap map[string][]string, startNode *vo.Node) (map[string]*vo.Node, error) {
result := make(map[string]*vo.Node)
result[startNode.ID] = startNode
queue := []string{startNode.ID}
visited := make(map[string]bool)
visited[startNode.ID] = true
for len(queue) > 0 {
currentID := queue[0]
queue = queue[1:]
for _, targetNodeID := range edgeMap[currentID] {
if !visited[targetNodeID] {
visited[targetNodeID] = true
node, ok := nodeMap[targetNodeID]
if !ok {
return nil, fmt.Errorf("node not found for %s in nodeMap", targetNodeID)
}
result[targetNodeID] = node
queue = append(queue, targetNodeID)
}
}
}
return result, nil
}
func toTerminatePlan(p int) string {
switch p {
case 0:
return "returnVariables"
case 1:
return "useAnswerContent"
default:
return ""
}
}
func detectCycles(nodes []string, controlSuccessors map[string][]string) [][]string {
visited := map[string]bool{}
var dfs func(path []string) [][]string
dfs = func(path []string) [][]string {
var ret [][]string
pathEnd := path[len(path)-1]
successors, ok := controlSuccessors[pathEnd]
if !ok {
return nil
}
for _, successor := range successors {
visited[successor] = true
var looped bool
for i, node := range path {
if node == successor {
ret = append(ret, append(path[i:], successor))
looped = true
break
}
}
if looped {
continue
}
ret = append(ret, dfs(append(path, successor))...)
}
return ret
}
var ret [][]string
for _, node := range nodes {
if !visited[node] {
ret = append(ret, dfs([]string{node})...)
}
}
return ret
}
func parseBlockInputRef(content any) (*vo.BlockInputReference, error) {
m, ok := content.(map[string]any)
if !ok {
return nil, fmt.Errorf("invalid content type: %T when parse BlockInputRef", content)
}
marshaled, err := sonic.Marshal(m)
if err != nil {
return nil, vo.WrapError(errno.ErrSerializationDeserializationFail, err)
}
p := &vo.BlockInputReference{}
if err = sonic.Unmarshal(marshaled, p); err != nil {
return nil, vo.WrapError(errno.ErrSerializationDeserializationFail, err)
}
return p, nil
}
var validateNameRegex = regexp.MustCompile(`^[A-Za-z_][A-Za-z0-9_]*$`)
func validateInputParameterName(name string) bool {
return validateNameRegex.Match([]byte(name))
}
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