Feature: allow arbitrary order in proxy group (#89)

2019-08-12 10:11:44 +08:00 · 2019-08-12 10:11:44 +08:00 · 92f3d9ae5b
commit 92f3d9ae5b
parent b6532b1f0f
2 changed files with 129 additions and 1 deletions
--- a/config/config.go
+++ b/config/config.go
@ -293,10 +293,13 @@ func parseProxies(cfg *rawConfig) (map[string]C.Proxy, error) {
 	}
 	// parse proxy group
 	if err := proxyGroupsDagSort(groupsConfig); err != nil {
 		return nil, err
 	}
 	for idx, mapping := range groupsConfig {
 		groupType, existType := mapping["type"].(string)
 		groupName, existName := mapping["name"].(string)
-		if !existType && existName {
+		if !(existType && existName) {
 			return nil, fmt.Errorf("ProxyGroup %d: missing type or name", idx)
 		}
--- a/config/utils.go
+++ b/config/utils.go
@ -34,3 +34,128 @@ func or(pointers ...*int) *int {
 	}
 	return pointers[len(pointers)-1]
 }
 // Check if ProxyGroups form DAG(Directed Acyclic Graph), and sort all ProxyGroups by dependency order.
 // Meanwhile, record the original index in the config file.
 // If loop is detected, return an error with location of loop.
 func proxyGroupsDagSort(groupsConfig []map[string]interface{}) error {
 	type Node struct {
 		indegree int
 		// topological order
 		topo int
 		// the origional data in `groupsConfig`
 		data map[string]interface{}
 		// `outdegree` and `from` are used in loop locating
 		outdegree int
 		from      []string
 	}
 	graph := make(map[string]*Node)
 	// Step 1.1 build dependency graph
 	for idx, mapping := range groupsConfig {
 		// record original order in config file.
 		// this field can be used determinate the display order in FrontEnd.
 		mapping["configIdx"] = idx
 		groupName, existName := mapping["name"].(string)
 		if !existName {
 			return fmt.Errorf("ProxyGroup %d: missing name", idx)
 		}
 		if node, ok := graph[groupName]; ok {
 			if node.data != nil {
 				return fmt.Errorf("ProxyGroup %s: duplicate group name", groupName)
 			}
 			node.data = mapping
 		} else {
 			graph[groupName] = &Node{0, -1, mapping, 0, nil}
 		}
 		proxies, existProxies := mapping["proxies"]
 		if !existProxies {
 			return fmt.Errorf("ProxyGroup %s: the `proxies` field is requried", groupName)
 		}
 		for _, proxy := range proxies.([]interface{}) {
 			proxy := proxy.(string)
 			if node, ex := graph[proxy]; ex {
 				node.indegree++
 			} else {
 				graph[proxy] = &Node{1, -1, nil, 0, nil}
 			}
 		}
 	}
 	// Step 1.2 Topological Sort
 	// topological index of **ProxyGroup**
 	index := 0
 	queue := make([]string, 0)
 	for name, node := range graph {
 		// in the begning, put nodes that have `node.indegree == 0` into queue.
 		if node.indegree == 0 {
 			queue = append(queue, name)
 		}
 	}
 	// every element in queue have indegree == 0
 	for ; len(queue) > 0; queue = queue[1:] {
 		name := queue[0]
 		node := graph[name]
 		if node.data != nil {
 			index++
 			groupsConfig[len(groupsConfig)-index] = node.data
 			for _, proxy := range node.data["proxies"].([]interface{}) {
 				child := graph[proxy.(string)]
 				child.indegree--
 				if child.indegree == 0 {
 					queue = append(queue, proxy.(string))
 				}
 			}
 		}
 		delete(graph, name)
 	}
 	// no loop is detected, return sorted ProxyGroup
 	if len(graph) == 0 {
 		return nil
 	}
 	// if loop is detected, locate the loop and throw an error
 	// Step 2.1 rebuild the graph, fill `outdegree` and `from` filed
 	for name, node := range graph {
 		if node.data == nil {
 			continue
 		}
 		for _, proxy := range node.data["proxies"].([]interface{}) {
 			node.outdegree++
 			child := graph[proxy.(string)]
 			if child.from == nil {
 				child.from = make([]string, 0, child.indegree)
 			}
 			child.from = append(child.from, name)
 		}
 	}
 	// Step 2.2 remove nodes outside the loop. so that we have only the loops remain in `graph`
 	queue = make([]string, 0)
 	// initialize queue with node have outdegree == 0
 	for name, node := range graph {
 		if node.outdegree == 0 {
 			queue = append(queue, name)
 		}
 	}
 	// every element in queue have outdegree == 0
 	for ; len(queue) > 0; queue = queue[1:] {
 		name := queue[0]
 		node := graph[name]
 		for _, f := range node.from {
 			graph[f].outdegree--
 			if graph[f].outdegree == 0 {
 				queue = append(queue, f)
 			}
 		}
 		delete(graph, name)
 	}
 	// Step 2.3 report the elements in loop
 	loopElements := make([]string, 0, len(graph))
 	for name := range graph {
 		loopElements = append(loopElements, name)
 		delete(graph, name)
 	}
 	return fmt.Errorf("Loop is detected in ProxyGroup, please check following ProxyGroups: %v", loopElements)
 }