// Package treeprint provides a simple ASCII tree composing tool. package treeprint import ( "bytes" "fmt" "io" "reflect" ) type Value interface{} type MetaValue interface{} // Tree represents a tree structure with leaf-nodes and branch-nodes. type Tree interface { // AddNode adds a new node to a branch. AddNode(v Value) Tree // AddMetaNode adds a new node with meta value provided to a branch. AddMetaNode(meta MetaValue, v Value) Tree // AddBranch adds a new branch node (a level deeper). AddBranch(v Value) Tree // AddMetaBranch adds a new branch node (a level deeper) with meta value provided. AddMetaBranch(meta MetaValue, v Value) Tree // Branch converts a leaf-node to a branch-node, // applying this on a branch-node does no effect. Branch() Tree // FindByMeta finds a node whose meta value matches the provided one by reflect.DeepEqual, // returns nil if not found. FindByMeta(meta MetaValue) Tree // FindByValue finds a node whose value matches the provided one by reflect.DeepEqual, // returns nil if not found. FindByValue(value Value) Tree // returns the last node of a tree FindLastNode() Tree // String renders the tree or subtree as a string. String() string // Bytes renders the tree or subtree as byteslice. Bytes() []byte SetValue(value Value) } type node struct { Root *node Meta MetaValue Value Value Nodes []*node } func (n *node) FindLastNode() Tree { ns := n.Nodes n = ns[len(ns)-1] return n } func (n *node) AddNode(v Value) Tree { n.Nodes = append(n.Nodes, &node{ Root: n, Value: v, }) if n.Root != nil { return n.Root } return n } func (n *node) AddMetaNode(meta MetaValue, v Value) Tree { n.Nodes = append(n.Nodes, &node{ Root: n, Meta: meta, Value: v, }) if n.Root != nil { return n.Root } return n } func (n *node) AddBranch(v Value) Tree { branch := &node{ Value: v, } n.Nodes = append(n.Nodes, branch) return branch } func (n *node) AddMetaBranch(meta MetaValue, v Value) Tree { branch := &node{ Meta: meta, Value: v, } n.Nodes = append(n.Nodes, branch) return branch } func (n *node) Branch() Tree { n.Root = nil return n } func (n *node) FindByMeta(meta MetaValue) Tree { for _, node := range n.Nodes { if reflect.DeepEqual(node.Meta, meta) { return node } if v := node.FindByMeta(meta); v != nil { return v } } return nil } func (n *node) FindByValue(value Value) Tree { for _, node := range n.Nodes { if reflect.DeepEqual(node.Value, value) { return node } if v := node.FindByMeta(value); v != nil { return v } } return nil } func (n *node) Bytes() []byte { buf := new(bytes.Buffer) level := 0 var levelsEnded []int if n.Root == nil { buf.WriteString(fmt.Sprintf("%v",n.Value)) buf.WriteByte('\n') } else { edge := EdgeTypeMid if len(n.Nodes) == 0 { edge = EdgeTypeEnd levelsEnded = append(levelsEnded, level) } printValues(buf, 0, levelsEnded, edge, n.Meta, n.Value) } if len(n.Nodes) > 0 { printNodes(buf, level, levelsEnded, n.Nodes) } return buf.Bytes() } func (n *node) String() string { return string(n.Bytes()) } func (n *node) SetValue(value Value){ n.Value = value } func printNodes(wr io.Writer, level int, levelsEnded []int, nodes []*node) { for i, node := range nodes { edge := EdgeTypeMid if i == len(nodes)-1 { levelsEnded = append(levelsEnded, level) edge = EdgeTypeEnd } printValues(wr, level, levelsEnded, edge, node.Meta, node.Value) if len(node.Nodes) > 0 { printNodes(wr, level+1, levelsEnded, node.Nodes) } } } func printValues(wr io.Writer, level int, levelsEnded []int, edge EdgeType, meta MetaValue, val Value) { for i := 0; i < level; i++ { if isEnded(levelsEnded, i) { fmt.Fprint(wr, " ") continue } fmt.Fprintf(wr, "%s   ", EdgeTypeLink) } if meta != nil { fmt.Fprintf(wr, "%s [%v] %v\n", edge, meta, val) return } fmt.Fprintf(wr, "%s %v\n", edge, val) } func isEnded(levelsEnded []int, level int) bool { for _, l := range levelsEnded { if l == level { return true } } return false } type EdgeType string var ( EdgeTypeLink EdgeType = "│" EdgeTypeMid EdgeType = "├──" EdgeTypeEnd EdgeType = "└──" ) func New() Tree { return &node{Value: "."} }