// Package treeprint provides a simple ASCII tree composing tool.
package treeprint
import (
"bytes"
"fmt"
"io"
"reflect"
"strings"
)
// Value defines any value
type Value interface{}
// MetaValue defines any meta value
type MetaValue interface{}
// NodeVisitor function type for iterating over nodes
type NodeVisitor func(item *Node)
// 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)
SetMetaValue(meta MetaValue)
// VisitAll iterates over the tree, branches and nodes.
// If need to iterate over the whole tree, use the root Node.
// Note this method uses a breadth-first approach.
VisitAll(fn NodeVisitor)
}
type Node struct {
Root *Node
Meta MetaValue
Value Value
Nodes []*Node
}
func (n *Node) FindLastNode() Tree {
ns := n.Nodes
if len(ns) == 0 {
return nil
}
return ns[len(ns)-1]
}
func (n *Node) AddNode(v Value) Tree {
n.Nodes = append(n.Nodes, &Node{
Root: n,
Value: v,
})
return n
}
func (n *Node) AddMetaNode(meta MetaValue, v Value) Tree {
n.Nodes = append(n.Nodes, &Node{
Root: n,
Meta: meta,
Value: v,
})
return n
}
func (n *Node) AddBranch(v Value) Tree {
branch := &Node{
Root: n,
Value: v,
}
n.Nodes = append(n.Nodes, branch)
return branch
}
func (n *Node) AddMetaBranch(meta MetaValue, v Value) Tree {
branch := &Node{
Root: n,
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 {
if n.Meta != nil {
buf.WriteString(fmt.Sprintf("[%v] %v", n.Meta, n.Value))
} else {
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)
}
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 (n *Node) SetMetaValue(meta MetaValue) {
n.Meta = meta
}
func (n *Node) VisitAll(fn NodeVisitor) {
for _, node := range n.Nodes {
fn(node)
if len(node.Nodes) > 0 {
node.VisitAll(fn)
continue
}
}
}
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)
if len(node.Nodes) > 0 {
printNodes(wr, level+1, levelsEnded, node.Nodes)
}
}
}
func printValues(wr io.Writer,
level int, levelsEnded []int, edge EdgeType, node *Node) {
for i := 0; i < level; i++ {
if isEnded(levelsEnded, i) {
fmt.Fprint(wr, strings.Repeat(" ", IndentSize+1))
continue
}
fmt.Fprintf(wr, "%s%s", EdgeTypeLink, strings.Repeat(" ", IndentSize))
}
val := renderValue(level, node)
meta := node.Meta
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
}
func renderValue(level int, node *Node) Value {
lines := strings.Split(fmt.Sprintf("%v", node.Value), "\n")
// If value does not contain multiple lines, return itself.
if len(lines) < 2 {
return node.Value
}
// If value contains multiple lines,
// generate a padding and prefix each line with it.
pad := padding(level, node)
for i := 1; i < len(lines); i++ {
lines[i] = fmt.Sprintf("%s%s", pad, lines[i])
}
return strings.Join(lines, "\n")
}
// padding returns a padding for the multiline values with correctly placed link edges.
// It is generated by traversing the tree upwards (from leaf to the root of the tree)
// and, on each level, checking if the Node the last one of its siblings.
// If a Node is the last one, the padding on that level should be empty (there's nothing to link to below it).
// If a Node is not the last one, the padding on that level should be the link edge so the sibling below is correctly connected.
func padding(level int, node *Node) string {
links := make([]string, level+1)
for node.Root != nil {
if isLast(node) {
links[level] = strings.Repeat(" ", IndentSize+1)
} else {
links[level] = fmt.Sprintf("%s%s", EdgeTypeLink, strings.Repeat(" ", IndentSize))
}
level--
node = node.Root
}
return strings.Join(links, "")
}
// isLast checks if the Node is the last one in the slice of its parent children
func isLast(n *Node) bool {
return n == n.Root.FindLastNode()
}
type EdgeType string
var (
EdgeTypeLink EdgeType = "│"
EdgeTypeMid EdgeType = "├──"
EdgeTypeEnd EdgeType = "└──"
)
// IndentSize is the number of spaces per tree level.
var IndentSize = 3
// New Generates new tree
func New() Tree {
return &Node{Value: "."}
}
// NewWithRoot Generates new tree with the given root value
func NewWithRoot(root Value) Tree {
return &Node{Value: root}
}