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forgejo/vendor/github.com/pelletier/go-toml/toml.go

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package toml
import (
"errors"
"fmt"
"io"
"io/ioutil"
"os"
"runtime"
"strings"
)
type tomlValue struct {
value interface{} // string, int64, uint64, float64, bool, time.Time, [] of any of this list
comment string
commented bool
multiline bool
literal bool
position Position
}
// Tree is the result of the parsing of a TOML file.
type Tree struct {
values map[string]interface{} // string -> *tomlValue, *Tree, []*Tree
comment string
commented bool
inline bool
position Position
}
func newTree() *Tree {
return newTreeWithPosition(Position{})
}
func newTreeWithPosition(pos Position) *Tree {
return &Tree{
values: make(map[string]interface{}),
position: pos,
}
}
// TreeFromMap initializes a new Tree object using the given map.
func TreeFromMap(m map[string]interface{}) (*Tree, error) {
result, err := toTree(m)
if err != nil {
return nil, err
}
return result.(*Tree), nil
}
// Position returns the position of the tree.
func (t *Tree) Position() Position {
return t.position
}
// Has returns a boolean indicating if the given key exists.
func (t *Tree) Has(key string) bool {
if key == "" {
return false
}
return t.HasPath(strings.Split(key, "."))
}
// HasPath returns true if the given path of keys exists, false otherwise.
func (t *Tree) HasPath(keys []string) bool {
return t.GetPath(keys) != nil
}
// Keys returns the keys of the toplevel tree (does not recurse).
func (t *Tree) Keys() []string {
keys := make([]string, len(t.values))
i := 0
for k := range t.values {
keys[i] = k
i++
}
return keys
}
// Get the value at key in the Tree.
// Key is a dot-separated path (e.g. a.b.c) without single/double quoted strings.
// If you need to retrieve non-bare keys, use GetPath.
// Returns nil if the path does not exist in the tree.
// If keys is of length zero, the current tree is returned.
func (t *Tree) Get(key string) interface{} {
if key == "" {
return t
}
return t.GetPath(strings.Split(key, "."))
}
// GetPath returns the element in the tree indicated by 'keys'.
// If keys is of length zero, the current tree is returned.
func (t *Tree) GetPath(keys []string) interface{} {
if len(keys) == 0 {
return t
}
subtree := t
for _, intermediateKey := range keys[:len(keys)-1] {
value, exists := subtree.values[intermediateKey]
if !exists {
return nil
}
switch node := value.(type) {
case *Tree:
subtree = node
case []*Tree:
// go to most recent element
if len(node) == 0 {
return nil
}
subtree = node[len(node)-1]
default:
return nil // cannot navigate through other node types
}
}
// branch based on final node type
switch node := subtree.values[keys[len(keys)-1]].(type) {
case *tomlValue:
return node.value
default:
return node
}
}
// GetArray returns the value at key in the Tree.
// It returns []string, []int64, etc type if key has homogeneous lists
// Key is a dot-separated path (e.g. a.b.c) without single/double quoted strings.
// Returns nil if the path does not exist in the tree.
// If keys is of length zero, the current tree is returned.
func (t *Tree) GetArray(key string) interface{} {
if key == "" {
return t
}
return t.GetArrayPath(strings.Split(key, "."))
}
// GetArrayPath returns the element in the tree indicated by 'keys'.
// If keys is of length zero, the current tree is returned.
func (t *Tree) GetArrayPath(keys []string) interface{} {
if len(keys) == 0 {
return t
}
subtree := t
for _, intermediateKey := range keys[:len(keys)-1] {
value, exists := subtree.values[intermediateKey]
if !exists {
return nil
}
switch node := value.(type) {
case *Tree:
subtree = node
case []*Tree:
// go to most recent element
if len(node) == 0 {
return nil
}
subtree = node[len(node)-1]
default:
return nil // cannot navigate through other node types
}
}
// branch based on final node type
switch node := subtree.values[keys[len(keys)-1]].(type) {
case *tomlValue:
switch n := node.value.(type) {
case []interface{}:
return getArray(n)
default:
return node.value
}
default:
return node
}
}
// if homogeneous array, then return slice type object over []interface{}
func getArray(n []interface{}) interface{} {
var s []string
var i64 []int64
var f64 []float64
var bl []bool
for _, value := range n {
switch v := value.(type) {
case string:
s = append(s, v)
case int64:
i64 = append(i64, v)
case float64:
f64 = append(f64, v)
case bool:
bl = append(bl, v)
default:
return n
}
}
if len(s) == len(n) {
return s
} else if len(i64) == len(n) {
return i64
} else if len(f64) == len(n) {
return f64
} else if len(bl) == len(n) {
return bl
}
return n
}
// GetPosition returns the position of the given key.
func (t *Tree) GetPosition(key string) Position {
if key == "" {
return t.position
}
return t.GetPositionPath(strings.Split(key, "."))
}
// SetPositionPath sets the position of element in the tree indicated by 'keys'.
// If keys is of length zero, the current tree position is set.
func (t *Tree) SetPositionPath(keys []string, pos Position) {
if len(keys) == 0 {
t.position = pos
return
}
subtree := t
for _, intermediateKey := range keys[:len(keys)-1] {
value, exists := subtree.values[intermediateKey]
if !exists {
return
}
switch node := value.(type) {
case *Tree:
subtree = node
case []*Tree:
// go to most recent element
if len(node) == 0 {
return
}
subtree = node[len(node)-1]
default:
return
}
}
// branch based on final node type
switch node := subtree.values[keys[len(keys)-1]].(type) {
case *tomlValue:
node.position = pos
return
case *Tree:
node.position = pos
return
case []*Tree:
// go to most recent element
if len(node) == 0 {
return
}
node[len(node)-1].position = pos
return
}
}
// GetPositionPath returns the element in the tree indicated by 'keys'.
// If keys is of length zero, the current tree is returned.
func (t *Tree) GetPositionPath(keys []string) Position {
if len(keys) == 0 {
return t.position
}
subtree := t
for _, intermediateKey := range keys[:len(keys)-1] {
value, exists := subtree.values[intermediateKey]
if !exists {
return Position{0, 0}
}
switch node := value.(type) {
case *Tree:
subtree = node
case []*Tree:
// go to most recent element
if len(node) == 0 {
return Position{0, 0}
}
subtree = node[len(node)-1]
default:
return Position{0, 0}
}
}
// branch based on final node type
switch node := subtree.values[keys[len(keys)-1]].(type) {
case *tomlValue:
return node.position
case *Tree:
return node.position
case []*Tree:
// go to most recent element
if len(node) == 0 {
return Position{0, 0}
}
return node[len(node)-1].position
default:
return Position{0, 0}
}
}
// GetDefault works like Get but with a default value
func (t *Tree) GetDefault(key string, def interface{}) interface{} {
val := t.Get(key)
if val == nil {
return def
}
return val
}
// SetOptions arguments are supplied to the SetWithOptions and SetPathWithOptions functions to modify marshalling behaviour.
// The default values within the struct are valid default options.
type SetOptions struct {
Comment string
Commented bool
Multiline bool
Literal bool
}
// SetWithOptions is the same as Set, but allows you to provide formatting
// instructions to the key, that will be used by Marshal().
func (t *Tree) SetWithOptions(key string, opts SetOptions, value interface{}) {
t.SetPathWithOptions(strings.Split(key, "."), opts, value)
}
// SetPathWithOptions is the same as SetPath, but allows you to provide
// formatting instructions to the key, that will be reused by Marshal().
func (t *Tree) SetPathWithOptions(keys []string, opts SetOptions, value interface{}) {
subtree := t
for i, intermediateKey := range keys[:len(keys)-1] {
nextTree, exists := subtree.values[intermediateKey]
if !exists {
nextTree = newTreeWithPosition(Position{Line: t.position.Line + i, Col: t.position.Col})
subtree.values[intermediateKey] = nextTree // add new element here
}
switch node := nextTree.(type) {
case *Tree:
subtree = node
case []*Tree:
// go to most recent element
if len(node) == 0 {
// create element if it does not exist
node = append(node, newTreeWithPosition(Position{Line: t.position.Line + i, Col: t.position.Col}))
subtree.values[intermediateKey] = node
}
subtree = node[len(node)-1]
}
}
var toInsert interface{}
switch v := value.(type) {
case *Tree:
v.comment = opts.Comment
v.commented = opts.Commented
toInsert = value
case []*Tree:
for i := range v {
v[i].commented = opts.Commented
}
toInsert = value
case *tomlValue:
v.comment = opts.Comment
v.commented = opts.Commented
v.multiline = opts.Multiline
v.literal = opts.Literal
toInsert = v
default:
toInsert = &tomlValue{value: value,
comment: opts.Comment,
commented: opts.Commented,
multiline: opts.Multiline,
literal: opts.Literal,
position: Position{Line: subtree.position.Line + len(subtree.values) + 1, Col: subtree.position.Col}}
}
subtree.values[keys[len(keys)-1]] = toInsert
}
// Set an element in the tree.
// Key is a dot-separated path (e.g. a.b.c).
// Creates all necessary intermediate trees, if needed.
func (t *Tree) Set(key string, value interface{}) {
t.SetWithComment(key, "", false, value)
}
// SetWithComment is the same as Set, but allows you to provide comment
// information to the key, that will be reused by Marshal().
func (t *Tree) SetWithComment(key string, comment string, commented bool, value interface{}) {
t.SetPathWithComment(strings.Split(key, "."), comment, commented, value)
}
// SetPath sets an element in the tree.
// Keys is an array of path elements (e.g. {"a","b","c"}).
// Creates all necessary intermediate trees, if needed.
func (t *Tree) SetPath(keys []string, value interface{}) {
t.SetPathWithComment(keys, "", false, value)
}
// SetPathWithComment is the same as SetPath, but allows you to provide comment
// information to the key, that will be reused by Marshal().
func (t *Tree) SetPathWithComment(keys []string, comment string, commented bool, value interface{}) {
t.SetPathWithOptions(keys, SetOptions{Comment: comment, Commented: commented}, value)
}
// Delete removes a key from the tree.
// Key is a dot-separated path (e.g. a.b.c).
func (t *Tree) Delete(key string) error {
keys, err := parseKey(key)
if err != nil {
return err
}
return t.DeletePath(keys)
}
// DeletePath removes a key from the tree.
// Keys is an array of path elements (e.g. {"a","b","c"}).
func (t *Tree) DeletePath(keys []string) error {
keyLen := len(keys)
if keyLen == 1 {
delete(t.values, keys[0])
return nil
}
tree := t.GetPath(keys[:keyLen-1])
item := keys[keyLen-1]
switch node := tree.(type) {
case *Tree:
delete(node.values, item)
return nil
}
return errors.New("no such key to delete")
}
// createSubTree takes a tree and a key and create the necessary intermediate
// subtrees to create a subtree at that point. In-place.
//
// e.g. passing a.b.c will create (assuming tree is empty) tree[a], tree[a][b]
// and tree[a][b][c]
//
// Returns nil on success, error object on failure
func (t *Tree) createSubTree(keys []string, pos Position) error {
subtree := t
for i, intermediateKey := range keys {
nextTree, exists := subtree.values[intermediateKey]
if !exists {
tree := newTreeWithPosition(Position{Line: t.position.Line + i, Col: t.position.Col})
tree.position = pos
tree.inline = subtree.inline
subtree.values[intermediateKey] = tree
nextTree = tree
}
switch node := nextTree.(type) {
case []*Tree:
subtree = node[len(node)-1]
case *Tree:
subtree = node
default:
return fmt.Errorf("unknown type for path %s (%s): %T (%#v)",
strings.Join(keys, "."), intermediateKey, nextTree, nextTree)
}
}
return nil
}
// LoadBytes creates a Tree from a []byte.
func LoadBytes(b []byte) (tree *Tree, err error) {
defer func() {
if r := recover(); r != nil {
if _, ok := r.(runtime.Error); ok {
panic(r)
}
err = errors.New(r.(string))
}
}()
if len(b) >= 4 && (hasUTF32BigEndianBOM4(b) || hasUTF32LittleEndianBOM4(b)) {
b = b[4:]
} else if len(b) >= 3 && hasUTF8BOM3(b) {
b = b[3:]
} else if len(b) >= 2 && (hasUTF16BigEndianBOM2(b) || hasUTF16LittleEndianBOM2(b)) {
b = b[2:]
}
tree = parseToml(lexToml(b))
return
}
func hasUTF16BigEndianBOM2(b []byte) bool {
return b[0] == 0xFE && b[1] == 0xFF
}
func hasUTF16LittleEndianBOM2(b []byte) bool {
return b[0] == 0xFF && b[1] == 0xFE
}
func hasUTF8BOM3(b []byte) bool {
return b[0] == 0xEF && b[1] == 0xBB && b[2] == 0xBF
}
func hasUTF32BigEndianBOM4(b []byte) bool {
return b[0] == 0x00 && b[1] == 0x00 && b[2] == 0xFE && b[3] == 0xFF
}
func hasUTF32LittleEndianBOM4(b []byte) bool {
return b[0] == 0xFF && b[1] == 0xFE && b[2] == 0x00 && b[3] == 0x00
}
// LoadReader creates a Tree from any io.Reader.
func LoadReader(reader io.Reader) (tree *Tree, err error) {
inputBytes, err := ioutil.ReadAll(reader)
if err != nil {
return
}
tree, err = LoadBytes(inputBytes)
return
}
// Load creates a Tree from a string.
func Load(content string) (tree *Tree, err error) {
return LoadBytes([]byte(content))
}
// LoadFile creates a Tree from a file.
func LoadFile(path string) (tree *Tree, err error) {
file, err := os.Open(path)
if err != nil {
return nil, err
}
defer file.Close()
return LoadReader(file)
}