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matterbridge/vendor/github.com/pelletier/go-toml/v2/internal/tracker/seen.go

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package tracker
import (
"bytes"
"fmt"
"sync"
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"github.com/pelletier/go-toml/v2/unstable"
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)
type keyKind uint8
const (
invalidKind keyKind = iota
valueKind
tableKind
arrayTableKind
)
func (k keyKind) String() string {
switch k {
case invalidKind:
return "invalid"
case valueKind:
return "value"
case tableKind:
return "table"
case arrayTableKind:
return "array table"
}
panic("missing keyKind string mapping")
}
// SeenTracker tracks which keys have been seen with which TOML type to flag
// duplicates and mismatches according to the spec.
//
// Each node in the visited tree is represented by an entry. Each entry has an
// identifier, which is provided by a counter. Entries are stored in the array
// entries. As new nodes are discovered (referenced for the first time in the
// TOML document), entries are created and appended to the array. An entry
// points to its parent using its id.
//
// To find whether a given key (sequence of []byte) has already been visited,
// the entries are linearly searched, looking for one with the right name and
// parent id.
//
// Given that all keys appear in the document after their parent, it is
// guaranteed that all descendants of a node are stored after the node, this
// speeds up the search process.
//
// When encountering [[array tables]], the descendants of that node are removed
// to allow that branch of the tree to be "rediscovered". To maintain the
// invariant above, the deletion process needs to keep the order of entries.
// This results in more copies in that case.
type SeenTracker struct {
entries []entry
currentIdx int
}
var pool sync.Pool
func (s *SeenTracker) reset() {
// Always contains a root element at index 0.
s.currentIdx = 0
if len(s.entries) == 0 {
s.entries = make([]entry, 1, 2)
} else {
s.entries = s.entries[:1]
}
s.entries[0].child = -1
s.entries[0].next = -1
}
type entry struct {
// Use -1 to indicate no child or no sibling.
child int
next int
name []byte
kind keyKind
explicit bool
kv bool
}
// Find the index of the child of parentIdx with key k. Returns -1 if
// it does not exist.
func (s *SeenTracker) find(parentIdx int, k []byte) int {
for i := s.entries[parentIdx].child; i >= 0; i = s.entries[i].next {
if bytes.Equal(s.entries[i].name, k) {
return i
}
}
return -1
}
// Remove all descendants of node at position idx.
func (s *SeenTracker) clear(idx int) {
if idx >= len(s.entries) {
return
}
for i := s.entries[idx].child; i >= 0; {
next := s.entries[i].next
n := s.entries[0].next
s.entries[0].next = i
s.entries[i].next = n
s.entries[i].name = nil
s.clear(i)
i = next
}
s.entries[idx].child = -1
}
func (s *SeenTracker) create(parentIdx int, name []byte, kind keyKind, explicit bool, kv bool) int {
e := entry{
child: -1,
next: s.entries[parentIdx].child,
name: name,
kind: kind,
explicit: explicit,
kv: kv,
}
var idx int
if s.entries[0].next >= 0 {
idx = s.entries[0].next
s.entries[0].next = s.entries[idx].next
s.entries[idx] = e
} else {
idx = len(s.entries)
s.entries = append(s.entries, e)
}
s.entries[parentIdx].child = idx
return idx
}
func (s *SeenTracker) setExplicitFlag(parentIdx int) {
for i := s.entries[parentIdx].child; i >= 0; i = s.entries[i].next {
if s.entries[i].kv {
s.entries[i].explicit = true
s.entries[i].kv = false
}
s.setExplicitFlag(i)
}
}
// CheckExpression takes a top-level node and checks that it does not contain
// keys that have been seen in previous calls, and validates that types are
// consistent.
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func (s *SeenTracker) CheckExpression(node *unstable.Node) error {
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if s.entries == nil {
s.reset()
}
switch node.Kind {
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case unstable.KeyValue:
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return s.checkKeyValue(node)
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case unstable.Table:
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return s.checkTable(node)
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case unstable.ArrayTable:
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return s.checkArrayTable(node)
default:
panic(fmt.Errorf("this should not be a top level node type: %s", node.Kind))
}
}
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func (s *SeenTracker) checkTable(node *unstable.Node) error {
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if s.currentIdx >= 0 {
s.setExplicitFlag(s.currentIdx)
}
it := node.Key()
parentIdx := 0
// This code is duplicated in checkArrayTable. This is because factoring
// it in a function requires to copy the iterator, or allocate it to the
// heap, which is not cheap.
for it.Next() {
if it.IsLast() {
break
}
k := it.Node().Data
idx := s.find(parentIdx, k)
if idx < 0 {
idx = s.create(parentIdx, k, tableKind, false, false)
} else {
entry := s.entries[idx]
if entry.kind == valueKind {
return fmt.Errorf("toml: expected %s to be a table, not a %s", string(k), entry.kind)
}
}
parentIdx = idx
}
k := it.Node().Data
idx := s.find(parentIdx, k)
if idx >= 0 {
kind := s.entries[idx].kind
if kind != tableKind {
return fmt.Errorf("toml: key %s should be a table, not a %s", string(k), kind)
}
if s.entries[idx].explicit {
return fmt.Errorf("toml: table %s already exists", string(k))
}
s.entries[idx].explicit = true
} else {
idx = s.create(parentIdx, k, tableKind, true, false)
}
s.currentIdx = idx
return nil
}
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func (s *SeenTracker) checkArrayTable(node *unstable.Node) error {
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if s.currentIdx >= 0 {
s.setExplicitFlag(s.currentIdx)
}
it := node.Key()
parentIdx := 0
for it.Next() {
if it.IsLast() {
break
}
k := it.Node().Data
idx := s.find(parentIdx, k)
if idx < 0 {
idx = s.create(parentIdx, k, tableKind, false, false)
} else {
entry := s.entries[idx]
if entry.kind == valueKind {
return fmt.Errorf("toml: expected %s to be a table, not a %s", string(k), entry.kind)
}
}
parentIdx = idx
}
k := it.Node().Data
idx := s.find(parentIdx, k)
if idx >= 0 {
kind := s.entries[idx].kind
if kind != arrayTableKind {
return fmt.Errorf("toml: key %s already exists as a %s, but should be an array table", kind, string(k))
}
s.clear(idx)
} else {
idx = s.create(parentIdx, k, arrayTableKind, true, false)
}
s.currentIdx = idx
return nil
}
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func (s *SeenTracker) checkKeyValue(node *unstable.Node) error {
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parentIdx := s.currentIdx
it := node.Key()
for it.Next() {
k := it.Node().Data
idx := s.find(parentIdx, k)
if idx < 0 {
idx = s.create(parentIdx, k, tableKind, false, true)
} else {
entry := s.entries[idx]
if it.IsLast() {
return fmt.Errorf("toml: key %s is already defined", string(k))
} else if entry.kind != tableKind {
return fmt.Errorf("toml: expected %s to be a table, not a %s", string(k), entry.kind)
} else if entry.explicit {
return fmt.Errorf("toml: cannot redefine table %s that has already been explicitly defined", string(k))
}
}
parentIdx = idx
}
s.entries[parentIdx].kind = valueKind
value := node.Value()
switch value.Kind {
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case unstable.InlineTable:
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return s.checkInlineTable(value)
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case unstable.Array:
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return s.checkArray(value)
}
return nil
}
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func (s *SeenTracker) checkArray(node *unstable.Node) error {
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it := node.Children()
for it.Next() {
n := it.Node()
switch n.Kind {
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case unstable.InlineTable:
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err := s.checkInlineTable(n)
if err != nil {
return err
}
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case unstable.Array:
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err := s.checkArray(n)
if err != nil {
return err
}
}
}
return nil
}
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func (s *SeenTracker) checkInlineTable(node *unstable.Node) error {
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if pool.New == nil {
pool.New = func() interface{} {
return &SeenTracker{}
}
}
s = pool.Get().(*SeenTracker)
s.reset()
it := node.Children()
for it.Next() {
n := it.Node()
err := s.checkKeyValue(n)
if err != nil {
return err
}
}
// As inline tables are self-contained, the tracker does not
// need to retain the details of what they contain. The
// keyValue element that creates the inline table is kept to
// mark the presence of the inline table and prevent
// redefinition of its keys: check* functions cannot walk into
// a value.
pool.Put(s)
return nil
}