// Copyright (c) Tailscale Inc & AUTHORS // SPDX-License-Identifier: BSD-3-Clause // Package views provides read-only accessors for commonly used // value types. package views import ( "encoding/json" "errors" "maps" ) func unmarshalSliceFromJSON[T any](b []byte, x *[]T) error { if *x != nil { return errors.New("already initialized") } if len(b) == 0 { return nil } return json.Unmarshal(b, x) } // StructView represents the corresponding StructView of a Viewable. The concrete types are // typically generated by tailscale.com/cmd/viewer. type StructView[T any] interface { // Valid reports whether the underlying Viewable is nil. Valid() bool // AsStruct returns a deep-copy of the underlying value. // It returns nil, if Valid() is false. AsStruct() T } // ViewCloner is any type that has had View and Clone funcs generated using // tailscale.com/cmd/viewer. type ViewCloner[T any, V StructView[T]] interface { // View returns a read-only view of Viewable. // If Viewable is nil, View().Valid() reports false. View() V // Clone returns a deep-clone of Viewable. // It returns nil, when Viewable is nil. Clone() T } // SliceOfViews returns a ViewSlice for x. func SliceOfViews[T ViewCloner[T, V], V StructView[T]](x []T) SliceView[T, V] { return SliceView[T, V]{x} } // SliceView is a read-only wrapper around a struct which should only be exposed // as a View. type SliceView[T ViewCloner[T, V], V StructView[T]] struct { // ж is the underlying mutable value, named with a hard-to-type // character that looks pointy like a pointer. // It is named distinctively to make you think of how dangerous it is to escape // to callers. You must not let callers be able to mutate it. ж []T } // MarshalJSON implements json.Marshaler. func (v SliceView[T, V]) MarshalJSON() ([]byte, error) { return json.Marshal(v.ж) } // UnmarshalJSON implements json.Unmarshaler. func (v *SliceView[T, V]) UnmarshalJSON(b []byte) error { return unmarshalSliceFromJSON(b, &v.ж) } // IsNil reports whether the underlying slice is nil. func (v SliceView[T, V]) IsNil() bool { return v.ж == nil } // Len returns the length of the slice. func (v SliceView[T, V]) Len() int { return len(v.ж) } // LenIter returns a slice the same length as the v.Len(). // The caller can then range over it to get the valid indexes. // It does not allocate. func (v SliceView[T, V]) LenIter() []struct{} { return make([]struct{}, len(v.ж)) } // At returns a View of the element at index `i` of the slice. func (v SliceView[T, V]) At(i int) V { return v.ж[i].View() } // SliceFrom returns v[i:]. func (v SliceView[T, V]) SliceFrom(i int) SliceView[T, V] { return SliceView[T, V]{v.ж[i:]} } // SliceTo returns v[:i] func (v SliceView[T, V]) SliceTo(i int) SliceView[T, V] { return SliceView[T, V]{v.ж[:i]} } // Slice returns v[i:j] func (v SliceView[T, V]) Slice(i, j int) SliceView[T, V] { return SliceView[T, V]{v.ж[i:j]} } // AppendTo appends the underlying slice values to dst. func (v SliceView[T, V]) AppendTo(dst []V) []V { for _, x := range v.ж { dst = append(dst, x.View()) } return dst } // AsSlice returns a copy of underlying slice. func (v SliceView[T, V]) AsSlice() []V { return v.AppendTo(nil) } // Slice is a read-only accessor for a slice. type Slice[T any] struct { // ж is the underlying mutable value, named with a hard-to-type // character that looks pointy like a pointer. // It is named distinctively to make you think of how dangerous it is to escape // to callers. You must not let callers be able to mutate it. ж []T } // SliceOf returns a Slice for the provided slice for immutable values. // It is the caller's responsibility to make sure V is immutable. func SliceOf[T any](x []T) Slice[T] { return Slice[T]{x} } // MarshalJSON implements json.Marshaler. func (v Slice[T]) MarshalJSON() ([]byte, error) { return json.Marshal(v.ж) } // UnmarshalJSON implements json.Unmarshaler. func (v *Slice[T]) UnmarshalJSON(b []byte) error { return unmarshalSliceFromJSON(b, &v.ж) } // IsNil reports whether the underlying slice is nil. func (v Slice[T]) IsNil() bool { return v.ж == nil } // Len returns the length of the slice. func (v Slice[T]) Len() int { return len(v.ж) } // LenIter returns a slice the same length as the v.Len(). // The caller can then range over it to get the valid indexes. // It does not allocate. func (v Slice[T]) LenIter() []struct{} { return make([]struct{}, len(v.ж)) } // At returns the element at index `i` of the slice. func (v Slice[T]) At(i int) T { return v.ж[i] } // SliceFrom returns v[i:]. func (v Slice[T]) SliceFrom(i int) Slice[T] { return Slice[T]{v.ж[i:]} } // SliceTo returns v[:i] func (v Slice[T]) SliceTo(i int) Slice[T] { return Slice[T]{v.ж[:i]} } // Slice returns v[i:j] func (v Slice[T]) Slice(i, j int) Slice[T] { return Slice[T]{v.ж[i:j]} } // AppendTo appends the underlying slice values to dst. func (v Slice[T]) AppendTo(dst []T) []T { return append(dst, v.ж...) } // AsSlice returns a copy of underlying slice. func (v Slice[T]) AsSlice() []T { return v.AppendTo(v.ж[:0:0]) } // IndexFunc returns the first index of an element in v satisfying f(e), // or -1 if none do. // // As it runs in O(n) time, use with care. func (v Slice[T]) IndexFunc(f func(T) bool) int { for i := 0; i < v.Len(); i++ { if f(v.At(i)) { return i } } return -1 } // ContainsFunc reports whether any element in v satisfies f(e). // // As it runs in O(n) time, use with care. func (v Slice[T]) ContainsFunc(f func(T) bool) bool { for i := 0; i < v.Len(); i++ { if f(v.At(i)) { return true } } return false } // SliceContains reports whether v contains element e. // // As it runs in O(n) time, use with care. func SliceContains[T comparable](v Slice[T], e T) bool { for i := 0; i < v.Len(); i++ { if v.At(i) == e { return true } } return false } // SliceEqualAnyOrder reports whether a and b contain the same elements, regardless of order. // The underlying slices for a and b can be nil. func SliceEqualAnyOrder[T comparable](a, b Slice[T]) bool { if a.Len() != b.Len() { return false } var diffStart int // beginning index where a and b differ for n := a.Len(); diffStart < n; diffStart++ { if a.At(diffStart) != b.At(diffStart) { break } } if diffStart == a.Len() { return true } // count the occurrences of remaining values and compare valueCount := make(map[T]int) for i, n := diffStart, a.Len(); i < n; i++ { valueCount[a.At(i)]++ valueCount[b.At(i)]-- } for _, count := range valueCount { if count != 0 { return false } } return true } // MapOf returns a view over m. It is the caller's responsibility to make sure K // and V is immutable, if this is being used to provide a read-only view over m. func MapOf[K comparable, V comparable](m map[K]V) Map[K, V] { return Map[K, V]{m} } // Map is a view over a map whose values are immutable. type Map[K comparable, V any] struct { // ж is the underlying mutable value, named with a hard-to-type // character that looks pointy like a pointer. // It is named distinctively to make you think of how dangerous it is to escape // to callers. You must not let callers be able to mutate it. ж map[K]V } // Has reports whether k has an entry in the map. func (m Map[K, V]) Has(k K) bool { _, ok := m.ж[k] return ok } // IsNil reports whether the underlying map is nil. func (m Map[K, V]) IsNil() bool { return m.ж == nil } // Len returns the number of elements in the map. func (m Map[K, V]) Len() int { return len(m.ж) } // Get returns the element with key k. func (m Map[K, V]) Get(k K) V { return m.ж[k] } // GetOk returns the element with key k and a bool representing whether the key // is in map. func (m Map[K, V]) GetOk(k K) (V, bool) { v, ok := m.ж[k] return v, ok } // MarshalJSON implements json.Marshaler. func (m Map[K, V]) MarshalJSON() ([]byte, error) { return json.Marshal(m.ж) } // UnmarshalJSON implements json.Unmarshaler. // It should only be called on an uninitialized Map. func (m *Map[K, V]) UnmarshalJSON(b []byte) error { if m.ж != nil { return errors.New("already initialized") } return json.Unmarshal(b, &m.ж) } // AsMap returns a shallow-clone of the underlying map. // If V is a pointer type, it is the caller's responsibility to make sure // the values are immutable. func (m *Map[K, V]) AsMap() map[K]V { if m == nil { return nil } return maps.Clone(m.ж) } // MapRangeFn is the func called from a Map.Range call. // Implementations should return false to stop range. type MapRangeFn[K comparable, V any] func(k K, v V) (cont bool) // Range calls f for every k,v pair in the underlying map. // It stops iteration immediately if f returns false. func (m Map[K, V]) Range(f MapRangeFn[K, V]) { for k, v := range m.ж { if !f(k, v) { return } } } // MapFnOf returns a MapFn for m. func MapFnOf[K comparable, T any, V any](m map[K]T, f func(T) V) MapFn[K, T, V] { return MapFn[K, T, V]{ ж: m, wrapv: f, } } // MapFn is like Map but with a func to convert values from T to V. // It is used to provide map of slices and views. type MapFn[K comparable, T any, V any] struct { // ж is the underlying mutable value, named with a hard-to-type // character that looks pointy like a pointer. // It is named distinctively to make you think of how dangerous it is to escape // to callers. You must not let callers be able to mutate it. ж map[K]T wrapv func(T) V } // Has reports whether k has an entry in the map. func (m MapFn[K, T, V]) Has(k K) bool { _, ok := m.ж[k] return ok } // Get returns the element with key k. func (m MapFn[K, T, V]) Get(k K) V { return m.wrapv(m.ж[k]) } // IsNil reports whether the underlying map is nil. func (m MapFn[K, T, V]) IsNil() bool { return m.ж == nil } // Len returns the number of elements in the map. func (m MapFn[K, T, V]) Len() int { return len(m.ж) } // GetOk returns the element with key k and a bool representing whether the key // is in map. func (m MapFn[K, T, V]) GetOk(k K) (V, bool) { v, ok := m.ж[k] return m.wrapv(v), ok } // Range calls f for every k,v pair in the underlying map. // It stops iteration immediately if f returns false. func (m MapFn[K, T, V]) Range(f MapRangeFn[K, V]) { for k, v := range m.ж { if !f(k, m.wrapv(v)) { return } } }