mirror of
https://github.com/tailscale/tailscale.git
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98b5da47e8
Needed for a future change. Updates #cleanup Change-Id: I6d89ee8a048b3bb1eb9cfb2e5a53c93aed30b021 Signed-off-by: Brad Fitzpatrick <bradfitz@tailscale.com>
458 lines
13 KiB
Go
458 lines
13 KiB
Go
// Copyright (c) Tailscale Inc & AUTHORS
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// SPDX-License-Identifier: BSD-3-Clause
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// Package views provides read-only accessors for commonly used
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// value types.
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package views
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import (
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"bytes"
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"encoding/json"
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"errors"
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"maps"
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"slices"
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"go4.org/mem"
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)
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func unmarshalSliceFromJSON[T any](b []byte, x *[]T) error {
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if *x != nil {
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return errors.New("already initialized")
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}
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if len(b) == 0 {
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return nil
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}
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return json.Unmarshal(b, x)
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}
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// ByteSlice is a read-only accessor for types that are backed by a []byte.
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type ByteSlice[T ~[]byte] struct {
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// ж is the underlying mutable value, named with a hard-to-type
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// character that looks pointy like a pointer.
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// It is named distinctively to make you think of how dangerous it is to escape
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// to callers. You must not let callers be able to mutate it.
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ж T
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}
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// ByteSliceOf returns a ByteSlice for the provided slice.
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func ByteSliceOf[T ~[]byte](x T) ByteSlice[T] {
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return ByteSlice[T]{x}
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}
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// Len returns the length of the slice.
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func (v ByteSlice[T]) Len() int {
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return len(v.ж)
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}
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// IsNil reports whether the underlying slice is nil.
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func (v ByteSlice[T]) IsNil() bool {
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return v.ж == nil
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}
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// Mem returns a read-only view of the underlying slice.
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func (v ByteSlice[T]) Mem() mem.RO {
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return mem.B(v.ж)
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}
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// Equal reports whether the underlying slice is equal to b.
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func (v ByteSlice[T]) Equal(b T) bool {
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return bytes.Equal(v.ж, b)
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}
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// EqualView reports whether the underlying slice is equal to b.
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func (v ByteSlice[T]) EqualView(b ByteSlice[T]) bool {
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return bytes.Equal(v.ж, b.ж)
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}
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// AsSlice returns a copy of the underlying slice.
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func (v ByteSlice[T]) AsSlice() T {
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return v.AppendTo(v.ж[:0:0])
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}
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// AppendTo appends the underlying slice values to dst.
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func (v ByteSlice[T]) AppendTo(dst T) T {
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return append(dst, v.ж...)
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}
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// LenIter returns a slice the same length as the v.Len().
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// The caller can then range over it to get the valid indexes.
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// It does not allocate.
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func (v ByteSlice[T]) LenIter() []struct{} { return make([]struct{}, len(v.ж)) }
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// At returns the byte at index `i` of the slice.
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func (v ByteSlice[T]) At(i int) byte { return v.ж[i] }
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// SliceFrom returns v[i:].
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func (v ByteSlice[T]) SliceFrom(i int) ByteSlice[T] { return ByteSlice[T]{v.ж[i:]} }
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// SliceTo returns v[:i]
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func (v ByteSlice[T]) SliceTo(i int) ByteSlice[T] { return ByteSlice[T]{v.ж[:i]} }
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// Slice returns v[i:j]
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func (v ByteSlice[T]) Slice(i, j int) ByteSlice[T] { return ByteSlice[T]{v.ж[i:j]} }
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// MarshalJSON implements json.Marshaler.
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func (v ByteSlice[T]) MarshalJSON() ([]byte, error) { return json.Marshal(v.ж) }
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// UnmarshalJSON implements json.Unmarshaler.
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func (v *ByteSlice[T]) UnmarshalJSON(b []byte) error {
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if v.ж != nil {
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return errors.New("already initialized")
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}
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return json.Unmarshal(b, &v.ж)
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}
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// StructView represents the corresponding StructView of a Viewable. The concrete types are
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// typically generated by tailscale.com/cmd/viewer.
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type StructView[T any] interface {
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// Valid reports whether the underlying Viewable is nil.
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Valid() bool
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// AsStruct returns a deep-copy of the underlying value.
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// It returns nil, if Valid() is false.
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AsStruct() T
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}
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// ViewCloner is any type that has had View and Clone funcs generated using
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// tailscale.com/cmd/viewer.
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type ViewCloner[T any, V StructView[T]] interface {
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// View returns a read-only view of Viewable.
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// If Viewable is nil, View().Valid() reports false.
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View() V
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// Clone returns a deep-clone of Viewable.
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// It returns nil, when Viewable is nil.
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Clone() T
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}
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// SliceOfViews returns a ViewSlice for x.
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func SliceOfViews[T ViewCloner[T, V], V StructView[T]](x []T) SliceView[T, V] {
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return SliceView[T, V]{x}
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}
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// SliceView wraps []T to provide accessors which return an immutable view V of
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// T. It is used to provide the equivalent of SliceOf([]V) without having to
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// allocate []V from []T.
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type SliceView[T ViewCloner[T, V], V StructView[T]] struct {
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// ж is the underlying mutable value, named with a hard-to-type
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// character that looks pointy like a pointer.
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// It is named distinctively to make you think of how dangerous it is to escape
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// to callers. You must not let callers be able to mutate it.
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ж []T
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}
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// MarshalJSON implements json.Marshaler.
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func (v SliceView[T, V]) MarshalJSON() ([]byte, error) { return json.Marshal(v.ж) }
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// UnmarshalJSON implements json.Unmarshaler.
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func (v *SliceView[T, V]) UnmarshalJSON(b []byte) error { return unmarshalSliceFromJSON(b, &v.ж) }
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// IsNil reports whether the underlying slice is nil.
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func (v SliceView[T, V]) IsNil() bool { return v.ж == nil }
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// Len returns the length of the slice.
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func (v SliceView[T, V]) Len() int { return len(v.ж) }
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// LenIter returns a slice the same length as the v.Len().
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// The caller can then range over it to get the valid indexes.
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// It does not allocate.
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func (v SliceView[T, V]) LenIter() []struct{} { return make([]struct{}, len(v.ж)) }
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// At returns a View of the element at index `i` of the slice.
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func (v SliceView[T, V]) At(i int) V { return v.ж[i].View() }
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// SliceFrom returns v[i:].
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func (v SliceView[T, V]) SliceFrom(i int) SliceView[T, V] { return SliceView[T, V]{v.ж[i:]} }
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// SliceTo returns v[:i]
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func (v SliceView[T, V]) SliceTo(i int) SliceView[T, V] { return SliceView[T, V]{v.ж[:i]} }
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// Slice returns v[i:j]
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func (v SliceView[T, V]) Slice(i, j int) SliceView[T, V] { return SliceView[T, V]{v.ж[i:j]} }
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// AppendTo appends the underlying slice values to dst.
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func (v SliceView[T, V]) AppendTo(dst []V) []V {
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for _, x := range v.ж {
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dst = append(dst, x.View())
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}
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return dst
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}
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// AsSlice returns a copy of underlying slice.
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func (v SliceView[T, V]) AsSlice() []V {
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return v.AppendTo(nil)
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}
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// Slice is a read-only accessor for a slice.
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type Slice[T any] struct {
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// ж is the underlying mutable value, named with a hard-to-type
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// character that looks pointy like a pointer.
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// It is named distinctively to make you think of how dangerous it is to escape
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// to callers. You must not let callers be able to mutate it.
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ж []T
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}
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// SliceOf returns a Slice for the provided slice for immutable values.
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// It is the caller's responsibility to make sure V is immutable.
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func SliceOf[T any](x []T) Slice[T] {
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return Slice[T]{x}
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}
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// MarshalJSON implements json.Marshaler.
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func (v Slice[T]) MarshalJSON() ([]byte, error) {
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return json.Marshal(v.ж)
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}
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// UnmarshalJSON implements json.Unmarshaler.
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func (v *Slice[T]) UnmarshalJSON(b []byte) error {
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return unmarshalSliceFromJSON(b, &v.ж)
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}
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// IsNil reports whether the underlying slice is nil.
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func (v Slice[T]) IsNil() bool { return v.ж == nil }
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// Len returns the length of the slice.
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func (v Slice[T]) Len() int { return len(v.ж) }
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// LenIter returns a slice the same length as the v.Len().
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// The caller can then range over it to get the valid indexes.
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// It does not allocate.
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func (v Slice[T]) LenIter() []struct{} { return make([]struct{}, len(v.ж)) }
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// At returns the element at index `i` of the slice.
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func (v Slice[T]) At(i int) T { return v.ж[i] }
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// SliceFrom returns v[i:].
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func (v Slice[T]) SliceFrom(i int) Slice[T] { return Slice[T]{v.ж[i:]} }
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// SliceTo returns v[:i]
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func (v Slice[T]) SliceTo(i int) Slice[T] { return Slice[T]{v.ж[:i]} }
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// Slice returns v[i:j]
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func (v Slice[T]) Slice(i, j int) Slice[T] { return Slice[T]{v.ж[i:j]} }
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// AppendTo appends the underlying slice values to dst.
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func (v Slice[T]) AppendTo(dst []T) []T {
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return append(dst, v.ж...)
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}
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// AsSlice returns a copy of underlying slice.
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func (v Slice[T]) AsSlice() []T {
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return v.AppendTo(v.ж[:0:0])
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}
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// IndexFunc returns the first index of an element in v satisfying f(e),
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// or -1 if none do.
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//
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// As it runs in O(n) time, use with care.
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func (v Slice[T]) IndexFunc(f func(T) bool) int {
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for i := 0; i < v.Len(); i++ {
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if f(v.At(i)) {
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return i
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}
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}
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return -1
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}
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// ContainsFunc reports whether any element in v satisfies f(e).
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//
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// As it runs in O(n) time, use with care.
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func (v Slice[T]) ContainsFunc(f func(T) bool) bool {
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for i := 0; i < v.Len(); i++ {
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if f(v.At(i)) {
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return true
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}
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}
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return false
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}
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// SliceContains reports whether v contains element e.
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//
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// As it runs in O(n) time, use with care.
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func SliceContains[T comparable](v Slice[T], e T) bool {
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for i := 0; i < v.Len(); i++ {
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if v.At(i) == e {
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return true
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}
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}
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return false
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}
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// SliceContainsFunc reports whether f reports true for any element in v.
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func SliceContainsFunc[T any](v Slice[T], f func(T) bool) bool {
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for i := 0; i < v.Len(); i++ {
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if f(v.At(i)) {
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return true
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}
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}
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return false
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}
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// SliceEqual is like the standard library's slices.Equal, but for two views.
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func SliceEqual[T comparable](a, b Slice[T]) bool {
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return slices.Equal(a.ж, b.ж)
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}
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// SliceEqualAnyOrder reports whether a and b contain the same elements, regardless of order.
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// The underlying slices for a and b can be nil.
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func SliceEqualAnyOrder[T comparable](a, b Slice[T]) bool {
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if a.Len() != b.Len() {
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return false
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}
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var diffStart int // beginning index where a and b differ
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for n := a.Len(); diffStart < n; diffStart++ {
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if a.At(diffStart) != b.At(diffStart) {
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break
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}
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}
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if diffStart == a.Len() {
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return true
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}
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// count the occurrences of remaining values and compare
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valueCount := make(map[T]int)
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for i, n := diffStart, a.Len(); i < n; i++ {
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valueCount[a.At(i)]++
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valueCount[b.At(i)]--
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}
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for _, count := range valueCount {
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if count != 0 {
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return false
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}
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}
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return true
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}
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// MapOf returns a view over m. It is the caller's responsibility to make sure K
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// and V is immutable, if this is being used to provide a read-only view over m.
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func MapOf[K comparable, V comparable](m map[K]V) Map[K, V] {
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return Map[K, V]{m}
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}
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// Map is a view over a map whose values are immutable.
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type Map[K comparable, V any] struct {
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// ж is the underlying mutable value, named with a hard-to-type
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// character that looks pointy like a pointer.
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// It is named distinctively to make you think of how dangerous it is to escape
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// to callers. You must not let callers be able to mutate it.
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ж map[K]V
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}
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// Has reports whether k has an entry in the map.
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func (m Map[K, V]) Has(k K) bool {
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_, ok := m.ж[k]
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return ok
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}
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// IsNil reports whether the underlying map is nil.
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func (m Map[K, V]) IsNil() bool {
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return m.ж == nil
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}
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// Len returns the number of elements in the map.
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func (m Map[K, V]) Len() int { return len(m.ж) }
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// Get returns the element with key k.
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func (m Map[K, V]) Get(k K) V {
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return m.ж[k]
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}
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// GetOk returns the element with key k and a bool representing whether the key
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// is in map.
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func (m Map[K, V]) GetOk(k K) (V, bool) {
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v, ok := m.ж[k]
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return v, ok
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}
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// MarshalJSON implements json.Marshaler.
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func (m Map[K, V]) MarshalJSON() ([]byte, error) {
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return json.Marshal(m.ж)
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}
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// UnmarshalJSON implements json.Unmarshaler.
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// It should only be called on an uninitialized Map.
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func (m *Map[K, V]) UnmarshalJSON(b []byte) error {
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if m.ж != nil {
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return errors.New("already initialized")
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}
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return json.Unmarshal(b, &m.ж)
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}
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// AsMap returns a shallow-clone of the underlying map.
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// If V is a pointer type, it is the caller's responsibility to make sure
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// the values are immutable.
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func (m *Map[K, V]) AsMap() map[K]V {
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if m == nil {
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return nil
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}
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return maps.Clone(m.ж)
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}
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// MapRangeFn is the func called from a Map.Range call.
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// Implementations should return false to stop range.
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type MapRangeFn[K comparable, V any] func(k K, v V) (cont bool)
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// Range calls f for every k,v pair in the underlying map.
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// It stops iteration immediately if f returns false.
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func (m Map[K, V]) Range(f MapRangeFn[K, V]) {
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for k, v := range m.ж {
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if !f(k, v) {
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return
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}
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}
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}
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// MapFnOf returns a MapFn for m.
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func MapFnOf[K comparable, T any, V any](m map[K]T, f func(T) V) MapFn[K, T, V] {
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return MapFn[K, T, V]{
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ж: m,
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wrapv: f,
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}
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}
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// MapFn is like Map but with a func to convert values from T to V.
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// It is used to provide map of slices and views.
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type MapFn[K comparable, T any, V any] struct {
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// ж is the underlying mutable value, named with a hard-to-type
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// character that looks pointy like a pointer.
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// It is named distinctively to make you think of how dangerous it is to escape
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// to callers. You must not let callers be able to mutate it.
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ж map[K]T
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wrapv func(T) V
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}
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// Has reports whether k has an entry in the map.
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func (m MapFn[K, T, V]) Has(k K) bool {
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_, ok := m.ж[k]
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return ok
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}
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// Get returns the element with key k.
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func (m MapFn[K, T, V]) Get(k K) V {
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return m.wrapv(m.ж[k])
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}
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// IsNil reports whether the underlying map is nil.
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func (m MapFn[K, T, V]) IsNil() bool {
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return m.ж == nil
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}
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// Len returns the number of elements in the map.
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func (m MapFn[K, T, V]) Len() int { return len(m.ж) }
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// GetOk returns the element with key k and a bool representing whether the key
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// is in map.
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func (m MapFn[K, T, V]) GetOk(k K) (V, bool) {
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v, ok := m.ж[k]
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return m.wrapv(v), ok
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}
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// Range calls f for every k,v pair in the underlying map.
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// It stops iteration immediately if f returns false.
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func (m MapFn[K, T, V]) Range(f MapRangeFn[K, V]) {
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for k, v := range m.ж {
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if !f(k, m.wrapv(v)) {
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return
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}
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}
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}
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