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![afero logo-sm](https://cloud.githubusercontent.com/assets/173412/11490338/d50e16dc-97a5-11e5-8b12-019a300d0fcb.png)
A FileSystem Abstraction System for Go
[![Test](https://github.com/spf13/afero/actions/workflows/test.yml/badge.svg)](https://github.com/spf13/afero/actions/workflows/test.yml) [![GoDoc](https://godoc.org/github.com/spf13/afero?status.svg)](https://godoc.org/github.com/spf13/afero) [![Join the chat at https://gitter.im/spf13/afero](https://badges.gitter.im/Dev%20Chat.svg)](https://gitter.im/spf13/afero?utm_source=badge&utm_medium=badge&utm_campaign=pr-badge&utm_content=badge)
# Overview
Afero is a filesystem framework providing a simple, uniform and universal API
interacting with any filesystem, as an abstraction layer providing interfaces,
types and methods. Afero has an exceptionally clean interface and simple design
without needless constructors or initialization methods.
Afero is also a library providing a base set of interoperable backend
filesystems that make it easy to work with afero while retaining all the power
and benefit of the os and ioutil packages.
Afero provides significant improvements over using the os package alone, most
notably the ability to create mock and testing filesystems without relying on the disk.
It is suitable for use in any situation where you would consider using the OS
package as it provides an additional abstraction that makes it easy to use a
memory backed file system during testing. It also adds support for the http
filesystem for full interoperability.
## Afero Features
* A single consistent API for accessing a variety of filesystems
* Interoperation between a variety of file system types
* A set of interfaces to encourage and enforce interoperability between backends
* An atomic cross platform memory backed file system
* Support for compositional (union) file systems by combining multiple file systems acting as one
* Specialized backends which modify existing filesystems (Read Only, Regexp filtered)
* A set of utility functions ported from io, ioutil & hugo to be afero aware
* Wrapper for go 1.16 filesystem abstraction `io/fs.FS`
# Using Afero
Afero is easy to use and easier to adopt.
A few different ways you could use Afero:
* Use the interfaces alone to define your own file system.
* Wrapper for the OS packages.
* Define different filesystems for different parts of your application.
* Use Afero for mock filesystems while testing
## Step 1: Install Afero
First use go get to install the latest version of the library.
$ go get github.com/spf13/afero
Next include Afero in your application.
```go
import "github.com/spf13/afero"
```
## Step 2: Declare a backend
First define a package variable and set it to a pointer to a filesystem.
```go
var AppFs = afero.NewMemMapFs()
or
var AppFs = afero.NewOsFs()
```
It is important to note that if you repeat the composite literal you
will be using a completely new and isolated filesystem. In the case of
OsFs it will still use the same underlying filesystem but will reduce
the ability to drop in other filesystems as desired.
## Step 3: Use it like you would the OS package
Throughout your application use any function and method like you normally
would.
So if my application before had:
```go
os.Open("/tmp/foo")
```
We would replace it with:
```go
AppFs.Open("/tmp/foo")
```
`AppFs` being the variable we defined above.
## List of all available functions
File System Methods Available:
```go
Chmod(name string, mode os.FileMode) : error
Chown(name string, uid, gid int) : error
Chtimes(name string, atime time.Time, mtime time.Time) : error
Create(name string) : File, error
Mkdir(name string, perm os.FileMode) : error
MkdirAll(path string, perm os.FileMode) : error
Name() : string
Open(name string) : File, error
OpenFile(name string, flag int, perm os.FileMode) : File, error
Remove(name string) : error
RemoveAll(path string) : error
Rename(oldname, newname string) : error
Stat(name string) : os.FileInfo, error
```
File Interfaces and Methods Available:
```go
io.Closer
io.Reader
io.ReaderAt
io.Seeker
io.Writer
io.WriterAt
Name() : string
Readdir(count int) : []os.FileInfo, error
Readdirnames(n int) : []string, error
Stat() : os.FileInfo, error
Sync() : error
Truncate(size int64) : error
WriteString(s string) : ret int, err error
```
In some applications it may make sense to define a new package that
simply exports the file system variable for easy access from anywhere.
## Using Afero's utility functions
Afero provides a set of functions to make it easier to use the underlying file systems.
These functions have been primarily ported from io & ioutil with some developed for Hugo.
The afero utilities support all afero compatible backends.
The list of utilities includes:
```go
DirExists(path string) (bool, error)
Exists(path string) (bool, error)
FileContainsBytes(filename string, subslice []byte) (bool, error)
GetTempDir(subPath string) string
IsDir(path string) (bool, error)
IsEmpty(path string) (bool, error)
ReadDir(dirname string) ([]os.FileInfo, error)
ReadFile(filename string) ([]byte, error)
SafeWriteReader(path string, r io.Reader) (err error)
TempDir(dir, prefix string) (name string, err error)
TempFile(dir, prefix string) (f File, err error)
Walk(root string, walkFn filepath.WalkFunc) error
WriteFile(filename string, data []byte, perm os.FileMode) error
WriteReader(path string, r io.Reader) (err error)
```
For a complete list see [Afero's GoDoc](https://godoc.org/github.com/spf13/afero)
They are available under two different approaches to use. You can either call
them directly where the first parameter of each function will be the file
system, or you can declare a new `Afero`, a custom type used to bind these
functions as methods to a given filesystem.
### Calling utilities directly
```go
fs := new(afero.MemMapFs)
f, err := afero.TempFile(fs,"", "ioutil-test")
```
### Calling via Afero
```go
fs := afero.NewMemMapFs()
afs := &afero.Afero{Fs: fs}
f, err := afs.TempFile("", "ioutil-test")
```
## Using Afero for Testing
There is a large benefit to using a mock filesystem for testing. It has a
completely blank state every time it is initialized and can be easily
reproducible regardless of OS. You could create files to your hearts content
and the file access would be fast while also saving you from all the annoying
issues with deleting temporary files, Windows file locking, etc. The MemMapFs
backend is perfect for testing.
* Much faster than performing I/O operations on disk
* Avoid security issues and permissions
* Far more control. 'rm -rf /' with confidence
* Test setup is far more easier to do
* No test cleanup needed
One way to accomplish this is to define a variable as mentioned above.
In your application this will be set to afero.NewOsFs() during testing you
can set it to afero.NewMemMapFs().
It wouldn't be uncommon to have each test initialize a blank slate memory
backend. To do this I would define my `appFS = afero.NewOsFs()` somewhere
appropriate in my application code. This approach ensures that Tests are order
independent, with no test relying on the state left by an earlier test.
Then in my tests I would initialize a new MemMapFs for each test:
```go
func TestExist(t *testing.T) {
appFS := afero.NewMemMapFs()
// create test files and directories
appFS.MkdirAll("src/a", 0755)
afero.WriteFile(appFS, "src/a/b", []byte("file b"), 0644)
afero.WriteFile(appFS, "src/c", []byte("file c"), 0644)
name := "src/c"
_, err := appFS.Stat(name)
if os.IsNotExist(err) {
t.Errorf("file \"%s\" does not exist.\n", name)
}
}
```
# Available Backends
## Operating System Native
### OsFs
The first is simply a wrapper around the native OS calls. This makes it
very easy to use as all of the calls are the same as the existing OS
calls. It also makes it trivial to have your code use the OS during
operation and a mock filesystem during testing or as needed.
```go
appfs := afero.NewOsFs()
appfs.MkdirAll("src/a", 0755)
```
## Memory Backed Storage
### MemMapFs
Afero also provides a fully atomic memory backed filesystem perfect for use in
mocking and to speed up unnecessary disk io when persistence isnt
necessary. It is fully concurrent and will work within go routines
safely.
```go
mm := afero.NewMemMapFs()
mm.MkdirAll("src/a", 0755)
```
#### InMemoryFile
As part of MemMapFs, Afero also provides an atomic, fully concurrent memory
backed file implementation. This can be used in other memory backed file
systems with ease. Plans are to add a radix tree memory stored file
system using InMemoryFile.
## Network Interfaces
### SftpFs
Afero has experimental support for secure file transfer protocol (sftp). Which can
be used to perform file operations over a encrypted channel.
### GCSFs
Afero has experimental support for Google Cloud Storage (GCS). You can either set the
`GOOGLE_APPLICATION_CREDENTIALS_JSON` env variable to your JSON credentials or use `opts` in
`NewGcsFS` to configure access to your GCS bucket.
Some known limitations of the existing implementation:
* No Chmod support - The GCS ACL could probably be mapped to *nix style permissions but that would add another level of complexity and is ignored in this version.
* No Chtimes support - Could be simulated with attributes (gcs a/m-times are set implicitly) but that's is left for another version.
* Not thread safe - Also assumes all file operations are done through the same instance of the GcsFs. File operations between different GcsFs instances are not guaranteed to be consistent.
## Filtering Backends
### BasePathFs
The BasePathFs restricts all operations to a given path within an Fs.
The given file name to the operations on this Fs will be prepended with
the base path before calling the source Fs.
```go
bp := afero.NewBasePathFs(afero.NewOsFs(), "/base/path")
```
### ReadOnlyFs
A thin wrapper around the source Fs providing a read only view.
```go
fs := afero.NewReadOnlyFs(afero.NewOsFs())
_, err := fs.Create("/file.txt")
// err = syscall.EPERM
```
# RegexpFs
A filtered view on file names, any file NOT matching
the passed regexp will be treated as non-existing.
Files not matching the regexp provided will not be created.
Directories are not filtered.
```go
fs := afero.NewRegexpFs(afero.NewMemMapFs(), regexp.MustCompile(`\.txt$`))
_, err := fs.Create("/file.html")
// err = syscall.ENOENT
```
### HttpFs
Afero provides an http compatible backend which can wrap any of the existing
backends.
The Http package requires a slightly specific version of Open which
returns an http.File type.
Afero provides an httpFs file system which satisfies this requirement.
Any Afero FileSystem can be used as an httpFs.
```go
httpFs := afero.NewHttpFs(<ExistingFS>)
fileserver := http.FileServer(httpFs.Dir(<PATH>))
http.Handle("/", fileserver)
```
## Composite Backends
Afero provides the ability have two filesystems (or more) act as a single
file system.
### CacheOnReadFs
The CacheOnReadFs will lazily make copies of any accessed files from the base
layer into the overlay. Subsequent reads will be pulled from the overlay
directly permitting the request is within the cache duration of when it was
created in the overlay.
If the base filesystem is writeable, any changes to files will be
done first to the base, then to the overlay layer. Write calls to open file
handles like `Write()` or `Truncate()` to the overlay first.
To writing files to the overlay only, you can use the overlay Fs directly (not
via the union Fs).
Cache files in the layer for the given time.Duration, a cache duration of 0
means "forever" meaning the file will not be re-requested from the base ever.
A read-only base will make the overlay also read-only but still copy files
from the base to the overlay when they're not present (or outdated) in the
caching layer.
```go
base := afero.NewOsFs()
layer := afero.NewMemMapFs()
ufs := afero.NewCacheOnReadFs(base, layer, 100 * time.Second)
```
### CopyOnWriteFs()
The CopyOnWriteFs is a read only base file system with a potentially
writeable layer on top.
Read operations will first look in the overlay and if not found there, will
serve the file from the base.
Changes to the file system will only be made in the overlay.
Any attempt to modify a file found only in the base will copy the file to the
overlay layer before modification (including opening a file with a writable
handle).
Removing and Renaming files present only in the base layer is not currently
permitted. If a file is present in the base layer and the overlay, only the
overlay will be removed/renamed.
```go
base := afero.NewOsFs()
roBase := afero.NewReadOnlyFs(base)
ufs := afero.NewCopyOnWriteFs(roBase, afero.NewMemMapFs())
fh, _ = ufs.Create("/home/test/file2.txt")
fh.WriteString("This is a test")
fh.Close()
```
In this example all write operations will only occur in memory (MemMapFs)
leaving the base filesystem (OsFs) untouched.
## Desired/possible backends
The following is a short list of possible backends we hope someone will
implement:
* SSH
* S3
# About the project
## What's in the name
Afero comes from the latin roots Ad-Facere.
**"Ad"** is a prefix meaning "to".
**"Facere"** is a form of the root "faciō" making "make or do".
The literal meaning of afero is "to make" or "to do" which seems very fitting
for a library that allows one to make files and directories and do things with them.
The English word that shares the same roots as Afero is "affair". Affair shares
the same concept but as a noun it means "something that is made or done" or "an
object of a particular type".
It's also nice that unlike some of my other libraries (hugo, cobra, viper) it
Googles very well.
## Release Notes
See the [Releases Page](https://github.com/spf13/afero/releases).
## Contributing
1. Fork it
2. Create your feature branch (`git checkout -b my-new-feature`)
3. Commit your changes (`git commit -am 'Add some feature'`)
4. Push to the branch (`git push origin my-new-feature`)
5. Create new Pull Request
## Contributors
Names in no particular order:
* [spf13](https://github.com/spf13)
* [jaqx0r](https://github.com/jaqx0r)
* [mbertschler](https://github.com/mbertschler)
* [xor-gate](https://github.com/xor-gate)
## License
Afero is released under the Apache 2.0 license. See
[LICENSE.txt](https://github.com/spf13/afero/blob/master/LICENSE.txt)

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// Copyright © 2014 Steve Francia <spf@spf13.com>.
// Copyright 2013 tsuru authors. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Package afero provides types and methods for interacting with the filesystem,
// as an abstraction layer.
// Afero also provides a few implementations that are mostly interoperable. One that
// uses the operating system filesystem, one that uses memory to store files
// (cross platform) and an interface that should be implemented if you want to
// provide your own filesystem.
package afero
import (
"errors"
"io"
"os"
"time"
)
type Afero struct {
Fs
}
// File represents a file in the filesystem.
type File interface {
io.Closer
io.Reader
io.ReaderAt
io.Seeker
io.Writer
io.WriterAt
Name() string
Readdir(count int) ([]os.FileInfo, error)
Readdirnames(n int) ([]string, error)
Stat() (os.FileInfo, error)
Sync() error
Truncate(size int64) error
WriteString(s string) (ret int, err error)
}
// Fs is the filesystem interface.
//
// Any simulated or real filesystem should implement this interface.
type Fs interface {
// Create creates a file in the filesystem, returning the file and an
// error, if any happens.
Create(name string) (File, error)
// Mkdir creates a directory in the filesystem, return an error if any
// happens.
Mkdir(name string, perm os.FileMode) error
// MkdirAll creates a directory path and all parents that does not exist
// yet.
MkdirAll(path string, perm os.FileMode) error
// Open opens a file, returning it or an error, if any happens.
Open(name string) (File, error)
// OpenFile opens a file using the given flags and the given mode.
OpenFile(name string, flag int, perm os.FileMode) (File, error)
// Remove removes a file identified by name, returning an error, if any
// happens.
Remove(name string) error
// RemoveAll removes a directory path and any children it contains. It
// does not fail if the path does not exist (return nil).
RemoveAll(path string) error
// Rename renames a file.
Rename(oldname, newname string) error
// Stat returns a FileInfo describing the named file, or an error, if any
// happens.
Stat(name string) (os.FileInfo, error)
// The name of this FileSystem
Name() string
// Chmod changes the mode of the named file to mode.
Chmod(name string, mode os.FileMode) error
// Chown changes the uid and gid of the named file.
Chown(name string, uid, gid int) error
// Chtimes changes the access and modification times of the named file
Chtimes(name string, atime time.Time, mtime time.Time) error
}
var (
ErrFileClosed = errors.New("File is closed")
ErrOutOfRange = errors.New("out of range")
ErrTooLarge = errors.New("too large")
ErrFileNotFound = os.ErrNotExist
ErrFileExists = os.ErrExist
ErrDestinationExists = os.ErrExist
)

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# This currently does nothing. We have moved to GitHub action, but this is kept
# until spf13 has disabled this project in AppVeyor.
version: '{build}'
clone_folder: C:\gopath\src\github.com\spf13\afero
environment:
GOPATH: C:\gopath
build_script:
- cmd: >-
go version

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package afero
import (
"io/fs"
"os"
"path/filepath"
"runtime"
"strings"
"time"
)
var (
_ Lstater = (*BasePathFs)(nil)
_ fs.ReadDirFile = (*BasePathFile)(nil)
)
// The BasePathFs restricts all operations to a given path within an Fs.
// The given file name to the operations on this Fs will be prepended with
// the base path before calling the base Fs.
// Any file name (after filepath.Clean()) outside this base path will be
// treated as non existing file.
//
// Note that it does not clean the error messages on return, so you may
// reveal the real path on errors.
type BasePathFs struct {
source Fs
path string
}
type BasePathFile struct {
File
path string
}
func (f *BasePathFile) Name() string {
sourcename := f.File.Name()
return strings.TrimPrefix(sourcename, filepath.Clean(f.path))
}
func (f *BasePathFile) ReadDir(n int) ([]fs.DirEntry, error) {
if rdf, ok := f.File.(fs.ReadDirFile); ok {
return rdf.ReadDir(n)
}
return readDirFile{f.File}.ReadDir(n)
}
func NewBasePathFs(source Fs, path string) Fs {
return &BasePathFs{source: source, path: path}
}
// on a file outside the base path it returns the given file name and an error,
// else the given file with the base path prepended
func (b *BasePathFs) RealPath(name string) (path string, err error) {
if err := validateBasePathName(name); err != nil {
return name, err
}
bpath := filepath.Clean(b.path)
path = filepath.Clean(filepath.Join(bpath, name))
if !strings.HasPrefix(path, bpath) {
return name, os.ErrNotExist
}
return path, nil
}
func validateBasePathName(name string) error {
if runtime.GOOS != "windows" {
// Not much to do here;
// the virtual file paths all look absolute on *nix.
return nil
}
// On Windows a common mistake would be to provide an absolute OS path
// We could strip out the base part, but that would not be very portable.
if filepath.IsAbs(name) {
return os.ErrNotExist
}
return nil
}
func (b *BasePathFs) Chtimes(name string, atime, mtime time.Time) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "chtimes", Path: name, Err: err}
}
return b.source.Chtimes(name, atime, mtime)
}
func (b *BasePathFs) Chmod(name string, mode os.FileMode) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "chmod", Path: name, Err: err}
}
return b.source.Chmod(name, mode)
}
func (b *BasePathFs) Chown(name string, uid, gid int) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "chown", Path: name, Err: err}
}
return b.source.Chown(name, uid, gid)
}
func (b *BasePathFs) Name() string {
return "BasePathFs"
}
func (b *BasePathFs) Stat(name string) (fi os.FileInfo, err error) {
if name, err = b.RealPath(name); err != nil {
return nil, &os.PathError{Op: "stat", Path: name, Err: err}
}
return b.source.Stat(name)
}
func (b *BasePathFs) Rename(oldname, newname string) (err error) {
if oldname, err = b.RealPath(oldname); err != nil {
return &os.PathError{Op: "rename", Path: oldname, Err: err}
}
if newname, err = b.RealPath(newname); err != nil {
return &os.PathError{Op: "rename", Path: newname, Err: err}
}
return b.source.Rename(oldname, newname)
}
func (b *BasePathFs) RemoveAll(name string) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "remove_all", Path: name, Err: err}
}
return b.source.RemoveAll(name)
}
func (b *BasePathFs) Remove(name string) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "remove", Path: name, Err: err}
}
return b.source.Remove(name)
}
func (b *BasePathFs) OpenFile(name string, flag int, mode os.FileMode) (f File, err error) {
if name, err = b.RealPath(name); err != nil {
return nil, &os.PathError{Op: "openfile", Path: name, Err: err}
}
sourcef, err := b.source.OpenFile(name, flag, mode)
if err != nil {
return nil, err
}
return &BasePathFile{sourcef, b.path}, nil
}
func (b *BasePathFs) Open(name string) (f File, err error) {
if name, err = b.RealPath(name); err != nil {
return nil, &os.PathError{Op: "open", Path: name, Err: err}
}
sourcef, err := b.source.Open(name)
if err != nil {
return nil, err
}
return &BasePathFile{File: sourcef, path: b.path}, nil
}
func (b *BasePathFs) Mkdir(name string, mode os.FileMode) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "mkdir", Path: name, Err: err}
}
return b.source.Mkdir(name, mode)
}
func (b *BasePathFs) MkdirAll(name string, mode os.FileMode) (err error) {
if name, err = b.RealPath(name); err != nil {
return &os.PathError{Op: "mkdir", Path: name, Err: err}
}
return b.source.MkdirAll(name, mode)
}
func (b *BasePathFs) Create(name string) (f File, err error) {
if name, err = b.RealPath(name); err != nil {
return nil, &os.PathError{Op: "create", Path: name, Err: err}
}
sourcef, err := b.source.Create(name)
if err != nil {
return nil, err
}
return &BasePathFile{File: sourcef, path: b.path}, nil
}
func (b *BasePathFs) LstatIfPossible(name string) (os.FileInfo, bool, error) {
name, err := b.RealPath(name)
if err != nil {
return nil, false, &os.PathError{Op: "lstat", Path: name, Err: err}
}
if lstater, ok := b.source.(Lstater); ok {
return lstater.LstatIfPossible(name)
}
fi, err := b.source.Stat(name)
return fi, false, err
}
func (b *BasePathFs) SymlinkIfPossible(oldname, newname string) error {
oldname, err := b.RealPath(oldname)
if err != nil {
return &os.LinkError{Op: "symlink", Old: oldname, New: newname, Err: err}
}
newname, err = b.RealPath(newname)
if err != nil {
return &os.LinkError{Op: "symlink", Old: oldname, New: newname, Err: err}
}
if linker, ok := b.source.(Linker); ok {
return linker.SymlinkIfPossible(oldname, newname)
}
return &os.LinkError{Op: "symlink", Old: oldname, New: newname, Err: ErrNoSymlink}
}
func (b *BasePathFs) ReadlinkIfPossible(name string) (string, error) {
name, err := b.RealPath(name)
if err != nil {
return "", &os.PathError{Op: "readlink", Path: name, Err: err}
}
if reader, ok := b.source.(LinkReader); ok {
return reader.ReadlinkIfPossible(name)
}
return "", &os.PathError{Op: "readlink", Path: name, Err: ErrNoReadlink}
}

315
vendor/github.com/spf13/afero/cacheOnReadFs.go generated vendored Normal file
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package afero
import (
"os"
"syscall"
"time"
)
// If the cache duration is 0, cache time will be unlimited, i.e. once
// a file is in the layer, the base will never be read again for this file.
//
// For cache times greater than 0, the modification time of a file is
// checked. Note that a lot of file system implementations only allow a
// resolution of a second for timestamps... or as the godoc for os.Chtimes()
// states: "The underlying filesystem may truncate or round the values to a
// less precise time unit."
//
// This caching union will forward all write calls also to the base file
// system first. To prevent writing to the base Fs, wrap it in a read-only
// filter - Note: this will also make the overlay read-only, for writing files
// in the overlay, use the overlay Fs directly, not via the union Fs.
type CacheOnReadFs struct {
base Fs
layer Fs
cacheTime time.Duration
}
func NewCacheOnReadFs(base Fs, layer Fs, cacheTime time.Duration) Fs {
return &CacheOnReadFs{base: base, layer: layer, cacheTime: cacheTime}
}
type cacheState int
const (
// not present in the overlay, unknown if it exists in the base:
cacheMiss cacheState = iota
// present in the overlay and in base, base file is newer:
cacheStale
// present in the overlay - with cache time == 0 it may exist in the base,
// with cacheTime > 0 it exists in the base and is same age or newer in the
// overlay
cacheHit
// happens if someone writes directly to the overlay without
// going through this union
cacheLocal
)
func (u *CacheOnReadFs) cacheStatus(name string) (state cacheState, fi os.FileInfo, err error) {
var lfi, bfi os.FileInfo
lfi, err = u.layer.Stat(name)
if err == nil {
if u.cacheTime == 0 {
return cacheHit, lfi, nil
}
if lfi.ModTime().Add(u.cacheTime).Before(time.Now()) {
bfi, err = u.base.Stat(name)
if err != nil {
return cacheLocal, lfi, nil
}
if bfi.ModTime().After(lfi.ModTime()) {
return cacheStale, bfi, nil
}
}
return cacheHit, lfi, nil
}
if err == syscall.ENOENT || os.IsNotExist(err) {
return cacheMiss, nil, nil
}
return cacheMiss, nil, err
}
func (u *CacheOnReadFs) copyToLayer(name string) error {
return copyToLayer(u.base, u.layer, name)
}
func (u *CacheOnReadFs) copyFileToLayer(name string, flag int, perm os.FileMode) error {
return copyFileToLayer(u.base, u.layer, name, flag, perm)
}
func (u *CacheOnReadFs) Chtimes(name string, atime, mtime time.Time) error {
st, _, err := u.cacheStatus(name)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit:
err = u.base.Chtimes(name, atime, mtime)
case cacheStale, cacheMiss:
if err := u.copyToLayer(name); err != nil {
return err
}
err = u.base.Chtimes(name, atime, mtime)
}
if err != nil {
return err
}
return u.layer.Chtimes(name, atime, mtime)
}
func (u *CacheOnReadFs) Chmod(name string, mode os.FileMode) error {
st, _, err := u.cacheStatus(name)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit:
err = u.base.Chmod(name, mode)
case cacheStale, cacheMiss:
if err := u.copyToLayer(name); err != nil {
return err
}
err = u.base.Chmod(name, mode)
}
if err != nil {
return err
}
return u.layer.Chmod(name, mode)
}
func (u *CacheOnReadFs) Chown(name string, uid, gid int) error {
st, _, err := u.cacheStatus(name)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit:
err = u.base.Chown(name, uid, gid)
case cacheStale, cacheMiss:
if err := u.copyToLayer(name); err != nil {
return err
}
err = u.base.Chown(name, uid, gid)
}
if err != nil {
return err
}
return u.layer.Chown(name, uid, gid)
}
func (u *CacheOnReadFs) Stat(name string) (os.FileInfo, error) {
st, fi, err := u.cacheStatus(name)
if err != nil {
return nil, err
}
switch st {
case cacheMiss:
return u.base.Stat(name)
default: // cacheStale has base, cacheHit and cacheLocal the layer os.FileInfo
return fi, nil
}
}
func (u *CacheOnReadFs) Rename(oldname, newname string) error {
st, _, err := u.cacheStatus(oldname)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit:
err = u.base.Rename(oldname, newname)
case cacheStale, cacheMiss:
if err := u.copyToLayer(oldname); err != nil {
return err
}
err = u.base.Rename(oldname, newname)
}
if err != nil {
return err
}
return u.layer.Rename(oldname, newname)
}
func (u *CacheOnReadFs) Remove(name string) error {
st, _, err := u.cacheStatus(name)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit, cacheStale, cacheMiss:
err = u.base.Remove(name)
}
if err != nil {
return err
}
return u.layer.Remove(name)
}
func (u *CacheOnReadFs) RemoveAll(name string) error {
st, _, err := u.cacheStatus(name)
if err != nil {
return err
}
switch st {
case cacheLocal:
case cacheHit, cacheStale, cacheMiss:
err = u.base.RemoveAll(name)
}
if err != nil {
return err
}
return u.layer.RemoveAll(name)
}
func (u *CacheOnReadFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
st, _, err := u.cacheStatus(name)
if err != nil {
return nil, err
}
switch st {
case cacheLocal, cacheHit:
default:
if err := u.copyFileToLayer(name, flag, perm); err != nil {
return nil, err
}
}
if flag&(os.O_WRONLY|syscall.O_RDWR|os.O_APPEND|os.O_CREATE|os.O_TRUNC) != 0 {
bfi, err := u.base.OpenFile(name, flag, perm)
if err != nil {
return nil, err
}
lfi, err := u.layer.OpenFile(name, flag, perm)
if err != nil {
bfi.Close() // oops, what if O_TRUNC was set and file opening in the layer failed...?
return nil, err
}
return &UnionFile{Base: bfi, Layer: lfi}, nil
}
return u.layer.OpenFile(name, flag, perm)
}
func (u *CacheOnReadFs) Open(name string) (File, error) {
st, fi, err := u.cacheStatus(name)
if err != nil {
return nil, err
}
switch st {
case cacheLocal:
return u.layer.Open(name)
case cacheMiss:
bfi, err := u.base.Stat(name)
if err != nil {
return nil, err
}
if bfi.IsDir() {
return u.base.Open(name)
}
if err := u.copyToLayer(name); err != nil {
return nil, err
}
return u.layer.Open(name)
case cacheStale:
if !fi.IsDir() {
if err := u.copyToLayer(name); err != nil {
return nil, err
}
return u.layer.Open(name)
}
case cacheHit:
if !fi.IsDir() {
return u.layer.Open(name)
}
}
// the dirs from cacheHit, cacheStale fall down here:
bfile, _ := u.base.Open(name)
lfile, err := u.layer.Open(name)
if err != nil && bfile == nil {
return nil, err
}
return &UnionFile{Base: bfile, Layer: lfile}, nil
}
func (u *CacheOnReadFs) Mkdir(name string, perm os.FileMode) error {
err := u.base.Mkdir(name, perm)
if err != nil {
return err
}
return u.layer.MkdirAll(name, perm) // yes, MkdirAll... we cannot assume it exists in the cache
}
func (u *CacheOnReadFs) Name() string {
return "CacheOnReadFs"
}
func (u *CacheOnReadFs) MkdirAll(name string, perm os.FileMode) error {
err := u.base.MkdirAll(name, perm)
if err != nil {
return err
}
return u.layer.MkdirAll(name, perm)
}
func (u *CacheOnReadFs) Create(name string) (File, error) {
bfh, err := u.base.Create(name)
if err != nil {
return nil, err
}
lfh, err := u.layer.Create(name)
if err != nil {
// oops, see comment about OS_TRUNC above, should we remove? then we have to
// remember if the file did not exist before
bfh.Close()
return nil, err
}
return &UnionFile{Base: bfh, Layer: lfh}, nil
}

23
vendor/github.com/spf13/afero/const_bsds.go generated vendored Normal file
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// Copyright © 2016 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//go:build aix || darwin || openbsd || freebsd || netbsd || dragonfly || zos
// +build aix darwin openbsd freebsd netbsd dragonfly zos
package afero
import (
"syscall"
)
const BADFD = syscall.EBADF

22
vendor/github.com/spf13/afero/const_win_unix.go generated vendored Normal file
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@ -0,0 +1,22 @@
// Copyright © 2016 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//go:build !darwin && !openbsd && !freebsd && !dragonfly && !netbsd && !aix && !zos
// +build !darwin,!openbsd,!freebsd,!dragonfly,!netbsd,!aix,!zos
package afero
import (
"syscall"
)
const BADFD = syscall.EBADFD

327
vendor/github.com/spf13/afero/copyOnWriteFs.go generated vendored Normal file
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package afero
import (
"fmt"
"os"
"path/filepath"
"syscall"
"time"
)
var _ Lstater = (*CopyOnWriteFs)(nil)
// The CopyOnWriteFs is a union filesystem: a read only base file system with
// a possibly writeable layer on top. Changes to the file system will only
// be made in the overlay: Changing an existing file in the base layer which
// is not present in the overlay will copy the file to the overlay ("changing"
// includes also calls to e.g. Chtimes(), Chmod() and Chown()).
//
// Reading directories is currently only supported via Open(), not OpenFile().
type CopyOnWriteFs struct {
base Fs
layer Fs
}
func NewCopyOnWriteFs(base Fs, layer Fs) Fs {
return &CopyOnWriteFs{base: base, layer: layer}
}
// Returns true if the file is not in the overlay
func (u *CopyOnWriteFs) isBaseFile(name string) (bool, error) {
if _, err := u.layer.Stat(name); err == nil {
return false, nil
}
_, err := u.base.Stat(name)
if err != nil {
if oerr, ok := err.(*os.PathError); ok {
if oerr.Err == os.ErrNotExist || oerr.Err == syscall.ENOENT || oerr.Err == syscall.ENOTDIR {
return false, nil
}
}
if err == syscall.ENOENT {
return false, nil
}
}
return true, err
}
func (u *CopyOnWriteFs) copyToLayer(name string) error {
return copyToLayer(u.base, u.layer, name)
}
func (u *CopyOnWriteFs) Chtimes(name string, atime, mtime time.Time) error {
b, err := u.isBaseFile(name)
if err != nil {
return err
}
if b {
if err := u.copyToLayer(name); err != nil {
return err
}
}
return u.layer.Chtimes(name, atime, mtime)
}
func (u *CopyOnWriteFs) Chmod(name string, mode os.FileMode) error {
b, err := u.isBaseFile(name)
if err != nil {
return err
}
if b {
if err := u.copyToLayer(name); err != nil {
return err
}
}
return u.layer.Chmod(name, mode)
}
func (u *CopyOnWriteFs) Chown(name string, uid, gid int) error {
b, err := u.isBaseFile(name)
if err != nil {
return err
}
if b {
if err := u.copyToLayer(name); err != nil {
return err
}
}
return u.layer.Chown(name, uid, gid)
}
func (u *CopyOnWriteFs) Stat(name string) (os.FileInfo, error) {
fi, err := u.layer.Stat(name)
if err != nil {
isNotExist := u.isNotExist(err)
if isNotExist {
return u.base.Stat(name)
}
return nil, err
}
return fi, nil
}
func (u *CopyOnWriteFs) LstatIfPossible(name string) (os.FileInfo, bool, error) {
llayer, ok1 := u.layer.(Lstater)
lbase, ok2 := u.base.(Lstater)
if ok1 {
fi, b, err := llayer.LstatIfPossible(name)
if err == nil {
return fi, b, nil
}
if !u.isNotExist(err) {
return nil, b, err
}
}
if ok2 {
fi, b, err := lbase.LstatIfPossible(name)
if err == nil {
return fi, b, nil
}
if !u.isNotExist(err) {
return nil, b, err
}
}
fi, err := u.Stat(name)
return fi, false, err
}
func (u *CopyOnWriteFs) SymlinkIfPossible(oldname, newname string) error {
if slayer, ok := u.layer.(Linker); ok {
return slayer.SymlinkIfPossible(oldname, newname)
}
return &os.LinkError{Op: "symlink", Old: oldname, New: newname, Err: ErrNoSymlink}
}
func (u *CopyOnWriteFs) ReadlinkIfPossible(name string) (string, error) {
if rlayer, ok := u.layer.(LinkReader); ok {
return rlayer.ReadlinkIfPossible(name)
}
if rbase, ok := u.base.(LinkReader); ok {
return rbase.ReadlinkIfPossible(name)
}
return "", &os.PathError{Op: "readlink", Path: name, Err: ErrNoReadlink}
}
func (u *CopyOnWriteFs) isNotExist(err error) bool {
if e, ok := err.(*os.PathError); ok {
err = e.Err
}
if err == os.ErrNotExist || err == syscall.ENOENT || err == syscall.ENOTDIR {
return true
}
return false
}
// Renaming files present only in the base layer is not permitted
func (u *CopyOnWriteFs) Rename(oldname, newname string) error {
b, err := u.isBaseFile(oldname)
if err != nil {
return err
}
if b {
return syscall.EPERM
}
return u.layer.Rename(oldname, newname)
}
// Removing files present only in the base layer is not permitted. If
// a file is present in the base layer and the overlay, only the overlay
// will be removed.
func (u *CopyOnWriteFs) Remove(name string) error {
err := u.layer.Remove(name)
switch err {
case syscall.ENOENT:
_, err = u.base.Stat(name)
if err == nil {
return syscall.EPERM
}
return syscall.ENOENT
default:
return err
}
}
func (u *CopyOnWriteFs) RemoveAll(name string) error {
err := u.layer.RemoveAll(name)
switch err {
case syscall.ENOENT:
_, err = u.base.Stat(name)
if err == nil {
return syscall.EPERM
}
return syscall.ENOENT
default:
return err
}
}
func (u *CopyOnWriteFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
b, err := u.isBaseFile(name)
if err != nil {
return nil, err
}
if flag&(os.O_WRONLY|os.O_RDWR|os.O_APPEND|os.O_CREATE|os.O_TRUNC) != 0 {
if b {
if err = u.copyToLayer(name); err != nil {
return nil, err
}
return u.layer.OpenFile(name, flag, perm)
}
dir := filepath.Dir(name)
isaDir, err := IsDir(u.base, dir)
if err != nil && !os.IsNotExist(err) {
return nil, err
}
if isaDir {
if err = u.layer.MkdirAll(dir, 0o777); err != nil {
return nil, err
}
return u.layer.OpenFile(name, flag, perm)
}
isaDir, err = IsDir(u.layer, dir)
if err != nil {
return nil, err
}
if isaDir {
return u.layer.OpenFile(name, flag, perm)
}
return nil, &os.PathError{Op: "open", Path: name, Err: syscall.ENOTDIR} // ...or os.ErrNotExist?
}
if b {
return u.base.OpenFile(name, flag, perm)
}
return u.layer.OpenFile(name, flag, perm)
}
// This function handles the 9 different possibilities caused
// by the union which are the intersection of the following...
//
// layer: doesn't exist, exists as a file, and exists as a directory
// base: doesn't exist, exists as a file, and exists as a directory
func (u *CopyOnWriteFs) Open(name string) (File, error) {
// Since the overlay overrides the base we check that first
b, err := u.isBaseFile(name)
if err != nil {
return nil, err
}
// If overlay doesn't exist, return the base (base state irrelevant)
if b {
return u.base.Open(name)
}
// If overlay is a file, return it (base state irrelevant)
dir, err := IsDir(u.layer, name)
if err != nil {
return nil, err
}
if !dir {
return u.layer.Open(name)
}
// Overlay is a directory, base state now matters.
// Base state has 3 states to check but 2 outcomes:
// A. It's a file or non-readable in the base (return just the overlay)
// B. It's an accessible directory in the base (return a UnionFile)
// If base is file or nonreadable, return overlay
dir, err = IsDir(u.base, name)
if !dir || err != nil {
return u.layer.Open(name)
}
// Both base & layer are directories
// Return union file (if opens are without error)
bfile, bErr := u.base.Open(name)
lfile, lErr := u.layer.Open(name)
// If either have errors at this point something is very wrong. Return nil and the errors
if bErr != nil || lErr != nil {
return nil, fmt.Errorf("BaseErr: %v\nOverlayErr: %v", bErr, lErr)
}
return &UnionFile{Base: bfile, Layer: lfile}, nil
}
func (u *CopyOnWriteFs) Mkdir(name string, perm os.FileMode) error {
dir, err := IsDir(u.base, name)
if err != nil {
return u.layer.MkdirAll(name, perm)
}
if dir {
return ErrFileExists
}
return u.layer.MkdirAll(name, perm)
}
func (u *CopyOnWriteFs) Name() string {
return "CopyOnWriteFs"
}
func (u *CopyOnWriteFs) MkdirAll(name string, perm os.FileMode) error {
dir, err := IsDir(u.base, name)
if err != nil {
return u.layer.MkdirAll(name, perm)
}
if dir {
// This is in line with how os.MkdirAll behaves.
return nil
}
return u.layer.MkdirAll(name, perm)
}
func (u *CopyOnWriteFs) Create(name string) (File, error) {
return u.OpenFile(name, os.O_CREATE|os.O_TRUNC|os.O_RDWR, 0o666)
}

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// Copyright © 2014 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"errors"
"net/http"
"os"
"path"
"path/filepath"
"strings"
"time"
)
type httpDir struct {
basePath string
fs HttpFs
}
func (d httpDir) Open(name string) (http.File, error) {
if filepath.Separator != '/' && strings.ContainsRune(name, filepath.Separator) ||
strings.Contains(name, "\x00") {
return nil, errors.New("http: invalid character in file path")
}
dir := string(d.basePath)
if dir == "" {
dir = "."
}
f, err := d.fs.Open(filepath.Join(dir, filepath.FromSlash(path.Clean("/"+name))))
if err != nil {
return nil, err
}
return f, nil
}
type HttpFs struct {
source Fs
}
func NewHttpFs(source Fs) *HttpFs {
return &HttpFs{source: source}
}
func (h HttpFs) Dir(s string) *httpDir {
return &httpDir{basePath: s, fs: h}
}
func (h HttpFs) Name() string { return "h HttpFs" }
func (h HttpFs) Create(name string) (File, error) {
return h.source.Create(name)
}
func (h HttpFs) Chmod(name string, mode os.FileMode) error {
return h.source.Chmod(name, mode)
}
func (h HttpFs) Chown(name string, uid, gid int) error {
return h.source.Chown(name, uid, gid)
}
func (h HttpFs) Chtimes(name string, atime time.Time, mtime time.Time) error {
return h.source.Chtimes(name, atime, mtime)
}
func (h HttpFs) Mkdir(name string, perm os.FileMode) error {
return h.source.Mkdir(name, perm)
}
func (h HttpFs) MkdirAll(path string, perm os.FileMode) error {
return h.source.MkdirAll(path, perm)
}
func (h HttpFs) Open(name string) (http.File, error) {
f, err := h.source.Open(name)
if err == nil {
if httpfile, ok := f.(http.File); ok {
return httpfile, nil
}
}
return nil, err
}
func (h HttpFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
return h.source.OpenFile(name, flag, perm)
}
func (h HttpFs) Remove(name string) error {
return h.source.Remove(name)
}
func (h HttpFs) RemoveAll(path string) error {
return h.source.RemoveAll(path)
}
func (h HttpFs) Rename(oldname, newname string) error {
return h.source.Rename(oldname, newname)
}
func (h HttpFs) Stat(name string) (os.FileInfo, error) {
return h.source.Stat(name)
}

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vendor/github.com/spf13/afero/internal/common/adapters.go generated vendored Normal file
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// Copyright © 2022 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package common
import "io/fs"
// FileInfoDirEntry provides an adapter from os.FileInfo to fs.DirEntry
type FileInfoDirEntry struct {
fs.FileInfo
}
var _ fs.DirEntry = FileInfoDirEntry{}
func (d FileInfoDirEntry) Type() fs.FileMode { return d.FileInfo.Mode().Type() }
func (d FileInfoDirEntry) Info() (fs.FileInfo, error) { return d.FileInfo, nil }

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//go:build go1.16
// +build go1.16
package afero
import (
"io"
"io/fs"
"os"
"path"
"sort"
"time"
"github.com/spf13/afero/internal/common"
)
// IOFS adopts afero.Fs to stdlib io/fs.FS
type IOFS struct {
Fs
}
func NewIOFS(fs Fs) IOFS {
return IOFS{Fs: fs}
}
var (
_ fs.FS = IOFS{}
_ fs.GlobFS = IOFS{}
_ fs.ReadDirFS = IOFS{}
_ fs.ReadFileFS = IOFS{}
_ fs.StatFS = IOFS{}
_ fs.SubFS = IOFS{}
)
func (iofs IOFS) Open(name string) (fs.File, error) {
const op = "open"
// by convention for fs.FS implementations we should perform this check
if !fs.ValidPath(name) {
return nil, iofs.wrapError(op, name, fs.ErrInvalid)
}
file, err := iofs.Fs.Open(name)
if err != nil {
return nil, iofs.wrapError(op, name, err)
}
// file should implement fs.ReadDirFile
if _, ok := file.(fs.ReadDirFile); !ok {
file = readDirFile{file}
}
return file, nil
}
func (iofs IOFS) Glob(pattern string) ([]string, error) {
const op = "glob"
// afero.Glob does not perform this check but it's required for implementations
if _, err := path.Match(pattern, ""); err != nil {
return nil, iofs.wrapError(op, pattern, err)
}
items, err := Glob(iofs.Fs, pattern)
if err != nil {
return nil, iofs.wrapError(op, pattern, err)
}
return items, nil
}
func (iofs IOFS) ReadDir(name string) ([]fs.DirEntry, error) {
f, err := iofs.Fs.Open(name)
if err != nil {
return nil, iofs.wrapError("readdir", name, err)
}
defer f.Close()
if rdf, ok := f.(fs.ReadDirFile); ok {
items, err := rdf.ReadDir(-1)
if err != nil {
return nil, iofs.wrapError("readdir", name, err)
}
sort.Slice(items, func(i, j int) bool { return items[i].Name() < items[j].Name() })
return items, nil
}
items, err := f.Readdir(-1)
if err != nil {
return nil, iofs.wrapError("readdir", name, err)
}
sort.Sort(byName(items))
ret := make([]fs.DirEntry, len(items))
for i := range items {
ret[i] = common.FileInfoDirEntry{FileInfo: items[i]}
}
return ret, nil
}
func (iofs IOFS) ReadFile(name string) ([]byte, error) {
const op = "readfile"
if !fs.ValidPath(name) {
return nil, iofs.wrapError(op, name, fs.ErrInvalid)
}
bytes, err := ReadFile(iofs.Fs, name)
if err != nil {
return nil, iofs.wrapError(op, name, err)
}
return bytes, nil
}
func (iofs IOFS) Sub(dir string) (fs.FS, error) { return IOFS{NewBasePathFs(iofs.Fs, dir)}, nil }
func (IOFS) wrapError(op, path string, err error) error {
if _, ok := err.(*fs.PathError); ok {
return err // don't need to wrap again
}
return &fs.PathError{
Op: op,
Path: path,
Err: err,
}
}
// readDirFile provides adapter from afero.File to fs.ReadDirFile needed for correct Open
type readDirFile struct {
File
}
var _ fs.ReadDirFile = readDirFile{}
func (r readDirFile) ReadDir(n int) ([]fs.DirEntry, error) {
items, err := r.File.Readdir(n)
if err != nil {
return nil, err
}
ret := make([]fs.DirEntry, len(items))
for i := range items {
ret[i] = common.FileInfoDirEntry{FileInfo: items[i]}
}
return ret, nil
}
// FromIOFS adopts io/fs.FS to use it as afero.Fs
// Note that io/fs.FS is read-only so all mutating methods will return fs.PathError with fs.ErrPermission
// To store modifications you may use afero.CopyOnWriteFs
type FromIOFS struct {
fs.FS
}
var _ Fs = FromIOFS{}
func (f FromIOFS) Create(name string) (File, error) { return nil, notImplemented("create", name) }
func (f FromIOFS) Mkdir(name string, perm os.FileMode) error { return notImplemented("mkdir", name) }
func (f FromIOFS) MkdirAll(path string, perm os.FileMode) error {
return notImplemented("mkdirall", path)
}
func (f FromIOFS) Open(name string) (File, error) {
file, err := f.FS.Open(name)
if err != nil {
return nil, err
}
return fromIOFSFile{File: file, name: name}, nil
}
func (f FromIOFS) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
return f.Open(name)
}
func (f FromIOFS) Remove(name string) error {
return notImplemented("remove", name)
}
func (f FromIOFS) RemoveAll(path string) error {
return notImplemented("removeall", path)
}
func (f FromIOFS) Rename(oldname, newname string) error {
return notImplemented("rename", oldname)
}
func (f FromIOFS) Stat(name string) (os.FileInfo, error) { return fs.Stat(f.FS, name) }
func (f FromIOFS) Name() string { return "fromiofs" }
func (f FromIOFS) Chmod(name string, mode os.FileMode) error {
return notImplemented("chmod", name)
}
func (f FromIOFS) Chown(name string, uid, gid int) error {
return notImplemented("chown", name)
}
func (f FromIOFS) Chtimes(name string, atime time.Time, mtime time.Time) error {
return notImplemented("chtimes", name)
}
type fromIOFSFile struct {
fs.File
name string
}
func (f fromIOFSFile) ReadAt(p []byte, off int64) (n int, err error) {
readerAt, ok := f.File.(io.ReaderAt)
if !ok {
return -1, notImplemented("readat", f.name)
}
return readerAt.ReadAt(p, off)
}
func (f fromIOFSFile) Seek(offset int64, whence int) (int64, error) {
seeker, ok := f.File.(io.Seeker)
if !ok {
return -1, notImplemented("seek", f.name)
}
return seeker.Seek(offset, whence)
}
func (f fromIOFSFile) Write(p []byte) (n int, err error) {
return -1, notImplemented("write", f.name)
}
func (f fromIOFSFile) WriteAt(p []byte, off int64) (n int, err error) {
return -1, notImplemented("writeat", f.name)
}
func (f fromIOFSFile) Name() string { return f.name }
func (f fromIOFSFile) Readdir(count int) ([]os.FileInfo, error) {
rdfile, ok := f.File.(fs.ReadDirFile)
if !ok {
return nil, notImplemented("readdir", f.name)
}
entries, err := rdfile.ReadDir(count)
if err != nil {
return nil, err
}
ret := make([]os.FileInfo, len(entries))
for i := range entries {
ret[i], err = entries[i].Info()
if err != nil {
return nil, err
}
}
return ret, nil
}
func (f fromIOFSFile) Readdirnames(n int) ([]string, error) {
rdfile, ok := f.File.(fs.ReadDirFile)
if !ok {
return nil, notImplemented("readdir", f.name)
}
entries, err := rdfile.ReadDir(n)
if err != nil {
return nil, err
}
ret := make([]string, len(entries))
for i := range entries {
ret[i] = entries[i].Name()
}
return ret, nil
}
func (f fromIOFSFile) Sync() error { return nil }
func (f fromIOFSFile) Truncate(size int64) error {
return notImplemented("truncate", f.name)
}
func (f fromIOFSFile) WriteString(s string) (ret int, err error) {
return -1, notImplemented("writestring", f.name)
}
func notImplemented(op, path string) error {
return &fs.PathError{Op: op, Path: path, Err: fs.ErrPermission}
}

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// Copyright ©2015 The Go Authors
// Copyright ©2015 Steve Francia <spf@spf13.com>
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"bytes"
"io"
"os"
"path/filepath"
"sort"
"strconv"
"strings"
"sync"
"time"
)
// byName implements sort.Interface.
type byName []os.FileInfo
func (f byName) Len() int { return len(f) }
func (f byName) Less(i, j int) bool { return f[i].Name() < f[j].Name() }
func (f byName) Swap(i, j int) { f[i], f[j] = f[j], f[i] }
// ReadDir reads the directory named by dirname and returns
// a list of sorted directory entries.
func (a Afero) ReadDir(dirname string) ([]os.FileInfo, error) {
return ReadDir(a.Fs, dirname)
}
func ReadDir(fs Fs, dirname string) ([]os.FileInfo, error) {
f, err := fs.Open(dirname)
if err != nil {
return nil, err
}
list, err := f.Readdir(-1)
f.Close()
if err != nil {
return nil, err
}
sort.Sort(byName(list))
return list, nil
}
// ReadFile reads the file named by filename and returns the contents.
// A successful call returns err == nil, not err == EOF. Because ReadFile
// reads the whole file, it does not treat an EOF from Read as an error
// to be reported.
func (a Afero) ReadFile(filename string) ([]byte, error) {
return ReadFile(a.Fs, filename)
}
func ReadFile(fs Fs, filename string) ([]byte, error) {
f, err := fs.Open(filename)
if err != nil {
return nil, err
}
defer f.Close()
// It's a good but not certain bet that FileInfo will tell us exactly how much to
// read, so let's try it but be prepared for the answer to be wrong.
var n int64
if fi, err := f.Stat(); err == nil {
// Don't preallocate a huge buffer, just in case.
if size := fi.Size(); size < 1e9 {
n = size
}
}
// As initial capacity for readAll, use n + a little extra in case Size is zero,
// and to avoid another allocation after Read has filled the buffer. The readAll
// call will read into its allocated internal buffer cheaply. If the size was
// wrong, we'll either waste some space off the end or reallocate as needed, but
// in the overwhelmingly common case we'll get it just right.
return readAll(f, n+bytes.MinRead)
}
// readAll reads from r until an error or EOF and returns the data it read
// from the internal buffer allocated with a specified capacity.
func readAll(r io.Reader, capacity int64) (b []byte, err error) {
buf := bytes.NewBuffer(make([]byte, 0, capacity))
// If the buffer overflows, we will get bytes.ErrTooLarge.
// Return that as an error. Any other panic remains.
defer func() {
e := recover()
if e == nil {
return
}
if panicErr, ok := e.(error); ok && panicErr == bytes.ErrTooLarge {
err = panicErr
} else {
panic(e)
}
}()
_, err = buf.ReadFrom(r)
return buf.Bytes(), err
}
// ReadAll reads from r until an error or EOF and returns the data it read.
// A successful call returns err == nil, not err == EOF. Because ReadAll is
// defined to read from src until EOF, it does not treat an EOF from Read
// as an error to be reported.
func ReadAll(r io.Reader) ([]byte, error) {
return readAll(r, bytes.MinRead)
}
// WriteFile writes data to a file named by filename.
// If the file does not exist, WriteFile creates it with permissions perm;
// otherwise WriteFile truncates it before writing.
func (a Afero) WriteFile(filename string, data []byte, perm os.FileMode) error {
return WriteFile(a.Fs, filename, data, perm)
}
func WriteFile(fs Fs, filename string, data []byte, perm os.FileMode) error {
f, err := fs.OpenFile(filename, os.O_WRONLY|os.O_CREATE|os.O_TRUNC, perm)
if err != nil {
return err
}
n, err := f.Write(data)
if err == nil && n < len(data) {
err = io.ErrShortWrite
}
if err1 := f.Close(); err == nil {
err = err1
}
return err
}
// Random number state.
// We generate random temporary file names so that there's a good
// chance the file doesn't exist yet - keeps the number of tries in
// TempFile to a minimum.
var (
randNum uint32
randmu sync.Mutex
)
func reseed() uint32 {
return uint32(time.Now().UnixNano() + int64(os.Getpid()))
}
func nextRandom() string {
randmu.Lock()
r := randNum
if r == 0 {
r = reseed()
}
r = r*1664525 + 1013904223 // constants from Numerical Recipes
randNum = r
randmu.Unlock()
return strconv.Itoa(int(1e9 + r%1e9))[1:]
}
// TempFile creates a new temporary file in the directory dir,
// opens the file for reading and writing, and returns the resulting *os.File.
// The filename is generated by taking pattern and adding a random
// string to the end. If pattern includes a "*", the random string
// replaces the last "*".
// If dir is the empty string, TempFile uses the default directory
// for temporary files (see os.TempDir).
// Multiple programs calling TempFile simultaneously
// will not choose the same file. The caller can use f.Name()
// to find the pathname of the file. It is the caller's responsibility
// to remove the file when no longer needed.
func (a Afero) TempFile(dir, pattern string) (f File, err error) {
return TempFile(a.Fs, dir, pattern)
}
func TempFile(fs Fs, dir, pattern string) (f File, err error) {
if dir == "" {
dir = os.TempDir()
}
var prefix, suffix string
if pos := strings.LastIndex(pattern, "*"); pos != -1 {
prefix, suffix = pattern[:pos], pattern[pos+1:]
} else {
prefix = pattern
}
nconflict := 0
for i := 0; i < 10000; i++ {
name := filepath.Join(dir, prefix+nextRandom()+suffix)
f, err = fs.OpenFile(name, os.O_RDWR|os.O_CREATE|os.O_EXCL, 0o600)
if os.IsExist(err) {
if nconflict++; nconflict > 10 {
randmu.Lock()
randNum = reseed()
randmu.Unlock()
}
continue
}
break
}
return
}
// TempDir creates a new temporary directory in the directory dir
// with a name beginning with prefix and returns the path of the
// new directory. If dir is the empty string, TempDir uses the
// default directory for temporary files (see os.TempDir).
// Multiple programs calling TempDir simultaneously
// will not choose the same directory. It is the caller's responsibility
// to remove the directory when no longer needed.
func (a Afero) TempDir(dir, prefix string) (name string, err error) {
return TempDir(a.Fs, dir, prefix)
}
func TempDir(fs Fs, dir, prefix string) (name string, err error) {
if dir == "" {
dir = os.TempDir()
}
nconflict := 0
for i := 0; i < 10000; i++ {
try := filepath.Join(dir, prefix+nextRandom())
err = fs.Mkdir(try, 0o700)
if os.IsExist(err) {
if nconflict++; nconflict > 10 {
randmu.Lock()
randNum = reseed()
randmu.Unlock()
}
continue
}
if err == nil {
name = try
}
break
}
return
}

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vendor/github.com/spf13/afero/lstater.go generated vendored Normal file
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// Copyright © 2018 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"os"
)
// Lstater is an optional interface in Afero. It is only implemented by the
// filesystems saying so.
// It will call Lstat if the filesystem iself is, or it delegates to, the os filesystem.
// Else it will call Stat.
// In addtion to the FileInfo, it will return a boolean telling whether Lstat was called or not.
type Lstater interface {
LstatIfPossible(name string) (os.FileInfo, bool, error)
}

110
vendor/github.com/spf13/afero/match.go generated vendored Normal file
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// Copyright © 2014 Steve Francia <spf@spf13.com>.
// Copyright 2009 The Go Authors. All rights reserved.
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"path/filepath"
"sort"
"strings"
)
// Glob returns the names of all files matching pattern or nil
// if there is no matching file. The syntax of patterns is the same
// as in Match. The pattern may describe hierarchical names such as
// /usr/*/bin/ed (assuming the Separator is '/').
//
// Glob ignores file system errors such as I/O errors reading directories.
// The only possible returned error is ErrBadPattern, when pattern
// is malformed.
//
// This was adapted from (http://golang.org/pkg/path/filepath) and uses several
// built-ins from that package.
func Glob(fs Fs, pattern string) (matches []string, err error) {
if !hasMeta(pattern) {
// Lstat not supported by a ll filesystems.
if _, err = lstatIfPossible(fs, pattern); err != nil {
return nil, nil
}
return []string{pattern}, nil
}
dir, file := filepath.Split(pattern)
switch dir {
case "":
dir = "."
case string(filepath.Separator):
// nothing
default:
dir = dir[0 : len(dir)-1] // chop off trailing separator
}
if !hasMeta(dir) {
return glob(fs, dir, file, nil)
}
var m []string
m, err = Glob(fs, dir)
if err != nil {
return
}
for _, d := range m {
matches, err = glob(fs, d, file, matches)
if err != nil {
return
}
}
return
}
// glob searches for files matching pattern in the directory dir
// and appends them to matches. If the directory cannot be
// opened, it returns the existing matches. New matches are
// added in lexicographical order.
func glob(fs Fs, dir, pattern string, matches []string) (m []string, e error) {
m = matches
fi, err := fs.Stat(dir)
if err != nil {
return
}
if !fi.IsDir() {
return
}
d, err := fs.Open(dir)
if err != nil {
return
}
defer d.Close()
names, _ := d.Readdirnames(-1)
sort.Strings(names)
for _, n := range names {
matched, err := filepath.Match(pattern, n)
if err != nil {
return m, err
}
if matched {
m = append(m, filepath.Join(dir, n))
}
}
return
}
// hasMeta reports whether path contains any of the magic characters
// recognized by Match.
func hasMeta(path string) bool {
// TODO(niemeyer): Should other magic characters be added here?
return strings.ContainsAny(path, "*?[")
}

37
vendor/github.com/spf13/afero/mem/dir.go generated vendored Normal file
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// Copyright © 2014 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package mem
type Dir interface {
Len() int
Names() []string
Files() []*FileData
Add(*FileData)
Remove(*FileData)
}
func RemoveFromMemDir(dir *FileData, f *FileData) {
dir.memDir.Remove(f)
}
func AddToMemDir(dir *FileData, f *FileData) {
dir.memDir.Add(f)
}
func InitializeDir(d *FileData) {
if d.memDir == nil {
d.dir = true
d.memDir = &DirMap{}
}
}

43
vendor/github.com/spf13/afero/mem/dirmap.go generated vendored Normal file
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// Copyright © 2015 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package mem
import "sort"
type DirMap map[string]*FileData
func (m DirMap) Len() int { return len(m) }
func (m DirMap) Add(f *FileData) { m[f.name] = f }
func (m DirMap) Remove(f *FileData) { delete(m, f.name) }
func (m DirMap) Files() (files []*FileData) {
for _, f := range m {
files = append(files, f)
}
sort.Sort(filesSorter(files))
return files
}
// implement sort.Interface for []*FileData
type filesSorter []*FileData
func (s filesSorter) Len() int { return len(s) }
func (s filesSorter) Swap(i, j int) { s[i], s[j] = s[j], s[i] }
func (s filesSorter) Less(i, j int) bool { return s[i].name < s[j].name }
func (m DirMap) Names() (names []string) {
for x := range m {
names = append(names, x)
}
return names
}

359
vendor/github.com/spf13/afero/mem/file.go generated vendored Normal file
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// Copyright © 2015 Steve Francia <spf@spf13.com>.
// Copyright 2013 tsuru authors. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package mem
import (
"bytes"
"errors"
"io"
"io/fs"
"os"
"path/filepath"
"sync"
"sync/atomic"
"time"
"github.com/spf13/afero/internal/common"
)
const FilePathSeparator = string(filepath.Separator)
var _ fs.ReadDirFile = &File{}
type File struct {
// atomic requires 64-bit alignment for struct field access
at int64
readDirCount int64
closed bool
readOnly bool
fileData *FileData
}
func NewFileHandle(data *FileData) *File {
return &File{fileData: data}
}
func NewReadOnlyFileHandle(data *FileData) *File {
return &File{fileData: data, readOnly: true}
}
func (f File) Data() *FileData {
return f.fileData
}
type FileData struct {
sync.Mutex
name string
data []byte
memDir Dir
dir bool
mode os.FileMode
modtime time.Time
uid int
gid int
}
func (d *FileData) Name() string {
d.Lock()
defer d.Unlock()
return d.name
}
func CreateFile(name string) *FileData {
return &FileData{name: name, mode: os.ModeTemporary, modtime: time.Now()}
}
func CreateDir(name string) *FileData {
return &FileData{name: name, memDir: &DirMap{}, dir: true, modtime: time.Now()}
}
func ChangeFileName(f *FileData, newname string) {
f.Lock()
f.name = newname
f.Unlock()
}
func SetMode(f *FileData, mode os.FileMode) {
f.Lock()
f.mode = mode
f.Unlock()
}
func SetModTime(f *FileData, mtime time.Time) {
f.Lock()
setModTime(f, mtime)
f.Unlock()
}
func setModTime(f *FileData, mtime time.Time) {
f.modtime = mtime
}
func SetUID(f *FileData, uid int) {
f.Lock()
f.uid = uid
f.Unlock()
}
func SetGID(f *FileData, gid int) {
f.Lock()
f.gid = gid
f.Unlock()
}
func GetFileInfo(f *FileData) *FileInfo {
return &FileInfo{f}
}
func (f *File) Open() error {
atomic.StoreInt64(&f.at, 0)
atomic.StoreInt64(&f.readDirCount, 0)
f.fileData.Lock()
f.closed = false
f.fileData.Unlock()
return nil
}
func (f *File) Close() error {
f.fileData.Lock()
f.closed = true
if !f.readOnly {
setModTime(f.fileData, time.Now())
}
f.fileData.Unlock()
return nil
}
func (f *File) Name() string {
return f.fileData.Name()
}
func (f *File) Stat() (os.FileInfo, error) {
return &FileInfo{f.fileData}, nil
}
func (f *File) Sync() error {
return nil
}
func (f *File) Readdir(count int) (res []os.FileInfo, err error) {
if !f.fileData.dir {
return nil, &os.PathError{Op: "readdir", Path: f.fileData.name, Err: errors.New("not a dir")}
}
var outLength int64
f.fileData.Lock()
files := f.fileData.memDir.Files()[f.readDirCount:]
if count > 0 {
if len(files) < count {
outLength = int64(len(files))
} else {
outLength = int64(count)
}
if len(files) == 0 {
err = io.EOF
}
} else {
outLength = int64(len(files))
}
f.readDirCount += outLength
f.fileData.Unlock()
res = make([]os.FileInfo, outLength)
for i := range res {
res[i] = &FileInfo{files[i]}
}
return res, err
}
func (f *File) Readdirnames(n int) (names []string, err error) {
fi, err := f.Readdir(n)
names = make([]string, len(fi))
for i, f := range fi {
_, names[i] = filepath.Split(f.Name())
}
return names, err
}
// Implements fs.ReadDirFile
func (f *File) ReadDir(n int) ([]fs.DirEntry, error) {
fi, err := f.Readdir(n)
if err != nil {
return nil, err
}
di := make([]fs.DirEntry, len(fi))
for i, f := range fi {
di[i] = common.FileInfoDirEntry{FileInfo: f}
}
return di, nil
}
func (f *File) Read(b []byte) (n int, err error) {
f.fileData.Lock()
defer f.fileData.Unlock()
if f.closed {
return 0, ErrFileClosed
}
if len(b) > 0 && int(f.at) == len(f.fileData.data) {
return 0, io.EOF
}
if int(f.at) > len(f.fileData.data) {
return 0, io.ErrUnexpectedEOF
}
if len(f.fileData.data)-int(f.at) >= len(b) {
n = len(b)
} else {
n = len(f.fileData.data) - int(f.at)
}
copy(b, f.fileData.data[f.at:f.at+int64(n)])
atomic.AddInt64(&f.at, int64(n))
return
}
func (f *File) ReadAt(b []byte, off int64) (n int, err error) {
prev := atomic.LoadInt64(&f.at)
atomic.StoreInt64(&f.at, off)
n, err = f.Read(b)
atomic.StoreInt64(&f.at, prev)
return
}
func (f *File) Truncate(size int64) error {
if f.closed {
return ErrFileClosed
}
if f.readOnly {
return &os.PathError{Op: "truncate", Path: f.fileData.name, Err: errors.New("file handle is read only")}
}
if size < 0 {
return ErrOutOfRange
}
f.fileData.Lock()
defer f.fileData.Unlock()
if size > int64(len(f.fileData.data)) {
diff := size - int64(len(f.fileData.data))
f.fileData.data = append(f.fileData.data, bytes.Repeat([]byte{0o0}, int(diff))...)
} else {
f.fileData.data = f.fileData.data[0:size]
}
setModTime(f.fileData, time.Now())
return nil
}
func (f *File) Seek(offset int64, whence int) (int64, error) {
if f.closed {
return 0, ErrFileClosed
}
switch whence {
case io.SeekStart:
atomic.StoreInt64(&f.at, offset)
case io.SeekCurrent:
atomic.AddInt64(&f.at, offset)
case io.SeekEnd:
atomic.StoreInt64(&f.at, int64(len(f.fileData.data))+offset)
}
return f.at, nil
}
func (f *File) Write(b []byte) (n int, err error) {
if f.closed {
return 0, ErrFileClosed
}
if f.readOnly {
return 0, &os.PathError{Op: "write", Path: f.fileData.name, Err: errors.New("file handle is read only")}
}
n = len(b)
cur := atomic.LoadInt64(&f.at)
f.fileData.Lock()
defer f.fileData.Unlock()
diff := cur - int64(len(f.fileData.data))
var tail []byte
if n+int(cur) < len(f.fileData.data) {
tail = f.fileData.data[n+int(cur):]
}
if diff > 0 {
f.fileData.data = append(f.fileData.data, append(bytes.Repeat([]byte{0o0}, int(diff)), b...)...)
f.fileData.data = append(f.fileData.data, tail...)
} else {
f.fileData.data = append(f.fileData.data[:cur], b...)
f.fileData.data = append(f.fileData.data, tail...)
}
setModTime(f.fileData, time.Now())
atomic.AddInt64(&f.at, int64(n))
return
}
func (f *File) WriteAt(b []byte, off int64) (n int, err error) {
atomic.StoreInt64(&f.at, off)
return f.Write(b)
}
func (f *File) WriteString(s string) (ret int, err error) {
return f.Write([]byte(s))
}
func (f *File) Info() *FileInfo {
return &FileInfo{f.fileData}
}
type FileInfo struct {
*FileData
}
// Implements os.FileInfo
func (s *FileInfo) Name() string {
s.Lock()
_, name := filepath.Split(s.name)
s.Unlock()
return name
}
func (s *FileInfo) Mode() os.FileMode {
s.Lock()
defer s.Unlock()
return s.mode
}
func (s *FileInfo) ModTime() time.Time {
s.Lock()
defer s.Unlock()
return s.modtime
}
func (s *FileInfo) IsDir() bool {
s.Lock()
defer s.Unlock()
return s.dir
}
func (s *FileInfo) Sys() interface{} { return nil }
func (s *FileInfo) Size() int64 {
if s.IsDir() {
return int64(42)
}
s.Lock()
defer s.Unlock()
return int64(len(s.data))
}
var (
ErrFileClosed = errors.New("File is closed")
ErrOutOfRange = errors.New("out of range")
ErrTooLarge = errors.New("too large")
ErrFileNotFound = os.ErrNotExist
ErrFileExists = os.ErrExist
ErrDestinationExists = os.ErrExist
)

465
vendor/github.com/spf13/afero/memmap.go generated vendored Normal file
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// Copyright © 2014 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"fmt"
"io"
"log"
"os"
"path/filepath"
"sort"
"strings"
"sync"
"time"
"github.com/spf13/afero/mem"
)
const chmodBits = os.ModePerm | os.ModeSetuid | os.ModeSetgid | os.ModeSticky // Only a subset of bits are allowed to be changed. Documented under os.Chmod()
type MemMapFs struct {
mu sync.RWMutex
data map[string]*mem.FileData
init sync.Once
}
func NewMemMapFs() Fs {
return &MemMapFs{}
}
func (m *MemMapFs) getData() map[string]*mem.FileData {
m.init.Do(func() {
m.data = make(map[string]*mem.FileData)
// Root should always exist, right?
// TODO: what about windows?
root := mem.CreateDir(FilePathSeparator)
mem.SetMode(root, os.ModeDir|0o755)
m.data[FilePathSeparator] = root
})
return m.data
}
func (*MemMapFs) Name() string { return "MemMapFS" }
func (m *MemMapFs) Create(name string) (File, error) {
name = normalizePath(name)
m.mu.Lock()
file := mem.CreateFile(name)
m.getData()[name] = file
m.registerWithParent(file, 0)
m.mu.Unlock()
return mem.NewFileHandle(file), nil
}
func (m *MemMapFs) unRegisterWithParent(fileName string) error {
f, err := m.lockfreeOpen(fileName)
if err != nil {
return err
}
parent := m.findParent(f)
if parent == nil {
log.Panic("parent of ", f.Name(), " is nil")
}
parent.Lock()
mem.RemoveFromMemDir(parent, f)
parent.Unlock()
return nil
}
func (m *MemMapFs) findParent(f *mem.FileData) *mem.FileData {
pdir, _ := filepath.Split(f.Name())
pdir = filepath.Clean(pdir)
pfile, err := m.lockfreeOpen(pdir)
if err != nil {
return nil
}
return pfile
}
func (m *MemMapFs) findDescendants(name string) []*mem.FileData {
fData := m.getData()
descendants := make([]*mem.FileData, 0, len(fData))
for p, dFile := range fData {
if strings.HasPrefix(p, name+FilePathSeparator) {
descendants = append(descendants, dFile)
}
}
sort.Slice(descendants, func(i, j int) bool {
cur := len(strings.Split(descendants[i].Name(), FilePathSeparator))
next := len(strings.Split(descendants[j].Name(), FilePathSeparator))
return cur < next
})
return descendants
}
func (m *MemMapFs) registerWithParent(f *mem.FileData, perm os.FileMode) {
if f == nil {
return
}
parent := m.findParent(f)
if parent == nil {
pdir := filepath.Dir(filepath.Clean(f.Name()))
err := m.lockfreeMkdir(pdir, perm)
if err != nil {
// log.Println("Mkdir error:", err)
return
}
parent, err = m.lockfreeOpen(pdir)
if err != nil {
// log.Println("Open after Mkdir error:", err)
return
}
}
parent.Lock()
mem.InitializeDir(parent)
mem.AddToMemDir(parent, f)
parent.Unlock()
}
func (m *MemMapFs) lockfreeMkdir(name string, perm os.FileMode) error {
name = normalizePath(name)
x, ok := m.getData()[name]
if ok {
// Only return ErrFileExists if it's a file, not a directory.
i := mem.FileInfo{FileData: x}
if !i.IsDir() {
return ErrFileExists
}
} else {
item := mem.CreateDir(name)
mem.SetMode(item, os.ModeDir|perm)
m.getData()[name] = item
m.registerWithParent(item, perm)
}
return nil
}
func (m *MemMapFs) Mkdir(name string, perm os.FileMode) error {
perm &= chmodBits
name = normalizePath(name)
m.mu.RLock()
_, ok := m.getData()[name]
m.mu.RUnlock()
if ok {
return &os.PathError{Op: "mkdir", Path: name, Err: ErrFileExists}
}
m.mu.Lock()
// Dobule check that it doesn't exist.
if _, ok := m.getData()[name]; ok {
m.mu.Unlock()
return &os.PathError{Op: "mkdir", Path: name, Err: ErrFileExists}
}
item := mem.CreateDir(name)
mem.SetMode(item, os.ModeDir|perm)
m.getData()[name] = item
m.registerWithParent(item, perm)
m.mu.Unlock()
return m.setFileMode(name, perm|os.ModeDir)
}
func (m *MemMapFs) MkdirAll(path string, perm os.FileMode) error {
err := m.Mkdir(path, perm)
if err != nil {
if err.(*os.PathError).Err == ErrFileExists {
return nil
}
return err
}
return nil
}
// Handle some relative paths
func normalizePath(path string) string {
path = filepath.Clean(path)
switch path {
case ".":
return FilePathSeparator
case "..":
return FilePathSeparator
default:
return path
}
}
func (m *MemMapFs) Open(name string) (File, error) {
f, err := m.open(name)
if f != nil {
return mem.NewReadOnlyFileHandle(f), err
}
return nil, err
}
func (m *MemMapFs) openWrite(name string) (File, error) {
f, err := m.open(name)
if f != nil {
return mem.NewFileHandle(f), err
}
return nil, err
}
func (m *MemMapFs) open(name string) (*mem.FileData, error) {
name = normalizePath(name)
m.mu.RLock()
f, ok := m.getData()[name]
m.mu.RUnlock()
if !ok {
return nil, &os.PathError{Op: "open", Path: name, Err: ErrFileNotFound}
}
return f, nil
}
func (m *MemMapFs) lockfreeOpen(name string) (*mem.FileData, error) {
name = normalizePath(name)
f, ok := m.getData()[name]
if ok {
return f, nil
} else {
return nil, ErrFileNotFound
}
}
func (m *MemMapFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
perm &= chmodBits
chmod := false
file, err := m.openWrite(name)
if err == nil && (flag&os.O_EXCL > 0) {
return nil, &os.PathError{Op: "open", Path: name, Err: ErrFileExists}
}
if os.IsNotExist(err) && (flag&os.O_CREATE > 0) {
file, err = m.Create(name)
chmod = true
}
if err != nil {
return nil, err
}
if flag == os.O_RDONLY {
file = mem.NewReadOnlyFileHandle(file.(*mem.File).Data())
}
if flag&os.O_APPEND > 0 {
_, err = file.Seek(0, io.SeekEnd)
if err != nil {
file.Close()
return nil, err
}
}
if flag&os.O_TRUNC > 0 && flag&(os.O_RDWR|os.O_WRONLY) > 0 {
err = file.Truncate(0)
if err != nil {
file.Close()
return nil, err
}
}
if chmod {
return file, m.setFileMode(name, perm)
}
return file, nil
}
func (m *MemMapFs) Remove(name string) error {
name = normalizePath(name)
m.mu.Lock()
defer m.mu.Unlock()
if _, ok := m.getData()[name]; ok {
err := m.unRegisterWithParent(name)
if err != nil {
return &os.PathError{Op: "remove", Path: name, Err: err}
}
delete(m.getData(), name)
} else {
return &os.PathError{Op: "remove", Path: name, Err: os.ErrNotExist}
}
return nil
}
func (m *MemMapFs) RemoveAll(path string) error {
path = normalizePath(path)
m.mu.Lock()
m.unRegisterWithParent(path)
m.mu.Unlock()
m.mu.RLock()
defer m.mu.RUnlock()
for p := range m.getData() {
if p == path || strings.HasPrefix(p, path+FilePathSeparator) {
m.mu.RUnlock()
m.mu.Lock()
delete(m.getData(), p)
m.mu.Unlock()
m.mu.RLock()
}
}
return nil
}
func (m *MemMapFs) Rename(oldname, newname string) error {
oldname = normalizePath(oldname)
newname = normalizePath(newname)
if oldname == newname {
return nil
}
m.mu.RLock()
defer m.mu.RUnlock()
if _, ok := m.getData()[oldname]; ok {
m.mu.RUnlock()
m.mu.Lock()
err := m.unRegisterWithParent(oldname)
if err != nil {
return err
}
fileData := m.getData()[oldname]
mem.ChangeFileName(fileData, newname)
m.getData()[newname] = fileData
err = m.renameDescendants(oldname, newname)
if err != nil {
return err
}
delete(m.getData(), oldname)
m.registerWithParent(fileData, 0)
m.mu.Unlock()
m.mu.RLock()
} else {
return &os.PathError{Op: "rename", Path: oldname, Err: ErrFileNotFound}
}
return nil
}
func (m *MemMapFs) renameDescendants(oldname, newname string) error {
descendants := m.findDescendants(oldname)
removes := make([]string, 0, len(descendants))
for _, desc := range descendants {
descNewName := strings.Replace(desc.Name(), oldname, newname, 1)
err := m.unRegisterWithParent(desc.Name())
if err != nil {
return err
}
removes = append(removes, desc.Name())
mem.ChangeFileName(desc, descNewName)
m.getData()[descNewName] = desc
m.registerWithParent(desc, 0)
}
for _, r := range removes {
delete(m.getData(), r)
}
return nil
}
func (m *MemMapFs) LstatIfPossible(name string) (os.FileInfo, bool, error) {
fileInfo, err := m.Stat(name)
return fileInfo, false, err
}
func (m *MemMapFs) Stat(name string) (os.FileInfo, error) {
f, err := m.Open(name)
if err != nil {
return nil, err
}
fi := mem.GetFileInfo(f.(*mem.File).Data())
return fi, nil
}
func (m *MemMapFs) Chmod(name string, mode os.FileMode) error {
mode &= chmodBits
m.mu.RLock()
f, ok := m.getData()[name]
m.mu.RUnlock()
if !ok {
return &os.PathError{Op: "chmod", Path: name, Err: ErrFileNotFound}
}
prevOtherBits := mem.GetFileInfo(f).Mode() & ^chmodBits
mode = prevOtherBits | mode
return m.setFileMode(name, mode)
}
func (m *MemMapFs) setFileMode(name string, mode os.FileMode) error {
name = normalizePath(name)
m.mu.RLock()
f, ok := m.getData()[name]
m.mu.RUnlock()
if !ok {
return &os.PathError{Op: "chmod", Path: name, Err: ErrFileNotFound}
}
m.mu.Lock()
mem.SetMode(f, mode)
m.mu.Unlock()
return nil
}
func (m *MemMapFs) Chown(name string, uid, gid int) error {
name = normalizePath(name)
m.mu.RLock()
f, ok := m.getData()[name]
m.mu.RUnlock()
if !ok {
return &os.PathError{Op: "chown", Path: name, Err: ErrFileNotFound}
}
mem.SetUID(f, uid)
mem.SetGID(f, gid)
return nil
}
func (m *MemMapFs) Chtimes(name string, atime time.Time, mtime time.Time) error {
name = normalizePath(name)
m.mu.RLock()
f, ok := m.getData()[name]
m.mu.RUnlock()
if !ok {
return &os.PathError{Op: "chtimes", Path: name, Err: ErrFileNotFound}
}
m.mu.Lock()
mem.SetModTime(f, mtime)
m.mu.Unlock()
return nil
}
func (m *MemMapFs) List() {
for _, x := range m.data {
y := mem.FileInfo{FileData: x}
fmt.Println(x.Name(), y.Size())
}
}

113
vendor/github.com/spf13/afero/os.go generated vendored Normal file
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// Copyright © 2014 Steve Francia <spf@spf13.com>.
// Copyright 2013 tsuru authors. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"os"
"time"
)
var _ Lstater = (*OsFs)(nil)
// OsFs is a Fs implementation that uses functions provided by the os package.
//
// For details in any method, check the documentation of the os package
// (http://golang.org/pkg/os/).
type OsFs struct{}
func NewOsFs() Fs {
return &OsFs{}
}
func (OsFs) Name() string { return "OsFs" }
func (OsFs) Create(name string) (File, error) {
f, e := os.Create(name)
if f == nil {
// while this looks strange, we need to return a bare nil (of type nil) not
// a nil value of type *os.File or nil won't be nil
return nil, e
}
return f, e
}
func (OsFs) Mkdir(name string, perm os.FileMode) error {
return os.Mkdir(name, perm)
}
func (OsFs) MkdirAll(path string, perm os.FileMode) error {
return os.MkdirAll(path, perm)
}
func (OsFs) Open(name string) (File, error) {
f, e := os.Open(name)
if f == nil {
// while this looks strange, we need to return a bare nil (of type nil) not
// a nil value of type *os.File or nil won't be nil
return nil, e
}
return f, e
}
func (OsFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
f, e := os.OpenFile(name, flag, perm)
if f == nil {
// while this looks strange, we need to return a bare nil (of type nil) not
// a nil value of type *os.File or nil won't be nil
return nil, e
}
return f, e
}
func (OsFs) Remove(name string) error {
return os.Remove(name)
}
func (OsFs) RemoveAll(path string) error {
return os.RemoveAll(path)
}
func (OsFs) Rename(oldname, newname string) error {
return os.Rename(oldname, newname)
}
func (OsFs) Stat(name string) (os.FileInfo, error) {
return os.Stat(name)
}
func (OsFs) Chmod(name string, mode os.FileMode) error {
return os.Chmod(name, mode)
}
func (OsFs) Chown(name string, uid, gid int) error {
return os.Chown(name, uid, gid)
}
func (OsFs) Chtimes(name string, atime time.Time, mtime time.Time) error {
return os.Chtimes(name, atime, mtime)
}
func (OsFs) LstatIfPossible(name string) (os.FileInfo, bool, error) {
fi, err := os.Lstat(name)
return fi, true, err
}
func (OsFs) SymlinkIfPossible(oldname, newname string) error {
return os.Symlink(oldname, newname)
}
func (OsFs) ReadlinkIfPossible(name string) (string, error) {
return os.Readlink(name)
}

106
vendor/github.com/spf13/afero/path.go generated vendored Normal file
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// Copyright ©2015 The Go Authors
// Copyright ©2015 Steve Francia <spf@spf13.com>
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"os"
"path/filepath"
"sort"
)
// readDirNames reads the directory named by dirname and returns
// a sorted list of directory entries.
// adapted from https://golang.org/src/path/filepath/path.go
func readDirNames(fs Fs, dirname string) ([]string, error) {
f, err := fs.Open(dirname)
if err != nil {
return nil, err
}
names, err := f.Readdirnames(-1)
f.Close()
if err != nil {
return nil, err
}
sort.Strings(names)
return names, nil
}
// walk recursively descends path, calling walkFn
// adapted from https://golang.org/src/path/filepath/path.go
func walk(fs Fs, path string, info os.FileInfo, walkFn filepath.WalkFunc) error {
err := walkFn(path, info, nil)
if err != nil {
if info.IsDir() && err == filepath.SkipDir {
return nil
}
return err
}
if !info.IsDir() {
return nil
}
names, err := readDirNames(fs, path)
if err != nil {
return walkFn(path, info, err)
}
for _, name := range names {
filename := filepath.Join(path, name)
fileInfo, err := lstatIfPossible(fs, filename)
if err != nil {
if err := walkFn(filename, fileInfo, err); err != nil && err != filepath.SkipDir {
return err
}
} else {
err = walk(fs, filename, fileInfo, walkFn)
if err != nil {
if !fileInfo.IsDir() || err != filepath.SkipDir {
return err
}
}
}
}
return nil
}
// if the filesystem supports it, use Lstat, else use fs.Stat
func lstatIfPossible(fs Fs, path string) (os.FileInfo, error) {
if lfs, ok := fs.(Lstater); ok {
fi, _, err := lfs.LstatIfPossible(path)
return fi, err
}
return fs.Stat(path)
}
// Walk walks the file tree rooted at root, calling walkFn for each file or
// directory in the tree, including root. All errors that arise visiting files
// and directories are filtered by walkFn. The files are walked in lexical
// order, which makes the output deterministic but means that for very
// large directories Walk can be inefficient.
// Walk does not follow symbolic links.
func (a Afero) Walk(root string, walkFn filepath.WalkFunc) error {
return Walk(a.Fs, root, walkFn)
}
func Walk(fs Fs, root string, walkFn filepath.WalkFunc) error {
info, err := lstatIfPossible(fs, root)
if err != nil {
return walkFn(root, nil, err)
}
return walk(fs, root, info, walkFn)
}

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vendor/github.com/spf13/afero/readonlyfs.go generated vendored Normal file
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package afero
import (
"os"
"syscall"
"time"
)
var _ Lstater = (*ReadOnlyFs)(nil)
type ReadOnlyFs struct {
source Fs
}
func NewReadOnlyFs(source Fs) Fs {
return &ReadOnlyFs{source: source}
}
func (r *ReadOnlyFs) ReadDir(name string) ([]os.FileInfo, error) {
return ReadDir(r.source, name)
}
func (r *ReadOnlyFs) Chtimes(n string, a, m time.Time) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) Chmod(n string, m os.FileMode) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) Chown(n string, uid, gid int) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) Name() string {
return "ReadOnlyFilter"
}
func (r *ReadOnlyFs) Stat(name string) (os.FileInfo, error) {
return r.source.Stat(name)
}
func (r *ReadOnlyFs) LstatIfPossible(name string) (os.FileInfo, bool, error) {
if lsf, ok := r.source.(Lstater); ok {
return lsf.LstatIfPossible(name)
}
fi, err := r.Stat(name)
return fi, false, err
}
func (r *ReadOnlyFs) SymlinkIfPossible(oldname, newname string) error {
return &os.LinkError{Op: "symlink", Old: oldname, New: newname, Err: ErrNoSymlink}
}
func (r *ReadOnlyFs) ReadlinkIfPossible(name string) (string, error) {
if srdr, ok := r.source.(LinkReader); ok {
return srdr.ReadlinkIfPossible(name)
}
return "", &os.PathError{Op: "readlink", Path: name, Err: ErrNoReadlink}
}
func (r *ReadOnlyFs) Rename(o, n string) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) RemoveAll(p string) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) Remove(n string) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
if flag&(os.O_WRONLY|syscall.O_RDWR|os.O_APPEND|os.O_CREATE|os.O_TRUNC) != 0 {
return nil, syscall.EPERM
}
return r.source.OpenFile(name, flag, perm)
}
func (r *ReadOnlyFs) Open(n string) (File, error) {
return r.source.Open(n)
}
func (r *ReadOnlyFs) Mkdir(n string, p os.FileMode) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) MkdirAll(n string, p os.FileMode) error {
return syscall.EPERM
}
func (r *ReadOnlyFs) Create(n string) (File, error) {
return nil, syscall.EPERM
}

223
vendor/github.com/spf13/afero/regexpfs.go generated vendored Normal file
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package afero
import (
"os"
"regexp"
"syscall"
"time"
)
// The RegexpFs filters files (not directories) by regular expression. Only
// files matching the given regexp will be allowed, all others get a ENOENT error (
// "No such file or directory").
type RegexpFs struct {
re *regexp.Regexp
source Fs
}
func NewRegexpFs(source Fs, re *regexp.Regexp) Fs {
return &RegexpFs{source: source, re: re}
}
type RegexpFile struct {
f File
re *regexp.Regexp
}
func (r *RegexpFs) matchesName(name string) error {
if r.re == nil {
return nil
}
if r.re.MatchString(name) {
return nil
}
return syscall.ENOENT
}
func (r *RegexpFs) dirOrMatches(name string) error {
dir, err := IsDir(r.source, name)
if err != nil {
return err
}
if dir {
return nil
}
return r.matchesName(name)
}
func (r *RegexpFs) Chtimes(name string, a, m time.Time) error {
if err := r.dirOrMatches(name); err != nil {
return err
}
return r.source.Chtimes(name, a, m)
}
func (r *RegexpFs) Chmod(name string, mode os.FileMode) error {
if err := r.dirOrMatches(name); err != nil {
return err
}
return r.source.Chmod(name, mode)
}
func (r *RegexpFs) Chown(name string, uid, gid int) error {
if err := r.dirOrMatches(name); err != nil {
return err
}
return r.source.Chown(name, uid, gid)
}
func (r *RegexpFs) Name() string {
return "RegexpFs"
}
func (r *RegexpFs) Stat(name string) (os.FileInfo, error) {
if err := r.dirOrMatches(name); err != nil {
return nil, err
}
return r.source.Stat(name)
}
func (r *RegexpFs) Rename(oldname, newname string) error {
dir, err := IsDir(r.source, oldname)
if err != nil {
return err
}
if dir {
return nil
}
if err := r.matchesName(oldname); err != nil {
return err
}
if err := r.matchesName(newname); err != nil {
return err
}
return r.source.Rename(oldname, newname)
}
func (r *RegexpFs) RemoveAll(p string) error {
dir, err := IsDir(r.source, p)
if err != nil {
return err
}
if !dir {
if err := r.matchesName(p); err != nil {
return err
}
}
return r.source.RemoveAll(p)
}
func (r *RegexpFs) Remove(name string) error {
if err := r.dirOrMatches(name); err != nil {
return err
}
return r.source.Remove(name)
}
func (r *RegexpFs) OpenFile(name string, flag int, perm os.FileMode) (File, error) {
if err := r.dirOrMatches(name); err != nil {
return nil, err
}
return r.source.OpenFile(name, flag, perm)
}
func (r *RegexpFs) Open(name string) (File, error) {
dir, err := IsDir(r.source, name)
if err != nil {
return nil, err
}
if !dir {
if err := r.matchesName(name); err != nil {
return nil, err
}
}
f, err := r.source.Open(name)
if err != nil {
return nil, err
}
return &RegexpFile{f: f, re: r.re}, nil
}
func (r *RegexpFs) Mkdir(n string, p os.FileMode) error {
return r.source.Mkdir(n, p)
}
func (r *RegexpFs) MkdirAll(n string, p os.FileMode) error {
return r.source.MkdirAll(n, p)
}
func (r *RegexpFs) Create(name string) (File, error) {
if err := r.matchesName(name); err != nil {
return nil, err
}
return r.source.Create(name)
}
func (f *RegexpFile) Close() error {
return f.f.Close()
}
func (f *RegexpFile) Read(s []byte) (int, error) {
return f.f.Read(s)
}
func (f *RegexpFile) ReadAt(s []byte, o int64) (int, error) {
return f.f.ReadAt(s, o)
}
func (f *RegexpFile) Seek(o int64, w int) (int64, error) {
return f.f.Seek(o, w)
}
func (f *RegexpFile) Write(s []byte) (int, error) {
return f.f.Write(s)
}
func (f *RegexpFile) WriteAt(s []byte, o int64) (int, error) {
return f.f.WriteAt(s, o)
}
func (f *RegexpFile) Name() string {
return f.f.Name()
}
func (f *RegexpFile) Readdir(c int) (fi []os.FileInfo, err error) {
var rfi []os.FileInfo
rfi, err = f.f.Readdir(c)
if err != nil {
return nil, err
}
for _, i := range rfi {
if i.IsDir() || f.re.MatchString(i.Name()) {
fi = append(fi, i)
}
}
return fi, nil
}
func (f *RegexpFile) Readdirnames(c int) (n []string, err error) {
fi, err := f.Readdir(c)
if err != nil {
return nil, err
}
for _, s := range fi {
n = append(n, s.Name())
}
return n, nil
}
func (f *RegexpFile) Stat() (os.FileInfo, error) {
return f.f.Stat()
}
func (f *RegexpFile) Sync() error {
return f.f.Sync()
}
func (f *RegexpFile) Truncate(s int64) error {
return f.f.Truncate(s)
}
func (f *RegexpFile) WriteString(s string) (int, error) {
return f.f.WriteString(s)
}

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vendor/github.com/spf13/afero/symlink.go generated vendored Normal file
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// Copyright © 2018 Steve Francia <spf@spf13.com>.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"errors"
)
// Symlinker is an optional interface in Afero. It is only implemented by the
// filesystems saying so.
// It indicates support for 3 symlink related interfaces that implement the
// behaviors of the os methods:
// - Lstat
// - Symlink, and
// - Readlink
type Symlinker interface {
Lstater
Linker
LinkReader
}
// Linker is an optional interface in Afero. It is only implemented by the
// filesystems saying so.
// It will call Symlink if the filesystem itself is, or it delegates to, the os filesystem,
// or the filesystem otherwise supports Symlink's.
type Linker interface {
SymlinkIfPossible(oldname, newname string) error
}
// ErrNoSymlink is the error that will be wrapped in an os.LinkError if a file system
// does not support Symlink's either directly or through its delegated filesystem.
// As expressed by support for the Linker interface.
var ErrNoSymlink = errors.New("symlink not supported")
// LinkReader is an optional interface in Afero. It is only implemented by the
// filesystems saying so.
type LinkReader interface {
ReadlinkIfPossible(name string) (string, error)
}
// ErrNoReadlink is the error that will be wrapped in an os.Path if a file system
// does not support the readlink operation either directly or through its delegated filesystem.
// As expressed by support for the LinkReader interface.
var ErrNoReadlink = errors.New("readlink not supported")

330
vendor/github.com/spf13/afero/unionFile.go generated vendored Normal file
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package afero
import (
"io"
"os"
"path/filepath"
"syscall"
)
// The UnionFile implements the afero.File interface and will be returned
// when reading a directory present at least in the overlay or opening a file
// for writing.
//
// The calls to
// Readdir() and Readdirnames() merge the file os.FileInfo / names from the
// base and the overlay - for files present in both layers, only those
// from the overlay will be used.
//
// When opening files for writing (Create() / OpenFile() with the right flags)
// the operations will be done in both layers, starting with the overlay. A
// successful read in the overlay will move the cursor position in the base layer
// by the number of bytes read.
type UnionFile struct {
Base File
Layer File
Merger DirsMerger
off int
files []os.FileInfo
}
func (f *UnionFile) Close() error {
// first close base, so we have a newer timestamp in the overlay. If we'd close
// the overlay first, we'd get a cacheStale the next time we access this file
// -> cache would be useless ;-)
if f.Base != nil {
f.Base.Close()
}
if f.Layer != nil {
return f.Layer.Close()
}
return BADFD
}
func (f *UnionFile) Read(s []byte) (int, error) {
if f.Layer != nil {
n, err := f.Layer.Read(s)
if (err == nil || err == io.EOF) && f.Base != nil {
// advance the file position also in the base file, the next
// call may be a write at this position (or a seek with SEEK_CUR)
if _, seekErr := f.Base.Seek(int64(n), io.SeekCurrent); seekErr != nil {
// only overwrite err in case the seek fails: we need to
// report an eventual io.EOF to the caller
err = seekErr
}
}
return n, err
}
if f.Base != nil {
return f.Base.Read(s)
}
return 0, BADFD
}
func (f *UnionFile) ReadAt(s []byte, o int64) (int, error) {
if f.Layer != nil {
n, err := f.Layer.ReadAt(s, o)
if (err == nil || err == io.EOF) && f.Base != nil {
_, err = f.Base.Seek(o+int64(n), io.SeekStart)
}
return n, err
}
if f.Base != nil {
return f.Base.ReadAt(s, o)
}
return 0, BADFD
}
func (f *UnionFile) Seek(o int64, w int) (pos int64, err error) {
if f.Layer != nil {
pos, err = f.Layer.Seek(o, w)
if (err == nil || err == io.EOF) && f.Base != nil {
_, err = f.Base.Seek(o, w)
}
return pos, err
}
if f.Base != nil {
return f.Base.Seek(o, w)
}
return 0, BADFD
}
func (f *UnionFile) Write(s []byte) (n int, err error) {
if f.Layer != nil {
n, err = f.Layer.Write(s)
if err == nil && f.Base != nil { // hmm, do we have fixed size files where a write may hit the EOF mark?
_, err = f.Base.Write(s)
}
return n, err
}
if f.Base != nil {
return f.Base.Write(s)
}
return 0, BADFD
}
func (f *UnionFile) WriteAt(s []byte, o int64) (n int, err error) {
if f.Layer != nil {
n, err = f.Layer.WriteAt(s, o)
if err == nil && f.Base != nil {
_, err = f.Base.WriteAt(s, o)
}
return n, err
}
if f.Base != nil {
return f.Base.WriteAt(s, o)
}
return 0, BADFD
}
func (f *UnionFile) Name() string {
if f.Layer != nil {
return f.Layer.Name()
}
return f.Base.Name()
}
// DirsMerger is how UnionFile weaves two directories together.
// It takes the FileInfo slices from the layer and the base and returns a
// single view.
type DirsMerger func(lofi, bofi []os.FileInfo) ([]os.FileInfo, error)
var defaultUnionMergeDirsFn = func(lofi, bofi []os.FileInfo) ([]os.FileInfo, error) {
files := make(map[string]os.FileInfo)
for _, fi := range lofi {
files[fi.Name()] = fi
}
for _, fi := range bofi {
if _, exists := files[fi.Name()]; !exists {
files[fi.Name()] = fi
}
}
rfi := make([]os.FileInfo, len(files))
i := 0
for _, fi := range files {
rfi[i] = fi
i++
}
return rfi, nil
}
// Readdir will weave the two directories together and
// return a single view of the overlayed directories.
// At the end of the directory view, the error is io.EOF if c > 0.
func (f *UnionFile) Readdir(c int) (ofi []os.FileInfo, err error) {
var merge DirsMerger = f.Merger
if merge == nil {
merge = defaultUnionMergeDirsFn
}
if f.off == 0 {
var lfi []os.FileInfo
if f.Layer != nil {
lfi, err = f.Layer.Readdir(-1)
if err != nil {
return nil, err
}
}
var bfi []os.FileInfo
if f.Base != nil {
bfi, err = f.Base.Readdir(-1)
if err != nil {
return nil, err
}
}
merged, err := merge(lfi, bfi)
if err != nil {
return nil, err
}
f.files = append(f.files, merged...)
}
files := f.files[f.off:]
if c <= 0 {
return files, nil
}
if len(files) == 0 {
return nil, io.EOF
}
if c > len(files) {
c = len(files)
}
defer func() { f.off += c }()
return files[:c], nil
}
func (f *UnionFile) Readdirnames(c int) ([]string, error) {
rfi, err := f.Readdir(c)
if err != nil {
return nil, err
}
var names []string
for _, fi := range rfi {
names = append(names, fi.Name())
}
return names, nil
}
func (f *UnionFile) Stat() (os.FileInfo, error) {
if f.Layer != nil {
return f.Layer.Stat()
}
if f.Base != nil {
return f.Base.Stat()
}
return nil, BADFD
}
func (f *UnionFile) Sync() (err error) {
if f.Layer != nil {
err = f.Layer.Sync()
if err == nil && f.Base != nil {
err = f.Base.Sync()
}
return err
}
if f.Base != nil {
return f.Base.Sync()
}
return BADFD
}
func (f *UnionFile) Truncate(s int64) (err error) {
if f.Layer != nil {
err = f.Layer.Truncate(s)
if err == nil && f.Base != nil {
err = f.Base.Truncate(s)
}
return err
}
if f.Base != nil {
return f.Base.Truncate(s)
}
return BADFD
}
func (f *UnionFile) WriteString(s string) (n int, err error) {
if f.Layer != nil {
n, err = f.Layer.WriteString(s)
if err == nil && f.Base != nil {
_, err = f.Base.WriteString(s)
}
return n, err
}
if f.Base != nil {
return f.Base.WriteString(s)
}
return 0, BADFD
}
func copyFile(base Fs, layer Fs, name string, bfh File) error {
// First make sure the directory exists
exists, err := Exists(layer, filepath.Dir(name))
if err != nil {
return err
}
if !exists {
err = layer.MkdirAll(filepath.Dir(name), 0o777) // FIXME?
if err != nil {
return err
}
}
// Create the file on the overlay
lfh, err := layer.Create(name)
if err != nil {
return err
}
n, err := io.Copy(lfh, bfh)
if err != nil {
// If anything fails, clean up the file
layer.Remove(name)
lfh.Close()
return err
}
bfi, err := bfh.Stat()
if err != nil || bfi.Size() != n {
layer.Remove(name)
lfh.Close()
return syscall.EIO
}
err = lfh.Close()
if err != nil {
layer.Remove(name)
lfh.Close()
return err
}
return layer.Chtimes(name, bfi.ModTime(), bfi.ModTime())
}
func copyToLayer(base Fs, layer Fs, name string) error {
bfh, err := base.Open(name)
if err != nil {
return err
}
defer bfh.Close()
return copyFile(base, layer, name, bfh)
}
func copyFileToLayer(base Fs, layer Fs, name string, flag int, perm os.FileMode) error {
bfh, err := base.OpenFile(name, flag, perm)
if err != nil {
return err
}
defer bfh.Close()
return copyFile(base, layer, name, bfh)
}

329
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// Copyright ©2015 Steve Francia <spf@spf13.com>
// Portions Copyright ©2015 The Hugo Authors
// Portions Copyright 2016-present Bjørn Erik Pedersen <bjorn.erik.pedersen@gmail.com>
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package afero
import (
"bytes"
"fmt"
"io"
"os"
"path/filepath"
"strings"
"unicode"
"golang.org/x/text/runes"
"golang.org/x/text/transform"
"golang.org/x/text/unicode/norm"
)
// Filepath separator defined by os.Separator.
const FilePathSeparator = string(filepath.Separator)
// Takes a reader and a path and writes the content
func (a Afero) WriteReader(path string, r io.Reader) (err error) {
return WriteReader(a.Fs, path, r)
}
func WriteReader(fs Fs, path string, r io.Reader) (err error) {
dir, _ := filepath.Split(path)
ospath := filepath.FromSlash(dir)
if ospath != "" {
err = fs.MkdirAll(ospath, 0o777) // rwx, rw, r
if err != nil {
if err != os.ErrExist {
return err
}
}
}
file, err := fs.Create(path)
if err != nil {
return
}
defer file.Close()
_, err = io.Copy(file, r)
return
}
// Same as WriteReader but checks to see if file/directory already exists.
func (a Afero) SafeWriteReader(path string, r io.Reader) (err error) {
return SafeWriteReader(a.Fs, path, r)
}
func SafeWriteReader(fs Fs, path string, r io.Reader) (err error) {
dir, _ := filepath.Split(path)
ospath := filepath.FromSlash(dir)
if ospath != "" {
err = fs.MkdirAll(ospath, 0o777) // rwx, rw, r
if err != nil {
return
}
}
exists, err := Exists(fs, path)
if err != nil {
return
}
if exists {
return fmt.Errorf("%v already exists", path)
}
file, err := fs.Create(path)
if err != nil {
return
}
defer file.Close()
_, err = io.Copy(file, r)
return
}
func (a Afero) GetTempDir(subPath string) string {
return GetTempDir(a.Fs, subPath)
}
// GetTempDir returns the default temp directory with trailing slash
// if subPath is not empty then it will be created recursively with mode 777 rwx rwx rwx
func GetTempDir(fs Fs, subPath string) string {
addSlash := func(p string) string {
if FilePathSeparator != p[len(p)-1:] {
p = p + FilePathSeparator
}
return p
}
dir := addSlash(os.TempDir())
if subPath != "" {
// preserve windows backslash :-(
if FilePathSeparator == "\\" {
subPath = strings.Replace(subPath, "\\", "____", -1)
}
dir = dir + UnicodeSanitize((subPath))
if FilePathSeparator == "\\" {
dir = strings.Replace(dir, "____", "\\", -1)
}
if exists, _ := Exists(fs, dir); exists {
return addSlash(dir)
}
err := fs.MkdirAll(dir, 0o777)
if err != nil {
panic(err)
}
dir = addSlash(dir)
}
return dir
}
// Rewrite string to remove non-standard path characters
func UnicodeSanitize(s string) string {
source := []rune(s)
target := make([]rune, 0, len(source))
for _, r := range source {
if unicode.IsLetter(r) ||
unicode.IsDigit(r) ||
unicode.IsMark(r) ||
r == '.' ||
r == '/' ||
r == '\\' ||
r == '_' ||
r == '-' ||
r == '%' ||
r == ' ' ||
r == '#' {
target = append(target, r)
}
}
return string(target)
}
// Transform characters with accents into plain forms.
func NeuterAccents(s string) string {
t := transform.Chain(norm.NFD, runes.Remove(runes.In(unicode.Mn)), norm.NFC)
result, _, _ := transform.String(t, string(s))
return result
}
func (a Afero) FileContainsBytes(filename string, subslice []byte) (bool, error) {
return FileContainsBytes(a.Fs, filename, subslice)
}
// Check if a file contains a specified byte slice.
func FileContainsBytes(fs Fs, filename string, subslice []byte) (bool, error) {
f, err := fs.Open(filename)
if err != nil {
return false, err
}
defer f.Close()
return readerContainsAny(f, subslice), nil
}
func (a Afero) FileContainsAnyBytes(filename string, subslices [][]byte) (bool, error) {
return FileContainsAnyBytes(a.Fs, filename, subslices)
}
// Check if a file contains any of the specified byte slices.
func FileContainsAnyBytes(fs Fs, filename string, subslices [][]byte) (bool, error) {
f, err := fs.Open(filename)
if err != nil {
return false, err
}
defer f.Close()
return readerContainsAny(f, subslices...), nil
}
// readerContains reports whether any of the subslices is within r.
func readerContainsAny(r io.Reader, subslices ...[]byte) bool {
if r == nil || len(subslices) == 0 {
return false
}
largestSlice := 0
for _, sl := range subslices {
if len(sl) > largestSlice {
largestSlice = len(sl)
}
}
if largestSlice == 0 {
return false
}
bufflen := largestSlice * 4
halflen := bufflen / 2
buff := make([]byte, bufflen)
var err error
var n, i int
for {
i++
if i == 1 {
n, err = io.ReadAtLeast(r, buff[:halflen], halflen)
} else {
if i != 2 {
// shift left to catch overlapping matches
copy(buff[:], buff[halflen:])
}
n, err = io.ReadAtLeast(r, buff[halflen:], halflen)
}
if n > 0 {
for _, sl := range subslices {
if bytes.Contains(buff, sl) {
return true
}
}
}
if err != nil {
break
}
}
return false
}
func (a Afero) DirExists(path string) (bool, error) {
return DirExists(a.Fs, path)
}
// DirExists checks if a path exists and is a directory.
func DirExists(fs Fs, path string) (bool, error) {
fi, err := fs.Stat(path)
if err == nil && fi.IsDir() {
return true, nil
}
if os.IsNotExist(err) {
return false, nil
}
return false, err
}
func (a Afero) IsDir(path string) (bool, error) {
return IsDir(a.Fs, path)
}
// IsDir checks if a given path is a directory.
func IsDir(fs Fs, path string) (bool, error) {
fi, err := fs.Stat(path)
if err != nil {
return false, err
}
return fi.IsDir(), nil
}
func (a Afero) IsEmpty(path string) (bool, error) {
return IsEmpty(a.Fs, path)
}
// IsEmpty checks if a given file or directory is empty.
func IsEmpty(fs Fs, path string) (bool, error) {
if b, _ := Exists(fs, path); !b {
return false, fmt.Errorf("%q path does not exist", path)
}
fi, err := fs.Stat(path)
if err != nil {
return false, err
}
if fi.IsDir() {
f, err := fs.Open(path)
if err != nil {
return false, err
}
defer f.Close()
list, err := f.Readdir(-1)
if err != nil {
return false, err
}
return len(list) == 0, nil
}
return fi.Size() == 0, nil
}
func (a Afero) Exists(path string) (bool, error) {
return Exists(a.Fs, path)
}
// Check if a file or directory exists.
func Exists(fs Fs, path string) (bool, error) {
_, err := fs.Stat(path)
if err == nil {
return true, nil
}
if os.IsNotExist(err) {
return false, nil
}
return false, err
}
func FullBaseFsPath(basePathFs *BasePathFs, relativePath string) string {
combinedPath := filepath.Join(basePathFs.path, relativePath)
if parent, ok := basePathFs.source.(*BasePathFs); ok {
return FullBaseFsPath(parent, combinedPath)
}
return combinedPath
}

25
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# Compiled Object files, Static and Dynamic libs (Shared Objects)
*.o
*.a
*.so
# Folders
_obj
_test
# Architecture specific extensions/prefixes
*.[568vq]
[568vq].out
*.cgo1.go
*.cgo2.c
_cgo_defun.c
_cgo_gotypes.go
_cgo_export.*
_testmain.go
*.exe
*.test
*.bench

21
vendor/github.com/spf13/cast/LICENSE generated vendored Normal file
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The MIT License (MIT)
Copyright (c) 2014 Steve Francia
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in all
copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE.

40
vendor/github.com/spf13/cast/Makefile generated vendored Normal file
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GOVERSION := $(shell go version | cut -d ' ' -f 3 | cut -d '.' -f 2)
.PHONY: check fmt lint test test-race vet test-cover-html help
.DEFAULT_GOAL := help
check: test-race fmt vet lint ## Run tests and linters
test: ## Run tests
go test ./...
test-race: ## Run tests with race detector
go test -race ./...
fmt: ## Run gofmt linter
ifeq "$(GOVERSION)" "12"
@for d in `go list` ; do \
if [ "`gofmt -l -s $$GOPATH/src/$$d | tee /dev/stderr`" ]; then \
echo "^ improperly formatted go files" && echo && exit 1; \
fi \
done
endif
lint: ## Run golint linter
@for d in `go list` ; do \
if [ "`golint $$d | tee /dev/stderr`" ]; then \
echo "^ golint errors!" && echo && exit 1; \
fi \
done
vet: ## Run go vet linter
@if [ "`go vet | tee /dev/stderr`" ]; then \
echo "^ go vet errors!" && echo && exit 1; \
fi
test-cover-html: ## Generate test coverage report
go test -coverprofile=coverage.out -covermode=count
go tool cover -func=coverage.out
help:
@grep -E '^[a-zA-Z0-9_-]+:.*?## .*$$' $(MAKEFILE_LIST) | sort | awk 'BEGIN {FS = ":.*?## "}; {printf "\033[36m%-30s\033[0m %s\n", $$1, $$2}'

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# cast
[![GitHub Workflow Status](https://img.shields.io/github/actions/workflow/status/spf13/cast/ci.yaml?branch=master&style=flat-square)](https://github.com/spf13/cast/actions/workflows/ci.yaml)
[![PkgGoDev](https://pkg.go.dev/badge/mod/github.com/spf13/cast)](https://pkg.go.dev/mod/github.com/spf13/cast)
![Go Version](https://img.shields.io/badge/go%20version-%3E=1.16-61CFDD.svg?style=flat-square)
[![Go Report Card](https://goreportcard.com/badge/github.com/spf13/cast?style=flat-square)](https://goreportcard.com/report/github.com/spf13/cast)
Easy and safe casting from one type to another in Go
Dont Panic! ... Cast
## What is Cast?
Cast is a library to convert between different go types in a consistent and easy way.
Cast provides simple functions to easily convert a number to a string, an
interface into a bool, etc. Cast does this intelligently when an obvious
conversion is possible. It doesnt make any attempts to guess what you meant,
for example you can only convert a string to an int when it is a string
representation of an int such as “8”. Cast was developed for use in
[Hugo](https://gohugo.io), a website engine which uses YAML, TOML or JSON
for meta data.
## Why use Cast?
When working with dynamic data in Go you often need to cast or convert the data
from one type into another. Cast goes beyond just using type assertion (though
it uses that when possible) to provide a very straightforward and convenient
library.
If you are working with interfaces to handle things like dynamic content
youll need an easy way to convert an interface into a given type. This
is the library for you.
If you are taking in data from YAML, TOML or JSON or other formats which lack
full types, then Cast is the library for you.
## Usage
Cast provides a handful of To_____ methods. These methods will always return
the desired type. **If input is provided that will not convert to that type, the
0 or nil value for that type will be returned**.
Cast also provides identical methods To_____E. These return the same result as
the To_____ methods, plus an additional error which tells you if it successfully
converted. Using these methods you can tell the difference between when the
input matched the zero value or when the conversion failed and the zero value
was returned.
The following examples are merely a sample of what is available. Please review
the code for a complete set.
### Example ToString:
cast.ToString("mayonegg") // "mayonegg"
cast.ToString(8) // "8"
cast.ToString(8.31) // "8.31"
cast.ToString([]byte("one time")) // "one time"
cast.ToString(nil) // ""
var foo interface{} = "one more time"
cast.ToString(foo) // "one more time"
### Example ToInt:
cast.ToInt(8) // 8
cast.ToInt(8.31) // 8
cast.ToInt("8") // 8
cast.ToInt(true) // 1
cast.ToInt(false) // 0
var eight interface{} = 8
cast.ToInt(eight) // 8
cast.ToInt(nil) // 0

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// Copyright © 2014 Steve Francia <spf@spf13.com>.
//
// Use of this source code is governed by an MIT-style
// license that can be found in the LICENSE file.
// Package cast provides easy and safe casting in Go.
package cast
import "time"
// ToBool casts an interface to a bool type.
func ToBool(i interface{}) bool {
v, _ := ToBoolE(i)
return v
}
// ToTime casts an interface to a time.Time type.
func ToTime(i interface{}) time.Time {
v, _ := ToTimeE(i)
return v
}
func ToTimeInDefaultLocation(i interface{}, location *time.Location) time.Time {
v, _ := ToTimeInDefaultLocationE(i, location)
return v
}
// ToDuration casts an interface to a time.Duration type.
func ToDuration(i interface{}) time.Duration {
v, _ := ToDurationE(i)
return v
}
// ToFloat64 casts an interface to a float64 type.
func ToFloat64(i interface{}) float64 {
v, _ := ToFloat64E(i)
return v
}
// ToFloat32 casts an interface to a float32 type.
func ToFloat32(i interface{}) float32 {
v, _ := ToFloat32E(i)
return v
}
// ToInt64 casts an interface to an int64 type.
func ToInt64(i interface{}) int64 {
v, _ := ToInt64E(i)
return v
}
// ToInt32 casts an interface to an int32 type.
func ToInt32(i interface{}) int32 {
v, _ := ToInt32E(i)
return v
}
// ToInt16 casts an interface to an int16 type.
func ToInt16(i interface{}) int16 {
v, _ := ToInt16E(i)
return v
}
// ToInt8 casts an interface to an int8 type.
func ToInt8(i interface{}) int8 {
v, _ := ToInt8E(i)
return v
}
// ToInt casts an interface to an int type.
func ToInt(i interface{}) int {
v, _ := ToIntE(i)
return v
}
// ToUint casts an interface to a uint type.
func ToUint(i interface{}) uint {
v, _ := ToUintE(i)
return v
}
// ToUint64 casts an interface to a uint64 type.
func ToUint64(i interface{}) uint64 {
v, _ := ToUint64E(i)
return v
}
// ToUint32 casts an interface to a uint32 type.
func ToUint32(i interface{}) uint32 {
v, _ := ToUint32E(i)
return v
}
// ToUint16 casts an interface to a uint16 type.
func ToUint16(i interface{}) uint16 {
v, _ := ToUint16E(i)
return v
}
// ToUint8 casts an interface to a uint8 type.
func ToUint8(i interface{}) uint8 {
v, _ := ToUint8E(i)
return v
}
// ToString casts an interface to a string type.
func ToString(i interface{}) string {
v, _ := ToStringE(i)
return v
}
// ToStringMapString casts an interface to a map[string]string type.
func ToStringMapString(i interface{}) map[string]string {
v, _ := ToStringMapStringE(i)
return v
}
// ToStringMapStringSlice casts an interface to a map[string][]string type.
func ToStringMapStringSlice(i interface{}) map[string][]string {
v, _ := ToStringMapStringSliceE(i)
return v
}
// ToStringMapBool casts an interface to a map[string]bool type.
func ToStringMapBool(i interface{}) map[string]bool {
v, _ := ToStringMapBoolE(i)
return v
}
// ToStringMapInt casts an interface to a map[string]int type.
func ToStringMapInt(i interface{}) map[string]int {
v, _ := ToStringMapIntE(i)
return v
}
// ToStringMapInt64 casts an interface to a map[string]int64 type.
func ToStringMapInt64(i interface{}) map[string]int64 {
v, _ := ToStringMapInt64E(i)
return v
}
// ToStringMap casts an interface to a map[string]interface{} type.
func ToStringMap(i interface{}) map[string]interface{} {
v, _ := ToStringMapE(i)
return v
}
// ToSlice casts an interface to a []interface{} type.
func ToSlice(i interface{}) []interface{} {
v, _ := ToSliceE(i)
return v
}
// ToBoolSlice casts an interface to a []bool type.
func ToBoolSlice(i interface{}) []bool {
v, _ := ToBoolSliceE(i)
return v
}
// ToStringSlice casts an interface to a []string type.
func ToStringSlice(i interface{}) []string {
v, _ := ToStringSliceE(i)
return v
}
// ToIntSlice casts an interface to a []int type.
func ToIntSlice(i interface{}) []int {
v, _ := ToIntSliceE(i)
return v
}
// ToDurationSlice casts an interface to a []time.Duration type.
func ToDurationSlice(i interface{}) []time.Duration {
v, _ := ToDurationSliceE(i)
return v
}

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27
vendor/github.com/spf13/cast/timeformattype_string.go generated vendored Normal file
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// Code generated by "stringer -type timeFormatType"; DO NOT EDIT.
package cast
import "strconv"
func _() {
// An "invalid array index" compiler error signifies that the constant values have changed.
// Re-run the stringer command to generate them again.
var x [1]struct{}
_ = x[timeFormatNoTimezone-0]
_ = x[timeFormatNamedTimezone-1]
_ = x[timeFormatNumericTimezone-2]
_ = x[timeFormatNumericAndNamedTimezone-3]
_ = x[timeFormatTimeOnly-4]
}
const _timeFormatType_name = "timeFormatNoTimezonetimeFormatNamedTimezonetimeFormatNumericTimezonetimeFormatNumericAndNamedTimezonetimeFormatTimeOnly"
var _timeFormatType_index = [...]uint8{0, 20, 43, 68, 101, 119}
func (i timeFormatType) String() string {
if i < 0 || i >= timeFormatType(len(_timeFormatType_index)-1) {
return "timeFormatType(" + strconv.FormatInt(int64(i), 10) + ")"
}
return _timeFormatType_name[_timeFormatType_index[i]:_timeFormatType_index[i+1]]
}

39
vendor/github.com/spf13/cobra/.gitignore generated vendored Normal file
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# Compiled Object files, Static and Dynamic libs (Shared Objects)
*.o
*.a
*.so
# Folders
_obj
_test
# Architecture specific extensions/prefixes
*.[568vq]
[568vq].out
*.cgo1.go
*.cgo2.c
_cgo_defun.c
_cgo_gotypes.go
_cgo_export.*
_testmain.go
# Vim files https://github.com/github/gitignore/blob/master/Global/Vim.gitignore
# swap
[._]*.s[a-w][a-z]
[._]s[a-w][a-z]
# session
Session.vim
# temporary
.netrwhist
*~
# auto-generated tag files
tags
*.exe
cobra.test
bin
.idea/
*.iml

62
vendor/github.com/spf13/cobra/.golangci.yml generated vendored Normal file
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# Copyright 2013-2023 The Cobra Authors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
run:
deadline: 5m
linters:
disable-all: true
enable:
#- bodyclose
# - deadcode ! deprecated since v1.49.0; replaced by 'unused'
#- depguard
#- dogsled
#- dupl
- errcheck
#- exhaustive
#- funlen
- gas
#- gochecknoinits
- goconst
#- gocritic
#- gocyclo
#- gofmt
- goimports
- golint
#- gomnd
#- goprintffuncname
#- gosec
#- gosimple
- govet
- ineffassign
- interfacer
#- lll
- maligned
- megacheck
#- misspell
#- nakedret
#- noctx
#- nolintlint
#- rowserrcheck
#- scopelint
#- staticcheck
#- structcheck ! deprecated since v1.49.0; replaced by 'unused'
#- stylecheck
#- typecheck
- unconvert
#- unparam
- unused
# - varcheck ! deprecated since v1.49.0; replaced by 'unused'
#- whitespace
fast: false

3
vendor/github.com/spf13/cobra/.mailmap generated vendored Normal file
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Steve Francia <steve.francia@gmail.com>
Bjørn Erik Pedersen <bjorn.erik.pedersen@gmail.com>
Fabiano Franz <ffranz@redhat.com> <contact@fabianofranz.com>

37
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## Cobra User Contract
### Versioning
Cobra will follow a steady release cadence. Non breaking changes will be released as minor versions quarterly. Patch bug releases are at the discretion of the maintainers. Users can expect security patch fixes to be released within relatively short order of a CVE becoming known. For more information on security patch fixes see the CVE section below. Releases will follow [Semantic Versioning](https://semver.org/). Users tracking the Master branch should expect unpredictable breaking changes as the project continues to move forward. For stability, it is highly recommended to use a release.
### Backward Compatibility
We will maintain two major releases in a moving window. The N-1 release will only receive bug fixes and security updates and will be dropped once N+1 is released.
### Deprecation
Deprecation of Go versions or dependent packages will only occur in major releases. To reduce the change of this taking users by surprise, any large deprecation will be preceded by an announcement in the [#cobra slack channel](https://gophers.slack.com/archives/CD3LP1199) and an Issue on Github.
### CVE
Maintainers will make every effort to release security patches in the case of a medium to high severity CVE directly impacting the library. The speed in which these patches reach a release is up to the discretion of the maintainers. A low severity CVE may be a lower priority than a high severity one.
### Communication
Cobra maintainers will use GitHub issues and the [#cobra slack channel](https://gophers.slack.com/archives/CD3LP1199) as the primary means of communication with the community. This is to foster open communication with all users and contributors.
### Breaking Changes
Breaking changes are generally allowed in the master branch, as this is the branch used to develop the next release of Cobra.
There may be times, however, when master is closed for breaking changes. This is likely to happen as we near the release of a new version.
Breaking changes are not allowed in release branches, as these represent minor versions that have already been released. These version have consumers who expect the APIs, behaviors, etc, to remain stable during the lifetime of the patch stream for the minor release.
Examples of breaking changes include:
- Removing or renaming exported constant, variable, type, or function.
- Updating the version of critical libraries such as `spf13/pflag`, `spf13/viper` etc...
- Some version updates may be acceptable for picking up bug fixes, but maintainers must exercise caution when reviewing.
There may, at times, need to be exceptions where breaking changes are allowed in release branches. These are at the discretion of the project's maintainers, and must be carefully considered before merging.
### CI Testing
Maintainers will ensure the Cobra test suite utilizes the current supported versions of Golang.
### Disclaimer
Changes to this document and the contents therein are at the discretion of the maintainers.
None of the contents of this document are legally binding in any way to the maintainers or the users.

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# Contributing to Cobra
Thank you so much for contributing to Cobra. We appreciate your time and help.
Here are some guidelines to help you get started.
## Code of Conduct
Be kind and respectful to the members of the community. Take time to educate
others who are seeking help. Harassment of any kind will not be tolerated.
## Questions
If you have questions regarding Cobra, feel free to ask it in the community
[#cobra Slack channel][cobra-slack]
## Filing a bug or feature
1. Before filing an issue, please check the existing issues to see if a
similar one was already opened. If there is one already opened, feel free
to comment on it.
1. If you believe you've found a bug, please provide detailed steps of
reproduction, the version of Cobra and anything else you believe will be
useful to help troubleshoot it (e.g. OS environment, environment variables,
etc...). Also state the current behavior vs. the expected behavior.
1. If you'd like to see a feature or an enhancement please open an issue with
a clear title and description of what the feature is and why it would be
beneficial to the project and its users.
## Submitting changes
1. CLA: Upon submitting a Pull Request (PR), contributors will be prompted to
sign a CLA. Please sign the CLA :slightly_smiling_face:
1. Tests: If you are submitting code, please ensure you have adequate tests
for the feature. Tests can be run via `go test ./...` or `make test`.
1. Since this is golang project, ensure the new code is properly formatted to
ensure code consistency. Run `make all`.
### Quick steps to contribute
1. Fork the project.
1. Download your fork to your PC (`git clone https://github.com/your_username/cobra && cd cobra`)
1. Create your feature branch (`git checkout -b my-new-feature`)
1. Make changes and run tests (`make test`)
1. Add them to staging (`git add .`)
1. Commit your changes (`git commit -m 'Add some feature'`)
1. Push to the branch (`git push origin my-new-feature`)
1. Create new pull request
<!-- Links -->
[cobra-slack]: https://gophers.slack.com/archives/CD3LP1199

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Apache License
Version 2.0, January 2004
http://www.apache.org/licenses/
TERMS AND CONDITIONS FOR USE, REPRODUCTION, AND DISTRIBUTION
1. Definitions.
"License" shall mean the terms and conditions for use, reproduction,
and distribution as defined by Sections 1 through 9 of this document.
"Licensor" shall mean the copyright owner or entity authorized by
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"Legal Entity" shall mean the union of the acting entity and all
other entities that control, are controlled by, or are under common
control with that entity. For the purposes of this definition,
"control" means (i) the power, direct or indirect, to cause the
direction or management of such entity, whether by contract or
otherwise, or (ii) ownership of fifty percent (50%) or more of the
outstanding shares, or (iii) beneficial ownership of such entity.
"You" (or "Your") shall mean an individual or Legal Entity
exercising permissions granted by this License.
"Source" form shall mean the preferred form for making modifications,
including but not limited to software source code, documentation
source, and configuration files.
"Object" form shall mean any form resulting from mechanical
transformation or translation of a Source form, including but
not limited to compiled object code, generated documentation,
and conversions to other media types.
"Work" shall mean the work of authorship, whether in Source or
Object form, made available under the License, as indicated by a
copyright notice that is included in or attached to the work
(an example is provided in the Appendix below).
"Derivative Works" shall mean any work, whether in Source or Object
form, that is based on (or derived from) the Work and for which the
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of this License, Derivative Works shall not include works that remain
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"Contribution" shall mean any work of authorship, including
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"Contributor" shall mean Licensor and any individual or Legal Entity
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2. Grant of Copyright License. Subject to the terms and conditions of
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(d) If the Work includes a "NOTICE" text file as part of its
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the conditions stated in this License.
5. Submission of Contributions. Unless You explicitly state otherwise,
any Contribution intentionally submitted for inclusion in the Work
by You to the Licensor shall be under the terms and conditions of
this License, without any additional terms or conditions.
Notwithstanding the above, nothing herein shall supersede or modify
the terms of any separate license agreement you may have executed
with Licensor regarding such Contributions.
6. Trademarks. This License does not grant permission to use the trade
names, trademarks, service marks, or product names of the Licensor,
except as required for reasonable and customary use in describing the
origin of the Work and reproducing the content of the NOTICE file.
7. Disclaimer of Warranty. Unless required by applicable law or
agreed to in writing, Licensor provides the Work (and each
Contributor provides its Contributions) on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
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of TITLE, NON-INFRINGEMENT, MERCHANTABILITY, or FITNESS FOR A
PARTICULAR PURPOSE. You are solely responsible for determining the
appropriateness of using or redistributing the Work and assume any
risks associated with Your exercise of permissions under this License.
8. Limitation of Liability. In no event and under no legal theory,
whether in tort (including negligence), contract, or otherwise,
unless required by applicable law (such as deliberate and grossly
negligent acts) or agreed to in writing, shall any Contributor be
liable to You for damages, including any direct, indirect, special,
incidental, or consequential damages of any character arising as a
result of this License or out of the use or inability to use the
Work (including but not limited to damages for loss of goodwill,
work stoppage, computer failure or malfunction, or any and all
other commercial damages or losses), even if such Contributor
has been advised of the possibility of such damages.
9. Accepting Warranty or Additional Liability. While redistributing
the Work or Derivative Works thereof, You may choose to offer,
and charge a fee for, acceptance of support, warranty, indemnity,
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License. However, in accepting such obligations, You may act only
on Your own behalf and on Your sole responsibility, not on behalf
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defend, and hold each Contributor harmless for any liability
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of your accepting any such warranty or additional liability.

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maintainers:
- spf13
- johnSchnake
- jpmcb
- marckhouzam
inactive:
- anthonyfok
- bep
- bogem
- broady
- eparis
- jharshman
- wfernandes

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BIN="./bin"
SRC=$(shell find . -name "*.go")
ifeq (, $(shell which golangci-lint))
$(warning "could not find golangci-lint in $(PATH), run: curl -sfL https://install.goreleaser.com/github.com/golangci/golangci-lint.sh | sh")
endif
.PHONY: fmt lint test install_deps clean
default: all
all: fmt test
fmt:
$(info ******************** checking formatting ********************)
@test -z $(shell gofmt -l $(SRC)) || (gofmt -d $(SRC); exit 1)
lint:
$(info ******************** running lint tools ********************)
golangci-lint run -v
test: install_deps
$(info ******************** running tests ********************)
go test -v ./...
richtest: install_deps
$(info ******************** running tests with kyoh86/richgo ********************)
richgo test -v ./...
install_deps:
$(info ******************** downloading dependencies ********************)
go get -v ./...
clean:
rm -rf $(BIN)

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![cobra logo](assets/CobraMain.png)
Cobra is a library for creating powerful modern CLI applications.
Cobra is used in many Go projects such as [Kubernetes](https://kubernetes.io/),
[Hugo](https://gohugo.io), and [GitHub CLI](https://github.com/cli/cli) to
name a few. [This list](site/content/projects_using_cobra.md) contains a more extensive list of projects using Cobra.
[![](https://img.shields.io/github/actions/workflow/status/spf13/cobra/test.yml?branch=main&longCache=true&label=Test&logo=github%20actions&logoColor=fff)](https://github.com/spf13/cobra/actions?query=workflow%3ATest)
[![Go Reference](https://pkg.go.dev/badge/github.com/spf13/cobra.svg)](https://pkg.go.dev/github.com/spf13/cobra)
[![Go Report Card](https://goreportcard.com/badge/github.com/spf13/cobra)](https://goreportcard.com/report/github.com/spf13/cobra)
[![Slack](https://img.shields.io/badge/Slack-cobra-brightgreen)](https://gophers.slack.com/archives/CD3LP1199)
# Overview
Cobra is a library providing a simple interface to create powerful modern CLI
interfaces similar to git & go tools.
Cobra provides:
* Easy subcommand-based CLIs: `app server`, `app fetch`, etc.
* Fully POSIX-compliant flags (including short & long versions)
* Nested subcommands
* Global, local and cascading flags
* Intelligent suggestions (`app srver`... did you mean `app server`?)
* Automatic help generation for commands and flags
* Grouping help for subcommands
* Automatic help flag recognition of `-h`, `--help`, etc.
* Automatically generated shell autocomplete for your application (bash, zsh, fish, powershell)
* Automatically generated man pages for your application
* Command aliases so you can change things without breaking them
* The flexibility to define your own help, usage, etc.
* Optional seamless integration with [viper](https://github.com/spf13/viper) for 12-factor apps
# Concepts
Cobra is built on a structure of commands, arguments & flags.
**Commands** represent actions, **Args** are things and **Flags** are modifiers for those actions.
The best applications read like sentences when used, and as a result, users
intuitively know how to interact with them.
The pattern to follow is
`APPNAME VERB NOUN --ADJECTIVE`
or
`APPNAME COMMAND ARG --FLAG`.
A few good real world examples may better illustrate this point.
In the following example, 'server' is a command, and 'port' is a flag:
hugo server --port=1313
In this command we are telling Git to clone the url bare.
git clone URL --bare
## Commands
Command is the central point of the application. Each interaction that
the application supports will be contained in a Command. A command can
have children commands and optionally run an action.
In the example above, 'server' is the command.
[More about cobra.Command](https://pkg.go.dev/github.com/spf13/cobra#Command)
## Flags
A flag is a way to modify the behavior of a command. Cobra supports
fully POSIX-compliant flags as well as the Go [flag package](https://golang.org/pkg/flag/).
A Cobra command can define flags that persist through to children commands
and flags that are only available to that command.
In the example above, 'port' is the flag.
Flag functionality is provided by the [pflag
library](https://github.com/spf13/pflag), a fork of the flag standard library
which maintains the same interface while adding POSIX compliance.
# Installing
Using Cobra is easy. First, use `go get` to install the latest version
of the library.
```
go get -u github.com/spf13/cobra@latest
```
Next, include Cobra in your application:
```go
import "github.com/spf13/cobra"
```
# Usage
`cobra-cli` is a command line program to generate cobra applications and command files.
It will bootstrap your application scaffolding to rapidly
develop a Cobra-based application. It is the easiest way to incorporate Cobra into your application.
It can be installed by running:
```
go install github.com/spf13/cobra-cli@latest
```
For complete details on using the Cobra-CLI generator, please read [The Cobra Generator README](https://github.com/spf13/cobra-cli/blob/main/README.md)
For complete details on using the Cobra library, please read the [The Cobra User Guide](site/content/user_guide.md).
# License
Cobra is released under the Apache 2.0 license. See [LICENSE.txt](LICENSE.txt)

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"fmt"
"os"
"regexp"
"strings"
)
const (
activeHelpMarker = "_activeHelp_ "
// The below values should not be changed: programs will be using them explicitly
// in their user documentation, and users will be using them explicitly.
activeHelpEnvVarSuffix = "_ACTIVE_HELP"
activeHelpGlobalEnvVar = "COBRA_ACTIVE_HELP"
activeHelpGlobalDisable = "0"
)
var activeHelpEnvVarPrefixSubstRegexp = regexp.MustCompile(`[^A-Z0-9_]`)
// AppendActiveHelp adds the specified string to the specified array to be used as ActiveHelp.
// Such strings will be processed by the completion script and will be shown as ActiveHelp
// to the user.
// The array parameter should be the array that will contain the completions.
// This function can be called multiple times before and/or after completions are added to
// the array. Each time this function is called with the same array, the new
// ActiveHelp line will be shown below the previous ones when completion is triggered.
func AppendActiveHelp(compArray []string, activeHelpStr string) []string {
return append(compArray, fmt.Sprintf("%s%s", activeHelpMarker, activeHelpStr))
}
// GetActiveHelpConfig returns the value of the ActiveHelp environment variable
// <PROGRAM>_ACTIVE_HELP where <PROGRAM> is the name of the root command in upper
// case, with all non-ASCII-alphanumeric characters replaced by `_`.
// It will always return "0" if the global environment variable COBRA_ACTIVE_HELP
// is set to "0".
func GetActiveHelpConfig(cmd *Command) string {
activeHelpCfg := os.Getenv(activeHelpGlobalEnvVar)
if activeHelpCfg != activeHelpGlobalDisable {
activeHelpCfg = os.Getenv(activeHelpEnvVar(cmd.Root().Name()))
}
return activeHelpCfg
}
// activeHelpEnvVar returns the name of the program-specific ActiveHelp environment
// variable. It has the format <PROGRAM>_ACTIVE_HELP where <PROGRAM> is the name of the
// root command in upper case, with all non-ASCII-alphanumeric characters replaced by `_`.
func activeHelpEnvVar(name string) string {
// This format should not be changed: users will be using it explicitly.
activeHelpEnvVar := strings.ToUpper(fmt.Sprintf("%s%s", name, activeHelpEnvVarSuffix))
activeHelpEnvVar = activeHelpEnvVarPrefixSubstRegexp.ReplaceAllString(activeHelpEnvVar, "_")
return activeHelpEnvVar
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"fmt"
"strings"
)
type PositionalArgs func(cmd *Command, args []string) error
// legacyArgs validation has the following behaviour:
// - root commands with no subcommands can take arbitrary arguments
// - root commands with subcommands will do subcommand validity checking
// - subcommands will always accept arbitrary arguments
func legacyArgs(cmd *Command, args []string) error {
// no subcommand, always take args
if !cmd.HasSubCommands() {
return nil
}
// root command with subcommands, do subcommand checking.
if !cmd.HasParent() && len(args) > 0 {
return fmt.Errorf("unknown command %q for %q%s", args[0], cmd.CommandPath(), cmd.findSuggestions(args[0]))
}
return nil
}
// NoArgs returns an error if any args are included.
func NoArgs(cmd *Command, args []string) error {
if len(args) > 0 {
return fmt.Errorf("unknown command %q for %q", args[0], cmd.CommandPath())
}
return nil
}
// OnlyValidArgs returns an error if there are any positional args that are not in
// the `ValidArgs` field of `Command`
func OnlyValidArgs(cmd *Command, args []string) error {
if len(cmd.ValidArgs) > 0 {
// Remove any description that may be included in ValidArgs.
// A description is following a tab character.
var validArgs []string
for _, v := range cmd.ValidArgs {
validArgs = append(validArgs, strings.Split(v, "\t")[0])
}
for _, v := range args {
if !stringInSlice(v, validArgs) {
return fmt.Errorf("invalid argument %q for %q%s", v, cmd.CommandPath(), cmd.findSuggestions(args[0]))
}
}
}
return nil
}
// ArbitraryArgs never returns an error.
func ArbitraryArgs(cmd *Command, args []string) error {
return nil
}
// MinimumNArgs returns an error if there is not at least N args.
func MinimumNArgs(n int) PositionalArgs {
return func(cmd *Command, args []string) error {
if len(args) < n {
return fmt.Errorf("requires at least %d arg(s), only received %d", n, len(args))
}
return nil
}
}
// MaximumNArgs returns an error if there are more than N args.
func MaximumNArgs(n int) PositionalArgs {
return func(cmd *Command, args []string) error {
if len(args) > n {
return fmt.Errorf("accepts at most %d arg(s), received %d", n, len(args))
}
return nil
}
}
// ExactArgs returns an error if there are not exactly n args.
func ExactArgs(n int) PositionalArgs {
return func(cmd *Command, args []string) error {
if len(args) != n {
return fmt.Errorf("accepts %d arg(s), received %d", n, len(args))
}
return nil
}
}
// RangeArgs returns an error if the number of args is not within the expected range.
func RangeArgs(min int, max int) PositionalArgs {
return func(cmd *Command, args []string) error {
if len(args) < min || len(args) > max {
return fmt.Errorf("accepts between %d and %d arg(s), received %d", min, max, len(args))
}
return nil
}
}
// MatchAll allows combining several PositionalArgs to work in concert.
func MatchAll(pargs ...PositionalArgs) PositionalArgs {
return func(cmd *Command, args []string) error {
for _, parg := range pargs {
if err := parg(cmd, args); err != nil {
return err
}
}
return nil
}
}
// ExactValidArgs returns an error if there are not exactly N positional args OR
// there are any positional args that are not in the `ValidArgs` field of `Command`
//
// Deprecated: use MatchAll(ExactArgs(n), OnlyValidArgs) instead
func ExactValidArgs(n int) PositionalArgs {
return MatchAll(ExactArgs(n), OnlyValidArgs)
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"bytes"
"fmt"
"io"
"os"
"sort"
"strings"
"github.com/spf13/pflag"
)
// Annotations for Bash completion.
const (
BashCompFilenameExt = "cobra_annotation_bash_completion_filename_extensions"
BashCompCustom = "cobra_annotation_bash_completion_custom"
BashCompOneRequiredFlag = "cobra_annotation_bash_completion_one_required_flag"
BashCompSubdirsInDir = "cobra_annotation_bash_completion_subdirs_in_dir"
)
func writePreamble(buf io.StringWriter, name string) {
WriteStringAndCheck(buf, fmt.Sprintf("# bash completion for %-36s -*- shell-script -*-\n", name))
WriteStringAndCheck(buf, fmt.Sprintf(`
__%[1]s_debug()
{
if [[ -n ${BASH_COMP_DEBUG_FILE:-} ]]; then
echo "$*" >> "${BASH_COMP_DEBUG_FILE}"
fi
}
# Homebrew on Macs have version 1.3 of bash-completion which doesn't include
# _init_completion. This is a very minimal version of that function.
__%[1]s_init_completion()
{
COMPREPLY=()
_get_comp_words_by_ref "$@" cur prev words cword
}
__%[1]s_index_of_word()
{
local w word=$1
shift
index=0
for w in "$@"; do
[[ $w = "$word" ]] && return
index=$((index+1))
done
index=-1
}
__%[1]s_contains_word()
{
local w word=$1; shift
for w in "$@"; do
[[ $w = "$word" ]] && return
done
return 1
}
__%[1]s_handle_go_custom_completion()
{
__%[1]s_debug "${FUNCNAME[0]}: cur is ${cur}, words[*] is ${words[*]}, #words[@] is ${#words[@]}"
local shellCompDirectiveError=%[3]d
local shellCompDirectiveNoSpace=%[4]d
local shellCompDirectiveNoFileComp=%[5]d
local shellCompDirectiveFilterFileExt=%[6]d
local shellCompDirectiveFilterDirs=%[7]d
local out requestComp lastParam lastChar comp directive args
# Prepare the command to request completions for the program.
# Calling ${words[0]} instead of directly %[1]s allows handling aliases
args=("${words[@]:1}")
# Disable ActiveHelp which is not supported for bash completion v1
requestComp="%[8]s=0 ${words[0]} %[2]s ${args[*]}"
lastParam=${words[$((${#words[@]}-1))]}
lastChar=${lastParam:$((${#lastParam}-1)):1}
__%[1]s_debug "${FUNCNAME[0]}: lastParam ${lastParam}, lastChar ${lastChar}"
if [ -z "${cur}" ] && [ "${lastChar}" != "=" ]; then
# If the last parameter is complete (there is a space following it)
# We add an extra empty parameter so we can indicate this to the go method.
__%[1]s_debug "${FUNCNAME[0]}: Adding extra empty parameter"
requestComp="${requestComp} \"\""
fi
__%[1]s_debug "${FUNCNAME[0]}: calling ${requestComp}"
# Use eval to handle any environment variables and such
out=$(eval "${requestComp}" 2>/dev/null)
# Extract the directive integer at the very end of the output following a colon (:)
directive=${out##*:}
# Remove the directive
out=${out%%:*}
if [ "${directive}" = "${out}" ]; then
# There is not directive specified
directive=0
fi
__%[1]s_debug "${FUNCNAME[0]}: the completion directive is: ${directive}"
__%[1]s_debug "${FUNCNAME[0]}: the completions are: ${out}"
if [ $((directive & shellCompDirectiveError)) -ne 0 ]; then
# Error code. No completion.
__%[1]s_debug "${FUNCNAME[0]}: received error from custom completion go code"
return
else
if [ $((directive & shellCompDirectiveNoSpace)) -ne 0 ]; then
if [[ $(type -t compopt) = "builtin" ]]; then
__%[1]s_debug "${FUNCNAME[0]}: activating no space"
compopt -o nospace
fi
fi
if [ $((directive & shellCompDirectiveNoFileComp)) -ne 0 ]; then
if [[ $(type -t compopt) = "builtin" ]]; then
__%[1]s_debug "${FUNCNAME[0]}: activating no file completion"
compopt +o default
fi
fi
fi
if [ $((directive & shellCompDirectiveFilterFileExt)) -ne 0 ]; then
# File extension filtering
local fullFilter filter filteringCmd
# Do not use quotes around the $out variable or else newline
# characters will be kept.
for filter in ${out}; do
fullFilter+="$filter|"
done
filteringCmd="_filedir $fullFilter"
__%[1]s_debug "File filtering command: $filteringCmd"
$filteringCmd
elif [ $((directive & shellCompDirectiveFilterDirs)) -ne 0 ]; then
# File completion for directories only
local subdir
# Use printf to strip any trailing newline
subdir=$(printf "%%s" "${out}")
if [ -n "$subdir" ]; then
__%[1]s_debug "Listing directories in $subdir"
__%[1]s_handle_subdirs_in_dir_flag "$subdir"
else
__%[1]s_debug "Listing directories in ."
_filedir -d
fi
else
while IFS='' read -r comp; do
COMPREPLY+=("$comp")
done < <(compgen -W "${out}" -- "$cur")
fi
}
__%[1]s_handle_reply()
{
__%[1]s_debug "${FUNCNAME[0]}"
local comp
case $cur in
-*)
if [[ $(type -t compopt) = "builtin" ]]; then
compopt -o nospace
fi
local allflags
if [ ${#must_have_one_flag[@]} -ne 0 ]; then
allflags=("${must_have_one_flag[@]}")
else
allflags=("${flags[*]} ${two_word_flags[*]}")
fi
while IFS='' read -r comp; do
COMPREPLY+=("$comp")
done < <(compgen -W "${allflags[*]}" -- "$cur")
if [[ $(type -t compopt) = "builtin" ]]; then
[[ "${COMPREPLY[0]}" == *= ]] || compopt +o nospace
fi
# complete after --flag=abc
if [[ $cur == *=* ]]; then
if [[ $(type -t compopt) = "builtin" ]]; then
compopt +o nospace
fi
local index flag
flag="${cur%%=*}"
__%[1]s_index_of_word "${flag}" "${flags_with_completion[@]}"
COMPREPLY=()
if [[ ${index} -ge 0 ]]; then
PREFIX=""
cur="${cur#*=}"
${flags_completion[${index}]}
if [ -n "${ZSH_VERSION:-}" ]; then
# zsh completion needs --flag= prefix
eval "COMPREPLY=( \"\${COMPREPLY[@]/#/${flag}=}\" )"
fi
fi
fi
if [[ -z "${flag_parsing_disabled}" ]]; then
# If flag parsing is enabled, we have completed the flags and can return.
# If flag parsing is disabled, we may not know all (or any) of the flags, so we fallthrough
# to possibly call handle_go_custom_completion.
return 0;
fi
;;
esac
# check if we are handling a flag with special work handling
local index
__%[1]s_index_of_word "${prev}" "${flags_with_completion[@]}"
if [[ ${index} -ge 0 ]]; then
${flags_completion[${index}]}
return
fi
# we are parsing a flag and don't have a special handler, no completion
if [[ ${cur} != "${words[cword]}" ]]; then
return
fi
local completions
completions=("${commands[@]}")
if [[ ${#must_have_one_noun[@]} -ne 0 ]]; then
completions+=("${must_have_one_noun[@]}")
elif [[ -n "${has_completion_function}" ]]; then
# if a go completion function is provided, defer to that function
__%[1]s_handle_go_custom_completion
fi
if [[ ${#must_have_one_flag[@]} -ne 0 ]]; then
completions+=("${must_have_one_flag[@]}")
fi
while IFS='' read -r comp; do
COMPREPLY+=("$comp")
done < <(compgen -W "${completions[*]}" -- "$cur")
if [[ ${#COMPREPLY[@]} -eq 0 && ${#noun_aliases[@]} -gt 0 && ${#must_have_one_noun[@]} -ne 0 ]]; then
while IFS='' read -r comp; do
COMPREPLY+=("$comp")
done < <(compgen -W "${noun_aliases[*]}" -- "$cur")
fi
if [[ ${#COMPREPLY[@]} -eq 0 ]]; then
if declare -F __%[1]s_custom_func >/dev/null; then
# try command name qualified custom func
__%[1]s_custom_func
else
# otherwise fall back to unqualified for compatibility
declare -F __custom_func >/dev/null && __custom_func
fi
fi
# available in bash-completion >= 2, not always present on macOS
if declare -F __ltrim_colon_completions >/dev/null; then
__ltrim_colon_completions "$cur"
fi
# If there is only 1 completion and it is a flag with an = it will be completed
# but we don't want a space after the =
if [[ "${#COMPREPLY[@]}" -eq "1" ]] && [[ $(type -t compopt) = "builtin" ]] && [[ "${COMPREPLY[0]}" == --*= ]]; then
compopt -o nospace
fi
}
# The arguments should be in the form "ext1|ext2|extn"
__%[1]s_handle_filename_extension_flag()
{
local ext="$1"
_filedir "@(${ext})"
}
__%[1]s_handle_subdirs_in_dir_flag()
{
local dir="$1"
pushd "${dir}" >/dev/null 2>&1 && _filedir -d && popd >/dev/null 2>&1 || return
}
__%[1]s_handle_flag()
{
__%[1]s_debug "${FUNCNAME[0]}: c is $c words[c] is ${words[c]}"
# if a command required a flag, and we found it, unset must_have_one_flag()
local flagname=${words[c]}
local flagvalue=""
# if the word contained an =
if [[ ${words[c]} == *"="* ]]; then
flagvalue=${flagname#*=} # take in as flagvalue after the =
flagname=${flagname%%=*} # strip everything after the =
flagname="${flagname}=" # but put the = back
fi
__%[1]s_debug "${FUNCNAME[0]}: looking for ${flagname}"
if __%[1]s_contains_word "${flagname}" "${must_have_one_flag[@]}"; then
must_have_one_flag=()
fi
# if you set a flag which only applies to this command, don't show subcommands
if __%[1]s_contains_word "${flagname}" "${local_nonpersistent_flags[@]}"; then
commands=()
fi
# keep flag value with flagname as flaghash
# flaghash variable is an associative array which is only supported in bash > 3.
if [[ -z "${BASH_VERSION:-}" || "${BASH_VERSINFO[0]:-}" -gt 3 ]]; then
if [ -n "${flagvalue}" ] ; then
flaghash[${flagname}]=${flagvalue}
elif [ -n "${words[ $((c+1)) ]}" ] ; then
flaghash[${flagname}]=${words[ $((c+1)) ]}
else
flaghash[${flagname}]="true" # pad "true" for bool flag
fi
fi
# skip the argument to a two word flag
if [[ ${words[c]} != *"="* ]] && __%[1]s_contains_word "${words[c]}" "${two_word_flags[@]}"; then
__%[1]s_debug "${FUNCNAME[0]}: found a flag ${words[c]}, skip the next argument"
c=$((c+1))
# if we are looking for a flags value, don't show commands
if [[ $c -eq $cword ]]; then
commands=()
fi
fi
c=$((c+1))
}
__%[1]s_handle_noun()
{
__%[1]s_debug "${FUNCNAME[0]}: c is $c words[c] is ${words[c]}"
if __%[1]s_contains_word "${words[c]}" "${must_have_one_noun[@]}"; then
must_have_one_noun=()
elif __%[1]s_contains_word "${words[c]}" "${noun_aliases[@]}"; then
must_have_one_noun=()
fi
nouns+=("${words[c]}")
c=$((c+1))
}
__%[1]s_handle_command()
{
__%[1]s_debug "${FUNCNAME[0]}: c is $c words[c] is ${words[c]}"
local next_command
if [[ -n ${last_command} ]]; then
next_command="_${last_command}_${words[c]//:/__}"
else
if [[ $c -eq 0 ]]; then
next_command="_%[1]s_root_command"
else
next_command="_${words[c]//:/__}"
fi
fi
c=$((c+1))
__%[1]s_debug "${FUNCNAME[0]}: looking for ${next_command}"
declare -F "$next_command" >/dev/null && $next_command
}
__%[1]s_handle_word()
{
if [[ $c -ge $cword ]]; then
__%[1]s_handle_reply
return
fi
__%[1]s_debug "${FUNCNAME[0]}: c is $c words[c] is ${words[c]}"
if [[ "${words[c]}" == -* ]]; then
__%[1]s_handle_flag
elif __%[1]s_contains_word "${words[c]}" "${commands[@]}"; then
__%[1]s_handle_command
elif [[ $c -eq 0 ]]; then
__%[1]s_handle_command
elif __%[1]s_contains_word "${words[c]}" "${command_aliases[@]}"; then
# aliashash variable is an associative array which is only supported in bash > 3.
if [[ -z "${BASH_VERSION:-}" || "${BASH_VERSINFO[0]:-}" -gt 3 ]]; then
words[c]=${aliashash[${words[c]}]}
__%[1]s_handle_command
else
__%[1]s_handle_noun
fi
else
__%[1]s_handle_noun
fi
__%[1]s_handle_word
}
`, name, ShellCompNoDescRequestCmd,
ShellCompDirectiveError, ShellCompDirectiveNoSpace, ShellCompDirectiveNoFileComp,
ShellCompDirectiveFilterFileExt, ShellCompDirectiveFilterDirs, activeHelpEnvVar(name)))
}
func writePostscript(buf io.StringWriter, name string) {
name = strings.ReplaceAll(name, ":", "__")
WriteStringAndCheck(buf, fmt.Sprintf("__start_%s()\n", name))
WriteStringAndCheck(buf, fmt.Sprintf(`{
local cur prev words cword split
declare -A flaghash 2>/dev/null || :
declare -A aliashash 2>/dev/null || :
if declare -F _init_completion >/dev/null 2>&1; then
_init_completion -s || return
else
__%[1]s_init_completion -n "=" || return
fi
local c=0
local flag_parsing_disabled=
local flags=()
local two_word_flags=()
local local_nonpersistent_flags=()
local flags_with_completion=()
local flags_completion=()
local commands=("%[1]s")
local command_aliases=()
local must_have_one_flag=()
local must_have_one_noun=()
local has_completion_function=""
local last_command=""
local nouns=()
local noun_aliases=()
__%[1]s_handle_word
}
`, name))
WriteStringAndCheck(buf, fmt.Sprintf(`if [[ $(type -t compopt) = "builtin" ]]; then
complete -o default -F __start_%s %s
else
complete -o default -o nospace -F __start_%s %s
fi
`, name, name, name, name))
WriteStringAndCheck(buf, "# ex: ts=4 sw=4 et filetype=sh\n")
}
func writeCommands(buf io.StringWriter, cmd *Command) {
WriteStringAndCheck(buf, " commands=()\n")
for _, c := range cmd.Commands() {
if !c.IsAvailableCommand() && c != cmd.helpCommand {
continue
}
WriteStringAndCheck(buf, fmt.Sprintf(" commands+=(%q)\n", c.Name()))
writeCmdAliases(buf, c)
}
WriteStringAndCheck(buf, "\n")
}
func writeFlagHandler(buf io.StringWriter, name string, annotations map[string][]string, cmd *Command) {
for key, value := range annotations {
switch key {
case BashCompFilenameExt:
WriteStringAndCheck(buf, fmt.Sprintf(" flags_with_completion+=(%q)\n", name))
var ext string
if len(value) > 0 {
ext = fmt.Sprintf("__%s_handle_filename_extension_flag ", cmd.Root().Name()) + strings.Join(value, "|")
} else {
ext = "_filedir"
}
WriteStringAndCheck(buf, fmt.Sprintf(" flags_completion+=(%q)\n", ext))
case BashCompCustom:
WriteStringAndCheck(buf, fmt.Sprintf(" flags_with_completion+=(%q)\n", name))
if len(value) > 0 {
handlers := strings.Join(value, "; ")
WriteStringAndCheck(buf, fmt.Sprintf(" flags_completion+=(%q)\n", handlers))
} else {
WriteStringAndCheck(buf, " flags_completion+=(:)\n")
}
case BashCompSubdirsInDir:
WriteStringAndCheck(buf, fmt.Sprintf(" flags_with_completion+=(%q)\n", name))
var ext string
if len(value) == 1 {
ext = fmt.Sprintf("__%s_handle_subdirs_in_dir_flag ", cmd.Root().Name()) + value[0]
} else {
ext = "_filedir -d"
}
WriteStringAndCheck(buf, fmt.Sprintf(" flags_completion+=(%q)\n", ext))
}
}
}
const cbn = "\")\n"
func writeShortFlag(buf io.StringWriter, flag *pflag.Flag, cmd *Command) {
name := flag.Shorthand
format := " "
if len(flag.NoOptDefVal) == 0 {
format += "two_word_"
}
format += "flags+=(\"-%s" + cbn
WriteStringAndCheck(buf, fmt.Sprintf(format, name))
writeFlagHandler(buf, "-"+name, flag.Annotations, cmd)
}
func writeFlag(buf io.StringWriter, flag *pflag.Flag, cmd *Command) {
name := flag.Name
format := " flags+=(\"--%s"
if len(flag.NoOptDefVal) == 0 {
format += "="
}
format += cbn
WriteStringAndCheck(buf, fmt.Sprintf(format, name))
if len(flag.NoOptDefVal) == 0 {
format = " two_word_flags+=(\"--%s" + cbn
WriteStringAndCheck(buf, fmt.Sprintf(format, name))
}
writeFlagHandler(buf, "--"+name, flag.Annotations, cmd)
}
func writeLocalNonPersistentFlag(buf io.StringWriter, flag *pflag.Flag) {
name := flag.Name
format := " local_nonpersistent_flags+=(\"--%[1]s" + cbn
if len(flag.NoOptDefVal) == 0 {
format += " local_nonpersistent_flags+=(\"--%[1]s=" + cbn
}
WriteStringAndCheck(buf, fmt.Sprintf(format, name))
if len(flag.Shorthand) > 0 {
WriteStringAndCheck(buf, fmt.Sprintf(" local_nonpersistent_flags+=(\"-%s\")\n", flag.Shorthand))
}
}
// prepareCustomAnnotationsForFlags setup annotations for go completions for registered flags
func prepareCustomAnnotationsForFlags(cmd *Command) {
flagCompletionMutex.RLock()
defer flagCompletionMutex.RUnlock()
for flag := range flagCompletionFunctions {
// Make sure the completion script calls the __*_go_custom_completion function for
// every registered flag. We need to do this here (and not when the flag was registered
// for completion) so that we can know the root command name for the prefix
// of __<prefix>_go_custom_completion
if flag.Annotations == nil {
flag.Annotations = map[string][]string{}
}
flag.Annotations[BashCompCustom] = []string{fmt.Sprintf("__%[1]s_handle_go_custom_completion", cmd.Root().Name())}
}
}
func writeFlags(buf io.StringWriter, cmd *Command) {
prepareCustomAnnotationsForFlags(cmd)
WriteStringAndCheck(buf, ` flags=()
two_word_flags=()
local_nonpersistent_flags=()
flags_with_completion=()
flags_completion=()
`)
if cmd.DisableFlagParsing {
WriteStringAndCheck(buf, " flag_parsing_disabled=1\n")
}
localNonPersistentFlags := cmd.LocalNonPersistentFlags()
cmd.NonInheritedFlags().VisitAll(func(flag *pflag.Flag) {
if nonCompletableFlag(flag) {
return
}
writeFlag(buf, flag, cmd)
if len(flag.Shorthand) > 0 {
writeShortFlag(buf, flag, cmd)
}
// localNonPersistentFlags are used to stop the completion of subcommands when one is set
// if TraverseChildren is true we should allow to complete subcommands
if localNonPersistentFlags.Lookup(flag.Name) != nil && !cmd.Root().TraverseChildren {
writeLocalNonPersistentFlag(buf, flag)
}
})
cmd.InheritedFlags().VisitAll(func(flag *pflag.Flag) {
if nonCompletableFlag(flag) {
return
}
writeFlag(buf, flag, cmd)
if len(flag.Shorthand) > 0 {
writeShortFlag(buf, flag, cmd)
}
})
WriteStringAndCheck(buf, "\n")
}
func writeRequiredFlag(buf io.StringWriter, cmd *Command) {
WriteStringAndCheck(buf, " must_have_one_flag=()\n")
flags := cmd.NonInheritedFlags()
flags.VisitAll(func(flag *pflag.Flag) {
if nonCompletableFlag(flag) {
return
}
for key := range flag.Annotations {
switch key {
case BashCompOneRequiredFlag:
format := " must_have_one_flag+=(\"--%s"
if flag.Value.Type() != "bool" {
format += "="
}
format += cbn
WriteStringAndCheck(buf, fmt.Sprintf(format, flag.Name))
if len(flag.Shorthand) > 0 {
WriteStringAndCheck(buf, fmt.Sprintf(" must_have_one_flag+=(\"-%s"+cbn, flag.Shorthand))
}
}
}
})
}
func writeRequiredNouns(buf io.StringWriter, cmd *Command) {
WriteStringAndCheck(buf, " must_have_one_noun=()\n")
sort.Strings(cmd.ValidArgs)
for _, value := range cmd.ValidArgs {
// Remove any description that may be included following a tab character.
// Descriptions are not supported by bash completion.
value = strings.Split(value, "\t")[0]
WriteStringAndCheck(buf, fmt.Sprintf(" must_have_one_noun+=(%q)\n", value))
}
if cmd.ValidArgsFunction != nil {
WriteStringAndCheck(buf, " has_completion_function=1\n")
}
}
func writeCmdAliases(buf io.StringWriter, cmd *Command) {
if len(cmd.Aliases) == 0 {
return
}
sort.Strings(cmd.Aliases)
WriteStringAndCheck(buf, fmt.Sprint(` if [[ -z "${BASH_VERSION:-}" || "${BASH_VERSINFO[0]:-}" -gt 3 ]]; then`, "\n"))
for _, value := range cmd.Aliases {
WriteStringAndCheck(buf, fmt.Sprintf(" command_aliases+=(%q)\n", value))
WriteStringAndCheck(buf, fmt.Sprintf(" aliashash[%q]=%q\n", value, cmd.Name()))
}
WriteStringAndCheck(buf, ` fi`)
WriteStringAndCheck(buf, "\n")
}
func writeArgAliases(buf io.StringWriter, cmd *Command) {
WriteStringAndCheck(buf, " noun_aliases=()\n")
sort.Strings(cmd.ArgAliases)
for _, value := range cmd.ArgAliases {
WriteStringAndCheck(buf, fmt.Sprintf(" noun_aliases+=(%q)\n", value))
}
}
func gen(buf io.StringWriter, cmd *Command) {
for _, c := range cmd.Commands() {
if !c.IsAvailableCommand() && c != cmd.helpCommand {
continue
}
gen(buf, c)
}
commandName := cmd.CommandPath()
commandName = strings.ReplaceAll(commandName, " ", "_")
commandName = strings.ReplaceAll(commandName, ":", "__")
if cmd.Root() == cmd {
WriteStringAndCheck(buf, fmt.Sprintf("_%s_root_command()\n{\n", commandName))
} else {
WriteStringAndCheck(buf, fmt.Sprintf("_%s()\n{\n", commandName))
}
WriteStringAndCheck(buf, fmt.Sprintf(" last_command=%q\n", commandName))
WriteStringAndCheck(buf, "\n")
WriteStringAndCheck(buf, " command_aliases=()\n")
WriteStringAndCheck(buf, "\n")
writeCommands(buf, cmd)
writeFlags(buf, cmd)
writeRequiredFlag(buf, cmd)
writeRequiredNouns(buf, cmd)
writeArgAliases(buf, cmd)
WriteStringAndCheck(buf, "}\n\n")
}
// GenBashCompletion generates bash completion file and writes to the passed writer.
func (c *Command) GenBashCompletion(w io.Writer) error {
buf := new(bytes.Buffer)
writePreamble(buf, c.Name())
if len(c.BashCompletionFunction) > 0 {
buf.WriteString(c.BashCompletionFunction + "\n")
}
gen(buf, c)
writePostscript(buf, c.Name())
_, err := buf.WriteTo(w)
return err
}
func nonCompletableFlag(flag *pflag.Flag) bool {
return flag.Hidden || len(flag.Deprecated) > 0
}
// GenBashCompletionFile generates bash completion file.
func (c *Command) GenBashCompletionFile(filename string) error {
outFile, err := os.Create(filename)
if err != nil {
return err
}
defer outFile.Close()
return c.GenBashCompletion(outFile)
}

396
vendor/github.com/spf13/cobra/bash_completionsV2.go generated vendored Normal file
View file

@ -0,0 +1,396 @@
// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"bytes"
"fmt"
"io"
"os"
)
func (c *Command) genBashCompletion(w io.Writer, includeDesc bool) error {
buf := new(bytes.Buffer)
genBashComp(buf, c.Name(), includeDesc)
_, err := buf.WriteTo(w)
return err
}
func genBashComp(buf io.StringWriter, name string, includeDesc bool) {
compCmd := ShellCompRequestCmd
if !includeDesc {
compCmd = ShellCompNoDescRequestCmd
}
WriteStringAndCheck(buf, fmt.Sprintf(`# bash completion V2 for %-36[1]s -*- shell-script -*-
__%[1]s_debug()
{
if [[ -n ${BASH_COMP_DEBUG_FILE-} ]]; then
echo "$*" >> "${BASH_COMP_DEBUG_FILE}"
fi
}
# Macs have bash3 for which the bash-completion package doesn't include
# _init_completion. This is a minimal version of that function.
__%[1]s_init_completion()
{
COMPREPLY=()
_get_comp_words_by_ref "$@" cur prev words cword
}
# This function calls the %[1]s program to obtain the completion
# results and the directive. It fills the 'out' and 'directive' vars.
__%[1]s_get_completion_results() {
local requestComp lastParam lastChar args
# Prepare the command to request completions for the program.
# Calling ${words[0]} instead of directly %[1]s allows handling aliases
args=("${words[@]:1}")
requestComp="${words[0]} %[2]s ${args[*]}"
lastParam=${words[$((${#words[@]}-1))]}
lastChar=${lastParam:$((${#lastParam}-1)):1}
__%[1]s_debug "lastParam ${lastParam}, lastChar ${lastChar}"
if [[ -z ${cur} && ${lastChar} != = ]]; then
# If the last parameter is complete (there is a space following it)
# We add an extra empty parameter so we can indicate this to the go method.
__%[1]s_debug "Adding extra empty parameter"
requestComp="${requestComp} ''"
fi
# When completing a flag with an = (e.g., %[1]s -n=<TAB>)
# bash focuses on the part after the =, so we need to remove
# the flag part from $cur
if [[ ${cur} == -*=* ]]; then
cur="${cur#*=}"
fi
__%[1]s_debug "Calling ${requestComp}"
# Use eval to handle any environment variables and such
out=$(eval "${requestComp}" 2>/dev/null)
# Extract the directive integer at the very end of the output following a colon (:)
directive=${out##*:}
# Remove the directive
out=${out%%:*}
if [[ ${directive} == "${out}" ]]; then
# There is not directive specified
directive=0
fi
__%[1]s_debug "The completion directive is: ${directive}"
__%[1]s_debug "The completions are: ${out}"
}
__%[1]s_process_completion_results() {
local shellCompDirectiveError=%[3]d
local shellCompDirectiveNoSpace=%[4]d
local shellCompDirectiveNoFileComp=%[5]d
local shellCompDirectiveFilterFileExt=%[6]d
local shellCompDirectiveFilterDirs=%[7]d
local shellCompDirectiveKeepOrder=%[8]d
if (((directive & shellCompDirectiveError) != 0)); then
# Error code. No completion.
__%[1]s_debug "Received error from custom completion go code"
return
else
if (((directive & shellCompDirectiveNoSpace) != 0)); then
if [[ $(type -t compopt) == builtin ]]; then
__%[1]s_debug "Activating no space"
compopt -o nospace
else
__%[1]s_debug "No space directive not supported in this version of bash"
fi
fi
if (((directive & shellCompDirectiveKeepOrder) != 0)); then
if [[ $(type -t compopt) == builtin ]]; then
# no sort isn't supported for bash less than < 4.4
if [[ ${BASH_VERSINFO[0]} -lt 4 || ( ${BASH_VERSINFO[0]} -eq 4 && ${BASH_VERSINFO[1]} -lt 4 ) ]]; then
__%[1]s_debug "No sort directive not supported in this version of bash"
else
__%[1]s_debug "Activating keep order"
compopt -o nosort
fi
else
__%[1]s_debug "No sort directive not supported in this version of bash"
fi
fi
if (((directive & shellCompDirectiveNoFileComp) != 0)); then
if [[ $(type -t compopt) == builtin ]]; then
__%[1]s_debug "Activating no file completion"
compopt +o default
else
__%[1]s_debug "No file completion directive not supported in this version of bash"
fi
fi
fi
# Separate activeHelp from normal completions
local completions=()
local activeHelp=()
__%[1]s_extract_activeHelp
if (((directive & shellCompDirectiveFilterFileExt) != 0)); then
# File extension filtering
local fullFilter filter filteringCmd
# Do not use quotes around the $completions variable or else newline
# characters will be kept.
for filter in ${completions[*]}; do
fullFilter+="$filter|"
done
filteringCmd="_filedir $fullFilter"
__%[1]s_debug "File filtering command: $filteringCmd"
$filteringCmd
elif (((directive & shellCompDirectiveFilterDirs) != 0)); then
# File completion for directories only
local subdir
subdir=${completions[0]}
if [[ -n $subdir ]]; then
__%[1]s_debug "Listing directories in $subdir"
pushd "$subdir" >/dev/null 2>&1 && _filedir -d && popd >/dev/null 2>&1 || return
else
__%[1]s_debug "Listing directories in ."
_filedir -d
fi
else
__%[1]s_handle_completion_types
fi
__%[1]s_handle_special_char "$cur" :
__%[1]s_handle_special_char "$cur" =
# Print the activeHelp statements before we finish
if ((${#activeHelp[*]} != 0)); then
printf "\n";
printf "%%s\n" "${activeHelp[@]}"
printf "\n"
# The prompt format is only available from bash 4.4.
# We test if it is available before using it.
if (x=${PS1@P}) 2> /dev/null; then
printf "%%s" "${PS1@P}${COMP_LINE[@]}"
else
# Can't print the prompt. Just print the
# text the user had typed, it is workable enough.
printf "%%s" "${COMP_LINE[@]}"
fi
fi
}
# Separate activeHelp lines from real completions.
# Fills the $activeHelp and $completions arrays.
__%[1]s_extract_activeHelp() {
local activeHelpMarker="%[9]s"
local endIndex=${#activeHelpMarker}
while IFS='' read -r comp; do
if [[ ${comp:0:endIndex} == $activeHelpMarker ]]; then
comp=${comp:endIndex}
__%[1]s_debug "ActiveHelp found: $comp"
if [[ -n $comp ]]; then
activeHelp+=("$comp")
fi
else
# Not an activeHelp line but a normal completion
completions+=("$comp")
fi
done <<<"${out}"
}
__%[1]s_handle_completion_types() {
__%[1]s_debug "__%[1]s_handle_completion_types: COMP_TYPE is $COMP_TYPE"
case $COMP_TYPE in
37|42)
# Type: menu-complete/menu-complete-backward and insert-completions
# If the user requested inserting one completion at a time, or all
# completions at once on the command-line we must remove the descriptions.
# https://github.com/spf13/cobra/issues/1508
local tab=$'\t' comp
while IFS='' read -r comp; do
[[ -z $comp ]] && continue
# Strip any description
comp=${comp%%%%$tab*}
# Only consider the completions that match
if [[ $comp == "$cur"* ]]; then
COMPREPLY+=("$comp")
fi
done < <(printf "%%s\n" "${completions[@]}")
;;
*)
# Type: complete (normal completion)
__%[1]s_handle_standard_completion_case
;;
esac
}
__%[1]s_handle_standard_completion_case() {
local tab=$'\t' comp
# Short circuit to optimize if we don't have descriptions
if [[ "${completions[*]}" != *$tab* ]]; then
IFS=$'\n' read -ra COMPREPLY -d '' < <(compgen -W "${completions[*]}" -- "$cur")
return 0
fi
local longest=0
local compline
# Look for the longest completion so that we can format things nicely
while IFS='' read -r compline; do
[[ -z $compline ]] && continue
# Strip any description before checking the length
comp=${compline%%%%$tab*}
# Only consider the completions that match
[[ $comp == "$cur"* ]] || continue
COMPREPLY+=("$compline")
if ((${#comp}>longest)); then
longest=${#comp}
fi
done < <(printf "%%s\n" "${completions[@]}")
# If there is a single completion left, remove the description text
if ((${#COMPREPLY[*]} == 1)); then
__%[1]s_debug "COMPREPLY[0]: ${COMPREPLY[0]}"
comp="${COMPREPLY[0]%%%%$tab*}"
__%[1]s_debug "Removed description from single completion, which is now: ${comp}"
COMPREPLY[0]=$comp
else # Format the descriptions
__%[1]s_format_comp_descriptions $longest
fi
}
__%[1]s_handle_special_char()
{
local comp="$1"
local char=$2
if [[ "$comp" == *${char}* && "$COMP_WORDBREAKS" == *${char}* ]]; then
local word=${comp%%"${comp##*${char}}"}
local idx=${#COMPREPLY[*]}
while ((--idx >= 0)); do
COMPREPLY[idx]=${COMPREPLY[idx]#"$word"}
done
fi
}
__%[1]s_format_comp_descriptions()
{
local tab=$'\t'
local comp desc maxdesclength
local longest=$1
local i ci
for ci in ${!COMPREPLY[*]}; do
comp=${COMPREPLY[ci]}
# Properly format the description string which follows a tab character if there is one
if [[ "$comp" == *$tab* ]]; then
__%[1]s_debug "Original comp: $comp"
desc=${comp#*$tab}
comp=${comp%%%%$tab*}
# $COLUMNS stores the current shell width.
# Remove an extra 4 because we add 2 spaces and 2 parentheses.
maxdesclength=$(( COLUMNS - longest - 4 ))
# Make sure we can fit a description of at least 8 characters
# if we are to align the descriptions.
if ((maxdesclength > 8)); then
# Add the proper number of spaces to align the descriptions
for ((i = ${#comp} ; i < longest ; i++)); do
comp+=" "
done
else
# Don't pad the descriptions so we can fit more text after the completion
maxdesclength=$(( COLUMNS - ${#comp} - 4 ))
fi
# If there is enough space for any description text,
# truncate the descriptions that are too long for the shell width
if ((maxdesclength > 0)); then
if ((${#desc} > maxdesclength)); then
desc=${desc:0:$(( maxdesclength - 1 ))}
desc+="…"
fi
comp+=" ($desc)"
fi
COMPREPLY[ci]=$comp
__%[1]s_debug "Final comp: $comp"
fi
done
}
__start_%[1]s()
{
local cur prev words cword split
COMPREPLY=()
# Call _init_completion from the bash-completion package
# to prepare the arguments properly
if declare -F _init_completion >/dev/null 2>&1; then
_init_completion -n =: || return
else
__%[1]s_init_completion -n =: || return
fi
__%[1]s_debug
__%[1]s_debug "========= starting completion logic =========="
__%[1]s_debug "cur is ${cur}, words[*] is ${words[*]}, #words[@] is ${#words[@]}, cword is $cword"
# The user could have moved the cursor backwards on the command-line.
# We need to trigger completion from the $cword location, so we need
# to truncate the command-line ($words) up to the $cword location.
words=("${words[@]:0:$cword+1}")
__%[1]s_debug "Truncated words[*]: ${words[*]},"
local out directive
__%[1]s_get_completion_results
__%[1]s_process_completion_results
}
if [[ $(type -t compopt) = "builtin" ]]; then
complete -o default -F __start_%[1]s %[1]s
else
complete -o default -o nospace -F __start_%[1]s %[1]s
fi
# ex: ts=4 sw=4 et filetype=sh
`, name, compCmd,
ShellCompDirectiveError, ShellCompDirectiveNoSpace, ShellCompDirectiveNoFileComp,
ShellCompDirectiveFilterFileExt, ShellCompDirectiveFilterDirs, ShellCompDirectiveKeepOrder,
activeHelpMarker))
}
// GenBashCompletionFileV2 generates Bash completion version 2.
func (c *Command) GenBashCompletionFileV2(filename string, includeDesc bool) error {
outFile, err := os.Create(filename)
if err != nil {
return err
}
defer outFile.Close()
return c.GenBashCompletionV2(outFile, includeDesc)
}
// GenBashCompletionV2 generates Bash completion file version 2
// and writes it to the passed writer.
func (c *Command) GenBashCompletionV2(w io.Writer, includeDesc bool) error {
return c.genBashCompletion(w, includeDesc)
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// Commands similar to git, go tools and other modern CLI tools
// inspired by go, go-Commander, gh and subcommand
package cobra
import (
"fmt"
"io"
"os"
"reflect"
"strconv"
"strings"
"text/template"
"time"
"unicode"
)
var templateFuncs = template.FuncMap{
"trim": strings.TrimSpace,
"trimRightSpace": trimRightSpace,
"trimTrailingWhitespaces": trimRightSpace,
"appendIfNotPresent": appendIfNotPresent,
"rpad": rpad,
"gt": Gt,
"eq": Eq,
}
var initializers []func()
var finalizers []func()
const (
defaultPrefixMatching = false
defaultCommandSorting = true
defaultCaseInsensitive = false
defaultTraverseRunHooks = false
)
// EnablePrefixMatching allows setting automatic prefix matching. Automatic prefix matching can be a dangerous thing
// to automatically enable in CLI tools.
// Set this to true to enable it.
var EnablePrefixMatching = defaultPrefixMatching
// EnableCommandSorting controls sorting of the slice of commands, which is turned on by default.
// To disable sorting, set it to false.
var EnableCommandSorting = defaultCommandSorting
// EnableCaseInsensitive allows case-insensitive commands names. (case sensitive by default)
var EnableCaseInsensitive = defaultCaseInsensitive
// EnableTraverseRunHooks executes persistent pre-run and post-run hooks from all parents.
// By default this is disabled, which means only the first run hook to be found is executed.
var EnableTraverseRunHooks = defaultTraverseRunHooks
// MousetrapHelpText enables an information splash screen on Windows
// if the CLI is started from explorer.exe.
// To disable the mousetrap, just set this variable to blank string ("").
// Works only on Microsoft Windows.
var MousetrapHelpText = `This is a command line tool.
You need to open cmd.exe and run it from there.
`
// MousetrapDisplayDuration controls how long the MousetrapHelpText message is displayed on Windows
// if the CLI is started from explorer.exe. Set to 0 to wait for the return key to be pressed.
// To disable the mousetrap, just set MousetrapHelpText to blank string ("").
// Works only on Microsoft Windows.
var MousetrapDisplayDuration = 5 * time.Second
// AddTemplateFunc adds a template function that's available to Usage and Help
// template generation.
func AddTemplateFunc(name string, tmplFunc interface{}) {
templateFuncs[name] = tmplFunc
}
// AddTemplateFuncs adds multiple template functions that are available to Usage and
// Help template generation.
func AddTemplateFuncs(tmplFuncs template.FuncMap) {
for k, v := range tmplFuncs {
templateFuncs[k] = v
}
}
// OnInitialize sets the passed functions to be run when each command's
// Execute method is called.
func OnInitialize(y ...func()) {
initializers = append(initializers, y...)
}
// OnFinalize sets the passed functions to be run when each command's
// Execute method is terminated.
func OnFinalize(y ...func()) {
finalizers = append(finalizers, y...)
}
// FIXME Gt is unused by cobra and should be removed in a version 2. It exists only for compatibility with users of cobra.
// Gt takes two types and checks whether the first type is greater than the second. In case of types Arrays, Chans,
// Maps and Slices, Gt will compare their lengths. Ints are compared directly while strings are first parsed as
// ints and then compared.
func Gt(a interface{}, b interface{}) bool {
var left, right int64
av := reflect.ValueOf(a)
switch av.Kind() {
case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice:
left = int64(av.Len())
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
left = av.Int()
case reflect.String:
left, _ = strconv.ParseInt(av.String(), 10, 64)
}
bv := reflect.ValueOf(b)
switch bv.Kind() {
case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice:
right = int64(bv.Len())
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
right = bv.Int()
case reflect.String:
right, _ = strconv.ParseInt(bv.String(), 10, 64)
}
return left > right
}
// FIXME Eq is unused by cobra and should be removed in a version 2. It exists only for compatibility with users of cobra.
// Eq takes two types and checks whether they are equal. Supported types are int and string. Unsupported types will panic.
func Eq(a interface{}, b interface{}) bool {
av := reflect.ValueOf(a)
bv := reflect.ValueOf(b)
switch av.Kind() {
case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice:
panic("Eq called on unsupported type")
case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64:
return av.Int() == bv.Int()
case reflect.String:
return av.String() == bv.String()
}
return false
}
func trimRightSpace(s string) string {
return strings.TrimRightFunc(s, unicode.IsSpace)
}
// FIXME appendIfNotPresent is unused by cobra and should be removed in a version 2. It exists only for compatibility with users of cobra.
// appendIfNotPresent will append stringToAppend to the end of s, but only if it's not yet present in s.
func appendIfNotPresent(s, stringToAppend string) string {
if strings.Contains(s, stringToAppend) {
return s
}
return s + " " + stringToAppend
}
// rpad adds padding to the right of a string.
func rpad(s string, padding int) string {
formattedString := fmt.Sprintf("%%-%ds", padding)
return fmt.Sprintf(formattedString, s)
}
// tmpl executes the given template text on data, writing the result to w.
func tmpl(w io.Writer, text string, data interface{}) error {
t := template.New("top")
t.Funcs(templateFuncs)
template.Must(t.Parse(text))
return t.Execute(w, data)
}
// ld compares two strings and returns the levenshtein distance between them.
func ld(s, t string, ignoreCase bool) int {
if ignoreCase {
s = strings.ToLower(s)
t = strings.ToLower(t)
}
d := make([][]int, len(s)+1)
for i := range d {
d[i] = make([]int, len(t)+1)
}
for i := range d {
d[i][0] = i
}
for j := range d[0] {
d[0][j] = j
}
for j := 1; j <= len(t); j++ {
for i := 1; i <= len(s); i++ {
if s[i-1] == t[j-1] {
d[i][j] = d[i-1][j-1]
} else {
min := d[i-1][j]
if d[i][j-1] < min {
min = d[i][j-1]
}
if d[i-1][j-1] < min {
min = d[i-1][j-1]
}
d[i][j] = min + 1
}
}
}
return d[len(s)][len(t)]
}
func stringInSlice(a string, list []string) bool {
for _, b := range list {
if b == a {
return true
}
}
return false
}
// CheckErr prints the msg with the prefix 'Error:' and exits with error code 1. If the msg is nil, it does nothing.
func CheckErr(msg interface{}) {
if msg != nil {
fmt.Fprintln(os.Stderr, "Error:", msg)
os.Exit(1)
}
}
// WriteStringAndCheck writes a string into a buffer, and checks if the error is not nil.
func WriteStringAndCheck(b io.StringWriter, s string) {
_, err := b.WriteString(s)
CheckErr(err)
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//go:build !windows
// +build !windows
package cobra
var preExecHookFn func(*Command)

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//go:build windows
// +build windows
package cobra
import (
"fmt"
"os"
"time"
"github.com/inconshreveable/mousetrap"
)
var preExecHookFn = preExecHook
func preExecHook(c *Command) {
if MousetrapHelpText != "" && mousetrap.StartedByExplorer() {
c.Print(MousetrapHelpText)
if MousetrapDisplayDuration > 0 {
time.Sleep(MousetrapDisplayDuration)
} else {
c.Println("Press return to continue...")
fmt.Scanln()
}
os.Exit(1)
}
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"fmt"
"os"
"strings"
"sync"
"github.com/spf13/pflag"
)
const (
// ShellCompRequestCmd is the name of the hidden command that is used to request
// completion results from the program. It is used by the shell completion scripts.
ShellCompRequestCmd = "__complete"
// ShellCompNoDescRequestCmd is the name of the hidden command that is used to request
// completion results without their description. It is used by the shell completion scripts.
ShellCompNoDescRequestCmd = "__completeNoDesc"
)
// Global map of flag completion functions. Make sure to use flagCompletionMutex before you try to read and write from it.
var flagCompletionFunctions = map[*pflag.Flag]func(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective){}
// lock for reading and writing from flagCompletionFunctions
var flagCompletionMutex = &sync.RWMutex{}
// ShellCompDirective is a bit map representing the different behaviors the shell
// can be instructed to have once completions have been provided.
type ShellCompDirective int
type flagCompError struct {
subCommand string
flagName string
}
func (e *flagCompError) Error() string {
return "Subcommand '" + e.subCommand + "' does not support flag '" + e.flagName + "'"
}
const (
// ShellCompDirectiveError indicates an error occurred and completions should be ignored.
ShellCompDirectiveError ShellCompDirective = 1 << iota
// ShellCompDirectiveNoSpace indicates that the shell should not add a space
// after the completion even if there is a single completion provided.
ShellCompDirectiveNoSpace
// ShellCompDirectiveNoFileComp indicates that the shell should not provide
// file completion even when no completion is provided.
ShellCompDirectiveNoFileComp
// ShellCompDirectiveFilterFileExt indicates that the provided completions
// should be used as file extension filters.
// For flags, using Command.MarkFlagFilename() and Command.MarkPersistentFlagFilename()
// is a shortcut to using this directive explicitly. The BashCompFilenameExt
// annotation can also be used to obtain the same behavior for flags.
ShellCompDirectiveFilterFileExt
// ShellCompDirectiveFilterDirs indicates that only directory names should
// be provided in file completion. To request directory names within another
// directory, the returned completions should specify the directory within
// which to search. The BashCompSubdirsInDir annotation can be used to
// obtain the same behavior but only for flags.
ShellCompDirectiveFilterDirs
// ShellCompDirectiveKeepOrder indicates that the shell should preserve the order
// in which the completions are provided
ShellCompDirectiveKeepOrder
// ===========================================================================
// All directives using iota should be above this one.
// For internal use.
shellCompDirectiveMaxValue
// ShellCompDirectiveDefault indicates to let the shell perform its default
// behavior after completions have been provided.
// This one must be last to avoid messing up the iota count.
ShellCompDirectiveDefault ShellCompDirective = 0
)
const (
// Constants for the completion command
compCmdName = "completion"
compCmdNoDescFlagName = "no-descriptions"
compCmdNoDescFlagDesc = "disable completion descriptions"
compCmdNoDescFlagDefault = false
)
// CompletionOptions are the options to control shell completion
type CompletionOptions struct {
// DisableDefaultCmd prevents Cobra from creating a default 'completion' command
DisableDefaultCmd bool
// DisableNoDescFlag prevents Cobra from creating the '--no-descriptions' flag
// for shells that support completion descriptions
DisableNoDescFlag bool
// DisableDescriptions turns off all completion descriptions for shells
// that support them
DisableDescriptions bool
// HiddenDefaultCmd makes the default 'completion' command hidden
HiddenDefaultCmd bool
}
// NoFileCompletions can be used to disable file completion for commands that should
// not trigger file completions.
func NoFileCompletions(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective) {
return nil, ShellCompDirectiveNoFileComp
}
// FixedCompletions can be used to create a completion function which always
// returns the same results.
func FixedCompletions(choices []string, directive ShellCompDirective) func(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective) {
return func(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective) {
return choices, directive
}
}
// RegisterFlagCompletionFunc should be called to register a function to provide completion for a flag.
func (c *Command) RegisterFlagCompletionFunc(flagName string, f func(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective)) error {
flag := c.Flag(flagName)
if flag == nil {
return fmt.Errorf("RegisterFlagCompletionFunc: flag '%s' does not exist", flagName)
}
flagCompletionMutex.Lock()
defer flagCompletionMutex.Unlock()
if _, exists := flagCompletionFunctions[flag]; exists {
return fmt.Errorf("RegisterFlagCompletionFunc: flag '%s' already registered", flagName)
}
flagCompletionFunctions[flag] = f
return nil
}
// GetFlagCompletionFunc returns the completion function for the given flag of the command, if available.
func (c *Command) GetFlagCompletionFunc(flagName string) (func(*Command, []string, string) ([]string, ShellCompDirective), bool) {
flag := c.Flag(flagName)
if flag == nil {
return nil, false
}
flagCompletionMutex.RLock()
defer flagCompletionMutex.RUnlock()
completionFunc, exists := flagCompletionFunctions[flag]
return completionFunc, exists
}
// Returns a string listing the different directive enabled in the specified parameter
func (d ShellCompDirective) string() string {
var directives []string
if d&ShellCompDirectiveError != 0 {
directives = append(directives, "ShellCompDirectiveError")
}
if d&ShellCompDirectiveNoSpace != 0 {
directives = append(directives, "ShellCompDirectiveNoSpace")
}
if d&ShellCompDirectiveNoFileComp != 0 {
directives = append(directives, "ShellCompDirectiveNoFileComp")
}
if d&ShellCompDirectiveFilterFileExt != 0 {
directives = append(directives, "ShellCompDirectiveFilterFileExt")
}
if d&ShellCompDirectiveFilterDirs != 0 {
directives = append(directives, "ShellCompDirectiveFilterDirs")
}
if d&ShellCompDirectiveKeepOrder != 0 {
directives = append(directives, "ShellCompDirectiveKeepOrder")
}
if len(directives) == 0 {
directives = append(directives, "ShellCompDirectiveDefault")
}
if d >= shellCompDirectiveMaxValue {
return fmt.Sprintf("ERROR: unexpected ShellCompDirective value: %d", d)
}
return strings.Join(directives, ", ")
}
// initCompleteCmd adds a special hidden command that can be used to request custom completions.
func (c *Command) initCompleteCmd(args []string) {
completeCmd := &Command{
Use: fmt.Sprintf("%s [command-line]", ShellCompRequestCmd),
Aliases: []string{ShellCompNoDescRequestCmd},
DisableFlagsInUseLine: true,
Hidden: true,
DisableFlagParsing: true,
Args: MinimumNArgs(1),
Short: "Request shell completion choices for the specified command-line",
Long: fmt.Sprintf("%[2]s is a special command that is used by the shell completion logic\n%[1]s",
"to request completion choices for the specified command-line.", ShellCompRequestCmd),
Run: func(cmd *Command, args []string) {
finalCmd, completions, directive, err := cmd.getCompletions(args)
if err != nil {
CompErrorln(err.Error())
// Keep going for multiple reasons:
// 1- There could be some valid completions even though there was an error
// 2- Even without completions, we need to print the directive
}
noDescriptions := (cmd.CalledAs() == ShellCompNoDescRequestCmd)
for _, comp := range completions {
if GetActiveHelpConfig(finalCmd) == activeHelpGlobalDisable {
// Remove all activeHelp entries in this case
if strings.HasPrefix(comp, activeHelpMarker) {
continue
}
}
if noDescriptions {
// Remove any description that may be included following a tab character.
comp = strings.Split(comp, "\t")[0]
}
// Make sure we only write the first line to the output.
// This is needed if a description contains a linebreak.
// Otherwise the shell scripts will interpret the other lines as new flags
// and could therefore provide a wrong completion.
comp = strings.Split(comp, "\n")[0]
// Finally trim the completion. This is especially important to get rid
// of a trailing tab when there are no description following it.
// For example, a sub-command without a description should not be completed
// with a tab at the end (or else zsh will show a -- following it
// although there is no description).
comp = strings.TrimSpace(comp)
// Print each possible completion to stdout for the completion script to consume.
fmt.Fprintln(finalCmd.OutOrStdout(), comp)
}
// As the last printout, print the completion directive for the completion script to parse.
// The directive integer must be that last character following a single colon (:).
// The completion script expects :<directive>
fmt.Fprintf(finalCmd.OutOrStdout(), ":%d\n", directive)
// Print some helpful info to stderr for the user to understand.
// Output from stderr must be ignored by the completion script.
fmt.Fprintf(finalCmd.ErrOrStderr(), "Completion ended with directive: %s\n", directive.string())
},
}
c.AddCommand(completeCmd)
subCmd, _, err := c.Find(args)
if err != nil || subCmd.Name() != ShellCompRequestCmd {
// Only create this special command if it is actually being called.
// This reduces possible side-effects of creating such a command;
// for example, having this command would cause problems to a
// cobra program that only consists of the root command, since this
// command would cause the root command to suddenly have a subcommand.
c.RemoveCommand(completeCmd)
}
}
func (c *Command) getCompletions(args []string) (*Command, []string, ShellCompDirective, error) {
// The last argument, which is not completely typed by the user,
// should not be part of the list of arguments
toComplete := args[len(args)-1]
trimmedArgs := args[:len(args)-1]
var finalCmd *Command
var finalArgs []string
var err error
// Find the real command for which completion must be performed
// check if we need to traverse here to parse local flags on parent commands
if c.Root().TraverseChildren {
finalCmd, finalArgs, err = c.Root().Traverse(trimmedArgs)
} else {
// For Root commands that don't specify any value for their Args fields, when we call
// Find(), if those Root commands don't have any sub-commands, they will accept arguments.
// However, because we have added the __complete sub-command in the current code path, the
// call to Find() -> legacyArgs() will return an error if there are any arguments.
// To avoid this, we first remove the __complete command to get back to having no sub-commands.
rootCmd := c.Root()
if len(rootCmd.Commands()) == 1 {
rootCmd.RemoveCommand(c)
}
finalCmd, finalArgs, err = rootCmd.Find(trimmedArgs)
}
if err != nil {
// Unable to find the real command. E.g., <program> someInvalidCmd <TAB>
return c, []string{}, ShellCompDirectiveDefault, fmt.Errorf("Unable to find a command for arguments: %v", trimmedArgs)
}
finalCmd.ctx = c.ctx
// These flags are normally added when `execute()` is called on `finalCmd`,
// however, when doing completion, we don't call `finalCmd.execute()`.
// Let's add the --help and --version flag ourselves but only if the finalCmd
// has not disabled flag parsing; if flag parsing is disabled, it is up to the
// finalCmd itself to handle the completion of *all* flags.
if !finalCmd.DisableFlagParsing {
finalCmd.InitDefaultHelpFlag()
finalCmd.InitDefaultVersionFlag()
}
// Check if we are doing flag value completion before parsing the flags.
// This is important because if we are completing a flag value, we need to also
// remove the flag name argument from the list of finalArgs or else the parsing
// could fail due to an invalid value (incomplete) for the flag.
flag, finalArgs, toComplete, flagErr := checkIfFlagCompletion(finalCmd, finalArgs, toComplete)
// Check if interspersed is false or -- was set on a previous arg.
// This works by counting the arguments. Normally -- is not counted as arg but
// if -- was already set or interspersed is false and there is already one arg then
// the extra added -- is counted as arg.
flagCompletion := true
_ = finalCmd.ParseFlags(append(finalArgs, "--"))
newArgCount := finalCmd.Flags().NArg()
// Parse the flags early so we can check if required flags are set
if err = finalCmd.ParseFlags(finalArgs); err != nil {
return finalCmd, []string{}, ShellCompDirectiveDefault, fmt.Errorf("Error while parsing flags from args %v: %s", finalArgs, err.Error())
}
realArgCount := finalCmd.Flags().NArg()
if newArgCount > realArgCount {
// don't do flag completion (see above)
flagCompletion = false
}
// Error while attempting to parse flags
if flagErr != nil {
// If error type is flagCompError and we don't want flagCompletion we should ignore the error
if _, ok := flagErr.(*flagCompError); !(ok && !flagCompletion) {
return finalCmd, []string{}, ShellCompDirectiveDefault, flagErr
}
}
// Look for the --help or --version flags. If they are present,
// there should be no further completions.
if helpOrVersionFlagPresent(finalCmd) {
return finalCmd, []string{}, ShellCompDirectiveNoFileComp, nil
}
// We only remove the flags from the arguments if DisableFlagParsing is not set.
// This is important for commands which have requested to do their own flag completion.
if !finalCmd.DisableFlagParsing {
finalArgs = finalCmd.Flags().Args()
}
if flag != nil && flagCompletion {
// Check if we are completing a flag value subject to annotations
if validExts, present := flag.Annotations[BashCompFilenameExt]; present {
if len(validExts) != 0 {
// File completion filtered by extensions
return finalCmd, validExts, ShellCompDirectiveFilterFileExt, nil
}
// The annotation requests simple file completion. There is no reason to do
// that since it is the default behavior anyway. Let's ignore this annotation
// in case the program also registered a completion function for this flag.
// Even though it is a mistake on the program's side, let's be nice when we can.
}
if subDir, present := flag.Annotations[BashCompSubdirsInDir]; present {
if len(subDir) == 1 {
// Directory completion from within a directory
return finalCmd, subDir, ShellCompDirectiveFilterDirs, nil
}
// Directory completion
return finalCmd, []string{}, ShellCompDirectiveFilterDirs, nil
}
}
var completions []string
var directive ShellCompDirective
// Enforce flag groups before doing flag completions
finalCmd.enforceFlagGroupsForCompletion()
// Note that we want to perform flagname completion even if finalCmd.DisableFlagParsing==true;
// doing this allows for completion of persistent flag names even for commands that disable flag parsing.
//
// When doing completion of a flag name, as soon as an argument starts with
// a '-' we know it is a flag. We cannot use isFlagArg() here as it requires
// the flag name to be complete
if flag == nil && len(toComplete) > 0 && toComplete[0] == '-' && !strings.Contains(toComplete, "=") && flagCompletion {
// First check for required flags
completions = completeRequireFlags(finalCmd, toComplete)
// If we have not found any required flags, only then can we show regular flags
if len(completions) == 0 {
doCompleteFlags := func(flag *pflag.Flag) {
if !flag.Changed ||
strings.Contains(flag.Value.Type(), "Slice") ||
strings.Contains(flag.Value.Type(), "Array") {
// If the flag is not already present, or if it can be specified multiple times (Array or Slice)
// we suggest it as a completion
completions = append(completions, getFlagNameCompletions(flag, toComplete)...)
}
}
// We cannot use finalCmd.Flags() because we may not have called ParsedFlags() for commands
// that have set DisableFlagParsing; it is ParseFlags() that merges the inherited and
// non-inherited flags.
finalCmd.InheritedFlags().VisitAll(func(flag *pflag.Flag) {
doCompleteFlags(flag)
})
// Try to complete non-inherited flags even if DisableFlagParsing==true.
// This allows programs to tell Cobra about flags for completion even
// if the actual parsing of flags is not done by Cobra.
// For instance, Helm uses this to provide flag name completion for
// some of its plugins.
finalCmd.NonInheritedFlags().VisitAll(func(flag *pflag.Flag) {
doCompleteFlags(flag)
})
}
directive = ShellCompDirectiveNoFileComp
if len(completions) == 1 && strings.HasSuffix(completions[0], "=") {
// If there is a single completion, the shell usually adds a space
// after the completion. We don't want that if the flag ends with an =
directive = ShellCompDirectiveNoSpace
}
if !finalCmd.DisableFlagParsing {
// If DisableFlagParsing==false, we have completed the flags as known by Cobra;
// we can return what we found.
// If DisableFlagParsing==true, Cobra may not be aware of all flags, so we
// let the logic continue to see if ValidArgsFunction needs to be called.
return finalCmd, completions, directive, nil
}
} else {
directive = ShellCompDirectiveDefault
if flag == nil {
foundLocalNonPersistentFlag := false
// If TraverseChildren is true on the root command we don't check for
// local flags because we can use a local flag on a parent command
if !finalCmd.Root().TraverseChildren {
// Check if there are any local, non-persistent flags on the command-line
localNonPersistentFlags := finalCmd.LocalNonPersistentFlags()
finalCmd.NonInheritedFlags().VisitAll(func(flag *pflag.Flag) {
if localNonPersistentFlags.Lookup(flag.Name) != nil && flag.Changed {
foundLocalNonPersistentFlag = true
}
})
}
// Complete subcommand names, including the help command
if len(finalArgs) == 0 && !foundLocalNonPersistentFlag {
// We only complete sub-commands if:
// - there are no arguments on the command-line and
// - there are no local, non-persistent flags on the command-line or TraverseChildren is true
for _, subCmd := range finalCmd.Commands() {
if subCmd.IsAvailableCommand() || subCmd == finalCmd.helpCommand {
if strings.HasPrefix(subCmd.Name(), toComplete) {
completions = append(completions, fmt.Sprintf("%s\t%s", subCmd.Name(), subCmd.Short))
}
directive = ShellCompDirectiveNoFileComp
}
}
}
// Complete required flags even without the '-' prefix
completions = append(completions, completeRequireFlags(finalCmd, toComplete)...)
// Always complete ValidArgs, even if we are completing a subcommand name.
// This is for commands that have both subcommands and ValidArgs.
if len(finalCmd.ValidArgs) > 0 {
if len(finalArgs) == 0 {
// ValidArgs are only for the first argument
for _, validArg := range finalCmd.ValidArgs {
if strings.HasPrefix(validArg, toComplete) {
completions = append(completions, validArg)
}
}
directive = ShellCompDirectiveNoFileComp
// If no completions were found within commands or ValidArgs,
// see if there are any ArgAliases that should be completed.
if len(completions) == 0 {
for _, argAlias := range finalCmd.ArgAliases {
if strings.HasPrefix(argAlias, toComplete) {
completions = append(completions, argAlias)
}
}
}
}
// If there are ValidArgs specified (even if they don't match), we stop completion.
// Only one of ValidArgs or ValidArgsFunction can be used for a single command.
return finalCmd, completions, directive, nil
}
// Let the logic continue so as to add any ValidArgsFunction completions,
// even if we already found sub-commands.
// This is for commands that have subcommands but also specify a ValidArgsFunction.
}
}
// Find the completion function for the flag or command
var completionFn func(cmd *Command, args []string, toComplete string) ([]string, ShellCompDirective)
if flag != nil && flagCompletion {
flagCompletionMutex.RLock()
completionFn = flagCompletionFunctions[flag]
flagCompletionMutex.RUnlock()
} else {
completionFn = finalCmd.ValidArgsFunction
}
if completionFn != nil {
// Go custom completion defined for this flag or command.
// Call the registered completion function to get the completions.
var comps []string
comps, directive = completionFn(finalCmd, finalArgs, toComplete)
completions = append(completions, comps...)
}
return finalCmd, completions, directive, nil
}
func helpOrVersionFlagPresent(cmd *Command) bool {
if versionFlag := cmd.Flags().Lookup("version"); versionFlag != nil &&
len(versionFlag.Annotations[FlagSetByCobraAnnotation]) > 0 && versionFlag.Changed {
return true
}
if helpFlag := cmd.Flags().Lookup("help"); helpFlag != nil &&
len(helpFlag.Annotations[FlagSetByCobraAnnotation]) > 0 && helpFlag.Changed {
return true
}
return false
}
func getFlagNameCompletions(flag *pflag.Flag, toComplete string) []string {
if nonCompletableFlag(flag) {
return []string{}
}
var completions []string
flagName := "--" + flag.Name
if strings.HasPrefix(flagName, toComplete) {
// Flag without the =
completions = append(completions, fmt.Sprintf("%s\t%s", flagName, flag.Usage))
// Why suggest both long forms: --flag and --flag= ?
// This forces the user to *always* have to type either an = or a space after the flag name.
// Let's be nice and avoid making users have to do that.
// Since boolean flags and shortname flags don't show the = form, let's go that route and never show it.
// The = form will still work, we just won't suggest it.
// This also makes the list of suggested flags shorter as we avoid all the = forms.
//
// if len(flag.NoOptDefVal) == 0 {
// // Flag requires a value, so it can be suffixed with =
// flagName += "="
// completions = append(completions, fmt.Sprintf("%s\t%s", flagName, flag.Usage))
// }
}
flagName = "-" + flag.Shorthand
if len(flag.Shorthand) > 0 && strings.HasPrefix(flagName, toComplete) {
completions = append(completions, fmt.Sprintf("%s\t%s", flagName, flag.Usage))
}
return completions
}
func completeRequireFlags(finalCmd *Command, toComplete string) []string {
var completions []string
doCompleteRequiredFlags := func(flag *pflag.Flag) {
if _, present := flag.Annotations[BashCompOneRequiredFlag]; present {
if !flag.Changed {
// If the flag is not already present, we suggest it as a completion
completions = append(completions, getFlagNameCompletions(flag, toComplete)...)
}
}
}
// We cannot use finalCmd.Flags() because we may not have called ParsedFlags() for commands
// that have set DisableFlagParsing; it is ParseFlags() that merges the inherited and
// non-inherited flags.
finalCmd.InheritedFlags().VisitAll(func(flag *pflag.Flag) {
doCompleteRequiredFlags(flag)
})
finalCmd.NonInheritedFlags().VisitAll(func(flag *pflag.Flag) {
doCompleteRequiredFlags(flag)
})
return completions
}
func checkIfFlagCompletion(finalCmd *Command, args []string, lastArg string) (*pflag.Flag, []string, string, error) {
if finalCmd.DisableFlagParsing {
// We only do flag completion if we are allowed to parse flags
// This is important for commands which have requested to do their own flag completion.
return nil, args, lastArg, nil
}
var flagName string
trimmedArgs := args
flagWithEqual := false
orgLastArg := lastArg
// When doing completion of a flag name, as soon as an argument starts with
// a '-' we know it is a flag. We cannot use isFlagArg() here as that function
// requires the flag name to be complete
if len(lastArg) > 0 && lastArg[0] == '-' {
if index := strings.Index(lastArg, "="); index >= 0 {
// Flag with an =
if strings.HasPrefix(lastArg[:index], "--") {
// Flag has full name
flagName = lastArg[2:index]
} else {
// Flag is shorthand
// We have to get the last shorthand flag name
// e.g. `-asd` => d to provide the correct completion
// https://github.com/spf13/cobra/issues/1257
flagName = lastArg[index-1 : index]
}
lastArg = lastArg[index+1:]
flagWithEqual = true
} else {
// Normal flag completion
return nil, args, lastArg, nil
}
}
if len(flagName) == 0 {
if len(args) > 0 {
prevArg := args[len(args)-1]
if isFlagArg(prevArg) {
// Only consider the case where the flag does not contain an =.
// If the flag contains an = it means it has already been fully processed,
// so we don't need to deal with it here.
if index := strings.Index(prevArg, "="); index < 0 {
if strings.HasPrefix(prevArg, "--") {
// Flag has full name
flagName = prevArg[2:]
} else {
// Flag is shorthand
// We have to get the last shorthand flag name
// e.g. `-asd` => d to provide the correct completion
// https://github.com/spf13/cobra/issues/1257
flagName = prevArg[len(prevArg)-1:]
}
// Remove the uncompleted flag or else there could be an error created
// for an invalid value for that flag
trimmedArgs = args[:len(args)-1]
}
}
}
}
if len(flagName) == 0 {
// Not doing flag completion
return nil, trimmedArgs, lastArg, nil
}
flag := findFlag(finalCmd, flagName)
if flag == nil {
// Flag not supported by this command, the interspersed option might be set so return the original args
return nil, args, orgLastArg, &flagCompError{subCommand: finalCmd.Name(), flagName: flagName}
}
if !flagWithEqual {
if len(flag.NoOptDefVal) != 0 {
// We had assumed dealing with a two-word flag but the flag is a boolean flag.
// In that case, there is no value following it, so we are not really doing flag completion.
// Reset everything to do noun completion.
trimmedArgs = args
flag = nil
}
}
return flag, trimmedArgs, lastArg, nil
}
// InitDefaultCompletionCmd adds a default 'completion' command to c.
// This function will do nothing if any of the following is true:
// 1- the feature has been explicitly disabled by the program,
// 2- c has no subcommands (to avoid creating one),
// 3- c already has a 'completion' command provided by the program.
func (c *Command) InitDefaultCompletionCmd() {
if c.CompletionOptions.DisableDefaultCmd || !c.HasSubCommands() {
return
}
for _, cmd := range c.commands {
if cmd.Name() == compCmdName || cmd.HasAlias(compCmdName) {
// A completion command is already available
return
}
}
haveNoDescFlag := !c.CompletionOptions.DisableNoDescFlag && !c.CompletionOptions.DisableDescriptions
completionCmd := &Command{
Use: compCmdName,
Short: "Generate the autocompletion script for the specified shell",
Long: fmt.Sprintf(`Generate the autocompletion script for %[1]s for the specified shell.
See each sub-command's help for details on how to use the generated script.
`, c.Root().Name()),
Args: NoArgs,
ValidArgsFunction: NoFileCompletions,
Hidden: c.CompletionOptions.HiddenDefaultCmd,
GroupID: c.completionCommandGroupID,
}
c.AddCommand(completionCmd)
out := c.OutOrStdout()
noDesc := c.CompletionOptions.DisableDescriptions
shortDesc := "Generate the autocompletion script for %s"
bash := &Command{
Use: "bash",
Short: fmt.Sprintf(shortDesc, "bash"),
Long: fmt.Sprintf(`Generate the autocompletion script for the bash shell.
This script depends on the 'bash-completion' package.
If it is not installed already, you can install it via your OS's package manager.
To load completions in your current shell session:
source <(%[1]s completion bash)
To load completions for every new session, execute once:
#### Linux:
%[1]s completion bash > /etc/bash_completion.d/%[1]s
#### macOS:
%[1]s completion bash > $(brew --prefix)/etc/bash_completion.d/%[1]s
You will need to start a new shell for this setup to take effect.
`, c.Root().Name()),
Args: NoArgs,
DisableFlagsInUseLine: true,
ValidArgsFunction: NoFileCompletions,
RunE: func(cmd *Command, args []string) error {
return cmd.Root().GenBashCompletionV2(out, !noDesc)
},
}
if haveNoDescFlag {
bash.Flags().BoolVar(&noDesc, compCmdNoDescFlagName, compCmdNoDescFlagDefault, compCmdNoDescFlagDesc)
}
zsh := &Command{
Use: "zsh",
Short: fmt.Sprintf(shortDesc, "zsh"),
Long: fmt.Sprintf(`Generate the autocompletion script for the zsh shell.
If shell completion is not already enabled in your environment you will need
to enable it. You can execute the following once:
echo "autoload -U compinit; compinit" >> ~/.zshrc
To load completions in your current shell session:
source <(%[1]s completion zsh)
To load completions for every new session, execute once:
#### Linux:
%[1]s completion zsh > "${fpath[1]}/_%[1]s"
#### macOS:
%[1]s completion zsh > $(brew --prefix)/share/zsh/site-functions/_%[1]s
You will need to start a new shell for this setup to take effect.
`, c.Root().Name()),
Args: NoArgs,
ValidArgsFunction: NoFileCompletions,
RunE: func(cmd *Command, args []string) error {
if noDesc {
return cmd.Root().GenZshCompletionNoDesc(out)
}
return cmd.Root().GenZshCompletion(out)
},
}
if haveNoDescFlag {
zsh.Flags().BoolVar(&noDesc, compCmdNoDescFlagName, compCmdNoDescFlagDefault, compCmdNoDescFlagDesc)
}
fish := &Command{
Use: "fish",
Short: fmt.Sprintf(shortDesc, "fish"),
Long: fmt.Sprintf(`Generate the autocompletion script for the fish shell.
To load completions in your current shell session:
%[1]s completion fish | source
To load completions for every new session, execute once:
%[1]s completion fish > ~/.config/fish/completions/%[1]s.fish
You will need to start a new shell for this setup to take effect.
`, c.Root().Name()),
Args: NoArgs,
ValidArgsFunction: NoFileCompletions,
RunE: func(cmd *Command, args []string) error {
return cmd.Root().GenFishCompletion(out, !noDesc)
},
}
if haveNoDescFlag {
fish.Flags().BoolVar(&noDesc, compCmdNoDescFlagName, compCmdNoDescFlagDefault, compCmdNoDescFlagDesc)
}
powershell := &Command{
Use: "powershell",
Short: fmt.Sprintf(shortDesc, "powershell"),
Long: fmt.Sprintf(`Generate the autocompletion script for powershell.
To load completions in your current shell session:
%[1]s completion powershell | Out-String | Invoke-Expression
To load completions for every new session, add the output of the above command
to your powershell profile.
`, c.Root().Name()),
Args: NoArgs,
ValidArgsFunction: NoFileCompletions,
RunE: func(cmd *Command, args []string) error {
if noDesc {
return cmd.Root().GenPowerShellCompletion(out)
}
return cmd.Root().GenPowerShellCompletionWithDesc(out)
},
}
if haveNoDescFlag {
powershell.Flags().BoolVar(&noDesc, compCmdNoDescFlagName, compCmdNoDescFlagDefault, compCmdNoDescFlagDesc)
}
completionCmd.AddCommand(bash, zsh, fish, powershell)
}
func findFlag(cmd *Command, name string) *pflag.Flag {
flagSet := cmd.Flags()
if len(name) == 1 {
// First convert the short flag into a long flag
// as the cmd.Flag() search only accepts long flags
if short := flagSet.ShorthandLookup(name); short != nil {
name = short.Name
} else {
set := cmd.InheritedFlags()
if short = set.ShorthandLookup(name); short != nil {
name = short.Name
} else {
return nil
}
}
}
return cmd.Flag(name)
}
// CompDebug prints the specified string to the same file as where the
// completion script prints its logs.
// Note that completion printouts should never be on stdout as they would
// be wrongly interpreted as actual completion choices by the completion script.
func CompDebug(msg string, printToStdErr bool) {
msg = fmt.Sprintf("[Debug] %s", msg)
// Such logs are only printed when the user has set the environment
// variable BASH_COMP_DEBUG_FILE to the path of some file to be used.
if path := os.Getenv("BASH_COMP_DEBUG_FILE"); path != "" {
f, err := os.OpenFile(path,
os.O_APPEND|os.O_CREATE|os.O_WRONLY, 0644)
if err == nil {
defer f.Close()
WriteStringAndCheck(f, msg)
}
}
if printToStdErr {
// Must print to stderr for this not to be read by the completion script.
fmt.Fprint(os.Stderr, msg)
}
}
// CompDebugln prints the specified string with a newline at the end
// to the same file as where the completion script prints its logs.
// Such logs are only printed when the user has set the environment
// variable BASH_COMP_DEBUG_FILE to the path of some file to be used.
func CompDebugln(msg string, printToStdErr bool) {
CompDebug(fmt.Sprintf("%s\n", msg), printToStdErr)
}
// CompError prints the specified completion message to stderr.
func CompError(msg string) {
msg = fmt.Sprintf("[Error] %s", msg)
CompDebug(msg, true)
}
// CompErrorln prints the specified completion message to stderr with a newline at the end.
func CompErrorln(msg string) {
CompError(fmt.Sprintf("%s\n", msg))
}

292
vendor/github.com/spf13/cobra/fish_completions.go generated vendored Normal file
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@ -0,0 +1,292 @@
// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"bytes"
"fmt"
"io"
"os"
"strings"
)
func genFishComp(buf io.StringWriter, name string, includeDesc bool) {
// Variables should not contain a '-' or ':' character
nameForVar := name
nameForVar = strings.ReplaceAll(nameForVar, "-", "_")
nameForVar = strings.ReplaceAll(nameForVar, ":", "_")
compCmd := ShellCompRequestCmd
if !includeDesc {
compCmd = ShellCompNoDescRequestCmd
}
WriteStringAndCheck(buf, fmt.Sprintf("# fish completion for %-36s -*- shell-script -*-\n", name))
WriteStringAndCheck(buf, fmt.Sprintf(`
function __%[1]s_debug
set -l file "$BASH_COMP_DEBUG_FILE"
if test -n "$file"
echo "$argv" >> $file
end
end
function __%[1]s_perform_completion
__%[1]s_debug "Starting __%[1]s_perform_completion"
# Extract all args except the last one
set -l args (commandline -opc)
# Extract the last arg and escape it in case it is a space
set -l lastArg (string escape -- (commandline -ct))
__%[1]s_debug "args: $args"
__%[1]s_debug "last arg: $lastArg"
# Disable ActiveHelp which is not supported for fish shell
set -l requestComp "%[10]s=0 $args[1] %[3]s $args[2..-1] $lastArg"
__%[1]s_debug "Calling $requestComp"
set -l results (eval $requestComp 2> /dev/null)
# Some programs may output extra empty lines after the directive.
# Let's ignore them or else it will break completion.
# Ref: https://github.com/spf13/cobra/issues/1279
for line in $results[-1..1]
if test (string trim -- $line) = ""
# Found an empty line, remove it
set results $results[1..-2]
else
# Found non-empty line, we have our proper output
break
end
end
set -l comps $results[1..-2]
set -l directiveLine $results[-1]
# For Fish, when completing a flag with an = (e.g., <program> -n=<TAB>)
# completions must be prefixed with the flag
set -l flagPrefix (string match -r -- '-.*=' "$lastArg")
__%[1]s_debug "Comps: $comps"
__%[1]s_debug "DirectiveLine: $directiveLine"
__%[1]s_debug "flagPrefix: $flagPrefix"
for comp in $comps
printf "%%s%%s\n" "$flagPrefix" "$comp"
end
printf "%%s\n" "$directiveLine"
end
# this function limits calls to __%[1]s_perform_completion, by caching the result behind $__%[1]s_perform_completion_once_result
function __%[1]s_perform_completion_once
__%[1]s_debug "Starting __%[1]s_perform_completion_once"
if test -n "$__%[1]s_perform_completion_once_result"
__%[1]s_debug "Seems like a valid result already exists, skipping __%[1]s_perform_completion"
return 0
end
set --global __%[1]s_perform_completion_once_result (__%[1]s_perform_completion)
if test -z "$__%[1]s_perform_completion_once_result"
__%[1]s_debug "No completions, probably due to a failure"
return 1
end
__%[1]s_debug "Performed completions and set __%[1]s_perform_completion_once_result"
return 0
end
# this function is used to clear the $__%[1]s_perform_completion_once_result variable after completions are run
function __%[1]s_clear_perform_completion_once_result
__%[1]s_debug ""
__%[1]s_debug "========= clearing previously set __%[1]s_perform_completion_once_result variable =========="
set --erase __%[1]s_perform_completion_once_result
__%[1]s_debug "Successfully erased the variable __%[1]s_perform_completion_once_result"
end
function __%[1]s_requires_order_preservation
__%[1]s_debug ""
__%[1]s_debug "========= checking if order preservation is required =========="
__%[1]s_perform_completion_once
if test -z "$__%[1]s_perform_completion_once_result"
__%[1]s_debug "Error determining if order preservation is required"
return 1
end
set -l directive (string sub --start 2 $__%[1]s_perform_completion_once_result[-1])
__%[1]s_debug "Directive is: $directive"
set -l shellCompDirectiveKeepOrder %[9]d
set -l keeporder (math (math --scale 0 $directive / $shellCompDirectiveKeepOrder) %% 2)
__%[1]s_debug "Keeporder is: $keeporder"
if test $keeporder -ne 0
__%[1]s_debug "This does require order preservation"
return 0
end
__%[1]s_debug "This doesn't require order preservation"
return 1
end
# This function does two things:
# - Obtain the completions and store them in the global __%[1]s_comp_results
# - Return false if file completion should be performed
function __%[1]s_prepare_completions
__%[1]s_debug ""
__%[1]s_debug "========= starting completion logic =========="
# Start fresh
set --erase __%[1]s_comp_results
__%[1]s_perform_completion_once
__%[1]s_debug "Completion results: $__%[1]s_perform_completion_once_result"
if test -z "$__%[1]s_perform_completion_once_result"
__%[1]s_debug "No completion, probably due to a failure"
# Might as well do file completion, in case it helps
return 1
end
set -l directive (string sub --start 2 $__%[1]s_perform_completion_once_result[-1])
set --global __%[1]s_comp_results $__%[1]s_perform_completion_once_result[1..-2]
__%[1]s_debug "Completions are: $__%[1]s_comp_results"
__%[1]s_debug "Directive is: $directive"
set -l shellCompDirectiveError %[4]d
set -l shellCompDirectiveNoSpace %[5]d
set -l shellCompDirectiveNoFileComp %[6]d
set -l shellCompDirectiveFilterFileExt %[7]d
set -l shellCompDirectiveFilterDirs %[8]d
if test -z "$directive"
set directive 0
end
set -l compErr (math (math --scale 0 $directive / $shellCompDirectiveError) %% 2)
if test $compErr -eq 1
__%[1]s_debug "Received error directive: aborting."
# Might as well do file completion, in case it helps
return 1
end
set -l filefilter (math (math --scale 0 $directive / $shellCompDirectiveFilterFileExt) %% 2)
set -l dirfilter (math (math --scale 0 $directive / $shellCompDirectiveFilterDirs) %% 2)
if test $filefilter -eq 1; or test $dirfilter -eq 1
__%[1]s_debug "File extension filtering or directory filtering not supported"
# Do full file completion instead
return 1
end
set -l nospace (math (math --scale 0 $directive / $shellCompDirectiveNoSpace) %% 2)
set -l nofiles (math (math --scale 0 $directive / $shellCompDirectiveNoFileComp) %% 2)
__%[1]s_debug "nospace: $nospace, nofiles: $nofiles"
# If we want to prevent a space, or if file completion is NOT disabled,
# we need to count the number of valid completions.
# To do so, we will filter on prefix as the completions we have received
# may not already be filtered so as to allow fish to match on different
# criteria than the prefix.
if test $nospace -ne 0; or test $nofiles -eq 0
set -l prefix (commandline -t | string escape --style=regex)
__%[1]s_debug "prefix: $prefix"
set -l completions (string match -r -- "^$prefix.*" $__%[1]s_comp_results)
set --global __%[1]s_comp_results $completions
__%[1]s_debug "Filtered completions are: $__%[1]s_comp_results"
# Important not to quote the variable for count to work
set -l numComps (count $__%[1]s_comp_results)
__%[1]s_debug "numComps: $numComps"
if test $numComps -eq 1; and test $nospace -ne 0
# We must first split on \t to get rid of the descriptions to be
# able to check what the actual completion will be.
# We don't need descriptions anyway since there is only a single
# real completion which the shell will expand immediately.
set -l split (string split --max 1 \t $__%[1]s_comp_results[1])
# Fish won't add a space if the completion ends with any
# of the following characters: @=/:.,
set -l lastChar (string sub -s -1 -- $split)
if not string match -r -q "[@=/:.,]" -- "$lastChar"
# In other cases, to support the "nospace" directive we trick the shell
# by outputting an extra, longer completion.
__%[1]s_debug "Adding second completion to perform nospace directive"
set --global __%[1]s_comp_results $split[1] $split[1].
__%[1]s_debug "Completions are now: $__%[1]s_comp_results"
end
end
if test $numComps -eq 0; and test $nofiles -eq 0
# To be consistent with bash and zsh, we only trigger file
# completion when there are no other completions
__%[1]s_debug "Requesting file completion"
return 1
end
end
return 0
end
# Since Fish completions are only loaded once the user triggers them, we trigger them ourselves
# so we can properly delete any completions provided by another script.
# Only do this if the program can be found, or else fish may print some errors; besides,
# the existing completions will only be loaded if the program can be found.
if type -q "%[2]s"
# The space after the program name is essential to trigger completion for the program
# and not completion of the program name itself.
# Also, we use '> /dev/null 2>&1' since '&>' is not supported in older versions of fish.
complete --do-complete "%[2]s " > /dev/null 2>&1
end
# Remove any pre-existing completions for the program since we will be handling all of them.
complete -c %[2]s -e
# this will get called after the two calls below and clear the $__%[1]s_perform_completion_once_result global
complete -c %[2]s -n '__%[1]s_clear_perform_completion_once_result'
# The call to __%[1]s_prepare_completions will setup __%[1]s_comp_results
# which provides the program's completion choices.
# If this doesn't require order preservation, we don't use the -k flag
complete -c %[2]s -n 'not __%[1]s_requires_order_preservation && __%[1]s_prepare_completions' -f -a '$__%[1]s_comp_results'
# otherwise we use the -k flag
complete -k -c %[2]s -n '__%[1]s_requires_order_preservation && __%[1]s_prepare_completions' -f -a '$__%[1]s_comp_results'
`, nameForVar, name, compCmd,
ShellCompDirectiveError, ShellCompDirectiveNoSpace, ShellCompDirectiveNoFileComp,
ShellCompDirectiveFilterFileExt, ShellCompDirectiveFilterDirs, ShellCompDirectiveKeepOrder, activeHelpEnvVar(name)))
}
// GenFishCompletion generates fish completion file and writes to the passed writer.
func (c *Command) GenFishCompletion(w io.Writer, includeDesc bool) error {
buf := new(bytes.Buffer)
genFishComp(buf, c.Name(), includeDesc)
_, err := buf.WriteTo(w)
return err
}
// GenFishCompletionFile generates fish completion file.
func (c *Command) GenFishCompletionFile(filename string, includeDesc bool) error {
outFile, err := os.Create(filename)
if err != nil {
return err
}
defer outFile.Close()
return c.GenFishCompletion(outFile, includeDesc)
}

290
vendor/github.com/spf13/cobra/flag_groups.go generated vendored Normal file
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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"fmt"
"sort"
"strings"
flag "github.com/spf13/pflag"
)
const (
requiredAsGroup = "cobra_annotation_required_if_others_set"
oneRequired = "cobra_annotation_one_required"
mutuallyExclusive = "cobra_annotation_mutually_exclusive"
)
// MarkFlagsRequiredTogether marks the given flags with annotations so that Cobra errors
// if the command is invoked with a subset (but not all) of the given flags.
func (c *Command) MarkFlagsRequiredTogether(flagNames ...string) {
c.mergePersistentFlags()
for _, v := range flagNames {
f := c.Flags().Lookup(v)
if f == nil {
panic(fmt.Sprintf("Failed to find flag %q and mark it as being required in a flag group", v))
}
if err := c.Flags().SetAnnotation(v, requiredAsGroup, append(f.Annotations[requiredAsGroup], strings.Join(flagNames, " "))); err != nil {
// Only errs if the flag isn't found.
panic(err)
}
}
}
// MarkFlagsOneRequired marks the given flags with annotations so that Cobra errors
// if the command is invoked without at least one flag from the given set of flags.
func (c *Command) MarkFlagsOneRequired(flagNames ...string) {
c.mergePersistentFlags()
for _, v := range flagNames {
f := c.Flags().Lookup(v)
if f == nil {
panic(fmt.Sprintf("Failed to find flag %q and mark it as being in a one-required flag group", v))
}
if err := c.Flags().SetAnnotation(v, oneRequired, append(f.Annotations[oneRequired], strings.Join(flagNames, " "))); err != nil {
// Only errs if the flag isn't found.
panic(err)
}
}
}
// MarkFlagsMutuallyExclusive marks the given flags with annotations so that Cobra errors
// if the command is invoked with more than one flag from the given set of flags.
func (c *Command) MarkFlagsMutuallyExclusive(flagNames ...string) {
c.mergePersistentFlags()
for _, v := range flagNames {
f := c.Flags().Lookup(v)
if f == nil {
panic(fmt.Sprintf("Failed to find flag %q and mark it as being in a mutually exclusive flag group", v))
}
// Each time this is called is a single new entry; this allows it to be a member of multiple groups if needed.
if err := c.Flags().SetAnnotation(v, mutuallyExclusive, append(f.Annotations[mutuallyExclusive], strings.Join(flagNames, " "))); err != nil {
panic(err)
}
}
}
// ValidateFlagGroups validates the mutuallyExclusive/oneRequired/requiredAsGroup logic and returns the
// first error encountered.
func (c *Command) ValidateFlagGroups() error {
if c.DisableFlagParsing {
return nil
}
flags := c.Flags()
// groupStatus format is the list of flags as a unique ID,
// then a map of each flag name and whether it is set or not.
groupStatus := map[string]map[string]bool{}
oneRequiredGroupStatus := map[string]map[string]bool{}
mutuallyExclusiveGroupStatus := map[string]map[string]bool{}
flags.VisitAll(func(pflag *flag.Flag) {
processFlagForGroupAnnotation(flags, pflag, requiredAsGroup, groupStatus)
processFlagForGroupAnnotation(flags, pflag, oneRequired, oneRequiredGroupStatus)
processFlagForGroupAnnotation(flags, pflag, mutuallyExclusive, mutuallyExclusiveGroupStatus)
})
if err := validateRequiredFlagGroups(groupStatus); err != nil {
return err
}
if err := validateOneRequiredFlagGroups(oneRequiredGroupStatus); err != nil {
return err
}
if err := validateExclusiveFlagGroups(mutuallyExclusiveGroupStatus); err != nil {
return err
}
return nil
}
func hasAllFlags(fs *flag.FlagSet, flagnames ...string) bool {
for _, fname := range flagnames {
f := fs.Lookup(fname)
if f == nil {
return false
}
}
return true
}
func processFlagForGroupAnnotation(flags *flag.FlagSet, pflag *flag.Flag, annotation string, groupStatus map[string]map[string]bool) {
groupInfo, found := pflag.Annotations[annotation]
if found {
for _, group := range groupInfo {
if groupStatus[group] == nil {
flagnames := strings.Split(group, " ")
// Only consider this flag group at all if all the flags are defined.
if !hasAllFlags(flags, flagnames...) {
continue
}
groupStatus[group] = map[string]bool{}
for _, name := range flagnames {
groupStatus[group][name] = false
}
}
groupStatus[group][pflag.Name] = pflag.Changed
}
}
}
func validateRequiredFlagGroups(data map[string]map[string]bool) error {
keys := sortedKeys(data)
for _, flagList := range keys {
flagnameAndStatus := data[flagList]
unset := []string{}
for flagname, isSet := range flagnameAndStatus {
if !isSet {
unset = append(unset, flagname)
}
}
if len(unset) == len(flagnameAndStatus) || len(unset) == 0 {
continue
}
// Sort values, so they can be tested/scripted against consistently.
sort.Strings(unset)
return fmt.Errorf("if any flags in the group [%v] are set they must all be set; missing %v", flagList, unset)
}
return nil
}
func validateOneRequiredFlagGroups(data map[string]map[string]bool) error {
keys := sortedKeys(data)
for _, flagList := range keys {
flagnameAndStatus := data[flagList]
var set []string
for flagname, isSet := range flagnameAndStatus {
if isSet {
set = append(set, flagname)
}
}
if len(set) >= 1 {
continue
}
// Sort values, so they can be tested/scripted against consistently.
sort.Strings(set)
return fmt.Errorf("at least one of the flags in the group [%v] is required", flagList)
}
return nil
}
func validateExclusiveFlagGroups(data map[string]map[string]bool) error {
keys := sortedKeys(data)
for _, flagList := range keys {
flagnameAndStatus := data[flagList]
var set []string
for flagname, isSet := range flagnameAndStatus {
if isSet {
set = append(set, flagname)
}
}
if len(set) == 0 || len(set) == 1 {
continue
}
// Sort values, so they can be tested/scripted against consistently.
sort.Strings(set)
return fmt.Errorf("if any flags in the group [%v] are set none of the others can be; %v were all set", flagList, set)
}
return nil
}
func sortedKeys(m map[string]map[string]bool) []string {
keys := make([]string, len(m))
i := 0
for k := range m {
keys[i] = k
i++
}
sort.Strings(keys)
return keys
}
// enforceFlagGroupsForCompletion will do the following:
// - when a flag in a group is present, other flags in the group will be marked required
// - when none of the flags in a one-required group are present, all flags in the group will be marked required
// - when a flag in a mutually exclusive group is present, other flags in the group will be marked as hidden
// This allows the standard completion logic to behave appropriately for flag groups
func (c *Command) enforceFlagGroupsForCompletion() {
if c.DisableFlagParsing {
return
}
flags := c.Flags()
groupStatus := map[string]map[string]bool{}
oneRequiredGroupStatus := map[string]map[string]bool{}
mutuallyExclusiveGroupStatus := map[string]map[string]bool{}
c.Flags().VisitAll(func(pflag *flag.Flag) {
processFlagForGroupAnnotation(flags, pflag, requiredAsGroup, groupStatus)
processFlagForGroupAnnotation(flags, pflag, oneRequired, oneRequiredGroupStatus)
processFlagForGroupAnnotation(flags, pflag, mutuallyExclusive, mutuallyExclusiveGroupStatus)
})
// If a flag that is part of a group is present, we make all the other flags
// of that group required so that the shell completion suggests them automatically
for flagList, flagnameAndStatus := range groupStatus {
for _, isSet := range flagnameAndStatus {
if isSet {
// One of the flags of the group is set, mark the other ones as required
for _, fName := range strings.Split(flagList, " ") {
_ = c.MarkFlagRequired(fName)
}
}
}
}
// If none of the flags of a one-required group are present, we make all the flags
// of that group required so that the shell completion suggests them automatically
for flagList, flagnameAndStatus := range oneRequiredGroupStatus {
set := 0
for _, isSet := range flagnameAndStatus {
if isSet {
set++
}
}
// None of the flags of the group are set, mark all flags in the group
// as required
if set == 0 {
for _, fName := range strings.Split(flagList, " ") {
_ = c.MarkFlagRequired(fName)
}
}
}
// If a flag that is mutually exclusive to others is present, we hide the other
// flags of that group so the shell completion does not suggest them
for flagList, flagnameAndStatus := range mutuallyExclusiveGroupStatus {
for flagName, isSet := range flagnameAndStatus {
if isSet {
// One of the flags of the mutually exclusive group is set, mark the other ones as hidden
// Don't mark the flag that is already set as hidden because it may be an
// array or slice flag and therefore must continue being suggested
for _, fName := range strings.Split(flagList, " ") {
if fName != flagName {
flag := c.Flags().Lookup(fName)
flag.Hidden = true
}
}
}
}
}
}

325
vendor/github.com/spf13/cobra/powershell_completions.go generated vendored Normal file
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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// The generated scripts require PowerShell v5.0+ (which comes Windows 10, but
// can be downloaded separately for windows 7 or 8.1).
package cobra
import (
"bytes"
"fmt"
"io"
"os"
"strings"
)
func genPowerShellComp(buf io.StringWriter, name string, includeDesc bool) {
// Variables should not contain a '-' or ':' character
nameForVar := name
nameForVar = strings.Replace(nameForVar, "-", "_", -1)
nameForVar = strings.Replace(nameForVar, ":", "_", -1)
compCmd := ShellCompRequestCmd
if !includeDesc {
compCmd = ShellCompNoDescRequestCmd
}
WriteStringAndCheck(buf, fmt.Sprintf(`# powershell completion for %-36[1]s -*- shell-script -*-
function __%[1]s_debug {
if ($env:BASH_COMP_DEBUG_FILE) {
"$args" | Out-File -Append -FilePath "$env:BASH_COMP_DEBUG_FILE"
}
}
filter __%[1]s_escapeStringWithSpecialChars {
`+" $_ -replace '\\s|#|@|\\$|;|,|''|\\{|\\}|\\(|\\)|\"|`|\\||<|>|&','`$&'"+`
}
[scriptblock]${__%[2]sCompleterBlock} = {
param(
$WordToComplete,
$CommandAst,
$CursorPosition
)
# Get the current command line and convert into a string
$Command = $CommandAst.CommandElements
$Command = "$Command"
__%[1]s_debug ""
__%[1]s_debug "========= starting completion logic =========="
__%[1]s_debug "WordToComplete: $WordToComplete Command: $Command CursorPosition: $CursorPosition"
# The user could have moved the cursor backwards on the command-line.
# We need to trigger completion from the $CursorPosition location, so we need
# to truncate the command-line ($Command) up to the $CursorPosition location.
# Make sure the $Command is longer then the $CursorPosition before we truncate.
# This happens because the $Command does not include the last space.
if ($Command.Length -gt $CursorPosition) {
$Command=$Command.Substring(0,$CursorPosition)
}
__%[1]s_debug "Truncated command: $Command"
$ShellCompDirectiveError=%[4]d
$ShellCompDirectiveNoSpace=%[5]d
$ShellCompDirectiveNoFileComp=%[6]d
$ShellCompDirectiveFilterFileExt=%[7]d
$ShellCompDirectiveFilterDirs=%[8]d
$ShellCompDirectiveKeepOrder=%[9]d
# Prepare the command to request completions for the program.
# Split the command at the first space to separate the program and arguments.
$Program,$Arguments = $Command.Split(" ",2)
$RequestComp="$Program %[3]s $Arguments"
__%[1]s_debug "RequestComp: $RequestComp"
# we cannot use $WordToComplete because it
# has the wrong values if the cursor was moved
# so use the last argument
if ($WordToComplete -ne "" ) {
$WordToComplete = $Arguments.Split(" ")[-1]
}
__%[1]s_debug "New WordToComplete: $WordToComplete"
# Check for flag with equal sign
$IsEqualFlag = ($WordToComplete -Like "--*=*" )
if ( $IsEqualFlag ) {
__%[1]s_debug "Completing equal sign flag"
# Remove the flag part
$Flag,$WordToComplete = $WordToComplete.Split("=",2)
}
if ( $WordToComplete -eq "" -And ( -Not $IsEqualFlag )) {
# If the last parameter is complete (there is a space following it)
# We add an extra empty parameter so we can indicate this to the go method.
__%[1]s_debug "Adding extra empty parameter"
# PowerShell 7.2+ changed the way how the arguments are passed to executables,
# so for pre-7.2 or when Legacy argument passing is enabled we need to use
`+" # `\"`\" to pass an empty argument, a \"\" or '' does not work!!!"+`
if ($PSVersionTable.PsVersion -lt [version]'7.2.0' -or
($PSVersionTable.PsVersion -lt [version]'7.3.0' -and -not [ExperimentalFeature]::IsEnabled("PSNativeCommandArgumentPassing")) -or
(($PSVersionTable.PsVersion -ge [version]'7.3.0' -or [ExperimentalFeature]::IsEnabled("PSNativeCommandArgumentPassing")) -and
$PSNativeCommandArgumentPassing -eq 'Legacy')) {
`+" $RequestComp=\"$RequestComp\" + ' `\"`\"'"+`
} else {
$RequestComp="$RequestComp" + ' ""'
}
}
__%[1]s_debug "Calling $RequestComp"
# First disable ActiveHelp which is not supported for Powershell
${env:%[10]s}=0
#call the command store the output in $out and redirect stderr and stdout to null
# $Out is an array contains each line per element
Invoke-Expression -OutVariable out "$RequestComp" 2>&1 | Out-Null
# get directive from last line
[int]$Directive = $Out[-1].TrimStart(':')
if ($Directive -eq "") {
# There is no directive specified
$Directive = 0
}
__%[1]s_debug "The completion directive is: $Directive"
# remove directive (last element) from out
$Out = $Out | Where-Object { $_ -ne $Out[-1] }
__%[1]s_debug "The completions are: $Out"
if (($Directive -band $ShellCompDirectiveError) -ne 0 ) {
# Error code. No completion.
__%[1]s_debug "Received error from custom completion go code"
return
}
$Longest = 0
[Array]$Values = $Out | ForEach-Object {
#Split the output in name and description
`+" $Name, $Description = $_.Split(\"`t\",2)"+`
__%[1]s_debug "Name: $Name Description: $Description"
# Look for the longest completion so that we can format things nicely
if ($Longest -lt $Name.Length) {
$Longest = $Name.Length
}
# Set the description to a one space string if there is none set.
# This is needed because the CompletionResult does not accept an empty string as argument
if (-Not $Description) {
$Description = " "
}
@{Name="$Name";Description="$Description"}
}
$Space = " "
if (($Directive -band $ShellCompDirectiveNoSpace) -ne 0 ) {
# remove the space here
__%[1]s_debug "ShellCompDirectiveNoSpace is called"
$Space = ""
}
if ((($Directive -band $ShellCompDirectiveFilterFileExt) -ne 0 ) -or
(($Directive -band $ShellCompDirectiveFilterDirs) -ne 0 )) {
__%[1]s_debug "ShellCompDirectiveFilterFileExt ShellCompDirectiveFilterDirs are not supported"
# return here to prevent the completion of the extensions
return
}
$Values = $Values | Where-Object {
# filter the result
$_.Name -like "$WordToComplete*"
# Join the flag back if we have an equal sign flag
if ( $IsEqualFlag ) {
__%[1]s_debug "Join the equal sign flag back to the completion value"
$_.Name = $Flag + "=" + $_.Name
}
}
# we sort the values in ascending order by name if keep order isn't passed
if (($Directive -band $ShellCompDirectiveKeepOrder) -eq 0 ) {
$Values = $Values | Sort-Object -Property Name
}
if (($Directive -band $ShellCompDirectiveNoFileComp) -ne 0 ) {
__%[1]s_debug "ShellCompDirectiveNoFileComp is called"
if ($Values.Length -eq 0) {
# Just print an empty string here so the
# shell does not start to complete paths.
# We cannot use CompletionResult here because
# it does not accept an empty string as argument.
""
return
}
}
# Get the current mode
$Mode = (Get-PSReadLineKeyHandler | Where-Object {$_.Key -eq "Tab" }).Function
__%[1]s_debug "Mode: $Mode"
$Values | ForEach-Object {
# store temporary because switch will overwrite $_
$comp = $_
# PowerShell supports three different completion modes
# - TabCompleteNext (default windows style - on each key press the next option is displayed)
# - Complete (works like bash)
# - MenuComplete (works like zsh)
# You set the mode with Set-PSReadLineKeyHandler -Key Tab -Function <mode>
# CompletionResult Arguments:
# 1) CompletionText text to be used as the auto completion result
# 2) ListItemText text to be displayed in the suggestion list
# 3) ResultType type of completion result
# 4) ToolTip text for the tooltip with details about the object
switch ($Mode) {
# bash like
"Complete" {
if ($Values.Length -eq 1) {
__%[1]s_debug "Only one completion left"
# insert space after value
[System.Management.Automation.CompletionResult]::new($($comp.Name | __%[1]s_escapeStringWithSpecialChars) + $Space, "$($comp.Name)", 'ParameterValue', "$($comp.Description)")
} else {
# Add the proper number of spaces to align the descriptions
while($comp.Name.Length -lt $Longest) {
$comp.Name = $comp.Name + " "
}
# Check for empty description and only add parentheses if needed
if ($($comp.Description) -eq " " ) {
$Description = ""
} else {
$Description = " ($($comp.Description))"
}
[System.Management.Automation.CompletionResult]::new("$($comp.Name)$Description", "$($comp.Name)$Description", 'ParameterValue', "$($comp.Description)")
}
}
# zsh like
"MenuComplete" {
# insert space after value
# MenuComplete will automatically show the ToolTip of
# the highlighted value at the bottom of the suggestions.
[System.Management.Automation.CompletionResult]::new($($comp.Name | __%[1]s_escapeStringWithSpecialChars) + $Space, "$($comp.Name)", 'ParameterValue', "$($comp.Description)")
}
# TabCompleteNext and in case we get something unknown
Default {
# Like MenuComplete but we don't want to add a space here because
# the user need to press space anyway to get the completion.
# Description will not be shown because that's not possible with TabCompleteNext
[System.Management.Automation.CompletionResult]::new($($comp.Name | __%[1]s_escapeStringWithSpecialChars), "$($comp.Name)", 'ParameterValue', "$($comp.Description)")
}
}
}
}
Register-ArgumentCompleter -CommandName '%[1]s' -ScriptBlock ${__%[2]sCompleterBlock}
`, name, nameForVar, compCmd,
ShellCompDirectiveError, ShellCompDirectiveNoSpace, ShellCompDirectiveNoFileComp,
ShellCompDirectiveFilterFileExt, ShellCompDirectiveFilterDirs, ShellCompDirectiveKeepOrder, activeHelpEnvVar(name)))
}
func (c *Command) genPowerShellCompletion(w io.Writer, includeDesc bool) error {
buf := new(bytes.Buffer)
genPowerShellComp(buf, c.Name(), includeDesc)
_, err := buf.WriteTo(w)
return err
}
func (c *Command) genPowerShellCompletionFile(filename string, includeDesc bool) error {
outFile, err := os.Create(filename)
if err != nil {
return err
}
defer outFile.Close()
return c.genPowerShellCompletion(outFile, includeDesc)
}
// GenPowerShellCompletionFile generates powershell completion file without descriptions.
func (c *Command) GenPowerShellCompletionFile(filename string) error {
return c.genPowerShellCompletionFile(filename, false)
}
// GenPowerShellCompletion generates powershell completion file without descriptions
// and writes it to the passed writer.
func (c *Command) GenPowerShellCompletion(w io.Writer) error {
return c.genPowerShellCompletion(w, false)
}
// GenPowerShellCompletionFileWithDesc generates powershell completion file with descriptions.
func (c *Command) GenPowerShellCompletionFileWithDesc(filename string) error {
return c.genPowerShellCompletionFile(filename, true)
}
// GenPowerShellCompletionWithDesc generates powershell completion file with descriptions
// and writes it to the passed writer.
func (c *Command) GenPowerShellCompletionWithDesc(w io.Writer) error {
return c.genPowerShellCompletion(w, true)
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"github.com/spf13/pflag"
)
// MarkFlagRequired instructs the various shell completion implementations to
// prioritize the named flag when performing completion,
// and causes your command to report an error if invoked without the flag.
func (c *Command) MarkFlagRequired(name string) error {
return MarkFlagRequired(c.Flags(), name)
}
// MarkPersistentFlagRequired instructs the various shell completion implementations to
// prioritize the named persistent flag when performing completion,
// and causes your command to report an error if invoked without the flag.
func (c *Command) MarkPersistentFlagRequired(name string) error {
return MarkFlagRequired(c.PersistentFlags(), name)
}
// MarkFlagRequired instructs the various shell completion implementations to
// prioritize the named flag when performing completion,
// and causes your command to report an error if invoked without the flag.
func MarkFlagRequired(flags *pflag.FlagSet, name string) error {
return flags.SetAnnotation(name, BashCompOneRequiredFlag, []string{"true"})
}
// MarkFlagFilename instructs the various shell completion implementations to
// limit completions for the named flag to the specified file extensions.
func (c *Command) MarkFlagFilename(name string, extensions ...string) error {
return MarkFlagFilename(c.Flags(), name, extensions...)
}
// MarkFlagCustom adds the BashCompCustom annotation to the named flag, if it exists.
// The bash completion script will call the bash function f for the flag.
//
// This will only work for bash completion.
// It is recommended to instead use c.RegisterFlagCompletionFunc(...) which allows
// to register a Go function which will work across all shells.
func (c *Command) MarkFlagCustom(name string, f string) error {
return MarkFlagCustom(c.Flags(), name, f)
}
// MarkPersistentFlagFilename instructs the various shell completion
// implementations to limit completions for the named persistent flag to the
// specified file extensions.
func (c *Command) MarkPersistentFlagFilename(name string, extensions ...string) error {
return MarkFlagFilename(c.PersistentFlags(), name, extensions...)
}
// MarkFlagFilename instructs the various shell completion implementations to
// limit completions for the named flag to the specified file extensions.
func MarkFlagFilename(flags *pflag.FlagSet, name string, extensions ...string) error {
return flags.SetAnnotation(name, BashCompFilenameExt, extensions)
}
// MarkFlagCustom adds the BashCompCustom annotation to the named flag, if it exists.
// The bash completion script will call the bash function f for the flag.
//
// This will only work for bash completion.
// It is recommended to instead use c.RegisterFlagCompletionFunc(...) which allows
// to register a Go function which will work across all shells.
func MarkFlagCustom(flags *pflag.FlagSet, name string, f string) error {
return flags.SetAnnotation(name, BashCompCustom, []string{f})
}
// MarkFlagDirname instructs the various shell completion implementations to
// limit completions for the named flag to directory names.
func (c *Command) MarkFlagDirname(name string) error {
return MarkFlagDirname(c.Flags(), name)
}
// MarkPersistentFlagDirname instructs the various shell completion
// implementations to limit completions for the named persistent flag to
// directory names.
func (c *Command) MarkPersistentFlagDirname(name string) error {
return MarkFlagDirname(c.PersistentFlags(), name)
}
// MarkFlagDirname instructs the various shell completion implementations to
// limit completions for the named flag to directory names.
func MarkFlagDirname(flags *pflag.FlagSet, name string) error {
return flags.SetAnnotation(name, BashCompSubdirsInDir, []string{})
}

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// Copyright 2013-2023 The Cobra Authors
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package cobra
import (
"bytes"
"fmt"
"io"
"os"
)
// GenZshCompletionFile generates zsh completion file including descriptions.
func (c *Command) GenZshCompletionFile(filename string) error {
return c.genZshCompletionFile(filename, true)
}
// GenZshCompletion generates zsh completion file including descriptions
// and writes it to the passed writer.
func (c *Command) GenZshCompletion(w io.Writer) error {
return c.genZshCompletion(w, true)
}
// GenZshCompletionFileNoDesc generates zsh completion file without descriptions.
func (c *Command) GenZshCompletionFileNoDesc(filename string) error {
return c.genZshCompletionFile(filename, false)
}
// GenZshCompletionNoDesc generates zsh completion file without descriptions
// and writes it to the passed writer.
func (c *Command) GenZshCompletionNoDesc(w io.Writer) error {
return c.genZshCompletion(w, false)
}
// MarkZshCompPositionalArgumentFile only worked for zsh and its behavior was
// not consistent with Bash completion. It has therefore been disabled.
// Instead, when no other completion is specified, file completion is done by
// default for every argument. One can disable file completion on a per-argument
// basis by using ValidArgsFunction and ShellCompDirectiveNoFileComp.
// To achieve file extension filtering, one can use ValidArgsFunction and
// ShellCompDirectiveFilterFileExt.
//
// Deprecated
func (c *Command) MarkZshCompPositionalArgumentFile(argPosition int, patterns ...string) error {
return nil
}
// MarkZshCompPositionalArgumentWords only worked for zsh. It has therefore
// been disabled.
// To achieve the same behavior across all shells, one can use
// ValidArgs (for the first argument only) or ValidArgsFunction for
// any argument (can include the first one also).
//
// Deprecated
func (c *Command) MarkZshCompPositionalArgumentWords(argPosition int, words ...string) error {
return nil
}
func (c *Command) genZshCompletionFile(filename string, includeDesc bool) error {
outFile, err := os.Create(filename)
if err != nil {
return err
}
defer outFile.Close()
return c.genZshCompletion(outFile, includeDesc)
}
func (c *Command) genZshCompletion(w io.Writer, includeDesc bool) error {
buf := new(bytes.Buffer)
genZshComp(buf, c.Name(), includeDesc)
_, err := buf.WriteTo(w)
return err
}
func genZshComp(buf io.StringWriter, name string, includeDesc bool) {
compCmd := ShellCompRequestCmd
if !includeDesc {
compCmd = ShellCompNoDescRequestCmd
}
WriteStringAndCheck(buf, fmt.Sprintf(`#compdef %[1]s
compdef _%[1]s %[1]s
# zsh completion for %-36[1]s -*- shell-script -*-
__%[1]s_debug()
{
local file="$BASH_COMP_DEBUG_FILE"
if [[ -n ${file} ]]; then
echo "$*" >> "${file}"
fi
}
_%[1]s()
{
local shellCompDirectiveError=%[3]d
local shellCompDirectiveNoSpace=%[4]d
local shellCompDirectiveNoFileComp=%[5]d
local shellCompDirectiveFilterFileExt=%[6]d
local shellCompDirectiveFilterDirs=%[7]d
local shellCompDirectiveKeepOrder=%[8]d
local lastParam lastChar flagPrefix requestComp out directive comp lastComp noSpace keepOrder
local -a completions
__%[1]s_debug "\n========= starting completion logic =========="
__%[1]s_debug "CURRENT: ${CURRENT}, words[*]: ${words[*]}"
# The user could have moved the cursor backwards on the command-line.
# We need to trigger completion from the $CURRENT location, so we need
# to truncate the command-line ($words) up to the $CURRENT location.
# (We cannot use $CURSOR as its value does not work when a command is an alias.)
words=("${=words[1,CURRENT]}")
__%[1]s_debug "Truncated words[*]: ${words[*]},"
lastParam=${words[-1]}
lastChar=${lastParam[-1]}
__%[1]s_debug "lastParam: ${lastParam}, lastChar: ${lastChar}"
# For zsh, when completing a flag with an = (e.g., %[1]s -n=<TAB>)
# completions must be prefixed with the flag
setopt local_options BASH_REMATCH
if [[ "${lastParam}" =~ '-.*=' ]]; then
# We are dealing with a flag with an =
flagPrefix="-P ${BASH_REMATCH}"
fi
# Prepare the command to obtain completions
requestComp="${words[1]} %[2]s ${words[2,-1]}"
if [ "${lastChar}" = "" ]; then
# If the last parameter is complete (there is a space following it)
# We add an extra empty parameter so we can indicate this to the go completion code.
__%[1]s_debug "Adding extra empty parameter"
requestComp="${requestComp} \"\""
fi
__%[1]s_debug "About to call: eval ${requestComp}"
# Use eval to handle any environment variables and such
out=$(eval ${requestComp} 2>/dev/null)
__%[1]s_debug "completion output: ${out}"
# Extract the directive integer following a : from the last line
local lastLine
while IFS='\n' read -r line; do
lastLine=${line}
done < <(printf "%%s\n" "${out[@]}")
__%[1]s_debug "last line: ${lastLine}"
if [ "${lastLine[1]}" = : ]; then
directive=${lastLine[2,-1]}
# Remove the directive including the : and the newline
local suffix
(( suffix=${#lastLine}+2))
out=${out[1,-$suffix]}
else
# There is no directive specified. Leave $out as is.
__%[1]s_debug "No directive found. Setting do default"
directive=0
fi
__%[1]s_debug "directive: ${directive}"
__%[1]s_debug "completions: ${out}"
__%[1]s_debug "flagPrefix: ${flagPrefix}"
if [ $((directive & shellCompDirectiveError)) -ne 0 ]; then
__%[1]s_debug "Completion received error. Ignoring completions."
return
fi
local activeHelpMarker="%[9]s"
local endIndex=${#activeHelpMarker}
local startIndex=$((${#activeHelpMarker}+1))
local hasActiveHelp=0
while IFS='\n' read -r comp; do
# Check if this is an activeHelp statement (i.e., prefixed with $activeHelpMarker)
if [ "${comp[1,$endIndex]}" = "$activeHelpMarker" ];then
__%[1]s_debug "ActiveHelp found: $comp"
comp="${comp[$startIndex,-1]}"
if [ -n "$comp" ]; then
compadd -x "${comp}"
__%[1]s_debug "ActiveHelp will need delimiter"
hasActiveHelp=1
fi
continue
fi
if [ -n "$comp" ]; then
# If requested, completions are returned with a description.
# The description is preceded by a TAB character.
# For zsh's _describe, we need to use a : instead of a TAB.
# We first need to escape any : as part of the completion itself.
comp=${comp//:/\\:}
local tab="$(printf '\t')"
comp=${comp//$tab/:}
__%[1]s_debug "Adding completion: ${comp}"
completions+=${comp}
lastComp=$comp
fi
done < <(printf "%%s\n" "${out[@]}")
# Add a delimiter after the activeHelp statements, but only if:
# - there are completions following the activeHelp statements, or
# - file completion will be performed (so there will be choices after the activeHelp)
if [ $hasActiveHelp -eq 1 ]; then
if [ ${#completions} -ne 0 ] || [ $((directive & shellCompDirectiveNoFileComp)) -eq 0 ]; then
__%[1]s_debug "Adding activeHelp delimiter"
compadd -x "--"
hasActiveHelp=0
fi
fi
if [ $((directive & shellCompDirectiveNoSpace)) -ne 0 ]; then
__%[1]s_debug "Activating nospace."
noSpace="-S ''"
fi
if [ $((directive & shellCompDirectiveKeepOrder)) -ne 0 ]; then
__%[1]s_debug "Activating keep order."
keepOrder="-V"
fi
if [ $((directive & shellCompDirectiveFilterFileExt)) -ne 0 ]; then
# File extension filtering
local filteringCmd
filteringCmd='_files'
for filter in ${completions[@]}; do
if [ ${filter[1]} != '*' ]; then
# zsh requires a glob pattern to do file filtering
filter="\*.$filter"
fi
filteringCmd+=" -g $filter"
done
filteringCmd+=" ${flagPrefix}"
__%[1]s_debug "File filtering command: $filteringCmd"
_arguments '*:filename:'"$filteringCmd"
elif [ $((directive & shellCompDirectiveFilterDirs)) -ne 0 ]; then
# File completion for directories only
local subdir
subdir="${completions[1]}"
if [ -n "$subdir" ]; then
__%[1]s_debug "Listing directories in $subdir"
pushd "${subdir}" >/dev/null 2>&1
else
__%[1]s_debug "Listing directories in ."
fi
local result
_arguments '*:dirname:_files -/'" ${flagPrefix}"
result=$?
if [ -n "$subdir" ]; then
popd >/dev/null 2>&1
fi
return $result
else
__%[1]s_debug "Calling _describe"
if eval _describe $keepOrder "completions" completions $flagPrefix $noSpace; then
__%[1]s_debug "_describe found some completions"
# Return the success of having called _describe
return 0
else
__%[1]s_debug "_describe did not find completions."
__%[1]s_debug "Checking if we should do file completion."
if [ $((directive & shellCompDirectiveNoFileComp)) -ne 0 ]; then
__%[1]s_debug "deactivating file completion"
# We must return an error code here to let zsh know that there were no
# completions found by _describe; this is what will trigger other
# matching algorithms to attempt to find completions.
# For example zsh can match letters in the middle of words.
return 1
else
# Perform file completion
__%[1]s_debug "Activating file completion"
# We must return the result of this command, so it must be the
# last command, or else we must store its result to return it.
_arguments '*:filename:_files'" ${flagPrefix}"
fi
fi
fi
}
# don't run the completion function when being source-ed or eval-ed
if [ "$funcstack[1]" = "_%[1]s" ]; then
_%[1]s
fi
`, name, compCmd,
ShellCompDirectiveError, ShellCompDirectiveNoSpace, ShellCompDirectiveNoFileComp,
ShellCompDirectiveFilterFileExt, ShellCompDirectiveFilterDirs, ShellCompDirectiveKeepOrder,
activeHelpMarker))
}

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.idea/*

22
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sudo: false
language: go
go:
- 1.9.x
- 1.10.x
- 1.11.x
- tip
matrix:
allow_failures:
- go: tip
install:
- go get golang.org/x/lint/golint
- export PATH=$GOPATH/bin:$PATH
- go install ./...
script:
- verify/all.sh -v
- go test ./...

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Copyright (c) 2012 Alex Ogier. All rights reserved.
Copyright (c) 2012 The Go Authors. All rights reserved.
Redistribution and use in source and binary forms, with or without
modification, are permitted provided that the following conditions are
met:
* Redistributions of source code must retain the above copyright
notice, this list of conditions and the following disclaimer.
* Redistributions in binary form must reproduce the above
copyright notice, this list of conditions and the following disclaimer
in the documentation and/or other materials provided with the
distribution.
* Neither the name of Google Inc. nor the names of its
contributors may be used to endorse or promote products derived from
this software without specific prior written permission.
THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

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[![Build Status](https://travis-ci.org/spf13/pflag.svg?branch=master)](https://travis-ci.org/spf13/pflag)
[![Go Report Card](https://goreportcard.com/badge/github.com/spf13/pflag)](https://goreportcard.com/report/github.com/spf13/pflag)
[![GoDoc](https://godoc.org/github.com/spf13/pflag?status.svg)](https://godoc.org/github.com/spf13/pflag)
## Description
pflag is a drop-in replacement for Go's flag package, implementing
POSIX/GNU-style --flags.
pflag is compatible with the [GNU extensions to the POSIX recommendations
for command-line options][1]. For a more precise description, see the
"Command-line flag syntax" section below.
[1]: http://www.gnu.org/software/libc/manual/html_node/Argument-Syntax.html
pflag is available under the same style of BSD license as the Go language,
which can be found in the LICENSE file.
## Installation
pflag is available using the standard `go get` command.
Install by running:
go get github.com/spf13/pflag
Run tests by running:
go test github.com/spf13/pflag
## Usage
pflag is a drop-in replacement of Go's native flag package. If you import
pflag under the name "flag" then all code should continue to function
with no changes.
``` go
import flag "github.com/spf13/pflag"
```
There is one exception to this: if you directly instantiate the Flag struct
there is one more field "Shorthand" that you will need to set.
Most code never instantiates this struct directly, and instead uses
functions such as String(), BoolVar(), and Var(), and is therefore
unaffected.
Define flags using flag.String(), Bool(), Int(), etc.
This declares an integer flag, -flagname, stored in the pointer ip, with type *int.
``` go
var ip *int = flag.Int("flagname", 1234, "help message for flagname")
```
If you like, you can bind the flag to a variable using the Var() functions.
``` go
var flagvar int
func init() {
flag.IntVar(&flagvar, "flagname", 1234, "help message for flagname")
}
```
Or you can create custom flags that satisfy the Value interface (with
pointer receivers) and couple them to flag parsing by
``` go
flag.Var(&flagVal, "name", "help message for flagname")
```
For such flags, the default value is just the initial value of the variable.
After all flags are defined, call
``` go
flag.Parse()
```
to parse the command line into the defined flags.
Flags may then be used directly. If you're using the flags themselves,
they are all pointers; if you bind to variables, they're values.
``` go
fmt.Println("ip has value ", *ip)
fmt.Println("flagvar has value ", flagvar)
```
There are helper functions available to get the value stored in a Flag if you have a FlagSet but find
it difficult to keep up with all of the pointers in your code.
If you have a pflag.FlagSet with a flag called 'flagname' of type int you
can use GetInt() to get the int value. But notice that 'flagname' must exist
and it must be an int. GetString("flagname") will fail.
``` go
i, err := flagset.GetInt("flagname")
```
After parsing, the arguments after the flag are available as the
slice flag.Args() or individually as flag.Arg(i).
The arguments are indexed from 0 through flag.NArg()-1.
The pflag package also defines some new functions that are not in flag,
that give one-letter shorthands for flags. You can use these by appending
'P' to the name of any function that defines a flag.
``` go
var ip = flag.IntP("flagname", "f", 1234, "help message")
var flagvar bool
func init() {
flag.BoolVarP(&flagvar, "boolname", "b", true, "help message")
}
flag.VarP(&flagVal, "varname", "v", "help message")
```
Shorthand letters can be used with single dashes on the command line.
Boolean shorthand flags can be combined with other shorthand flags.
The default set of command-line flags is controlled by
top-level functions. The FlagSet type allows one to define
independent sets of flags, such as to implement subcommands
in a command-line interface. The methods of FlagSet are
analogous to the top-level functions for the command-line
flag set.
## Setting no option default values for flags
After you create a flag it is possible to set the pflag.NoOptDefVal for
the given flag. Doing this changes the meaning of the flag slightly. If
a flag has a NoOptDefVal and the flag is set on the command line without
an option the flag will be set to the NoOptDefVal. For example given:
``` go
var ip = flag.IntP("flagname", "f", 1234, "help message")
flag.Lookup("flagname").NoOptDefVal = "4321"
```
Would result in something like
| Parsed Arguments | Resulting Value |
| ------------- | ------------- |
| --flagname=1357 | ip=1357 |
| --flagname | ip=4321 |
| [nothing] | ip=1234 |
## Command line flag syntax
```
--flag // boolean flags, or flags with no option default values
--flag x // only on flags without a default value
--flag=x
```
Unlike the flag package, a single dash before an option means something
different than a double dash. Single dashes signify a series of shorthand
letters for flags. All but the last shorthand letter must be boolean flags
or a flag with a default value
```
// boolean or flags where the 'no option default value' is set
-f
-f=true
-abc
but
-b true is INVALID
// non-boolean and flags without a 'no option default value'
-n 1234
-n=1234
-n1234
// mixed
-abcs "hello"
-absd="hello"
-abcs1234
```
Flag parsing stops after the terminator "--". Unlike the flag package,
flags can be interspersed with arguments anywhere on the command line
before this terminator.
Integer flags accept 1234, 0664, 0x1234 and may be negative.
Boolean flags (in their long form) accept 1, 0, t, f, true, false,
TRUE, FALSE, True, False.
Duration flags accept any input valid for time.ParseDuration.
## Mutating or "Normalizing" Flag names
It is possible to set a custom flag name 'normalization function.' It allows flag names to be mutated both when created in the code and when used on the command line to some 'normalized' form. The 'normalized' form is used for comparison. Two examples of using the custom normalization func follow.
**Example #1**: You want -, _, and . in flags to compare the same. aka --my-flag == --my_flag == --my.flag
``` go
func wordSepNormalizeFunc(f *pflag.FlagSet, name string) pflag.NormalizedName {
from := []string{"-", "_"}
to := "."
for _, sep := range from {
name = strings.Replace(name, sep, to, -1)
}
return pflag.NormalizedName(name)
}
myFlagSet.SetNormalizeFunc(wordSepNormalizeFunc)
```
**Example #2**: You want to alias two flags. aka --old-flag-name == --new-flag-name
``` go
func aliasNormalizeFunc(f *pflag.FlagSet, name string) pflag.NormalizedName {
switch name {
case "old-flag-name":
name = "new-flag-name"
break
}
return pflag.NormalizedName(name)
}
myFlagSet.SetNormalizeFunc(aliasNormalizeFunc)
```
## Deprecating a flag or its shorthand
It is possible to deprecate a flag, or just its shorthand. Deprecating a flag/shorthand hides it from help text and prints a usage message when the deprecated flag/shorthand is used.
**Example #1**: You want to deprecate a flag named "badflag" as well as inform the users what flag they should use instead.
```go
// deprecate a flag by specifying its name and a usage message
flags.MarkDeprecated("badflag", "please use --good-flag instead")
```
This hides "badflag" from help text, and prints `Flag --badflag has been deprecated, please use --good-flag instead` when "badflag" is used.
**Example #2**: You want to keep a flag name "noshorthandflag" but deprecate its shortname "n".
```go
// deprecate a flag shorthand by specifying its flag name and a usage message
flags.MarkShorthandDeprecated("noshorthandflag", "please use --noshorthandflag only")
```
This hides the shortname "n" from help text, and prints `Flag shorthand -n has been deprecated, please use --noshorthandflag only` when the shorthand "n" is used.
Note that usage message is essential here, and it should not be empty.
## Hidden flags
It is possible to mark a flag as hidden, meaning it will still function as normal, however will not show up in usage/help text.
**Example**: You have a flag named "secretFlag" that you need for internal use only and don't want it showing up in help text, or for its usage text to be available.
```go
// hide a flag by specifying its name
flags.MarkHidden("secretFlag")
```
## Disable sorting of flags
`pflag` allows you to disable sorting of flags for help and usage message.
**Example**:
```go
flags.BoolP("verbose", "v", false, "verbose output")
flags.String("coolflag", "yeaah", "it's really cool flag")
flags.Int("usefulflag", 777, "sometimes it's very useful")
flags.SortFlags = false
flags.PrintDefaults()
```
**Output**:
```
-v, --verbose verbose output
--coolflag string it's really cool flag (default "yeaah")
--usefulflag int sometimes it's very useful (default 777)
```
## Supporting Go flags when using pflag
In order to support flags defined using Go's `flag` package, they must be added to the `pflag` flagset. This is usually necessary
to support flags defined by third-party dependencies (e.g. `golang/glog`).
**Example**: You want to add the Go flags to the `CommandLine` flagset
```go
import (
goflag "flag"
flag "github.com/spf13/pflag"
)
var ip *int = flag.Int("flagname", 1234, "help message for flagname")
func main() {
flag.CommandLine.AddGoFlagSet(goflag.CommandLine)
flag.Parse()
}
```
## More info
You can see the full reference documentation of the pflag package
[at godoc.org][3], or through go's standard documentation system by
running `godoc -http=:6060` and browsing to
[http://localhost:6060/pkg/github.com/spf13/pflag][2] after
installation.
[2]: http://localhost:6060/pkg/github.com/spf13/pflag
[3]: http://godoc.org/github.com/spf13/pflag

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package pflag
import "strconv"
// optional interface to indicate boolean flags that can be
// supplied without "=value" text
type boolFlag interface {
Value
IsBoolFlag() bool
}
// -- bool Value
type boolValue bool
func newBoolValue(val bool, p *bool) *boolValue {
*p = val
return (*boolValue)(p)
}
func (b *boolValue) Set(s string) error {
v, err := strconv.ParseBool(s)
*b = boolValue(v)
return err
}
func (b *boolValue) Type() string {
return "bool"
}
func (b *boolValue) String() string { return strconv.FormatBool(bool(*b)) }
func (b *boolValue) IsBoolFlag() bool { return true }
func boolConv(sval string) (interface{}, error) {
return strconv.ParseBool(sval)
}
// GetBool return the bool value of a flag with the given name
func (f *FlagSet) GetBool(name string) (bool, error) {
val, err := f.getFlagType(name, "bool", boolConv)
if err != nil {
return false, err
}
return val.(bool), nil
}
// BoolVar defines a bool flag with specified name, default value, and usage string.
// The argument p points to a bool variable in which to store the value of the flag.
func (f *FlagSet) BoolVar(p *bool, name string, value bool, usage string) {
f.BoolVarP(p, name, "", value, usage)
}
// BoolVarP is like BoolVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BoolVarP(p *bool, name, shorthand string, value bool, usage string) {
flag := f.VarPF(newBoolValue(value, p), name, shorthand, usage)
flag.NoOptDefVal = "true"
}
// BoolVar defines a bool flag with specified name, default value, and usage string.
// The argument p points to a bool variable in which to store the value of the flag.
func BoolVar(p *bool, name string, value bool, usage string) {
BoolVarP(p, name, "", value, usage)
}
// BoolVarP is like BoolVar, but accepts a shorthand letter that can be used after a single dash.
func BoolVarP(p *bool, name, shorthand string, value bool, usage string) {
flag := CommandLine.VarPF(newBoolValue(value, p), name, shorthand, usage)
flag.NoOptDefVal = "true"
}
// Bool defines a bool flag with specified name, default value, and usage string.
// The return value is the address of a bool variable that stores the value of the flag.
func (f *FlagSet) Bool(name string, value bool, usage string) *bool {
return f.BoolP(name, "", value, usage)
}
// BoolP is like Bool, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BoolP(name, shorthand string, value bool, usage string) *bool {
p := new(bool)
f.BoolVarP(p, name, shorthand, value, usage)
return p
}
// Bool defines a bool flag with specified name, default value, and usage string.
// The return value is the address of a bool variable that stores the value of the flag.
func Bool(name string, value bool, usage string) *bool {
return BoolP(name, "", value, usage)
}
// BoolP is like Bool, but accepts a shorthand letter that can be used after a single dash.
func BoolP(name, shorthand string, value bool, usage string) *bool {
b := CommandLine.BoolP(name, shorthand, value, usage)
return b
}

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package pflag
import (
"io"
"strconv"
"strings"
)
// -- boolSlice Value
type boolSliceValue struct {
value *[]bool
changed bool
}
func newBoolSliceValue(val []bool, p *[]bool) *boolSliceValue {
bsv := new(boolSliceValue)
bsv.value = p
*bsv.value = val
return bsv
}
// Set converts, and assigns, the comma-separated boolean argument string representation as the []bool value of this flag.
// If Set is called on a flag that already has a []bool assigned, the newly converted values will be appended.
func (s *boolSliceValue) Set(val string) error {
// remove all quote characters
rmQuote := strings.NewReplacer(`"`, "", `'`, "", "`", "")
// read flag arguments with CSV parser
boolStrSlice, err := readAsCSV(rmQuote.Replace(val))
if err != nil && err != io.EOF {
return err
}
// parse boolean values into slice
out := make([]bool, 0, len(boolStrSlice))
for _, boolStr := range boolStrSlice {
b, err := strconv.ParseBool(strings.TrimSpace(boolStr))
if err != nil {
return err
}
out = append(out, b)
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
// Type returns a string that uniquely represents this flag's type.
func (s *boolSliceValue) Type() string {
return "boolSlice"
}
// String defines a "native" format for this boolean slice flag value.
func (s *boolSliceValue) String() string {
boolStrSlice := make([]string, len(*s.value))
for i, b := range *s.value {
boolStrSlice[i] = strconv.FormatBool(b)
}
out, _ := writeAsCSV(boolStrSlice)
return "[" + out + "]"
}
func (s *boolSliceValue) fromString(val string) (bool, error) {
return strconv.ParseBool(val)
}
func (s *boolSliceValue) toString(val bool) string {
return strconv.FormatBool(val)
}
func (s *boolSliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *boolSliceValue) Replace(val []string) error {
out := make([]bool, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *boolSliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func boolSliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []bool{}, nil
}
ss := strings.Split(val, ",")
out := make([]bool, len(ss))
for i, t := range ss {
var err error
out[i], err = strconv.ParseBool(t)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetBoolSlice returns the []bool value of a flag with the given name.
func (f *FlagSet) GetBoolSlice(name string) ([]bool, error) {
val, err := f.getFlagType(name, "boolSlice", boolSliceConv)
if err != nil {
return []bool{}, err
}
return val.([]bool), nil
}
// BoolSliceVar defines a boolSlice flag with specified name, default value, and usage string.
// The argument p points to a []bool variable in which to store the value of the flag.
func (f *FlagSet) BoolSliceVar(p *[]bool, name string, value []bool, usage string) {
f.VarP(newBoolSliceValue(value, p), name, "", usage)
}
// BoolSliceVarP is like BoolSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BoolSliceVarP(p *[]bool, name, shorthand string, value []bool, usage string) {
f.VarP(newBoolSliceValue(value, p), name, shorthand, usage)
}
// BoolSliceVar defines a []bool flag with specified name, default value, and usage string.
// The argument p points to a []bool variable in which to store the value of the flag.
func BoolSliceVar(p *[]bool, name string, value []bool, usage string) {
CommandLine.VarP(newBoolSliceValue(value, p), name, "", usage)
}
// BoolSliceVarP is like BoolSliceVar, but accepts a shorthand letter that can be used after a single dash.
func BoolSliceVarP(p *[]bool, name, shorthand string, value []bool, usage string) {
CommandLine.VarP(newBoolSliceValue(value, p), name, shorthand, usage)
}
// BoolSlice defines a []bool flag with specified name, default value, and usage string.
// The return value is the address of a []bool variable that stores the value of the flag.
func (f *FlagSet) BoolSlice(name string, value []bool, usage string) *[]bool {
p := []bool{}
f.BoolSliceVarP(&p, name, "", value, usage)
return &p
}
// BoolSliceP is like BoolSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BoolSliceP(name, shorthand string, value []bool, usage string) *[]bool {
p := []bool{}
f.BoolSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// BoolSlice defines a []bool flag with specified name, default value, and usage string.
// The return value is the address of a []bool variable that stores the value of the flag.
func BoolSlice(name string, value []bool, usage string) *[]bool {
return CommandLine.BoolSliceP(name, "", value, usage)
}
// BoolSliceP is like BoolSlice, but accepts a shorthand letter that can be used after a single dash.
func BoolSliceP(name, shorthand string, value []bool, usage string) *[]bool {
return CommandLine.BoolSliceP(name, shorthand, value, usage)
}

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package pflag
import (
"encoding/base64"
"encoding/hex"
"fmt"
"strings"
)
// BytesHex adapts []byte for use as a flag. Value of flag is HEX encoded
type bytesHexValue []byte
// String implements pflag.Value.String.
func (bytesHex bytesHexValue) String() string {
return fmt.Sprintf("%X", []byte(bytesHex))
}
// Set implements pflag.Value.Set.
func (bytesHex *bytesHexValue) Set(value string) error {
bin, err := hex.DecodeString(strings.TrimSpace(value))
if err != nil {
return err
}
*bytesHex = bin
return nil
}
// Type implements pflag.Value.Type.
func (*bytesHexValue) Type() string {
return "bytesHex"
}
func newBytesHexValue(val []byte, p *[]byte) *bytesHexValue {
*p = val
return (*bytesHexValue)(p)
}
func bytesHexConv(sval string) (interface{}, error) {
bin, err := hex.DecodeString(sval)
if err == nil {
return bin, nil
}
return nil, fmt.Errorf("invalid string being converted to Bytes: %s %s", sval, err)
}
// GetBytesHex return the []byte value of a flag with the given name
func (f *FlagSet) GetBytesHex(name string) ([]byte, error) {
val, err := f.getFlagType(name, "bytesHex", bytesHexConv)
if err != nil {
return []byte{}, err
}
return val.([]byte), nil
}
// BytesHexVar defines an []byte flag with specified name, default value, and usage string.
// The argument p points to an []byte variable in which to store the value of the flag.
func (f *FlagSet) BytesHexVar(p *[]byte, name string, value []byte, usage string) {
f.VarP(newBytesHexValue(value, p), name, "", usage)
}
// BytesHexVarP is like BytesHexVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BytesHexVarP(p *[]byte, name, shorthand string, value []byte, usage string) {
f.VarP(newBytesHexValue(value, p), name, shorthand, usage)
}
// BytesHexVar defines an []byte flag with specified name, default value, and usage string.
// The argument p points to an []byte variable in which to store the value of the flag.
func BytesHexVar(p *[]byte, name string, value []byte, usage string) {
CommandLine.VarP(newBytesHexValue(value, p), name, "", usage)
}
// BytesHexVarP is like BytesHexVar, but accepts a shorthand letter that can be used after a single dash.
func BytesHexVarP(p *[]byte, name, shorthand string, value []byte, usage string) {
CommandLine.VarP(newBytesHexValue(value, p), name, shorthand, usage)
}
// BytesHex defines an []byte flag with specified name, default value, and usage string.
// The return value is the address of an []byte variable that stores the value of the flag.
func (f *FlagSet) BytesHex(name string, value []byte, usage string) *[]byte {
p := new([]byte)
f.BytesHexVarP(p, name, "", value, usage)
return p
}
// BytesHexP is like BytesHex, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BytesHexP(name, shorthand string, value []byte, usage string) *[]byte {
p := new([]byte)
f.BytesHexVarP(p, name, shorthand, value, usage)
return p
}
// BytesHex defines an []byte flag with specified name, default value, and usage string.
// The return value is the address of an []byte variable that stores the value of the flag.
func BytesHex(name string, value []byte, usage string) *[]byte {
return CommandLine.BytesHexP(name, "", value, usage)
}
// BytesHexP is like BytesHex, but accepts a shorthand letter that can be used after a single dash.
func BytesHexP(name, shorthand string, value []byte, usage string) *[]byte {
return CommandLine.BytesHexP(name, shorthand, value, usage)
}
// BytesBase64 adapts []byte for use as a flag. Value of flag is Base64 encoded
type bytesBase64Value []byte
// String implements pflag.Value.String.
func (bytesBase64 bytesBase64Value) String() string {
return base64.StdEncoding.EncodeToString([]byte(bytesBase64))
}
// Set implements pflag.Value.Set.
func (bytesBase64 *bytesBase64Value) Set(value string) error {
bin, err := base64.StdEncoding.DecodeString(strings.TrimSpace(value))
if err != nil {
return err
}
*bytesBase64 = bin
return nil
}
// Type implements pflag.Value.Type.
func (*bytesBase64Value) Type() string {
return "bytesBase64"
}
func newBytesBase64Value(val []byte, p *[]byte) *bytesBase64Value {
*p = val
return (*bytesBase64Value)(p)
}
func bytesBase64ValueConv(sval string) (interface{}, error) {
bin, err := base64.StdEncoding.DecodeString(sval)
if err == nil {
return bin, nil
}
return nil, fmt.Errorf("invalid string being converted to Bytes: %s %s", sval, err)
}
// GetBytesBase64 return the []byte value of a flag with the given name
func (f *FlagSet) GetBytesBase64(name string) ([]byte, error) {
val, err := f.getFlagType(name, "bytesBase64", bytesBase64ValueConv)
if err != nil {
return []byte{}, err
}
return val.([]byte), nil
}
// BytesBase64Var defines an []byte flag with specified name, default value, and usage string.
// The argument p points to an []byte variable in which to store the value of the flag.
func (f *FlagSet) BytesBase64Var(p *[]byte, name string, value []byte, usage string) {
f.VarP(newBytesBase64Value(value, p), name, "", usage)
}
// BytesBase64VarP is like BytesBase64Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BytesBase64VarP(p *[]byte, name, shorthand string, value []byte, usage string) {
f.VarP(newBytesBase64Value(value, p), name, shorthand, usage)
}
// BytesBase64Var defines an []byte flag with specified name, default value, and usage string.
// The argument p points to an []byte variable in which to store the value of the flag.
func BytesBase64Var(p *[]byte, name string, value []byte, usage string) {
CommandLine.VarP(newBytesBase64Value(value, p), name, "", usage)
}
// BytesBase64VarP is like BytesBase64Var, but accepts a shorthand letter that can be used after a single dash.
func BytesBase64VarP(p *[]byte, name, shorthand string, value []byte, usage string) {
CommandLine.VarP(newBytesBase64Value(value, p), name, shorthand, usage)
}
// BytesBase64 defines an []byte flag with specified name, default value, and usage string.
// The return value is the address of an []byte variable that stores the value of the flag.
func (f *FlagSet) BytesBase64(name string, value []byte, usage string) *[]byte {
p := new([]byte)
f.BytesBase64VarP(p, name, "", value, usage)
return p
}
// BytesBase64P is like BytesBase64, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) BytesBase64P(name, shorthand string, value []byte, usage string) *[]byte {
p := new([]byte)
f.BytesBase64VarP(p, name, shorthand, value, usage)
return p
}
// BytesBase64 defines an []byte flag with specified name, default value, and usage string.
// The return value is the address of an []byte variable that stores the value of the flag.
func BytesBase64(name string, value []byte, usage string) *[]byte {
return CommandLine.BytesBase64P(name, "", value, usage)
}
// BytesBase64P is like BytesBase64, but accepts a shorthand letter that can be used after a single dash.
func BytesBase64P(name, shorthand string, value []byte, usage string) *[]byte {
return CommandLine.BytesBase64P(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- count Value
type countValue int
func newCountValue(val int, p *int) *countValue {
*p = val
return (*countValue)(p)
}
func (i *countValue) Set(s string) error {
// "+1" means that no specific value was passed, so increment
if s == "+1" {
*i = countValue(*i + 1)
return nil
}
v, err := strconv.ParseInt(s, 0, 0)
*i = countValue(v)
return err
}
func (i *countValue) Type() string {
return "count"
}
func (i *countValue) String() string { return strconv.Itoa(int(*i)) }
func countConv(sval string) (interface{}, error) {
i, err := strconv.Atoi(sval)
if err != nil {
return nil, err
}
return i, nil
}
// GetCount return the int value of a flag with the given name
func (f *FlagSet) GetCount(name string) (int, error) {
val, err := f.getFlagType(name, "count", countConv)
if err != nil {
return 0, err
}
return val.(int), nil
}
// CountVar defines a count flag with specified name, default value, and usage string.
// The argument p points to an int variable in which to store the value of the flag.
// A count flag will add 1 to its value every time it is found on the command line
func (f *FlagSet) CountVar(p *int, name string, usage string) {
f.CountVarP(p, name, "", usage)
}
// CountVarP is like CountVar only take a shorthand for the flag name.
func (f *FlagSet) CountVarP(p *int, name, shorthand string, usage string) {
flag := f.VarPF(newCountValue(0, p), name, shorthand, usage)
flag.NoOptDefVal = "+1"
}
// CountVar like CountVar only the flag is placed on the CommandLine instead of a given flag set
func CountVar(p *int, name string, usage string) {
CommandLine.CountVar(p, name, usage)
}
// CountVarP is like CountVar only take a shorthand for the flag name.
func CountVarP(p *int, name, shorthand string, usage string) {
CommandLine.CountVarP(p, name, shorthand, usage)
}
// Count defines a count flag with specified name, default value, and usage string.
// The return value is the address of an int variable that stores the value of the flag.
// A count flag will add 1 to its value every time it is found on the command line
func (f *FlagSet) Count(name string, usage string) *int {
p := new(int)
f.CountVarP(p, name, "", usage)
return p
}
// CountP is like Count only takes a shorthand for the flag name.
func (f *FlagSet) CountP(name, shorthand string, usage string) *int {
p := new(int)
f.CountVarP(p, name, shorthand, usage)
return p
}
// Count defines a count flag with specified name, default value, and usage string.
// The return value is the address of an int variable that stores the value of the flag.
// A count flag will add 1 to its value evey time it is found on the command line
func Count(name string, usage string) *int {
return CommandLine.CountP(name, "", usage)
}
// CountP is like Count only takes a shorthand for the flag name.
func CountP(name, shorthand string, usage string) *int {
return CommandLine.CountP(name, shorthand, usage)
}

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package pflag
import (
"time"
)
// -- time.Duration Value
type durationValue time.Duration
func newDurationValue(val time.Duration, p *time.Duration) *durationValue {
*p = val
return (*durationValue)(p)
}
func (d *durationValue) Set(s string) error {
v, err := time.ParseDuration(s)
*d = durationValue(v)
return err
}
func (d *durationValue) Type() string {
return "duration"
}
func (d *durationValue) String() string { return (*time.Duration)(d).String() }
func durationConv(sval string) (interface{}, error) {
return time.ParseDuration(sval)
}
// GetDuration return the duration value of a flag with the given name
func (f *FlagSet) GetDuration(name string) (time.Duration, error) {
val, err := f.getFlagType(name, "duration", durationConv)
if err != nil {
return 0, err
}
return val.(time.Duration), nil
}
// DurationVar defines a time.Duration flag with specified name, default value, and usage string.
// The argument p points to a time.Duration variable in which to store the value of the flag.
func (f *FlagSet) DurationVar(p *time.Duration, name string, value time.Duration, usage string) {
f.VarP(newDurationValue(value, p), name, "", usage)
}
// DurationVarP is like DurationVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) DurationVarP(p *time.Duration, name, shorthand string, value time.Duration, usage string) {
f.VarP(newDurationValue(value, p), name, shorthand, usage)
}
// DurationVar defines a time.Duration flag with specified name, default value, and usage string.
// The argument p points to a time.Duration variable in which to store the value of the flag.
func DurationVar(p *time.Duration, name string, value time.Duration, usage string) {
CommandLine.VarP(newDurationValue(value, p), name, "", usage)
}
// DurationVarP is like DurationVar, but accepts a shorthand letter that can be used after a single dash.
func DurationVarP(p *time.Duration, name, shorthand string, value time.Duration, usage string) {
CommandLine.VarP(newDurationValue(value, p), name, shorthand, usage)
}
// Duration defines a time.Duration flag with specified name, default value, and usage string.
// The return value is the address of a time.Duration variable that stores the value of the flag.
func (f *FlagSet) Duration(name string, value time.Duration, usage string) *time.Duration {
p := new(time.Duration)
f.DurationVarP(p, name, "", value, usage)
return p
}
// DurationP is like Duration, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) DurationP(name, shorthand string, value time.Duration, usage string) *time.Duration {
p := new(time.Duration)
f.DurationVarP(p, name, shorthand, value, usage)
return p
}
// Duration defines a time.Duration flag with specified name, default value, and usage string.
// The return value is the address of a time.Duration variable that stores the value of the flag.
func Duration(name string, value time.Duration, usage string) *time.Duration {
return CommandLine.DurationP(name, "", value, usage)
}
// DurationP is like Duration, but accepts a shorthand letter that can be used after a single dash.
func DurationP(name, shorthand string, value time.Duration, usage string) *time.Duration {
return CommandLine.DurationP(name, shorthand, value, usage)
}

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package pflag
import (
"fmt"
"strings"
"time"
)
// -- durationSlice Value
type durationSliceValue struct {
value *[]time.Duration
changed bool
}
func newDurationSliceValue(val []time.Duration, p *[]time.Duration) *durationSliceValue {
dsv := new(durationSliceValue)
dsv.value = p
*dsv.value = val
return dsv
}
func (s *durationSliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]time.Duration, len(ss))
for i, d := range ss {
var err error
out[i], err = time.ParseDuration(d)
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *durationSliceValue) Type() string {
return "durationSlice"
}
func (s *durationSliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%s", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *durationSliceValue) fromString(val string) (time.Duration, error) {
return time.ParseDuration(val)
}
func (s *durationSliceValue) toString(val time.Duration) string {
return fmt.Sprintf("%s", val)
}
func (s *durationSliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *durationSliceValue) Replace(val []string) error {
out := make([]time.Duration, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *durationSliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func durationSliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []time.Duration{}, nil
}
ss := strings.Split(val, ",")
out := make([]time.Duration, len(ss))
for i, d := range ss {
var err error
out[i], err = time.ParseDuration(d)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetDurationSlice returns the []time.Duration value of a flag with the given name
func (f *FlagSet) GetDurationSlice(name string) ([]time.Duration, error) {
val, err := f.getFlagType(name, "durationSlice", durationSliceConv)
if err != nil {
return []time.Duration{}, err
}
return val.([]time.Duration), nil
}
// DurationSliceVar defines a durationSlice flag with specified name, default value, and usage string.
// The argument p points to a []time.Duration variable in which to store the value of the flag.
func (f *FlagSet) DurationSliceVar(p *[]time.Duration, name string, value []time.Duration, usage string) {
f.VarP(newDurationSliceValue(value, p), name, "", usage)
}
// DurationSliceVarP is like DurationSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) DurationSliceVarP(p *[]time.Duration, name, shorthand string, value []time.Duration, usage string) {
f.VarP(newDurationSliceValue(value, p), name, shorthand, usage)
}
// DurationSliceVar defines a duration[] flag with specified name, default value, and usage string.
// The argument p points to a duration[] variable in which to store the value of the flag.
func DurationSliceVar(p *[]time.Duration, name string, value []time.Duration, usage string) {
CommandLine.VarP(newDurationSliceValue(value, p), name, "", usage)
}
// DurationSliceVarP is like DurationSliceVar, but accepts a shorthand letter that can be used after a single dash.
func DurationSliceVarP(p *[]time.Duration, name, shorthand string, value []time.Duration, usage string) {
CommandLine.VarP(newDurationSliceValue(value, p), name, shorthand, usage)
}
// DurationSlice defines a []time.Duration flag with specified name, default value, and usage string.
// The return value is the address of a []time.Duration variable that stores the value of the flag.
func (f *FlagSet) DurationSlice(name string, value []time.Duration, usage string) *[]time.Duration {
p := []time.Duration{}
f.DurationSliceVarP(&p, name, "", value, usage)
return &p
}
// DurationSliceP is like DurationSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) DurationSliceP(name, shorthand string, value []time.Duration, usage string) *[]time.Duration {
p := []time.Duration{}
f.DurationSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// DurationSlice defines a []time.Duration flag with specified name, default value, and usage string.
// The return value is the address of a []time.Duration variable that stores the value of the flag.
func DurationSlice(name string, value []time.Duration, usage string) *[]time.Duration {
return CommandLine.DurationSliceP(name, "", value, usage)
}
// DurationSliceP is like DurationSlice, but accepts a shorthand letter that can be used after a single dash.
func DurationSliceP(name, shorthand string, value []time.Duration, usage string) *[]time.Duration {
return CommandLine.DurationSliceP(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- float32 Value
type float32Value float32
func newFloat32Value(val float32, p *float32) *float32Value {
*p = val
return (*float32Value)(p)
}
func (f *float32Value) Set(s string) error {
v, err := strconv.ParseFloat(s, 32)
*f = float32Value(v)
return err
}
func (f *float32Value) Type() string {
return "float32"
}
func (f *float32Value) String() string { return strconv.FormatFloat(float64(*f), 'g', -1, 32) }
func float32Conv(sval string) (interface{}, error) {
v, err := strconv.ParseFloat(sval, 32)
if err != nil {
return 0, err
}
return float32(v), nil
}
// GetFloat32 return the float32 value of a flag with the given name
func (f *FlagSet) GetFloat32(name string) (float32, error) {
val, err := f.getFlagType(name, "float32", float32Conv)
if err != nil {
return 0, err
}
return val.(float32), nil
}
// Float32Var defines a float32 flag with specified name, default value, and usage string.
// The argument p points to a float32 variable in which to store the value of the flag.
func (f *FlagSet) Float32Var(p *float32, name string, value float32, usage string) {
f.VarP(newFloat32Value(value, p), name, "", usage)
}
// Float32VarP is like Float32Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float32VarP(p *float32, name, shorthand string, value float32, usage string) {
f.VarP(newFloat32Value(value, p), name, shorthand, usage)
}
// Float32Var defines a float32 flag with specified name, default value, and usage string.
// The argument p points to a float32 variable in which to store the value of the flag.
func Float32Var(p *float32, name string, value float32, usage string) {
CommandLine.VarP(newFloat32Value(value, p), name, "", usage)
}
// Float32VarP is like Float32Var, but accepts a shorthand letter that can be used after a single dash.
func Float32VarP(p *float32, name, shorthand string, value float32, usage string) {
CommandLine.VarP(newFloat32Value(value, p), name, shorthand, usage)
}
// Float32 defines a float32 flag with specified name, default value, and usage string.
// The return value is the address of a float32 variable that stores the value of the flag.
func (f *FlagSet) Float32(name string, value float32, usage string) *float32 {
p := new(float32)
f.Float32VarP(p, name, "", value, usage)
return p
}
// Float32P is like Float32, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float32P(name, shorthand string, value float32, usage string) *float32 {
p := new(float32)
f.Float32VarP(p, name, shorthand, value, usage)
return p
}
// Float32 defines a float32 flag with specified name, default value, and usage string.
// The return value is the address of a float32 variable that stores the value of the flag.
func Float32(name string, value float32, usage string) *float32 {
return CommandLine.Float32P(name, "", value, usage)
}
// Float32P is like Float32, but accepts a shorthand letter that can be used after a single dash.
func Float32P(name, shorthand string, value float32, usage string) *float32 {
return CommandLine.Float32P(name, shorthand, value, usage)
}

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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- float32Slice Value
type float32SliceValue struct {
value *[]float32
changed bool
}
func newFloat32SliceValue(val []float32, p *[]float32) *float32SliceValue {
isv := new(float32SliceValue)
isv.value = p
*isv.value = val
return isv
}
func (s *float32SliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]float32, len(ss))
for i, d := range ss {
var err error
var temp64 float64
temp64, err = strconv.ParseFloat(d, 32)
if err != nil {
return err
}
out[i] = float32(temp64)
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *float32SliceValue) Type() string {
return "float32Slice"
}
func (s *float32SliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%f", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *float32SliceValue) fromString(val string) (float32, error) {
t64, err := strconv.ParseFloat(val, 32)
if err != nil {
return 0, err
}
return float32(t64), nil
}
func (s *float32SliceValue) toString(val float32) string {
return fmt.Sprintf("%f", val)
}
func (s *float32SliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *float32SliceValue) Replace(val []string) error {
out := make([]float32, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *float32SliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func float32SliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []float32{}, nil
}
ss := strings.Split(val, ",")
out := make([]float32, len(ss))
for i, d := range ss {
var err error
var temp64 float64
temp64, err = strconv.ParseFloat(d, 32)
if err != nil {
return nil, err
}
out[i] = float32(temp64)
}
return out, nil
}
// GetFloat32Slice return the []float32 value of a flag with the given name
func (f *FlagSet) GetFloat32Slice(name string) ([]float32, error) {
val, err := f.getFlagType(name, "float32Slice", float32SliceConv)
if err != nil {
return []float32{}, err
}
return val.([]float32), nil
}
// Float32SliceVar defines a float32Slice flag with specified name, default value, and usage string.
// The argument p points to a []float32 variable in which to store the value of the flag.
func (f *FlagSet) Float32SliceVar(p *[]float32, name string, value []float32, usage string) {
f.VarP(newFloat32SliceValue(value, p), name, "", usage)
}
// Float32SliceVarP is like Float32SliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float32SliceVarP(p *[]float32, name, shorthand string, value []float32, usage string) {
f.VarP(newFloat32SliceValue(value, p), name, shorthand, usage)
}
// Float32SliceVar defines a float32[] flag with specified name, default value, and usage string.
// The argument p points to a float32[] variable in which to store the value of the flag.
func Float32SliceVar(p *[]float32, name string, value []float32, usage string) {
CommandLine.VarP(newFloat32SliceValue(value, p), name, "", usage)
}
// Float32SliceVarP is like Float32SliceVar, but accepts a shorthand letter that can be used after a single dash.
func Float32SliceVarP(p *[]float32, name, shorthand string, value []float32, usage string) {
CommandLine.VarP(newFloat32SliceValue(value, p), name, shorthand, usage)
}
// Float32Slice defines a []float32 flag with specified name, default value, and usage string.
// The return value is the address of a []float32 variable that stores the value of the flag.
func (f *FlagSet) Float32Slice(name string, value []float32, usage string) *[]float32 {
p := []float32{}
f.Float32SliceVarP(&p, name, "", value, usage)
return &p
}
// Float32SliceP is like Float32Slice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float32SliceP(name, shorthand string, value []float32, usage string) *[]float32 {
p := []float32{}
f.Float32SliceVarP(&p, name, shorthand, value, usage)
return &p
}
// Float32Slice defines a []float32 flag with specified name, default value, and usage string.
// The return value is the address of a []float32 variable that stores the value of the flag.
func Float32Slice(name string, value []float32, usage string) *[]float32 {
return CommandLine.Float32SliceP(name, "", value, usage)
}
// Float32SliceP is like Float32Slice, but accepts a shorthand letter that can be used after a single dash.
func Float32SliceP(name, shorthand string, value []float32, usage string) *[]float32 {
return CommandLine.Float32SliceP(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- float64 Value
type float64Value float64
func newFloat64Value(val float64, p *float64) *float64Value {
*p = val
return (*float64Value)(p)
}
func (f *float64Value) Set(s string) error {
v, err := strconv.ParseFloat(s, 64)
*f = float64Value(v)
return err
}
func (f *float64Value) Type() string {
return "float64"
}
func (f *float64Value) String() string { return strconv.FormatFloat(float64(*f), 'g', -1, 64) }
func float64Conv(sval string) (interface{}, error) {
return strconv.ParseFloat(sval, 64)
}
// GetFloat64 return the float64 value of a flag with the given name
func (f *FlagSet) GetFloat64(name string) (float64, error) {
val, err := f.getFlagType(name, "float64", float64Conv)
if err != nil {
return 0, err
}
return val.(float64), nil
}
// Float64Var defines a float64 flag with specified name, default value, and usage string.
// The argument p points to a float64 variable in which to store the value of the flag.
func (f *FlagSet) Float64Var(p *float64, name string, value float64, usage string) {
f.VarP(newFloat64Value(value, p), name, "", usage)
}
// Float64VarP is like Float64Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float64VarP(p *float64, name, shorthand string, value float64, usage string) {
f.VarP(newFloat64Value(value, p), name, shorthand, usage)
}
// Float64Var defines a float64 flag with specified name, default value, and usage string.
// The argument p points to a float64 variable in which to store the value of the flag.
func Float64Var(p *float64, name string, value float64, usage string) {
CommandLine.VarP(newFloat64Value(value, p), name, "", usage)
}
// Float64VarP is like Float64Var, but accepts a shorthand letter that can be used after a single dash.
func Float64VarP(p *float64, name, shorthand string, value float64, usage string) {
CommandLine.VarP(newFloat64Value(value, p), name, shorthand, usage)
}
// Float64 defines a float64 flag with specified name, default value, and usage string.
// The return value is the address of a float64 variable that stores the value of the flag.
func (f *FlagSet) Float64(name string, value float64, usage string) *float64 {
p := new(float64)
f.Float64VarP(p, name, "", value, usage)
return p
}
// Float64P is like Float64, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float64P(name, shorthand string, value float64, usage string) *float64 {
p := new(float64)
f.Float64VarP(p, name, shorthand, value, usage)
return p
}
// Float64 defines a float64 flag with specified name, default value, and usage string.
// The return value is the address of a float64 variable that stores the value of the flag.
func Float64(name string, value float64, usage string) *float64 {
return CommandLine.Float64P(name, "", value, usage)
}
// Float64P is like Float64, but accepts a shorthand letter that can be used after a single dash.
func Float64P(name, shorthand string, value float64, usage string) *float64 {
return CommandLine.Float64P(name, shorthand, value, usage)
}

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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- float64Slice Value
type float64SliceValue struct {
value *[]float64
changed bool
}
func newFloat64SliceValue(val []float64, p *[]float64) *float64SliceValue {
isv := new(float64SliceValue)
isv.value = p
*isv.value = val
return isv
}
func (s *float64SliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]float64, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.ParseFloat(d, 64)
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *float64SliceValue) Type() string {
return "float64Slice"
}
func (s *float64SliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%f", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *float64SliceValue) fromString(val string) (float64, error) {
return strconv.ParseFloat(val, 64)
}
func (s *float64SliceValue) toString(val float64) string {
return fmt.Sprintf("%f", val)
}
func (s *float64SliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *float64SliceValue) Replace(val []string) error {
out := make([]float64, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *float64SliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func float64SliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []float64{}, nil
}
ss := strings.Split(val, ",")
out := make([]float64, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.ParseFloat(d, 64)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetFloat64Slice return the []float64 value of a flag with the given name
func (f *FlagSet) GetFloat64Slice(name string) ([]float64, error) {
val, err := f.getFlagType(name, "float64Slice", float64SliceConv)
if err != nil {
return []float64{}, err
}
return val.([]float64), nil
}
// Float64SliceVar defines a float64Slice flag with specified name, default value, and usage string.
// The argument p points to a []float64 variable in which to store the value of the flag.
func (f *FlagSet) Float64SliceVar(p *[]float64, name string, value []float64, usage string) {
f.VarP(newFloat64SliceValue(value, p), name, "", usage)
}
// Float64SliceVarP is like Float64SliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float64SliceVarP(p *[]float64, name, shorthand string, value []float64, usage string) {
f.VarP(newFloat64SliceValue(value, p), name, shorthand, usage)
}
// Float64SliceVar defines a float64[] flag with specified name, default value, and usage string.
// The argument p points to a float64[] variable in which to store the value of the flag.
func Float64SliceVar(p *[]float64, name string, value []float64, usage string) {
CommandLine.VarP(newFloat64SliceValue(value, p), name, "", usage)
}
// Float64SliceVarP is like Float64SliceVar, but accepts a shorthand letter that can be used after a single dash.
func Float64SliceVarP(p *[]float64, name, shorthand string, value []float64, usage string) {
CommandLine.VarP(newFloat64SliceValue(value, p), name, shorthand, usage)
}
// Float64Slice defines a []float64 flag with specified name, default value, and usage string.
// The return value is the address of a []float64 variable that stores the value of the flag.
func (f *FlagSet) Float64Slice(name string, value []float64, usage string) *[]float64 {
p := []float64{}
f.Float64SliceVarP(&p, name, "", value, usage)
return &p
}
// Float64SliceP is like Float64Slice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Float64SliceP(name, shorthand string, value []float64, usage string) *[]float64 {
p := []float64{}
f.Float64SliceVarP(&p, name, shorthand, value, usage)
return &p
}
// Float64Slice defines a []float64 flag with specified name, default value, and usage string.
// The return value is the address of a []float64 variable that stores the value of the flag.
func Float64Slice(name string, value []float64, usage string) *[]float64 {
return CommandLine.Float64SliceP(name, "", value, usage)
}
// Float64SliceP is like Float64Slice, but accepts a shorthand letter that can be used after a single dash.
func Float64SliceP(name, shorthand string, value []float64, usage string) *[]float64 {
return CommandLine.Float64SliceP(name, shorthand, value, usage)
}

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// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package pflag
import (
goflag "flag"
"reflect"
"strings"
)
// flagValueWrapper implements pflag.Value around a flag.Value. The main
// difference here is the addition of the Type method that returns a string
// name of the type. As this is generally unknown, we approximate that with
// reflection.
type flagValueWrapper struct {
inner goflag.Value
flagType string
}
// We are just copying the boolFlag interface out of goflag as that is what
// they use to decide if a flag should get "true" when no arg is given.
type goBoolFlag interface {
goflag.Value
IsBoolFlag() bool
}
func wrapFlagValue(v goflag.Value) Value {
// If the flag.Value happens to also be a pflag.Value, just use it directly.
if pv, ok := v.(Value); ok {
return pv
}
pv := &flagValueWrapper{
inner: v,
}
t := reflect.TypeOf(v)
if t.Kind() == reflect.Interface || t.Kind() == reflect.Ptr {
t = t.Elem()
}
pv.flagType = strings.TrimSuffix(t.Name(), "Value")
return pv
}
func (v *flagValueWrapper) String() string {
return v.inner.String()
}
func (v *flagValueWrapper) Set(s string) error {
return v.inner.Set(s)
}
func (v *flagValueWrapper) Type() string {
return v.flagType
}
// PFlagFromGoFlag will return a *pflag.Flag given a *flag.Flag
// If the *flag.Flag.Name was a single character (ex: `v`) it will be accessiblei
// with both `-v` and `--v` in flags. If the golang flag was more than a single
// character (ex: `verbose`) it will only be accessible via `--verbose`
func PFlagFromGoFlag(goflag *goflag.Flag) *Flag {
// Remember the default value as a string; it won't change.
flag := &Flag{
Name: goflag.Name,
Usage: goflag.Usage,
Value: wrapFlagValue(goflag.Value),
// Looks like golang flags don't set DefValue correctly :-(
//DefValue: goflag.DefValue,
DefValue: goflag.Value.String(),
}
// Ex: if the golang flag was -v, allow both -v and --v to work
if len(flag.Name) == 1 {
flag.Shorthand = flag.Name
}
if fv, ok := goflag.Value.(goBoolFlag); ok && fv.IsBoolFlag() {
flag.NoOptDefVal = "true"
}
return flag
}
// AddGoFlag will add the given *flag.Flag to the pflag.FlagSet
func (f *FlagSet) AddGoFlag(goflag *goflag.Flag) {
if f.Lookup(goflag.Name) != nil {
return
}
newflag := PFlagFromGoFlag(goflag)
f.AddFlag(newflag)
}
// AddGoFlagSet will add the given *flag.FlagSet to the pflag.FlagSet
func (f *FlagSet) AddGoFlagSet(newSet *goflag.FlagSet) {
if newSet == nil {
return
}
newSet.VisitAll(func(goflag *goflag.Flag) {
f.AddGoFlag(goflag)
})
if f.addedGoFlagSets == nil {
f.addedGoFlagSets = make([]*goflag.FlagSet, 0)
}
f.addedGoFlagSets = append(f.addedGoFlagSets, newSet)
}

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package pflag
import "strconv"
// -- int Value
type intValue int
func newIntValue(val int, p *int) *intValue {
*p = val
return (*intValue)(p)
}
func (i *intValue) Set(s string) error {
v, err := strconv.ParseInt(s, 0, 64)
*i = intValue(v)
return err
}
func (i *intValue) Type() string {
return "int"
}
func (i *intValue) String() string { return strconv.Itoa(int(*i)) }
func intConv(sval string) (interface{}, error) {
return strconv.Atoi(sval)
}
// GetInt return the int value of a flag with the given name
func (f *FlagSet) GetInt(name string) (int, error) {
val, err := f.getFlagType(name, "int", intConv)
if err != nil {
return 0, err
}
return val.(int), nil
}
// IntVar defines an int flag with specified name, default value, and usage string.
// The argument p points to an int variable in which to store the value of the flag.
func (f *FlagSet) IntVar(p *int, name string, value int, usage string) {
f.VarP(newIntValue(value, p), name, "", usage)
}
// IntVarP is like IntVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IntVarP(p *int, name, shorthand string, value int, usage string) {
f.VarP(newIntValue(value, p), name, shorthand, usage)
}
// IntVar defines an int flag with specified name, default value, and usage string.
// The argument p points to an int variable in which to store the value of the flag.
func IntVar(p *int, name string, value int, usage string) {
CommandLine.VarP(newIntValue(value, p), name, "", usage)
}
// IntVarP is like IntVar, but accepts a shorthand letter that can be used after a single dash.
func IntVarP(p *int, name, shorthand string, value int, usage string) {
CommandLine.VarP(newIntValue(value, p), name, shorthand, usage)
}
// Int defines an int flag with specified name, default value, and usage string.
// The return value is the address of an int variable that stores the value of the flag.
func (f *FlagSet) Int(name string, value int, usage string) *int {
p := new(int)
f.IntVarP(p, name, "", value, usage)
return p
}
// IntP is like Int, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IntP(name, shorthand string, value int, usage string) *int {
p := new(int)
f.IntVarP(p, name, shorthand, value, usage)
return p
}
// Int defines an int flag with specified name, default value, and usage string.
// The return value is the address of an int variable that stores the value of the flag.
func Int(name string, value int, usage string) *int {
return CommandLine.IntP(name, "", value, usage)
}
// IntP is like Int, but accepts a shorthand letter that can be used after a single dash.
func IntP(name, shorthand string, value int, usage string) *int {
return CommandLine.IntP(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- int16 Value
type int16Value int16
func newInt16Value(val int16, p *int16) *int16Value {
*p = val
return (*int16Value)(p)
}
func (i *int16Value) Set(s string) error {
v, err := strconv.ParseInt(s, 0, 16)
*i = int16Value(v)
return err
}
func (i *int16Value) Type() string {
return "int16"
}
func (i *int16Value) String() string { return strconv.FormatInt(int64(*i), 10) }
func int16Conv(sval string) (interface{}, error) {
v, err := strconv.ParseInt(sval, 0, 16)
if err != nil {
return 0, err
}
return int16(v), nil
}
// GetInt16 returns the int16 value of a flag with the given name
func (f *FlagSet) GetInt16(name string) (int16, error) {
val, err := f.getFlagType(name, "int16", int16Conv)
if err != nil {
return 0, err
}
return val.(int16), nil
}
// Int16Var defines an int16 flag with specified name, default value, and usage string.
// The argument p points to an int16 variable in which to store the value of the flag.
func (f *FlagSet) Int16Var(p *int16, name string, value int16, usage string) {
f.VarP(newInt16Value(value, p), name, "", usage)
}
// Int16VarP is like Int16Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int16VarP(p *int16, name, shorthand string, value int16, usage string) {
f.VarP(newInt16Value(value, p), name, shorthand, usage)
}
// Int16Var defines an int16 flag with specified name, default value, and usage string.
// The argument p points to an int16 variable in which to store the value of the flag.
func Int16Var(p *int16, name string, value int16, usage string) {
CommandLine.VarP(newInt16Value(value, p), name, "", usage)
}
// Int16VarP is like Int16Var, but accepts a shorthand letter that can be used after a single dash.
func Int16VarP(p *int16, name, shorthand string, value int16, usage string) {
CommandLine.VarP(newInt16Value(value, p), name, shorthand, usage)
}
// Int16 defines an int16 flag with specified name, default value, and usage string.
// The return value is the address of an int16 variable that stores the value of the flag.
func (f *FlagSet) Int16(name string, value int16, usage string) *int16 {
p := new(int16)
f.Int16VarP(p, name, "", value, usage)
return p
}
// Int16P is like Int16, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int16P(name, shorthand string, value int16, usage string) *int16 {
p := new(int16)
f.Int16VarP(p, name, shorthand, value, usage)
return p
}
// Int16 defines an int16 flag with specified name, default value, and usage string.
// The return value is the address of an int16 variable that stores the value of the flag.
func Int16(name string, value int16, usage string) *int16 {
return CommandLine.Int16P(name, "", value, usage)
}
// Int16P is like Int16, but accepts a shorthand letter that can be used after a single dash.
func Int16P(name, shorthand string, value int16, usage string) *int16 {
return CommandLine.Int16P(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- int32 Value
type int32Value int32
func newInt32Value(val int32, p *int32) *int32Value {
*p = val
return (*int32Value)(p)
}
func (i *int32Value) Set(s string) error {
v, err := strconv.ParseInt(s, 0, 32)
*i = int32Value(v)
return err
}
func (i *int32Value) Type() string {
return "int32"
}
func (i *int32Value) String() string { return strconv.FormatInt(int64(*i), 10) }
func int32Conv(sval string) (interface{}, error) {
v, err := strconv.ParseInt(sval, 0, 32)
if err != nil {
return 0, err
}
return int32(v), nil
}
// GetInt32 return the int32 value of a flag with the given name
func (f *FlagSet) GetInt32(name string) (int32, error) {
val, err := f.getFlagType(name, "int32", int32Conv)
if err != nil {
return 0, err
}
return val.(int32), nil
}
// Int32Var defines an int32 flag with specified name, default value, and usage string.
// The argument p points to an int32 variable in which to store the value of the flag.
func (f *FlagSet) Int32Var(p *int32, name string, value int32, usage string) {
f.VarP(newInt32Value(value, p), name, "", usage)
}
// Int32VarP is like Int32Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int32VarP(p *int32, name, shorthand string, value int32, usage string) {
f.VarP(newInt32Value(value, p), name, shorthand, usage)
}
// Int32Var defines an int32 flag with specified name, default value, and usage string.
// The argument p points to an int32 variable in which to store the value of the flag.
func Int32Var(p *int32, name string, value int32, usage string) {
CommandLine.VarP(newInt32Value(value, p), name, "", usage)
}
// Int32VarP is like Int32Var, but accepts a shorthand letter that can be used after a single dash.
func Int32VarP(p *int32, name, shorthand string, value int32, usage string) {
CommandLine.VarP(newInt32Value(value, p), name, shorthand, usage)
}
// Int32 defines an int32 flag with specified name, default value, and usage string.
// The return value is the address of an int32 variable that stores the value of the flag.
func (f *FlagSet) Int32(name string, value int32, usage string) *int32 {
p := new(int32)
f.Int32VarP(p, name, "", value, usage)
return p
}
// Int32P is like Int32, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int32P(name, shorthand string, value int32, usage string) *int32 {
p := new(int32)
f.Int32VarP(p, name, shorthand, value, usage)
return p
}
// Int32 defines an int32 flag with specified name, default value, and usage string.
// The return value is the address of an int32 variable that stores the value of the flag.
func Int32(name string, value int32, usage string) *int32 {
return CommandLine.Int32P(name, "", value, usage)
}
// Int32P is like Int32, but accepts a shorthand letter that can be used after a single dash.
func Int32P(name, shorthand string, value int32, usage string) *int32 {
return CommandLine.Int32P(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/int32_slice.go generated vendored Normal file
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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- int32Slice Value
type int32SliceValue struct {
value *[]int32
changed bool
}
func newInt32SliceValue(val []int32, p *[]int32) *int32SliceValue {
isv := new(int32SliceValue)
isv.value = p
*isv.value = val
return isv
}
func (s *int32SliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]int32, len(ss))
for i, d := range ss {
var err error
var temp64 int64
temp64, err = strconv.ParseInt(d, 0, 32)
if err != nil {
return err
}
out[i] = int32(temp64)
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *int32SliceValue) Type() string {
return "int32Slice"
}
func (s *int32SliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%d", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *int32SliceValue) fromString(val string) (int32, error) {
t64, err := strconv.ParseInt(val, 0, 32)
if err != nil {
return 0, err
}
return int32(t64), nil
}
func (s *int32SliceValue) toString(val int32) string {
return fmt.Sprintf("%d", val)
}
func (s *int32SliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *int32SliceValue) Replace(val []string) error {
out := make([]int32, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *int32SliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func int32SliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []int32{}, nil
}
ss := strings.Split(val, ",")
out := make([]int32, len(ss))
for i, d := range ss {
var err error
var temp64 int64
temp64, err = strconv.ParseInt(d, 0, 32)
if err != nil {
return nil, err
}
out[i] = int32(temp64)
}
return out, nil
}
// GetInt32Slice return the []int32 value of a flag with the given name
func (f *FlagSet) GetInt32Slice(name string) ([]int32, error) {
val, err := f.getFlagType(name, "int32Slice", int32SliceConv)
if err != nil {
return []int32{}, err
}
return val.([]int32), nil
}
// Int32SliceVar defines a int32Slice flag with specified name, default value, and usage string.
// The argument p points to a []int32 variable in which to store the value of the flag.
func (f *FlagSet) Int32SliceVar(p *[]int32, name string, value []int32, usage string) {
f.VarP(newInt32SliceValue(value, p), name, "", usage)
}
// Int32SliceVarP is like Int32SliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int32SliceVarP(p *[]int32, name, shorthand string, value []int32, usage string) {
f.VarP(newInt32SliceValue(value, p), name, shorthand, usage)
}
// Int32SliceVar defines a int32[] flag with specified name, default value, and usage string.
// The argument p points to a int32[] variable in which to store the value of the flag.
func Int32SliceVar(p *[]int32, name string, value []int32, usage string) {
CommandLine.VarP(newInt32SliceValue(value, p), name, "", usage)
}
// Int32SliceVarP is like Int32SliceVar, but accepts a shorthand letter that can be used after a single dash.
func Int32SliceVarP(p *[]int32, name, shorthand string, value []int32, usage string) {
CommandLine.VarP(newInt32SliceValue(value, p), name, shorthand, usage)
}
// Int32Slice defines a []int32 flag with specified name, default value, and usage string.
// The return value is the address of a []int32 variable that stores the value of the flag.
func (f *FlagSet) Int32Slice(name string, value []int32, usage string) *[]int32 {
p := []int32{}
f.Int32SliceVarP(&p, name, "", value, usage)
return &p
}
// Int32SliceP is like Int32Slice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int32SliceP(name, shorthand string, value []int32, usage string) *[]int32 {
p := []int32{}
f.Int32SliceVarP(&p, name, shorthand, value, usage)
return &p
}
// Int32Slice defines a []int32 flag with specified name, default value, and usage string.
// The return value is the address of a []int32 variable that stores the value of the flag.
func Int32Slice(name string, value []int32, usage string) *[]int32 {
return CommandLine.Int32SliceP(name, "", value, usage)
}
// Int32SliceP is like Int32Slice, but accepts a shorthand letter that can be used after a single dash.
func Int32SliceP(name, shorthand string, value []int32, usage string) *[]int32 {
return CommandLine.Int32SliceP(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/int64.go generated vendored Normal file
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package pflag
import "strconv"
// -- int64 Value
type int64Value int64
func newInt64Value(val int64, p *int64) *int64Value {
*p = val
return (*int64Value)(p)
}
func (i *int64Value) Set(s string) error {
v, err := strconv.ParseInt(s, 0, 64)
*i = int64Value(v)
return err
}
func (i *int64Value) Type() string {
return "int64"
}
func (i *int64Value) String() string { return strconv.FormatInt(int64(*i), 10) }
func int64Conv(sval string) (interface{}, error) {
return strconv.ParseInt(sval, 0, 64)
}
// GetInt64 return the int64 value of a flag with the given name
func (f *FlagSet) GetInt64(name string) (int64, error) {
val, err := f.getFlagType(name, "int64", int64Conv)
if err != nil {
return 0, err
}
return val.(int64), nil
}
// Int64Var defines an int64 flag with specified name, default value, and usage string.
// The argument p points to an int64 variable in which to store the value of the flag.
func (f *FlagSet) Int64Var(p *int64, name string, value int64, usage string) {
f.VarP(newInt64Value(value, p), name, "", usage)
}
// Int64VarP is like Int64Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int64VarP(p *int64, name, shorthand string, value int64, usage string) {
f.VarP(newInt64Value(value, p), name, shorthand, usage)
}
// Int64Var defines an int64 flag with specified name, default value, and usage string.
// The argument p points to an int64 variable in which to store the value of the flag.
func Int64Var(p *int64, name string, value int64, usage string) {
CommandLine.VarP(newInt64Value(value, p), name, "", usage)
}
// Int64VarP is like Int64Var, but accepts a shorthand letter that can be used after a single dash.
func Int64VarP(p *int64, name, shorthand string, value int64, usage string) {
CommandLine.VarP(newInt64Value(value, p), name, shorthand, usage)
}
// Int64 defines an int64 flag with specified name, default value, and usage string.
// The return value is the address of an int64 variable that stores the value of the flag.
func (f *FlagSet) Int64(name string, value int64, usage string) *int64 {
p := new(int64)
f.Int64VarP(p, name, "", value, usage)
return p
}
// Int64P is like Int64, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int64P(name, shorthand string, value int64, usage string) *int64 {
p := new(int64)
f.Int64VarP(p, name, shorthand, value, usage)
return p
}
// Int64 defines an int64 flag with specified name, default value, and usage string.
// The return value is the address of an int64 variable that stores the value of the flag.
func Int64(name string, value int64, usage string) *int64 {
return CommandLine.Int64P(name, "", value, usage)
}
// Int64P is like Int64, but accepts a shorthand letter that can be used after a single dash.
func Int64P(name, shorthand string, value int64, usage string) *int64 {
return CommandLine.Int64P(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/int64_slice.go generated vendored Normal file
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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- int64Slice Value
type int64SliceValue struct {
value *[]int64
changed bool
}
func newInt64SliceValue(val []int64, p *[]int64) *int64SliceValue {
isv := new(int64SliceValue)
isv.value = p
*isv.value = val
return isv
}
func (s *int64SliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]int64, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.ParseInt(d, 0, 64)
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *int64SliceValue) Type() string {
return "int64Slice"
}
func (s *int64SliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%d", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *int64SliceValue) fromString(val string) (int64, error) {
return strconv.ParseInt(val, 0, 64)
}
func (s *int64SliceValue) toString(val int64) string {
return fmt.Sprintf("%d", val)
}
func (s *int64SliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *int64SliceValue) Replace(val []string) error {
out := make([]int64, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *int64SliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func int64SliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []int64{}, nil
}
ss := strings.Split(val, ",")
out := make([]int64, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.ParseInt(d, 0, 64)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetInt64Slice return the []int64 value of a flag with the given name
func (f *FlagSet) GetInt64Slice(name string) ([]int64, error) {
val, err := f.getFlagType(name, "int64Slice", int64SliceConv)
if err != nil {
return []int64{}, err
}
return val.([]int64), nil
}
// Int64SliceVar defines a int64Slice flag with specified name, default value, and usage string.
// The argument p points to a []int64 variable in which to store the value of the flag.
func (f *FlagSet) Int64SliceVar(p *[]int64, name string, value []int64, usage string) {
f.VarP(newInt64SliceValue(value, p), name, "", usage)
}
// Int64SliceVarP is like Int64SliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int64SliceVarP(p *[]int64, name, shorthand string, value []int64, usage string) {
f.VarP(newInt64SliceValue(value, p), name, shorthand, usage)
}
// Int64SliceVar defines a int64[] flag with specified name, default value, and usage string.
// The argument p points to a int64[] variable in which to store the value of the flag.
func Int64SliceVar(p *[]int64, name string, value []int64, usage string) {
CommandLine.VarP(newInt64SliceValue(value, p), name, "", usage)
}
// Int64SliceVarP is like Int64SliceVar, but accepts a shorthand letter that can be used after a single dash.
func Int64SliceVarP(p *[]int64, name, shorthand string, value []int64, usage string) {
CommandLine.VarP(newInt64SliceValue(value, p), name, shorthand, usage)
}
// Int64Slice defines a []int64 flag with specified name, default value, and usage string.
// The return value is the address of a []int64 variable that stores the value of the flag.
func (f *FlagSet) Int64Slice(name string, value []int64, usage string) *[]int64 {
p := []int64{}
f.Int64SliceVarP(&p, name, "", value, usage)
return &p
}
// Int64SliceP is like Int64Slice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int64SliceP(name, shorthand string, value []int64, usage string) *[]int64 {
p := []int64{}
f.Int64SliceVarP(&p, name, shorthand, value, usage)
return &p
}
// Int64Slice defines a []int64 flag with specified name, default value, and usage string.
// The return value is the address of a []int64 variable that stores the value of the flag.
func Int64Slice(name string, value []int64, usage string) *[]int64 {
return CommandLine.Int64SliceP(name, "", value, usage)
}
// Int64SliceP is like Int64Slice, but accepts a shorthand letter that can be used after a single dash.
func Int64SliceP(name, shorthand string, value []int64, usage string) *[]int64 {
return CommandLine.Int64SliceP(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/int8.go generated vendored Normal file
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package pflag
import "strconv"
// -- int8 Value
type int8Value int8
func newInt8Value(val int8, p *int8) *int8Value {
*p = val
return (*int8Value)(p)
}
func (i *int8Value) Set(s string) error {
v, err := strconv.ParseInt(s, 0, 8)
*i = int8Value(v)
return err
}
func (i *int8Value) Type() string {
return "int8"
}
func (i *int8Value) String() string { return strconv.FormatInt(int64(*i), 10) }
func int8Conv(sval string) (interface{}, error) {
v, err := strconv.ParseInt(sval, 0, 8)
if err != nil {
return 0, err
}
return int8(v), nil
}
// GetInt8 return the int8 value of a flag with the given name
func (f *FlagSet) GetInt8(name string) (int8, error) {
val, err := f.getFlagType(name, "int8", int8Conv)
if err != nil {
return 0, err
}
return val.(int8), nil
}
// Int8Var defines an int8 flag with specified name, default value, and usage string.
// The argument p points to an int8 variable in which to store the value of the flag.
func (f *FlagSet) Int8Var(p *int8, name string, value int8, usage string) {
f.VarP(newInt8Value(value, p), name, "", usage)
}
// Int8VarP is like Int8Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int8VarP(p *int8, name, shorthand string, value int8, usage string) {
f.VarP(newInt8Value(value, p), name, shorthand, usage)
}
// Int8Var defines an int8 flag with specified name, default value, and usage string.
// The argument p points to an int8 variable in which to store the value of the flag.
func Int8Var(p *int8, name string, value int8, usage string) {
CommandLine.VarP(newInt8Value(value, p), name, "", usage)
}
// Int8VarP is like Int8Var, but accepts a shorthand letter that can be used after a single dash.
func Int8VarP(p *int8, name, shorthand string, value int8, usage string) {
CommandLine.VarP(newInt8Value(value, p), name, shorthand, usage)
}
// Int8 defines an int8 flag with specified name, default value, and usage string.
// The return value is the address of an int8 variable that stores the value of the flag.
func (f *FlagSet) Int8(name string, value int8, usage string) *int8 {
p := new(int8)
f.Int8VarP(p, name, "", value, usage)
return p
}
// Int8P is like Int8, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Int8P(name, shorthand string, value int8, usage string) *int8 {
p := new(int8)
f.Int8VarP(p, name, shorthand, value, usage)
return p
}
// Int8 defines an int8 flag with specified name, default value, and usage string.
// The return value is the address of an int8 variable that stores the value of the flag.
func Int8(name string, value int8, usage string) *int8 {
return CommandLine.Int8P(name, "", value, usage)
}
// Int8P is like Int8, but accepts a shorthand letter that can be used after a single dash.
func Int8P(name, shorthand string, value int8, usage string) *int8 {
return CommandLine.Int8P(name, shorthand, value, usage)
}

158
vendor/github.com/spf13/pflag/int_slice.go generated vendored Normal file
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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- intSlice Value
type intSliceValue struct {
value *[]int
changed bool
}
func newIntSliceValue(val []int, p *[]int) *intSliceValue {
isv := new(intSliceValue)
isv.value = p
*isv.value = val
return isv
}
func (s *intSliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]int, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.Atoi(d)
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *intSliceValue) Type() string {
return "intSlice"
}
func (s *intSliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%d", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *intSliceValue) Append(val string) error {
i, err := strconv.Atoi(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *intSliceValue) Replace(val []string) error {
out := make([]int, len(val))
for i, d := range val {
var err error
out[i], err = strconv.Atoi(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *intSliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = strconv.Itoa(d)
}
return out
}
func intSliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []int{}, nil
}
ss := strings.Split(val, ",")
out := make([]int, len(ss))
for i, d := range ss {
var err error
out[i], err = strconv.Atoi(d)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetIntSlice return the []int value of a flag with the given name
func (f *FlagSet) GetIntSlice(name string) ([]int, error) {
val, err := f.getFlagType(name, "intSlice", intSliceConv)
if err != nil {
return []int{}, err
}
return val.([]int), nil
}
// IntSliceVar defines a intSlice flag with specified name, default value, and usage string.
// The argument p points to a []int variable in which to store the value of the flag.
func (f *FlagSet) IntSliceVar(p *[]int, name string, value []int, usage string) {
f.VarP(newIntSliceValue(value, p), name, "", usage)
}
// IntSliceVarP is like IntSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IntSliceVarP(p *[]int, name, shorthand string, value []int, usage string) {
f.VarP(newIntSliceValue(value, p), name, shorthand, usage)
}
// IntSliceVar defines a int[] flag with specified name, default value, and usage string.
// The argument p points to a int[] variable in which to store the value of the flag.
func IntSliceVar(p *[]int, name string, value []int, usage string) {
CommandLine.VarP(newIntSliceValue(value, p), name, "", usage)
}
// IntSliceVarP is like IntSliceVar, but accepts a shorthand letter that can be used after a single dash.
func IntSliceVarP(p *[]int, name, shorthand string, value []int, usage string) {
CommandLine.VarP(newIntSliceValue(value, p), name, shorthand, usage)
}
// IntSlice defines a []int flag with specified name, default value, and usage string.
// The return value is the address of a []int variable that stores the value of the flag.
func (f *FlagSet) IntSlice(name string, value []int, usage string) *[]int {
p := []int{}
f.IntSliceVarP(&p, name, "", value, usage)
return &p
}
// IntSliceP is like IntSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IntSliceP(name, shorthand string, value []int, usage string) *[]int {
p := []int{}
f.IntSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// IntSlice defines a []int flag with specified name, default value, and usage string.
// The return value is the address of a []int variable that stores the value of the flag.
func IntSlice(name string, value []int, usage string) *[]int {
return CommandLine.IntSliceP(name, "", value, usage)
}
// IntSliceP is like IntSlice, but accepts a shorthand letter that can be used after a single dash.
func IntSliceP(name, shorthand string, value []int, usage string) *[]int {
return CommandLine.IntSliceP(name, shorthand, value, usage)
}

94
vendor/github.com/spf13/pflag/ip.go generated vendored Normal file
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package pflag
import (
"fmt"
"net"
"strings"
)
// -- net.IP value
type ipValue net.IP
func newIPValue(val net.IP, p *net.IP) *ipValue {
*p = val
return (*ipValue)(p)
}
func (i *ipValue) String() string { return net.IP(*i).String() }
func (i *ipValue) Set(s string) error {
ip := net.ParseIP(strings.TrimSpace(s))
if ip == nil {
return fmt.Errorf("failed to parse IP: %q", s)
}
*i = ipValue(ip)
return nil
}
func (i *ipValue) Type() string {
return "ip"
}
func ipConv(sval string) (interface{}, error) {
ip := net.ParseIP(sval)
if ip != nil {
return ip, nil
}
return nil, fmt.Errorf("invalid string being converted to IP address: %s", sval)
}
// GetIP return the net.IP value of a flag with the given name
func (f *FlagSet) GetIP(name string) (net.IP, error) {
val, err := f.getFlagType(name, "ip", ipConv)
if err != nil {
return nil, err
}
return val.(net.IP), nil
}
// IPVar defines an net.IP flag with specified name, default value, and usage string.
// The argument p points to an net.IP variable in which to store the value of the flag.
func (f *FlagSet) IPVar(p *net.IP, name string, value net.IP, usage string) {
f.VarP(newIPValue(value, p), name, "", usage)
}
// IPVarP is like IPVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPVarP(p *net.IP, name, shorthand string, value net.IP, usage string) {
f.VarP(newIPValue(value, p), name, shorthand, usage)
}
// IPVar defines an net.IP flag with specified name, default value, and usage string.
// The argument p points to an net.IP variable in which to store the value of the flag.
func IPVar(p *net.IP, name string, value net.IP, usage string) {
CommandLine.VarP(newIPValue(value, p), name, "", usage)
}
// IPVarP is like IPVar, but accepts a shorthand letter that can be used after a single dash.
func IPVarP(p *net.IP, name, shorthand string, value net.IP, usage string) {
CommandLine.VarP(newIPValue(value, p), name, shorthand, usage)
}
// IP defines an net.IP flag with specified name, default value, and usage string.
// The return value is the address of an net.IP variable that stores the value of the flag.
func (f *FlagSet) IP(name string, value net.IP, usage string) *net.IP {
p := new(net.IP)
f.IPVarP(p, name, "", value, usage)
return p
}
// IPP is like IP, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPP(name, shorthand string, value net.IP, usage string) *net.IP {
p := new(net.IP)
f.IPVarP(p, name, shorthand, value, usage)
return p
}
// IP defines an net.IP flag with specified name, default value, and usage string.
// The return value is the address of an net.IP variable that stores the value of the flag.
func IP(name string, value net.IP, usage string) *net.IP {
return CommandLine.IPP(name, "", value, usage)
}
// IPP is like IP, but accepts a shorthand letter that can be used after a single dash.
func IPP(name, shorthand string, value net.IP, usage string) *net.IP {
return CommandLine.IPP(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/ip_slice.go generated vendored Normal file
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package pflag
import (
"fmt"
"io"
"net"
"strings"
)
// -- ipSlice Value
type ipSliceValue struct {
value *[]net.IP
changed bool
}
func newIPSliceValue(val []net.IP, p *[]net.IP) *ipSliceValue {
ipsv := new(ipSliceValue)
ipsv.value = p
*ipsv.value = val
return ipsv
}
// Set converts, and assigns, the comma-separated IP argument string representation as the []net.IP value of this flag.
// If Set is called on a flag that already has a []net.IP assigned, the newly converted values will be appended.
func (s *ipSliceValue) Set(val string) error {
// remove all quote characters
rmQuote := strings.NewReplacer(`"`, "", `'`, "", "`", "")
// read flag arguments with CSV parser
ipStrSlice, err := readAsCSV(rmQuote.Replace(val))
if err != nil && err != io.EOF {
return err
}
// parse ip values into slice
out := make([]net.IP, 0, len(ipStrSlice))
for _, ipStr := range ipStrSlice {
ip := net.ParseIP(strings.TrimSpace(ipStr))
if ip == nil {
return fmt.Errorf("invalid string being converted to IP address: %s", ipStr)
}
out = append(out, ip)
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
// Type returns a string that uniquely represents this flag's type.
func (s *ipSliceValue) Type() string {
return "ipSlice"
}
// String defines a "native" format for this net.IP slice flag value.
func (s *ipSliceValue) String() string {
ipStrSlice := make([]string, len(*s.value))
for i, ip := range *s.value {
ipStrSlice[i] = ip.String()
}
out, _ := writeAsCSV(ipStrSlice)
return "[" + out + "]"
}
func (s *ipSliceValue) fromString(val string) (net.IP, error) {
return net.ParseIP(strings.TrimSpace(val)), nil
}
func (s *ipSliceValue) toString(val net.IP) string {
return val.String()
}
func (s *ipSliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *ipSliceValue) Replace(val []string) error {
out := make([]net.IP, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *ipSliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func ipSliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []net.IP{}, nil
}
ss := strings.Split(val, ",")
out := make([]net.IP, len(ss))
for i, sval := range ss {
ip := net.ParseIP(strings.TrimSpace(sval))
if ip == nil {
return nil, fmt.Errorf("invalid string being converted to IP address: %s", sval)
}
out[i] = ip
}
return out, nil
}
// GetIPSlice returns the []net.IP value of a flag with the given name
func (f *FlagSet) GetIPSlice(name string) ([]net.IP, error) {
val, err := f.getFlagType(name, "ipSlice", ipSliceConv)
if err != nil {
return []net.IP{}, err
}
return val.([]net.IP), nil
}
// IPSliceVar defines a ipSlice flag with specified name, default value, and usage string.
// The argument p points to a []net.IP variable in which to store the value of the flag.
func (f *FlagSet) IPSliceVar(p *[]net.IP, name string, value []net.IP, usage string) {
f.VarP(newIPSliceValue(value, p), name, "", usage)
}
// IPSliceVarP is like IPSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPSliceVarP(p *[]net.IP, name, shorthand string, value []net.IP, usage string) {
f.VarP(newIPSliceValue(value, p), name, shorthand, usage)
}
// IPSliceVar defines a []net.IP flag with specified name, default value, and usage string.
// The argument p points to a []net.IP variable in which to store the value of the flag.
func IPSliceVar(p *[]net.IP, name string, value []net.IP, usage string) {
CommandLine.VarP(newIPSliceValue(value, p), name, "", usage)
}
// IPSliceVarP is like IPSliceVar, but accepts a shorthand letter that can be used after a single dash.
func IPSliceVarP(p *[]net.IP, name, shorthand string, value []net.IP, usage string) {
CommandLine.VarP(newIPSliceValue(value, p), name, shorthand, usage)
}
// IPSlice defines a []net.IP flag with specified name, default value, and usage string.
// The return value is the address of a []net.IP variable that stores the value of that flag.
func (f *FlagSet) IPSlice(name string, value []net.IP, usage string) *[]net.IP {
p := []net.IP{}
f.IPSliceVarP(&p, name, "", value, usage)
return &p
}
// IPSliceP is like IPSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPSliceP(name, shorthand string, value []net.IP, usage string) *[]net.IP {
p := []net.IP{}
f.IPSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// IPSlice defines a []net.IP flag with specified name, default value, and usage string.
// The return value is the address of a []net.IP variable that stores the value of the flag.
func IPSlice(name string, value []net.IP, usage string) *[]net.IP {
return CommandLine.IPSliceP(name, "", value, usage)
}
// IPSliceP is like IPSlice, but accepts a shorthand letter that can be used after a single dash.
func IPSliceP(name, shorthand string, value []net.IP, usage string) *[]net.IP {
return CommandLine.IPSliceP(name, shorthand, value, usage)
}

122
vendor/github.com/spf13/pflag/ipmask.go generated vendored Normal file
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package pflag
import (
"fmt"
"net"
"strconv"
)
// -- net.IPMask value
type ipMaskValue net.IPMask
func newIPMaskValue(val net.IPMask, p *net.IPMask) *ipMaskValue {
*p = val
return (*ipMaskValue)(p)
}
func (i *ipMaskValue) String() string { return net.IPMask(*i).String() }
func (i *ipMaskValue) Set(s string) error {
ip := ParseIPv4Mask(s)
if ip == nil {
return fmt.Errorf("failed to parse IP mask: %q", s)
}
*i = ipMaskValue(ip)
return nil
}
func (i *ipMaskValue) Type() string {
return "ipMask"
}
// ParseIPv4Mask written in IP form (e.g. 255.255.255.0).
// This function should really belong to the net package.
func ParseIPv4Mask(s string) net.IPMask {
mask := net.ParseIP(s)
if mask == nil {
if len(s) != 8 {
return nil
}
// net.IPMask.String() actually outputs things like ffffff00
// so write a horrible parser for that as well :-(
m := []int{}
for i := 0; i < 4; i++ {
b := "0x" + s[2*i:2*i+2]
d, err := strconv.ParseInt(b, 0, 0)
if err != nil {
return nil
}
m = append(m, int(d))
}
s := fmt.Sprintf("%d.%d.%d.%d", m[0], m[1], m[2], m[3])
mask = net.ParseIP(s)
if mask == nil {
return nil
}
}
return net.IPv4Mask(mask[12], mask[13], mask[14], mask[15])
}
func parseIPv4Mask(sval string) (interface{}, error) {
mask := ParseIPv4Mask(sval)
if mask == nil {
return nil, fmt.Errorf("unable to parse %s as net.IPMask", sval)
}
return mask, nil
}
// GetIPv4Mask return the net.IPv4Mask value of a flag with the given name
func (f *FlagSet) GetIPv4Mask(name string) (net.IPMask, error) {
val, err := f.getFlagType(name, "ipMask", parseIPv4Mask)
if err != nil {
return nil, err
}
return val.(net.IPMask), nil
}
// IPMaskVar defines an net.IPMask flag with specified name, default value, and usage string.
// The argument p points to an net.IPMask variable in which to store the value of the flag.
func (f *FlagSet) IPMaskVar(p *net.IPMask, name string, value net.IPMask, usage string) {
f.VarP(newIPMaskValue(value, p), name, "", usage)
}
// IPMaskVarP is like IPMaskVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPMaskVarP(p *net.IPMask, name, shorthand string, value net.IPMask, usage string) {
f.VarP(newIPMaskValue(value, p), name, shorthand, usage)
}
// IPMaskVar defines an net.IPMask flag with specified name, default value, and usage string.
// The argument p points to an net.IPMask variable in which to store the value of the flag.
func IPMaskVar(p *net.IPMask, name string, value net.IPMask, usage string) {
CommandLine.VarP(newIPMaskValue(value, p), name, "", usage)
}
// IPMaskVarP is like IPMaskVar, but accepts a shorthand letter that can be used after a single dash.
func IPMaskVarP(p *net.IPMask, name, shorthand string, value net.IPMask, usage string) {
CommandLine.VarP(newIPMaskValue(value, p), name, shorthand, usage)
}
// IPMask defines an net.IPMask flag with specified name, default value, and usage string.
// The return value is the address of an net.IPMask variable that stores the value of the flag.
func (f *FlagSet) IPMask(name string, value net.IPMask, usage string) *net.IPMask {
p := new(net.IPMask)
f.IPMaskVarP(p, name, "", value, usage)
return p
}
// IPMaskP is like IPMask, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPMaskP(name, shorthand string, value net.IPMask, usage string) *net.IPMask {
p := new(net.IPMask)
f.IPMaskVarP(p, name, shorthand, value, usage)
return p
}
// IPMask defines an net.IPMask flag with specified name, default value, and usage string.
// The return value is the address of an net.IPMask variable that stores the value of the flag.
func IPMask(name string, value net.IPMask, usage string) *net.IPMask {
return CommandLine.IPMaskP(name, "", value, usage)
}
// IPMaskP is like IP, but accepts a shorthand letter that can be used after a single dash.
func IPMaskP(name, shorthand string, value net.IPMask, usage string) *net.IPMask {
return CommandLine.IPMaskP(name, shorthand, value, usage)
}

98
vendor/github.com/spf13/pflag/ipnet.go generated vendored Normal file
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package pflag
import (
"fmt"
"net"
"strings"
)
// IPNet adapts net.IPNet for use as a flag.
type ipNetValue net.IPNet
func (ipnet ipNetValue) String() string {
n := net.IPNet(ipnet)
return n.String()
}
func (ipnet *ipNetValue) Set(value string) error {
_, n, err := net.ParseCIDR(strings.TrimSpace(value))
if err != nil {
return err
}
*ipnet = ipNetValue(*n)
return nil
}
func (*ipNetValue) Type() string {
return "ipNet"
}
func newIPNetValue(val net.IPNet, p *net.IPNet) *ipNetValue {
*p = val
return (*ipNetValue)(p)
}
func ipNetConv(sval string) (interface{}, error) {
_, n, err := net.ParseCIDR(strings.TrimSpace(sval))
if err == nil {
return *n, nil
}
return nil, fmt.Errorf("invalid string being converted to IPNet: %s", sval)
}
// GetIPNet return the net.IPNet value of a flag with the given name
func (f *FlagSet) GetIPNet(name string) (net.IPNet, error) {
val, err := f.getFlagType(name, "ipNet", ipNetConv)
if err != nil {
return net.IPNet{}, err
}
return val.(net.IPNet), nil
}
// IPNetVar defines an net.IPNet flag with specified name, default value, and usage string.
// The argument p points to an net.IPNet variable in which to store the value of the flag.
func (f *FlagSet) IPNetVar(p *net.IPNet, name string, value net.IPNet, usage string) {
f.VarP(newIPNetValue(value, p), name, "", usage)
}
// IPNetVarP is like IPNetVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPNetVarP(p *net.IPNet, name, shorthand string, value net.IPNet, usage string) {
f.VarP(newIPNetValue(value, p), name, shorthand, usage)
}
// IPNetVar defines an net.IPNet flag with specified name, default value, and usage string.
// The argument p points to an net.IPNet variable in which to store the value of the flag.
func IPNetVar(p *net.IPNet, name string, value net.IPNet, usage string) {
CommandLine.VarP(newIPNetValue(value, p), name, "", usage)
}
// IPNetVarP is like IPNetVar, but accepts a shorthand letter that can be used after a single dash.
func IPNetVarP(p *net.IPNet, name, shorthand string, value net.IPNet, usage string) {
CommandLine.VarP(newIPNetValue(value, p), name, shorthand, usage)
}
// IPNet defines an net.IPNet flag with specified name, default value, and usage string.
// The return value is the address of an net.IPNet variable that stores the value of the flag.
func (f *FlagSet) IPNet(name string, value net.IPNet, usage string) *net.IPNet {
p := new(net.IPNet)
f.IPNetVarP(p, name, "", value, usage)
return p
}
// IPNetP is like IPNet, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) IPNetP(name, shorthand string, value net.IPNet, usage string) *net.IPNet {
p := new(net.IPNet)
f.IPNetVarP(p, name, shorthand, value, usage)
return p
}
// IPNet defines an net.IPNet flag with specified name, default value, and usage string.
// The return value is the address of an net.IPNet variable that stores the value of the flag.
func IPNet(name string, value net.IPNet, usage string) *net.IPNet {
return CommandLine.IPNetP(name, "", value, usage)
}
// IPNetP is like IPNet, but accepts a shorthand letter that can be used after a single dash.
func IPNetP(name, shorthand string, value net.IPNet, usage string) *net.IPNet {
return CommandLine.IPNetP(name, shorthand, value, usage)
}

80
vendor/github.com/spf13/pflag/string.go generated vendored Normal file
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package pflag
// -- string Value
type stringValue string
func newStringValue(val string, p *string) *stringValue {
*p = val
return (*stringValue)(p)
}
func (s *stringValue) Set(val string) error {
*s = stringValue(val)
return nil
}
func (s *stringValue) Type() string {
return "string"
}
func (s *stringValue) String() string { return string(*s) }
func stringConv(sval string) (interface{}, error) {
return sval, nil
}
// GetString return the string value of a flag with the given name
func (f *FlagSet) GetString(name string) (string, error) {
val, err := f.getFlagType(name, "string", stringConv)
if err != nil {
return "", err
}
return val.(string), nil
}
// StringVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a string variable in which to store the value of the flag.
func (f *FlagSet) StringVar(p *string, name string, value string, usage string) {
f.VarP(newStringValue(value, p), name, "", usage)
}
// StringVarP is like StringVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringVarP(p *string, name, shorthand string, value string, usage string) {
f.VarP(newStringValue(value, p), name, shorthand, usage)
}
// StringVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a string variable in which to store the value of the flag.
func StringVar(p *string, name string, value string, usage string) {
CommandLine.VarP(newStringValue(value, p), name, "", usage)
}
// StringVarP is like StringVar, but accepts a shorthand letter that can be used after a single dash.
func StringVarP(p *string, name, shorthand string, value string, usage string) {
CommandLine.VarP(newStringValue(value, p), name, shorthand, usage)
}
// String defines a string flag with specified name, default value, and usage string.
// The return value is the address of a string variable that stores the value of the flag.
func (f *FlagSet) String(name string, value string, usage string) *string {
p := new(string)
f.StringVarP(p, name, "", value, usage)
return p
}
// StringP is like String, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringP(name, shorthand string, value string, usage string) *string {
p := new(string)
f.StringVarP(p, name, shorthand, value, usage)
return p
}
// String defines a string flag with specified name, default value, and usage string.
// The return value is the address of a string variable that stores the value of the flag.
func String(name string, value string, usage string) *string {
return CommandLine.StringP(name, "", value, usage)
}
// StringP is like String, but accepts a shorthand letter that can be used after a single dash.
func StringP(name, shorthand string, value string, usage string) *string {
return CommandLine.StringP(name, shorthand, value, usage)
}

129
vendor/github.com/spf13/pflag/string_array.go generated vendored Normal file
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package pflag
// -- stringArray Value
type stringArrayValue struct {
value *[]string
changed bool
}
func newStringArrayValue(val []string, p *[]string) *stringArrayValue {
ssv := new(stringArrayValue)
ssv.value = p
*ssv.value = val
return ssv
}
func (s *stringArrayValue) Set(val string) error {
if !s.changed {
*s.value = []string{val}
s.changed = true
} else {
*s.value = append(*s.value, val)
}
return nil
}
func (s *stringArrayValue) Append(val string) error {
*s.value = append(*s.value, val)
return nil
}
func (s *stringArrayValue) Replace(val []string) error {
out := make([]string, len(val))
for i, d := range val {
var err error
out[i] = d
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *stringArrayValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = d
}
return out
}
func (s *stringArrayValue) Type() string {
return "stringArray"
}
func (s *stringArrayValue) String() string {
str, _ := writeAsCSV(*s.value)
return "[" + str + "]"
}
func stringArrayConv(sval string) (interface{}, error) {
sval = sval[1 : len(sval)-1]
// An empty string would cause a array with one (empty) string
if len(sval) == 0 {
return []string{}, nil
}
return readAsCSV(sval)
}
// GetStringArray return the []string value of a flag with the given name
func (f *FlagSet) GetStringArray(name string) ([]string, error) {
val, err := f.getFlagType(name, "stringArray", stringArrayConv)
if err != nil {
return []string{}, err
}
return val.([]string), nil
}
// StringArrayVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a []string variable in which to store the values of the multiple flags.
// The value of each argument will not try to be separated by comma. Use a StringSlice for that.
func (f *FlagSet) StringArrayVar(p *[]string, name string, value []string, usage string) {
f.VarP(newStringArrayValue(value, p), name, "", usage)
}
// StringArrayVarP is like StringArrayVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringArrayVarP(p *[]string, name, shorthand string, value []string, usage string) {
f.VarP(newStringArrayValue(value, p), name, shorthand, usage)
}
// StringArrayVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a []string variable in which to store the value of the flag.
// The value of each argument will not try to be separated by comma. Use a StringSlice for that.
func StringArrayVar(p *[]string, name string, value []string, usage string) {
CommandLine.VarP(newStringArrayValue(value, p), name, "", usage)
}
// StringArrayVarP is like StringArrayVar, but accepts a shorthand letter that can be used after a single dash.
func StringArrayVarP(p *[]string, name, shorthand string, value []string, usage string) {
CommandLine.VarP(newStringArrayValue(value, p), name, shorthand, usage)
}
// StringArray defines a string flag with specified name, default value, and usage string.
// The return value is the address of a []string variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma. Use a StringSlice for that.
func (f *FlagSet) StringArray(name string, value []string, usage string) *[]string {
p := []string{}
f.StringArrayVarP(&p, name, "", value, usage)
return &p
}
// StringArrayP is like StringArray, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringArrayP(name, shorthand string, value []string, usage string) *[]string {
p := []string{}
f.StringArrayVarP(&p, name, shorthand, value, usage)
return &p
}
// StringArray defines a string flag with specified name, default value, and usage string.
// The return value is the address of a []string variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma. Use a StringSlice for that.
func StringArray(name string, value []string, usage string) *[]string {
return CommandLine.StringArrayP(name, "", value, usage)
}
// StringArrayP is like StringArray, but accepts a shorthand letter that can be used after a single dash.
func StringArrayP(name, shorthand string, value []string, usage string) *[]string {
return CommandLine.StringArrayP(name, shorthand, value, usage)
}

163
vendor/github.com/spf13/pflag/string_slice.go generated vendored Normal file
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package pflag
import (
"bytes"
"encoding/csv"
"strings"
)
// -- stringSlice Value
type stringSliceValue struct {
value *[]string
changed bool
}
func newStringSliceValue(val []string, p *[]string) *stringSliceValue {
ssv := new(stringSliceValue)
ssv.value = p
*ssv.value = val
return ssv
}
func readAsCSV(val string) ([]string, error) {
if val == "" {
return []string{}, nil
}
stringReader := strings.NewReader(val)
csvReader := csv.NewReader(stringReader)
return csvReader.Read()
}
func writeAsCSV(vals []string) (string, error) {
b := &bytes.Buffer{}
w := csv.NewWriter(b)
err := w.Write(vals)
if err != nil {
return "", err
}
w.Flush()
return strings.TrimSuffix(b.String(), "\n"), nil
}
func (s *stringSliceValue) Set(val string) error {
v, err := readAsCSV(val)
if err != nil {
return err
}
if !s.changed {
*s.value = v
} else {
*s.value = append(*s.value, v...)
}
s.changed = true
return nil
}
func (s *stringSliceValue) Type() string {
return "stringSlice"
}
func (s *stringSliceValue) String() string {
str, _ := writeAsCSV(*s.value)
return "[" + str + "]"
}
func (s *stringSliceValue) Append(val string) error {
*s.value = append(*s.value, val)
return nil
}
func (s *stringSliceValue) Replace(val []string) error {
*s.value = val
return nil
}
func (s *stringSliceValue) GetSlice() []string {
return *s.value
}
func stringSliceConv(sval string) (interface{}, error) {
sval = sval[1 : len(sval)-1]
// An empty string would cause a slice with one (empty) string
if len(sval) == 0 {
return []string{}, nil
}
return readAsCSV(sval)
}
// GetStringSlice return the []string value of a flag with the given name
func (f *FlagSet) GetStringSlice(name string) ([]string, error) {
val, err := f.getFlagType(name, "stringSlice", stringSliceConv)
if err != nil {
return []string{}, err
}
return val.([]string), nil
}
// StringSliceVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a []string variable in which to store the value of the flag.
// Compared to StringArray flags, StringSlice flags take comma-separated value as arguments and split them accordingly.
// For example:
// --ss="v1,v2" --ss="v3"
// will result in
// []string{"v1", "v2", "v3"}
func (f *FlagSet) StringSliceVar(p *[]string, name string, value []string, usage string) {
f.VarP(newStringSliceValue(value, p), name, "", usage)
}
// StringSliceVarP is like StringSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringSliceVarP(p *[]string, name, shorthand string, value []string, usage string) {
f.VarP(newStringSliceValue(value, p), name, shorthand, usage)
}
// StringSliceVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a []string variable in which to store the value of the flag.
// Compared to StringArray flags, StringSlice flags take comma-separated value as arguments and split them accordingly.
// For example:
// --ss="v1,v2" --ss="v3"
// will result in
// []string{"v1", "v2", "v3"}
func StringSliceVar(p *[]string, name string, value []string, usage string) {
CommandLine.VarP(newStringSliceValue(value, p), name, "", usage)
}
// StringSliceVarP is like StringSliceVar, but accepts a shorthand letter that can be used after a single dash.
func StringSliceVarP(p *[]string, name, shorthand string, value []string, usage string) {
CommandLine.VarP(newStringSliceValue(value, p), name, shorthand, usage)
}
// StringSlice defines a string flag with specified name, default value, and usage string.
// The return value is the address of a []string variable that stores the value of the flag.
// Compared to StringArray flags, StringSlice flags take comma-separated value as arguments and split them accordingly.
// For example:
// --ss="v1,v2" --ss="v3"
// will result in
// []string{"v1", "v2", "v3"}
func (f *FlagSet) StringSlice(name string, value []string, usage string) *[]string {
p := []string{}
f.StringSliceVarP(&p, name, "", value, usage)
return &p
}
// StringSliceP is like StringSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringSliceP(name, shorthand string, value []string, usage string) *[]string {
p := []string{}
f.StringSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// StringSlice defines a string flag with specified name, default value, and usage string.
// The return value is the address of a []string variable that stores the value of the flag.
// Compared to StringArray flags, StringSlice flags take comma-separated value as arguments and split them accordingly.
// For example:
// --ss="v1,v2" --ss="v3"
// will result in
// []string{"v1", "v2", "v3"}
func StringSlice(name string, value []string, usage string) *[]string {
return CommandLine.StringSliceP(name, "", value, usage)
}
// StringSliceP is like StringSlice, but accepts a shorthand letter that can be used after a single dash.
func StringSliceP(name, shorthand string, value []string, usage string) *[]string {
return CommandLine.StringSliceP(name, shorthand, value, usage)
}

149
vendor/github.com/spf13/pflag/string_to_int.go generated vendored Normal file
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package pflag
import (
"bytes"
"fmt"
"strconv"
"strings"
)
// -- stringToInt Value
type stringToIntValue struct {
value *map[string]int
changed bool
}
func newStringToIntValue(val map[string]int, p *map[string]int) *stringToIntValue {
ssv := new(stringToIntValue)
ssv.value = p
*ssv.value = val
return ssv
}
// Format: a=1,b=2
func (s *stringToIntValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make(map[string]int, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return fmt.Errorf("%s must be formatted as key=value", pair)
}
var err error
out[kv[0]], err = strconv.Atoi(kv[1])
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
for k, v := range out {
(*s.value)[k] = v
}
}
s.changed = true
return nil
}
func (s *stringToIntValue) Type() string {
return "stringToInt"
}
func (s *stringToIntValue) String() string {
var buf bytes.Buffer
i := 0
for k, v := range *s.value {
if i > 0 {
buf.WriteRune(',')
}
buf.WriteString(k)
buf.WriteRune('=')
buf.WriteString(strconv.Itoa(v))
i++
}
return "[" + buf.String() + "]"
}
func stringToIntConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// An empty string would cause an empty map
if len(val) == 0 {
return map[string]int{}, nil
}
ss := strings.Split(val, ",")
out := make(map[string]int, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return nil, fmt.Errorf("%s must be formatted as key=value", pair)
}
var err error
out[kv[0]], err = strconv.Atoi(kv[1])
if err != nil {
return nil, err
}
}
return out, nil
}
// GetStringToInt return the map[string]int value of a flag with the given name
func (f *FlagSet) GetStringToInt(name string) (map[string]int, error) {
val, err := f.getFlagType(name, "stringToInt", stringToIntConv)
if err != nil {
return map[string]int{}, err
}
return val.(map[string]int), nil
}
// StringToIntVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a map[string]int variable in which to store the values of the multiple flags.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToIntVar(p *map[string]int, name string, value map[string]int, usage string) {
f.VarP(newStringToIntValue(value, p), name, "", usage)
}
// StringToIntVarP is like StringToIntVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToIntVarP(p *map[string]int, name, shorthand string, value map[string]int, usage string) {
f.VarP(newStringToIntValue(value, p), name, shorthand, usage)
}
// StringToIntVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a map[string]int variable in which to store the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToIntVar(p *map[string]int, name string, value map[string]int, usage string) {
CommandLine.VarP(newStringToIntValue(value, p), name, "", usage)
}
// StringToIntVarP is like StringToIntVar, but accepts a shorthand letter that can be used after a single dash.
func StringToIntVarP(p *map[string]int, name, shorthand string, value map[string]int, usage string) {
CommandLine.VarP(newStringToIntValue(value, p), name, shorthand, usage)
}
// StringToInt defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]int variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToInt(name string, value map[string]int, usage string) *map[string]int {
p := map[string]int{}
f.StringToIntVarP(&p, name, "", value, usage)
return &p
}
// StringToIntP is like StringToInt, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToIntP(name, shorthand string, value map[string]int, usage string) *map[string]int {
p := map[string]int{}
f.StringToIntVarP(&p, name, shorthand, value, usage)
return &p
}
// StringToInt defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]int variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToInt(name string, value map[string]int, usage string) *map[string]int {
return CommandLine.StringToIntP(name, "", value, usage)
}
// StringToIntP is like StringToInt, but accepts a shorthand letter that can be used after a single dash.
func StringToIntP(name, shorthand string, value map[string]int, usage string) *map[string]int {
return CommandLine.StringToIntP(name, shorthand, value, usage)
}

149
vendor/github.com/spf13/pflag/string_to_int64.go generated vendored Normal file
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package pflag
import (
"bytes"
"fmt"
"strconv"
"strings"
)
// -- stringToInt64 Value
type stringToInt64Value struct {
value *map[string]int64
changed bool
}
func newStringToInt64Value(val map[string]int64, p *map[string]int64) *stringToInt64Value {
ssv := new(stringToInt64Value)
ssv.value = p
*ssv.value = val
return ssv
}
// Format: a=1,b=2
func (s *stringToInt64Value) Set(val string) error {
ss := strings.Split(val, ",")
out := make(map[string]int64, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return fmt.Errorf("%s must be formatted as key=value", pair)
}
var err error
out[kv[0]], err = strconv.ParseInt(kv[1], 10, 64)
if err != nil {
return err
}
}
if !s.changed {
*s.value = out
} else {
for k, v := range out {
(*s.value)[k] = v
}
}
s.changed = true
return nil
}
func (s *stringToInt64Value) Type() string {
return "stringToInt64"
}
func (s *stringToInt64Value) String() string {
var buf bytes.Buffer
i := 0
for k, v := range *s.value {
if i > 0 {
buf.WriteRune(',')
}
buf.WriteString(k)
buf.WriteRune('=')
buf.WriteString(strconv.FormatInt(v, 10))
i++
}
return "[" + buf.String() + "]"
}
func stringToInt64Conv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// An empty string would cause an empty map
if len(val) == 0 {
return map[string]int64{}, nil
}
ss := strings.Split(val, ",")
out := make(map[string]int64, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return nil, fmt.Errorf("%s must be formatted as key=value", pair)
}
var err error
out[kv[0]], err = strconv.ParseInt(kv[1], 10, 64)
if err != nil {
return nil, err
}
}
return out, nil
}
// GetStringToInt64 return the map[string]int64 value of a flag with the given name
func (f *FlagSet) GetStringToInt64(name string) (map[string]int64, error) {
val, err := f.getFlagType(name, "stringToInt64", stringToInt64Conv)
if err != nil {
return map[string]int64{}, err
}
return val.(map[string]int64), nil
}
// StringToInt64Var defines a string flag with specified name, default value, and usage string.
// The argument p point64s to a map[string]int64 variable in which to store the values of the multiple flags.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToInt64Var(p *map[string]int64, name string, value map[string]int64, usage string) {
f.VarP(newStringToInt64Value(value, p), name, "", usage)
}
// StringToInt64VarP is like StringToInt64Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToInt64VarP(p *map[string]int64, name, shorthand string, value map[string]int64, usage string) {
f.VarP(newStringToInt64Value(value, p), name, shorthand, usage)
}
// StringToInt64Var defines a string flag with specified name, default value, and usage string.
// The argument p point64s to a map[string]int64 variable in which to store the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToInt64Var(p *map[string]int64, name string, value map[string]int64, usage string) {
CommandLine.VarP(newStringToInt64Value(value, p), name, "", usage)
}
// StringToInt64VarP is like StringToInt64Var, but accepts a shorthand letter that can be used after a single dash.
func StringToInt64VarP(p *map[string]int64, name, shorthand string, value map[string]int64, usage string) {
CommandLine.VarP(newStringToInt64Value(value, p), name, shorthand, usage)
}
// StringToInt64 defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]int64 variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToInt64(name string, value map[string]int64, usage string) *map[string]int64 {
p := map[string]int64{}
f.StringToInt64VarP(&p, name, "", value, usage)
return &p
}
// StringToInt64P is like StringToInt64, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToInt64P(name, shorthand string, value map[string]int64, usage string) *map[string]int64 {
p := map[string]int64{}
f.StringToInt64VarP(&p, name, shorthand, value, usage)
return &p
}
// StringToInt64 defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]int64 variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToInt64(name string, value map[string]int64, usage string) *map[string]int64 {
return CommandLine.StringToInt64P(name, "", value, usage)
}
// StringToInt64P is like StringToInt64, but accepts a shorthand letter that can be used after a single dash.
func StringToInt64P(name, shorthand string, value map[string]int64, usage string) *map[string]int64 {
return CommandLine.StringToInt64P(name, shorthand, value, usage)
}

160
vendor/github.com/spf13/pflag/string_to_string.go generated vendored Normal file
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package pflag
import (
"bytes"
"encoding/csv"
"fmt"
"strings"
)
// -- stringToString Value
type stringToStringValue struct {
value *map[string]string
changed bool
}
func newStringToStringValue(val map[string]string, p *map[string]string) *stringToStringValue {
ssv := new(stringToStringValue)
ssv.value = p
*ssv.value = val
return ssv
}
// Format: a=1,b=2
func (s *stringToStringValue) Set(val string) error {
var ss []string
n := strings.Count(val, "=")
switch n {
case 0:
return fmt.Errorf("%s must be formatted as key=value", val)
case 1:
ss = append(ss, strings.Trim(val, `"`))
default:
r := csv.NewReader(strings.NewReader(val))
var err error
ss, err = r.Read()
if err != nil {
return err
}
}
out := make(map[string]string, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return fmt.Errorf("%s must be formatted as key=value", pair)
}
out[kv[0]] = kv[1]
}
if !s.changed {
*s.value = out
} else {
for k, v := range out {
(*s.value)[k] = v
}
}
s.changed = true
return nil
}
func (s *stringToStringValue) Type() string {
return "stringToString"
}
func (s *stringToStringValue) String() string {
records := make([]string, 0, len(*s.value)>>1)
for k, v := range *s.value {
records = append(records, k+"="+v)
}
var buf bytes.Buffer
w := csv.NewWriter(&buf)
if err := w.Write(records); err != nil {
panic(err)
}
w.Flush()
return "[" + strings.TrimSpace(buf.String()) + "]"
}
func stringToStringConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// An empty string would cause an empty map
if len(val) == 0 {
return map[string]string{}, nil
}
r := csv.NewReader(strings.NewReader(val))
ss, err := r.Read()
if err != nil {
return nil, err
}
out := make(map[string]string, len(ss))
for _, pair := range ss {
kv := strings.SplitN(pair, "=", 2)
if len(kv) != 2 {
return nil, fmt.Errorf("%s must be formatted as key=value", pair)
}
out[kv[0]] = kv[1]
}
return out, nil
}
// GetStringToString return the map[string]string value of a flag with the given name
func (f *FlagSet) GetStringToString(name string) (map[string]string, error) {
val, err := f.getFlagType(name, "stringToString", stringToStringConv)
if err != nil {
return map[string]string{}, err
}
return val.(map[string]string), nil
}
// StringToStringVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a map[string]string variable in which to store the values of the multiple flags.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToStringVar(p *map[string]string, name string, value map[string]string, usage string) {
f.VarP(newStringToStringValue(value, p), name, "", usage)
}
// StringToStringVarP is like StringToStringVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToStringVarP(p *map[string]string, name, shorthand string, value map[string]string, usage string) {
f.VarP(newStringToStringValue(value, p), name, shorthand, usage)
}
// StringToStringVar defines a string flag with specified name, default value, and usage string.
// The argument p points to a map[string]string variable in which to store the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToStringVar(p *map[string]string, name string, value map[string]string, usage string) {
CommandLine.VarP(newStringToStringValue(value, p), name, "", usage)
}
// StringToStringVarP is like StringToStringVar, but accepts a shorthand letter that can be used after a single dash.
func StringToStringVarP(p *map[string]string, name, shorthand string, value map[string]string, usage string) {
CommandLine.VarP(newStringToStringValue(value, p), name, shorthand, usage)
}
// StringToString defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]string variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func (f *FlagSet) StringToString(name string, value map[string]string, usage string) *map[string]string {
p := map[string]string{}
f.StringToStringVarP(&p, name, "", value, usage)
return &p
}
// StringToStringP is like StringToString, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) StringToStringP(name, shorthand string, value map[string]string, usage string) *map[string]string {
p := map[string]string{}
f.StringToStringVarP(&p, name, shorthand, value, usage)
return &p
}
// StringToString defines a string flag with specified name, default value, and usage string.
// The return value is the address of a map[string]string variable that stores the value of the flag.
// The value of each argument will not try to be separated by comma
func StringToString(name string, value map[string]string, usage string) *map[string]string {
return CommandLine.StringToStringP(name, "", value, usage)
}
// StringToStringP is like StringToString, but accepts a shorthand letter that can be used after a single dash.
func StringToStringP(name, shorthand string, value map[string]string, usage string) *map[string]string {
return CommandLine.StringToStringP(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- uint Value
type uintValue uint
func newUintValue(val uint, p *uint) *uintValue {
*p = val
return (*uintValue)(p)
}
func (i *uintValue) Set(s string) error {
v, err := strconv.ParseUint(s, 0, 64)
*i = uintValue(v)
return err
}
func (i *uintValue) Type() string {
return "uint"
}
func (i *uintValue) String() string { return strconv.FormatUint(uint64(*i), 10) }
func uintConv(sval string) (interface{}, error) {
v, err := strconv.ParseUint(sval, 0, 0)
if err != nil {
return 0, err
}
return uint(v), nil
}
// GetUint return the uint value of a flag with the given name
func (f *FlagSet) GetUint(name string) (uint, error) {
val, err := f.getFlagType(name, "uint", uintConv)
if err != nil {
return 0, err
}
return val.(uint), nil
}
// UintVar defines a uint flag with specified name, default value, and usage string.
// The argument p points to a uint variable in which to store the value of the flag.
func (f *FlagSet) UintVar(p *uint, name string, value uint, usage string) {
f.VarP(newUintValue(value, p), name, "", usage)
}
// UintVarP is like UintVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) UintVarP(p *uint, name, shorthand string, value uint, usage string) {
f.VarP(newUintValue(value, p), name, shorthand, usage)
}
// UintVar defines a uint flag with specified name, default value, and usage string.
// The argument p points to a uint variable in which to store the value of the flag.
func UintVar(p *uint, name string, value uint, usage string) {
CommandLine.VarP(newUintValue(value, p), name, "", usage)
}
// UintVarP is like UintVar, but accepts a shorthand letter that can be used after a single dash.
func UintVarP(p *uint, name, shorthand string, value uint, usage string) {
CommandLine.VarP(newUintValue(value, p), name, shorthand, usage)
}
// Uint defines a uint flag with specified name, default value, and usage string.
// The return value is the address of a uint variable that stores the value of the flag.
func (f *FlagSet) Uint(name string, value uint, usage string) *uint {
p := new(uint)
f.UintVarP(p, name, "", value, usage)
return p
}
// UintP is like Uint, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) UintP(name, shorthand string, value uint, usage string) *uint {
p := new(uint)
f.UintVarP(p, name, shorthand, value, usage)
return p
}
// Uint defines a uint flag with specified name, default value, and usage string.
// The return value is the address of a uint variable that stores the value of the flag.
func Uint(name string, value uint, usage string) *uint {
return CommandLine.UintP(name, "", value, usage)
}
// UintP is like Uint, but accepts a shorthand letter that can be used after a single dash.
func UintP(name, shorthand string, value uint, usage string) *uint {
return CommandLine.UintP(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- uint16 value
type uint16Value uint16
func newUint16Value(val uint16, p *uint16) *uint16Value {
*p = val
return (*uint16Value)(p)
}
func (i *uint16Value) Set(s string) error {
v, err := strconv.ParseUint(s, 0, 16)
*i = uint16Value(v)
return err
}
func (i *uint16Value) Type() string {
return "uint16"
}
func (i *uint16Value) String() string { return strconv.FormatUint(uint64(*i), 10) }
func uint16Conv(sval string) (interface{}, error) {
v, err := strconv.ParseUint(sval, 0, 16)
if err != nil {
return 0, err
}
return uint16(v), nil
}
// GetUint16 return the uint16 value of a flag with the given name
func (f *FlagSet) GetUint16(name string) (uint16, error) {
val, err := f.getFlagType(name, "uint16", uint16Conv)
if err != nil {
return 0, err
}
return val.(uint16), nil
}
// Uint16Var defines a uint flag with specified name, default value, and usage string.
// The argument p points to a uint variable in which to store the value of the flag.
func (f *FlagSet) Uint16Var(p *uint16, name string, value uint16, usage string) {
f.VarP(newUint16Value(value, p), name, "", usage)
}
// Uint16VarP is like Uint16Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint16VarP(p *uint16, name, shorthand string, value uint16, usage string) {
f.VarP(newUint16Value(value, p), name, shorthand, usage)
}
// Uint16Var defines a uint flag with specified name, default value, and usage string.
// The argument p points to a uint variable in which to store the value of the flag.
func Uint16Var(p *uint16, name string, value uint16, usage string) {
CommandLine.VarP(newUint16Value(value, p), name, "", usage)
}
// Uint16VarP is like Uint16Var, but accepts a shorthand letter that can be used after a single dash.
func Uint16VarP(p *uint16, name, shorthand string, value uint16, usage string) {
CommandLine.VarP(newUint16Value(value, p), name, shorthand, usage)
}
// Uint16 defines a uint flag with specified name, default value, and usage string.
// The return value is the address of a uint variable that stores the value of the flag.
func (f *FlagSet) Uint16(name string, value uint16, usage string) *uint16 {
p := new(uint16)
f.Uint16VarP(p, name, "", value, usage)
return p
}
// Uint16P is like Uint16, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint16P(name, shorthand string, value uint16, usage string) *uint16 {
p := new(uint16)
f.Uint16VarP(p, name, shorthand, value, usage)
return p
}
// Uint16 defines a uint flag with specified name, default value, and usage string.
// The return value is the address of a uint variable that stores the value of the flag.
func Uint16(name string, value uint16, usage string) *uint16 {
return CommandLine.Uint16P(name, "", value, usage)
}
// Uint16P is like Uint16, but accepts a shorthand letter that can be used after a single dash.
func Uint16P(name, shorthand string, value uint16, usage string) *uint16 {
return CommandLine.Uint16P(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- uint32 value
type uint32Value uint32
func newUint32Value(val uint32, p *uint32) *uint32Value {
*p = val
return (*uint32Value)(p)
}
func (i *uint32Value) Set(s string) error {
v, err := strconv.ParseUint(s, 0, 32)
*i = uint32Value(v)
return err
}
func (i *uint32Value) Type() string {
return "uint32"
}
func (i *uint32Value) String() string { return strconv.FormatUint(uint64(*i), 10) }
func uint32Conv(sval string) (interface{}, error) {
v, err := strconv.ParseUint(sval, 0, 32)
if err != nil {
return 0, err
}
return uint32(v), nil
}
// GetUint32 return the uint32 value of a flag with the given name
func (f *FlagSet) GetUint32(name string) (uint32, error) {
val, err := f.getFlagType(name, "uint32", uint32Conv)
if err != nil {
return 0, err
}
return val.(uint32), nil
}
// Uint32Var defines a uint32 flag with specified name, default value, and usage string.
// The argument p points to a uint32 variable in which to store the value of the flag.
func (f *FlagSet) Uint32Var(p *uint32, name string, value uint32, usage string) {
f.VarP(newUint32Value(value, p), name, "", usage)
}
// Uint32VarP is like Uint32Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint32VarP(p *uint32, name, shorthand string, value uint32, usage string) {
f.VarP(newUint32Value(value, p), name, shorthand, usage)
}
// Uint32Var defines a uint32 flag with specified name, default value, and usage string.
// The argument p points to a uint32 variable in which to store the value of the flag.
func Uint32Var(p *uint32, name string, value uint32, usage string) {
CommandLine.VarP(newUint32Value(value, p), name, "", usage)
}
// Uint32VarP is like Uint32Var, but accepts a shorthand letter that can be used after a single dash.
func Uint32VarP(p *uint32, name, shorthand string, value uint32, usage string) {
CommandLine.VarP(newUint32Value(value, p), name, shorthand, usage)
}
// Uint32 defines a uint32 flag with specified name, default value, and usage string.
// The return value is the address of a uint32 variable that stores the value of the flag.
func (f *FlagSet) Uint32(name string, value uint32, usage string) *uint32 {
p := new(uint32)
f.Uint32VarP(p, name, "", value, usage)
return p
}
// Uint32P is like Uint32, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint32P(name, shorthand string, value uint32, usage string) *uint32 {
p := new(uint32)
f.Uint32VarP(p, name, shorthand, value, usage)
return p
}
// Uint32 defines a uint32 flag with specified name, default value, and usage string.
// The return value is the address of a uint32 variable that stores the value of the flag.
func Uint32(name string, value uint32, usage string) *uint32 {
return CommandLine.Uint32P(name, "", value, usage)
}
// Uint32P is like Uint32, but accepts a shorthand letter that can be used after a single dash.
func Uint32P(name, shorthand string, value uint32, usage string) *uint32 {
return CommandLine.Uint32P(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- uint64 Value
type uint64Value uint64
func newUint64Value(val uint64, p *uint64) *uint64Value {
*p = val
return (*uint64Value)(p)
}
func (i *uint64Value) Set(s string) error {
v, err := strconv.ParseUint(s, 0, 64)
*i = uint64Value(v)
return err
}
func (i *uint64Value) Type() string {
return "uint64"
}
func (i *uint64Value) String() string { return strconv.FormatUint(uint64(*i), 10) }
func uint64Conv(sval string) (interface{}, error) {
v, err := strconv.ParseUint(sval, 0, 64)
if err != nil {
return 0, err
}
return uint64(v), nil
}
// GetUint64 return the uint64 value of a flag with the given name
func (f *FlagSet) GetUint64(name string) (uint64, error) {
val, err := f.getFlagType(name, "uint64", uint64Conv)
if err != nil {
return 0, err
}
return val.(uint64), nil
}
// Uint64Var defines a uint64 flag with specified name, default value, and usage string.
// The argument p points to a uint64 variable in which to store the value of the flag.
func (f *FlagSet) Uint64Var(p *uint64, name string, value uint64, usage string) {
f.VarP(newUint64Value(value, p), name, "", usage)
}
// Uint64VarP is like Uint64Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint64VarP(p *uint64, name, shorthand string, value uint64, usage string) {
f.VarP(newUint64Value(value, p), name, shorthand, usage)
}
// Uint64Var defines a uint64 flag with specified name, default value, and usage string.
// The argument p points to a uint64 variable in which to store the value of the flag.
func Uint64Var(p *uint64, name string, value uint64, usage string) {
CommandLine.VarP(newUint64Value(value, p), name, "", usage)
}
// Uint64VarP is like Uint64Var, but accepts a shorthand letter that can be used after a single dash.
func Uint64VarP(p *uint64, name, shorthand string, value uint64, usage string) {
CommandLine.VarP(newUint64Value(value, p), name, shorthand, usage)
}
// Uint64 defines a uint64 flag with specified name, default value, and usage string.
// The return value is the address of a uint64 variable that stores the value of the flag.
func (f *FlagSet) Uint64(name string, value uint64, usage string) *uint64 {
p := new(uint64)
f.Uint64VarP(p, name, "", value, usage)
return p
}
// Uint64P is like Uint64, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint64P(name, shorthand string, value uint64, usage string) *uint64 {
p := new(uint64)
f.Uint64VarP(p, name, shorthand, value, usage)
return p
}
// Uint64 defines a uint64 flag with specified name, default value, and usage string.
// The return value is the address of a uint64 variable that stores the value of the flag.
func Uint64(name string, value uint64, usage string) *uint64 {
return CommandLine.Uint64P(name, "", value, usage)
}
// Uint64P is like Uint64, but accepts a shorthand letter that can be used after a single dash.
func Uint64P(name, shorthand string, value uint64, usage string) *uint64 {
return CommandLine.Uint64P(name, shorthand, value, usage)
}

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package pflag
import "strconv"
// -- uint8 Value
type uint8Value uint8
func newUint8Value(val uint8, p *uint8) *uint8Value {
*p = val
return (*uint8Value)(p)
}
func (i *uint8Value) Set(s string) error {
v, err := strconv.ParseUint(s, 0, 8)
*i = uint8Value(v)
return err
}
func (i *uint8Value) Type() string {
return "uint8"
}
func (i *uint8Value) String() string { return strconv.FormatUint(uint64(*i), 10) }
func uint8Conv(sval string) (interface{}, error) {
v, err := strconv.ParseUint(sval, 0, 8)
if err != nil {
return 0, err
}
return uint8(v), nil
}
// GetUint8 return the uint8 value of a flag with the given name
func (f *FlagSet) GetUint8(name string) (uint8, error) {
val, err := f.getFlagType(name, "uint8", uint8Conv)
if err != nil {
return 0, err
}
return val.(uint8), nil
}
// Uint8Var defines a uint8 flag with specified name, default value, and usage string.
// The argument p points to a uint8 variable in which to store the value of the flag.
func (f *FlagSet) Uint8Var(p *uint8, name string, value uint8, usage string) {
f.VarP(newUint8Value(value, p), name, "", usage)
}
// Uint8VarP is like Uint8Var, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint8VarP(p *uint8, name, shorthand string, value uint8, usage string) {
f.VarP(newUint8Value(value, p), name, shorthand, usage)
}
// Uint8Var defines a uint8 flag with specified name, default value, and usage string.
// The argument p points to a uint8 variable in which to store the value of the flag.
func Uint8Var(p *uint8, name string, value uint8, usage string) {
CommandLine.VarP(newUint8Value(value, p), name, "", usage)
}
// Uint8VarP is like Uint8Var, but accepts a shorthand letter that can be used after a single dash.
func Uint8VarP(p *uint8, name, shorthand string, value uint8, usage string) {
CommandLine.VarP(newUint8Value(value, p), name, shorthand, usage)
}
// Uint8 defines a uint8 flag with specified name, default value, and usage string.
// The return value is the address of a uint8 variable that stores the value of the flag.
func (f *FlagSet) Uint8(name string, value uint8, usage string) *uint8 {
p := new(uint8)
f.Uint8VarP(p, name, "", value, usage)
return p
}
// Uint8P is like Uint8, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) Uint8P(name, shorthand string, value uint8, usage string) *uint8 {
p := new(uint8)
f.Uint8VarP(p, name, shorthand, value, usage)
return p
}
// Uint8 defines a uint8 flag with specified name, default value, and usage string.
// The return value is the address of a uint8 variable that stores the value of the flag.
func Uint8(name string, value uint8, usage string) *uint8 {
return CommandLine.Uint8P(name, "", value, usage)
}
// Uint8P is like Uint8, but accepts a shorthand letter that can be used after a single dash.
func Uint8P(name, shorthand string, value uint8, usage string) *uint8 {
return CommandLine.Uint8P(name, shorthand, value, usage)
}

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vendor/github.com/spf13/pflag/uint_slice.go generated vendored Normal file
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package pflag
import (
"fmt"
"strconv"
"strings"
)
// -- uintSlice Value
type uintSliceValue struct {
value *[]uint
changed bool
}
func newUintSliceValue(val []uint, p *[]uint) *uintSliceValue {
uisv := new(uintSliceValue)
uisv.value = p
*uisv.value = val
return uisv
}
func (s *uintSliceValue) Set(val string) error {
ss := strings.Split(val, ",")
out := make([]uint, len(ss))
for i, d := range ss {
u, err := strconv.ParseUint(d, 10, 0)
if err != nil {
return err
}
out[i] = uint(u)
}
if !s.changed {
*s.value = out
} else {
*s.value = append(*s.value, out...)
}
s.changed = true
return nil
}
func (s *uintSliceValue) Type() string {
return "uintSlice"
}
func (s *uintSliceValue) String() string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = fmt.Sprintf("%d", d)
}
return "[" + strings.Join(out, ",") + "]"
}
func (s *uintSliceValue) fromString(val string) (uint, error) {
t, err := strconv.ParseUint(val, 10, 0)
if err != nil {
return 0, err
}
return uint(t), nil
}
func (s *uintSliceValue) toString(val uint) string {
return fmt.Sprintf("%d", val)
}
func (s *uintSliceValue) Append(val string) error {
i, err := s.fromString(val)
if err != nil {
return err
}
*s.value = append(*s.value, i)
return nil
}
func (s *uintSliceValue) Replace(val []string) error {
out := make([]uint, len(val))
for i, d := range val {
var err error
out[i], err = s.fromString(d)
if err != nil {
return err
}
}
*s.value = out
return nil
}
func (s *uintSliceValue) GetSlice() []string {
out := make([]string, len(*s.value))
for i, d := range *s.value {
out[i] = s.toString(d)
}
return out
}
func uintSliceConv(val string) (interface{}, error) {
val = strings.Trim(val, "[]")
// Empty string would cause a slice with one (empty) entry
if len(val) == 0 {
return []uint{}, nil
}
ss := strings.Split(val, ",")
out := make([]uint, len(ss))
for i, d := range ss {
u, err := strconv.ParseUint(d, 10, 0)
if err != nil {
return nil, err
}
out[i] = uint(u)
}
return out, nil
}
// GetUintSlice returns the []uint value of a flag with the given name.
func (f *FlagSet) GetUintSlice(name string) ([]uint, error) {
val, err := f.getFlagType(name, "uintSlice", uintSliceConv)
if err != nil {
return []uint{}, err
}
return val.([]uint), nil
}
// UintSliceVar defines a uintSlice flag with specified name, default value, and usage string.
// The argument p points to a []uint variable in which to store the value of the flag.
func (f *FlagSet) UintSliceVar(p *[]uint, name string, value []uint, usage string) {
f.VarP(newUintSliceValue(value, p), name, "", usage)
}
// UintSliceVarP is like UintSliceVar, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) UintSliceVarP(p *[]uint, name, shorthand string, value []uint, usage string) {
f.VarP(newUintSliceValue(value, p), name, shorthand, usage)
}
// UintSliceVar defines a uint[] flag with specified name, default value, and usage string.
// The argument p points to a uint[] variable in which to store the value of the flag.
func UintSliceVar(p *[]uint, name string, value []uint, usage string) {
CommandLine.VarP(newUintSliceValue(value, p), name, "", usage)
}
// UintSliceVarP is like the UintSliceVar, but accepts a shorthand letter that can be used after a single dash.
func UintSliceVarP(p *[]uint, name, shorthand string, value []uint, usage string) {
CommandLine.VarP(newUintSliceValue(value, p), name, shorthand, usage)
}
// UintSlice defines a []uint flag with specified name, default value, and usage string.
// The return value is the address of a []uint variable that stores the value of the flag.
func (f *FlagSet) UintSlice(name string, value []uint, usage string) *[]uint {
p := []uint{}
f.UintSliceVarP(&p, name, "", value, usage)
return &p
}
// UintSliceP is like UintSlice, but accepts a shorthand letter that can be used after a single dash.
func (f *FlagSet) UintSliceP(name, shorthand string, value []uint, usage string) *[]uint {
p := []uint{}
f.UintSliceVarP(&p, name, shorthand, value, usage)
return &p
}
// UintSlice defines a []uint flag with specified name, default value, and usage string.
// The return value is the address of a []uint variable that stores the value of the flag.
func UintSlice(name string, value []uint, usage string) *[]uint {
return CommandLine.UintSliceP(name, "", value, usage)
}
// UintSliceP is like UintSlice, but accepts a shorthand letter that can be used after a single dash.
func UintSliceP(name, shorthand string, value []uint, usage string) *[]uint {
return CommandLine.UintSliceP(name, shorthand, value, usage)
}

18
vendor/github.com/spf13/viper/.editorconfig generated vendored Normal file
View file

@ -0,0 +1,18 @@
root = true
[*]
charset = utf-8
end_of_line = lf
indent_size = 4
indent_style = space
insert_final_newline = true
trim_trailing_whitespace = true
[*.go]
indent_style = tab
[{Makefile,*.mk}]
indent_style = tab
[*.nix]
indent_size = 2

4
vendor/github.com/spf13/viper/.envrc generated vendored Normal file
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@ -0,0 +1,4 @@
if ! has nix_direnv_version || ! nix_direnv_version 2.3.0; then
source_url "https://raw.githubusercontent.com/nix-community/nix-direnv/2.3.0/direnvrc" "sha256-Dmd+j63L84wuzgyjITIfSxSD57Tx7v51DMxVZOsiUD8="
fi
use flake . --impure

8
vendor/github.com/spf13/viper/.gitignore generated vendored Normal file
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@ -0,0 +1,8 @@
/.devenv/
/.direnv/
/.idea/
/.pre-commit-config.yaml
/bin/
/build/
/var/
/vendor/

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