terraform-provider-gitea/vendor/github.com/mitchellh/cli/cli.go

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2022-04-03 04:07:16 +00:00
package cli
import (
"fmt"
"io"
"io/ioutil"
"os"
"regexp"
"sort"
"strings"
"sync"
"text/template"
"github.com/Masterminds/sprig"
"github.com/armon/go-radix"
"github.com/posener/complete"
)
// CLI contains the state necessary to run subcommands and parse the
// command line arguments.
//
// CLI also supports nested subcommands, such as "cli foo bar". To use
// nested subcommands, the key in the Commands mapping below contains the
// full subcommand. In this example, it would be "foo bar".
//
// If you use a CLI with nested subcommands, some semantics change due to
// ambiguities:
//
// * We use longest prefix matching to find a matching subcommand. This
// means if you register "foo bar" and the user executes "cli foo qux",
// the "foo" command will be executed with the arg "qux". It is up to
// you to handle these args. One option is to just return the special
// help return code `RunResultHelp` to display help and exit.
//
// * The help flag "-h" or "-help" will look at all args to determine
// the help function. For example: "otto apps list -h" will show the
// help for "apps list" but "otto apps -h" will show it for "apps".
// In the normal CLI, only the first subcommand is used.
//
// * The help flag will list any subcommands that a command takes
// as well as the command's help itself. If there are no subcommands,
// it will note this. If the CLI itself has no subcommands, this entire
// section is omitted.
//
// * Any parent commands that don't exist are automatically created as
// no-op commands that just show help for other subcommands. For example,
// if you only register "foo bar", then "foo" is automatically created.
//
type CLI struct {
// Args is the list of command-line arguments received excluding
// the name of the app. For example, if the command "./cli foo bar"
// was invoked, then Args should be []string{"foo", "bar"}.
Args []string
// Commands is a mapping of subcommand names to a factory function
// for creating that Command implementation. If there is a command
// with a blank string "", then it will be used as the default command
// if no subcommand is specified.
//
// If the key has a space in it, this will create a nested subcommand.
// For example, if the key is "foo bar", then to access it our CLI
// must be accessed with "./cli foo bar". See the docs for CLI for
// notes on how this changes some other behavior of the CLI as well.
//
// The factory should be as cheap as possible, ideally only allocating
// a struct. The factory may be called multiple times in the course
// of a command execution and certain events such as help require the
// instantiation of all commands. Expensive initialization should be
// deferred to function calls within the interface implementation.
Commands map[string]CommandFactory
// HiddenCommands is a list of commands that are "hidden". Hidden
// commands are not given to the help function callback and do not
// show up in autocomplete. The values in the slice should be equivalent
// to the keys in the command map.
HiddenCommands []string
// Name defines the name of the CLI.
Name string
// Version of the CLI.
Version string
// Autocomplete enables or disables subcommand auto-completion support.
// This is enabled by default when NewCLI is called. Otherwise, this
// must enabled explicitly.
//
// Autocomplete requires the "Name" option to be set on CLI. This name
// should be set exactly to the binary name that is autocompleted.
//
// Autocompletion is supported via the github.com/posener/complete
// library. This library supports bash, zsh and fish. To add support
// for other shells, please see that library.
//
// AutocompleteInstall and AutocompleteUninstall are the global flag
// names for installing and uninstalling the autocompletion handlers
// for the user's shell. The flag should omit the hyphen(s) in front of
// the value. Both single and double hyphens will automatically be supported
// for the flag name. These default to `autocomplete-install` and
// `autocomplete-uninstall` respectively.
//
// AutocompleteNoDefaultFlags is a boolean which controls if the default auto-
// complete flags like -help and -version are added to the output.
//
// AutocompleteGlobalFlags are a mapping of global flags for
// autocompletion. The help and version flags are automatically added.
Autocomplete bool
AutocompleteInstall string
AutocompleteUninstall string
AutocompleteNoDefaultFlags bool
AutocompleteGlobalFlags complete.Flags
autocompleteInstaller autocompleteInstaller // For tests
// HelpFunc is the function called to generate the generic help
// text that is shown if help must be shown for the CLI that doesn't
// pertain to a specific command.
HelpFunc HelpFunc
// HelpWriter is used to print help text and version when requested.
// Defaults to os.Stderr for backwards compatibility.
// It is recommended that you set HelpWriter to os.Stdout, and
// ErrorWriter to os.Stderr.
HelpWriter io.Writer
// ErrorWriter used to output errors when a command can not be run.
// Defaults to the value of HelpWriter for backwards compatibility.
// It is recommended that you set HelpWriter to os.Stdout, and
// ErrorWriter to os.Stderr.
ErrorWriter io.Writer
//---------------------------------------------------------------
// Internal fields set automatically
once sync.Once
autocomplete *complete.Complete
commandTree *radix.Tree
commandNested bool
commandHidden map[string]struct{}
subcommand string
subcommandArgs []string
topFlags []string
// These are true when special global flags are set. We can/should
// probably use a bitset for this one day.
isHelp bool
isVersion bool
isAutocompleteInstall bool
isAutocompleteUninstall bool
}
// NewClI returns a new CLI instance with sensible defaults.
func NewCLI(app, version string) *CLI {
return &CLI{
Name: app,
Version: version,
HelpFunc: BasicHelpFunc(app),
Autocomplete: true,
}
}
// IsHelp returns whether or not the help flag is present within the
// arguments.
func (c *CLI) IsHelp() bool {
c.once.Do(c.init)
return c.isHelp
}
// IsVersion returns whether or not the version flag is present within the
// arguments.
func (c *CLI) IsVersion() bool {
c.once.Do(c.init)
return c.isVersion
}
// Run runs the actual CLI based on the arguments given.
func (c *CLI) Run() (int, error) {
c.once.Do(c.init)
// If this is a autocompletion request, satisfy it. This must be called
// first before anything else since its possible to be autocompleting
// -help or -version or other flags and we want to show completions
// and not actually write the help or version.
if c.Autocomplete && c.autocomplete.Complete() {
return 0, nil
}
// Just show the version and exit if instructed.
if c.IsVersion() && c.Version != "" {
c.HelpWriter.Write([]byte(c.Version + "\n"))
return 0, nil
}
// Just print the help when only '-h' or '--help' is passed.
if c.IsHelp() && c.Subcommand() == "" {
c.HelpWriter.Write([]byte(c.HelpFunc(c.helpCommands(c.Subcommand())) + "\n"))
return 0, nil
}
// If we're attempting to install or uninstall autocomplete then handle
if c.Autocomplete {
// Autocomplete requires the "Name" to be set so that we know what
// command to setup the autocomplete on.
if c.Name == "" {
return 1, fmt.Errorf(
"internal error: CLI.Name must be specified for autocomplete to work")
}
// If both install and uninstall flags are specified, then error
if c.isAutocompleteInstall && c.isAutocompleteUninstall {
return 1, fmt.Errorf(
"Either the autocomplete install or uninstall flag may " +
"be specified, but not both.")
}
// If the install flag is specified, perform the install or uninstall
if c.isAutocompleteInstall {
if err := c.autocompleteInstaller.Install(c.Name); err != nil {
return 1, err
}
return 0, nil
}
if c.isAutocompleteUninstall {
if err := c.autocompleteInstaller.Uninstall(c.Name); err != nil {
return 1, err
}
return 0, nil
}
}
// Attempt to get the factory function for creating the command
// implementation. If the command is invalid or blank, it is an error.
raw, ok := c.commandTree.Get(c.Subcommand())
if !ok {
c.ErrorWriter.Write([]byte(c.HelpFunc(c.helpCommands(c.subcommandParent())) + "\n"))
return 127, nil
}
command, err := raw.(CommandFactory)()
if err != nil {
return 1, err
}
// If we've been instructed to just print the help, then print it
if c.IsHelp() {
c.commandHelp(c.HelpWriter, command)
return 0, nil
}
// If there is an invalid flag, then error
if len(c.topFlags) > 0 {
c.ErrorWriter.Write([]byte(
"Invalid flags before the subcommand. If these flags are for\n" +
"the subcommand, please put them after the subcommand.\n\n"))
c.commandHelp(c.ErrorWriter, command)
return 1, nil
}
code := command.Run(c.SubcommandArgs())
if code == RunResultHelp {
// Requesting help
c.commandHelp(c.ErrorWriter, command)
return 1, nil
}
return code, nil
}
// Subcommand returns the subcommand that the CLI would execute. For
// example, a CLI from "--version version --help" would return a Subcommand
// of "version"
func (c *CLI) Subcommand() string {
c.once.Do(c.init)
return c.subcommand
}
// SubcommandArgs returns the arguments that will be passed to the
// subcommand.
func (c *CLI) SubcommandArgs() []string {
c.once.Do(c.init)
return c.subcommandArgs
}
// subcommandParent returns the parent of this subcommand, if there is one.
// If there isn't on, "" is returned.
func (c *CLI) subcommandParent() string {
// Get the subcommand, if it is "" alread just return
sub := c.Subcommand()
if sub == "" {
return sub
}
// Clear any trailing spaces and find the last space
sub = strings.TrimRight(sub, " ")
idx := strings.LastIndex(sub, " ")
if idx == -1 {
// No space means our parent is root
return ""
}
return sub[:idx]
}
func (c *CLI) init() {
if c.HelpFunc == nil {
c.HelpFunc = BasicHelpFunc("app")
if c.Name != "" {
c.HelpFunc = BasicHelpFunc(c.Name)
}
}
if c.HelpWriter == nil {
c.HelpWriter = os.Stderr
}
if c.ErrorWriter == nil {
c.ErrorWriter = c.HelpWriter
}
// Build our hidden commands
if len(c.HiddenCommands) > 0 {
c.commandHidden = make(map[string]struct{})
for _, h := range c.HiddenCommands {
c.commandHidden[h] = struct{}{}
}
}
// Build our command tree
c.commandTree = radix.New()
c.commandNested = false
for k, v := range c.Commands {
k = strings.TrimSpace(k)
c.commandTree.Insert(k, v)
if strings.ContainsRune(k, ' ') {
c.commandNested = true
}
}
// Go through the key and fill in any missing parent commands
if c.commandNested {
var walkFn radix.WalkFn
toInsert := make(map[string]struct{})
walkFn = func(k string, raw interface{}) bool {
idx := strings.LastIndex(k, " ")
if idx == -1 {
// If there is no space, just ignore top level commands
return false
}
// Trim up to that space so we can get the expected parent
k = k[:idx]
if _, ok := c.commandTree.Get(k); ok {
// Yay we have the parent!
return false
}
// We're missing the parent, so let's insert this
toInsert[k] = struct{}{}
// Call the walk function recursively so we check this one too
return walkFn(k, nil)
}
// Walk!
c.commandTree.Walk(walkFn)
// Insert any that we're missing
for k := range toInsert {
var f CommandFactory = func() (Command, error) {
return &MockCommand{
HelpText: "This command is accessed by using one of the subcommands below.",
RunResult: RunResultHelp,
}, nil
}
c.commandTree.Insert(k, f)
}
}
// Setup autocomplete if we have it enabled. We have to do this after
// the command tree is setup so we can use the radix tree to easily find
// all subcommands.
if c.Autocomplete {
c.initAutocomplete()
}
// Process the args
c.processArgs()
}
func (c *CLI) initAutocomplete() {
if c.AutocompleteInstall == "" {
c.AutocompleteInstall = defaultAutocompleteInstall
}
if c.AutocompleteUninstall == "" {
c.AutocompleteUninstall = defaultAutocompleteUninstall
}
if c.autocompleteInstaller == nil {
c.autocompleteInstaller = &realAutocompleteInstaller{}
}
// We first set c.autocomplete to a noop autocompleter that outputs
// to nul so that we can detect if we're autocompleting or not. If we're
// not, then we do nothing. This saves a LOT of compute cycles since
// initAutoCompleteSub has to walk every command.
c.autocomplete = complete.New(c.Name, complete.Command{})
c.autocomplete.Out = ioutil.Discard
if !c.autocomplete.Complete() {
return
}
// Build the root command
cmd := c.initAutocompleteSub("")
// For the root, we add the global flags to the "Flags". This way
// they don't show up on every command.
if !c.AutocompleteNoDefaultFlags {
cmd.Flags = map[string]complete.Predictor{
"-" + c.AutocompleteInstall: complete.PredictNothing,
"-" + c.AutocompleteUninstall: complete.PredictNothing,
"-help": complete.PredictNothing,
"-version": complete.PredictNothing,
}
}
cmd.GlobalFlags = c.AutocompleteGlobalFlags
c.autocomplete = complete.New(c.Name, cmd)
}
// initAutocompleteSub creates the complete.Command for a subcommand with
// the given prefix. This will continue recursively for all subcommands.
// The prefix "" (empty string) can be used for the root command.
func (c *CLI) initAutocompleteSub(prefix string) complete.Command {
var cmd complete.Command
walkFn := func(k string, raw interface{}) bool {
// Ignore the empty key which can be present for default commands.
if k == "" {
return false
}
// Keep track of the full key so that we can nest further if necessary
fullKey := k
if len(prefix) > 0 {
// If we have a prefix, trim the prefix + 1 (for the space)
// Example: turns "sub one" to "one" with prefix "sub"
k = k[len(prefix)+1:]
}
if idx := strings.Index(k, " "); idx >= 0 {
// If there is a space, we trim up to the space. This turns
// "sub sub2 sub3" into "sub". The prefix trim above will
// trim our current depth properly.
k = k[:idx]
}
if _, ok := cmd.Sub[k]; ok {
// If we already tracked this subcommand then ignore
return false
}
// If the command is hidden, don't record it at all
if _, ok := c.commandHidden[fullKey]; ok {
return false
}
if cmd.Sub == nil {
cmd.Sub = complete.Commands(make(map[string]complete.Command))
}
subCmd := c.initAutocompleteSub(fullKey)
// Instantiate the command so that we can check if the command is
// a CommandAutocomplete implementation. If there is an error
// creating the command, we just ignore it since that will be caught
// later.
impl, err := raw.(CommandFactory)()
if err != nil {
impl = nil
}
// Check if it implements ComandAutocomplete. If so, setup the autocomplete
if c, ok := impl.(CommandAutocomplete); ok {
subCmd.Args = c.AutocompleteArgs()
subCmd.Flags = c.AutocompleteFlags()
}
cmd.Sub[k] = subCmd
return false
}
walkPrefix := prefix
if walkPrefix != "" {
walkPrefix += " "
}
c.commandTree.WalkPrefix(walkPrefix, walkFn)
return cmd
}
func (c *CLI) commandHelp(out io.Writer, command Command) {
// Get the template to use
tpl := strings.TrimSpace(defaultHelpTemplate)
if t, ok := command.(CommandHelpTemplate); ok {
tpl = t.HelpTemplate()
}
if !strings.HasSuffix(tpl, "\n") {
tpl += "\n"
}
// Parse it
t, err := template.New("root").Funcs(sprig.TxtFuncMap()).Parse(tpl)
if err != nil {
t = template.Must(template.New("root").Parse(fmt.Sprintf(
"Internal error! Failed to parse command help template: %s\n", err)))
}
// Template data
data := map[string]interface{}{
"Name": c.Name,
"SubcommandName": c.Subcommand(),
"Help": command.Help(),
}
// Build subcommand list if we have it
var subcommandsTpl []map[string]interface{}
if c.commandNested {
// Get the matching keys
subcommands := c.helpCommands(c.Subcommand())
keys := make([]string, 0, len(subcommands))
for k := range subcommands {
keys = append(keys, k)
}
// Sort the keys
sort.Strings(keys)
// Figure out the padding length
var longest int
for _, k := range keys {
if v := len(k); v > longest {
longest = v
}
}
// Go through and create their structures
subcommandsTpl = make([]map[string]interface{}, 0, len(subcommands))
for _, k := range keys {
// Get the command
raw, ok := subcommands[k]
if !ok {
c.ErrorWriter.Write([]byte(fmt.Sprintf(
"Error getting subcommand %q", k)))
}
sub, err := raw()
if err != nil {
c.ErrorWriter.Write([]byte(fmt.Sprintf(
"Error instantiating %q: %s", k, err)))
}
// Find the last space and make sure we only include that last part
name := k
if idx := strings.LastIndex(k, " "); idx > -1 {
name = name[idx+1:]
}
subcommandsTpl = append(subcommandsTpl, map[string]interface{}{
"Name": name,
"NameAligned": name + strings.Repeat(" ", longest-len(k)),
"Help": sub.Help(),
"Synopsis": sub.Synopsis(),
})
}
}
data["Subcommands"] = subcommandsTpl
// Write
err = t.Execute(out, data)
if err == nil {
return
}
// An error, just output...
c.ErrorWriter.Write([]byte(fmt.Sprintf(
"Internal error rendering help: %s", err)))
}
// helpCommands returns the subcommands for the HelpFunc argument.
// This will only contain immediate subcommands.
func (c *CLI) helpCommands(prefix string) map[string]CommandFactory {
// If our prefix isn't empty, make sure it ends in ' '
if prefix != "" && prefix[len(prefix)-1] != ' ' {
prefix += " "
}
// Get all the subkeys of this command
var keys []string
c.commandTree.WalkPrefix(prefix, func(k string, raw interface{}) bool {
// Ignore any sub-sub keys, i.e. "foo bar baz" when we want "foo bar"
if !strings.Contains(k[len(prefix):], " ") {
keys = append(keys, k)
}
return false
})
// For each of the keys return that in the map
result := make(map[string]CommandFactory, len(keys))
for _, k := range keys {
raw, ok := c.commandTree.Get(k)
if !ok {
// We just got it via WalkPrefix above, so we just panic
panic("not found: " + k)
}
// If this is a hidden command, don't show it
if _, ok := c.commandHidden[k]; ok {
continue
}
result[k] = raw.(CommandFactory)
}
return result
}
func (c *CLI) processArgs() {
for i, arg := range c.Args {
if arg == "--" {
break
}
// Check for help flags.
if arg == "-h" || arg == "-help" || arg == "--help" {
c.isHelp = true
continue
}
// Check for autocomplete flags
if c.Autocomplete {
if arg == "-"+c.AutocompleteInstall || arg == "--"+c.AutocompleteInstall {
c.isAutocompleteInstall = true
continue
}
if arg == "-"+c.AutocompleteUninstall || arg == "--"+c.AutocompleteUninstall {
c.isAutocompleteUninstall = true
continue
}
}
if c.subcommand == "" {
// Check for version flags if not in a subcommand.
if arg == "-v" || arg == "-version" || arg == "--version" {
c.isVersion = true
continue
}
if arg != "" && arg[0] == '-' {
// Record the arg...
c.topFlags = append(c.topFlags, arg)
}
}
// If we didn't find a subcommand yet and this is the first non-flag
// argument, then this is our subcommand.
if c.subcommand == "" && arg != "" && arg[0] != '-' {
c.subcommand = arg
if c.commandNested {
// If the command has a space in it, then it is invalid.
// Set a blank command so that it fails.
if strings.ContainsRune(arg, ' ') {
c.subcommand = ""
return
}
// Determine the argument we look to to end subcommands.
// We look at all arguments until one has a space. This
// disallows commands like: ./cli foo "bar baz". An argument
// with a space is always an argument.
j := 0
for k, v := range c.Args[i:] {
if strings.ContainsRune(v, ' ') {
break
}
j = i + k + 1
}
// Nested CLI, the subcommand is actually the entire
// arg list up to a flag that is still a valid subcommand.
searchKey := strings.Join(c.Args[i:j], " ")
k, _, ok := c.commandTree.LongestPrefix(searchKey)
if ok {
// k could be a prefix that doesn't contain the full
// command such as "foo" instead of "foobar", so we
// need to verify that we have an entire key. To do that,
// we look for an ending in a space or an end of string.
reVerify := regexp.MustCompile(regexp.QuoteMeta(k) + `( |$)`)
if reVerify.MatchString(searchKey) {
c.subcommand = k
i += strings.Count(k, " ")
}
}
}
// The remaining args the subcommand arguments
c.subcommandArgs = c.Args[i+1:]
}
}
// If we never found a subcommand and support a default command, then
// switch to using that.
if c.subcommand == "" {
if _, ok := c.Commands[""]; ok {
args := c.topFlags
args = append(args, c.subcommandArgs...)
c.topFlags = nil
c.subcommandArgs = args
}
}
}
// defaultAutocompleteInstall and defaultAutocompleteUninstall are the
// default values for the autocomplete install and uninstall flags.
const defaultAutocompleteInstall = "autocomplete-install"
const defaultAutocompleteUninstall = "autocomplete-uninstall"
const defaultHelpTemplate = `
{{.Help}}{{if gt (len .Subcommands) 0}}
Subcommands:
{{- range $value := .Subcommands }}
{{ $value.NameAligned }} {{ $value.Synopsis }}{{ end }}
{{- end }}
`