- Version 1.0.0 Release
- Introduction
- Help
- Command handling
- Hooks: BeforeReset(), BeforeResolve(), BeforeApply(), AfterApply() and the Bind() option
- Flags
- Commands and sub-commands
- Branching positional arguments
- Positional arguments
- Slices
- Maps
- Pointers
- Nested data structure
- Custom named decoders
- Supported field types
- Custom decoders (mappers)
- Supported tags
- Plugins
- Dynamic Commands
- Variable interpolation
- Validation
- Modifying Kong's behaviour
Name(help)
andDescription(help)
- set the application name descriptionConfiguration(loader, paths...)
- load defaults from configuration filesResolver(...)
- support for default values from external sources*Mapper(...)
- customising how the command-line is mapped to Go valuesConfigureHelp(HelpOptions)
andHelp(HelpFunc)
- customising help- Injecting values into
Run()
methods - Other options
Kong has been stable for a long time, so it seemed appropriate to cut a 1.0 release.
There is one breaking change, #436, which should effect relatively few users.
Kong aims to support arbitrarily complex command-line structures with as little developer effort as possible.
To achieve that, command-lines are expressed as Go types, with the structure and tags directing how the command line is mapped onto the struct.
For example, the following command-line:
shell rm [-f] [-r] <paths> ...
shell ls [<paths> ...]
Can be represented by the following command-line structure:
package main
import "github.com/alecthomas/kong"
var CLI struct {
Rm struct {
Force bool `help:"Force removal."`
Recursive bool `help:"Recursively remove files."`
Paths []string `arg:"" name:"path" help:"Paths to remove." type:"path"`
} `cmd:"" help:"Remove files."`
Ls struct {
Paths []string `arg:"" optional:"" name:"path" help:"Paths to list." type:"path"`
} `cmd:"" help:"List paths."`
}
func main() {
ctx := kong.Parse(&CLI)
switch ctx.Command() {
case "rm <path>":
case "ls":
default:
panic(ctx.Command())
}
}
Every Kong application includes a --help
flag that will display auto-generated help.
eg.
$ shell --help
usage: shell <command>
A shell-like example app.
Flags:
--help Show context-sensitive help.
--debug Debug mode.
Commands:
rm <path> ...
Remove files.
ls [<path> ...]
List paths.
If a command is provided, the help will show full detail on the command including all available flags.
eg.
$ shell --help rm
usage: shell rm <paths> ...
Remove files.
Arguments:
<paths> ... Paths to remove.
Flags:
--debug Debug mode.
-f, --force Force removal.
-r, --recursive Recursively remove files.
Help is automatically generated from the command-line structure itself,
including help:""
and other tags. Variables will
also be interpolated into the help string.
Finally, any command, or argument type implementing the interface
Help() string
will have this function called to retrieve more detail to
augment the help tag. This allows for much more descriptive text than can
fit in Go tags. See _examples/shell/help
A command's additional help text is not shown from top-level help, but can be displayed within contextual help:
Top level help
$ go run ./_examples/shell/help --help
Usage: help <command>
An app demonstrating HelpProviders
Flags:
-h, --help Show context-sensitive help.
--flag Regular flag help
Commands:
echo Regular command help
Contextual
$ go run ./_examples/shell/help echo --help
Usage: help echo <msg>
Regular command help
🚀 additional command help
Arguments:
<msg> Regular argument help
Flags:
-h, --help Show context-sensitive help.
--flag Regular flag help
Custom help will only be shown for positional arguments with named fields (see the README section on positional arguments for more details on what that means)
Contextual argument help
$ go run ./_examples/shell/help msg --help
Usage: help echo <msg>
Regular argument help
📣 additional argument help
Flags:
-h, --help Show context-sensitive help.
--flag Regular flag help
There are two ways to handle commands in Kong.
When you call kong.Parse()
it will return a unique string representation of the command. Each command branch in the hierarchy will be a bare word and each branching argument or required positional argument will be the name surrounded by angle brackets. Here's an example:
There's an example of this pattern here.
eg.
package main
import "github.com/alecthomas/kong"
var CLI struct {
Rm struct {
Force bool `help:"Force removal."`
Recursive bool `help:"Recursively remove files."`
Paths []string `arg:"" name:"path" help:"Paths to remove." type:"path"`
} `cmd:"" help:"Remove files."`
Ls struct {
Paths []string `arg:"" optional:"" name:"path" help:"Paths to list." type:"path"`
} `cmd:"" help:"List paths."`
}
func main() {
ctx := kong.Parse(&CLI)
switch ctx.Command() {
case "rm <path>":
case "ls":
default:
panic(ctx.Command())
}
}
This has the advantage that it is convenient, but the downside that if you modify your CLI structure, the strings may change. This can be fragile.
A more robust approach is to break each command out into their own structs:
- Break leaf commands out into separate structs.
- Attach a
Run(...) error
method to all leaf commands. - Call
kong.Kong.Parse()
to obtain akong.Context
. - Call
kong.Context.Run(bindings...)
to call the selected parsed command.
Once a command node is selected by Kong it will search from that node back to the root. Each
encountered command node with a Run(...) error
will be called in reverse order. This allows
sub-trees to be re-used fairly conveniently.
In addition to values bound with the kong.Bind(...)
option, any values
passed through to kong.Context.Run(...)
are also bindable to the target's
Run()
arguments.
Finally, hooks can also contribute bindings via kong.Context.Bind()
and kong.Context.BindTo()
.
There's a full example emulating part of the Docker CLI here.
eg.
type Context struct {
Debug bool
}
type RmCmd struct {
Force bool `help:"Force removal."`
Recursive bool `help:"Recursively remove files."`
Paths []string `arg:"" name:"path" help:"Paths to remove." type:"path"`
}
func (r *RmCmd) Run(ctx *Context) error {
fmt.Println("rm", r.Paths)
return nil
}
type LsCmd struct {
Paths []string `arg:"" optional:"" name:"path" help:"Paths to list." type:"path"`
}
func (l *LsCmd) Run(ctx *Context) error {
fmt.Println("ls", l.Paths)
return nil
}
var cli struct {
Debug bool `help:"Enable debug mode."`
Rm RmCmd `cmd:"" help:"Remove files."`
Ls LsCmd `cmd:"" help:"List paths."`
}
func main() {
ctx := kong.Parse(&cli)
// Call the Run() method of the selected parsed command.
err := ctx.Run(&Context{Debug: cli.Debug})
ctx.FatalIfErrorf(err)
}
If a node in the CLI, or any of its embedded fields, has a BeforeReset(...) error
, BeforeResolve (...) error
, BeforeApply(...) error
and/or AfterApply(...) error
method, those
methods will be called before values are reset, before validation/assignment,
and after validation/assignment, respectively.
The --help
flag is implemented with a BeforeReset
hook.
Arguments to hooks are provided via the Run(...)
method or Bind(...)
option. *Kong
, *Context
and *Path
are also bound and finally, hooks can also contribute bindings via kong.Context.Bind()
and kong.Context.BindTo()
.
eg.
// A flag with a hook that, if triggered, will set the debug loggers output to stdout.
type debugFlag bool
func (d debugFlag) BeforeApply(logger *log.Logger) error {
logger.SetOutput(os.Stdout)
return nil
}
var cli struct {
Debug debugFlag `help:"Enable debug logging."`
}
func main() {
// Debug logger going to discard.
logger := log.New(io.Discard, "", log.LstdFlags)
ctx := kong.Parse(&cli, kong.Bind(logger))
// ...
}
Any mapped field in the command structure not tagged with cmd
or arg
will be a flag. Flags are optional by default.
eg. The command-line app [--flag="foo"]
can be represented by the following.
type CLI struct {
Flag string
}
Sub-commands are specified by tagging a struct field with cmd
. Kong supports arbitrarily nested commands.
eg. The following struct represents the CLI structure command [--flag="str"] sub-command
.
type CLI struct {
Command struct {
Flag string
SubCommand struct {
} `cmd`
} `cmd`
}
If a sub-command is tagged with default:"1"
it will be selected if there are no further arguments. If a sub-command is tagged with default:"withargs"
it will be selected even if there are further arguments or flags and those arguments or flags are valid for the sub-command. This allows the user to omit the sub-command name on the CLI if its arguments/flags are not ambiguous with the sibling commands or flags.
In addition to sub-commands, structs can also be configured as branching positional arguments.
This is achieved by tagging an unmapped nested struct field with arg
, then including a positional argument field inside that struct with the same name. For example, the following command structure:
app rename <name> to <name>
Can be represented with the following:
var CLI struct {
Rename struct {
Name struct {
Name string `arg` // <-- NOTE: identical name to enclosing struct field.
To struct {
Name struct {
Name string `arg`
} `arg`
} `cmd`
} `arg`
} `cmd`
}
This looks a little verbose in this contrived example, but typically this will not be the case.
If a field is tagged with arg:""
it will be treated as the final positional
value to be parsed on the command line. By default positional arguments are
required, but specifying optional:""
will alter this.
If a positional argument is a slice, all remaining arguments will be appended to that slice.
Slice values are treated specially. First the input is split on the sep:"<rune>"
tag (defaults to ,
), then each element is parsed by the slice element type and appended to the slice. If the same value is encountered multiple times, elements continue to be appended.
To represent the following command-line:
cmd ls <file> <file> ...
You would use the following:
var CLI struct {
Ls struct {
Files []string `arg:"" type:"existingfile"`
} `cmd`
}
Maps are similar to slices except that only one key/value pair can be assigned per value, and the sep
tag denotes the assignment character and defaults to =
.
To represent the following command-line:
cmd config set <key>=<value> <key>=<value> ...
You would use the following:
var CLI struct {
Config struct {
Set struct {
Config map[string]float64 `arg:"" type:"file:"`
} `cmd`
} `cmd`
}
For flags, multiple key+value pairs should be separated by mapsep:"rune"
tag (defaults to ;
) eg. --set="key1=value1;key2=value2"
.
Pointers work like the underlying type, except that you can differentiate between the presence of the zero value and no value being supplied.
For example:
var CLI struct {
Foo *int
}
Would produce a nil value for Foo
if no --foo
argument is supplied, but would have a pointer to the value 0 if the argument --foo=0
was supplied.
Kong support a nested data structure as well with embed:""
. You can combine embed:""
with prefix:""
:
var CLI struct {
Logging struct {
Level string `enum:"debug,info,warn,error" default:"info"`
Type string `enum:"json,console" default:"console"`
} `embed:"" prefix:"logging."`
}
This configures Kong to accept flags --logging.level
and --logging.type
.
Kong includes a number of builtin custom type mappers. These can be used by
specifying the tag type:"<type>"
. They are registered with the option
function NamedMapper(name, mapper)
.
Name | Description |
---|---|
path |
A path. ~ expansion is applied. - is accepted for stdout, and will be passed unaltered. |
existingfile |
An existing file. ~ expansion is applied. - is accepted for stdin, and will be passed unaltered. |
existingdir |
An existing directory. ~ expansion is applied. |
counter |
Increment a numeric field. Useful for -vvv . Can accept -s , --long or --long=N . |
filecontent |
Read the file at path into the field. ~ expansion is applied. - is accepted for stdin, and will be passed unaltered. |
Slices and maps treat type tags specially. For slices, the type:""
tag
specifies the element type. For maps, the tag has the format
tag:"[<key>]:[<value>]"
where either may be omitted.
Any field implementing encoding.TextUnmarshaler
or json.Unmarshaler
will use those interfaces
for decoding values. Kong also includes builtin support for many common Go types:
Type | Description |
---|---|
time.Duration |
Populated using time.ParseDuration() . |
time.Time |
Populated using time.Parse() . Format defaults to RFC3339 but can be overridden with the format:"X" tag. |
*os.File |
Path to a file that will be opened, or - for os.Stdin . File must be closed by the user. |
*url.URL |
Populated with url.Parse() . |
For more fine-grained control, if a field implements the MapperValue interface it will be used to decode arguments into the field.
Tags can be in two forms:
- Standard Go syntax, eg.
kong:"required,name='foo'"
. - Bare tags, eg.
required:"" name:"foo"
Both can coexist with standard Tag parsing.
Tag | Description |
---|---|
cmd:"" |
If present, struct is a command. |
arg:"" |
If present, field is an argument. Required by default. |
env:"X,Y,..." |
Specify envars to use for default value. The envs are resolved in the declared order. The first value found is used. |
name:"X" |
Long name, for overriding field name. |
help:"X" |
Help text. |
type:"X" |
Specify named types to use. |
placeholder:"X" |
Placeholder input, if flag. e.g. `placeholder:"<the-placeholder>"` will show --flag-name=<the-placeholder> when displaying help. |
default:"X" |
Default value. |
default:"1" |
On a command, make it the default. |
default:"withargs" |
On a command, make it the default and allow args/flags from that command |
short:"X" |
Short name, if flag. |
aliases:"X,Y" |
One or more aliases (for cmd or flag). |
required:"" |
If present, flag/arg is required. |
optional:"" |
If present, flag/arg is optional. |
hidden:"" |
If present, command or flag is hidden. |
negatable:"" |
If present on a bool field, supports prefixing a flag with --no- to invert the default value |
negatable:"X" |
If present on a bool field, supports --X to invert the default value |
format:"X" |
Format for parsing input, if supported. |
sep:"X" |
Separator for sequences (defaults to ","). May be none to disable splitting. |
mapsep:"X" |
Separator for maps (defaults to ";"). May be none to disable splitting. |
enum:"X,Y,..." |
Set of valid values allowed for this flag. An enum field must be required or have a valid default . |
group:"X" |
Logical group for a flag or command. |
xor:"X,Y,..." |
Exclusive OR groups for flags. Only one flag in the group can be used which is restricted within the same command. When combined with required , at least one of the xor group will be required. |
and:"X,Y,..." |
AND groups for flags. All flags in the group must be used in the same command. When combined with required , all flags in the group will be required. |
prefix:"X" |
Prefix for all sub-flags. |
envprefix:"X" |
Envar prefix for all sub-flags. |
set:"K=V" |
Set a variable for expansion by child elements. Multiples can occur. |
embed:"" |
If present, this field's children will be embedded in the parent. Useful for composition. |
passthrough:"<mode>" 1 |
If present on a positional argument, it stops flag parsing when encountered, as if -- was processed before. Useful for external command wrappers, like exec . On a command it requires that the command contains only one argument of type []string which is then filled with everything following the command, unparsed. |
- |
Ignore the field. Useful for adding non-CLI fields to a configuration struct. e.g `kong:"-"` |
Kong CLI's can be extended by embedding the kong.Plugin
type and populating it with pointers to Kong annotated structs. For example:
var pluginOne struct {
PluginOneFlag string
}
var pluginTwo struct {
PluginTwoFlag string
}
var cli struct {
BaseFlag string
kong.Plugins
}
cli.Plugins = kong.Plugins{&pluginOne, &pluginTwo}
Additionally if an interface type is embedded, it can also be populated with a Kong annotated struct.
While plugins give complete control over extending command-line interfaces, Kong
also supports dynamically adding commands via kong.DynamicCommand()
.
Kong supports limited variable interpolation into help strings, enum lists and default values.
Variables are in the form:
${<name>}
${<name>=<default>}
Variables are set with the Vars{"key": "value", ...}
option. Undefined
variable references in the grammar without a default will result in an error at
construction time.
Variables can also be set via the set:"K=V"
tag. In this case, those variables will be available for that
node and all children. This is useful for composition by allowing the same struct to be reused.
When interpolating into flag or argument help strings, some extra variables are defined from the value itself:
${default}
${enum}
For flags with associated environment variables, the variable ${env}
can be
interpolated into the help string. In the absence of this variable in the
help string, Kong will append ($$${env})
to the help string.
eg.
type cli struct {
Config string `type:"path" default:"${config_file}"`
}
func main() {
kong.Parse(&cli,
kong.Vars{
"config_file": "~/.app.conf",
})
}
Kong does validation on the structure of a command-line, but also supports extensible validation. Any node in the tree may implement either of the following interfaces:
type Validatable interface {
Validate() error
}
type Validatable interface {
Validate(kctx *kong.Context) error
}
If one of these nodes is in the active command-line it will be called during normal validation.
Each Kong parser can be configured via functional options passed to New(cli interface{}, options...Option)
.
The full set of options can be found here.
Set the application name and/or description.
The name of the application will default to the binary name, but can be overridden with Name(name)
.
As with all help in Kong, text will be wrapped to the terminal.
This option provides Kong with support for loading defaults from a set of configuration files. Each file is opened, if possible, and the loader called to create a resolver for that file.
eg.
kong.Parse(&cli, kong.Configuration(kong.JSON, "/etc/myapp.json", "~/.myapp.json"))
See the tests for an example of how the JSON file is structured.
Resolvers are Kong's extension point for providing default values from external sources. As an example, support for environment variables via the env
tag is provided by a resolver. There's also a builtin resolver for JSON configuration files.
Example resolvers can be found in resolver.go.
Command-line arguments are mapped to Go values via the Mapper interface:
// A Mapper represents how a field is mapped from command-line values to Go.
//
// Mappers can be associated with concrete fields via pointer, reflect.Type, reflect.Kind, or via a "type" tag.
//
// Additionally, if a type implements the MapperValue interface, it will be used.
type Mapper interface {
// Decode ctx.Value with ctx.Scanner into target.
Decode(ctx *DecodeContext, target reflect.Value) error
}
All builtin Go types (as well as a bunch of useful stdlib types like time.Time
) have mappers registered by default. Mappers for custom types can be added using kong.??Mapper(...)
options. Mappers are applied to fields in four ways:
NamedMapper(string, Mapper)
and using the tag keytype:"<name>"
.KindMapper(reflect.Kind, Mapper)
.TypeMapper(reflect.Type, Mapper)
.ValueMapper(interface{}, Mapper)
, passing in a pointer to a field of the grammar.
The default help output is usually sufficient, but if not there are two solutions.
- Use
ConfigureHelp(HelpOptions)
to configure how help is formatted (see HelpOptions for details). - Custom help can be wired into Kong via the
Help(HelpFunc)
option. TheHelpFunc
is passed aContext
, which contains the parsed context for the current command-line. See the implementation ofDefaultHelpPrinter
for an example. - Use
ValueFormatter(HelpValueFormatter)
if you want to just customize the help text that is accompanied by flags and arguments. - Use
Groups([]Group)
if you want to customize group titles or add a header.
There are several ways to inject values into Run()
methods:
- Use
Bind()
to bind values directly. - Use
BindTo()
to bind values to an interface type. - Use
BindToProvider()
to bind values to a function that provides the value. - Implement
Provide<Type>() error
methods on the command structure.
The full set of options can be found here.
Footnotes
-
<mode>
can bepartial
orall
(the default).all
will pass through all arguments including flags, including flags.partial
will validate flags until the first positional argument is encountered, then pass through all remaining positional arguments. ↩