go-arg/usage.go

364 lines
9.9 KiB
Go

package arg
import (
"fmt"
"io"
"strings"
)
// the width of the left column
const colWidth = 25
// Fail prints usage information to stderr and exits with non-zero status
func (p *Parser) Fail(msg string) {
p.failWithSubcommand(msg, p.cmd)
}
// FailSubcommand prints usage information for a specified subcommand to stderr,
// then exits with non-zero status. To write usage information for a top-level
// subcommand, provide just the name of that subcommand. To write usage
// information for a subcommand that is nested under another subcommand, provide
// a sequence of subcommand names starting with the top-level subcommand and so
// on down the tree.
func (p *Parser) FailSubcommand(msg string, subcommand ...string) error {
cmd, err := p.lookupCommand(subcommand...)
if err != nil {
return err
}
p.failWithSubcommand(msg, cmd)
return nil
}
// failWithSubcommand prints usage information for the given subcommand to stderr and exits with non-zero status
func (p *Parser) failWithSubcommand(msg string, cmd *command) {
p.writeUsageForSubcommand(p.config.Out, cmd)
fmt.Fprintln(p.config.Out, "error:", msg)
p.config.Exit(-1)
}
// WriteUsage writes usage information to the given writer
func (p *Parser) WriteUsage(w io.Writer) {
cmd := p.cmd
if p.lastCmd != nil {
cmd = p.lastCmd
}
p.writeUsageForSubcommand(w, cmd)
}
// WriteUsageForSubcommand writes the usage information for a specified
// subcommand. To write usage information for a top-level subcommand, provide
// just the name of that subcommand. To write usage information for a subcommand
// that is nested under another subcommand, provide a sequence of subcommand
// names starting with the top-level subcommand and so on down the tree.
func (p *Parser) WriteUsageForSubcommand(w io.Writer, subcommand ...string) error {
cmd, err := p.lookupCommand(subcommand...)
if err != nil {
return err
}
p.writeUsageForSubcommand(w, cmd)
return nil
}
// writeUsageForSubcommand writes usage information for the given subcommand
func (p *Parser) writeUsageForSubcommand(w io.Writer, cmd *command) {
var positionals, longOptions, shortOptions []*spec
for _, spec := range cmd.specs {
switch {
case spec.positional:
positionals = append(positionals, spec)
case spec.long != "":
longOptions = append(longOptions, spec)
case spec.short != "":
shortOptions = append(shortOptions, spec)
}
}
if p.version != "" {
fmt.Fprintln(w, p.version)
}
// make a list of ancestor commands so that we print with full context
var ancestors []string
ancestor := cmd
for ancestor != nil {
ancestors = append(ancestors, ancestor.name)
ancestor = ancestor.parent
}
// print the beginning of the usage string
fmt.Fprint(w, "Usage:")
for i := len(ancestors) - 1; i >= 0; i-- {
fmt.Fprint(w, " "+ancestors[i])
}
// write the option component of the usage message
for _, spec := range shortOptions {
// prefix with a space
fmt.Fprint(w, " ")
if !spec.required {
fmt.Fprint(w, "[")
}
fmt.Fprint(w, synopsis(spec, "-"+spec.short))
if !spec.required {
fmt.Fprint(w, "]")
}
}
for _, spec := range longOptions {
// prefix with a space
fmt.Fprint(w, " ")
if !spec.required {
fmt.Fprint(w, "[")
}
fmt.Fprint(w, synopsis(spec, "--"+spec.long))
if !spec.required {
fmt.Fprint(w, "]")
}
}
// When we parse positionals, we check that:
// 1. required positionals come before non-required positionals
// 2. there is at most one multiple-value positional
// 3. if there is a multiple-value positional then it comes after all other positionals
// Here we merely print the usage string, so we do not explicitly re-enforce those rules
// write the positionals in following form:
// REQUIRED1 REQUIRED2
// REQUIRED1 REQUIRED2 [OPTIONAL1 [OPTIONAL2]]
// REQUIRED1 REQUIRED2 REPEATED [REPEATED ...]
// REQUIRED1 REQUIRED2 [REPEATEDOPTIONAL [REPEATEDOPTIONAL ...]]
// REQUIRED1 REQUIRED2 [OPTIONAL1 [REPEATEDOPTIONAL [REPEATEDOPTIONAL ...]]]
var closeBrackets int
for _, spec := range positionals {
fmt.Fprint(w, " ")
if !spec.required {
fmt.Fprint(w, "[")
closeBrackets += 1
}
if spec.cardinality == multiple {
fmt.Fprintf(w, "%s [%s ...]", spec.placeholder, spec.placeholder)
} else {
fmt.Fprint(w, spec.placeholder)
}
}
fmt.Fprint(w, strings.Repeat("]", closeBrackets))
// if the program supports subcommands, give a hint to the user about their existence
if len(cmd.subcommands) > 0 {
fmt.Fprint(w, " <command> [<args>]")
}
fmt.Fprint(w, "\n")
}
func printTwoCols(w io.Writer, left, help string, defaultVal string, envVal string) {
lhs := " " + left
fmt.Fprint(w, lhs)
if help != "" {
if len(lhs)+2 < colWidth {
fmt.Fprint(w, strings.Repeat(" ", colWidth-len(lhs)))
} else {
fmt.Fprint(w, "\n"+strings.Repeat(" ", colWidth))
}
fmt.Fprint(w, help)
}
bracketsContent := []string{}
if defaultVal != "" {
bracketsContent = append(bracketsContent,
fmt.Sprintf("default: %s", defaultVal),
)
}
if envVal != "" {
bracketsContent = append(bracketsContent,
fmt.Sprintf("env: %s", envVal),
)
}
if len(bracketsContent) > 0 {
fmt.Fprintf(w, " [%s]", strings.Join(bracketsContent, ", "))
}
fmt.Fprint(w, "\n")
}
// WriteHelp writes the usage string followed by the full help string for each option
func (p *Parser) WriteHelp(w io.Writer) {
cmd := p.cmd
if p.lastCmd != nil {
cmd = p.lastCmd
}
p.writeHelpForSubcommand(w, cmd)
}
// WriteHelpForSubcommand writes the usage string followed by the full help
// string for a specified subcommand. To write help for a top-level subcommand,
// provide just the name of that subcommand. To write help for a subcommand that
// is nested under another subcommand, provide a sequence of subcommand names
// starting with the top-level subcommand and so on down the tree.
func (p *Parser) WriteHelpForSubcommand(w io.Writer, subcommand ...string) error {
cmd, err := p.lookupCommand(subcommand...)
if err != nil {
return err
}
p.writeHelpForSubcommand(w, cmd)
return nil
}
// writeHelp writes the usage string for the given subcommand
func (p *Parser) writeHelpForSubcommand(w io.Writer, cmd *command) {
var positionals, longOptions, shortOptions, envOnlyOptions []*spec
var hasVersionOption bool
for _, spec := range cmd.specs {
switch {
case spec.positional:
positionals = append(positionals, spec)
case spec.long != "":
longOptions = append(longOptions, spec)
case spec.short != "":
shortOptions = append(shortOptions, spec)
case spec.short == "" && spec.long == "":
envOnlyOptions = append(envOnlyOptions, spec)
}
}
if p.description != "" {
fmt.Fprintln(w, p.description)
}
p.writeUsageForSubcommand(w, cmd)
// write the list of positionals
if len(positionals) > 0 {
fmt.Fprint(w, "\nPositional arguments:\n")
for _, spec := range positionals {
printTwoCols(w, spec.placeholder, spec.help, "", "")
}
}
// write the list of options with the short-only ones first to match the usage string
if len(shortOptions)+len(longOptions) > 0 || cmd.parent == nil {
fmt.Fprint(w, "\nOptions:\n")
for _, spec := range shortOptions {
p.printOption(w, spec)
}
for _, spec := range longOptions {
p.printOption(w, spec)
if spec.long == "version" {
hasVersionOption = true
}
}
}
// obtain a flattened list of options from all ancestors
var globals []*spec
ancestor := cmd.parent
for ancestor != nil {
globals = append(globals, ancestor.specs...)
ancestor = ancestor.parent
}
// write the list of global options
if len(globals) > 0 {
fmt.Fprint(w, "\nGlobal options:\n")
for _, spec := range globals {
p.printOption(w, spec)
if spec.long == "version" {
hasVersionOption = true
}
}
}
// write the list of built in options
p.printOption(w, &spec{
cardinality: zero,
long: "help",
short: "h",
help: "display this help and exit",
})
if !hasVersionOption && p.version != "" {
p.printOption(w, &spec{
cardinality: zero,
long: "version",
help: "display version and exit",
})
}
// write the list of environment only variables
if len(envOnlyOptions) > 0 {
fmt.Fprint(w, "\nEnvironment variables:\n")
for _, spec := range envOnlyOptions {
p.printEnvOnlyVar(w, spec)
}
}
// write the list of subcommands
if len(cmd.subcommands) > 0 {
fmt.Fprint(w, "\nCommands:\n")
for _, subcmd := range cmd.subcommands {
printTwoCols(w, subcmd.name, subcmd.help, "", "")
}
}
if p.epilogue != "" {
fmt.Fprintln(w, "\n"+p.epilogue)
}
}
func (p *Parser) printOption(w io.Writer, spec *spec) {
ways := make([]string, 0, 2)
if spec.long != "" {
ways = append(ways, synopsis(spec, "--"+spec.long))
}
if spec.short != "" {
ways = append(ways, synopsis(spec, "-"+spec.short))
}
if len(ways) > 0 {
printTwoCols(w, strings.Join(ways, ", "), spec.help, spec.defaultString, spec.env)
}
}
func (p *Parser) printEnvOnlyVar(w io.Writer, spec *spec) {
ways := make([]string, 0, 2)
if spec.required {
ways = append(ways, "Required.")
} else {
ways = append(ways, "Optional.")
}
if spec.help != "" {
ways = append(ways, spec.help)
}
printTwoCols(w, spec.env, strings.Join(ways, " "), spec.defaultString, "")
}
// lookupCommand finds a subcommand based on a sequence of subcommand names. The
// first string should be a top-level subcommand, the next should be a child
// subcommand of that subcommand, and so on. If no strings are given then the
// root command is returned. If no such subcommand exists then an error is
// returned.
func (p *Parser) lookupCommand(path ...string) (*command, error) {
cmd := p.cmd
for _, name := range path {
var found *command
for _, child := range cmd.subcommands {
if child.name == name {
found = child
}
}
if found == nil {
return nil, fmt.Errorf("%q is not a subcommand of %s", name, cmd.name)
}
cmd = found
}
return cmd, nil
}
func synopsis(spec *spec, form string) string {
if spec.cardinality == zero {
return form
}
return form + " " + spec.placeholder
}