clap/src/app/parser.rs

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use std::collections::{BTreeMap, HashMap, VecDeque};
use std::slice::Iter;
use std::io::{self, BufWriter, Write};
use std::ffi::{OsStr, OsString};
use std::fmt::Display;
#[cfg(feature = "debug")]
use std::os::unix::ffi::OsStrExt;
use vec_map::VecMap;
use app::App;
use args::{Arg, FlagBuilder, OptBuilder, ArgGroup, PosBuilder};
use app::settings::{AppSettings, AppFlags};
use args::{AnyArg, ArgMatcher};
use args::settings::{ArgSettings, ArgFlags};
use errors::{ErrorKind, Error};
use errors::Result as ClapResult;
use utf8::INVALID_UTF8;
use suggestions;
use INTERNAL_ERROR_MSG;
use SubCommand;
use fmt::Format;
use osstringext::OsStrExt2;
use app::meta::AppMeta;
pub struct Parser<'a, 'b> where 'a: 'b {
required: Vec<&'b str>,
short_list: Vec<char>,
long_list: Vec<&'b str>,
blacklist: Vec<&'b str>,
// A list of possible flags
flags: Vec<FlagBuilder<'a, 'b>>,
// A list of possible options
opts: Vec<OptBuilder<'a, 'b>>,
// A list of positional arguments
positionals: VecMap<PosBuilder<'a, 'b>>,
// A list of subcommands
subcommands: Vec<App<'a, 'b>>,
groups: HashMap<&'a str, ArgGroup<'a>>,
global_args: Vec<Arg<'a, 'b>>,
overrides: Vec<&'b str>,
help_short: Option<char>,
version_short: Option<char>,
settings: AppFlags,
version: Option<&'b str>,
pub meta: AppMeta<'b>,
}
impl<'a, 'b> Default for Parser<'a, 'b> {
fn default() -> Self {
Parser {
flags: vec![],
opts: vec![],
positionals: VecMap::new(),
subcommands: vec![],
help_short: None,
version_short: None,
required: vec![],
short_list: vec![],
long_list: vec![],
blacklist: vec![],
groups: HashMap::new(),
global_args: vec![],
overrides: vec![],
settings: AppFlags::new(),
version: None,
meta: AppMeta::new(),
}
}
}
macro_rules! parse_positional {
($_self:ident, $p:ident, $arg_os:ident, $pos_only:ident, $pos_counter:ident, $matcher:ident) => {
debugln!("macro=parse_positional!;");
validate_multiples!($_self, $p, $matcher);
if let Err(e) = $_self.add_val_to_arg($p, &$arg_os, $matcher) {
return Err(e);
}
if !$pos_only &&
($_self.settings.is_set(AppSettings::TrailingVarArg) &&
$pos_counter == $_self.positionals.len()) {
$pos_only = true;
}
arg_post_processing!($_self, $p, $matcher);
// Only increment the positional counter if it doesn't allow multiples
if !$p.settings.is_set(ArgSettings::Multiple) {
$pos_counter += 1;
}
};
}
impl<'a, 'b> Parser<'a, 'b> where 'a: 'b {
pub fn with_name(n: String) -> Self {
Parser { meta: AppMeta::with_name(n), ..Default::default() }
}
pub fn help_short<'z>(&mut self, s: &'z str) {
self.help_short = s.trim_left_matches(|c| c == '-')
.chars()
.nth(0);
}
pub fn version_short(&mut self, s: &str) {
self.version_short = s.trim_left_matches(|c| c == '-')
.chars()
.nth(0);
}
// actually adds the arguments
pub fn add_arg(&mut self, a: &Arg<'a, 'b>) {
if self.flags.iter().any(|f| &f.name == &a.name) ||
self.opts.iter().any(|o| o.name == a.name) ||
self.positionals.values().any(|p| p.name == a.name) {
panic!("Non-unique argument name: {} is already in use", a.name);
}
if let Some(grp) = a.group {
let ag = self.groups.entry(grp).or_insert(ArgGroup::with_name(grp));
ag.args.push(a.name);
}
if let Some(s) = a.short {
if self.short_list.contains(&s) {
panic!("Argument short must be unique\n\n\t-{} is already in use",
s);
} else {
self.short_list.push(s);
}
}
if let Some(l) = a.long {
if self.long_list.contains(&l) {
panic!("Argument long must be unique\n\n\t--{} is already in use",
l);
} else {
self.long_list.push(l);
}
if l == "help" {
self.set(AppSettings::NeedsLongHelp);
} else if l == "version" {
self.set(AppSettings::NeedsLongVersion);
}
}
if a.required {
self.required.push(a.name);
}
if a.index.is_some() || (a.short.is_none() && a.long.is_none()) {
let i = if a.index.is_none() {
(self.positionals.len() + 1)
} else {
a.index.unwrap() as usize
};
if self.positionals.contains_key(&i) {
panic!("Argument \"{}\" has the same index as another positional \
argument\n\n\tPerhaps try .multiple(true) to allow one positional argument \
to take multiple values",
a.name);
}
let pb = PosBuilder::from_arg(&a, i as u8, &mut self.required);
// self.positionals_name.insert(pb.name, i);
self.positionals.insert(i, pb);
} else if a.takes_value {
let ob = OptBuilder::from_arg(&a, &mut self.required);
self.opts.push(ob);
} else {
let fb = FlagBuilder::from(a);
self.flags.push(fb);
}
if a.global {
if a.required {
panic!("Global arguments cannot be required.\n\n\t'{}' is marked as global and \
required",
a.name);
}
self.global_args.push(a.into());
}
}
pub fn add_group(&mut self, group: ArgGroup<'a>) {
if group.required {
self.required.push(group.name.into());
if let Some(ref reqs) = group.requires {
for &r in reqs {
self.required.push(r.into());
}
}
if let Some(ref bl) = group.conflicts {
for &b in bl {
self.blacklist.push(b.into());
}
}
}
let mut found = false;
if let Some(ref mut grp) = self.groups.get_mut(&group.name) {
for a in &group.args {
grp.args.push(a);
}
grp.requires = group.requires.clone();
grp.conflicts = group.conflicts.clone();
grp.required = group.required;
found = true;
}
if !found {
self.groups.insert(group.name.into(), group);
}
}
pub fn add_subcommand(&mut self, mut subcmd: App<'a, 'b>) {
if subcmd.0.meta.name == "help" {
self.settings.set(AppSettings::NeedsSubcommandHelp);
}
if self.settings.is_set(AppSettings::VersionlessSubcommands) {
subcmd.0.settings.set(AppSettings::DisableVersion);
}
if self.settings.is_set(AppSettings::GlobalVersion) && subcmd.0.meta.version.is_none() &&
self.version.is_some() {
subcmd.0.meta.version = Some(self.version.unwrap());
}
self.subcommands.push(subcmd);
}
pub fn required(&self) -> Iter<&str> {
self.required.iter()
}
pub fn get_required_from(&self,
reqs: &[&'a str],
matcher: Option<&ArgMatcher<'a>>)
-> VecDeque<String> {
let mut c_flags: Vec<&str> = vec![];
let mut c_pos: Vec<&str> = vec![];
let mut c_opt: Vec<&str> = vec![];
let mut grps: Vec<&str> = vec![];
for name in reqs {
if self.flags.iter().any(|f| &f.name == name) {
c_flags.push(name);
} else if self.opts.iter().any(|o| &o.name == name) {
c_opt.push(name);
} else if self.groups.contains_key(name) {
grps.push(name);
} else {
c_pos.push(name);
}
}
let mut tmp_f = vec![];
for f in &c_flags {
if let Some(f) = self.flags.iter().filter(|flg| &flg.name == f).next() {
if let Some(ref rl) = f.requires {
for r in rl {
if !reqs.contains(r) {
if self.flags.iter().any(|f| &f.name == r) {
tmp_f.push(r);
} else if self.opts.iter().any(|o| &o.name == r) {
c_opt.push(r);
} else if self.groups.contains_key(r) {
grps.push(r);
} else {
c_pos.push(r);
}
}
}
}
}
}
for f in tmp_f.into_iter() {
c_flags.push(f);
}
let mut tmp_o = vec![];
for f in &c_opt {
if let Some(f) = self.opts.iter().filter(|o| &o.name == f).next() {
if let Some(ref rl) = f.requires {
for r in rl {
if !reqs.contains(&r) {
if self.flags.iter().any(|f| &f.name == r) {
c_flags.push(r);
} else if self.opts.iter().any(|o| &o.name == r) {
tmp_o.push(r);
} else if self.groups.contains_key(r) {
grps.push(&r);
} else {
c_pos.push(r);
}
}
}
}
}
}
for f in tmp_o.into_iter() {
c_opt.push(f);
}
let mut tmp_p = vec![];
for p in c_pos.iter() {
if let Some(p) = self.positionals.values().filter(|pos| &pos.name == p).next() {
if let Some(ref rl) = p.requires {
for r in rl {
if !reqs.contains(&&**r) {
if self.flags.iter().any(|f| &f.name == r) {
c_flags.push(r);
} else if self.opts.iter().any(|o| &o.name == r) {
c_opt.push(r);
} else if self.groups.contains_key(r) {
grps.push(&&**r);
} else {
tmp_p.push(r);
}
}
}
}
}
}
for f in tmp_p.into_iter() {
c_pos.push(f);
}
let mut ret_val = VecDeque::new();
let mut pmap = BTreeMap::new();
for p in c_pos.into_iter() {
if matcher.is_some() && matcher.as_ref().unwrap().contains(p) {
continue;
}
if let Some(p) = self.positionals.values().filter(|x| &x.name == &p).next() {
pmap.insert(p.index, format!("{}", p));
}
}
for (_, s) in pmap {
ret_val.push_back(s);
}
for f in c_flags.into_iter() {
if matcher.is_some() && matcher.as_ref().unwrap().contains(f) {
continue;
}
ret_val.push_back(format!("{}", self.flags
.iter()
.filter(|flg| &flg.name == &f)
.next()
.unwrap()));
}
for o in c_opt.into_iter() {
if matcher.is_some() && matcher.as_ref().unwrap().contains(o) {
continue;
}
ret_val.push_back(format!("{}",
self.opts
.iter()
.filter(|opt| &opt.name == &o)
.next()
.unwrap()));
}
for g in grps.into_iter() {
let g_string = self.args_in_group(g)
.iter()
.fold(String::new(), |acc, s| acc + &format!(" {} |", s)[..]);
ret_val.push_back(format!("[{}]", &g_string[..g_string.len() - 1]));
}
ret_val
}
pub fn has_flags(&self) -> bool {
self.flags.is_empty()
}
pub fn has_opts(&self) -> bool {
self.opts.is_empty()
}
pub fn has_positionals(&self) -> bool {
self.positionals.is_empty()
}
pub fn has_subcommands(&self) -> bool {
self.subcommands.is_empty()
}
pub fn is_set(&self, s: AppSettings) -> bool {
self.settings.is_set(s)
}
pub fn set(&mut self, s: AppSettings) {
self.settings.set(s)
}
pub fn verify_positionals(&mut self) {
// Because you must wait until all arguments have been supplied, this is the first chance
// to make assertions on positional argument indexes
//
// Firt we verify that the index highest supplied index, is equal to the number of
// positional arguments to verify there are no gaps (i.e. supplying an index of 1 and 3
// but no 2)
if let Some((idx, ref p)) = self.positionals.iter().rev().next() {
if idx != self.positionals.len() {
panic!("Found positional argument \"{}\" who's index is {} but there are only {} \
positional arguments defined",
p.name,
idx,
self.positionals.len());
}
}
// Next we verify that only the highest index has a .multiple(true) (if any)
assert!(!self.positionals.values()
.any(|a|
a.settings.is_set(ArgSettings::Multiple) &&
(a.index as usize != self.positionals.len())
),
"Only the positional argument with the highest index may accept multiple values");
// If it's required we also need to ensure all previous positionals are
// required too
let mut found = false;
for p in self.positionals.values().rev() {
if !found {
if p.settings.is_set(ArgSettings::Required) {
found = true;
continue;
}
} else {
assert!(p.settings.is_set(ArgSettings::Required),
"Found positional argument which is not required with a lower index than a \
required positional argument: {:?} index {}",
p.name,
p.index);
}
}
}
pub fn propogate_globals(&mut self) {
for sc in self.subcommands.iter_mut() {
// We have to create a new scope in order to tell rustc the borrow of `sc` is
// done and to recursively call this method
{
for a in self.global_args.iter() {
sc.0.add_arg(a);
}
}
sc.0.propogate_globals();
}
}
// The actual parsing function
#[cfg_attr(feature = "lints", allow(while_let_on_iterator))]
pub fn get_matches_with<I, T>(&mut self,
matcher: &mut ArgMatcher<'a>,
it: &mut I)
-> ClapResult<()>
where I: Iterator<Item = T>,
T: Into<OsString>
{
debugln!("fn=get_matches_with;");
// First we create the `--help` and `--version` arguments and add them if
// necessary
self.create_help_and_version();
let mut pos_only = false;
let mut subcmd_name: Option<String> = None;
let mut needs_val_of: Option<&str> = None;
let mut pos_counter = 1;
while let Some(arg) = it.next() {
let arg_os = arg.into();
debugln!("Begin parsing '{:?}' ({:?})", arg_os, &*arg_os.as_bytes());
// Is this a new argument, or values from a previous option?
debug!("Starts new arg...");
let starts_new_arg = if arg_os.starts_with(b"-") {
sdebugln!("Yes");
!(arg_os.len() == 1)
} else {
sdebugln!("No");
false
};
// Has the user already passed '--'?
if !pos_only {
if !starts_new_arg {
// Check to see if parsing a value from an option
if let Some(nvo) = needs_val_of {
// get the OptBuilder so we can check the settings
if let Some(opt) = self.opts.iter().filter(|o| &o.name == &nvo).next() {
needs_val_of = try!(self.add_val_to_arg(opt, &arg_os, matcher));
// get the next value from the iterator
continue;
}
}
}
if arg_os.starts_with(b"--") {
if arg_os.len() == 2 {
// The user has passed '--' which means only positional args follow no matter
// what they start with
pos_only = true;
continue;
}
needs_val_of = try!(self.parse_long_arg(matcher, &arg_os));
continue;
} else if arg_os.starts_with(b"-") && arg_os.len() != 1 {
needs_val_of = try!(self.parse_short_arg(matcher, &arg_os));
continue;
}
// let arg_str = arg_os.to_str().expect(INVALID_UTF8);
if self.subcommands.iter().any(|s| &s.0.meta.name[..] == &*arg_os) {
if &*arg_os == "help" &&
self.settings.is_set(AppSettings::NeedsSubcommandHelp) {
return self._help();
}
// subcommands only support valid UTF-8
subcmd_name = Some(arg_os.to_str().expect(INVALID_UTF8).to_owned());
break;
} else if let Some(candidate) = suggestions::did_you_mean(
&*arg_os.to_string_lossy(),
self.subcommands.iter().map(|s| &s.0.meta.name)) {
return Err(
Error::invalid_subcommand(arg_os.to_string_lossy().into_owned(),
candidate,
self.meta.bin_name.as_ref().unwrap_or(&self.meta.name),
&*self.create_current_usage(matcher)));
}
}
if let Some(p) = self.positionals.get(&pos_counter) {
parse_positional!(self, p, arg_os, pos_only, pos_counter, matcher);
} else {
if self.settings.is_set(AppSettings::AllowExternalSubcommands) {
// let arg_str = arg_os.to_str().expect(INVALID_UTF8);
let mut sc_m = ArgMatcher::new();
while let Some(v) = it.next() {
let a = v.into();
if let None = a.to_str() {
if !self.settings.is_set(AppSettings::StrictUtf8) {
return Err(
Error::invalid_utf8(&*self.create_current_usage(matcher))
);
}
}
sc_m.add_val_to("EXTERNAL_SUBCOMMAND", &a);
}
matcher.subcommand(SubCommand {
name: "EXTERNAL_SUBCOMMAND".into(),
matches: sc_m.into(),
});
} else {
return Err(Error::unknown_argument(
&*arg_os.to_string_lossy(),
"", //self.meta.bin_name.as_ref().unwrap_or(&self.meta.name),
&*self.create_current_usage(matcher)));
}
}
}
let mut reqs_validated = false;
if let Some(a) = needs_val_of {
if let Some(o) = self.opts.iter().filter(|o| &o.name == &a).next() {
try!(self.validate_required(matcher));
reqs_validated = true;
let should_err = if let Some(ref v) = matcher.0.args.get(&*o.name) {
v.vals.is_empty()
} else {
true
};
if should_err {
return Err(Error::empty_value(o, &*self.create_current_usage(matcher)));
}
} else {
return Err(Error::empty_value(self.positionals
.values()
.filter(|p| &p.name == &a)
.next()
.expect(INTERNAL_ERROR_MSG),
&*self.create_current_usage(matcher)));
}
}
try!(self.validate_blacklist(matcher));
try!(self.validate_num_args(matcher));
matcher.usage(self.create_usage(&[]));
if !(self.settings.is_set(AppSettings::SubcommandsNegateReqs) && subcmd_name.is_some()) &&
!reqs_validated {
try!(self.validate_required(matcher));
}
if let Some(sc_name) = subcmd_name {
try!(self.parse_subcommand(sc_name, matcher, it));
} else if self.is_set(AppSettings::SubcommandRequired) {
let bn = self.meta.bin_name.as_ref().unwrap_or(&self.meta.name);
return Err(Error::missing_subcommand(bn, &self.create_current_usage(matcher)));
} else if self.is_set(AppSettings::SubcommandRequiredElseHelp) {
let mut out = vec![];
try!(self.write_help(&mut out));
return Err(Error {
message: String::from_utf8_lossy(&*out).into_owned(),
kind: ErrorKind::MissingArgumentOrSubcommand,
info: None,
});
}
if matcher.is_empty() && matcher.subcommand_name().is_none() &&
self.is_set(AppSettings::ArgRequiredElseHelp) {
let mut out = vec![];
try!(self.write_help(&mut out));
return Err(Error {
message: String::from_utf8_lossy(&*out).into_owned(),
kind: ErrorKind::MissingArgumentOrSubcommand,
info: None,
});
}
Ok(())
}
fn parse_subcommand<I, T>(&mut self, sc_name: String, matcher: &mut ArgMatcher<'a>, it: &mut I) -> ClapResult<()>
where I: Iterator<Item = T>,
T: Into<OsString>
{
use std::fmt::Write;
debugln!("fn=parse_subcommand;");
let mut mid_string = String::new();
if !self.settings.is_set(AppSettings::SubcommandsNegateReqs) {
let mut hs: Vec<&str> = self.required.iter().map(|n| &**n).collect();
for k in matcher.arg_names() {
hs.push(k);
}
let reqs = self.get_required_from(&hs, Some(matcher));
for s in reqs.iter() {
write!(&mut mid_string, " {}", s).expect(INTERNAL_ERROR_MSG);
}
}
mid_string.push_str(" ");
if let Some(ref mut sc) = self.subcommands
.iter_mut()
.filter(|s| &s.0.meta.name[..] == &sc_name)
.next() {
let mut sc_matcher = ArgMatcher::new();
// bin_name should be parent's bin_name + [<reqs>] + the sc's name separated by
// a space
sc.0.meta.usage = Some(format!("{}{}{}",
self.meta.bin_name.as_ref().unwrap_or(&String::new()),
if self.meta.bin_name.is_some() {
&*mid_string
} else {
""
},
&*sc.0.meta.name));
sc.0.meta.bin_name = Some(format!("{}{}{}",
self.meta.bin_name.as_ref().unwrap_or(&String::new()),
if self.meta.bin_name.is_some() {
" "
} else {
""
},
&*sc.0.meta.name));
if let Err(e) = sc.0.get_matches_with(&mut sc_matcher, it) {
e.exit();
}
matcher.subcommand(SubCommand {
name: sc.0.meta.name.clone(),
matches: sc_matcher.into(),
});
}
Ok(())
}
fn blacklisted_from(&self, name: &str, matcher: &ArgMatcher) -> Option<String> {
for k in matcher.arg_names() {
if let Some(f) = self.flags.iter().filter(|f| &f.name == &k).next() {
if let Some(ref bl) = f.blacklist {
if bl.contains(&name) {
return Some(format!("{}", f));
}
}
}
if let Some(o) = self.opts.iter().filter(|o| &o.name == &k).next() {
if let Some(ref bl) = o.blacklist {
if bl.contains(&name) {
return Some(format!("{}", o));
}
}
}
if let Some(pos) = self.positionals.values().filter(|p| &p.name == &k).next() {
if let Some(ref bl) = pos.blacklist {
if bl.contains(&name) {
return Some(format!("{}", pos));
}
}
}
}
None
}
fn overriden_from(&self, name: &str, matcher: &ArgMatcher) -> Option<&'a str> {
for k in matcher.arg_names() {
if let Some(f) = self.flags.iter().filter(|f| &f.name == &k).next() {
if let Some(ref bl) = f.overrides {
if bl.contains(&name.into()) {
return Some(f.name);
}
}
}
if let Some(o) = self.opts.iter().filter(|o| &o.name == &k).next() {
if let Some(ref bl) = o.overrides {
if bl.contains(&name.into()) {
return Some(o.name);
}
}
}
if let Some(pos) = self.positionals.values().filter(|p| &p.name == &k).next() {
if let Some(ref bl) = pos.overrides {
if bl.contains(&name.into()) {
return Some(pos.name);
}
}
}
}
None
}
fn groups_for_arg(&self, name: &str) -> Option<Vec<&'a str>> {
debugln!("fn=groups_for_arg;");
if self.groups.is_empty() {
debugln!("No groups defined");
return None;
}
let mut res = vec![];
debugln!("Searching through groups...");
for (gn, grp) in &self.groups {
for a in &grp.args {
if a == &name {
sdebugln!("\tFound '{}'", gn);
res.push(*gn);
}
}
}
if res.is_empty() {
return None;
}
Some(res)
}
fn args_in_group(&self, group: &str) -> Vec<String> {
let mut g_vec = vec![];
let mut args = vec![];
for n in &self.groups.get(group).unwrap().args {
if let Some(f) = self.flags.iter().filter(|f| &f.name == n).next() {
args.push(f.to_string());
} else if let Some(f) = self.opts.iter().filter(|o| &o.name == n).next() {
args.push(f.to_string());
} else if self.groups.contains_key(&**n) {
g_vec.push(*n);
} else {
if let Some(p) = self.positionals
.values()
.filter(|p| &p.name == n)
.next() {
args.push(p.to_string());
}
}
}
if !g_vec.is_empty() {
for av in g_vec.iter().map(|g| self.args_in_group(g)) {
for a in av {
args.push(a);
}
}
}
assert!(!args.is_empty(),
"ArgGroup '{}' doesn't contain any args",
group);
args.dedup();
args.iter().map(ToOwned::to_owned).collect()
}
fn arg_names_in_group(&self, group: &str) -> Vec<&'a str> {
let mut g_vec = vec![];
let mut args = vec![];
for n in &self.groups.get(group).unwrap().args {
if self.flags.iter().any(|f| &f.name == n) {
args.push(*n);
} else if self.opts.iter().any(|o| &o.name == n) {
args.push(*n);
} else if self.groups.contains_key(&**n) {
g_vec.push(*n);
} else if self.positionals.values().any(|p| &p.name == n) {
args.push(*n);
}
}
if !g_vec.is_empty() {
for av in g_vec.iter().map(|g| self.arg_names_in_group(g)) {
for a in av {
args.push(a.into());
}
}
}
assert!(!args.is_empty(),
"ArgGroup '{}' doesn't contain any args",
group);
args.dedup();
args.iter().map(|s| *s).collect()
}
fn create_help_and_version(&mut self) {
debugln!("fn=create_help_and_version;");
// name is "hclap_help" because flags are sorted by name
if !self.flags.iter().any(|a| a.long.is_some() && a.long.unwrap() == "help") {
if self.help_short.is_none() && !self.short_list.contains(&'h') {
self.help_short = Some('h');
}
let arg = FlagBuilder {
name: "hclap_help".into(),
short: self.help_short,
long: Some("help".into()),
help: Some("Prints help information".into()),
blacklist: None,
requires: None,
overrides: None,
settings: ArgFlags::new(),
};
self.long_list.push("help".into());
self.flags.push(arg);
}
if !self.settings.is_set(AppSettings::DisableVersion) &&
!self.flags.iter().any(|a| a.long.is_some() && a.long.unwrap() == "version") {
if self.version_short.is_none() && !self.short_list.contains(&'V') {
self.version_short = Some('V');
}
// name is "vclap_version" because flags are sorted by name
let arg = FlagBuilder {
name: "vclap_version".into(),
short: self.version_short,
long: Some("version".into()),
help: Some("Prints version information".into()),
blacklist: None,
requires: None,
overrides: None,
settings: ArgFlags::new(),
};
self.long_list.push("version".into());
self.flags.push(arg);
}
if !self.subcommands.is_empty() &&
!self.subcommands
.iter()
.any(|s| &s.0.meta.name[..] == "help") {
self.subcommands.push(App::new("help").about("Prints this message"));
}
}
// Retrieves the names of all args the user has supplied thus far, except required ones
// because those will be listed in self.required
pub fn create_current_usage(&self, matcher: &'b ArgMatcher<'a>) -> String {
self.create_usage(
&*matcher.arg_names()
.iter()
.filter(|n| {
if let Some(o) = self.opts
.iter()
.filter(|&o| &&o.name == n)
.next() {
!o.settings.is_set(ArgSettings::Required)
} else if let Some(p) = self.positionals
.values()
.filter(|&p| &&p.name == n)
.next() {
!p.settings.is_set(ArgSettings::Required)
} else {
true // flags can't be required, so they're always true
}})
.map(|&n| n)
.collect::<Vec<_>>())
}
fn check_for_help_and_version_str(&self, arg: &OsStr) -> ClapResult<()> {
debug!("Checking if --{} is help or version...", arg.to_str().unwrap());
if arg == "help" && self.settings.is_set(AppSettings::NeedsLongHelp) {
try!(self._help());
}
if arg == "version" && self.settings.is_set(AppSettings::NeedsLongVersion) {
try!(self._version());
}
sdebugln!("Neither");
Ok(())
}
fn check_for_help_and_version_char(&self, arg: char) -> ClapResult<()> {
debug!("Checking if -{} is help or version...", arg);
if let Some(h) = self.help_short { if arg == h { try!(self._help()); } }
if let Some(v) = self.version_short { if arg == v { try!(self._version()); } }
sdebugln!("Neither");
Ok(())
}
fn _help(&self) -> ClapResult<()> {
try!(self.print_help());
Err(Error {
message: String::new(),
kind: ErrorKind::HelpDisplayed,
info: None,
})
}
fn _version(&self) -> ClapResult<()> {
let out = io::stdout();
let mut buf_w = BufWriter::new(out.lock());
try!(self.print_version(&mut buf_w));
Err(Error {
message: String::new(),
kind: ErrorKind::VersionDisplayed,
info: None,
})
}
fn parse_long_arg(&mut self,
matcher: &mut ArgMatcher<'a>,
full_arg: &OsStr)
-> ClapResult<Option<&'b str>> { // maybe here lifetime should be 'a
debugln!("fn=parse_long_arg;");
let mut val = None;
debug!("Does it contain '='...");
let arg = if full_arg.contains_byte(b'=') {
let (p0, p1) = full_arg.trim_left_matches(b'-').split_at_byte(b'=');
sdebugln!("Yes '{:?}'", p1);
val = Some(p1);
p0
} else {
sdebugln!("No");
full_arg.trim_left_matches(b'-')
};
if let Some(opt) = self.opts
.iter()
.filter(|v| v.long.is_some() && &*v.long.unwrap() == arg)
.next() {
debugln!("Found valid opt '{}'", opt.to_string());
let ret = try!(self.parse_opt(val, opt, matcher));
arg_post_processing!(self, opt, matcher);
return Ok(ret);
} else if let Some(flag) = self.flags
.iter()
.filter(|v| v.long.is_some() && &*v.long.unwrap() == arg)
.next() {
debugln!("Found valid flag '{}'", flag.to_string());
// Only flags could be help or version, and we need to check the raw long
// so this is the first point to check
try!(self.check_for_help_and_version_str(&arg));
try!(self.parse_flag(flag, matcher));
// Handle conflicts, requirements, etc.
arg_post_processing!(self, flag, matcher);
return Ok(None);
}
debugln!("Didn't match anything");
self.did_you_mean_error(arg.to_str().expect(INVALID_UTF8), matcher).map(|_| None)
}
fn parse_short_arg(&mut self,
matcher: &mut ArgMatcher<'a>,
full_arg: &OsStr)
-> ClapResult<Option<&'a str>> {
debugln!("fn=parse_short_arg;");
// let mut utf8 = true;
let arg_os = full_arg.trim_left_matches(b'-');
let arg = arg_os.to_string_lossy();
for c in arg.chars() {
// Check for matching short options, and return the name if there is no trailing
// concatenated value: -oval
// Option: -o
// Value: val
if let Some(opt) = self.opts
.iter()
.filter(|&v| v.short.is_some() && v.short.unwrap() == c)
.next() {
debugln!("Found valid short opt -{} in '{}'", c, arg);
// Check for trailing concatenated value
let p: Vec<_> = arg.splitn(2, c).collect();
debugln!("arg: {:?}, arg_os: {:?}, full_arg: {:?}", arg, arg_os, full_arg);
debugln!("p[0]: {:?}, p[1]: {:?}", p[0].as_bytes(), p[1].as_bytes());
let i = p[0].as_bytes().len() + 1;
let val = if p[1].as_bytes().len() > 0 {
debugln!("setting val: {:?} (bytes), {:?} (ascii)", arg_os.split_at(i).1.as_bytes(), arg_os.split_at(i).1);
Some(arg_os.split_at(i).1)
} else {
None
};
// Default to "we're expecting a value later"
let ret = try!(self.parse_opt(val, opt, matcher));
arg_post_processing!(self, opt, matcher);
return Ok(ret);
} else if let Some(flag) = self.flags.iter().filter(|&v| v.short.is_some() && v.short.unwrap() == c).next() {
debugln!("Found valid short flag -{}", c);
// Only flags can be help or version
try!(self.check_for_help_and_version_char(c));
try!(self.parse_flag(flag, matcher));
// Handle conflicts, requirements, overrides, etc.
// Must be called here due to mutablilty
arg_post_processing!(self, flag, matcher);
} else {
let mut arg = String::new();
arg.push('-');
arg.push(c);
return Err(
Error::unknown_argument(&*arg, "", &*self.create_current_usage(matcher)));
}
}
Ok(None)
}
fn parse_opt(&self,
val: Option<&OsStr>,
opt: &OptBuilder<'a, 'b>,
matcher: &mut ArgMatcher<'a>)
-> ClapResult<Option<&'a str>> {
debugln!("fn=parse_opt;");
validate_multiples!(self, opt, matcher);
debug!("Checking for val...");
if let Some(mut v) = val {
v = v.trim_left_matches(b'=');
if !opt.is_set(ArgSettings::EmptyValues) && v.len() == 0 {
sdebugln!("Found Empty - Error");
return Err(Error::empty_value(opt, &*self.create_current_usage(matcher)));
}
sdebugln!("Found");
try!(self.add_val_to_arg(opt, v, matcher));
} else { sdebugln!("None"); }
if (opt.is_set(ArgSettings::Multiple) || opt.num_vals().is_some())
|| val.is_none() {
return Ok(Some(opt.name));
}
Ok(None)
}
fn add_val_to_arg<A>(&self,
arg: &A,
val: &OsStr,
matcher: &mut ArgMatcher<'a>)
-> ClapResult<Option<&'a str>>
where A: AnyArg<'a, 'b> + Display {
matcher.add_val_to(&*arg.name(), val);
// Increment or create the group "args"
if let Some(grps) = self.groups_for_arg(&*arg.name()) {
for grp in grps {
matcher.add_val_to(&*grp, val);
}
}
// The validation must come AFTER inserting into 'matcher' or the usage string
// can't be built
self.validate_value(arg, val, matcher)
}
fn validate_value<A>(&self, arg: &A, val: &OsStr, matcher: &ArgMatcher<'a>) -> ClapResult<Option<&'a str>>
where A: AnyArg<'a, 'b> {
debugln!("fn=validate_value; val={:?}", val);
if self.is_set(AppSettings::StrictUtf8) && val.to_str().is_none() {
return Err(Error::invalid_utf8(&*self.create_current_usage(matcher)));
}
if let Some(ref p_vals) = arg.possible_vals() {
let val_str = val.to_string_lossy();
if !p_vals.contains(&&*val_str) {
return Err(
Error::invalid_value(val_str,
p_vals,
arg,
&*self.create_current_usage(matcher)));
}
}
if !arg.is_set(ArgSettings::EmptyValues) &&
val.is_empty() &&
matcher.contains(&*arg.name()) {
return Err(Error::empty_value(arg, &*self.create_current_usage(matcher)));
}
if let Some(ref vtor) = arg.validator() {
if let Err(e) = vtor(val.to_string_lossy().into_owned()) {
return Err(Error::value_validation(e));
}
}
let vals = matcher.get(&*arg.name())
.expect(INTERNAL_ERROR_MSG)
.vals.len();
if let Some(max) = arg.max_vals() {
if (vals as u8) < max {
return Ok(Some(arg.name()));
} else {
return Ok(None);
}
}
if let Some(..) = arg.min_vals() {
return Ok(Some(arg.name()));
}
if let Some(num) = arg.num_vals() {
if arg.is_set(ArgSettings::Multiple) {
if (vals as u8) < num {
return Ok(Some(arg.name()));
}
} else {
if (vals as u8 % num) != 0 {
return Ok(Some(arg.name()));
}
}
}
if arg.is_set(ArgSettings::Multiple) {
return Ok(Some(arg.name()));
}
Ok(None)
}
fn parse_flag(&self, flag: &FlagBuilder<'a, 'b>, matcher: &mut ArgMatcher<'a>) -> ClapResult<()> {
debugln!("fn=parse_flag;");
validate_multiples!(self, flag, matcher);
matcher.inc_occurrence_of(&*flag.name.clone());
// Increment or create the group "args"
self.groups_for_arg(flag.name).and_then(|vec| Some(matcher.inc_occurrences_of(&*vec)));
Ok(())
}
// fn validate_arg<A>(&self, arg: &A, matcher: &mut ArgMatcher) -> ClapResult<()>
// where A: AnyArg<'a, 'b> + Display {
// debugln!("fn=validate_arg;");
//
// /*
// Might not be required if we validate the blacklist later on as well too...
//
// debug!("Can we use '{}'...", arg.to_string());
// // Ensure this arg isn't on the mutually excludes list
// if self.blacklist.contains(&arg.name()) {
// sdebugln!("No");
// matcher.remove(&*arg.name());
// return Err(
// Error::argument_conflict(arg,
// self.blacklisted_from(&*arg.name(), &matcher),
// &*self.create_current_usage(matcher)));
// }
// sdebugln!("Yes");
// */
//
// // Make sure this isn't one being added multiple times if it doesn't support it
// if matcher.contains(&*arg.name()) && !arg.is_set(ArgSettings::Multiple) {
// return Err(
// Error::unexpected_multiple_usage(arg, &*self.create_current_usage(matcher)));
// }
//
// Ok(())
// }
fn validate_blacklist(&self, matcher: &mut ArgMatcher) -> ClapResult<()> {
debugln!("fn=validate_blacklist;");
macro_rules! build_err {
($me:ident, $name:expr, $matcher:ident) => ({
debugln!("macro=build_err;");
let c_with = $me.blacklisted_from($name, &$matcher);
debugln!("'{:?}' conflicts with '{}'", c_with, $name);
let usg = $me.create_current_usage($matcher);
if let Some(f) = $me.flags.iter().filter(|f| f.name == $name).next() {
debugln!("It was a flag...");
Error::argument_conflict(f, c_with, &*usg)
} else if let Some(o) = $me.opts.iter()
.filter(|o| o.name == $name)
.next() {
debugln!("It was an option...");
Error::argument_conflict(o, c_with, &*usg)
} else {
match $me.positionals.values()
.filter(|p| p.name == $name)
.next() {
Some(p) => {
debugln!("It was a positional...");
Error::argument_conflict(p, c_with, &*usg)
},
None => panic!(INTERNAL_ERROR_MSG)
}
}
});
}
for name in &self.blacklist {
debugln!("Checking blacklisted name: {}", name);
if self.groups.contains_key(name) {
debugln!("groups contains it...");
for n in self.arg_names_in_group(name) {
debugln!("Checking arg '{}' in group...", n);
if matcher.contains(&n) {
debugln!("matcher contains it...");
return Err(build_err!(self, n, matcher));
}
}
} else if matcher.contains(name) {
debugln!("matcher contains it...");
return Err(build_err!(self, *name, matcher));
}
}
Ok(())
}
fn validate_num_args(&self, matcher: &mut ArgMatcher) -> ClapResult<()> {
for (name, ma) in matcher.iter() {
if self.groups.contains_key(&**name) {
continue;
} else {
if let Some(opt) = self.opts
.iter()
.filter(|o| &o.name == name)
.next() {
if let Some(num) = opt.num_vals {
let should_err = if opt.settings.is_set(ArgSettings::Multiple) {
((ma.vals.len() as u8) % num) != 0
} else {
num != (ma.vals.len() as u8)
};
if should_err {
return Err(Error::wrong_number_of_values(
opt,
num,
if opt.settings.is_set(ArgSettings::Multiple) {
(ma.vals.len() % num as usize)
} else {
ma.vals.len()
},
if ma.vals.len() == 1 ||
(opt.settings.is_set(ArgSettings::Multiple) &&
(ma.vals.len() % num as usize) == 1) {
"as"
} else {
"ere"
},
&*self.create_current_usage(matcher)));
}
}
if let Some(num) = opt.max_vals {
if (ma.vals.len() as u8) > num {
return Err(Error::too_many_values(
ma.vals.get(&ma.vals.keys()
.last()
.expect(INTERNAL_ERROR_MSG))
.expect(INTERNAL_ERROR_MSG).to_str().expect(INVALID_UTF8),
opt,
&*self.create_current_usage(matcher)));
}
}
if let Some(num) = opt.min_vals {
if (ma.vals.len() as u8) < num {
return Err(Error::too_few_values(
opt,
num,
ma.vals.len(),
&*self.create_current_usage(matcher)));
}
}
} else if let Some(pos) = self.positionals
.values()
.filter(|p| &p.name == name)
.next() {
if let Some(num) = pos.num_vals {
if num != ma.vals.len() as u8 {
return Err(Error::wrong_number_of_values(
pos,
num,
ma.vals.len(),
if ma.vals.len() == 1 {
"as"
} else {
"ere"
},
&*self.create_current_usage(matcher)));
}
} else if let Some(max) = pos.max_vals {
if (ma.vals.len() as u8) > max {
return Err(
Error::too_many_values(
ma.vals.get(&ma.vals.keys()
.last()
.expect(INTERNAL_ERROR_MSG))
.expect(INTERNAL_ERROR_MSG)
.to_string_lossy()
.into_owned(),
pos,
&*self.create_current_usage(matcher)));
}
}
if let Some(min) = pos.min_vals {
if (ma.vals.len() as u8) < min {
return Err(Error::too_few_values(
pos,
min,
ma.vals.len(),
&*self.create_current_usage(matcher)));
}
}
}
}
}
Ok(())
}
fn validate_required(&self, matcher: &ArgMatcher) -> ClapResult<()> {
'outer: for name in self.required.iter() {
if matcher.contains(name) {
continue 'outer;
}
if let Some(grp) = self.groups.get(name) {
for arg in &grp.args {
if matcher.contains(arg) { continue 'outer; }
}
}
if self.groups.values().any(|g| g.args.contains(name)) {
continue 'outer;
}
if let Some(a) = self.flags.iter().filter(|f| &f.name == name).next() {
if self._validate_blacklist_required(a, matcher) { continue 'outer; }
}
if let Some(a) = self.opts.iter().filter(|o| &o.name == name).next() {
if self._validate_blacklist_required(a, matcher) { continue 'outer; }
}
if let Some(a) = self.positionals.values().filter(|p| &p.name == name).next() {
if self._validate_blacklist_required(a, matcher) { continue 'outer; }
}
let err = if self.settings.is_set(AppSettings::ArgRequiredElseHelp) && matcher.is_empty() {
self._help().unwrap_err()
} else {
Error::missing_required_argument(
&*self.get_required_from(&*self.required.iter().map(|&r| &*r).collect::<Vec<_>>(), Some(matcher))
.iter()
.fold(String::new(),
|acc, s| acc + &format!("\n\t{}", Format::Error(s))[..]),
&*self.create_current_usage(matcher))
};
return Err(err);
}
Ok(())
}
fn _validate_blacklist_required<A>(&self, a: &A, matcher: &ArgMatcher) -> bool where A: AnyArg<'a, 'b> {
if let Some(bl) = a.blacklist() {
for n in bl.iter() {
if matcher.contains(n) {
return true;
} else if self.groups
.get(n)
.map_or(false, |g| g.args.iter().any(|an| matcher.contains(an))) {
return true;
}
}
}
false
}
fn did_you_mean_error(&self, arg: &str, matcher: &mut ArgMatcher<'a>) -> ClapResult<()> {
// Didn't match a flag or option...maybe it was a typo and close to one
let suffix = suggestions::did_you_mean_suffix(arg,
self.long_list.iter(),
suggestions::DidYouMeanMessageStyle::LongFlag);
// Add the arg to the matches to build a proper usage string
if let Some(name) = suffix.1 {
if let Some(opt) = self.opts
.iter()
.filter(|o| o.long.is_some() && o.long.unwrap() == name)
.next() {
self.groups_for_arg(&*opt.name).and_then(|grps| Some(matcher.inc_occurrences_of(&*grps)));
matcher.insert(&*opt.name.clone());
} else if let Some(flg) = self.flags
.iter()
.filter(|f| f.long.is_some() && f.long.unwrap() == name)
.next() {
self.groups_for_arg(&*flg.name).and_then(|grps| Some(matcher.inc_occurrences_of(&*grps)));
matcher.insert(&*flg.name.clone());
}
}
Err(Error::unknown_argument(arg, &*suffix.0, &*self.create_current_usage(matcher)))
}
// Creates a usage string if one was not provided by the user manually. This happens just
// after all arguments were parsed, but before any subcommands have been parsed
// (so as to give subcommands their own usage recursively)
fn create_usage(&self, used: &[&str]) -> String {
debugln!("fn=create_usage;");
let mut usage = String::with_capacity(75);
usage.push_str("USAGE:\n\t");
if let Some(u) = self.meta.usage_str {
usage.push_str(&*u);
} else if !used.is_empty() {
self.smart_usage(&mut usage, used);
} else {
usage.push_str(&*self.meta.usage
.as_ref()
.unwrap_or(self.meta.bin_name
.as_ref()
.unwrap_or(&self.meta.name)));
let reqs: Vec<&str> = self.required().map(|r| &**r).collect();
let req_string = self.get_required_from(&reqs, None)
.iter()
.fold(String::new(), |a, s| a + &format!(" {}", s)[..]);
if !self.has_flags() && !self.is_set(AppSettings::UnifiedHelpMessage) {
usage.push_str(" [FLAGS]");
} else {
usage.push_str(" [OPTIONS]");
}
if !self.is_set(AppSettings::UnifiedHelpMessage) && !self.has_opts() &&
self.opts.iter().any(|a| !a.settings.is_set(ArgSettings::Required)) {
usage.push_str(" [OPTIONS]");
}
usage.push_str(&req_string[..]);
// places a '--' in the usage string if there are args and options
// supporting multiple values
if !self.has_positionals()
&& (self.opts.iter().any(|a| a.settings.is_set(ArgSettings::Multiple))
|| self.positionals.values().any(|a| a.settings.is_set(ArgSettings::Multiple)))
&& !self.opts.iter().any(|a| a.settings.is_set(ArgSettings::Required))
&& self.has_subcommands() {
usage.push_str(" [--]")
}
if !self.has_positionals()
&& self.positionals.values().any(|a| !a.settings.is_set(ArgSettings::Required)) {
usage.push_str(" [ARGS]");
}
if !self.has_subcommands() && !self.is_set(AppSettings::SubcommandRequired) {
usage.push_str(" [SUBCOMMAND]");
} else if self.is_set(AppSettings::SubcommandRequired) && !self.has_subcommands() {
usage.push_str(" <SUBCOMMAND>");
}
}
usage.shrink_to_fit();
usage
}
// Creates a context aware usage string, or "smart usage" from currently used
// args, and requirements
fn smart_usage(&self, usage: &mut String, used: &[&str]) {
let mut hs: Vec<&str> = self.required().map(|s| &**s).collect();
for n in used {
hs.push(n);
}
let r_string = self.get_required_from(&hs, None)
.iter()
.fold(String::new(), |acc, s| acc + &format!(" {}", s)[..]);
usage.push_str(&self.meta.usage.as_ref()
.unwrap_or(self.meta.bin_name.as_ref().unwrap_or(&self.meta.name))[..]);
usage.push_str(&*r_string);
if self.is_set(AppSettings::SubcommandRequired) {
usage.push_str(" <SUBCOMMAND>");
}
}
// Prints the version to the user and exits if quit=true
fn print_version<W: Write>(&self, w: &mut W) -> ClapResult<()> {
try!(self.write_version(w));
w.flush().map_err(Error::from)
}
fn write_version<W: Write>(&self, w: &mut W) -> io::Result<()> {
if let Some(bn) = self.meta.bin_name.as_ref() {
if bn.contains(" ") {
// Incase we're dealing with subcommands i.e. git mv is translated to git-mv
writeln!(w, "{} {}", bn.replace(" ", "-"), self.meta.version.unwrap_or("".into()))
} else {
writeln!(w, "{} {}", &self.meta.name[..], self.meta.version.unwrap_or("".into()))
}
} else {
writeln!(w, "{} {}", &self.meta.name[..], self.meta.version.unwrap_or("".into()))
}
}
pub fn print_help(&self) -> ClapResult<()> {
let out = io::stdout();
let mut buf_w = BufWriter::new(out.lock());
self.write_help(&mut buf_w)
}
pub fn write_help<W: Write>(&self, w: &mut W) -> ClapResult<()> {
if let Some(h) = self.meta.help_str {
return writeln!(w, "{}", h).map_err(Error::from);
}
// Print the version
try!(self.write_version(w));
if let Some(author) = self.meta.author {
try!(write!(w, "{}\n", author));
}
if let Some(about) = self.meta.about {
try!(write!(w, "{}\n", about));
}
try!(write!(w, "\n{}", self.create_usage(&[])));
let flags = !self.has_flags();
let pos = !self.has_positionals();
let opts = !self.has_opts();
let subcmds = !self.has_subcommands();
let unified_help = self.is_set(AppSettings::UnifiedHelpMessage);
let mut longest_flag = 0;
for fl in self.flags.iter()
.filter(|f| f.long.is_some() && !f.settings.is_set(ArgSettings::Hidden))
.map(|a| a.to_string().len()) {
if fl > longest_flag {
longest_flag = fl;
}
}
let mut longest_opt = 0;
for ol in self.opts.iter()
.filter(|o| !o.settings.is_set(ArgSettings::Hidden))
.map(|a| a.to_string().len()) {
if ol > longest_opt {
longest_opt = ol;
}
}
let mut longest_pos = 0;
for pl in self.positionals
.values()
.filter(|p| !p.settings.is_set(ArgSettings::Hidden))
.map(|f| f.to_string().len()) {
if pl > longest_pos {
longest_pos = pl;
}
}
let mut longest_sc = 0;
for scl in self.subcommands
.iter()
.filter(|s| !s.0.is_set(AppSettings::Hidden))
.map(|s| s.0.meta.name.len()) {
if scl > longest_sc {
longest_sc = scl;
}
}
if flags || opts || pos || subcmds {
try!(write!(w, "\n"));
}
let tab = " ";
let longest = if !unified_help || longest_opt == 0 {
longest_flag
} else {
longest_opt
};
if unified_help && (flags || opts) {
try!(write!(w, "\nOPTIONS:\n"));
let mut combined = BTreeMap::new();
for f in self.flags.iter().filter(|f| !f.settings.is_set(ArgSettings::Hidden)) {
let mut v = vec![];
try!(f.write_help(&mut v, tab, longest));
combined.insert(f.name, v);
}
for o in self.opts.iter().filter(|o| !o.settings.is_set(ArgSettings::Hidden)) {
let mut v = vec![];
try!(o.write_help(&mut v, tab, longest));
combined.insert(o.name, v);
}
for (_, a) in combined {
// Only valid UTF-8 is supported, so panicing on invalid UTF-8 is ok
try!(write!(w, "{}", unsafe { String::from_utf8_unchecked(a) }));
}
} else {
if flags {
try!(write!(w, "\nFLAGS:\n"));
for (_, f) in self.flags.iter()
.filter(|f| !f.settings.is_set(ArgSettings::Hidden))
.map(|f| (f.name, f))
.collect::<BTreeMap<_, _>>() {
try!(f.write_help(w, tab, longest));
}
}
if opts {
try!(write!(w, "\nOPTIONS:\n"));
for (_, o) in self.opts.iter()
.filter(|o| !o.settings.is_set(ArgSettings::Hidden))
.map(|o| (o.name, o))
.collect::<BTreeMap<_, _>>() {
try!(o.write_help(w, tab, longest_opt));
}
}
}
if pos {
try!(write!(w, "\nARGS:\n"));
for v in self.positionals.values()
.filter(|p| !p.settings.is_set(ArgSettings::Hidden)) {
try!(v.write_help(w, tab, longest_pos));
}
}
if subcmds {
try!(write!(w, "\nSUBCOMMANDS:\n"));
for (name, sc) in self.subcommands.iter()
.filter(|s| !s.0.is_set(AppSettings::Hidden))
.map(|s| (&s.0.meta.name[..], s))
.collect::<BTreeMap<_, _>>() {
try!(write!(w, "{}{}", tab, name));
write_spaces!((longest_sc + 4) - (name.len()), w);
if let Some(a) = sc.0.meta.about {
if a.contains("{n}") {
let mut ab = a.split("{n}");
while let Some(part) = ab.next() {
try!(write!(w, "{}\n", part));
write_spaces!(longest_sc + 8, w);
try!(write!(w, "{}", ab.next().unwrap_or("")));
}
} else {
try!(write!(w, "{}", a));
}
}
try!(write!(w, "\n"));
}
}
if let Some(h) = self.meta.more_help {
try!(write!(w, "\n{}", h));
}
w.flush().map_err(Error::from)
}
}