fish-shell/src/expand.rs
Mahmoud Al-Qudsi 5f8f799cf7 Replace C++ doc \return with "Return"
quick_replace '\\\\return(s)? ' 'Return$1 ' src/

Filtered to only lines beginning with //
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Rust

//! String expansion functions. These functions perform several kinds of parameter expansion. There
//! are a lot of issues with regards to memory allocation. Overall, these functions would benefit
//! from using a more clever memory allocation scheme, perhaps an evil combination of talloc,
//! string buffers and reference counting.
use crate::builtins::shared::{
STATUS_CMD_ERROR, STATUS_CMD_UNKNOWN, STATUS_EXPAND_ERROR, STATUS_ILLEGAL_CMD,
STATUS_INVALID_ARGS, STATUS_NOT_EXECUTABLE, STATUS_READ_TOO_MUCH, STATUS_UNMATCHED_WILDCARD,
};
use crate::common::{
char_offset, charptr2wcstring, escape, escape_string, escape_string_for_double_quotes,
unescape_string, valid_var_name_char, wcs2zstring, EscapeFlags, EscapeStringStyle,
UnescapeFlags, UnescapeStringStyle, EXPAND_RESERVED_BASE, EXPAND_RESERVED_END,
};
use crate::complete::{CompleteFlags, Completion, CompletionList, CompletionReceiver};
use crate::env::{EnvVar, Environment};
use crate::exec::exec_subshell_for_expand;
use crate::future_feature_flags::{feature_test, FeatureFlag};
use crate::history::{history_session_id, History};
use crate::operation_context::OperationContext;
use crate::parse_constants::{ParseError, ParseErrorCode, ParseErrorList, SOURCE_LOCATION_UNKNOWN};
use crate::parse_util::{
parse_util_expand_variable_error, parse_util_locate_cmdsubst_range, MaybeParentheses,
};
use crate::path::path_apply_working_directory;
use crate::util::wcsfilecmp_glob;
use crate::wchar::prelude::*;
use crate::wcstringutil::{join_strings, trim};
use crate::wildcard::{wildcard_expand_string, wildcard_has_internal};
use crate::wildcard::{WildcardResult, ANY_CHAR, ANY_STRING, ANY_STRING_RECURSIVE};
use crate::wutil::{normalize_path, wcstoi_partial, Options};
use bitflags::bitflags;
bitflags! {
/// Set of flags controlling expansions.
#[derive(Copy, Clone, Default)]
pub struct ExpandFlags : u16 {
/// Fail expansion if there is a command substitution.
const FAIL_ON_CMDSUBST = 1 << 0;
/// Skip command substitutions.
const SKIP_CMDSUBST = 1 << 14;
/// Skip variable expansion.
const SKIP_VARIABLES = 1 << 1;
/// Skip wildcard expansion.
const SKIP_WILDCARDS = 1 << 2;
/// The expansion is being done for tab or auto completions. Returned completions may have the
/// wildcard as a prefix instead of a match.
const FOR_COMPLETIONS = 1 << 3;
/// Only match files that are executable by the current user.
const EXECUTABLES_ONLY = 1 << 4;
/// Only match directories.
const DIRECTORIES_ONLY = 1 << 5;
/// Generate descriptions, stored in the description field of completions.
const GEN_DESCRIPTIONS = 1 << 6;
/// Un-expand home directories to tildes after.
const PRESERVE_HOME_TILDES = 1 << 7;
/// Allow fuzzy matching.
const FUZZY_MATCH = 1 << 8;
/// Disallow directory abbreviations like /u/l/b for /usr/local/bin. Only applicable if
/// fuzzy_match is set.
const NO_FUZZY_DIRECTORIES = 1 << 9;
/// Allows matching a leading dot even if the wildcard does not contain one.
/// By default, wildcards only match a leading dot literally; this is why e.g. '*' does not
/// match hidden files.
const ALLOW_NONLITERAL_LEADING_DOT = 1 << 10;
/// Do expansions specifically to support cd. This means using CDPATH as a list of potential
/// working directories, and to use logical instead of physical paths.
const SPECIAL_FOR_CD = 1 << 11;
/// Do expansions specifically for cd autosuggestion. This is to differentiate between cd
/// completions and cd autosuggestions.
const SPECIAL_FOR_CD_AUTOSUGGESTION = 1 << 12;
/// Do expansions specifically to support external command completions. This means using PATH as
/// a list of potential working directories.
const SPECIAL_FOR_COMMAND = 1 << 13;
}
}
/// Character representing a home directory.
pub const HOME_DIRECTORY: char = char_offset(EXPAND_RESERVED_BASE, 0);
/// Character representing process expansion for %self.
pub const PROCESS_EXPAND_SELF: char = char_offset(EXPAND_RESERVED_BASE, 1);
/// Character representing variable expansion.
pub const VARIABLE_EXPAND: char = char_offset(EXPAND_RESERVED_BASE, 2);
/// Character representing variable expansion into a single element.
pub const VARIABLE_EXPAND_SINGLE: char = char_offset(EXPAND_RESERVED_BASE, 3);
/// Character representing the start of a bracket expansion.
pub const BRACE_BEGIN: char = char_offset(EXPAND_RESERVED_BASE, 4);
/// Character representing the end of a bracket expansion.
pub const BRACE_END: char = char_offset(EXPAND_RESERVED_BASE, 5);
/// Character representing separation between two bracket elements.
pub const BRACE_SEP: char = char_offset(EXPAND_RESERVED_BASE, 6);
/// Character that takes the place of any whitespace within non-quoted text in braces
pub const BRACE_SPACE: char = char_offset(EXPAND_RESERVED_BASE, 7);
/// Separate subtokens in a token with this character.
pub const INTERNAL_SEPARATOR: char = char_offset(EXPAND_RESERVED_BASE, 8);
/// Character representing an empty variable expansion. Only used transitively while expanding
/// variables.
pub const VARIABLE_EXPAND_EMPTY: char = char_offset(EXPAND_RESERVED_BASE, 9);
const _: () = assert!(
EXPAND_RESERVED_END as u32 > VARIABLE_EXPAND_EMPTY as u32,
"Characters used in expansions must stay within private use area"
);
impl ExpandResult {
pub fn new(result: ExpandResultCode) -> Self {
Self { result, status: 0 }
}
pub fn ok() -> Self {
Self::new(ExpandResultCode::ok)
}
/// Make an error value with the given status.
pub fn make_error(status: libc::c_int) -> Self {
assert!(status != 0, "status cannot be 0 for an error result");
Self {
result: ExpandResultCode::error,
status,
}
}
}
impl PartialEq<ExpandResultCode> for ExpandResult {
fn eq(&self, other: &ExpandResultCode) -> bool {
self.result == *other
}
}
/// The string represented by PROCESS_EXPAND_SELF
pub const PROCESS_EXPAND_SELF_STR: &wstr = L!("%self");
/// Perform various forms of expansion on in, such as tilde expansion (\~USER becomes the users home
/// directory), variable expansion (\$VAR_NAME becomes the value of the environment variable
/// VAR_NAME), cmdsubst expansion and wildcard expansion. The results are inserted into the list
/// out.
///
/// If the parameter does not need expansion, it is copied into the list out.
///
/// \param input The parameter to expand
/// \param output The list to which the result will be appended.
/// \param ctx The parser, variables, and cancellation checker for this operation. The parser may
/// be null. \param errors Resulting errors, or nullptr to ignore
///
/// Return An expand_result_t.
/// wildcard_no_match and wildcard_match are normal exit conditions used only on
/// strings containing wildcards to tell if the wildcard produced any matches.
pub fn expand_string(
input: WString,
out_completions: &mut CompletionList,
flags: ExpandFlags,
ctx: &OperationContext,
errors: Option<&mut ParseErrorList>,
) -> ExpandResult {
let mut completions = vec![];
std::mem::swap(&mut completions, out_completions);
let mut recv = CompletionReceiver::from_list(completions, ctx.expansion_limit);
let result = expand_to_receiver(input, &mut recv, flags, ctx, errors);
*out_completions = recv.take();
result
}
/// Variant of string that inserts its results into a completion_receiver_t.
pub fn expand_to_receiver(
input: WString,
out_completions: &mut CompletionReceiver,
flags: ExpandFlags,
ctx: &OperationContext,
errors: Option<&mut ParseErrorList>,
) -> ExpandResult {
Expander::expand_string(input, out_completions, flags, ctx, errors)
}
/// expand_one is identical to expand_string, except it will fail if in expands to more than one
/// string. This is used for expanding command names.
///
/// \param inout_str The parameter to expand in-place
/// \param ctx The parser, variables, and cancellation checker for this operation. The parser may be
/// null.
/// \param errors Resulting errors, or nullptr to ignore
///
/// Return Whether expansion succeeded.
pub fn expand_one(
s: &mut WString,
flags: ExpandFlags,
ctx: &OperationContext,
errors: Option<&mut ParseErrorList>,
) -> bool {
let mut completions = CompletionList::new();
if !flags.contains(ExpandFlags::FOR_COMPLETIONS) && expand_is_clean(s) {
return true;
}
let mut tmp = WString::new();
std::mem::swap(s, &mut tmp);
if expand_string(tmp, &mut completions, flags, ctx, errors) == ExpandResultCode::ok
&& completions.len() == 1
{
std::mem::swap(s, &mut completions[0].completion);
return true;
}
false
}
/// Expand a command string like $HOME/bin/cmd into a command and list of arguments.
/// Return the command and arguments by reference.
/// If the expansion resulted in no or an empty command, the command will be an empty string. Note
/// that API does not distinguish between expansion resulting in an empty command (''), and
/// expansion resulting in no command (e.g. unset variable).
/// If `skip_wildcards` is true, then do not do wildcard expansion
/// Return an expand error.
pub fn expand_to_command_and_args(
instr: &wstr,
ctx: &OperationContext<'_>,
out_cmd: &mut WString,
mut out_args: Option<&mut Vec<WString>>,
errors: Option<&mut ParseErrorList>,
skip_wildcards: bool,
) -> ExpandResult {
// Fast path.
if expand_is_clean(instr) {
*out_cmd = instr.to_owned();
return ExpandResult::ok();
}
let mut eflags = ExpandFlags::FAIL_ON_CMDSUBST;
if skip_wildcards {
eflags |= ExpandFlags::SKIP_WILDCARDS;
}
let mut completions = CompletionList::new();
let expand_err = expand_string(instr.to_owned(), &mut completions, eflags, ctx, errors);
if expand_err == ExpandResultCode::ok {
// The first completion is the command, any remaining are arguments.
let mut completions = completions.into_iter();
if let Some(comp) = completions.next() {
*out_cmd = comp.completion;
}
if let Some(ref mut out_args) = out_args {
for comp in completions {
out_args.push(comp.completion);
}
}
}
expand_err
}
/// Convert the variable value to a human readable form, i.e. escape things, handle arrays, etc.
/// Suitable for pretty-printing.
pub fn expand_escape_variable(var: &EnvVar) -> WString {
let mut buff = WString::new();
let lst = var.as_list();
for el in lst {
if !buff.is_empty() {
buff.push_str(" ");
}
// We want to use quotes if we have more than one string, or the string contains a space.
let prefer_quotes = lst.len() > 1 || el.contains(' ');
if prefer_quotes && is_quotable(el) {
buff.push('\'');
buff.push_utfstr(el);
buff.push('\'');
} else {
buff.push_utfstr(&escape(el));
}
}
buff
}
/// Convert a string value to a human readable form, i.e. escape things, handle arrays, etc.
/// Suitable for pretty-printing.
pub fn expand_escape_string(el: &wstr) -> WString {
let mut buff = WString::new();
let prefer_quotes = el.contains(' ');
if prefer_quotes && is_quotable(el) {
buff.push('\'');
buff.push_utfstr(el);
buff.push('\'');
} else {
buff.push_utfstr(&escape(el));
}
buff
}
/// Perform tilde expansion and nothing else on the specified string, which is modified in place.
///
/// \param input the string to tilde expand
pub fn expand_tilde(input: &mut WString, vars: &dyn Environment) {
if input.chars().next() == Some('~') {
input.replace_range(0..1, wstr::from_char_slice(&[HOME_DIRECTORY]));
expand_home_directory(input, vars);
}
}
/// Perform the opposite of tilde expansion on the string, which is modified in place.
pub fn replace_home_directory_with_tilde(s: &wstr, vars: &dyn Environment) -> WString {
let mut result = s.to_owned();
// Only absolute paths get this treatment.
if result.starts_with(L!("/")) {
let mut home_directory = L!("~").to_owned();
expand_tilde(&mut home_directory, vars);
// If we can't get a home directory, don't replace anything.
// This is the case e.g. with --no-execute
if home_directory.is_empty() {
return result;
}
if !home_directory.ends_with(L!("/")) {
home_directory.push('/');
}
// Now check if the home_directory prefixes the string.
if result.starts_with(&home_directory) {
// Success
result.replace_range(0..home_directory.len(), L!("~/"));
}
}
result
}
/// Characters which make a string unclean if they are the first character of the string. See \c
/// expand_is_clean().
const UNCLEAN_FIRST: &wstr = L!("~%");
/// Unclean characters. See \c expand_is_clean().
const UNCLEAN: &wstr = L!("$*?\\\"'({})");
/// Test if the specified argument is clean, i.e. it does not contain any tokens which need to be
/// expanded or otherwise altered. Clean strings can be passed through expand_string and expand_one
/// without changing them. About two thirds of all strings are clean, so skipping expansion on them
/// actually does save a small amount of time, since it avoids multiple memory allocations during
/// the expansion process.
///
/// \param in the string to test
fn expand_is_clean(input: &wstr) -> bool {
if input.is_empty() {
return true;
}
// Test characters that have a special meaning in the first character position.
if UNCLEAN_FIRST.contains(input.as_char_slice()[0]) {
return false;
}
// Test characters that have a special meaning in any character position.
!input.chars().any(|c| UNCLEAN.contains(c))
}
/// Append a syntax error to the given error list.
macro_rules! append_syntax_error {
(
$errors:expr, $source_start:expr,
$fmt:expr $(, $arg:expr )* $(,)?
) => {
if let Some(ref mut errors) = $errors {
let mut error = ParseError::default();
error.source_start = $source_start;
error.source_length = 0;
error.code = ParseErrorCode::syntax;
error.text = wgettext_maybe_fmt!($fmt $(, $arg)*);
errors.push(error);
}
}
}
/// Append a cmdsub error to the given error list. But only do so if the error hasn't already been
/// recorded. This is needed because command substitution is a recursive process and some errors
/// could consequently be recorded more than once.
macro_rules! append_cmdsub_error {
(
$errors:expr, $source_start:expr, $source_end:expr,
$fmt:expr $(, $arg:expr )* $(,)?
) => {
append_cmdsub_error_formatted!(
$errors, $source_start, $source_end,
wgettext_maybe_fmt!($fmt $(, $arg)*));
}
}
macro_rules! append_cmdsub_error_formatted {
(
$errors:expr, $source_start:expr, $source_end:expr,
$text:expr $(,)?
) => {
if let Some(ref mut errors) = $errors {
let mut error = ParseError::default();
error.source_start = $source_start;
error.source_length = $source_end - $source_start + 1;
error.code = ParseErrorCode::cmdsubst;
error.text = $text;
if !errors.iter().any(|e| e.text == error.text) {
errors.push(error);
}
}
};
}
/// Append an overflow error, when expansion produces too much data.
fn append_overflow_error(
errors: &mut Option<&mut ParseErrorList>,
source_start: Option<usize>,
) -> ExpandResult {
if let Some(ref mut errors) = errors {
let mut error = ParseError::default();
error.source_start = source_start.unwrap_or(SOURCE_LOCATION_UNKNOWN);
error.source_length = 0;
error.code = ParseErrorCode::generic;
error.text = wgettext!("Expansion produced too many results").to_owned();
errors.push(error);
}
ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap())
}
/// Test if the specified string does not contain character which can not be used inside a quoted
/// string.
fn is_quotable(s: &wstr) -> bool {
!s.chars().any(|c| "\n\t\r\x08\x1B".contains(c))
}
enum ParseSliceError {
zero_index,
invalid_index,
}
/// Parse an array slicing specification Returns 0 on success. If a parse error occurs, returns the
/// index of the bad token. Note that 0 can never be a bad index because the string always starts
/// with [.
fn parse_slice(
input: &wstr,
idx: &mut Vec<i64>,
array_size: usize,
) -> Result<usize, (usize, ParseSliceError)> {
let size = i64::try_from(array_size).unwrap();
let mut pos = 1; // skip past the opening square bracket
loop {
while input.char_at(pos).is_whitespace() || input.char_at(pos) == INTERNAL_SEPARATOR {
pos += 1;
}
if input.char_at(pos) == ']' {
pos += 1;
break;
}
let tmp = if idx.is_empty() && input.char_at(pos) == '.' && input.char_at(pos + 1) == '.' {
// If we are at the first index expression, a missing start-index means the range starts
// at the first item.
1 // first index
} else {
let mut consumed = 0;
match wcstoi_partial(&input[pos..], Options::default(), &mut consumed) {
Ok(tmp) => {
if tmp == 0 {
// Explicitly refuse $foo[0] as valid syntax, regardless of whether or
// not we're going to show an error if the index ultimately evaluates
// to zero. This will help newcomers to fish avoid a common off-by-one
// error. See #4862.
return Err((pos, ParseSliceError::zero_index));
}
pos += consumed;
// Skip trailing whitespace.
pos += input[pos..]
.chars()
.take_while(|c| c.is_whitespace())
.count();
tmp
}
Err(_error) => {
// We don't test `*end` as is typically done because we expect it to not
// be the null char. Ignore the case of errno==-1 because it means the end
// char wasn't the null char.
return Err((pos, ParseSliceError::invalid_index));
}
}
};
let mut i1 = if tmp > -1 { tmp } else { size + tmp + 1 };
while input.char_at(pos) == INTERNAL_SEPARATOR {
pos += 1;
}
if input.char_at(pos) == '.' && input.char_at(pos + 1) == '.' {
pos += 2;
while input.char_at(pos) == INTERNAL_SEPARATOR {
pos += 1;
}
while input.char_at(pos).is_whitespace() {
pos += 1; // Allow the space in "[.. ]".
}
// If we are at the last index range expression then a missing end-index means the
// range spans until the last item.
let tmp1 = if input.char_at(pos) == ']' {
-1 // last index
} else {
let mut consumed = 0;
match wcstoi_partial(&input[pos..], Options::default(), &mut consumed) {
Ok(tmp) => {
if tmp == 0 {
return Err((pos, ParseSliceError::zero_index));
}
pos += consumed;
// Skip trailing whitespace.
pos += input[pos..]
.chars()
.take_while(|c| c.is_whitespace())
.count();
tmp
}
Err(_error) => {
return Err((pos, ParseSliceError::invalid_index));
}
}
};
let mut i2 = if tmp1 > -1 { tmp1 } else { size + tmp1 + 1 };
// Skip sequences that are entirely outside.
// This means "17..18" expands to nothing if there are less than 17 elements.
if i1 > size && i2 > size {
continue;
}
let mut direction = if i2 < i1 { -1 } else { 1 };
// If only the beginning is negative, always go reverse.
// If only the end, always go forward.
// Prevents `[x..-1]` from going reverse if less than x elements are there.
if (tmp1 > -1) != (tmp > -1) {
direction = if tmp1 > -1 { -1 } else { 1 };
} else {
// Clamp to array size when not forcing direction
// - otherwise "2..-1" clamps both to 1 and then becomes "1..1".
i1 = i1.min(size);
i2 = i2.min(size);
}
let mut jjj = i1;
while jjj * direction <= i2 * direction {
idx.push(jjj);
jjj += direction;
}
continue;
}
idx.push(i1);
}
Ok(pos)
}
/// Expand all environment variables in the string *ptr.
///
/// This function is slow, fragile and complicated. There are lots of little corner cases, like
/// $$foo should do a double expansion, $foo$bar should not double expand bar, etc.
///
/// This function operates on strings backwards, starting at last_idx.
///
/// Note: last_idx is considered to be where it previously finished processing. This means it
/// actually starts operating on last_idx-1. As such, to process a string fully, pass string.size()
/// as last_idx instead of string.size()-1.
///
/// Return the result of expansion.
fn expand_variables(
instr: WString,
out: &mut CompletionReceiver,
last_idx: usize,
vars: &dyn Environment,
errors: &mut Option<&mut ParseErrorList>,
) -> ExpandResult {
// last_idx may be 1 past the end of the string, but no further.
assert!(last_idx <= instr.len(), "Invalid last_idx");
if last_idx == 0 {
if !out.add(instr) {
return append_overflow_error(errors, None);
}
return ExpandResult::ok();
}
// Locate the last VARIABLE_EXPAND or VARIABLE_EXPAND_SINGLE
let mut is_single = false;
let mut varexp_char_idx = last_idx;
loop {
let done = varexp_char_idx == 0;
varexp_char_idx = varexp_char_idx.wrapping_sub(1);
if done {
break;
}
let c = instr.as_char_slice()[varexp_char_idx];
if [VARIABLE_EXPAND, VARIABLE_EXPAND_SINGLE].contains(&c) {
is_single = c == VARIABLE_EXPAND_SINGLE;
break;
}
}
if varexp_char_idx == usize::MAX {
// No variable expand char, we're done.
if !out.add(instr) {
return append_overflow_error(errors, None);
}
return ExpandResult::ok();
}
// Get the variable name.
let var_name_start = varexp_char_idx + 1;
let mut var_name_stop = var_name_start;
while var_name_stop < instr.len() {
let nc = instr.as_char_slice()[var_name_stop];
if nc == VARIABLE_EXPAND_EMPTY {
var_name_stop += 1;
break;
}
if !valid_var_name_char(nc) {
break;
}
var_name_stop += 1;
}
assert!(
var_name_stop >= var_name_start,
"Bogus variable name indexes"
);
// Get the variable name as a string, then try to get the variable from env.
let var_name = &instr[var_name_start..var_name_stop];
// It's an error if the name is empty.
if var_name.is_empty() {
if let Some(ref mut errors) = errors {
parse_util_expand_variable_error(
&instr,
0, /* global_token_pos */
varexp_char_idx,
errors,
);
}
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
// Do a dirty hack to make sliced history fast (#4650). We expand from either a variable, or a
// history_t. Note that "history" is read only in env.cpp so it's safe to special-case it in
// this way (it cannot be shadowed, etc).
let mut history = None;
let mut var = None;
if var_name == "history" {
history = Some(History::with_name(&history_session_id(vars)));
} else if var_name.as_char_slice() != [VARIABLE_EXPAND_EMPTY] {
var = vars.get(var_name);
}
// Parse out any following slice.
// Record the end of the variable name and any following slice.
let mut var_name_and_slice_stop = var_name_stop;
let mut all_values = true;
let slice_start = var_name_stop;
let mut var_idx_list = vec![];
if instr.as_char_slice().get(slice_start) == Some(&'[') {
all_values = false;
// If a variable is missing, behave as though we have one value, so that $var[1] always
// works.
let mut effective_val_count = 1;
if let Some(ref var) = var {
effective_val_count = var.as_list().len();
} else if let Some(ref history) = history {
effective_val_count = history.size();
}
match parse_slice(
&instr[slice_start..],
&mut var_idx_list,
effective_val_count,
) {
Ok(offset) => {
var_name_and_slice_stop = slice_start + offset;
}
Err((bad_pos, error)) => {
match error {
ParseSliceError::zero_index => {
append_syntax_error!(
errors,
slice_start + bad_pos,
"array indices start at 1, not 0."
);
}
ParseSliceError::invalid_index => {
append_syntax_error!(errors, slice_start + bad_pos, "Invalid index value");
}
}
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
}
}
let var_idx_list = var_idx_list.iter().filter_map(|&n| n.try_into().ok());
if var.is_none() && history.is_none() {
// Expanding a non-existent variable.
if !is_single {
// Normal expansions of missing variables successfully expand to nothing.
return ExpandResult::ok();
} else {
// Expansion to single argument.
// Replace the variable name and slice with VARIABLE_EXPAND_EMPTY.
let mut res = instr[..varexp_char_idx].to_owned();
if res.as_char_slice().last() == Some(&VARIABLE_EXPAND_SINGLE) {
res.push(VARIABLE_EXPAND_EMPTY);
}
res.push_utfstr(&instr[var_name_and_slice_stop..]);
return expand_variables(res, out, varexp_char_idx, vars, errors);
}
}
// Ok, we have a variable or a history. Let's expand it.
// Start by respecting the sliced elements.
assert!(
var.is_some() || history.is_some(),
"Should have variable or history here",
);
let mut var_item_list = vec![];
if all_values {
var_item_list = if let Some(ref history) = history {
history.get_history()
} else {
var.as_ref().unwrap().as_list().to_vec()
};
} else {
// We have to respect the slice.
if let Some(ref history) = history {
// Ask history to map indexes to item strings.
// Note this may have missing entries for out-of-bounds.
let item_map = history.items_at_indexes(var_idx_list.clone());
for item_index in var_idx_list {
if let Some(item) = item_map.get(&item_index) {
var_item_list.push(item.clone());
}
}
} else {
let all_var_items = var.as_ref().unwrap().as_list();
for item_index in var_idx_list {
// Check that we are within array bounds. If not, skip the element. Note:
// Negative indices (`echo $foo[-1]`) are already converted to positive ones
// here, So tmp < 1 means it's definitely not in.
// Note we are 1-based.
if item_index >= 1 && item_index <= all_var_items.len() {
var_item_list.push(all_var_items[item_index - 1].to_owned());
}
}
}
}
if is_single {
// Quoted expansion. Here we expect the variable's delimiter.
// Note history always has a space delimiter.
let delimit = if history.is_some() {
' '
} else {
var.as_ref().unwrap().get_delimiter()
};
let mut res = instr[..varexp_char_idx].to_owned();
if !res.is_empty() {
if res.as_char_slice().last() != Some(&VARIABLE_EXPAND_SINGLE) {
res.push(INTERNAL_SEPARATOR);
} else if var_item_list.is_empty() || var_item_list[0].is_empty() {
// First expansion is empty, but we need to recursively expand.
res.push(VARIABLE_EXPAND_EMPTY);
}
}
// Append all entries in var_item_list, separated by the delimiter.
res.push_utfstr(&join_strings(&var_item_list, delimit));
res.push_utfstr(&instr[var_name_and_slice_stop..]);
return expand_variables(res, out, varexp_char_idx, vars, errors);
} else {
// Normal cartesian-product expansion.
for item in var_item_list {
if varexp_char_idx == 0 && var_name_and_slice_stop == instr.len() {
if !out.add(item) {
return append_overflow_error(errors, None);
}
} else {
let mut new_in = instr[..varexp_char_idx].to_owned();
if !new_in.is_empty() {
if new_in.as_char_slice().last() != Some(&VARIABLE_EXPAND) {
new_in.push(INTERNAL_SEPARATOR);
} else if item.is_empty() {
new_in.push(VARIABLE_EXPAND_EMPTY);
}
}
new_in.push_utfstr(&item);
new_in.push_utfstr(&instr[var_name_and_slice_stop..]);
let res = expand_variables(new_in, out, varexp_char_idx, vars, errors);
if res.result != ExpandResultCode::ok {
return res;
}
}
}
}
ExpandResult::ok()
}
/// Perform brace expansion, placing the expanded strings into `out`.
fn expand_braces(
input: WString,
flags: ExpandFlags,
out: &mut CompletionReceiver,
errors: &mut Option<&mut ParseErrorList>,
) -> ExpandResult {
let mut syntax_error = false;
let mut brace_count = 0;
let mut brace_begin = None;
let mut brace_end = None;
let mut last_sep = None;
// Locate the first non-nested brace pair.
for (pos, c) in input.chars().enumerate() {
match c {
BRACE_BEGIN => {
if brace_count == 0 {
brace_begin = Some(pos);
}
brace_count += 1;
}
BRACE_END => {
brace_count -= 1;
#[allow(clippy::comparison_chain)]
if brace_count < 0 {
syntax_error = true;
} else if brace_count == 0 {
brace_end = Some(pos);
}
}
BRACE_SEP => {
if brace_count == 1 {
last_sep = Some(pos);
}
}
_ => {
// we ignore all other characters here
}
}
}
if brace_count > 0 {
if !flags.contains(ExpandFlags::FOR_COMPLETIONS) {
syntax_error = true;
} else {
// The user hasn't typed an end brace yet; make one up and append it, then expand
// that.
let mut synth = WString::new();
if let Some(last_sep) = last_sep {
synth.push_utfstr(&input[..brace_begin.unwrap() + 1]);
synth.push_utfstr(&input[last_sep + 1..]);
synth.push(BRACE_END);
} else {
synth.push_utfstr(&input);
synth.push(BRACE_END);
}
// Note: this code looks very fishy, apparently it has never worked.
return expand_braces(synth, ExpandFlags::FAIL_ON_CMDSUBST, out, errors);
}
}
if syntax_error {
append_syntax_error!(errors, SOURCE_LOCATION_UNKNOWN, "Mismatched braces");
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
let Some(brace_begin) = brace_begin else {
// No more brace expansions left; we can return the value as-is.
if !out.add(input) {
return append_overflow_error(errors, None);
}
return ExpandResult::ok();
};
let brace_end = brace_end.unwrap();
let length_preceding_braces = brace_begin;
let length_following_braces = input.len() - brace_end - 1;
let tot_len = length_preceding_braces + length_following_braces;
let mut item_begin = brace_begin + 1;
for (pos, c) in input.chars().enumerate().skip(brace_begin + 1) {
if brace_count == 0 && (c == BRACE_SEP || pos == brace_end) {
assert!(pos >= item_begin);
let item_len = pos - item_begin;
let item = input[item_begin..pos].to_owned();
let mut item = trim(item, Some(wstr::from_char_slice(&[BRACE_SPACE, '\0'])));
for c in item.as_char_slice_mut() {
if *c == BRACE_SPACE {
*c = ' ';
}
}
// `whole_item` is a whitespace- and brace-stripped member of a single pass of brace
// expansion, e.g. in `{ alpha , b,{c, d }}`, `alpha`, `b`, and `c, d` will, in the
// first round of expansion, each in turn be a `whole_item` (with recursive commas
// replaced by special placeholders).
// We recursively call `expand_braces` with each item until it's been fully expanded.
let mut whole_item = WString::new();
whole_item.reserve(tot_len + item_len + 2);
whole_item.push_utfstr(&input[..length_preceding_braces]);
whole_item.push_utfstr(&item);
whole_item.push_utfstr(&input[brace_end + 1..]);
let _ = expand_braces(whole_item, flags, out, errors);
item_begin = pos + 1;
if pos == brace_end {
break;
}
}
if c == BRACE_BEGIN {
brace_count += 1;
}
if c == BRACE_END {
brace_count -= 1;
}
}
ExpandResult::ok()
}
/// Expand a command substitution `input`, executing on `ctx`, and inserting the results into
/// `out_list`, or any errors into `errors`. Return an expand result.
pub fn expand_cmdsubst(
input: WString,
ctx: &OperationContext,
out: &mut CompletionReceiver,
errors: &mut Option<&mut ParseErrorList>,
) -> ExpandResult {
let mut cursor = 0;
let mut is_quoted = false;
let mut has_dollar = false;
let parens = match parse_util_locate_cmdsubst_range(
&input,
&mut cursor,
false,
Some(&mut is_quoted),
Some(&mut has_dollar),
) {
MaybeParentheses::Error => {
append_syntax_error!(errors, SOURCE_LOCATION_UNKNOWN, "Mismatched parenthesis");
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
MaybeParentheses::None => {
if !out.add(input) {
return append_overflow_error(errors, None);
}
return ExpandResult::ok();
}
MaybeParentheses::CommandSubstitution(parens) => parens,
};
let mut sub_res = vec![];
let job_group = ctx.job_group.clone();
let subshell_status = exec_subshell_for_expand(
&input[parens.command()],
ctx.parser(),
job_group.as_ref(),
&mut sub_res,
);
if subshell_status != 0 {
// TODO: Ad-hoc switch, how can we enumerate the possible errors more safely?
let err = match subshell_status {
_ if subshell_status == STATUS_READ_TOO_MUCH.unwrap() => {
wgettext!("Too much data emitted by command substitution so it was discarded")
}
// TODO: STATUS_CMD_ERROR is overused and too generic. We shouldn't have to test things
// to figure out what error to show after we've already been given an error code.
_ if subshell_status == STATUS_CMD_ERROR.unwrap() => {
if ctx.parser().is_eval_depth_exceeded() {
wgettext!("Unable to evaluate string substitution")
} else {
wgettext!("Too many active file descriptors")
}
}
_ if subshell_status == STATUS_CMD_UNKNOWN.unwrap() => {
wgettext!("Unknown command")
}
_ if subshell_status == STATUS_ILLEGAL_CMD.unwrap() => {
wgettext!("Commandname was invalid")
}
_ if subshell_status == STATUS_NOT_EXECUTABLE.unwrap() => {
wgettext!("Command not executable")
}
_ if subshell_status == STATUS_INVALID_ARGS.unwrap() => {
// TODO: Also overused
// This is sent for:
// invalid redirections or pipes (like `<&foo`),
// invalid variables (invalid name or read-only) for for-loops,
// switch $foo if $foo expands to more than one argument
// time in a background job.
wgettext!("Invalid arguments")
}
_ if subshell_status == STATUS_EXPAND_ERROR.unwrap() => {
// Sent in `for $foo in ...` if $foo expands to more than one word
wgettext!("Expansion error")
}
_ if subshell_status == STATUS_UNMATCHED_WILDCARD.unwrap() => {
// Sent in `for $foo in ...` if $foo expands to more than one word
wgettext!("Unmatched wildcard")
}
_ => {
wgettext!("Unknown error while evaluating command substitution")
}
};
append_cmdsub_error_formatted!(errors, parens.start(), parens.end() - 1, err.to_owned());
return ExpandResult::make_error(subshell_status);
}
// Expand slices like (cat /var/words)[1]
let mut tail_begin = parens.end();
if input.as_char_slice().get(tail_begin) == Some(&'[') {
let mut slice_idx = vec![];
let slice_begin = tail_begin;
let slice_end = match parse_slice(&input[slice_begin..], &mut slice_idx, sub_res.len()) {
Ok(offset) => slice_begin + offset,
Err((bad_pos, error)) => {
match error {
ParseSliceError::zero_index => {
append_syntax_error!(
errors,
slice_begin + bad_pos,
"array indices start at 1, not 0."
);
}
ParseSliceError::invalid_index => {
append_syntax_error!(errors, slice_begin + bad_pos, "Invalid index value");
}
}
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
};
let mut sub_res2 = vec![];
tail_begin = slice_end;
for idx in slice_idx {
if idx as usize > sub_res.len() || idx < 1 {
continue;
}
// -1 to convert from 1-based slice index to 0-based vector index.
sub_res2.push(sub_res[idx as usize - 1].to_owned());
}
sub_res = sub_res2;
}
// Recursively call ourselves to expand any remaining command substitutions. The result of this
// recursive call using the tail of the string is inserted into the tail_expand array list
let mut tail_expand_recv = out.subreceiver();
let mut tail = input[tail_begin..].to_owned();
// A command substitution inside double quotes magically closes the quoted string.
// Reopen the quotes just after the command substitution.
if is_quoted {
tail.insert(0, '"');
}
let _ = expand_cmdsubst(tail, ctx, &mut tail_expand_recv, errors); // TODO: offset error locations
let tail_expand = tail_expand_recv.take();
// Combine the result of the current command substitution with the result of the recursive tail
// expansion.
if is_quoted {
// Awkwardly reconstruct the command output.
let approx_size = sub_res.iter().map(|sub_item| sub_item.len() + 1).sum();
let mut sub_res_joined = WString::new();
sub_res_joined.reserve(approx_size);
for line in sub_res {
sub_res_joined.push_utfstr(&escape_string_for_double_quotes(&line));
sub_res_joined.push('\n');
}
// Mimic POSIX shells by stripping all trailing newlines.
if !sub_res_joined.is_empty() {
let mut i = sub_res_joined.len();
while i > 0 && sub_res_joined.as_char_slice()[i - 1] == '\n' {
i -= 1;
}
sub_res_joined.truncate(i);
}
// Instead of performing cartesian product expansion, we directly insert the command
// substitution output into the current expansion results.
for tail_item in tail_expand {
let mut whole_item = WString::new();
whole_item.reserve(
parens.start() + 1 + sub_res_joined.len() + 1 + tail_item.completion.len(),
);
whole_item.push_utfstr(&input[..parens.start() - if has_dollar { 1 } else { 0 }]);
whole_item.push(INTERNAL_SEPARATOR);
whole_item.push_utfstr(&sub_res_joined);
whole_item.push(INTERNAL_SEPARATOR);
whole_item.push_utfstr(&tail_item.completion["\"".len()..]);
if !out.add(whole_item) {
return append_overflow_error(errors, None);
}
}
return ExpandResult::ok();
}
for sub_item in sub_res {
let sub_item2 = escape_string(&sub_item, EscapeStringStyle::Script(EscapeFlags::COMMA));
for tail_item in &*tail_expand {
let mut whole_item = WString::new();
whole_item
.reserve(parens.start() + 1 + sub_item2.len() + 1 + tail_item.completion.len());
whole_item.push_utfstr(&input[..parens.start() - if has_dollar { 1 } else { 0 }]);
whole_item.push(INTERNAL_SEPARATOR);
whole_item.push_utfstr(&sub_item2);
whole_item.push(INTERNAL_SEPARATOR);
whole_item.push_utfstr(&tail_item.completion);
if !out.add(whole_item) {
return append_overflow_error(errors, None);
}
}
}
ExpandResult::ok()
}
// Given that input[0] is HOME_DIRECTORY or tilde (ugh), return the user's name. Return the empty
// string if it is just a tilde. Also return by reference the index of the first character of the
// remaining part of the string (e.g. the subsequent slash).
fn get_home_directory_name<'a>(input: &'a wstr, out_tail_idx: &mut usize) -> &'a wstr {
assert!([HOME_DIRECTORY, '~'].contains(&input.as_char_slice()[0]));
// We get the position of the /, but we need to remove it as well.
if let Some(pos) = input.chars().position(|c| c == '/') {
*out_tail_idx = pos;
&input[1..pos]
} else {
*out_tail_idx = input.len();
&input[1..]
}
}
/// Attempts tilde expansion of the string specified, modifying it in place.
fn expand_home_directory(input: &mut WString, vars: &dyn Environment) {
if input.as_char_slice().first() != Some(&HOME_DIRECTORY) {
return;
}
let mut tail_idx = usize::MAX;
let username = get_home_directory_name(input, &mut tail_idx);
let mut home = None;
if username.is_empty() {
// Current users home directory.
match vars.get_unless_empty(L!("HOME")) {
None => {
input.clear();
return;
}
Some(home_var) => {
home = Some(home_var.as_string());
tail_idx = 1;
}
};
} else {
// Some other user's home directory.
let name_cstr = wcs2zstring(username);
let mut userinfo: libc::passwd = unsafe { std::mem::zeroed() };
let mut result: *mut libc::passwd = std::ptr::null_mut();
let mut buf = [0 as libc::c_char; 8192];
let retval = unsafe {
libc::getpwnam_r(
name_cstr.as_ptr(),
&mut userinfo,
&mut buf[0],
std::mem::size_of_val(&buf),
&mut result,
)
};
if retval == 0 && !result.is_null() {
home = Some(charptr2wcstring(userinfo.pw_dir));
}
}
if let Some(home) = home {
input.replace_range(..tail_idx, &normalize_path(&home, true));
} else {
input.replace_range(0..1, L!("~"));
}
}
/// Expand the %self escape. Note this can only come at the beginning of the string.
fn expand_percent_self(input: &mut WString) {
if input.as_char_slice().first() == Some(&PROCESS_EXPAND_SELF) {
input.replace_range(0..1, &unsafe { libc::getpid() }.to_wstring());
}
}
/// Remove any internal separators. Also optionally convert wildcard characters to regular
/// equivalents. This is done to support skip_wildcards.
fn remove_internal_separator(s: &mut WString, conv: bool) {
// Remove all instances of INTERNAL_SEPARATOR.
s.retain(|c| c != INTERNAL_SEPARATOR);
// If conv is true, replace all instances of ANY_STRING with '*',
// ANY_STRING_RECURSIVE with '*'.
if conv {
for idx in s.as_char_slice_mut() {
match *idx {
ANY_CHAR => {
*idx = '?';
}
ANY_STRING | ANY_STRING_RECURSIVE => {
*idx = '*';
}
_ => {
// we ignore all other characters
}
}
}
}
}
/// A type that knows how to perform expansions.
struct Expander<'a, 'b, 'c> {
/// Operation context for this expansion.
ctx: &'c OperationContext<'b>,
/// Flags to use during expansion.
flags: ExpandFlags,
/// List to receive any errors generated during expansion, or null to ignore errors.
errors: &'c mut Option<&'a mut ParseErrorList>,
}
impl<'a, 'b, 'c> Expander<'a, 'b, 'c> {
fn new(
ctx: &'c OperationContext<'b>,
flags: ExpandFlags,
errors: &'c mut Option<&'a mut ParseErrorList>,
) -> Self {
Self { ctx, flags, errors }
}
fn expand_string(
input: WString,
out_completions: &'a mut CompletionReceiver,
flags: ExpandFlags,
ctx: &'a OperationContext<'b>,
mut errors: Option<&'a mut ParseErrorList>,
) -> ExpandResult {
assert!(
flags.contains(ExpandFlags::FAIL_ON_CMDSUBST) || ctx.has_parser(),
"Must have a parser if not skipping command substitutions"
);
// Early out. If we're not completing, and there's no magic in the input, we're done.
if !flags.contains(ExpandFlags::FOR_COMPLETIONS) && expand_is_clean(&input) {
if !out_completions.add(input) {
return append_overflow_error(&mut errors, None);
}
return ExpandResult::ok();
}
let mut expand = Expander::new(ctx, flags, &mut errors);
// Our expansion stages.
// An expansion stage is a member function pointer.
// It accepts the input string (transferring ownership) and returns the list of output
// completions by reference. It may return an error, which halts expansion.
let stages = [
Expander::stage_cmdsubst,
Expander::stage_variables,
Expander::stage_braces,
Expander::stage_home_and_self,
Expander::stage_wildcards,
];
// Load up our single initial completion.
let mut completions = vec![Completion::from_completion(input.clone())];
let mut total_result = ExpandResult::ok();
let mut output_storage = out_completions.subreceiver();
for stage in stages {
for comp in completions {
if expand.ctx.check_cancel() {
total_result = ExpandResult::new(ExpandResultCode::cancel);
break;
}
let this_result = (stage)(&mut expand, comp.completion, &mut output_storage);
total_result = this_result;
if total_result == ExpandResultCode::error {
break;
}
}
// Output becomes our next stage's input.
completions = output_storage.take();
if total_result == ExpandResultCode::error {
break;
}
}
// This is a little tricky: if one wildcard failed to match but we still got output, it
// means that a previous expansion resulted in multiple strings. For example:
// set dirs ./a ./b
// echo $dirs/*.txt
// Here if ./a/*.txt matches and ./b/*.txt does not, then we don't want to report a failed
// wildcard. So swallow failed-wildcard errors if we got any output.
if total_result == ExpandResultCode::wildcard_no_match && !completions.is_empty() {
total_result = ExpandResult::ok();
}
if total_result == ExpandResultCode::ok {
// Unexpand tildes if we want to preserve them (see #647).
if flags.contains(ExpandFlags::PRESERVE_HOME_TILDES) {
expand.unexpand_tildes(&input, &mut completions);
}
if !out_completions.extend(completions) {
total_result = append_overflow_error(expand.errors, None);
}
}
total_result
}
fn stage_cmdsubst(&mut self, input: WString, out: &mut CompletionReceiver) -> ExpandResult {
if self.flags.contains(ExpandFlags::SKIP_CMDSUBST) {
if !out.add(input) {
return append_overflow_error(self.errors, None);
}
return ExpandResult::ok();
}
if self.flags.contains(ExpandFlags::FAIL_ON_CMDSUBST) {
let mut cursor = 0;
match parse_util_locate_cmdsubst_range(&input, &mut cursor, true, None, None) {
MaybeParentheses::Error => {
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
MaybeParentheses::None => {
if !out.add(input) {
return append_overflow_error(self.errors, None);
}
return ExpandResult::ok();
}
MaybeParentheses::CommandSubstitution(parens) => {
append_cmdsub_error!(
self.errors,
parens.start(),
parens.end()-1,
"command substitutions not allowed in command position. Try var=(your-cmd) $var ..."
);
return ExpandResult::make_error(STATUS_EXPAND_ERROR.unwrap());
}
}
} else {
assert!(
self.ctx.has_parser(),
"Must have a parser to expand command substitutions"
);
expand_cmdsubst(input, self.ctx, out, self.errors)
}
}
// We pass by value to match other stages. NOLINTNEXTLINE(performance-unnecessary-value-param)
fn stage_variables(&mut self, input: WString, out: &mut CompletionReceiver) -> ExpandResult {
// We accept incomplete strings here, since complete uses expand_string to expand incomplete
// strings from the commandline.
let mut next = unescape_string(
&input,
UnescapeStringStyle::Script(UnescapeFlags::SPECIAL | UnescapeFlags::INCOMPLETE),
)
.unwrap_or_default();
if self.flags.contains(ExpandFlags::SKIP_VARIABLES) {
for i in next.as_char_slice_mut() {
if [VARIABLE_EXPAND, VARIABLE_EXPAND_SINGLE].contains(i) {
*i = '$';
}
}
if !out.add(next) {
return append_overflow_error(self.errors, None);
}
ExpandResult::ok()
} else {
let size = next.len();
expand_variables(next, out, size, self.ctx.vars(), self.errors)
}
}
fn stage_braces(&mut self, input: WString, out: &mut CompletionReceiver) -> ExpandResult {
expand_braces(input, self.flags, out, self.errors)
}
fn stage_home_and_self(
&mut self,
mut input: WString,
out: &mut CompletionReceiver,
) -> ExpandResult {
expand_home_directory(&mut input, self.ctx.vars());
if !feature_test(FeatureFlag::remove_percent_self) {
expand_percent_self(&mut input);
}
if !out.add(input) {
return append_overflow_error(self.errors, None);
}
ExpandResult::ok()
}
fn stage_wildcards(
&mut self,
mut path_to_expand: WString,
out: &mut CompletionReceiver,
) -> ExpandResult {
let mut result = ExpandResult::ok();
remove_internal_separator(
&mut path_to_expand,
self.flags.contains(ExpandFlags::SKIP_WILDCARDS),
);
let has_wildcard = wildcard_has_internal(&path_to_expand); // e.g. ANY_STRING
let for_completions = self.flags.contains(ExpandFlags::FOR_COMPLETIONS);
let skip_wildcards = self.flags.contains(ExpandFlags::SKIP_WILDCARDS);
if has_wildcard && self.flags.contains(ExpandFlags::EXECUTABLES_ONLY) {
// don't do wildcard expansion for executables, see issue #785
} else if (for_completions && !skip_wildcards) || has_wildcard {
// We either have a wildcard, or we don't have a wildcard but we're doing completion
// expansion (so we want to get the completion of a file path). Note that if
// skip_wildcards is set, we stomped wildcards in remove_internal_separator above, so
// there actually aren't any.
//
// So we're going to treat this input as a file path. Compute the "working directories",
// which may be CDPATH if the special flag is set.
let working_dir = self.ctx.vars().get_pwd_slash();
let mut effective_working_dirs = vec![];
let for_cd = self.flags.contains(ExpandFlags::SPECIAL_FOR_CD);
let for_command = self.flags.contains(ExpandFlags::SPECIAL_FOR_COMMAND);
if !for_cd && !for_command {
// Common case.
effective_working_dirs.push(working_dir);
} else {
// Either special_for_command or special_for_cd. We can handle these
// mostly the same. There's the following differences:
//
// 1. An empty CDPATH should be treated as '.', but an empty PATH should be left empty
// (no commands can be found). Also, an empty element in either is treated as '.' for
// consistency with POSIX shells. Note that we rely on the latter by having called
// `munge_colon_delimited_array()` for these special env vars. Thus we do not
// special-case them here.
//
// 2. PATH is only "one level," while CDPATH is multiple levels. That is, input like
// 'foo/bar' should resolve against CDPATH, but not PATH.
//
// In either case, we ignore the path if we start with ./ or /. Also ignore it if we are
// doing command completion and we contain a slash, per IEEE 1003.1, chapter 8 under
// PATH.
if path_to_expand.starts_with(L!("/"))
|| path_to_expand.starts_with(L!("./"))
|| path_to_expand.starts_with(L!("../"))
|| (for_command && path_to_expand.contains('/'))
{
effective_working_dirs.push(working_dir);
} else {
// Get the PATH/CDPATH and CWD. Perhaps these should be passed in. An empty CDPATH
// implies just the current directory, while an empty PATH is left empty.
let mut paths = self
.ctx
.vars()
.get(if for_cd { L!("CDPATH") } else { L!("PATH") })
.map(|var| var.as_list().to_owned())
.unwrap_or_default();
// The current directory is always valid.
paths.push(if for_cd { L!(".") } else { L!("") }.to_owned());
for next_path in paths {
effective_working_dirs
.push(path_apply_working_directory(&next_path, &working_dir));
}
}
}
result = ExpandResult::new(ExpandResultCode::wildcard_no_match);
let mut expanded_recv = out.subreceiver();
for effective_working_dir in effective_working_dirs {
let expand_res = wildcard_expand_string(
&path_to_expand,
&effective_working_dir,
self.flags,
&*self.ctx.cancel_checker,
&mut expanded_recv,
);
match expand_res {
WildcardResult::Match => result = ExpandResult::ok(),
WildcardResult::NoMatch => (),
WildcardResult::Overflow => return append_overflow_error(self.errors, None),
WildcardResult::Cancel => return ExpandResult::new(ExpandResultCode::cancel),
}
}
let mut expanded = expanded_recv.take();
expanded.sort_by(|a, b| wcsfilecmp_glob(&a.completion, &b.completion));
if !out.extend(expanded) {
result = ExpandResult::new(ExpandResultCode::error);
}
} else {
// Can't fully justify this check. I think it's that SKIP_WILDCARDS is used when completing
// to mean don't do file expansions, so if we're not doing file expansions, just drop this
// completion on the floor.
#[allow(clippy::collapsible_if)]
if !self.flags.contains(ExpandFlags::FOR_COMPLETIONS) {
if !out.add(path_to_expand) {
return append_overflow_error(self.errors, None);
}
}
}
result
}
// Given an original input string, if it starts with a tilde, "unexpand" the expanded home
// directory. Note this may be just a tilde or a user name like ~foo/.
fn unexpand_tildes(&self, input: &wstr, completions: &mut CompletionList) {
// If input begins with tilde, then try to replace the corresponding string in each completion
// with the tilde. If it does not, there's nothing to do.
if input.as_char_slice().first() != Some(&'~') {
return;
}
// This is a subtle kludge. We need to decide whether to unexpand tildes for all
// completions, or only those which replace their tokens. The problem is that we're sloppy
// about setting the COMPLETE_REPLACES_TOKEN flag, except when we're completing in the
// wildcard stage, because no other clients of string expansion care. Example:
// HOME=/foo
// mkdir ~/foo # makes /foo/foo
// cd ~/<tab>
// Here we are likely to get a completion 'foo' which may match $HOME, but it extends its token
// instead of replacing it, so we don't modify it (it will just be appended to the original ~/).
//
// However if we are not completing, just expanding, then expansion just produces the full paths
// so we should unconditionally unexpand tildes.
let only_replacers = self.flags.contains(ExpandFlags::FOR_COMPLETIONS);
// Helper to decide whether to process a completion.
let should_process = |c: &Completion| !only_replacers || c.replaces_token();
// Early out if none qualify.
if !completions.iter().any(should_process) {
return;
}
// Get the username_with_tilde (like ~bert) and expand it into a home directory.
let mut tail_idx = usize::MAX;
let username_with_tilde =
WString::from_str("~") + get_home_directory_name(input, &mut tail_idx);
let mut home = username_with_tilde.clone();
expand_tilde(&mut home, self.ctx.vars());
// Now for each completion that starts with home, replace it with the username_with_tilde.
for comp in completions {
if should_process(comp) && comp.completion.starts_with(&home) {
comp.completion
.replace_range(..home.len(), &username_with_tilde);
// And mark that our tilde is literal, so it doesn't try to escape it.
comp.flags |= CompleteFlags::DONT_ESCAPE_TILDES;
}
}
}
}
#[derive(Copy, Clone, Debug, Eq, PartialEq)]
pub enum ExpandResultCode {
/// There was an error, for example, unmatched braces.
error,
/// Expansion succeeded.
ok,
/// Expansion was cancelled (e.g. control-C).
cancel,
/// Expansion succeeded, but a wildcard in the string matched no files,
/// so the output is empty.
wildcard_no_match,
}
/// These are the possible return values for expand_string.
#[must_use]
#[derive(Debug)]
pub struct ExpandResult {
/// The result of expansion.
pub result: ExpandResultCode,
/// If expansion resulted in an error, this is an appropriate value with which to populate
/// $status.
// todo!("should be c_int?");
pub status: i32,
}