//! Prototypes for various functions, mostly string utilities, that are used by most parts of fish. use crate::compat::MB_CUR_MAX; use crate::expand::{ BRACE_BEGIN, BRACE_END, BRACE_SEP, BRACE_SPACE, HOME_DIRECTORY, INTERNAL_SEPARATOR, PROCESS_EXPAND_SELF, PROCESS_EXPAND_SELF_STR, VARIABLE_EXPAND, VARIABLE_EXPAND_SINGLE, }; use crate::ffi::{self, fish_wcwidth}; use crate::future_feature_flags::{feature_test, FeatureFlag}; use crate::global_safety::RelaxedAtomicBool; use crate::termsize::Termsize; use crate::wchar::{decode_byte_from_char, encode_byte_to_char, wstr, WString, L}; use crate::wchar_ext::WExt; use crate::wchar_ffi::WCharToFFI; use crate::wcstringutil::wcs2string_callback; use crate::wildcard::{ANY_CHAR, ANY_STRING, ANY_STRING_RECURSIVE}; use crate::wutil::encoding::{mbrtowc, wcrtomb, zero_mbstate, AT_LEAST_MB_LEN_MAX}; use crate::wutil::{fish_iswalnum, sprintf, wgettext}; use bitflags::bitflags; use core::slice; use cxx::{CxxWString, UniquePtr}; use libc::{EINTR, EIO, O_WRONLY, SIGTTOU, SIG_IGN, STDERR_FILENO, STDIN_FILENO, STDOUT_FILENO}; use num_traits::ToPrimitive; use once_cell::sync::Lazy; use std::cell::RefCell; use std::env; use std::ffi::CString; use std::mem::{self, ManuallyDrop}; use std::ops::{Deref, DerefMut}; use std::os::fd::AsRawFd; use std::path::PathBuf; use std::rc::Rc; use std::str::FromStr; use std::sync::atomic::{AtomicI32, AtomicU32, AtomicU64, Ordering}; use std::sync::Mutex; use std::time; use widestring_suffix::widestrs; // Highest legal ASCII value. pub const ASCII_MAX: char = 127 as char; // Highest legal 16-bit Unicode value. pub const UCS2_MAX: char = '\u{FFFF}'; // Highest legal byte value. pub const BYTE_MAX: char = 0xFF as char; // Unicode BOM value. pub const UTF8_BOM_WCHAR: char = '\u{FEFF}'; // Use Unicode "non-characters" for internal characters as much as we can. This // gives us 32 "characters" for internal use that we can guarantee should not // appear in our input stream. See http://www.unicode.org/faq/private_use.html. pub const RESERVED_CHAR_BASE: char = '\u{FDD0}'; pub const RESERVED_CHAR_END: char = '\u{FDF0}'; // Split the available non-character values into two ranges to ensure there are // no conflicts among the places we use these special characters. pub const EXPAND_RESERVED_BASE: char = RESERVED_CHAR_BASE; pub const EXPAND_RESERVED_END: char = char_offset(EXPAND_RESERVED_BASE, 16); pub const WILDCARD_RESERVED_BASE: char = EXPAND_RESERVED_END; pub const WILDCARD_RESERVED_END: char = char_offset(WILDCARD_RESERVED_BASE, 16); // Make sure the ranges defined above don't exceed the range for non-characters. // This is to make sure we didn't do something stupid in subdividing the // Unicode range for our needs. const _: () = assert!(WILDCARD_RESERVED_END <= RESERVED_CHAR_END); // These are in the Unicode private-use range. We really shouldn't use this // range but have little choice in the matter given how our lexer/parser works. // We can't use non-characters for these two ranges because there are only 66 of // them and we need at least 256 + 64. // // If sizeof(wchar_t))==4 we could avoid using private-use chars; however, that // would result in fish having different behavior on machines with 16 versus 32 // bit wchar_t. It's better that fish behave the same on both types of systems. // // Note: We don't use the highest 8 bit range (0xF800 - 0xF8FF) because we know // of at least one use of a codepoint in that range: the Apple symbol (0xF8FF) // on Mac OS X. See http://www.unicode.org/faq/private_use.html. pub const ENCODE_DIRECT_BASE: char = '\u{F600}'; pub const ENCODE_DIRECT_END: char = char_offset(ENCODE_DIRECT_BASE, 256); #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum EscapeStringStyle { Script(EscapeFlags), Url, Var, Regex, } impl Default for EscapeStringStyle { fn default() -> Self { Self::Script(EscapeFlags::default()) } } bitflags! { /// Flags for the [`escape_string()`] function. These are only applicable when the escape style is /// [`EscapeStringStyle::Script`]. #[derive(Default)] pub struct EscapeFlags: u32 { /// Do not escape special fish syntax characters like the semicolon. Only escape non-printable /// characters and backslashes. const NO_PRINTABLES = 1 << 0; /// Do not try to use 'simplified' quoted escapes, and do not use empty quotes as the empty /// string. const NO_QUOTED = 1 << 1; /// Do not escape tildes. const NO_TILDE = 1 << 2; /// Replace non-printable control characters with Unicode symbols. const SYMBOLIC = 1 << 3; } } #[derive(Debug, Clone, Copy, PartialEq, Eq)] pub enum UnescapeStringStyle { Script(UnescapeFlags), Url, Var, } impl Default for UnescapeStringStyle { fn default() -> Self { Self::Script(UnescapeFlags::default()) } } bitflags! { /// Flags for unescape_string functions. #[derive(Default)] pub struct UnescapeFlags: u32 { /// default behavior const DEFAULT = 0; /// escape special fish syntax characters like the semicolon const SPECIAL = 1 << 0; /// allow incomplete escape sequences const INCOMPLETE = 1 << 1; /// don't handle backslash escapes const NO_BACKSLASHES = 1 << 2; } } /// Replace special characters with backslash escape sequences. Newline is replaced with `\n`, etc. pub fn escape_string(s: &wstr, style: EscapeStringStyle) -> WString { match style { EscapeStringStyle::Script(flags) => escape_string_script(s, flags), EscapeStringStyle::Url => escape_string_url(s), EscapeStringStyle::Var => escape_string_var(s), EscapeStringStyle::Regex => escape_string_pcre2(s), } } /// Escape a string in a fashion suitable for using in fish script. #[widestrs] fn escape_string_script(input: &wstr, flags: EscapeFlags) -> WString { let escape_printables = !flags.contains(EscapeFlags::NO_PRINTABLES); let no_quoted = flags.contains(EscapeFlags::NO_QUOTED); let no_tilde = flags.contains(EscapeFlags::NO_TILDE); let no_qmark = feature_test(FeatureFlag::qmark_noglob); let symbolic = flags.contains(EscapeFlags::SYMBOLIC) && MB_CUR_MAX() > 1; assert!( !symbolic || !escape_printables, "symbolic implies escape-no-printables" ); let mut need_escape = false; let mut need_complex_escape = false; if !no_quoted && input.is_empty() { return "''"L.to_owned(); } let mut out = WString::new(); for c in input.chars() { if let Some(val) = decode_byte_from_char(c) { out += "\\X"; let nibble1 = val / 16; let nibble2 = val % 16; out.push(char::from_digit(nibble1.into(), 16).unwrap()); out.push(char::from_digit(nibble2.into(), 16).unwrap()); need_escape = true; need_complex_escape = true; continue; } match c { '\t' => { if symbolic { out.push('␉'); } else { out += "\\t"L; } need_escape = true; need_complex_escape = true; } '\n' => { if symbolic { out.push('␤'); } else { out += "\\n"L; } need_escape = true; need_complex_escape = true; } '\x08' => { if symbolic { out.push('␈'); } else { out += "\\b"L; } need_escape = true; need_complex_escape = true; } '\r' => { if symbolic { out.push('␍'); } else { out += "\\r"L; } need_escape = true; need_complex_escape = true; } '\x1B' => { if symbolic { out.push('␛'); } else { out += "\\e"L; } need_escape = true; need_complex_escape = true; } '\x7F' => { if symbolic { out.push('␡'); } else { out += "\\x7f"L; } need_escape = true; need_complex_escape = true; } '\\' | '\'' => { need_escape = true; need_complex_escape = true; if escape_printables || (c == '\\' && !symbolic) { out.push('\\'); } out.push(c); } ANY_CHAR => { // See #1614 out.push('?'); } ANY_STRING => { out.push('*'); } ANY_STRING_RECURSIVE => { out += "**"L; } '&' | '$' | ' ' | '#' | '<' | '>' | '(' | ')' | '[' | ']' | '{' | '}' | '?' | '*' | '|' | ';' | '"' | '%' | '~' => { let char_is_normal = (c == '~' && no_tilde) || (c == '?' && no_qmark); if !char_is_normal { need_escape = true; if escape_printables { out.push('\\') }; } out.push(c); } _ => { let cval = u32::from(c); if cval < 32 { need_escape = true; need_complex_escape = true; if symbolic { out.push(char::from_u32(0x2400 + cval).unwrap()); break; } if cval < 27 && cval != 0 { out.push('\\'); out.push('c'); out.push(char::from_u32(u32::from(b'a') + cval - 1).unwrap()); break; } let nibble = cval % 16; out.push('\\'); out.push('x'); out.push(if cval > 15 { '1' } else { '0' }); out.push(char::from_digit(nibble, 16).unwrap()); } else { out.push(c); } } } } // Use quoted escaping if possible, since most people find it easier to read. if !no_quoted && need_escape && !need_complex_escape && escape_printables { let single_quote = '\''; out.clear(); out.reserve(2 + input.len()); out.push(single_quote); out.push_utfstr(input); out.push(single_quote); } out } /// Escape a string in a fashion suitable for using as a URL. Store the result in out_str. #[widestrs] fn escape_string_url(input: &wstr) -> WString { let narrow = wcs2string(input); let mut out = WString::new(); for byte in narrow.into_iter() { if (byte & 0x80) == 0 { let c = char::from_u32(u32::from(byte)).unwrap(); if c.is_alphanumeric() || [b'/', b'.', b'~', b'-', b'_'].contains(&byte) { // The above characters don't need to be encoded. out.push(c); continue; } } // All other chars need to have their UTF-8 representation encoded in hex. out += &sprintf!("%%%02X"L, byte)[..]; } out } /// Escape a string in a fashion suitable for using as a fish var name. Store the result in out_str. #[widestrs] fn escape_string_var(input: &wstr) -> WString { let mut prev_was_hex_encoded = false; let narrow = wcs2string(input); let mut out = WString::new(); for byte in narrow.into_iter() { if (byte & 0x80) == 0 { let c = char::from_u32(u32::from(byte)).unwrap(); if c.is_alphanumeric() && (!prev_was_hex_encoded || c.to_digit(16).is_none()) { // ASCII alphanumerics don't need to be encoded. if prev_was_hex_encoded { out.push('_'); prev_was_hex_encoded = false; } out.push(c); continue; } } else if byte == b'_' { // Underscores are encoded by doubling them. out += "__"L; prev_was_hex_encoded = false; continue; } // All other chars need to have their UTF-8 representation encoded in hex. out += &sprintf!("_%02X"L, byte)[..]; prev_was_hex_encoded = true; } out } /// Escapes a string for use in a regex string. Not safe for use with `eval` as only /// characters reserved by PCRE2 are escaped. /// \param in is the raw string to be searched for literally when substituted in a PCRE2 expression. fn escape_string_pcre2(input: &wstr) -> WString { let mut out = WString::new(); out.reserve( (f64::from(u32::try_from(input.len()).unwrap()) * 1.3) // a wild guess .to_i128() .unwrap() .try_into() .unwrap(), ); for c in input.chars() { if [ '.', '^', '$', '*', '+', '(', ')', '?', '[', '{', '}', '\\', '|', // these two only *need* to be escaped within a character class, and technically it // makes no sense to ever use process substitution output to compose a character class, // but... '-', ']', ] .contains(&c) { out.push('\\'); } out.push(c); } out } /// Escape a string so that it may be inserted into a double-quoted string. /// This permits ownership transfer. pub fn escape_string_for_double_quotes(input: &wstr) -> WString { // We need to escape backslashes, double quotes, and dollars only. let mut result = input.to_owned(); let mut idx = result.len(); while idx > 0 { idx -= 1; if ['\\', '$', '"'].contains(&result.char_at(idx)) { result.insert(idx, '\\'); } } result } pub fn unescape_string(input: &wstr, style: UnescapeStringStyle) -> Option { match style { UnescapeStringStyle::Script(flags) => unescape_string_internal(input, flags), UnescapeStringStyle::Url => unescape_string_url(input), UnescapeStringStyle::Var => unescape_string_var(input), } } // TODO Delete this. pub fn unescape_string_in_place(s: &mut WString, style: UnescapeStringStyle) -> bool { unescape_string(s, style) .map(|unescaped| *s = unescaped) .is_some() } /// Returns the unescaped version of input, or None on error. fn unescape_string_internal(input: &wstr, flags: UnescapeFlags) -> Option { let mut result = WString::new(); result.reserve(input.len()); let unescape_special = flags.contains(UnescapeFlags::SPECIAL); let allow_incomplete = flags.contains(UnescapeFlags::INCOMPLETE); let ignore_backslashes = flags.contains(UnescapeFlags::NO_BACKSLASHES); // The positions of open braces. let mut braces = vec![]; // The positions of variable expansions or brace ","s. // We only read braces as expanders if there's a variable expansion or "," in them. let mut vars_or_seps = vec![]; let mut brace_count = 0; let mut errored = false; #[derive(PartialEq, Eq)] enum Mode { Unquoted, SingleQuotes, DoubleQuotes, } let mut mode = Mode::Unquoted; let mut input_position = 0; while input_position < input.len() && !errored { let c = input.char_at(input_position); // Here's the character we'll append to result, or none() to suppress it. let mut to_append_or_none = Some(c); if mode == Mode::Unquoted { match c { '\\' => { if !ignore_backslashes { // Backslashes (escapes) are complicated and may result in errors, or // appending INTERNAL_SEPARATORs, so we have to handle them specially. if let Some(escape_chars) = read_unquoted_escape( &input[input_position..], &mut result, allow_incomplete, unescape_special, ) { // Skip over the characters we read, minus one because the outer loop // will increment it. assert!(escape_chars > 0); input_position += escape_chars - 1; } else { // A none() return indicates an error. errored = true; } // We've already appended, don't append anything else. to_append_or_none = None; } } '~' => { if unescape_special && input_position == 0 { to_append_or_none = Some(HOME_DIRECTORY); } } '%' => { // Note that this only recognizes %self if the string is literally %self. // %self/foo will NOT match this. if unescape_special && input_position == 0 && input == PROCESS_EXPAND_SELF_STR { to_append_or_none = Some(PROCESS_EXPAND_SELF); input_position += PROCESS_EXPAND_SELF_STR.len() - 1; // skip over 'self's } } '*' => { if unescape_special { // In general, this is ANY_STRING. But as a hack, if the last appended char // is ANY_STRING, delete the last char and store ANY_STRING_RECURSIVE to // reflect the fact that ** is the recursive wildcard. if result.chars().last() == Some(ANY_STRING) { assert!(!result.is_empty()); result.truncate(result.len() - 1); to_append_or_none = Some(ANY_STRING_RECURSIVE); } else { to_append_or_none = Some(ANY_STRING); } } } '?' => { if unescape_special && !feature_test(FeatureFlag::qmark_noglob) { to_append_or_none = Some(ANY_CHAR); } } '$' => { if unescape_special { let is_cmdsub = input_position + 1 < input.len() && input.char_at(input_position + 1) == '('; if !is_cmdsub { to_append_or_none = Some(VARIABLE_EXPAND); vars_or_seps.push(input_position); } } } '{' => { if unescape_special { brace_count += 1; to_append_or_none = Some(BRACE_BEGIN); // We need to store where the brace *ends up* in the output. braces.push(result.len()); } } '}' => { if unescape_special { // HACK: The completion machinery sometimes hands us partial tokens. // We can't parse them properly, but it shouldn't hurt, // so we don't assert here. // See #4954. // assert(brace_count > 0 && "imbalanced brackets are a tokenizer error, we // shouldn't be able to get here"); brace_count -= 1; to_append_or_none = Some(BRACE_END); if let Some(brace) = braces.pop() { // HACK: To reduce accidental use of brace expansion, treat a brace // with zero or one items as literal input. See #4632. (The hack is // doing it here and like this.) if vars_or_seps.last().map(|i| *i < brace).unwrap_or(true) { result.as_char_slice_mut()[brace] = '{'; // We also need to turn all spaces back. for i in brace + 1..result.len() { if result.char_at(i) == BRACE_SPACE { result.as_char_slice_mut()[i] = ' '; } } to_append_or_none = Some('}'); } // Remove all seps inside the current brace pair, so if we have a // surrounding pair we only get seps inside *that*. if !vars_or_seps.is_empty() { while vars_or_seps.last().map(|i| *i > brace).unwrap_or_default() { vars_or_seps.pop(); } } } } } ',' => { if unescape_special && brace_count > 0 { to_append_or_none = Some(BRACE_SEP); vars_or_seps.push(input_position); } } ' ' => { if unescape_special && brace_count > 0 { to_append_or_none = Some(BRACE_SPACE); } } '\'' => { mode = Mode::SingleQuotes; to_append_or_none = if unescape_special { Some(INTERNAL_SEPARATOR) } else { None }; } '"' => { mode = Mode::DoubleQuotes; to_append_or_none = if unescape_special { Some(INTERNAL_SEPARATOR) } else { None }; } _ => (), } } else if mode == Mode::SingleQuotes { if c == '\\' { // A backslash may or may not escape something in single quotes. match input.char_at(input_position + 1) { '\\' | '\'' => { to_append_or_none = Some(input.char_at(input_position + 1)); input_position += 1; // skip over the backslash } '\0' => { if !allow_incomplete { errored = true; } else { // PCA this line had the following cryptic comment: 'We may ever escape // a NULL character, but still appending a \ in case I am wrong.' Not // sure what it means or the importance of this. input_position += 1; /* Skip over the backslash */ to_append_or_none = Some('\\'); } } _ => { // Literal backslash that doesn't escape anything! Leave things alone; we'll // append the backslash itself. } } } else if c == '\'' { to_append_or_none = if unescape_special { Some(INTERNAL_SEPARATOR) } else { None }; mode = Mode::Unquoted; } } else if mode == Mode::DoubleQuotes { match c { '"' => { mode = Mode::Unquoted; to_append_or_none = if unescape_special { Some(INTERNAL_SEPARATOR) } else { None }; } '\\' => { match input.char_at(input_position + 1) { '\0' => { if !allow_incomplete { errored = true; } else { to_append_or_none = Some('\0'); } } '\\' | '$' | '"' => { to_append_or_none = Some(input.char_at(input_position + 1)); input_position += 1; /* Skip over the backslash */ } '\n' => { /* Swallow newline */ to_append_or_none = None; input_position += 1; /* Skip over the backslash */ } _ => { /* Literal backslash that doesn't escape anything! Leave things alone; * we'll append the backslash itself */ } } } '$' => { if unescape_special { to_append_or_none = Some(VARIABLE_EXPAND_SINGLE); vars_or_seps.push(input_position); } } _ => (), } } // Now maybe append the char. if let Some(c) = to_append_or_none { result.push(c); } input_position += 1; } // Return the string by reference, and then success. if errored { return None; } Some(result) } /// Reverse the effects of `escape_string_url()`. By definition the string has consist of just ASCII /// chars. fn unescape_string_url(input: &wstr) -> Option { let mut result: Vec = vec![]; let mut i = 0; while i < input.len() { let c = input.char_at(i); if c > '\u{7F}' { return None; // invalid character means we can't decode the string } if c == '%' { let c1 = input.char_at(i + 1); if c1 == '\0' { return None; } else if c1 == '%' { result.push(b'%'); i += 1; } else { let c2 = input.char_at(i + 2); if c2 == '\0' { return None; // string ended prematurely } let d1 = c1.to_digit(16)?; let d2 = c2.to_digit(16)?; result.push((16 * d1 + d2) as u8); i += 2; } } else { result.push(c as u8); } i += 1 } Some(str2wcstring(&result)) } /// Reverse the effects of `escape_string_var()`. By definition the string has consist of just ASCII /// chars. fn unescape_string_var(input: &wstr) -> Option { let mut result: Vec = vec![]; let mut prev_was_hex_encoded = false; let mut i = 0; while i < input.len() { let c = input.char_at(i); if c > '\u{7F}' { return None; // invalid character means we can't decode the string } if c == '_' { let c1 = input.char_at(i + 1); if c1 == '\0' { if prev_was_hex_encoded { break; } return None; // found unexpected escape char at end of string } if c1 == '_' { result.push(b'_'); i += 1; } else if ('0'..='9').contains(&c1) || ('A'..='F').contains(&c1) { let c2 = input.char_at(i + 2); if c2 == '\0' { return None; // string ended prematurely } let d1 = convert_hex_digit(c1)?; let d2 = convert_hex_digit(c2)?; result.push((16 * d1 + d2) as u8); i += 2; prev_was_hex_encoded = true; } // No "else" clause because if the first char after an underscore is not another // underscore or a valid hex character then the underscore is there to improve // readability after we've encoded a character not valid in a var name. } else { result.push(c as u8); } i += 1; } Some(str2wcstring(&result)) } /// Given a string starting with a backslash, read the escape as if it is unquoted, appending /// to result. Return the number of characters consumed, or none on error. pub fn read_unquoted_escape( input: &wstr, result: &mut WString, allow_incomplete: bool, unescape_special: bool, ) -> Option { assert!(input.char_at(0) == '\\', "not an escape"); // Here's the character we'll ultimately append, or none. Note that '\0' is a // valid thing to append. let mut result_char_or_none: Option = None; let mut errored = false; let mut in_pos = 1; // in_pos always tracks the next character to read (and therefore the number // of characters read so far) // For multibyte \X sequences. let mut byte_buff: Vec = vec![]; loop { let c = input.char_at(in_pos); in_pos += 1; match c { // A null character after a backslash is an error. '\0' => { // Adjust in_pos to only include the backslash. assert!(in_pos > 0); in_pos -= 1; // It's an error, unless we're allowing incomplete escapes. if !allow_incomplete { errored = true; } } // Numeric escape sequences. No prefix means octal escape, otherwise hexadecimal. '0'..='7' | 'u' | 'U' | 'x' | 'X' => { let mut res: u64 = 0; let mut chars = 2; let mut base = 16; let mut byte_literal = false; let mut max_val = ASCII_MAX; match c { 'u' => { chars = 4; max_val = UCS2_MAX; } 'U' => { chars = 8; // Don't exceed the largest Unicode code point - see #1107. max_val = char::MAX; } 'x' | 'X' => { byte_literal = true; max_val = BYTE_MAX; } _ => { base = 8; chars = 3; // Note that in_pos currently is just after the first post-backslash // character; we want to start our escape from there. assert!(in_pos > 0); in_pos -= 1; } } for i in 0..chars { let Some(d) = input.char_at(in_pos).to_digit(base) else { // If we have no digit, this is a tokenizer error. if i == 0 { errored = true; } break; }; res = (res * u64::from(base)) + u64::from(d); in_pos += 1; } if !errored && res <= u64::from(max_val) { if byte_literal { // Multibyte encodings necessitate that we keep adjacent byte escapes. // - `\Xc3\Xb6` is "ö", but only together. // (this assumes a valid codepoint can't consist of multiple bytes // that are valid on their own, which is true for UTF-8) byte_buff.push(res.try_into().unwrap()); result_char_or_none = None; if input[in_pos..].starts_with("\\X") || input[in_pos..].starts_with("\\x") { in_pos += 1; continue; } } else { result_char_or_none = Some(char::from_u32(res.try_into().unwrap()).unwrap_or('\u{FFFD}')); } } else { errored = true; } } // \a means bell (alert). 'a' => { result_char_or_none = Some('\x07'); } // \b means backspace. 'b' => { result_char_or_none = Some('\x08'); } // \cX means control sequence X. 'c' => { let sequence_char = u32::from(input.char_at(in_pos)); in_pos += 1; if sequence_char >= u32::from('a') && sequence_char <= u32::from('a') + 32 { result_char_or_none = Some(char::from_u32(sequence_char - u32::from('a') + 1).unwrap()); } else if sequence_char >= u32::from('A') && sequence_char <= u32::from('A') + 32 { result_char_or_none = Some(char::from_u32(sequence_char - u32::from('A') + 1).unwrap()); } else { errored = true; } } // \x1B means escape. 'e' => { result_char_or_none = Some('\x1B'); } // \f means form feed. 'f' => { result_char_or_none = Some('\x0C'); } // \n means newline. 'n' => { result_char_or_none = Some('\n'); } // \r means carriage return. 'r' => { result_char_or_none = Some('\x0D'); } // \t means tab. 't' => { result_char_or_none = Some('\t'); } // \v means vertical tab. 'v' => { result_char_or_none = Some('\x0b'); } // If a backslash is followed by an actual newline, swallow them both. '\n' => { result_char_or_none = None; } _ => { if unescape_special { result.push(INTERNAL_SEPARATOR); } result_char_or_none = Some(c); } } if errored { return None; } if !byte_buff.is_empty() { result.push_utfstr(&str2wcstring(&byte_buff)); } break; } if let Some(c) = result_char_or_none { result.push(c); } Some(in_pos) } /// This is a specialization of `char::to_digit()` that only handles base 16 and only uppercase. fn convert_hex_digit(d: char) -> Option { let val = if ('0'..='9').contains(&d) { u32::from(d) - u32::from('0') } else if ('A'..='Z').contains(&d) { 10 + u32::from(d) - u32::from('A') } else { return None; }; Some(val) } pub const fn char_offset(base: char, offset: u32) -> char { match char::from_u32(base as u32 + offset) { Some(c) => c, None => panic!("not a valid char"), } } /// Exits without invoking destructors (via _exit), useful for code after fork. fn exit_without_destructors(code: i32) -> ! { unsafe { libc::_exit(code); } } /// Save the shell mode on startup so we can restore them on exit. static SHELL_MODES: Lazy> = Lazy::new(|| Mutex::new(unsafe { mem::zeroed() })); /// The character to use where the text has been truncated. Is an ellipsis on unicode system and a $ /// on other systems. pub fn get_ellipsis_char() -> char { char::from_u32(ELLIPSIS_CHAR.load(Ordering::Relaxed)).unwrap() } static ELLIPSIS_CHAR: AtomicU32 = AtomicU32::new(0); /// The character or string to use where text has been truncated (ellipsis if possible, otherwise /// ...) pub static mut ELLIPSIS_STRING: Lazy<&'static wstr> = Lazy::new(|| L!("")); /// Character representing an omitted newline at the end of text. pub fn get_omitted_newline_str() -> &'static wstr { unsafe { &OMITTED_NEWLINE_STR } } static mut OMITTED_NEWLINE_STR: Lazy<&'static wstr> = Lazy::new(|| L!("")); pub fn get_omitted_newline_width() -> usize { unsafe { OMITTED_NEWLINE_STR.len() } } static OBFUSCATION_READ_CHAR: AtomicU32 = AtomicU32::new(0); pub fn get_obfuscation_read_char() -> char { char::from_u32(OBFUSCATION_READ_CHAR.load(Ordering::Relaxed)).unwrap() } /// Profiling flag. True if commands should be profiled. pub static G_PROFILING_ACTIVE: RelaxedAtomicBool = RelaxedAtomicBool::new(false); /// Name of the current program. Should be set at startup. Used by the debug function. pub static mut PROGRAM_NAME: Lazy<&'static wstr> = Lazy::new(|| L!("")); #[cfg(windows)] /// Set to false if it's been determined we can't trust the last modified timestamp on the tty. pub const HAS_WORKING_TTY_TIMESTAMPS: bool = false; #[cfg(not(windows))] /// Set to false if it's been determined we can't trust the last modified timestamp on the tty. pub const HAS_WORKING_TTY_TIMESTAMPS: bool = true; /// A global, empty string. This is useful for functions which wish to return a reference to an /// empty string. pub static G_EMPTY_STRING: WString = WString::new(); /// A global, empty wcstring_list_t. This is useful for functions which wish to return a reference /// to an empty string. pub static G_EMPTY_STRING_LIST: Vec = vec![]; /// A function type to check for cancellation. /// \return true if execution should cancel. pub type CancelChecker = dyn Fn() -> bool; /// Converts the narrow character string \c in into its wide equivalent, and return it. /// /// The string may contain embedded nulls. /// /// This function encodes illegal character sequences in a reversible way using the private use /// area. pub fn str2wcstring(inp: &[u8]) -> WString { if inp.is_empty() { return WString::new(); } let mut result = WString::new(); result.reserve(inp.len()); let mut pos = 0; let mut state = zero_mbstate(); while pos < inp.len() { // Append any initial sequence of ascii characters. // Note we do not support character sets which are not supersets of ASCII. let ascii_prefix_length = count_ascii_prefix(&inp[pos..]); result.push_str(std::str::from_utf8(&inp[pos..pos + ascii_prefix_length]).unwrap()); pos += ascii_prefix_length; assert!(pos <= inp.len(), "Position overflowed length"); if pos == inp.len() { break; } // We have found a non-ASCII character. let mut ret = 0; let mut c = '\0'; let use_encode_direct = if inp[pos] & 0xF8 == 0xF8 { // Protect against broken mbrtowc() implementations which attempt to encode UTF-8 // sequences longer than four bytes (e.g., OS X Snow Leopard). // TODO This check used to be conditionally compiled only on affected platforms. true } else { const _: () = assert!(mem::size_of::() == mem::size_of::()); let mut codepoint = u32::from(c); ret = unsafe { mbrtowc( std::ptr::addr_of_mut!(codepoint).cast(), std::ptr::addr_of!(inp[pos]).cast(), inp.len() - pos, &mut state, ) }; match char::from_u32(codepoint) { Some(codepoint) => { c = codepoint; // Determine whether to encode this character with our crazy scheme. (c >= ENCODE_DIRECT_BASE && c < ENCODE_DIRECT_END) || c == INTERNAL_SEPARATOR || // Incomplete sequence. ret == 0_usize.wrapping_sub(2) || // Invalid data. ret == 0_usize.wrapping_sub(1) || // Other error codes? Terrifying, should never happen. ret > inp.len() - pos } None => true, } }; if use_encode_direct { c = encode_byte_to_char(inp[pos]); result.push(c); pos += 1; state = zero_mbstate(); } else if ret == 0 { // embedded null byte! result.push('\0'); pos += 1; state = zero_mbstate(); } else { // normal case result.push(c); pos += ret; } } result } /// Returns a newly allocated multibyte character string equivalent of the specified wide character /// string. /// /// This function decodes illegal character sequences in a reversible way using the private use /// area. pub fn wcs2string(input: &wstr) -> Vec { if input.is_empty() { return vec![]; } let mut result = vec![]; wcs2string_appending(&mut result, input); result } pub fn wcs2zstring(input: &wstr) -> CString { if input.is_empty() { return CString::default(); } let mut result = vec![]; wcs2string_callback(input, |buff| { result.extend_from_slice(buff); true }); let until_nul = match result.iter().position(|c| *c == b'\0') { Some(pos) => &result[..pos], None => &result[..], }; CString::new(until_nul).unwrap() } /// Like wcs2string, but appends to \p receiver instead of returning a new string. pub fn wcs2string_appending(output: &mut Vec, input: &wstr) { output.reserve(input.len()); wcs2string_callback(input, |buff| { output.extend_from_slice(buff); true }); } /// \return the count of initial characters in \p in which are ASCII. fn count_ascii_prefix(inp: &[u8]) -> usize { // The C++ version had manual vectorization. inp.iter().take_while(|c| c.is_ascii()).count() } // Check if we are running in the test mode, where we should suppress error output #[widestrs] pub const TESTS_PROGRAM_NAME: &wstr = "(ignore)"L; /// Hack to not print error messages in the tests. Do not call this from functions in this module /// like `debug()`. It is only intended to suppress diagnostic noise from testing things like the /// fish parser where we expect a lot of diagnostic messages due to testing error conditions. pub fn should_suppress_stderr_for_tests() -> bool { unsafe { !PROGRAM_NAME.is_empty() && *PROGRAM_NAME != TESTS_PROGRAM_NAME } } fn assert_is_main_thread() { assert!(is_main_thread() || THREAD_ASSERTS_CFG_FOR_TESTING.load()); } fn assert_is_background_thread() { assert!(!is_main_thread() || THREAD_ASSERTS_CFG_FOR_TESTING.load()); } static THREAD_ASSERTS_CFG_FOR_TESTING: RelaxedAtomicBool = RelaxedAtomicBool::new(false); thread_local! { static TL_TID: RefCell = RefCell::new(0); } static S_LAST_THREAD_ID: AtomicU64 = AtomicU64::new(0); fn next_thread_id() -> u64 { // Note 0 is an invalid thread id. // Note fetch_add is a CAS which returns the value *before* the modification. 1 + S_LAST_THREAD_ID.fetch_add(1, Ordering::Relaxed) } fn thread_id() -> u64 { TL_TID.with(|tid| { if *tid.borrow() == 0 { *tid.borrow_mut() = next_thread_id() } *tid.borrow() }) } /// Format the specified size (in bytes, kilobytes, etc.) into the specified stringbuffer. #[widestrs] fn format_size(mut sz: i64) -> WString { let mut result = WString::new(); const sz_names: [&wstr; 8] = ["kB"L, "MB"L, "GB"L, "TB"L, "PB"L, "EB"L, "ZB"L, "YB"L]; if sz < 0 { result += "unknown"L; } else if sz == 0 { result += wgettext!("empty"); } else if sz < 1024 { result += &sprintf!("%lldB"L, sz)[..]; } else { for (i, sz_name) in sz_names.iter().enumerate() { if sz < (1024 * 1024) || i == sz_names.len() - 1 { let isz = sz / 1024; if isz > 9 { result += &sprintf!("%ld%ls"L, isz, *sz_name)[..]; } else { result += &sprintf!("%.1f%ls"L, sz as f64 / 1024.0, *sz_name)[..]; } break; } sz /= 1024; } } result } /// Version of format_size that does not allocate memory. fn format_size_safe(buff: &mut [u8; 128], mut sz: u64) { let buff_size = 128; let max_len = buff_size - 1; // need to leave room for a null terminator buff.fill(0); let mut idx = 0; const sz_names: [&str; 8] = ["kB", "MB", "GB", "TB", "PB", "EB", "ZB", "YB"]; if sz == 0 { let empty = "empty".as_bytes(); buff[..empty.len()].copy_from_slice(empty); } else if sz < 1024 { append_ull(buff, &mut sz, &mut idx, max_len); append_str(buff, "B", &mut idx, max_len); } else { for (i, sz_name) in sz_names.iter().enumerate() { if sz < (1024 * 1024) || i == sz_names.len() - 1 { let mut isz = sz / 1024; append_ull(buff, &mut isz, &mut idx, max_len); if isz <= 9 { // Maybe append a single fraction digit. let mut remainder = sz % 1024; if remainder > 0 { let tmp = [b'.', extract_most_significant_digit(&mut remainder)]; let tmp = std::str::from_utf8(&tmp).unwrap(); append_str(buff, tmp, &mut idx, max_len); } } append_str(buff, sz_name, &mut idx, max_len); break; } sz /= 1024; } } } /// Writes out a long safely. pub fn format_llong_safe>(buff: &mut [CharT; 64], val: i64) { let uval = val.unsigned_abs(); if val >= 0 { format_safe_impl(buff, 64, uval); } else { buff[0] = CharT::from(b'-'); format_safe_impl(&mut buff[1..], 63, uval); } } pub fn format_ullong_safe>(buff: &mut [CharT; 64], val: u64) { format_safe_impl(buff, 64, val); } fn format_safe_impl>(buff: &mut [CharT], size: usize, mut val: u64) { let mut idx = 0; if val == 0 { buff[idx] = CharT::from(b'0'); } else { // Generate the string backwards, then reverse it. while val != 0 { buff[idx] = CharT::from((val % 10) as u8 + b'0'); val /= 10; } buff[..idx].reverse(); } buff[idx] = CharT::from(b'\0'); idx += 1; assert!(idx <= size, "Buffer overflowed"); } fn append_ull(buff: &mut [u8], val: &mut u64, inout_idx: &mut usize, max_len: usize) { let mut idx = *inout_idx; while *val > 0 && idx < max_len { buff[idx] = extract_most_significant_digit(val); idx += 1; } *inout_idx = idx; } fn append_str(buff: &mut [u8], s: &str, inout_idx: &mut usize, max_len: usize) { let mut idx = *inout_idx; let bytes = s.as_bytes(); while idx < bytes.len().min(max_len) { buff[idx] = bytes[idx]; idx += 1; } *inout_idx = idx; } /// Crappy function to extract the most significant digit of an unsigned long long value. fn extract_most_significant_digit(xp: &mut u64) -> u8 { let mut place_value = 1; let mut x = *xp; while x >= 10 { x /= 10; place_value *= 10; } *xp -= place_value * x; x as u8 + b'0' } /// "Narrows" a wide character string. This just grabs any ASCII characters and truncates. pub fn narrow_string_safe(buff: &mut [u8; 64], s: &wstr) { let mut idx = 0; for c in s.chars() { if c as u32 <= 127 { buff[idx] = c as u8; idx += 1; if idx + 1 == 64 { break; } } } buff[idx] = b'\0'; } /// Stored in blocks to reference the file which created the block. pub type FilenameRef = Rc; /// This function should be called after calling `setlocale()` to perform fish specific locale /// initialization. #[widestrs] fn fish_setlocale() { // Use various Unicode symbols if they can be encoded using the current locale, else a simple // ASCII char alternative. All of the can_be_encoded() invocations should return the same // true/false value since the code points are in the BMP but we're going to be paranoid. This // is also technically wrong if we're not in a Unicode locale but we expect (or hope) // can_be_encoded() will return false in that case. if can_be_encoded('\u{2026}') { ELLIPSIS_CHAR.store(u32::from('\u{2026}'), Ordering::Relaxed); unsafe { ELLIPSIS_STRING = Lazy::new(|| "\u{2026}"L); } } else { ELLIPSIS_CHAR.store(u32::from('$'), Ordering::Relaxed); // "horizontal ellipsis" unsafe { ELLIPSIS_STRING = Lazy::new(|| "..."L); } } if is_windows_subsystem_for_linux() { // neither of \u23CE and \u25CF can be displayed in the default fonts on Windows, though // they can be *encoded* just fine. Use alternative glyphs. unsafe { OMITTED_NEWLINE_STR = Lazy::new(|| "\u{00b6}"L); // "pilcrow" } OBFUSCATION_READ_CHAR.store(u32::from('\u{2022}'), Ordering::Relaxed); // "bullet" } else if is_console_session() { unsafe { OMITTED_NEWLINE_STR = Lazy::new(|| "^J"L); } OBFUSCATION_READ_CHAR.store(u32::from('*'), Ordering::Relaxed); } else { if can_be_encoded('\u{23CE}') { unsafe { OMITTED_NEWLINE_STR = Lazy::new(|| "\u{23CE}"L); // "return symbol" (⏎) } } else { unsafe { OMITTED_NEWLINE_STR = Lazy::new(|| "^J"L); } } OBFUSCATION_READ_CHAR.store( u32::from(if can_be_encoded('\u{25CF}') { '\u{25CF}' // "black circle" } else { '#' }), Ordering::Relaxed, ); } G_PROFILING_ACTIVE.store(true); } /// Test if the character can be encoded using the current locale. fn can_be_encoded(wc: char) -> bool { let mut converted = [0_i8; AT_LEAST_MB_LEN_MAX]; let mut state = zero_mbstate(); unsafe { wcrtomb(&mut converted[0], wc as libc::wchar_t, &mut state) != 0_usize.wrapping_sub(1) } } /// Call read, blocking and repeating on EINTR. Exits on EAGAIN. /// \return the number of bytes read, or 0 on EOF. On EAGAIN, returns -1 if nothing was read. pub fn read_blocked(fd: i32, mut buf: &mut [u8]) -> isize { loop { let res = unsafe { libc::read(fd, std::ptr::addr_of_mut!(buf).cast(), buf.len()) }; if res < 0 && errno::errno().0 == EINTR { continue; } return res; } } /// Test if the string is a valid function name. pub fn valid_func_name(name: &wstr) -> bool { if name.is_empty() { return false; }; if name.char_at(0) == '-' { return false; }; // A function name needs to be a valid path, so no / and no NULL. if name.find_char('/').is_some() { return false; }; if name.find_char('\0').is_some() { return false; }; true } /// A rusty port of the C++ `write_loop()` function from `common.cpp`. This should be deprecated in /// favor of native rust read/write methods at some point. /// /// Returns the number of bytes written or an IO error. pub fn write_loop(fd: &Fd, buf: &[u8]) -> std::io::Result { let fd = fd.as_raw_fd(); let mut total = 0; while total < buf.len() { let written = unsafe { libc::write(fd, buf[total..].as_ptr() as *const _, buf.len() - total) }; if written < 0 { let errno = errno::errno().0; if matches!(errno, libc::EAGAIN | libc::EINTR) { continue; } return Err(std::io::Error::from_raw_os_error(errno)); } total += written as usize; } Ok(total) } /// A rusty port of the C++ `read_loop()` function from `common.cpp`. This should be deprecated in /// favor of native rust read/write methods at some point. /// /// Returns the number of bytes read or an IO error. pub fn read_loop(fd: &Fd, buf: &mut [u8]) -> std::io::Result { let fd = fd.as_raw_fd(); loop { let read = unsafe { libc::read(fd, buf.as_mut_ptr() as *mut _, buf.len()) }; if read < 0 { let errno = errno::errno().0; if matches!(errno, libc::EAGAIN | libc::EINTR) { continue; } return Err(std::io::Error::from_raw_os_error(errno)); } return Ok(read as usize); } } /// Write the given paragraph of output, redoing linebreaks to fit \p termsize. #[widestrs] fn reformat_for_screen(msg: &wstr, termsize: &Termsize) -> WString { let mut buff = WString::new(); let screen_width = termsize.width; if screen_width != 0 { let mut start = 0; let mut pos = start; let mut line_width = 0; while pos < msg.len() { let mut overflow = false; let mut tok_width = 0; // Tokenize on whitespace, and also calculate the width of the token. while pos < msg.len() && [' ', '\n', '\r', '\t'].contains(&msg.char_at(pos)) { // Check is token is wider than one line. If so we mark it as an overflow and break // the token. let width = fish_wcwidth(msg.char_at(pos).into()).0 as isize; if (tok_width + width) > (screen_width - 1) { overflow = true; break; } tok_width += width; pos += 1; } // If token is zero character long, we don't do anything. if pos == 0 { pos += 1; } else if overflow { // In case of overflow, we print a newline, except if we already are at position 0. let token = &msg[start..pos]; if line_width != 0 { buff.push('\n'); } buff += &sprintf!("%ls-\n"L, token)[..]; line_width = 0; } else { // Print the token. let token = &msg[start..pos]; let line_width_unit = (if line_width != 0 { 1 } else { 0 }); if (line_width + line_width_unit + tok_width) > screen_width { buff.push('\n'); line_width = 0; } if line_width != 0 { buff += " "L; } buff += token; line_width += line_width_unit + tok_width; } start = pos; } } else { buff += msg; } buff.push('\n'); buff } pub type Timepoint = f64; /// Return the number of seconds from the UNIX epoch, with subsecond precision. This function uses /// the gettimeofday function and will have the same precision as that function. pub fn timef() -> Timepoint { match time::SystemTime::now().duration_since(time::UNIX_EPOCH) { Ok(difference) => difference.as_secs() as f64, Err(until_epoch) => -(until_epoch.duration().as_secs() as f64), } } /// Call the following function early in main to set the main thread. This is our replacement for /// pthread_main_np(). pub fn set_main_thread() { // Just call thread_id() once to force increment of thread_id. let tid = thread_id(); assert!(tid == 1, "main thread should have thread ID 1"); } pub fn is_main_thread() -> bool { thread_id() == 1 } pub fn configure_thread_assertions_for_testing() { THREAD_ASSERTS_CFG_FOR_TESTING.store(true) } /// This allows us to notice when we've forked. static IS_FORKED_PROC: RelaxedAtomicBool = RelaxedAtomicBool::new(false); pub fn setup_fork_guards() { IS_FORKED_PROC.store(false); todo!(); } pub fn is_forked_child() -> bool { IS_FORKED_PROC.load() } /// Be able to restore the term's foreground process group. /// This is set during startup and not modified after. static INITIAL_FG_PROCESS_GROUP: AtomicI32 = AtomicI32::new(-1); // HACK, should be pid_t const _: () = assert!(mem::size_of::() >= mem::size_of::()); /// Save the value of tcgetpgrp so we can restore it on exit. pub fn save_term_foreground_process_group() { INITIAL_FG_PROCESS_GROUP.store(unsafe { libc::tcgetpgrp(STDIN_FILENO) }, Ordering::Relaxed); } pub fn restore_term_foreground_process_group_for_exit() { // We wish to restore the tty to the initial owner. There's two ways this can go wrong: // 1. We may steal the tty from someone else (#7060). // 2. The call to tcsetpgrp may deliver SIGSTOP to us, and we will not exit. // Hanging on exit seems worse, so ensure that SIGTTOU is ignored so we do not get SIGSTOP. // Note initial_fg_process_group == 0 is possible with Linux pid namespaces. // This is called during shutdown and from a signal handler. We don't bother to complain on // failure because doing so is unlikely to be noticed. let initial_fg_process_group = INITIAL_FG_PROCESS_GROUP.load(Ordering::Relaxed); if initial_fg_process_group > 0 && initial_fg_process_group != unsafe { libc::getpgrp() } { unsafe { libc::signal(SIGTTOU, SIG_IGN); libc::tcsetpgrp(STDIN_FILENO, initial_fg_process_group); } } } /// Determines if we are running under Microsoft's Windows Subsystem for Linux to work around /// some known limitations and/or bugs. /// See https://github.com/Microsoft/WSL/issues/423 and Microsoft/WSL#2997 pub fn is_windows_subsystem_for_linux() -> bool { // We are purposely not using std::call_once as it may invoke locking, which is an unnecessary // overhead since there's no actual race condition here - even if multiple threads call this // routine simultaneously the first time around, we just end up needlessly querying uname(2) one // more time. *IS_WINDOWS_SUBSYSTEM_FOR_LINUX } fn slice_contains_slice(a: &[T], b: &[T]) -> bool { a.windows(b.len()).any(|aw| aw == b) } #[cfg(not(windows))] static IS_WINDOWS_SUBSYSTEM_FOR_LINUX: Lazy = Lazy::new(|| false); #[cfg(windows)] static IS_WINDOWS_SUBSYSTEM_FOR_LINUX: Lazy = Lazy::new(|| { let mut info: libc::utsname = unsafe { mem::zeroed() }; unsafe { libc::uname(&mut info); } // Sample utsname.release under WSL, testing for something like `4.4.0-17763-Microsoft` if !slice_contains_slice(&info.release, b"Microsoft") { return false; } let dash = info.release.iter().position('-'); if dash .map(|d| unsafe { libc::strtod(&info.release[d + 1], std::ptr::null()) } >= 17763) .unwrap_or(false) { return false; } // #5298, #5661: There are acknowledged, published, and (later) fixed issues with // job control under early WSL releases that prevent fish from running correctly, // with unexpected failures when piping. Fish 3.0 nightly builds worked around this // issue with some needlessly complicated code that was later stripped from the // fish 3.0 release, so we just bail. Note that fish 2.0 was also broken, but we // just didn't warn about it. // #6038 & 5101bde: It's been requested that there be some sort of way to disable // this check: if the environment variable FISH_NO_WSL_CHECK is present, this test // is bypassed. We intentionally do not include this in the error message because // it'll only allow fish to run but not to actually work. Here be dragons! if env::var("FISH_NO_WSL_CHECK") == Err(env::VarError::NotPresent) { FLOG!( error, "This version of WSL has known bugs that prevent fish from working.\ Please upgrade to Windows 10 1809 (17763) or higher to use fish!" ); } true; }); /// Return true if the character is in a range reserved for fish's private use. /// /// NOTE: This is used when tokenizing the input. It is also used when reading input, before /// tokenization, to replace such chars with REPLACEMENT_WCHAR if they're not part of a quoted /// string. We don't want external input to be able to feed reserved characters into our /// lexer/parser or code evaluator. // // TODO: Actually implement the replacement as documented above. pub fn fish_reserved_codepoint(c: char) -> bool { (c >= RESERVED_CHAR_BASE && c < RESERVED_CHAR_END) || (c >= ENCODE_DIRECT_BASE && c < ENCODE_DIRECT_END) } pub fn redirect_tty_output() { unsafe { let mut t: libc::termios = mem::zeroed(); let s = CString::new("/dev/null").unwrap(); let fd = libc::open(s.as_ptr(), O_WRONLY); assert!(fd != -1, "Could not open /dev/null!"); for stdfd in [STDIN_FILENO, STDOUT_FILENO, STDERR_FILENO] { if libc::tcgetattr(stdfd, &mut t) == -1 && errno::errno().0 == EIO { libc::dup2(fd, stdfd); } } } } /// Test if the given char is valid in a variable name. pub fn valid_var_name_char(chr: char) -> bool { fish_iswalnum(chr) || chr == '_' } /// Test if the given string is a valid variable name. fn valid_var_name(s: &wstr) -> bool { // Note do not use c_str(), we want to fail on embedded nul bytes. !s.is_empty() && s.chars().all(valid_var_name_char) } /// Get the absolute path to the fish executable itself fn get_executable_path(argv0: &str) -> PathBuf { std::env::current_exe().unwrap_or_else(|_| PathBuf::from_str(argv0).unwrap()) } /// Like [`std::mem::replace()`] but provides a reference to the old value in a callback to obtain /// the replacement value. Useful to avoid errors about multiple references (`&mut T` for `old` then /// `&T` again in the `new` expression). pub fn replace_with T>(old: &mut T, with: F) -> T { let new = with(&*old); std::mem::replace(old, new) } pub type Cleanup = ScopeGuard; /// A RAII cleanup object. Unlike in C++ where there is no borrow checker, we can't just provide a /// callback that modifies live objects willy-nilly because then there would be two &mut references /// to the same object - the original variables we keep around to use and their captured references /// held by the closure until its scope expires. /// /// Instead we have a `ScopeGuard` type that takes exclusive ownership of (a mutable reference to) /// the object to be managed. In lieu of keeping the original value around, we obtain a regular or /// mutable reference to it via ScopeGuard's [`Deref`] and [`DerefMut`] impls. /// /// The `ScopeGuard` is considered to be the exclusively owner of the passed value for the /// duration of its lifetime. If you need to use the value again, use `ScopeGuard` to shadow the /// value and obtain a reference to it via the `ScopeGuard` itself: /// /// ```rust /// use std::io::prelude::*; /// /// let file = std::fs::File::open("/dev/null"); /// // Create a scope guard to write to the file when the scope expires. /// // To be able to still use the file, shadow `file` with the ScopeGuard itself. /// let mut file = ScopeGuard::new(file, |file| file.write_all(b"goodbye\n").unwrap()); /// // Now write to the file normally "through" the capturing ScopeGuard instance. /// file.write_all(b"hello\n").unwrap(); /// /// // hello will be written first, then goodbye. /// ``` pub struct ScopeGuard { captured: ManuallyDrop, on_drop: Option, } impl ScopeGuard { /// Creates a new `ScopeGuard` wrapping `value`. The `on_drop` callback is executed when the /// ScopeGuard's lifetime expires or when it is manually dropped. pub fn new(value: T, on_drop: F) -> Self { Self { captured: ManuallyDrop::new(value), on_drop: Some(on_drop), } } /// Cancel the unwind operation, e.g. do not call the previously passed-in `on_drop` callback /// when the current scope expires. pub fn cancel(guard: &mut Self) { guard.on_drop.take(); } /// Cancels the unwind operation like [`ScopeGuard::cancel()`] but also returns the captured /// value (consuming the `ScopeGuard` in the process). pub fn rollback(mut guard: Self) -> T { guard.on_drop.take(); // Safety: we're about to forget the guard altogether let value = unsafe { ManuallyDrop::take(&mut guard.captured) }; std::mem::forget(guard); value } /// Commits the unwind operation (i.e. applies the provided callback) and returns the captured /// value (consuming the `ScopeGuard` in the process). pub fn commit(mut guard: Self) -> T { (guard.on_drop.take().expect("ScopeGuard already canceled!"))(&mut guard.captured); // Safety: we're about to forget the guard altogether let value = unsafe { ManuallyDrop::take(&mut guard.captured) }; std::mem::forget(guard); value } } impl Deref for ScopeGuard { type Target = T; fn deref(&self) -> &Self::Target { &self.captured } } impl DerefMut for ScopeGuard { fn deref_mut(&mut self) -> &mut Self::Target { &mut self.captured } } impl Drop for ScopeGuard { fn drop(&mut self) { if let Some(on_drop) = self.on_drop.take() { on_drop(&mut self.captured); } // Safety: we're in the Drop so `self` will never be accessed again. unsafe { ManuallyDrop::drop(&mut self.captured) }; } } /// A scoped manager to save the current value of some variable, and optionally set it to a new /// value. When dropped, it restores the variable to its old value. /// /// This can be handy when there are multiple code paths to exit a block. Note that this can only be /// used if the code does not access the captured variable again for the duration of the scope. If /// that's not the case (the code will refuse to compile), use a [`ScopeGuard`] instance instead. pub struct ScopedPush<'a, T> { var: &'a mut T, saved_value: Option, } impl<'a, T> ScopedPush<'a, T> { pub fn new(var: &'a mut T, new_value: T) -> Self { let saved_value = mem::replace(var, new_value); Self { var, saved_value: Some(saved_value), } } pub fn restore(&mut self) { if let Some(saved_value) = self.saved_value.take() { *self.var = saved_value; } } } impl<'a, T> Drop for ScopedPush<'a, T> { fn drop(&mut self) { self.restore() } } pub const fn assert_send() {} pub const fn assert_sync() {} /// This function attempts to distinguish between a console session (at the actual login vty) and a /// session within a terminal emulator inside a desktop environment or over SSH. Unfortunately /// there are few values of $TERM that we can interpret as being exclusively console sessions, and /// most common operating systems do not use them. The value is cached for the duration of the fish /// session. We err on the side of assuming it's not a console session. This approach isn't /// bullet-proof and that's OK. pub fn is_console_session() -> bool { *CONSOLE_SESSION } static CONSOLE_SESSION: Lazy = Lazy::new(|| { const path_max: usize = libc::PATH_MAX as _; let mut tty_name: [u8; path_max] = [0; path_max]; if unsafe { libc::ttyname_r( STDIN_FILENO, std::ptr::addr_of_mut!(tty_name).cast(), path_max, ) } != 0 { return false; } // Test that the tty matches /dev/(console|dcons|tty[uv\d]) let len = "/dev/tty".len(); ( ( tty_name.starts_with(b"/dev/tty") && ([b'u', b'v'].contains(&tty_name[len]) || tty_name[len].is_ascii_digit()) ) || tty_name.starts_with(b"/dev/dcons\0") || tty_name.starts_with(b"/dev/console\0")) // and that $TERM is simple, e.g. `xterm` or `vt100`, not `xterm-something` && match env::var("TERM") { Ok(term) => ["-", "sun-color"].contains(&term.as_str()), Err(env::VarError::NotPresent) => true, Err(_) => false, } }); /// Asserts that a slice is alphabetically sorted by a [`&wstr`] `name` field. /// /// Mainly useful for static asserts/const eval. /// /// # Panics /// /// This function panics if the given slice is unsorted. /// /// # Examples /// /// ```rust /// const COLORS: &[(&wstr, u32)] = &[ /// // must be in alphabetical order /// (L!("blue"), 0x0000ff), /// (L!("green"), 0x00ff00), /// (L!("red"), 0xff0000), /// ]; /// /// assert_sorted_by_name!(COLORS, 0); /// ``` macro_rules! assert_sorted_by_name { ($slice:expr, $field:tt) => { const _: () = { use std::cmp::Ordering; // ugly const eval workarounds below. const fn cmp_i32(lhs: i32, rhs: i32) -> Ordering { match lhs - rhs { ..=-1 => Ordering::Less, 0 => Ordering::Equal, 1.. => Ordering::Greater, } } const fn cmp_slice(s1: &[char], s2: &[char]) -> Ordering { let mut i = 0; while i < s1.len() && i < s2.len() { match cmp_i32(s1[i] as i32, s2[i] as i32) { Ordering::Equal => i += 1, other => return other, } } cmp_i32(s1.len() as i32, s2.len() as i32) } let mut i = 1; while i < $slice.len() { let prev = $slice[i - 1].$field.as_char_slice(); let cur = $slice[i].$field.as_char_slice(); if matches!(cmp_slice(prev, cur), Ordering::Greater) { panic!("array must be sorted"); } i += 1; } }; }; ($slice:expr) => { assert_sorted_by_name!($slice, name); }; } mod tests { use crate::common::{ escape_string, str2wcstring, wcs2string, EscapeStringStyle, ENCODE_DIRECT_BASE, ENCODE_DIRECT_END, }; use crate::wchar::widestrs; use crate::wutil::encoding::{wcrtomb, zero_mbstate, AT_LEAST_MB_LEN_MAX}; use rand::random; #[widestrs] pub fn test_escape_string() { let regex = |input| escape_string(input, EscapeStringStyle::Regex); // plain text should not be needlessly escaped assert_eq!(regex("hello world!"L), "hello world!"L); // all the following are intended to be ultimately matched literally - even if they // don't look like that's the intent - so we escape them. assert_eq!(regex(".ext"L), "\\.ext"L); assert_eq!(regex("{word}"L), "\\{word\\}"L); assert_eq!(regex("hola-mundo"L), "hola\\-mundo"L); assert_eq!( regex("$17.42 is your total?"L), "\\$17\\.42 is your total\\?"L ); assert_eq!( regex("not really escaped\\?"L), "not really escaped\\\\\\?"L ); } /// The number of tests to run. const ESCAPE_TEST_COUNT: usize = 100000; /// The average length of strings to unescape. const ESCAPE_TEST_LENGTH: usize = 100; /// The highest character number of character to try and escape. const ESCAPE_TEST_CHAR: usize = 4000; /// Helper to convert a narrow string to a sequence of hex digits. fn str2hex(input: &[u8]) -> String { let mut output = "".to_string(); for byte in input { output += &format!("0x{:2X} ", *byte); } output } /// Test wide/narrow conversion by creating random strings and verifying that the original /// string comes back through double conversion. pub fn test_convert() { for _ in 0..ESCAPE_TEST_COUNT { let mut origin: Vec = vec![]; while (random::() % ESCAPE_TEST_LENGTH) != 0 { let byte = random(); origin.push(byte); } let w = str2wcstring(&origin[..]); let n = wcs2string(&w); assert_eq!( origin, n, "Conversion cycle of string:\n{:4} chars: {}\n\ produced different string:\n\ {:4} chars: {}", origin.len(), &str2hex(&origin), n.len(), &str2hex(&n) ); } } /// Verify that ASCII narrow->wide conversions are correct. pub fn test_convert_ascii() { let mut s = vec![b'\0'; 4096]; for (i, c) in s.iter_mut().enumerate() { *c = u8::try_from(i % 10).unwrap() + b'0'; } // Test a variety of alignments. for left in 0..16 { for right in 0..16 { let len = s.len() - left - right; let input = &s[left..left + len]; let wide = str2wcstring(input); let narrow = wcs2string(&wide); assert_eq!(narrow, input); } } // Put some non-ASCII bytes in and ensure it all still works. for i in 0..s.len() { let saved = s[i]; s[i] = 0xF7; assert_eq!(wcs2string(&str2wcstring(&s)), s); s[i] = saved; } } /// fish uses the private-use range to encode bytes that could not be decoded using the /// user's locale. If the input could be decoded, but decoded to private-use codepoints, /// then fish should also use the direct encoding for those bytes. Verify that characters /// in the private use area are correctly round-tripped. See #7723. pub fn test_convert_private_use() { for c in ENCODE_DIRECT_BASE..ENCODE_DIRECT_END { // Encode the char via the locale. Do not use fish functions which interpret these // specially. let mut converted = [0_u8; AT_LEAST_MB_LEN_MAX]; let mut state = zero_mbstate(); let len = unsafe { wcrtomb( std::ptr::addr_of_mut!(converted[0]).cast(), c as libc::wchar_t, &mut state, ) }; if len == 0_usize.wrapping_sub(1) { // Could not be encoded in this locale. continue; } let s = &converted[..len]; // Ask fish to decode this via str2wcstring. // str2wcstring should notice that the decoded form collides with its private use // and encode it directly. let ws = str2wcstring(s); // Each byte should be encoded directly, and round tripping should work. assert_eq!(ws.len(), s.len()); assert_eq!(wcs2string(&ws), s); } } } crate::ffi_tests::add_test!("escape_string", tests::test_escape_string); crate::ffi_tests::add_test!("escape_string", tests::test_convert); crate::ffi_tests::add_test!("escape_string", tests::test_convert_ascii); crate::ffi_tests::add_test!("escape_string", tests::test_convert_private_use); #[cxx::bridge] mod common_ffi { extern "C++" { include!("wutil.h"); include!("common.h"); type escape_string_style_t = crate::ffi::escape_string_style_t; } extern "Rust" { fn rust_unescape_string( input: *const wchar_t, len: usize, escape_special: u32, style: escape_string_style_t, ) -> UniquePtr; } } fn rust_unescape_string( input: *const ffi::wchar_t, len: usize, escape_special: u32, style: ffi::escape_string_style_t, ) -> UniquePtr { let style = match style { ffi::escape_string_style_t::STRING_STYLE_SCRIPT => { UnescapeStringStyle::Script(UnescapeFlags::from_bits(escape_special).unwrap()) } ffi::escape_string_style_t::STRING_STYLE_URL => UnescapeStringStyle::Url, ffi::escape_string_style_t::STRING_STYLE_VAR => UnescapeStringStyle::Var, _ => panic!(), }; let input = unsafe { slice::from_raw_parts(input, len) }; let input = wstr::from_slice(input).unwrap(); match unescape_string(input, style) { Some(result) => result.to_ffi(), None => UniquePtr::null(), } }