gpui_rn_util 0.1.1

pub mod arc_cow;
pub mod archive;
pub mod command;
pub mod fs;
pub mod markdown;
pub mod paths;
pub mod process;
pub mod redact;
pub mod rel_path;
pub mod schemars;
pub mod serde;
pub mod shell;
pub mod shell_builder;
pub mod shell_env;
pub mod size;
#[cfg(any(test, feature = "test-support"))]
pub mod test;
pub mod time;

use anyhow::{Context as _, Result};
use futures::Future;
use itertools::Either;
use paths::PathExt;
use regex::Regex;
use std::path::PathBuf;
use std::sync::{LazyLock, OnceLock};
use std::{
    borrow::Cow,
    cmp::{self, Ordering},
    env,
    ops::{AddAssign, Range, RangeInclusive},
    panic::Location,
    pin::Pin,
    task::{Context, Poll},
    time::Instant,
};
use unicase::UniCase;

pub use take_until::*;
#[cfg(any(test, feature = "test-support"))]
pub use util_macros::{line_endings, path, uri};

#[macro_export]
macro_rules! debug_panic {
    ( $($fmt_arg:tt)* ) => {
        if cfg!(debug_assertions) {
            panic!( $($fmt_arg)* );
        } else {
            let backtrace = std::backtrace::Backtrace::capture();
            log::error!("{}\n{:?}", format_args!($($fmt_arg)*), backtrace);
        }
    };
}

#[inline]
pub const fn is_utf8_char_boundary(u8: u8) -> bool {
    // This is bit magic equivalent to: b < 128 || b >= 192
    (u8 as i8) >= -0x40
}

pub fn truncate(s: &str, max_chars: usize) -> &str {
    match s.char_indices().nth(max_chars) {
        None => s,
        Some((idx, _)) => &s[..idx],
    }
}

/// Removes characters from the end of the string if its length is greater than `max_chars` and
/// appends "..." to the string. Returns string unchanged if its length is smaller than max_chars.
pub fn truncate_and_trailoff(s: &str, max_chars: usize) -> String {
    debug_assert!(max_chars >= 5);

    // If the string's byte length is <= max_chars, walking the string can be skipped since the
    // number of chars is <= the number of bytes.
    if s.len() <= max_chars {
        return s.to_string();
    }
    let truncation_ix = s.char_indices().map(|(i, _)| i).nth(max_chars);
    match truncation_ix {
        Some(index) => s[..index].to_string() + "…",
        _ => s.to_string(),
    }
}

/// Removes characters from the front of the string if its length is greater than `max_chars` and
/// prepends the string with "...". Returns string unchanged if its length is smaller than max_chars.
pub fn truncate_and_remove_front(s: &str, max_chars: usize) -> String {
    debug_assert!(max_chars >= 5);

    // If the string's byte length is <= max_chars, walking the string can be skipped since the
    // number of chars is <= the number of bytes.
    if s.len() <= max_chars {
        return s.to_string();
    }
    let suffix_char_length = max_chars.saturating_sub(1);
    let truncation_ix = s
        .char_indices()
        .map(|(i, _)| i)
        .nth_back(suffix_char_length);
    match truncation_ix {
        Some(index) if index > 0 => "…".to_string() + &s[index..],
        _ => s.to_string(),
    }
}

/// Takes only `max_lines` from the string and, if there were more than `max_lines-1`, appends a
/// a newline and "..." to the string, so that `max_lines` are returned.
/// Returns string unchanged if its length is smaller than max_lines.
pub fn truncate_lines_and_trailoff(s: &str, max_lines: usize) -> String {
    let mut lines = s.lines().take(max_lines).collect::<Vec<_>>();
    if lines.len() > max_lines - 1 {
        lines.pop();
        lines.join("\n") + "\n…"
    } else {
        lines.join("\n")
    }
}

/// Truncates the string at a character boundary, such that the result is less than `max_bytes` in
/// length.
pub fn truncate_to_byte_limit(s: &str, max_bytes: usize) -> &str {
    if s.len() < max_bytes {
        return s;
    }

    for i in (0..max_bytes).rev() {
        if s.is_char_boundary(i) {
            return &s[..i];
        }
    }

    ""
}

/// Takes a prefix of complete lines which fit within the byte limit. If the first line is longer
/// than the limit, truncates at a character boundary.
pub fn truncate_lines_to_byte_limit(s: &str, max_bytes: usize) -> &str {
    if s.len() < max_bytes {
        return s;
    }

    for i in (0..max_bytes).rev() {
        if s.is_char_boundary(i) && s.as_bytes()[i] == b'\n' {
            // Since the i-th character is \n, valid to slice at i + 1.
            return &s[..i + 1];
        }
    }

    truncate_to_byte_limit(s, max_bytes)
}

#[test]
fn test_truncate_lines_to_byte_limit() {
    let text = "Line 1\nLine 2\nLine 3\nLine 4";

    // Limit that includes all lines
    assert_eq!(truncate_lines_to_byte_limit(text, 100), text);

    // Exactly the first line
    assert_eq!(truncate_lines_to_byte_limit(text, 7), "Line 1\n");

    // Limit between lines
    assert_eq!(truncate_lines_to_byte_limit(text, 13), "Line 1\n");
    assert_eq!(truncate_lines_to_byte_limit(text, 20), "Line 1\nLine 2\n");

    // Limit before first newline
    assert_eq!(truncate_lines_to_byte_limit(text, 6), "Line ");

    // Test with non-ASCII characters
    let text_utf8 = "Line 1\nLíne 2\nLine 3";
    assert_eq!(
        truncate_lines_to_byte_limit(text_utf8, 15),
        "Line 1\nLíne 2\n"
    );
}

pub fn post_inc<T: From<u8> + AddAssign<T> + Copy>(value: &mut T) -> T {
    let prev = *value;
    *value += T::from(1);
    prev
}

/// Extend a sorted vector with a sorted sequence of items, maintaining the vector's sort order and
/// enforcing a maximum length. This also de-duplicates items. Sort the items according to the given callback. Before calling this,
/// both `vec` and `new_items` should already be sorted according to the `cmp` comparator.
pub fn extend_sorted<T, I, F>(vec: &mut Vec<T>, new_items: I, limit: usize, mut cmp: F)
where
    I: IntoIterator<Item = T>,
    F: FnMut(&T, &T) -> Ordering,
{
    let mut start_index = 0;
    for new_item in new_items {
        if let Err(i) = vec[start_index..].binary_search_by(|m| cmp(m, &new_item)) {
            let index = start_index + i;
            if vec.len() < limit {
                vec.insert(index, new_item);
            } else if index < vec.len() {
                vec.pop();
                vec.insert(index, new_item);
            }
            start_index = index;
        }
    }
}

pub fn truncate_to_bottom_n_sorted_by<T, F>(items: &mut Vec<T>, limit: usize, compare: &F)
where
    F: Fn(&T, &T) -> Ordering,
{
    if limit == 0 {
        items.truncate(0);
    }
    if items.len() <= limit {
        items.sort_by(compare);
        return;
    }
    // When limit is near to items.len() it may be more efficient to sort the whole list and
    // truncate, rather than always doing selection first as is done below. It's hard to analyze
    // where the threshold for this should be since the quickselect style algorithm used by
    // `select_nth_unstable_by` makes the prefix partially sorted, and so its work is not wasted -
    // the expected number of comparisons needed by `sort_by` is less than it is for some arbitrary
    // unsorted input.
    items.select_nth_unstable_by(limit, compare);
    items.truncate(limit);
    items.sort_by(compare);
}

/// Prevents execution of the application with root privileges on Unix systems.
///
/// This function checks if the current process is running with root privileges
/// and terminates the program with an error message unless explicitly allowed via the
/// `ZED_ALLOW_ROOT` environment variable.
#[cfg(unix)]
pub fn prevent_root_execution() {
    let is_root = nix::unistd::geteuid().is_root();
    let allow_root = std::env::var("ZED_ALLOW_ROOT").is_ok_and(|val| val == "true");

    if is_root && !allow_root {
        eprintln!(
            "\
Error: Running Zed as root or via sudo is unsupported.
       Doing so (even once) may subtly break things for all subsequent non-root usage of Zed.
       It is untested and not recommended, don't complain when things break.
       If you wish to proceed anyways, set `ZED_ALLOW_ROOT=true` in your environment."
        );
        std::process::exit(1);
    }
}

#[cfg(unix)]
fn load_shell_from_passwd() -> Result<()> {
    let buflen = match unsafe { libc::sysconf(libc::_SC_GETPW_R_SIZE_MAX) } {
        n if n < 0 => 1024,
        n => n as usize,
    };
    let mut buffer = Vec::with_capacity(buflen);

    let mut pwd: std::mem::MaybeUninit<libc::passwd> = std::mem::MaybeUninit::uninit();
    let mut result: *mut libc::passwd = std::ptr::null_mut();

    let uid = unsafe { libc::getuid() };
    let status = unsafe {
        libc::getpwuid_r(
            uid,
            pwd.as_mut_ptr(),
            buffer.as_mut_ptr() as *mut libc::c_char,
            buflen,
            &mut result,
        )
    };
    anyhow::ensure!(!result.is_null(), "passwd entry for uid {} not found", uid);

    // SAFETY: If `getpwuid_r` doesn't error, we have the entry here.
    let entry = unsafe { pwd.assume_init() };

    anyhow::ensure!(
        status == 0,
        "call to getpwuid_r failed. uid: {}, status: {}",
        uid,
        status
    );
    anyhow::ensure!(
        entry.pw_uid == uid,
        "passwd entry has different uid ({}) than getuid ({}) returned",
        entry.pw_uid,
        uid,
    );

    let shell = unsafe { std::ffi::CStr::from_ptr(entry.pw_shell).to_str().unwrap() };
    let should_set_shell = env::var("SHELL").map_or(true, |shell_env| {
        shell_env != shell && !std::path::Path::new(&shell_env).exists()
    });

    if should_set_shell {
        log::info!(
            "updating SHELL environment variable to value from passwd entry: {:?}",
            shell,
        );
        unsafe { env::set_var("SHELL", shell) };
    }

    Ok(())
}

/// Returns a shell escaped path for the current zed executable
pub fn get_shell_safe_zed_path(shell_kind: shell::ShellKind) -> anyhow::Result<String> {
    let zed_path =
        std::env::current_exe().context("Failed to determine current zed executable path.")?;

    zed_path
        .try_shell_safe(shell_kind)
        .context("Failed to shell-escape Zed executable path.")
}

/// Returns a path for the zed cli executable, this function
/// should be called from the zed executable, not zed-cli.
pub fn get_zed_cli_path() -> Result<PathBuf> {
    let zed_path =
        std::env::current_exe().context("Failed to determine current zed executable path.")?;
    let parent = zed_path
        .parent()
        .context("Failed to determine parent directory of zed executable path.")?;

    let possible_locations: &[&str] = if cfg!(target_os = "macos") {
        // On macOS, the zed executable and zed-cli are inside the app bundle,
        // so here ./cli is for both installed and development builds.
        &["./cli"]
    } else if cfg!(target_os = "windows") {
        // bin/zed.exe is for installed builds, ./cli.exe is for development builds.
        &["bin/zed.exe", "./cli.exe"]
    } else if cfg!(target_os = "linux") || cfg!(target_os = "freebsd") {
        // bin is the standard, ./cli is for the target directory in development builds.
        &["../bin/zed", "./cli"]
    } else {
        anyhow::bail!("unsupported platform for determining zed-cli path");
    };

    possible_locations
        .iter()
        .find_map(|p| {
            parent
                .join(p)
                .canonicalize()
                .ok()
                .filter(|p| p != &zed_path)
        })
        .with_context(|| {
            format!(
                "could not find zed-cli from any of: {}",
                possible_locations.join(", ")
            )
        })
}

#[cfg(unix)]
pub async fn load_login_shell_environment() -> Result<()> {
    load_shell_from_passwd().log_err();

    // If possible, we want to `cd` in the user's `$HOME` to trigger programs
    // such as direnv, asdf, mise, ... to adjust the PATH. These tools often hook
    // into shell's `cd` command (and hooks) to manipulate env.
    // We do this so that we get the env a user would have when spawning a shell
    // in home directory.
    for (name, value) in shell_env::capture(get_system_shell(), &[], paths::home_dir())
        .await
        .with_context(|| format!("capturing environment with {:?}", get_system_shell()))?
    {
        unsafe { env::set_var(&name, &value) };
    }

    log::info!(
        "set environment variables from shell:{}, path:{}",
        std::env::var("SHELL").unwrap_or_default(),
        std::env::var("PATH").unwrap_or_default(),
    );

    Ok(())
}

/// Configures the process to start a new session, to prevent interactive shells from taking control
/// of the terminal.
///
/// For more details: <https://registerspill.thorstenball.com/p/how-to-lose-control-of-your-shell>
pub fn set_pre_exec_to_start_new_session(
    command: &mut std::process::Command,
) -> &mut std::process::Command {
    // safety: code in pre_exec should be signal safe.
    // https://man7.org/linux/man-pages/man7/signal-safety.7.html
    #[cfg(not(target_os = "windows"))]
    unsafe {
        use std::os::unix::process::CommandExt;
        command.pre_exec(|| {
            libc::setsid();
            #[cfg(target_os = "macos")]
            crate::command::reset_exception_ports();
            Ok(())
        });
    };
    command
}

pub fn merge_json_lenient_value_into(
    source: serde_json_lenient::Value,
    target: &mut serde_json_lenient::Value,
) {
    match (source, target) {
        (serde_json_lenient::Value::Object(source), serde_json_lenient::Value::Object(target)) => {
            for (key, value) in source {
                if let Some(target) = target.get_mut(&key) {
                    merge_json_lenient_value_into(value, target);
                } else {
                    target.insert(key, value);
                }
            }
        }

        (serde_json_lenient::Value::Array(source), serde_json_lenient::Value::Array(target)) => {
            for value in source {
                target.push(value);
            }
        }

        (source, target) => *target = source,
    }
}

pub fn merge_json_value_into(source: serde_json::Value, target: &mut serde_json::Value) {
    use serde_json::Value;

    match (source, target) {
        (Value::Object(source), Value::Object(target)) => {
            for (key, value) in source {
                if let Some(target) = target.get_mut(&key) {
                    merge_json_value_into(value, target);
                } else {
                    target.insert(key, value);
                }
            }
        }

        (Value::Array(source), Value::Array(target)) => {
            for value in source {
                target.push(value);
            }
        }

        (source, target) => *target = source,
    }
}

pub fn merge_non_null_json_value_into(source: serde_json::Value, target: &mut serde_json::Value) {
    use serde_json::Value;
    if let Value::Object(source_object) = source {
        let target_object = if let Value::Object(target) = target {
            target
        } else {
            *target = Value::Object(Default::default());
            target.as_object_mut().unwrap()
        };
        for (key, value) in source_object {
            if let Some(target) = target_object.get_mut(&key) {
                merge_non_null_json_value_into(value, target);
            } else if !value.is_null() {
                target_object.insert(key, value);
            }
        }
    } else if !source.is_null() {
        *target = source
    }
}

pub fn measure<R>(label: &str, f: impl FnOnce() -> R) -> R {
    static ZED_MEASUREMENTS: OnceLock<bool> = OnceLock::new();
    let zed_measurements = ZED_MEASUREMENTS.get_or_init(|| {
        env::var("ZED_MEASUREMENTS")
            .map(|measurements| measurements == "1" || measurements == "true")
            .unwrap_or(false)
    });

    if *zed_measurements {
        let start = Instant::now();
        let result = f();
        let elapsed = start.elapsed();
        eprintln!("{}: {:?}", label, elapsed);
        result
    } else {
        f()
    }
}

pub fn expanded_and_wrapped_usize_range(
    range: Range<usize>,
    additional_before: usize,
    additional_after: usize,
    wrap_length: usize,
) -> impl Iterator<Item = usize> {
    let start_wraps = range.start < additional_before;
    let end_wraps = wrap_length < range.end + additional_after;
    if start_wraps && end_wraps {
        Either::Left(0..wrap_length)
    } else if start_wraps {
        let wrapped_start = (range.start + wrap_length).saturating_sub(additional_before);
        if wrapped_start <= range.end {
            Either::Left(0..wrap_length)
        } else {
            Either::Right((0..range.end + additional_after).chain(wrapped_start..wrap_length))
        }
    } else if end_wraps {
        let wrapped_end = range.end + additional_after - wrap_length;
        if range.start <= wrapped_end {
            Either::Left(0..wrap_length)
        } else {
            Either::Right((0..wrapped_end).chain(range.start - additional_before..wrap_length))
        }
    } else {
        Either::Left((range.start - additional_before)..(range.end + additional_after))
    }
}

/// Yields `[i, i + 1, i - 1, i + 2, ..]`, each modulo `wrap_length` and bounded by
/// `additional_before` and `additional_after`. If the wrapping causes overlap, duplicates are not
/// emitted. If wrap_length is 0, nothing is yielded.
pub fn wrapped_usize_outward_from(
    start: usize,
    additional_before: usize,
    additional_after: usize,
    wrap_length: usize,
) -> impl Iterator<Item = usize> {
    let mut count = 0;
    let mut after_offset = 1;
    let mut before_offset = 1;

    std::iter::from_fn(move || {
        count += 1;
        if count > wrap_length {
            None
        } else if count == 1 {
            Some(start % wrap_length)
        } else if after_offset <= additional_after && after_offset <= before_offset {
            let value = (start + after_offset) % wrap_length;
            after_offset += 1;
            Some(value)
        } else if before_offset <= additional_before {
            let value = (start + wrap_length - before_offset) % wrap_length;
            before_offset += 1;
            Some(value)
        } else if after_offset <= additional_after {
            let value = (start + after_offset) % wrap_length;
            after_offset += 1;
            Some(value)
        } else {
            None
        }
    })
}

pub trait ResultExt<E> {
    type Ok;

    fn log_err(self) -> Option<Self::Ok>;
    /// Assert that this result should never be an error in development or tests.
    fn debug_assert_ok(self, reason: &str) -> Self;
    fn warn_on_err(self) -> Option<Self::Ok>;
    fn log_with_level(self, level: log::Level) -> Option<Self::Ok>;
    fn anyhow(self) -> anyhow::Result<Self::Ok>
    where
        E: Into<anyhow::Error>;
}

impl<T, E> ResultExt<E> for Result<T, E>
where
    E: std::fmt::Debug,
{
    type Ok = T;

    #[track_caller]
    fn log_err(self) -> Option<T> {
        self.log_with_level(log::Level::Error)
    }

    #[track_caller]
    fn debug_assert_ok(self, reason: &str) -> Self {
        if let Err(error) = &self {
            debug_panic!("{reason} - {error:?}");
        }
        self
    }

    #[track_caller]
    fn warn_on_err(self) -> Option<T> {
        self.log_with_level(log::Level::Warn)
    }

    #[track_caller]
    fn log_with_level(self, level: log::Level) -> Option<T> {
        match self {
            Ok(value) => Some(value),
            Err(error) => {
                log_error_with_caller(*Location::caller(), error, level);
                None
            }
        }
    }

    fn anyhow(self) -> anyhow::Result<T>
    where
        E: Into<anyhow::Error>,
    {
        self.map_err(Into::into)
    }
}

fn log_error_with_caller<E>(caller: core::panic::Location<'_>, error: E, level: log::Level)
where
    E: std::fmt::Debug,
{
    #[cfg(not(target_os = "windows"))]
    let file = caller.file();
    #[cfg(target_os = "windows")]
    let file = caller.file().replace('\\', "/");
    // In this codebase all crates reside in a `crates` directory,
    // so discard the prefix up to that segment to find the crate name
    let file = file.split_once("crates/");
    let target = file.as_ref().and_then(|(_, s)| s.split_once("/src/"));

    let module_path = target.map(|(krate, module)| {
        if module.starts_with(krate) {
            module.trim_end_matches(".rs").replace('/', "::")
        } else {
            krate.to_owned() + "::" + &module.trim_end_matches(".rs").replace('/', "::")
        }
    });
    let file = file.map(|(_, file)| format!("crates/{file}"));
    log::logger().log(
        &log::Record::builder()
            .target(module_path.as_deref().unwrap_or(""))
            .module_path(file.as_deref())
            .args(format_args!("{:?}", error))
            .file(Some(caller.file()))
            .line(Some(caller.line()))
            .level(level)
            .build(),
    );
}

pub fn log_err<E: std::fmt::Debug>(error: &E) {
    log_error_with_caller(*Location::caller(), error, log::Level::Error);
}

pub trait TryFutureExt {
    fn log_err(self) -> LogErrorFuture<Self>
    where
        Self: Sized;

    fn log_tracked_err(self, location: core::panic::Location<'static>) -> LogErrorFuture<Self>
    where
        Self: Sized;

    fn warn_on_err(self) -> LogErrorFuture<Self>
    where
        Self: Sized;
    fn unwrap(self) -> UnwrapFuture<Self>
    where
        Self: Sized;
}

impl<F, T, E> TryFutureExt for F
where
    F: Future<Output = Result<T, E>>,
    E: std::fmt::Debug,
{
    #[track_caller]
    fn log_err(self) -> LogErrorFuture<Self>
    where
        Self: Sized,
    {
        let location = Location::caller();
        LogErrorFuture(self, log::Level::Error, *location)
    }

    fn log_tracked_err(self, location: core::panic::Location<'static>) -> LogErrorFuture<Self>
    where
        Self: Sized,
    {
        LogErrorFuture(self, log::Level::Error, location)
    }

    #[track_caller]
    fn warn_on_err(self) -> LogErrorFuture<Self>
    where
        Self: Sized,
    {
        let location = Location::caller();
        LogErrorFuture(self, log::Level::Warn, *location)
    }

    fn unwrap(self) -> UnwrapFuture<Self>
    where
        Self: Sized,
    {
        UnwrapFuture(self)
    }
}

#[must_use]
pub struct LogErrorFuture<F>(F, log::Level, core::panic::Location<'static>);

impl<F, T, E> Future for LogErrorFuture<F>
where
    F: Future<Output = Result<T, E>>,
    E: std::fmt::Debug,
{
    type Output = Option<T>;

    fn poll(self: Pin<&mut Self>, cx: &mut Context) -> Poll<Self::Output> {
        let level = self.1;
        let location = self.2;
        let inner = unsafe { Pin::new_unchecked(&mut self.get_unchecked_mut().0) };
        match inner.poll(cx) {
            Poll::Ready(output) => Poll::Ready(match output {
                Ok(output) => Some(output),
                Err(error) => {
                    log_error_with_caller(location, error, level);
                    None
                }
            }),
            Poll::Pending => Poll::Pending,
        }
    }
}

pub struct UnwrapFuture<F>(F);

impl<F, T, E> Future for UnwrapFuture<F>
where
    F: Future<Output = Result<T, E>>,
    E: std::fmt::Debug,
{
    type Output = T;

    fn poll(self: Pin<&mut Self>, cx: &mut Context) -> Poll<Self::Output> {
        let inner = unsafe { Pin::new_unchecked(&mut self.get_unchecked_mut().0) };
        match inner.poll(cx) {
            Poll::Ready(result) => Poll::Ready(result.unwrap()),
            Poll::Pending => Poll::Pending,
        }
    }
}

pub struct Deferred<F: FnOnce()>(Option<F>);

impl<F: FnOnce()> Deferred<F> {
    /// Drop without running the deferred function.
    pub fn abort(mut self) {
        self.0.take();
    }
}

impl<F: FnOnce()> Drop for Deferred<F> {
    fn drop(&mut self) {
        if let Some(f) = self.0.take() {
            f()
        }
    }
}

/// Run the given function when the returned value is dropped (unless it's cancelled).
#[must_use]
pub fn defer<F: FnOnce()>(f: F) -> Deferred<F> {
    Deferred(Some(f))
}

#[cfg(any(test, feature = "test-support"))]
mod rng {
    use rand::prelude::*;

    pub struct RandomCharIter<T: Rng> {
        rng: T,
        simple_text: bool,
    }

    impl<T: Rng> RandomCharIter<T> {
        pub fn new(rng: T) -> Self {
            Self {
                rng,
                simple_text: std::env::var("SIMPLE_TEXT").is_ok_and(|v| !v.is_empty()),
            }
        }

        pub fn with_simple_text(mut self) -> Self {
            self.simple_text = true;
            self
        }
    }

    impl<T: Rng> Iterator for RandomCharIter<T> {
        type Item = char;

        fn next(&mut self) -> Option<Self::Item> {
            if self.simple_text {
                return if self.rng.random_range(0..100) < 5 {
                    Some('\n')
                } else {
                    Some(self.rng.random_range(b'a'..b'z' + 1).into())
                };
            }

            match self.rng.random_range(0..100) {
                // whitespace
                0..=19 => [' ', '\n', '\r', '\t'].choose(&mut self.rng).copied(),
                // two-byte greek letters
                20..=32 => char::from_u32(self.rng.random_range(('α' as u32)..('ω' as u32 + 1))),
                // // three-byte characters
                33..=45 => ['✋', '✅', '❌', '❎', '⭐']
                    .choose(&mut self.rng)
                    .copied(),
                // // four-byte characters
                46..=58 => ['🍐', '🏀', '🍗', '🎉'].choose(&mut self.rng).copied(),
                // ascii letters
                _ => Some(self.rng.random_range(b'a'..b'z' + 1).into()),
            }
        }
    }
}
#[cfg(any(test, feature = "test-support"))]
pub use rng::RandomCharIter;

/// Get an embedded file as a string.
pub fn asset_str<A: rust_embed::RustEmbed>(path: &str) -> Cow<'static, str> {
    match A::get(path).expect(path).data {
        Cow::Borrowed(bytes) => Cow::Borrowed(std::str::from_utf8(bytes).unwrap()),
        Cow::Owned(bytes) => Cow::Owned(String::from_utf8(bytes).unwrap()),
    }
}

/// Expands to an immediately-invoked function expression. Good for using the ? operator
/// in functions which do not return an Option or Result.
///
/// Accepts a normal block, an async block, or an async move block.
#[macro_export]
macro_rules! maybe {
    ($block:block) => {
        (|| $block)()
    };
    (async $block:block) => {
        (async || $block)()
    };
    (async move $block:block) => {
        (async move || $block)()
    };
}

pub trait RangeExt<T> {
    fn sorted(&self) -> Self;
    fn to_inclusive(&self) -> RangeInclusive<T>;
    fn overlaps(&self, other: &Range<T>) -> bool;
    fn contains_inclusive(&self, other: &Range<T>) -> bool;
}

impl<T: Ord + Clone> RangeExt<T> for Range<T> {
    fn sorted(&self) -> Self {
        cmp::min(&self.start, &self.end).clone()..cmp::max(&self.start, &self.end).clone()
    }

    fn to_inclusive(&self) -> RangeInclusive<T> {
        self.start.clone()..=self.end.clone()
    }

    fn overlaps(&self, other: &Range<T>) -> bool {
        self.start < other.end && other.start < self.end
    }

    fn contains_inclusive(&self, other: &Range<T>) -> bool {
        self.start <= other.start && other.end <= self.end
    }
}

impl<T: Ord + Clone> RangeExt<T> for RangeInclusive<T> {
    fn sorted(&self) -> Self {
        cmp::min(self.start(), self.end()).clone()..=cmp::max(self.start(), self.end()).clone()
    }

    fn to_inclusive(&self) -> RangeInclusive<T> {
        self.clone()
    }

    fn overlaps(&self, other: &Range<T>) -> bool {
        self.start() < &other.end && &other.start <= self.end()
    }

    fn contains_inclusive(&self, other: &Range<T>) -> bool {
        self.start() <= &other.start && &other.end <= self.end()
    }
}

/// A way to sort strings with starting numbers numerically first, falling back to alphanumeric one,
/// case-insensitive.
///
/// This is useful for turning regular alphanumerically sorted sequences as `1-abc, 10, 11-def, .., 2, 21-abc`
/// into `1-abc, 2, 10, 11-def, .., 21-abc`
#[derive(Debug, PartialEq, Eq)]
pub struct NumericPrefixWithSuffix<'a>(Option<u64>, &'a str);

impl<'a> NumericPrefixWithSuffix<'a> {
    pub fn from_numeric_prefixed_str(str: &'a str) -> Self {
        let i = str.chars().take_while(|c| c.is_ascii_digit()).count();
        let (prefix, remainder) = str.split_at(i);

        let prefix = prefix.parse().ok();
        Self(prefix, remainder)
    }
}

/// When dealing with equality, we need to consider the case of the strings to achieve strict equality
/// to handle cases like "a" < "A" instead of "a" == "A".
impl Ord for NumericPrefixWithSuffix<'_> {
    fn cmp(&self, other: &Self) -> Ordering {
        match (self.0, other.0) {
            (None, None) => UniCase::new(self.1)
                .cmp(&UniCase::new(other.1))
                .then_with(|| self.1.cmp(other.1).reverse()),
            (None, Some(_)) => Ordering::Greater,
            (Some(_), None) => Ordering::Less,
            (Some(a), Some(b)) => a.cmp(&b).then_with(|| {
                UniCase::new(self.1)
                    .cmp(&UniCase::new(other.1))
                    .then_with(|| self.1.cmp(other.1).reverse())
            }),
        }
    }
}

impl PartialOrd for NumericPrefixWithSuffix<'_> {
    fn partial_cmp(&self, other: &Self) -> Option<Ordering> {
        Some(self.cmp(other))
    }
}

/// Capitalizes the first character of a string.
///
/// This function takes a string slice as input and returns a new `String` with the first character
/// capitalized.
///
/// # Examples
///
/// ```
/// use util::capitalize;
///
/// assert_eq!(capitalize("hello"), "Hello");
/// assert_eq!(capitalize("WORLD"), "WORLD");
/// assert_eq!(capitalize(""), "");
/// ```
pub fn capitalize(str: &str) -> String {
    let mut chars = str.chars();
    match chars.next() {
        None => String::new(),
        Some(first_char) => first_char.to_uppercase().collect::<String>() + chars.as_str(),
    }
}

fn emoji_regex() -> &'static Regex {
    static EMOJI_REGEX: LazyLock<Regex> =
        LazyLock::new(|| Regex::new("(\\p{Emoji}|\u{200D})").unwrap());
    &EMOJI_REGEX
}

/// Returns true if the given string consists of emojis only.
/// E.g. "👨‍👩‍👧‍👧👋" will return true, but "👋!" will return false.
pub fn word_consists_of_emojis(s: &str) -> bool {
    let mut prev_end = 0;
    for capture in emoji_regex().find_iter(s) {
        if capture.start() != prev_end {
            return false;
        }
        prev_end = capture.end();
    }
    prev_end == s.len()
}

/// Similar to `str::split`, but also provides byte-offset ranges of the results. Unlike
/// `str::split`, this is not generic on pattern types and does not return an `Iterator`.
pub fn split_str_with_ranges(s: &str, pat: impl Fn(char) -> bool) -> Vec<(Range<usize>, &str)> {
    let mut result = Vec::new();
    let mut start = 0;

    for (i, ch) in s.char_indices() {
        if pat(ch) {
            if i > start {
                result.push((start..i, &s[start..i]));
            }
            start = i + ch.len_utf8();
        }
    }

    if s.len() > start {
        result.push((start..s.len(), &s[start..s.len()]));
    }

    result
}

pub fn default<D: Default>() -> D {
    Default::default()
}

pub use self::shell::{
    get_default_system_shell, get_default_system_shell_preferring_bash, get_system_shell,
};

#[derive(Debug)]
pub enum ConnectionResult<O> {
    Timeout,
    ConnectionReset,
    Result(anyhow::Result<O>),
}

impl<O> ConnectionResult<O> {
    pub fn into_response(self) -> anyhow::Result<O> {
        match self {
            ConnectionResult::Timeout => anyhow::bail!("Request timed out"),
            ConnectionResult::ConnectionReset => anyhow::bail!("Server reset the connection"),
            ConnectionResult::Result(r) => r,
        }
    }
}

impl<O> From<anyhow::Result<O>> for ConnectionResult<O> {
    fn from(result: anyhow::Result<O>) -> Self {
        ConnectionResult::Result(result)
    }
}

#[track_caller]
pub fn some_or_debug_panic<T>(option: Option<T>) -> Option<T> {
    #[cfg(debug_assertions)]
    if option.is_none() {
        panic!("Unexpected None");
    }
    option
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn test_extend_sorted() {
        let mut vec = vec![];

        extend_sorted(&mut vec, vec![21, 17, 13, 8, 1, 0], 5, |a, b| b.cmp(a));
        assert_eq!(vec, &[21, 17, 13, 8, 1]);

        extend_sorted(&mut vec, vec![101, 19, 17, 8, 2], 8, |a, b| b.cmp(a));
        assert_eq!(vec, &[101, 21, 19, 17, 13, 8, 2, 1]);

        extend_sorted(&mut vec, vec![1000, 19, 17, 9, 5], 8, |a, b| b.cmp(a));
        assert_eq!(vec, &[1000, 101, 21, 19, 17, 13, 9, 8]);
    }

    #[test]
    fn test_truncate_to_bottom_n_sorted_by() {
        let mut vec: Vec<u32> = vec![5, 2, 3, 4, 1];
        truncate_to_bottom_n_sorted_by(&mut vec, 10, &u32::cmp);
        assert_eq!(vec, &[1, 2, 3, 4, 5]);

        vec = vec![5, 2, 3, 4, 1];
        truncate_to_bottom_n_sorted_by(&mut vec, 5, &u32::cmp);
        assert_eq!(vec, &[1, 2, 3, 4, 5]);

        vec = vec![5, 2, 3, 4, 1];
        truncate_to_bottom_n_sorted_by(&mut vec, 4, &u32::cmp);
        assert_eq!(vec, &[1, 2, 3, 4]);

        vec = vec![5, 2, 3, 4, 1];
        truncate_to_bottom_n_sorted_by(&mut vec, 1, &u32::cmp);
        assert_eq!(vec, &[1]);

        vec = vec![5, 2, 3, 4, 1];
        truncate_to_bottom_n_sorted_by(&mut vec, 0, &u32::cmp);
        assert!(vec.is_empty());
    }

    #[test]
    fn test_iife() {
        fn option_returning_function() -> Option<()> {
            None
        }

        let foo = maybe!({
            option_returning_function()?;
            Some(())
        });

        assert_eq!(foo, None);
    }

    #[test]
    fn test_truncate_and_trailoff() {
        assert_eq!(truncate_and_trailoff("", 5), "");
        assert_eq!(truncate_and_trailoff("aaaaaa", 7), "aaaaaa");
        assert_eq!(truncate_and_trailoff("aaaaaa", 6), "aaaaaa");
        assert_eq!(truncate_and_trailoff("aaaaaa", 5), "aaaaa…");
        assert_eq!(truncate_and_trailoff("èèèèèè", 7), "èèèèèè");
        assert_eq!(truncate_and_trailoff("èèèèèè", 6), "èèèèèè");
        assert_eq!(truncate_and_trailoff("èèèèèè", 5), "èèèèè…");
    }

    #[test]
    fn test_truncate_and_remove_front() {
        assert_eq!(truncate_and_remove_front("", 5), "");
        assert_eq!(truncate_and_remove_front("aaaaaa", 7), "aaaaaa");
        assert_eq!(truncate_and_remove_front("aaaaaa", 6), "aaaaaa");
        assert_eq!(truncate_and_remove_front("aaaaaa", 5), "…aaaaa");
        assert_eq!(truncate_and_remove_front("èèèèèè", 7), "èèèèèè");
        assert_eq!(truncate_and_remove_front("èèèèèè", 6), "èèèèèè");
        assert_eq!(truncate_and_remove_front("èèèèèè", 5), "…èèèèè");
    }

    #[test]
    fn test_numeric_prefix_str_method() {
        let target = "1a";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(1), "a")
        );

        let target = "12ab";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(12), "ab")
        );

        let target = "12_ab";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(12), "_ab")
        );

        let target = "1_2ab";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(1), "_2ab")
        );

        let target = "1.2";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(1), ".2")
        );

        let target = "1.2_a";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(1), ".2_a")
        );

        let target = "12.2_a";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(12), ".2_a")
        );

        let target = "12a.2_a";
        assert_eq!(
            NumericPrefixWithSuffix::from_numeric_prefixed_str(target),
            NumericPrefixWithSuffix(Some(12), "a.2_a")
        );
    }

    #[test]
    fn test_numeric_prefix_with_suffix() {
        let mut sorted = vec!["1-abc", "10", "11def", "2", "21-abc"];
        sorted.sort_by_key(|s| NumericPrefixWithSuffix::from_numeric_prefixed_str(s));
        assert_eq!(sorted, ["1-abc", "2", "10", "11def", "21-abc"]);

        for numeric_prefix_less in ["numeric_prefix_less", "aaa", "~™£"] {
            assert_eq!(
                NumericPrefixWithSuffix::from_numeric_prefixed_str(numeric_prefix_less),
                NumericPrefixWithSuffix(None, numeric_prefix_less),
                "String without numeric prefix `{numeric_prefix_less}` should not be converted into NumericPrefixWithSuffix"
            )
        }
    }

    #[test]
    fn test_word_consists_of_emojis() {
        let words_to_test = vec![
            ("👨‍👩‍👧‍👧👋🥒", true),
            ("👋", true),
            ("!👋", false),
            ("👋!", false),
            ("👋 ", false),
            (" 👋", false),
            ("Test", false),
        ];

        for (text, expected_result) in words_to_test {
            assert_eq!(word_consists_of_emojis(text), expected_result);
        }
    }

    #[test]
    fn test_truncate_lines_and_trailoff() {
        let text = r#"Line 1
Line 2
Line 3"#;

        assert_eq!(
            truncate_lines_and_trailoff(text, 2),
            r#"Line 1
…"#
        );

        assert_eq!(
            truncate_lines_and_trailoff(text, 3),
            r#"Line 1
Line 2
…"#
        );

        assert_eq!(
            truncate_lines_and_trailoff(text, 4),
            r#"Line 1
Line 2
Line 3"#
        );
    }

    #[test]
    fn test_expanded_and_wrapped_usize_range() {
        // Neither wrap
        assert_eq!(
            expanded_and_wrapped_usize_range(2..4, 1, 1, 8).collect::<Vec<usize>>(),
            (1..5).collect::<Vec<usize>>()
        );
        // Start wraps
        assert_eq!(
            expanded_and_wrapped_usize_range(2..4, 3, 1, 8).collect::<Vec<usize>>(),
            ((0..5).chain(7..8)).collect::<Vec<usize>>()
        );
        // Start wraps all the way around
        assert_eq!(
            expanded_and_wrapped_usize_range(2..4, 5, 1, 8).collect::<Vec<usize>>(),
            (0..8).collect::<Vec<usize>>()
        );
        // Start wraps all the way around and past 0
        assert_eq!(
            expanded_and_wrapped_usize_range(2..4, 10, 1, 8).collect::<Vec<usize>>(),
            (0..8).collect::<Vec<usize>>()
        );
        // End wraps
        assert_eq!(
            expanded_and_wrapped_usize_range(3..5, 1, 4, 8).collect::<Vec<usize>>(),
            (0..1).chain(2..8).collect::<Vec<usize>>()
        );
        // End wraps all the way around
        assert_eq!(
            expanded_and_wrapped_usize_range(3..5, 1, 5, 8).collect::<Vec<usize>>(),
            (0..8).collect::<Vec<usize>>()
        );
        // End wraps all the way around and past the end
        assert_eq!(
            expanded_and_wrapped_usize_range(3..5, 1, 10, 8).collect::<Vec<usize>>(),
            (0..8).collect::<Vec<usize>>()
        );
        // Both start and end wrap
        assert_eq!(
            expanded_and_wrapped_usize_range(3..5, 4, 4, 8).collect::<Vec<usize>>(),
            (0..8).collect::<Vec<usize>>()
        );
    }

    #[test]
    fn test_wrapped_usize_outward_from() {
        // No wrapping
        assert_eq!(
            wrapped_usize_outward_from(4, 2, 2, 10).collect::<Vec<usize>>(),
            vec![4, 5, 3, 6, 2]
        );
        // Wrapping at end
        assert_eq!(
            wrapped_usize_outward_from(8, 2, 3, 10).collect::<Vec<usize>>(),
            vec![8, 9, 7, 0, 6, 1]
        );
        // Wrapping at start
        assert_eq!(
            wrapped_usize_outward_from(1, 3, 2, 10).collect::<Vec<usize>>(),
            vec![1, 2, 0, 3, 9, 8]
        );
        // All values wrap around
        assert_eq!(
            wrapped_usize_outward_from(5, 10, 10, 8).collect::<Vec<usize>>(),
            vec![5, 6, 4, 7, 3, 0, 2, 1]
        );
        // None before / after
        assert_eq!(
            wrapped_usize_outward_from(3, 0, 0, 8).collect::<Vec<usize>>(),
            vec![3]
        );
        // Starting point already wrapped
        assert_eq!(
            wrapped_usize_outward_from(15, 2, 2, 10).collect::<Vec<usize>>(),
            vec![5, 6, 4, 7, 3]
        );
        // wrap_length of 0
        assert_eq!(
            wrapped_usize_outward_from(4, 2, 2, 0).collect::<Vec<usize>>(),
            Vec::<usize>::new()
        );
    }

    #[test]
    fn test_split_with_ranges() {
        let input = "hi";
        let result = split_str_with_ranges(input, |c| c == ' ');

        assert_eq!(result.len(), 1);
        assert_eq!(result[0], (0..2, "hi"));

        let input = "héllo🦀world";
        let result = split_str_with_ranges(input, |c| c == '🦀');

        assert_eq!(result.len(), 2);
        assert_eq!(result[0], (0..6, "héllo")); // 'é' is 2 bytes
        assert_eq!(result[1], (10..15, "world")); // '🦀' is 4 bytes
    }
}