// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use deno_core::error::AnyError; use deno_core::parking_lot::Mutex; use deno_terminal::colors; use once_cell::sync::Lazy; use std::fmt::Write; use std::io::BufRead; use std::io::IsTerminal; use std::io::StderrLock; use std::io::StdinLock; use std::io::Write as IoWrite; /// Helper function to make control characters visible so users can see the underlying filename. fn escape_control_characters(s: &str) -> std::borrow::Cow { if !s.contains(|c: char| c.is_ascii_control() || c.is_control()) { return std::borrow::Cow::Borrowed(s); } let mut output = String::with_capacity(s.len() * 2); for c in s.chars() { match c { c if c.is_ascii_control() => output.push_str( &colors::white_bold_on_red(c.escape_debug().to_string()).to_string(), ), c if c.is_control() => output.push_str( &colors::white_bold_on_red(c.escape_debug().to_string()).to_string(), ), c => output.push(c), } } output.into() } pub const PERMISSION_EMOJI: &str = "⚠️"; // 10kB of permission prompting should be enough for anyone const MAX_PERMISSION_PROMPT_LENGTH: usize = 10 * 1024; #[derive(Debug, Eq, PartialEq)] pub enum PromptResponse { Allow, Deny, AllowAll, } static PERMISSION_PROMPTER: Lazy>> = Lazy::new(|| Mutex::new(Box::new(TtyPrompter))); static MAYBE_BEFORE_PROMPT_CALLBACK: Lazy>> = Lazy::new(|| Mutex::new(None)); static MAYBE_AFTER_PROMPT_CALLBACK: Lazy>> = Lazy::new(|| Mutex::new(None)); pub fn permission_prompt( message: &str, flag: &str, api_name: Option<&str>, is_unary: bool, ) -> PromptResponse { if let Some(before_callback) = MAYBE_BEFORE_PROMPT_CALLBACK.lock().as_mut() { before_callback(); } let r = PERMISSION_PROMPTER .lock() .prompt(message, flag, api_name, is_unary); if let Some(after_callback) = MAYBE_AFTER_PROMPT_CALLBACK.lock().as_mut() { after_callback(); } r } pub fn set_prompt_callbacks( before_callback: PromptCallback, after_callback: PromptCallback, ) { *MAYBE_BEFORE_PROMPT_CALLBACK.lock() = Some(before_callback); *MAYBE_AFTER_PROMPT_CALLBACK.lock() = Some(after_callback); } pub type PromptCallback = Box; pub trait PermissionPrompter: Send + Sync { fn prompt( &mut self, message: &str, name: &str, api_name: Option<&str>, is_unary: bool, ) -> PromptResponse; } pub struct TtyPrompter; #[cfg(unix)] fn clear_stdin( _stdin_lock: &mut StdinLock, _stderr_lock: &mut StderrLock, ) -> Result<(), AnyError> { // TODO(bartlomieju): #[allow(clippy::undocumented_unsafe_blocks)] let r = unsafe { libc::tcflush(0, libc::TCIFLUSH) }; assert_eq!(r, 0); Ok(()) } #[cfg(not(unix))] fn clear_stdin( stdin_lock: &mut StdinLock, stderr_lock: &mut StderrLock, ) -> Result<(), AnyError> { use deno_core::anyhow::bail; use winapi::shared::minwindef::TRUE; use winapi::shared::minwindef::UINT; use winapi::shared::minwindef::WORD; use winapi::shared::ntdef::WCHAR; use winapi::um::processenv::GetStdHandle; use winapi::um::winbase::STD_INPUT_HANDLE; use winapi::um::wincon::FlushConsoleInputBuffer; use winapi::um::wincon::PeekConsoleInputW; use winapi::um::wincon::WriteConsoleInputW; use winapi::um::wincontypes::INPUT_RECORD; use winapi::um::wincontypes::KEY_EVENT; use winapi::um::winnt::HANDLE; use winapi::um::winuser::MapVirtualKeyW; use winapi::um::winuser::MAPVK_VK_TO_VSC; use winapi::um::winuser::VK_RETURN; // SAFETY: winapi calls unsafe { let stdin = GetStdHandle(STD_INPUT_HANDLE); // emulate an enter key press to clear any line buffered console characters emulate_enter_key_press(stdin)?; // read the buffered line or enter key press read_stdin_line(stdin_lock)?; // check if our emulated key press was executed if is_input_buffer_empty(stdin)? { // if so, move the cursor up to prevent a blank line move_cursor_up(stderr_lock)?; } else { // the emulated key press is still pending, so a buffered line was read // and we can flush the emulated key press flush_input_buffer(stdin)?; } } return Ok(()); unsafe fn flush_input_buffer(stdin: HANDLE) -> Result<(), AnyError> { let success = FlushConsoleInputBuffer(stdin); if success != TRUE { bail!( "Could not flush the console input buffer: {}", std::io::Error::last_os_error() ) } Ok(()) } unsafe fn emulate_enter_key_press(stdin: HANDLE) -> Result<(), AnyError> { // https://github.com/libuv/libuv/blob/a39009a5a9252a566ca0704d02df8dabc4ce328f/src/win/tty.c#L1121-L1131 let mut input_record: INPUT_RECORD = std::mem::zeroed(); input_record.EventType = KEY_EVENT; input_record.Event.KeyEvent_mut().bKeyDown = TRUE; input_record.Event.KeyEvent_mut().wRepeatCount = 1; input_record.Event.KeyEvent_mut().wVirtualKeyCode = VK_RETURN as WORD; input_record.Event.KeyEvent_mut().wVirtualScanCode = MapVirtualKeyW(VK_RETURN as UINT, MAPVK_VK_TO_VSC) as WORD; *input_record.Event.KeyEvent_mut().uChar.UnicodeChar_mut() = '\r' as WCHAR; let mut record_written = 0; let success = WriteConsoleInputW(stdin, &input_record, 1, &mut record_written); if success != TRUE { bail!( "Could not emulate enter key press: {}", std::io::Error::last_os_error() ); } Ok(()) } unsafe fn is_input_buffer_empty(stdin: HANDLE) -> Result { let mut buffer = Vec::with_capacity(1); let mut events_read = 0; let success = PeekConsoleInputW(stdin, buffer.as_mut_ptr(), 1, &mut events_read); if success != TRUE { bail!( "Could not peek the console input buffer: {}", std::io::Error::last_os_error() ) } Ok(events_read == 0) } fn move_cursor_up(stderr_lock: &mut StderrLock) -> Result<(), AnyError> { write!(stderr_lock, "\x1B[1A")?; Ok(()) } fn read_stdin_line(stdin_lock: &mut StdinLock) -> Result<(), AnyError> { let mut input = String::new(); stdin_lock.read_line(&mut input)?; Ok(()) } } // Clear n-lines in terminal and move cursor to the beginning of the line. fn clear_n_lines(stderr_lock: &mut StderrLock, n: usize) { write!(stderr_lock, "\x1B[{n}A\x1B[0J").unwrap(); } #[cfg(unix)] fn get_stdin_metadata() -> std::io::Result { use std::os::fd::FromRawFd; use std::os::fd::IntoRawFd; // SAFETY: we don't know if fd 0 is valid but metadata() will return an error in this case (bad file descriptor) // and we can panic. unsafe { let stdin = std::fs::File::from_raw_fd(0); let metadata = stdin.metadata().unwrap(); stdin.into_raw_fd(); Ok(metadata) } } impl PermissionPrompter for TtyPrompter { fn prompt( &mut self, message: &str, name: &str, api_name: Option<&str>, is_unary: bool, ) -> PromptResponse { if !std::io::stdin().is_terminal() || !std::io::stderr().is_terminal() { return PromptResponse::Deny; }; if message.len() > MAX_PERMISSION_PROMPT_LENGTH { eprintln!("❌ Permission prompt length ({} bytes) was larger than the configured maximum length ({} bytes): denying request.", message.len(), MAX_PERMISSION_PROMPT_LENGTH); eprintln!("❌ WARNING: This may indicate that code is trying to bypass or hide permission check requests."); eprintln!("❌ Run again with --allow-{name} to bypass this check if this is really what you want to do."); return PromptResponse::Deny; } #[cfg(unix)] let metadata_before = get_stdin_metadata().unwrap(); // Lock stdio streams, so no other output is written while the prompt is // displayed. let stdout_lock = std::io::stdout().lock(); let mut stderr_lock = std::io::stderr().lock(); let mut stdin_lock = std::io::stdin().lock(); // For security reasons we must consume everything in stdin so that previously // buffered data cannot affect the prompt. if let Err(err) = clear_stdin(&mut stdin_lock, &mut stderr_lock) { eprintln!("Error clearing stdin for permission prompt. {err:#}"); return PromptResponse::Deny; // don't grant permission if this fails } let message = escape_control_characters(message); let name = escape_control_characters(name); let api_name = api_name.map(escape_control_characters); // print to stderr so that if stdout is piped this is still displayed. let opts: String = if is_unary { format!("[y/n/A] (y = yes, allow; n = no, deny; A = allow all {name} permissions)") } else { "[y/n] (y = yes, allow; n = no, deny)".to_string() }; // output everything in one shot to make the tests more reliable { let mut output = String::new(); write!(&mut output, "┌ {PERMISSION_EMOJI} ").unwrap(); write!(&mut output, "{}", colors::bold("Deno requests ")).unwrap(); write!(&mut output, "{}", colors::bold(message.clone())).unwrap(); writeln!(&mut output, "{}", colors::bold(".")).unwrap(); if let Some(api_name) = api_name.clone() { writeln!(&mut output, "├ Requested by `{api_name}` API.").unwrap(); } let msg = format!("Run again with --allow-{name} to bypass this prompt."); writeln!(&mut output, "├ {}", colors::italic(&msg)).unwrap(); write!(&mut output, "└ {}", colors::bold("Allow?")).unwrap(); write!(&mut output, " {opts} > ").unwrap(); stderr_lock.write_all(output.as_bytes()).unwrap(); } let value = loop { let mut input = String::new(); let result = stdin_lock.read_line(&mut input); if result.is_err() { break PromptResponse::Deny; }; let ch = match input.chars().next() { None => break PromptResponse::Deny, Some(v) => v, }; match ch { 'y' | 'Y' => { clear_n_lines( &mut stderr_lock, if api_name.is_some() { 4 } else { 3 }, ); let msg = format!("Granted {message}."); writeln!(stderr_lock, "✅ {}", colors::bold(&msg)).unwrap(); break PromptResponse::Allow; } 'n' | 'N' => { clear_n_lines( &mut stderr_lock, if api_name.is_some() { 4 } else { 3 }, ); let msg = format!("Denied {message}."); writeln!(stderr_lock, "❌ {}", colors::bold(&msg)).unwrap(); break PromptResponse::Deny; } 'A' if is_unary => { clear_n_lines( &mut stderr_lock, if api_name.is_some() { 4 } else { 3 }, ); let msg = format!("Granted all {name} access."); writeln!(stderr_lock, "✅ {}", colors::bold(&msg)).unwrap(); break PromptResponse::AllowAll; } _ => { // If we don't get a recognized option try again. clear_n_lines(&mut stderr_lock, 1); write!( stderr_lock, "└ {} {opts} > ", colors::bold("Unrecognized option. Allow?") ) .unwrap(); } }; }; drop(stdout_lock); drop(stderr_lock); drop(stdin_lock); // Ensure that stdin has not changed from the beginning to the end of the prompt. We consider // it sufficient to check a subset of stat calls. We do not consider the likelihood of a stdin // swap attack on Windows to be high enough to add this check for that platform. These checks will // terminate the runtime as they indicate something nefarious is going on. #[cfg(unix)] { use std::os::unix::fs::MetadataExt; let metadata_after = get_stdin_metadata().unwrap(); assert_eq!(metadata_before.dev(), metadata_after.dev()); assert_eq!(metadata_before.ino(), metadata_after.ino()); assert_eq!(metadata_before.rdev(), metadata_after.rdev()); assert_eq!(metadata_before.uid(), metadata_after.uid()); assert_eq!(metadata_before.gid(), metadata_after.gid()); assert_eq!(metadata_before.mode(), metadata_after.mode()); } // Ensure that stdin and stderr are still terminals before we yield the response. assert!(std::io::stdin().is_terminal() && std::io::stderr().is_terminal()); value } } #[cfg(test)] pub mod tests { use super::*; use std::sync::atomic::AtomicBool; use std::sync::atomic::Ordering; pub struct TestPrompter; impl PermissionPrompter for TestPrompter { fn prompt( &mut self, _message: &str, _name: &str, _api_name: Option<&str>, _is_unary: bool, ) -> PromptResponse { if STUB_PROMPT_VALUE.load(Ordering::SeqCst) { PromptResponse::Allow } else { PromptResponse::Deny } } } static STUB_PROMPT_VALUE: AtomicBool = AtomicBool::new(true); pub static PERMISSION_PROMPT_STUB_VALUE_SETTER: Lazy< Mutex, > = Lazy::new(|| Mutex::new(PermissionPromptStubValueSetter)); pub struct PermissionPromptStubValueSetter; impl PermissionPromptStubValueSetter { pub fn set(&self, value: bool) { STUB_PROMPT_VALUE.store(value, Ordering::SeqCst); } } pub fn set_prompter(prompter: Box) { *PERMISSION_PROMPTER.lock() = prompter; } }