sail/exec.rs
1//! Streaming exec engine: a running command in a sailbox with live output.
2//!
3//! [`ExecProcess::start`] opens a server-streaming exec request. The first frame
4//! reports that the command has started (carrying the durable
5//! `exec_request_id`); chunk frames carry live stdout/stderr; a terminal frame
6//! carries the result. The command is detached on the server, so dropping the
7//! handle never kills it.
8//!
9//! A background pump task drains the stream into two drop-oldest ring buffers
10//! that synchronous readers ([`StreamReader`]) pull from. If the stream breaks
11//! mid-run, the pump reconnects with the same idempotency key and the per-stream
12//! seqs it last saw, so the guest replays only the unseen tail. Only when the
13//! stream cannot be resumed does [`ExecProcess::wait`] fall back to fetching the
14//! authoritative buffered result. Stdin rides a separate offset-idempotent unary
15//! request, independent of the output stream.
16
17use std::collections::VecDeque;
18use std::sync::atomic::{AtomicBool, Ordering};
19use std::sync::{Arc, Condvar, Mutex};
20use std::time::Duration;
21
22use serde::Serialize;
23use tokio::sync::Mutex as AsyncMutex;
24use tokio::sync::Notify;
25use tonic::{Code, Status, Streaming};
26
27use crate::error::SailError;
28use crate::pb::workerproxy::v1 as pb;
29use crate::worker::{
30 retry_deadline, rpc_attempt_timeout, should_invalidate_channel,
31 should_retry_transient_exec_rpc, sleep_before_retry, WorkerProxy,
32 EXEC_TRANSIENT_RETRY_INITIAL_DELAY_SECONDS,
33};
34
35/// Default budget for transient-RPC retries against a waking/migrating sailbox;
36/// the default value of [`ExecOptions::retry_timeout`].
37#[doc(hidden)]
38pub const EXEC_TRANSIENT_RETRY_TIMEOUT_SECONDS: f64 = 30.0;
39/// Local cap on buffered stream output: a slow reader loses the oldest output
40/// rather than blocking the stream. Sized to the server's in-memory exec
41/// replay ring so a locally resolved tail is the same size the server replays
42/// on a reattach. A backend test keeps this in lockstep with the ring
43/// (`guestExecChunkBufferBytes`); change both together.
44const STREAM_BUFFER_CAP_BYTES: usize = 1024 * 1024;
45/// Stdin writes are chunked so a single RPC stays well under gRPC message limits
46/// and partial accepts resume cheaply.
47const STDIN_WRITE_CHUNK_BYTES: usize = 256 * 1024;
48
49/// Lock a mutex, recovering the guard if a peer panicked while holding it
50/// (matching `channels.rs`). The data under these locks is simple, so a poisoned
51/// peer should degrade rather than cascade a panic into reader/pump threads.
52fn lock<T>(mutex: &Mutex<T>) -> std::sync::MutexGuard<'_, T> {
53 mutex
54 .lock()
55 .unwrap_or_else(std::sync::PoisonError::into_inner)
56}
57
58/// Which output stream a chunk or reader belongs to.
59#[derive(Debug, Clone, Copy, PartialEq, Eq)]
60pub enum OutputStream {
61 /// The standard output stream.
62 Stdout,
63 /// The standard error stream.
64 Stderr,
65}
66
67/// One step of reading a live output stream.
68#[derive(Debug, Clone, PartialEq, Eq)]
69pub enum ReadStep {
70 /// The next retained chunk of output, exactly as the command wrote it: the
71 /// live stream is a byte pipe (escape sequences and binary payloads
72 /// included), not decoded text. String-typed conveniences decode at the
73 /// edge ([`ExecResult`], the bindings' str iterators).
74 Chunk(Vec<u8>),
75 /// The stream is closed and fully drained.
76 Eof,
77 /// Nothing new before the timeout; the caller may check for signals and
78 /// retry.
79 Pending,
80}
81
82/// The buffered result of a finished exec.
83#[derive(Debug, Clone, Serialize)]
84#[non_exhaustive]
85#[allow(clippy::struct_excessive_bools)]
86pub struct ExecResult {
87 /// Buffered stdout, lossily decoded as UTF-8 (the live byte stream is
88 /// unmodified; the decode happens only here). For a pty exec that was
89 /// reattached, this is the last screen repaint plus the output after it,
90 /// not a full transcript.
91 pub stdout: String,
92 /// Buffered stderr, lossily decoded as UTF-8 (see `stdout`).
93 pub stderr: String,
94 /// The command's exit code.
95 pub exit_code: i32,
96 /// Whether the command was killed for exceeding its timeout.
97 pub timed_out: bool,
98 /// Whether stdout overflowed the server output ring and lost its oldest
99 /// bytes.
100 pub stdout_truncated: bool,
101 /// Whether stderr overflowed the server output ring and lost its oldest
102 /// bytes.
103 pub stderr_truncated: bool,
104 /// Whether the live stream delivered stdout through to the command's exit.
105 /// When true, a consumer that streamed the output live already holds the
106 /// complete stdout even if `stdout` here is a truncated buffered tail. When
107 /// false (the stream ended before the exit, or no exit was observed),
108 /// `stdout` is the authoritative buffered copy to fall back on.
109 pub stdout_complete: bool,
110 /// Whether the live stream delivered stderr through to the command's exit
111 /// (see `stdout_complete`).
112 pub stderr_complete: bool,
113 /// Total bytes the command wrote to stdout over its whole run, including
114 /// bytes truncation dropped from the buffered `stdout` field above. `0` when
115 /// unknown (no exit was observed on the stream, or an older guest). Subtract
116 /// what a consumer actually saw to learn how much was lost.
117 pub stdout_total_bytes: i64,
118 /// Total bytes the command wrote to stderr over its whole run (see
119 /// `stdout_total_bytes`).
120 pub stderr_total_bytes: i64,
121}
122
123/// Which signal to send when cancelling a running exec.
124#[derive(Debug, Clone, Copy, PartialEq, Eq)]
125pub enum CancelSignal {
126 /// SIGINT: ask the command to stop (what a first Ctrl-C sends).
127 Interrupt,
128 /// SIGKILL: force-kill a command that ignored the interrupt.
129 Kill,
130}
131
132impl CancelSignal {
133 /// Whether this is the forceful (SIGKILL) variant, as the wire encodes it.
134 fn is_force(self) -> bool {
135 matches!(self, CancelSignal::Kill)
136 }
137}
138
139/// How long to keep retrying transient RPCs against a waking or migrating
140/// sailbox before giving up.
141#[derive(Debug, Clone, Copy, PartialEq)]
142pub enum RetryBudget {
143 /// Do not retry; fail on the first transient error.
144 None,
145 /// Retry for at most this long.
146 Within(Duration),
147 /// Retry indefinitely, until the call succeeds or hits a non-transient error.
148 Forever,
149}
150
151impl RetryBudget {
152 /// Encode as the seconds the core's retry loop expects: `0` = none, a finite
153 /// count = a bounded budget, `+inf` = forever.
154 #[doc(hidden)]
155 pub fn as_secs_f64(self) -> f64 {
156 match self {
157 RetryBudget::None => 0.0,
158 RetryBudget::Within(d) => d.as_secs_f64(),
159 RetryBudget::Forever => f64::INFINITY,
160 }
161 }
162
163 /// Decode from seconds at the FFI boundary (Python passes an `f64`): `<= 0` =
164 /// none, a non-finite value = forever, otherwise a bounded budget.
165 #[doc(hidden)]
166 pub fn from_secs_f64(secs: f64) -> RetryBudget {
167 if secs <= 0.0 {
168 RetryBudget::None
169 } else if secs.is_finite() {
170 RetryBudget::Within(Duration::from_secs_f64(secs))
171 } else {
172 RetryBudget::Forever
173 }
174 }
175}
176
177/// Optional settings for [`Sailbox::exec`](crate::Sailbox::exec) and
178/// [`Sailbox::exec_shell`](crate::Sailbox::exec_shell). `Default` runs a
179/// plain foreground command (no pty, no stdin, no timeout) and retries transient
180/// failures against a waking or migrating sailbox for 30 seconds (see
181/// [`retry_timeout`](Self::retry_timeout)).
182#[derive(Debug, Clone)]
183#[allow(clippy::struct_excessive_bools)]
184pub struct ExecOptions {
185 /// Wall-clock limit before the server kills the command; `None` means no
186 /// limit. The wire is whole seconds, so a set sub-second timeout rounds up
187 /// to 1 second (it never collapses to the no-limit `0`).
188 pub timeout: Option<Duration>,
189 /// Leave the command's stdin open for [`ExecProcess::write_stdin`].
190 pub open_stdin: bool,
191 /// Allocate a pseudo-terminal for the command.
192 pub pty: bool,
193 /// TERM value for the pty (e.g. `xterm-256color`); ignored without `pty`.
194 pub term: String,
195 /// Initial pty width in columns; ignored without `pty`.
196 pub cols: u32,
197 /// Initial pty height in rows; ignored without `pty`.
198 pub rows: u32,
199 /// Extra environment for the command, applied for pty and non-pty execs
200 /// alike. Entries override the guest's defaults (including `LANG`) and the
201 /// image env. A few reserved variables that identify the sailbox (such as
202 /// `SAILBOX_ID`) cannot be overridden. For pty execs the terminal variables
203 /// (`COLORTERM`, `LANG`, `LC_*`, `TERM_PROGRAM`) are auto-forwarded from the
204 /// local environment for keys not set here.
205 pub env: Vec<(String, String)>,
206 /// Stable key that dedupes the launch so a reconnect reattaches to the same
207 /// command. Empty mints a fresh one per call.
208 pub idempotency_key: String,
209 /// Budget for retrying transient RPC failures against a waking or migrating
210 /// sailbox: both while opening the stream and when [`ExecProcess::wait`]
211 /// falls back to `WaitSailboxExec`, which reattaches to the guest for the
212 /// result.
213 pub retry_timeout: RetryBudget,
214 /// Working directory to run a shell command in. Only valid with
215 /// [`Sailbox::exec_shell`](crate::Sailbox::exec_shell).
216 pub cwd: Option<String>,
217 /// Detach a shell command so it keeps running and the call returns
218 /// immediately; output is discarded. Only valid with
219 /// [`Sailbox::exec_shell`](crate::Sailbox::exec_shell), and incompatible with
220 /// `open_stdin` and `pty`.
221 pub background: bool,
222 /// Forward the command's localhost servers to the user's machine. Set by the
223 /// interactive shell; off for ordinary execs.
224 pub forward_ports: bool,
225 /// Forward the command's browser opens to the user's machine. Set by the
226 /// interactive shell; off for ordinary execs.
227 pub forward_browser: bool,
228}
229
230impl Default for ExecOptions {
231 fn default() -> ExecOptions {
232 ExecOptions {
233 timeout: None,
234 open_stdin: false,
235 pty: false,
236 term: String::new(),
237 cols: 0,
238 rows: 0,
239 env: Vec::new(),
240 idempotency_key: String::new(),
241 retry_timeout: RetryBudget::Within(Duration::from_secs_f64(
242 EXEC_TRANSIENT_RETRY_TIMEOUT_SECONDS,
243 )),
244 cwd: None,
245 background: false,
246 forward_ports: false,
247 forward_browser: false,
248 }
249 }
250}
251
252/// Derive the exec forwarding flags from an interactive session's opt-out flags,
253/// returning `(forward_ports, forward_browser)`. `no_forward` turns off both
254/// localhost-server and browser-open forwarding; `no_forward_browser` turns off
255/// only browser opens. Browser forwarding always implies port forwarding — a
256/// login's OAuth callback is itself a forwarded localhost server — so it is gated
257/// on both opt-outs.
258pub fn forward_flags(no_forward: bool, no_forward_browser: bool) -> (bool, bool) {
259 let forward_ports = !no_forward;
260 let forward_browser = forward_ports && !no_forward_browser;
261 (forward_ports, forward_browser)
262}
263
264/// POSIX single-quote a string for safe inclusion in a shell command.
265pub(crate) fn sh_quote(value: &str) -> String {
266 format!("'{}'", value.replace('\'', "'\\''"))
267}
268
269/// Local env vars auto-forwarded to pty execs so terminal programs render
270/// correctly (truecolor detection, locale-driven width math). TERM rides the
271/// dedicated `term` field, not this list.
272const PTY_ENV_WHITELIST: [&str; 3] = ["COLORTERM", "LANG", "TERM_PROGRAM"];
273
274fn pty_env_whitelisted(key: &str) -> bool {
275 PTY_ENV_WHITELIST.contains(&key) || key.starts_with("LC_")
276}
277
278/// Snapshot the local environment filtered to the pty forwarding whitelist.
279pub(crate) fn pty_forward_env() -> Vec<(String, String)> {
280 // vars_os, not vars: std::env::vars panics on any non-Unicode entry in the
281 // inherited environment, even one unrelated to the whitelist. Entries that
282 // do not decode cannot ride a proto string map anyway, so they are skipped.
283 pty_forward_env_from(
284 std::env::vars_os()
285 .filter_map(|(key, value)| Some((key.into_string().ok()?, value.into_string().ok()?))),
286 )
287}
288
289fn pty_forward_env_from(vars: impl Iterator<Item = (String, String)>) -> Vec<(String, String)> {
290 vars.filter(|(key, _)| pty_env_whitelisted(key)).collect()
291}
292
293/// Validate user-supplied env pairs into the wire map. Values are free-form;
294/// keys must be non-empty and free of `=` and NUL (execve constraints). Every
295/// binding's user env funnels through here (the Rust client and the bindings
296/// that build `ExecParams` directly), so a key like `"A=B"` fails loudly
297/// instead of silently becoming a different variable in the guest.
298#[doc(hidden)]
299pub fn encode_env(
300 pairs: &[(String, String)],
301) -> Result<std::collections::HashMap<String, String>, SailError> {
302 let mut env = std::collections::HashMap::with_capacity(pairs.len());
303 for (key, value) in pairs {
304 // The name must be a portable identifier and the value must carry no NUL
305 // (execve cannot represent either). is_portable_env_name already rejects
306 // '=', whitespace, and NUL in the name, so only the value needs a guard.
307 if !is_portable_env_name(key) || value.contains('\0') {
308 return Err(SailError::InvalidArgument {
309 message: format!("invalid env entry {key:?}"),
310 });
311 }
312 env.insert(key.clone(), value.clone());
313 }
314 Ok(env)
315}
316
317/// Whether `name` is a portable environment variable name: a non-empty run of
318/// `[A-Za-z_][A-Za-z0-9_]*`. Rejects a leading digit, whitespace, `=`, a NUL, or
319/// any other character the guest could not represent (or a shell could not read
320/// back) as an environment entry.
321fn is_portable_env_name(name: &str) -> bool {
322 let mut chars = name.chars();
323 match chars.next() {
324 Some(c) if c.is_ascii_alphabetic() || c == '_' => {}
325 _ => return false,
326 }
327 chars.all(|c| c.is_ascii_alphanumeric() || c == '_')
328}
329
330/// Build the `argv` that runs `command` via `/bin/sh -lc`, applying the
331/// `cwd`/`background` shell conveniences from `options` and validating their
332/// combinations. This is the single implementation behind every SDK's
333/// string-command exec.
334#[doc(hidden)]
335pub fn shell_argv(command: &str, options: &ExecOptions) -> Result<Vec<String>, SailError> {
336 let invalid = |message: &str| {
337 Err(SailError::InvalidArgument {
338 message: message.to_string(),
339 })
340 };
341 if command.is_empty() {
342 return invalid("command must be non-empty");
343 }
344 if options.background && (options.open_stdin || options.pty) {
345 return invalid("background is not supported with open_stdin or pty");
346 }
347 let mut command = command.to_string();
348 if let Some(cwd) = &options.cwd {
349 let cwd = cwd.trim();
350 if cwd.is_empty() {
351 return invalid("cwd must be non-empty");
352 }
353 command = format!(
354 "cd {} && exec /bin/sh -lc {}",
355 sh_quote(cwd),
356 sh_quote(&command)
357 );
358 }
359 if options.background {
360 command = format!(
361 "nohup /bin/sh -lc {} </dev/null >/dev/null 2>&1 &",
362 sh_quote(&command)
363 );
364 }
365 Ok(vec!["/bin/sh".to_string(), "-lc".to_string(), command])
366}
367
368/// Parameters captured at launch and reused on every reconnect.
369#[doc(hidden)]
370#[derive(Debug, Clone)]
371#[allow(clippy::struct_excessive_bools)]
372pub struct ExecParams {
373 /// The sailbox the command runs in.
374 pub sailbox_id: String,
375 /// Worker-proxy endpoint that terminates the exec RPCs for this sailbox.
376 pub exec_endpoint: String,
377 /// The command and its arguments.
378 pub argv: Vec<String>,
379 /// Wall-clock limit in seconds before the server kills the command; 0 means
380 /// no limit.
381 pub timeout_seconds: u32,
382 /// Stable key that dedupes the launch and identifies the stream so a
383 /// reconnect reattaches to the same command rather than starting a new one.
384 pub idempotency_key: String,
385 /// Whether the command's stdin is left open for writes.
386 pub open_stdin: bool,
387 /// Whether to allocate a pseudo-terminal for the command.
388 pub pty: bool,
389 /// TERM value for the pty (e.g. `xterm-256color`); empty when not a pty.
390 pub term: String,
391 /// Initial pty width in columns.
392 pub cols: u32,
393 /// Initial pty height in rows.
394 pub rows: u32,
395 /// Extra environment for the command as wire-ready KEY=VALUE entries,
396 /// resolved once at launch (including the pty terminal whitelist) and
397 /// resent verbatim on every reconnect.
398 pub env: std::collections::HashMap<String, String>,
399 /// Budget in seconds for retrying transient failures while opening or
400 /// resuming the stream.
401 pub retry_timeout: f64,
402 /// Forward the command's localhost servers to the user's machine. Set by the
403 /// interactive shell.
404 pub forward_ports: bool,
405 /// Forward the command's browser opens to the user's machine. Set by the
406 /// interactive shell.
407 pub forward_browser: bool,
408 /// Tracing metadata the wrapper injects (e.g. Voyages); opaque to the core.
409 pub extra_metadata: Vec<(String, String)>,
410}
411
412/// Drop-oldest byte ring mirroring the server output ring. Appends never
413/// block; past the cap the oldest bytes are dropped (byte-exact) and `dropped`
414/// latches. Pieces carry absolute indices so a reader that falls behind skips
415/// the dropped head instead of stalling.
416#[derive(Default)]
417struct Ring {
418 pieces: Vec<Vec<u8>>,
419 first_idx: usize,
420 size: usize,
421 dropped: bool,
422 /// Monotonic count of in-place front-piece clips. A clip drops bytes from
423 /// the piece at `first_idx` without advancing it, so a reader parked on
424 /// that piece cannot see the loss through `first_idx` alone; it compares
425 /// this instead.
426 front_clips: u64,
427 /// Monotonic count of `reset_to` repaints. A repaint advances `first_idx`
428 /// past a reader's cursor like an eviction, but it supersedes those bytes
429 /// with a fresh screen instead of losing them, so a reader compares this to
430 /// tell a heal from a fall-behind drop.
431 resets: u64,
432}
433
434impl Ring {
435 fn append(&mut self, data: Vec<u8>) {
436 self.size += data.len();
437 self.pieces.push(data);
438 while self.size > STREAM_BUFFER_CAP_BYTES {
439 let overflow = self.size - STREAM_BUFFER_CAP_BYTES;
440 if self.pieces[0].len() <= overflow {
441 self.size -= self.pieces[0].len();
442 self.pieces.remove(0);
443 self.first_idx += 1;
444 } else {
445 self.pieces[0].drain(..overflow);
446 self.size -= overflow;
447 self.front_clips += 1;
448 }
449 self.dropped = true;
450 }
451 }
452
453 /// Replace the retained content with a pty screen repaint. Advancing
454 /// `first_idx` past the old pieces makes every attached reader (cursor
455 /// below it) skip straight to the repaint, and a late reader replays only
456 /// the repaint. `dropped` is cleared: the repaint supersedes everything
457 /// the ring ever dropped, so a healed session must not read as truncated
458 /// (which would force `wait()` into the server fallback). `append`
459 /// re-latches it only if the repaint itself overflows.
460 fn reset_to(&mut self, repaint: Vec<u8>) {
461 self.first_idx += self.pieces.len();
462 self.pieces.clear();
463 self.size = 0;
464 self.dropped = false;
465 self.resets += 1;
466 if !repaint.is_empty() {
467 self.append(repaint);
468 }
469 }
470
471 fn tail(&self) -> Vec<u8> {
472 self.pieces.concat()
473 }
474}
475
476/// Lossily decode a ring's retained bytes for the string-typed [`ExecResult`].
477/// The only place live output becomes text in the core. NUL is replaced too:
478/// it is valid UTF-8 that `from_utf8_lossy` keeps, but the text result is the
479/// client twin of the guest's persisted tail (which replaces NUL with U+FFFD
480/// for its Postgres text column), so the two agree. The raw byte readers keep NUL.
481fn lossy_tail(ring: &Ring) -> String {
482 String::from_utf8_lossy(&ring.tail()).replace('\0', "\u{FFFD}")
483}
484
485#[derive(Default)]
486struct State {
487 stdout: Ring,
488 stderr: Ring,
489 ended: bool,
490}
491
492impl State {
493 fn ring(&self, which: OutputStream) -> &Ring {
494 match which {
495 OutputStream::Stdout => &self.stdout,
496 OutputStream::Stderr => &self.stderr,
497 }
498 }
499}
500
501/// Terminal exec result captured from the Exit frame or a poll.
502#[derive(Clone)]
503struct ExitInfo {
504 status: i32,
505 exit_code: i32,
506 timed_out: bool,
507 stdout_truncated: bool,
508 stderr_truncated: bool,
509 error_message: String,
510 stdout_seq: i64,
511 stderr_seq: i64,
512 stdout_total_bytes: i64,
513 stderr_total_bytes: i64,
514}
515
516#[derive(Default)]
517struct StdinState {
518 offset: i64,
519 eof_sent: bool,
520 broken: bool,
521 /// Set under the lock for the duration of a data write, which holds the lock
522 /// across its network send. A clean return clears it; a write whose future
523 /// is dropped mid-send (the caller cancelled it) releases the lock with this
524 /// still set, so the next writer observes it and poisons rather than
525 /// resuming from a stale offset. This is the cancellation latch: it lives in
526 /// the same lock that serializes writes, so no later write can race ahead of
527 /// it.
528 write_in_flight: bool,
529}
530
531/// A local-forwarding request the guest sends for an interactive session,
532/// consumed by the shell driver to act on the user's machine.
533#[derive(Debug, Clone)]
534pub enum ForwardEvent {
535 /// Open this URL in the user's local browser.
536 OpenUrl(String),
537 /// The current set of localhost servers in the sandbox. The client forwards
538 /// these and drops forwards for any no longer listed.
539 PortSnapshot(Vec<u16>),
540}
541
542struct ExecShared {
543 worker: Arc<WorkerProxy>,
544 params: ExecParams,
545 state: Mutex<State>,
546 /// Local-forwarding events for an interactive session (browser opens and
547 /// localhost-server snapshots), queued by the pump and drained by the shell
548 /// driver.
549 forward_events: Mutex<VecDeque<ForwardEvent>>,
550 forward_notify: Notify,
551 /// Wakes synchronous readers/waiters when output is appended or the stream
552 /// ends.
553 cond: Condvar,
554 /// The async counterpart of `cond`: wakes [`AsyncStreamReader`]s without
555 /// parking a runtime thread. Notified on every append and at end of stream.
556 data_notify: Notify,
557 exit: Mutex<Option<ExitInfo>>,
558 /// Highest chunk seq received per stream, published when the pump ends.
559 high_seq: Mutex<(i64, i64)>,
560 stdin: AsyncMutex<StdinState>,
561 ended: AtomicBool,
562 ended_notify: Notify,
563 closing: AtomicBool,
564 close_notify: Notify,
565}
566
567/// A handle to a running command. Drop or [`ExecProcess::close`] releases the
568/// stream without killing the command.
569pub struct ExecProcess {
570 shared: Arc<ExecShared>,
571 exec_request_id: String,
572}
573
574impl Drop for ExecProcess {
575 fn drop(&mut self) {
576 // Honor the documented contract: a handle dropped without an explicit
577 // close() (e.g. by Python GC) still stops the pump and releases the
578 // stream, instead of leaving the gRPC stream running until the command
579 // finishes on its own.
580 self.close();
581 }
582}
583
584impl ExecProcess {
585 /// Submit the exec and start pumping output. Blocks until the server sends
586 /// the `Started` frame (the launch is durably settled).
587 ///
588 /// # Runtime
589 ///
590 /// Spawns the background output pump on the calling task's tokio runtime, so
591 /// call it from within one. The reconnect dials co-locate on that runtime.
592 #[doc(hidden)]
593 pub async fn start(
594 worker: Arc<WorkerProxy>,
595 mut params: ExecParams,
596 ) -> Result<ExecProcess, SailError> {
597 // The idempotency key dedupes the launch and lets a reconnect reattach
598 // to the same command. Mint one when the caller didn't supply their own,
599 // so every binding gets a stable key without restating the format.
600 let key = params.idempotency_key.trim();
601 params.idempotency_key = if key.is_empty() {
602 format!("exec_{}", uuid::Uuid::new_v4())
603 } else {
604 key.to_string()
605 };
606 // Resolve the pty terminal-env whitelist once at launch (caller-supplied
607 // keys win); params is reused verbatim on every reconnect.
608 if params.pty {
609 for (key, value) in pty_forward_env() {
610 params.env.entry(key).or_insert(value);
611 }
612 }
613 let (exec_request_id, stream) = submit(
614 &worker, ¶ms, /* stdout_resume_seq */ 0, /* stderr_resume_seq */ 0,
615 )
616 .await?;
617 let shared = Arc::new(ExecShared {
618 worker,
619 params,
620 state: Mutex::new(State::default()),
621 forward_events: Mutex::new(VecDeque::new()),
622 forward_notify: Notify::new(),
623 cond: Condvar::new(),
624 data_notify: Notify::new(),
625 exit: Mutex::new(None),
626 high_seq: Mutex::new((0, 0)),
627 stdin: AsyncMutex::new(StdinState::default()),
628 ended: AtomicBool::new(false),
629 ended_notify: Notify::new(),
630 closing: AtomicBool::new(false),
631 close_notify: Notify::new(),
632 });
633 let pump_shared = shared.clone();
634 tokio::spawn(async move { pump(pump_shared, stream).await });
635 Ok(ExecProcess {
636 shared,
637 exec_request_id,
638 })
639 }
640
641 /// The durable server-assigned id for this exec, taken from the `Started`
642 /// frame. Identifies the command for wait, cancel, resize, and stdin RPCs.
643 pub fn exec_request_id(&self) -> &str {
644 &self.exec_request_id
645 }
646
647 /// The sailbox this exec runs on.
648 pub fn sailbox_id(&self) -> &str {
649 &self.shared.params.sailbox_id
650 }
651
652 /// The idempotency key this exec launched with: the caller's, or the one
653 /// minted in `start` when none was supplied.
654 pub fn idempotency_key(&self) -> &str {
655 &self.shared.params.idempotency_key
656 }
657
658 /// Forward a local port to a guest-local port over this session. The
659 /// listener binds on `127.0.0.1`; passing `local_port` 0 lets the OS pick a
660 /// free port (read back from the returned handle). Dropping the handle stops
661 /// the forward.
662 pub async fn forward_port(
663 &self,
664 local_port: u16,
665 remote_port: u16,
666 ) -> Result<crate::forward::PortForward, SailError> {
667 crate::forward::forward_port(
668 Arc::clone(&self.shared.worker),
669 self.shared.params.exec_endpoint.clone(),
670 self.shared.params.sailbox_id.clone(),
671 local_port,
672 remote_port,
673 )
674 .await
675 }
676
677 /// Await the next local-forwarding event (e.g. a browser open) for an
678 /// interactive session. Returns `None` once the stream has ended and no
679 /// queued events remain. The shell driver consumes these to act on the
680 /// user's machine.
681 pub async fn next_forward_event(&self) -> Option<ForwardEvent> {
682 loop {
683 if let Some(event) = lock(&self.shared.forward_events).pop_front() {
684 return Some(event);
685 }
686 if self.shared.ended.load(Ordering::SeqCst) {
687 return None;
688 }
689 // Arm both wakers, then re-check so an event or end that landed
690 // between the drain above and here is not missed. `notified()`
691 // snapshots the notify generation at creation, so a `notify_waiters`
692 // that fires before the first poll still wakes the awaited future.
693 let on_event = self.shared.forward_notify.notified();
694 let on_end = self.shared.ended_notify.notified();
695 if !lock(&self.shared.forward_events).is_empty()
696 || self.shared.ended.load(Ordering::SeqCst)
697 {
698 continue;
699 }
700 tokio::select! {
701 () = on_event => {}
702 () = on_end => {}
703 }
704 }
705 }
706
707 /// Create a reader over a live output stream. A fresh reader replays the
708 /// retained tail from the start, then follows live.
709 pub fn reader(&self, which: OutputStream) -> StreamReader {
710 StreamReader {
711 shared: self.shared.clone(),
712 which,
713 cursor: 0,
714 dropped: false,
715 reset: false,
716 seen_front_clips: 0,
717 seen_resets: 0,
718 }
719 }
720
721 /// Create an async reader over a live output stream (the awaiting twin of
722 /// [`reader`](Self::reader)).
723 pub fn reader_async(&self, which: OutputStream) -> AsyncStreamReader {
724 AsyncStreamReader {
725 shared: self.shared.clone(),
726 which,
727 cursor: 0,
728 }
729 }
730
731 /// The locally buffered raw bytes of one stream (the byte-typed twin of the
732 /// lossily decoded [`ExecResult`] fields): exactly what the readers have
733 /// been fed, capped drop-oldest. A byte-count reconciliation against what a
734 /// consumer already printed must use this, not the decoded strings, whose
735 /// lengths diverge from the raw stream on invalid UTF-8.
736 #[doc(hidden)]
737 pub fn buffered_output(&self, which: OutputStream) -> Vec<u8> {
738 lock(&self.shared.state).ring(which).tail()
739 }
740
741 /// Returns the exit code if the Exit frame arrived on the stream, mapping a
742 /// not-a-real-result terminal status to its error. `None` means the result
743 /// is not known on the stream yet. `wait` is authoritative.
744 pub fn poll(&self) -> Option<Result<i32, SailError>> {
745 let exit = lock(&self.shared.exit);
746 exit.as_ref()
747 .map(|exit| match terminal_status_error(exit.status) {
748 Some(err) => Err(err),
749 None => Ok(exit.exit_code),
750 })
751 }
752
753 /// Stop the pump and release the stream without touching the remote command.
754 pub fn close(&self) {
755 self.shared.closing.store(true, Ordering::SeqCst);
756 // notify_one stores a permit if the pump is between its `closing` check
757 // and registering on close_notify, so a close racing the pump is not
758 // missed (notify_waiters wakes only already-registered waiters). The
759 // pump is the sole waiter, so one permit suffices.
760 self.shared.close_notify.notify_one();
761 }
762
763 /// Block up to `timeout` for the output stream to end; returns whether it
764 /// has. Lets a synchronous caller stay responsive to its own signals and
765 /// stop conditions between ticks before committing to the blocking
766 /// [`wait`](Self::wait) resolve.
767 #[doc(hidden)]
768 pub async fn wait_stream_ended(&self, timeout: Duration) -> bool {
769 let _ = tokio::time::timeout(timeout, self.await_ended()).await;
770 self.shared.ended.load(Ordering::SeqCst)
771 }
772
773 /// Resolve once the output stream has ended (the pump set `ended`).
774 async fn await_ended(&self) {
775 loop {
776 let notified = self.shared.ended_notify.notified();
777 if self.shared.ended.load(Ordering::SeqCst) {
778 return;
779 }
780 notified.await;
781 }
782 }
783
784 /// Wait for the command to finish and return its buffered result.
785 ///
786 /// A clean Exit resolves from the local rings; a stream that ended without
787 /// one (or whose tail is truncated or short) falls back to `WaitSailboxExec`,
788 /// which reattaches to the guest session for the authoritative result,
789 /// retrying a not-ready box for the exec's configured `retry_timeout` budget.
790 pub async fn wait(&self) -> Result<ExecResult, SailError> {
791 self.await_ended().await;
792 let exit = lock(&self.shared.exit).clone();
793 let (high_out, high_err) = *lock(&self.shared.high_seq);
794 let (out_dropped, err_dropped) = {
795 let state = lock(&self.shared.state);
796 (state.stdout.dropped, state.stderr.dropped)
797 };
798
799 // The server fallback only recovers a MISSING ENDING: a stream with no
800 // Exit, or one that fell short of the exit's high-water seq (a migration
801 // replay that did not deliver the tail). It does NOT help a stream that
802 // is complete but merely truncated at the front — the server's persisted
803 // tail is smaller than the local ring, so falling back there returns a
804 // worse result and burns a WaitSailboxExec RPC. Truncation is reported
805 // honestly on the local result instead.
806 let incomplete = exit
807 .as_ref()
808 .is_some_and(|exit| exit.stdout_seq > high_out || exit.stderr_seq > high_err);
809 // Whether the buffered `stdout`/`stderr` fields dropped their oldest
810 // bytes — the guest ring overflowed, or the local ring evicted output
811 // the reader may already have consumed. Complete streams still report
812 // it so a caller knows the convenience field is a tail, not the whole.
813 let stdout_truncated_flag = exit
814 .as_ref()
815 .is_some_and(|exit| exit.stdout_truncated || out_dropped);
816 let stderr_truncated_flag = exit
817 .as_ref()
818 .is_some_and(|exit| exit.stderr_truncated || err_dropped);
819
820 // Whether the live stream reached each stream's final chunk. When true,
821 // a live consumer already saw the whole stream (the buffered tail below
822 // can only repeat its ending); when false, the buffered copy is the only
823 // way to recover the missing tail.
824 let stdout_complete = exit
825 .as_ref()
826 .is_some_and(|exit| exit.stdout_seq <= high_out);
827 let stderr_complete = exit
828 .as_ref()
829 .is_some_and(|exit| exit.stderr_seq <= high_err);
830
831 // Total bytes the command produced on each stream (0 when no exit was
832 // observed on the stream, or the guest is too old to report it). A caller
833 // subtracts what it saw to learn how much truncation dropped.
834 let stdout_total_bytes = exit.as_ref().map_or(0, |exit| exit.stdout_total_bytes);
835 let stderr_total_bytes = exit.as_ref().map_or(0, |exit| exit.stderr_total_bytes);
836
837 if exit.is_none() || incomplete {
838 let outcome = self
839 .shared
840 .worker
841 .wait_exec(
842 &self.shared.params.exec_endpoint,
843 &self.shared.params.sailbox_id,
844 &self.exec_request_id,
845 self.shared.params.retry_timeout,
846 )
847 .await?;
848 // Record the polled terminal outcome (when the stream carried no
849 // Exit) so poll()/returncode agree with this wait().
850 {
851 let mut exit_slot = lock(&self.shared.exit);
852 if exit_slot.is_none() {
853 *exit_slot = Some(ExitInfo {
854 status: outcome.status,
855 exit_code: outcome.exit_code,
856 timed_out: outcome.timed_out,
857 stdout_truncated: outcome.stdout_truncated,
858 stderr_truncated: outcome.stderr_truncated,
859 error_message: String::new(),
860 stdout_seq: 0,
861 stderr_seq: 0,
862 // WaitSailboxExec carries no byte totals; 0 = unknown.
863 stdout_total_bytes: 0,
864 stderr_total_bytes: 0,
865 });
866 }
867 }
868 // A real terminal Exit was already witnessed on the live stream, so
869 // a worker_lost poll is stale: the worker can be lost between the
870 // command finishing and the persisted row being read. The witnessed
871 // completion is authoritative, so return it from the local rings
872 // rather than raising worker-lost.
873 if let Some(witnessed) = exit.as_ref() {
874 if outcome.status == pb::SailboxExecStatus::WorkerLost as i32 {
875 let state = lock(&self.shared.state);
876 let mut stderr = lossy_tail(&state.stderr);
877 if witnessed.status == pb::SailboxExecStatus::Failed as i32
878 && !witnessed.error_message.is_empty()
879 {
880 stderr = witnessed.error_message.clone();
881 }
882 return Ok(ExecResult {
883 stdout: lossy_tail(&state.stdout),
884 stderr,
885 exit_code: witnessed.exit_code,
886 timed_out: witnessed.timed_out,
887 stdout_truncated: witnessed.stdout_truncated
888 || out_dropped
889 || witnessed.stdout_seq > high_out,
890 stderr_truncated: witnessed.stderr_truncated
891 || err_dropped
892 || witnessed.stderr_seq > high_err,
893 stdout_complete,
894 stderr_complete,
895 stdout_total_bytes,
896 stderr_total_bytes,
897 });
898 }
899 }
900 if let Some(err) = terminal_status_error(outcome.status) {
901 return Err(err);
902 }
903 return Ok(ExecResult {
904 stdout: outcome.stdout,
905 stderr: outcome.stderr,
906 exit_code: outcome.exit_code,
907 timed_out: outcome.timed_out,
908 stdout_truncated: outcome.stdout_truncated,
909 stderr_truncated: outcome.stderr_truncated,
910 stdout_complete,
911 stderr_complete,
912 stdout_total_bytes,
913 stderr_total_bytes,
914 });
915 }
916
917 let exit = exit.expect("exit present on the clean path");
918 if let Some(err) = terminal_status_error(exit.status) {
919 return Err(err);
920 }
921 let state = lock(&self.shared.state);
922 let mut stderr = lossy_tail(&state.stderr);
923 if exit.status == pb::SailboxExecStatus::Failed as i32 && !exit.error_message.is_empty() {
924 // A failed row persists its failure text as stderr; mirror the poll path.
925 stderr = exit.error_message.clone();
926 }
927 Ok(ExecResult {
928 stdout: lossy_tail(&state.stdout),
929 stderr,
930 exit_code: exit.exit_code,
931 timed_out: exit.timed_out,
932 stdout_truncated: stdout_truncated_flag,
933 stderr_truncated: stderr_truncated_flag,
934 stdout_complete,
935 stderr_complete,
936 stdout_total_bytes,
937 stderr_total_bytes,
938 })
939 }
940
941 /// Signal the command: [`CancelSignal::Interrupt`] (SIGINT) or
942 /// [`CancelSignal::Kill`] (SIGKILL).
943 pub async fn cancel(&self, signal: CancelSignal, retry: RetryBudget) -> Result<(), SailError> {
944 self.shared
945 .worker
946 .cancel_exec(
947 &self.shared.params.exec_endpoint,
948 &self.shared.params.sailbox_id,
949 &self.exec_request_id,
950 signal.is_force(),
951 retry.as_secs_f64(),
952 )
953 .await
954 }
955
956 /// Set the pty window for a `pty` exec. Advisory and best-effort: an
957 /// unknown, finished, or not-yet-placed exec is a server no-op, and a
958 /// transient transport error is swallowed (the next resize resends).
959 pub async fn resize(&self, cols: u32, rows: u32) {
960 let message = pb::ResizeSailboxExecRequest {
961 sailbox_id: self.shared.params.sailbox_id.clone(),
962 exec_request_id: self.exec_request_id.clone(),
963 cols,
964 rows,
965 };
966 let Ok(request) =
967 self.shared
968 .worker
969 .request_for(message, &[], Some(Duration::from_secs(5)))
970 else {
971 return;
972 };
973 if let Ok(mut client) = self
974 .shared
975 .worker
976 .client_for(&self.shared.params.exec_endpoint)
977 {
978 let _ = client.resize_sailbox_exec(request).await;
979 }
980 }
981
982 /// Ask a `pty` exec to re-emit its current screen as a Snapshot on the live
983 /// stream. A client whose local buffer dropped output (it fell behind a
984 /// fast producer) calls this to repaint instead of rendering a torn tail;
985 /// the command keeps running detached. Advisory and best-effort like
986 /// [`resize`](Self::resize): an unknown, finished, or non-pty exec is a
987 /// server no-op, and a transient error is swallowed (the client re-requests
988 /// if it is still behind).
989 pub async fn resync(&self) {
990 let message = pb::ResyncSailboxExecRequest {
991 sailbox_id: self.shared.params.sailbox_id.clone(),
992 exec_request_id: self.exec_request_id.clone(),
993 };
994 let Ok(request) =
995 self.shared
996 .worker
997 .request_for(message, &[], Some(Duration::from_secs(5)))
998 else {
999 return;
1000 };
1001 if let Ok(mut client) = self
1002 .shared
1003 .worker
1004 .client_for(&self.shared.params.exec_endpoint)
1005 {
1006 let _ = client.resync_sailbox_exec(request).await;
1007 }
1008 }
1009
1010 /// Write to the command's stdin. Chunked with absolute offsets; an uncertain
1011 /// mid-flight failure poisons the writer (a stale-offset resume could
1012 /// silently drop bytes). Blocks (with backoff) while the guest buffer is full.
1013 pub async fn write_stdin(&self, data: &[u8]) -> Result<(), SailError> {
1014 let mut stdin = self.shared.stdin.lock().await;
1015 if stdin.eof_sent {
1016 return Err(SailError::BrokenPipe {
1017 message: "stdin is closed".to_string(),
1018 });
1019 }
1020 if stdin.broken {
1021 return Err(SailError::BrokenPipe {
1022 message: "an earlier stdin write failed".to_string(),
1023 });
1024 }
1025 if stdin.write_in_flight {
1026 // The previous write held the lock across its send and never cleared
1027 // this, so its future was cancelled mid-flight: bytes may have landed
1028 // and the offset is uncertain. Poison rather than resume.
1029 stdin.broken = true;
1030 return Err(SailError::BrokenPipe {
1031 message: "an earlier stdin write was interrupted".to_string(),
1032 });
1033 }
1034 if data.is_empty() {
1035 return Ok(());
1036 }
1037 stdin.write_in_flight = true;
1038 let result = self.send_stdin(&mut stdin, data, /* eof */ false).await;
1039 // Reached only if the send was not cancelled. A clean return clears the
1040 // latch; an uncertain failure already set `broken` inside send_stdin.
1041 stdin.write_in_flight = false;
1042 result
1043 }
1044
1045 /// Close the command's stdin (send EOF).
1046 pub async fn close_stdin(&self) -> Result<(), SailError> {
1047 let mut stdin = self.shared.stdin.lock().await;
1048 if stdin.eof_sent {
1049 return Ok(());
1050 }
1051 if stdin.broken || stdin.write_in_flight {
1052 // An earlier write failed or was cancelled mid-flight, so the stream
1053 // is undeliverable at a known offset.
1054 stdin.eof_sent = true;
1055 return Ok(());
1056 }
1057 // The EOF write carries no data and is idempotent, so a transient
1058 // failure can't corrupt the offset: send directly without poisoning, and
1059 // leave eof_sent false until it lands so a later eof retries it.
1060 match self.send_stdin(&mut stdin, &[], /* eof */ true).await {
1061 Ok(()) => {
1062 stdin.eof_sent = true;
1063 Ok(())
1064 }
1065 // The command already exited / closed stdin: nothing to deliver.
1066 Err(SailError::BrokenPipe { .. }) => {
1067 stdin.eof_sent = true;
1068 Ok(())
1069 }
1070 Err(err) => Err(err),
1071 }
1072 }
1073
1074 /// Drive the chunked WriteSailboxExecStdin loop. `eof` latches only when the
1075 /// final chunk is fully accepted. Poisons `stdin.broken` on an uncertain
1076 /// mid-flight failure (anything but a clean broken-pipe).
1077 async fn send_stdin(
1078 &self,
1079 stdin: &mut StdinState,
1080 payload: &[u8],
1081 eof: bool,
1082 ) -> Result<(), SailError> {
1083 let endpoint = &self.shared.params.exec_endpoint;
1084 let sailbox_id = &self.shared.params.sailbox_id;
1085 let mut deadline = retry_deadline(EXEC_TRANSIENT_RETRY_TIMEOUT_SECONDS);
1086 let mut delay = EXEC_TRANSIENT_RETRY_INITIAL_DELAY_SECONDS;
1087 let mut sent = 0usize;
1088 loop {
1089 let end = (sent + STDIN_WRITE_CHUNK_BYTES).min(payload.len());
1090 let chunk = &payload[sent..end];
1091 let last = end >= payload.len();
1092 let message = pb::WriteSailboxExecStdinRequest {
1093 sailbox_id: sailbox_id.clone(),
1094 exec_request_id: self.exec_request_id.clone(),
1095 offset: stdin.offset,
1096 data: chunk.to_vec(),
1097 eof: eof && last,
1098 };
1099 // Bound each attempt so a stalled connection (one that never
1100 // returns a status) times out and the retry/poison logic below
1101 // runs, instead of one await blocking the whole budget.
1102 let request = match self.shared.worker.request_for(
1103 message,
1104 &[],
1105 Some(rpc_attempt_timeout(deadline)),
1106 ) {
1107 Ok(request) => request,
1108 Err(err) => return Err(err),
1109 };
1110 let result = match self.shared.worker.client_for(endpoint) {
1111 Ok(mut client) => client.write_sailbox_exec_stdin(request).await,
1112 Err(err) => return Err(err),
1113 };
1114 match result {
1115 Ok(resp) => {
1116 let accepted_through = resp.into_inner().accepted_through;
1117 // Clamp to the chunk we actually sent: a server that
1118 // over-reports accepted_through must not push `sent` past the
1119 // payload (a slice panic) or advance the idempotent offset
1120 // beyond delivered bytes.
1121 let accepted =
1122 ((accepted_through - stdin.offset).max(0) as usize).min(chunk.len());
1123 stdin.offset += accepted as i64;
1124 sent += accepted;
1125 if sent >= payload.len() && (!eof || (last && accepted == chunk.len())) {
1126 return Ok(());
1127 }
1128 // A success proves the transport healthy: restart the budget.
1129 deadline = retry_deadline(EXEC_TRANSIENT_RETRY_TIMEOUT_SECONDS);
1130 if accepted > 0 {
1131 delay = EXEC_TRANSIENT_RETRY_INITIAL_DELAY_SECONDS;
1132 } else {
1133 // Guest buffer full: block like a pipe write, no deadline.
1134 delay = sleep_no_deadline(delay).await;
1135 }
1136 }
1137 Err(status) => {
1138 if matches!(status.code(), Code::NotFound | Code::FailedPrecondition) {
1139 // The exec is over or closed its stdin: a dead pipe.
1140 return Err(SailError::BrokenPipe {
1141 message: status.message().to_string(),
1142 });
1143 }
1144 if is_exec_not_ready(&status) {
1145 // Row open but guest not reachable yet (wake/migration):
1146 // wait it out against the exec's lifetime, no deadline,
1147 // resetting the transport budget on each "; retry".
1148 delay = sleep_no_deadline(delay).await;
1149 deadline = retry_deadline(EXEC_TRANSIENT_RETRY_TIMEOUT_SECONDS);
1150 continue;
1151 }
1152 if !should_retry_transient_exec_rpc(&status, deadline) {
1153 // Uncertain whether bytes landed: poison so a stale-offset
1154 // resume can't silently drop overlapping bytes.
1155 stdin.broken = true;
1156 return Err(SailError::from_exec_status(&status));
1157 }
1158 tracing::warn!(code = ?status.code(), "retrying exec stdin write");
1159 if should_invalidate_channel(&status) {
1160 self.shared.worker.channels().invalidate(endpoint);
1161 }
1162 delay = sleep_before_retry(delay, deadline).await;
1163 }
1164 }
1165 }
1166 }
1167}
1168
1169/// A cursor over one live output stream. [`StreamReader::next`] blocks up to a
1170/// timeout for the next chunk.
1171pub struct StreamReader {
1172 shared: Arc<ExecShared>,
1173 which: OutputStream,
1174 cursor: usize,
1175 dropped: bool,
1176 /// Set when the ring was reset to a repaint since the last read. Surfaced
1177 /// via took_reset so an interactive consumer drops its stale local backlog
1178 /// before rendering the repaint, rather than leaving it stuck behind bytes
1179 /// the terminal will never finish draining.
1180 reset: bool,
1181 /// The ring's `front_clips` value this reader has already accounted for, so
1182 /// an in-place clip of the piece it is parked on registers as a drop once.
1183 seen_front_clips: u64,
1184 /// The ring's `reset_to` count this reader has accounted for. A repaint
1185 /// advances `first_idx` past the cursor like an eviction, but reading the
1186 /// repaint heals the screen, so it must not register as a fall-behind drop.
1187 seen_resets: u64,
1188}
1189
1190impl StreamReader {
1191 /// Block up to `timeout` for the next step: the next retained chunk, `Eof`
1192 /// once the stream is closed and fully drained, or `Pending` if nothing new
1193 /// arrived in time.
1194 pub fn next(&mut self, timeout: Duration) -> ReadStep {
1195 let mut state = lock(&self.shared.state);
1196 loop {
1197 let ring = state.ring(self.which);
1198 // Reconcile with the ring head. A reset_to repaint replaced the ring
1199 // and supersedes whatever was skipped, so it is a heal surfaced via
1200 // took_reset, not a drop; it also supersedes a drop an earlier read
1201 // had already latched. Adopt the ring's own dropped flag rather than
1202 // clearing unconditionally: reset_to clears it, so it is false for a
1203 // clean heal, but re-latches if the repaint itself was then evicted
1204 // by later output before this read. In that case the reader is about
1205 // to hand back a torn post-repaint suffix, so it must still report a
1206 // drop for the consumer to resync. Otherwise a cursor below the head
1207 // means the ring evicted chunks this reader had not consumed, and a
1208 // front-clip trims the piece at first_idx in place without advancing
1209 // it; both latch a drop so an interactive consumer can repaint
1210 // (took_drop).
1211 if ring.resets != self.seen_resets {
1212 self.reset = true;
1213 self.dropped = ring.dropped;
1214 if self.cursor < ring.first_idx {
1215 self.cursor = ring.first_idx;
1216 }
1217 } else if self.cursor < ring.first_idx {
1218 self.cursor = ring.first_idx;
1219 self.dropped = true;
1220 } else if self.cursor == ring.first_idx && ring.front_clips != self.seen_front_clips {
1221 self.dropped = true;
1222 }
1223 self.seen_front_clips = ring.front_clips;
1224 self.seen_resets = ring.resets;
1225 let available = ring.first_idx + ring.pieces.len();
1226 if self.cursor < available {
1227 let piece = ring.pieces[self.cursor - ring.first_idx].clone();
1228 self.cursor += 1;
1229 return ReadStep::Chunk(piece);
1230 }
1231 if state.ended {
1232 return ReadStep::Eof;
1233 }
1234 let (next_state, timed_out) = self
1235 .shared
1236 .cond
1237 .wait_timeout(state, timeout)
1238 .expect("exec state mutex poisoned");
1239 state = next_state;
1240 if timed_out.timed_out() {
1241 return ReadStep::Pending;
1242 }
1243 }
1244 }
1245
1246 /// The next retained chunk if one is already buffered, without blocking.
1247 /// `None` means the ring is momentarily drained (not that the stream
1248 /// ended); callers batch-draining an interactive stream use it to flush
1249 /// several chunks in one write.
1250 pub fn try_next(&mut self) -> Option<Vec<u8>> {
1251 let state = lock(&self.shared.state);
1252 let ring = state.ring(self.which);
1253 if ring.resets != self.seen_resets {
1254 self.reset = true;
1255 // Adopt the ring's dropped flag: a clean repaint clears it, but a
1256 // repaint evicted by later output before this read leaves it set, so
1257 // the torn suffix still reports a drop. See next() for the full note.
1258 self.dropped = ring.dropped;
1259 if self.cursor < ring.first_idx {
1260 self.cursor = ring.first_idx;
1261 }
1262 } else if self.cursor < ring.first_idx {
1263 self.cursor = ring.first_idx;
1264 self.dropped = true;
1265 } else if self.cursor == ring.first_idx && ring.front_clips != self.seen_front_clips {
1266 self.dropped = true;
1267 }
1268 self.seen_front_clips = ring.front_clips;
1269 self.seen_resets = ring.resets;
1270 if self.cursor < ring.first_idx + ring.pieces.len() {
1271 let piece = ring.pieces[self.cursor - ring.first_idx].clone();
1272 self.cursor += 1;
1273 Some(piece)
1274 } else {
1275 None
1276 }
1277 }
1278
1279 /// Whether the ring evicted output this reader had not yet consumed since
1280 /// the last call, clearing the flag. An interactive consumer uses it to
1281 /// trigger a screen repaint ([`ExecProcess::resync`]) after falling behind.
1282 pub fn took_drop(&mut self) -> bool {
1283 std::mem::take(&mut self.dropped)
1284 }
1285
1286 /// Whether the ring was reset to a repaint (a Snapshot superseded the
1287 /// stream) since the last call, clearing the flag. An interactive consumer
1288 /// drops any stale terminal-local backlog on this so the repaint it is about
1289 /// to read renders at once instead of stuck behind bytes the terminal will
1290 /// never finish draining.
1291 pub fn took_reset(&mut self) -> bool {
1292 std::mem::take(&mut self.reset)
1293 }
1294}
1295
1296/// An async cursor over one live output stream, the awaiting counterpart of
1297/// [`StreamReader`]. [`AsyncStreamReader::next`] yields the next chunk without
1298/// parking a runtime thread, so many streams can be read on one event loop.
1299pub struct AsyncStreamReader {
1300 shared: Arc<ExecShared>,
1301 which: OutputStream,
1302 cursor: usize,
1303}
1304
1305impl AsyncStreamReader {
1306 /// The next retained chunk of raw bytes, or `None` once the stream is
1307 /// closed and fully drained. A reader that falls more than the buffer cap
1308 /// behind skips the dropped head rather than stalling.
1309 pub async fn next(&mut self) -> Option<Vec<u8>> {
1310 loop {
1311 // Arm the wakeup before inspecting the ring: `notify_waiters` only
1312 // wakes already-registered waiters, so enabling first closes the gap
1313 // where an append between the check and the await would be missed.
1314 let notified = self.shared.data_notify.notified();
1315 tokio::pin!(notified);
1316 notified.as_mut().enable();
1317 {
1318 let state = lock(&self.shared.state);
1319 let ring = state.ring(self.which);
1320 if self.cursor < ring.first_idx {
1321 self.cursor = ring.first_idx;
1322 }
1323 let available = ring.first_idx + ring.pieces.len();
1324 if self.cursor < available {
1325 let piece = ring.pieces[self.cursor - ring.first_idx].clone();
1326 self.cursor += 1;
1327 return Some(piece);
1328 }
1329 if state.ended {
1330 return None;
1331 }
1332 }
1333 notified.await;
1334 }
1335 }
1336}
1337
1338/// Sleep one backoff step with no deadline (used when the guest stdin buffer is
1339/// full or the guest is not reachable yet); returns the doubled delay.
1340async fn sleep_no_deadline(delay: f64) -> f64 {
1341 let sleep_for = delay.min(crate::worker::EXEC_TRANSIENT_RETRY_MAX_DELAY_SECONDS);
1342 tokio::time::sleep(Duration::from_secs_f64(sleep_for.max(0.0))).await;
1343 (delay * 2.0).min(crate::worker::EXEC_TRANSIENT_RETRY_MAX_DELAY_SECONDS)
1344}
1345
1346fn is_exec_not_ready(status: &Status) -> bool {
1347 status.code() == Code::Unavailable && status.message().contains("; retry")
1348}
1349
1350/// Map a worker-lost status (no real return code) to its error; `None` for a
1351/// normal exit (succeeded/failed/timed-out, which carry a real return code).
1352fn terminal_status_error(status: i32) -> Option<SailError> {
1353 if status == pb::SailboxExecStatus::WorkerLost as i32 {
1354 return Some(SailError::WorkerLost {
1355 message: "the machine hosting your sailbox was lost before the command \
1356 finished; run exec again to retry"
1357 .to_string(),
1358 });
1359 }
1360 None
1361}
1362
1363/// Open the exec stream and read the `Started` frame, retrying transient
1364/// failures. Non-zero resume seqs reattach a dropped stream.
1365async fn submit(
1366 worker: &Arc<WorkerProxy>,
1367 params: &ExecParams,
1368 stdout_resume_seq: i64,
1369 stderr_resume_seq: i64,
1370) -> Result<(String, Streaming<pb::StreamSailboxExecResponse>), SailError> {
1371 let deadline = retry_deadline(params.retry_timeout);
1372 let mut delay = EXEC_TRANSIENT_RETRY_INITIAL_DELAY_SECONDS;
1373 loop {
1374 let message = pb::StreamSailboxExecRequest {
1375 sailbox_id: params.sailbox_id.clone(),
1376 argv: params.argv.clone(),
1377 timeout_seconds: params.timeout_seconds,
1378 idempotency_key: params.idempotency_key.clone(),
1379 open_stdin: params.open_stdin,
1380 stdout_resume_seq,
1381 stderr_resume_seq,
1382 pty: params.pty,
1383 term_cols: params.cols,
1384 term_rows: params.rows,
1385 term: params.term.clone(),
1386 env: params.env.clone(),
1387 forward_ports: params.forward_ports,
1388 forward_browser: params.forward_browser,
1389 };
1390 let request =
1391 worker.request_for(message, ¶ms.extra_metadata, /* timeout */ None)?;
1392 let status = match worker
1393 .client_for(¶ms.exec_endpoint)?
1394 .stream_sailbox_exec(request)
1395 .await
1396 {
1397 Ok(resp) => {
1398 let mut stream = resp.into_inner();
1399 match stream.message().await {
1400 Ok(Some(first)) => match first.frame {
1401 Some(pb::stream_sailbox_exec_response::Frame::Started(started)) => {
1402 return Ok((started.exec_request_id, stream));
1403 }
1404 _ => {
1405 return Err(SailError::Execution {
1406 code: crate::error::GrpcCode::Internal,
1407 detail: "exec stream opened with a non-started frame".to_string(),
1408 });
1409 }
1410 },
1411 // On a fresh launch (resume seqs 0,0) a clean end before the
1412 // Started frame is a transport-level teardown, not a server
1413 // verdict — the server deliberately sends Started even for
1414 // lost sessions on that path. Nothing was confirmed and the
1415 // relaunch reuses the idempotency key, so route it through
1416 // the transient-retry gate like any dropped connection. On a
1417 // mid-run reconnect the same clean end IS a verdict (the box
1418 // parked: autoslept, lost, or re-homing) — surface it so the
1419 // caller falls back to wait(), which wakes the box, instead
1420 // of re-submitting against a server that will not act.
1421 Ok(None) if stdout_resume_seq == 0 && stderr_resume_seq == 0 => {
1422 tonic::Status::unavailable(
1423 "exec stream ended before the server confirmed the launch",
1424 )
1425 }
1426 Ok(None) => {
1427 return Err(SailError::Execution {
1428 code: crate::error::GrpcCode::Internal,
1429 detail: "exec stream ended before the server confirmed the launch"
1430 .to_string(),
1431 });
1432 }
1433 Err(status) => status,
1434 }
1435 }
1436 Err(status) => status,
1437 };
1438 if !should_retry_transient_exec_rpc(&status, deadline) {
1439 return Err(SailError::from_exec_status(&status));
1440 }
1441 tracing::warn!(
1442 code = ?status.code(),
1443 stdout_resume_seq,
1444 stderr_resume_seq,
1445 "reconnecting exec stream"
1446 );
1447 if should_invalidate_channel(&status) {
1448 worker.channels().invalidate(¶ms.exec_endpoint);
1449 }
1450 delay = sleep_before_retry(delay, deadline).await;
1451 }
1452}
1453
1454/// Drains exec frames into the rings while tracking the per-stream high-water
1455/// seqs (the resume points sent on reconnect). Split out from the transport
1456/// loop so the resume/replay state machine is testable in-process without a
1457/// gRPC stream: a mid-stream break is just "keep applying frames after a gap".
1458struct Pump {
1459 shared: Arc<ExecShared>,
1460 stdout_seq: i64,
1461 stderr_seq: i64,
1462}
1463
1464impl Pump {
1465 fn new(shared: Arc<ExecShared>) -> Pump {
1466 Pump {
1467 shared,
1468 stdout_seq: 0,
1469 stderr_seq: 0,
1470 }
1471 }
1472
1473 /// Apply one frame. Returns `true` for a terminal Exit frame (stop draining).
1474 /// Chunk seqs only advance the high-water mark, never rewind — a server that
1475 /// replays an already-seen tail after reconnect can't lower the resume point
1476 /// — with one deliberate exception: a pty Snapshot assigns its basis, since
1477 /// the repaint supersedes everything before it.
1478 fn apply_frame(&mut self, frame: pb::StreamSailboxExecResponse) -> bool {
1479 match frame.frame {
1480 Some(pb::stream_sailbox_exec_response::Frame::Chunk(chunk)) => {
1481 let is_stderr = chunk.stream == pb::SailboxExecStream::Stderr as i32;
1482 let which = if is_stderr {
1483 self.stderr_seq = self.stderr_seq.max(chunk.seq);
1484 OutputStream::Stderr
1485 } else {
1486 self.stdout_seq = self.stdout_seq.max(chunk.seq);
1487 OutputStream::Stdout
1488 };
1489 if !chunk.data.is_empty() {
1490 let mut state = lock(&self.shared.state);
1491 match which {
1492 OutputStream::Stdout => state.stdout.append(chunk.data),
1493 OutputStream::Stderr => state.stderr.append(chunk.data),
1494 }
1495 self.shared.cond.notify_all();
1496 self.shared.data_notify.notify_waiters();
1497 }
1498 false
1499 }
1500 Some(pb::stream_sailbox_exec_response::Frame::Snapshot(snap)) => {
1501 // A pty screen resync (reattach or server-side overflow
1502 // recovery): the repaint replaces the retained stream and seq
1503 // accounting continues from the basis, so Exit-completeness
1504 // math stays honest without any snapshot-specific logic in
1505 // wait() or the readers.
1506 self.stdout_seq = snap.stdout_seq_basis;
1507 let mut state = lock(&self.shared.state);
1508 state.stdout.reset_to(snap.repaint);
1509 self.shared.cond.notify_all();
1510 self.shared.data_notify.notify_waiters();
1511 false
1512 }
1513 Some(pb::stream_sailbox_exec_response::Frame::OpenUrl(open)) => {
1514 // A browser-open inside the sandbox. It carries no output, so it
1515 // is queued for the shell driver rather than entering the ring.
1516 lock(&self.shared.forward_events).push_back(ForwardEvent::OpenUrl(open.url));
1517 self.shared.forward_notify.notify_waiters();
1518 false
1519 }
1520 Some(pb::stream_sailbox_exec_response::Frame::PortSnapshot(snapshot)) => {
1521 // The current set of localhost servers. Off-ring like OpenUrl.
1522 let ports = snapshot
1523 .ports
1524 .into_iter()
1525 .filter_map(|port| u16::try_from(port).ok())
1526 .collect();
1527 lock(&self.shared.forward_events).push_back(ForwardEvent::PortSnapshot(ports));
1528 self.shared.forward_notify.notify_waiters();
1529 false
1530 }
1531 Some(pb::stream_sailbox_exec_response::Frame::Exit(exit)) => {
1532 *lock(&self.shared.exit) = Some(ExitInfo {
1533 status: exit.status,
1534 exit_code: exit.return_code,
1535 timed_out: exit.timed_out,
1536 stdout_truncated: exit.stdout_truncated,
1537 stderr_truncated: exit.stderr_truncated,
1538 error_message: exit.error_message,
1539 stdout_seq: exit.stdout_seq,
1540 stderr_seq: exit.stderr_seq,
1541 stdout_total_bytes: exit.stdout_total_bytes,
1542 stderr_total_bytes: exit.stderr_total_bytes,
1543 });
1544 true
1545 }
1546 _ => false,
1547 }
1548 }
1549
1550 /// Publish the high-water seqs, close the rings, and wake every reader and
1551 /// waiter. Consumes the pump: nothing follows finalize.
1552 fn finalize(self) {
1553 {
1554 let mut state = lock(&self.shared.state);
1555 state.ended = true;
1556 self.shared.cond.notify_all();
1557 self.shared.data_notify.notify_waiters();
1558 }
1559 *lock(&self.shared.high_seq) = (self.stdout_seq, self.stderr_seq);
1560 self.shared.ended.store(true, Ordering::SeqCst);
1561 self.shared.ended_notify.notify_waiters();
1562 }
1563}
1564
1565/// Drain the output stream into the rings, reconnecting on a transient break,
1566/// until the Exit frame or an unrecoverable end. Always finalizes the rings.
1567async fn pump(shared: Arc<ExecShared>, mut stream: Streaming<pb::StreamSailboxExecResponse>) {
1568 let mut state = Pump::new(shared.clone());
1569 loop {
1570 if shared.closing.load(Ordering::SeqCst) {
1571 break;
1572 }
1573 let message = tokio::select! {
1574 biased;
1575 () = shared.close_notify.notified() => break,
1576 message = stream.message() => message,
1577 };
1578 match message {
1579 Ok(Some(frame)) => {
1580 if state.apply_frame(frame) {
1581 break;
1582 }
1583 }
1584 // The stream ended cleanly without an Exit; leave it to wait()'s poll.
1585 Ok(None) => break,
1586 Err(_status) => {
1587 if shared.closing.load(Ordering::SeqCst) {
1588 break;
1589 }
1590 // Reconnect from the last seq we saw, so the guest replays only
1591 // the unseen tail.
1592 match submit(
1593 &shared.worker,
1594 &shared.params,
1595 state.stdout_seq,
1596 state.stderr_seq,
1597 )
1598 .await
1599 {
1600 Ok((_id, fresh)) => {
1601 stream = fresh;
1602 continue;
1603 }
1604 Err(_) => break,
1605 }
1606 }
1607 }
1608 }
1609 state.finalize();
1610}
1611
1612/// Fuzz entry point: drive an arbitrary byte stream through the incremental
1613/// UTF-8 decoder (split at data-derived boundaries) and the drop-oldest ring,
1614/// asserting the engine's invariants. Any violation panics, which libfuzzer
1615/// flags as a crash. Compiled only under `cfg(test)` or the `fuzzing` feature,
1616/// so it is never part of a production build.
1617#[cfg(any(test, feature = "fuzzing"))]
1618pub fn fuzz_exec_ring(data: &[u8]) {
1619 // Append the input split at data-derived boundaries (cut after every odd
1620 // byte) and as one piece: the retained tail must be identical — the ring is
1621 // chunk-boundary invariant on raw bytes.
1622 let mut chunked = Ring::default();
1623 let mut start = 0;
1624 for (i, byte) in data.iter().enumerate() {
1625 if byte & 1 == 1 {
1626 chunked.append(data[start..=i].to_vec());
1627 start = i + 1;
1628 }
1629 }
1630 if start < data.len() {
1631 chunked.append(data[start..].to_vec());
1632 }
1633 let mut whole = Ring::default();
1634 if !data.is_empty() {
1635 whole.append(data.to_vec());
1636 }
1637 assert_eq!(
1638 chunked.tail(),
1639 whole.tail(),
1640 "ring is not chunk-boundary invariant"
1641 );
1642
1643 // Overrun the cap by a hair so the drop-oldest clip lands inside the
1644 // fuzz-derived front piece: the ring must stay within the cap (byte-exact)
1645 // and its retained bytes must remain a suffix of everything appended.
1646 let mut ring = Ring::default();
1647 ring.append(data.to_vec());
1648 let filler = vec![b'a'; STREAM_BUFFER_CAP_BYTES + 1 - data.len().min(STREAM_BUFFER_CAP_BYTES)];
1649 ring.append(filler.clone());
1650 assert!(
1651 ring.size <= STREAM_BUFFER_CAP_BYTES,
1652 "ring exceeded its cap"
1653 );
1654 let mut full = data.to_vec();
1655 full.extend_from_slice(&filler);
1656 assert!(
1657 full.ends_with(&ring.tail()),
1658 "ring tail is not a suffix of the appended bytes"
1659 );
1660
1661 // A reset supersedes everything retained: prior pieces become unreachable
1662 // (first_idx advanced past them) and the tail is exactly the repaint,
1663 // clipped to the cap.
1664 let before_reset_pieces = ring.first_idx + ring.pieces.len();
1665 ring.reset_to(data.to_vec());
1666 assert!(
1667 ring.first_idx >= before_reset_pieces,
1668 "reset left old pieces reachable"
1669 );
1670 let expected = &data[data.len().saturating_sub(STREAM_BUFFER_CAP_BYTES)..];
1671 assert_eq!(
1672 ring.tail(),
1673 expected,
1674 "reset tail is not the capped repaint"
1675 );
1676}
1677
1678#[cfg(test)]
1679mod tests {
1680 use super::*;
1681
1682 #[test]
1683 fn shell_argv_wraps_cwd_and_background() {
1684 let plain = shell_argv("echo hi", &ExecOptions::default()).unwrap();
1685 assert_eq!(plain, ["/bin/sh", "-lc", "echo hi"]);
1686
1687 let cwd = shell_argv(
1688 "echo hi",
1689 &ExecOptions {
1690 cwd: Some("/app".to_string()),
1691 ..ExecOptions::default()
1692 },
1693 )
1694 .unwrap();
1695 assert_eq!(cwd[2], "cd '/app' && exec /bin/sh -lc 'echo hi'");
1696
1697 let background = shell_argv(
1698 "echo hi",
1699 &ExecOptions {
1700 cwd: Some("/app".to_string()),
1701 background: true,
1702 ..ExecOptions::default()
1703 },
1704 )
1705 .unwrap();
1706 assert_eq!(
1707 background[2],
1708 "nohup /bin/sh -lc 'cd '\\''/app'\\'' && exec /bin/sh -lc '\\''echo hi'\\''' </dev/null >/dev/null 2>&1 &"
1709 );
1710 }
1711
1712 #[test]
1713 fn shell_argv_rejects_invalid_combinations() {
1714 assert!(shell_argv("", &ExecOptions::default()).is_err());
1715 assert!(shell_argv(
1716 "x",
1717 &ExecOptions {
1718 cwd: Some(" ".to_string()),
1719 ..ExecOptions::default()
1720 }
1721 )
1722 .is_err());
1723 for (open_stdin, pty) in [(true, false), (false, true)] {
1724 assert!(shell_argv(
1725 "x",
1726 &ExecOptions {
1727 background: true,
1728 open_stdin,
1729 pty,
1730 ..ExecOptions::default()
1731 }
1732 )
1733 .is_err());
1734 }
1735 }
1736
1737 #[test]
1738 fn fuzz_exec_ring_holds_on_samples() {
1739 // Verifies the fuzz entry point itself: hand-picked inputs covering valid
1740 // multibyte chars, split sequences, and invalid bytes.
1741 for sample in [
1742 &b""[..],
1743 b"hello",
1744 b"\xff\xfe\xfd",
1745 "€ µ é".as_bytes(),
1746 b"ab\xc3\xa9cd",
1747 &[0xC3, 0x28],
1748 ] {
1749 fuzz_exec_ring(sample);
1750 }
1751 }
1752
1753 #[test]
1754 fn ring_drops_oldest_past_cap_and_latches() {
1755 let mut ring = Ring::default();
1756 ring.append(vec![b'a'; STREAM_BUFFER_CAP_BYTES]);
1757 assert!(!ring.dropped);
1758 ring.append(b"bbbb".to_vec());
1759 assert!(ring.dropped);
1760 assert_eq!(ring.size, STREAM_BUFFER_CAP_BYTES);
1761 assert_eq!(ring.tail().len(), STREAM_BUFFER_CAP_BYTES);
1762 assert!(ring.tail().ends_with(b"bbbb"));
1763 }
1764
1765 #[test]
1766 fn ring_clip_is_byte_exact() {
1767 // Overflow of 1 lands inside the leading 2-byte 'é'. The byte ring
1768 // clips at the exact byte — split multibyte sequences are the reader's
1769 // concern (decode at the edge), never the ring's.
1770 let mut ring = Ring::default();
1771 let mut data = "é".as_bytes().to_vec();
1772 data.extend(std::iter::repeat_n(b'a', STREAM_BUFFER_CAP_BYTES - 1));
1773 ring.append(data);
1774 assert_eq!(ring.size, STREAM_BUFFER_CAP_BYTES);
1775 assert!(ring.dropped);
1776 let tail = ring.tail();
1777 assert_eq!(tail.len(), STREAM_BUFFER_CAP_BYTES);
1778 // The clip cut the first byte of 'é'; its continuation byte survives.
1779 assert_eq!(tail[0], "é".as_bytes()[1]);
1780 }
1781
1782 #[test]
1783 fn ring_reset_to_supersedes_retained_pieces() {
1784 let mut ring = Ring::default();
1785 ring.append(b"old output".to_vec());
1786 ring.append(b"more".to_vec());
1787 let reachable_end = ring.first_idx + ring.pieces.len();
1788 ring.reset_to(b"\x1b[2J\x1b[Hrepaint".to_vec());
1789 assert!(ring.first_idx >= reachable_end);
1790 assert_eq!(ring.tail(), b"\x1b[2J\x1b[Hrepaint");
1791 // A catch-up, not a loss: dropped must not latch.
1792 assert!(!ring.dropped);
1793
1794 let mut empty = Ring::default();
1795 empty.append(b"x".to_vec());
1796 empty.reset_to(Vec::new());
1797 assert!(empty.tail().is_empty());
1798 }
1799
1800 /// A drop latched before the snapshot must not survive it: the repaint
1801 /// supersedes the lost bytes, and a stale `dropped` would force `wait()`
1802 /// into the server fallback for a fully healed pty session.
1803 #[test]
1804 fn pty_forward_env_filters_to_the_whitelist() {
1805 let vars = vec![
1806 ("COLORTERM".to_string(), "truecolor".to_string()),
1807 ("LC_ALL".to_string(), "en_US.UTF-8".to_string()),
1808 ("LANG".to_string(), "en_US.UTF-8".to_string()),
1809 ("TERM_PROGRAM".to_string(), "TestTerm".to_string()),
1810 ("PATH".to_string(), "/bin".to_string()),
1811 ("TERM".to_string(), "xterm".to_string()), // rides the term field, not env
1812 ("SECRET_TOKEN".to_string(), "x".to_string()),
1813 ];
1814 let forwarded = pty_forward_env_from(vars.into_iter());
1815 let keys: Vec<&str> = forwarded.iter().map(|(k, _)| k.as_str()).collect();
1816 assert_eq!(keys, ["COLORTERM", "LC_ALL", "LANG", "TERM_PROGRAM"]);
1817 }
1818
1819 #[test]
1820 fn encode_env_rejects_malformed_keys() {
1821 for (key, value) in [
1822 ("", "v"),
1823 ("A=B", "v"),
1824 ("NUL\0KEY", "v"),
1825 ("K", "nul\0value"),
1826 // Non-portable names: leading digit, whitespace, punctuation.
1827 ("1FOO", "v"),
1828 ("FO O", "v"),
1829 ("FOO-BAR", "v"),
1830 ("FOO.BAR", "v"),
1831 ] {
1832 let pairs = vec![(key.to_string(), value.to_string())];
1833 assert!(
1834 encode_env(&pairs).is_err(),
1835 "expected rejection for {key:?}={value:?}"
1836 );
1837 }
1838 // A leading-underscore name and an opaque value (including '=') are fine.
1839 let ok = encode_env(&[
1840 ("_FOO".to_string(), "bar=baz".to_string()),
1841 ("LC_ALL".to_string(), "C.UTF-8".to_string()),
1842 ])
1843 .unwrap();
1844 assert_eq!(ok.get("_FOO").map(String::as_str), Some("bar=baz"));
1845 }
1846
1847 #[test]
1848 fn ring_reset_to_clears_prior_dropped() {
1849 let mut ring = Ring::default();
1850 ring.append(vec![b'a'; STREAM_BUFFER_CAP_BYTES + 1]);
1851 assert!(ring.dropped);
1852 ring.reset_to(b"repaint".to_vec());
1853 assert!(!ring.dropped);
1854 assert_eq!(ring.tail(), b"repaint");
1855
1856 // An over-cap repaint re-latches through append's normal path.
1857 let mut over = Ring::default();
1858 over.append(vec![b'b'; STREAM_BUFFER_CAP_BYTES + 1]);
1859 over.reset_to(vec![b'c'; STREAM_BUFFER_CAP_BYTES + 1]);
1860 assert!(over.dropped);
1861 assert_eq!(over.size, STREAM_BUFFER_CAP_BYTES);
1862 }
1863
1864 #[test]
1865 fn terminal_status_mapping() {
1866 assert!(matches!(
1867 terminal_status_error(pb::SailboxExecStatus::WorkerLost as i32),
1868 Some(SailError::WorkerLost { .. })
1869 ));
1870 assert!(terminal_status_error(pb::SailboxExecStatus::Succeeded as i32).is_none());
1871 // Retired wire values (canceled=9, interrupted_retryable=6, interrupted_unsafe_to_retry=7,
1872 // reserved in the proto) carry no error: an old backend that still emits one falls through
1873 // to a normal result rather than raising.
1874 for retired in [9, 6, 7] {
1875 assert!(terminal_status_error(retired).is_none());
1876 }
1877 }
1878
1879 fn test_shared() -> Arc<ExecShared> {
1880 Arc::new(ExecShared {
1881 worker: Arc::new(WorkerProxy::new("test-key").unwrap()),
1882 params: ExecParams {
1883 sailbox_id: "sb".into(),
1884 exec_endpoint: "endpoint".into(),
1885 argv: vec!["echo".into()],
1886 timeout_seconds: 0,
1887 idempotency_key: "idem".into(),
1888 open_stdin: false,
1889 pty: false,
1890 term: String::new(),
1891 cols: 0,
1892 rows: 0,
1893 env: std::collections::HashMap::default(),
1894 retry_timeout: 0.0,
1895 forward_ports: false,
1896 forward_browser: false,
1897 extra_metadata: vec![],
1898 },
1899 state: Mutex::new(State::default()),
1900 forward_events: Mutex::new(VecDeque::new()),
1901 forward_notify: Notify::new(),
1902 cond: Condvar::new(),
1903 data_notify: Notify::new(),
1904 exit: Mutex::new(None),
1905 high_seq: Mutex::new((0, 0)),
1906 stdin: AsyncMutex::new(StdinState::default()),
1907 ended: AtomicBool::new(false),
1908 ended_notify: Notify::new(),
1909 closing: AtomicBool::new(false),
1910 close_notify: Notify::new(),
1911 })
1912 }
1913
1914 fn chunk(which: OutputStream, seq: i64, data: &[u8]) -> pb::StreamSailboxExecResponse {
1915 let stream = match which {
1916 OutputStream::Stdout => pb::SailboxExecStream::Stdout,
1917 OutputStream::Stderr => pb::SailboxExecStream::Stderr,
1918 };
1919 pb::StreamSailboxExecResponse {
1920 frame: Some(pb::stream_sailbox_exec_response::Frame::Chunk(
1921 pb::SailboxExecChunk {
1922 stream: stream as i32,
1923 data: data.to_vec(),
1924 seq,
1925 },
1926 )),
1927 }
1928 }
1929
1930 fn exit_frame(status: pb::SailboxExecStatus, stdout_seq: i64) -> pb::StreamSailboxExecResponse {
1931 pb::StreamSailboxExecResponse {
1932 frame: Some(pb::stream_sailbox_exec_response::Frame::Exit(
1933 pb::SailboxExecExit {
1934 status: status as i32,
1935 return_code: 0,
1936 timed_out: false,
1937 stdout_truncated: false,
1938 stderr_truncated: false,
1939 error_message: String::new(),
1940 stdout_seq,
1941 stderr_seq: 0,
1942 ..Default::default()
1943 },
1944 )),
1945 }
1946 }
1947
1948 /// The resume state machine: bytes split across a mid-stream break arrive
1949 /// verbatim (a mid-char break is just two chunks; the edge decode heals it),
1950 /// the high-water seq only advances (so a replayed tail can't lower the
1951 /// resume point), and finalize publishes the seqs `wait()` checks for
1952 /// completeness.
1953 #[tokio::test]
1954 async fn exec_resume_carries_bytes_and_tracks_seq_across_break() {
1955 let shared = test_shared();
1956 let mut pump = Pump::new(shared.clone());
1957
1958 // Pre-break: seq 1 ends mid-'é' (0xC3 0xA9), delivering only the lead byte.
1959 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 1, b"ab\xc3")));
1960 assert_eq!(shared.state.lock().unwrap().stdout.tail(), b"ab\xc3");
1961 // The reconnect would call submit(.., stdout_resume_seq = 1, ..).
1962 assert_eq!(pump.stdout_seq, 1);
1963
1964 // The socket breaks; the guest replays only seq > 1. Seq 2 supplies the
1965 // rest of 'é' plus more; the ring concatenates the raw bytes, and the
1966 // string edge lossy-decodes them whole.
1967 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 2, b"\xa9cd")));
1968 assert_eq!(
1969 shared.state.lock().unwrap().stdout.tail(),
1970 "abécd".as_bytes()
1971 );
1972 assert_eq!(lossy_tail(&shared.state.lock().unwrap().stdout), "abécd");
1973 assert_eq!(pump.stdout_seq, 2);
1974
1975 // An out-of-order/replayed lower seq must not rewind the resume point.
1976 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 1, b"!")));
1977 assert_eq!(pump.stdout_seq, 2);
1978
1979 assert!(pump.apply_frame(exit_frame(pb::SailboxExecStatus::Succeeded, 2)));
1980 pump.finalize();
1981 assert_eq!(*shared.high_seq.lock().unwrap(), (2, 0));
1982 assert!(shared.ended.load(Ordering::SeqCst));
1983 }
1984
1985 fn snapshot_frame(repaint: &[u8], basis: i64) -> pb::StreamSailboxExecResponse {
1986 pb::StreamSailboxExecResponse {
1987 frame: Some(pb::stream_sailbox_exec_response::Frame::Snapshot(
1988 pb::SailboxExecSnapshot {
1989 repaint: repaint.to_vec(),
1990 stdout_seq_basis: basis,
1991 },
1992 )),
1993 }
1994 }
1995
1996 /// A pty Snapshot supersedes the retained stream: readers skip to the
1997 /// repaint, a late reader sees only the repaint, the seq high-water is
1998 /// assigned to the basis, and Exit-completeness math continues from it.
1999 #[tokio::test]
2000 async fn snapshot_resets_ring_seq_basis_and_skips_readers() {
2001 let shared = test_shared();
2002 let mut pump = Pump::new(shared.clone());
2003 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 1, b"pre-disconnect ")));
2004 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 2, b"tail")));
2005
2006 // The reattach answers with a repaint based at the guest's high seq.
2007 assert!(!pump.apply_frame(snapshot_frame(b"\x1b[2J\x1b[Hscreen", 7)));
2008 assert_eq!(pump.stdout_seq, 7);
2009
2010 // A late reader replays only the repaint, then the post-snapshot chunk.
2011 assert!(!pump.apply_frame(chunk(OutputStream::Stdout, 8, b" after")));
2012 assert!(pump.apply_frame(exit_frame(pb::SailboxExecStatus::Succeeded, 8)));
2013 pump.finalize();
2014
2015 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2016 let mut out = Vec::new();
2017 loop {
2018 match reader.next(Duration::from_millis(50)) {
2019 ReadStep::Chunk(piece) => out.extend_from_slice(&piece),
2020 ReadStep::Eof => break,
2021 ReadStep::Pending => panic!("ended ring should not return Pending"),
2022 }
2023 }
2024 assert_eq!(out, b"\x1b[2J\x1b[Hscreen after");
2025 // Completeness: exit.stdout_seq (8) <= published high seq (8).
2026 assert_eq!(*shared.high_seq.lock().unwrap(), (8, 0));
2027 }
2028
2029 #[test]
2030 fn snapshot_with_empty_repaint_is_reset_only() {
2031 let shared = test_shared();
2032 let mut pump = Pump::new(shared.clone());
2033 pump.apply_frame(chunk(OutputStream::Stdout, 3, b"stale"));
2034 pump.apply_frame(snapshot_frame(b"", 3));
2035 assert_eq!(pump.stdout_seq, 3);
2036 let state = lock(&shared.state);
2037 assert!(state.stdout.tail().is_empty());
2038 assert!(!state.stdout.dropped);
2039 }
2040
2041 /// A reader started before any output replays the retained tail in order, then
2042 /// follows live chunks (including ones that arrive after a reconnect gap), and
2043 /// stops at Eof once the pump finalizes.
2044 #[tokio::test]
2045 async fn exec_reader_follows_replayed_then_live() {
2046 let shared = test_shared();
2047 let mut reader = StreamReader {
2048 shared: shared.clone(),
2049 which: OutputStream::Stdout,
2050 cursor: 0,
2051 dropped: false,
2052 reset: false,
2053 seen_front_clips: 0,
2054 seen_resets: 0,
2055 };
2056 let collector = tokio::task::spawn_blocking(move || {
2057 let mut out = Vec::new();
2058 loop {
2059 match reader.next(Duration::from_millis(50)) {
2060 ReadStep::Chunk(piece) => out.extend_from_slice(&piece),
2061 ReadStep::Eof => return out,
2062 ReadStep::Pending => {}
2063 }
2064 }
2065 });
2066
2067 let mut pump = Pump::new(shared.clone());
2068 pump.apply_frame(chunk(OutputStream::Stdout, 1, b"hello "));
2069 tokio::time::sleep(Duration::from_millis(10)).await;
2070 // A reconnect gap, then the live tail resumes.
2071 pump.apply_frame(chunk(OutputStream::Stdout, 2, b"world"));
2072 tokio::time::sleep(Duration::from_millis(10)).await;
2073 pump.apply_frame(exit_frame(pb::SailboxExecStatus::Succeeded, 2));
2074 pump.finalize();
2075
2076 assert_eq!(collector.await.unwrap(), b"hello world");
2077 }
2078
2079 /// A reader created after output is already buffered still replays the
2080 /// retained tail from the start (cursor 0), then sees Eof.
2081 #[test]
2082 fn exec_reader_started_late_replays_retained_tail() {
2083 let shared = test_shared();
2084 let mut pump = Pump::new(shared.clone());
2085 pump.apply_frame(chunk(OutputStream::Stdout, 1, b"early "));
2086 pump.apply_frame(chunk(OutputStream::Stdout, 2, b"output"));
2087 pump.finalize();
2088
2089 // Construct the reader only now, against an already-populated, ended ring.
2090 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2091 let mut out = Vec::new();
2092 loop {
2093 match reader.next(Duration::from_millis(50)) {
2094 ReadStep::Chunk(piece) => out.extend_from_slice(&piece),
2095 ReadStep::Eof => break,
2096 ReadStep::Pending => panic!("ended ring should not return Pending"),
2097 }
2098 }
2099 assert_eq!(out, b"early output");
2100 }
2101
2102 // A reader that falls behind a ring overflow skips the evicted chunks and
2103 // reports the drop once (then clears it), and try_next batch-drains without
2104 // blocking. This is what the interactive bridge keys its repaint request on.
2105 #[test]
2106 fn reader_reports_drop_and_batch_drains() {
2107 let shared = test_shared();
2108 {
2109 // A small head chunk plus a cap-sized chunk overflows the ring,
2110 // fully evicting the head (advancing first_idx past it).
2111 let mut state = lock(&shared.state);
2112 state.stdout.append(b"HEAD".to_vec());
2113 state.stdout.append(vec![b'x'; STREAM_BUFFER_CAP_BYTES]);
2114 state.ended = true;
2115 }
2116 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2117
2118 // The reader skips the evicted head and reports the drop once.
2119 let first = reader.next(Duration::from_millis(50));
2120 let ReadStep::Chunk(first) = first else {
2121 panic!("expected the retained chunk, got {first:?}");
2122 };
2123 assert!(
2124 reader.took_drop(),
2125 "the overflow evicted an unconsumed chunk"
2126 );
2127 assert!(!reader.took_drop(), "took_drop clears the latch");
2128
2129 // The retained content is the surviving chunk; the head is gone.
2130 assert_eq!(first, vec![b'x'; STREAM_BUFFER_CAP_BYTES]);
2131 assert!(
2132 reader.try_next().is_none(),
2133 "a drained ring yields None without blocking"
2134 );
2135 }
2136
2137 #[test]
2138 fn reader_does_not_report_a_reset_repaint_as_a_drop() {
2139 let shared = test_shared();
2140 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2141 {
2142 let mut state = lock(&shared.state);
2143 state.stdout.append(b"one".to_vec());
2144 }
2145 // Consume the first chunk cleanly: no drop yet.
2146 assert!(matches!(
2147 reader.next(Duration::from_millis(50)),
2148 ReadStep::Chunk(_)
2149 ));
2150 assert!(!reader.took_drop(), "a clean read latches no drop");
2151 assert!(!reader.took_reset(), "a clean read is not a reset");
2152
2153 {
2154 // More live output the reader has not read, then a repaint that
2155 // supersedes the ring and advances first_idx past the cursor. The
2156 // reader must read the repaint as a heal, not report a new drop:
2157 // otherwise the pump discards the repaint and loops on resyncs.
2158 let mut state = lock(&shared.state);
2159 state.stdout.append(b"two".to_vec());
2160 state.stdout.append(b"three".to_vec());
2161 state.stdout.reset_to(b"REPAINT".to_vec());
2162 state.ended = true;
2163 }
2164 let repaint = reader.next(Duration::from_millis(50));
2165 let ReadStep::Chunk(repaint) = repaint else {
2166 panic!("expected the repaint chunk, got {repaint:?}");
2167 };
2168 assert_eq!(repaint, b"REPAINT");
2169 assert!(
2170 !reader.took_drop(),
2171 "reading a reset repaint is a heal, not a fall-behind drop"
2172 );
2173 assert!(
2174 reader.took_reset(),
2175 "the reset repaint is surfaced as a took_reset event so the pump can \
2176 drop stale terminal-local backlog buffered ahead of it"
2177 );
2178 assert!(!reader.took_reset(), "took_reset clears the latch");
2179 }
2180
2181 #[test]
2182 fn reader_reset_supersedes_a_previously_latched_drop() {
2183 let shared = test_shared();
2184 {
2185 // A small head plus a cap-sized chunk overflows the ring, evicting
2186 // the head so the first read below latches a drop.
2187 let mut state = lock(&shared.state);
2188 state.stdout.append(b"HEAD".to_vec());
2189 state.stdout.append(vec![b'x'; STREAM_BUFFER_CAP_BYTES]);
2190 }
2191 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2192
2193 // Read the surviving chunk. The drop is latched but not yet observed,
2194 // the way the output pump reads a chunk and only checks took_drop at the
2195 // end of its loop iteration.
2196 assert!(matches!(
2197 reader.next(Duration::from_millis(50)),
2198 ReadStep::Chunk(_)
2199 ));
2200
2201 {
2202 // A repaint supersedes the stream before that pending drop is
2203 // observed. The repaint heals the drop too, so the drop latch must
2204 // not survive to trigger a resync that would discard the repaint.
2205 let mut state = lock(&shared.state);
2206 state.stdout.reset_to(b"REPAINT".to_vec());
2207 state.ended = true;
2208 }
2209 let repaint = reader.next(Duration::from_millis(50));
2210 let ReadStep::Chunk(repaint) = repaint else {
2211 panic!("expected the repaint chunk, got {repaint:?}");
2212 };
2213 assert_eq!(repaint, b"REPAINT");
2214 assert!(reader.took_reset(), "the repaint is surfaced as a reset");
2215 assert!(
2216 !reader.took_drop(),
2217 "the reset superseded the stale drop latch, so no redundant resync \
2218 clobbers the repaint"
2219 );
2220 }
2221
2222 #[test]
2223 fn reader_reports_a_drop_when_output_evicts_the_repaint_before_it_is_read() {
2224 let shared = test_shared();
2225 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2226 {
2227 let mut state = lock(&shared.state);
2228 state.stdout.append(b"one".to_vec());
2229 }
2230 // Consume the first chunk cleanly: no drop, no reset yet.
2231 assert!(matches!(
2232 reader.next(Duration::from_millis(50)),
2233 ReadStep::Chunk(_)
2234 ));
2235 assert!(!reader.took_drop());
2236 assert!(!reader.took_reset());
2237
2238 {
2239 // A repaint resets the ring, then a burst larger than the cap evicts
2240 // that repaint before the reader observes the reset. The reader is
2241 // now about to hand the terminal a torn post-repaint suffix, not the
2242 // repaint. It must still report a drop so the pump resyncs for a
2243 // fresh repaint, rather than leaving the terminal on an arbitrary
2244 // fragment when the stream then goes idle.
2245 let mut state = lock(&shared.state);
2246 state.stdout.reset_to(b"REPAINT".to_vec());
2247 state.stdout.append(vec![b'x'; STREAM_BUFFER_CAP_BYTES + 1]);
2248 state.ended = true;
2249 }
2250 let chunk = reader.next(Duration::from_millis(50));
2251 let ReadStep::Chunk(chunk) = chunk else {
2252 panic!("expected the retained suffix, got {chunk:?}");
2253 };
2254 assert_ne!(chunk, b"REPAINT", "the repaint was evicted by the burst");
2255 assert!(reader.took_reset(), "a reset did occur");
2256 assert!(
2257 reader.took_drop(),
2258 "the repaint was evicted after the reset, so the reader reports a \
2259 drop and the pump resyncs instead of showing a torn suffix"
2260 );
2261 }
2262
2263 #[test]
2264 fn reader_try_next_batch_drains_buffered_chunks() {
2265 let shared = test_shared();
2266 {
2267 let mut state = lock(&shared.state);
2268 state.stdout.append(b"one".to_vec());
2269 state.stdout.append(b"two".to_vec());
2270 state.stdout.append(b"three".to_vec());
2271 state.ended = true;
2272 }
2273 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2274
2275 // next() takes the first chunk; try_next() drains the rest in one batch
2276 // without blocking, then reports the ring is momentarily empty.
2277 let first = reader.next(Duration::from_millis(50));
2278 let ReadStep::Chunk(first) = first else {
2279 panic!("expected the first buffered chunk, got {first:?}");
2280 };
2281 assert_eq!(first, b"one");
2282 assert_eq!(reader.try_next(), Some(b"two".to_vec()));
2283 assert_eq!(reader.try_next(), Some(b"three".to_vec()));
2284 assert!(reader.try_next().is_none(), "the ring is drained");
2285 assert!(!reader.took_drop(), "no eviction, so no drop is latched");
2286 }
2287
2288 #[test]
2289 fn reader_reports_a_front_clip_as_a_drop() {
2290 let shared = test_shared();
2291 {
2292 // Fill the ring to exactly the cap with one piece the reader parks on.
2293 let mut state = lock(&shared.state);
2294 state.stdout.append(vec![b'a'; STREAM_BUFFER_CAP_BYTES]);
2295 }
2296 let mut reader = shared_reader(&shared, OutputStream::Stdout);
2297 {
2298 // A small append overflows by less than the front piece, so the ring
2299 // trims that piece in place rather than evicting it: first_idx holds.
2300 let mut state = lock(&shared.state);
2301 state.stdout.append(b"tail".to_vec());
2302 state.ended = true;
2303 assert_eq!(
2304 state.stdout.first_idx, 0,
2305 "the front piece was clipped, not evicted"
2306 );
2307 }
2308 // The reader is still parked on the clipped piece, so it must latch the
2309 // drop even though first_idx never moved.
2310 let step = reader.next(Duration::from_millis(50));
2311 let ReadStep::Chunk(_) = step else {
2312 panic!("expected the clipped front piece, got {step:?}");
2313 };
2314 assert!(
2315 reader.took_drop(),
2316 "an in-place front clip of the parked piece is a drop"
2317 );
2318 }
2319
2320 fn shared_reader(shared: &Arc<ExecShared>, which: OutputStream) -> StreamReader {
2321 StreamReader {
2322 shared: shared.clone(),
2323 which,
2324 cursor: 0,
2325 dropped: false,
2326 reset: false,
2327 seen_front_clips: 0,
2328 seen_resets: 0,
2329 }
2330 }
2331
2332 use proptest::prelude::*;
2333
2334 proptest! {
2335 /// Under the cap the ring is lossless: it keeps every byte in order,
2336 /// reports no drop, and its accounting matches the input exactly.
2337 #[test]
2338 fn ring_without_overflow_is_lossless(
2339 pieces in proptest::collection::vec(proptest::collection::vec(any::<u8>(), 0..512), 0..32)
2340 ) {
2341 let concat: Vec<u8> = pieces.concat();
2342 prop_assume!(concat.len() <= STREAM_BUFFER_CAP_BYTES);
2343 let mut ring = Ring::default();
2344 for piece in &pieces {
2345 ring.append(piece.clone());
2346 }
2347 prop_assert!(!ring.dropped);
2348 prop_assert_eq!(ring.size, concat.len());
2349 prop_assert_eq!(ring.tail(), concat);
2350 }
2351 }
2352
2353 proptest! {
2354 // Each case allocates ~1 MiB, so keep the case count modest.
2355 #![proptest_config(ProptestConfig::with_cases(48))]
2356
2357 /// Once total output exceeds the cap, the ring drops oldest bytes: it
2358 /// stays byte-exactly at the cap and its retained bytes are always a
2359 /// suffix of everything appended (drops only ever come off the front).
2360 #[test]
2361 fn ring_eviction_keeps_byte_suffix_at_cap(
2362 overflow in 1usize..8192,
2363 tail_pieces in proptest::collection::vec(proptest::collection::vec(any::<u8>(), 0..64), 0..8),
2364 ) {
2365 let head = vec![b'h'; STREAM_BUFFER_CAP_BYTES + overflow];
2366 let mut full = head.clone();
2367 let mut ring = Ring::default();
2368 ring.append(head);
2369 for piece in &tail_pieces {
2370 ring.append(piece.clone());
2371 full.extend_from_slice(piece);
2372 }
2373 prop_assert!(ring.dropped);
2374 prop_assert_eq!(ring.size, STREAM_BUFFER_CAP_BYTES);
2375 let tail = ring.tail();
2376 prop_assert_eq!(tail.len(), STREAM_BUFFER_CAP_BYTES);
2377 prop_assert!(full.ends_with(&tail));
2378 }
2379 }
2380
2381 proptest! {
2382 /// A Snapshot assigns the seq basis regardless of prior seqs (the one
2383 /// deliberate exception to never-rewind), and the ring afterwards holds
2384 /// exactly the repaint.
2385 #[test]
2386 fn pump_snapshot_assigns_basis_and_replaces_ring(
2387 pre_seqs in proptest::collection::vec(0i64..10_000, 0..16),
2388 basis in 0i64..10_000,
2389 ) {
2390 let shared = test_shared();
2391 let mut pump = Pump::new(shared.clone());
2392 for seq in pre_seqs {
2393 pump.apply_frame(chunk(OutputStream::Stdout, seq, b"x"));
2394 }
2395 pump.apply_frame(snapshot_frame(b"repaint", basis));
2396 prop_assert_eq!(pump.stdout_seq, basis);
2397 prop_assert_eq!(lock(&shared.state).stdout.tail(), b"repaint".to_vec());
2398 }
2399 }
2400
2401 proptest! {
2402 /// The per-stream high-water seq is the running max of the seqs seen on
2403 /// that stream and only ever advances, regardless of frame order, so a
2404 /// replayed or out-of-order tail after a reconnect can't lower the
2405 /// resume point, and the two streams are tracked independently.
2406 #[test]
2407 fn pump_seq_is_monotonic_running_max_per_stream(
2408 frames in proptest::collection::vec(
2409 (any::<bool>(), 0i64..10_000, proptest::collection::vec(any::<u8>(), 0..8)),
2410 0..64,
2411 )
2412 ) {
2413 let mut pump = Pump::new(test_shared());
2414 let (mut expect_out, mut expect_err) = (0i64, 0i64);
2415 let (mut prev_out, mut prev_err) = (0i64, 0i64);
2416 for (is_stderr, seq, data) in frames {
2417 let which = if is_stderr { OutputStream::Stderr } else { OutputStream::Stdout };
2418 pump.apply_frame(chunk(which, seq, &data));
2419 if is_stderr {
2420 expect_err = expect_err.max(seq);
2421 } else {
2422 expect_out = expect_out.max(seq);
2423 }
2424 prop_assert_eq!(pump.stdout_seq, expect_out);
2425 prop_assert_eq!(pump.stderr_seq, expect_err);
2426 prop_assert!(pump.stdout_seq >= prev_out);
2427 prop_assert!(pump.stderr_seq >= prev_err);
2428 prev_out = pump.stdout_seq;
2429 prev_err = pump.stderr_seq;
2430 }
2431 }
2432 }
2433}