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clark_agent/
exec.rs

1//! Tool batch execution.
2//!
3//! Canonical prepare / execute / finalize chain for model-emitted tool
4//! calls.
5//!
6//! Two modes:
7//!
8//! - **Parallel** (default): all tools in the batch prep sequentially,
9//!   then run concurrently, then finalize sequentially in source order.
10//! - **Sequential**: each tool is prepped, executed, and finalized
11//!   before the next starts. Triggered by either:
12//!     - any tool in the batch setting `requires_exclusive_sandbox = true`, or
13//!     - `LoopConfig.default_execution_mode = Sequential` (loop-wide pin).
14//!
15//! Hook plumbing:
16//! - `BeforeToolCall::on_before_tool_call` runs after argument validation,
17//!   before `tool.execute`. May `block` to short-circuit with an error
18//!   tool result.
19//! - `AfterToolCall::on_after_tool_call` runs after `tool.execute`. May
20//!   `override_result`, `mark_error`, or vote `terminate`.
21
22use std::sync::Arc;
23use std::time::{Duration, SystemTime, UNIX_EPOCH};
24
25use serde_json::{json, Value};
26use tokio::sync::mpsc;
27use tokio::time::timeout;
28use tokio_util::sync::CancellationToken;
29
30use crate::config::LoopConfig;
31use crate::error::{LoopError, ToolError};
32use crate::event::{AgentEvent, EventSink};
33use crate::plugin::{AfterToolCallContext, BeforeToolCallContext, EventObserver};
34use crate::tool::{detect_arg_parse_error, AgentTool, ExecutionMode, ToolCall, ToolResult};
35use crate::types::{AgentContext, AgentMessage, AssistantContent, ToolResultContent};
36
37const TOOL_UPDATE_DRAIN_GRACE: Duration = Duration::from_millis(50);
38const TOOL_UPDATE_EVENT_QUEUE_CAPACITY: usize = 256;
39
40fn spawn_tool_update_dispatcher(
41    event_sink: Arc<dyn EventSink>,
42    observers: Vec<Arc<dyn EventObserver>>,
43) -> mpsc::Sender<AgentEvent> {
44    let (tx, mut rx) = mpsc::channel::<AgentEvent>(TOOL_UPDATE_EVENT_QUEUE_CAPACITY);
45    tokio::spawn(async move {
46        while let Some(event) = rx.recv().await {
47            event_sink.emit(event.clone()).await;
48            for observer in observers.iter() {
49                observer.on_event(&event).await;
50            }
51        }
52    });
53    tx
54}
55
56fn enqueue_tool_update_event(tx: &mpsc::Sender<AgentEvent>, event: AgentEvent) {
57    match tx.try_send(event) {
58        Ok(()) => {}
59        Err(mpsc::error::TrySendError::Full(_)) => {
60            tracing::warn!("tool update event queue full; dropping partial update");
61        }
62        Err(mpsc::error::TrySendError::Closed(_)) => {}
63    }
64}
65
66/// Result of executing one batch.
67pub(crate) struct ExecutedBatch {
68    /// Tool result messages in source order, ready to push to history.
69    pub messages: Vec<AgentMessage>,
70    /// Unanimous-vote terminate signal: true when every finalized result
71    /// in the batch had `terminate = true`. Empty batches return false.
72    pub terminate: bool,
73}
74
75pub(crate) async fn execute_tool_batch(
76    assistant: &AgentMessage,
77    tool_calls: Vec<ToolCall>,
78    context: &AgentContext,
79    config: &LoopConfig,
80    signal: &CancellationToken,
81    turn_allowlist: Option<&std::collections::HashSet<String>>,
82) -> Result<ExecutedBatch, LoopError> {
83    if tool_calls.is_empty() {
84        return Ok(ExecutedBatch {
85            messages: Vec::new(),
86            terminate: false,
87        });
88    }
89
90    // Let the active protocol policy normalize the batch before registry
91    // lookup — e.g. fold a product's known alias names into a canonical
92    // tool. The default policy is a no-op; the core performs no alias
93    // repair of its own, so no product tool vocabulary lives here.
94    let mut tool_calls = tool_calls;
95    config
96        .protocol
97        .normalize_tool_calls(&mut tool_calls, &config.tools);
98
99    let total_tool_calls = tool_calls.len();
100    let limit_counted_tool_calls = count_limit_counted_tool_calls(&tool_calls, &config.tools);
101    let (tool_calls, unexecuted_tool_calls, max_executed) =
102        split_tool_calls_for_execution(tool_calls, &config.tools, config.max_tool_calls_per_turn);
103
104    let assistant_content = match assistant {
105        AgentMessage::Assistant { content, .. } => content.clone(),
106        _ => AssistantContent { blocks: Vec::new() },
107    };
108
109    if tool_calls.is_empty() {
110        let messages = synthesize_unexecuted_tool_results(
111            assistant,
112            &assistant_content,
113            unexecuted_tool_calls,
114            total_tool_calls,
115            limit_counted_tool_calls,
116            max_executed.unwrap_or(0),
117            context,
118            config,
119        )
120        .await;
121        return Ok(ExecutedBatch {
122            messages,
123            terminate: false,
124        });
125    }
126
127    // A batch downgrades to Sequential when either (a) the loop is
128    // pinned to Sequential mode, or (b) any participating tool needs
129    // exclusive sandbox access.
130    let any_exclusive = tool_calls.iter().any(|call| {
131        config
132            .tools
133            .get(&call.name)
134            .map(|t| t.requires_exclusive_sandbox())
135            .unwrap_or(false)
136    });
137
138    let effective_mode =
139        if any_exclusive || config.default_execution_mode == ExecutionMode::Sequential {
140            ExecutionMode::Sequential
141        } else {
142            ExecutionMode::Parallel
143        };
144
145    let mut batch = match effective_mode {
146        ExecutionMode::Sequential => {
147            execute_sequential(
148                assistant,
149                &assistant_content,
150                tool_calls,
151                context,
152                config,
153                signal,
154                turn_allowlist,
155            )
156            .await
157        }
158        ExecutionMode::Parallel => {
159            execute_parallel(
160                assistant,
161                &assistant_content,
162                tool_calls,
163                context,
164                config,
165                signal,
166                turn_allowlist,
167            )
168            .await
169        }
170    }?;
171
172    if !unexecuted_tool_calls.is_empty() {
173        batch.messages.extend(
174            synthesize_unexecuted_tool_results(
175                assistant,
176                &assistant_content,
177                unexecuted_tool_calls,
178                total_tool_calls,
179                limit_counted_tool_calls,
180                max_executed.unwrap_or(0),
181                context,
182                config,
183            )
184            .await,
185        );
186        batch.terminate = false;
187    }
188
189    Ok(batch)
190}
191
192fn split_tool_calls_for_execution(
193    tool_calls: Vec<ToolCall>,
194    tools: &crate::tool::ToolRegistry,
195    max_tool_calls: Option<usize>,
196) -> (Vec<ToolCall>, Vec<ToolCall>, Option<usize>) {
197    let Some(max_tool_calls) = max_tool_calls else {
198        return (tool_calls, Vec::new(), None);
199    };
200    let max_tool_calls = max_tool_calls.max(1);
201    if count_limit_counted_tool_calls(&tool_calls, tools) <= max_tool_calls {
202        return (tool_calls, Vec::new(), Some(max_tool_calls));
203    }
204
205    let mut executable = Vec::with_capacity(tool_calls.len());
206    let mut unexecuted = Vec::new();
207    let mut executed_counted = 0usize;
208    for call in tool_calls {
209        if !tool_counts_toward_call_limit(tools, &call.name) {
210            // Progress-only tools, parallel-safe reads, and malformed calls
211            // that resolve to no registered tool never burn the per-turn cap;
212            // let them all through (see `tool_counts_toward_call_limit`). A
213            // malformed call still lands as a synthetic "no such tool" error
214            // in `prepare_call`; it just cannot preempt a real call's slot.
215            executable.push(call);
216        } else if executed_counted < max_tool_calls {
217            executed_counted += 1;
218            executable.push(call);
219        } else {
220            unexecuted.push(call);
221        }
222    }
223    (executable, unexecuted, Some(max_tool_calls))
224}
225
226fn count_limit_counted_tool_calls(
227    tool_calls: &[ToolCall],
228    tools: &crate::tool::ToolRegistry,
229) -> usize {
230    tool_calls
231        .iter()
232        .filter(|call| tool_counts_toward_call_limit(tools, &call.name))
233        .count()
234}
235
236/// Whether a tool consumes a slot from the per-turn cap.
237///
238/// A call is exempt from the cap when ANY of these hold:
239/// - it opts out of the cap (progress-only signals that report status
240///   without doing work — see [`AgentTool::counts_toward_tool_call_limit`]);
241/// - it is marked parallel-safe (idempotent reads like `web_search`,
242///   `file_read`, `grep`, `glob`);
243/// - it does not resolve to a registered tool at all — an empty/blank name,
244///   or a name no tool exists for.
245///
246/// The last case is the load-bearing one. A call that resolves to no tool
247/// does NO real work: `prepare_call` short-circuits it to a synchronous
248/// "no such tool" error result without ever invoking a tool. Counting it
249/// would let a glitch — e.g. a streamed tool call that arrived with an empty
250/// `name` — spend the turn's only slot and bump a *real* call into the
251/// unexecuted bin. That was observed in production: under
252/// `max_tool_calls_per_turn = 1`, an empty-name call preempted the model's
253/// real next call. A malformed call must never preempt real work; it still
254/// surfaces its error so the model can react next turn.
255///
256/// Note this is the opposite of the *termination*-vote rule: there, an
257/// unresolved name DOES count (see `tool_counts_toward_termination_vote`),
258/// so a stray call cannot accidentally end the run. The asymmetry is
259/// intentional — a malformed call does no work (so it must not spend the
260/// work budget) and is not a satisfied terminator (so it must not vote to
261/// stop).
262fn tool_counts_toward_call_limit(tools: &crate::tool::ToolRegistry, name: &str) -> bool {
263    tools
264        .get(name)
265        .map(|tool| tool.counts_toward_tool_call_limit() && !tool.parallel_safe_per_turn())
266        .unwrap_or(false)
267}
268
269/// Whether a tool's terminate vote is counted in the unanimous-vote
270/// tally. Unknown / unregistered names default to `true` so a stray
271/// tool call cannot accidentally end the run by being treated as
272/// advisory. See `AgentTool::counts_toward_termination_vote`.
273fn tool_counts_toward_termination_vote(tools: &crate::tool::ToolRegistry, name: &str) -> bool {
274    tools
275        .get(name)
276        .map(|tool| tool.counts_toward_termination_vote())
277        .unwrap_or(true)
278}
279
280/// Compute the batch-level terminate signal, ignoring tools that opt
281/// out via `counts_toward_termination_vote() == false`.
282///
283/// The batch terminates iff:
284/// - at least one *counted* tool is present, AND
285/// - every counted tool voted `terminate: true`.
286///
287/// An all-advisory batch (e.g. only progress-note calls) returns
288/// `false` because no counted tool voted yes — progress notes never
289/// end the run on their own.
290///
291/// When the batch terminates AND advisory siblings were skipped from
292/// the tally, emits a structured `tracing::info` line so operators can
293/// measure how often this fallback actually fires in production — a
294/// non-zero rate names which model still needs the safety net.
295fn compute_batch_terminate<'a, I>(tools: &crate::tool::ToolRegistry, votes: I) -> bool
296where
297    I: IntoIterator<Item = (&'a str, bool)>,
298{
299    let mut counted_total = 0usize;
300    let mut counted_terminate = 0usize;
301    let mut terminating: Vec<&'a str> = Vec::new();
302    let mut advisory_skipped: Vec<&'a str> = Vec::new();
303    for (name, terminate) in votes {
304        if !tool_counts_toward_termination_vote(tools, name) {
305            advisory_skipped.push(name);
306            continue;
307        }
308        counted_total += 1;
309        if terminate {
310            counted_terminate += 1;
311            terminating.push(name);
312        }
313    }
314    let terminated = counted_total > 0 && counted_terminate == counted_total;
315    if terminated && !advisory_skipped.is_empty() {
316        tracing::info!(
317            terminating_tools = ?terminating,
318            advisory_tools = ?advisory_skipped,
319            counted_total,
320            "advisory siblings excluded from unanimous termination vote"
321        );
322    }
323    terminated
324}
325
326// The execution helpers share the same loop context tuple. Keeping the
327// signatures explicit is clearer than introducing a one-off bag of references.
328#[allow(clippy::too_many_arguments)]
329async fn synthesize_unexecuted_tool_results(
330    assistant: &AgentMessage,
331    assistant_content: &AssistantContent,
332    tool_calls: Vec<ToolCall>,
333    total_tool_calls: usize,
334    limit_counted_tool_calls: usize,
335    max_executed: usize,
336    context: &AgentContext,
337    config: &LoopConfig,
338) -> Vec<AgentMessage> {
339    let mut messages = Vec::with_capacity(tool_calls.len());
340    for call in tool_calls {
341        let outcome = finalize(
342            assistant,
343            assistant_content,
344            &call,
345            &call.arguments,
346            ExecutedOutcome {
347                result: unexecuted_tool_call_result(
348                    total_tool_calls,
349                    limit_counted_tool_calls,
350                    max_executed,
351                ),
352                is_error: true,
353            },
354            &context.messages,
355            &config.plugins.after_tool_call,
356        )
357        .await;
358        emit_tool_end(config, &call, &outcome).await;
359        messages.push(outcome_to_message(&call, outcome));
360    }
361    messages
362}
363
364fn unexecuted_tool_call_message(
365    total_tool_calls: usize,
366    limit_counted_tool_calls: usize,
367    max_executed: usize,
368) -> String {
369    let call_word = if total_tool_calls == 1 {
370        "tool call"
371    } else {
372        "tool calls"
373    };
374    let limited_call_word = if limit_counted_tool_calls == 1 {
375        "limit-counted tool call"
376    } else {
377        "limit-counted tool calls"
378    };
379    let executed_word = if max_executed == 1 { "call" } else { "calls" };
380    if limit_counted_tool_calls != total_tool_calls {
381        return format!(
382            "This tool call was not executed because the assistant turn emitted \
383             {limit_counted_tool_calls} {limited_call_word} ({total_tool_calls} \
384             {call_word} total, including progress-only calls), but only the \
385             first {max_executed} limit-counted {executed_word} can run in one \
386             turn. The earlier allowed calls already ran. Reissue this call in \
387             a later turn, one tool call at a time."
388        );
389    }
390    format!(
391        "This tool call was not executed because the assistant turn emitted \
392         {total_tool_calls} {call_word}, but only the first {max_executed} \
393         {executed_word} can run in one turn. The earlier {max_executed} \
394         {executed_word} already ran. Reissue this call in a later turn, \
395         one tool call at a time."
396    )
397}
398
399fn unexecuted_tool_call_result(
400    total_tool_calls: usize,
401    limit_counted_tool_calls: usize,
402    max_executed: usize,
403) -> ToolResult {
404    let mut result = ToolResult::error(unexecuted_tool_call_message(
405        total_tool_calls,
406        limit_counted_tool_calls,
407        max_executed,
408    ));
409    result.details = json!({
410        "kind": "tool_call_not_executed",
411        "reason": "max_tool_calls_per_turn",
412        "total_tool_calls": total_tool_calls,
413        "limit_counted_tool_calls": limit_counted_tool_calls,
414        "max_executed": max_executed,
415    });
416    result
417}
418
419#[allow(clippy::too_many_arguments)]
420async fn execute_sequential(
421    assistant: &AgentMessage,
422    assistant_content: &AssistantContent,
423    tool_calls: Vec<ToolCall>,
424    context: &AgentContext,
425    config: &LoopConfig,
426    signal: &CancellationToken,
427    turn_allowlist: Option<&std::collections::HashSet<String>>,
428) -> Result<ExecutedBatch, LoopError> {
429    let mut messages = Vec::with_capacity(tool_calls.len());
430    let mut votes: Vec<(String, bool)> = Vec::with_capacity(tool_calls.len());
431
432    for call in tool_calls {
433        let outcome = run_one(
434            assistant,
435            assistant_content,
436            &call,
437            context,
438            config,
439            signal,
440            turn_allowlist,
441        )
442        .await?;
443        votes.push((call.name.clone(), outcome.terminate));
444        messages.push(outcome_to_message(&call, outcome));
445    }
446
447    let terminate =
448        compute_batch_terminate(&config.tools, votes.iter().map(|(n, t)| (n.as_str(), *t)));
449
450    Ok(ExecutedBatch {
451        messages,
452        terminate,
453    })
454}
455
456#[allow(clippy::too_many_arguments)]
457async fn execute_parallel(
458    assistant: &AgentMessage,
459    assistant_content: &AssistantContent,
460    tool_calls: Vec<ToolCall>,
461    context: &AgentContext,
462    config: &LoopConfig,
463    signal: &CancellationToken,
464    turn_allowlist: Option<&std::collections::HashSet<String>>,
465) -> Result<ExecutedBatch, LoopError> {
466    use futures::stream::{FuturesUnordered, StreamExt};
467
468    // Per-batch cancellation lever. As a child of `signal` it auto-
469    // cancels when the run-wide signal cancels (so tools react to the
470    // user's abort). It can also be cancelled independently on
471    // sibling-error opt-in (`AgentTool::aborts_siblings_on_error`),
472    // propagating only to siblings in *this* batch — neither sibling
473    // failures nor sibling-triggered cancels affect the run-wide
474    // signal.
475    let batch_token = signal.child_token();
476
477    // Prep + emit starts sequentially so validation and event ordering are
478    // deterministic. A start means the real tool implementation is about to
479    // run; parse, registry, validation, and before-hook failures never start.
480    let mut prepared: Vec<(ToolCall, PreparedCall)> = Vec::with_capacity(tool_calls.len());
481    for call in tool_calls {
482        let prep = prepare_call(
483            assistant,
484            assistant_content,
485            &call,
486            context,
487            config,
488            turn_allowlist,
489        )
490        .await;
491        if matches!(prep, PreparedCall::Prepared { .. }) {
492            emit_tool_start(config, &call).await;
493        }
494        prepared.push((call, prep));
495    }
496
497    let mut futures = Vec::with_capacity(prepared.len());
498    let mut immediate: Vec<(usize, ToolCall, FinalizedOutcome)> = Vec::new();
499
500    for (idx, (call, prep)) in prepared.into_iter().enumerate() {
501        match prep {
502            PreparedCall::Immediate(executed) => {
503                // Route Immediate outcomes through finalize so
504                // AfterToolCall hooks observe every tool result —
505                // including arg-parse / validation / before-block
506                // errors. The `args` we hand to hooks is the original
507                // (potentially sentinel-bearing) call arguments since
508                // we never built prepared args for short-circuited
509                // calls.
510                let finalized = finalize(
511                    assistant,
512                    assistant_content,
513                    &call,
514                    &call.arguments,
515                    executed,
516                    &context.messages,
517                    &config.plugins.after_tool_call,
518                )
519                .await;
520                immediate.push((idx, call, finalized));
521            }
522            PreparedCall::Prepared { tool, args } => {
523                let tool_signal = batch_token.child_token();
524                let run_signal = signal.clone();
525                let batch_token_clone = batch_token.clone();
526                let assistant_clone = assistant.clone();
527                let assistant_content_clone = assistant_content.clone();
528                let context_messages = context.messages.clone();
529                let after_hooks = config.plugins.after_tool_call.clone();
530                let event_sink = config.event_sink.clone();
531                let event_observers = config.plugins.event_observer.clone();
532                let call_clone = call.clone();
533                let fut = async move {
534                    let id = call_clone.id.clone();
535                    let name = call_clone.name.clone();
536                    let name_for_message = name.clone();
537                    let update_events = spawn_tool_update_dispatcher(event_sink, event_observers);
538                    let executed_result = execute_prepared(
539                        &tool,
540                        &call_clone,
541                        args.clone(),
542                        tool_signal,
543                        Box::new(move |update| {
544                            let event = AgentEvent::ToolExecutionUpdate {
545                                tool_call_id: id.clone(),
546                                tool_name: name.clone(),
547                                partial: update,
548                            };
549                            enqueue_tool_update_event(&update_events, event);
550                        }),
551                    )
552                    .await;
553                    let executed = match executed_result {
554                        Ok(executed) => executed,
555                        Err(LoopError::Aborted)
556                            if batch_token_clone.is_cancelled() && !run_signal.is_cancelled() =>
557                        {
558                            // Sibling abort, not user abort. Convert
559                            // to a recoverable tool result so the
560                            // model sees what happened next turn and
561                            // the unanimous-vote termination rule
562                            // stays intact.
563                            ExecutedOutcome {
564                                result: ToolResult::error(format!(
565                                    "aborted because a sibling tool in the \
566                                     parallel batch errored — re-run this \
567                                     {name_for_message} call after addressing the \
568                                     sibling failure"
569                                )),
570                                is_error: true,
571                            }
572                        }
573                        Err(other) => return Err(other),
574                    };
575                    let finalized = finalize(
576                        &assistant_clone,
577                        &assistant_content_clone,
578                        &call_clone,
579                        &args,
580                        executed,
581                        &context_messages,
582                        &after_hooks,
583                    )
584                    .await;
585                    Ok::<_, LoopError>((idx, call_clone, finalized))
586                };
587                futures.push(fut);
588            }
589        }
590    }
591
592    // Drain futures as they complete. When an opted-in tool returns
593    // an error, cancel `batch_token` so still-running siblings exit
594    // promptly (cooperatively — they must check the signal). The
595    // futures already in flight that complete *before* the trigger
596    // produce their natural result. Cancelled siblings produce a
597    // typed `is_error: true` ToolResult via the match arm above.
598    let mut unordered: FuturesUnordered<_> = futures.into_iter().collect();
599    let mut completed: Vec<(usize, ToolCall, FinalizedOutcome)> =
600        Vec::with_capacity(unordered.len() + immediate.len());
601    while let Some(result) = unordered.next().await {
602        let entry = result?;
603        if entry.2.is_error {
604            let aborts = config
605                .tools
606                .get(&entry.1.name)
607                .map(|t| t.aborts_siblings_on_error())
608                .unwrap_or(false);
609            if aborts && !batch_token.is_cancelled() {
610                batch_token.cancel();
611            }
612        }
613        completed.push(entry);
614    }
615    completed.extend(immediate);
616    completed.sort_by_key(|(idx, _, _)| *idx);
617
618    let mut messages = Vec::with_capacity(completed.len());
619    let mut votes: Vec<(String, bool)> = Vec::with_capacity(completed.len());
620    for (_idx, call, outcome) in completed {
621        emit_tool_end(config, &call, &outcome).await;
622        votes.push((call.name.clone(), outcome.terminate));
623        messages.push(outcome_to_message(&call, outcome));
624    }
625
626    let terminate =
627        compute_batch_terminate(&config.tools, votes.iter().map(|(n, t)| (n.as_str(), *t)));
628
629    Ok(ExecutedBatch {
630        messages,
631        terminate,
632    })
633}
634
635/// Execute one tool call synchronously: prep → execute → finalize.
636/// Used by the sequential path.
637#[allow(clippy::too_many_arguments)]
638async fn run_one(
639    assistant: &AgentMessage,
640    assistant_content: &AssistantContent,
641    call: &ToolCall,
642    context: &AgentContext,
643    config: &LoopConfig,
644    signal: &CancellationToken,
645    turn_allowlist: Option<&std::collections::HashSet<String>>,
646) -> Result<FinalizedOutcome, LoopError> {
647    let prep = prepare_call(
648        assistant,
649        assistant_content,
650        call,
651        context,
652        config,
653        turn_allowlist,
654    )
655    .await;
656    let outcome = match prep {
657        PreparedCall::Immediate(executed) => {
658            finalize(
659                assistant,
660                assistant_content,
661                call,
662                &call.arguments,
663                executed,
664                &context.messages,
665                &config.plugins.after_tool_call,
666            )
667            .await
668        }
669        PreparedCall::Prepared { tool, args } => {
670            emit_tool_start(config, call).await;
671            let event_sink = config.event_sink.clone();
672            let event_observers = config.plugins.event_observer.clone();
673            let id = call.id.clone();
674            let name = call.name.clone();
675            let update_events = spawn_tool_update_dispatcher(event_sink, event_observers);
676            let executed = execute_prepared(
677                &tool,
678                call,
679                args.clone(),
680                signal.clone(),
681                Box::new(move |update| {
682                    let event = AgentEvent::ToolExecutionUpdate {
683                        tool_call_id: id.clone(),
684                        tool_name: name.clone(),
685                        partial: update,
686                    };
687                    enqueue_tool_update_event(&update_events, event);
688                }),
689            )
690            .await?;
691            finalize(
692                assistant,
693                assistant_content,
694                call,
695                &args,
696                executed,
697                &context.messages,
698                &config.plugins.after_tool_call,
699            )
700            .await
701        }
702    };
703
704    emit_tool_end(config, call, &outcome).await;
705    Ok(outcome)
706}
707
708// ─── Internal pipeline ────────────────────────────────────────────
709
710enum PreparedCall {
711    /// Argument validation, parse-error detection, or `BeforeToolCall`
712    /// short-circuited the call. The loop emits the error tool result
713    /// without invoking `tool.execute`, but still runs `AfterToolCall`
714    /// hooks so observers (terminal-message guard, system-reminder hook,
715    /// etc.) see every tool result — successes and failures alike.
716    Immediate(ExecutedOutcome),
717    /// Ready to execute.
718    Prepared {
719        tool: Arc<dyn AgentTool>,
720        args: Value,
721    },
722}
723
724struct ExecutedOutcome {
725    result: ToolResult,
726    is_error: bool,
727}
728
729pub(crate) struct FinalizedOutcome {
730    pub result: ToolResult,
731    pub is_error: bool,
732    pub terminate: bool,
733}
734
735/// Walk every registered `ToolGate` and ask each for a specific reason
736/// it denies `tool_name`. Returns the first specific reason; `None` if
737/// no gate claims responsibility (caller falls back to the active
738/// [`crate::protocol::ProtocolPolicy`], then to the core's generic
739/// hidden-tool message).
740struct GateDenial {
741    reason: String,
742    gate: &'static str,
743}
744
745async fn gate_attributed_denial(
746    tool_name: &str,
747    config: &LoopConfig,
748    messages: &[AgentMessage],
749) -> Option<GateDenial> {
750    let available_tool_names: Vec<&str> = config.tools.iter().map(|t| t.name()).collect();
751    let iteration = messages
752        .iter()
753        .filter(|m| matches!(m, AgentMessage::Assistant { .. }))
754        .count();
755    for gate in &config.plugins.tool_gate {
756        let ctx = crate::plugin::ToolGateContext {
757            iteration,
758            messages,
759            conversation_id: config.conversation_id.as_deref(),
760            available_tool_names: &available_tool_names,
761        };
762        if let Some(reason) = gate.denial_reason(tool_name, ctx).await {
763            return Some(GateDenial {
764                reason,
765                gate: gate.name(),
766            });
767        }
768    }
769    None
770}
771
772async fn prepare_call(
773    assistant: &AgentMessage,
774    assistant_content: &AssistantContent,
775    call: &ToolCall,
776    context: &AgentContext,
777    config: &LoopConfig,
778    turn_allowlist: Option<&std::collections::HashSet<String>>,
779) -> PreparedCall {
780    let Some(tool) = config.tools.get(&call.name) else {
781        return PreparedCall::Immediate(ExecutedOutcome {
782            result: ToolResult::error(format!("Tool `{}` not found", call.name)),
783            is_error: true,
784        });
785    };
786
787    // Hard-enforce per-turn `ToolGate` narrowing. The allowlist filters
788    // what schemas the model SEES; without this check, the model can
789    // hallucinate a tool name that wasn't advertised this turn and the
790    // dispatcher runs it anyway because the registry is global. That was
791    // observed in production: a model called a terminal delivery tool
792    // after a no-work narrowing had dropped it from the catalog, claimed
793    // success without doing any work, and the file it claimed to create
794    // didn't exist. Refuse here so the model sees a typed tool error and
795    // either picks an allowed tool or surfaces an unrecoverable state.
796    //
797    // Message + details are sourced in priority order:
798    //   1. a `ToolGate` that attributes the denial via `denial_reason`;
799    //   2. the active `ProtocolPolicy` (product vocabulary, if any);
800    //   3. the core's generic, vocabulary-free fallback.
801    if let Some(allowlist) = turn_allowlist {
802        if !allowlist.contains(call.name.as_str()) {
803            let attributed = gate_attributed_denial(&call.name, config, &context.messages).await;
804            let (message, details) =
805                match attributed {
806                    Some(denial) => {
807                        let details = crate::protocol::generic_hidden_tool_details(
808                            &call.name,
809                            allowlist,
810                            Some(denial.gate),
811                        );
812                        (denial.reason, details)
813                    }
814                    None => match config.protocol.hidden_tool_error(
815                        crate::protocol::HiddenToolContext {
816                            requested_tool: &call.name,
817                            allowlist,
818                            messages: &context.messages,
819                        },
820                    ) {
821                        Some(err) => (err.message, err.details),
822                        None => (
823                            crate::protocol::generic_hidden_tool_message(&call.name, allowlist),
824                            crate::protocol::generic_hidden_tool_details(
825                                &call.name, allowlist, None,
826                            ),
827                        ),
828                    },
829                };
830            let mut result = ToolResult::error(message);
831            result.details = details;
832            return PreparedCall::Immediate(ExecutedOutcome {
833                result,
834                is_error: true,
835            });
836        }
837    }
838
839    // Provider stream layers wrap a malformed-JSON tool-args buffer in
840    // a sentinel object so we can surface a clean, model-recoverable
841    // error here instead of the cryptic `invalid type: string, expected
842    // struct …` that comes from each tool's `serde_json::from_value`
843    // running over a `Value::String` fallback. Detect the sentinel
844    // before validation/dispatch.
845    if let Some((parse_err, raw)) = detect_arg_parse_error(&call.arguments) {
846        return PreparedCall::Immediate(ExecutedOutcome {
847            result: ToolResult::error(format_arg_parse_error(&call.name, parse_err, raw)),
848            is_error: true,
849        });
850    }
851
852    let prepared_args = tool.prepare_arguments(call.arguments.clone());
853
854    if let Err(err) = tool.validate(&prepared_args) {
855        return PreparedCall::Immediate(ExecutedOutcome {
856            result: ToolResult::error(err.to_string()),
857            is_error: true,
858        });
859    }
860
861    let ctx = BeforeToolCallContext {
862        assistant_message: assistant,
863        assistant_content,
864        tool_call: call,
865        args: &prepared_args,
866        messages: &context.messages,
867    };
868    for hook in &config.plugins.before_tool_call {
869        let decision = hook
870            .on_before_tool_call(BeforeToolCallContext {
871                assistant_message: ctx.assistant_message,
872                assistant_content: ctx.assistant_content,
873                tool_call: ctx.tool_call,
874                args: ctx.args,
875                messages: ctx.messages,
876            })
877            .await;
878        if decision.block {
879            let reason = decision
880                .reason
881                .unwrap_or_else(|| format!("blocked by {}", hook.name()));
882            let mut result = ToolResult::error(reason);
883            if let Some(details) = decision.details {
884                result.details = details;
885            }
886            return PreparedCall::Immediate(ExecutedOutcome {
887                result,
888                is_error: true,
889            });
890        }
891    }
892
893    PreparedCall::Prepared {
894        tool,
895        args: prepared_args,
896    }
897}
898
899async fn execute_prepared(
900    tool: &Arc<dyn AgentTool>,
901    call: &ToolCall,
902    args: Value,
903    signal: CancellationToken,
904    on_update: Box<dyn Fn(ToolResult) + Send + Sync + 'static>,
905) -> Result<ExecutedOutcome, LoopError> {
906    let (tx, mut rx) = mpsc::unbounded_channel::<ToolResult>();
907
908    // Drain partial updates concurrently so they don't backpressure the tool.
909    let mut drain_handle = tokio::spawn(async move {
910        while let Some(partial) = rx.recv().await {
911            on_update(partial);
912        }
913    });
914
915    let result = match tool.execute(&call.id, args, signal, tx).await {
916        Ok(result) => {
917            let is_error = result.is_error;
918            Ok(ExecutedOutcome { result, is_error })
919        }
920        Err(ToolError::Execution(reason)) => Ok(ExecutedOutcome {
921            result: ToolResult::error(ToolError::Execution(reason).to_string()),
922            is_error: true,
923        }),
924        Err(ToolError::Aborted) => Err(LoopError::Aborted),
925        Err(ToolError::Fatal(reason)) => Err(LoopError::ToolFatal {
926            tool: call.name.clone(),
927            reason,
928        }),
929    };
930
931    match timeout(TOOL_UPDATE_DRAIN_GRACE, &mut drain_handle).await {
932        Ok(joined) => {
933            if let Err(error) = joined {
934                tracing::debug!(?error, "tool update dispatcher join failed");
935            }
936        }
937        Err(_) => {
938            drain_handle.abort();
939            if let Err(error) = drain_handle.await {
940                tracing::debug!(?error, "aborted tool update dispatcher");
941            }
942        }
943    }
944    result
945}
946
947#[allow(clippy::too_many_arguments)]
948async fn finalize(
949    assistant: &AgentMessage,
950    _assistant_content: &AssistantContent,
951    call: &ToolCall,
952    args: &Value,
953    mut executed: ExecutedOutcome,
954    messages: &[AgentMessage],
955    after_hooks: &[Arc<dyn crate::plugin::AfterToolCall>],
956) -> FinalizedOutcome {
957    for hook in after_hooks {
958        let ctx = AfterToolCallContext {
959            assistant_message: assistant,
960            tool_call: call,
961            args,
962            result: &executed.result,
963            is_error: executed.is_error,
964            messages,
965        };
966        let decision = hook.on_after_tool_call(ctx).await;
967        if let Some(new_result) = decision.result {
968            executed.is_error = new_result.is_error;
969            executed.result = new_result;
970        }
971        if let Some(mark_error) = decision.mark_error {
972            executed.is_error = mark_error;
973            executed.result.is_error = mark_error;
974        }
975        if let Some(terminate) = decision.terminate {
976            executed.result.terminate = terminate;
977        }
978    }
979
980    FinalizedOutcome {
981        result: executed.result,
982        is_error: executed.is_error,
983        terminate: false,
984    }
985    // Carry forward the result's own `terminate` field as the outcome's
986    // vote. (Done after the after-hooks have had a chance to override.)
987    .with_vote()
988}
989
990impl FinalizedOutcome {
991    fn with_vote(mut self) -> Self {
992        self.terminate = self.result.terminate;
993        self
994    }
995}
996
997fn outcome_to_message(call: &ToolCall, outcome: FinalizedOutcome) -> AgentMessage {
998    let details = match outcome.result.details {
999        serde_json::Value::Null => None,
1000        other => Some(other),
1001    };
1002    let message = AgentMessage::ToolResult {
1003        tool_call_id: call.id.clone(),
1004        tool_name: call.name.clone(),
1005        content: ToolResultContent {
1006            blocks: outcome.result.content,
1007        },
1008        is_error: outcome.is_error,
1009        // Carry the row-caption prose ("Ran `ls`.", "Wrote
1010        // `index.html` (4 KB).") into the persisted history so
1011        // history-aware plugins (working_memory_anchor, smart_context,
1012        // history_repair) see the same prose the UI renders without
1013        // having to walk content blocks past densification headers.
1014        narration: outcome.result.narration,
1015        // Carry the host-side structured payload so downstream plugins
1016        // (delivery gates, artifact dispatchers, …) can read canonical
1017        // fields without text-grepping the prose body. Stripped from
1018        // provider wire formats — the model still sees `content` only.
1019        details,
1020        timestamp: Some(now_ms()),
1021    };
1022    // Instrumentation: the post-`AfterToolCall` boundary is where any
1023    // plugin-driven `override_result` has already landed. Logging the
1024    // final content text head/tail at this point lets
1025    // `RUST_LOG=clark_agent::exec::tool_result_built=debug` captures show
1026    // what actually enters `messages` per turn — useful for triangulating
1027    // any divergence between a tool's emitted args and the user-visible
1028    // result a downstream terminal walker later selects.
1029    if let AgentMessage::ToolResult {
1030        content,
1031        is_error,
1032        tool_call_id,
1033        tool_name,
1034        ..
1035    } = &message
1036    {
1037        let plain = content.plain_text();
1038        let (head, tail) = head_tail_for_log(&plain);
1039        tracing::debug!(
1040            target: "clark_agent::exec::tool_result_built",
1041            tool_call_id = %tool_call_id,
1042            tool_name = %tool_name,
1043            is_error = *is_error,
1044            content_len = plain.len(),
1045            content_head = %head,
1046            content_tail = %tail,
1047            "outcome_to_message wrote ToolResult into messages"
1048        );
1049    }
1050    message
1051}
1052
1053const TOOL_RESULT_LOG_HEAD: usize = 200;
1054const TOOL_RESULT_LOG_TAIL: usize = 200;
1055
1056/// Head/tail snippets of a tool-result text for diagnostic logging.
1057/// Avoids dumping multi-KB tool outputs into the trace stream while
1058/// still making divergence between two snapshots of the "same" text
1059/// visible at a glance.
1060fn head_tail_for_log(text: &str) -> (String, String) {
1061    if text.len() <= TOOL_RESULT_LOG_HEAD + TOOL_RESULT_LOG_TAIL {
1062        return (text.to_string(), String::new());
1063    }
1064    let head_end = char_boundary_at_or_before(text, TOOL_RESULT_LOG_HEAD);
1065    let tail_start = char_boundary_at_or_after(text, text.len() - TOOL_RESULT_LOG_TAIL);
1066    (text[..head_end].to_string(), text[tail_start..].to_string())
1067}
1068
1069fn char_boundary_at_or_before(text: &str, mut idx: usize) -> usize {
1070    if idx >= text.len() {
1071        return text.len();
1072    }
1073    while idx > 0 && !text.is_char_boundary(idx) {
1074        idx -= 1;
1075    }
1076    idx
1077}
1078
1079fn char_boundary_at_or_after(text: &str, mut idx: usize) -> usize {
1080    if idx >= text.len() {
1081        return text.len();
1082    }
1083    while idx < text.len() && !text.is_char_boundary(idx) {
1084        idx += 1;
1085    }
1086    idx
1087}
1088
1089fn now_ms() -> u64 {
1090    SystemTime::now()
1091        .duration_since(UNIX_EPOCH)
1092        .map(|d| d.as_millis() as u64)
1093        .unwrap_or(0)
1094}
1095
1096async fn emit_tool_start(config: &LoopConfig, call: &ToolCall) {
1097    let event = AgentEvent::ToolExecutionStart {
1098        tool_call_id: call.id.clone(),
1099        tool_name: call.name.clone(),
1100        args: call.arguments.clone(),
1101    };
1102    config.event_sink.emit(event.clone()).await;
1103    for o in &config.plugins.event_observer {
1104        o.on_event(&event).await;
1105    }
1106}
1107
1108/// Build a human-readable, model-recoverable error for an argument
1109/// payload that failed JSON parsing in the provider stream layer. Shape
1110/// the message so the model knows (1) it was a syntax problem, not a
1111/// schema problem, (2) what raw text it produced, and (3) what to do
1112/// next. Truncate the raw payload to keep error contexts bounded.
1113fn format_arg_parse_error(tool_name: &str, parse_err: &str, raw: &str) -> String {
1114    const RAW_MAX: usize = 1024;
1115    let raw_snippet = if raw.len() > RAW_MAX {
1116        format!(
1117            "{}…<{} bytes truncated>",
1118            &raw[..RAW_MAX],
1119            raw.len() - RAW_MAX
1120        )
1121    } else {
1122        raw.to_string()
1123    };
1124    format!(
1125        "Tool `{tool_name}` arguments were not valid JSON: {parse_err}. \
1126         You sent (raw): {raw_snippet}. \
1127         Re-emit the call with a JSON object matching the tool's schema; \
1128         this is a syntax error in your tool-call arguments, not a problem \
1129         with the file or the runtime."
1130    )
1131}
1132
1133async fn emit_tool_end(config: &LoopConfig, call: &ToolCall, outcome: &FinalizedOutcome) {
1134    let event = AgentEvent::ToolExecutionEnd {
1135        tool_call_id: call.id.clone(),
1136        tool_name: call.name.clone(),
1137        result: outcome.result.clone(),
1138        is_error: outcome.is_error,
1139    };
1140    config.event_sink.emit(event.clone()).await;
1141    for o in &config.plugins.event_observer {
1142        o.on_event(&event).await;
1143    }
1144}
1145
1146#[cfg(test)]
1147mod tests {
1148    use super::*;
1149    use crate::ToolResultBlock;
1150    use std::sync::Arc;
1151
1152    struct LimitTool {
1153        name: &'static str,
1154        counts: bool,
1155        vote_counts: bool,
1156        parallel_safe: bool,
1157    }
1158
1159    #[async_trait::async_trait]
1160    impl AgentTool for LimitTool {
1161        fn name(&self) -> &str {
1162            self.name
1163        }
1164
1165        fn description(&self) -> &str {
1166            "test tool"
1167        }
1168
1169        fn parameters_schema(&self) -> Value {
1170            json!({"type": "object"})
1171        }
1172
1173        fn counts_toward_tool_call_limit(&self) -> bool {
1174            self.counts
1175        }
1176
1177        fn parallel_safe_per_turn(&self) -> bool {
1178            self.parallel_safe
1179        }
1180
1181        fn counts_toward_termination_vote(&self) -> bool {
1182            self.vote_counts
1183        }
1184
1185        async fn execute(
1186            &self,
1187            _call_id: &str,
1188            _args: Value,
1189            _signal: CancellationToken,
1190            _update: mpsc::UnboundedSender<ToolResult>,
1191        ) -> Result<ToolResult, ToolError> {
1192            unreachable!("split tests do not execute tools")
1193        }
1194    }
1195
1196    fn registry() -> crate::tool::ToolRegistry {
1197        // Same registry the call-limit tests use plus the
1198        // termination-vote opt-out: `message_info` is advisory, the
1199        // other tools count.
1200        crate::tool::ToolRegistry::new()
1201            .with(Arc::new(LimitTool {
1202                name: "message_info",
1203                counts: false,
1204                vote_counts: false,
1205                parallel_safe: false,
1206            }))
1207            .with(Arc::new(LimitTool {
1208                name: "browser_navigate",
1209                counts: true,
1210                vote_counts: true,
1211                parallel_safe: true,
1212            }))
1213            .with(Arc::new(LimitTool {
1214                name: "browser_capture",
1215                counts: true,
1216                vote_counts: true,
1217                parallel_safe: true,
1218            }))
1219            .with(Arc::new(LimitTool {
1220                name: "browser_inspect",
1221                counts: true,
1222                vote_counts: true,
1223                parallel_safe: true,
1224            }))
1225            .with(Arc::new(LimitTool {
1226                name: "shell",
1227                counts: true,
1228                vote_counts: true,
1229                parallel_safe: false,
1230            }))
1231            .with(Arc::new(LimitTool {
1232                name: "message_result",
1233                counts: true,
1234                vote_counts: true,
1235                parallel_safe: false,
1236            }))
1237            .with(Arc::new(LimitTool {
1238                name: "message_ask",
1239                counts: true,
1240                vote_counts: true,
1241                parallel_safe: false,
1242            }))
1243            .with(Arc::new(LimitTool {
1244                name: "web_search",
1245                counts: true,
1246                vote_counts: true,
1247                parallel_safe: true,
1248            }))
1249            .with(Arc::new(LimitTool {
1250                name: "file_read",
1251                counts: true,
1252                vote_counts: true,
1253                parallel_safe: true,
1254            }))
1255    }
1256
1257    fn call(name: &str) -> ToolCall {
1258        ToolCall {
1259            id: format!("tc-{name}"),
1260            name: name.to_string(),
1261            arguments: Value::Null,
1262        }
1263    }
1264
1265    fn names(calls: &[ToolCall]) -> Vec<&str> {
1266        calls.iter().map(|call| call.name.as_str()).collect()
1267    }
1268
1269    #[test]
1270    fn progress_only_tools_do_not_starve_first_work_tool() {
1271        let registry = registry();
1272        let (executable, unexecuted, max) = split_tool_calls_for_execution(
1273            vec![call("message_info"), call("browser_navigate")],
1274            &registry,
1275            Some(1),
1276        );
1277
1278        assert_eq!(max, Some(1));
1279        assert_eq!(names(&executable), vec!["message_info", "browser_navigate"]);
1280        assert!(unexecuted.is_empty());
1281    }
1282
1283    #[test]
1284    fn extra_limit_counted_tools_still_get_synthetic_errors() {
1285        let registry = registry();
1286        let (executable, unexecuted, max) = split_tool_calls_for_execution(
1287            vec![call("message_info"), call("shell"), call("message_result")],
1288            &registry,
1289            Some(1),
1290        );
1291
1292        assert_eq!(max, Some(1));
1293        assert_eq!(names(&executable), vec!["message_info", "shell"]);
1294        assert_eq!(names(&unexecuted), vec!["message_result"]);
1295    }
1296
1297    #[test]
1298    fn parallel_safe_reads_do_not_burn_the_per_turn_cap() {
1299        // Two web_searches + one browser_navigate in a single turn:
1300        // before this change the second web_search would be dropped with
1301        // "only the first 1 call can run". After, the parallel-safe
1302        // reads execute alongside the one counted work tool.
1303        let registry = registry();
1304        let (executable, unexecuted, max) = split_tool_calls_for_execution(
1305            vec![
1306                call("web_search"),
1307                call("web_search"),
1308                call("browser_navigate"),
1309            ],
1310            &registry,
1311            Some(1),
1312        );
1313
1314        assert_eq!(max, Some(1));
1315        assert_eq!(
1316            names(&executable),
1317            vec!["web_search", "web_search", "browser_navigate"]
1318        );
1319        assert!(
1320            unexecuted.is_empty(),
1321            "unexecuted: {:?}",
1322            names(&unexecuted)
1323        );
1324    }
1325
1326    #[test]
1327    fn parallel_safe_reads_do_not_compete_with_a_write_for_the_cap() {
1328        // shell (write) still gets its single slot; the parallel-safe
1329        // reads pass through. A second shell would still be dropped.
1330        let registry = registry();
1331        let (executable, unexecuted, max) = split_tool_calls_for_execution(
1332            vec![
1333                call("file_read"),
1334                call("file_read"),
1335                call("shell"),
1336                call("shell"),
1337            ],
1338            &registry,
1339            Some(1),
1340        );
1341
1342        assert_eq!(max, Some(1));
1343        assert_eq!(names(&executable), vec!["file_read", "file_read", "shell"]);
1344        assert_eq!(names(&unexecuted), vec!["shell"]);
1345    }
1346
1347    #[test]
1348    fn browser_tools_do_not_burn_the_per_turn_cap() {
1349        // Browser tools require exclusive sandbox access, so the
1350        // executor still runs this batch sequentially. They are
1351        // nevertheless safe to admit together in one assistant turn:
1352        // a model often opens two related URLs, captures one page, and
1353        // inspects another before yielding. The per-turn cap should
1354        // not drop the later browser calls.
1355        let registry = registry();
1356        let (executable, unexecuted, max) = split_tool_calls_for_execution(
1357            vec![
1358                call("browser_navigate"),
1359                call("browser_navigate"),
1360                call("browser_capture"),
1361                call("browser_inspect"),
1362                call("shell"),
1363            ],
1364            &registry,
1365            Some(1),
1366        );
1367
1368        assert_eq!(max, Some(1));
1369        assert_eq!(
1370            names(&executable),
1371            vec![
1372                "browser_navigate",
1373                "browser_navigate",
1374                "browser_capture",
1375                "browser_inspect",
1376                "shell",
1377            ]
1378        );
1379        assert!(
1380            unexecuted.is_empty(),
1381            "unexecuted: {:?}",
1382            names(&unexecuted)
1383        );
1384    }
1385
1386    #[test]
1387    fn malformed_calls_do_not_burn_the_cap_or_preempt_real_work() {
1388        // A call that resolves to no registered tool (unknown name, or an
1389        // empty/blank name from a streaming glitch) does no real work — it
1390        // only yields a synthetic "no such tool" error in `prepare_call`. It
1391        // must NOT spend the turn's slot, or it bumps a real call into the
1392        // unexecuted bin. Regression for a production case where, under
1393        // `max_tool_calls_per_turn = 1`, an empty-name call preempted the
1394        // model's real next call.
1395        let registry = registry();
1396
1397        // Unknown name first, real counting tool second: both run; nothing deferred.
1398        let (executable, unexecuted, _) = split_tool_calls_for_execution(
1399            vec![call("missing"), call("shell")],
1400            &registry,
1401            Some(1),
1402        );
1403        assert_eq!(names(&executable), vec!["missing", "shell"]);
1404        assert!(
1405            unexecuted.is_empty(),
1406            "real work must not be preempted by an unknown name: {:?}",
1407            names(&unexecuted)
1408        );
1409
1410        // Empty name first (the prod glitch shape): the real call still runs.
1411        let (executable, unexecuted, _) =
1412            split_tool_calls_for_execution(vec![call(""), call("shell")], &registry, Some(1));
1413        assert_eq!(names(&executable), vec!["", "shell"]);
1414        assert!(
1415            unexecuted.is_empty(),
1416            "empty-name glitch must not preempt real work: {:?}",
1417            names(&unexecuted)
1418        );
1419
1420        // Two real counting tools: the cap still bites — the second is deferred.
1421        let (executable, unexecuted, _) =
1422            split_tool_calls_for_execution(vec![call("shell"), call("shell")], &registry, Some(1));
1423        assert_eq!(names(&executable), vec!["shell"]);
1424        assert_eq!(names(&unexecuted), vec!["shell"]);
1425    }
1426
1427    #[test]
1428    fn compute_batch_terminate_passes_when_only_advisory_siblings_dont_vote() {
1429        // Some models tail a terminating delivery call with a polite,
1430        // advisory sign-off call that opts out of the termination vote
1431        // (`counts_toward_termination_vote == false`). Under a strict
1432        // every-result-must-vote rule the trailing advisory call
1433        // (terminate=false) would block termination and the run would
1434        // grind to its iteration cap. With the advisory opt-out the
1435        // batch terminates on the strength of the delivery call alone.
1436        let registry = registry();
1437        let votes = [("message_result", true), ("message_info", false)];
1438        assert!(compute_batch_terminate(
1439            &registry,
1440            votes.iter().map(|(n, t)| (*n, *t))
1441        ));
1442    }
1443
1444    #[test]
1445    fn compute_batch_terminate_fails_when_any_counted_tool_did_not_vote_terminate() {
1446        let registry = registry();
1447        // `message_result` voted yes, but a real work tool (`shell`)
1448        // is still mid-flight or didn't vote — keep running.
1449        let votes = [("message_result", true), ("shell", false)];
1450        assert!(!compute_batch_terminate(
1451            &registry,
1452            votes.iter().map(|(n, t)| (*n, *t))
1453        ));
1454    }
1455
1456    #[test]
1457    fn compute_batch_terminate_returns_false_for_all_advisory_batches() {
1458        // An all-`message_info` batch must NEVER end the run; progress
1459        // notes are status, not termination, even when the model
1460        // emits several in a row.
1461        let registry = registry();
1462        let votes = [("message_info", false), ("message_info", false)];
1463        assert!(!compute_batch_terminate(
1464            &registry,
1465            votes.iter().map(|(n, t)| (*n, *t))
1466        ));
1467    }
1468
1469    #[test]
1470    fn compute_batch_terminate_returns_false_for_empty_batch() {
1471        let registry = registry();
1472        let votes: Vec<(&str, bool)> = Vec::new();
1473        assert!(!compute_batch_terminate(&registry, votes.into_iter()));
1474    }
1475
1476    #[test]
1477    fn compute_batch_terminate_treats_unknown_tools_as_counted() {
1478        // Unknown / unregistered tool names default to counted so a
1479        // stray call cannot accidentally terminate the run by being
1480        // silently classified as advisory.
1481        let registry = registry();
1482        // `message_result` voted yes, but an unknown tool emitted
1483        // `terminate=false`. Unknown counts → must not terminate.
1484        let votes = [("message_result", true), ("ghost_tool", false)];
1485        assert!(!compute_batch_terminate(
1486            &registry,
1487            votes.iter().map(|(n, t)| (*n, *t))
1488        ));
1489
1490        // And the symmetric case: an unknown tool that voted yes,
1491        // alongside `message_result` voting yes → still counted, so
1492        // the batch terminates.
1493        let votes = [("message_result", true), ("ghost_tool", true)];
1494        assert!(compute_batch_terminate(
1495            &registry,
1496            votes.iter().map(|(n, t)| (*n, *t))
1497        ));
1498    }
1499
1500    #[test]
1501    fn compute_batch_terminate_passes_when_message_ask_is_only_counted_terminator() {
1502        // Symmetric to the message_result case: message_ask (also a
1503        // terminating tool) tailed by message_info still terminates.
1504        let registry = registry();
1505        let votes = [("message_ask", true), ("message_info", false)];
1506        assert!(compute_batch_terminate(
1507            &registry,
1508            votes.iter().map(|(n, t)| (*n, *t))
1509        ));
1510    }
1511
1512    #[test]
1513    fn head_tail_for_log_returns_full_text_when_short() {
1514        // Short payloads (≤ HEAD+TAIL) round-trip in `head` with an
1515        // empty `tail` so the trace line stays compact and the
1516        // diagnostic reader doesn't have to reconstruct the full
1517        // string from two halves when there's nothing to truncate.
1518        let (head, tail) = head_tail_for_log("hello");
1519        assert_eq!(head, "hello");
1520        assert_eq!(tail, "");
1521    }
1522
1523    #[test]
1524    fn head_tail_for_log_truncates_long_text_with_head_and_tail() {
1525        let payload: String = "abc".repeat(500);
1526        assert!(payload.len() > TOOL_RESULT_LOG_HEAD + TOOL_RESULT_LOG_TAIL);
1527        let (head, tail) = head_tail_for_log(&payload);
1528        assert_eq!(head.len(), TOOL_RESULT_LOG_HEAD);
1529        assert_eq!(tail.len(), TOOL_RESULT_LOG_TAIL);
1530        // First/last bytes must come from the original — guards
1531        // against a regression where the helper accidentally re-orders
1532        // or drops the boundary characters.
1533        assert!(payload.starts_with(&head));
1534        assert!(payload.ends_with(&tail));
1535    }
1536
1537    #[test]
1538    fn head_tail_for_log_respects_utf8_char_boundaries() {
1539        // Multi-byte chars must not be split mid-codepoint or the
1540        // tracing macro would panic (and instrumentation would crash
1541        // the loop). Build a payload long enough to truncate, padded
1542        // with multi-byte chars at both boundary regions.
1543        let mid = "πλάκα".repeat(50); // each char is 2 bytes
1544        let prefix: String = "x".repeat(150);
1545        let suffix: String = "y".repeat(150);
1546        let payload = format!("{prefix}{mid}{suffix}");
1547        let (head, tail) = head_tail_for_log(&payload);
1548        // Validity assertions: both slices are valid UTF-8 (they
1549        // already are since they came from `&str`), and the boundary
1550        // is on a char boundary in the original. Round-trip check:
1551        // the head must be a prefix of payload and tail a suffix.
1552        assert!(payload.starts_with(&head));
1553        assert!(payload.ends_with(&tail));
1554        // Head capped at HEAD bytes (last char-boundary at or before).
1555        assert!(head.len() <= TOOL_RESULT_LOG_HEAD);
1556        assert!(tail.len() <= TOOL_RESULT_LOG_TAIL + 1); // +1 for boundary slack
1557    }
1558
1559    #[test]
1560    fn unexecuted_message_mentions_progress_only_calls_when_present() {
1561        let result = unexecuted_tool_call_result(3, 2, 1);
1562        let text = match result.content.first() {
1563            Some(ToolResultBlock::Text(text)) => text.text.as_str(),
1564            _ => panic!("expected text result"),
1565        };
1566
1567        assert!(text.contains("2 limit-counted tool calls"));
1568        assert!(text.contains("3 tool calls total, including progress-only calls"));
1569        assert_eq!(
1570            result
1571                .details
1572                .get("limit_counted_tool_calls")
1573                .and_then(Value::as_u64),
1574            Some(2)
1575        );
1576    }
1577}