datum-core 0.6.0

//! Runtime-checked graph, shape, port, and junction primitives.
//!
//! This module contains Datum's Akka-like graph layer: typed public ports,
//! runtime-validated GraphDSL wiring, fused acyclic fast paths, and a queued
//! fused interpreter for cyclic feedback topologies. Invalid wiring and illegal
//! stage operations fail deterministically.

use std::{
    any::{Any, TypeId, type_name},
    collections::{HashMap, HashSet, VecDeque},
    fmt,
    marker::PhantomData,
    sync::{
        Arc, Mutex, OnceLock,
        atomic::{AtomicUsize, Ordering},
    },
    thread,
};

#[cfg(test)]
use std::sync::mpsc;

use crate::{
    actor::{Actor, ActorProcessingErr, ActorRef},
    stream::{OverflowStrategy, StreamError, StreamResult},
};

type DatumValue = Box<dyn DatumElement>;
type StageMapFn = dyn Fn(DatumValue) -> StreamResult<DatumValue> + Send + Sync;
type StageTypedMapFn = dyn Any + Send + Sync;
type StageZipFn = dyn Fn(DatumValue, DatumValue) -> StreamResult<DatumValue> + Send + Sync;
type StageUnzipFn = dyn Fn(DatumValue) -> (DatumValue, DatumValue) + Send + Sync;
/// Opaque container for a typed split function `Arc<dyn Fn(In) -> (Out0, Out1)>`.
/// Down-cast at plan time — same pattern as [`StageTypedMapFn`].
type StageTypedUnzipFn = dyn Any + Send + Sync;
type StageCompareFn = dyn Fn(&DatumValue, &DatumValue) -> std::cmp::Ordering + Send + Sync;
type StageSequenceFn = dyn Fn(&DatumValue) -> u64 + Send + Sync;
/// Opaque container for a typed sequence-extractor `Arc<dyn Fn(&T) -> u64>`.
/// Down-cast at plan time.
type StageTypedSequenceFn = dyn Any + Send + Sync;
type StageSnapshotFn = dyn Fn(&[&DatumValue]) -> DatumValue + Send + Sync;
/// Opaque container for a typed snapshot builder `Arc<dyn Fn(&[Option<T>]) -> Vec<T>>`.
/// Down-cast at plan time.
type StageTypedSnapshotFn = dyn Any + Send + Sync;
type StagePartitionFn = dyn Fn(&DatumValue) -> usize + Send + Sync;
/// Opaque container for a typed partitioner `Arc<dyn Fn(&T) -> usize>`.
/// Down-cast at plan time.
type StageTypedPartitionFn = dyn Any + Send + Sync;

#[derive(Clone)]
struct StageMapFns {
    erased: Arc<StageMapFn>,
    typed: Arc<StageTypedMapFn>,
}

/// Optional typed metadata attached to an `Opaque` stage so the typed **cyclic**
/// executor can run it without `DatumValue` boxing or `GraphStageLogic`.
///
/// Built-in `Buffer`/`TakeWhile` stages surface this through
/// [`GraphStage::typed_cyclic_op`]; every other stage returns `None` and the
/// cyclic typed planner falls back to the erased queued interpreter. The erased
/// executor never reads this — it keeps running the stage's `GraphStageLogic`.
#[derive(Clone)]
pub(super) enum TypedCyclicOp {
    /// A `Buffer` stage. In the synchronous fused executor a buffer drains one
    /// element per step and therefore never overflows — it is a pass-through.
    BufferPassthrough,
    /// A `TakeWhile` stage carrying its typed predicate
    /// `Arc<dyn Fn(&T) -> bool + Send + Sync>` (down-cast at plan time, same
    /// pattern as [`StageTypedMapFn`]).
    TakeWhile(Arc<dyn Any + Send + Sync>),
}

impl fmt::Debug for TypedCyclicOp {
    fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
        match self {
            Self::BufferPassthrough => f.write_str("BufferPassthrough"),
            Self::TakeWhile(_) => f.write_str("TakeWhile(..)"),
        }
    }
}

pub(crate) trait DatumElement: Any + Send {
    fn clone_box(&self) -> DatumValue;
    fn into_any(self: Box<Self>) -> Box<dyn Any + Send>;
    fn as_any_ref(&self) -> &dyn Any;
}

impl<T> DatumElement for T
where
    T: Any + Clone + Send,
{
    fn clone_box(&self) -> DatumValue {
        Box::new(self.clone())
    }

    fn into_any(self: Box<Self>) -> Box<dyn Any + Send> {
        self
    }

    fn as_any_ref(&self) -> &dyn Any {
        self
    }
}

fn datum<T>(value: T) -> DatumValue
where
    T: Clone + Send + 'static,
{
    Box::new(value)
}

fn downcast_datum<T, S>(
    value: DatumValue,
    operation: &'static str,
    port: impl FnOnce() -> S,
) -> StreamResult<T>
where
    T: Send + 'static,
    S: Into<String>,
{
    // `port` is only evaluated on the cold error path so the success path
    // (the per-element fused hot path) allocates nothing for diagnostics. It
    // returns `impl Into<String>` so callers can hand back a `&'static str`
    // without an eager `to_owned()`.
    value
        .into_any()
        .downcast::<T>()
        .map(|value| *value)
        .map_err(|_| StreamError::InvalidPortOperation {
            operation,
            port: port().into(),
            reason: format!("element type did not match {}", type_name::<T>()),
        })
}

static NEXT_PORT_ID: AtomicUsize = AtomicUsize::new(1);

fn next_port_id() -> PortId {
    PortId(NEXT_PORT_ID.fetch_add(1, Ordering::Relaxed))
}

fn next_port_id_block(count: usize) -> PortId {
    debug_assert!(count > 0);
    PortId(NEXT_PORT_ID.fetch_add(count, Ordering::Relaxed))
}

#[derive(Clone, Copy, Debug, PartialEq, Eq, PartialOrd, Ord, Hash)]
pub struct PortId(usize);

impl PortId {
    #[must_use]
    pub const fn as_usize(self) -> usize {
        self.0
    }

    const fn offset(self, offset: usize) -> Self {
        Self(self.0 + offset)
    }
}

#[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)]
pub enum PortKind {
    Inlet,
    Outlet,
}

macro_rules! shared_name {
    ($fn_name:ident, $value:literal) => {
        fn $fn_name() -> Arc<str> {
            static NAME: OnceLock<Arc<str>> = OnceLock::new();
            Arc::clone(NAME.get_or_init(|| Arc::from($value)))
        }
    };
}

shared_name!(identity_stage_name, "Identity");
shared_name!(identity_inlet_name, "Identity.in");
shared_name!(identity_outlet_name, "Identity.out");
shared_name!(map_stage_name, "Map");
shared_name!(map_inlet_name, "Map.in");
shared_name!(map_outlet_name, "Map.out");
shared_name!(broadcast_stage_name, "Broadcast");
shared_name!(broadcast_inlet_name, "Broadcast.in");
shared_name!(balance_stage_name, "Balance");
shared_name!(balance_inlet_name, "Balance.in");
shared_name!(merge_stage_name, "Merge");
shared_name!(merge_outlet_name, "Merge.out");
shared_name!(merge_preferred_stage_name, "MergePreferred");
shared_name!(merge_preferred_preferred_name, "MergePreferred.preferred");
shared_name!(merge_preferred_outlet_name, "MergePreferred.out");
shared_name!(merge_prioritized_stage_name, "MergePrioritized");
shared_name!(merge_prioritized_outlet_name, "MergePrioritized.out");
shared_name!(concat_stage_name, "Concat");
shared_name!(concat_outlet_name, "Concat.out");
shared_name!(or_else_stage_name, "OrElse");
shared_name!(or_else_primary_name, "OrElse.primary");
shared_name!(or_else_secondary_name, "OrElse.secondary");
shared_name!(or_else_outlet_name, "OrElse.out");
shared_name!(interleave_stage_name, "Interleave");
shared_name!(interleave_outlet_name, "Interleave.out");
shared_name!(zip_stage_name, "Zip");
shared_name!(zip_in0_name, "Zip.in0");
shared_name!(zip_in1_name, "Zip.in1");
shared_name!(zip_outlet_name, "Zip.out");
shared_name!(async_boundary_stage_name, "AsyncBoundary");
shared_name!(async_boundary_inlet_name, "AsyncBoundary.in");
shared_name!(async_boundary_outlet_name, "AsyncBoundary.out");

mod builder;
mod executor;
mod junctions;
mod ports;
mod shapes;
mod stage;

#[cfg(test)]
use self::executor::BoundaryCountExecutor;
use self::{
    builder::StageRecord,
    stage::{StageKind, StageTimerMailbox, StageTimerRuntime},
};

pub use self::{
    builder::{
        AsyncBoundaryExecutionConfig, FusedExecutionConfig, FusedExecutionReport, FusedSegment,
        FusedTerminalReport, Graph, GraphBlueprint, GraphBuilder, GraphDsl, ImportedGraph,
        PartialGraph,
    },
    junctions::{
        AsyncBoundary, Balance, Broadcast, Buffer, Concat, Identity, Interleave, MapStage, Merge,
        MergeLatest, MergePreferred, MergePrioritized, MergeSequence, MergeSorted, OrElse,
        Partition, TakeWhile, Unzip, UnzipWith, Zip,
    },
    ports::{AnyInlet, AnyOutlet, Inlet, Outlet, PortRef},
    shapes::{
        BidiShape, FanInShape, FanOutShape, FanOutShape2, FlowShape, MergePreferredShape,
        PortAllocator, Shape, SinkShape, SourceShape, ZipShape,
    },
    stage::{
        AsyncCallback, GraphStage, GraphStageLogic, InHandler, OutHandler, StageSpec, TimerHandler,
    },
};

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

    #[test]
    fn graph_dsl_builds_broadcast_zip_flow() {
        let graph = GraphDsl::try_create(|builder| {
            let broadcast = builder.add(Broadcast::<i32>::new(2));
            let zip = builder.add(Zip::<i32, i32>::new());

            builder.connect(broadcast.outlet(0)?, zip.in0())?;
            builder.connect(broadcast.outlet(1)?, zip.in1())?;

            Ok(FlowShape::new(broadcast.inlet(), zip.outlet()))
        })
        .unwrap();

        assert_eq!(graph.stage_count(), 2);
        assert_eq!(graph.edge_count(), 2);
        assert_eq!(graph.shape().inlets().len(), 1);
        assert_eq!(graph.shape().outlets().len(), 1);
        assert_eq!(
            graph.run_with_input([1, 2, 3]).unwrap(),
            vec![(1, 1), (2, 2), (3, 3)]
        );
    }

    #[test]
    fn graph_dsl_zip_slots_follow_inlet_ids() {
        let graph = GraphDsl::try_create(|builder| {
            let broadcast = builder.add(Broadcast::<i32>::new(2));
            let identity = builder.add(Identity::<i32>::new());
            let zip = builder.add(Zip::<i32, i32>::new());

            builder.connect(broadcast.outlet(0)?, identity.inlet())?;
            builder.connect(identity.outlet(), zip.in1())?;
            builder.connect(broadcast.outlet(1)?, zip.in0())?;

            Ok(FlowShape::new(broadcast.inlet(), zip.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([1, 2, 3]).unwrap(),
            vec![(1, 1), (2, 2), (3, 3)]
        );
    }

    #[test]
    fn graph_dsl_zip_buffers_skewed_inlet_arrivals() {
        // Regression test for per-inlet Zip buffering. This asymmetric topology
        // delivers TWO elements to zip.in0 for every ONE that reaches zip.in1
        // within a single fused cycle:
        //
        //   in -> Broadcast A(2)
        //          A.out0 -> Broadcast B(2) -> Merge(2).out -> zip.in0   (two arrivals)
        //          A.out1 ----------------------------------> zip.in1   (one arrival)
        //
        // The fused executor drains A.out0 depth-first, so both Merge emissions
        // hit zip.in0 before A.out1 ever feeds zip.in1. With single-slot Zip
        // state this errors ("second element before its pair"); bounded
        // per-inlet buffering must instead queue the surplus and pair in FIFO
        // arrival order without error. Neither Broadcast matches the fused
        // Broadcast(2)->Zip fast path (A feeds two different stages; B feeds a
        // Merge), so this exercises the general buffered Zip path.
        let graph = GraphDsl::try_create(|builder| {
            let fan = builder.add(Broadcast::<i32>::new(2));
            let doubler = builder.add(Broadcast::<i32>::new(2));
            let merge = builder.add(Merge::<i32>::new(2));
            let zip = builder.add(Zip::<i32, i32>::new());

            builder.connect(fan.outlet(0)?, doubler.inlet())?;
            builder.connect(doubler.outlet(0)?, merge.inlet(0)?)?;
            builder.connect(doubler.outlet(1)?, merge.inlet(1)?)?;
            builder.connect(merge.outlet(), zip.in0())?;
            builder.connect(fan.outlet(1)?, zip.in1())?;

            Ok(FlowShape::new(fan.inlet(), zip.outlet()))
        })
        .unwrap();

        // in0 accumulates two per item while in1 gets one, so FIFO pairing runs
        // in0 one item ahead: 10 pairs with 10, then the leftover 10 pairs with
        // 20. The point is that this succeeds (no error) and pairs in order.
        assert_eq!(
            graph.run_with_input([10, 20]).unwrap(),
            vec![(10, 10), (10, 20)]
        );
    }

    #[test]
    fn graph_dsl_runs_merge_preferred_buffered_feedback_cycle() {
        let graph = GraphDsl::try_create(|builder| {
            let merge = builder.add(MergePreferred::<i32>::new(1));
            let broadcast = builder.add(Broadcast::<i32>::new(2));
            let buffer = builder.add(Buffer::<i32>::new(8, OverflowStrategy::Backpressure));
            let positive = builder.add(TakeWhile::<i32>::new(|item| *item > 0));
            let decrement = builder.add(MapStage::new(|item: i32| item - 1));

            builder.connect(merge.outlet(), broadcast.inlet())?;
            builder.connect(broadcast.outlet(1)?, buffer.inlet())?;
            builder.connect(buffer.outlet(), positive.inlet())?;
            builder.connect(positive.outlet(), decrement.inlet())?;
            builder.connect(decrement.outlet(), merge.preferred())?;

            Ok(FlowShape::new(merge.secondary(0)?, broadcast.outlet(0)?))
        })
        .unwrap();

        assert_eq!(graph.run_with_input([3]).unwrap(), vec![3, 2, 1, 0]);
    }

    #[test]
    fn graph_dsl_runs_buffered_merge_feedback_cycle() {
        let graph = GraphDsl::try_create(|builder| {
            let merge = builder.add(Merge::<i32>::new(2));
            let broadcast = builder.add(Broadcast::<i32>::new(2));
            let buffer = builder.add(Buffer::<i32>::new(8, OverflowStrategy::Backpressure));
            let positive = builder.add(TakeWhile::<i32>::new(|item| *item > 0));
            let decrement = builder.add(MapStage::new(|item: i32| item - 1));

            builder.connect(merge.outlet(), broadcast.inlet())?;
            builder.connect(broadcast.outlet(1)?, buffer.inlet())?;
            builder.connect(buffer.outlet(), positive.inlet())?;
            builder.connect(positive.outlet(), decrement.inlet())?;
            builder.connect(decrement.outlet(), merge.inlet(1)?)?;

            Ok(FlowShape::new(merge.inlet(0)?, broadcast.outlet(0)?))
        })
        .unwrap();

        assert_eq!(graph.run_with_input([3]).unwrap(), vec![3, 2, 1, 0]);
    }

    #[test]
    fn graph_dsl_unbuffered_merge_cycle_surfaces_event_limit() {
        let graph = GraphDsl::try_create(|builder| {
            let merge = builder.add(Merge::<i32>::new(2));
            let broadcast = builder.add(Broadcast::<i32>::new(2));

            builder.connect(merge.outlet(), broadcast.inlet())?;
            builder.connect(broadcast.outlet(1)?, merge.inlet(1)?)?;

            Ok(FlowShape::new(merge.inlet(0)?, broadcast.outlet(0)?))
        })
        .unwrap();

        let result = graph.run_with_input_report([1], FusedExecutionConfig { event_limit: 256 });

        assert_eq!(result, Err(StreamError::EventLimitExceeded { limit: 256 }));
    }

    #[test]
    fn partial_graph_can_be_imported_with_its_shape() {
        let partial = GraphDsl::partial(|builder| {
            let first = builder.add(Identity::<i32>::new());
            let second = builder.add_named(Identity::<i32>::new(), "partial.tail");
            builder.connect(first.outlet(), second.inlet())?;
            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .named("partial.identity");

        let graph = GraphDsl::try_create(|builder| {
            let imported = builder.import(&partial)?;
            let after = builder.add(Identity::<i32>::new());
            builder.connect(imported.outlet(), after.inlet())?;
            Ok(FlowShape::new(imported.inlet(), after.outlet()))
        })
        .unwrap()
        .named("outer.graph");

        assert_eq!(graph.run_with_input([1, 2, 3]).unwrap(), vec![1, 2, 3]);
        assert_eq!(graph.attributes().name(), Some("outer.graph"));
    }

    #[test]
    fn graph_attributes_follow_innermost_wins_order() {
        let graph = GraphDsl::create(|builder| {
            builder.add_with_attributes(
                Identity::<i32>::new(),
                Attributes::named("stage-outer").and(Attributes::named("stage-inner")),
            )
        })
        .unwrap()
        .add_attributes(Attributes::dispatcher("graph-outer"))
        .add_attributes(Attributes::dispatcher("graph-inner"));

        assert_eq!(graph.attributes().dispatcher_hint(), Some("graph-inner"));
        assert_eq!(
            graph.stages[0].spec.attributes().name(),
            Some("stage-inner")
        );
    }

    #[test]
    fn graph_dsl_rejects_invalid_and_incomplete_wiring() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(Identity::<i32>::new());
            let second = builder.add(Identity::<i32>::new());
            let third = builder.add(Identity::<i32>::new());

            builder.connect(first.outlet(), second.inlet())?;
            let duplicate = builder.connect(first.outlet(), third.inlet());
            assert!(matches!(duplicate, Err(StreamError::GraphValidation(_))));

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        });

        assert!(matches!(graph, Err(StreamError::GraphValidation(_))));

        let graph = GraphDsl::create(|builder| {
            let broadcast = builder.add(Broadcast::<i32>::new(2));
            SourceShape::new(broadcast.outlet(0).unwrap())
        });
        assert!(matches!(graph, Err(StreamError::GraphValidation(_))));
    }

    #[test]
    fn graph_dsl_rejects_erased_type_mismatch() {
        let graph = GraphDsl::try_create(|builder| {
            let left = builder.add(Identity::<i32>::new());
            let right = builder.add(Identity::<u64>::new());
            let mismatch = builder.connect_any(left.outlet().erase(), right.inlet().erase());
            assert!(matches!(mismatch, Err(StreamError::GraphValidation(_))));
            Ok(FlowShape::new(left.inlet(), right.outlet()))
        });

        assert!(matches!(graph, Err(StreamError::GraphValidation(_))));
    }

    #[test]
    fn graph_dsl_rejects_result_ports_with_spoofed_metadata() {
        let graph = GraphDsl::create(|builder| {
            let shape = builder.add(Identity::<i32>::new());
            FlowShape::new(
                Inlet::<u64>::with_id(shape.inlet().id(), "Identity.in"),
                shape.outlet(),
            )
        });

        assert!(matches!(graph, Err(StreamError::GraphValidation(_))));
    }

    #[test]
    fn allocated_ports_do_not_collide_with_manual_ports() {
        let manual = Inlet::<i32>::new("manual");
        let graph = GraphDsl::try_create(|builder| {
            let shape = builder.add(Identity::<i32>::new());
            assert_ne!(manual.id(), shape.inlet().id());
            Ok(shape)
        });

        assert!(graph.is_ok());
    }

    #[test]
    fn identity_ports_keep_static_names_and_unique_ids() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(Identity::<i32>::new());
            let second = builder.add(Identity::<i32>::new());

            assert_eq!(first.inlet().name(), "Identity.in");
            assert_eq!(first.outlet().name(), "Identity.out");
            assert_eq!(second.inlet().name(), "Identity.in");
            assert_eq!(second.outlet().name(), "Identity.out");
            assert_ne!(first.inlet().id(), first.outlet().id());
            assert_ne!(first.outlet().id(), second.inlet().id());
            assert_ne!(second.inlet().id(), second.outlet().id());

            builder.connect(first.outlet(), second.inlet())?;
            Ok(FlowShape::new(first.inlet(), second.outlet()))
        });

        assert!(graph.is_ok());
    }

    #[test]
    fn graph_stage_logic_checks_port_operations() {
        let shape = FlowShape::new(Inlet::<i32>::new("in"), Outlet::<i32>::new("out"));
        let inlet = shape.inlet();
        let outlet = shape.outlet();
        let mut logic = GraphStageLogic::new(&shape);

        assert!(matches!(
            logic.grab(&inlet),
            Err(StreamError::InvalidPortOperation { .. })
        ));
        logic.pull(&inlet).unwrap();
        assert!(logic.has_been_pulled(&inlet));
        assert!(matches!(
            logic.pull(&inlet),
            Err(StreamError::InvalidPortOperation { .. })
        ));
        logic.offer(&inlet, 41).unwrap();
        assert!(!logic.has_been_pulled(&inlet));
        assert_eq!(logic.grab(&inlet).unwrap(), 41);

        assert!(matches!(
            logic.push(&outlet, 1),
            Err(StreamError::InvalidPortOperation { .. })
        ));
        logic.request(&outlet).unwrap();
        assert!(logic.is_available(&outlet));
        logic.push(&outlet, 42).unwrap();
        assert!(!logic.is_available(&outlet));
        logic.complete(&outlet).unwrap();
        assert!(logic.is_closed(&outlet));
        assert!(matches!(
            logic.request(&outlet),
            Err(StreamError::InvalidPortOperation { .. })
        ));
    }

    #[test]
    fn fused_execution_enforces_event_limit() {
        let graph = GraphDsl::create(|builder| builder.add(Identity::<i32>::new())).unwrap();

        let result = graph.run_with_input_report([1, 2], FusedExecutionConfig { event_limit: 1 });

        assert_eq!(result, Err(StreamError::EventLimitExceeded { limit: 1 }));
    }

    #[test]
    fn async_boundary_splits_fused_segments() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(Identity::<i32>::new());
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item + 1));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        assert_eq!(graph.segments().len(), 3);
        let report = graph
            .run_with_input_report([1, 2], FusedExecutionConfig::default())
            .unwrap();
        assert_eq!(report.output, vec![2, 3]);
        assert_eq!(report.async_boundary_crossings, 2);
    }

    #[test]
    fn async_boundary_count_path_uses_ractor_handoff_segments() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: i32| item + 1));
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item * 2));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let report = graph
            .run_async_boundary_count_with_input_report(
                [1, 2, 3],
                AsyncBoundaryExecutionConfig {
                    fused: FusedExecutionConfig::default(),
                    buffer_size: 2,
                },
            )
            .unwrap();

        assert_eq!(report.result, 3);
        assert_eq!(report.async_boundary_crossings, 3);
        assert_eq!(report.events, 18);
    }

    #[test]
    fn threaded_async_boundary_baseline_matches_ractor_count_path() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: i32| item + 1));
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item * 2));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let config = AsyncBoundaryExecutionConfig {
            fused: FusedExecutionConfig::default(),
            buffer_size: 2,
        };
        let ractor_report = graph
            .run_async_boundary_count_with_input_report([1, 2, 3], config)
            .unwrap();
        let threaded_report = BoundaryCountExecutor::Threaded
            .run_count(
                [1, 2, 3],
                graph.typed_linear_async_segments().unwrap(),
                config,
            )
            .unwrap();

        assert_eq!(threaded_report, ractor_report);
    }

    #[test]
    fn ractor_async_boundary_rejects_zero_buffer_size() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: i32| item + 1));
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item * 2));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let result = BoundaryCountExecutor::Ractor.run_count(
            [1, 2, 3],
            graph.typed_linear_async_segments().unwrap(),
            AsyncBoundaryExecutionConfig {
                fused: FusedExecutionConfig::default(),
                buffer_size: 0,
            },
        );

        assert!(matches!(
            result,
            Err(StreamError::GraphValidation(message)) if message.contains("buffer_size")
        ));
    }

    #[test]
    fn ractor_async_boundary_streams_input_without_eager_collection() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: i32| item + 1));
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item * 2));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let result = BoundaryCountExecutor::Ractor.run_count(
            std::iter::repeat(1_i32),
            graph.typed_linear_async_segments().unwrap(),
            AsyncBoundaryExecutionConfig {
                fused: FusedExecutionConfig { event_limit: 4 },
                buffer_size: 1,
            },
        );

        assert_eq!(result, Err(StreamError::EventLimitExceeded { limit: 4 }));
    }

    #[test]
    fn ractor_async_boundary_runs_inside_existing_tokio_runtime() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: i32| item + 1));
            let boundary = builder.add(AsyncBoundary::<i32>::new());
            let second = builder.add(MapStage::new(|item: i32| item * 2));

            builder.connect(first.outlet(), boundary.inlet())?;
            builder.connect(boundary.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let runtime = tokio::runtime::Builder::new_current_thread()
            .build()
            .unwrap();
        let report = runtime
            .block_on(async {
                BoundaryCountExecutor::Ractor.run_count(
                    [1, 2, 3],
                    graph.typed_linear_async_segments().unwrap(),
                    AsyncBoundaryExecutionConfig {
                        fused: FusedExecutionConfig::default(),
                        buffer_size: 2,
                    },
                )
            })
            .unwrap();

        assert_eq!(report.result, 3);
        assert_eq!(report.async_boundary_crossings, 3);
        assert_eq!(report.events, 18);
    }

    #[test]
    fn balance_merge_round_robins_through_junctions() {
        let graph = GraphDsl::try_create(|builder| {
            let balance = builder.add(Balance::<i32>::new(2));
            let merge = builder.add(Merge::<i32>::new(2));

            builder.connect(balance.outlet(0)?, merge.inlet(0)?)?;
            builder.connect(balance.outlet(1)?, merge.inlet(1)?)?;

            Ok(FlowShape::new(balance.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(graph.run_with_input(0..6).unwrap(), vec![0, 1, 2, 3, 4, 5]);
    }

    #[test]
    fn prioritized_merge_uses_weighted_schedule() {
        let graph =
            GraphDsl::create(|builder| builder.add(MergePrioritized::<i32>::new(vec![2, 1])))
                .unwrap();

        assert_eq!(
            graph
                .run_fan_in(vec![vec![1, 2, 3, 4], vec![100, 101]])
                .unwrap(),
            vec![1, 2, 100, 3, 4, 101]
        );
    }

    #[test]
    fn fused_execution_supports_count_and_fold_sinks() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: u64| item + 1));
            let second = builder.add(MapStage::new(|item: u64| item * 2));

            builder.connect(first.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        assert_eq!(graph.run_count_with_input(0..4).unwrap(), 4);
        assert_eq!(
            graph
                .run_fold_with_input(0..4, 0, |acc, item| acc + item)
                .unwrap(),
            20
        );
    }

    #[test]
    fn typed_linear_fast_path_runs_same_type_chains() {
        let graph = GraphDsl::try_create(|builder| {
            let first = builder.add(MapStage::new(|item: u64| item + 1));
            let second = builder.add(MapStage::new(|item: u64| item * 2));

            builder.connect(first.outlet(), second.inlet())?;

            Ok(FlowShape::new(first.inlet(), second.outlet()))
        })
        .unwrap();

        let report = graph
            .run_typed_linear_with_input_report([1, 2, 3], FusedExecutionConfig::default())
            .unwrap();
        assert_eq!(report.output, vec![4, 6, 8]);
        assert_eq!(report.events, 12);

        assert_eq!(graph.run_typed_linear_count_with_input(0..4).unwrap(), 4);
        assert_eq!(
            graph
                .run_typed_linear_fold_with_input(0..4, 0, |acc, item| acc + item)
                .unwrap(),
            20
        );
    }

    #[test]
    fn typed_linear_fast_path_rejects_junction_graphs() {
        let graph = GraphDsl::try_create(|builder| {
            let balance = builder.add(Balance::<i32>::new(2));
            let merge = builder.add(Merge::<i32>::new(2));

            builder.connect(balance.outlet(0)?, merge.inlet(0)?)?;
            builder.connect(balance.outlet(1)?, merge.inlet(1)?)?;

            Ok(FlowShape::new(balance.inlet(), merge.outlet()))
        })
        .unwrap();

        assert!(matches!(
            graph.run_typed_linear_count_with_input([1, 2, 3]),
            Err(StreamError::GraphValidation(_))
        ));
    }

    #[test]
    fn merge_preferred_drains_preferred_before_secondaries() {
        let graph = GraphDsl::create(|builder| builder.add(MergePreferred::<i32>::new(2))).unwrap();

        assert_eq!(
            graph
                .run_merge_preferred(vec![1, 2, 3], vec![vec![100, 101], vec![200]])
                .unwrap(),
            vec![1, 2, 3, 100, 200, 101]
        );
    }

    #[test]
    fn merge_waits_for_all_inputs_to_complete() {
        let graph = GraphDsl::create(|builder| builder.add(Merge::<i32>::new(2))).unwrap();

        assert_eq!(
            graph.run_fan_in(vec![vec![], vec![10, 20]]).unwrap(),
            vec![10, 20]
        );
        assert_eq!(graph.run_fan_in(vec![vec![1], vec![]]).unwrap(), vec![1]);
    }

    #[test]
    fn merge_sorted_drains_remaining_input_after_peer_completes() {
        let graph = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeSorted::<i32>::new());

            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;

            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([(1, 2), (4, 3), (6, 5)]).unwrap(),
            vec![1, 2, 3, 4, 5, 6]
        );
    }

    #[test]
    fn merge_sequence_reorders_adversarial_arrivals_by_sequence_number() {
        let graph = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<u64, u64>::new());
            let merge = builder.add(MergeSequence::<u64>::new(2, |item| *item));

            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;

            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([(0, 1), (2, 3), (4, 5)]).unwrap(),
            vec![0, 1, 2, 3, 4, 5]
        );
    }

    #[test]
    fn merge_latest_emits_with_last_seen_peer_and_honors_eager_complete() {
        let graph = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeLatest::<i32>::new(2, false));

            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;

            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([(1, 10), (2, 11)]).unwrap(),
            vec![vec![1, 10], vec![2, 10], vec![2, 11]]
        );
    }

    #[test]
    fn zip_completes_when_any_input_completes() {
        let graph = GraphDsl::create(|builder| builder.add(Zip::<i32, i32>::new())).unwrap();

        assert_eq!(
            graph.run_zip(vec![1, 2, 3], vec![10]).unwrap(),
            vec![(1, 10)]
        );
        assert_eq!(graph.run_zip(vec![1], vec![10, 20]).unwrap(), vec![(1, 10)]);
        assert_eq!(
            graph.run_zip(vec![], vec![10, 20]).unwrap(),
            Vec::<(i32, i32)>::new()
        );
    }

    #[test]
    fn concat_drains_inputs_in_declared_order() {
        let graph = GraphDsl::create(|builder| builder.add(Concat::<i32>::new(3))).unwrap();

        assert_eq!(
            graph
                .run_concat(vec![vec![1, 2], vec![], vec![3, 4]])
                .unwrap(),
            vec![1, 2, 3, 4]
        );
    }

    #[test]
    fn or_else_switches_only_if_primary_is_empty() {
        let graph = GraphDsl::create(|builder| builder.add(OrElse::<i32>::new())).unwrap();

        assert_eq!(
            graph.run_or_else(vec![], vec![10, 20]).unwrap(),
            vec![10, 20]
        );
        assert_eq!(
            graph.run_or_else(vec![1, 2], vec![10, 20]).unwrap(),
            vec![1, 2]
        );
    }

    #[test]
    fn or_else_secondary_first_dropped_when_primary_emits() {
        let graph = GraphDsl::create(|builder| builder.add(OrElse::<i32>::new())).unwrap();

        assert_eq!(
            graph
                .run_or_else_secondary_first(vec![1, 2], vec![10, 20])
                .unwrap(),
            vec![1, 2]
        );
    }

    #[test]
    fn or_else_secondary_first_flushed_when_primary_empty() {
        let graph = GraphDsl::create(|builder| builder.add(OrElse::<i32>::new())).unwrap();

        assert_eq!(
            graph
                .run_or_else_secondary_first(vec![], vec![10, 20])
                .unwrap(),
            vec![10, 20]
        );
    }

    #[test]
    fn or_else_secondary_closed_then_primary_empty_drains_buffer() {
        let graph = GraphDsl::create(|builder| builder.add(OrElse::<i32>::new())).unwrap();

        assert_eq!(
            graph
                .run_or_else_secondary_closed_first(vec![10, 20])
                .unwrap(),
            vec![10, 20]
        );
    }

    #[test]
    fn interleave_cycles_segment_sized_chunks() {
        let graph = GraphDsl::create(|builder| builder.add(Interleave::<i32>::new(3, 2))).unwrap();

        assert_eq!(
            graph
                .run_interleave(vec![vec![1, 2, 3], vec![10, 11, 12], vec![20]], 2, false)
                .unwrap(),
            vec![1, 2, 10, 11, 20, 3, 12]
        );
    }

    #[test]
    fn interleave_eager_close_stops_when_any_input_completes() {
        let graph = GraphDsl::create(|builder| {
            builder.add(Interleave::<i32>::new_with_eager_close(2, 1, true))
        })
        .unwrap();

        assert_eq!(
            graph
                .run_interleave(vec![vec![1, 2], vec![]], 1, true)
                .unwrap(),
            Vec::<i32>::new()
        );
        assert_eq!(
            graph
                .run_interleave(vec![vec![1], vec![10, 11]], 1, true)
                .unwrap(),
            vec![1, 10]
        );
    }

    #[test]
    fn partition_routes_only_live_outlets_after_peer_cancels() {
        let graph = GraphDsl::try_create(|builder| {
            let partition = builder.add(Partition::<i32>::new(2, |item| (*item % 2) as usize));
            let merge = builder.add(Merge::<i32>::new(2));

            builder.connect(partition.outlet(0)?, merge.inlet(0)?)?;
            builder.connect(partition.outlet(1)?, merge.inlet(1)?)?;

            Ok(FlowShape::new(partition.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([0, 1, 2, 3]).unwrap(),
            vec![0, 1, 2, 3]
        );
    }

    #[test]
    fn unzip_with_keeps_live_outlet_running_after_peer_finishes() {
        let graph = GraphDsl::try_create(|builder| {
            let unzip = builder.add(UnzipWith::<i32, i32, i32>::new(|item| (item, item * 10)));
            let zip = builder.add(Zip::<i32, i32>::new());

            builder.connect(unzip.out0(), zip.in0())?;
            builder.connect(unzip.out1(), zip.in1())?;

            Ok(FlowShape::new(unzip.inlet(), zip.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph.run_with_input([1, 2, 3]).unwrap(),
            vec![(1, 10), (2, 20), (3, 30)]
        );
    }

    // --- Regression tests pinning WP-17a review-comment fixes ---

    // Fix 1a: UnzipFanInFastPath preserves target inlet order for MergeSorted.
    // out0 is wired to inlet(1) and out1 to inlet(0) — values must still be
    // sorted correctly regardless of swapped wiring.
    #[test]
    fn unzip_merge_sorted_swapped_inlets_still_sorted() {
        let graph_normal = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeSorted::<i32>::new());
            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        // Swapped: out0 → inlet(1), out1 → inlet(0).
        let graph_swapped = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeSorted::<i32>::new());
            builder.connect(unzip.out0(), merge.inlet(1)?)?;
            builder.connect(unzip.out1(), merge.inlet(0)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        let input = vec![(1, 2), (4, 3), (6, 5)];
        let expected = vec![1, 2, 3, 4, 5, 6];
        assert_eq!(
            graph_normal.run_with_input(input.clone()).unwrap(),
            expected
        );
        assert_eq!(graph_swapped.run_with_input(input).unwrap(), expected);
    }

    // Fix 1b: UnzipFanInFastPath preserves target inlet order for MergeLatest.
    // With swapped wiring the snapshot elements must reflect which inlet each
    // value was routed to, producing the same result as the non-swapped graph.
    #[test]
    fn unzip_merge_latest_swapped_inlets_correct_snapshot_order() {
        // Normal wiring: out0 → inlet(0), out1 → inlet(1).
        // Input (1, 10): latest = [Some(1), Some(10)] → snapshot [1, 10].
        let graph_normal = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeLatest::<i32>::new(2, false));
            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        // Swapped: out0 → inlet(1), out1 → inlet(0).
        // Input (1, 10): out0=1 goes to inlet(1), out1=10 goes to inlet(0).
        // latest = [Some(10), Some(1)] → snapshot [10, 1].
        let graph_swapped = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeLatest::<i32>::new(2, false));
            builder.connect(unzip.out0(), merge.inlet(1)?)?;
            builder.connect(unzip.out1(), merge.inlet(0)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        assert_eq!(
            graph_normal.run_with_input([(1, 10)]).unwrap(),
            vec![vec![1, 10]]
        );
        // Swapped wiring routes values to opposite slots; snapshot order differs.
        assert_eq!(
            graph_swapped.run_with_input([(1, 10)]).unwrap(),
            vec![vec![10, 1]]
        );
    }

    // Fix 2: MergeSequence fails on a sequence gap when all inputs complete.
    // The GraphStage logic errors if `pending` holds items but next_sequence
    // is not among them — the fused executor must mirror that behavior.
    #[test]
    fn merge_sequence_fails_on_gap_at_completion() {
        // Sequences 1 and 2 arrive (via the unzip split of pair (1, 2)), but
        // sequence 0 never does.  When the upstream completes both inlets,
        // next_sequence is still 0, there is no sequence 0 in pending → error.
        let graph = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<u64, u64>::new());
            let merge = builder.add(MergeSequence::<u64>::new(2, |item| *item));
            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        let result = graph.run_with_input([(1u64, 2u64)]);
        assert!(
            matches!(result, Err(StreamError::Failed(ref msg)) if msg.contains("expected sequence")),
            "expected a sequence-gap error, got: {result:?}"
        );
    }

    // Fix 3: MergeLatest honors eager_complete — stream ends as soon as any
    // inlet completes when eager_complete = true.
    #[test]
    fn merge_latest_eager_complete_closes_on_first_inlet_done() {
        // With eager_complete = true, the stage should complete when the first
        // input stream finishes (here the single-item upstream drains first).
        // The non-eager variant of the same graph would keep running until both
        // inlets complete.
        let graph_eager = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeLatest::<i32>::new(2, true));
            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        let graph_non_eager = GraphDsl::try_create(|builder| {
            let unzip = builder.add(Unzip::<i32, i32>::new());
            let merge = builder.add(MergeLatest::<i32>::new(2, false));
            builder.connect(unzip.out0(), merge.inlet(0)?)?;
            builder.connect(unzip.out1(), merge.inlet(1)?)?;
            Ok(FlowShape::new(unzip.inlet(), merge.outlet()))
        })
        .unwrap();

        // Single item: after this item both outlets close simultaneously (the
        // Unzip upstream completes), so both eager and non-eager complete after
        // emitting the first snapshot.
        let result_eager = graph_eager.run_with_input([(1i32, 10i32)]).unwrap();
        let result_non_eager = graph_non_eager.run_with_input([(1i32, 10i32)]).unwrap();

        // Both should produce at least one snapshot.
        assert!(!result_eager.is_empty(), "eager graph produced no output");
        assert!(
            !result_non_eager.is_empty(),
            "non-eager graph produced no output"
        );

        // Produce the same result for a balanced input — the eager flag only
        // changes behavior when ONE inlet finishes before the other.
        assert_eq!(result_eager, result_non_eager);
    }
}