using Akka.Actor;
using Akka.Hosting;
using Microsoft.Extensions.DependencyInjection;
using Shouldly;
using Xunit;
using ZB.MOM.WW.OtOpcUa.Runtime;
using ZB.MOM.WW.OtOpcUa.Runtime.Drivers;
namespace ZB.MOM.WW.OtOpcUa.Host.IntegrationTests;
///
/// archreview 03/S4 delivery-path guard — the "unit tests can't catch delivery" half. Proves that the
/// REAL DistributedPubSub-delivered redundancy snapshot (not a test-injected RedundancyStateChanged)
/// actually drives the Primary write gate end-to-end across a live 2-node Akka cluster: after both nodes
/// join and the snapshot converges, exactly ONE node's rejects a
/// with "not primary" (the Secondary) while the other
/// passes the gate (the Primary — its rejection, if any, is about node MAPPING, never the gate).
///
/// Before the snapshot delivers, BOTH nodes have an unknown role on a 2-driver cluster and so both
/// default-DENY with "not primary (role unknown)" (archreview 03/S4). The poll below therefore
/// waits for the delivered snapshot to promote exactly one node to Primary — a broken redundancy-topic
/// subscribe (the historical double-break) would leave both stuck "role unknown" and time this out, which
/// is exactly the negative control this test provides over the pure-TestKit guards.
///
[Trait("Category", "Failover")]
public sealed class PrimaryGateFailoverTests
{
private static CancellationToken Ct => TestContext.Current.CancellationToken;
// A NodeId that is guaranteed to have no driver mapping — so a node that PASSES the primary gate
// rejects it with a MAPPING reason ("no driver mapping for node …"), never a gate reason.
private const string UnmappedProbeNode = "__pgate_delivery_probe__";
[Fact]
public async Task Delivered_redundancy_snapshot_drives_the_primary_write_gate_across_the_cluster()
{
await using var harness = await TwoNodeClusterHarness.StartAsync();
var driverHostA = harness.NodeA.Services.GetRequiredService().Get();
var driverHostB = harness.NodeB.Services.GetRequiredService().Get();
// Poll until the DELIVERED snapshot has promoted exactly one node to Primary: one host passes the
// gate (reason not "not primary*") and the other is gated ("not primary"). Deadline covers the
// ~250ms-debounced initial publish plus cluster convergence margin.
var deadline = DateTime.UtcNow + TimeSpan.FromSeconds(45);
(bool aGated, bool bGated, string? aReason, string? bReason) last = default;
while (DateTime.UtcNow < deadline)
{
var a = await RouteProbeWriteAsync(driverHostA);
var b = await RouteProbeWriteAsync(driverHostB);
last = (IsGateReject(a), IsGateReject(b), a.Reason, b.Reason);
// Exactly one node gated ⇒ the snapshot converged (one Primary, one Secondary).
if (last.aGated ^ last.bGated) break;
await Task.Delay(500, Ct);
}
// Exactly one node is the Secondary (gate-rejected); the other is the Primary (passed the gate —
// its reject, if any, is a MAPPING reason). This proves the delivered snapshot drives the gate.
(last.aGated ^ last.bGated).ShouldBeTrue(
$"exactly one node should be gated once the redundancy snapshot converges (A gated={last.aGated} reason='{last.aReason}', B gated={last.bGated} reason='{last.bReason}')");
var primaryReason = last.aGated ? last.bReason : last.aReason;
primaryReason.ShouldNotBeNull();
primaryReason!.StartsWith("not primary", StringComparison.Ordinal).ShouldBeFalse(
$"the Primary must PASS the gate — its reject reason should be a mapping reason, not '{primaryReason}'");
}
private static async Task RouteProbeWriteAsync(IActorRef driverHost)
=> await driverHost.Ask(
new DriverHostActor.RouteNodeWrite(UnmappedProbeNode, 0.0), TimeSpan.FromSeconds(10));
private static bool IsGateReject(DriverHostActor.NodeWriteResult r)
=> !r.Success && r.Reason is not null && r.Reason.StartsWith("not primary", StringComparison.Ordinal);
}