Files
Martino Ferrari c0f7e662be Testing
2026-06-24 01:39:15 +02:00

155 lines
5.4 KiB
Go

package synthetic
import (
"context"
"log/slog"
"os"
"testing"
"time"
"github.com/uopi/uopi/internal/broker"
"github.com/uopi/uopi/internal/datasource"
)
// seqSource is a test DataSource that emits a fixed sequence of values, each
// carrying its own timestamp, so tests can control upstream sample times.
type seqSource struct {
name string
seq []datasource.Value
}
func (s *seqSource) Name() string { return s.name }
func (s *seqSource) Connect(context.Context) error { return nil }
func (s *seqSource) ListSignals(context.Context) ([]datasource.Metadata, error) { return nil, nil }
func (s *seqSource) GetMetadata(context.Context, string) (datasource.Metadata, error) {
return datasource.Metadata{Name: "x", Type: datasource.TypeFloat64}, nil
}
func (s *seqSource) Write(context.Context, string, any) error { return datasource.ErrNotWritable }
func (s *seqSource) History(context.Context, string, time.Time, time.Time, int) ([]datasource.Value, error) {
return nil, datasource.ErrHistoryUnavailable
}
func (s *seqSource) Subscribe(ctx context.Context, _ string, ch chan<- datasource.Value) (datasource.CancelFunc, error) {
go func() {
for _, v := range s.seq {
select {
case ch <- v:
case <-ctx.Done():
return
}
time.Sleep(8 * time.Millisecond)
}
}()
return func() {}, nil
}
// TestSubscribePreservesUpstreamTimestamp verifies a single-source synthetic
// emits each computed value with the upstream sample's timestamp.
func TestSubscribePreservesUpstreamTimestamp(t *testing.T) {
log := slog.New(slog.NewTextHandler(os.Stderr, nil))
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
base := time.Date(2026, 6, 19, 10, 0, 0, 0, time.UTC)
src := &seqSource{name: "src", seq: []datasource.Value{
{Timestamp: base.Add(1 * time.Second), Data: 1.0, Quality: datasource.QualityGood},
{Timestamp: base.Add(2 * time.Second), Data: 2.0, Quality: datasource.QualityGood},
{Timestamp: base.Add(3 * time.Second), Data: 3.0, Quality: datasource.QualityGood},
}}
brk := broker.New(ctx, log)
brk.Register(src)
syn := New(t.TempDir(), brk, log)
if err := syn.Connect(ctx); err != nil {
t.Fatal(err)
}
if err := syn.AddSignal(SignalDef{
Name: "g", DS: "src", Signal: "x",
Pipeline: []NodeDef{{Type: "gain", Params: map[string]any{"gain": 10.0}}},
}); err != nil {
t.Fatal(err)
}
ch := make(chan datasource.Value, 8)
if _, err := syn.Subscribe(ctx, "g", ch); err != nil {
t.Fatal(err)
}
want := []time.Time{base.Add(1 * time.Second), base.Add(2 * time.Second), base.Add(3 * time.Second)}
for i, w := range want {
select {
case v := <-ch:
if !v.Timestamp.Equal(w) {
t.Errorf("emit #%d timestamp: want %s, got %s", i, w, v.Timestamp)
}
case <-time.After(2 * time.Second):
t.Fatalf("timeout waiting for emit #%d", i)
}
}
}
// TestSubscribeMultiSourceUsesLatestTimestamp verifies that a synthetic combining
// two independent sources stamps each output with the MOST RECENT contributing
// sample time — not the timestamp of whichever source happened to trigger the
// computation. A slow source carrying a stale timestamp must not drag the output
// backwards in time (which previously produced wrong/non-monotonic plot points).
func TestSubscribeMultiSourceUsesLatestTimestamp(t *testing.T) {
log := slog.New(slog.NewTextHandler(os.Stderr, nil))
ctx, cancel := context.WithCancel(context.Background())
defer cancel()
now := time.Date(2026, 6, 19, 12, 0, 0, 0, time.UTC)
// Fast source A with current timestamps.
a := &seqSource{name: "A", seq: []datasource.Value{
{Timestamp: now.Add(10 * time.Second), Data: 1.0, Quality: datasource.QualityGood},
{Timestamp: now.Add(11 * time.Second), Data: 2.0, Quality: datasource.QualityGood},
{Timestamp: now.Add(12 * time.Second), Data: 3.0, Quality: datasource.QualityGood},
{Timestamp: now.Add(13 * time.Second), Data: 4.0, Quality: datasource.QualityGood},
}}
// Slow source B: a single sample with a much older timestamp.
b := &seqSource{name: "B", seq: []datasource.Value{
{Timestamp: now.Add(1 * time.Second), Data: 100.0, Quality: datasource.QualityGood},
}}
brk := broker.New(ctx, log)
brk.Register(a)
brk.Register(b)
syn := New(t.TempDir(), brk, log)
if err := syn.Connect(ctx); err != nil {
t.Fatal(err)
}
if err := syn.AddSignal(SignalDef{
Name: "diff",
Graph: &Graph{Output: "out", Nodes: []GraphNode{
{ID: "sa", Kind: "source", DS: "A", Signal: "x"},
{ID: "sb", Kind: "source", DS: "B", Signal: "x"},
{ID: "sub", Kind: "op", Op: "subtract", Inputs: []string{"sa", "sb"}},
{ID: "out", Kind: "output", Inputs: []string{"sub"}},
}},
}); err != nil {
t.Fatal(err)
}
ch := make(chan datasource.Value, 16)
if _, err := syn.Subscribe(ctx, "diff", ch); err != nil {
t.Fatal(err)
}
var last time.Time
for i := 0; i < 4; i++ {
select {
case v := <-ch:
// The stale source-B timestamp (t=1s) must never be used: every output
// is stamped with the newest input time, so emits stay monotonic.
if v.Timestamp.Equal(now.Add(1 * time.Second)) {
t.Errorf("emit #%d used the stale source-B timestamp %s", i, v.Timestamp)
}
if !last.IsZero() && v.Timestamp.Before(last) {
t.Errorf("emit #%d went backwards: %s before previous %s", i, v.Timestamp, last)
}
last = v.Timestamp
case <-time.After(2 * time.Second):
t.Fatalf("timeout waiting for emit #%d", i)
}
}
}