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indexdata_test.go
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indexdata_test.go
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package zoekt
import (
"math/rand"
"reflect"
"slices"
"testing"
"testing/quick"
)
const exampleQuery = "const data: Event = { ...JSON.parse(message.data), type: message.event }"
func genFrequencies(ngramOffs []runeNgramOff, max int) []uint32 {
seen := map[ngram]uint32{}
var frequencies []uint32
for _, n := range ngramOffs {
freq, ok := seen[n.ngram]
if !ok {
freq = uint32(rand.Intn(max))
seen[n.ngram] = freq
}
frequencies = append(frequencies, freq)
}
return frequencies
}
func BenchmarkMinFrequencyNgramOffsets(b *testing.B) {
ngramOffs := splitNGrams([]byte(exampleQuery))
slices.SortFunc(ngramOffs, runeNgramOff.Compare)
frequencies := genFrequencies(ngramOffs, 100)
for i := 0; i < b.N; i++ {
x0, x1 := minFrequencyNgramOffsets(ngramOffs, frequencies)
if x0 == x1 {
b.Fatal("should not be the same")
}
}
}
func TestMinFrequencyNgramOffsets(t *testing.T) {
// Our implementation has ill-defined tie breaks when the 2nd smallest
// frequency can be tied with others. Fixing that would make the CPU perf
// worse, so what we do instead is just validate that what we get back is
// acceptable.
if err := quick.Check(func(s string, maxFreq uint16) bool {
// Ensure maximum frequency is nonzero so that random sampling will work
maxFreq = max(maxFreq, 1)
ngramOffs := splitNGrams([]byte(s))
if len(ngramOffs) == 0 {
return true
}
slices.SortFunc(ngramOffs, runeNgramOff.Compare)
frequencies := genFrequencies(ngramOffs, int(maxFreq))
x0, x1 := minFrequencyNgramOffsets(ngramOffs, frequencies)
if x0.index > x1.index {
t.Log("x0 should be before x1")
return false
}
if len(ngramOffs) <= 1 {
return true
}
// Now we just assert that we found two items with the smallest
// frequencies.
idx0 := slices.IndexFunc(ngramOffs, func(a runeNgramOff) bool { return a == x0 })
idx1 := slices.IndexFunc(ngramOffs, func(a runeNgramOff) bool { return a == x1 })
start := []uint32{frequencies[idx0], frequencies[idx1]}
slices.Sort(start)
slices.Sort(frequencies)
return reflect.DeepEqual(start, frequencies[:2])
}, nil); err != nil {
t.Fatal(err)
}
}
func TestFindSelectiveNGrams(t *testing.T) {
if err := quick.Check(func(s string, maxFreq uint16) bool {
// Ensure maximum frequency is nonzero so that random sampling will work
maxFreq = max(maxFreq, 1)
ngramOffs := splitNGrams([]byte(s))
if len(ngramOffs) == 0 {
return true
}
slices.SortFunc(ngramOffs, runeNgramOff.Compare)
indexMap := make([]int, len(ngramOffs))
for i, n := range ngramOffs {
indexMap[n.index] = i
}
frequencies := genFrequencies(ngramOffs, int(maxFreq))
x0, x1 := findSelectiveNgrams(ngramOffs, indexMap, frequencies)
if len(ngramOffs) <= 1 {
return true
}
// Just assert the invariant that x0 is before x1. This test mostly checks
// for out-of-bounds errors.
return x0.index < x1.index
}, nil); err != nil {
t.Fatal(err)
}
}