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bloom_test.go
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bloom_test.go
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package bloom
import (
"bytes"
"encoding/binary"
"encoding/gob"
"encoding/json"
"math"
"testing"
)
// This implementation of Bloom filters is _not_
// safe for concurrent use. Uncomment the following
// method and run go test -race
//
// func TestConcurrent(t *testing.T) {
// gmp := runtime.GOMAXPROCS(2)
// defer runtime.GOMAXPROCS(gmp)
//
// f := New(1000, 4)
// n1 := []byte("Bess")
// n2 := []byte("Jane")
// f.Add(n1)
// f.Add(n2)
//
// var wg sync.WaitGroup
// const try = 1000
// var err1, err2 error
//
// wg.Add(1)
// go func() {
// for i := 0; i < try; i++ {
// n1b := f.Test(n1)
// if !n1b {
// err1 = fmt.Errorf("%v should be in", n1)
// break
// }
// }
// wg.Done()
// }()
//
// wg.Add(1)
// go func() {
// for i := 0; i < try; i++ {
// n2b := f.Test(n2)
// if !n2b {
// err2 = fmt.Errorf("%v should be in", n2)
// break
// }
// }
// wg.Done()
// }()
//
// wg.Wait()
//
// if err1 != nil {
// t.Fatal(err1)
// }
// if err2 != nil {
// t.Fatal(err2)
// }
// }
func TestBasic(t *testing.T) {
f := New(1000, 4)
n1 := []byte("Bess")
n2 := []byte("Jane")
n3 := []byte("Emma")
f.Add(n1)
n3a := f.TestAndAdd(n3)
n1b := f.Test(n1)
n2b := f.Test(n2)
n3b := f.Test(n3)
if !n1b {
t.Errorf("%v should be in.", n1)
}
if n2b {
t.Errorf("%v should not be in.", n2)
}
if n3a {
t.Errorf("%v should not be in the first time we look.", n3)
}
if !n3b {
t.Errorf("%v should be in the second time we look.", n3)
}
}
func TestBasicUint32(t *testing.T) {
f := New(1000, 4)
n1 := make([]byte, 4)
n2 := make([]byte, 4)
n3 := make([]byte, 4)
n4 := make([]byte, 4)
binary.BigEndian.PutUint32(n1, 100)
binary.BigEndian.PutUint32(n2, 101)
binary.BigEndian.PutUint32(n3, 102)
binary.BigEndian.PutUint32(n4, 103)
f.Add(n1)
n3a := f.TestAndAdd(n3)
n1b := f.Test(n1)
n2b := f.Test(n2)
n3b := f.Test(n3)
f.Test(n4)
if !n1b {
t.Errorf("%v should be in.", n1)
}
if n2b {
t.Errorf("%v should not be in.", n2)
}
if n3a {
t.Errorf("%v should not be in the first time we look.", n3)
}
if !n3b {
t.Errorf("%v should be in the second time we look.", n3)
}
}
func TestNewWithLowNumbers(t *testing.T) {
f := New(0, 0)
if f.k != 1 {
t.Errorf("%v should be 1", f.k)
}
if f.m != 1 {
t.Errorf("%v should be 1", f.m)
}
}
func TestString(t *testing.T) {
f := NewWithEstimates(1000, 0.001)
n1 := "Love"
n2 := "is"
n3 := "in"
n4 := "bloom"
f.AddString(n1)
n3a := f.TestAndAddString(n3)
n1b := f.TestString(n1)
n2b := f.TestString(n2)
n3b := f.TestString(n3)
f.TestString(n4)
if !n1b {
t.Errorf("%v should be in.", n1)
}
if n2b {
t.Errorf("%v should not be in.", n2)
}
if n3a {
t.Errorf("%v should not be in the first time we look.", n3)
}
if !n3b {
t.Errorf("%v should be in the second time we look.", n3)
}
}
func testEstimated(n uint, maxFp float64, t *testing.T) {
m, k := EstimateParameters(n, maxFp)
f := NewWithEstimates(n, maxFp)
fpRate := f.EstimateFalsePositiveRate(n)
if fpRate > 1.5*maxFp {
t.Errorf("False positive rate too high: n: %v; m: %v; k: %v; maxFp: %f; fpRate: %f, fpRate/maxFp: %f", n, m, k, maxFp, fpRate, fpRate/maxFp)
}
}
func TestEstimated1000_0001(t *testing.T) { testEstimated(1000, 0.000100, t) }
func TestEstimated10000_0001(t *testing.T) { testEstimated(10000, 0.000100, t) }
func TestEstimated100000_0001(t *testing.T) { testEstimated(100000, 0.000100, t) }
func TestEstimated1000_001(t *testing.T) { testEstimated(1000, 0.001000, t) }
func TestEstimated10000_001(t *testing.T) { testEstimated(10000, 0.001000, t) }
func TestEstimated100000_001(t *testing.T) { testEstimated(100000, 0.001000, t) }
func TestEstimated1000_01(t *testing.T) { testEstimated(1000, 0.010000, t) }
func TestEstimated10000_01(t *testing.T) { testEstimated(10000, 0.010000, t) }
func TestEstimated100000_01(t *testing.T) { testEstimated(100000, 0.010000, t) }
func min(a, b uint) uint {
if a < b {
return a
}
return b
}
// The following function courtesy of Nick @turgon
// This helper function ranges over the input data, applying the hashing
// which returns the bit locations to set in the filter.
// For each location, increment a counter for that bit address.
//
// If the Bloom Filter's location() method distributes locations uniformly
// at random, a property it should inherit from its hash function, then
// each bit location in the filter should end up with roughly the same
// number of hits. Importantly, the value of k should not matter.
//
// Once the results are collected, we can run a chi squared goodness of fit
// test, comparing the result histogram with the uniform distribition.
// This yields a test statistic with degrees-of-freedom of m-1.
func chiTestBloom(m, k, rounds uint, elements [][]byte) (succeeds bool) {
f := New(m, k)
results := make([]uint, m)
chi := make([]float64, m)
for _, data := range elements {
h := baseHashes(data)
for i := uint(0); i < f.k; i++ {
results[f.location(h, i)]++
}
}
// Each element of results should contain the same value: k * rounds / m.
// Let's run a chi-square goodness of fit and see how it fares.
var chiStatistic float64
e := float64(k*rounds) / float64(m)
for i := uint(0); i < m; i++ {
chi[i] = math.Pow(float64(results[i])-e, 2.0) / e
chiStatistic += chi[i]
}
// this tests at significant level 0.005 up to 20 degrees of freedom
table := [20]float64{
7.879, 10.597, 12.838, 14.86, 16.75, 18.548, 20.278,
21.955, 23.589, 25.188, 26.757, 28.3, 29.819, 31.319, 32.801, 34.267,
35.718, 37.156, 38.582, 39.997}
df := min(m-1, 20)
succeeds = table[df-1] > chiStatistic
return
}
func TestLocation(t *testing.T) {
var m, k, rounds uint
m = 8
k = 3
rounds = 100000 // 15000000
elements := make([][]byte, rounds)
for x := uint(0); x < rounds; x++ {
ctrlist := make([]uint8, 4)
ctrlist[0] = uint8(x)
ctrlist[1] = uint8(x >> 8)
ctrlist[2] = uint8(x >> 16)
ctrlist[3] = uint8(x >> 24)
data := []byte(ctrlist)
elements[x] = data
}
succeeds := chiTestBloom(m, k, rounds, elements)
if !succeeds {
t.Error("random assignment is too unrandom")
}
}
func TestCap(t *testing.T) {
f := New(1000, 4)
if f.Cap() != f.m {
t.Error("not accessing Cap() correctly")
}
}
func TestK(t *testing.T) {
f := New(1000, 4)
if f.K() != f.k {
t.Error("not accessing K() correctly")
}
}
func TestMarshalUnmarshalJSON(t *testing.T) {
f := New(1000, 4)
data, err := json.Marshal(f)
if err != nil {
t.Fatal(err.Error())
}
var g BloomFilter
err = json.Unmarshal(data, &g)
if err != nil {
t.Fatal(err.Error())
}
if g.m != f.m {
t.Error("invalid m value")
}
if g.k != f.k {
t.Error("invalid k value")
}
if g.b == nil {
t.Fatal("bitset is nil")
}
if !g.b.Equal(f.b) {
t.Error("bitsets are not equal")
}
}
func TestUnmarshalInvalidJSON(t *testing.T) {
data := []byte("{invalid}")
var g BloomFilter
err := g.UnmarshalJSON(data)
if err == nil {
t.Error("expected error while unmarshalling invalid data")
}
}
func TestWriteToReadFrom(t *testing.T) {
var b bytes.Buffer
f := New(1000, 4)
_, err := f.WriteTo(&b)
if err != nil {
t.Fatal(err)
}
g := New(1000, 1)
_, err = g.ReadFrom(&b)
if err != nil {
t.Fatal(err)
}
if g.m != f.m {
t.Error("invalid m value")
}
if g.k != f.k {
t.Error("invalid k value")
}
if g.b == nil {
t.Fatal("bitset is nil")
}
if !g.b.Equal(f.b) {
t.Error("bitsets are not equal")
}
g.Test([]byte(""))
}
func TestReadWriteBinary(t *testing.T) {
f := New(1000, 4)
var buf bytes.Buffer
bytesWritten, err := f.WriteTo(&buf)
if err != nil {
t.Fatal(err.Error())
}
if bytesWritten != int64(buf.Len()) {
t.Errorf("incorrect write length %d != %d", bytesWritten, buf.Len())
}
var g BloomFilter
bytesRead, err := g.ReadFrom(&buf)
if err != nil {
t.Fatal(err.Error())
}
if bytesRead != bytesWritten {
t.Errorf("read unexpected number of bytes %d != %d", bytesRead, bytesWritten)
}
if g.m != f.m {
t.Error("invalid m value")
}
if g.k != f.k {
t.Error("invalid k value")
}
if g.b == nil {
t.Fatal("bitset is nil")
}
if !g.b.Equal(f.b) {
t.Error("bitsets are not equal")
}
}
func TestEncodeDecodeGob(t *testing.T) {
f := New(1000, 4)
f.Add([]byte("one"))
f.Add([]byte("two"))
f.Add([]byte("three"))
var buf bytes.Buffer
err := gob.NewEncoder(&buf).Encode(f)
if err != nil {
t.Fatal(err.Error())
}
var g BloomFilter
err = gob.NewDecoder(&buf).Decode(&g)
if err != nil {
t.Fatal(err.Error())
}
if g.m != f.m {
t.Error("invalid m value")
}
if g.k != f.k {
t.Error("invalid k value")
}
if g.b == nil {
t.Fatal("bitset is nil")
}
if !g.b.Equal(f.b) {
t.Error("bitsets are not equal")
}
if !g.Test([]byte("three")) {
t.Errorf("missing value 'three'")
}
if !g.Test([]byte("two")) {
t.Errorf("missing value 'two'")
}
if !g.Test([]byte("one")) {
t.Errorf("missing value 'one'")
}
}
func TestEqual(t *testing.T) {
f := New(1000, 4)
f1 := New(1000, 4)
g := New(1000, 20)
h := New(10, 20)
n1 := []byte("Bess")
f1.Add(n1)
if !f.Equal(f) {
t.Errorf("%v should be equal to itself", f)
}
if f.Equal(f1) {
t.Errorf("%v should not be equal to %v", f, f1)
}
if f.Equal(g) {
t.Errorf("%v should not be equal to %v", f, g)
}
if f.Equal(h) {
t.Errorf("%v should not be equal to %v", f, h)
}
}
func BenchmarkEstimated(b *testing.B) {
for n := uint(100000); n <= 100000; n *= 10 {
for fp := 0.1; fp >= 0.0001; fp /= 10.0 {
f := NewWithEstimates(n, fp)
f.EstimateFalsePositiveRate(n)
}
}
}
func BenchmarkSeparateTestAndAdd(b *testing.B) {
f := NewWithEstimates(uint(b.N), 0.0001)
key := make([]byte, 100)
b.ResetTimer()
for i := 0; i < b.N; i++ {
binary.BigEndian.PutUint32(key, uint32(i))
f.Test(key)
f.Add(key)
}
}
func BenchmarkCombinedTestAndAdd(b *testing.B) {
f := NewWithEstimates(uint(b.N), 0.0001)
key := make([]byte, 100)
b.ResetTimer()
for i := 0; i < b.N; i++ {
binary.BigEndian.PutUint32(key, uint32(i))
f.TestAndAdd(key)
}
}
func TestMerge(t *testing.T) {
f := New(1000, 4)
n1 := []byte("f")
f.Add(n1)
g := New(1000, 4)
n2 := []byte("g")
g.Add(n2)
h := New(999, 4)
n3 := []byte("h")
h.Add(n3)
j := New(1000, 5)
n4 := []byte("j")
j.Add(n4)
err := f.Merge(g)
if err != nil {
t.Errorf("There should be no error when merging two similar filters")
}
err = f.Merge(h)
if err == nil {
t.Errorf("There should be an error when merging filters with mismatched m")
}
err = f.Merge(j)
if err == nil {
t.Errorf("There should be an error when merging filters with mismatched k")
}
n2b := f.Test(n2)
if !n2b {
t.Errorf("The value doesn't exist after a valid merge")
}
n3b := f.Test(n3)
if n3b {
t.Errorf("The value exists after an invalid merge")
}
n4b := f.Test(n4)
if n4b {
t.Errorf("The value exists after an invalid merge")
}
}
func TestCopy(t *testing.T) {
f := New(1000, 4)
n1 := []byte("f")
f.Add(n1)
// copy here instead of New
g := f.Copy()
n2 := []byte("g")
g.Add(n2)
n1fb := f.Test(n1)
if !n1fb {
t.Errorf("The value doesn't exist in original after making a copy")
}
n1gb := g.Test(n1)
if !n1gb {
t.Errorf("The value doesn't exist in the copy")
}
n2fb := f.Test(n2)
if n2fb {
t.Errorf("The value exists in the original, it should only exist in copy")
}
n2gb := g.Test(n2)
if !n2gb {
t.Errorf("The value doesn't exist in copy after Add()")
}
}
func TestFrom(t *testing.T) {
var (
k = uint(5)
data = make([]uint64, 10)
test = []byte("test")
)
bf := From(data, k)
if bf.K() != k {
t.Errorf("Constant k does not match the expected value")
}
if bf.Cap() != uint(len(data)*64) {
t.Errorf("Capacity does not match the expected value")
}
if bf.Test(test) {
t.Errorf("Bloom filter should not contain the value")
}
bf.Add(test)
if !bf.Test(test) {
t.Errorf("Bloom filter should contain the value")
}
// create a new Bloom filter from an existing (populated) data slice.
bf = From(data, k)
if !bf.Test(test) {
t.Errorf("Bloom filter should contain the value")
}
}
func TestTestLocations(t *testing.T) {
f := NewWithEstimates(1000, 0.001)
n1 := []byte("Love")
n2 := []byte("is")
n3 := []byte("in")
n4 := []byte("bloom")
f.Add(n1)
n3a := f.TestLocations(Locations(n3, f.K()))
f.Add(n3)
n1b := f.TestLocations(Locations(n1, f.K()))
n2b := f.TestLocations(Locations(n2, f.K()))
n3b := f.TestLocations(Locations(n3, f.K()))
n4b := f.TestLocations(Locations(n4, f.K()))
if !n1b {
t.Errorf("%v should be in.", n1)
}
if n2b {
t.Errorf("%v should not be in.", n2)
}
if n3a {
t.Errorf("%v should not be in the first time we look.", n3)
}
if !n3b {
t.Errorf("%v should be in the second time we look.", n3)
}
if n4b {
t.Errorf("%v should be in.", n4)
}
}