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tendermint/p2p/pex/addrbook_test.go

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package pex
import (
"encoding/hex"
"fmt"
"io/ioutil"
"math"
"os"
"testing"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
"github.com/tendermint/tendermint/libs/log"
tmmath "github.com/tendermint/tendermint/libs/math"
tmrand "github.com/tendermint/tendermint/libs/rand"
"github.com/tendermint/tendermint/p2p"
)
// FIXME These tests should not rely on .(*addrBook) assertions
func TestAddrBookPickAddress(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
// 0 addresses
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
assert.Zero(t, book.Size())
addr := book.PickAddress(50)
assert.Nil(t, addr, "expected no address")
randAddrs := randNetAddressPairs(t, 1)
addrSrc := randAddrs[0]
book.AddAddress(addrSrc.addr, addrSrc.src)
// pick an address when we only have new address
addr = book.PickAddress(0)
assert.NotNil(t, addr, "expected an address")
addr = book.PickAddress(50)
assert.NotNil(t, addr, "expected an address")
addr = book.PickAddress(100)
assert.NotNil(t, addr, "expected an address")
// pick an address when we only have old address
book.MarkGood(addrSrc.addr.ID)
addr = book.PickAddress(0)
assert.NotNil(t, addr, "expected an address")
addr = book.PickAddress(50)
assert.NotNil(t, addr, "expected an address")
// in this case, nNew==0 but we biased 100% to new, so we return nil
addr = book.PickAddress(100)
assert.Nil(t, addr, "did not expected an address")
}
func TestAddrBookSaveLoad(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
// 0 addresses
book := NewAddrBook(fname, true).(*addrBook)
book.SetLogger(log.TestingLogger())
book.saveToFile(fname)
book = NewAddrBook(fname, true).(*addrBook)
book.SetLogger(log.TestingLogger())
book.loadFromFile(fname)
assert.Zero(t, book.Size())
// 100 addresses
randAddrs := randNetAddressPairs(t, 100)
for _, addrSrc := range randAddrs {
book.AddAddress(addrSrc.addr, addrSrc.src)
}
assert.Equal(t, 100, book.Size())
book.saveToFile(fname)
book = NewAddrBook(fname, true).(*addrBook)
book.SetLogger(log.TestingLogger())
book.loadFromFile(fname)
assert.Equal(t, 100, book.Size())
}
func TestAddrBookLookup(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
randAddrs := randNetAddressPairs(t, 100)
book := NewAddrBook(fname, true).(*addrBook)
book.SetLogger(log.TestingLogger())
for _, addrSrc := range randAddrs {
addr := addrSrc.addr
src := addrSrc.src
book.AddAddress(addr, src)
ka := book.addrLookup[addr.ID]
assert.NotNil(t, ka, "Expected to find KnownAddress %v but wasn't there.", addr)
if !(ka.Addr.Equals(addr) && ka.Src.Equals(src)) {
t.Fatalf("KnownAddress doesn't match addr & src")
}
}
}
func TestAddrBookPromoteToOld(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
randAddrs := randNetAddressPairs(t, 100)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
for _, addrSrc := range randAddrs {
book.AddAddress(addrSrc.addr, addrSrc.src)
}
// Attempt all addresses.
for _, addrSrc := range randAddrs {
book.MarkAttempt(addrSrc.addr)
}
// Promote half of them
for i, addrSrc := range randAddrs {
if i%2 == 0 {
book.MarkGood(addrSrc.addr.ID)
}
}
// TODO: do more testing :)
selection := book.GetSelection()
t.Logf("selection: %v", selection)
if len(selection) > book.Size() {
t.Errorf("selection could not be bigger than the book")
}
selection = book.GetSelectionWithBias(30)
t.Logf("selection: %v", selection)
if len(selection) > book.Size() {
t.Errorf("selection with bias could not be bigger than the book")
}
assert.Equal(t, book.Size(), 100, "expecting book size to be 100")
}
func TestAddrBookHandlesDuplicates(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
randAddrs := randNetAddressPairs(t, 100)
differentSrc := randIPv4Address(t)
for _, addrSrc := range randAddrs {
book.AddAddress(addrSrc.addr, addrSrc.src)
book.AddAddress(addrSrc.addr, addrSrc.src) // duplicate
book.AddAddress(addrSrc.addr, differentSrc) // different src
}
assert.Equal(t, 100, book.Size())
}
type netAddressPair struct {
addr *p2p.NetAddress
src *p2p.NetAddress
}
func randNetAddressPairs(t *testing.T, n int) []netAddressPair {
randAddrs := make([]netAddressPair, n)
for i := 0; i < n; i++ {
randAddrs[i] = netAddressPair{addr: randIPv4Address(t), src: randIPv4Address(t)}
}
return randAddrs
}
func randIPv4Address(t *testing.T) *p2p.NetAddress {
for {
ip := fmt.Sprintf("%v.%v.%v.%v",
tmrand.Intn(254)+1,
tmrand.Intn(255),
tmrand.Intn(255),
tmrand.Intn(255),
)
port := tmrand.Intn(65535-1) + 1
id := p2p.ID(hex.EncodeToString(tmrand.Bytes(p2p.IDByteLength)))
idAddr := p2p.IDAddressString(id, fmt.Sprintf("%v:%v", ip, port))
addr, err := p2p.NewNetAddressString(idAddr)
assert.Nil(t, err, "error generating rand network address")
if addr.Routable() {
return addr
}
}
}
func TestAddrBookRemoveAddress(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
addr := randIPv4Address(t)
book.AddAddress(addr, addr)
assert.Equal(t, 1, book.Size())
book.RemoveAddress(addr)
assert.Equal(t, 0, book.Size())
nonExistingAddr := randIPv4Address(t)
book.RemoveAddress(nonExistingAddr)
assert.Equal(t, 0, book.Size())
}
func TestAddrBookGetSelectionWithOneMarkedGood(t *testing.T) {
// create a book with 10 addresses, 1 good/old and 9 new
book, fname := createAddrBookWithMOldAndNNewAddrs(t, 1, 9)
defer deleteTempFile(fname)
addrs := book.GetSelectionWithBias(biasToSelectNewPeers)
assert.NotNil(t, addrs)
assertMOldAndNNewAddrsInSelection(t, 1, 9, addrs, book)
}
func TestAddrBookGetSelectionWithOneNotMarkedGood(t *testing.T) {
// create a book with 10 addresses, 9 good/old and 1 new
book, fname := createAddrBookWithMOldAndNNewAddrs(t, 9, 1)
defer deleteTempFile(fname)
addrs := book.GetSelectionWithBias(biasToSelectNewPeers)
assert.NotNil(t, addrs)
assertMOldAndNNewAddrsInSelection(t, 9, 1, addrs, book)
}
func TestAddrBookGetSelectionReturnsNilWhenAddrBookIsEmpty(t *testing.T) {
book, fname := createAddrBookWithMOldAndNNewAddrs(t, 0, 0)
defer deleteTempFile(fname)
addrs := book.GetSelectionWithBias(biasToSelectNewPeers)
assert.Nil(t, addrs)
}
func TestAddrBookGetSelection(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
// 1) empty book
assert.Empty(t, book.GetSelection())
// 2) add one address
addr := randIPv4Address(t)
book.AddAddress(addr, addr)
assert.Equal(t, 1, len(book.GetSelection()))
assert.Equal(t, addr, book.GetSelection()[0])
// 3) add a bunch of addresses
randAddrs := randNetAddressPairs(t, 100)
for _, addrSrc := range randAddrs {
book.AddAddress(addrSrc.addr, addrSrc.src)
}
// check there is no duplicates
addrs := make(map[string]*p2p.NetAddress)
selection := book.GetSelection()
for _, addr := range selection {
if dup, ok := addrs[addr.String()]; ok {
t.Fatalf("selection %v contains duplicates %v", selection, dup)
}
addrs[addr.String()] = addr
}
if len(selection) > book.Size() {
t.Errorf("selection %v could not be bigger than the book", selection)
}
}
func TestAddrBookGetSelectionWithBias(t *testing.T) {
const biasTowardsNewAddrs = 30
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
// 1) empty book
selection := book.GetSelectionWithBias(biasTowardsNewAddrs)
assert.Empty(t, selection)
// 2) add one address
addr := randIPv4Address(t)
book.AddAddress(addr, addr)
selection = book.GetSelectionWithBias(biasTowardsNewAddrs)
assert.Equal(t, 1, len(selection))
assert.Equal(t, addr, selection[0])
// 3) add a bunch of addresses
randAddrs := randNetAddressPairs(t, 100)
for _, addrSrc := range randAddrs {
book.AddAddress(addrSrc.addr, addrSrc.src)
}
// check there is no duplicates
addrs := make(map[string]*p2p.NetAddress)
selection = book.GetSelectionWithBias(biasTowardsNewAddrs)
for _, addr := range selection {
if dup, ok := addrs[addr.String()]; ok {
t.Fatalf("selection %v contains duplicates %v", selection, dup)
}
addrs[addr.String()] = addr
}
if len(selection) > book.Size() {
t.Fatalf("selection %v could not be bigger than the book", selection)
}
// 4) mark 80% of the addresses as good
randAddrsLen := len(randAddrs)
for i, addrSrc := range randAddrs {
if int((float64(i)/float64(randAddrsLen))*100) >= 20 {
book.MarkGood(addrSrc.addr.ID)
}
}
selection = book.GetSelectionWithBias(biasTowardsNewAddrs)
// check that ~70% of addresses returned are good
good := 0
for _, addr := range selection {
if book.IsGood(addr) {
good++
}
}
got, expected := int((float64(good)/float64(len(selection)))*100), (100 - biasTowardsNewAddrs)
// compute some slack to protect against small differences due to rounding:
slack := int(math.Round(float64(100) / float64(len(selection))))
if got > expected+slack {
t.Fatalf(
"got more good peers (%% got: %d, %% expected: %d, number of good addrs: %d, total: %d)",
got,
expected,
good,
len(selection),
)
}
if got < expected-slack {
t.Fatalf(
"got fewer good peers (%% got: %d, %% expected: %d, number of good addrs: %d, total: %d)",
got,
expected,
good,
len(selection),
)
}
}
func TestAddrBookHasAddress(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
addr := randIPv4Address(t)
book.AddAddress(addr, addr)
assert.True(t, book.HasAddress(addr))
book.RemoveAddress(addr)
assert.False(t, book.HasAddress(addr))
}
func testCreatePrivateAddrs(t *testing.T, numAddrs int) ([]*p2p.NetAddress, []string) {
addrs := make([]*p2p.NetAddress, numAddrs)
for i := 0; i < numAddrs; i++ {
addrs[i] = randIPv4Address(t)
}
private := make([]string, numAddrs)
for i, addr := range addrs {
private[i] = string(addr.ID)
}
return addrs, private
}
func TestAddrBookEmpty(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
// Check that empty book is empty
require.True(t, book.Empty())
// Check that book with our address is empty
book.AddOurAddress(randIPv4Address(t))
require.True(t, book.Empty())
// Check that book with private addrs is empty
_, privateIds := testCreatePrivateAddrs(t, 5)
book.AddPrivateIDs(privateIds)
require.True(t, book.Empty())
// Check that book with address is not empty
book.AddAddress(randIPv4Address(t), randIPv4Address(t))
require.False(t, book.Empty())
}
func TestPrivatePeers(t *testing.T) {
fname := createTempFileName("addrbook_test")
defer deleteTempFile(fname)
book := NewAddrBook(fname, true)
book.SetLogger(log.TestingLogger())
addrs, private := testCreatePrivateAddrs(t, 10)
book.AddPrivateIDs(private)
// private addrs must not be added
for _, addr := range addrs {
err := book.AddAddress(addr, addr)
if assert.Error(t, err) {
_, ok := err.(ErrAddrBookPrivate)
assert.True(t, ok)
}
}
// addrs coming from private peers must not be added
err := book.AddAddress(randIPv4Address(t), addrs[0])
if assert.Error(t, err) {
_, ok := err.(ErrAddrBookPrivateSrc)
assert.True(t, ok)
}
}
func testAddrBookAddressSelection(t *testing.T, bookSize int) {
// generate all combinations of old (m) and new addresses
for nBookOld := 0; nBookOld <= bookSize; nBookOld++ {
nBookNew := bookSize - nBookOld
dbgStr := fmt.Sprintf("book of size %d (new %d, old %d)", bookSize, nBookNew, nBookOld)
// create book and get selection
book, fname := createAddrBookWithMOldAndNNewAddrs(t, nBookOld, nBookNew)
defer deleteTempFile(fname)
addrs := book.GetSelectionWithBias(biasToSelectNewPeers)
assert.NotNil(t, addrs, "%s - expected a non-nil selection", dbgStr)
nAddrs := len(addrs)
assert.NotZero(t, nAddrs, "%s - expected at least one address in selection", dbgStr)
// check there's no nil addresses
for _, addr := range addrs {
if addr == nil {
t.Fatalf("%s - got nil address in selection %v", dbgStr, addrs)
}
}
// XXX: shadowing
nOld, nNew := countOldAndNewAddrsInSelection(addrs, book)
// Given:
// n - num new addrs, m - num old addrs
// k - num new addrs expected in the beginning (based on bias %)
// i=min(n, max(k,r-m)), aka expNew
// j=min(m, r-i), aka expOld
//
// We expect this layout:
// indices: 0...i-1 i...i+j-1
// addresses: N0..Ni-1 O0..Oj-1
//
// There is at least one partition and at most three.
var (
k = percentageOfNum(biasToSelectNewPeers, nAddrs)
expNew = tmmath.MinInt(nNew, tmmath.MaxInt(k, nAddrs-nBookOld))
expOld = tmmath.MinInt(nOld, nAddrs-expNew)
)
// Verify that the number of old and new addresses are as expected
if nNew != expNew {
t.Fatalf("%s - expected new addrs %d, got %d", dbgStr, expNew, nNew)
}
if nOld != expOld {
t.Fatalf("%s - expected old addrs %d, got %d", dbgStr, expOld, nOld)
}
// Verify that the order of addresses is as expected
// Get the sequence types and lengths of the selection
seqLens, seqTypes, err := analyseSelectionLayout(book, addrs)
assert.NoError(t, err, "%s", dbgStr)
// Build a list with the expected lengths of partitions and another with the expected types, e.g.:
// expSeqLens = [10, 22], expSeqTypes = [1, 2]
// means we expect 10 new (type 1) addresses followed by 22 old (type 2) addresses.
var expSeqLens []int
var expSeqTypes []int
switch {
case expOld == 0: // all new addresses
expSeqLens = []int{nAddrs}
expSeqTypes = []int{1}
case expNew == 0: // all old addresses
expSeqLens = []int{nAddrs}
expSeqTypes = []int{2}
case nAddrs-expNew-expOld == 0: // new addresses, old addresses
expSeqLens = []int{expNew, expOld}
expSeqTypes = []int{1, 2}
}
assert.Equal(t, expSeqLens, seqLens,
"%s - expected sequence lengths of old/new %v, got %v",
dbgStr, expSeqLens, seqLens)
assert.Equal(t, expSeqTypes, seqTypes,
"%s - expected sequence types (1-new, 2-old) was %v, got %v",
dbgStr, expSeqTypes, seqTypes)
}
}
func TestMultipleAddrBookAddressSelection(t *testing.T) {
// test books with smaller size, < N
const N = 32
for bookSize := 1; bookSize < N; bookSize++ {
testAddrBookAddressSelection(t, bookSize)
}
// Test for two books with sizes from following ranges
ranges := [...][]int{{33, 100}, {100, 175}}
bookSizes := make([]int, 0, len(ranges))
for _, r := range ranges {
bookSizes = append(bookSizes, tmrand.Intn(r[1]-r[0])+r[0])
}
t.Logf("Testing address selection for the following book sizes %v\n", bookSizes)
for _, bookSize := range bookSizes {
testAddrBookAddressSelection(t, bookSize)
}
}
func assertMOldAndNNewAddrsInSelection(t *testing.T, m, n int, addrs []*p2p.NetAddress, book *addrBook) {
nOld, nNew := countOldAndNewAddrsInSelection(addrs, book)
assert.Equal(t, m, nOld, "old addresses")
assert.Equal(t, n, nNew, "new addresses")
}
func createTempFileName(prefix string) string {
f, err := ioutil.TempFile("", prefix)
if err != nil {
panic(err)
}
fname := f.Name()
err = f.Close()
if err != nil {
panic(err)
}
return fname
}
func deleteTempFile(fname string) {
err := os.Remove(fname)
if err != nil {
panic(err)
}
}
func createAddrBookWithMOldAndNNewAddrs(t *testing.T, nOld, nNew int) (book *addrBook, fname string) {
fname = createTempFileName("addrbook_test")
book = NewAddrBook(fname, true).(*addrBook)
book.SetLogger(log.TestingLogger())
assert.Zero(t, book.Size())
randAddrs := randNetAddressPairs(t, nOld)
for _, addr := range randAddrs {
book.AddAddress(addr.addr, addr.src)
book.MarkGood(addr.addr.ID)
}
randAddrs = randNetAddressPairs(t, nNew)
for _, addr := range randAddrs {
book.AddAddress(addr.addr, addr.src)
}
return
}
func countOldAndNewAddrsInSelection(addrs []*p2p.NetAddress, book *addrBook) (nOld, nNew int) {
for _, addr := range addrs {
if book.IsGood(addr) {
nOld++
} else {
nNew++
}
}
return
}
// Analyse the layout of the selection specified by 'addrs'
// Returns:
// - seqLens - the lengths of the sequences of addresses of same type
// - seqTypes - the types of sequences in selection
func analyseSelectionLayout(book *addrBook, addrs []*p2p.NetAddress) (seqLens, seqTypes []int, err error) {
// address types are: 0 - nil, 1 - new, 2 - old
var (
prevType = 0
currentSeqLen = 0
)
for _, addr := range addrs {
addrType := 0
if book.IsGood(addr) {
addrType = 2
} else {
addrType = 1
}
if addrType != prevType && prevType != 0 {
seqLens = append(seqLens, currentSeqLen)
seqTypes = append(seqTypes, prevType)
currentSeqLen = 0
}
currentSeqLen++
prevType = addrType
}
seqLens = append(seqLens, currentSeqLen)
seqTypes = append(seqTypes, prevType)
return
}