lnd.xprv/channeldb/invoice_test.go

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package channeldb
import (
"crypto/rand"
"fmt"
"math"
"testing"
"time"
"github.com/lightningnetwork/lnd/lntypes"
"github.com/lightningnetwork/lnd/lnwire"
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"github.com/lightningnetwork/lnd/record"
"github.com/stretchr/testify/assert"
"github.com/stretchr/testify/require"
)
var (
emptyFeatures = lnwire.NewFeatureVector(nil, lnwire.Features)
testNow = time.Unix(1, 0)
)
func randInvoice(value lnwire.MilliSatoshi) (*Invoice, error) {
var (
pre lntypes.Preimage
payAddr [32]byte
)
if _, err := rand.Read(pre[:]); err != nil {
return nil, err
}
if _, err := rand.Read(payAddr[:]); err != nil {
return nil, err
}
i := &Invoice{
CreationDate: testNow,
Terms: ContractTerm{
Expiry: 4000,
PaymentPreimage: &pre,
PaymentAddr: payAddr,
Value: value,
Features: emptyFeatures,
},
Htlcs: map[CircuitKey]*InvoiceHTLC{},
}
i.Memo = []byte("memo")
// Create a random byte slice of MaxPaymentRequestSize bytes to be used
// as a dummy paymentrequest, and determine if it should be set based
// on one of the random bytes.
var r [MaxPaymentRequestSize]byte
if _, err := rand.Read(r[:]); err != nil {
return nil, err
}
if r[0]&1 == 0 {
i.PaymentRequest = r[:]
} else {
i.PaymentRequest = []byte("")
}
return i, nil
}
// settleTestInvoice settles a test invoice.
func settleTestInvoice(invoice *Invoice, settleIndex uint64) {
invoice.SettleDate = testNow
invoice.AmtPaid = invoice.Terms.Value
invoice.State = ContractSettled
invoice.Htlcs[CircuitKey{}] = &InvoiceHTLC{
Amt: invoice.Terms.Value,
AcceptTime: testNow,
ResolveTime: testNow,
State: HtlcStateSettled,
CustomRecords: make(record.CustomSet),
}
invoice.SettleIndex = settleIndex
}
// Tests that pending invoices are those which are either in ContractOpen or
// in ContractAccepted state.
func TestInvoiceIsPending(t *testing.T) {
contractStates := []ContractState{
ContractOpen, ContractSettled, ContractCanceled, ContractAccepted,
}
for _, state := range contractStates {
invoice := Invoice{
State: state,
}
// We expect that an invoice is pending if it's either in ContractOpen
// or ContractAccepted state.
pending := (state == ContractOpen || state == ContractAccepted)
if invoice.IsPending() != pending {
t.Fatalf("expected pending: %v, got: %v, invoice: %v",
pending, invoice.IsPending(), invoice)
}
}
}
type invWorkflowTest struct {
name string
queryPayHash bool
queryPayAddr bool
}
var invWorkflowTests = []invWorkflowTest{
{
name: "unknown",
queryPayHash: false,
queryPayAddr: false,
},
{
name: "only payhash known",
queryPayHash: true,
queryPayAddr: false,
},
{
name: "payaddr and payhash known",
queryPayHash: true,
queryPayAddr: true,
},
}
// TestInvoiceWorkflow asserts the basic process of inserting, fetching, and
// updating an invoice. We assert that the flow is successful using when
// querying with various combinations of payment hash and payment address.
func TestInvoiceWorkflow(t *testing.T) {
t.Parallel()
for _, test := range invWorkflowTests {
test := test
t.Run(test.name, func(t *testing.T) {
testInvoiceWorkflow(t, test)
})
}
}
func testInvoiceWorkflow(t *testing.T, test invWorkflowTest) {
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
// Create a fake invoice which we'll use several times in the tests
// below.
fakeInvoice, err := randInvoice(10000)
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
invPayHash := fakeInvoice.Terms.PaymentPreimage.Hash()
// Select the payment hash and payment address we will use to lookup or
// update the invoice for the remainder of the test.
var (
payHash lntypes.Hash
payAddr *[32]byte
ref InvoiceRef
)
switch {
case test.queryPayHash && test.queryPayAddr:
payHash = invPayHash
payAddr = &fakeInvoice.Terms.PaymentAddr
ref = InvoiceRefByHashAndAddr(payHash, *payAddr)
case test.queryPayHash:
payHash = invPayHash
ref = InvoiceRefByHash(payHash)
}
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// Add the invoice to the database, this should succeed as there aren't
// any existing invoices within the database with the same payment
// hash.
if _, err := db.AddInvoice(fakeInvoice, invPayHash); err != nil {
t.Fatalf("unable to find invoice: %v", err)
}
// Attempt to retrieve the invoice which was just added to the
// database. It should be found, and the invoice returned should be
// identical to the one created above.
dbInvoice, err := db.LookupInvoice(ref)
if !test.queryPayAddr && !test.queryPayHash {
if err != ErrInvoiceNotFound {
t.Fatalf("invoice should not exist: %v", err)
}
return
}
require.Equal(t,
*fakeInvoice, dbInvoice,
"invoice fetched from db doesn't match original",
)
// The add index of the invoice retrieved from the database should now
// be fully populated. As this is the first index written to the DB,
// the addIndex should be 1.
if dbInvoice.AddIndex != 1 {
t.Fatalf("wrong add index: expected %v, got %v", 1,
dbInvoice.AddIndex)
}
// Settle the invoice, the version retrieved from the database should
// now have the settled bit toggle to true and a non-default
// SettledDate
payAmt := fakeInvoice.Terms.Value * 2
_, err = db.UpdateInvoice(ref, getUpdateInvoice(payAmt))
if err != nil {
t.Fatalf("unable to settle invoice: %v", err)
}
dbInvoice2, err := db.LookupInvoice(ref)
if err != nil {
t.Fatalf("unable to fetch invoice: %v", err)
}
if dbInvoice2.State != ContractSettled {
t.Fatalf("invoice should now be settled but isn't")
}
if dbInvoice2.SettleDate.IsZero() {
t.Fatalf("invoice should have non-zero SettledDate but isn't")
}
// Our 2x payment should be reflected, and also the settle index of 1
// should also have been committed for this index.
if dbInvoice2.AmtPaid != payAmt {
t.Fatalf("wrong amt paid: expected %v, got %v", payAmt,
dbInvoice2.AmtPaid)
}
if dbInvoice2.SettleIndex != 1 {
t.Fatalf("wrong settle index: expected %v, got %v", 1,
dbInvoice2.SettleIndex)
}
// Attempt to insert generated above again, this should fail as
// duplicates are rejected by the processing logic.
if _, err := db.AddInvoice(fakeInvoice, payHash); err != ErrDuplicateInvoice {
t.Fatalf("invoice insertion should fail due to duplication, "+
"instead %v", err)
}
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// Attempt to look up a non-existent invoice, this should also fail but
// with a "not found" error.
var fakeHash [32]byte
fakeRef := InvoiceRefByHash(fakeHash)
_, err = db.LookupInvoice(fakeRef)
if err != ErrInvoiceNotFound {
t.Fatalf("lookup should have failed, instead %v", err)
}
// Add 10 random invoices.
const numInvoices = 10
amt := lnwire.NewMSatFromSatoshis(1000)
invoices := make([]*Invoice, numInvoices+1)
invoices[0] = &dbInvoice2
for i := 1; i < len(invoices); i++ {
invoice, err := randInvoice(amt)
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
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hash := invoice.Terms.PaymentPreimage.Hash()
if _, err := db.AddInvoice(invoice, hash); err != nil {
t.Fatalf("unable to add invoice %v", err)
}
invoices[i] = invoice
}
// Perform a scan to collect all the active invoices.
query := InvoiceQuery{
IndexOffset: 0,
NumMaxInvoices: math.MaxUint64,
PendingOnly: false,
}
response, err := db.QueryInvoices(query)
if err != nil {
t.Fatalf("invoice query failed: %v", err)
}
// The retrieve list of invoices should be identical as since we're
// using big endian, the invoices should be retrieved in ascending
// order (and the primary key should be incremented with each
// insertion).
for i := 0; i < len(invoices); i++ {
assert.Equal(t,
*invoices[i], response.Invoices[i],
"retrieved invoice doesn't match",
)
}
}
// TestAddDuplicatePayAddr asserts that the payment addresses of inserted
// invoices are unique.
func TestAddDuplicatePayAddr(t *testing.T) {
db, cleanUp, err := makeTestDB()
defer cleanUp()
assert.Nil(t, err)
// Create two invoices with the same payment addr.
invoice1, err := randInvoice(1000)
assert.Nil(t, err)
invoice2, err := randInvoice(20000)
assert.Nil(t, err)
invoice2.Terms.PaymentAddr = invoice1.Terms.PaymentAddr
// First insert should succeed.
inv1Hash := invoice1.Terms.PaymentPreimage.Hash()
_, err = db.AddInvoice(invoice1, inv1Hash)
assert.Nil(t, err)
// Second insert should fail with duplicate payment addr.
inv2Hash := invoice2.Terms.PaymentPreimage.Hash()
_, err = db.AddInvoice(invoice2, inv2Hash)
assert.Equal(t, ErrDuplicatePayAddr, err)
}
// TestInvRefEquivocation asserts that retrieving or updating an invoice using
// an equivocating InvoiceRef results in ErrInvRefEquivocation.
func TestInvRefEquivocation(t *testing.T) {
db, cleanUp, err := makeTestDB()
defer cleanUp()
assert.Nil(t, err)
// Add two random invoices.
invoice1, err := randInvoice(1000)
assert.Nil(t, err)
inv1Hash := invoice1.Terms.PaymentPreimage.Hash()
_, err = db.AddInvoice(invoice1, inv1Hash)
assert.Nil(t, err)
invoice2, err := randInvoice(2000)
assert.Nil(t, err)
inv2Hash := invoice2.Terms.PaymentPreimage.Hash()
_, err = db.AddInvoice(invoice2, inv2Hash)
assert.Nil(t, err)
// Now, query using invoice 1's payment address, but invoice 2's payment
// hash. We expect an error since the invref points to multiple
// invoices.
ref := InvoiceRefByHashAndAddr(inv2Hash, invoice1.Terms.PaymentAddr)
_, err = db.LookupInvoice(ref)
assert.Equal(t, ErrInvRefEquivocation, err)
// The same error should be returned when updating an equivocating
// reference.
nop := func(_ *Invoice) (*InvoiceUpdateDesc, error) {
return nil, nil
}
_, err = db.UpdateInvoice(ref, nop)
assert.Equal(t, ErrInvRefEquivocation, err)
}
// TestInvoiceCancelSingleHtlc tests that a single htlc can be canceled on the
// invoice.
func TestInvoiceCancelSingleHtlc(t *testing.T) {
t.Parallel()
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
preimage := lntypes.Preimage{1}
paymentHash := preimage.Hash()
testInvoice := &Invoice{
Htlcs: map[CircuitKey]*InvoiceHTLC{},
Terms: ContractTerm{
Value: lnwire.NewMSatFromSatoshis(10000),
Features: emptyFeatures,
PaymentPreimage: &preimage,
},
}
if _, err := db.AddInvoice(testInvoice, paymentHash); err != nil {
t.Fatalf("unable to find invoice: %v", err)
}
// Accept an htlc on this invoice.
key := CircuitKey{ChanID: lnwire.NewShortChanIDFromInt(1), HtlcID: 4}
htlc := HtlcAcceptDesc{
Amt: 500,
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CustomRecords: make(record.CustomSet),
}
ref := InvoiceRefByHash(paymentHash)
invoice, err := db.UpdateInvoice(ref,
func(invoice *Invoice) (*InvoiceUpdateDesc, error) {
return &InvoiceUpdateDesc{
AddHtlcs: map[CircuitKey]*HtlcAcceptDesc{
key: &htlc,
},
}, nil
})
if err != nil {
t.Fatalf("unable to add invoice htlc: %v", err)
}
if len(invoice.Htlcs) != 1 {
t.Fatalf("expected the htlc to be added")
}
if invoice.Htlcs[key].State != HtlcStateAccepted {
t.Fatalf("expected htlc in state accepted")
}
// Cancel the htlc again.
invoice, err = db.UpdateInvoice(ref,
func(invoice *Invoice) (*InvoiceUpdateDesc, error) {
return &InvoiceUpdateDesc{
CancelHtlcs: map[CircuitKey]struct{}{
key: {},
},
}, nil
})
if err != nil {
t.Fatalf("unable to cancel htlc: %v", err)
}
if len(invoice.Htlcs) != 1 {
t.Fatalf("expected the htlc to be present")
}
if invoice.Htlcs[key].State != HtlcStateCanceled {
t.Fatalf("expected htlc in state canceled")
}
}
// TestInvoiceTimeSeries tests that newly added invoices invoices, as well as
// settled invoices are added to the database are properly placed in the add
// add or settle index which serves as an event time series.
func TestInvoiceAddTimeSeries(t *testing.T) {
t.Parallel()
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
_, err = db.InvoicesAddedSince(0)
assert.Nil(t, err)
// We'll start off by creating 20 random invoices, and inserting them
// into the database.
const numInvoices = 20
amt := lnwire.NewMSatFromSatoshis(1000)
invoices := make([]Invoice, numInvoices)
for i := 0; i < len(invoices); i++ {
invoice, err := randInvoice(amt)
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
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paymentHash := invoice.Terms.PaymentPreimage.Hash()
if _, err := db.AddInvoice(invoice, paymentHash); err != nil {
t.Fatalf("unable to add invoice %v", err)
}
invoices[i] = *invoice
}
// With the invoices constructed, we'll now create a series of queries
// that we'll use to assert expected return values of
// InvoicesAddedSince.
addQueries := []struct {
sinceAddIndex uint64
resp []Invoice
}{
// If we specify a value of zero, we shouldn't get any invoices
// back.
{
sinceAddIndex: 0,
},
// If we specify a value well beyond the number of inserted
// invoices, we shouldn't get any invoices back.
{
sinceAddIndex: 99999999,
},
// Using an index of 1 should result in all values, but the
// first one being returned.
{
sinceAddIndex: 1,
resp: invoices[1:],
},
// If we use an index of 10, then we should retrieve the
// reaming 10 invoices.
{
sinceAddIndex: 10,
resp: invoices[10:],
},
}
for i, query := range addQueries {
resp, err := db.InvoicesAddedSince(query.sinceAddIndex)
if err != nil {
t.Fatalf("unable to query: %v", err)
}
require.Equal(t, len(query.resp), len(resp))
for j := 0; j < len(query.resp); j++ {
require.Equal(t,
query.resp[j], resp[j],
fmt.Sprintf("test: #%v, item: #%v", i, j),
)
}
}
_, err = db.InvoicesSettledSince(0)
assert.Nil(t, err)
var settledInvoices []Invoice
var settleIndex uint64 = 1
// We'll now only settle the latter half of each of those invoices.
for i := 10; i < len(invoices); i++ {
invoice := &invoices[i]
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paymentHash := invoice.Terms.PaymentPreimage.Hash()
ref := InvoiceRefByHash(paymentHash)
_, err := db.UpdateInvoice(
ref, getUpdateInvoice(invoice.Terms.Value),
)
if err != nil {
t.Fatalf("unable to settle invoice: %v", err)
}
// Create the settled invoice for the expectation set.
settleTestInvoice(invoice, settleIndex)
settleIndex++
settledInvoices = append(settledInvoices, *invoice)
}
// We'll now prepare an additional set of queries to ensure the settle
// time series has properly been maintained in the database.
settleQueries := []struct {
sinceSettleIndex uint64
resp []Invoice
}{
// If we specify a value of zero, we shouldn't get any settled
// invoices back.
{
sinceSettleIndex: 0,
},
// If we specify a value well beyond the number of settled
// invoices, we shouldn't get any invoices back.
{
sinceSettleIndex: 99999999,
},
// Using an index of 1 should result in the final 10 invoices
// being returned, as we only settled those.
{
sinceSettleIndex: 1,
resp: settledInvoices[1:],
},
}
for i, query := range settleQueries {
resp, err := db.InvoicesSettledSince(query.sinceSettleIndex)
if err != nil {
t.Fatalf("unable to query: %v", err)
}
require.Equal(t, len(query.resp), len(resp))
for j := 0; j < len(query.resp); j++ {
require.Equal(t,
query.resp[j], resp[j],
fmt.Sprintf("test: #%v, item: #%v", i, j),
)
}
}
}
// Tests that FetchAllInvoicesWithPaymentHash returns all invoices with their
// corresponding payment hashes.
func TestFetchAllInvoicesWithPaymentHash(t *testing.T) {
t.Parallel()
db, cleanup, err := makeTestDB()
defer cleanup()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
// With an empty DB we expect to return no error and an empty list.
empty, err := db.FetchAllInvoicesWithPaymentHash(false)
if err != nil {
t.Fatalf("failed to call FetchAllInvoicesWithPaymentHash on empty DB: %v",
err)
}
if len(empty) != 0 {
t.Fatalf("expected empty list as a result, got: %v", empty)
}
states := []ContractState{
ContractOpen, ContractSettled, ContractCanceled, ContractAccepted,
}
numInvoices := len(states) * 2
testPendingInvoices := make(map[lntypes.Hash]*Invoice)
testAllInvoices := make(map[lntypes.Hash]*Invoice)
// Now populate the DB and check if we can get all invoices with their
// payment hashes as expected.
for i := 1; i <= numInvoices; i++ {
invoice, err := randInvoice(lnwire.MilliSatoshi(i))
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
// Set the contract state of the next invoice such that there's an equal
// number for all possbile states.
invoice.State = states[i%len(states)]
paymentHash := invoice.Terms.PaymentPreimage.Hash()
if invoice.IsPending() {
testPendingInvoices[paymentHash] = invoice
}
testAllInvoices[paymentHash] = invoice
if _, err := db.AddInvoice(invoice, paymentHash); err != nil {
t.Fatalf("unable to add invoice: %v", err)
}
}
pendingInvoices, err := db.FetchAllInvoicesWithPaymentHash(true)
if err != nil {
t.Fatalf("can't fetch invoices with payment hash: %v", err)
}
if len(testPendingInvoices) != len(pendingInvoices) {
t.Fatalf("expected %v pending invoices, got: %v",
len(testPendingInvoices), len(pendingInvoices))
}
allInvoices, err := db.FetchAllInvoicesWithPaymentHash(false)
if err != nil {
t.Fatalf("can't fetch invoices with payment hash: %v", err)
}
if len(testAllInvoices) != len(allInvoices) {
t.Fatalf("expected %v invoices, got: %v",
len(testAllInvoices), len(allInvoices))
}
for i := range pendingInvoices {
expected, ok := testPendingInvoices[pendingInvoices[i].PaymentHash]
if !ok {
t.Fatalf("coulnd't find invoice with hash: %v",
pendingInvoices[i].PaymentHash)
}
// Zero out add index to not confuse require.Equal.
pendingInvoices[i].Invoice.AddIndex = 0
expected.AddIndex = 0
require.Equal(t, *expected, pendingInvoices[i].Invoice)
}
for i := range allInvoices {
expected, ok := testAllInvoices[allInvoices[i].PaymentHash]
if !ok {
t.Fatalf("coulnd't find invoice with hash: %v",
allInvoices[i].PaymentHash)
}
// Zero out add index to not confuse require.Equal.
allInvoices[i].Invoice.AddIndex = 0
expected.AddIndex = 0
require.Equal(t, *expected, allInvoices[i].Invoice)
}
}
// TestDuplicateSettleInvoice tests that if we add a new invoice and settle it
// twice, then the second time we also receive the invoice that we settled as a
// return argument.
func TestDuplicateSettleInvoice(t *testing.T) {
t.Parallel()
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
// We'll start out by creating an invoice and writing it to the DB.
amt := lnwire.NewMSatFromSatoshis(1000)
invoice, err := randInvoice(amt)
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
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payHash := invoice.Terms.PaymentPreimage.Hash()
if _, err := db.AddInvoice(invoice, payHash); err != nil {
t.Fatalf("unable to add invoice %v", err)
}
// With the invoice in the DB, we'll now attempt to settle the invoice.
ref := InvoiceRefByHash(payHash)
dbInvoice, err := db.UpdateInvoice(ref, getUpdateInvoice(amt))
if err != nil {
t.Fatalf("unable to settle invoice: %v", err)
}
// We'll update what we expect the settle invoice to be so that our
// comparison below has the correct assumption.
invoice.SettleIndex = 1
invoice.State = ContractSettled
invoice.AmtPaid = amt
invoice.SettleDate = dbInvoice.SettleDate
invoices: replay awareness Previously the invoice registry wasn't aware of replayed htlcs. This was dealt with by keeping the invoice accept/settle logic idempotent, so that a replay wouldn't have an effect. This mechanism has two limitations: 1. No accurate tracking of the total amount paid to an invoice. The total amount couldn't just be increased with every htlc received, because it could be a replay which would lead to counting the htlc amount multiple times. Therefore the total amount was set to the amount of the first htlc that was received, even though there may have been multiple htlcs paying to the invoice. 2. Impossible to check htlc expiry consistently for hodl invoices. When an htlc is new, its expiry needs to be checked against the invoice cltv delta. But for a replay, that check must be skipped. The htlc was accepted in time, the invoice was moved to the accepted state and a replay some blocks later shouldn't lead to that htlc being cancelled. Because the invoice registry couldn't recognize replays, it stopped checking htlc expiry heights when the invoice reached the accepted state. This prevents hold htlcs from being cancelled after a restart. But unfortunately this also caused additional htlcs to be accepted on an already accepted invoice without their expiry being checked. In this commit, the invoice registry starts to persistently track htlcs so that replays can be recognized. For replays, an htlc resolution action is returned early. This fixes both limitations mentioned above.
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invoice.Htlcs = map[CircuitKey]*InvoiceHTLC{
{}: {
Amt: amt,
AcceptTime: time.Unix(1, 0),
ResolveTime: time.Unix(1, 0),
State: HtlcStateSettled,
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CustomRecords: make(record.CustomSet),
invoices: replay awareness Previously the invoice registry wasn't aware of replayed htlcs. This was dealt with by keeping the invoice accept/settle logic idempotent, so that a replay wouldn't have an effect. This mechanism has two limitations: 1. No accurate tracking of the total amount paid to an invoice. The total amount couldn't just be increased with every htlc received, because it could be a replay which would lead to counting the htlc amount multiple times. Therefore the total amount was set to the amount of the first htlc that was received, even though there may have been multiple htlcs paying to the invoice. 2. Impossible to check htlc expiry consistently for hodl invoices. When an htlc is new, its expiry needs to be checked against the invoice cltv delta. But for a replay, that check must be skipped. The htlc was accepted in time, the invoice was moved to the accepted state and a replay some blocks later shouldn't lead to that htlc being cancelled. Because the invoice registry couldn't recognize replays, it stopped checking htlc expiry heights when the invoice reached the accepted state. This prevents hold htlcs from being cancelled after a restart. But unfortunately this also caused additional htlcs to be accepted on an already accepted invoice without their expiry being checked. In this commit, the invoice registry starts to persistently track htlcs so that replays can be recognized. For replays, an htlc resolution action is returned early. This fixes both limitations mentioned above.
2019-08-09 16:09:57 +03:00
},
}
// We should get back the exact same invoice that we just inserted.
require.Equal(t, invoice, dbInvoice, "wrong invoice after settle")
// If we try to settle the invoice again, then we should get the very
// same invoice back, but with an error this time.
dbInvoice, err = db.UpdateInvoice(ref, getUpdateInvoice(amt))
if err != ErrInvoiceAlreadySettled {
t.Fatalf("expected ErrInvoiceAlreadySettled")
}
if dbInvoice == nil {
t.Fatalf("invoice from db is nil after settle!")
}
invoice.SettleDate = dbInvoice.SettleDate
require.Equal(t, invoice, dbInvoice, "wrong invoice after second settle")
}
// TestQueryInvoices ensures that we can properly query the invoice database for
// invoices using different types of queries.
func TestQueryInvoices(t *testing.T) {
t.Parallel()
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
// To begin the test, we'll add 50 invoices to the database. We'll
// assume that the index of the invoice within the database is the same
// as the amount of the invoice itself.
const numInvoices = 50
var settleIndex uint64 = 1
var invoices []Invoice
var pendingInvoices []Invoice
for i := 1; i <= numInvoices; i++ {
amt := lnwire.MilliSatoshi(i)
invoice, err := randInvoice(amt)
if err != nil {
t.Fatalf("unable to create invoice: %v", err)
}
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paymentHash := invoice.Terms.PaymentPreimage.Hash()
if _, err := db.AddInvoice(invoice, paymentHash); err != nil {
t.Fatalf("unable to add invoice: %v", err)
}
// We'll only settle half of all invoices created.
if i%2 == 0 {
ref := InvoiceRefByHash(paymentHash)
_, err := db.UpdateInvoice(ref, getUpdateInvoice(amt))
if err != nil {
t.Fatalf("unable to settle invoice: %v", err)
}
// Create the settled invoice for the expectation set.
settleTestInvoice(invoice, settleIndex)
settleIndex++
} else {
pendingInvoices = append(pendingInvoices, *invoice)
}
invoices = append(invoices, *invoice)
}
// The test will consist of several queries along with their respective
// expected response. Each query response should match its expected one.
testCases := []struct {
query InvoiceQuery
expected []Invoice
}{
// Fetch all invoices with a single query.
{
query: InvoiceQuery{
NumMaxInvoices: numInvoices,
},
expected: invoices,
},
// Fetch all invoices with a single query, reversed.
{
query: InvoiceQuery{
Reversed: true,
NumMaxInvoices: numInvoices,
},
expected: invoices,
},
// Fetch the first 25 invoices.
{
query: InvoiceQuery{
NumMaxInvoices: numInvoices / 2,
},
expected: invoices[:numInvoices/2],
},
// Fetch the first 10 invoices, but this time iterating
// backwards.
{
query: InvoiceQuery{
IndexOffset: 11,
Reversed: true,
NumMaxInvoices: numInvoices,
},
expected: invoices[:10],
},
// Fetch the last 40 invoices.
{
query: InvoiceQuery{
IndexOffset: 10,
NumMaxInvoices: numInvoices,
},
expected: invoices[10:],
},
// Fetch all but the first invoice.
{
query: InvoiceQuery{
IndexOffset: 1,
NumMaxInvoices: numInvoices,
},
expected: invoices[1:],
},
// Fetch one invoice, reversed, with index offset 3. This
// should give us the second invoice in the array.
{
query: InvoiceQuery{
IndexOffset: 3,
Reversed: true,
NumMaxInvoices: 1,
},
expected: invoices[1:2],
},
// Same as above, at index 2.
{
query: InvoiceQuery{
IndexOffset: 2,
Reversed: true,
NumMaxInvoices: 1,
},
expected: invoices[0:1],
},
// Fetch one invoice, at index 1, reversed. Since invoice#1 is
// the very first, there won't be any left in a reverse search,
// so we expect no invoices to be returned.
{
query: InvoiceQuery{
IndexOffset: 1,
Reversed: true,
NumMaxInvoices: 1,
},
expected: nil,
},
// Same as above, but don't restrict the number of invoices to
// 1.
{
query: InvoiceQuery{
IndexOffset: 1,
Reversed: true,
NumMaxInvoices: numInvoices,
},
expected: nil,
},
// Fetch one invoice, reversed, with no offset set. We expect
// the last invoice in the response.
{
query: InvoiceQuery{
Reversed: true,
NumMaxInvoices: 1,
},
expected: invoices[numInvoices-1:],
},
// Fetch one invoice, reversed, the offset set at numInvoices+1.
// We expect this to return the last invoice.
{
query: InvoiceQuery{
IndexOffset: numInvoices + 1,
Reversed: true,
NumMaxInvoices: 1,
},
expected: invoices[numInvoices-1:],
},
// Same as above, at offset numInvoices.
{
query: InvoiceQuery{
IndexOffset: numInvoices,
Reversed: true,
NumMaxInvoices: 1,
},
expected: invoices[numInvoices-2 : numInvoices-1],
},
// Fetch one invoice, at no offset (same as offset 0). We
// expect the first invoice only in the response.
{
query: InvoiceQuery{
NumMaxInvoices: 1,
},
expected: invoices[:1],
},
// Same as above, at offset 1.
{
query: InvoiceQuery{
IndexOffset: 1,
NumMaxInvoices: 1,
},
expected: invoices[1:2],
},
// Same as above, at offset 2.
{
query: InvoiceQuery{
IndexOffset: 2,
NumMaxInvoices: 1,
},
expected: invoices[2:3],
},
// Same as above, at offset numInvoices-1. Expect the last
// invoice to be returned.
{
query: InvoiceQuery{
IndexOffset: numInvoices - 1,
NumMaxInvoices: 1,
},
expected: invoices[numInvoices-1:],
},
// Same as above, at offset numInvoices. No invoices should be
// returned, as there are no invoices after this offset.
{
query: InvoiceQuery{
IndexOffset: numInvoices,
NumMaxInvoices: 1,
},
expected: nil,
},
// Fetch all pending invoices with a single query.
{
query: InvoiceQuery{
PendingOnly: true,
NumMaxInvoices: numInvoices,
},
expected: pendingInvoices,
},
// Fetch the first 12 pending invoices.
{
query: InvoiceQuery{
PendingOnly: true,
NumMaxInvoices: numInvoices / 4,
},
expected: pendingInvoices[:len(pendingInvoices)/2],
},
// Fetch the first 5 pending invoices, but this time iterating
// backwards.
{
query: InvoiceQuery{
IndexOffset: 10,
PendingOnly: true,
Reversed: true,
NumMaxInvoices: numInvoices,
},
// Since we seek to the invoice with index 10 and
// iterate backwards, there should only be 5 pending
// invoices before it as every other invoice within the
// index is settled.
expected: pendingInvoices[:5],
},
// Fetch the last 15 invoices.
{
query: InvoiceQuery{
IndexOffset: 20,
PendingOnly: true,
NumMaxInvoices: numInvoices,
},
// Since we seek to the invoice with index 20, there are
// 30 invoices left. From these 30, only 15 of them are
// still pending.
expected: pendingInvoices[len(pendingInvoices)-15:],
},
}
for i, testCase := range testCases {
response, err := db.QueryInvoices(testCase.query)
if err != nil {
t.Fatalf("unable to query invoice database: %v", err)
}
require.Equal(t, len(testCase.expected), len(response.Invoices))
for j, expected := range testCase.expected {
require.Equal(t,
expected, response.Invoices[j],
fmt.Sprintf("test: #%v, item: #%v", i, j),
)
}
}
}
// getUpdateInvoice returns an invoice update callback that, when called,
// settles the invoice with the given amount.
func getUpdateInvoice(amt lnwire.MilliSatoshi) InvoiceUpdateCallback {
return func(invoice *Invoice) (*InvoiceUpdateDesc, error) {
if invoice.State == ContractSettled {
return nil, ErrInvoiceAlreadySettled
}
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noRecords := make(record.CustomSet)
update := &InvoiceUpdateDesc{
State: &InvoiceStateUpdateDesc{
Preimage: invoice.Terms.PaymentPreimage,
NewState: ContractSettled,
},
AddHtlcs: map[CircuitKey]*HtlcAcceptDesc{
invoices: replay awareness Previously the invoice registry wasn't aware of replayed htlcs. This was dealt with by keeping the invoice accept/settle logic idempotent, so that a replay wouldn't have an effect. This mechanism has two limitations: 1. No accurate tracking of the total amount paid to an invoice. The total amount couldn't just be increased with every htlc received, because it could be a replay which would lead to counting the htlc amount multiple times. Therefore the total amount was set to the amount of the first htlc that was received, even though there may have been multiple htlcs paying to the invoice. 2. Impossible to check htlc expiry consistently for hodl invoices. When an htlc is new, its expiry needs to be checked against the invoice cltv delta. But for a replay, that check must be skipped. The htlc was accepted in time, the invoice was moved to the accepted state and a replay some blocks later shouldn't lead to that htlc being cancelled. Because the invoice registry couldn't recognize replays, it stopped checking htlc expiry heights when the invoice reached the accepted state. This prevents hold htlcs from being cancelled after a restart. But unfortunately this also caused additional htlcs to be accepted on an already accepted invoice without their expiry being checked. In this commit, the invoice registry starts to persistently track htlcs so that replays can be recognized. For replays, an htlc resolution action is returned early. This fixes both limitations mentioned above.
2019-08-09 16:09:57 +03:00
{}: {
Amt: amt,
CustomRecords: noRecords,
invoices: replay awareness Previously the invoice registry wasn't aware of replayed htlcs. This was dealt with by keeping the invoice accept/settle logic idempotent, so that a replay wouldn't have an effect. This mechanism has two limitations: 1. No accurate tracking of the total amount paid to an invoice. The total amount couldn't just be increased with every htlc received, because it could be a replay which would lead to counting the htlc amount multiple times. Therefore the total amount was set to the amount of the first htlc that was received, even though there may have been multiple htlcs paying to the invoice. 2. Impossible to check htlc expiry consistently for hodl invoices. When an htlc is new, its expiry needs to be checked against the invoice cltv delta. But for a replay, that check must be skipped. The htlc was accepted in time, the invoice was moved to the accepted state and a replay some blocks later shouldn't lead to that htlc being cancelled. Because the invoice registry couldn't recognize replays, it stopped checking htlc expiry heights when the invoice reached the accepted state. This prevents hold htlcs from being cancelled after a restart. But unfortunately this also caused additional htlcs to be accepted on an already accepted invoice without their expiry being checked. In this commit, the invoice registry starts to persistently track htlcs so that replays can be recognized. For replays, an htlc resolution action is returned early. This fixes both limitations mentioned above.
2019-08-09 16:09:57 +03:00
},
},
}
return update, nil
}
}
// TestCustomRecords tests that custom records are properly recorded in the
// invoice database.
func TestCustomRecords(t *testing.T) {
t.Parallel()
db, cleanUp, err := makeTestDB()
defer cleanUp()
if err != nil {
t.Fatalf("unable to make test db: %v", err)
}
preimage := lntypes.Preimage{1}
paymentHash := preimage.Hash()
testInvoice := &Invoice{
Htlcs: map[CircuitKey]*InvoiceHTLC{},
Terms: ContractTerm{
Value: lnwire.NewMSatFromSatoshis(10000),
Features: emptyFeatures,
PaymentPreimage: &preimage,
},
}
if _, err := db.AddInvoice(testInvoice, paymentHash); err != nil {
t.Fatalf("unable to add invoice: %v", err)
}
// Accept an htlc with custom records on this invoice.
key := CircuitKey{ChanID: lnwire.NewShortChanIDFromInt(1), HtlcID: 4}
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records := record.CustomSet{
100000: []byte{},
100001: []byte{1, 2},
}
ref := InvoiceRefByHash(paymentHash)
_, err = db.UpdateInvoice(ref,
func(invoice *Invoice) (*InvoiceUpdateDesc, error) {
return &InvoiceUpdateDesc{
AddHtlcs: map[CircuitKey]*HtlcAcceptDesc{
key: {
Amt: 500,
CustomRecords: records,
},
},
}, nil
},
)
if err != nil {
t.Fatalf("unable to add invoice htlc: %v", err)
}
// Retrieve the invoice from that database and verify that the custom
// records are present.
dbInvoice, err := db.LookupInvoice(ref)
if err != nil {
t.Fatalf("unable to lookup invoice: %v", err)
}
if len(dbInvoice.Htlcs) != 1 {
t.Fatalf("expected the htlc to be added")
}
require.Equal(t,
records, dbInvoice.Htlcs[key].CustomRecords,
"invalid custom records",
)
}
// TestInvoiceRef asserts that the proper identifiers are returned from an
// InvoiceRef depending on the constructor used.
func TestInvoiceRef(t *testing.T) {
payHash := lntypes.Hash{0x01}
payAddr := [32]byte{0x02}
// An InvoiceRef by hash should return the provided hash and a nil
// payment addr.
refByHash := InvoiceRefByHash(payHash)
require.Equal(t, payHash, refByHash.PayHash())
require.Equal(t, (*[32]byte)(nil), refByHash.PayAddr())
// An InvoiceRef by hash and addr should return the payment hash and
// payment addr passed to the constructor.
refByHashAndAddr := InvoiceRefByHashAndAddr(payHash, payAddr)
require.Equal(t, payHash, refByHashAndAddr.PayHash())
require.Equal(t, &payAddr, refByHashAndAddr.PayAddr())
}