btcd/database/ffldb/interface_test.go
Dave Collins 915fa6639b
multi: Simplify code per gosimple linter.
This simplifies the code based on the recommendations of the gosimple
lint tool.
2016-11-03 13:00:35 -05:00

2302 lines
64 KiB
Go

// Copyright (c) 2015-2016 The btcsuite developers
// Use of this source code is governed by an ISC
// license that can be found in the LICENSE file.
// This file intended to be copied into each backend driver directory. Each
// driver should have their own driver_test.go file which creates a database and
// invokes the testInterface function in this file to ensure the driver properly
// implements the interface.
//
// NOTE: When copying this file into the backend driver folder, the package name
// will need to be changed accordingly.
package ffldb_test
import (
"bytes"
"compress/bzip2"
"encoding/binary"
"fmt"
"io"
"os"
"path/filepath"
"reflect"
"sync/atomic"
"testing"
"time"
"github.com/btcsuite/btcd/chaincfg"
"github.com/btcsuite/btcd/chaincfg/chainhash"
"github.com/btcsuite/btcd/database"
"github.com/btcsuite/btcd/wire"
"github.com/btcsuite/btcutil"
)
var (
// blockDataNet is the expected network in the test block data.
blockDataNet = wire.MainNet
// blockDataFile is the path to a file containing the first 256 blocks
// of the block chain.
blockDataFile = filepath.Join("..", "testdata", "blocks1-256.bz2")
// errSubTestFail is used to signal that a sub test returned false.
errSubTestFail = fmt.Errorf("sub test failure")
)
// loadBlocks loads the blocks contained in the testdata directory and returns
// a slice of them.
func loadBlocks(t *testing.T, dataFile string, network wire.BitcoinNet) ([]*btcutil.Block, error) {
// Open the file that contains the blocks for reading.
fi, err := os.Open(dataFile)
if err != nil {
t.Errorf("failed to open file %v, err %v", dataFile, err)
return nil, err
}
defer func() {
if err := fi.Close(); err != nil {
t.Errorf("failed to close file %v %v", dataFile,
err)
}
}()
dr := bzip2.NewReader(fi)
// Set the first block as the genesis block.
blocks := make([]*btcutil.Block, 0, 256)
genesis := btcutil.NewBlock(chaincfg.MainNetParams.GenesisBlock)
blocks = append(blocks, genesis)
// Load the remaining blocks.
for height := 1; ; height++ {
var net uint32
err := binary.Read(dr, binary.LittleEndian, &net)
if err == io.EOF {
// Hit end of file at the expected offset. No error.
break
}
if err != nil {
t.Errorf("Failed to load network type for block %d: %v",
height, err)
return nil, err
}
if net != uint32(network) {
t.Errorf("Block doesn't match network: %v expects %v",
net, network)
return nil, err
}
var blockLen uint32
err = binary.Read(dr, binary.LittleEndian, &blockLen)
if err != nil {
t.Errorf("Failed to load block size for block %d: %v",
height, err)
return nil, err
}
// Read the block.
blockBytes := make([]byte, blockLen)
_, err = io.ReadFull(dr, blockBytes)
if err != nil {
t.Errorf("Failed to load block %d: %v", height, err)
return nil, err
}
// Deserialize and store the block.
block, err := btcutil.NewBlockFromBytes(blockBytes)
if err != nil {
t.Errorf("Failed to parse block %v: %v", height, err)
return nil, err
}
blocks = append(blocks, block)
}
return blocks, nil
}
// checkDbError ensures the passed error is a database.Error with an error code
// that matches the passed error code.
func checkDbError(t *testing.T, testName string, gotErr error, wantErrCode database.ErrorCode) bool {
dbErr, ok := gotErr.(database.Error)
if !ok {
t.Errorf("%s: unexpected error type - got %T, want %T",
testName, gotErr, database.Error{})
return false
}
if dbErr.ErrorCode != wantErrCode {
t.Errorf("%s: unexpected error code - got %s (%s), want %s",
testName, dbErr.ErrorCode, dbErr.Description,
wantErrCode)
return false
}
return true
}
// testContext is used to store context information about a running test which
// is passed into helper functions.
type testContext struct {
t *testing.T
db database.DB
bucketDepth int
isWritable bool
blocks []*btcutil.Block
}
// keyPair houses a key/value pair. It is used over maps so ordering can be
// maintained.
type keyPair struct {
key []byte
value []byte
}
// lookupKey is a convenience method to lookup the requested key from the
// provided keypair slice along with whether or not the key was found.
func lookupKey(key []byte, values []keyPair) ([]byte, bool) {
for _, item := range values {
if bytes.Equal(item.key, key) {
return item.value, true
}
}
return nil, false
}
// toGetValues returns a copy of the provided keypairs with all of the nil
// values set to an empty byte slice. This is used to ensure that keys set to
// nil values result in empty byte slices when retrieved instead of nil.
func toGetValues(values []keyPair) []keyPair {
ret := make([]keyPair, len(values))
copy(ret, values)
for i := range ret {
if ret[i].value == nil {
ret[i].value = make([]byte, 0)
}
}
return ret
}
// rollbackValues returns a copy of the provided keypairs with all values set to
// nil. This is used to test that values are properly rolled back.
func rollbackValues(values []keyPair) []keyPair {
ret := make([]keyPair, len(values))
copy(ret, values)
for i := range ret {
ret[i].value = nil
}
return ret
}
// testCursorKeyPair checks that the provide key and value match the expected
// keypair at the provided index. It also ensures the index is in range for the
// provided slice of expected keypairs.
func testCursorKeyPair(tc *testContext, k, v []byte, index int, values []keyPair) bool {
if index >= len(values) || index < 0 {
tc.t.Errorf("Cursor: exceeded the expected range of values - "+
"index %d, num values %d", index, len(values))
return false
}
pair := &values[index]
if !bytes.Equal(k, pair.key) {
tc.t.Errorf("Mismatched cursor key: index %d does not match "+
"the expected key - got %q, want %q", index, k,
pair.key)
return false
}
if !bytes.Equal(v, pair.value) {
tc.t.Errorf("Mismatched cursor value: index %d does not match "+
"the expected value - got %q, want %q", index, v,
pair.value)
return false
}
return true
}
// testGetValues checks that all of the provided key/value pairs can be
// retrieved from the database and the retrieved values match the provided
// values.
func testGetValues(tc *testContext, bucket database.Bucket, values []keyPair) bool {
for _, item := range values {
gotValue := bucket.Get(item.key)
if !reflect.DeepEqual(gotValue, item.value) {
tc.t.Errorf("Get: unexpected value for %q - got %q, "+
"want %q", item.key, gotValue, item.value)
return false
}
}
return true
}
// testPutValues stores all of the provided key/value pairs in the provided
// bucket while checking for errors.
func testPutValues(tc *testContext, bucket database.Bucket, values []keyPair) bool {
for _, item := range values {
if err := bucket.Put(item.key, item.value); err != nil {
tc.t.Errorf("Put: unexpected error: %v", err)
return false
}
}
return true
}
// testDeleteValues removes all of the provided key/value pairs from the
// provided bucket.
func testDeleteValues(tc *testContext, bucket database.Bucket, values []keyPair) bool {
for _, item := range values {
if err := bucket.Delete(item.key); err != nil {
tc.t.Errorf("Delete: unexpected error: %v", err)
return false
}
}
return true
}
// testCursorInterface ensures the cursor itnerface is working properly by
// exercising all of its functions on the passed bucket.
func testCursorInterface(tc *testContext, bucket database.Bucket) bool {
// Ensure a cursor can be obtained for the bucket.
cursor := bucket.Cursor()
if cursor == nil {
tc.t.Error("Bucket.Cursor: unexpected nil cursor returned")
return false
}
// Ensure the cursor returns the same bucket it was created for.
if cursor.Bucket() != bucket {
tc.t.Error("Cursor.Bucket: does not match the bucket it was " +
"created for")
return false
}
if tc.isWritable {
unsortedValues := []keyPair{
{[]byte("cursor"), []byte("val1")},
{[]byte("abcd"), []byte("val2")},
{[]byte("bcd"), []byte("val3")},
{[]byte("defg"), nil},
}
sortedValues := []keyPair{
{[]byte("abcd"), []byte("val2")},
{[]byte("bcd"), []byte("val3")},
{[]byte("cursor"), []byte("val1")},
{[]byte("defg"), nil},
}
// Store the values to be used in the cursor tests in unsorted
// order and ensure they were actually stored.
if !testPutValues(tc, bucket, unsortedValues) {
return false
}
if !testGetValues(tc, bucket, toGetValues(unsortedValues)) {
return false
}
// Ensure the cursor returns all items in byte-sorted order when
// iterating forward.
curIdx := 0
for ok := cursor.First(); ok; ok = cursor.Next() {
k, v := cursor.Key(), cursor.Value()
if !testCursorKeyPair(tc, k, v, curIdx, sortedValues) {
return false
}
curIdx++
}
if curIdx != len(unsortedValues) {
tc.t.Errorf("Cursor: expected to iterate %d values, "+
"but only iterated %d", len(unsortedValues),
curIdx)
return false
}
// Ensure the cursor returns all items in reverse byte-sorted
// order when iterating in reverse.
curIdx = len(sortedValues) - 1
for ok := cursor.Last(); ok; ok = cursor.Prev() {
k, v := cursor.Key(), cursor.Value()
if !testCursorKeyPair(tc, k, v, curIdx, sortedValues) {
return false
}
curIdx--
}
if curIdx > -1 {
tc.t.Errorf("Reverse cursor: expected to iterate %d "+
"values, but only iterated %d",
len(sortedValues), len(sortedValues)-(curIdx+1))
return false
}
// Ensure forward iteration works as expected after seeking.
middleIdx := (len(sortedValues) - 1) / 2
seekKey := sortedValues[middleIdx].key
curIdx = middleIdx
for ok := cursor.Seek(seekKey); ok; ok = cursor.Next() {
k, v := cursor.Key(), cursor.Value()
if !testCursorKeyPair(tc, k, v, curIdx, sortedValues) {
return false
}
curIdx++
}
if curIdx != len(sortedValues) {
tc.t.Errorf("Cursor after seek: expected to iterate "+
"%d values, but only iterated %d",
len(sortedValues)-middleIdx, curIdx-middleIdx)
return false
}
// Ensure reverse iteration works as expected after seeking.
curIdx = middleIdx
for ok := cursor.Seek(seekKey); ok; ok = cursor.Prev() {
k, v := cursor.Key(), cursor.Value()
if !testCursorKeyPair(tc, k, v, curIdx, sortedValues) {
return false
}
curIdx--
}
if curIdx > -1 {
tc.t.Errorf("Reverse cursor after seek: expected to "+
"iterate %d values, but only iterated %d",
len(sortedValues)-middleIdx, middleIdx-curIdx)
return false
}
// Ensure the cursor deletes items properly.
if !cursor.First() {
tc.t.Errorf("Cursor.First: no value")
return false
}
k := cursor.Key()
if err := cursor.Delete(); err != nil {
tc.t.Errorf("Cursor.Delete: unexpected error: %v", err)
return false
}
if val := bucket.Get(k); val != nil {
tc.t.Errorf("Cursor.Delete: value for key %q was not "+
"deleted", k)
return false
}
}
return true
}
// testNestedBucket reruns the testBucketInterface against a nested bucket along
// with a counter to only test a couple of level deep.
func testNestedBucket(tc *testContext, testBucket database.Bucket) bool {
// Don't go more than 2 nested levels deep.
if tc.bucketDepth > 1 {
return true
}
tc.bucketDepth++
defer func() {
tc.bucketDepth--
}()
return testBucketInterface(tc, testBucket)
}
// testBucketInterface ensures the bucket interface is working properly by
// exercising all of its functions. This includes the cursor interface for the
// cursor returned from the bucket.
func testBucketInterface(tc *testContext, bucket database.Bucket) bool {
if bucket.Writable() != tc.isWritable {
tc.t.Errorf("Bucket writable state does not match.")
return false
}
if tc.isWritable {
// keyValues holds the keys and values to use when putting
// values into the bucket.
keyValues := []keyPair{
{[]byte("bucketkey1"), []byte("foo1")},
{[]byte("bucketkey2"), []byte("foo2")},
{[]byte("bucketkey3"), []byte("foo3")},
{[]byte("bucketkey4"), nil},
}
expectedKeyValues := toGetValues(keyValues)
if !testPutValues(tc, bucket, keyValues) {
return false
}
if !testGetValues(tc, bucket, expectedKeyValues) {
return false
}
// Ensure errors returned from the user-supplied ForEach
// function are returned.
forEachError := fmt.Errorf("example foreach error")
err := bucket.ForEach(func(k, v []byte) error {
return forEachError
})
if err != forEachError {
tc.t.Errorf("ForEach: inner function error not "+
"returned - got %v, want %v", err, forEachError)
return false
}
// Iterate all of the keys using ForEach while making sure the
// stored values are the expected values.
keysFound := make(map[string]struct{}, len(keyValues))
err = bucket.ForEach(func(k, v []byte) error {
wantV, found := lookupKey(k, expectedKeyValues)
if !found {
return fmt.Errorf("ForEach: key '%s' should "+
"exist", k)
}
if !reflect.DeepEqual(v, wantV) {
return fmt.Errorf("ForEach: value for key '%s' "+
"does not match - got %s, want %s", k,
v, wantV)
}
keysFound[string(k)] = struct{}{}
return nil
})
if err != nil {
tc.t.Errorf("%v", err)
return false
}
// Ensure all keys were iterated.
for _, item := range keyValues {
if _, ok := keysFound[string(item.key)]; !ok {
tc.t.Errorf("ForEach: key '%s' was not iterated "+
"when it should have been", item.key)
return false
}
}
// Delete the keys and ensure they were deleted.
if !testDeleteValues(tc, bucket, keyValues) {
return false
}
if !testGetValues(tc, bucket, rollbackValues(keyValues)) {
return false
}
// Ensure creating a new bucket works as expected.
testBucketName := []byte("testbucket")
testBucket, err := bucket.CreateBucket(testBucketName)
if err != nil {
tc.t.Errorf("CreateBucket: unexpected error: %v", err)
return false
}
if !testNestedBucket(tc, testBucket) {
return false
}
// Ensure errors returned from the user-supplied ForEachBucket
// function are returned.
err = bucket.ForEachBucket(func(k []byte) error {
return forEachError
})
if err != forEachError {
tc.t.Errorf("ForEachBucket: inner function error not "+
"returned - got %v, want %v", err, forEachError)
return false
}
// Ensure creating a bucket that already exists fails with the
// expected error.
wantErrCode := database.ErrBucketExists
_, err = bucket.CreateBucket(testBucketName)
if !checkDbError(tc.t, "CreateBucket", err, wantErrCode) {
return false
}
// Ensure CreateBucketIfNotExists returns an existing bucket.
testBucket, err = bucket.CreateBucketIfNotExists(testBucketName)
if err != nil {
tc.t.Errorf("CreateBucketIfNotExists: unexpected "+
"error: %v", err)
return false
}
if !testNestedBucket(tc, testBucket) {
return false
}
// Ensure retrieving an existing bucket works as expected.
testBucket = bucket.Bucket(testBucketName)
if !testNestedBucket(tc, testBucket) {
return false
}
// Ensure deleting a bucket works as intended.
if err := bucket.DeleteBucket(testBucketName); err != nil {
tc.t.Errorf("DeleteBucket: unexpected error: %v", err)
return false
}
if b := bucket.Bucket(testBucketName); b != nil {
tc.t.Errorf("DeleteBucket: bucket '%s' still exists",
testBucketName)
return false
}
// Ensure deleting a bucket that doesn't exist returns the
// expected error.
wantErrCode = database.ErrBucketNotFound
err = bucket.DeleteBucket(testBucketName)
if !checkDbError(tc.t, "DeleteBucket", err, wantErrCode) {
return false
}
// Ensure CreateBucketIfNotExists creates a new bucket when
// it doesn't already exist.
testBucket, err = bucket.CreateBucketIfNotExists(testBucketName)
if err != nil {
tc.t.Errorf("CreateBucketIfNotExists: unexpected "+
"error: %v", err)
return false
}
if !testNestedBucket(tc, testBucket) {
return false
}
// Ensure the cursor interface works as expected.
if !testCursorInterface(tc, testBucket) {
return false
}
// Delete the test bucket to avoid leaving it around for future
// calls.
if err := bucket.DeleteBucket(testBucketName); err != nil {
tc.t.Errorf("DeleteBucket: unexpected error: %v", err)
return false
}
if b := bucket.Bucket(testBucketName); b != nil {
tc.t.Errorf("DeleteBucket: bucket '%s' still exists",
testBucketName)
return false
}
} else {
// Put should fail with bucket that is not writable.
testName := "unwritable tx put"
wantErrCode := database.ErrTxNotWritable
failBytes := []byte("fail")
err := bucket.Put(failBytes, failBytes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Delete should fail with bucket that is not writable.
testName = "unwritable tx delete"
err = bucket.Delete(failBytes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// CreateBucket should fail with bucket that is not writable.
testName = "unwritable tx create bucket"
_, err = bucket.CreateBucket(failBytes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// CreateBucketIfNotExists should fail with bucket that is not
// writable.
testName = "unwritable tx create bucket if not exists"
_, err = bucket.CreateBucketIfNotExists(failBytes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// DeleteBucket should fail with bucket that is not writable.
testName = "unwritable tx delete bucket"
err = bucket.DeleteBucket(failBytes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure the cursor interface works as expected with read-only
// buckets.
if !testCursorInterface(tc, bucket) {
return false
}
}
return true
}
// rollbackOnPanic rolls the passed transaction back if the code in the calling
// function panics. This is useful in case the tests unexpectedly panic which
// would leave any manually created transactions with the database mutex locked
// thereby leading to a deadlock and masking the real reason for the panic. It
// also logs a test error and repanics so the original panic can be traced.
func rollbackOnPanic(t *testing.T, tx database.Tx) {
if err := recover(); err != nil {
t.Errorf("Unexpected panic: %v", err)
_ = tx.Rollback()
panic(err)
}
}
// testMetadataManualTxInterface ensures that the manual transactions metadata
// interface works as expected.
func testMetadataManualTxInterface(tc *testContext) bool {
// populateValues tests that populating values works as expected.
//
// When the writable flag is false, a read-only tranasction is created,
// standard bucket tests for read-only transactions are performed, and
// the Commit function is checked to ensure it fails as expected.
//
// Otherwise, a read-write transaction is created, the values are
// written, standard bucket tests for read-write transactions are
// performed, and then the transaction is either committed or rolled
// back depending on the flag.
bucket1Name := []byte("bucket1")
populateValues := func(writable, rollback bool, putValues []keyPair) bool {
tx, err := tc.db.Begin(writable)
if err != nil {
tc.t.Errorf("Begin: unexpected error %v", err)
return false
}
defer rollbackOnPanic(tc.t, tx)
metadataBucket := tx.Metadata()
if metadataBucket == nil {
tc.t.Errorf("Metadata: unexpected nil bucket")
_ = tx.Rollback()
return false
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
tc.t.Errorf("Bucket1: unexpected nil bucket")
return false
}
tc.isWritable = writable
if !testBucketInterface(tc, bucket1) {
_ = tx.Rollback()
return false
}
if !writable {
// The transaction is not writable, so it should fail
// the commit.
testName := "unwritable tx commit"
wantErrCode := database.ErrTxNotWritable
err := tx.Commit()
if !checkDbError(tc.t, testName, err, wantErrCode) {
_ = tx.Rollback()
return false
}
} else {
if !testPutValues(tc, bucket1, putValues) {
return false
}
if rollback {
// Rollback the transaction.
if err := tx.Rollback(); err != nil {
tc.t.Errorf("Rollback: unexpected "+
"error %v", err)
return false
}
} else {
// The commit should succeed.
if err := tx.Commit(); err != nil {
tc.t.Errorf("Commit: unexpected error "+
"%v", err)
return false
}
}
}
return true
}
// checkValues starts a read-only transaction and checks that all of
// the key/value pairs specified in the expectedValues parameter match
// what's in the database.
checkValues := func(expectedValues []keyPair) bool {
tx, err := tc.db.Begin(false)
if err != nil {
tc.t.Errorf("Begin: unexpected error %v", err)
return false
}
defer rollbackOnPanic(tc.t, tx)
metadataBucket := tx.Metadata()
if metadataBucket == nil {
tc.t.Errorf("Metadata: unexpected nil bucket")
_ = tx.Rollback()
return false
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
tc.t.Errorf("Bucket1: unexpected nil bucket")
return false
}
if !testGetValues(tc, bucket1, expectedValues) {
_ = tx.Rollback()
return false
}
// Rollback the read-only transaction.
if err := tx.Rollback(); err != nil {
tc.t.Errorf("Commit: unexpected error %v", err)
return false
}
return true
}
// deleteValues starts a read-write transaction and deletes the keys
// in the passed key/value pairs.
deleteValues := func(values []keyPair) bool {
tx, err := tc.db.Begin(true)
if err != nil {
}
defer rollbackOnPanic(tc.t, tx)
metadataBucket := tx.Metadata()
if metadataBucket == nil {
tc.t.Errorf("Metadata: unexpected nil bucket")
_ = tx.Rollback()
return false
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
tc.t.Errorf("Bucket1: unexpected nil bucket")
return false
}
// Delete the keys and ensure they were deleted.
if !testDeleteValues(tc, bucket1, values) {
_ = tx.Rollback()
return false
}
if !testGetValues(tc, bucket1, rollbackValues(values)) {
_ = tx.Rollback()
return false
}
// Commit the changes and ensure it was successful.
if err := tx.Commit(); err != nil {
tc.t.Errorf("Commit: unexpected error %v", err)
return false
}
return true
}
// keyValues holds the keys and values to use when putting values into a
// bucket.
var keyValues = []keyPair{
{[]byte("umtxkey1"), []byte("foo1")},
{[]byte("umtxkey2"), []byte("foo2")},
{[]byte("umtxkey3"), []byte("foo3")},
{[]byte("umtxkey4"), nil},
}
// Ensure that attempting populating the values using a read-only
// transaction fails as expected.
if !populateValues(false, true, keyValues) {
return false
}
if !checkValues(rollbackValues(keyValues)) {
return false
}
// Ensure that attempting populating the values using a read-write
// transaction and then rolling it back yields the expected values.
if !populateValues(true, true, keyValues) {
return false
}
if !checkValues(rollbackValues(keyValues)) {
return false
}
// Ensure that attempting populating the values using a read-write
// transaction and then committing it stores the expected values.
if !populateValues(true, false, keyValues) {
return false
}
if !checkValues(toGetValues(keyValues)) {
return false
}
// Clean up the keys.
if !deleteValues(keyValues) {
return false
}
return true
}
// testManagedTxPanics ensures calling Rollback of Commit inside a managed
// transaction panics.
func testManagedTxPanics(tc *testContext) bool {
testPanic := func(fn func()) (paniced bool) {
// Setup a defer to catch the expected panic and update the
// return variable.
defer func() {
if err := recover(); err != nil {
paniced = true
}
}()
fn()
return false
}
// Ensure calling Commit on a managed read-only transaction panics.
paniced := testPanic(func() {
tc.db.View(func(tx database.Tx) error {
tx.Commit()
return nil
})
})
if !paniced {
tc.t.Error("Commit called inside View did not panic")
return false
}
// Ensure calling Rollback on a managed read-only transaction panics.
paniced = testPanic(func() {
tc.db.View(func(tx database.Tx) error {
tx.Rollback()
return nil
})
})
if !paniced {
tc.t.Error("Rollback called inside View did not panic")
return false
}
// Ensure calling Commit on a managed read-write transaction panics.
paniced = testPanic(func() {
tc.db.Update(func(tx database.Tx) error {
tx.Commit()
return nil
})
})
if !paniced {
tc.t.Error("Commit called inside Update did not panic")
return false
}
// Ensure calling Rollback on a managed read-write transaction panics.
paniced = testPanic(func() {
tc.db.Update(func(tx database.Tx) error {
tx.Rollback()
return nil
})
})
if !paniced {
tc.t.Error("Rollback called inside Update did not panic")
return false
}
return true
}
// testMetadataTxInterface tests all facets of the managed read/write and
// manual transaction metadata interfaces as well as the bucket interfaces under
// them.
func testMetadataTxInterface(tc *testContext) bool {
if !testManagedTxPanics(tc) {
return false
}
bucket1Name := []byte("bucket1")
err := tc.db.Update(func(tx database.Tx) error {
_, err := tx.Metadata().CreateBucket(bucket1Name)
return err
})
if err != nil {
tc.t.Errorf("Update: unexpected error creating bucket: %v", err)
return false
}
if !testMetadataManualTxInterface(tc) {
return false
}
// keyValues holds the keys and values to use when putting values
// into a bucket.
keyValues := []keyPair{
{[]byte("mtxkey1"), []byte("foo1")},
{[]byte("mtxkey2"), []byte("foo2")},
{[]byte("mtxkey3"), []byte("foo3")},
{[]byte("mtxkey4"), nil},
}
// Test the bucket interface via a managed read-only transaction.
err = tc.db.View(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
return fmt.Errorf("Bucket1: unexpected nil bucket")
}
tc.isWritable = false
if !testBucketInterface(tc, bucket1) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Ensure errors returned from the user-supplied View function are
// returned.
viewError := fmt.Errorf("example view error")
err = tc.db.View(func(tx database.Tx) error {
return viewError
})
if err != viewError {
tc.t.Errorf("View: inner function error not returned - got "+
"%v, want %v", err, viewError)
return false
}
// Test the bucket interface via a managed read-write transaction.
// Also, put a series of values and force a rollback so the following
// code can ensure the values were not stored.
forceRollbackError := fmt.Errorf("force rollback")
err = tc.db.Update(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
return fmt.Errorf("Bucket1: unexpected nil bucket")
}
tc.isWritable = true
if !testBucketInterface(tc, bucket1) {
return errSubTestFail
}
if !testPutValues(tc, bucket1, keyValues) {
return errSubTestFail
}
// Return an error to force a rollback.
return forceRollbackError
})
if err != forceRollbackError {
if err == errSubTestFail {
return false
}
tc.t.Errorf("Update: inner function error not returned - got "+
"%v, want %v", err, forceRollbackError)
return false
}
// Ensure the values that should not have been stored due to the forced
// rollback above were not actually stored.
err = tc.db.View(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
if !testGetValues(tc, metadataBucket, rollbackValues(keyValues)) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Store a series of values via a managed read-write transaction.
err = tc.db.Update(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
return fmt.Errorf("Bucket1: unexpected nil bucket")
}
if !testPutValues(tc, bucket1, keyValues) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Ensure the values stored above were committed as expected.
err = tc.db.View(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
return fmt.Errorf("Bucket1: unexpected nil bucket")
}
if !testGetValues(tc, bucket1, toGetValues(keyValues)) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Clean up the values stored above in a managed read-write transaction.
err = tc.db.Update(func(tx database.Tx) error {
metadataBucket := tx.Metadata()
if metadataBucket == nil {
return fmt.Errorf("Metadata: unexpected nil bucket")
}
bucket1 := metadataBucket.Bucket(bucket1Name)
if bucket1 == nil {
return fmt.Errorf("Bucket1: unexpected nil bucket")
}
if !testDeleteValues(tc, bucket1, keyValues) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
return true
}
// testFetchBlockIOMissing ensures that all of the block retrieval API functions
// work as expected when requesting blocks that don't exist.
func testFetchBlockIOMissing(tc *testContext, tx database.Tx) bool {
wantErrCode := database.ErrBlockNotFound
// ---------------------
// Non-bulk Block IO API
// ---------------------
// Test the individual block APIs one block at a time to ensure they
// return the expected error. Also, build the data needed to test the
// bulk APIs below while looping.
allBlockHashes := make([]chainhash.Hash, len(tc.blocks))
allBlockRegions := make([]database.BlockRegion, len(tc.blocks))
for i, block := range tc.blocks {
blockHash := block.Hash()
allBlockHashes[i] = *blockHash
txLocs, err := block.TxLoc()
if err != nil {
tc.t.Errorf("block.TxLoc(%d): unexpected error: %v", i,
err)
return false
}
// Ensure FetchBlock returns expected error.
testName := fmt.Sprintf("FetchBlock #%d on missing block", i)
_, err = tx.FetchBlock(blockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockHeader returns expected error.
testName = fmt.Sprintf("FetchBlockHeader #%d on missing block",
i)
_, err = tx.FetchBlockHeader(blockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure the first transaction fetched as a block region from
// the database returns the expected error.
region := database.BlockRegion{
Hash: blockHash,
Offset: uint32(txLocs[0].TxStart),
Len: uint32(txLocs[0].TxLen),
}
allBlockRegions[i] = region
_, err = tx.FetchBlockRegion(&region)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure HasBlock returns false.
hasBlock, err := tx.HasBlock(blockHash)
if err != nil {
tc.t.Errorf("HasBlock #%d: unexpected err: %v", i, err)
return false
}
if hasBlock {
tc.t.Errorf("HasBlock #%d: should not have block", i)
return false
}
}
// -----------------
// Bulk Block IO API
// -----------------
// Ensure FetchBlocks returns expected error.
testName := "FetchBlocks on missing blocks"
_, err := tx.FetchBlocks(allBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockHeaders returns expected error.
testName = "FetchBlockHeaders on missing blocks"
_, err = tx.FetchBlockHeaders(allBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockRegions returns expected error.
testName = "FetchBlockRegions on missing blocks"
_, err = tx.FetchBlockRegions(allBlockRegions)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure HasBlocks returns false for all blocks.
hasBlocks, err := tx.HasBlocks(allBlockHashes)
if err != nil {
tc.t.Errorf("HasBlocks: unexpected err: %v", err)
}
for i, hasBlock := range hasBlocks {
if hasBlock {
tc.t.Errorf("HasBlocks #%d: should not have block", i)
return false
}
}
return true
}
// testFetchBlockIO ensures all of the block retrieval API functions work as
// expected for the provide set of blocks. The blocks must already be stored in
// the database, or at least stored into the the passed transaction. It also
// tests several error conditions such as ensuring the expected errors are
// returned when fetching blocks, headers, and regions that don't exist.
func testFetchBlockIO(tc *testContext, tx database.Tx) bool {
// ---------------------
// Non-bulk Block IO API
// ---------------------
// Test the individual block APIs one block at a time. Also, build the
// data needed to test the bulk APIs below while looping.
allBlockHashes := make([]chainhash.Hash, len(tc.blocks))
allBlockBytes := make([][]byte, len(tc.blocks))
allBlockTxLocs := make([][]wire.TxLoc, len(tc.blocks))
allBlockRegions := make([]database.BlockRegion, len(tc.blocks))
for i, block := range tc.blocks {
blockHash := block.Hash()
allBlockHashes[i] = *blockHash
blockBytes, err := block.Bytes()
if err != nil {
tc.t.Errorf("block.Bytes(%d): unexpected error: %v", i,
err)
return false
}
allBlockBytes[i] = blockBytes
txLocs, err := block.TxLoc()
if err != nil {
tc.t.Errorf("block.TxLoc(%d): unexpected error: %v", i,
err)
return false
}
allBlockTxLocs[i] = txLocs
// Ensure the block data fetched from the database matches the
// expected bytes.
gotBlockBytes, err := tx.FetchBlock(blockHash)
if err != nil {
tc.t.Errorf("FetchBlock(%s): unexpected error: %v",
blockHash, err)
return false
}
if !bytes.Equal(gotBlockBytes, blockBytes) {
tc.t.Errorf("FetchBlock(%s): bytes mismatch: got %x, "+
"want %x", blockHash, gotBlockBytes, blockBytes)
return false
}
// Ensure the block header fetched from the database matches the
// expected bytes.
wantHeaderBytes := blockBytes[0:wire.MaxBlockHeaderPayload]
gotHeaderBytes, err := tx.FetchBlockHeader(blockHash)
if err != nil {
tc.t.Errorf("FetchBlockHeader(%s): unexpected error: %v",
blockHash, err)
return false
}
if !bytes.Equal(gotHeaderBytes, wantHeaderBytes) {
tc.t.Errorf("FetchBlockHeader(%s): bytes mismatch: "+
"got %x, want %x", blockHash, gotHeaderBytes,
wantHeaderBytes)
return false
}
// Ensure the first transaction fetched as a block region from
// the database matches the expected bytes.
region := database.BlockRegion{
Hash: blockHash,
Offset: uint32(txLocs[0].TxStart),
Len: uint32(txLocs[0].TxLen),
}
allBlockRegions[i] = region
endRegionOffset := region.Offset + region.Len
wantRegionBytes := blockBytes[region.Offset:endRegionOffset]
gotRegionBytes, err := tx.FetchBlockRegion(&region)
if err != nil {
tc.t.Errorf("FetchBlockRegion(%s): unexpected error: %v",
blockHash, err)
return false
}
if !bytes.Equal(gotRegionBytes, wantRegionBytes) {
tc.t.Errorf("FetchBlockRegion(%s): bytes mismatch: "+
"got %x, want %x", blockHash, gotRegionBytes,
wantRegionBytes)
return false
}
// Ensure the block header fetched from the database matches the
// expected bytes.
hasBlock, err := tx.HasBlock(blockHash)
if err != nil {
tc.t.Errorf("HasBlock(%s): unexpected error: %v",
blockHash, err)
return false
}
if !hasBlock {
tc.t.Errorf("HasBlock(%s): database claims it doesn't "+
"have the block when it should", blockHash)
return false
}
// -----------------------
// Invalid blocks/regions.
// -----------------------
// Ensure fetching a block that doesn't exist returns the
// expected error.
badBlockHash := &chainhash.Hash{}
testName := fmt.Sprintf("FetchBlock(%s) invalid block",
badBlockHash)
wantErrCode := database.ErrBlockNotFound
_, err = tx.FetchBlock(badBlockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching a block header that doesn't exist returns
// the expected error.
testName = fmt.Sprintf("FetchBlockHeader(%s) invalid block",
badBlockHash)
_, err = tx.FetchBlockHeader(badBlockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching a block region in a block that doesn't exist
// return the expected error.
testName = fmt.Sprintf("FetchBlockRegion(%s) invalid hash",
badBlockHash)
wantErrCode = database.ErrBlockNotFound
region.Hash = badBlockHash
region.Offset = ^uint32(0)
_, err = tx.FetchBlockRegion(&region)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching a block region that is out of bounds returns
// the expected error.
testName = fmt.Sprintf("FetchBlockRegion(%s) invalid region",
blockHash)
wantErrCode = database.ErrBlockRegionInvalid
region.Hash = blockHash
region.Offset = ^uint32(0)
_, err = tx.FetchBlockRegion(&region)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
}
// -----------------
// Bulk Block IO API
// -----------------
// Ensure the bulk block data fetched from the database matches the
// expected bytes.
blockData, err := tx.FetchBlocks(allBlockHashes)
if err != nil {
tc.t.Errorf("FetchBlocks: unexpected error: %v", err)
return false
}
if len(blockData) != len(allBlockBytes) {
tc.t.Errorf("FetchBlocks: unexpected number of results - got "+
"%d, want %d", len(blockData), len(allBlockBytes))
return false
}
for i := 0; i < len(blockData); i++ {
blockHash := allBlockHashes[i]
wantBlockBytes := allBlockBytes[i]
gotBlockBytes := blockData[i]
if !bytes.Equal(gotBlockBytes, wantBlockBytes) {
tc.t.Errorf("FetchBlocks(%s): bytes mismatch: got %x, "+
"want %x", blockHash, gotBlockBytes,
wantBlockBytes)
return false
}
}
// Ensure the bulk block headers fetched from the database match the
// expected bytes.
blockHeaderData, err := tx.FetchBlockHeaders(allBlockHashes)
if err != nil {
tc.t.Errorf("FetchBlockHeaders: unexpected error: %v", err)
return false
}
if len(blockHeaderData) != len(allBlockBytes) {
tc.t.Errorf("FetchBlockHeaders: unexpected number of results "+
"- got %d, want %d", len(blockHeaderData),
len(allBlockBytes))
return false
}
for i := 0; i < len(blockHeaderData); i++ {
blockHash := allBlockHashes[i]
wantHeaderBytes := allBlockBytes[i][0:wire.MaxBlockHeaderPayload]
gotHeaderBytes := blockHeaderData[i]
if !bytes.Equal(gotHeaderBytes, wantHeaderBytes) {
tc.t.Errorf("FetchBlockHeaders(%s): bytes mismatch: "+
"got %x, want %x", blockHash, gotHeaderBytes,
wantHeaderBytes)
return false
}
}
// Ensure the first transaction of every block fetched in bulk block
// regions from the database matches the expected bytes.
allRegionBytes, err := tx.FetchBlockRegions(allBlockRegions)
if err != nil {
tc.t.Errorf("FetchBlockRegions: unexpected error: %v", err)
return false
}
if len(allRegionBytes) != len(allBlockRegions) {
tc.t.Errorf("FetchBlockRegions: unexpected number of results "+
"- got %d, want %d", len(allRegionBytes),
len(allBlockRegions))
return false
}
for i, gotRegionBytes := range allRegionBytes {
region := &allBlockRegions[i]
endRegionOffset := region.Offset + region.Len
wantRegionBytes := blockData[i][region.Offset:endRegionOffset]
if !bytes.Equal(gotRegionBytes, wantRegionBytes) {
tc.t.Errorf("FetchBlockRegions(%d): bytes mismatch: "+
"got %x, want %x", i, gotRegionBytes,
wantRegionBytes)
return false
}
}
// Ensure the bulk determination of whether a set of block hashes are in
// the database returns true for all loaded blocks.
hasBlocks, err := tx.HasBlocks(allBlockHashes)
if err != nil {
tc.t.Errorf("HasBlocks: unexpected error: %v", err)
return false
}
for i, hasBlock := range hasBlocks {
if !hasBlock {
tc.t.Errorf("HasBlocks(%d): should have block", i)
return false
}
}
// -----------------------
// Invalid blocks/regions.
// -----------------------
// Ensure fetching blocks for which one doesn't exist returns the
// expected error.
testName := "FetchBlocks invalid hash"
badBlockHashes := make([]chainhash.Hash, len(allBlockHashes)+1)
copy(badBlockHashes, allBlockHashes)
badBlockHashes[len(badBlockHashes)-1] = chainhash.Hash{}
wantErrCode := database.ErrBlockNotFound
_, err = tx.FetchBlocks(badBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching block headers for which one doesn't exist returns the
// expected error.
testName = "FetchBlockHeaders invalid hash"
_, err = tx.FetchBlockHeaders(badBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching block regions for which one of blocks doesn't exist
// returns expected error.
testName = "FetchBlockRegions invalid hash"
badBlockRegions := make([]database.BlockRegion, len(allBlockRegions)+1)
copy(badBlockRegions, allBlockRegions)
badBlockRegions[len(badBlockRegions)-1].Hash = &chainhash.Hash{}
wantErrCode = database.ErrBlockNotFound
_, err = tx.FetchBlockRegions(badBlockRegions)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure fetching block regions that are out of bounds returns the
// expected error.
testName = "FetchBlockRegions invalid regions"
badBlockRegions = badBlockRegions[:len(badBlockRegions)-1]
for i := range badBlockRegions {
badBlockRegions[i].Offset = ^uint32(0)
}
wantErrCode = database.ErrBlockRegionInvalid
_, err = tx.FetchBlockRegions(badBlockRegions)
return checkDbError(tc.t, testName, err, wantErrCode)
}
// testBlockIOTxInterface ensures that the block IO interface works as expected
// for both managed read/write and manual transactions. This function leaves
// all of the stored blocks in the database.
func testBlockIOTxInterface(tc *testContext) bool {
// Ensure attempting to store a block with a read-only transaction fails
// with the expected error.
err := tc.db.View(func(tx database.Tx) error {
wantErrCode := database.ErrTxNotWritable
for i, block := range tc.blocks {
testName := fmt.Sprintf("StoreBlock(%d) on ro tx", i)
err := tx.StoreBlock(block)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return errSubTestFail
}
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Populate the database with loaded blocks and ensure all of the data
// fetching APIs work properly on them within the transaction before a
// commit or rollback. Then, force a rollback so the code below can
// ensure none of the data actually gets stored.
forceRollbackError := fmt.Errorf("force rollback")
err = tc.db.Update(func(tx database.Tx) error {
// Store all blocks in the same transaction.
for i, block := range tc.blocks {
err := tx.StoreBlock(block)
if err != nil {
tc.t.Errorf("StoreBlock #%d: unexpected error: "+
"%v", i, err)
return errSubTestFail
}
}
// Ensure attempting to store the same block again, before the
// transaction has been committed, returns the expected error.
wantErrCode := database.ErrBlockExists
for i, block := range tc.blocks {
testName := fmt.Sprintf("duplicate block entry #%d "+
"(before commit)", i)
err := tx.StoreBlock(block)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return errSubTestFail
}
}
// Ensure that all data fetches from the stored blocks before
// the transaction has been committed work as expected.
if !testFetchBlockIO(tc, tx) {
return errSubTestFail
}
return forceRollbackError
})
if err != forceRollbackError {
if err == errSubTestFail {
return false
}
tc.t.Errorf("Update: inner function error not returned - got "+
"%v, want %v", err, forceRollbackError)
return false
}
// Ensure rollback was successful
err = tc.db.View(func(tx database.Tx) error {
if !testFetchBlockIOMissing(tc, tx) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Populate the database with loaded blocks and ensure all of the data
// fetching APIs work properly.
err = tc.db.Update(func(tx database.Tx) error {
// Store a bunch of blocks in the same transaction.
for i, block := range tc.blocks {
err := tx.StoreBlock(block)
if err != nil {
tc.t.Errorf("StoreBlock #%d: unexpected error: "+
"%v", i, err)
return errSubTestFail
}
}
// Ensure attempting to store the same block again while in the
// same transaction, but before it has been committed, returns
// the expected error.
for i, block := range tc.blocks {
testName := fmt.Sprintf("duplicate block entry #%d "+
"(before commit)", i)
wantErrCode := database.ErrBlockExists
err := tx.StoreBlock(block)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return errSubTestFail
}
}
// Ensure that all data fetches from the stored blocks before
// the transaction has been committed work as expected.
if !testFetchBlockIO(tc, tx) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Ensure all data fetch tests work as expected using a managed
// read-only transaction after the data was successfully committed
// above.
err = tc.db.View(func(tx database.Tx) error {
if !testFetchBlockIO(tc, tx) {
return errSubTestFail
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
// Ensure all data fetch tests work as expected using a managed
// read-write transaction after the data was successfully committed
// above.
err = tc.db.Update(func(tx database.Tx) error {
if !testFetchBlockIO(tc, tx) {
return errSubTestFail
}
// Ensure attempting to store existing blocks again returns the
// expected error. Note that this is different from the
// previous version since this is a new transaction after the
// blocks have been committed.
wantErrCode := database.ErrBlockExists
for i, block := range tc.blocks {
testName := fmt.Sprintf("duplicate block entry #%d "+
"(before commit)", i)
err := tx.StoreBlock(block)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return errSubTestFail
}
}
return nil
})
if err != nil {
if err != errSubTestFail {
tc.t.Errorf("%v", err)
}
return false
}
return true
}
// testClosedTxInterface ensures that both the metadata and block IO API
// functions behave as expected when attempted against a closed transaction.
func testClosedTxInterface(tc *testContext, tx database.Tx) bool {
wantErrCode := database.ErrTxClosed
bucket := tx.Metadata()
cursor := tx.Metadata().Cursor()
bucketName := []byte("closedtxbucket")
keyName := []byte("closedtxkey")
// ------------
// Metadata API
// ------------
// Ensure that attempting to get an existing bucket returns nil when the
// transaction is closed.
if b := bucket.Bucket(bucketName); b != nil {
tc.t.Errorf("Bucket: did not return nil on closed tx")
return false
}
// Ensure CreateBucket returns expected error.
testName := "CreateBucket on closed tx"
_, err := bucket.CreateBucket(bucketName)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure CreateBucketIfNotExists returns expected error.
testName = "CreateBucketIfNotExists on closed tx"
_, err = bucket.CreateBucketIfNotExists(bucketName)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure Delete returns expected error.
testName = "Delete on closed tx"
err = bucket.Delete(keyName)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure DeleteBucket returns expected error.
testName = "DeleteBucket on closed tx"
err = bucket.DeleteBucket(bucketName)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure ForEach returns expected error.
testName = "ForEach on closed tx"
err = bucket.ForEach(nil)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure ForEachBucket returns expected error.
testName = "ForEachBucket on closed tx"
err = bucket.ForEachBucket(nil)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure Get returns expected error.
testName = "Get on closed tx"
if k := bucket.Get(keyName); k != nil {
tc.t.Errorf("Get: did not return nil on closed tx")
return false
}
// Ensure Put returns expected error.
testName = "Put on closed tx"
err = bucket.Put(keyName, []byte("test"))
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// -------------------
// Metadata Cursor API
// -------------------
// Ensure attempting to get a bucket from a cursor on a closed tx gives
// back nil.
if b := cursor.Bucket(); b != nil {
tc.t.Error("Cursor.Bucket: returned non-nil on closed tx")
return false
}
// Ensure Cursor.Delete returns expected error.
testName = "Cursor.Delete on closed tx"
err = cursor.Delete()
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure Cursor.First on a closed tx returns false and nil key/value.
if cursor.First() {
tc.t.Error("Cursor.First: claims ok on closed tx")
return false
}
if cursor.Key() != nil || cursor.Value() != nil {
tc.t.Error("Cursor.First: key and/or value are not nil on " +
"closed tx")
return false
}
// Ensure Cursor.Last on a closed tx returns false and nil key/value.
if cursor.Last() {
tc.t.Error("Cursor.Last: claims ok on closed tx")
return false
}
if cursor.Key() != nil || cursor.Value() != nil {
tc.t.Error("Cursor.Last: key and/or value are not nil on " +
"closed tx")
return false
}
// Ensure Cursor.Next on a closed tx returns false and nil key/value.
if cursor.Next() {
tc.t.Error("Cursor.Next: claims ok on closed tx")
return false
}
if cursor.Key() != nil || cursor.Value() != nil {
tc.t.Error("Cursor.Next: key and/or value are not nil on " +
"closed tx")
return false
}
// Ensure Cursor.Prev on a closed tx returns false and nil key/value.
if cursor.Prev() {
tc.t.Error("Cursor.Prev: claims ok on closed tx")
return false
}
if cursor.Key() != nil || cursor.Value() != nil {
tc.t.Error("Cursor.Prev: key and/or value are not nil on " +
"closed tx")
return false
}
// Ensure Cursor.Seek on a closed tx returns false and nil key/value.
if cursor.Seek([]byte{}) {
tc.t.Error("Cursor.Seek: claims ok on closed tx")
return false
}
if cursor.Key() != nil || cursor.Value() != nil {
tc.t.Error("Cursor.Seek: key and/or value are not nil on " +
"closed tx")
return false
}
// ---------------------
// Non-bulk Block IO API
// ---------------------
// Test the individual block APIs one block at a time to ensure they
// return the expected error. Also, build the data needed to test the
// bulk APIs below while looping.
allBlockHashes := make([]chainhash.Hash, len(tc.blocks))
allBlockRegions := make([]database.BlockRegion, len(tc.blocks))
for i, block := range tc.blocks {
blockHash := block.Hash()
allBlockHashes[i] = *blockHash
txLocs, err := block.TxLoc()
if err != nil {
tc.t.Errorf("block.TxLoc(%d): unexpected error: %v", i,
err)
return false
}
// Ensure StoreBlock returns expected error.
testName = "StoreBlock on closed tx"
err = tx.StoreBlock(block)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlock returns expected error.
testName = fmt.Sprintf("FetchBlock #%d on closed tx", i)
_, err = tx.FetchBlock(blockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockHeader returns expected error.
testName = fmt.Sprintf("FetchBlockHeader #%d on closed tx", i)
_, err = tx.FetchBlockHeader(blockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure the first transaction fetched as a block region from
// the database returns the expected error.
region := database.BlockRegion{
Hash: blockHash,
Offset: uint32(txLocs[0].TxStart),
Len: uint32(txLocs[0].TxLen),
}
allBlockRegions[i] = region
_, err = tx.FetchBlockRegion(&region)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure HasBlock returns expected error.
testName = fmt.Sprintf("HasBlock #%d on closed tx", i)
_, err = tx.HasBlock(blockHash)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
}
// -----------------
// Bulk Block IO API
// -----------------
// Ensure FetchBlocks returns expected error.
testName = "FetchBlocks on closed tx"
_, err = tx.FetchBlocks(allBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockHeaders returns expected error.
testName = "FetchBlockHeaders on closed tx"
_, err = tx.FetchBlockHeaders(allBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure FetchBlockRegions returns expected error.
testName = "FetchBlockRegions on closed tx"
_, err = tx.FetchBlockRegions(allBlockRegions)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// Ensure HasBlocks returns expected error.
testName = "HasBlocks on closed tx"
_, err = tx.HasBlocks(allBlockHashes)
if !checkDbError(tc.t, testName, err, wantErrCode) {
return false
}
// ---------------
// Commit/Rollback
// ---------------
// Ensure that attempting to rollback or commit a transaction that is
// already closed returns the expected error.
err = tx.Rollback()
if !checkDbError(tc.t, "closed tx rollback", err, wantErrCode) {
return false
}
err = tx.Commit()
return checkDbError(tc.t, "closed tx commit", err, wantErrCode)
}
// testTxClosed ensures that both the metadata and block IO API functions behave
// as expected when attempted against both read-only and read-write
// transactions.
func testTxClosed(tc *testContext) bool {
bucketName := []byte("closedtxbucket")
keyName := []byte("closedtxkey")
// Start a transaction, create a bucket and key used for testing, and
// immediately perform a commit on it so it is closed.
tx, err := tc.db.Begin(true)
if err != nil {
tc.t.Errorf("Begin(true): unexpected error: %v", err)
return false
}
defer rollbackOnPanic(tc.t, tx)
if _, err := tx.Metadata().CreateBucket(bucketName); err != nil {
tc.t.Errorf("CreateBucket: unexpected error: %v", err)
return false
}
if err := tx.Metadata().Put(keyName, []byte("test")); err != nil {
tc.t.Errorf("Put: unexpected error: %v", err)
return false
}
if err := tx.Commit(); err != nil {
tc.t.Errorf("Commit: unexpected error: %v", err)
return false
}
// Ensure invoking all of the functions on the closed read-write
// transaction behave as expected.
if !testClosedTxInterface(tc, tx) {
return false
}
// Repeat the tests with a rolled-back read-only transaction.
tx, err = tc.db.Begin(false)
if err != nil {
tc.t.Errorf("Begin(false): unexpected error: %v", err)
return false
}
defer rollbackOnPanic(tc.t, tx)
if err := tx.Rollback(); err != nil {
tc.t.Errorf("Rollback: unexpected error: %v", err)
return false
}
// Ensure invoking all of the functions on the closed read-only
// transaction behave as expected.
return testClosedTxInterface(tc, tx)
}
// testConcurrecy ensure the database properly supports concurrent readers and
// only a single writer. It also ensures views act as snapshots at the time
// they are acquired.
func testConcurrecy(tc *testContext) bool {
// sleepTime is how long each of the concurrent readers should sleep to
// aid in detection of whether or not the data is actually being read
// concurrently. It starts with a sane lower bound.
var sleepTime = time.Millisecond * 250
// Determine about how long it takes for a single block read. When it's
// longer than the default minimum sleep time, adjust the sleep time to
// help prevent durations that are too short which would cause erroneous
// test failures on slower systems.
startTime := time.Now()
err := tc.db.View(func(tx database.Tx) error {
_, err := tx.FetchBlock(tc.blocks[0].Hash())
return err
})
if err != nil {
tc.t.Errorf("Unexpected error in view: %v", err)
return false
}
elapsed := time.Since(startTime)
if sleepTime < elapsed {
sleepTime = elapsed
}
tc.t.Logf("Time to load block 0: %v, using sleep time: %v", elapsed,
sleepTime)
// reader takes a block number to load and channel to return the result
// of the operation on. It is used below to launch multiple concurrent
// readers.
numReaders := len(tc.blocks)
resultChan := make(chan bool, numReaders)
reader := func(blockNum int) {
err := tc.db.View(func(tx database.Tx) error {
time.Sleep(sleepTime)
_, err := tx.FetchBlock(tc.blocks[blockNum].Hash())
return err
})
if err != nil {
tc.t.Errorf("Unexpected error in concurrent view: %v",
err)
resultChan <- false
}
resultChan <- true
}
// Start up several concurrent readers for the same block and wait for
// the results.
startTime = time.Now()
for i := 0; i < numReaders; i++ {
go reader(0)
}
for i := 0; i < numReaders; i++ {
if result := <-resultChan; !result {
return false
}
}
elapsed = time.Since(startTime)
tc.t.Logf("%d concurrent reads of same block elapsed: %v", numReaders,
elapsed)
// Consider it a failure if it took longer than half the time it would
// take with no concurrency.
if elapsed > sleepTime*time.Duration(numReaders/2) {
tc.t.Errorf("Concurrent views for same block did not appear to "+
"run simultaneously: elapsed %v", elapsed)
return false
}
// Start up several concurrent readers for different blocks and wait for
// the results.
startTime = time.Now()
for i := 0; i < numReaders; i++ {
go reader(i)
}
for i := 0; i < numReaders; i++ {
if result := <-resultChan; !result {
return false
}
}
elapsed = time.Since(startTime)
tc.t.Logf("%d concurrent reads of different blocks elapsed: %v",
numReaders, elapsed)
// Consider it a failure if it took longer than half the time it would
// take with no concurrency.
if elapsed > sleepTime*time.Duration(numReaders/2) {
tc.t.Errorf("Concurrent views for different blocks did not "+
"appear to run simultaneously: elapsed %v", elapsed)
return false
}
// Start up a few readers and wait for them to acquire views. Each
// reader waits for a signal from the writer to be finished to ensure
// that the data written by the writer is not seen by the view since it
// was started before the data was set.
concurrentKey := []byte("notthere")
concurrentVal := []byte("someval")
started := make(chan struct{})
writeComplete := make(chan struct{})
reader = func(blockNum int) {
err := tc.db.View(func(tx database.Tx) error {
started <- struct{}{}
// Wait for the writer to complete.
<-writeComplete
// Since this reader was created before the write took
// place, the data it added should not be visible.
val := tx.Metadata().Get(concurrentKey)
if val != nil {
return fmt.Errorf("%s should not be visible",
concurrentKey)
}
return nil
})
if err != nil {
tc.t.Errorf("Unexpected error in concurrent view: %v",
err)
resultChan <- false
}
resultChan <- true
}
for i := 0; i < numReaders; i++ {
go reader(0)
}
for i := 0; i < numReaders; i++ {
<-started
}
// All readers are started and waiting for completion of the writer.
// Set some data the readers are expecting to not find and signal the
// readers the write is done by closing the writeComplete channel.
err = tc.db.Update(func(tx database.Tx) error {
return tx.Metadata().Put(concurrentKey, concurrentVal)
})
if err != nil {
tc.t.Errorf("Unexpected error in update: %v", err)
return false
}
close(writeComplete)
// Wait for reader results.
for i := 0; i < numReaders; i++ {
if result := <-resultChan; !result {
return false
}
}
// Start a few writers and ensure the total time is at least the
// writeSleepTime * numWriters. This ensures only one write transaction
// can be active at a time.
writeSleepTime := time.Millisecond * 250
writer := func() {
err := tc.db.Update(func(tx database.Tx) error {
time.Sleep(writeSleepTime)
return nil
})
if err != nil {
tc.t.Errorf("Unexpected error in concurrent view: %v",
err)
resultChan <- false
}
resultChan <- true
}
numWriters := 3
startTime = time.Now()
for i := 0; i < numWriters; i++ {
go writer()
}
for i := 0; i < numWriters; i++ {
if result := <-resultChan; !result {
return false
}
}
elapsed = time.Since(startTime)
tc.t.Logf("%d concurrent writers elapsed using sleep time %v: %v",
numWriters, writeSleepTime, elapsed)
// The total time must have been at least the sum of all sleeps if the
// writes blocked properly.
if elapsed < writeSleepTime*time.Duration(numWriters) {
tc.t.Errorf("Concurrent writes appeared to run simultaneously: "+
"elapsed %v", elapsed)
return false
}
return true
}
// testConcurrentClose ensures that closing the database with open transactions
// blocks until the transactions are finished.
//
// The database will be closed upon returning from this function.
func testConcurrentClose(tc *testContext) bool {
// Start up a few readers and wait for them to acquire views. Each
// reader waits for a signal to complete to ensure the transactions stay
// open until they are explicitly signalled to be closed.
var activeReaders int32
numReaders := 3
started := make(chan struct{})
finishReaders := make(chan struct{})
resultChan := make(chan bool, numReaders+1)
reader := func() {
err := tc.db.View(func(tx database.Tx) error {
atomic.AddInt32(&activeReaders, 1)
started <- struct{}{}
<-finishReaders
atomic.AddInt32(&activeReaders, -1)
return nil
})
if err != nil {
tc.t.Errorf("Unexpected error in concurrent view: %v",
err)
resultChan <- false
}
resultChan <- true
}
for i := 0; i < numReaders; i++ {
go reader()
}
for i := 0; i < numReaders; i++ {
<-started
}
// Close the database in a separate goroutine. This should block until
// the transactions are finished. Once the close has taken place, the
// dbClosed channel is closed to signal the main goroutine below.
dbClosed := make(chan struct{})
go func() {
started <- struct{}{}
err := tc.db.Close()
if err != nil {
tc.t.Errorf("Unexpected error in concurrent view: %v",
err)
resultChan <- false
}
close(dbClosed)
resultChan <- true
}()
<-started
// Wait a short period and then signal the reader transactions to
// finish. When the db closed channel is received, ensure there are no
// active readers open.
time.AfterFunc(time.Millisecond*250, func() { close(finishReaders) })
<-dbClosed
if nr := atomic.LoadInt32(&activeReaders); nr != 0 {
tc.t.Errorf("Close did not appear to block with active "+
"readers: %d active", nr)
return false
}
// Wait for all results.
for i := 0; i < numReaders+1; i++ {
if result := <-resultChan; !result {
return false
}
}
return true
}
// testInterface tests performs tests for the various interfaces of the database
// package which require state in the database for the given database type.
func testInterface(t *testing.T, db database.DB) {
// Create a test context to pass around.
context := testContext{t: t, db: db}
// Load the test blocks and store in the test context for use throughout
// the tests.
blocks, err := loadBlocks(t, blockDataFile, blockDataNet)
if err != nil {
t.Errorf("loadBlocks: Unexpected error: %v", err)
return
}
context.blocks = blocks
// Test the transaction metadata interface including managed and manual
// transactions as well as buckets.
if !testMetadataTxInterface(&context) {
return
}
// Test the transaction block IO interface using managed and manual
// transactions. This function leaves all of the stored blocks in the
// database since they're used later.
if !testBlockIOTxInterface(&context) {
return
}
// Test all of the transaction interface functions against a closed
// transaction work as expected.
if !testTxClosed(&context) {
return
}
// Test the database properly supports concurrency.
if !testConcurrecy(&context) {
return
}
// Test that closing the database with open transactions blocks until
// the transactions are finished.
//
// The database will be closed upon returning from this function, so it
// must be the last thing called.
testConcurrentClose(&context)
}