// Copyright (C) 2014 The Protocol Authors. package protocol import ( "bytes" "context" "crypto/sha256" "encoding/hex" "encoding/json" "errors" "io" "io/ioutil" "runtime" "sync" "testing" "testing/quick" "time" "github.com/syncthing/syncthing/lib/rand" "github.com/syncthing/syncthing/lib/testutils" ) var ( c0ID = NewDeviceID([]byte{1}) c1ID = NewDeviceID([]byte{2}) quickCfg = &quick.Config{} ) func TestPing(t *testing.T) { ar, aw := io.Pipe() br, bw := io.Pipe() c0 := NewConnection(c0ID, ar, bw, newTestModel(), "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c0.Start() defer closeAndWait(c0, ar, bw) c1 := NewConnection(c1ID, br, aw, newTestModel(), "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c1.Start() defer closeAndWait(c1, ar, bw) c0.ClusterConfig(ClusterConfig{}) c1.ClusterConfig(ClusterConfig{}) if ok := c0.ping(); !ok { t.Error("c0 ping failed") } if ok := c1.ping(); !ok { t.Error("c1 ping failed") } } var errManual = errors.New("manual close") func TestClose(t *testing.T) { m0 := newTestModel() m1 := newTestModel() ar, aw := io.Pipe() br, bw := io.Pipe() c0 := NewConnection(c0ID, ar, bw, m0, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c0.Start() defer closeAndWait(c0, ar, bw) c1 := NewConnection(c1ID, br, aw, m1, "name", CompressionAlways) c1.Start() defer closeAndWait(c1, ar, bw) c0.ClusterConfig(ClusterConfig{}) c1.ClusterConfig(ClusterConfig{}) c0.internalClose(errManual) <-c0.closed if err := m0.closedError(); err != errManual { t.Fatal("Connection should be closed") } // None of these should panic, some should return an error if c0.ping() { t.Error("Ping should not return true") } ctx := context.Background() c0.Index(ctx, "default", nil) c0.Index(ctx, "default", nil) if _, err := c0.Request(ctx, "default", "foo", 0, 0, 0, nil, 0, false); err == nil { t.Error("Request should return an error") } } // TestCloseOnBlockingSend checks that the connection does not deadlock when // Close is called while the underlying connection is broken (send blocks). // https://github.com/syncthing/syncthing/pull/5442 func TestCloseOnBlockingSend(t *testing.T) { oldCloseTimeout := CloseTimeout CloseTimeout = 100 * time.Millisecond defer func() { CloseTimeout = oldCloseTimeout }() m := newTestModel() rw := testutils.NewBlockingRW() c := NewConnection(c0ID, rw, rw, m, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c.Start() defer closeAndWait(c, rw) wg := sync.WaitGroup{} wg.Add(1) go func() { c.ClusterConfig(ClusterConfig{}) wg.Done() }() wg.Add(1) go func() { c.Close(errManual) wg.Done() }() // This simulates an error from ping timeout wg.Add(1) go func() { c.internalClose(ErrTimeout) wg.Done() }() done := make(chan struct{}) go func() { wg.Wait() close(done) }() select { case <-done: case <-time.After(time.Second): t.Fatal("timed out before all functions returned") } } func TestCloseRace(t *testing.T) { indexReceived := make(chan struct{}) unblockIndex := make(chan struct{}) m0 := newTestModel() m0.indexFn = func(_ DeviceID, _ string, _ []FileInfo) { close(indexReceived) <-unblockIndex } m1 := newTestModel() ar, aw := io.Pipe() br, bw := io.Pipe() c0 := NewConnection(c0ID, ar, bw, m0, "c0", CompressionNever).(wireFormatConnection).Connection.(*rawConnection) c0.Start() defer closeAndWait(c0, ar, bw) c1 := NewConnection(c1ID, br, aw, m1, "c1", CompressionNever) c1.Start() defer closeAndWait(c1, ar, bw) c0.ClusterConfig(ClusterConfig{}) c1.ClusterConfig(ClusterConfig{}) c1.Index(context.Background(), "default", nil) select { case <-indexReceived: case <-time.After(time.Second): t.Fatal("timed out before receiving index") } go c0.internalClose(errManual) select { case <-c0.closed: case <-time.After(time.Second): t.Fatal("timed out before c0.closed was closed") } select { case <-m0.closedCh: t.Errorf("receiver.Closed called before receiver.Index") default: } close(unblockIndex) if err := m0.closedError(); err != errManual { t.Fatal("Connection should be closed") } } func TestClusterConfigFirst(t *testing.T) { m := newTestModel() rw := testutils.NewBlockingRW() c := NewConnection(c0ID, rw, &testutils.NoopRW{}, m, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c.Start() defer closeAndWait(c, rw) select { case c.outbox <- asyncMessage{&Ping{}, nil}: t.Fatal("able to send ping before cluster config") case <-time.After(100 * time.Millisecond): // Allow some time for c.writerLoop to setup after c.Start } c.ClusterConfig(ClusterConfig{}) done := make(chan struct{}) if ok := c.send(context.Background(), &Ping{}, done); !ok { t.Fatal("send ping after cluster config returned false") } select { case <-done: case <-time.After(time.Second): t.Fatal("timed out before ping was sent") } done = make(chan struct{}) go func() { c.internalClose(errManual) close(done) }() select { case <-done: case <-time.After(5 * time.Second): t.Fatal("Close didn't return before timeout") } if err := m.closedError(); err != errManual { t.Fatal("Connection should be closed") } } // TestCloseTimeout checks that calling Close times out and proceeds, if sending // the close message does not succeed. func TestCloseTimeout(t *testing.T) { oldCloseTimeout := CloseTimeout CloseTimeout = 100 * time.Millisecond defer func() { CloseTimeout = oldCloseTimeout }() m := newTestModel() rw := testutils.NewBlockingRW() c := NewConnection(c0ID, rw, rw, m, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c.Start() defer closeAndWait(c, rw) done := make(chan struct{}) go func() { c.Close(errManual) close(done) }() select { case <-done: case <-time.After(5 * CloseTimeout): t.Fatal("timed out before Close returned") } } func TestMarshalIndexMessage(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 Index) bool { if len(m1.Files) == 0 { m1.Files = nil } for i, f := range m1.Files { if len(f.BlocksHash) == 0 { m1.Files[i].BlocksHash = nil } if len(f.VersionHash) == 0 { m1.Files[i].VersionHash = nil } if len(f.Blocks) == 0 { m1.Files[i].Blocks = nil } else { for j := range f.Blocks { f.Blocks[j].Offset = 0 if len(f.Blocks[j].Hash) == 0 { f.Blocks[j].Hash = nil } } } if len(f.Version.Counters) == 0 { m1.Files[i].Version.Counters = nil } if len(f.Encrypted) == 0 { m1.Files[i].Encrypted = nil } } return testMarshal(t, "index", &m1, &Index{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestMarshalRequestMessage(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 Request) bool { if len(m1.Hash) == 0 { m1.Hash = nil } return testMarshal(t, "request", &m1, &Request{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestMarshalResponseMessage(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 Response) bool { if len(m1.Data) == 0 { m1.Data = nil } return testMarshal(t, "response", &m1, &Response{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestMarshalClusterConfigMessage(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 ClusterConfig) bool { if len(m1.Folders) == 0 { m1.Folders = nil } for i := range m1.Folders { if len(m1.Folders[i].Devices) == 0 { m1.Folders[i].Devices = nil } for j := range m1.Folders[i].Devices { if len(m1.Folders[i].Devices[j].Addresses) == 0 { m1.Folders[i].Devices[j].Addresses = nil } if len(m1.Folders[i].Devices[j].EncryptionPasswordToken) == 0 { m1.Folders[i].Devices[j].EncryptionPasswordToken = nil } } } return testMarshal(t, "clusterconfig", &m1, &ClusterConfig{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestMarshalCloseMessage(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 Close) bool { return testMarshal(t, "close", &m1, &Close{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestMarshalFDPU(t *testing.T) { if testing.Short() { quickCfg.MaxCount = 10 } f := func(m1 FileDownloadProgressUpdate) bool { if len(m1.Version.Counters) == 0 { m1.Version.Counters = nil } if len(m1.BlockIndexes) == 0 { m1.BlockIndexes = nil } return testMarshal(t, "fdpu", &m1, &FileDownloadProgressUpdate{}) } if err := quick.Check(f, quickCfg); err != nil { t.Error(err) } } func TestUnmarshalFDPUv16v17(t *testing.T) { var fdpu FileDownloadProgressUpdate m0, _ := hex.DecodeString("08cda1e2e3011278f3918787f3b89b8af2958887f0aa9389f3a08588f3aa8f96f39aa8a5f48b9188f19286a0f3848da4f3aba799f3beb489f0a285b9f487b684f2a3bda2f48598b4f2938a89f2a28badf187a0a2f2aebdbdf4849494f4808fbbf2b3a2adf2bb95bff0a6ada4f198ab9af29a9c8bf1abb793f3baabb2f188a6ba1a0020bb9390f60220f6d9e42220b0c7e2b2fdffffffff0120fdb2dfcdfbffffffff0120cedab1d50120bd8784c0feffffffff0120ace99591fdffffffff0120eed7d09af9ffffffff01") if err := fdpu.Unmarshal(m0); err != nil { t.Fatal("Unmarshalling message from v0.14.16:", err) } m1, _ := hex.DecodeString("0880f1969905128401f099b192f0abb1b9f3b280aff19e9aa2f3b89e84f484b39df1a7a6b0f1aea4b1f0adac94f3b39caaf1939281f1928a8af0abb1b0f0a8b3b3f3a88e94f2bd85acf29c97a9f2969da6f0b7a188f1908ea2f09a9c9bf19d86a6f29aada8f389bb95f0bf9d88f1a09d89f1b1a4b5f29b9eabf298a59df1b2a589f2979ebdf0b69880f18986b21a440a1508c7d8fb8897ca93d90910e8c4d8e8f2f8f0ccee010a1508afa8ffd8c085b393c50110e5bdedc3bddefe9b0b0a1408a1bedddba4cac5da3c10b8e5d9958ca7e3ec19225ae2f88cb2f8ffffffff018ceda99cfbffffffff01b9c298a407e295e8e9fcffffffff01f3b9ade5fcffffffff01c08bfea9fdffffffff01a2c2e5e1ffffffffff0186dcc5dafdffffffff01e9ffc7e507c9d89db8fdffffffff01") if err := fdpu.Unmarshal(m1); err != nil { t.Fatal("Unmarshalling message from v0.14.16:", err) } } func testMarshal(t *testing.T, prefix string, m1, m2 message) bool { buf, err := m1.Marshal() if err != nil { t.Fatal(err) } err = m2.Unmarshal(buf) if err != nil { t.Fatal(err) } bs1, _ := json.MarshalIndent(m1, "", " ") bs2, _ := json.MarshalIndent(m2, "", " ") if !bytes.Equal(bs1, bs2) { ioutil.WriteFile(prefix+"-1.txt", bs1, 0644) ioutil.WriteFile(prefix+"-2.txt", bs2, 0644) return false } return true } func TestLZ4Compression(t *testing.T) { c := new(rawConnection) for i := 0; i < 10; i++ { dataLen := 150 + rand.Intn(150) data := make([]byte, dataLen) _, err := io.ReadFull(rand.Reader, data[100:]) if err != nil { t.Fatal(err) } comp, err := c.lz4Compress(data) if err != nil { t.Errorf("compressing %d bytes: %v", dataLen, err) continue } res, err := c.lz4Decompress(comp) if err != nil { t.Errorf("decompressing %d bytes to %d: %v", len(comp), dataLen, err) continue } if len(res) != len(data) { t.Errorf("Incorrect len %d != expected %d", len(res), len(data)) } if !bytes.Equal(data, res) { t.Error("Incorrect decompressed data") } t.Logf("OK #%d, %d -> %d -> %d", i, dataLen, len(comp), dataLen) } } func TestStressLZ4CompressGrows(t *testing.T) { c := new(rawConnection) success := 0 for i := 0; i < 100; i++ { // Create a slize that is precisely one min block size, fill it with // random data. This shouldn't compress at all, so will in fact // become larger when LZ4 does its thing. data := make([]byte, MinBlockSize) if _, err := rand.Reader.Read(data); err != nil { t.Fatal("randomness failure") } comp, err := c.lz4Compress(data) if err != nil { t.Fatal("unexpected compression error: ", err) } if len(comp) < len(data) { // data size should grow. We must have been really unlucky in // the random generation, try again. continue } // Putting it into the buffer pool shouldn't panic because the block // should come from there to begin with. BufferPool.Put(comp) success++ } if success == 0 { t.Fatal("unable to find data that grows when compressed") } } func TestCheckFilename(t *testing.T) { cases := []struct { name string ok bool }{ // Valid filenames {"foo", true}, {"foo/bar/baz", true}, {"foo/bar:baz", true}, // colon is ok in general, will be filtered on windows {`\`, true}, // path separator on the wire is forward slash, so as above {`\.`, true}, {`\..`, true}, {".foo", true}, {"foo..", true}, // Invalid filenames {"foo/..", false}, {"foo/../bar", false}, {"../foo/../bar", false}, {"", false}, {".", false}, {"..", false}, {"/", false}, {"/.", false}, {"/..", false}, {"/foo", false}, {"./foo", false}, {"foo./", false}, {"foo/.", false}, {"foo/", false}, } for _, tc := range cases { err := checkFilename(tc.name) if (err == nil) != tc.ok { t.Errorf("Unexpected result for checkFilename(%q): %v", tc.name, err) } } } func TestCheckConsistency(t *testing.T) { cases := []struct { fi FileInfo ok bool }{ { // valid fi: FileInfo{ Name: "foo", Type: FileInfoTypeFile, Blocks: []BlockInfo{{Size: 1234, Offset: 0, Hash: []byte{1, 2, 3, 4}}}, }, ok: true, }, { // deleted with blocks fi: FileInfo{ Name: "foo", Deleted: true, Type: FileInfoTypeFile, Blocks: []BlockInfo{{Size: 1234, Offset: 0, Hash: []byte{1, 2, 3, 4}}}, }, ok: false, }, { // no blocks fi: FileInfo{ Name: "foo", Type: FileInfoTypeFile, }, ok: false, }, { // directory with blocks fi: FileInfo{ Name: "foo", Type: FileInfoTypeDirectory, Blocks: []BlockInfo{{Size: 1234, Offset: 0, Hash: []byte{1, 2, 3, 4}}}, }, ok: false, }, } for _, tc := range cases { err := checkFileInfoConsistency(tc.fi) if tc.ok && err != nil { t.Errorf("Unexpected error %v (want nil) for %v", err, tc.fi) } if !tc.ok && err == nil { t.Errorf("Unexpected nil error for %v", tc.fi) } } } func TestBlockSize(t *testing.T) { cases := []struct { fileSize int64 blockSize int }{ {1 << KiB, 128 << KiB}, {1 << MiB, 128 << KiB}, {499 << MiB, 256 << KiB}, {500 << MiB, 512 << KiB}, {501 << MiB, 512 << KiB}, {1 << GiB, 1 << MiB}, {2 << GiB, 2 << MiB}, {3 << GiB, 2 << MiB}, {500 << GiB, 16 << MiB}, {50000 << GiB, 16 << MiB}, } for _, tc := range cases { size := BlockSize(tc.fileSize) if size != tc.blockSize { t.Errorf("BlockSize(%d), size=%d, expected %d", tc.fileSize, size, tc.blockSize) } } } var blockSize int func BenchmarkBlockSize(b *testing.B) { for i := 0; i < b.N; i++ { blockSize = BlockSize(16 << 30) } } func TestLocalFlagBits(t *testing.T) { var f FileInfo if f.IsIgnored() || f.MustRescan() || f.IsInvalid() { t.Error("file should have no weird bits set by default") } f.SetIgnored(42) if !f.IsIgnored() || f.MustRescan() || !f.IsInvalid() { t.Error("file should be ignored and invalid") } f.SetMustRescan(42) if f.IsIgnored() || !f.MustRescan() || !f.IsInvalid() { t.Error("file should be must-rescan and invalid") } f.SetUnsupported(42) if f.IsIgnored() || f.MustRescan() || !f.IsInvalid() { t.Error("file should be invalid") } } func TestIsEquivalent(t *testing.T) { b := func(v bool) *bool { return &v } type testCase struct { a FileInfo b FileInfo ignPerms *bool // nil means should not matter, we'll test both variants ignBlocks *bool ignFlags uint32 eq bool } cases := []testCase{ // Empty FileInfos are equivalent {eq: true}, // Various basic attributes, all of which cause ineqality when // they differ { a: FileInfo{Name: "foo"}, b: FileInfo{Name: "bar"}, eq: false, }, { a: FileInfo{Type: FileInfoTypeFile}, b: FileInfo{Type: FileInfoTypeDirectory}, eq: false, }, { a: FileInfo{Size: 1234}, b: FileInfo{Size: 2345}, eq: false, }, { a: FileInfo{Deleted: false}, b: FileInfo{Deleted: true}, eq: false, }, { a: FileInfo{RawInvalid: false}, b: FileInfo{RawInvalid: true}, eq: false, }, { a: FileInfo{ModifiedS: 1234}, b: FileInfo{ModifiedS: 2345}, eq: false, }, { a: FileInfo{ModifiedNs: 1234}, b: FileInfo{ModifiedNs: 2345}, eq: false, }, // Special handling of local flags and invalidity. "MustRescan" // files are never equivalent to each other. Otherwise, equivalence // is based just on whether the file becomes IsInvalid() or not, not // the specific reason or flag bits. { a: FileInfo{LocalFlags: FlagLocalMustRescan}, b: FileInfo{LocalFlags: FlagLocalMustRescan}, eq: false, }, { a: FileInfo{RawInvalid: true}, b: FileInfo{RawInvalid: true}, eq: true, }, { a: FileInfo{LocalFlags: FlagLocalUnsupported}, b: FileInfo{LocalFlags: FlagLocalUnsupported}, eq: true, }, { a: FileInfo{RawInvalid: true}, b: FileInfo{LocalFlags: FlagLocalUnsupported}, eq: true, }, { a: FileInfo{LocalFlags: 0}, b: FileInfo{LocalFlags: FlagLocalReceiveOnly}, eq: false, }, { a: FileInfo{LocalFlags: 0}, b: FileInfo{LocalFlags: FlagLocalReceiveOnly}, ignFlags: FlagLocalReceiveOnly, eq: true, }, // Difference in blocks is not OK { a: FileInfo{Blocks: []BlockInfo{{Hash: []byte{1, 2, 3, 4}}}}, b: FileInfo{Blocks: []BlockInfo{{Hash: []byte{2, 3, 4, 5}}}}, ignBlocks: b(false), eq: false, }, // ... unless we say it is { a: FileInfo{Blocks: []BlockInfo{{Hash: []byte{1, 2, 3, 4}}}}, b: FileInfo{Blocks: []BlockInfo{{Hash: []byte{2, 3, 4, 5}}}}, ignBlocks: b(true), eq: true, }, // Difference in permissions is not OK. { a: FileInfo{Permissions: 0444}, b: FileInfo{Permissions: 0666}, ignPerms: b(false), eq: false, }, // ... unless we say it is { a: FileInfo{Permissions: 0666}, b: FileInfo{Permissions: 0444}, ignPerms: b(true), eq: true, }, // These attributes are not checked at all { a: FileInfo{NoPermissions: false}, b: FileInfo{NoPermissions: true}, eq: true, }, { a: FileInfo{Version: Vector{Counters: []Counter{{ID: 1, Value: 42}}}}, b: FileInfo{Version: Vector{Counters: []Counter{{ID: 42, Value: 1}}}}, eq: true, }, { a: FileInfo{Sequence: 1}, b: FileInfo{Sequence: 2}, eq: true, }, // The block size is not checked (but this would fail the blocks // check in real world) { a: FileInfo{RawBlockSize: 1}, b: FileInfo{RawBlockSize: 2}, eq: true, }, // The symlink target is checked for symlinks { a: FileInfo{Type: FileInfoTypeSymlink, SymlinkTarget: "a"}, b: FileInfo{Type: FileInfoTypeSymlink, SymlinkTarget: "b"}, eq: false, }, // ... but not for non-symlinks { a: FileInfo{Type: FileInfoTypeFile, SymlinkTarget: "a"}, b: FileInfo{Type: FileInfoTypeFile, SymlinkTarget: "b"}, eq: true, }, } if runtime.GOOS == "windows" { // On windows we only check the user writable bit of the permission // set, so these are equivalent. cases = append(cases, testCase{ a: FileInfo{Permissions: 0777}, b: FileInfo{Permissions: 0600}, ignPerms: b(false), eq: true, }) } for i, tc := range cases { // Check the standard attributes with all permutations of the // special ignore flags, unless the value of those flags are given // in the tests. for _, ignPerms := range []bool{true, false} { for _, ignBlocks := range []bool{true, false} { if tc.ignPerms != nil && *tc.ignPerms != ignPerms { continue } if tc.ignBlocks != nil && *tc.ignBlocks != ignBlocks { continue } if res := tc.a.isEquivalent(tc.b, 0, ignPerms, ignBlocks, tc.ignFlags); res != tc.eq { t.Errorf("Case %d:\na: %v\nb: %v\na.IsEquivalent(b, %v, %v) => %v, expected %v", i, tc.a, tc.b, ignPerms, ignBlocks, res, tc.eq) } if res := tc.b.isEquivalent(tc.a, 0, ignPerms, ignBlocks, tc.ignFlags); res != tc.eq { t.Errorf("Case %d:\na: %v\nb: %v\nb.IsEquivalent(a, %v, %v) => %v, expected %v", i, tc.a, tc.b, ignPerms, ignBlocks, res, tc.eq) } } } } } func TestSha256OfEmptyBlock(t *testing.T) { // every block size should have a correct entry in sha256OfEmptyBlock for blockSize := MinBlockSize; blockSize <= MaxBlockSize; blockSize *= 2 { expected := sha256.Sum256(make([]byte, blockSize)) if sha256OfEmptyBlock[blockSize] != expected { t.Error("missing or wrong hash for block of size", blockSize) } } } // TestClusterConfigAfterClose checks that ClusterConfig does not deadlock when // ClusterConfig is called on a closed connection. func TestClusterConfigAfterClose(t *testing.T) { m := newTestModel() rw := testutils.NewBlockingRW() c := NewConnection(c0ID, rw, rw, m, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) c.Start() defer closeAndWait(c, rw) c.internalClose(errManual) done := make(chan struct{}) go func() { c.ClusterConfig(ClusterConfig{}) close(done) }() select { case <-done: case <-time.After(time.Second): t.Fatal("timed out before Cluster Config returned") } } func TestDispatcherToCloseDeadlock(t *testing.T) { // Verify that we don't deadlock when calling Close() from within one of // the model callbacks (ClusterConfig). m := newTestModel() rw := testutils.NewBlockingRW() c := NewConnection(c0ID, rw, &testutils.NoopRW{}, m, "name", CompressionAlways).(wireFormatConnection).Connection.(*rawConnection) m.ccFn = func(devID DeviceID, cc ClusterConfig) { c.Close(errManual) } c.Start() defer closeAndWait(c, rw) c.inbox <- &ClusterConfig{} select { case <-c.dispatcherLoopStopped: case <-time.After(time.Second): t.Fatal("timed out before dispatcher loop terminated") } } func TestBlocksEqual(t *testing.T) { blocksOne := []BlockInfo{{Hash: []byte{1, 2, 3, 4}}} blocksTwo := []BlockInfo{{Hash: []byte{5, 6, 7, 8}}} hashOne := []byte{42, 42, 42, 42} hashTwo := []byte{29, 29, 29, 29} cases := []struct { b1 []BlockInfo h1 []byte b2 []BlockInfo h2 []byte eq bool }{ {blocksOne, hashOne, blocksOne, hashOne, true}, // everything equal {blocksOne, hashOne, blocksTwo, hashTwo, false}, // nothing equal {blocksOne, hashOne, blocksOne, nil, true}, // blocks compared {blocksOne, nil, blocksOne, nil, true}, // blocks compared {blocksOne, nil, blocksTwo, nil, false}, // blocks compared {blocksOne, hashOne, blocksTwo, hashOne, true}, // hashes equal, blocks not looked at {blocksOne, hashOne, blocksOne, hashTwo, true}, // hashes different, blocks compared {blocksOne, hashOne, blocksTwo, hashTwo, false}, // hashes different, blocks compared {blocksOne, hashOne, nil, nil, false}, // blocks is different from no blocks {blocksOne, nil, nil, nil, false}, // blocks is different from no blocks {nil, hashOne, nil, nil, true}, // nil blocks are equal, even of one side has a hash } for _, tc := range cases { f1 := FileInfo{Blocks: tc.b1, BlocksHash: tc.h1} f2 := FileInfo{Blocks: tc.b2, BlocksHash: tc.h2} if !f1.BlocksEqual(f1) { t.Error("f1 is always equal to itself", f1) } if !f2.BlocksEqual(f2) { t.Error("f2 is always equal to itself", f2) } if res := f1.BlocksEqual(f2); res != tc.eq { t.Log("f1", f1.BlocksHash, f1.Blocks) t.Log("f2", f2.BlocksHash, f2.Blocks) t.Errorf("f1.BlocksEqual(f2) == %v but should be %v", res, tc.eq) } if res := f2.BlocksEqual(f1); res != tc.eq { t.Log("f1", f1.BlocksHash, f1.Blocks) t.Log("f2", f2.BlocksHash, f2.Blocks) t.Errorf("f2.BlocksEqual(f1) == %v but should be %v", res, tc.eq) } } } func TestIndexIDString(t *testing.T) { // Index ID is a 64 bit, zero padded hex integer. var i IndexID = 42 if i.String() != "0x000000000000002A" { t.Error(i.String()) } } func closeAndWait(c Connection, closers ...io.Closer) { for _, closer := range closers { closer.Close() } var raw *rawConnection switch i := c.(type) { case wireFormatConnection: raw = i.Connection.(*rawConnection) case *rawConnection: raw = i } raw.internalClose(ErrClosed) raw.loopWG.Wait() }