package chanbackup import ( "bytes" "net" "testing" ) // TestMultiPackUnpack... func TestMultiPackUnpack(t *testing.T) { t.Parallel() var multi Multi numSingles := 10 originalSingles := make([]Single, 0, numSingles) for i := 0; i < numSingles; i++ { channel, err := genRandomOpenChannelShell() if err != nil { t.Fatalf("unable to gen channel: %v", err) } single := NewSingle(channel, []net.Addr{addr1, addr2}) originalSingles = append(originalSingles, single) multi.StaticBackups = append(multi.StaticBackups, single) } keyRing := &mockKeyRing{} versionTestCases := []struct { // version is the pack/unpack version that we should use to // decode/encode the final SCB. version MultiBackupVersion // valid tests us if this test case should pass or not. valid bool }{ // The default version, should pack/unpack with no problem. { version: DefaultSingleVersion, valid: true, }, // A non-default version, atm this should result in a failure. { version: 99, valid: false, }, } for i, versionCase := range versionTestCases { multi.Version = versionCase.version var b bytes.Buffer err := multi.PackToWriter(&b, keyRing) switch { // If this is a valid test case, and we failed, then we'll // return an error. case err != nil && versionCase.valid: t.Fatalf("#%v, unable to pack multi: %v", i, err) // If this is an invalid test case, and we passed it, then // we'll return an error. case err == nil && !versionCase.valid: t.Fatalf("#%v got nil error for invalid pack: %v", i, err) } // If this is a valid test case, then we'll continue to ensure // we can unpack it, and also that if we mutate the packed // version, then we trigger an error. if versionCase.valid { var unpackedMulti Multi err = unpackedMulti.UnpackFromReader(&b, keyRing) if err != nil { t.Fatalf("#%v unable to unpack multi: %v", i, err) } // First, we'll ensure that the unpacked version of the // packed multi is the same as the original set. if len(originalSingles) != len(unpackedMulti.StaticBackups) { t.Fatalf("expected %v singles, got %v", len(originalSingles), len(unpackedMulti.StaticBackups)) } for i := 0; i < numSingles; i++ { assertSingleEqual( t, originalSingles[i], unpackedMulti.StaticBackups[i], ) } // Next, we'll make a fake packed multi, it'll have an // unknown version relative to what's implemented atm. var fakePackedMulti bytes.Buffer fakeRawMulti := bytes.NewBuffer( bytes.Repeat([]byte{99}, 20), ) err := encryptPayloadToWriter( *fakeRawMulti, &fakePackedMulti, keyRing, ) if err != nil { t.Fatalf("unable to pack fake multi; %v", err) } // We should reject this fake multi as it contains an // unknown version. err = unpackedMulti.UnpackFromReader( &fakePackedMulti, keyRing, ) if err == nil { t.Fatalf("#%v unpack with unknown version "+ "should have failed", i) } } } } // TestPackedMultiUnpack tests that we're able to properly unpack a typed // packed multi. func TestPackedMultiUnpack(t *testing.T) { t.Parallel() keyRing := &mockKeyRing{} // First, we'll make a new unpacked multi with a random channel. testChannel, err := genRandomOpenChannelShell() if err != nil { t.Fatalf("unable to gen random channel: %v", err) } var multi Multi multi.StaticBackups = append( multi.StaticBackups, NewSingle(testChannel, nil), ) // Now that we have our multi, we'll pack it into a new buffer. var b bytes.Buffer if err := multi.PackToWriter(&b, keyRing); err != nil { t.Fatalf("unable to pack multi: %v", err) } // We should be able to properly unpack this typed packed multi. packedMulti := PackedMulti(b.Bytes()) unpackedMulti, err := packedMulti.Unpack(keyRing) if err != nil { t.Fatalf("unable to unpack multi: %v", err) } // Finally, the versions should match, and the unpacked singles also // identical. if multi.Version != unpackedMulti.Version { t.Fatalf("version mismatch: expected %v got %v", multi.Version, unpackedMulti.Version) } assertSingleEqual( t, multi.StaticBackups[0], unpackedMulti.StaticBackups[0], ) }