Beispiel #1
0
func (sc *systemChain) authorize(configEnvelope *cb.ConfigurationEnvelope) cb.Status {
	creationConfigItem := &cb.ConfigurationItem{}
	err := proto.Unmarshal(configEnvelope.Items[0].ConfigurationItem, creationConfigItem)
	if err != nil {
		logger.Debugf("Failing to validate chain creation because of unmarshaling error: %s", err)
		return cb.Status_BAD_REQUEST
	}

	if creationConfigItem.Key != utils.CreationPolicyKey {
		logger.Debugf("Failing to validate chain creation because first configuration item was not the CreationPolicy")
		return cb.Status_BAD_REQUEST
	}

	creationPolicy := &ab.CreationPolicy{}
	err = proto.Unmarshal(creationConfigItem.Value, creationPolicy)
	if err != nil {
		logger.Debugf("Failing to validate chain creation because first configuration item could not unmarshal to a CreationPolicy: %s", err)
		return cb.Status_BAD_REQUEST
	}

	ok := false
	for _, chainCreatorPolicy := range sc.support.SharedConfig().ChainCreators() {
		if chainCreatorPolicy == creationPolicy.Policy {
			ok = true
			break
		}
	}

	if !ok {
		logger.Debugf("Failed to validate chain creation because chain creation policy is not authorized for chain creation")
		return cb.Status_FORBIDDEN
	}

	policy, ok := sc.support.PolicyManager().GetPolicy(creationPolicy.Policy)
	if !ok {
		logger.Debugf("Failed to get policy for chain creation despite it being listed as an authorized policy")
		return cb.Status_INTERNAL_SERVER_ERROR
	}

	// XXX actually do policy signature validation
	_ = policy

	var remainingBytes []byte
	for i, item := range configEnvelope.Items {
		if i == 0 {
			// Do not include the creation policy
			continue
		}
		remainingBytes = append(remainingBytes, item.ConfigurationItem...)
	}

	configHash := util.ComputeCryptoHash(remainingBytes)

	if !bytes.Equal(configHash, creationPolicy.Digest) {
		logger.Debugf("Validly signed chain creation did not contain correct digest for remaining configuration %x vs. %x", configHash, creationPolicy.Digest)
		return cb.Status_BAD_REQUEST
	}

	return cb.Status_SUCCESS
}
Beispiel #2
0
// TestHashContentChange changes a random byte in a content and checks for hash change
func TestHashContentChange(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	b2 := []byte("To be, or not to be- that is the question: Whether 'tis nobler in the mind to suffer The slings and arrows of outrageous fortune Or to take arms against a sea of troubles, And by opposing end them. To die- to sleep- No more; and by a sleep to say we end The heartache, and the thousand natural shocks That flesh is heir to. 'Tis a consummation Devoutly to be wish'd.")

	h1 := computeHash(b2, hash)

	r := rand.New(rand.NewSource(time.Now().UnixNano()))
	randIndex := (int(r.Uint32())) % len(b2)

	randByte := byte((int(r.Uint32())) % 128)

	//make sure the two bytes are different
	for {
		if randByte != b2[randIndex] {
			break
		}

		randByte = byte((int(r.Uint32())) % 128)
	}

	//change a random byte
	b2[randIndex] = randByte

	//this is the core hash func under test
	h2 := computeHash(b2, hash)

	//the two hashes should be different
	if bytes.Compare(h1, h2) == 0 {
		t.Fail()
		t.Logf("Hash expected to be different but is same")
	}
}
Beispiel #3
0
func (trieNode *trieNode) computeCryptoHash() []byte {
	stateTrieLogger.Debug("Enter computeCryptoHash() for trieNode [%s]", trieNode)
	var cryptoHashContent []byte
	if trieNode.containsValue() {
		stateTrieLogger.Debug("Adding value to hash computation for trieNode [%s]", trieNode)
		key := trieNode.trieKey.getEncodedBytes()
		cryptoHashContent = append(cryptoHashContent, proto.EncodeVarint(uint64(len(key)))...)
		cryptoHashContent = append(cryptoHashContent, key...)
		cryptoHashContent = append(cryptoHashContent, trieNode.value...)
	}

	sortedChildrenIndexes := trieNode.getSortedChildrenIndex()
	for _, index := range sortedChildrenIndexes {
		childCryptoHash := trieNode.childrenCryptoHashes[index]
		stateTrieLogger.Debug("Adding hash [%#v] for child number [%d] to hash computation for trieNode [%s]", childCryptoHash, index, trieNode)
		cryptoHashContent = append(cryptoHashContent, childCryptoHash...)
	}

	if cryptoHashContent == nil {
		// node has no associated value and no associated children.
		stateTrieLogger.Debug("Returning nil as hash for trieNode = [%s]. Also, marking this key for deletion.", trieNode)
		trieNode.markedForDeletion = true
		return nil
	}

	if !trieNode.containsValue() && trieNode.getNumChildren() == 1 {
		// node has no associated value and has a single child. Propagate the child hash up
		stateTrieLogger.Debug("Returning hash as of a single child for trieKey = [%s]", trieNode.trieKey)
		return cryptoHashContent
	}

	stateTrieLogger.Debug("Recomputing hash for trieKey = [%s]", trieNode)
	return util.ComputeCryptoHash(cryptoHashContent)
}
Beispiel #4
0
func TestGoodProposal(t *testing.T) {
	newChainID := "NewChainID"

	mcc := newMockChainCreator()
	mcc.ms.msc.chainCreators = []string{provisional.AcceptAllPolicyKey}
	mcc.ms.mpm.mp = &mockPolicy{}

	chainCreateTx := &cb.ConfigurationItem{
		Header: &cb.ChainHeader{
			ChainID: newChainID,
			Type:    int32(cb.HeaderType_CONFIGURATION_ITEM),
		},
		Key:  utils.CreationPolicyKey,
		Type: cb.ConfigurationItem_Orderer,
		Value: utils.MarshalOrPanic(&ab.CreationPolicy{
			Policy: provisional.AcceptAllPolicyKey,
			Digest: coreutil.ComputeCryptoHash([]byte{}),
		}),
	}
	ingressTx := makeConfigTxWithItems(newChainID, chainCreateTx)
	status := mcc.sysChain.proposeChain(ingressTx)
	if status != cb.Status_SUCCESS {
		t.Fatalf("Should have successfully proposed chain")
	}

	expected := 1
	if len(mcc.ms.queue) != expected {
		t.Fatalf("Expected %d creation txs in the chain, but found %d", expected, len(mcc.ms.queue))
	}

	wrapped := mcc.ms.queue[0]
	payload := utils.UnmarshalPayloadOrPanic(wrapped.Payload)
	if payload.Header.ChainHeader.Type != int32(cb.HeaderType_ORDERER_TRANSACTION) {
		t.Fatalf("Wrapped transaction should be of type ORDERER_TRANSACTION")
	}
	envelope := utils.UnmarshalEnvelopeOrPanic(payload.Data)
	if !reflect.DeepEqual(envelope, ingressTx) {
		t.Fatalf("Received different configtx than ingressed into the system")
	}

	sysFilter := newSystemChainFilter(mcc)
	action, committer := sysFilter.Apply(wrapped)

	if action != filter.Accept {
		t.Fatalf("Should have accepted the transaction, as it was already validated")
	}

	if !committer.Isolated() {
		t.Fatalf("Chain creation transactions should be isolated on commit")
	}

	committer.Commit()
	if len(mcc.newChains) != 1 {
		t.Fatalf("Proposal should only have created 1 new chain")
	}

	if !reflect.DeepEqual(mcc.newChains[0], ingressTx) {
		t.Fatalf("New chain should have been created with ingressTx")
	}
}
Beispiel #5
0
func TestHashSameRemoteRepo(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	srcPath1, err := getCodeFromHTTP("https://github.com/xspeedcruiser/javachaincodemvn")
	srcPath2, err := getCodeFromHTTP("https://github.com/xspeedcruiser/javachaincodemvn")

	if err != nil {
		t.Logf("Error getting code from remote repo %s", err)
		t.Fail()
	}

	defer func() {
		os.RemoveAll(srcPath1)
	}()
	defer func() {
		os.RemoveAll(srcPath2)
	}()
	hash1, err := hashFilesInDir(srcPath1, srcPath1, hash, nil)
	if err != nil {
		t.Logf("Error getting code %s", err)
		t.Fail()
	}
	hash2, err := hashFilesInDir(srcPath2, srcPath2, hash, nil)
	if err != nil {
		t.Logf("Error getting code %s", err)
		t.Fail()
	}
	if bytes.Compare(hash1, hash2) != 0 {
		t.Logf("Hash should be same across multiple downloads")
		t.Fail()
	}
}
Beispiel #6
0
func (b *BlockData) Hash() []byte {
	data, err := proto.Marshal(b) // XXX this is wrong, protobuf is not the right mechanism to serialize for a hash, AND, it is not a MerkleTree hash
	if err != nil {
		panic("This should never fail and is generally irrecoverable")
	}

	return util.ComputeCryptoHash(data)
}
Beispiel #7
0
func (c *bucketHashCalculator) computeCryptoHash() []byte {
	if c.currentChaincodeID != "" {
		c.appendCurrentChaincodeData()
		c.currentChaincodeID = ""
		c.dataNodes = nil
	}
	logger.Debug("Hashable content for bucket [%s]: length=%d, contentInStringForm=[%s]", c.bucketKey, len(c.hashingData), string(c.hashingData))
	if util.IsNil(c.hashingData) {
		return nil
	}
	return openchainUtil.ComputeCryptoHash(c.hashingData)
}
Beispiel #8
0
func expectedCryptoHashForTest(key *trieKey, value []byte, childrenHashes ...[]byte) []byte {
	expectedHash := []byte{}
	if key != nil {
		keyBytes := key.getEncodedBytes()
		expectedHash = append(expectedHash, proto.EncodeVarint(uint64(len(keyBytes)))...)
		expectedHash = append(expectedHash, keyBytes...)
		expectedHash = append(expectedHash, value...)
	}
	for _, b := range childrenHashes {
		expectedHash = append(expectedHash, b...)
	}
	return util.ComputeCryptoHash(expectedHash)
}
Beispiel #9
0
//GetName returns canonical chaincode name based on chain name
func (ccid *CCID) GetName() string {
	if ccid.ChaincodeSpec == nil {
		panic("nil chaincode spec")
	}

	//this better be chainless system chaincode!
	if ccid.ChainID != "" {
		hash := util.ComputeCryptoHash([]byte(ccid.ChainID))
		hexstr := hex.EncodeToString(hash[:])
		return ccid.ChaincodeSpec.ChaincodeID.Name + "-" + hexstr
	}

	return ccid.ChaincodeSpec.ChaincodeID.Name
}
Beispiel #10
0
func hash(msg interface{}) string {
	var raw []byte
	switch converted := msg.(type) {
	case *Request:
		raw, _ = proto.Marshal(converted)
	case *RequestBatch:
		raw, _ = proto.Marshal(converted)
	default:
		logger.Error("Asked to hash non-supported message type, ignoring")
		return ""
	}
	return base64.StdEncoding.EncodeToString(util.ComputeCryptoHash(raw))

}
Beispiel #11
0
//core hash computation factored out for testing
func computeHash(contents []byte, hash []byte) []byte {
	newSlice := make([]byte, len(hash)+len(contents))

	//copy the contents
	copy(newSlice[0:len(contents)], contents[:])

	//add the previous hash
	copy(newSlice[len(contents):], hash[:])

	//compute new hash
	hash = util.ComputeCryptoHash(newSlice)

	return hash
}
Beispiel #12
0
// TestHashOrderChange changes a order of hash computation over a list of lines and checks for hash change
func TestHashOrderChange(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	b2 := [][]byte{[]byte("To be, or not to be- that is the question:"),
		[]byte("Whether 'tis nobler in the mind to suffer"),
		[]byte("The slings and arrows of outrageous fortune"),
		[]byte("Or to take arms against a sea of troubles,"),
		[]byte("And by opposing end them."),
		[]byte("To die- to sleep- No more; and by a sleep to say we end"),
		[]byte("The heartache, and the thousand natural shocks"),
		[]byte("That flesh is heir to."),
		[]byte("'Tis a consummation Devoutly to be wish'd.")}
	h1 := hash

	for _, l := range b2 {
		h1 = computeHash(l, h1)
	}

	r := rand.New(rand.NewSource(time.Now().UnixNano()))
	randIndex1 := (int(r.Uint32())) % len(b2)
	randIndex2 := (int(r.Uint32())) % len(b2)

	//make sure the two indeces are different
	for {
		if randIndex2 != randIndex1 {
			break
		}

		randIndex2 = (int(r.Uint32())) % len(b2)
	}

	//switch two arbitrary lines
	tmp := b2[randIndex2]
	b2[randIndex2] = b2[randIndex1]
	b2[randIndex1] = tmp

	h2 := hash
	for _, l := range b2 {
		h2 = computeHash(l, hash)
	}

	//hash should be different
	if bytes.Compare(h1, h2) == 0 {
		t.Fail()
		t.Logf("Hash expected to be different but is same")
	}
}
Beispiel #13
0
func BenchmarkCryptoHash(b *testing.B) {
	flags := flag.NewFlagSet("testParams", flag.ExitOnError)
	numBytesPointer := flags.Int("NumBytes", -1, "Number of Bytes")
	flags.Parse(testParams)
	numBytes := *numBytesPointer
	if numBytes == -1 {
		b.Fatal("Missing value for parameter NumBytes")
	}

	randomBytes := testutil.ConstructRandomBytes(b, numBytes)
	//b.Logf("byte size=%d, b.N=%d", len(randomBytes), b.N)
	b.ResetTimer()
	for i := 0; i < b.N; i++ {
		util.ComputeCryptoHash(randomBytes)
	}
}
Beispiel #14
0
func TestHashOverLocalDir(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	hash, err := hashFilesInDir(".", "../golang/hashtestfiles", hash, nil)

	if err != nil {
		t.Fail()
		t.Logf("error : %s", err)
	}

	expectedHash := "7b3b2193bed2bd7c19300aa5d6d7f6bb4d61602e4978a78bc08028379cb5cf0ed877bd9db3e990230e8bf6c974edd765f3027f061fd8657d30fc858a676a6f4a"

	computedHash := hex.EncodeToString(hash[:])

	if expectedHash != computedHash {
		t.Fail()
		t.Logf("Hash expected to be unchanged")
	}
}
Beispiel #15
0
// GetHash returns the hash of this block.
func (block *Block) GetHash() ([]byte, error) {

	// copy the block and remove the non-hash data
	blockBytes, err := block.Bytes()
	if err != nil {
		return nil, fmt.Errorf("Could not calculate hash of block: %s", err)
	}
	blockCopy, err := UnmarshallBlock(blockBytes)
	if err != nil {
		return nil, fmt.Errorf("Could not calculate hash of block: %s", err)
	}
	blockCopy.NonHashData = nil

	// Hash the block
	data, err := proto.Marshal(blockCopy)
	if err != nil {
		return nil, fmt.Errorf("Could not calculate hash of block: %s", err)
	}
	hash := util.ComputeCryptoHash(data)
	return hash, nil
}
Beispiel #16
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// TestHashOverFiles computes hash over a directory and ensures it matches precomputed, hardcoded, hash
func TestHashOverFiles(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	hash, err := hashFilesInDir(".", "hashtestfiles", hash, nil)

	if err != nil {
		t.Fail()
		t.Logf("error : %s", err)
	}

	//as long as no files under "hashtestfiles" are changed, hash should always compute to the following
	expectedHash := "a4fe18bebf3d7e1c030c042903bdda9019b33829d03d9b95ab1edc8957be70dee6d786ab27b207210d29b5d9f88456ff753b8da5c244458cdcca6eb3c28a17ce"

	computedHash := hex.EncodeToString(hash[:])

	if expectedHash != computedHash {
		t.Fail()
		t.Logf("Hash expected to be unchanged")
	}
}
Beispiel #17
0
//generateHashcode gets hashcode of the code under path. If path is a HTTP(s) url
//it downloads the code first to compute the hash.
//NOTE: for dev mode, user builds and runs chaincode manually. The name provided
//by the user is equivalent to the path. This method will treat the name
//as codebytes and compute the hash from it. ie, user cannot run the chaincode
//with the same (name, ctor, args)
func generateHashcode(spec *pb.ChaincodeSpec, path string) (string, error) {

	ctor := spec.CtorMsg
	if ctor == nil || ctor.Function == "" {
		return "", fmt.Errorf("Cannot generate hashcode from empty ctor")
	}

	hash := util.GenerateHashFromSignature(spec.ChaincodeID.Path, ctor.Function, ctor.Args)

	buf, err := ioutil.ReadFile(path)
	if err != nil {
		return "", fmt.Errorf("Error reading file: %s", err)
	}

	newSlice := make([]byte, len(hash)+len(buf))
	copy(newSlice[len(buf):], hash[:])
	//hash = md5.Sum(newSlice)
	hash = util.ComputeCryptoHash(newSlice)

	return hex.EncodeToString(hash[:]), nil
}
Beispiel #18
0
// TestHashLenChange changes a random length of a content and checks for hash change
func TestHashLenChange(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)

	b2 := []byte("To be, or not to be-")

	h1 := computeHash(b2, hash)

	r := rand.New(rand.NewSource(time.Now().UnixNano()))
	randIndex := (int(r.Uint32())) % len(b2)

	b2 = b2[0:randIndex]

	h2 := computeHash(b2, hash)

	//hash should be different
	if bytes.Compare(h1, h2) == 0 {
		t.Fail()
		t.Logf("Hash expected to be different but is same")
	}
}
Beispiel #19
0
func (bucketNode *bucketNode) computeCryptoHash() []byte {
	cryptoHashContent := []byte{}
	numChildren := 0
	for i, childCryptoHash := range bucketNode.childrenCryptoHash {
		if childCryptoHash != nil {
			numChildren++
			logger.Debugf("Appending crypto-hash for child bucket = [%s]", bucketNode.bucketKey.getChildKey(i))
			cryptoHashContent = append(cryptoHashContent, childCryptoHash...)
		}
	}
	if numChildren == 0 {
		logger.Debugf("Returning <nil> crypto-hash of bucket = [%s] - because, it has not children", bucketNode.bucketKey)
		bucketNode.markedForDeletion = true
		return nil
	}
	if numChildren == 1 {
		logger.Debugf("Propagating crypto-hash of single child node for bucket = [%s]", bucketNode.bucketKey)
		return cryptoHashContent
	}
	logger.Debugf("Computing crypto-hash for bucket [%s] by merging [%d] children", bucketNode.bucketKey, numChildren)
	return openchainUtil.ComputeCryptoHash(cryptoHashContent)
}
Beispiel #20
0
//hashFilesInDir computes h=hash(h,file bytes) for each file in a directory
//Directory entries are traversed recursively. In the end a single
//hash value is returned for the entire directory structure
func hashFilesInDir(rootDir string, dir string, hash []byte, tw *tar.Writer) ([]byte, error) {
	currentDir := filepath.Join(rootDir, dir)
	logger.Debug("hashFiles %s", currentDir)
	//ReadDir returns sorted list of files in dir
	fis, err := ioutil.ReadDir(currentDir)
	if err != nil {
		return hash, fmt.Errorf("ReadDir failed %s\n", err)
	}
	for _, fi := range fis {
		name := filepath.Join(dir, fi.Name())
		if fi.IsDir() {
			var err error
			hash, err = hashFilesInDir(rootDir, name, hash, tw)
			if err != nil {
				return hash, err
			}
			continue
		}
		fqp := filepath.Join(rootDir, name)
		buf, err := ioutil.ReadFile(fqp)
		if err != nil {
			fmt.Printf("Error reading %s\n", err)
			return hash, err
		}

		newSlice := make([]byte, len(hash)+len(buf))
		copy(newSlice[len(buf):], hash[:])
		//hash = md5.Sum(newSlice)
		hash = util.ComputeCryptoHash(newSlice)

		if tw != nil {
			is := bytes.NewReader(buf)
			if err = cutil.WriteStreamToPackage(is, fqp, filepath.Join("src", name), tw); err != nil {
				return hash, fmt.Errorf("Error adding file to tar %s", err)
			}
		}
	}
	return hash, nil
}
Beispiel #21
0
func TestProposalWithMissingPolicy(t *testing.T) {
	newChainID := "NewChainID"

	mcc := newMockChainCreator()
	mcc.ms.msc.chainCreators = []string{provisional.AcceptAllPolicyKey}

	chainCreateTx := &cb.ConfigurationItem{
		Key:  utils.CreationPolicyKey,
		Type: cb.ConfigurationItem_Orderer,
		Value: utils.MarshalOrPanic(&ab.CreationPolicy{
			Policy: provisional.AcceptAllPolicyKey,
			Digest: coreutil.ComputeCryptoHash([]byte{}),
		}),
	}
	ingressTx := makeConfigTxWithItems(newChainID, chainCreateTx)

	status := mcc.sysChain.proposeChain(ingressTx)

	if status == cb.Status_SUCCESS {
		t.Fatalf("Should not have validated the transaction with missing policy")
	}
}
Beispiel #22
0
// ComputeCryptoHash computes crypto-hash for the data held
// returns nil if no data is present
func (stateDelta *StateDelta) ComputeCryptoHash() []byte {
	if stateDelta.IsEmpty() {
		return nil
	}
	var buffer bytes.Buffer
	sortedChaincodeIds := stateDelta.GetUpdatedChaincodeIds(true)
	for _, chaincodeID := range sortedChaincodeIds {
		buffer.WriteString(chaincodeID)
		chaincodeStateDelta := stateDelta.ChaincodeStateDeltas[chaincodeID]
		sortedKeys := chaincodeStateDelta.getSortedKeys()
		for _, key := range sortedKeys {
			buffer.WriteString(key)
			updatedValue := chaincodeStateDelta.get(key)
			if !updatedValue.IsDeleted() {
				buffer.Write(updatedValue.Value)
			}
		}
	}
	hashingContent := buffer.Bytes()
	logger.Debugf("computing hash on %#v", hashingContent)
	return util.ComputeCryptoHash(hashingContent)
}
Beispiel #23
0
//hashFilesInDir computes h=hash(h,file bytes) for each file in a directory
//Directory entries are traversed recursively. In the end a single
//hash value is returned for the entire directory structure
func hashFilesInDir(cutoff string, dir string, hash []byte, tw *tar.Writer) ([]byte, error) {
	//ReadDir returns sorted list of files in dir
	fis, err := ioutil.ReadDir(dir)
	if err != nil {
		return hash, fmt.Errorf("ReadDir failed %s\n", err)
	}
	for _, fi := range fis {
		name := fmt.Sprintf("%s/%s", dir, fi.Name())
		if fi.IsDir() {
			var err error
			hash, err = hashFilesInDir(cutoff, name, hash, tw)
			if err != nil {
				return hash, err
			}
			continue
		}
		buf, err := ioutil.ReadFile(name)
		if err != nil {
			fmt.Printf("Error reading %s\n", err)
			return hash, err
		}

		newSlice := make([]byte, len(hash)+len(buf))
		copy(newSlice[len(buf):], hash[:])
		//hash = md5.Sum(newSlice)
		hash = util.ComputeCryptoHash(newSlice)

		if tw != nil {
			is := bytes.NewReader(buf)
			if err = cutil.WriteStreamToPackage(is, name, name[len(cutoff):], tw); err != nil {
				return hash, fmt.Errorf("Error adding file to tar %s", err)
			}
		}
	}
	return hash, nil
}
Beispiel #24
0
func TestHashDiffRemoteRepo(t *testing.T) {
	b := []byte("firstcontent")
	hash := util.ComputeCryptoHash(b)
	// TODO Change reference to an official test repo once established
	// Same repo being used in behave tests

	srcPath1, err := getCodeFromHTTP("https://github.com/xspeedcruiser/javachaincodemvn")
	srcPath2, err := getCodeFromHTTP("https://github.com/xspeedcruiser/javachaincode")

	if err != nil {
		t.Logf("Error getting code from remote repo %s", err)
		t.Fail()
	}

	defer func() {
		os.RemoveAll(srcPath1)
	}()
	defer func() {
		os.RemoveAll(srcPath2)
	}()
	hash1, err := hashFilesInDir(srcPath1, srcPath1, hash, nil)
	if err != nil {
		t.Logf("Error getting code %s", err)
		t.Fail()
	}
	hash2, err := hashFilesInDir(srcPath2, srcPath2, hash, nil)
	if err != nil {
		t.Logf("Error getting code %s", err)
		t.Fail()
	}
	if bytes.Compare(hash1, hash2) == 0 {
		t.Logf("Hash should be different for 2 different remote repos")
		t.Fail()
	}

}
Beispiel #25
0
// ChainCreationConfiguration creates a new chain creation configuration envelope from
// the supplied creationPolicy, new chainID, and a template configuration envelope
// The template configuration envelope will have the correct chainID set on all items,
// and the first item will be a CreationPolicy which is ready for the signatures as
// required by the policy
func ChainCreationConfiguration(creationPolicy, newChainID string, template *cb.ConfigurationEnvelope) *cb.ConfigurationEnvelope {
	newConfigItems := make([]*cb.SignedConfigurationItem, len(template.Items))
	var hashBytes []byte

	for i, item := range template.Items {
		configItem := UnmarshalConfigurationItemOrPanic(item.ConfigurationItem)
		configItem.Header.ChainID = newChainID
		newConfigItems[i] = &cb.SignedConfigurationItem{
			ConfigurationItem: MarshalOrPanic(configItem),
		}
		hashBytes = append(hashBytes, newConfigItems[i].ConfigurationItem...)
	}

	digest := cu.ComputeCryptoHash(hashBytes)

	authorizeItem := &cb.SignedConfigurationItem{
		ConfigurationItem: MarshalOrPanic(&cb.ConfigurationItem{
			Header: &cb.ChainHeader{
				ChainID: newChainID,
				Type:    int32(cb.HeaderType_CONFIGURATION_ITEM),
			},
			Type: cb.ConfigurationItem_Orderer,
			Key:  CreationPolicyKey,
			Value: MarshalOrPanic(&ab.CreationPolicy{
				Policy: creationPolicy,
				Digest: digest,
			}),
		}),
	}

	authorizedConfig := append([]*cb.SignedConfigurationItem{authorizeItem}, newConfigItems...)

	return &cb.ConfigurationEnvelope{
		Items: authorizedConfig,
	}
}
Beispiel #26
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func hashReq(req *Request) string {
	raw, _ := proto.Marshal(req)
	return base64.StdEncoding.EncodeToString(util.ComputeCryptoHash(raw))
}
Beispiel #27
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			Expect(ledgerPtr.SetState("chaincode2", "key2", []byte("value2"))).To(BeNil())
			ledgerPtr.TxFinished("txUuid2", true)
		})
		It("creates, but does not populate and finishes a transaction", func() {
			ledgerPtr.TxBegin("txUuid3")
			ledgerPtr.TxFinished("txUuid3", true)
		})
		It("creates, populates and finishes a transaction", func() {
			ledgerPtr.TxBegin("txUuid4")
			Expect(ledgerPtr.SetState("chaincode4", "key4", []byte("value4"))).To(BeNil())
			ledgerPtr.TxFinished("txUuid4", false)
		})
		It("should retrieve the delta state hash array containing expected values", func() {
			_, txDeltaHashes, err := ledgerPtr.GetTempStateHashWithTxDeltaStateHashes()
			Expect(err).To(BeNil())
			Expect(util.ComputeCryptoHash(appendAll([]byte("chaincode1key1value1")))).To(Equal(txDeltaHashes["txUuid1"]))
			Expect(util.ComputeCryptoHash(appendAll([]byte("chaincode2key2value2")))).To(Equal(txDeltaHashes["txUuid2"]))
			Expect(txDeltaHashes["txUuid3"]).To(BeNil())
			_, ok := txDeltaHashes["txUuid4"]
			Expect(ok).To(Equal(false))
		})
		It("should commit the batch", func() {
			Expect(ledgerPtr.CommitTxBatch(1, []*protos.Transaction{}, nil, []byte("proof"))).To(BeNil())
		})
		It("creates, populates and finishes a transaction", func() {
			Expect(ledgerPtr.BeginTxBatch(2)).To(BeNil())
			ledgerPtr.TxBegin("txUuid1")
			Expect(ledgerPtr.SetState("chaincode1", "key1", []byte("value1"))).To(BeNil())
			ledgerPtr.TxFinished("txUuid1", true)
		})
		It("should retrieve a delta state hash array of length 1", func() {
Beispiel #28
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func ComputeCryptoHash(content ...[]byte) []byte {
	return util.ComputeCryptoHash(AppendAll(content...))
}
Beispiel #29
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func (op *obcSieve) processExecute() {
	if op.currentReq != "" {
		return
	}

	primary := op.pbft.primary(op.epoch)
	exec := op.queuedExec[primary]
	delete(op.queuedExec, primary)

	if exec == nil {
		return
	}

	if !(exec.View == op.epoch && op.pbft.primary(op.epoch) == exec.ReplicaId && op.pbft.activeView) {
		logger.Debug("Invalid execute from %d", exec.ReplicaId)
		return
	}

	if exec.BlockNumber != op.blockNumber+1 {
		logger.Debug("Block block number in execute wrong: expected %d, got %d",
			op.blockNumber, exec.BlockNumber)
		return
	}

	op.currentReq = base64.StdEncoding.EncodeToString(util.ComputeCryptoHash(exec.Request))

	logger.Debug("Sieve replica %d received exec from %d, epoch=%d, blockNo=%d from request=%s",
		op.id, exec.ReplicaId, exec.View, exec.BlockNumber, op.currentReq)

	// With the execution decoupled from the ordering, this sanity check is challenging and introduces a race
	/*
		blockchainSize, _ := op.stack.GetBlockchainSize()
		blockchainSize--
		if op.blockNumber != blockchainSize {
			logger.Critical("Sieve replica %d block number and ledger blockchain size diverged: blockNo=%d, blockchainSize=%d", op.id, op.blockNumber, blockchainSize)
			return
		}
	*/

	op.blockNumber = exec.BlockNumber

	tx := &pb.Transaction{}
	proto.Unmarshal(exec.Request, tx)

	op.stack.BeginTxBatch(op.currentReq)
	results, err := op.stack.ExecTxs(op.currentReq, []*pb.Transaction{tx})
	_ = results // XXX what to do?
	_ = err     // XXX what to do?

	logger.Debug("Sieve replica %d results=%x err=%v using lastPbftExec of %d", op.id, results, err, op.lastExecPbftSeqNo)

	meta, _ := proto.Marshal(&Metadata{op.lastExecPbftSeqNo})
	op.currentResult, err = op.stack.PreviewCommitTxBatch(op.currentReq, meta)
	if err != nil {
		logger.Error("could not preview next block: %s", err)
		op.rollback()
		return
	}

	logger.Debug("Sieve replica %d executed blockNo=%d, request=%s", op.id, op.blockNumber, op.currentReq)

	verify := &Verify{
		View:          op.epoch,
		BlockNumber:   op.blockNumber,
		RequestDigest: op.currentReq,
		ResultDigest:  op.currentResult,
		ReplicaId:     op.id,
	}
	op.pbft.sign(verify)

	logger.Debug("Sieve replica %d sending verify blockNo=%d with result %x",
		op.id, verify.BlockNumber, op.currentResult)

	op.recvVerify(verify)
	op.broadcastMsg(&SieveMessage{&SieveMessage_Verify{verify}})

	// To prevent races, have the main pbft thread start this timer, as it will need to stop it
	op.pbft.inject(func() { op.pbft.startTimer(op.pbft.requestTimeout, fmt.Sprintf("new request %s", op.currentReq)) })
}