def add_encrypted_request_hash(self):
"""
calculates request has based on EEA trusted-computing spec 6.1.8.1
and set encryptedRequestHash parameter in the request.
"""
sig_obj = signature.ClientSignature()
concat_string = self.get_requester_nonce() + \
self.get_work_order_id() + \
self.get_worker_id() + \
self.get_workload_id() + \
self.get_requester_id()
concat_bytes = bytes(concat_string, "UTF-8")
# SHA-256 hashing is used
hash_1 = crypto.byte_array_to_base64(
crypto.compute_message_hash(concat_bytes)
)
hash_2 = sig_obj.calculate_datahash(self.get_in_data())
hash_3 = ""
out_data = self.get_out_data()
if out_data and len(out_data) > 0:
hash_3 = sig_obj.calculate_datahash(out_data)
concat_hash = hash_1 + hash_2 + hash_3
concat_hash = bytes(concat_hash, "UTF-8")
self.final_hash = crypto.compute_message_hash(concat_hash)
encrypted_request_hash = crypto_utility.encrypt_data(
self.final_hash, self.session_key, self.session_iv)
self.params_obj["encryptedRequestHash"] = crypto.byte_array_to_hex(
encrypted_request_hash)
def calculate_request_hash(self, input_json):
"""
Function to create the work order reuest hash
as defined in EEA spec 6.1.8.1
Parameters:
- input_json is dictionary contains work order request payload
as define EEA spec 6.1.1
Returns hash of work order request as string
"""
wo_request_params = input_json["params"]
concat_string = wo_request_params["requesterNonce"] + \
wo_request_params["workOrderId"] + \
wo_request_params["workerId"] + \
wo_request_params["workloadId"] + \
wo_request_params["requesterId"]
concat_bytes = bytes(concat_string, "UTF-8")
# SHA-256 hashing is used
hash_1 = crypto.byte_array_to_base64(
crypto.compute_message_hash(concat_bytes))
hash_2 = self.calculate_datahash(wo_request_params["inData"])
hash_3 = ""
if "outData" in wo_request_params and \
len(wo_request_params["outData"]) > 0:
hash_3 = self.calculate_datahash(wo_request_params["outData"])
concat_hash = hash_1 + hash_2 + hash_3
concat_hash = bytes(concat_hash, "UTF-8")
final_hash = crypto.compute_message_hash(concat_hash)
final_hash_str = crypto.byte_array_to_hex(final_hash)
return final_hash_str
def update_receipt(self, work_order_id, update_type,
update_data, signing_key):
"""
Update the existing work order receipt with
update_type, update_data.
Parameters:
- work_order_id is work order id whose receipt
needs to be updated.
- update_type is integer, these values corresponds to
receipt status as defined in 7.1.1
- update_data is update-specific data that depend on
the workOrderStatus
Returns jrpc work order update receipt request of type dictionary
"""
data = update_data
if update_type in [ReceiptCreateStatus.PROCESSED.value,
ReceiptCreateStatus.COMPLETED.value]:
# Work Order Receipt status is set to be completed or processed,
# then update_data should be work order response.
wo_resp_str = json.dumps(update_data)
wo_resp_bytes = bytes(wo_resp_str, "UTF-8")
# Hash of work order response is update_data
wo_resp_hash = crypto.compute_message_hash(wo_resp_bytes)
wo_resp_hash_str = crypto.byte_array_to_hex(wo_resp_hash)
data = wo_resp_hash_str
public_key = signing_key.GetPublicKey().Serialize()
updater_id = crypto_utility.strip_begin_end_public_key(public_key)
wo_receipt_update = {
"workOrderId": work_order_id,
"updaterId": updater_id,
"updateType": update_type,
"updateData": data,
"signatureRules":
self.HASHING_ALGORITHM + "/" + self.SIGNING_ALGORITHM,
"receiptVerificationKey": public_key
}
wo_receipt_str = wo_receipt_update["workOrderId"] + \
str(wo_receipt_update["updateType"]) + \
wo_receipt_update["updateData"]
wo_receipt_bytes = bytes(wo_receipt_str, "UTF-8")
wo_receipt_hash = crypto.compute_message_hash(wo_receipt_bytes)
status, wo_receipt_sign = self.sig_obj.generate_signature(
wo_receipt_hash,
signing_key
)
if status is False:
# if generating signature failed.
wo_receipt_update["updateSignature"] = ""
raise Exception("Generate signature is failed")
else:
wo_receipt_update["updateSignature"] = wo_receipt_sign
return wo_receipt_update
def _add_data_item(self, data_copy, data_item):
try:
index = data_item['index']
data = data_item['data'].encode('UTF-8')
if 'encryptedDataEncryptionKey' in data_item:
e_key = data_item['encryptedDataEncryptionKey'].encode('UTF-8')
else:
e_key = "null".encode('UTF-8')
if (not e_key) or (e_key == "null".encode('UTF-8')):
enc_data = self.encrypt_data(data, self.session_key,
self.session_iv)
base64_enc_data = (crypto.byte_array_to_base64(enc_data))
if 'dataHash' in data_item:
dataHash_enc_data = (self.byte_array_to_hex_str(
crypto.compute_message_hash(data)))
logger.debug("encrypted indata - %s",
crypto.byte_array_to_base64(enc_data))
elif e_key == "-".encode('UTF-8'):
# Skip encryption and just encode workorder data
# to base64 format
base64_enc_data = (crypto.byte_array_to_base64(data))
if 'dataHash' in data_item:
dataHash_enc_data = (self.byte_array_to_hex_str(
crypto.compute_message_hash(data)))
else:
data_key = None
data_iv = None
enc_data = self.encrypt_data(data, data_key, data_iv)
base64_enc_data = (crypto.byte_array_to_base64(enc_data))
if 'dataHash' in data_item:
dataHash_enc_data = (self.byte_array_to_hex_str(
crypto.compute_message_hash(data)))
logger.debug("encrypted indata - %s",
crypto.byte_array_to_base64(enc_data))
enc_indata_item = {
'index':
index,
'dataHash':
dataHash_enc_data,
'data':
base64_enc_data,
'encryptedDataEncryptionKey':
data_item['encryptedDataEncryptionKey'],
'iv':
data_item['iv']
}
data_copy.append(enc_indata_item)
return data_copy
except Exception:
return None
def _compute_encrypted_request_hash(self):
first_string = self.nonce_hash
worker_order_id = self.get_work_order_id()
if worker_order_id is not None:
first_string = first_string + worker_order_id.encode('UTF-8')
logger.info("first_string - %s", first_string)
else:
first_string = first_string + "".encode('UTF-8')
worker_id = self.get_worker_id()
if worker_id is not None:
first_string = first_string + worker_id.encode('UTF-8')
else:
first_string = first_string + "".encode('UTF-8')
workload_id = self.get_workload_id()
if workload_id is not None:
first_string = first_string + workload_id.encode('UTF-8')
else:
first_string = first_string + "".encode('UTF-8')
requester_id = self.get_requester_id()
if requester_id is not None:
first_string = first_string + requester_id.encode('UTF-8')
else:
first_string = first_string + "".encode('UTF-8')
concat_hash = bytes(first_string)
self.hash_1 = crypto.byte_array_to_base64(
crypto.compute_message_hash(concat_hash))
in_data = self.get_in_data()
out_data = self.get_out_data()
self.hash_2 = ""
if in_data is not None:
self.hash_2 = self._compute_hash_string(in_data)
self.hash_3 = ""
if out_data is not None:
self.hash_3 = self._compute_hash_string(out_data)
final_string = self.hash_1 + self.hash_2 + self.hash_3
self.final_hash = crypto.compute_message_hash(
bytes(final_string, 'UTF-8'))
self.encrypted_request_hash = self.byte_array_to_hex_str(
self.encrypt_data(self.final_hash, self.session_key,
self.session_iv))
self.params_obj["encryptedRequestHash"] = self.encrypted_request_hash
def verify_update_receipt_signature(self, input_json):
"""
Function to verify the signature of work order receipt update
Parameters:
- input_json is dictionary contains payload returned by the
WorkOrderReceiptUpdateRetrieve API as define EEA spec 7.2.7
Returns enum type SignatureStatus
"""
input_json_params = input_json['result']
concat_string = input_json_params["workOrderId"] + \
str(input_json_params["updateType"]) + \
input_json_params["updateData"]
concat_hash = bytes(concat_string, 'UTF-8')
final_hash = crypto.compute_message_hash(concat_hash)
signature = input_json_params["updateSignature"]
verification_key = input_json_params["receiptVerificationKey"]
try:
_verifying_key = crypto.SIG_PublicKey(verification_key)
except Exception as error:
logger.info("Error in verification key : %s", error)
return SignatureStatus.INVALID_VERIFICATION_KEY
decoded_signature = crypto.base64_to_byte_array(signature)
sig_result = _verifying_key.VerifySignature(final_hash,
decoded_signature)
if sig_result == 1:
return SignatureStatus.PASSED
elif sig_result == 0:
return SignatureStatus.FAILED
else:
return SignatureStatus.INVALID_SIGNATURE_FORMAT
def calculate_datahash(self, data_objects):
"""
Function to calculate a hash value of the array concatenating dataHash,
data, encryptedDataEncryptionKey, iv for each item in the
inData/outData array
Parameters:
- data_objects is each item in inData or outData part of workorder
request as per TCF API 6.1.7 Work Order Data Formats
"""
hash_str = ""
for item in data_objects:
datahash = "".encode('UTF-8')
e_key = "".encode('UTF-8')
iv = "".encode('UTF-8')
if 'dataHash' in item:
datahash = item['dataHash'].encode('UTF-8')
data = item['data'].encode('UTF-8')
if 'encryptedDataEncryptionKey' in item:
e_key = item['encryptedDataEncryptionKey'].encode('UTF-8')
if 'iv' in item:
iv = item['iv'].encode('UTF-8')
concat_string = datahash + data + e_key + iv
concat_hash = bytes(concat_string)
hash = crypto.compute_message_hash(concat_hash)
hash_str = hash_str + crypto.byte_array_to_base64(hash)
return hash_str
def __calculate_hash_on_concatenated_string(self, input_json_params,
nonce_hash):
"""
Function to calculate a hash value of the string concatenating the
following values:
requesterNonce, workOrderId, workerId, workloadId, and requesterId.
Parameters:
- input_json_params is a collection of parameters,
as per TCF APi 6.1.1 Work Order Request Payload
- nonce_hash is SHA256 hashed value of a random string generated by
the participant.
"""
workorder_id = (input_json_params['workOrderId']).encode('UTF-8')
worker_id = (input_json_params['workerId']).encode('UTF-8')
workload_id = "".encode('UTF-8')
if 'workloadId' in input_json_params:
workload_id = (input_json_params['workloadId']).encode('UTF-8')
requester_id = (input_json_params['requesterId']).encode('UTF-8')
concat_string = nonce_hash + workorder_id + worker_id + workload_id + \
requester_id
concat_hash = bytes(concat_string)
# SHA-256 hashing is used
hash_1 = crypto.compute_message_hash(concat_hash)
result_hash = crypto.byte_array_to_base64(hash_1)
return result_hash
def create_receipt(self,
wo_request,
receipt_create_status,
signing_key,
nonce=None):
"""
Create work order receipt corresponding to workorder id
Parameters:
- wo_request is jrpc work order request used to create the
work order request as defined in EEA spec 6.1.1.
- receipt_create_status is enum of type ReceiptCreateStatus
- signing_key is private key
- nonce is int type random number or monotonic counter
Returns jrpc request of type dictionary
"""
final_hash_str = self.sig_obj.calculate_request_hash(wo_request)
wo_request_params = wo_request["params"]
worker_id = wo_request_params["workerId"]
requester_nonce = nonce
if nonce is None:
requester_nonce = str(random.randint(1, 10**10))
public_key = signing_key.GetPublicKey().Serialize()
wo_receipt_request = {
"workOrderId": wo_request_params["workOrderId"],
# TODO: workerServiceId is same as worker id,
# needs to be updated with actual service id
"workerServiceId": worker_id,
"workerId": worker_id,
"requesterId": wo_request_params["requesterId"],
"receiptCreateStatus": receipt_create_status,
"workOrderRequestHash": final_hash_str,
"requesterGeneratedNonce": requester_nonce,
"signatureRules":
self.HASHING_ALGORITHM + "/" + self.SIGNING_ALGORITHM,
"receiptVerificationKey": public_key
}
wo_receipt_str = wo_receipt_request["workOrderId"] + \
wo_receipt_request["workerServiceId"] + \
wo_receipt_request["workerId"] + \
wo_receipt_request["requesterId"] + \
str(wo_receipt_request["receiptCreateStatus"]) + \
wo_receipt_request["workOrderRequestHash"] + \
wo_receipt_request["requesterGeneratedNonce"]
wo_receipt_bytes = bytes(wo_receipt_str, "UTF-8")
wo_receipt_hash = crypto.compute_message_hash(wo_receipt_bytes)
status, wo_receipt_sign = self.sig_obj.generate_signature(
wo_receipt_hash, signing_key)
if status is False:
# if generate signature is failed.
wo_receipt_request["requesterSignature"] = ""
raise Exception("Generate signature is failed")
else:
wo_receipt_request["requesterSignature"] = wo_receipt_sign
return wo_receipt_request
def __validate_work_order_receipt_update_req(self, wo_receipt_req):
"""
Function to validate the work order receipt create request parameters
Parameters:
- wo_receipt_req is work order receipt request as dictionary
Returns - tuple containing validation status(Boolean) and error
message(string)
"""
valid_params = ["workOrderId", "updaterId", "updateType", "updateData",
"updateSignature", "signatureRules",
"receiptVerificationKey"]
for key in wo_receipt_req["params"]:
if key not in valid_params:
return False, "Missing parameter " + key + " in the request"
else:
if key in ["workOrderId", "updaterId"]:
if not is_valid_hex_str(wo_receipt_req[key]):
return False, "invalid data parameter for " + key
elif key in ["updateData", "updateSignature"]:
try:
base64.b64decode(wo_receipt_req[key])
except Exception:
return False, "Invalid data format for " + key
update_type = wo_receipt_req["params"]["updateType"]
try:
update_enum_value = ReceiptCreateStatus(update_type)
except Exception as err:
return False, "Invalid receipt update type {}: {}".format(
update_enum_value, str(err))
# If update type is completed or processed,
# it is a hash value of the Work Order Response
if wo_receipt_req["params"]["updateType"] in [
ReceiptCreateStatus.PROCESSED.value,
ReceiptCreateStatus.COMPLETED.value
]:
wo_id = wo_receipt_req["params"]["workOrderId"]
# Load the work order response and calculate it's hash
wo_resp = self.kv_helper.get("wo-responses", wo_id)
wo_resp_bytes = bytes(wo_resp, "UTF-8")
wo_resp_hash = crypto.compute_message_hash(wo_resp_bytes)
wo_resp_hash_str = crypto.byte_array_to_hex(wo_resp_hash)
if wo_resp_hash_str != wo_receipt_req["params"]["updateData"]:
return False, "Invalid Update data in the request"
# If all validation is pass
return True, ""
def EncryptionKeyGet(self, **params):
"""
Function to process get encryption key request.
Parameters:
- param is the 'param' object in the a worker request as per TCF
API 6.1.10 Get Encryption Key Request Payload
"""
worker_id = str(params['workerId'])
value = self.kv_helper.get("workers", worker_id)
if value is None:
raise JSONRPCDispatchException(
WorkerError.INVALID_PARAMETER_FORMAT_OR_VALUE,
"Worker id not found in the database. Hence invalid parameter")
worker_type_data = json.loads(value).get("details").get(
"workerTypeData")
encryptionKey = worker_type_data["encryptionKey"]
try:
encryptionKeyNonce = worker_type_data["encryptionKeyNonce"]
except Exception:
encryptionKeyNonce = crypto.random_bit_string(NO_OF_BYTES)
tag = ""
# calculate signature
concat_string = worker_id.encode('UTF-8') + encryptionKey.encode(
'UTF-8') + encryptionKeyNonce.encode('UTF-8') + tag.encode('UTF-8')
concat_hash = bytes(concat_string)
hash_1 = crypto.compute_message_hash(concat_hash)
s1 = crypto.byte_array_to_base64(hash_1)
# Requires worker private key to sign.
# signature = self.PrivateKey.SignMessage(hash)
result = {
"workerId": worker_id,
"encryptionKey": encryptionKey,
"encryptionKeyNonce": encryptionKeyNonce,
"tag": "",
"signature": s1,
}
return result
def verify_signature(self, input_json, verification_key):
"""
Function to verify the signature received from the enclave
Parameters:
- input_json is dictionary contains payload returned by the
Worker Service in response to successful workorder submit request
as per TCF API 6.1.2 Work Order Result Payload
- verification_key is ECDSA/SECP256K1 public key used to verify
signatures created by the Enclave.
Returns enum type SignatureStatus
"""
input_json_params = input_json['result']
nonce = (input_json_params['workerNonce']).encode('UTF-8')
signature = input_json_params['workerSignature']
hash_string_1 = self.__calculate_hash_on_concatenated_string(
input_json_params, nonce)
data_objects = input_json_params['outData']
data_objects.sort(key=lambda x: x['index'])
hash_string_2 = self.calculate_datahash(data_objects)
concat_string = hash_string_1 + hash_string_2
concat_hash = bytes(concat_string, 'UTF-8')
final_hash = crypto.compute_message_hash(concat_hash)
try:
_verifying_key = crypto.SIG_PublicKey(verification_key)
except Exception as error:
logger.info("Error in verification key : %s", error)
return SignatureStatus.INVALID_VERIFICATION_KEY
decoded_signature = crypto.base64_to_byte_array(signature)
sig_result = _verifying_key.VerifySignature(final_hash,
decoded_signature)
if sig_result == 1:
return SignatureStatus.PASSED
elif sig_result == 0:
return SignatureStatus.FAILED
else:
return SignatureStatus.INVALID_SIGNATURE_FORMAT
def _compute_hash_string(self, data):
final_hash_str = ""
hash_string = ""
for data_item in data:
data = "".encode('UTF-8')
datahash = "".encode('UTF-8')
e_key = "".encode('UTF-8')
iv = "".encode('UTF-8')
if 'dataHash' in data_item:
datahash = data_item['dataHash'].encode('UTF-8')
if 'data' in data_item:
data = data_item['data'].encode('UTF-8')
if 'encryptedDataEncryptionKey' in data_item:
e_key = \
data_item['encryptedDataEncryptionKey'].encode('UTF-8')
if 'iv' in data_item:
iv = data_item['iv'].encode('UTF-8')
hash_string = datahash + data + e_key + iv
complete_bytes = bytes(hash_string)
hash = crypto.compute_message_hash(complete_bytes)
final_hash_str = final_hash_str + crypto.byte_array_to_base64(hash)
return final_hash_str
def compute_data_hash(data):
'''
Computes SHA-256 hash of data
'''
data_hash = crypto.compute_message_hash(data.encode("UTF-8"))
return data_hash
def generate_client_signature(self,
input_json_str,
worker,
private_key,
session_key,
session_iv,
encrypted_session_key,
data_key=None,
data_iv=None):
"""
Function to generate client signature
Parameters:
- input_json_str is requester Work Order Request payload in a
JSON-RPC based format defined 6.1.1 Work Order Request Payload
- worker is a worker object to store all the common details of
worker as per TCF API 8.1 Common Data for All Worker Types
- private_key is Client private key
- session_key is one time session key generated by the participant
submitting the work order.
- session_iv is an initialization vector if required by the
data encryption algorithm (encryptedSessionKey).
The default is all zeros.
- data_key is a one time key generated by participant used to
encrypt work order indata
- data_iv is an initialization vector used along with data_key.
Default is all zeros.
- encrypted_session_key is a encrypted version of session_key.
Returns a tuple containing signature and status
"""
if (self.__payload_json_check(input_json_str) is False):
logger.error("ERROR: Signing the request failed")
return None
if (self.tcs_worker['HashingAlgorithm'] != worker.hashing_algorithm):
logger.error(
"ERROR: Signing the request failed. Hashing " +
"algorithm is not supported for %s", worker.hashing_algorithm)
return None
if (self.tcs_worker['SigningAlgorithm'] != worker.signing_algorithm):
logger.error(
"ERROR: Signing the request failed. Signing " +
"algorithm is not supported for %s", worker.signing_algorithm)
return None
input_json = json.loads(input_json_str)
input_json_params = input_json['params']
input_json_params["sessionKeyIv"] = byte_array_to_hex_str(session_iv)
encrypted_session_key_str = byte_array_to_hex_str(
encrypted_session_key)
self.__encrypt_workorder_indata(input_json_params, session_key,
session_iv, worker.encryption_key,
data_key, data_iv)
if input_json_params["requesterNonce"] and \
is_valid_hex_str(input_json_params["requesterNonce"]):
nonce = crypto.string_to_byte_array(
input_json_params["requesterNonce"])
else:
# [NO_OF_BYTES] 16 BYTES for nonce.
# This is the recommendation by NIST to
# avoid collisions by the "Birthday Paradox".
nonce = crypto.random_bit_string(NO_OF_BYTES)
request_nonce_hash = crypto.compute_message_hash(nonce)
nonce_hash = (
crypto.byte_array_to_base64(request_nonce_hash)).encode('UTF-8')
hash_string_1 = self.__calculate_hash_on_concatenated_string(
input_json_params, nonce_hash)
data_objects = input_json_params['inData']
hash_string_2 = self.calculate_datahash(data_objects)
hash_string_3 = ""
if 'outData' in input_json_params:
data_objects = input_json_params['outData']
data_objects.sort(key=lambda x: x['index'])
hash_string_3 = self.calculate_datahash(data_objects)
concat_string = hash_string_1 + hash_string_2 + hash_string_3
concat_hash = bytes(concat_string, 'UTF-8')
final_hash = crypto.compute_message_hash(concat_hash)
encrypted_request_hash = crypto_utility.encrypt_data(
final_hash, session_key, session_iv)
encrypted_request_hash_str = \
byte_array_to_hex_str(encrypted_request_hash)
logger.debug("encrypted request hash: \n%s",
encrypted_request_hash_str)
# Update the input json params
input_json_params["encryptedRequestHash"] = encrypted_request_hash_str
status, signature = self.generate_signature(final_hash, private_key)
if status is False:
return SignatureStatus.FAILED
input_json_params['requesterSignature'] = signature
input_json_params["encryptedSessionKey"] = encrypted_session_key_str
# Temporary mechanism to share client's public key. Not a part of Spec
input_json_params['verifyingKey'] = self.public_key
input_json_params['requesterNonce'] = crypto.byte_array_to_base64(
request_nonce_hash)
input_json['params'] = input_json_params
input_json_str = json.dumps(input_json)
logger.info("Request Json successfully Signed")
return input_json_str, SignatureStatus.PASSED
def add_json_values(self, input_json_temp, worker_obj, private_key,
tamper):
self.private_key = private_key
self.worker_obj = worker_obj
input_params_list = input_json_temp["params"].keys()
if "responseTimeoutMSecs" in input_params_list:
if input_json_temp["params"]["responseTimeoutMSecs"] != "":
self.set_response_timeout_msecs(
input_json_temp["params"]["responseTimeoutMSecs"])
else:
self.set_response_timeout_msecs(6000)
if "payloadFormat" in input_params_list:
if input_json_temp["params"]["payloadFormat"] != "":
self.set_payload_format(
input_json_temp["params"]["payloadFormat"])
else:
self.set_payload_format("JSON-RPC")
if "resultUri" in input_params_list:
if input_json_temp["params"]["resultUri"] != "":
self.set_result_uri(input_json_temp["params"]["resultUri"])
else:
self.set_result_uri("")
if "notifyUri" in input_params_list:
if input_json_temp["params"]["notifyUri"] != "":
self.set_notify_uri(input_json_temp["params"]["notifyUri"])
else:
self.set_notify_uri("")
if "workOrderId" in input_params_list:
if input_json_temp["params"]["workOrderId"] != "":
self.set_work_order_id(
input_json_temp["params"]["workOrderId"])
else:
work_order_id = hex(random.randint(1, 2**64 - 1))
self.set_work_order_id(work_order_id)
if "workerId" in input_params_list:
if input_json_temp["params"]["workerId"] != "":
self.set_worker_id(input_json_temp["params"]["workerId"])
else:
self.set_worker_id(worker_obj.worker_id)
if "workloadId" in input_params_list:
if input_json_temp["params"]["workloadId"] != "":
self.set_workload_id(input_json_temp["params"]
["workloadId"].encode('UTF-8').hex())
else:
workload_id = "echo-client"
self.set_workload_id(workload_id.encode('UTF-8').hex())
if "requesterId" in input_params_list:
if input_json_temp["params"]["requesterId"] != "":
self.set_requester_id(input_json_temp["params"]["requesterId"])
else:
self.set_requester_id("0x3456")
if "workerEncryptionKey" in input_params_list:
if input_json_temp["params"]["workerEncryptionKey"] != "":
self.set_worker_encryption_key(
input_json_temp["params"]["workerEncryptionKey"].encode(
"UTF-8").hex())
else:
self.set_worker_encryption_key(
crypto_utils.strip_begin_end_public_key(
worker_obj.encryption_key).encode("UTF-8").hex())
if "dataEncryptionAlgorithm" in input_params_list:
if input_json_temp["params"]["dataEncryptionAlgorithm"] != "":
self.set_data_encryption_algorithm(
input_json_temp["params"]["dataEncryptionAlgorithm"])
else:
self.set_data_encryption_algorithm("AES-GCM-256")
if "sessionKeyIv" in input_params_list:
if input_json_temp["params"]["sessionKeyIv"] != "":
self.set_session_key_iv(
input_json_temp["params"]["sessionKeyIv"])
else:
self.set_session_key_iv(
self.byte_array_to_hex_str(self.session_iv))
if "encryptedSessionKey" in input_params_list:
if input_json_temp["params"]["encryptedSessionKey"] != "":
self.set_encrypted_session_key(
input_json_temp["params"]["encryptedSessionKey"])
self.encrypted_session_key = (
input_json_temp["params"]["encryptedSessionKey"])
else:
self.encrypted_session_key = (self.generate_encrypted_key(
self.session_key, worker_obj.encryption_key))
self.set_encrypted_session_key(
self.byte_array_to_hex_str(self.encrypted_session_key))
if "requesterNonce" in input_params_list:
if input_json_temp["params"]["requesterNonce"] != "":
self.nonce = crypto.string_to_byte_array(
input_json_temp["params"]["requesterNonce"])
self.nonce_hash = (crypto.byte_array_to_base64(
crypto.compute_message_hash(self.nonce))).encode('UTF-8')
self.set_requester_nonce(
crypto.byte_array_to_base64(
crypto.compute_message_hash(self.nonce)))
else:
self.nonce = crypto.random_bit_string(NO_OF_BYTES)
self.nonce_hash = (crypto.byte_array_to_base64(
crypto.compute_message_hash(self.nonce))).encode('UTF-8')
self.set_requester_nonce(
crypto.byte_array_to_base64(
crypto.compute_message_hash(self.nonce)))
if "inData" in input_params_list:
if input_json_temp["params"]["inData"] != "":
input_json_inData = input_json_temp["params"]["inData"]
self.add_in_data(input_json_inData)
else:
self.params_obj["inData"] = ""
if "outData" in input_params_list:
if input_json_temp["params"]["outData"] != "":
input_json_outData = input_json_temp["params"]["outData"]
self.add_out_data(input_json_outData)
else:
self.params_obj["outData"] = ""
if "encryptedRequestHash" in input_params_list:
if input_json_temp["params"]["encryptedRequestHash"] != "":
self.params_obj["encryptedRequestHash"] = \
input_json_temp["params"]["encryptedRequestHash"]
else:
self._compute_encrypted_request_hash()
if "requesterSignature" in input_params_list:
if input_json_temp["params"]["requesterSignature"] != "":
self.params_obj["requesterSignature"] = \
input_json_temp["params"]["requesterSignature"]
else:
self.params_obj["requesterSignature"] = ""
if "verifyingKey" in input_params_list:
if input_json_temp["params"]["verifyingKey"] != "":
self.params_obj["verifyingKey"] = \
input_json_temp["params"]["verifyingKey"]
if "default" in tamper.keys():
if "params" in tamper["default"].keys():
for key, value in tamper["default"]["params"]:
param = key
value = value
self.set_unknown_parameter(param, value)
def hashed_identity(self):
key_byte_array = crypto.string_to_byte_array(self.txn_public)
hashed_txn_key = crypto.compute_message_hash(key_byte_array)
encoded_hashed_key = crypto.byte_array_to_hex(hashed_txn_key)
encoded_hashed_key = encoded_hashed_key.lower()
return encoded_hashed_key
