Abstract: A computing device includes a processor and a machine-readable storage medium storing instructions. The instructions are executable by the processor to: initiate a transition mode in a database comprising a plurality of data elements; and responsive to a first query for a first data element during the transition mode, determine whether the first data element is already encrypted in the database. The instructions are further executable to, responsive to a determination that the first data element is already encrypted in the database: decrypt the first data element, and return the decrypted first data element to the first query. The instructions are further executable to, responsive to a determination that the first data element is not already encrypted in the database: return the first data element to the first query without decryption, and encrypt the first data element in the database.

Abstract: Example implementations relate to a security information sharing platform that enables sharing of security information among a plurality of members. For example, in an implementation, a system may determine that a first member of a community of a security information sharing platform is entitled access to a first set of encrypted information shared by a second member of the community. The system may also receive a request, from the first member, to access the first set of encrypted information, the request including a masked parameter. The system may also determine that the masked parameter matches an access parameter for accessing the first set of encrypted information and provide the first member access to the first set of encrypted information in response to determining that the masked parameter matches the access parameter.

Abstract: Examples disclosed herein relate to controlling data access on a security information sharing platform. Some examples may enable receiving, from a first member of a first community of the security information sharing platform that enables sharing of security information among a plurality of users, a request to share a first set of information. Some examples may enable determining, based on a set of parameters associated with the request to share the first set of information, an encryption mechanism to use to encrypt the first set of information. Some examples may enable encrypting the first set of information using the determined encryption mechanism. Some examples may enable sharing the encrypted first set of information.

Abstract: Examples relate to transaction authentication. In one example, a computing device may: receive, from a payment terminal: transaction data for a transaction, a terminal identifier of the payment terminal, and a first message authentication code (MAC) for the transaction; obtain, from an authentication cache and using the terminal identifier, a terminal secret for the payment terminal; combine the transaction data and the terminal identifier to create a message; generate a second message authentication code (MAC) using the message as input and the terminal secret as a key; and determine, using the first MAC and second MAC, whether the transaction data is authentic.

Abstract: A system may include a point-of-sale system that gathers payment card track data from a payment card and a payment card gateway that processes the track data to authorize purchase transactions. The point-of-sale system may remove sensitive data such as a portion of a primary account number from the track data and may compress the removed data. The compressed version of the data may be appended to a discretionary field in the track data. The discretionary field may be encrypted following insertion of the compressed data. Track data that has been modified in this way may be conveyed to the payment gateway for processing.

Abstract: A system may include a point-of-sale system that gathers payment card track data from a payment card and a payment gateway that processes the track data to authorize purchase transactions. Discretionary data in a discretionary field of the track data may be compressed to create space that may be used to accommodate additional security data. The sensitive information may be moved to the discretionary field. The compressed discretionary data and the sensitive information may be encrypted using a structure preserving encryption algorithm and a managed encryption key. The managed encryption key or other additional security data may be added the discretionary field. Track data that has been modified in this way may be conveyed to the payment gateway for processing. The payment gateway may extract the key management data, decrypt the encrypted data, and reconstruct the original track data by decompressing the discretionary data and replacing the sensitive track data.

Abstract: Systems and methods are provided for securing payment card information. A user may present a payment card such as a credit card to point-of-sale equipment. The point-of-sale equipment may use a symmetric key to encrypt payment card information associated with the payment card. The symmetric key may be encrypted at the point-of-sale equipment using the identity-based-encryption (IBE) public key of a purchase transaction processor to produce a key transfer block. The key transfer block and the encrypted payment card information may be conveyed from the point-of-sale equipment to the purchase transaction processor over a communications network. At the purchase transaction processor, an IBE private key may be used to recover the symmetric key from the key transfer block. The symmetric key can be used to decrypt the encrypted payment card information for processing and re-encryption using a key associated with the purchase transaction processor.

Abstract: Format-preserving encryption and decryption processes are provided. The encryption and decryption processes may use a block cipher. A string that is to be encrypted or decrypted may be converted to a unique binary value. The block cipher may operate on the binary value. If the output of the block cipher that is produced is not representative of a string that is in the same format as the original string, the block cipher may be applied again. The block cipher may be repeatedly applied in this way during format-preserving encryption operations and during format-preserving decryption operations until a format-compliant output is produced. Selective access may be provided to portions of a string that have been encrypted using format-preserving encryption.

Abstract: Format preserving encryption (FPE) cryptographic engines are provided for performing encryption and decryption on strings. A plaintext string may be converted to ciphertext by repeated application of a format preserving encryption cryptographic algorithm. Following each application of the format preserving cryptographic algorithm, the resulting version of the string may be analyzed to determine whether desired string constraints have been satisfied. If the string constraints have not been satisfied, further applications of the format preserving cryptographic algorithm may be performed. If the string constraints have been satisfied, the current version of the string may be used as an output for the cryptographic engine.

Abstract: Key requests in a data processing system may include identifiers such as user names, policy names, and application names. The identifiers may also include validity period information indicating when corresponding keys are valid. When fulfilling a key request, a key server may use identifier information from the key request in determining which key access policies to apply and may use the identifier in determining whether an applicable policy has been satisfied. When a key request is authorized, the key server may generate a key by applying a one-way function to a root secret and the identifier. Validity period information for use by a decryption engine may be embedded in data items that include redundant information. Application testing can be facilitated by populating a test database with data that has been encrypted using a format-preserving encryption algorithm. Parts of a data string may be selectively encrypted based on their sensitivity.

Abstract: Online ordering systems allow a user to submit sensitive information such as payment card information to a merchant in encrypted form. A payment card processor server may be used to provide the user's web browser with code for an encryption function, a cryptographic key, and a key identifier. The web browser may encrypt the payment card information by executing the encryption function and using the key. The encrypted payment card information may be supplied to the merchant over the internet. A key identifier that identifies which cryptographic key was used in encrypting the payment card information may be provided to the merchant without providing the merchant with access to the key. The merchant can forward the encrypted payment card information to the credit card processor server with the key identifier. The processor server can use the key identifier to obtain the key and decrypt the payment card information for authorization.

Abstract: Key requests in a data processing system may include identifiers such as user names, policy names, and application names. The identifiers may also include validity period information indicating when corresponding keys are valid. When fulfilling a key request, a key server may use identifier information from the key request in determining which key access policies to apply and may use the identifier in determining whether an applicable policy has been satisfied. When a key request is authorized, the key server may generate a key by applying a one-way function to a root secret and the identifier. Validity period information for use by a decryption engine may be embedded in data items that include redundant information. Application testing can be facilitated by populating a test database with data that has been encrypted using a format-preserving encryption algorithm. Parts of a data string may be selectively encrypted based on their sensitivity.

Abstract: A data processing system is provided that includes applications, databases, encryption engines, and decryption engines. Encryption and decryption engines may be used to perform format-preserving encryption on data strings stored in a database. Applications may be used to embed information in data strings. Information may be embedded by using a character set that is larger than a character set being used by a data string. A data string may be converted into a larger character set, analogous to converting a number from a lower base to higher base. Such a conversion may shorten a data string, allowing information to be embedded as appended characters.

Abstract: Format preserving encryption (FPE) cryptographic engines are provided for performing encryption and decryption on strings. A plaintext string may be converted to ciphertext by repeated application of a format preserving encryption cryptographic algorithm. Following each application of the format preserving cryptographic algorithm, the resulting version of the string may be analyzed to determine whether desired string constraints have been satisfied. If the string constraints have not been satisfied, further applications of the format preserving cryptographic algorithm may be performed. If the string constraints have been satisfied, the current version of the string may be used as an output for the cryptographic engine.

Abstract: A user who is browsing the web may use a web site verification service to ascertain whether a web site that appears to be associated with a trusted entity is actually associated with that entity. The web site verification service retains the URL of an unauthenticated web site. The user types a text string naming the entity that the user believes should be associated with the web site into a text box. A database such as an internet search engine database or a database containing a list of trusted entities and their URLs may be queried using the user-supplied text string. The retained URL may be compared to the resulting list of URLs. If the retained URL does not match one of the URLs in the query results, the user may be warned that the web site does not appear to be associated with the trusted entity.

Abstract: Key requests in a data processing system may include identifiers such as user names, policy names, and application names. The identifiers may also include validity period information indicating when corresponding keys are valid. When fulfilling a key request, a key server may use identifier information from the key request in determining which key access policies to apply and may use the identifier in determining whether an applicable policy has been satisfied. When a key request is authorized, the key server may generate a key by applying a one-way function to a root secret and the identifier. Validity period information for use by a decryption engine may be embedded in data items that include redundant information. Application testing can be facilitated by populating a test database with data that has been encrypted using a format-preserving encryption algorithm. Parts of a data string may be selectively encrypted based on their sensitivity.

Abstract: A data processing system is provided that includes applications, databases, encryption engines, and decryption engines. Encryption and decryption engines may be used to perform format-preserving encryption on data strings stored in a database. Applications may be used to embed information in data strings. Information may be embedded by using a character set that is larger than a character set being used by a data string. A data string may be converted into a larger character set, analogous to converting a number from a lower base to higher base. Such a conversion may shorten a data string, allowing information to be embedded as appended characters.

Abstract: A data processing system is provided that includes applications, databases, encryption engines, and decryption engines. Encryption and decryption engines may be used to perform format-preserving encryption on data strings stored in a database. Encryption and decryption engines may include embedded-format-preserving encryption and decryption engines. Embedded-format-preserving encryption engines may be used to encrypt data strings and embed information in data strings. Information corresponding to a format-preserving encryption operation of a data string may be embedded in an associated data string. The associated data string may be encrypted before or after embedding the information in the associated data string. The embedded information may include key management data that corresponds to a managed encryption key that was used to encrypt the data string.

Abstract: Format preserving encryption (FPE) cryptographic engines are provided for performing encryption and decryption on strings. A plaintext string may be converted to ciphertext by repeated application of a format preserving encryption cryptographic algorithm. Following each application of the format preserving cryptographic algorithm, the resulting version of the string may be analyzed to determine whether desired string constraints have been satisfied. If the string constraints have not been satisfied, further applications of the format preserving cryptographic algorithm may be performed. If the string constraints have been satisfied, the current version of the string may be used as an output for the cryptographic engine.

Abstract: Online ordering systems allow a user to submit sensitive information such as payment card information to a merchant in encrypted form. A payment card processor server may be used to provide the user's web browser with code for an encryption function, a cryptographic key, and a key identifier. The web browser may encrypt the payment card information by executing the encryption function and using the key. The encrypted payment card information may be supplied to the merchant over the internet. A key identifier that identifies which cryptographic key was used in encrypting the payment card information may be provided to the merchant without providing the merchant with access to the key. The merchant can forward the encrypted payment card information to the credit card processor server with the key identifier. The processor server can use the key identifier to obtain the key and decrypt the payment card information for authorization.