Systems and methods are disclosed for data protection in a cluster of data processing accelerators (DPAs). The cluster of accelerators may include DPAs of a third party accelerator that may not be trusted. To ensure data protection in the cluster, a first DPA that receives a request from a second DPA to access a resource of the first DPA authenticates the second DPA. If the second DPA passes authentication, the second DPA is permitted to access non-sensitive resources of the first DPA, otherwise the second DPA is not permitted access to any resources of the first DPA and the first DPA breaks a communication link with the second DPA. Authentication is premised on a shared secret function between DPAs and a random number generated by the first DPA. The shared secret function is updateable by, e.g., a patch from a manufacturer of the DPA.

Certificate and key management is provided. A signed certificate corresponding to an enterprise is deployed to a plurality of cryptographic communication protocol endpoint proxies located in a heterogeneous distributed computing environment where a private key corresponding to the enterprise is not placed in any of the plurality of cryptographic communication protocol endpoint proxies. Offload of cryptographic communications from the plurality of cryptographic communication protocol endpoint proxies to the hardware security module is received by the hardware security module where the hardware security module verifies connection authenticity for the plurality of cryptographic communication protocol endpoint proxies across the heterogeneous distributed computing environment using the private key corresponding to the enterprise that remains within a security boundary of the hardware security module.

Embodiments include systems, methods, computer readable media, and devices configured to, for a first processor of a platform, generate a platform root key; create a data structure to encapsulate the platform root key, the data structure comprising a platform provisioning key and an identification of a registration service; and transmit, on a secure connection, the data structure to the registration service to register the platform root key for the first processor of the platform. Embodiments include systems, methods, computer readable media, and devices configured to store a device certificate received from a key generation facility; receive a manifest from a platform, the manifest comprising an identification of a processor associated with the platform; and validate the processor using a stored device certificate.

A computer storage device having a host interface, a controller, non-volatile storage media, and firmware. The firmware instructs the controller to: limit a crypto key to be used in data access requests made in a first namespace allocated on the non-volatile storage media of the computer storage device; store data in the first namespace in an encrypted form that is to be decrypted using the crypto key; free a portion of the non-volatile storage media from the first namespace, the portion storing the data; and make the portion of the non-volatile storage media available in a second namespace without erasing the data stored in the portion of the non-volatile storage media.

Providing revocation status of at least one associated credential includes providing a primary credential that is at least initially independent of the associated credential, binding the at least one associated credential to the primary credential, and deeming the at least one associated credential to be revoked if the primary credential is revoked. Providing revocation status of at least one associated credential may also include deeming the at least one associated credential to be not revoked if the primary credential is not revoked. Binding may be independent of the contents of the credentials and may be independent of whether any of the credentials authenticate any other ones of the credentials. The at least one associated credential may be provided on an integrated circuit card (ICC). The ICC may be part of a mobile phone or a smart card.

A technique for securing on-board bus transactions in a computing device is discussed. A shared key is generated and then programmed into the read-only non-volatile write-once storage of two on-board components. The shared key may be generated during the manufacturing process. Once complete, all transactions between the two on-board components are encrypted by the components using the shared key without exposing the key on any external bus.

The present disclosure relates to highly secure, high speed encryption methodologies suitable for applications such as media streaming, streamed virtual private network (VPN) services, large file transfers and the like. For example, encryption methodologies as described herein can provide stream ciphers for streaming data from, for example, a media service provider to a plurality of users. Certain configurations provide wire speed single use encryption. The methodologies as described herein are suited for use with blockchain (e.g. Bitcoin) technologies.

The present disclosure, in some embodiments, relates to a data protection method comprising: determining a file comprising content data on a computing system; generating index information for the file; transmitting the index information to a cloud system; executing a corruption operation on the file comprising: dividing the content data of the file into a plurality of data chunks; executing a first encryption operation based on an encryption protocol, on the first data chunk; executing a second encryption operation based on the encryption protocol, on the second data chunk; generating or assigning a first name for the first data and a second name for the second data chunk; and generating a key associated with an order of the first data chunk and the second data chunk.

A method for generating a public key for an electronic device is provided, wherein the method comprises generating a public key 103 based on a private key and a unique identifier associated with the electronic device 200.

Aspects of various embodiments are directed to applications utilizing secret keys for authentication and/or encrypted communication. In certain embodiments, authentication data is provided from a source network communication device to a target network communication device that allows a computing server to verify that the key migration has been is authorized by the source network communication device. The authentication data also enables the data provider and the target network communication device to independently determine a temporary key for establishing a secure communication channel between the service provider and the target network communication device and/or determine a new key for the target network communication device. In some implementations, the authentication data may be exchanged between the source and target network communication devices between offline without involvement of the computing server. When the target network communication device later connects to the computing server, the authentication data may be used to verify that the key migration is authorized and/or generate key(s).