Methods, systems, and apparatus for implementing a hexadecimal to quantum computation translation. In one aspect, a method includes obtaining one or more hexadecimal data inputs; applying a quantum computation translation operation to each hexadecimal data input to generate one or more corresponding sequences of quantum computations; implementing the one or more sequences of quantum computations using quantum computing hardware to obtain one or more corresponding sequence of measurement results; and providing the one or more sequences of measurement results as respective representations of the one or more hexadecimal data inputs.

A device may not trust another device with which it is in communication. To establish trust, a first device may send a second device an indication of signed code that is stored in a protected memory of the first device. Based on determining that the first device is a trusted device, the second device may send the first device an encrypted content asset, a decryption key associated with the content asset, and/or an encryption key associated with the content asset.

An example operation may include one or more of storing one or more public keys of one or more policy services, receiving, via a signing service, a blockchain transaction that has content that has been verified by a policy service and includes a signature created by a private key of the policy service, verifying, via a hardware security module (HSM), the signature of the policy service based on a public key of the policy service from among the one or more public keys, and in response to a verification of the signature of the policy service, signing, via the HSM, the blockchain transaction using a wallet key of a user of the blockchain transaction.

Embodiments relate to progressively validating access token. In response to intercepting an initial call for a transaction for a service from a client, a token is validated for the initial call of the transaction for the service, the validating including contacting an authentication sever and locally storing a time to live received for the token. In response to intercepting at least one successive call for the transaction for the service from the client, it is determined that the token for the at least one successive call is valid based on the time to live locally saved. The at least one successive call for the transaction for the service is permitted to pass without contacting the authentication sever.

A method is disclosed. The method includes receiving, by an application on a communication device from an access device, a unique identifier associated with a resource provider in a transaction. The method also includes transmitting, by the application, a message comprising the unique identifier and an access data reference identifier associated with access data to a remote server computer associated with the application. The remote server computer searches a database for access data using the access data reference identifier, retrieves the access data, and provides the access data to a transport computer which processes the transaction using the access data.

Systems, methods, apparatuses, and computer-readable media for secure management of accounts on display devices using a contactless card. An application executing on a display device may receive a request specifying a service provider. The display device may receive a cryptogram generated a contactless card, and transmit the cryptogram to an authentication server. The authentication server may decrypt the cryptogram and generate a virtual account number associated with the contactless card. The authentication server may transmit the virtual account number to the service provider, which may create an account based at least in part on the virtual account number and the decryption of the cryptogram by the authentication server. The display may receive an authentication token generated by the service provider for the account, and access the account created by the service provider based at least in part on the authentication token.

An information handling system may include a processor and a basic input/output system (BIOS) comprising a program of instructions comprising boot firmware configured to be the first code executed by the processor when the information handling system is booted or powered on, the BIOS configured to, during boot of the information handling system: (i) read a predefined measurement of an order of loading of BIOS drivers configured to execute during execution of the BIOS, such predefined measurement made during build of the BIOS; (ii) perform a runtime measurement of an order of loading of the BIOS drivers during actual runtime of the information handling system; (iii) compare the predefined measurement to the runtime measurement; and (iv) responsive to a mismatch between the predefined measurement and the runtime measurement, respond with a remedial action.

A method and system for mitigating a threat associated with network data packets are provided. The method commences with receiving, by an authentication server, a request for access to a server from a client. The method further includes authenticating the client by the authentication server. The authentication includes providing an authentication token to the client. The method continues with receiving, by a mitigation device, from the client, at least one network packet directed to the server. The at least one network packet embeds the authentication token. The method further includes validating, by the mitigation device, authenticity of the authentication token and selectively forwarding, based on the validation, the at least one network packet to the server. The authentication token is independently generated by the authentication server, the mitigation device, and the server using a shared token generation algorithm based on a hash salt value.

Functional data for use in one or more digital transactions are secured by using an encapsulated security token (EST). In certain embodiments, the EST is created by encapsulating digital data including the functional data using at least two cryptographic systems of two parties. The encapsulation and subsequent de-encapsulation can utilize cryptographic systems of the parties that involve a private key for signing and decryption and a public key for encryption and signature verification. If constructed carefully over a series of rigorous events, the resulting EST can be practically impossible to counterfeit. In addition, a propagation of rights can be tracked for auditing and rights can be easily terminated or modified.

Exemplary embodiments may use a contactless card as a secondary form of authentication in a multi-factor authentication for a secure messaging service. The recipient party of a request to initiate a messaging service session (such as a server computing device) may be programmed to use the phone number of the originating device to look up records regarding an identity of a party and their associated phone number as a primary credential and then may require an authentication credential originating from the contactless card as a secondary credential for the initiating party. In some instances, the credential originating from the contactless card is a onetime password that is valid only for a period of time. The recipient party determines whether the onetime password is valid. If both credentials are valid, a secure messaging session may be initiated with the initiating party.