Aspects include obtaining data to be transformed. A selected transformation to be applied to the data is determined based on a storage block address list entry (SBALE) in a storage block address list (SBAL). The SBALE includes at least one field that is used in determining the selected transformation to be applied. The selected transformation is applied on the data to generate transformed data and the transformed data is placed in a location specified by the SBAL.

A method and apparatus for scrambling and descrambling data in a computer system includes transmitting non-scrambled data from a first high speed inter chip (IP) link circuit located on a first chip to a first serializer/deserializer (SERDES) physical (PHY) circuit located on the first chip, the first high speed link IP indicating the data is not scrambled. The received non-scrambled data is scrambled by the first SERDES PHY circuit and transmitted to a second chip. The received scrambled data is descrambled by a second SERDES PHY circuit located on the second chip. The non-scrambled data is transmitted by the second SERDES PHY circuit to a second high speed link IP circuit located on the second chip to a third circuit for further processing or transmission.

Isochronous channels may be used for transporting non-isochronous data between components in an electronic device, such as when non-isochronous data is aggregated from multiple non-isochronous data streams to achieve a high peak-to-average bandwidth. The aggregated non-isochronous data sources may include data streams from general-purpose communications interfaces for interconnecting components or sub-systems of components within an electronic device. For example, I2C networks for control and programming of components may be connected to other I2C networks through an isochronous channel, such as a differential pair of Soundwire SWI3S wires.

The present invention relates to a computing device for executing a first cryptographic operation of a cryptographic process on useful input data, said computing device comprising a first processor, a second processor and a selection circuit wherein: —said selection circuit is configured: —for receiving, from an input bus, expanded input data obtained by interleaving dummy input data with said useful input data, —for determining positions of the dummy input data in said expanded input data, —and for extracting said dummy input data and said useful input data from the expanded input data based on said determined positions, —said first processor is configured for executing said first cryptographic operation of said cryptographic process on said extracted useful input data to obtain useful output data, —said second processor is configured for executing a second operation on said extracted dummy input data to obtain dummy output data, said computing device being configured for having said operations executed such that leakage generated by said first cryptographic operation is jammed by leakage generated by the second operation.

A system has an unmatched communication architecture for a unidirectional command bus and compensates for drift on the command bus based on data provided on a bidirectional data bus. The memory device has an oscillator to measure drift or an amount of delay for the command bus over a time interval. The memory device can return a value over the data bus to the memory controller based on the delay measured with the oscillator. Based on receiving the value, the memory controller can adjust configuration settings for communication on the command bus.

Packets may be compressed based on predictive analyses. For example, in one embodiment, it is determined that an explicit value for a particular header field can be inferred by the receiver agent, a packet header is constructed that either omits the header field or includes a differential value for the header field in lieu of the explicit value for the header field. The packet header may be decompressed upon receipt by deriving the explicit value for the particular header field.

Aspects include obtaining data to be transformed. A selected transformation to be applied to the data is determined based on a storage block address list entry (SBALE) in a storage block address list (SBAL). The SBALE includes at least one field that is used in determining the selected transformation to be applied. The selected transformation is applied on the data to generate transformed data and the transformed data is placed in a location specified by the SBAL.

Embodiments herein describe on-demand packetization where data that is too large to be converted directly into data words (DWs) for a chip-to-chip (C2C) interface are packetized instead. When identifying a protocol word that is larger than the DW of the C2C interface, a protocol layer can perform packetization where a plurality of protocol words are packetized and sent as a transfer. In one embodiment, the protocol layer removes some or all of the control data or signals in the protocol words so that the protocol words no longer exceed the size of the DW. These shortened protocol words can then be mapped to DWs and transmitted as separate packets on the C2C. The protocol layer can then collect the portion of the control data that was removed from the protocol words and transmit this data as a separate packet on the C2C interface.

A method for supporting TCM communication by a BIOS of an ARM server, including: setting an access mode of a LPC bus device to a 4-byte mode by means of a BIOS of an ARM server; causing the BIOS to perform data communication with a TCM chip of the LPC bus device in the 4-byte mode; in response to the BIOS reading a register by means of the LPC bus device, determining a type of the register; in response to determining that the type of the register is a specific FIFO register, changing a control register from the 4-byte mode to a single-byte mode, and performing single-byte read-write on the specific FIFO register; and in response to completion of read-write of the specific FIFO register, changing the control register to the 4-byte mode by means of the BIOS, and performing a read-write operation on other FIFO registers.

Embodiments herein describe on-demand packetization where data that is too large to be converted directly into data words (DWs) for a chip-to-chip (C2C) interface are packetized instead. When identifying a protocol word that is larger than the DW of the C2C interface, a protocol layer can perform packetization where a plurality of protocol words are packetized and sent as a transfer. In one embodiment, the protocol layer removes some or all of the control data or signals in the protocol words so that the protocol words no longer exceed the size of the DW. These shortened protocol words can then be mapped to DWs and transmitted as separate packets on the C2C. The protocol layer can then collect the portion of the control data that was removed from the protocol words and transmit this data as a separate packet on the C2C interface.