Packet routing within a multi-chip processing system is shown. A first chip has a first interconnect bus, and a first microprocessor coupled to the first interconnect bus. The first interconnect bus has a first routing register. When the first microprocessor operates the first chip as a source node to output a packet to be transferred to a destination node, routing information indicating a routing path from the source node to the destination node is written into the first routing register and then loaded from the first routing register to a header of the packet. While being transferred within the multi-chip processing system from the source node to the destination node, the packet is guided along the routing path indicated in the routing information carried in the header of the packet.

A self-optimizing System-on-Chip (SOC) includes multiple cores, multiple hardware accelerators, multiple memories and an interconnect framework. The SOC also includes a machine learning (ML) module that uses data flow information to build a ML network dynamically and configures all the various hardware blocks autonomously, to achieve predetermined application performance targets. The SOC is able to recover from hangs caused when testing various configuration settings. The SOC also avoids configuration settings that cause severe drops in performance.

This disclosure describes system on a chip (SOC) communications that prevent direct memory access (DMA) attacks. An example SoC includes an encryption engine and a security processor. The encryption engine is configured to encrypt raw input data using a cipher key to form an encrypted payload. The security processor is configured to select the cipher key from a key store holding a plurality of cipher keys based on a channel ID describing a {source subsystem, destination subsystem} tuple for the encrypted payload, to form an encryption header that includes the channel ID, to encapsulate the encrypted payload with the encryption header that includes the channel ID to form a crypto packet, and to transmit the crypto packet to a destination SoC that is external to the SoC.

There is provided a semiconductor apparatus including a memory operation terminal group that includes a plurality of memory operation terminals; an inspection terminal group that includes a plurality of inspection terminals; a constant voltage terminal group that includes a plurality of constant voltage terminals; a drive terminal group that includes a plurality of drive terminals, the inspection terminal group, and the constant voltage terminal group, and of which voltage values change in accordance with an operation of a CPU; and a terminal mounting surface, in which at the terminal mounting surface, the inspection terminal group and the constant voltage terminal group are located to separate the memory operation terminal group and the drive terminal group, and the memory operation terminal group is located not to be adjacent to a terminal which is not included in the inspection terminal group and the constant voltage terminal group.

Disclosed is a data transfer system capable of accelerating data transmission between two chips. The data transfer system includes: a master system-on-a-chip (SoC) including a master transmission circular buffer and a master reception circular buffer; and a slave SoC including a slave reception circular buffer and a slave transmission circular buffer. The slave/master reception circular buffer is a duplicate of the master/slave transmission circular buffer; accordingly, the write pointers of the two corresponding buffers are substantially synchronous and the read pointers of the two corresponding buffers are substantially synchronous as well. In light of the above, the read and write operations of the master/slave transmission circular buffer can be treated as the read and write operations of the slave/master reception circular buffer; therefore some conventional data reproducing procedure(s) for the data transmission can be omitted and the data transmission is accelerated.

Throttling recommendations for a systolic array may be arbitrated. Throttling recommendations may be received at an arbiter for a systolic array from different sources, such as one or more monitors implemented in an integrated circuit along with the systolic array or sources external to the integrated circuit with the systolic array. A strongest throttling recommendation may be selected. The rate at which data enters the systolic array may be modified according to the strongest throttling recommendation.

A system on chip includes a monitoring circuit that detects an anomalous behavior of the system on chip. The monitoring circuit compares a behavior of the system on chip to at least one reference parameter representing the anomalous behavior of the system. Using this comparison, the anomalous behavior of the system on chip is detected. An interrupt is the issued in response to the detected anomalous behavior of the system on chip.

In one embodiment, an apparatus includes: a first trace source to generate a plurality of first trace messages and a first local platform description identifier to identify the first trace source; a second trace source to generate a plurality of second trace messages and a second local platform description identifier to identify the second trace source; and a trace aggregator coupled to the first and the second trace sources, the trace aggregator to generate a global platform description identifier for the apparatus and output a trace stream including the global platform destination identifier, the first and second local platform description identifiers, the plurality of first trace messages and the plurality of second trace messages. Other embodiments are described and claimed.

Devices, methods, and systems for secure communications on a computing device. A host operating system (OS) runs on a host processor in communication with a host memory. A secure OS runs on a coprocessor in communication with a secure memory. The coprocessor receives information from an external device over a secure peer-to-peer (P2P) connection. The secure P2P connection is managed by the secure OS and is not accessible by the host OS.

The present disclosure presents an exemplary tier-based reconfigurable security architecture that can adapt to different use-case scenarios by selecting security tiers and configure parameters in each security tier based on system requirements. An exemplary system comprises a security agent that is configured to monitor system characteristics of embedded components on a system-on-chip and communicate a status of the system characteristics to a reconfigurable service engine integrated on the system-on-chip, such that the reconfigurable service engine is configured to activate one of a plurality of tiers of security based at least upon the status of the system characteristics communicated.