Abstract: Methods and apparatus for scalable MCTP infrastructure. A system is split into independent MCTP domains, wherein each MCTP domain uses Endpoint Identifiers (EIDs) for endpoint devices within the MCTP domain in a manner similar to conventional MCTP operations. A new class of MCTP devices (referred to as a Domain Controllers) is provided to enable inter-domain communication and communication with global devices. Global traffic originators or receivers like a BMC (Baseboard Management Controller), Infrastructure Processing Unit (IPU), Smart NIC (Network Interface Card), Debugger, or PROT (Platform Root or Trust) discover and establish two-way communication through the Domain Controllers to any of the devices in the target domain(s). The Domain Controllers are configured to implement tunneled connections between global devices and domain endpoint devices.

Abstract: Systems, apparatuses and methods may provide for technology that detects a successful boot of a first firmware component in a computing system, receives a signal from a second firmware component in the computing system, and detects an incompatibility of the first firmware component with respect to the second firmware component based on the signal. In one example, only the first firmware component is repaired in response to the incompatibility.

Abstract: Methods and apparatus for scalable MCTP infrastructure. A system is split into independent MCTP domains, wherein each MCTP domain uses Endpoint Identifiers (EIDs) for endpoint devices within the MCTP domain in a manner similar to conventional MCTP operations. A new class of MCTP devices (referred to as a Domain Controllers) is provided to enable inter-domain communication and communication with global devices. Global traffic originators or receivers like a BMC (Baseboard Management Controller), Infrastructure Processing Unit (IPU), Smart NIC (Network Interface Card), Debugger, or PROT (Platform Root or Trust) discover and establish two-way communication through the Domain Controllers to any of the devices in the target domain(s). The Domain Controllers are configured to implement tunneled connections between global devices and domain endpoint devices.

Abstract: Examples described herein relate to circuitry that is to manage communications to and from a manageability controller. In some examples, during communications on a first port, circuitry generates a bus busy condition for one or more other ports to block transactions from one or more devices.

Abstract: In one embodiment, an apparatus includes: a peer-to-peer (P2P) control circuit to issue a P2P communication request to a bus master of a multi-drop interconnect to request authorization to send a P2P transaction to at least one slave device coupled to the multi-drop interconnect; a transmitter to transmit the P2P transaction to the at least one slave device when the bus master grants the authorization for the P2P transaction; and another transmitter to output the clock signal to the multi-drop interconnect during the P2P transaction. Other embodiments are described and claimed.

Abstract: Systems, apparatuses and methods may provide for technology that detects a successful boot of a first firmware component in a computing system, receives a signal from a second firmware component in the computing system, and detects an incompatibility of the first firmware component with respect to the second firmware component based on the signal. In one example, only the first firmware component is repaired in response to the incompatibility.

Abstract: An apparatus may include a controller for a system management bus. The controller may be to: detect a trigger event associated with the system management bus; in response to a detection of the trigger event, transmit a broadcast address on the system management bus, where the broadcast address is not used in a first communication protocol; and in response to a determination that the transmitted broadcast address was acknowledged, use a second communication protocol for transmissions on the system management bus. Other embodiments are described and claimed.

Abstract: Systems, apparatuses and methods may provide for technology that detects a successful boot of a first firmware component in a computing system, receives a signal from a second firmware component in the computing system, and detects an incompatibility of the first firmware component with respect to the second firmware component based on the signal. In one example, only the first firmware component is repaired in response to the incompatibility.

Abstract: Embodiments of the present disclosure may relate to apparatus, process, or techniques in a I3C protocol environment that include identifying a pending read notification message by a slave device to be sent to a master device to indicate that the data is available to be read by the master device from a buffer associated with the slave device. The pending read notification may be subsequently transmitted to the master device. Subsequently, until the data in the buffer has been read by the master device, the slave device may wait an identified amount of time that is less than a value of a timeout of the master device, and retransmit the pending read notification message to the master device. Other embodiments may be described and/or claimed.

Abstract: In one embodiment, an apparatus includes: a peer-to-peer (P2P) control circuit to issue a P2P communication request to a bus master of a multi-drop interconnect to request authorization to send a P2P transaction to at least one slave device coupled to the multi-drop interconnect; a transmitter to transmit the P2P transaction to the at least one slave device when the bus master grants the authorization for the P2P transaction; and another transmitter to output the clock signal to the multi-drop interconnect during the P2P transaction. Other embodiments are described and claimed.

Abstract: Systems, apparatuses and methods may provide for technology that detects a successful boot of a first firmware component in a computing system, receives a signal from a second firmware component in the computing system, and detects an incompatibility of the first firmware component with respect to the second firmware component based on the signal. In one example, only the first firmware component is repaired in response to the incompatibility.

Abstract: Technologies for providing manageability redundancy for micro server and clustered System-on-a-Chip (SoC) deployments are presented. A configurable multi-processor apparatus may include multiple integrated circuit (IC) blocks where each IC block includes a task block to perform one or more assignable task functions and a management block to perform management functions with respect to the corresponding IC block. Each task block and each management block may include one or more instruction processors and corresponding memory. Each IC block may be controllable to perform a function of one or more other IC blocks. The IC blocks may communicate with each other via a management communication infrastructure that may include a communication path from each of the management blocks to each of the other management blocks. Via the management communication infrastructure, the management blocks may bridge communication paths between pairs of management blocks.

Abstract: An apparatus and system for throttling I/O devices in a computer system is provided. In an example, a method for throttling device power demand during critical power events. The method includes detecting a critical power event and issuing a signal to system devices to defer optional transactions during the critical power event.

Abstract: Technologies for facilitating inter-system-on-a-chip (SoC) communication include a first SoC, a second SoC, and a dedicated manageability controller network. The first SoC includes a first main processor, a first manageability controller, and a memory dedicated to the first manageability controller and having manageability controller firmware stored thereon. The first manageability controller is different from the first main processor and to control functions of the first SoC. The second SoC is different from the first SoC and includes a second main processor and a second manageability control, which is different from the second main processor and to control functions of the second SoC. The second SoC is to access the manageability controller firmware of the memory of the first SoC over the dedicated manageability network.

Abstract: Technologies for providing manageability redundancy for micro server and clustered System-on-a-Chip (SoC) deployments are presented. A configurable multi-processor apparatus may include multiple integrated circuit (IC) blocks where each IC block includes a task block to perform one or more assignable task functions and a management block to perform management functions with respect to the corresponding IC block. Each task block and each management block may include one or more instruction processors and corresponding memory. Each IC block may be controllable to perform a function of one or more other IC blocks. The IC blocks may communicate with each other via a management communication infrastructure that may include a communication path from each of the management blocks to each of the other management blocks. Via the management communication infrastructure, the management blocks may bridge communication paths between pairs of management blocks.

Abstract: Technologies for facilitating inter-system-on-a-chip (SoC) communication include a first SoC, a second SoC, and a dedicated manageability controller network. The first SoC includes a first main processor, a first manageability controller, and a memory dedicated to the first manageability controller and having manageability controller firmware stored thereon. The first manageability controller is different from the first main processor and to control functions of the first SoC. The second SoC is different from the first SoC and includes a second main processor and a second manageability control, which is different from the second main processor and to control functions of the second SoC. The second SoC is to access the manageability controller firmware of the memory of the first SoC over the dedicated manageability network.

Abstract: Technologies for providing manageability redundancy for micro server and clustered System-on-a-Chip (SoC) deployments are presented. A configurable multi-processor apparatus may include multiple integrated circuit (IC) blocks where each IC block includes a task block to perform one or more assignable task functions and a management block to perform management functions with respect to the corresponding IC block. Each task block and each management block may include one or more instruction processors and corresponding memory. Each IC block may be controllable to perform a function of one or more other IC blocks. The IC blocks may communicate with each other via a management communication infrastructure that may include a communication path from each of the management blocks to each of the other management blocks. Via the management communication infrastructure, the management blocks may bridge communication paths between pairs of management blocks.

Abstract: An apparatus and system for throttling I/O devices in a computer system is provided. In an example, a method for throttling device power demand during critical power events. The method includes detecting a critical power event and issuing a signal to system devices to defer optional transactions during the critical power event.

Abstract: Technologies for providing manageability redundancy for micro server and clustered System-on-a-Chip (SoC) deployments are presented. A configurable multi-processor apparatus may include multiple integrated circuit (IC) blocks where each IC block includes a task block to perform one or more assignable task functions and a management block to perform management functions with respect to the corresponding IC block. Each task block and each management block may include one or more instruction processors and corresponding memory. Each IC block may be controllable to perform a function of one or more other IC blocks. The IC blocks may communicate with each other via a management communication infrastructure that may include a communication path from each of the management blocks to each of the other management blocks. Via the management communication infrastructure, the management blocks may bridge communication paths between pairs of management blocks.