Abstract: Methods and apparatus for synchronizing data transfers across clock domains for using heads-up indications. An integrated circuit includes a first-in first-out buffer (FIFO); a memory controller configured to operate in a first clock domain and coupled to the FIFO, the first clock domain associated with a first clock signal; a data fabric configured to operate in a second clock domain and coupled to the FIFO, the second clock domain associated with a second clock signal, a second frequency of the second clock signal being different from a first frequency of the first clock signal; and a controller coupled to the FIFO. In some instances, the controller determines a phase relationship between the first clock signal and the second clock signal; monitors one or more first clock edges of the first clock signal and one or more second clock edges of the second clock signal; and sends a first heads-up signal to the memory controller.

Abstract: A system and method for efficient power management of an integrated circuit are described. In various implementations, a computing system includes an integrated circuit, multiple voltage regulators, and circuitry that detects when current drawn from a power rail from one of the multiple voltage regulators exceeds a limit. Upon detection, a single global alarm signal is asserted and conveyed to the integrate circuit. The integrated circuit includes at least a first group of functional blocks sharing a first power rail and a second group of functional blocks sharing a second power rail. When the global alarm signal is asserted, the functional blocks of the first group and the second group perform steps to immediately reduce power consumption. In order to maintain performance and satisfy a quality of service (QoS) parameter, a power management controller of the integrated circuit reassigns power limits shortly thereafter.

Abstract: A handshake mechanism allows die discovery in a stacked die architecture that keeps inputs isolated until the handshake is complete. Power good indications are used as handshake signals between the die. A die keeps inputs isolated from above until a power good indication from the die above indicates presence of the die above. The die keeps inputs isolated from below until the die detects power is good and receives a power good indication from the die and the die below. In an implementation drivers and receivers, apart from configuration bus drivers and receivers are disabled until a fuse distribution done signal indicates that repairs have been completed. Drivers are then enabled and after a delay to ensure signals are driven, receivers are deisolated. A top die in the die stack never sees a power good indication from a die above and therefore keeps inputs from above isolated. That allows the height of the die stack to be unknown at power on.

Abstract: A method and apparatus for synchronizing a time stamp counter (TSC) associated with a processor core in a computer system includes initializing the TSC associated with the processor core by synchronizing the TSC associated with the processor core with at least one other TSC in a hierarchy of TSCs. One or more processor cores are powered down. Upon powering up of the one or more processor cores, the TSC associated with the processor core is synchronized with the at least one other TSC in the hierarchy of TSCs.

Abstract: Systems, apparatuses, and methods for reducing chiplet interrupt latency are disclosed. A system includes one or more processing nodes, one or more memory devices, a communication fabric coupled to the processing unit(s) and memory device(s) via link interfaces, and a power management unit. The power management unit manages the power states of the various components and the link interfaces of the system. If the power management unit detects a request to wake up a given component, and the link interface to the given component is powered down, then the power management unit sends an out-of-band signal to wake up the given component in parallel with powering up the link interface. Also, when multiple link interfaces need to be powered up, the power management unit powers up the multiple link interfaces in an order which complies with voltage regulator load-step requirements while minimizing the latency of pending operations.

Abstract: A method and apparatus for synchronizing a time stamp counter (TSC) associated with a processor core in a computer system includes initializing the TSC associated with the processor core by synchronizing the TSC associated with the processor core with at least one other TSC in a hierarchy of TSCs. One or more processor cores are powered down. Upon powering up of the one or more processor cores, the TSC associated with the processor core is synchronized with the at least one other TSC in the hierarchy of TSCs.

Abstract: Systems, apparatuses, and methods for reducing chiplet interrupt latency are disclosed. A system includes one or more processing nodes, one or more memory devices, a communication fabric coupled to the processing unit(s) and memory device(s) via link interfaces, and a power management unit. The power management unit manages the power states of the various components and the link interfaces of the system. If the power management unit detects a request to wake up a given component, and the link interface to the given component is powered down, then the power management unit sends an out-of-band signal to wake up the given component in parallel with powering up the link interface. Also, when multiple link interfaces need to be powered up, the power management unit powers up the multiple link interfaces in an order which complies with voltage regulator load-step requirements while minimizing the latency of pending operations.

Abstract: A handshake mechanism allows die discovery in a stacked die architecture that keeps inputs isolated until the handshake is complete. Power good indications are used as handshake signals between the die. A die keeps inputs isolated from above until a power good indication from the die above indicates presence of the die above. The die keeps inputs isolated from below until the die detects power is good and receives a power good indication from the die and the die below. In an implementation drivers and receivers, apart from configuration bus drivers and receivers are disabled until a fuse distribution done signal indicates that repairs have been completed. Drivers are then enabled and after a delay to ensure signals are driven, receivers are deisolated. A top die in the die stack never sees a power good indication from a die above and therefore keeps inputs from above isolated. That allows the height of the die stack to be unknown at power on.

Abstract: Systems, apparatuses, and methods for reducing chiplet interrupt latency are disclosed. A system includes one or more processing nodes, one or more memory devices, a communication fabric coupled to the processing unit(s) and memory device(s) via link interfaces, and a power management unit. The power management unit manages the power states of the various components and the link interfaces of the system. If the power management unit detects a request to wake up a given component, and the link interface to the given component is powered down, then the power management unit sends an out-of-band signal to wake up the given component in parallel with powering up the link interface. Also, when multiple link interfaces need to be powered up, the power management unit powers up the multiple link interfaces in an order which complies with voltage regulator load-step requirements while minimizing the latency of pending operations.

Abstract: A method and apparatus for performing a bus lock and a translation lookaside buffer invalidate transaction includes receiving, by a lock master, a lock request from a first processor in a system. The lock master sends a quiesce request to all processors in the system, and upon receipt of the quiesce request from the lock master, all processors cease issuing any new transactions and issue a quiesce granted transaction. Upon receipt of the quiesce granted transactions from all processors, the lock master issues a lock granted message that includes an identifier of the first processor. The first processor performs an atomic transaction sequence and sends a first lock release message to the lock master upon completion of the atomic transaction sequence. The lock master sends a second lock release message to all processors upon receiving the first lock release message from the first processor.

Abstract: A method and apparatus for performing a bus lock and a translation lookaside buffer invalidate transaction includes receiving, by a lock master, a lock request from a first processor in a system. The lock master sends a quiesce request to all processors in the system, and upon receipt of the quiesce request from the lock master, all processors cease issuing any new transactions and issue a quiesce granted transaction. Upon receipt of the quiesce granted transactions from all processors, the lock master issues a lock granted message that includes an identifier of the first processor. The first processor performs an atomic transaction sequence and sends a first lock release message to the lock master upon completion of the atomic transaction sequence. The lock master sends a second lock release message to all processors upon receiving the first lock release message from the first processor.

Abstract: An interface apparatus provides a connection between a host having an IEEE 1394 input/output port and a mass storage device having an ATA input/output port. A receive FIFO and a transmit FIFO within the interface apparatus operates to store small-size packets, or operates to store the buffer address of large-size packets, as the small and large size packets are respectively received from the host or transmitted to the host. In both the host receive and host transmit modes of operation of the interface apparatus, the small-size packets are found in the receive FIFO or the transmit FIFO, whereas the data content of large-size packets is stored in the buffer as the corresponding buffer address is stored in the receive FIFO or the transmit FIFO.

Abstract: A clock divider circuit and methods of operating same includes a standard integral clock divider circuit and a phase slip non-integral divider circuit for high granularity non-integral clock division. A multi-phase frequency synthesizer produces a plurality of phases of a clock frequency and applies the multiple phases to the divider circuit of the present invention. In a first embodiment, each phase is applied to a phase slip divider circuit which includes a integral divider portion and a programmable phase slip divider portion which receives the output of the integral division portion. Each phase of the input clock may therefore be divided by a wide variety of integral and non-integral divisors. In a second, simpler embodiment, a multi-phase frequency synthesizer produces a plurality of phases and applies the phases to a single phase slip divider.

Abstract: In a storage target device controller capable of managing multiple command contexts, methods and associated apparatus are provided for automatically managing the plurality of contexts using a state machine model. The state machine model is operable on a target device controller having an active context register set for processing of the presently active transfer on the host channel and an inactive context register set for storing an inactive context. The active context register set and inactive context register set are rapidly and automatically swapped by operation of the state machine model to resume or start processing of an inactive context. Additional inactive contexts are stored in a buffer memory associated with the target device controller. The inactive context register set is automatically stored into a selected one of the additional inactive contexts or loaded from a selected one of the additional inactive contexts by operation of the state machine model of the present invention.

Abstract: In a storage target device controller capable of managing multiple command contexts, methods and associated apparatus are provided for enabling simultaneous, independent operation of the disk channel and the host channel. In a multi-context target device controller, an active context initiates a requested exchange of data blocks between the host channel and the disk channel of the target device. The controller may swap the active context with an inactive context to better utilize resources of the target device such as the host channel bandwidth. The present invention provides for continued independent operation of the host channel and the disk channel. Counters associated with the active context are only updated by operation of the disk channel if the active context is the initiating context of the disk operations.

Abstract: Apparatus, and an associated method, for generating multi-bit sequences used, for instance, to form an address pointer or a data pointer of a computer system. The circuitry is embodied in a single-cycle path and is operable to generate an output sequence which is of a bit length which is a multiple of an input sequence. In one implementation, the circuitry is used to generate 48-bit address pointers and 16-bit data pointers.

Abstract: A method and system for converting computer peripheral equipment to SCSI-compliant devices includes an interface controller which converts a mass storage device communicating on an ATA interface to a target device communicating in SCSI commands across an IEEE-1394 interface. The controller converts SCSI commands in CDBs in the IEEE-1394 ORBs to ATA ORBs and then directly to ATA/ATAPI commands, through a mapping function.

Abstract: A storage target device controller (such as an embedded controller in a SCSI disk drive) processes multiple commands concurrently in accordance with the methods and structures of the present invention. Each command is stored within its own context within the target device controller to retain all unique parameters required for the processing of each command. Processing of multiple commands permits switching of command contexts within the target device to improve utilization of resources associated with the target device. For example, when a first, active, command context is prevented from further processing due to the status of the disk channel, an inactive command context may be swapped with the active command context to better utilize the host channel communication bandwidth. Similarly, a first active command context may be configured to automatically switch to a linked command context upon completion of processing to further ease management of multiple contexts.

Abstract: A method and apparatus for writing data to a storage device such as a hard disk drive in which two write commands from an initiator are processed as a single command at the storage device. A first request is received from a small computer systems interface (SCSI) bus to write a first set of data to a storage device. The first set of data is transferred to memory for temporary storage prior to transfer to the storage device. Thereafter, a second write request is received to write a second set of data to the storage device in which the write request includes a logical block address. An ending logical block address determined after transferring the first set of data is compared to the logical block address of the second request to determine whether the second set of data can be written to the storage device along with the first set of data as a single write operation based on the comparison of the logical block address of the second request and the ending logical block address.