Abstract: Hardware assisted high speed serial (HSS) transceiver testing including receiving, by a link layer hardware state machine on a HSS transmitting device, an instruction to generate a test pattern, wherein the test pattern comprises a sequence of data units; loading, by the link layer hardware state machine, each unique data unit into embedded random access memory (RAM); generating, by the link layer hardware state machine, the test pattern comprising the sequence of data units using the unique data units stored in the embedded RAM, wherein at least one of the unique data units is repeated in the sequence of data units of the test pattern; and sending, by the link layer hardware state machine, the generated test pattern to an input of a HSS transceiver.

Abstract: Hardware error detection on a high-speed serial (HSS) connection including tracking, by a hardware state machine on a HSS receiver, errors in a data stream, wherein tracking, by the hardware state machine, the errors in the data stream comprises, for each sample of incoming data: inspecting, by the hardware state machine, a detected error indicator in a test control register to determine whether an error has been detected in the sample; incrementing, by the hardware state machine, an error count in a hardware error counter if the test control register indicates an error has been detected in the sample; clearing, by the hardware state machine, the detected error indicator if the test control register indicates an error has been detected in the sample; and incrementing, by the hardware state machine, a sample count in a sample count register.

Abstract: Hardware assisted high speed serial (HSS) transceiver testing including receiving, by a link layer hardware state machine on a HSS transmitting device, an instruction to generate a test pattern, wherein the test pattern comprises a sequence of data units; loading, by the link layer hardware state machine, each unique data unit into embedded random access memory (RAM); generating, by the link layer hardware state machine, the test pattern comprising the sequence of data units using the unique data units stored in the embedded RAM, wherein at least one of the unique data units is repeated in the sequence of data units of the test pattern; and sending, by the link layer hardware state machine, the generated test pattern to an input of a HSS transceiver.

Abstract: Hardware error detection on a high-speed serial (HSS) connection including tracking, by a hardware state machine on a HSS receiver, errors in a data stream, wherein tracking, by the hardware state machine, the errors in the data stream comprises, for each sample of incoming data: inspecting, by the hardware state machine, a detected error indicator in a test control register to determine whether an error has been detected in the sample; incrementing, by the hardware state machine, an error count in a hardware error counter if the test control register indicates an error has been detected in the sample; clearing, by the hardware state machine, the detected error indicator if the test control register indicates an error has been detected in the sample; and incrementing, by the hardware state machine, a sample count in a sample count register.

Abstract: An interface receives a command corresponding to a non-volatile memory. The interface determines whether a bypass mode is enabled and whether the command is a medium-access command. A primary processing node processes the command in response to determining at least one of the following: that the bypass mode is disabled or that the command is not a medium-access command. A secondary processing node processes the command, in response to determining that the bypass mode is enabled and that the command is a medium-access command.

Abstract: An interface receives a command corresponding to a non-volatile memory. The interface determines whether a bypass mode is enabled and whether the command is a medium-access command. A primary processing node processes the command in response to determining at least one of the following: that the bypass mode is disabled or that the command is not a medium-access command. A secondary processing node processes the command, in response to determining that the bypass mode is enabled and that the command is a medium-access command.

Abstract: A method and controller for implementing storage adapter performance optimization with parity update footprint mirroring between dual adapters minimizing firmware operations, and a design structure on which the subject controller circuit resides are provided. Each of a first controller and a second controller includes a plurality of hardware engines, a control store configured to store parity update footprint (PUFP) data; a data store; and a nonvolatile random access memory (NVRAM). One controller operates in a first initiator mode for transferring PUFP data to the other controller operating in a target mode. Respective initiator hardware engines transfers PUFP data from the initiator control store, selectively updating PUFP data, and writing PUFP data to the initiator data store and to the initiator NVRAM, and simultaneously transmitting PUFP data to the other controller. Respective target hardware engines write PUFP data to the target data store and the target NVRAM, eliminating firmware operations.

Abstract: A method and controller for implementing storage adapter performance optimization with cache data and cache directory mirroring between dual adapters minimizing firmware operations, and a design structure on which the subject controller circuit resides are provided. One of the first controller or the second controller operates in a first initiator mode includes firmware to set up an initiator write operation building a data frame for transferring data and a respective cache line (CL) for each page index to the other controller operating in a second target mode. Respective initiator hardware engines transfers data, reading CLs from an initiator control store, and writing updated CLs to an initiator data store, and simultaneously sends data and updated CLs to the other controller. Respective target hardware engines write data and updated CLs to the target data store, eliminating firmware operations of the controller operating in the second target mode.

Abstract: A method and controller for implementing storage adapter performance optimization with enhanced resource pool allocation, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; a processor, and a plurality of resource pools. A plurality of work queues is associated with the resource pools. The processor initializes a list of types, and the associated amount of pages for each allocate type. The hardware engines maintain a count of allocate types, specifying a type on each allocation and deallocation, and performing allocation from the resource pools for deadlock avoidance.

Abstract: A method and controller for implementing storage adapter performance optimization with a predefined chain of hardware operations configured to minimize hardware and firmware interactions and a bridge code configured to select a firmware sequence for error recovery to complete the operations responsive to an identified error in the predefined chain, and a design structure on which the subject controller circuit resides are provided. A selected predefined chain is configured to implement a particular performance path to maximize performance. Responsive to an identified predefined error during hardware operations in the predefined hardware chain, a bridge code is configured to select a non-performance path firmware sequence for error recovery completion of remaining operations.

Abstract: A method and controller for implementing storage adapter performance optimization with chained hardware operations minimizing hardware and firmware interactions, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; and one or more processors. An event queue is coupled to at least one processor notifying the processor of a plurality of predefined events. A control block is designed to control an operation in one of the plurality of hardware engines including the hardware engine writing an event queue entry. A plurality of the control blocks are selectively arranged in a predefined chain to minimize the hardware engine writing event queue entries to the processor.

Abstract: A method and controller for implementing storage adapter performance optimization with chained hardware operations and an enhanced hardware (HW) and firmware (FW) interface minimizing hardware and firmware interactions, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; and a processor. A data store is configured to store a plurality of control blocks. A global work queue includes a plurality of the control blocks selectively arranged in a predefined chain to define sequences of hardware operations. The global work queue includes a queue input coupled to the processor and the hardware engines and an output coupled to the hardware engines. The control blocks are arranged in respective engine work queues designed to control hardware operations of the respective hardware engines and respective control blocks are arranged in an event queue to provide completion results to the processor.

Abstract: A method and controller for implementing storage adapter performance optimization with automatic chained hardware operations eliminating firmware operations, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines and a control store configured to store a plurality of control blocks. Each control block is designed to control a hardware operation in one of the plurality of hardware engines. A plurality of the control blocks is selectively arranged in a respective predefined chain to define sequences of hardware operations. An automatic hardware structure is configured to build the respective predefined chain controlling the hardware operations for a predefined hardware function. The predefined hardware function includes buffer allocation and automatic DMA data from a host system to the controller for write operations, eliminating firmware operations.

Abstract: A method and controller for implementing storage adapter performance optimization with a predefined chain of hardware operations configured to implement a particular performance path minimizing hardware and firmware interactions, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; and a data store configured to store a plurality of control blocks selectively arranged in one of a plurality of predefined chains. Each predefined chain defines a sequence of operations. Each control block is designed to control a hardware operation in one of the plurality of hardware engines. A resource handle structure is configured to select a predefined chain based upon a particular characteristic of the system. Each predefined chain is configured to implement a particular performance path to maximize performance.

Abstract: A method and controller for implementing storage adapter performance optimization with chained hardware operations minimizing hardware and firmware interactions, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; and one or more processors. An event queue is coupled to at least one processor notifying the processor of a plurality of predefined events. A control block is designed to control an operation in one of the plurality of hardware engines including the hardware engine writing an event queue entry. A plurality of the control blocks are selectively arranged in a predefined chain to minimize the hardware engine writing event queue entries to the processor.

Abstract: A method and controller for implementing storage adapter performance optimization with chained hardware operations and an enhanced hardware (HW) and firmware (FW) interface minimizing hardware and firmware interactions, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; and a processor. A data store is configured to store a plurality of control blocks. A global work queue includes a plurality of the control blocks selectively arranged in a predefined chain to define sequences of hardware operations. The global work queue includes a queue input coupled to the processor and the hardware engines and an output coupled to the hardware engines. The control blocks are arranged in respective engine work queues designed to control hardware operations of the respective hardware engines and respective control blocks are arranged in an event queue to provide completion results to the processor.

Abstract: A method and controller for implementing storage adapter performance optimization with enhanced resource pool allocation, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines; a processor, and a plurality of resource pools. A plurality of work queues is associated with the resource pools. The processor initializes a list of types, and the associated amount of pages for each allocate type. The hardware engines maintain a count of allocate types, specifying a type on each allocation and deallocation, and performing allocation from the resource pools for deadlock avoidance.

Abstract: A method and controller for implementing storage adapter performance optimization with a predefined chain of hardware operations configured to minimize hardware and firmware interactions and a bridge code configured to select a firmware sequence for error recovery to complete the operations responsive to an identified error in the predefined chain, and a design structure on which the subject controller circuit resides are provided. A selected predefined chain is configured to implement a particular performance path to maximize performance. Responsive to an identified predefined error during hardware operations in the predefined hardware chain, a bridge code is configured to select a non-performance path firmware sequence for error recovery completion of remaining operations.

Abstract: A method and controller for implementing storage adapter performance optimization with cache data and cache directory mirroring between dual adapters minimizing firmware operations, and a design structure on which the subject controller circuit resides are provided. One of the first controller or the second controller operates in a first initiator mode includes firmware to set up an initiator write operation building a data frame for transferring data and a respective cache line (CL) for each page index to the other controller operating in a second target mode. Respective initiator hardware engines transfers data, reading CLs from an initiator control store, and writing updated CLs to an initiator data store, and simultaneously sends data and updated CLs to the other controller. Respective target hardware engines write data and updated CLs to the target data store, eliminating firmware operations of the controller operating in the second target mode.

Abstract: A method and controller for implementing storage adapter performance optimization with automatic chained hardware operations eliminating firmware operations, and a design structure on which the subject controller circuit resides are provided. The controller includes a plurality of hardware engines and a control store configured to store a plurality of control blocks. Each control block is designed to control a hardware operation in one of the plurality of hardware engines. A plurality of the control blocks is selectively arranged in a respective predefined chain to define sequences of hardware operations. An automatic hardware structure is configured to build the respective predefined chain controlling the hardware operations for a predefined hardware function. The predefined hardware function includes buffer allocation and automatic DMA data from a host system to the controller for write operations, eliminating firmware operations.