Abstract: A method and apparatus are provided for implementing multiple configurable sub-busses of a point-to-point bus. Each of a plurality of bus interconnects include a transmit interface and a receive interface connected to the point-to-point bus. Each transmit interface includes a transmit buffer and a serializer coupled between the buffer and the point-to-point bus. The transmit buffer provides an asynchronous interface between a transmit source and the serializer. The serializer receives data and control signals from the transmit buffer at a first frequency and transmits data and control signals over the point-to-point bus at a higher second frequency. Transmit steering logic is coupled between the transmit source and each transmit buffer of the plurality of bus interconnects. Transmit steering logic directs data and control signals from transmit source to each selected one of the transmit buffers based upon a selected bus configuration.

Abstract: A Network Processor (NP) is formed from a plurality of operatively coupled chips. The NP includes a Network Processor Complex (NPC) Chip coupled to a Data Flow Chip and Data Store Memory coupled to the Data Flow Chip. An optional Scheduler Chip is coupled to the Data Flow Chip. The named components are replicated to create a symmetric ingress and egress structure. Communications between the chips are provided by a pair of Chip to Chip Macros, one of each operatively positioned on one of the chips, and a Chip to Chip Bus Interface operatively coupling the Chip to Chip Macros.

Abstract: A method and apparatus are provided for implementing chip-to-chip interconnect bus initialization. The chip-to-chip interconnect bus includes first and second unidirectional buses for full duplex communications between two chips. A lower than normal bus frequency is used during the initialization process. A transmit initialization sequencer of a source transmits predefined SYNC symbols on the connected unidirectional bus. A receive initialization sequencer of a destination chip checks for a defined number of valid SYNC or IDLE symbols. When the receive initialization sequencer of a destination detects the defined number of valid SYNC or IDLE symbols, the receive initialization sequencer triggers a transmit initialization sequencer of the destination to transmit IDLE symbols on the connected unidirectional bus. The transmitted IDLE symbols are detected by a receive initialization sequencer at the source, indicating that both ends of the interconnect bus have synchronized.

Abstract: A method, apparatus and computer program product are provided for implementing a pointer and stake model for frame alteration code in a network processor. A current pointer and a stake are provided for a packet selected for transmit. The current pointer is maintained for tracking a current position for frame alteration operations in the packet. The stake is maintained for tracking a start of a current header for frame alteration operations in the packet. The current pointer is used by frame alteration code instructions to specify a sequence of operations relative to the current pointer. The specified frame alteration sequence is compact in terms of code size to operate on data within a small window of bytes. Advance pointer instructions allow the current and stake pointers to be advanced an arbitrary number of bytes into the packet.

Abstract: A method, apparatus and computer program product are provided for implementing conditional packet alterations based upon a transmit port. A selection mechanism is provided for implementing packet alterations. A sequence of frame alteration instructions and transmit port numbers associated with a packet being transmitted is applied to the selection mechanism. The selection mechanism performs alterations on the packet being transmitted responsive to the applied sequence of frame alteration instructions and port numbers associated with the packet. The selection mechanism includes a multiplexer that sequentially receives frame alteration instructions and port numbers associated with a packet being transmitted, and an indirect data array for providing packet alteration data from the indirect data array.

Abstract: A method is provided for address mapping in a network processor. The method includes the steps of (1) determining a port number of a port that receives a data cell; (2) determining a virtual path identifier and a virtual channel identifier for the data cell; and (3) creating a first index based on at least one of the port number, the virtual path identifier and the virtual channel identifier. The method further includes (1) accessing one of a plurality of entries stored in a first on-chip memory using the first index; (2) creating a second index based on the accessed entry of the first on-chip memory; and (3) accessing an entry of a second memory based on the second index. Numerous other aspects are provided.

Abstract: A method and apparatus are provided for implementing frame header alterations on multiple concurrent frames. Each of a plurality of frame data alteration engines includes a pair of a command decoder and an associated data aligner. A command buffer arbiter sequentially receives frame alteration commands and sequentially selects one of the frame data alteration engines for the sequentially received frame alteration commands. Each command decoder receives and decodes frame alteration commands and provides frame alignment commands and alteration instructions and each associated data aligner receives frame data and selectively latches data bytes of the received frame data responsive to the frame alignment commands and sequentially provides an aligned frame data output of a predefined number of bytes.

Abstract: A method and apparatus are provided for implementing frame header alterations using byte-wise arithmetic logic units (ALUs). First and second stage alteration engines include a plurality of first stage byte-wise arithmetic logic units (ALUs). Each ALU includes inputs for receiving frame data, command data, register data, and commands, and register data and data outputs. The first and second stage byte-wise ALUs respectively perform the received first and second stage commands and the second stage ALUs provide altered frame data output. The commands enable operations such as load, add, and, or, move, and the like used by the two-stages of byte-wise ALUs forming the alteration engines to perform the alterations or combine new header data into a stream of frame data.

Abstract: A method and apparatus are provided for implementing frame header alterations in a network processor. A command decoder receives and decodes frame alteration commands and provides frame alignment commands and alteration instructions. A data aligner receives frame data and is coupled to the command decoder receiving the frame alignment commands. The data aligner includes an insert and delete unit that sequentially receives a predefined number of bytes of frame data, selectively latches data bytes of the received predefined number of bytes of frame data responsive to the frame alignment commands and sequentially provides an aligned frame data output of the predefined number of bytes. An alteration engine is coupled to the data aligner receiving the sequential aligned frame data output and is coupled to the command decoder receiving the alteration instructions. The alteration engine provides sequential altered frame data responsive to the received alteration instructions.

Abstract: A method and apparatus are provided for implementing chip-to-chip interconnect bus initialization. The chip-to-chip interconnect bus includes first and second unidirectional buses for full duplex communications between two chips. A lower than normal bus frequency is used during the initialization process. A transmit initialization sequencer of a source transmits predefined SYNC symbols on the connected unidirectional bus. A receive initialization sequencer of a destination chip checks for a defined number of valid SYNC or IDLE symbols. When the receive initialization sequencer of a destination detects the defined number of valid SYNC or IDLE symbols, the receive initialization sequencer triggers a transmit initialization sequencer of the destination to transmit IDLE symbols on the connected unidirectional bus. The transmitted IDLE symbols are detected by a receive initialization sequencer at the source, indicating that both ends of the interconnect bus have synchronized.

Abstract: A method and apparatus are provided for implementing multiple configurable sub-busses of a point-to-point bus. Each of a plurality of bus interconnects include a transmit interface and a receive interface connected to the point-to-point bus. Each transmit interface includes a transmit buffer and a serializer coupled between the buffer and the point-to-point bus. The transmit buffer provides an asynchronous interface between a transmit source and the serializer. The serializer receives data and control signals from the transmit buffer at a first frequency and transmits data and control signals over the point-to-point bus at a higher second frequency. Transmit steering logic is coupled between the transmit source and each transmit buffer of the plurality of bus interconnects. Transmit steering logic directs data and control signals from transmit source to each selected one of the transmit buffers based upon a selected bus configuration.

Abstract: A Network Processor (NP) is formed from a plurality of operatively coupled chips. The NP includes a Network Processor Complex (NPC) Chip coupled to a Data Flow Chip and Data Store Memory coupled to the Data Flow Chip. An optional Scheduler Chip is coupled to the Data Flow Chip. The named components are replicated to create a symmetric ingress and egress structure. Communications between the chips are provided by a pair of Chip to Chip Macros, one of each operatively positioned on one of the chips, and a Chip to Chip Bus Interface operatively coupling the Chip to Chip Macros.