Patent application number | Description | Published |
20110078249 | SHARED ADDRESS COLLECTIVES USING COUNTER MECHANISMS - A shared address space on a compute node stores data received from a network and data to transmit to the network. The shared address space includes an application buffer that can be directly operated upon by a plurality of processes, for instance, running on different cores on the compute node. A shared counter is used for one or more of signaling arrival of the data across the plurality of processes running on the compute node, signaling completion of an operation performed by one or more of the plurality of processes, obtaining reservation slots by one or more of the plurality of processes, or combinations thereof. | 03-31-2011 |
20110119468 | MECHANISM OF SUPPORTING SUB-COMMUNICATOR COLLECTIVES WITH O(64) COUNTERS AS OPPOSED TO ONE COUNTER FOR EACH SUB-COMMUNICATOR - A system and method for enhancing barrier collective synchronization on a computer system comprises a computer system including a data storage device. The computer system includes a program stored in the data storage device and steps of the program being executed by a processor. The system includes providing a plurality of communicators for storing state information for a bather algorithm. Each communicator designates a master core in a multi-processor environment of the computer system. The system allocates or designates one counter for each of a plurality of threads. The system configures a table with a number of entries equal to the maximum number of threads. The system sets a table entry with an ID associated with a communicator when a process thread initiates a collective. The system determines an allocated or designated counter by searching entries in the table. | 05-19-2011 |
20110219208 | MULTI-PETASCALE HIGHLY EFFICIENT PARALLEL SUPERCOMPUTER - A Multi-Petascale Highly Efficient Parallel Supercomputer of 100 petaOPS-scale computing, at decreased cost, power and footprint, and that allows for a maximum packaging density of processing nodes from an interconnect point of view. The Supercomputer exploits technological advances in VLSI that enables a computing model where many processors can be integrated into a single Application Specific Integrated Circuit (ASIC). Each ASIC computing node comprises a system-on-chip ASIC utilizing four or more processors integrated into one die, with each having full access to all system resources and enabling adaptive partitioning of the processors to functions such as compute or messaging I/O on an application by application basis, and preferably, enable adaptive partitioning of functions in accordance with various algorithmic phases within an application, or if I/O or other processors are underutilized, then can participate in computation or communication nodes are interconnected by a five dimensional torus network with DMA that optimally maximize the throughput of packet communications between nodes and minimize latency. | 09-08-2011 |
20120117137 | Fencing Data Transfers In A Parallel Active Messaging Interface Of A Parallel Computer - Fencing data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including a specification of data communications parameters for a thread of execution on a compute node, including specifications of a client, a context, and a task; the compute nodes coupled for data communications through the PAMI and through data communications resources including at least one segment of shared random access memory; including initiating execution through the PAMI of an ordered sequence of active SEND instructions for SEND data transfers between two endpoints, effecting deterministic SEND data transfers through a segment of shared memory; and executing through the PAMI, with no FENCE accounting for SEND data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all SEND instructions initiated prior to execution of the FENCE instruction for SEND data transfers between the two endpoints. | 05-10-2012 |
20120117138 | Fencing Network Direct Memory Access Data Transfers In A Parallel Active Messaging Interface Of A Parallel Computer - Fencing direct memory access (‘DMA’) data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including specifications of a client, a context, and a task, the endpoints coupled for data communications through the PAMI and through DMA controllers operatively coupled to a deterministic data communications network through which the DMA controllers deliver data communications deterministically, including initiating execution through the PAMI of an ordered sequence of active DMA instructions for DMA data transfers between two endpoints, effecting deterministic DMA data transfers through a DMA controller and the deterministic data communications network; and executing through the PAMI, with no FENCE accounting for DMA data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all DMA instructions initiated prior to execution of the FENCE instruction for DMA data transfers between the two endpoints. | 05-10-2012 |
20120117211 | Fencing Data Transfers In A Parallel Active Messaging Interface Of A Parallel Computer - Fencing data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint comprising a specification of data communications parameters for a thread of execution on a compute node, including specifications of a client, a context, and a task, the compute nodes coupled for data communications through the PAMI and through data communications resources including a deterministic data communications network, including initiating execution through the PAMI of an ordered sequence of active SEND instructions for SEND data transfers between two endpoints, effecting deterministic SEND data transfers; and executing through the PAMI, with no FENCE accounting for SEND data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all SEND instructions initiated prior to execution of the FENCE instruction for SEND data transfers between the two endpoints. | 05-10-2012 |
20120117281 | Fencing Direct Memory Access Data Transfers In A Parallel Active Messaging Interface Of A Parallel Computer - Fencing direct memory access (‘DMA’) data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including specifications of a client, a context, and a task, the endpoints coupled for data communications through the PAMI and through DMA controllers operatively coupled to segments of shared random access memory through which the DMA controllers deliver data communications deterministically, including initiating execution through the PAMI of an ordered sequence of active DMA instructions for DMA data transfers between two endpoints, effecting deterministic DMA data transfers through a DMA controller and a segment of shared memory; and executing through the PAMI, with no FENCE accounting for DMA data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all DMA instructions initiated prior to execution of the FENCE instruction for DMA data transfers between the two endpoints. | 05-10-2012 |
20120179879 | MECHANISMS FOR EFFICIENT INTRA-DIE/INTRA-CHIP COLLECTIVE MESSAGING - Mechanism of efficient intra-die collective processing across the nodelets with separate shared memory coherency domains is provided. An integrated circuit die may include a hardware collective unit implemented on the integrated circuit die. A plurality of cores on the integrated circuit die is grouped into a plurality of shared memory coherence domains. Each of the plurality of shared memory coherence domains is connected to the collective unit for performing collective operations between the plurality of shared memory coherence domains. | 07-12-2012 |
20130007378 | MECHANISMS FOR EFFICIENT INTRA-DIE/INTRA-CHIP COLLECTIVE MESSAGING - Mechanism of efficient intra-die collective processing across the nodelets with separate shared memory coherency domains is provided. An integrated circuit die may include a hardware collective unit implemented on the integrated circuit die. A plurality of cores on the integrated circuit die is grouped into a plurality of shared memory coherence domains. Each of the plurality of shared memory coherence domains is connected to the collective unit for performing collective operations between the plurality of shared memory coherence domains. | 01-03-2013 |
20130073751 | FENCING NETWORK DIRECT MEMORY ACCESS DATA TRANSFERS IN A PARALLEL ACTIVE MESSAGING INTERFACE OF A PARALLEL COMPUTER - Fencing direct memory access (‘DMA’) data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including specifications of a client, a context, and a task, the endpoints coupled for data communications through the PAMI and through DMA controllers operatively coupled to a deterministic data communications network through which the DMA controllers deliver data communications deterministically, including initiating execution through the PAMI of an ordered sequence of active DMA instructions for DMA data transfers between two endpoints, effecting deterministic DMA data transfers through a DMA controller and the deterministic data communications network; and executing through the PAMI, with no FENCE accounting for DMA data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all DMA instructions initiated prior to execution of the FENCE instruction for DMA data transfers between the two endpoints. | 03-21-2013 |
20130097614 | FENCING DATA TRANSFERS IN A PARALLEL ACTIVE MESSAGING INTERFACE OF A PARALLEL COMPUTER - Fencing data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including a specification of data communications parameters for a thread of execution on a compute node, including specifications of a client, a context, and a task; the compute nodes coupled for data communications through the PAMI and through data communications resources including at least one segment of shared random access memory; including initiating execution through the PAMI of an ordered sequence of active SEND instructions for SEND data transfers between two endpoints, effecting deterministic SEND data transfers through a segment of shared memory; and executing through the PAMI, with no FENCE accounting for SEND data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all SEND instructions initiated prior to execution of the FENCE instruction for SEND data transfers between the two endpoints. | 04-18-2013 |
20130174180 | FENCING DATA TRANSFERS IN A PARALLEL ACTIVE MESSAGING INTERFACE OF A PARALLEL COMPUTER - Fencing data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint comprising a specification of data communications parameters for a thread of execution on a compute node, including specifications of a client, a context, and a task, the compute nodes coupled for data communications through the PAMI and through data communications resources including a deterministic data communications network, including initiating execution through the PAMI of an ordered sequence of active SEND instructions for SEND data transfers between two endpoints, effecting deterministic SEND data transfers; and executing through the PAMI, with no FENCE accounting for SEND data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all SEND instructions initiated prior to execution of the FENCE instruction for SEND data transfers between the two endpoints. | 07-04-2013 |
20130185465 | Fencing Direct Memory Access Data Transfers In A Parallel Active Messaging Interface Of A Parallel Computer - Fencing direct memory access (‘DMA’) data transfers in a parallel active messaging interface (‘PAMI’) of a parallel computer, the PAMI including data communications endpoints, each endpoint including specifications of a client, a context, and a task, the endpoints coupled for data communications through the PAMI and through DMA controllers operatively coupled to segments of shared random access memory through which the DMA controllers deliver data communications deterministically, including initiating execution through the PAMI of an ordered sequence of active DMA instructions for DMA data transfers between two endpoints, effecting deterministic DMA data transfers through a DMA controller and a segment of shared memory; and executing through the PAMI, with no FENCE accounting for DMA data transfers, an active FENCE instruction, the FENCE instruction completing execution only after completion of all DMA instructions initiated prior to execution of the FENCE instruction for DMA data transfers between the two endpoints. | 07-18-2013 |
20130312010 | Processing Posted Receive Commands In A Parallel Computer - Processing posted receive commands in a parallel computer, including: posting, by a parallel process of a compute node, a receive command, the receive command including a set of parameters excluding the receive command from being directed among parallel posted receive queues; flattening the parallel unexpected message queues into a single unexpected message queue; determining whether the posted receive command is satisfied by an entry in the single unexpected message queue; if the posted receive command is satisfied by an entry in the single unexpected message queue, processing the posted receive command; if the posted receive command is not satisfied by an entry in the single unexpected message queue: flattening the parallel posted receive queues into a single posted receive queue; and storing the posted receive command in the single posted receive queue. | 11-21-2013 |
20130312011 | PROCESSING POSTED RECEIVE COMMANDS IN A PARALLEL COMPUTER - Processing posted receive commands in a parallel computer, including: posting, by a parallel process of a compute node, a receive command, the receive command including a set of parameters excluding the receive command from being directed among parallel posted receive queues; flattening the parallel unexpected message queues into a single unexpected message queue; determining whether the posted receive command is satisfied by an entry in the single unexpected message queue; if the posted receive command is satisfied by an entry in the single unexpected message queue, processing the posted receive command; if the posted receive command is not satisfied by an entry in the single unexpected message queue: flattening the parallel posted receive queues into a single posted receive queue; and storing the posted receive command in the single posted receive queue. | 11-21-2013 |
20130326180 | MECHANISM FOR OPTIMIZED INTRA-DIE INTER-NODELET MESSAGING COMMUNICATION - Point-to-point intra-nodelet messaging support for nodelets on a single chip that obey MPI semantics may be provided. In one aspect, a local buffering mechanism is employed that obeys standard communication protocols for the network communications between the nodelets integrated in a single chip. Sending messages from one nodelet to another nodelet on the same chip may be performed not via the network, but by exchanging messages in the point-to-point messaging buckets between the nodelets. The messaging buckets need not be part of the memory system of the nodelets. Specialized hardware controllers may be used for moving data between the nodelets and each messaging bucket, and ensuring correct operation of the network protocol. | 12-05-2013 |
20130346997 | MECHANISM OF SUPPORTING SUB-COMMUNICATOR COLLECTIVES WITH O(64) COUNTERS AS OPPOSED TO ONE COUNTER FOR EACH SUB-COMMUNICATOR - A system and method for enhancing barrier collective synchronization on a computer system comprises a computer system including a data storage device. The computer system includes a program stored in the data storage device and steps of the program being executed by a processor. The system includes providing a plurality of communicators for storing state information for a barrier algorithm. Each communicator designates a master core in a multi-processor environment of the computer system. The system allocates or designates one counter for each of a plurality of threads. The system configures a table with a number of entries equal to the maximum number of threads. The system sets a table entry with an ID associated with a communicator when a process thread initiates a collective. The system determines an allocated or designated counter by searching entries in the table. | 12-26-2013 |