Patent application number | Description | Published |
20090141630 | METHOD FOR MONITORING DATA CONGESTION IN A COMPUTER NETWORK WITH MULTIPLE NODES AND METHOD FOR CONTROLLING DATA TRANSMISSION IN THE COMPUTER NETWORK - A method for monitoring data congestion in a computer network with multiple nodes and for controlling data transmission in the computer network. The method includes generating a congestion notification by the node which detects a data congestion and transmitting the congestion notification to the data source which is involved in the data congestion. The method also includes generating in the data source a congestion value which indicates how severe the data congestion is, and storing in a worst case array of the data source those congestion values which indicate the most severe data congestions. | 06-04-2009 |
20090147679 | NETWORK DEVICE AND METHOD FOR OPERATING NETWORK DEVICE - A network device including at least one rate-limited-queue and multiple timer modules, the network device being operable to receive and/or transmit data flows from and/or to a communication network. Each data flow includes multiple data packets. The network device being further operable to limit the predetermined transmission rate of the respective data flow dependent on whether a data congestion in the communication network has been indicated, in such a way, that in case of an indicated congested communication network a respective timer module is associated to each of the data flows and/or each group of data flows, whereas the data packets of the respective data flows and/or group of data flows are buffered in the rate-limited-queue. Each data packet in the rate-limited-queue is transmitted with a limited transmission rate predetermined by the respectively associated timer module when the data packet is at the head of the rate-limited-queue. | 06-11-2009 |
20090296577 | METHOD AND APPARATUS FOR END-TO-END NETWORK CONGESTION MANAGEMENT - The invention provides a method and apparatus for network congestion management. The method includes inserting a probe frame into data traffic in the network from a first endpoint in the network, reflecting the probe frame from a second endpoint in the network back to the first endpoint, receiving the reflected probe frame at the first endpoint via the network, determining a round-trip delay based on flow of the probe frame through the network, and throttling network traffic according to the determined delay to manage network traffic congestion. | 12-03-2009 |
20130163419 | FLEXIBLE AND SCALABLE DATA LINK LAYER FLOW CONTROL FOR NETWORK FABRICS - A network fabric may divide a physical connection into a plurality of VLANs as defined by IEEE 802.1Q. Moreover, many network fabrics use Priority Flow Control to identify and segregate network traffic based on different traffic classes or priorities. Current routing protocols define only eight traffic classes. In contrast, a network fabric may contain thousands of unique VLANs. When network congestion occurs, network devices (e.g., switches, bridges, routers, servers, etc.) can negotiate to pause the network traffic associated with one of the different traffic classes. Pausing the data packets associated with a single traffic class may also stop the data packets associated with thousands of VLANs. The embodiments disclosed herein permit a network fabric to individually pause VLANs rather than entire traffic classes. | 06-27-2013 |
20130163611 | FLEXIBLE AND SCALABLE ENHANCED TRANSMISSION SELECTION METHOD FOR NETWORK FABRICS - IEEE 802.1Q and Enhanced Transmission Selection provide only eight different traffic classes that may be used to control bandwidth in a particular physical connection (or link). Instead of relying only on these eight traffic classes to manage bandwidth, the embodiments discussed herein disclose using an Enhanced Transmission Selection scheduler that permits a network device to set the bandwidth for an individual virtual LAN. Allocating bandwidth in a port based on a virtual LAN ID permits a network device to allocate bandwidth to, e.g., millions of unique virtual LANs. Thus, this technique may increase the granular control of the network fabric and its performance. | 06-27-2013 |
20130166753 | FLEXIBLE AND SCALABLE ENHANCED TRANSMISSION SELECTION METHOD FOR NETWORK FABRICS - IEEE 802.1Q and Enhanced Transmission Selection provide only eight different traffic classes that may be used to control bandwidth in a particular physical connection (or link). Instead of relying only on these eight traffic classes to manage bandwidth, the embodiments discussed herein disclose using an Enhanced Transmission Selection scheduler that permits a network device to set the bandwidth for an individual virtual LAN. Allocating bandwidth in a port based on a virtual LAN ID permits a network device to allocate bandwidth to, e.g., millions of unique virtual LANs. Thus, this technique may increase the granular control of the network fabric and its performance. | 06-27-2013 |
20130166773 | Flexible and scalable data link layer flow control for network fabrics - A network fabric may divide a physical connection into a plurality of VLANs as defined by IEEE 802.1Q. Moreover, many network fabrics use Priority Flow Control to identify and segregate network traffic based on different traffic classes or priorities. Current routing protocols define only eight traffic classes. In contrast, a network fabric may contain thousands of unique VLANs. When network congestion occurs, network devices (e.g., switches, bridges, routers, servers, etc.) can negotiate to pause the network traffic associated with one of the different traffic classes. Pausing the data packets associated with a single traffic class may also stop the data packets associated with thousands of VLANs. The embodiments disclosed herein permit a network fabric to individually pause VLANs rather than entire traffic classes. | 06-27-2013 |
20130194923 | CONVERGED ENHANCED ETHERNET NETWORK - A system to improve a Converged Enhanced Ethernet network may include a controller having a computer processor connected to a layer 2 endpoint buffer. The system may also include a manager executing on the controller to monitor the layer 2 endpoint buffer by determining buffer data packet occupancy and/or rate of change in the buffer data packet occupancy. The system may further include a reporter to notify a congestion source of the layer 2 endpoint buffer based upon the buffer data packet occupancy and/or rate of change in the buffer data packet occupancy. | 08-01-2013 |
20130194946 | CONVERGED ENHANCED ETHERNET NETWORK - A system to improve a Converged Enhanced Ethernet network may include a controller having a computer processor connected to a layer 2 endpoint buffer. The system may also include a manager executing on the controller to monitor the layer 2 endpoint buffer by determining buffer data packet occupancy and/or rate of change in the buffer data packet occupancy. The system may further include a reporter to notify a congestion source of the layer 2 endpoint buffer based upon the buffer data packet occupancy and/or rate of change in the buffer data packet occupancy. | 08-01-2013 |
20130205038 | LOSSLESS SOCKET-BASED LAYER 4 TRANSPORT (RELIABILITY) SYSTEM FOR A CONVERGED ETHERNET NETWORK - A reliability system for a Converged Enhanced Ethernet network may include a plurality of end points each comprising a layer 4 transport layer, where each end point is connected to a data center bridging (DCB) layer 2 network. The system may also include an adaptor between the layer 4 transport layer and the DCB layer 2 network to translate at least one of flow and congestion control feedback signals, provided by at least one of the DCB network and the transport layer, to consolidated feedback signals for controlling transmission by the transport layer. | 08-08-2013 |
20130322237 | Network congestion notification preservation and modification during transmission of netwrok data between physical network and virtual network - A virtual network is implemented on a physical network. A virtual network data packet is tunneled through the physical network via encapsulation within a physical network data packet and via transmission of the physical network data packet through the physical network. A network congestion notification capability of the virtual network is preserved and modified during transmission of virtual network data through the physical network and vice-versa. Congestion notification metadata can be copied from a header of a virtual network data packet to a header of a physical network data packet when the virtual network data packet is encapsulated into the physical network data packet. Congestion notification metadata can be copied from a header of a physical network data packet to a header of a virtual network data packet when the virtual network data packet is decapsulated from the physical network data packet. | 12-05-2013 |
20130322252 | Network congestion notification preservation and modification during transmission of network data between physical network and virtual network - A virtual network is implemented on a physical network. A virtual network data packet is tunneled through the physical network via encapsulation within a physical network data packet and via transmission of the physical network data packet through the physical network. A network congestion notification capability of the virtual network is preserved and modified during transmission of virtual network data through the physical network and vice-versa. Congestion notification metadata can be copied from a header of a virtual network data packet to a header of a physical network data packet when the virtual network data packet is encapsulated into the physical network data packet. Congestion notification metadata can be copied from a header of a physical network data packet to a header of a virtual network data packet when the virtual network data packet is decapsulated from the physical network data packet. | 12-05-2013 |
20140204748 | ARBITRATION OF MULTIPLE-THOUSANDS OF FLOWS FOR CONVERGENCE ENHANCED ETHERNET - In one embodiment, a system includes a processor and logic integrated with and/or executable by the processor, the logic being adapted to: receive a plurality of flows, each flow comprising packets of data, assign a service credit to each of the plurality of flows, assign a weight parameter to each of the plurality of flows, select a flow from a head of a first control queue unless the first control queue is empty or there is indication that the first control queue should be avoided, wherein a flow is selected from a head of a second control queue when the first control queue is empty or there is indication that the first control queue should be avoided, provide a number of units of service to the selected flow, and decrease the selected flow's service credit by an amount corresponding to the number of units of service provided thereto. | 07-24-2014 |
20140219287 | VIRTUAL SWITCHING BASED FLOW CONTROL - Flow control of data packets in a network may be enabled to at least one side of a virtual switching interface to provide a lossless environment. In some embodiments, wherever two buffer queues are in communication with at least one buffer queue being connected to a virtual switching interface, flow control may be used to determine if a threshold has been exceeded in one of the buffer queues. When exceeded, the transmission of data packets may cease to one of the buffer queues to prevent packet dropping and loss of data. | 08-07-2014 |
20140241345 | SOURCE ROUTING WITH FABRIC SWITCHES IN AN ETHERNET FABRIC NETWORK - In one embodiment, a system includes a network fabric having a plurality of fabric switches interconnected in the network fabric and a switch controller having logic adapted to configure the network fabric, determine one or more paths through the network fabric between any two hosts connected thereto, and create a source-routing table to store the one or more paths through the network fabric between any two hosts connected thereto. In another embodiment, a method includes receiving or creating a packet using a NIC of a host connected to a network fabric having a plurality of fabric switches interconnected therein, determining a path through the network fabric by consulting a source-routing table stored to the host, storing source-routing information to a packet header for the packet, the source-routing information including the path, and sending the packet to a first device or hop indicated by the path in the source-routing information. | 08-28-2014 |
20140269274 | CREDIT-BASED FLOW CONTROL IN LOSSLESS ETHERNET NETWORKS - In one embodiment, a system includes a hardware processor and logic integrated with and/or executable by the processor or media access control (MAC) functionality of a network port, the logic being adapted to initialize a link between a receiving endpoint and a sending endpoint, the receiving and sending endpoints being connected in a network fabric, wherein at least one virtual link is created within the link, receive an amount of available flow credits from the receiving endpoint, wherein the amount of available flow credits are used to determine a capacity to process packets at the receiving endpoint, and transmit one or more packets to the receiving endpoint until all packets are sent or the amount of available flow credits is insufficient to process additional packets, wherein exchange of flow credits is performed on a per virtual link basis. | 09-18-2014 |
20140269325 | BYPASSING CONGESTION POINTS IN A CONVERGED ENHANCED ETHERNET FABRIC - Embodiments relate to bypassing congestion points in a network. An aspect includes sampling queues of a plurality of switches in a network. When packet congestion is detected at a congestion point of a first switch, the packet flow contributing to the packet congestion is identified. A congestion notification message indicating the identified packet flow is then propagated to upstream switches, which are upstream from the first switch in the network. The congestion notification message is then snooped by the upstream switches. Virtual queues within the upstream switches are associated with the identified packet flow to hold packets associated with the identified packet flow. The packets associated with the identified packet flow are then re-routed to bypass the packet congestion in the first switch. | 09-18-2014 |
20140269403 | Coherent Load monitoring of physical and virtual networks with synchronous status acquisition - Embodiments relate to creating a coherent load or congestion map that displays the simultaneous activity of all queues of physical and virtual switches and adapters in a network without forcing clock synchronization. An aspect includes sampling, by a central processing device, a status of all queues in a plurality of elements in a network. The sampled data flows are received from the plurality of elements in the network and an image is created of the network. The image includes the status of all sampled queues in the plurality of elements at a point in time. Accordingly, a load map is created without synchronizing clocks of the plurality of elements. The load map is assembled using segments of the image of the network. | 09-18-2014 |
20140269415 | CREDIT-BASED FLOW CONTROL FOR MULTICAST PACKETS IN LOSSLESS ETHERNET NETWORKS - Methods, systems, and computer program products presented herein provide for self-routing multicast. In one embodiment, a system includes a switch controller including a hardware processor and logic integrated with and/or executable by the processor, the logic being adapted to receive a multicast data stream join request from a source device in a network, create a multipath identifier (ID) for the multipath data stream, create a series of path identifiers (IDs) for each intermediate switch in the network based on a local network topology database, each path ID being associated with a desired output port bitmap, and transmit the multipath ID and a path ID to a source of the multicast data stream, the path ID corresponding to the source of the multicast data stream join request. | 09-18-2014 |
20140269705 | HETEROGENEOUS OVERLAY NETWORK TRANSLATION FOR DOMAIN UNIFICATION - In one embodiment, a method for providing multi-protocol overlay handling includes receiving first traffic via an input overlay tunnel at a multi-protocol virtual tunnel end point (VTEP)-enabled device, the first traffic including a plurality of overlay-encapsulated packets which adhere to a first overlay network protocol, and wherein the input overlay tunnel adheres to the first overlay network protocol; routing the first traffic to a second overlay network tunnel which adheres to a second overlay network protocol when a destination of the first traffic is specified as the second overlay network tunnel, the second overlay network tunnel being terminated at the multi-protocol VTEP-enabled device; and bridging the first traffic to a destination overlay network tunnel terminated at the multi-protocol VTEP-enabled device when the destination of the first traffic is specified as the destination overlay network tunnel, the destination overlay network tunnel being terminated at the multi-protocol VTEP-enabled device. | 09-18-2014 |
20140281020 | SOURCE-DRIVEN SWITCH PROBING WITH FEEDBACK REQUEST - Embodiments relate to proactively probing the packet queues of elements in a physical or virtual network to predict and prevent the occurrence of congestion points. An aspect includes receiving a first feedback request at a central controller connected to a plurality of switches in a network. The first feedback request includes a request to periodically probe a status of queues of switches in the network. A second feedback request is then transmitted to one or all the switches in a path leading to a designated destination. Responses to the second feedback request are received at the central controller from a designated proxy switch, which aggregated the responses into a single data packet. Accordingly, the responses extracted from the single data packet at the central controller are used to preventing future congestion points. | 09-18-2014 |
20140281021 | ADAPTIVE SETTING OF THE QUANTIZED CONGESTION NOTIFICATION EQUILIBRIUM SETPOINT IN CONVERGED ENHANCED EITHERNET NETWORKS - Embodiments relate to controlling workload flow on converged Ethernet links. An aspect includes coupling, by a processing device, a first control loop to a second control loop. The second control loop monitors the operation of the first control loop. An equilibrium set point is initialized for the second control loop prior to commencing operation of the first control loop. Accordingly, the equilibrium set point value is adjusted in the second control loop continuously based on a rate of operation of the first control loop. | 09-18-2014 |
20140301187 | CREDIT-BASED LINK LEVEL FLOW CONTROL AND CREDIT EXCHANGE USING DCBX - In one embodiment, a system includes a network having one or more devices interconnected therebetween, the network including a first device having a first port and logic integrated with and/or executable by a first processor, the logic being adapted to exchange credit exchange (CE) capabilities between the first port and a second port of a second device in the network, receive a credit grant packet from the second port, the credit grant packet indicating credits granted to the first port, and send one or more packets of data from the first port to the second port, the one or more packets corresponding with the granted credits. Other systems and methods for providing credit-based flow control are described according to more embodiments. | 10-09-2014 |
20140301197 | VIRTUAL QUANTIZED CONGESTION NOTIFICATION - Congestion management for data traffic in a virtual domain identifies a congestion source and sends a message to the source to adjust data traffic rates. The source may be a virtual machine hosted by a physical server with one or more virtual servers incorporated. A congestion manager may identify the source and send the message to the source without affecting other data sources hosted by the physical server or the virtual servers. In some embodiments, information about the congestion source may be encapsulated in a packet payload readable only by the congestion source so only the congestion source receives the instruction to adjust the transmission rate. | 10-09-2014 |
20140307554 | VIRTUAL ENHANCED TRANSMISSION SELECTION (VETS) FOR LOSSLESS ETHERNET - In one embodiment, a system includes a hardware processor and logic integrated with and/or executable by the processor, the logic being adapted to receive a traffic flow having a plurality of packets, classify the traffic flow into a traffic class based on a characteristic of the traffic flow, the traffic class being selected from a plurality of traffic classes, store an identifier of the selected traffic class to one or more of the packets, and transmit the traffic flow according to its destination based on a priority of its selected traffic class. In more embodiments, additional systems, methods, and computer program products for prioritizing traffic flow handling are described. | 10-16-2014 |
20140307555 | FLOW CONTROL CREDITS FOR PRIORITY IN LOSSLESS ETHERNET - In one embodiment, a system includes an initiator port adapted to receive a traffic flow having a plurality of packets and a hardware processor and logic integrated with and/or executable by the processor, the logic being adapted to classify the traffic flow into a traffic class based on at least one criteria related to the traffic flow, the traffic class being selected from a plurality of traffic classes and transmit one or more packets of the traffic flow to a target port designated by the one or more packets of the traffic flow until an amount of flow credits allocated to the target port is insufficient to service additional packets. Other systems, methods, and computer program products for providing credit-based flow control are described in more embodiments. | 10-16-2014 |
20140328340 | VIRTUAL DATA CENTER BRIDGING EXCHANGE (VDCBX) PROTOCOL - In one embodiment, a system includes processor; and logic integrated with and/or executable by the processor, the logic being adapted to: assign a VLAN type to each of a plurality of VLANs of an architecture; generate a VLAN list type-length-value (vTLV) message; and transmit information to resources based at least in part on the vTLV message, wherein the resources comprise at least one virtual switch and one or more of: at least one physical switch; at least one virtual port; at least one physical port; at least one virtual machine; at least one converged network adapter (CNA); and at least one fibre channel forwarder (FCF). | 11-06-2014 |
20150016252 | SOURCE-DRIVEN SWITCH PROBING WITH FEEDBACK REQUEST - Embodiments relate to proactively probing the packet queues of elements in a physical or virtual network to predict and prevent the occurrence of congestion points. An aspect includes receiving a first feedback request at a central controller connected to a plurality of switches in a network. The first feedback request includes a request to periodically probe a status of queues of switches in the network. A second feedback request is then transmitted to one or all the switches in a path leading to a designated destination. Responses to the second feedback request are received at the central controller from a designated proxy switch, which aggregated the responses into a single data packet. Accordingly, the responses extracted from the single data packet at the central controller are used to preventing future congestion points. | 01-15-2015 |
20150019752 | ADAPTIVE SETTING OF THE QUANTIZED CONGESTION NOTIFICATION EQUILIBRIUM SETPOINT IN CONVERGED ENHANCED EITHERNET NETWORKS - Embodiments relate to controlling workload flow on converged Ethernet links. An aspect includes coupling, by a processing device, a first control loop to a second control loop. The second control loop monitors the operation of the first control loop. An equilibrium set point is initialized for the second control loop prior to commencing operation of the first control loop. Accordingly, the equilibrium set point value is adjusted in the second control loop continuously based on a rate of operation of the first control loop. | 01-15-2015 |
20150074276 | WORKLOAD DEPLOYMENT WITH REAL-TIME CONSIDERATION OF GLOBAL NETWORK CONGESTION - In one embodiment, a system includes a switch controller configured to communicate with each of a plurality of network devices in a network, the switch controller including a processor and logic integrated with and/or executable by the processor, the logic being configured to: receive a request to instantiate a new workload or to move a current workload in the network, determine a throughput associated with the new or current workload, and select an optimum location to place the new workload or to move the current workload in the network based on the throughput associated with the new or current workload. According to another embodiment, a method includes receiving a request at a switch controller to instantiate or move a workload, determining a throughput associated with the workload, and selecting an optimum location to place or move the workload based on the throughput associated with the workload. | 03-12-2015 |
20150078170 | BYPASSING CONGESTION POINTS IN A CONVERGED ENHANCED ETHERNET FABRIC - Embodiments relate to bypassing congestion points in a network. An aspect includes sampling queues of a plurality of switches in a network. When packet congestion is detected at a congestion point of a first switch, the packet flow contributing to the packet congestion is identified. A congestion notification message indicating the identified packet flow is then propagated to upstream switches, which are upstream from the first switch in the network. The congestion notification message is then snooped by the upstream switches. Virtual queues within the upstream switches are associated with the identified packet flow to hold packets associated with the identified packet flow. The packets associated with the identified packet flow are then re-routed to bypass the packet congestion in the first switch. | 03-19-2015 |