Abstract: The subject matter described herein includes methods, systems, and computer readable media for stateless service traffic generation. A method for stateless service traffic generation occurs at a network equipment test system. The method includes generating, at a first transmit port associated with the network equipment test system, a first test packet flow comprising one or more packets, wherein the first test packet flow indicates a match and action instruction for triggering an action at a second transmit port associated with the network equipment test system; sending the first test packet flow toward a node associated with a data center under test (DCUT); receiving the first test packet flow from the node associated with the DCUT; and performing, using the match and action instruction, the action at the second transmit port associated with the network equipment test system.

Abstract: A method for providing timing security in a time sensitive network (TSN), includes monitoring TSN times in timing synchronization packets exchanged between TSN network nodes. The method further includes monitoring TSN timing values calculated by TSN network nodes. The method further includes determining, using TSN times and TSN timing values, whether a timing attack is indicated. The method further includes, in response to determining that a timing attack is indicated, performing a timing attack effects mitigation action.

Abstract: The subject matter described herein includes methods, systems, and computer readable media for stateless service traffic generation. A method for stateless service traffic generation occurs at a network equipment test system. The method includes generating, at a first transmit port associated with the network equipment test system, a first test packet flow comprising one or more packets, wherein the first test packet flow indicates a match and action instruction for triggering an action at a second transmit port associated with the network equipment test system; sending the first test packet flow toward a node associated with a data center under test (DCUT); receiving the first test packet flow from the node associated with the DCUT; and performing, using the match and action instruction, the action at the second transmit port associated with the network equipment test system.

Abstract: Methods, systems, and computer readable media for testing effects of simulated frame preemption and deterministic fragmentation of preemptable frames in a frame-preemption-capable network are disclosed. According to one method, a device under test including at least one processor simulates frame preemption by generating a plurality of simulated preempted frame fragments and an express frame. The test device deterministically orders, independently from MAC merge sublayer fragmentation and ordering, the simulated preempted frame fragments and the express frame for transmission to the DUT. The test device transmits the simulated preempted frame fragments and the express frame to the DUT in an order corresponding to the deterministic ordering. The test device receives a response of the DUT to the simulated preempted frame fragments and the express frame. The test device determines, based on the response of the DUT, whether the DUT operates in accordance with specifications for frame preemption.

Abstract: A method for providing a network tap supporting time sensitive network standards includes scanning, by an active network tap, received frames on a network port of the active network tap to identify timing synchronization messages of targeted message types. The method further includes identifying a timing synchronization message of the targeted message type. The method further includes modifying a timing value in the timing synchronization message to account for delay introduced by the active network tap. The method further includes forwarding the timing synchronization message with the modifying timing value to a destination time sensitive network node via an egress network port of the active network tap.

Abstract: A method for providing timing security in a time sensitive network (TSN), includes monitoring TSN times in timing synchronization packets exchanged between TSN network nodes. The method further includes monitoring TSN timing values calculated by TSN network nodes. The method further includes determining, using TSN times and TSN timing values, whether a timing attack is indicated. The method further includes, in response to determining that a timing attack is indicated, performing a timing attack effects mitigation action.

Abstract: A method for providing a network tap supporting time sensitive network standards includes scanning, by an active network tap, received frames on a network port of the active network tap to identify timing synchronization messages of targeted message types. The method further includes identifying a timing synchronization message of the targeted message type. The method further includes modifying a timing value in the timing synchronization message to account for delay introduced by the active network tap. The method further includes forwarding the timing synchronization message with the modifying timing value to a destination time sensitive network node via an egress network port of the active network tap.

Abstract: A computerized apparatus configured for high-speed data transactions between components thereof. In one embodiment, the computerized apparatus includes a high-speed ring data bus apparatus with a plurality of nodes, and associated application apparatus in data communication with at least one of the nodes. A synchronous ring protocol is used to transfer data packets or frames around the ring data bus, so as to avoid data collisions. The packets or frames include both payload and control data, and may be addressed to higher layer processes of the application apparatus. In one variant, differentially signaled optical or electrical bus segments are utilized to interface with the nodes, and data is serialized before transmission on the ring data bus. In another variant, a common clock signal is transmitted around the ring with the data packets or frames.

Abstract: Methods, systems, and computer readable media for testing effects of simulated frame preemption and deterministic fragmentation of preemptable frames in a frame-preemption-capable network are disclosed. According to one method, a device under test including at least one processor simulates frame preemption by generating a plurality of simulated preempted frame fragments and an express frame. The test device deterministically orders, independently from MAC merge sublayer fragmentation and ordering, the simulated preempted frame fragments and the express frame for transmission to the DUT. The test device transmits the simulated preempted frame fragments and the express frame to the DUT in an order corresponding to the deterministic ordering. The test device receives a response of the DUT to the simulated preempted frame fragments and the express frame. The test device determines, based on the response of the DUT, whether the DUT operates in accordance with specifications for frame preemption.

Abstract: Methods, systems, and computer readable media for testing and/or determining scheduling fidelity in a time sensitive network (TSN) are disclosed. According to one method for determining scheduling fidelity in a TSN, the method occurs in a test system. The method includes receiving, via a system under test (SUT), at least one expected receive time indicating when a test packet is expected to be received by at least one destination. The method further includes computing, using the at least one expected receive time and at least one actual receive time, a time variation metric associated with the test packet.

Abstract: Methods, systems, and computer readable media for testing time sensitive network (TSN) elements are disclosed. According to one method for testing a TSN element, the method occurs at a test system. The method includes synchronizing a test system clock with a clock at a system under test (SUT). The method also includes receiving a sequence of messages, wherein the sequence of messages is generated using schedule rules associated with a TSN stream. The method further includes determining, using timing information associated with the test system clock, whether the schedule rules are accurately implemented by the SUT.

Abstract: Methods, systems, and computer readable media for monitoring and/or testing network communications are disclosed. A method for monitoring network communications includes receiving packets from a network connected device, determining features associated with either the network connected device or a communications network to which the network connected device is connected by actively or passively monitoring or testing the packets, and automatically switching between passively monitoring or testing the packets and actively monitoring or testing the packets in response to receiving a packet carrying instructions.

Abstract: Methods, systems, and computer readable media for providing an anticipated data integrity check are disclosed. According to one method, the method includes generating a test message including an anticipated data integrity check value (ADICV), wherein the ADICV is computed using at least one value based on at least one expected modification to message data in the test message by at least one system under test (SUT), and sending the test message to the at least one SUT.

Abstract: Methods, systems, and computer readable media for testing and/or determining scheduling fidelity in a time sensitive network (TSN) are disclosed. According to one method for determining scheduling fidelity in a TSN, the method occurs in a test system. The method includes receiving, via a system under test (SUT), at least one expected receive time indicating when a test packet is expected to be received by at least one destination. The method further includes computing, using the at least one expected receive time and at least one actual receive time, a time variation metric associated with the test packet.

Abstract: Methods, systems, and computer readable media for testing time sensitive network (TSN) elements are disclosed. According to one method for testing a TSN element, the method occurs at a test system. The method includes synchronizing a test system clock with a clock at a system under test (SUT). The method also includes receiving a sequence of messages, wherein the sequence of messages is generated using schedule rules associated with a TSN stream. The method further includes determining, using timing information associated with the test system clock, whether the schedule rules are accurately implemented by the SUT.

Abstract: A computerized apparatus configured for high-speed data transactions between components thereof. In one embodiment, the computerized apparatus includes a high-speed ring data bus apparatus with a plurality of nodes, and associated application apparatus in data communication with at least one of the nodes. A synchronous ring protocol is used to transfer data packets or frames around the ring data bus, so as to avoid data collisions. The packets or frames include both payload and control data, and may be addressed to higher layer processes of the application apparatus. In one variant, differentially signaled optical or electrical bus segments are utilized to interface with the nodes, and data is serialized before transmission on the ring data bus. In another variant, a common clock signal is transmitted around the ring with the data packets or frames.

Abstract: The subject matter described herein relates to methods, systems, and computer readable media for emulating network devices with different clocks. One method includes steps occurring in a network equipment test device. The steps include generating or obtaining timing information. The steps further include obtaining clock modification information. The steps further include emulating a plurality of different clocks using the timing information and the clock modification information. The method further includes emulating at least one network device that transmits test packets to a device under test using the different clocks.

Abstract: A system for testing recovered clock quality includes a test device for operating as a timing synchronization protocol master for communicating with a device under test functioning as a timing synchronization protocol slave or a timing synchronization protocol boundary clock to synchronize a clock of the device under test with a clock of the test device. The system further includes a recovered clock quality tester for receiving, from the device under test, a reverse synchronization message including clock information and for using the clock information to quantify a synchronization error between the clock of the device under test and the clock of the test device.

Abstract: A computerized apparatus configured for high-speed data transactions between components thereof. In one embodiment, the computerized apparatus includes a high-speed data bus apparatus; a user interface apparatus in data communication with the high-speed data bus apparatus configured to enable a user to interact with the computerized apparatus; an input/output apparatus in data communication with the high-speed data bus apparatus and configured to interchange data with one or more devices external to the computerized apparatus; a mass storage apparatus in data communication with the high-speed data bus apparatus and configured to store data; a computer program for use by the high-speed data bus apparatus; and a substantially unified data interface in data communication with each of the user interface apparatus, the input/output apparatus, the mass storage apparatus, and the high-speed data bus apparatus.

Abstract: Methods, systems, and computer readable media for emulating virtualization resources are disclosed. According to one method, the method occurs at a computing platform. The method includes receiving a message associated with a device under test (DUT) and in response to receiving the message, performing an action associated with at least one of an emulated hypervisor and an emulated virtual machine (VM).