JP2006115038A - Main signal load testing device and testing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a main signal load testing device etc., capable of conducting a load test in the device even if the difference between the packet transfer processing capability in the device and the packet transmission and reception capability of a CPU is ≥255 times. <P>SOLUTION: Disclosed is the main signal load testing device etc., equipped with a line termination section 13 which converts a received packet into a processable signal, a load monitor 15 which measures the transfer speed of a packet sent as a main signal, a core switch 12 which determines a port for transfer from received packet information, and a CPU 11 which transmits the packet to a port determined by the core switch 12 and collates the sent packet and the received packet with a packet whose port for transfer cannot be determined. The core switch 12 is equipped with a retrieval table 14 and transfers the packet to the designated port when there is a packets meeting conditions in the retrieval table 14 or to the CPU 11 when not. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a main signal load test apparatus and a test method, and more particularly to a main signal load test apparatus and a test method used for communication devices such as an exchange, a layer 2, a 3 switch, and a router.

  In communication devices such as exchanges, layer 2 and 3 switches (switches that support layer 2 and layer 3 management functions), routers, etc., a measuring instrument is connected to each interface, and a load test is performed by transmitting packets from the measuring instrument. It was.

  FIG. 5 shows a configuration example of a conventional load test apparatus. In this test apparatus, a measuring instrument 2 is connected to a port of the router 1 and a packet is transmitted from the measuring instrument 2. The packet received by the line termination unit 13 in the router 1 is converted into a signal that can be processed in the router 1 and reaches the core switch unit 12. Then, by setting a transfer port for the packet received by the search table 14 of the core switch unit 12, the packet received by the core switch unit 12 is transferred to the line termination unit 13 of the port specified by the search table 14. Is done. The transferred packet is again converted into a signal to the line by the line terminating unit 13 and received by the measuring instrument 2 through the line. Then, the load test was performed by increasing the transfer rate of the packet transmitted from the measuring instrument 2 and increasing the transfer load in the router 1.

  However, there is a problem that the measuring instrument used in the load test apparatus needs to correspond to each interface of the communication apparatus to be tested. Thus, Patent Document 1 discloses an inter-network connection device that performs a load test without using a measuring instrument. In this inter-network connection device, as shown in FIG. 6, the line termination unit 13 is set so as to be turned back into the device, and the transfer port for the packet to be transmitted is set in the search table 14 of the core switch unit 12. The CPU unit 11 transmits a load test IPv4 packet to the core switch unit 12. The core switch unit 12 transfers the packet received from the CPU unit 11 to a transfer port designated by using the search table 14. At this time, 1 is subtracted from the TTL value in the IPv4 header field.

  The packet transferred from the core switch unit 12 is returned to the core switch unit 12 again when it reaches the line termination unit 13. The packet returned to the core switch unit 12 is again decremented by 1 in the TTL value and transferred from the search table 14 to the designated transfer port (the same port as the previous one). As a result, the packet loops between the core switch unit 12 and the line termination unit 13. Each time the packet passes through the core switch unit 12, the TTL value is decremented by 1 and finally becomes 0.

  As illustrated in FIG. 7, when the core switch unit 12 receives a packet with a TTL value of 0, the core switch unit 12 transfers the packet to the CPU unit 11. When receiving the packet, the CPU unit 11 compares the transmitted packet with the received packet and confirms the normality of the transferred packet. In this way, a load test in the router 1 is performed by periodically transmitting packets from the CPU unit 11 and increasing the number of packets that are loop-transferred between the core switch unit 12 and the line termination unit 13.

JP 2000-151701 A

  However, in the inter-network connection device described in Patent Document 1, since the TTL value of the IPv4 header is 8 bits, the load test packet loops only a maximum of 255 times in the loop transfer path. If the difference between the transfer processing capacity and the packet transfer processing capacity of the CPU is 255 times or more, the transmitted packet ends the loop before the CPU transmits the next packet. It becomes only a packet and the load cannot be increased. Therefore, as a main signal, there is a problem that the load between the packet transfer processing capability in the apparatus and the packet transmission / reception capability of the CPU can only be a load of 255 times or less.

  Therefore, the present invention has been made in view of the above problems in the prior art, and even if the difference between the packet transfer processing capability in the device and the packet transmission / reception capability of the CPU is more than 255 times, It is an object of the present invention to provide a main signal load test apparatus and a test method capable of performing a load test.

  In order to achieve the above object, the present invention is a main signal load test apparatus, which is a line termination unit that converts received packets into signals that can be processed, and a load monitoring unit that measures the transfer rate of packets that flow as main signals. A core switch unit that determines a port to be transferred from packet information received via the line termination unit, and a port that transmits the packet to the port determined by the core switch unit and that is to be transferred by the core switch unit. A CPU unit that compares a transmitted packet with a received packet for a packet that cannot be determined is provided.

  According to the present invention, packet transmission is repeated until a predetermined load is applied, and the transmitted packet is loop-transferred between the line termination unit and the core switch unit, and the CPU unit transfers only a specific packet to the CPU. By instructing to transfer the packet, the received packet is checked against the transmitted packet to confirm whether the packet has been transferred normally. For this reason, the main signal load test can be performed by performing packet transmission and reception at a timing suitable for the packet transmission / reception capability of the CPU, and regardless of the packet transmission / reception capability of the in-device CPU unit, A load test can be performed.

  In the main signal load test apparatus, the core switch unit is configured to include a search table for determining a port to transfer a packet that matches the search condition, and when there is a packet that satisfies the condition in the search table When the packet is transferred to a predetermined port and there is no packet that satisfies the condition in the search table, the packet can be transferred to the CPU unit.

  The present invention is also a main signal load test method, which converts a received packet into a processable signal, loop-transfers the packet converted into the processable signal, and the number of packets being loop-transferred. When the packet transferred in a loop reaches a predetermined transfer rate, the transfer rate of the packet that flows as the main signal is measured, and the received packet and the transmitted packet are collated for a specific packet. And

  According to the present invention, packet transmission is repeated until a predetermined load is applied, and after the predetermined load is applied, the transmitted packet is compared with the received packet to confirm whether or not the packet is normally transferred. Therefore, the main signal load test can be performed with the maximum load regardless of the packet transmission / reception capability of the CPU unit in the apparatus.

  As described above, according to the present invention, even when the difference between the packet transfer processing capability in the device and the packet transmission / reception capability of the CPU is 255 times or more, a load test in the device can be performed.

  FIG. 1 shows a case where an embodiment of a main signal load test apparatus according to the present invention is applied to a router. The main signal load test apparatus includes a CPU unit 11 and a core switch unit 12 including a search table 14. The line termination unit 13 and the load monitoring unit 15 are configured.

  The CPU unit 11 performs processing for a packet for which the port to be transferred by the core switch unit 12 cannot be determined, a specific packet, or the like.

  The core switch unit 12 determines a transfer port from the received packet information. The core switch unit 12 includes a search table 14 that determines to which port a packet that matches the search condition as shown in FIG. The packet received by the core switch unit 12 is searched for whether or not there is a condition in the search table 14 and transferred to a port that satisfies the condition. If none of the conditions in the search table 14 is satisfied, the packet is transferred to the CPU unit 11 and how it is processed by the CPU unit 11 is determined.

  The line termination unit 13 converts a packet received from the line into a signal that can be processed in the apparatus. Also, a process of converting the packet in the apparatus into a signal to the line is performed. Further, the load monitoring unit 15 measures the transfer rate of a packet that flows as a main signal.

  Next, the operation of the main signal load test apparatus having the above configuration will be described. First, how to apply a load to the main signal will be described with reference to FIG. It is set back to the line termination unit 13 so that the packet is loop-transferred between the line termination unit 13 and the core switch unit 12. That is, the CPU table 11 is set in the search table 14 in the core switch unit 12 so as to be forwarded to a specific port with respect to the condition (for example, destination address) of the transmission packet.

  After the setting, the CPU unit 11 transmits a packet that satisfies the search condition to the core switch unit 12. When the core switch unit 12 receives a packet from the CPU unit 11, the core switch unit 12 performs a search using the search table 14 in order to determine a transfer port. Here, since the previously set condition is satisfied, the port to be transferred is determined, and the packet is transferred to that port.

  The packet transferred from the core switch unit 12 reaches the line termination unit 13. Since the line termination unit 13 is set to be turned back, the packet transferred from the core switch unit 12 is turned back at the line termination unit 13 and transferred to the core switch unit 12 again. Since the core switch unit 12 determines the transfer port again, the search table 14 is searched, and the same port becomes the transfer port and is transferred to the line termination unit 13 of the same port. Since this transfer is repeated, the packet continues to loop between the core switch unit 12 and the line termination unit 13.

  Further, the search table 14 in the core switch unit 12 is set to forward to the same port under different conditions from the previous one, and the CPU unit 11 transmits a packet satisfying this condition to the core switch unit 12. The transmitted packet is transferred to the same port as the packet transferred first by the search table 14 of the core switch unit 12. As a result, two packets are looped. By repeating this, the number of packets that are loop-transferred between the core switch 12 and the line termination unit 13 is increased, and the transfer load of the main signal is increased. When the packet transferred into the load monitoring unit 15 reaches a predetermined transfer rate, the transmission load of the main signal can be adjusted by stopping the transmission of the packet from the CPU unit 11.

  Next, a method for confirming the normality of the transferred packet will be described with reference to FIG. After a predetermined time has passed, the packets transferred in the loop are verified. First, the core switch unit 12 deletes the search condition for the packet whose normality is to be checked from the search table 14. Then, when a specific packet that is loop-transferred between the core switch unit 12 and the line termination unit 13 is transferred to the core switch unit 12, there is no condition that satisfies the condition when being searched in the search table 14. Therefore, the transfer port is not determined. For this reason, the packet is transferred to the CPU unit 11, and the normality of the transferred packet can be confirmed by the CPU unit 11 comparing the received packet with the transmitted packet. Further, by repeating the same process for other packets, the normality of all the transfer packets can be confirmed.

  Next, an embodiment of the main signal load test apparatus according to the present invention will be described. First, an embodiment in which a main signal transfer load is applied will be described with reference to FIG. The CPU unit 11 makes a loopback setting to the line termination unit 13 of the port that performs the main signal load test. In this embodiment, the main signal load test is performed on the port 1. Next, a search condition and a transfer port are set in the search table 14 of the core switch unit 12. As a search condition in this embodiment, the destination address A is set and the transfer port 1 is set.

  After the setting, the CPU unit 11 transfers the packet whose destination address is A to the core switch unit 12. When receiving the packet from the CPU unit 11, the core switch unit 12 searches whether the destination address A of the received packet is in the search condition of the search table 14. Here, since the previous destination address A is set as the search condition, the core switch unit 12 obtains the transfer port 1 from the matched search condition, and transfers the packet to the line termination unit 13 of the port 1. Since the packet that has reached the line termination unit 13 is set to return, it is transferred to the core switch unit 12 again.

  The core switch unit 12 searches again whether the destination address A is in the search condition of the search table 14, obtains the transfer port 1 from the matched search condition, and transfers it to the line termination unit 13 of the port 1 again. Since this operation is repeated, the packet of the destination address A transferred from the CPU unit 11 is transferred between the core switch unit 12 and the line termination unit 13 of the port 1.

  The CPU unit 11 further sets the transfer port 1 using the destination address B as a search condition in the search table 14 of the core switch unit 12. The packet of the destination address B is transferred from the CPU unit 11 to the core switch unit 12. The core switch unit 12 receives the packet of the destination address B from the CPU unit 11 and searches the search table 14 for matching search conditions. Here, since the destination address B is set as a search condition, the packet is transferred to the transfer port 1. Similarly to the packet of the destination address A, the packet of the destination address B is returned from the line termination unit 13 of the port 1 and transferred to the core switch unit 12 again. As a result, two packets of destination addresses A and B are transferred between the core switch unit 12 and the line termination unit 13 of the port 1.

  Similarly, the transfer port 1 is set as a search condition in the search table 14 in the order of destination addresses C, D, E, and F, and the packet is transmitted from the CPU unit 11, so that the core switch unit 12 and the line termination unit of the port 1 are transmitted. Destination addresses A, B, C, D, E, and F are transferred to and from 13, and the transfer load of the main signal between them increases. When the packet transfer rate reaches the load test transfer rate, the load monitoring unit 15 stops packet transmission from the CPU unit 11. FIG. 2 shows the setting status of the search table 14 when packets A to F are transmitted.

  Next, a description will be given of an embodiment in which packets being transferred are collated from the above state. Packets of destination addresses A, B, C, D, E, and F are transferred between the core switch unit 12 and the line termination unit 13 of the port 1. The search table 14 is set as shown in FIG. In order for the CPU unit 11 to collate the packet with the destination address A, the one with the search condition of the destination address A is deleted from the search table 14 of the core switch unit 12.

  Then, the packet of the destination address A that has reached the core switch unit 2 is searched in the search table 14, but since the destination address A has already been deleted from the search condition, the core switch unit 12 The transfer port cannot be determined. Therefore, the core switch unit 12 transfers the packet of the destination address A to the CPU unit 11 as shown in FIG. The CPU unit 11 receives the packet of the destination address A and collates it with the packet at the time of transmission.

  Next, in order to collate the packet with the destination address B, the one with the search condition of the destination address B is deleted from the search table 14 of the core switch unit 12. Similarly, when the packet of the destination address B reaches the core switch unit 12, since there is no search condition matching the search table 14, the core switch unit 12 cannot determine the transfer port, and the packet is stored in the CPU unit 11. Forwarded to The CPU unit 11 collates the received packet of the destination address B with the transmitted packet. By collating C, D, E, and F in the same manner, it is possible to collate all transmitted packets.

  Next, another embodiment of the main signal load testing apparatus according to the present invention will be described with reference to FIG. In this embodiment, the load test is performed not only in the apparatus but also between connected routers.

  The CPU unit 11 of the router 1 transmits a packet to the core switch unit 12. The core switch unit 12 determines a transfer port from the search table 14 and transfers it to the line termination unit 13. The line termination unit 13 converts the signal into a line signal, transmits the packet to the line, and is received by the router 3. If the packet received by the router 3 is a packet from the router 3 to the router 1 again, the line termination unit 13 of the router 1 receives the packet and transfers it to the core switch unit 12.

  In the core switch unit 12, loop path transfer is performed between the router 1 and the router 3 in order to transfer to the same port from the search table. When a similar packet is transmitted from the CPU unit 11, the number of transfer packets increases between the router 1 and the router 3, which increases the transfer load of the main signal. The load monitoring unit 15 monitors the transfer rate between the router 1 and the router 3, and when reaching a predetermined transfer rate, the CPU unit 11 stops the packet transmission.

  As for the method for confirming the normality of the transferred packet, as in the first embodiment, by deleting the search condition of the packet to be collated from the search table 14 of the core switch unit 12, the core switch unit 12 The arrived packet is transferred to the CPU unit 11. Normality can be confirmed by comparing the packet received by the CPU unit 11 with the transmitted packet.

  In the example shown in FIG. 4, the load test is performed between the two routers 1 and 3, but the packet transmitted by the CPU unit 11 of the router 1 returns to the core switch unit 12 of the router 1 again. With such a configuration, it is possible to perform a load test regardless of how many routers are connected.

It is a figure which shows the flow of the packet at the time of the test packet transmission in one Embodiment of the main signal load testing apparatus concerning this invention. It is a figure which shows the example of a setting of the search packet in the main signal load test apparatus of FIG. It is a figure which shows the flow of the packet at the time of the test packet collation in the main signal load test apparatus of FIG. It is a figure which shows the load test block diagram between two routers of the main signal load test apparatus concerning this invention, and the flow of a packet. It is a figure which shows the structure of an example of the conventional main signal load test apparatus, and the flow of a packet. It is a figure which shows the flow of the packet at the time of the test packet transmission in the main signal load test apparatus of FIG. It is a figure which shows the flow of the packet at the time of the test packet collation in the main signal load test apparatus of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Router 2 Measuring device 3 Router 11 CPU part 12 Core switch part 13 Line termination part 14 Search table 15 Load monitoring part

Claims (3)

A line terminator that converts received packets into processable signals;
A load monitoring unit that measures the transfer rate of a packet that flows as a main signal;
A core switch unit that determines a port to be transferred from packet information received via the line termination unit;
A CPU unit that transmits the packet to a port determined by the core switch unit, and that collates the transmitted packet with the received packet for a packet for which the port to be transferred cannot be determined by the core switch unit; A main signal load test apparatus characterized by the above. The core switch unit includes a search table for determining a port to transfer a packet that matches a search condition,
When there is a packet that satisfies the condition in the search table, the packet is transferred to a predetermined port, and when there is no packet that satisfies the condition in the search table, the packet is transferred to the CPU unit. The main signal load testing apparatus according to claim 1. Convert received packets into processable signals,
Loop-transferring the packet converted into the processable signal, increasing the number of packets being loop-transferred,
A main signal characterized in that when a packet transferred in a loop reaches a predetermined transfer rate, a transfer rate of a packet flowing as a main signal is measured, and a received packet and a transmitted packet are collated with respect to a specific packet. Load test method.

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