KR20130085489A - Method and apparatus for blocking the search for the website - Google Patents

Abstract

PURPOSE: A high available static multi-cast routing method and a system for the same are provided to adequately route a multi-cast packet although a highly available routing system operates in an active-active mode. CONSTITUTION: A plurality of routers (110,120) has high availability by forming one group. The routers operate in an active-active mode. A first switch (130) connects an external network with the routers. A second switch (140) connects the routers with at least one host. One of the routers is selected as a multi-cast packet forwarder and routes a multi-cast packet. [Reference numerals] (110) Router 1; (120) Router 2; (130) Switch 1; (140) Switch 2; (180) Transmitter; (190) Receiver; (AA) HA slave; (BB) HA master

Description

High availability static multicast routing method and system {METHOD AND APPARATUS FOR BLOCKING THE SEARCH FOR THE WEBSITE}

The present invention relates to a high availability static multicast routing technology, and more particularly, to a high availability static multicast routing for processing multicast packets normally when a plurality of routers form a group to operate in an active-active mode. A method and system are disclosed.

Multicast transmission is a technology that sends data to multiple recipients at once without sending information to the receiver. Multicasting, unlike one-to-one unicasting, can transmit and receive data with many receivers at once, and is widely used for transmitting multimedia data such as Internet broadcasting service, distance education, games, simulation, video conference, and real-time news transmission. Multicast can only send to specific hosts that you want to receive data from, but your switch or router must support this feature. The router receives the data packet with the destination address and forwards the data packet through the path that can be reached most quickly to the destination address. Static multicast routing is a method in which an administrator adds routing information to forward only multicast packets matching the routing information. High Availability (HA) static multicast routing system that groups multiple devices to provide nondisruptive service and load balancing. When the system operates in active-active mode, the same static multicast routing is set up for all devices in the group. If so, there is a problem that a plurality of identical multicast packets are forwarded toward the output interface. Accordingly, there is a need for a method for properly routing multicast packets even when the high availability static multicast routing system operates in an active-active mode.

Provided are a high availability static multicast routing method and system capable of properly routing multicast packets even when the high availability routing system operates in an active-active mode.

In a high availability static multicast routing method according to an embodiment of the present invention, a multicast packet forwarder is connected to one of the plurality of routers in a high availability routing system in which a plurality of routers form a group to operate in an active-active mode. And adding multicast routing information to the routing table of the multicast packet forwarder.

The high availability static multicast routing system according to another embodiment of the present invention forms a group for high availability and connects a plurality of routers operating in an active-active manner, a first network and the plurality of routers. And a second switch connecting the first network and the second network and the plurality of routers, wherein one of the plurality of routers is selected as a multicast packet forwarder to route the multicast packets.

According to the present invention, multicast packets can be properly routed even when the high availability routing system operates in an active-active mode.

BRIEF DESCRIPTION OF THE DRAWINGS A brief description of each drawing is provided to more fully understand the drawings recited in the description of the invention.
1 illustrates a high availability static multicast routing system and one operating state in accordance with an embodiment of the present invention.
FIG. 2 illustrates the high availability static multicast routing system 100 and other operating states shown in FIG. 1.
FIG. 3 shows the high availability static multicast routing system 100 shown in FIG. 1 and another operational state.
4 illustrates a high availability static multicast routing system and one operating state according to another embodiment of the present invention.
FIG. 5 illustrates the high availability static multicast routing system 400 and other operating states shown in FIG. 4.
FIG. 6 illustrates the high availability static multicast routing system 400 shown in FIG. 4 and another operational state.
7 illustrates a high availability static multicast routing method according to another embodiment of the present invention.
FIG. 8 illustrates one embodiment of the selecting step S710 shown in FIG.
FIG. 9 illustrates another embodiment of the selecting step S710 shown in FIG. 7.
FIG. 10 illustrates another embodiment of the selecting step S710 illustrated in FIG. 7.

In order to fully understand the present invention, operational advantages of the present invention, and objects achieved by the practice of the present invention, reference should be made to the accompanying drawings and the accompanying drawings which illustrate preferred embodiments of the present invention.

Embodiments of the present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which exemplary embodiments of the invention are shown. These embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. The present invention is not limited to these embodiments. Rather, these embodiments are provided so that this disclosure will be more thorough and complete, and will fully convey the concept of the invention to those skilled in the art to which the present invention pertains.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 illustrates a high availability static multicast routing system and one operating state in accordance with an embodiment of the present invention. Referring to FIG. 1, a high availability static multicast routing system 100 includes a first router 110, a second router 120, a first switch 130, and a second switch 140. The first router 110 and the second router 120 operate in an active-active mode, respectively. Thus, the high availability static multicast routing system 100 can support load balancing with non-disruptive services. The first router 110 may initially be in a master state (HA master), and the second router 120 may initially be in a slave state (HA slave). Subsequently, when the first router 110 fails to operate normally, the first router 110 is changed to a backup state, and the second router 120 is changed to a master state. The first router 110 and the second router 120 may exchange hello packets through the HA link 170 to enable the switching operation. When the failure is resolved, the first router 110 may fail back to the master state. The first switch 130 and the second switch 140 may be L2 switches or L3 switches, respectively. The first switch 130 connects the first router 110 and the second router 120 with the external network through the external link 150, and the second switch 140 connects the first router 110 and the second. Router 120 may be connected to receiver 190 via internal link 160. The high availability static multicast routing system 100 supports multicast routing. When the first router 110 and the second router 120 operate in an active-active mode, only one of the first router 110 and the second router 120 is configured to forward the multicast packet. That is, only one of the first router 110 and the second router 120 is selected as the multicast packet forwarder. The multicast packet may be a UDP packet in which a multicast group is set as a destination.

The high availability static multicast routing system 100 may select a multicast packet forwarder in the following manner. First, when the high availability static multicast routing system 100 uses the virtual IP, the router to which the virtual IP is assigned may be selected as the multicast packet forwarder. When the high availability static multicast routing system 100 uses the virtual IP, the first router 110 and the second router 120 share a single virtual IP. However, the first router 110 and the second router 120 does not have the one virtual IP at the same time. In the case where the first router 110 and the second router 120 share one virtual IP, the first router 110 and the second router 120 recognize the first router 110 and the second router 120 as one single router. The high availability static multicast routing system 100 utilizes virtual IPs vip0 and vip1. In detail, one of the first router 110 and the second router 120 has an input port eth0 (2.2.2.10) and an output port eth1 (1.1.1.10), respectively, for the virtual IP vip0 (2.2.2.11) and vip1 (1.1. 1.11). When the high availability static multicast routing system 100 is operating normally, the virtual IP is assigned to the first router 110. Therefore, the first router 110 is selected as the multicast packet forwarder, and forwards the multicast packet. Then, when a failure occurs and the first router 110 cannot act as a multicast packet forwarder, the second router 120 receives the virtual IP address and takes over the role of the multicast packet forwarder. As a protocol for controlling virtual IP, VRRP (Virtual Router Redundancy Protocol) and HSRP (Hot Standby Routing Protocol) are well known. Meanwhile, the high availability static multicast routing system 100 forms a group with a plurality of routers as described above to realize uninterrupted service and load balancing. In this case, the plurality of routers may take the master state or the slave state according to the priority. For this purpose, a plurality of routers communicate by exchanging hello packets. If a hello packet is not received from the router in the master state within a certain time, it is determined that the router in the master state has failed, and the router in the slave state changes to the master state and operates. The high availability static multicast routing system 100 may select a router in a master state among the plurality of routers as a multicast packet forwarder. Referring to FIG. 1, the router in the master state (HA master) is the first router 110. Therefore, the first router 110 is selected as the multicast packet forwarder, and forwards the multicast packet. In summary, the high availability static multicast routing system 100 selects a multicast packet forwarder according to whether the first master 110 and the second master 120 have a virtual IP or not. In addition, the two criteria may be applied together. That is, the high availability static multicast routing system 100 selects a multicast packet forwarder according to whether the virtual IP is held when using the virtual IP, and multicast packet forwarder according to the master state when the virtual IP is not used. Can be selected. The high availability static multicast routing system 100 may be configured to add multicast routing information to a routing table of a router selected as a multicast packet forwarder. The first router 110 and the second router 120 may have multicast routing information 112, respectively. Multicast routing information 112 may include an input port, an output port, a source IP, and a multicast group. Multicast group means the IP address pertaining to class D itself. Accordingly, the multicast routing information 112 is added to the routing table 114 of the first router 110 that is the multicast packet forwarder. On the other hand, the routing table 124 of the router other than the multicast packet forwarder is configured such that the multicast routing information 112 is not included. Therefore, the multicast routing information 112 does not exist in the routing table of the second router 120. If the routing information 112 is included in the routing table of the second router 120, the routing information 112 is deleted. Since the routing table 114 of the first router 110 among the first router 110 and the second router 120 includes the multicast routing information 112, only the first router 110 receives the multicast packet. Will be routed. The high availability static multicast routing system 100 can properly route multicast packets even when operating in an active-active mode. Briefly describing the operation of the high availability static multicast routing system 100 shown in FIG. 1, the first router 110 is selected as a multicast packet forwarder according to the criteria described above, and multicasts to the routing table 114. Add routing information 112. The multicast packet having the source IP “210.10.10.10” and the multicast group “224.10.10.10” sent by the sender 180 is inputted to the first router 110 via the first switch 130, and the first router ( 110 forwards the multicast packet to receiver 190 based on routing table 114.

2 illustrates another operational state of the high availability static multicast routing system 100 shown in FIG. Referring to FIG. 2, a failure such as a shutdown occurs in the first router 210 of the high availability static multicast routing system 200 so that the second router 220 forwards the multicast packet. The high availability static multicast routing system 200 uses virtual IP, and the first router 210 and the second router 220 share the virtual IP. Therefore, a failure such as a shutdown occurs in the first router 210 and the second router 220 receives the virtual IP that the first router 210 has. In addition, the second router 220 does not receive a hello packet from the first router 210 due to the failure of the first router 210 such as a shutdown, and changes to a master state (HA master). 1 The router 210 is changed to the slave state (HA slave). As mentioned in the description of FIG. 1, the second router 220 is selected as a multicast packet forwarder and operates according to whether the virtual IP is retained or the master state is retained. Briefly describing the operation of the high availability static multicast routing system 200 shown in FIG. 2, the second router 220 is selected as a multicast packet forwarder according to the criteria described above, and multicasts to the routing table 214. Add routing information 222. Meanwhile, since the first router 210 was previously a multicast packet forwarder, the first router 210 includes the multicast routing information 222 in the routing table 214 and deletes it. The multicast packet having the source IP "210.10.10.10" and the multicast group "224.10.10.10" sent by the sender 280 is input to the second router 220 via the first switch 230, and the second router ( 220 forwards the multicast packet to receiver 290 based on routing table 214.

FIG. 3 shows another operational state of the high availability static multicast routing system 100 shown in FIG. 1. Referring to FIG. 3, a problem occurs in an internal link of the high availability static multicast routing system 300, and the second router 120 forwards the multicast packet. Unlike FIG. 2, the first router 310 itself does not have a failure, but the link between the first router 310 and the second switch 340 has failed. As an example of a failure in the link, an error may occur in the port eth1 of the first router 310 or the line may be disconnected. The high availability static multicast routing system 300 uses virtual IP, and the first router 310 and the second router 320 share the virtual IP. Therefore, due to a failure in the link between the first router 310 and the second switch 340, the second router 220 receives the virtual IP that the first router 210 has. Meanwhile, the second router 220 still maintains a slave state (HA slave) in a relation of normally receiving a hello packet from the first router 210. As mentioned in the description of FIG. 1, the second router 320 is selected and operated as a multicast packet forwarder according to whether or not a virtual IP is held. However, if the multicast packet forwarder is selected only by considering the master state, the first router 220 is selected. In this case, the high availability static multicast routing system 300 cannot normally perform multicast routing due to a failure occurring in the link between the first router 110 and the second switch 340. Therefore, when a link failure occurs as shown in FIG. 3, it is preferable to select a multicast packet forwarder according to whether or not a virtual IP is held. Briefly describing the operation of the high availability static multicast routing system 300 shown in FIG. 3, the second router 320 is selected as a multicast packet forwarder according to whether or not a virtual IP is held, and is multiplied in the routing table 314. Add cast routing information 322. Meanwhile, since the first router 310 was a multicast packet forwarder, the first router 310 includes the multicast routing information 322 in the routing table 314 and deletes it. The multicast packet having the source IP “210.10.10.10” and the multicast group “224.10.10.10” sent by the sender 380 is input to the second router 320 via the first switch 330, and the second router ( 320 forwards the multicast packet to receiver 390 based on routing table 314.

4 illustrates a high availability static multicast routing system and one operating state according to another embodiment of the present invention. Referring to FIG. 4, the high availability static multicast routing system 400 includes a first router 410, a second router 420, a third router 430, a first switch 440, and a second switch 450. ) And a third switch 460. Each of the first to third routers 410, 420, and 430 operates in an active-active mode. Thus, the high availability static multicast routing system 400 supports load balancing with non-disruptive services. The first router 410 may be initially in a master state (HA master), and the second router 420 and the third router 430 may be initially in a slave state (HA slave). Subsequently, when the first router 410 fails and normal operation is impossible, the first router 410 is changed to a backup state, and one of the second router 420 or the third router 430 is changed according to the priority. Can be changed to the master state. The third switch 460 connects the HA links of the first to third routers 410, 420, and 430 with each other so as to enable the switching operation. Hello packets may be exchanged over the HA link. When the failure is resolved, the first router 410 may fail back to the master state. The first to third switches 440, 450, and 460 may be L2 switches or L3 switches, respectively. The first switch 440 connects the first router to the third router 410, 420, and 430 with the sender 480 through an external network, and the second switch 450 connects the first router to the third router 410. , 420, 430 may be connected to the receiver 490. The high availability static multicast routing system 400 supports multicast routing. When the first to third routers 410, 420, 430 operate in an active-active mode, only one of the first to third routers 410, 420, 430 is configured to forward the multicast packet. That is, only one of the first to third routers 410, 420, and 430 is selected as the multicast packet forwarder. The high availability static multicast routing system 400 has three routers forming a group with the high availability static multicast routing system 100 of FIG. The only difference is that it is added. Thus, the high availability static multicast routing system 400 may select a multicast packet forwarder in a manner similar to the high availability static multicast routing system 100 shown in FIG. That is, the multicast packet forwarder is selected according to whether to hold a virtual IP or a master state. As a result, the first router 410 has a virtual IP and may be selected as a multicast packet forwarder. In addition, since the first router 410 has a master state, it may be selected as a multicast packet forwarder. A router selected as a multicast packet forwarder may add multicast routing information to a routing table. Accordingly, the first router 410 may add the multicast routing information 412 to the routing table 414. The second router 420 and the third router 430 have multicast routing information 412 but are not included in the routing tables 424 and 434. Briefly describing the operation of the high availability static multicast routing system 400 shown in FIG. Add routing information 412. The multicast routing information 412 is not included in the routing table 424 of the second router 420. The multicast packet having the source IP "210.10.10.10" and the multicast group "224.10.10.10" sent by the sender 480 is input to the first router 410 via the first switch 440, and the first router ( 410 forwards the multicast packet to receiver 490 based on routing table 414.

5 illustrates another operational state of the high availability static multicast routing system 400 shown in FIG. Referring to FIG. 5, a failure such as shutdown occurs in the first router 510 of the high availability static multicast routing system 500 so that the second router 520 forwards the multicast packet. The high availability static multicast routing system 500 has three routers forming a group with the high availability static multicast routing system 200 of FIG. The only difference is that it is added. Therefore, since description regarding FIG. 2 is enough, it does not demonstrate FIG. 5 separately. In conclusion, the high availability static multicast routing system 500 selects the second master 520 as a multicast packet forwarder according to whether virtual IP is retained or master state is retained. The second master 520 adds multicast routing information 512 to the routing table 514. Meanwhile, since the first router 510 was previously a multicast packet forwarder, the first router 510 includes the multicast routing information 512 in the routing table 514 and deletes it. The multicast routing information 512 is not included in the routing tables 514 and 534 of the first router 510 and the third router 530. The multicast packet having the source IP "210.10.10.10" and the multicast group "224.10.10.10" sent by the sender 480 is input to the second router 520 via the first switch 540 and the second router ( 520 forwards the multicast packet to receiver 590 based on routing table 514.

FIG. 6 illustrates another operational state of the high availability static multicast routing system 400 shown in FIG. 4. Referring to FIG. 6, a failure such as a shutdown occurs in the first router 610 of the high availability static multicast routing system 600, and additionally, a problem occurs in a link between the second router 620 and the second switch. If so, the third router 630 forwards the multicast packet. A case in which a failure such as a shutdown occurs in the first router 610 has been described in detail with reference to FIGS. 2 and 5, which will not be repeated here. In addition, since a link failure between the second router 620 and the second switch 650 has been described in detail in FIG. 3, it will not be repeated here. In conclusion, the high availability static multicast routing system 600 selects the third master 630 as a multicast packet forwarder according to whether a virtual IP is held. The third master 630 adds multicast routing information 612 to the routing table 614. Meanwhile, since the first router 610 or the second router 620 was previously a multicast packet forwarder, the first router 610 or the second router 620 includes the multicast routing information 612 in the routing tables 614 and 624 and deletes the multicast routing information 612. The multicast routing information 612 is not included in the routing tables 614 and 624 of the first router 610 and the second router 620. The multicast packet having the source IP "210.10.10.10" and the multicast group "224.10.10.10" sent by the sender 480 is input to the third router 630 via the first switch 640, and the third router ( 630 forwards the multicast packet to receiver 690 based on routing table 614. If the multicast packet forwarder is selected according to whether the master state is retained, the second router 620 may be selected, so that the high availability static multicast routing system 600 cannot normally perform multicast routing. Can cause.

7 illustrates a high availability static multicast routing method according to another embodiment of the present invention. Referring to FIG. 7, the high availability static multicast routing method is a method for supporting multicast routing in a high availability routing system in which a plurality of routers form a group to operate in an active-active mode. Selecting one of the multicast packet forwarders (S710), and adding multicast routing information to the routing table of the multicast packet forwarder (S720). Each of the plurality of routers may have multicast routing information. When the plurality of routers are selected as multicast packet forwarders, the multicast routing information may be added to the routing table. The high availability static multicast routing method may further include deleting multicast routing information from the routing table of routers other than the multicast packet forwarder among the plurality of routers (S730). Multicast routing information may include input ports, output ports, source IPs, and multicast groups.

8 to 10 illustrate embodiments of the selecting step S710 illustrated in FIG. 7. First, referring to FIG. 8, when the one of the plurality of routers is selected as a multicast packet forwarder (S710), when the plurality of routers share a virtual IP, the router to which the virtual IP is allocated is multicasted. The packet forwarder may be selected (S712).

Next, referring to FIG. 9, in operation S710, one of the plurality of routers may be selected as the multicast packet forwarder as the multicast packet forwarder. ).

Finally, referring to FIG. 10, selecting one of the plurality of routers as a multicast packet forwarder (S710) may include determining whether a high availability static multicast routing system uses virtual IP (S716), Determine if the first router is assigned a virtual IP if the high availability static multimaster routing system uses virtual IP, that is, if multiple routers in the high availability static multimass routing system share a single virtual IP (S717) and checking whether the first router is in a master state when the high availability static multicast routing system does not use the virtual IP (S718), and the first router has a virtual IP address or Or, if it has a master state, determining the multicast packet forwarder (S719).

As described above, an optimal embodiment has been disclosed in the drawings and specification. Although specific terms have been employed herein, they are used for purposes of illustration only and are not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100, 200, 300, 400, 500: High Availability Static Multicast Routing System
110, 210, 310, 410, 510, 610: first router
112, 212, 312, 412, 512, and 612: Static Multicast Routing Information
114, 214, 314, 414, 514, 614: Multicast Routing Table
120, 220, 320, 420, 520, 620: second router
430, 530, 630: third router
130, 230, 330, 440, 540, 640: first switch
140, 240, 340, 450, 550, 650: second switch
150, 250, 350, 472, 572, 672: external links
160, 260, 360, 474, 574, 674: internal links
170, 270, 370, 476, 477, 478, 576, 577, 578, 676, 677, 678: HA link
180, 280, 380, 480, 580, 680: sender
190, 290, 390, 490, 590, 690: Recipient

Claims (16)

In the static multicast routing method of a high availability routing system in which a plurality of routers form a group to operate in an active-active mode,
Selecting one of the plurality of routers as a multicast packet forwarder; And
And adding multicast routing information to the routing table of the multicast packet forwarder. The method of claim 1, wherein each of the plurality of routers
And having the multicast routing information, and adding the multicast routing information to a routing table when the multicast packet forwarder is selected. The method of claim 1,
And deleting the multicast routing information from a routing table of routers other than the multicast packet forwarder among the plurality of routers. The method of claim 1, wherein the multicast routing information is
A high availability static multicast routing method comprising an input port, an output port, a source IP, and a multicast group. The method of claim 1, wherein the selecting step
And when the plurality of routers share a virtual IP, selecting the router to which the virtual IP is assigned as the multicast packet forwarder. The method of claim 1, wherein the selecting step
And selecting a router in a master state among the plurality of routers as the multicast packet forwarder. The method of claim 1, wherein the selecting step
Determining whether a virtual IP is assigned to the high availability routing system; And
And determining a router to which the virtual IP is assigned as a multicast packet forwarder when the virtual IP is assigned. The method of claim 7, wherein the selecting step
And if the virtual IP is not assigned, determining a router in a master state among the plurality of routers as a multicast packet forwarder. A plurality of routers operating in an active-active manner by forming a group for high availability;
A first switch connecting the external network and the plurality of routers; And
A second switch connecting the plurality of routers with at least one host;
And wherein one of the plurality of routers is selected as a multicast packet forwarder and configured to route multicast packets. The method of claim 9, wherein each of the plurality of routers
And if selected as the multicast packet forwarder, add multicast routing information to a routing table. The method of claim 9, wherein each of the plurality of routers
And if not selected as the multicast packet forwarder, remove the multicast routing information from the routing table. 10. The method of claim 9, wherein the multicast routing information is
A high availability static multicast routing system comprising an input port, an output port, a source IP, and a multicast group. The method of claim 9,
And when the plurality of routers share a virtual IP, the router to which the virtual IP is assigned is configured to be selected as the multicast packet forwarder. The method of claim 9,
And a router in a master state among the plurality of routers is configured to be selected as the multicast packet forwarder. The method of claim 9,
And when the plurality of routers share a virtual IP, the router to which the virtual IP is assigned is configured to be selected as the multicast packet forwarder. The method of claim 15,
And a router in a master state of the plurality of routers is selected as the multicast packet forwarder when there is no router to which the virtual IP is assigned.

Images