KR101074465B1 - Method and apparatus for controlling traffic by cooperating with peer - Google Patents

Abstract

The server of the first network receives the amount of traffic transmitted and received for a predetermined time from the peers of the first network and the information on the at least one peer, and based on the received information, the amount of available traffic of the predetermined link is determined. A method and apparatus are disclosed for controlling traffic to allow peers of a first network to transmit and receive data over an optimal link with an optimal peer by calculating.

P2P, traffic, control

Description

Method and apparatus for controlling traffic by cooperating with peer}

The present invention relates to a method and apparatus for controlling traffic, and more particularly, to a method and apparatus for controlling traffic in a P2P network.

Peer-to-peer (P2P) network refers to an over-lay network composed of peers with equal qualifications for the purpose of sharing distributed resources, away from the conventional server and client concept. In the client-server based network, since the server must provide services to all clients on the network, a resource bottleneck occurs and it is impossible to guarantee sufficient quality of service (QoS) for all clients. To solve this problem, in peer-to-peer networks, all peers on the network act as client and server simultaneously as equivalent network entities without the concept of client / server.

Aside from client-server based networks, various algorithms have been developed to control traffic of P2P networks in order to more efficiently achieve the distribution and sharing of network resources, which is the original purpose of P2P networks.

The present invention has been made in an effort to provide a method and apparatus for controlling traffic in a P2P network, and to provide a computer-readable recording medium having recorded thereon a program for executing the method.

According to an aspect of the present invention, a method of controlling a traffic of a predetermined link by a server of a first network according to an embodiment of the present invention includes an amount of traffic transmitted and received for a predetermined time from peers of the first network and at least one of Receiving information about the peer of the peer; Calculating for each of at least one external network the amount of available traffic of the given link based on the received information; And transmitting the calculation result to peers of the first network.

According to another embodiment of the present invention, the calculating step further includes calculating information on the preference for the predetermined link based on the utilization rate of the predetermined link.

According to another embodiment of the present invention, the calculating step includes calculating an amount of total available traffic of the predetermined link based on the received information; And the total amount of available traffic on the given link, the overall probability that traffic will occur from the first network to at least one external network over the given link, and the traffic from the first network to the second network over the given link. Calculating an amount of traffic of the predetermined link that is available for traffic from the first network to the second network based on the probability of this occurrence.

According to another embodiment of the present invention, the amount of traffic of the predetermined link available for traffic from the first network to the second network, T ₁₂ is T ₁₂ = T _A * (P _T12 / P _TA ) T _A is a total amount of available traffic of the predetermined link, P _T12 is a probability that traffic occurs from the first network to the second network through the predetermined link, and P _TA is determined by the predetermined link. It is characterized in that the overall probability that the traffic from the first network to at least one external network.

According to another embodiment of the present invention, the probability that traffic occurs on the predetermined link from the first network to the second network, P _T12 is P _T12 = (N _P1 * N _P2 ) / (N _P1 + N _P2 N _P1 is the number of peers of the first network, and N _P2 is the number of peers of peers of the first network existing in the second network.

According to another embodiment of the present invention, the overall probability that traffic occurs on the predetermined link from the first network to at least one external network, P _TA is P _TA = P _T12 + P _T13 + ... + P _T1k P _T1k is a probability that traffic occurs over the predetermined link to a k-th network, which is a first network and an external network.

According to another embodiment of the present invention, calculating the total amount of available traffic of the predetermined link based on the received information may be based on the received information of the server during the predetermined one of the traffic of the predetermined link based on the received information. Calculating an amount of traffic that did not follow guidance; Estimating the amount of traffic that does not follow the guidance of the server based on the calculated amount of traffic that did not follow the guidance of the server; And subtracting the prediction result from the capacity of the total traffic of the given link to calculate the total amount of available traffic of the given link.

An apparatus for controlling traffic of a predetermined link of a server of a first network according to an embodiment of the present invention for solving the technical problem is an amount and at least one of the traffic transmitted and received for a predetermined time from the peers of the first network Traffic information receiving unit for receiving information on the peer of the; A traffic calculator for calculating, for each of at least one external network, the amount of usable traffic of the given link based on the received information; And a traffic information transmitter for transmitting the calculation result to peers of the first network.

In order to solve the above technical problem, an embodiment of the present invention provides a computer-readable recording medium having recorded thereon a program for executing the above traffic control method.

Hereinafter, with reference to the drawings will be described embodiments of the present invention;

1 is a flowchart illustrating a traffic control method according to an embodiment of the present invention.

Referring to FIG. 1, in step 110, the peers 11 of the first network transmit information on the amount of traffic and information on a counterpart peer to the server 10 of the first network. The server 10 is a guidance server that provides the peers of the first network with guidance information for selecting an optimal peer and an optimal link. An ISP (Internet Service Provider) is connected to its network. It may be a server operating to provide guidance information to peers. The first network may be a network distinguished from other networks by an IP prefix.

A P2P network is an overlay network that resides on a physical network connection that can be distinguished by its IP prefix. Therefore, when a peer of the first network connects to a peer of another network outside and transmits and receives data, traffic between networks may occur. Therefore, the issue of efficiently distributing and sharing network resources by controlling traffic between different networks more efficiently is particularly important in recent years, in which ISPs are the main agents to efficiently control traffic generated from the first network to the external network. Technologies are being developed.

However, if the ISP alone controls the traffic without the cooperation of peers, the traffic of the P2P network cannot be efficiently controlled because the traffic cannot be controlled according to the accurate information about the traffic occurring between the peers.

Accordingly, the present invention provides an IPS (Informed Peer Selection) method in which the server 10 controls the traffic of the P2P network based on the cooperation of the peers. For this purpose, in step 110, the peers determine the amount of traffic they are generating. It provides the server 10 with information about and information about itself and the peer peer connected via the P2P network. The peer information may be IP addresses of all peers connected to the peer 11 themselves and the P2P network and capable of transmitting and receiving data.

In addition, the information on the amount of traffic and the information on the counterpart peer may be information on the amount of traffic during the predetermined period T and information on the counterpart peer. By providing the server 10 with information about the amount of traffic and information about the peer of the peer at each predetermined period T, the server 10 can perform traffic control in units of a predetermined period T.

In step 120, the server 10 processes the traffic information based on the information on the amount of traffic received from the peers 11 of the first network and the information on the other peer in step 110.

The server 10 may collect information on traffic of a link managed by the server 10 through exchange of a Simple Network Management Protocol (SNMP) message with a network device (for example, a router) inside the first network. Accordingly, in step 120, the server 10 processes the traffic information to control traffic of the link managed by the server 10 based on the information collected by the server 10 and the information received from the peers 11 in step 110.

The server 10 calculates for each external network the amount of available traffic of the given link based on the information received in step 110. This will be described in detail with reference to FIG. 2.

2 illustrates at least one network in which traffic occurs over a given link in accordance with one embodiment of the present invention.

Referring to FIG. 2, peers of the first network 210 communicate data with peers of the external network 220 through 240 through link A managed by a server (eg, a guidance server) of the first network 210. Send and receive

The server 10 of the first network 210 calculates the amount of available traffic of the link A for each of the external networks 220 to 240 based on the information received from the peers 11 in step 110. In other words, the total amount of available traffic of link A is divided and allocated to each of the external networks 220 to 240. The larger amount of traffic available on link A is allocated to the network that is more likely to generate traffic by communicating with a peer of the first network 210 of the external networks 220-240.

To do this, the server 10 first calculates the total amount of available traffic on link A. Since the processing of the traffic information and the generation of the guidance information are performed based on the predetermined period T described above, the server 10 adds all the traffic of peers generating traffic based on the guidance information of the server 10 to the predetermined period. The amount of traffic along the guidance is calculated first. The amount of traffic that did not follow the guidance is then calculated by subtracting the amount of traffic along the guidance from the total amount of traffic that occurred during the given period.

The total amount of traffic, T _G , generated during a predetermined period may be calculated by 'T _G = link utilization * link capacity * T'. Link capacity is the maximum amount of traffic that can be sent and received per unit time over link A. The link utilization rate is a ratio of the amount of traffic being used to the maximum amount of traffic, and is information that the server 10 can collect from the network equipment of the first network through the exchange of the above-described SNMP messages.

The amount of traffic along the guidance may be calculated based on the information on the amount of traffic received at step 110 and information on the peer of the server 10 at the server 10. In step 110, the traffic of the peers having transmitted the information about the amount of traffic and the peer information to the server 10 may be regarded as FMS traffic according to the guidance. Therefore, it is possible to calculate the amount of traffic that follows the guidance of the traffic transmitted and received through the link A for a predetermined period by adding all the traffic of the peers that transmitted the information.

Subtracting the amount of traffic along the guidance for a predetermined period from the total amount of traffic generated during a certain period, the amount of traffic not following the guidance for the predetermined period is calculated. From the amount of traffic that does not follow the guidance for a certain period, one can predict the amount of traffic that does not follow the guidance for the next period. Various algorithms for estimating the amount of traffic after the present from the amount of past traffic are readily apparent to those of ordinary skill in the art, so based on these algorithms the amount of traffic that does not follow the guidance for the next cycle Can be predicted.

If the amount of traffic that does not follow the guidance for the next period is predicted, then subtracting the prediction result from the maximum amount of traffic on link A calculates the total amount of available traffic on link A during the next period. The maximum amount of traffic on link A, T _MAX , can be calculated by 'T _MAX = link capacity * T'.

If the total amount of available traffic of link A, T _A, is calculated during the next period, server 10 allocates it for each of the external networks. As described above, more traffic is allocated to a network that is more likely to generate traffic with an external network. Taking the second network as an example, as shown in Equation 1, some of the total amount of available traffic of link A may be allocated for traffic from the first network 210 to the second network 220.

T ₁₂ = T _A * (P _T12 / P _TA )

T ₁₂ is the amount of traffic of link A available for traffic from the first network 210 to the second network 220 during the predetermined period, and T _A is the total available traffic of link A for the predetermined period as described above. Is the amount. P _T12 is the probability that traffic occurs from the first network 210 to the second network 220 via link A, and P _TA is the first network 210 to external networks 220 to 240 via link A. The overall probability that traffic will occur.

In the same manner as in Equation 1, the amount of available traffic of link A may be calculated for each of the external networks 230 and 240 other than the second network 220. Generalizing Equation 2, the amount of traffic of Link A available for traffic from the first network 210 to the kth network may be calculated as shown in Equation 2 below.

T _1k = T _A * (P _T1k / P _TA )

The probability of generating traffic may be calculated based on the number of peers of the first network 210 and the number of peers existing in the external networks 220 to 240. For example, if the number of peers of the first network 210 is N _P1, and the number of peers existing in the second network 220 among the peers of the peers of the first network 210 is N _P2 , P _T12 may be calculated as in Equation 3 below.

P _T12 = (N _P1 * N _P2 ) / (N _P1 + N _P2 )

According to Equation 3, as the number of counterpart peers in the second network 220 that peers of the first network 210 can communicate with, the probability that traffic from the first network 210 to the second network 220 occurs. Is higher. In the same manner as in Equation 3, the probability of generating traffic from the first network 210 to the third network 230 through the link A may be calculated, and the probability of generating traffic for all external networks 220 to 240. Can also be calculated. When all the probabilities of generating traffic for the external networks 220 to 240 are summed up, the probabilities of generating total traffic, P _TA , may be calculated as in Equation 4 below.

P _TA = P _T12 + P _T13 + ... + P _T1k

In Equation 4, P _T1k is a probability that traffic occurs from the first network 230 through the link A from the first network 230 to the k th network 240.

Referring back to FIG. 1, in step 120, the server 10 may also calculate a preference for each of the links managed by the server 10. As described above, the server 10 may calculate a link utilization rate for each of the links managed by the server 10 based on information received from peers and information collected from the network device through the exchange of SNMP messages. If the link utilization of a given link is already high, it is obvious that the amount of traffic is no longer available, so the link can set a lower preference, and if the link utilization is low, it is obvious that the amount of available traffic is large. The link can set a higher preference. For example, the preference of link A, PR _A may be calculated according to the utilization rate of PR _A = 1-link A.

In step 130, the server 10 generates guidance information including information about the amount of available traffic of the predetermined link and information about the preference calculated for each external network in step 120. Generate guidance information so that peers can select the best peer and link. Guidance information may be generated periodically every predetermined period.

In step 140, the server 10 transmits the guidance information generated in step 130 to peers of the first network. Only when explicitly requested to transmit the guidance information may be transmitted to the peers of the first network, even if there is no explicit request can be sent to the peers of the first network periodically every predetermined period.

In step 150, the peers of the first network select an optimal peer and link based on the guidance information received in step 140. The optimal counterpart peer may be selected based on the amount of available traffic of a given link calculated for each of the external networks. For example, if the amount of available traffic of link A calculated for the second network 220 is less than the amount of available traffic of link A calculated for the third network 230, the third network 230 is used. ) Can choose the peer of the peer.

It is also possible to select another link based on the preference. When the link A and the link B can transmit and receive data with a specific peer, if the link A has a high utilization rate because the link A is high, the peer may transmit and receive data with the peer.

3 shows a server controlling traffic according to an embodiment of the present invention.

3 may be a guidance server that controls traffic of a first network classified by an IP prefix as in the server 10 of FIG. 1.

Referring to FIG. 3, the server 300 according to an embodiment of the present invention includes a traffic information receiver 310, a traffic calculator 320, a preference calculator 330, and a guidance information transmitter 340. .

The traffic information receiver 310 receives information on the amount of traffic from peers of the first network and information on a peer of a peer connected through the P2P network.

The traffic calculator 320 calculates the amount of usable traffic of a predetermined link based on the information on the amount of traffic received from the peers of the first network and the information on the peer of the peer in the traffic information receiver 310. Compute the amount of available traffic on a given link for each of the at least one external network that includes peers.

According to the calculation method described above with reference to FIG. 2, the total amount of usable traffic of a given link is calculated, and the calculated total amount of usable traffic is assigned to each of the at least one external network.

The preference calculator 330 calculates link utilization for each of the links managed by the link based on information received from peers and information collected from the network equipment through the exchange of SNMP messages. Calculate the preference of each of the links based on that.

The guidance information transmitter 340 generates guidance information based on the calculation results of the traffic calculator 320 and the preference calculator 330, and transmits the generated guidance information to peers of the first network. Generate guidance information including information on the amount of available traffic of a given link for each external network calculated by the traffic calculator 320 and the preference calculated by the preference calculator 330 to generate peer information of the first network. send. Guidance information may be transmitted only when there is an explicit request from peers, or periodically, even when there is no explicit request.

4 illustrates a peer in accordance with an embodiment of the present invention.

Referring to FIG. 4, the peer 400 according to an embodiment of the present invention includes a traffic information transmitter 410, a guidance information receiver 420, and a traffic controller 430.

The traffic information transmitter 410 transmits the amount of traffic generated by the peer 400 and information on the peer of the peer connected through the P2P network to the server 300.

The guidance information receiver 420 receives the guidance information generated and transmitted by the server 300 based on the amount of traffic transmitted from the traffic information transmitter 410 to the server 300 and information about the peer. The guidance information is information for selecting an optimal peer and link, and may include information on the amount of available traffic of a predetermined link for each external network and information on the preference of a link managed by the server 300. have.

The traffic controller 430 selects an optimal peer and link based on the guidance information received from the guidance information receiver 420. When the peer and link of the other party are selected, data is transmitted and received according to the amount of available traffic determined by the guidance information.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited to the above-described embodiments, which can be modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications will fall within the scope of the invention. In addition, the system according to the present invention can be embodied as computer readable codes on a computer readable recording medium.

For example, a server and a peer according to an exemplary embodiment of the present invention may include a bus coupled to respective units of the apparatus as shown in FIGS. 3 and 4, and at least one processor coupled to the bus. Can be. It may also include a memory coupled to the bus for storing instructions, received messages or generated messages and coupled to at least one processor for performing instructions as described above.

The computer-readable recording medium also includes any type of recording device in which data that can be read by a computer system is stored. Examples of the recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and also include a carrier wave (for example, transmission through the Internet). The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

1 is a flowchart illustrating a traffic control method according to an embodiment of the present invention.

2 illustrates at least one network in which traffic occurs over a given link in accordance with one embodiment of the present invention.

3 shows a server controlling traffic according to an embodiment of the present invention.

4 illustrates a peer in accordance with an embodiment of the present invention.

Claims (11)

A method in which a server of a first network controls traffic of a predetermined link, Receiving information about at least one counterpart peer and an amount of traffic transmitted and received for a predetermined time from peers of the first network; Calculating for each of at least one external network the amount of available traffic of the given link based on the received information; And Transmitting the result of the calculation to peers of the first network, The calculating step, Calculating the total amount of available traffic of the given link based on the received information; And The total amount of available traffic on the given link, the overall probability of generating traffic from the first network to at least one external network over the given link, and the traffic from the first network to the second network over the given link Calculating an amount of traffic of the predetermined link available for traffic from the first network to the second network based on a probability of occurrence. The method of claim 1, wherein the calculating And calculating information on a preference for the predetermined link based on the utilization rate of the predetermined link. delete The method of claim 1, wherein the amount of traffic of the predetermined link available for traffic from the first network to the second network, T ₁₂ is T ₁₂ = T _A * (P _T12 / P _TA ) T _A is a total amount of available traffic of the predetermined link, P _T12 is a probability that traffic occurs from the first network to the second network through the predetermined link, and P _TA is determined by the predetermined link. Traffic control method, characterized in that the overall probability of generating traffic from the first network to at least one external network. 5. The method of claim 4, wherein the probability that traffic occurs on the predetermined link from the first network to the second network, P _T12 is P _T12 = (N _P1 * N _P2 ) / (N _P1 + N _P2 ) N _P1 is the number of peers of the first network, and N _P2 is the number of peers of peers of the first network existing in the second network. The method of claim 4, wherein the overall probability that the traffic occurs on the predetermined link from the first network to at least one external network, P _TA is P _TA = P _T12 + P _T13 + ... + P _T1k And P _T1k is a probability of generating traffic through the predetermined link from a first network to a k-th network, which is an external network. 2. The method of claim 1, wherein calculating the total amount of available traffic on the given link based on the received information Calculating an amount of traffic of a predetermined link based on the received information that did not follow the guidance of the server during the predetermined time; Estimating the amount of traffic that does not follow the guidance of the server based on the calculated amount of traffic that did not follow the guidance of the server; And Subtracting the prediction result from the maximum amount of traffic on the predetermined link to calculate the total amount of available traffic on the predetermined link. An apparatus for controlling traffic of a predetermined link of a server of a first network, the apparatus comprising: A traffic information receiver for receiving the amount of traffic transmitted and received for a predetermined time from peers of the first network and information on at least one counterpart peer; A traffic calculator for calculating, for each of at least one external network, the amount of usable traffic of the given link based on the received information; And A guidance information transmitter for transmitting the calculation result to peers of the first network; The traffic calculation unit, Calculate the total amount of available traffic on the given link based on the received information and generate traffic from the first network to at least one external network over the given link. The amount of traffic on the given link available for traffic from the first network to the second network based on the overall probability of occurrence and the probability of traffic from the first network to the second network on the given link. Traffic control apparatus, characterized in that the calculation. The method of claim 8, And a preference calculator configured to calculate information on a preference for the predetermined link based on the utilization rate of the predetermined link. delete A computer-readable recording medium having recorded thereon a program for executing the method of any one of claims 1, 2, and 4-7.

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