KR101086834B1 - An Apparatus and a Method for Realizing Flow Control Based on Rate Restrict for MSTP Device - Google Patents

Abstract

The present invention provides an apparatus and method for implementing flow control based on rate limiting in an MSTP facility.

The present invention mainly performs the input / output flow control monitoring of the data flow using the Policing module, and when the data flow exceeds the flow control limit, it sends a flow control signal to the remote facility to reduce the input data flow, current equipment Avoid packet discard due to rate limiting Flow control monitoring for output data, service flow notation function, 2 layer pause frame port flow control of Ethernet and 3 layer specific service flow control can be implemented, and service damage caused by output queue congestion To prevent.

The present invention can ensure the uninterrupted transmission of packet-based service data flows over a network, provide service bandwidth detection and reporting, and satisfy specific service flow control requirements in MSTP transmission facilities of Ethernet services.

Network, MSTP, Data Flow, Multi Layer, Policing Module

Description

An Apparatus and a Method for Realizing Flow Control Based on Rate Restrict for MSTP Device}

The present invention relates to a multi-service transport platform (MSTP) transmission facility in a communication system, and more particularly, to an apparatus and method for implementing flow control based on a speed limit in an MSTP transmission facility.

In the data network of a communication system, the flow control function is one of frequently used functions. MSTP facilities support the reception of service data, such as Ethernet and ATM (Asynchronous Transfer Mode). In an Ethernet application, the MSTP facility may limit the speed to the input data and discard service data exceeding the bandwidth after the Ethernet data connected to the MSTP facility exceeds the negotiated speed; Alternatively, when Ethernet data connected to the MSTP facility is congested due to non-timely scheduling in the sending direction, flow control is implemented by sending a two-layer PAUSE flow control frame to a remote facility to prevent output queue congestion. do. In other words, data flow has two aspects as input flow monitoring and output queue monitoring in MSTP facilities.

When implementing first-in first-out (FIFO) or queue-based flow control using conventional flow control schemes, flow control of FIFO control supports service lossless processing. Generally, MAC FIFO is almost full or exit queue is Under almost cold conditions, send a flow control frame to the source port (the input port of the data flow). In the prior art, inlet flow monitoring may be on or off, i.e., there may be input speed limiting or no speed control in terms of speed limiting. In the presence of speed control, only bandwidth control can be implemented, and packets exceeding the bandwidth limit of the input data are discarded, resulting in service loss. And, the flow control mechanism and the speed limit are completely separate and have no relation to each other. Because speed control is implemented at the inlet and is not related between packet loss due to rate limiting and triggering of the flow control frame, it can cause damage to the service.

Currently used input rate limiting method damages the service, and cannot guarantee the integrity of service data.

The technical problem of the present invention is to solve problems such as packet discard processing due to exceeding the input data bandwidth limit and damage to the service by the situation, such as no relationship between the rate limit and the flow control frame, and solve the problem accurately and completely. An object of the present invention is to provide an apparatus and method for implementing flow control based on a speed limit in an MSTP facility that implements flow control to secure a service.

The present invention provides an apparatus for implementing flow control based on rate limiting in a multi-service transmission platform facility, and includes a data input module, a flow classification module, a polishing module, and a queue management connected according to the level order. / Including a scheduling module, a data output module and a management control module that controls and is connected to all of them.

The data input module is used for receiving an input data flow;

The flow classification module assigns a flow label to an input data flow according to the flow classification rule, determines a corresponding output queue, and transmits the flow label to the management control module, thereby sending the labeled data flow to the Policing module. Send to;

The management control module is configured to set the Policing control parameters according to the agreed rules, the speed control limit value used for the speed control and the flow control limit value used for the flow control;

The Policing module performs flow monitoring on the received data based on the flow label sent from the flow classification module and the agreement Policing parameter of the corresponding flow label sent from the management control module. Send a flow control frame to the remote facility node instructing to reduce the input data flow; If the output data flow is greater than the rate limiting threshold, discard the corresponding packet or mark the packet as rule violation data, and output the data flow to the queue management / scheduling module;

The queue management / scheduling module manages and schedules the received data, discards the packet indicated by the rule violation data, inserts the packet indicated by the normal data into a queue, processes it, transmits it to the corresponding output port, and outputs it;

The data output module is used to output a normal data flow according to the processing result of the queue management / scheduling module; It is characterized by.

In addition, the device is further advanced,

A data encapsulation and EOS processing module connected to the queue management / scheduling module, used to detect a situation of an SDH channel, and reporting SDH channel real-time bandwidth information of the VCG to a management control module when the number of members of a virtual connection VCG changes;

A flow control frame trigger module connected to the Policing module and triggering a corresponding flow control frame according to a monitoring result of a specific service flow label of the Policing module; And,

A MAC control module for completing outgoing / receiving control on the Ethernet interface of the packet; .

Further, the Policing control parameter set by the management control module is

A rate limiting threshold used for rate control, which includes a data rate Vd and a packet burst length Ld when deployed with a single bucket parameter, and a Vdmax / Ldmax and Vdmin / Ldmin when deployed with a double bucket parameter;

A flow control threshold used for flow control including a data rate Vc and a data burst length Lc that, when deployed with a single bucket parameter, trigger the flow control; And,

Among them, the burst length of all said packets must be greater than the maximum packet length that the data flow allows to pass.

Further, in the Policing module,

When the input data flow is less than or equal to the flow control threshold, stop sending the flow control frame indicating reduction of the input data flow to the remote facility node;

If the remote equipment does not respond to the flow control frame, flow monitoring is performed on the output data.

When the rate limit is configured with a single bucket parameter (Vd, Ld), if the output data flow is greater than the rate limit, Vd, the corresponding packet is discarded, or the packet is marked in red to indicate violation of the data. Otherwise, mark the packet as green to indicate normal data and output the data flow to the queue management / scheduling module;

When the speed limit limit is placed with the double bucket parameters Vdmax / Ldmax and Vdmin / Ldmin,

If the monitored service data flow does not violate the negotiated lower limit parameters (Vdmin, Ldmin), the packet is marked in green;

If the monitored service data flow exceeds the negotiated lower limit parameters (Vdmin, Ldmin) but does not exceed the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in yellow;

If the service data flow exceeds the negotiated high limit parameters (Vdmax, Ldmax), mark the packet in red or discard the packet directly;

The color notation of the packet is sent to the queue management / scheduling module.

Further, in the queue management / scheduling module,

There are two discard control parameters of the queue: half full low limit Lh and high limit Lf;

When processing received packets, received packets marked in red are discarded directly, and received packets marked in yellow / green are processed as follows according to the queue status.

When all packet capacity in the queue is less than the lower limit Lh of the queue, all packets enter the queue;

When all the packet capacity in the queue is greater than the low limit Lh of the queue and less than the high limit Lf of the queue, packets marked in green enter the queue and packets marked in yellow are discarded;

When all packet capacity in the queue is greater than the high limit Lf of the queue, all newly received packets are discarded.

Further, the data encapsulation and EOS processing module reports to the management control module when the bandwidth of the virtual connection group VCG is less than the flow control limit, so that the management control module is used for the Policing module by the actual bandwidth of the virtual connection group VCG. Modify the flow control threshold so that it is less than or equal to the actual bandwidth of the virtual link group VCG.

The present invention also provides a method for implementing flow control based on the device, which

(1) the flow classification module assigns a corresponding flow label for the input data flow according to the flow classification rule, determines the output queue of the input packet, and reports the flow label to the management control module;

(2) the management control module sets Policing control parameters for the service corresponding to the flow label according to the agreed rules, the flow control limit used for the flow control and the speed limit used for the speed limiting;

(3) The Policing module performs the flow monitoring on the service data with the flow label according to the Policing control parameters negotiated by the management control module, and starts the flow control when the input data flow is larger than the flow control threshold value. Send a flow control frame instructing the remote facility node to reduce input data flow;

(4) When the remote equipment does not respond to the flow control frame, the Policing module monitors the service data with the flow label according to the Policing control parameters negotiated by the management control module, and the output data rate is the speed limit limit value. If larger, mark the packet as violation of data, otherwise mark it as normal data, and forward the marked packet to the queue management / scheduling module;

(5) The queue management / scheduling module manages and schedules the received data, and discards the packet indicated by the rule violation data according to the received information of the received packet, inserts the packet indicated by the normal data into the queue, and processes the received data. To schedule and transmit to a corresponding output port; It consists of steps.

Further, the step of arranging the Policing control parameters in step (2),

Deploy the speed limit thresholds used for speed control, which include the data rate Vd and packet burst length Ld that trigger speed control when deployed with a single bucket parameter, and Vdmax / Ldmax and Vdmin when deployed with double bucket parameters. / Ldmin;

Deploy a flow control threshold used for flow control, the data rate Vc and data burst length Lc which, when deployed with a single bucket parameter, trigger the flow control; Including steps,

Among them, the burst length of all packets must be larger than the maximum packet length that the data flow allows through.

Further, step (3) is,

According to the flow label transmitted from the flow classification module and the agreement Policing parameter of the corresponding label transmitted from the management control module, flow monitoring is performed on the input data flow.

When the input data flow is greater than the flow control threshold, send a flow control frame to the remote facility node indicating the input data flow reduction;

When the input data flow recovers to be less than or equal to the flow control threshold Vc, stopping sending the flow control frame indicating reduction of the input data flow to the remote facility node; It consists of steps.

Further, step (4) moreover,

According to the flow label transmitted from the flow classification module and the agreement Policing parameter of the corresponding label transmitted from the management control module, flow monitoring is performed on the output data.

When the rate limit threshold is placed with a single bucket parameter (Vd, Ld), if the output data flow is greater than the rate limit threshold Vd, the corresponding packet is discarded, or the packet is marked in red to indicate violation of the data, Otherwise, mark the packet as green to indicate normal data and output the data flow to the queue management / scheduling module;

If you place the speed limit limit with the double bucket parameters Vdmax / Ldmax and Vdmin / Ldmin,

If the monitored service data flow does not violate the negotiated lower limit parameters (Vdmin, Ldmin), then mark the packet in green;

If the monitored service data flow exceeds the negotiated lower limit parameters (Vdmin, Ldmin) but does not exceed the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in yellow;

If the service data flow exceeds the negotiated high limit parameters (Vdmax, Ldmax), mark the packet in red or discard the packet directly;

Color notation of the packet is sent to the queue management / scheduling module; It consists of steps.

In addition, step (2) further includes a discard control parameter arranging step of the queue, wherein the discard control parameter of the queue to be placed includes a half full low limit Lh and a nearly full high limit Lf;

Accordingly, when the queue management / scheduling module processes the received packet in step (5), the received packet indicated in red is discarded directly, and the received packet indicated in yellow / green is processed as follows according to the queue state.

When all packet capacity in the queue is less than the lower limit Lh of the queue, all packets enter the queue;

When all the packet capacity in the queue is greater than the low limit Lh of the queue and less than the high limit Lf, the packet marked green enters the queue, and the packet marked yellow is discarded;

When all packet capacity in the queue is greater than the high limit Lf of the queue, all newly received packets are discarded; It consists of steps.

Further, the method furthermore,

When outputting data encapsulation and EOS processing module, if the bandwidth of the virtual connection group VCG is less than the flow control limit, it is reported to the management control module, so that the management control module is connected to the Policing module by the actual bandwidth of the virtual connection group VCG. Modify the flow control threshold used so that it is less than or equal to the actual bandwidth of the virtual connection group VCG; Steps.

Using the technical scheme of the present invention, it is possible to implement the flow control of the specified bandwidth flow, if the data flow exceeds the flow control threshold, and sends a flow control signal to the remote facility, the remote facility receives data after receiving the flow control frame By reducing the flow, it is possible to handle packet discards due to rate limitations in the current installation.

In addition, the present invention can implement the flow control for the 2 layer pause frame port of Ethernet and the specific service of the 3 layer by using the service flow marking function, and can prevent service damage due to output queue congestion.

The present invention optimizes the flow control strategy in the MSTP transmission network to ensure the uninterrupted transmission of packet-based service data flow on the network, and provides service bandwidth detection and reporting, allowing the operator to easily grasp the service operation status on the network. It can make the flow control strategy of the urban area network more complete, and meet the specific service flow control requirements in the MSTP transmission facility of Ethernet service.

In addition, the bandwidth and flow control mechanism according to the present invention can reduce the occupancy of resources by the abnormal service, prevent damage to the service, and improve network transmission quality.

1 is a functional block diagram on an MSTP facility in an embodiment of the present invention.

FIG. 2 is a service process diagram at the time of flow control of an apparatus implementing flow control on a rate limiting basis in an embodiment of the invention. FIG.

3 is a flowchart of flow control in an embodiment of the present invention.

4 is a flow parameter adjustment processing flowchart for flow control in the embodiment of the present invention.

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

In this embodiment, the main idea of implementing the flow control based on the speed limit,

If the incoming data flow detected by the Policing module at the MSTP facility receiving end exceeds its contracted bandwidth, the MSTP is notified to the remote facility by returning a flow control frame to the remote facility (rather than discarding the excess bandwidth service). By reducing the data flow entering the facility, it implements port-based or flow-based bandwidth control of service data and prevents service transmission damage.

In addition, in the direction from Ethernet to synchronous optical network (ETHERNET → SDH), when the EOS channel sending direction of the MSTP facility decreases beyond the link, the Ethernet input service flow of the link is transmitted through the Policing module of the facility. If a corresponding flow control bandwidth parameter is adjusted and it is detected that the input service data flow bandwidth exceeds the set output flow control bandwidth parameter, the flow control frame is returned to the remote facility to control the bandwidth of the service data. In addition, it is possible to report the link actual bandwidth change in real time through the management interface.

In the present embodiment, there is provided an apparatus for implementing the flow control based on the speed limit in the MSTP facility, its hardware functional block diagram is shown in Figure 1, mainly the data input module, flow classification module, Policing module, It includes a queue management / scheduling module, a data output module, and a management control module. Among them,

1) The data input module includes a MAC, EOS processing module, i.e., an input interface of data, to receive a service data flow input from the outside, and to transmit the service data flow to the flow classification module;

2) The flow classification module assigns a flow label and an output queue to service data flows input from outside according to the agreed rules.

In the flow classification module, an input service packet must be matched according to an agreed rule (i.e., a flow classification rule) to implement classification and identification of a service data flow, and a corresponding flow label for a packet meeting the agreed rule is generated. The corresponding flow label shall be sent to the management control module. Processing of the flow classification module also includes determining a delivery target output queue of the input packet.

The contracted rule is a flow classification rule, which may be port / port + VLAN / port + VLAN + DSCP / port + VLAN + 802.1P in the Ethernet service, but is not limited thereto. Create a flow label, which is a method of defining the flow of a service). The above-mentioned contracted rules are all conventional general purpose techniques.

3) The management control module provides a batch management interface to manage and control the data input / output module, the flow classification module, the Policing module, and the queue management / scheduling module, and the data flow and queue parameters according to the flow labels of the service data flow. For example, the control parameters of Policing are implemented, including information processing such as flow control thresholds used for flow control, speed limit thresholds used for speed limiting, and VCG bandwidth monitoring. do.

The management control module sets an agreement Policing control parameter of the service data flow for the service corresponding to the flow label according to the agreed rules, which includes a data rate V and a packet burst length L.

One is the data rate Vd and packet burst length Ld, which trigger rate control, i.e. the rate limit threshold used for rate limiting;

One is the data rate Vc and packet burst length Lc, which triggers flow control, i.e. the flow control threshold used for flow control;

In various parameter setting modes, the burst length L of all packets must be larger than the maximum packet length that the data flow allows to pass.

4) Policing module performs service bandwidth monitoring according to Policing control parameter (mainly speed parameter) set by management control module, performs speed control by service flow, or sends flow control frame.

After receiving the packet, the Policing module performs flow monitoring on the data flow according to the data flow label ID transmitted from the flow classification module and the agreement Policing parameter of the corresponding flow label transmitted from the management control module, and the flow monitoring result (rule violation). The corresponding process according to whether or not);

If the input service data flow exceeds the set flow control threshold, send a flow control frame to the service source node to notify the lowering of the input data to reduce the input flow;

When the input service data flow exceeds the set speed limit, data violation / marking processing is performed for the violation data, and the marked packet is sent to the queue management / scheduling module.

5) The queue management / scheduling module allocates the received packet according to the flow label according to the output port and priority, proceeds with queue management and scheduling, and transmits the packet to the corresponding sending port. Among them, after receiving the data, the queue management / scheduling module performs a queue insertion or discarding process for the incoming packet according to the packet marking information and the resource usage of the target queue corresponding to the packet. In addition, scheduling is performed on the packets in the queue, and the packets are transmitted to the corresponding output ports (Ethernet port or EOS port).

6) The data output module includes a MAC control module, an EOS module, and the like, and outputs a packet to a corresponding port.

As shown in FIG. 2, an apparatus for implementing flow control based on the speed limit of the present embodiment may further include:

A data encapsulation and EOS processing module, used for checking the status of the SDH channel and reporting real-time bandwidth information of the SDH channel of the VCG to the management control module when the number of members of the VCG changes;

A flow control frame trigger module for triggering a corresponding flow control frame according to a monitoring result of a specific service flow label of the Policing module;

A MAC control module for completing outgoing / receiving control on the Ethernet interface of the packet; As shown in FIG.

Each combination of modules configured by the hardware shown in FIG. 1 shows a flowchart in which flow control processing is performed on the input data flow by arrangement, as shown in FIG. Control the speed and flow, and finally output through VCG port.

Among them, the water port is service data connected to the corresponding Ethernet port, the allowed service guarantee bandwidth is 30M, the peak bandwidth is 35M, the VCG bandwidth is 30M, the VCG output uses GFP encapsulation, and the virtual connection uses the LCAS protocol. It is to support. It comprises the following steps.

A. By arrangement of services, the flow classification module assigns a flow label ID to the incoming data of the corresponding Ethernet port and assigns an output queue, and the agreement Policing parameter used for flow control / rate limiting of the flow label ID in the management control module. VCG member and work mode arrangement.

A1. The Policing parameter negotiated by the management control module includes two parameters, the negotiated data rate V and the negotiated burst length L. In the present embodiment, two types of policing parameters correspond to the following.

Policing parameters of flow control to trigger flow control frames to limit input bandwidth;

Policing parameter of rate limiting which limits the sending bandwidth of the output direction; to be.

For Policing parameters of rate limiting, you can use single bucket or double bucket control parameters as the service type is different. The single bucket parameter is Vd / Ld. Double bucket parameters are Vdmax / Ldmax and Vdmin / Ldmin, among which the monitoring bandwidth corresponding to Vdmax, Ldmax is relatively large and corresponds to the burst bandwidth of the high limit parameter; The monitoring bandwidth corresponding to Vdmin and Ldmin is relatively small and corresponds to the guaranteed bandwidth of the low limit parameter. In this embodiment, Vdmax = 35M and Vdmin = 30M. At the time of output, the output flow is monitored using the Policing parameter of speed control, and the corresponding processing strategy is applied to the rule violation packet based on the flow monitoring result.

The Policing parameter of the flow control uses a single bucket parameter Vc / Lc, and performs a collation arrangement with the lower limit parameter (guaranteed bandwidth) where the monitoring bandwidth is relatively small in the velocity control Policing parameter. For example, the parameter setting method is described below.

a. The data rate that triggers rate control is equal to the data rate that triggers flow control (Vd = Vc), and Vd if the packet burst length that triggers rate control is greater than the packet burst length that triggers flow control (Ld> = Lc). = Vc = 30M, Ld = Lc = 64 kbytes;

b. The data rate that triggers rate control is greater than the data rate that triggers flow control (Vd> Vc), and if the packet burst length that triggers rate control is equal to the packet burst length that triggers flow control (Ld = Lc), then Vd = 30M / Vc = 29M, Ld = Lc = 64kbytes;

c. If the data rate that triggers rate control is greater than the data rate that triggers flow control (Vd> Vc), and the packet burst length that triggers rate control is greater than the packet burst length that triggers flow control (Ld> Lc), Vd = 30M / Vc = 29M and Ld = 64kbytes / Lc = 60kbytes.

A2. The flow classification module designates an output queue for the service of the corresponding flow label ID, and the queue corresponds to the output VCG port. You can set multiple priority queues under the VCG port. There are two discard control parameters of the queue: half full low limit Lh and high limit Lf. When the packet capacity in the queue is larger than the corresponding capacity, the newly inputted packet proceeds with the corresponding operation according to the color notation, and the corresponding processing operation is referred to C 2. below.

B. As shown in Fig. 3, the Policing module monitors service data flows (including monitoring of input data flows and output data flows) provided with flow label IDs by a bucket algorithm, and corresponding operations according to the monitoring results. Proceed.

 B1. When the service data violates the flow control parameters (Vc, Lc), flow control is started. In full-duplex mode, the PAUSE flow control frame is sent periodically to the remote facility connected to the facility Ethernet port via the MAC to notify the remote facility of the data flow reduction; If the service data flow of the monitored flow label ID does not violate the agreement Policing parameters (Vc, Lc), stop sending PAUSE flow control frames.

"Violation" as used herein means that the actual speed of the data flow exceeds the data rate Vc in the Policing parameter. Through the flow control frame processing mechanism, it is possible to secure effective control over the actual flow / bandwidth of the received service data. The flow control frame enters the highest priority dispatch queue to ensure real time dispatch of the PAUSE flow control frame. The contents of the PAUSE flow control frame belong to standard technology. The flow control frame contains time stamp information that defines the time when the remote facility stops sending data frames after receiving the PAUSE frame. The PAUSE frame time stamp value sent by the facility is 0, indicating that the present flow control process is finished.

B2. If the remote equipment did not respond to the flow control frame, the data flow received by the equipment side could continue to increase, at which point the output bandwidth limit of the Policing module would be in effect, leading to normal operation of the equipment and network. To ensure work, see B3 below for the process.

B3. Policing module monitors the flow of data with flow label ID by rate limiting parameters (Vd, Ld).

If the monitored service data flow does not violate the negotiated lower limit parameters (Vdmin, Ldmin), then mark the packet in green;

If the monitored service data flow exceeds the negotiated lower limit parameters (Vdmin, Ldmin) but does not exceed the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in yellow;

When the service data flow exceeds the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in red or the packet is discarded directly.

The color notation of the packet is sent to the queue management / scheduling module.

C. After the packet is received, the queue management / scheduling module determines whether to enter a queue for a newly received packet with respect to the queue based on the capacity of the scheduling waiting packet in the target queue under the VCG port and the newly received packet color representation and length. .

C1. Drop the received packet marked in red directly.

C2. Receive packets marked in yellow / green are processed as follows according to the queue status.

When all packet capacity in the queue is less than the lower limit Lh of the queue, all packets enter the queue;

When all the packet capacity in the queue is greater than the low limit Lh of the queue and less than the high limit Lf, the packet marked green enters the queue, and the packet marked yellow is discarded;

When all packet capacity in the queue is greater than the high limit Lf of the queue, all newly received packets are discarded; It consists of steps.

D. Queue management / scheduling module performs scheduling process according to port bandwidth, sends packets in queue below port to output port, and sends packets from this equipment. The output port includes a VCG protocol and an Ethernet port, and data sent by the VCG port is sent from the facility through the SDH interface after GFP encapsulation in the EOS module.

In this embodiment, the bandwidth-free control is implemented through two-step flow monitoring,

Step 1: Monitoring and processing to trigger flow control only affects the processing of the PAUSE frame;

Step 2: Only monitoring and processing of rate limiting can cause packet loss.

If the monitoring bandwidth that triggers the flow control is less than the monitoring bandwidth of the rate limit, the service can be harmless, so that the remote equipment does not receive the PAUSE frame and reduce the packet sending rate, and the second rate This is because when the restriction mechanism detects that the service is not legal, the discarding process may cause packet loss.

2 and 3 illustrate a method of implementing flow control based on a general speed limit as an example. 4 shows an extended application of flow control.

Hereinafter, a flow control processing method when a bandwidth change of a VCG output port that the virtual connection supports the LCAS protocol will be described as an example. For the processing, refer to the flowchart of FIG. 4.

D.1 When EOS processing supports the LCAS protocol, some VC channel failures cause dynamic increases and decreases in the number of members in the VCG and changes in the bandwidth of the VCG. When the bandwidth of the VCG is less than the speed limit Vc of the flow control parameters, the rate limiting parameters (Vd, Ld) cannot effectively control the sending data rate, and the data may cause packet loss due to scheduling congestion in the queue of the output port. Can be. Therefore, when the bandwidth that the VCG can provide is less than Vc, the management control module modifies the Policing parameter used by the flow label ID under the Policing module according to the actual bandwidth of the VCG, modifying Vc to make it smaller than the VCG actual bandwidth. Or equal, and Lc does not change.

D.2 The flow control process and normal process of the Policing module are the same, monitoring the flow of the input service data with the flow label ID, and when the service data flow violates the new flow control Policing parameters (Vc, Lc) Trigger frame processing; Policing parameter processing of speed control is consistent with general processing.

The flow control adjustment of the data flow dynamically by the VCG bandwidth using the Policing parameter scheme can effectively reduce the packet loss occurrence rate of the service data and avoid the service loss on the transmission path when the VCG bandwidth is smaller than the default arrangement.

2, 3, and 4, the management control module may report the bandwidth change of the service through the software interface, provide real-time bandwidth information of the access service, and manage the service on the MSTP facility. The functionality can be implemented more fully.

The present invention provides an apparatus and method for implementing flow control based on rate limiting in an MSTP facility, and implements flow control based on rate limiting on a multi-service transmission platform transmission facility of a communication system. securing the non-affected transmission of the service data flow network, service bandwidth, and provides detection and reporting, and reduced to the above service by the bandwidth and flow control mechanism occupying the resources and prevent damage to the service, network transmission, Improve quality.

Claims (12)

A data input module, a flow classification module, a Policing module, a queue management / scheduling module, a data output module, and a management control module which controls the module and is connected to all of them, among which The data input module receives an input data flow; The flow classification module assigns flow labels to the input data flows according to the flow classification rules, determines the corresponding output queues, and transmits the flow labels to the management control module to Policing the labeled data flows. Send to module; The management control module is configured to set the Policing control parameters according to the agreed rules, the speed limit limit used for the speed control and the flow control limit used for the flow control; The Policing module performs flow monitoring on the received data according to the flow label sent from the flow classification module and the agreement Policing parameter of the corresponding label sent from the management control module, so that when the input data flow is larger than the flow control threshold, Send a flow control frame instructing the remote facility node to reduce input data flow; If the output data flow is greater than the rate limiting threshold, discard the corresponding packet or mark the packet as rule violation data, and output the data flow to the queue management / scheduling module; The queue management / scheduling module manages and schedules the received data, discards the packet indicated by the rule violation data, inserts the packet indicated by the normal data into a queue, processes the packet, and transmits the output to the corresponding output port; The data output module outputs a normal data flow according to a processing result of the queue management / scheduling module; Apparatus for implementing flow control based on rate limiting in a multi-service transmission platform facility, characterized in that. The method of claim 1, The device is connected to the queue management / scheduling module, is used for detecting the status of the SDH channel, and the data encapsulation and EOS processing for reporting the SDH channel real-time bandwidth cleanup of the VCG to the management control module when the number of members of the virtual connection VCG changes. A module; A flow control frame trigger module connected to the Policing module, wherein the Policing module triggers a corresponding flow control frame according to a monitoring result of a specific service flow label; A MAC control module for completing outgoing / receiving control on the Ethernet interface of the packet; Apparatus for implementing flow control based on the speed limit in the multi-service transmission platform facility, characterized in that further comprises. The method of claim 1, Policing control parameters set by the management control module, A rate limiting threshold used for rate control, comprising a data rate Vd and a packet burst length Ld, which, when deployed with a single bucket parameter, trigger the rate control, and when deployed with a double bucket parameter, Vdmax / Ldmax and Vdmin / Ldmin; A flow control threshold used for flow control comprising a data rate Vc and a packetburst length Lc that, when deployed with a single bucket parameter, trigger the flow control; And, Wherein said burst length of all said packets is greater than a maximum packet length that allows data flow to pass through. Apparatus for implementing flow control based on rate limiting in a multiple service transport platform facility. The method of claim 3, wherein In the Policing module, When the input data flow is less than or equal to the flow control threshold, stop sending the flow control frame indicating reduction of the input data flow to the remote facility node; If the remote equipment does not respond to the flow control frame, flow monitoring is performed on the output data. When the rate limit threshold is placed with a single bucket parameter (Vd, Ld), if the output data flow is greater than the rate limit threshold Vd, the corresponding packet is discarded, or the packet is marked in red to indicate violation of the data, Otherwise, mark the packet as green to indicate normal data and output the data flow to the queue management / scheduling module; When the speed limit limit is placed with the double bucket parameters Vdmax / Ldmax and Vdmin / Ldmin, If the monitored service data flow does not violate the negotiated lower limit parameters (Vdmin, Ldmin), then mark the packet in green; If the monitored service data flow exceeds the negotiated lower limit parameters (Vdmin, Ldmin) but does not exceed the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in yellow; If the service data flow exceeds the negotiated high limit parameters (Vdmax, Ldmax), mark the packet in red or discard the packet directly; Color notation of the packet is sent to the queue management / scheduling module; An apparatus for implementing flow control based on rate limiting in a multi-service transmission platform facility, characterized in that. The method of claim 4, wherein In the queue management / scheduling module, There are two discard control parameters of the queue: half full low limit Lh and high limit Lf; When processing received packets, received packets marked in red are discarded directly, and received packets marked in yellow / green are processed as follows according to the queue status. When all packet capacity in the queue is less than the lower limit Lh of the queue, all packets enter the queue; When all the packet capacity in the queue is greater than the low limit Lh of the queue and less than the high limit Lf of the queue, packets marked in green enter the queue and packets marked in yellow are discarded; When all packet capacity in the queue is greater than the high limit Lf of the queue, all newly received packets are discarded; An apparatus for implementing flow control based on rate limiting in a multi-service transmission platform facility, characterized in that. The method of claim 2, The data encapsulation and EOS processing module reports to the management control module when the band of the virtual connection group VCG is smaller than the flow control limit, so that the management control module uses the Policing module by the actual band of the virtual connection group VCG. By modifying a value, such that it is less than or equal to the actual band of the virtual connection group VCG. (1) the flow classification module assigns a corresponding flow label for the input data flow according to the flow classification rule, determines the output queue of the input packet, and reports the flow label to the management control module; (2) the management control module sets Policing control parameters for the service corresponding to the flow label according to the agreed rules, the flow control limit used for the flow control and the speed limit used for the speed limiting; (3) The Policing module performs the flow monitoring on the service data with the flow label according to the Policing control parameters negotiated by the management control module, and starts the flow control when the input data flow is larger than the flow control threshold value. Send a flow control frame used for input data flow reduction indication to the remote facility node; (4) When the remote equipment does not respond to the flow control frame, the Policing module monitors the service data with the flow label according to the Policing control parameter negotiated by the management control module, and the output data rate is the speed limit limit value. If larger, mark the packet as violation of data, otherwise mark it as normal data, and forward the marked packet to the queue management / scheduling module; (5) The queue management / scheduling module manages and schedules the received data, and discards the packet indicated by the rule violation data according to the received information of the received packet, inserts the packet indicated by the normal data into the queue, and processes it. Scheduling and transmitting to a corresponding output port; A method for implementing flow control based on the apparatus of claim 1, characterized in that it comprises a step. The method of claim 7, wherein Arranging the Policing control parameters in step (2) above, The speed limit threshold used for speed control is placed, which includes the data rate Vd and the packet burst length Ld that trigger speed control when placed with a single bucket parameter, Vdmax / Ldmax and Vdmin / Ldmin; Deploying a flow control threshold used for flow control, comprising a data rate Vc and a data burst length Lc which, when deployed with a single bucket parameter, trigger the flow control; Including steps, Wherein the burst length of all the packets is greater than the maximum packet length that the data flow allows to pass through. The method of claim 8, In step (3), the flow monitoring is performed on the input data flow according to the agreement labeling parameter of the flow label transmitted from the flow classification module and the corresponding flow label transmitted from the management control module. When the input data flow is greater than the flow control threshold, send a flow control frame to the remote facility node indicating the input data flow reduction; When the input data flow recovers to be less than or equal to the flow control threshold Vc, stopping sending the flow control frame indicating reduction of the input data flow to the remote facility node; A method for implementing flow control based on the apparatus of claim 1, characterized in that it comprises a step. 10. The method according to claim 8 or 9, In step (4), flow monitoring is performed on the output data according to the flow label transmitted from the flow classification module and the agreement Policing parameter of the corresponding label transmitted from the management control module. When the rate limit threshold is placed with a single bucket parameter (Vd, Ld), if the output data flow is greater than the rate limit threshold Vd, the corresponding packet is discarded, or the packet is marked in red to indicate violation of the data, Otherwise, mark the packet as green to indicate normal data and output the data flow to the queue management / scheduling module; When the speed limit limit is placed with the double bucket parameters Vdmax / Ldmax and Vdmin / Ldmin, If the monitored service data flow does not violate the negotiated lower limit parameters (Vdmin, Ldmin), then mark the packet in green; If the monitored service data flow exceeds the negotiated lower limit parameters (Vdmin, Ldmin) but does not exceed the negotiated high limit parameters (Vdmax, Ldmax), the packet is marked in yellow; If the service data flow exceeds the negotiated high limit parameters (Vdmax, Ldmax), mark the packet in red or discard the packet directly; Color notation of the packet is sent to the queue management / scheduling module; A method for implementing flow control based on the apparatus of claim 1, characterized in that it comprises a step. 11. The method of claim 10, Step (2) comprises a discard control parameter placement step of the queue, wherein the discard control parameters of the queue to be placed comprise two half-lower limit Lh and a high limit Lf; Accordingly, when the queue management / scheduling module processes the received packet in step (5), the received packet indicated in red is discarded directly, and the received packet indicated in yellow / green is processed as follows according to the queue state. When all packet capacity in the queue is less than the lower limit Lh of the queue, all packets enter the queue; When all the packet capacity in the queue is greater than the low limit Lh of the queue and less than the high limit Lf, the packet marked green enters the queue, and the packet marked yellow is discarded; When all packet capacity in the queue is greater than the high limit Lf of the queue, all newly received packets are discarded; A method for implementing flow control based on said apparatus of claim 1. The method of claim 1, When outputting the data encapsulation and EOS processing module, if the band of the virtual connection group VCG is smaller than the flow control limit, it is reported to the management control module, and the management control module is connected to the Policing module by the actual band of the virtual connection group VCG. Modifying the flow control threshold used to cause it to be less than or equal to the actual band of the virtual connection group VCG, thereby implementing flow control based on rate limiting in a multi-service transport platform facility. Device.

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