Abstract:
Methods and apparatus for an improvement on Random Early Detection (RED) router congestion avoidance are disclosed. A traffic conditioner stores a drop probability profile as a collection of configurable profile segments. A multi-stage comparator compares an average queue size (AQS) for a packet queue to the segments, and determines which segment the AQS lies within. This segment is keyed to a corresponding drop probability, which is used to make a packet discard/admit decision for a packet. 
     In a preferred implementation, this computational core is surrounded by a set of registers, allowing it to serve multiple packet queues and packets with different discard priorities. Each queue and discard priority can be keyed to a drop probability profile selected from a pool of such profiles. This provides a highly-configurable, inexpensive, and fast RED solution for a high-performance router.

Description:
FIELD OF THE INVENTION 
   This present invention relates to data packet routing and routers, and more particularly to a method and apparatus for implementing random early detection of congestion in a router queue. 
   BACKGROUND OF THE INVENTION 
   In packet-switched networks, routers, switches, and gateways are examples of the types of network devices that effect delivery of packets from source endpoints to destination endpoints. These routing devices receive network packets at one or more ingress ports. For each received packet, the routing device examines one or more of the packet&#39;s headers and then determines an egress port that will move the packet most effectively towards its destination. The device switches the packet to that egress port, where it will be placed back on the network to wend its way towards the destination endpoint. 
   Routing devices generally queue a packet in an internal queue until the packet can be switched to the appropriate egress port, and/or until the egress port has transmitted earlier-arriving packets. These queues must generally be large enough to accommodate traffic bursts—such a burst can occur, e.g., when packets arriving at roughly the same time at multiple ingress ports must be switched to the same egress port. But if the queues are allowed to grow too large, arriving packets are unduly delayed in the router, resulting in service degradation for many forms of traffic. This condition is generally referred to as router “congestion”. 
   Sophisticated routing devices employ active queue management strategies to keep queue sizes within a desired operating range, thereby avoiding congestion. For example, because most of the traffic on a packet-switched network is not allotted a dedicated circuit, transmitting devices are usually expected to conform to a traffic profile that specifies an average and a peak data rate for that device. When a transmitting device fails to conform to its profile, a router may choose to “drop”, or discard, some of the packets from the device in order to place the data rate back within profile. By dropping packets from the offending endpoint, the router prevents that endpoint from consuming an unfair portion of a router queue. Also, TCP and TCP-like applications interpret packet loss as an indicator of congestion, scale back their rate, and then ramp back up in a “slow-start” mode. 
   Unfortunately, transient congestion can occur at a router even when all endpoints are behaving in a reasonable manner. Under these conditions, the router must generally choose some packets to be discarded, hopefully in a manner that is both “fair” and causes traffic to return to a reasonable level. Early routers often implemented Drop Tail or Random Drop algorithms. Drop Tail simply drops a packet which arrives to a full queue. Random Drop drops one packet at random from the queue when a packet arrives to a full queue. 
   Researchers found that several undesirable situations can arise with the Drop Tail and Random Drop algorithms. Because these algorithms were reactive rather than proactive, no control was exercised until congestion was actually occurring. This results in a phenomenon termed “global synchronization”, which causes a large number of senders to reduce their rates in lockstep as a result of congestion, resulting in periods of high drop rates followed by periods of network underutilization. It was also found that misbehaving users were not always effectively controlled by these schemes. 
   Floyd and Jacobson proposed a different congestion avoidance algorithm to deal with these problems. “Random Early Detection Gateways for Congestion Avoidance”,  IEEE/ACM Trans. On Networking , August 1993. The desired congestion response of the Random Early Detection (RED) algorithm proposed by Floyd and Jacobson is depicted in FIG.  1 . An average queue size avg, i.e., a low-pass filtered version of the instantaneous queue size, is calculated. When avg is below a lower threshold min th , no packets are dropped. When avg is above an upper threshold max th  (which is preferably less than the queue&#39;s maximum capacity), all packets are dropped. When avg is between these two extremes, an initial packet-marking probability p b  varies linearly between 0 and P mark :
 
 p   b   ←P   mark (avg−min th )/(max th −min th ).
 
   The final packet-marking probability p a  increases slowly as the count increases since the last marked packet:
 
 p   a   ←p   b /(1−count· p   b ).
 
   Basing the final packet-marking probability on count ensures that the algorithm will not wait too long before marking a packet. 
   When a packet arrives at a RED-enabled queue, the average queue size is used to determine an operating point on the curve of FIG.  1 . The operating point, together with count, defines a packet discard probability p a . A random trial determines whether the current packet will be discarded or not, with the “discard” outcome having a probability equal to the packet discard probability p a . 
   The RED algorithm has several desirable characteristics. Because it uses a filtered queue size, it does not react strongly to short-duration traffic bursts. The probability that a given endpoint&#39;s traffic will be dropped is roughly proportional to that endpoint&#39;s share of the overall traffic load in the queue. Traffic is managed before congestion reaches a critical level. And dropped packets are spread somewhat randomly within the traffic pattern, instead of being bunched together. 
     FIG. 2  shows one variation on the RED congestion avoidance approach. Traffic that is “out-of-profile”, i.e., not conforming to its allowable rates, is controlled using a first RED threshold set Omin th  and Omax th . Traffic that is “in-profile” is controlled using a second RED threshold set Imin th  and Imax th . In operation, out-of-profile traffic will be dropped under the  FIG. 2  scheme at a higher rate than in-profile traffic for most average queue sizes. 
   SUMMARY OF THE INVENTION 
   Today&#39;s high-performance routers process packets at extremely high data rates, and thus packet discard decisions must be made quickly, if at all. At the same time, these routers are often called upon to provide differentiated services, i.e., different classes of traffic may exist, and each class may receive more or less favorable treatment by the router than other classes receive. Such routers often also monitor and police traffic, and are expected to deal with misbehaving users in a fair and consistent approach. The disclosed embodiments describe improvements on the basic RED approach that can be beneficial, e.g., in such a high-speed, differentiated-services router. 
   It is recognized herein that a wire-speed RED implementation is desirable. Although prior art RED implementations use software and a CPU, some of the embodiments described herein use hardware, e.g., an application-specific integrated circuit (ASIC), to provide a wirespeed implementation of RED. These embodiments “snoop” a packet as the packet proceeds through a pipeline to be distributed to its appropriate queue, and produce a drop/no-drop decision for the packet before it reaches the end of the pipeline. With such an approach, RED can be implemented at low cost in a high-performance router. 
   It is also recognized herein that it may be desirable to allow a packet discard probability curve to approximate a function other than a linear function, and/or to have that function be changeable by the user. This presents a challenge when the RED implementation must run at wire speed, and/or when the RED implementation resides on a circuit with no complex mathematical capabilities. Some of the embodiments described herein meet this challenge with user-defined discard probability curves, represented by a finite number of parameters, that require only simple operations such as shifts, adds, and compares. The preferred parametric representation is as a set of segments (i.e., a “profile”), each segment corresponding to an assigned drop probability and representing a specified range of average queue sizes. By manipulating a profile&#39;s segment positioning and drop probabilities, a user can approximate virtually any function that is desired. 
   It is recognized herein that it may be desirable, where multiple packet queues exist, to allow different RED profiles to be used with different queues. In some of the preferred embodiments, a shared “pool” of RED profiles is provided. Each queue can be associated with whichever one of the pooled profiles is desired. This approach is easier for the user, who does not have to parameterize a profile for each queue individually. It is also more efficient in a hardware implementation where literally hundreds of queues may be served by a single RED circuit, since the RED circuit does not have to store a separate profile for each packet queue. This approach also scales easily to accommodate the concept of “drop priority”, where more than one RED profile may exist for a given queue, keyed to a drop priority identifier. The profile selected for a given data packet can depend not only on that packet&#39;s destination queue, but on that packet&#39;s drop priority. 
   In one aspect of the invention, a method of implementing random early detection of congestion for a data packet queue is disclosed. This method uses a configurable segment-based drop probability profile to make a drop/no-drop decision for a data packet. 
   In a related aspect of the invention, a method of implementing random early detection of congestion for multiple data packet queues is disclosed. This method maintains a pool of drop probability profiles, and allows each data packet queue to associate with at least one profile selected from the pool. The method uses the queue/pooled-profile association to select a drop probability profile for each packet, and use that profile to arrive at a drop/nodrop decision for that packet. 
   Although one preferred method of implementing each of these methods is with a special-purpose chip, the methods are also amenable to software implementation. Thus in another aspect of the invention, the disclosed methods can be implemented in an apparatus comprising a computer-readable medium containing computer instructions that, when executed, cause a processor or multiple communicating processors to perform that method. 
   An integrated circuit is also disclosed having hardware tailored to a RED implementation capable of serving multiple queues. A profile register stores an array of segment-based drop probability profiles. A profile matcher accepts a data packet queue identifier and selects an active drop probability profile, from the array of drop probability profiles, that is associated with the data packet queue identifier. A segment selector accepts an average queue size AQS associated with the selected data packet queue and the active drop probability profile. The selector uses this information to identify the segment of the active profile within which AQS falls. And a probability comparator accepts a drop probability corresponding to the segment identification from the segment selector, and produces a random packet-discard signal with a probability approximately equal to the drop probability. 
   A packet routing device is also disclosed. The device comprises a packet pipeline to receive and delay a packet, and a multiple-queue packet memory to receive a packet into the queue designated for that packet, when that packet reaches the end of the packet pipeline without being discarded. The device further comprises a random early detection traffic conditioning circuit to snoop queue information from the packet while the packet is in the pipeline. The traffic conditioning circuit has the capability to select a segment-based drop probability profile corresponding to the queue information and then produce a packet discard/admit decision, based on that profile, before the packet reaches the end of the pipeline. 

   
     BRIEF DESCRIPTION OF THE DRAWING 
     The invention may be best understood by reading the disclosure with reference to the drawing, wherein: 
       FIGS. 1 and 2  illustrates packet discard probability vs. average queue size for two prior-art RED approaches; 
       FIG. 3  shows a high-level block diagram for a router embodiment that can embody the invention; 
       FIG. 4  shows a high-level model for providing differentiated services in a router; 
       FIG. 5  contains a block diagram for ingress packet processing according to an embodiment of the invention; 
       FIG. 6  contains a block diagram for egress packet processing according to an embodiment of the invention; 
       FIGS. 7 and 8  illustrate, in block diagram form, two RED processor implementations according to embodiments of the invention; 
       FIGS. 9 and 10  illustrate two profile segment definition schemes, relative to a high threshold and a delta threshold for a profile; and 
       FIGS. 11 and 12  show two packet discard probability profiles that can be implemented with an embodiment of the invention. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Several terms have been assigned particular meanings within the context of this disclosure. As used herein, “drop” and “dropping” encompasses both the concept of discarding a packet and the concept of marking a packet to indicate congestion. A “drop probability” need not be in the range [0,1] understood for mathematical probabilities—rather, the drop probability occupies a range of values that, when used in a method or device, produces a desired probabilistic result. A “segment-based” drop probability profile requires more than one segment. For instance,  FIG. 1  does not illustrate such a drop probability profile as it has only one linear segment (the never-drop region below min th  and the always-drop region above max th  are not segments, since no probabilistic outcome is associated with them). An “average” queue size refers to a moving average. Something that is “configurable” can have its value electronically changed through a computer interface, without requiring manual alteration of a circuit, recompilation of software, etc. A “packet-routing device” is a multi-port device that performs packet switching between its ports. Routers, switches, access concentrators, and gateways are common examples of packet routing devices. 
     FIG. 3  shows a high-level block diagram for a packet-routing device  20 . Line cards  30 ,  40 ,  50 , and  60  provide physical ports to the device. For instance, line card  30  can provide up to 24 Gigabit Ethernet ports  32  to device  20 , and line card  40  can provide similar capabilities. Line card  50  provides two 10-Gigabit Ethernet ports  52 , and line card  60  provides an OC-192 POS (Packet-Over-Sonet) port  62 . Although four line cards are shown, many systems provide slots to accommodate many more cards, e.g., up to fourteen line cards in one embodiment. The user can configure device  20  to accommodate different traffic models and physical port mixes by the appropriate selection of line cards. 
   Switching fabric  70  moves each data packet from its ingress port/line card to its egress port/line card. Switching fabric  70  connects to each line card through two switching fabric port connections (see, e.g., port connections  34 ,  36  to line card  30 ). Switching fabric  70  can be rapidly reconfigured, e.g., at one instant, it may be switching packets from ingress port  34  to egress port  54  and from ingress port  36  to egress port  66 , and at the next instant, it could be switching packets from ingress port  34  to egress port  44 . At the same time, packets from ingress port  54  could be routed to egress port  46 , and packets from ingress port  64  could be routed to egress port  34 , for example. 
   Route processing module (RPM)  80  has several duties. RPM  80  is responsible for overall system operation, i.e., recognizing and booting new line cards, identifying faulty line cards, packet route discovery, and sharing routing table information with the line cards. RPM  80  also provides a user interface to allow a system operator to configure the system and view system parameters. For each of these functions, RPM generally communicates with the line cards over control bus  90 . 
   Another duty of RPM  80  is scheduling switching fabric  70 . In a preferred implementation, switching fabric  70  is reconfigured by RPM  80  every epoch, where an epoch is a selected time interval. RPM  80  uses scheduling bus  100  to communicate to switching fabric  70  and to line cards  30 ,  40 ,  50 ,  60  the switching fabric configuration for the next epoch. RPM  80  attempts to schedule as many fabric ports as possible during each epoch, and to ensure that data is handled promptly. 
   RPM  80  also maintains its own switching fabric port connections  82 ,  84 , allowing it to receive and transmit packets over any of the line card physical ports. 
     FIG. 4  illustrates how the concept of “differentiated services management” can be applied in a packet routing device such as device  20 . Differentiated services management block  110  is, i.e., a software process running on RPM  80 . Block  110  receives management packets  112  containing instructions as to how packets associated with the various ports of device  20  should be treated. For instance, each port can have committed and peak data rates for its service contract. The instructions may further specify how different classes of packets are to be prioritized, both in RED and in queue priority. Management block  110  implements the instructions by setting appropriate parameters in ingress interface  120  and egress interface  140 . Typically, each switching fabric port connection will have at least one such ingress interface and at least one such egress interface. 
     FIG. 5  illustrates a more-detailed block diagram for ingress interface  120  of  FIG. 4 , e.g., as implemented on line card  30 , although other line card implementations would be similar. In particular, only two line interfaces, L 1  and L 2 , are shown, although line card  30  is described as having twelve such interfaces per switching fabric connection. Two interfaces are sufficient to illustrate which circuitry is and is not replicated per-port, and thus the other ten interfaces have been omitted for clarity. In line card  50  or  60 , line interface L 2  and its related circuitry would not be needed. 
   Initial processing of a packet by ingress interface  120  is as follows. When a packet begins to arrive at line interface L 1 , packet classifier C 1  receives the packet header, and uses selected header fields to perform a lookup operation in the CAM (Content-Addressable Memory). The CAM lookup returns both the switching fabric port to the destination line card (SPort) and the destination port on that line card (OPort). Several packet classification parameters are also determined during lookup: traffic class, or queuing priority (QP), which will be used to assign the packet to one of eight queues associated with the SPort, ODSCP (Outgoing Differentiated Services Code Point), which is a differentiated services header field that is to be inserted in the packet before it leaves the routing device drop precedence; and drop precedence (DP), which is used to differentiate the drop priority for packets sharing the same queue. The drop priority DP preferably takes one of three values corresponding to the “colors” Green, Yellow, and Red. Red packets will generally be dropped before Yellow packets, and Yellow packet will generally be dropped before Green packets. The lookup results are bundled in an internal-use header and prepended to the data packet in packet FIFO F 1 . Note that packets arriving at line interface L 2  experience a similar process, but with classifier C 2 , FIFO F 2 , and the shared CAM. 
   Packets in FIFOs F 1  and F 2  compete for admission to packet pipeline  122 , and are admitted based on a weighted round-robin admission policy. Once a packet is admitted to packet pipeline  122 , traffic monitor  124  snoops the packet&#39;s DP, QP and IPort (i.e., either L 1  or L 2  in this example). 
   Traffic monitor  124  uses dual token buckets to classify the packet according to the packet&#39;s DP (if preexisting), QP, and IPort. The first token bucket detects whether traffic from the packet&#39;s particular class (QP) and IPort is exceeding a peak rate, and if so, the Peak OOP (Out-of-Profile) signal is asserted to traffic conditioner  126 . The second token bucket detects whether traffic from the packet&#39;s particular class and IPort is, although not exceeding a peak rate, exceeding a longer-term committed information rate—if so, the Comt (Committed) OOP signal is asserted to traffic conditioner  126 . 
   Traffic conditioner  126  receives Peak OOP and Comt OOP from traffic monitor  124 , and snoops the packet&#39;s DP, QP, and SPort from packet pipeline  122 . Conditioner  126  produces (as will be explained shortly) a discard/admit signal back to packet pipeline  122 . If the signal has a value understood as drop, packet pipeline  122  may use the signal to discard the packet before it reaches queue memory  132 , or it may simply mark the packet to indicate congestion. Otherwise, when the packet reaches the end of the queue, it will be queued in queue memory  132  according to the packet&#39;s SPort and QP. 
   Packet pipeline  122  tracks the size of each queue in queue memory  132 , i.e., when a packet is de-queued, pipeline  122  decrements a value CQS (Current Queue Size) by the packet&#39;s size, and when a packet is queued, pipeline  122  increments CQS by the packet&#39;s size. Updates to CQS for each queue are supplied to traffic conditioner  126  and queue scheduler  128 . 
   Queue scheduler  128  determines, when a given SPort is enabled, the order in which queues sharing that SPort will be selected to transmit to the switch fabric. 
     FIG. 6  illustrates a more-detailed block diagram for egress interface  140  of  FIG. 4 , e.g., as implemented on line card  50  or  60 , although other line card implementations would be similar (but with more egress paths). Egress interface  140  operates much as ingress interface  120  operates, but with the following significant differences. First, no CAM lookup is required, as the lookup has already occurred in the ingress interface, the results appearing in the internal header passed with the packet. Second, traffic monitor  144  uses OPort instead of IPort, to perform traffic rate monitoring based on an output traffic profile. By similar reasoning, traffic conditioner  146  uses OPort instead of SPort. Egress interface  140  typically also must strip the internal header and modify the packet headers as needed. Finally, a traffic shaper  152  is used to conform the outgoing packet rate to the contracted rate. 
     FIG. 7  depicts one embodiment for a traffic conditioner  126  (or  146 ). Not shown is a DSCP Marking Function (DMF), which may increase a packet&#39;s DP before RED processing. The DMF is a lookup table indexed by the packet&#39;s original DSCP, DP, QP, Peak OOP, Comt OOP, and source port ID (ingress mode) or destination port ID (egress mode), and is populated with new DSCP values for each valid index. 
   In addition, the DMF also computes a new DP value from the original DP value, Peak OOP, and Comt OOP. If the original drop priority for a packet is Green or Yellow and Peak OOP is set, the new DP value is changed to Red; otherwise, a Green DP is changed to Yellow if Comt OOP is set. When neither Peak OOP nor Comt OOP is set, the new DP is set to the original DP. 
   Traffic conditioner  126  comprises several registers, including profile pointer register  160 , profile register  162 , and average queue size register  164 . When a packet is snooped by conditioner  126 , the packet&#39;s port, QP, and DP from the DMF are used as a register index for register  160 . Profile pointer register  160  has N×K×L valid indices, where N is the number of distinct ports served by the queue memory, K is the number of traffic classes, and L is the number of distinct discard priorities that a packet can have. Thus, with N=32, K=8, and L=3, the number of addressable locations needed in register  160  is 768. This allows each of the 768 possible queue/drop precedence combinations to be served by its own drop probability profile. 
   It is highly probable that 768 different drop probability profiles are not needed to handle the 768 different queue/drop precedence combinations that can exist in this example. 
   Thus although such an approach is feasible, it is not the most preferred implementation. 
   Instead, a smaller (e.g., 32 registers) profile register array  162  stores a pool of profiles that can be shared by all queues. Profile pointer register  160  stores, for each queue/DP, a pointer to one register in array  162 . 
   Profile register  162  accepts a five-bit address and outputs two stored values. The output of profile register  162  is a high threshold T H  and a delta threshold T δ  corresponding to the five-bit address. Thresholds T H  and T δ  are supplied to multi-stage comparator  166 . 
   Average queue size register  164  stores a filtered queue size for each queue (in this example, with 32 served ports and 8 service classes, this equates to 256 filtered values). When queried by port and QP, register  164  supplies the appropriate average queue size AQS to multi-stage comparator  166 . 
   Multi-stage comparator  166  uses T H , T δ , and AQS to determine which, if any, of eight segments of the active profile that AQS falls in. The operation of multi-stage comparator  166  is explained in more detail in conjunction with the explanation of  FIGS. 9-12 . 
   Register  168  stores a set of eight drop probabilities P 0 , P 1 , . . . P 7 , each one corresponding to one of the eight segments. Thus in  FIG. 7 , when comparator  166  selects a segment S 1 , register  168  supplies a probability P 1  to probability comparator  170 . Note that when AQS falls outside of any segment, no drop probability is needed, as the discard/admit decision is made deterministically (admit if AQS&lt;T H −T δ , discard if AQS≧T H ). 
   Probability comparator  170  makes discard/admit decisions when AQS falls within a defined segment. Comparator  170  accepts a random number from random number generator  172 , and compares the random number to the drop probability supplied by register  168 . If the random number is less than the drop probability, the discard signal is asserted. 
   In alternate implementations, probability comparator  170  can use other dropping schemes. For instance, comparator  170  can be supplemented with a register allowing it to track how many packets m have passed through each queue since the last packet was dropped for that queue. The drop comparison can then compare the random number to mP i  instead of P i . 
   One optional element of traffic conditioner  126  is AQS filter  174  (filtered values may equivalently be calculated, e.g., by packet pipeline  122 , although this requires access to register  164 ). Filter  174  accepts a CQS value from packet pipeline  122 , along with the corresponding port and QP, when that CQS changes (or at fixed intervals). Filter  174  retrieves the corresponding AQS(Port, QP) value from register  164 . After filtering, the updated AQS value is written back to AQS(Port, QP). Preferably, filter  174  implements an exponentially-weighted moving average (EWMA), e.g., represented by the equation
 
 AQS=AQS +2 −n ( CQS−AQS ),
 
where n is a positive integer. The exact value selected for n will depend on the desired damping characteristics, and should be used to determine the provisioned buffer size of the queue.
 
   Many alternate register structures can be devised for a traffic conditioner.  FIG. 8  shows another traffic conditioner embodiment  180  with a different profile register structure  182 . Each profile in register  182  stores T H , T δ , and a corresponding set of drop probabilities P 0 , P 1 , . . . P 7 . Whereas the previous embodiment allowed only dilation and translation of a single basic curve shape, embodiment  180  allows different curve shapes to be set for each profile. 
   Note that although the previous discussion described profiles in terms of “segments”, endpoints for the segments are not shown explicitly stored for each profile. This is because in the most preferred embodiments, multi-stage comparator  166  calculates the segment endpoints from the two parameters T H  and T δ .  FIG. 9  shows one set of calculated segment endpoints. With N segments S i , 0≦i&lt;N, the lower endpoint for each segment S i  is defined as
 
T H −T δ /2 i .
 
   The upper endpoint of segment S i  is the lower endpoint of segment S i+1 . The upper endpoint for segment S N−1  is simply T H . Note that each segment endpoint is the result of at most one shift of T δ  and at most one add operation. The proper segment S i  for AQS is the segment for which the following relationship holds true:
 
 T   H   −T   δ /2 i   ≦AQS&lt;T   H   −T   δ /2 i+1    i≠N −1
 
 T   H   −T   δ /2 i   ≦AQS&lt;T   H    i=N −1
 
   Of course, if AQS&lt;T H −T δ  then no segments evaluate true and the packet should be admitted. And if AQS≧T H , then the packet should be discarded. 
   Many other predefined segment relationships are possible. For example,  FIG. 10  shows a set of equally-distributed segments. Where N segments exist, this method requires only log 2 (N) shifts, but some threshold calculations will require as many as log 2 (N) adds. 
   One possibility is that more than one segment relationship maybe specified. For example, an additional bit stored with each profile could indicate whether the segmentation scheme of  FIG. 9  or the scheme of  FIG. 10  is to be applied to a given profile. Comparator  166  would need the flexibility to handle either segment relationship. Alternately, if memory is not at a premium, each profile could include explicit segment boundaries. 
   Although these alternate designs are possible, generally, the single segment relationship of  FIG. 9  should be adequate to represent most packet discard probability curves if P i  are set appropriately. For instance,  FIG. 11  shows one curve that approximates an exponential relationship between queue size and drop probability. And  FIG. 12  shows another curve that approximates a linear relationship between queue size and drop probability. Because P i  are configurable, the present invention offers the ability to readily change the drop probability curve should research show that a different shape is preferable. 
   It should be noted at this point that a distinct advantage of the segment approach is that such an approach is amenable to a simple and fast hardware solution, no matter what shape the drop probability curve is to take. This allows for a flexible, inexpensive RED-on-a-chip implementation that can process packets at wire speed. The register implementation allows differentiated RED services to be provided inexpensively for a large number of queues, allowing a single RED-on-a-chip implementation to serve many queues. Preferably, the router&#39;s operator interface provides the capability to set the values in the profile registers as well as in the profile pointer registers. 
   Although the simplest approach is to select a constant drop probability P i  for each segment S i , other implementations are possible, e.g., the segments can be arranged in a piecewise-linear fashion. 
   One of ordinary skill in the art will recognize that the concepts taught herein can be tailored to a particular application in many other advantageous ways. For instance, the high/delta threshold pair could be replaced with a low/delta pair, a low/high pair, or some other equivalent set of parameters. The AQS filter need not use a power of two (although this provides a simple hardware solution), or even be an exponential filter. The filter may operate on actual data size or on number of packets. Although it is preferable that a hardware implementation of a traffic conditioner embodiment provide a single-chip solution, various registers, as well as the random number generator, may be located off-chip. Many natural division points also exist for dividing the remaining functionality among several chips. Such minor modifications are encompassed within the invention, and are intended to fall within the scope of the claims. 
   Although the specification may refer to “an”, “one”, “another”, or “some” embodiment(s) in several locations, this does not necessarily mean that each such reference is to the same embodiment(s), or that the feature only applies to a single embodiment.