Abstract:
In order to be able to use a smaller routing table ( 4 ) and, thus, to reduce the costs and power consumption and to improve the performance of an IP router, it is proposed to extract a destination address identifier (ADR) from a data packet to be forwarded by the IP router, compress the extracted destination address identifier (ADR) by using a lossless data compression algorithm, and compare the compressed destination address identifier with entries stored in the routing table ( 4 ) so as to find a correspondence between the destination address identifier and one of the entries of the routing table ( 4 ). Each entry of the routing table ( 4 ) corresponds to a possible or available forwarding address of the IP router, the forwarding addresses having been compressed with the same data compression algorithm as the destination address identifier. After having found a correspondence between the destination address identifier and one of the compressed forwarding addresses stored in the routing table ( 4 ), a switch ( 6 ) of the IP router switches the respective data packet to one of its output links (OUT) which is associated with the respective forwarding address matching the destination address identifier (ADR).

Description:
FIELD OF THE INVENTION 
     The present invention relates to a method for routing of data packets as well as a respective routing apparatus. In particular, the present invention relates to a method for routing of data packets according to the IPv6 protocol (“Internet Protocol Version 6”) and a respective routing apparatus. 
     BACKGROUND 
     As one of the essential components of an internet data transmission system, an IP router (“Internet Protocol”) makes a forwarding decision for an input data packet, i.e. it checks a destination address identifier carried in the packet header and directs it to the next output port or output link through which the data packet should be sent. For example, depending on the destination address identifier of the input data packet, the IP router can direct the data packet to a Next Hop router or an Egress™ port for transmission over a respective output link. In a computer network, the NHRP protocol (“Next Hop Resolution Protocol”) is a protocol which can be used so that a computer sending data to another computer can learn the most direct route to the receiving computer. An Egress™ port is a new type of port used in modern IP routers. 
     In the following, the routing of data is briefly explained with reference to  FIG. 7  which shows the schematic construction of an IP router according to the prior art. 
     The IP router shown in  FIG. 7  comprises an input block  1  which receives a plurality of input data packets over N input links or input ports IN 1 -INN. The input block  1  serves as an input queue and outputs the received data packets in a “First In First Out” (FIFO) manner. A header extracting block  2  is provided which extracts the packet header from the respective data packet to be transmitted so as to obtain the destination address identifier which is included in the packet header. In addition, the data packet is transferred to an output block  6  which serves as a switch. A routing table  4  stores all possible or available forwarding addresses and the respective output link/port numbers of the router. That is to say the routing table comprises a plurality of entries, each entry corresponding to a respective forwarding address to which a data packet can be forwarded by the IP router. The routing table  4  is generated and updated by a block  5  using routing protocols. In  FIG. 7 , the routing updates are indicated with reference sign UPD. A routing unit  3  receives the destination address identifier extracted by the header extracting block  2  and uses this destination address identifier as a key for searching for a match in the routing table  4 , i.e. the routing unit  3  compares the destination address identifier with every entry corresponding to a respective forwarding address information stored in the routing table  4 . If the routing unit  3  finds a correspondence between the destination address identifier and one of the forwarding addresses stored in the routing table  4 , the respective output link/port number is transferred to the switch  6 , and the switch  6  switches the data packet to a respective one of a plurality of M output links/output ports OUT 1 -OUTM. 
     Hence, as long as the routing unit  3  finds a correspondence between the destination address identifier extracted by the header extracting block  2  and at least one of the entries stored in the routing table  4 , the respective data packet can be switched to one of the output links OUT 1 -OUTM. If, however, there is no match for the destination address identifier in the routing table  4 , the switch  6  cannot switch the respective data packet to one of the output links, and the data packet cannot be forwarded to its destination. 
     It is obvious that the cost associated with an IP router of the type shown in  FIG. 7  and its performance depend very much on the size of the routing table  4 . The routing table  4  consumes silicon area and the look-up procedure consumes time as well as power, especially if the routing table  4  is large. 
     This problem in particular becomes more and more serious with the fast expansion of internet. The newly introduced IPv6 protocol provides address identifiers comprising 128 bits. Theoretically, for an n-bit destination address identifier, the routing table  4  may have up to 2 n  entries. Hence, as regards the IPv6 protocol, there is a need for an enormous storing capacity for storing such a large routing table  4 . Such a large table size, however, makes the look-up procedure even impractical. Therefore, routing table look-up is regarded as the major bottleneck in today&#39;s routers. 
     The most straightforward method for routing table look-up is to perform a linear searching, i.e. compare the destination address identifier of the input data packet with each entry of the routing table until a correspondence between the address identifier and one of the entries in the routing table is recognized. Although this approach is simple, it is hardly used in actual practice due to its poor performance. 
     To speed up the look-up procedure, various strategies have been used. The most important ones are the usage of a so-called contents-addressed memory (CAM), the search according to a tree-based data structure, and the usage of so-called hashing strategies. Each of these known strategies has its own advantages and disadvantages. However, all of them are based on a search in the original data domain of the destination address identifier. Thus, all of these strategies require a relatively complex search procedure and a relatively large routing table size. 
     SUMMARY 
     Therefore, the object underlying the present invention is to provide a routing method for data packets as well as a respective routing apparatus which allow a smaller size of the routing table and, thus, enable a faster search for a correspondence between the respective destination address identifier and the entries stored in the routing table and decrease the costs associated with the routing table. 
     This object is achieved by a routing method and a routing apparatus according to embodiments of the present invention. 
     The basic idea of the present invention is that the routing table look-up can be performed in a compressed domain, i.e., before performing the look-up operation for an input data packet, its destination address identifier is first compressed to remove redundancy. Then, the look-up operation is carried out with the compressed destination address identifier as the key with respect to the routing table, the entries of which having been also compressed in the same manner as the destination address identifier of the input data packet. 
     Therefore, the look-up operation can be performed with respect to a smaller routing table and, thus, the costs and power consumption associated with the respective router can be reduced, while the performance of the router can be improved. 
     The compression of the destination address identifier as well as the forwarding address information entries of the routing table is performed according to one and the same data compression algorithm. In particular, a so-called lossless data compression algorithm is used which eliminates redundancy in the data without sacrificing any information content. There are several popular algorithms and variants of them which can be used for lossless compression. The most important examples are those of the Huffman, Arithmetic, and Lempel-Ziv (LZ) family. 
     Since the compression efficiency depends on the data characteristics of the destination address identifiers which the router deals with, parameters of the respective compressor, e.g. the code table, should be assigned or adjusted according to these characteristics. 
     As regards the data compression algorithm, a data compression algorithm can be used which utilizes a code table which assigns a symbol of the address information to be compressed a respective code word. Each code word has preferably a length which is inversely proportional to the appearance probability of the respective symbol in a given address table, for example an IPv6 address table. As a matter of course, the appearance probability of the symbols at the router input may also be considered to improve the overall performance. 
     By applying the above-mentioned data compression algorithm, the redundancy of the appearance distribution of some symbols or bit combinations in the destination address identifier is taken into account. Therefore, a kind of a spatial redundancy can be removed. However, there can still be other kinds of redundancy, e.g. redundancy in the time domain if there is a similarity of the destination address identifier for successive data packets. In order to remove such a redundancy in the time domain as well, there is preferably a feedback from the routing unit to the compressor unit used for compressing the destination address identifier so as to eliminate such a time domain redundancy and consider the similarity of a plurality of destination address identifiers within a data packet sequence. 
     Although the present invention can preferably be used for the routing of IPv6 data packets, the present invention is not limited to this preferred field of application and, as a matter of course, can be used for all kinds of data packets. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the following, preferred embodiments of the present invention will be explained in more detail with reference to the enclosed drawings. 
         FIG. 1  shows schematically an IP router according to a preferred embodiment of the present invention, 
         FIG. 2  shows an implementation example for an address compressor, a routing unit and a routing table shown in  FIG. 1 , using a Huffman data compression algorithm, 
         FIG. 3  shows an example for a code table for the address compressor shown in  FIG. 2 , 
         FIG. 4  shows an example for a hexadecimal address to be processed by the address compressor according to the code table shown in  FIG. 3 , 
         FIG. 5  shows a table illustrating the test results of a test concerning the compression ratio of different IPv6 address tables, 
         FIG. 6  shows the dependence of the number of averaged bits and the number of entropy bits per byte in an IPv6 address, and 
         FIG. 7  shows schematically an IP router according to the prior art. 
     
    
    
     DETAILED DESCRIPTION 
     In practice, much redundancy may be involved in the destination address identifier to be processed by an IP router. To explore how much redundancy may be involved in an IP address, an experiment was carried out that tested, with various address tables, how many bits are really necessary to represent the information included in a quad, i.e. 4 bits, of an IPv6 address. 
     In  FIG. 6 , the result of the test is shown in dependence upon the IPv6 address table size. A graph (i) shows the result of the test if a respective 4 bit-quad of an IPv6 address is compressed by using a Huffman encoder, i.e. graph (i) shows the number of averaged bits, which are obtained after the Huffman coding, depending on the address table size. In addition, a graph (ii) shows the number of entropy bits per quad depending on the address table size. That is to say graph (ii) shows the theoretical result, i.e. the number of bits which are really necessary to carry the information of the quad. From  FIG. 6  it can be seen that, instead of 4 bits, the necessary bit number varies between 1.5 and 2. As the address table size exceeds 3×10 6 , the number of bits which are really necessary to carry the respective address information reaches a stable value of about 1.8. This means a compression potential of approximately (at least) 50%. It is to be noted that in this experiment only the redundancy of appearance distribution of some symbols (bit combinations) in an address identifier was taken into account. This corresponds to a kind of spatial redundancy. There can still be other kinds of redundancy, for example a redundancy in the time domain if there is a significant similarity of the address identifiers for some data packets which are to be processed one after the other. 
     It is not easy for a general look-up method to consider all kinds of redundancy completely. The approach described in the following in detail, however, makes it possible to combine the routing table look-up technique with a data compression technique. While the former technique is associated with a searching operation in a compact address table, the latter technique deals with all possible kinds of redundancy. By combining the advantages of both techniques, an optimum solution for the routing table look-up problem can be achieved. 
       FIG. 1  shows the structure of an IP router according to a preferred embodiment of the present invention. Those components which correspond to the components shown in  FIG. 7  and having already been described before are indicated with the same reference signs as in  FIG. 7 . In order to avoid repetitions reference can be made to the description with respect to  FIG. 7 . 
     The IP router of  FIG. 1  differs from that shown in  FIG. 7  in that the IP router works in a compressed address domain. A first address compressor  7  is arranged in the path between the header extracting block  2  and the routing unit  3 . This address compressor  7  translates the destination address identifier provided by the header extracting block  2 , which comprises 128 bits for an IPv6 destination address identifier, for example, into an in average shorter form using a data compression algorithm. The compressed destination address identifier is then forwarded to the routing unit  3  and used as the key for the look-up operation with respect to the routing table  4 . In addition, an identical address compressor  8  is arranged in the path between the block  5  generating and updating the routing table  4  and the routing table  4 . Hence, the address compressor  8  stores the forwarding address information in a compressed form in the routing table  4  using the same data compression algorithm as the address compressor  7 . Thus, the routing table  4  is provided in a very compact form and, in particular, the routing table  4  is consistent with the compressed destination address identifier output by the address compressor  7  and used as the key for the look-up operation by the routing unit  3 . The routing unit  3  may use conventional methods for searching for a correspondence between the compressed destination address identifier and one of the compressed forwarding addresses stored in the routing table  4 . 
     The data compression algorithm used by the address compressors  7 ,  8  is particularly a so-called lossless data compression algorithm. Such a lossless data compression algorithm eliminates redundancy in the respective data without sacrificing any information content. There are several popular algorithms and variants of them which could be used for such a lossless data compression. The most important examples are the data compression algorithms of the Huffman, Arithmetic, and Lempel-Ziv (LZ) family. 
     Since the compression efficiency depends on the data characteristics of the destination address identifiers that the router deals with, at least some of the parameters of the address compressors  7 ,  8 , e.g. the code table used by the address compressor, should be assigned or adjusted according to or in dependence upon these data characteristics. Therefore, the IP router shown in  FIG. 1  comprises a compressor parameter block  9  which collects this information on the data characteristics of the respective destination address identifier from the header extracting block  2  and calculates the compression parameters for the data compression algorithm used by the address compressors  7  and  8 . 
     As already described above, the address compression effected by the address compressors  7 ,  8  takes into account the redundancy of the appearance distribution of some symbols (bit combinations) in the respective destination address identifier. However, there can be another kind of redundancy in terms of the similarity of the destination address identifiers of a plurality of successive data packets. In order to eliminate such a redundancy in the time domain as well, the IP router according to  FIG. 1  comprises a feedback connection from the routing unit  3  to the address compressor  7  used for compressing the destination address identifiers. Such a feedback from the routing unit  3  to the address compressor  7  allows to take into account the similarity of the destination address identifiers within a data packet sequence. This can be done, for example, by determining the forwarding address for the switch  6  on the basis of a forwarding address having been determined before in case the new destination address identifier, for which the forwarding address is to be determined by the routing unit  3 , is very similar to the respective preceding destination address identifier. 
       FIG. 2  shows an implementation example for the address compressor  7 , the routing unit  3 , and the routing table  4  shown in  FIG. 1 . In particular, this implementation example corresponds to an architecture for processing IPv6 data packets. Although  FIG. 2  shows a hardware diagram of the respective components, as a matter of course, the proposed architecture can be implemented with different hardware in software or in a combination of hardware and software as well. 
     The address compressor  7  shown in  FIG. 2  receives an extracted destination address identifier ADR from the header extracting block  2  shown in  FIG. 1 . In the case of an IPv6 data packet, this destination address identifier ADR comprises 128 bits which are divided into 32 4 bit-quads by a block  10 . Each quad is then translated into a code word comprising several bits using for example a code table shown in  FIG. 3 . This is done by a coding block  13 . 
     The code table shown in  FIG. 3  comprises a first column (A) listing all possible hexadecimal values of a quad comprising 4 bits. In a second column (B), the respective binary code assigned to each quad value is depicted. In addition, in a column (C) the code length for each code word is depicted. 
     The 32 code words output by the coding block  13  are then combined by an address composing block  14  so as to obtain the compressed destination address which is then buffered in a first buffer  20  of the routing unit  3 . In addition, there is a block  11  storing the respective code word length table corresponding to column (C) of  FIG. 3 , and a block  12  sums up the code word lengths output by the block  11  for the respective address identifier ADR. The result is then buffered in a second buffer  15 . Hence, the buffer  15  stores the sum of the length of the code words for the respective destination address identifier ADR, i.e. the length of the compressed address identifier, while the buffer  20  stores the combination of the code words assigned to the respective destination address identifier ADR, i.e. the compressed destination address identifier. The result stored in the buffer  15  is calculated by the block  12  on the basis of column (C) shown in  FIG. 3 , while the result stored in the buffer  20  is determined by the block  14  on the basis of column (B) shown in  FIG. 3 . 
       FIG. 4  shows an example for a destination address identifier ADR to be compressed in accordance with the code table shown in  FIG. 3 . According to the code table of  FIG. 3 , this address is compressed to 56 bits. Each “F” value results in 1 bit of the compressed address, each “E” value results in 1 bit of the compressed address, each “D” value results in 3 bits of the compressed address, the “B” value results in 5 bits of the compressed address, the “7” value also results in 5 bits of the compressed address, the “4” value results in 6 bits of the compressed address, and the “3” value also results in 6 bits of the compressed address. Hence, the compressed address determined according to the code table shown in  FIG. 3  comprises 22×1=22 bits for all “F” values, 1×6=6 bits for the “4” value, 1×5=5 bits for the “B” value, 1×6=6 bits for the “3” value, 1×5=5 bits for the “7” value, 3×1 =3 bits for all “E” values and 3×3=9 bits for all “D” values of the input destination address. Thus, the compressed address comprises 56 bits in total. 
     The code table shown in  FIG. 3  is generated by the compressor parameter block  9  shown in  FIG. 1  which outputs the compressor parameters CPAR used by the blocks  11 ,  13  of the address compressor  7  shown in  FIG. 2 . In particular, the code table of  FIG. 3  corresponds to a code having been implemented by a Huffman encoder. In the present case, the Huffman encoder assigns to each symbol (quad) a code word that has a length which is inversely proportional to the appearance probability of the respective symbol in an IPv6 address table comprising 872640 entries (13962240 bytes). The implementation of such a Huffman encoder, either in software or in hardware, can be found in many documents and publications dealing with data compression. Therefore, a detailed description of such a Huffman encoder or of the construction of the compressor parameter block  9 , which is implemented with a Huffman encoder, is not considered necessary. 
     The routing table  4  shown in  FIG. 2  is composed of possible forwarding addresses that are compressed with the same compression parameters CPAR, i.e. the same code tables as those used by the address compressor  7 . These compressed forwarding addresses are arranged in sub-tables according to their length. The compressed address length b 0 -b N , the number of entries n 0 -n N , and the base address a 0 -a N  of each sub-table are stored in a leading table  27 . The routing unit  3  works to find a match for the compressed input destination address in the compressed routing table  4 . This is effected as follows: 
     A block  17  reads an entry of the leading table  27  and sends the address length bi thereof to a length comparator  16 . The length comparator  16  compares the length of the compressed input address as stored in the buffer  15  with each entry read out by the block  17 . The length comparator  16  compares the length of the compressed input address with each address length b i  stored in the leading table  27  so as to find the corresponding sub-table. If a match is found by the length comparator  16 , a block  18  is reset, and thereafter the block  18  sends the base address a i  of the found sub-table to a block  24  and initializes a counter  23  to the number of entries n i  of the respective sub-table for the following address look-up operation. 
     Then, the routing unit  3  compares the compressed input address itself, as stored in the buffer  20 , with the compressed address c j,i  stored in the sub-table as determined by the above-described search operation. A block  24  reads an entry from the respective sub-table  28  and sends the address c j,i  to an address comparator  21 . This address comparator  21  compares the compressed input address stored in the buffer  20  with the compressed forwarding address provided by the block  24 . With each comparison operation effected by the address comparator  21 , an AND gate  22  decrements the counter  23 . Therefore, the comparison operation of the address comparator  21  is repeated until a correspondence is found between the compressed destination address and one of the compressed forwarding addresses stored in the sub-table  28 , or until the counter  23  is decremented to zero. An 1 bit-latch  25  holds the latest comparison results of the address comparator  21 . If there is a correspondence between the compressed input destination address and one of the compressed forwarding addresses stored in the sub-table  28 , the 1 bit-latch  25  generates a signal for a logic gate  26 , which effects a logic AND operation between the output signal of the 1 bit-latch  25  and an inverted output signal of the counter  23 . This output signal of the counter  23  has a low level as long as the counter  23  has not reached the value zero. Hence, the output signal VALID of the logic gate  26  indicates whether the output port number or output link number o j,i  currently processed by the block  24  is valid and can be used for the forwarding operation of the switch  6  (see  FIG. 1 ). It should be noted that the index “i” indicates the number of the respective sub-table, while the index “j” indicates the number of the respective entry within a sub-table. 
     A further block  19  of the routing unit  3  effects a byte alignment operation of the coded or compressed input address, which is stored in the buffer  20 , by zero padding of the remaining bits. 
     According to the implementation example shown in  FIG. 2 , each destination address identifier ADR is divided up into 4 bit-symbols. However, as a matter of course, the destination address identifier may also be divided up in a different manner. In addition, the code table shown in  FIG. 3  is determined only by considering the appearance probability of the respective symbols (quads) in a given address table, in the present case in an IPv6 address table. However, the appearance probability of the symbols at the router input can also be considered in order to improve the performance of the IP router. Finally, as already indicated above, the present invention is by no means limited to Huffman codes. Any lossless data compression algorithm can be used as a basis for the implementation of the address compressors  7 ,  8 , the routing unit  3  and the routing table  4 . 
     The model of using compressed destination address identifiers and compressed forwarding addresses was tested using a plurality of IPv6 address tables of various sizes.  FIG. 5  illustrates the test result. Column (A) indicates the number of the respective IPv6 address table, column (B) contains the number of entries of the respective IPv6 address table, column (C) contains the original sizes (bytes) of the IPv6 address table, column (D) contains the compressed sizes (bytes) of the IPv6 address table, and column (E) indicates the compression ratio (%) which could be achieved. As can be seen, the required size of the routing table can be reduced dramatically. This leads to an improved performance of the IP router and helps to save memory and power for the look-up operation. The test result coincides with the theoretical analysis of  FIG. 6 .