Patent Abstract:
A multi-module switching system comprising at least two switching modules adapted for receiving data packets from at least one input adapter and transmitting the data packets to at least one output adapter, each of the switching modules including a shared buffer for buffering a portion of a data packet received from an input adapter and transmitting the portion to an output adapter. One of the switching modules is a master module receiving a portion of a data packet containing a packet header and sending control information contained therein serially to each other switching module as a slave module. Each slave module includes a delay computing structure adapted for computing a delay needed to transmit the control information from the master module to this slave module and a first storing structure adapted for storing a portion of a data packet transmitted from an input adapter to the slave module during the delay, before transmitting the portion to a respective shared buffer such that the portion of data packet is not received by the shared buffer before the slave module has received the control information from the master module.

Full Description:
FIELD OF THE INVENTION 
   The present invention relates to telecommunications within a data transmission network and more particularly a multi-module switching system for achieving routing of packets from an input port to an output port of a router. 
   BACKGROUND OF THE INVENTION 
   The need for higher speed systems is increasing, particularly with the development of more sophisticated networks, multimedia applications and high speed communications. The needs are such that today, switches accepting speeds of 100 gigabits will be more and more in demand. However, a problem arises from the fact that the speed of a switch is strongly dependent on the actual technology that is used. 
   Therefore, for a given state of technology, it would appear difficult to achieve enhancement of switches that are known. There is therefore a need in the art for aggregating basic switching modules in such a manner that preserves the internal capabilities and efficiency of the module. Particularly, it is preferable that the aggregated switching structure does not require input or output ports, thus decreasing the number of ports that remain for a user. Additionally, it is preferable that the aggregate switching structure remains in a single stage. 
   Another problem arises from the circumstances that a user&#39;s premises are often equipped with line attachments that are fixed and determined for a relatively long period of time, as investments made in telecommunications equipment are often substantial. Therefore, although there is a strong need for higher speed switching systems, there is a desire for utilizing investments that have already been made, and thus for permitting a wide range of attachments. 
   As is known, speed expansion from input lines having a speed of 2 gigabits/second to input lines having a speed of 4 gigabits/second may be achieved by combining two switching modules. When received by an adapter, a packet may be split into two portions. A first portion containing a packet header with control information therein, for example routing or priority information, is sent to a master module while, at the same time, a second portion containing data is sent to a slave module. When the master module receives the packet header, validity of the packet is verified. If the packet is valid, the master module sends the control information to the slave module using a speed expansion bus. The slave module receives the control information within a packet cycle which, in one example, is 128 nanoseconds (hereinafter referred to as “ns”) with packets of 64 bytes. Subsequently, the portion of the packet respectively received in the master and slave switching modules is stored in a shared buffer. 
   Similarly, when control logic associated with a switch sends a packet to an output adapter, the master module reads the shared buffer and a packet address is sent from the master module to the slave module using the speed expansion bus. The packet address is received within a packet cycle by the slave module which then reads the shared buffer and both master and slave modules start to send respective portions of the packet at substantially the same time within the packet cycle. 
   Therefore, as is described hereinabove, it is possible to use two switching modules in association with a data transmission line, the speed of which has doubled, insofar as it is possible for the master module to send control information within a packet cycle. However, assuming that data speed expansion is such that a plurality of switching modules, for example eight (8) modules, are needed to accommodate a given data speed, it would no longer be possible to send the control information to all switching modules linked in series before data are received by each module. 
   Moreover, it would not be possible at relatively higher speeds to use a multi-drop configuration wherein the master module drives a single bus, or to implement a bus inside the master module because of the resulting large number of input/output ports in the module. 
   It is believed, therefore, that a multi-module switching system which provides the many advantages taught herein would obviate many of the problems and limitations described hereinabove, and would constitute a significant advancement in the art. 
   OBJECTS AND SUMMARY OF THE INVENTION 
   It is a primary object of the present invention to provide a multi-module switching system wherein data from an input adapter are received in slave switching modules at substantially the same time as control information is received through a speed expansion bus. 
   In accordance with one embodiment of the invention, these is provided a multi-module switching system comprising at least two switching modules adapted for receiving data packets from at least one input adapter and transmitting the data packets to at least one output adapter, each of the switching modules comprising a shared buffer adapted for buffering a portion of a data packet received from one of the input adapters and transmitting the portion of data packet to one of the output adapters, one of the switching modules being a master module adapted for receiving a portion of data packet containing a packet header and sending control information contained therein serially to each other switching module as a slave module, each slave module comprising a delay computing structure adapted for computing a first delay needed to transmit the control information from the master module to the slave module and a first storing structure adapted for storing the portion of data packet transmitted from the input adapter to the slave module during the first delay before transmitting the portion to the shared buffer such that the portion of data packet is not received by the shared buffer before the slave module has received the control information from the master module. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above and other objects, features and advantages of the present invention will be better understood by reading the following more particular description of the invention in conjunction with the accompanying drawings wherein: 
       FIG. 1  is a schematic diagram showing transmission of a data packet from an input adapter to an output adapter of a switching device wherein the device comprises eight switching modules according to one embodiment of the invention. 
       FIG. 2  is a diagram showing delays to be introduced for switching modules in an ingress path according to one embodiment of the invention. 
       FIG. 3  is a schematic diagram showing a delay computing structure used in a slave module to compute a delay for control information to reach the module according to one embodiment of the invention. 
       FIG. 4  is a diagram showing delays to be introduced for switching modules in an egress path according to one embodiment of the invention. 
       FIG. 5  is a schematic diagram showing a delay computing structure used in a slave module to introduce a programmed delay in ingress and egress paths according to one embodiment of the invention. 
       FIG. 6  is a diagram showing that processing time of a master module should be greater than a timing skew which may occur between links on a speed expansion bus. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
   Assuming that data packets are received in a port of an input adapter (not shown) from a link working at about 16 gigabits/second and that switching modules operate at a speed of about 2 gigabits/second, 8 switching modules  10 - 1  to  10 - 8  would be utilized as shown in  FIG. 1 . Data packet  12  received in an input adapter is divided into 8 portions of substantially the same size, with first portion  14  containing a packet header. The 8 portions of data packet  12  are transmitted respectively to switching modules  10 - 1  to  10 - 8  using a set of 8 physical connections, each connection operating at a speed of about 2 gigabits/second. First portion  14  containing a packet header is transmitted to first switching module  10 - 1 , also known as a master module, whereas the 7 other portions containing data payload are transmitted to switching modules  10 - 2  to  10 - 8 , also known as slave modules. 
   When master module  10 - 1  receives the packet header, control information contained therein is transmitted using speed expansion bus  18 - 1  to slave module  10 - 2 , which transmits the information to slave module  10 - 3  using speed expansion bus  18 - 2 , and so on, until slave module  10 - 7  transmits the information to slave module  10 - 8  using speed expansion bus  18 - 7  such that all slave modules receive control information containing a memory address at which data packet  12  is to be stored. In one example, speed expansion bus  18  (shown in  FIG. 3 ) comprises speed expansion bus  18 - 1  to  18 - 7 . 
   Similarly, when master module  10 - 1  retrieves data packet  12  from memory (not shown), control information is sent to slave modules  10 - 2  to  10 - 8 . When a slave module receives control information from master module  10 - 1 , the control information contains a memory address from which packet  12  is to be retrieved. The 8 portions are transmitted to an output adapter (not shown) using a set of 8 physical connections, and data packet  12 ′ with header  14 ′ may be re-assembled. 
   However, as described hereinabove, there is a delay during propagation of control information through a speed expansion bus from a switching module to a following switching module. As shown in  FIG. 2 , a delay from master module  10 - 1  to slave module  10 - 2  is also known as D 1 , a delay from slave module  10 - 2  to slave module  10 - 3  is also known as D 2  and so on, with a delay to propagate information from slave module  10 - 7  to slave module  10 - 8  also being known as D 7 . Therefore, a first delay may be introduced in a data path of a slave module to prevent a portion of data packet sent by an input adapter to a slave module from being received before control information is received thereby. If control information is not received first, a portion of data packet sent by an input adapter is discarded as this portion does not correspond to a destination address. Furthermore, a delay or data latency to be introduced starting at a time known as To is substantially the same delay as that taken for control information to reach a given slave module. In one example, To is a time at which master module  10 - 1  receives a packet portion containing control information for transmitting data payload to a corresponding slave module in an ingress path. For example, D 1  is introduced for slave module  10 - 2 , D 1 +D 2  for slave module  10 - 3  and so on, with D 1 +D 2 +D 3 +D 4 +D 5 +D 6 +D 7  introduced for slave module  10 - 8 . Also, data is transmitted to and from switching modules substantially contemporaneously with a time pulse delimiting a cycle corresponding to a portion of data packet being transmitted. For example, assuming that a packet comprises 64 bytes received at a speed of 16 gigabits/second, a packet portion cycle corresponding to transmission time of a data packet portion is about 32 ns in duration. Given a clock cycle of 8 ns, this packet portion cycle corresponds to 4 clock cycles. 
   Therefore, by way of example, delays D 1 , D 2  . . . . D 8  may be converted to a data latency as shown in Table 1 hereinbelow: 
   
     
       
             
             
             
           
             
             
             
           
         
             
                 
               TABLE 1 
             
             
                 
                 
             
             
                 
               Speed Expansion 
                 
             
             
                 
               Bus Delay 
               Data Latency 
             
             
                 
                 
             
           
           
             
                 
             
           
        
         
             
               0 to 32 
               ns 
               1 packet portion cycle 
             
             
               33 to 64 
               ns 
               2 packet portion cycles 
             
             
               65 to 96 
               ns 
               3 packet portion cycles 
             
             
               97 to 128 
               ns 
               4 packet portion cycles 
             
             
               129 to 160 
               ns 
               5 packet portion cycles 
             
             
               161 to 192 
               ns 
               6 packet portion cycles 
             
             
               &gt;192 
               ns 
               Error: speed expansion bus too slow 
             
             
                 
             
           
        
       
     
   
   The delay through a speed expansion bus may be computed for a given slave module. As shown in  FIG. 3 , a slave module, in one example slave module  10 - 2 , includes counter  30  which is incremented by clock pulses. At initialization time, master module  10 - 1  sends a synchro pulse to counter  30  of slave module  10 - 2 , and to respective counters (not shown) of slave modules  10 - 3  to  10 - 8  (shown in  FIG. 1 ) using synchro line  32  for resetting these counters to zero. Thereafter, a synchro bit is transmitted through speed expansion bus  18 . When a synchro bit is detected by synchro bit detector  34 , contents of counter  30  are loaded in delay register  36 . These components  30 ,  34  and  36  thus serve as a delay computing structure. Therefore, after propagation of a synchro bit through speed expansion bus  18 , respective delay registers of slave modules  10 - 2  to  10 - 8  (shown in  FIG. 1 ) contain a delay to be used for these slave modules. 
   In an egress path, a second delay may be introduced in a data path of master module  10 - 1  and slave modules  10 - 2  to  10 - 7  to allow these switching modules to send respective packet portions to an output adapter at substantially the same time, such that the packet portions reach the adapter at substantially the same time. A delay would not need to be introduced in a data path of slave module  10 - 8 , as this module is at the end of speed expansion bus  18 . As shown in  FIG. 4 , a delay introduced by master module  10 - 1 , also known as a maximum delay, is substantially the same as a delay to transmit control information from master module  10 - 1  to slave module  10 - 8  at the end of speed expansion bus  18 , i.e. D 1 +D 2 +D 3 +D 4 +D 5 +D 6 +D 7  ( 10 - 1  to  10 - 8  are shown in  FIG. 1 ,  18  is shown in  FIG. 3 ). A delay introduced by slave module  10 - 2  is substantially the same as a delay introduced by master module  10 - 1  minus delay D 1  and so on, with a delay introduced by an nth slave module being a delay for an n−1th slave module minus Dn. However, there is no delay introduced by slave module  10 - 8  at the end of speed expansion bus  18 . Therefore, with delays computed as described hereinabove, switching modules may transmit respective packet portions to an output adapter at substantially the same time, T 1 . Thus, the second delay is substantially equal to the maximum delay minus the first delay, i.e. a delay in which control information may be transmitted from master module  10 - 1  to a given slave module. It should also be noted that computed delays may be converted into data latencies as shown, for example, in Table 1 hereinabove. 
   A mechanism for transferring data packets for a given switching module, in one example slave module  10 - 2 , is shown in  FIG. 5 . Slave module  10 - 2  comprises shared buffer  40 , input FIFO queue  42  and output FIFO queue  44 . FIFO queue  42  buffers packet portions received from an input adapter, whereas FIFO queue  44  buffers packet portions to be transmitted to an output adapter. In FIFO queue  42 , data are written at a FIFO queue address defined by first write pointer  46 , and read at a FIFO queue address defined by first read pointer  48 . In FIFO queue  44 , data are written at a FIFO queue address defined by second write pointer  50  and read at a FIFO queue address defined by second read pointer  52 . 
   At initialization time, write pointer  46  is initialized by control program  54  using bus  56  with a delay value that has been loaded in delay register  36  (shown in  FIG. 3 ), whereas read pointer  48  is set to zero (0) using bus  58 . Thereafter, pointers  46  and  48 , controlled respectively by control program  54  using control lines  60  and  62 , are incremented such that data written into input FIFO queue  42  are transferred into shared buffer  40  with a delay substantially equal to a delay value contained in delay register  36 . In one example, the delay value is Dl for slave module  10 - 2 . Input FIFO queue  42  thus serves as a first storing structure in which a time interval between an operation of writing a portion of data packet controlled by first write pointer  46 , and an operation of reading a portion of data packet controlled by first read pointer  48  is substantially equal to the first delay, in one example D 1 . 
   Similarly, at initialization time, write pointer  50  is initialized by control program  54  using bus  64  with a delay that has been determined for a given switching module as shown in  FIG. 4 , whereas read pointer  52  is set to zero (0) using bus  66 . Thereafter, pointers  50  and  52 , controlled respectively by control lines  68  and  70 , are incremented such that data written into output FIFO queue  44  are transferred to an output adapter with a delay substantially equal to a delay for a given module. Thus, in one example, the delay value is D 2 +D 3 +D 4 +D 5 +D 6 +D 7  for slave module  10 - 2 . Output FIFO queue  44  thus serves as a second storing structure in which a time interval between an operation of writing a portion of data packet controlled by second write pointer  50 , and an operation of reading a portion of data packet controlled by second read pointer  52  is substantially equal to the second delay, in one example D 2 +D 3 +D 4 +D 5 +D 6 +D 7 . 
   It should be noted, however, that in order to provide a reduction in packet transit time through a switching module, packet portions may be processed in such a manner that only latency introduced in an egress path has an impact on packet transit time in a module. Consequently, data may be read from a shared buffer in master module  10 - 1  before a slave module at the end of speed expansion bus  18 , in one example slave module  10 - 8 , has written data into a respective shared buffer ( 10 - 1  and  10 - 8  are shown in  FIG. 1 ,  18  is shown in  FIG. 3 ). 
   Due to the nature of physical links used in speed expansion bus  18 , a timing skew may be introduced between links used for ingress and egress paths. However, a given module should not transmit data from a respective shared buffer before associated data have been written in a respective shared buffer of another module, in one example slave module  10 - 8 , at the end of speed expansion bus  18 . As shown in  FIG. 6 , processing time of a master module, in one example master module  10 - 1 , should be greater than a timing skew that may occur between links of speed expansion bus  18 . 
   While there have been shown and described what are at present the preferred embodiments of the invention, it will be obvious to those skilled in the art that various changes and modifications may be made therein without departing from the scope of the invention as defined by the appended claims.

Technology Classification (CPC): 7