Patent Document

TECHNICAL FIELD OF THE INVENTION 
   This invention relates to a memory controller, and in particular to a controller for a SDRAM (Synchronous Dynamic Random Access Memory) device, although the invention is also applicable to other types of memory, and to a method of operation of a memory controller. 
   BACKGROUND OF THE INVENTION 
   Computer systems must be provided with sufficient data storage capacity to operate correctly. This data storage capacity is typically provided as Random Access Memory (RAM), and SDRAM is a common form of RAM. 
   However, the rate at which data can in practice be transferred from a SDRAM remains lower than the rate at which data can in theory be transferred. That is, each access request sent to a SDRAM memory chip, relating to a read operation, incurs a read latency. 
   When a master device makes multiple read access requests, this read latency can be incurred for each access request. 
   Accesses to the SDRAM chip are performed by a SDRAM controller, which typically takes the form of an integrated circuit which is separate from the SDRAM. The SDRAM controller is connected to the SDRAM by means of a memory data bus, and the SDRAM controller must operate as far as possible to maximize efficient use of the bandwidth of that bus. 
   SUMMARY OF THE INVENTION 
   It is an object of the present invention to minimise the time required to return all of the data read from the memory to the requesting master, while also ensuring efficient use of the bandwidth of the memory data bus. 
   More specifically, according to a first aspect of the present invention, a SDRAM controller determines for each received access request whether the required data can be retrieved in a single burst, or whether multiple bursts are required. 
   The SDRAM controller forms a queue of bus access requests, and, if multiple bursts are required for a single read access request, the bus access requests relating to the multiple bursts are queued effectively simultaneously, or at least on successive clock cycles. 
   This has the advantage that the overall performance of the computer system is optimized since a higher bandwidth can be achieved on the memory data bus, thereby allowing the memory to be used more efficiently. 

   
     BRIEF DESCRIPTION OF DRAWINGS 
       FIG. 1  is a block schematic diagram of a computer system in accordance with the present invention. 
       FIG. 2  is a block schematic diagram of a SDRAM controller in the computer system of  FIG. 1 . 
       FIG. 3  is a flow chart illustrating a method in accordance with the present invention. 
   

   DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS 
     FIG. 1  is a block schematic diagram of a computer system  10 . The general form of the system  10  is conventional, and will be described herein only to the extent necessary for a complete understanding of the present invention. 
   In the illustrated embodiment, the system  10  includes an application-specific integrated circuit (ASIC)  20 , which includes various modules  25 , such as a processor core (CPU)  27 . These modules are interconnected by a bus  30 , which may advantageously be an AHB bus, but which can be any convenient form of bus. 
   However, the invention is not limited to such a structure. The invention is also applicable to a device such as a programmable logic device (PLD) or field programmable gate array (FPGA), which can then be configured to contain multiple modules which act as bus masters. The device may then, but need not, contain an embedded processor. 
   Connected to the ASIC  20  is a memory chip  40 , in the form of a Synchronous Dynamic Random Access Memory (SDRAM). 
   Accesses to the SDRAM  40  from the ASIC  20  are performed by a specific SDRAM controller  50  connected to the bus  30  in the ASIC  20 . 
   Again, the invention is not limited to such a structure. The SDRAM controller  50  may be integrated with the bus masters in a single device, or may be provided as a separate device. 
   The SDRAM controller  50  is connected to the SDRAM  40  by way of a memory bus  60 , which in the illustrated embodiment of the invention is also an AHB bus. 
     FIG. 2  is a block schematic diagram, showing the form of the SDRAM controller  50 . 
   The SDRAM controller  50  is shown in  FIG. 2 , and described herein, only to the extent required for an understanding of the present invention. Other features of the SDRAM controller, which are not required for that purpose, will not be described, and may be assumed to be generally conventional, as known to the person of ordinary skill in the art. 
   In the illustrated embodiment, the SDRAM controller  50  has multiple bus interface blocks  52 , for connection to respective bus master devices. For example, in the system shown in  FIG. 1 , there may be one bus interface  52  allocated for connection to each of the modules  25  and the CPU  27 . However, in other embodiments of the invention, there may be only one such bus interface block. 
   Memory access requests, received by the SDRAM controller  50  at the bus interface blocks  52 , are passed to a control logic block  54 , the operation of which is described more fully below. 
   After processing in the control logic block  54 , the memory access requests are placed in a queue in a queue store block  56 , which may for example take the form of a first-in, first-out memory. The memory access requests from the queue are then passed in turn to a SDRAM interface block  58 . 
     FIG. 3  is a flow chart, illustrating a method performed in the control logic block  54 , according to an aspect of the present invention. 
   The process starts at step  300 , when a read access request is received at a bus interface  52  from one of the master devices. 
   The read access request indicates the amount of required data with reference to the properties of the AHB bus  60 , namely the burst length, which is a feature of the bus protocol, and the AHB word size, which can be less than or equal to the width of the bus. The read access request also indicates the burst type, i.e. whether a wrapping burst or an incrementing burst is required. 
   Also in step  300 , the control logic  56  reads the starting address of the request, that is, the address within the SDRAM  40  from which data is first to be retrieved. 
   In step  308 , the control logic  56  then calculates the number of SDRAM bursts required to fulfil the access request. 
   For example, if the AHB word size is 64 bits, and the AHB burst length is 16, while the SDRAM word size is 32 bits, and the SDRAM burst length is 8, then four SDRAM bursts are required to fulfil the access request if the starting address of the request corresponds with a SDRAM burst boundary, while four or five SDRAM bursts are required, depending on whether the burst type is wrapping or incrementing, if the starting address of the request does not correspond with a SDRAM burst boundary. 
   As another example, again taking the SDRAM word size to be 32 bits, and the SDRAM burst length to be 8, if the AHB word size is 32 bits, and the AHB burst length is 8, but the starting address of the request does not correspond with a SDRAM burst boundary, then two SDRAM bursts are required to fulfil the access request if the access request indicates that the required burst type is incrementing, as opposed to wrapping. 
   Next, the control logic  54  determines the starting SDRAM addresses of the required SDRAM bursts. Thus, in step  312 , the control logic then translates the AHB address into a SDRAM address, within the SDRAM  40 . In the case discussed above, where more than one SDRAM burst is required, the control logic calculates the SDRAM address for the first SDRAM burst. The SDRAM address is made up of a SDRAM chip select, a SDRAM row address and a SDRAM column address. 
   Thus, a set of SDRAM devices returning data for a particular request comprise a physical bank of memory. Multiple physical banks may be provided, in which case each physical bank is accessed using a different chip select. Within the physical bank, a specific memory location is defined by a row address and a column address. The calculated SDRAM address therefore uniquely identifies a memory location within the memory device. 
   In step  314 , in the case where more than one SDRAM burst is required, the control logic  54  also determines SDRAM addresses for the remaining SDRAM bursts. 
   In each case, since the chip select and starting row address values remain the same throughout an AHB burst, the calculated starting SDRAM addresses for the second and subsequent SDRAM bursts need relate only to the column address values. 
   The separate read requests for each required SDRAM burst, including the respective starting addresses, are then placed into a queue of access requests in the queue store  56  of the SDRAM controller  50 . The stored access requests are then handled in turn by the SDRAM interface  58 . 
   As is known to the person skilled in the art, the control logic  56  may also, in addition to the processes described herein, apply a form of prioritisation to the access requests when placing them into the queue of access requests in the queue store  56 . For example, access requests received on different bus interfaces  52  may be given different priorities. 
   In addition, or alternatively, access requests received on different bus interfaces  52  may be prioritised in a way which maximises the efficiency of use of the memory bus  60 . For example, opening a page of the SDRAM to process an access request results in a delay in processing. Therefore, it is advantageous if access requests relating to the same page of the SDRAM can be queued consecutively. 
   In accordance with the invention, therefore, the SDRAM controller can ensure that, for an AHB burst corresponding to multiple SDRAM bursts, the access requests corresponding to the multiple SDRAM bursts are queued together, so that the read latency is incurred only once. When placing the multiple access requests in the queue store  56 , a flag may be set on at least the first of said stored access requests. This allows the SDRAM controller  50  to perform back-to-back SDRAM read bursts, and therefore increases the effective rate at which data can be read from the SDRAM. 
   Further, when enough SDRAM read bursts have been performed to retrieve all of the data requested in the access request received on the bus interfaces  52 , no additional data need be retrieved. 
   The invention has been described herein with reference to one particular embodiment. However, other embodiments of the invention are also possible. The scope of the present invention is therefore to be determined only by the accompanying claims.

Technology Category: 3