Abstract:
The present invention relates to a data processing system comprising a processor provided with two memory access units operating in parallel; two separate memories respectively associated with the two access units; and circuitry for, when the address of a datum to be written into a memory is in a predetermined address range, writing the datum into both memories at the same time at the same address.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a digital signal processor (DSP), and more specifically to a memory organization particularly well adapted to a DSP. 
     2. Discussion of the Related Art 
     FIG. 1 schematically and partially shows a conventional DSP architecture. The DSP includes four processing units operating in parallel. Two of these units are memory access units  10 . An arithmetic unit  12  and a branch management unit  14  are further provided. Each of memory access units  10  is associated with an independent memory bus X or Y. A program memory  16  contains compound instructions INST, each compound instruction being actually formed of four simple instructions (INST 1 -INST 4 ) provided at the same time to the respective units  10 ,  12 , and  14 . Of course, the four units are often not used at the same time. Then, the compound instruction provided by memory  16  includes NOPs corresponding to the unused units. 
     A DSP of the type of FIG. 1 is optimized to perform vector operations of the type x[i] OP y[j], where i and j vary, generally in a loop, and where OP designates any operation to be performed by arithmetic unit  12 . Indeed, operands x[i] and y[i] can be fetched together via, respectively, bus X and bus Y and processed in the same cycle by arithmetic unit  12 . 
     For this type of operation, values x[i] and values y[i] can be respectively stored in two independent memories respectively connected to buses X and Y. 
     However, a DSP may also need to perform operations of the type z[i] OP z[j], the values of z being all stored in a same memory. In this case, a value z, according to the unit  10  which receives the corresponding read instruction, may be fetched at one time by bus X, at another time by bus Y, or even by both buses at the same time. Thus, access should be possible to a same value z over both buses X and Y. 
     Theoretically, a dual port memory connected to buses X and Y may be used for this purpose. However, dual port memories are particularly costly in terms of surface. 
     FIG. 2 illustrates a memory organization which is preferred given the fact that the number of values submitted to operations of the type z[i] OP z[j] is relatively low. This organization includes a dual port memory  18 , the size of which is sufficient to contain “z”-type values, that is, the values which have to be accessible over both buses X and Y. Two single port memories  20  and  22  are respectively associated to “x”-type values and to “y”-type values, the “x”-type values being those which are only accessible over bus X and the “y”-type values being those only accessible over bus Y. 
     The first address bus of dual port memory  18  and the address bus of single port memory  20  are connected to address bus XA of memory bus X. Similarly, the second address bus of dual port memory  18  and the address bus of single port memory  22  are connected to address bus YA of memory bus Y. The first data bus of memory  18  and the data bus of memory  20  are routed to data bus XD of memory bus X via a multiplexer/demultiplexer  24 . Similarly, the second data bus of memory  18  and the data bus of memory  22  are routed towards data bus YD of memory bus Y by a multiplexer/demultiplexer  26 . 
     A decoder  28  controls multiplexers/demultiplexers  24  and  26  according to the addresses presented over buses XA and YA. In particular, when the address present on bus XA is in a specific range, decoder  28  controls multiplexer/demultiplexer  24  to route bus XD to memory  18 . Outside the specific range, decoder  28  routes bus XD to memory  20 . The same mechanism is used to control multiplexer/demultiplexer  26  according to the address present on bus YA. 
     Despite the complexity of multiplexers/demultiplexers  24  and  26 , the surface occupied by this memory organization is generally smaller than that occupied by a single dual port memory gathering memories  18 ,  20 , and  22 , this given the fact that the capacity of dual port memory  18  is relatively low. 
     Multiplexers/demultiplexers  24  and  26  considerably increase the latency times of the read and write operations in the memories. 
     SUMMARY OF THE INVENTION 
     An object of the present invention is to provide a memory organization adapted to a digital signal processor enabling access to a same datum by two distinct channels while occupying a particularly small surface and not affecting the latency times of access to the data. 
     This and other objects are achieved by means of a data processing system comprising a processor provided with two memory access units operating in parallel; two separate memories respectively associated with the two access units; and means for, when the address of a datum to be written into a memory is in a predetermined address range, writing the datum into both memories at the same time at the same address. 
     According to an embodiment of the present invention, said means comprise two identical write instructions provided at the same time to the two access units. 
     According to an embodiment of the present invention, said means comprise a first multiplexer connected to copy, in a first access unit a write instruction provided to the second access unit when the write address is in the predetermined range. 
     According to an embodiment of the present invention, said means comprise a second multiplexer connected to copy into the second access unit a write instruction provided to the first access unit when the write address is in the predetermined range. 
     The foregoing objects, features and advantages of the present invention will be discussed in detail in the following non-limiting description of specific embodiments in connection with the accompanying drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1, previously described, schematically and partially shows a conventional DSP memory architecture; 
     FIG. 2 schematically shows a conventional organization adapted to a DSP of the type of FIG. 1; 
     FIG. 3 schematically shows a memory organization according to the present invention; 
     FIG. 4 illustrates a solution enabling to use the memory organization of FIG. 3, in a specific case where it is not desired to modify the program of a conventional DSP; and 
     FIG. 5 illustrates an alternative to the solution of FIG.  4 . 
    
    
     DETAILED DESCRIPTION 
     In FIG. 3, a memory organization for a DSP of the type in FIG. 2 comprises two single port memories  30  and  32  only. Memories  30  and  32  are respectively connected to buses X and Y of the DSP of FIG.  1 . Memory  30  comprises an area X for storing “x”-type values, while memory  32  comprises an area Y for storing “y”-type values. The two areas correspond to memories  20  and  22  of the conventional organization of FIG.  2 . It should be reminded that the “x” or “y”-type values are those to which access is always had over the same bus X or Y. 
     According to the present invention, each of memories  30  and  32  is increased by a respective area Z of same size for containing the “z”-type values, that is, the values which must be accessible either over bus X, or over bus Y. Areas Z of memories  30  and  32  are exact copies of each other and are accessible by a same address range, for example, the addresses used to access to memory  18  of FIG.  2 . In other words, if access is had over bus X to a value in area Z of memory  30 , access can be had to this same value at the same address in memory  32  over bus Y. 
     Of course, for such a memory organization to properly operate, it is necessary to ensure that each value written into area Z of memory  30  is also written at the same address in memory  32 . 
     In a conventional memory organization of the type in FIG. 2, to write a value z into memory  18 , it is enough to provide a write instruction to any of the access units  10  of the DSP of FIG.  1 . By so operating with a memory organization of the type in FIG. 3, value z is written into a single one of memories  30  and  32 , which is not desirable. 
     In order to avoid this, an advantageous solution comprises modifying the instructions of the DSP program to always provide to both access units  10  a same instruction of writing of a “z”-type value. This solution requires no hardware modification of the DSP or of the memory organization. 
     The surface occupied by the two redundant areas Z is comparable to the surface occupied by dual port memory  18  of FIG.  2 . However, multiplexers/demultiplexers  24  and  26  and decoder  28  are omitted, which enables a significant surface saving and a decrease of the latency time of access to memories  30  and  32 . 
     FIG. 4 illustrates a solution to write a “z”-type value into both memories  30  and  32  without modifying the DSP program. The instruction input of second memory access unit  10  is preceded by a multiplexer  34  that selects the instruction INST 2  provided to this unit, or the instruction INST 1  provided to the first unit  10 . The position of multiplexer  34  is determined by a decoder  36  according to the address carried in the write mode by instruction INST 1 . If this address corresponds to a value z, multiplexer  34  is positioned to select instruction INST 1 . Otherwise, it is positioned to select instruction INST 2 . 
     This solution of course requires a modification of the DSP of FIG.  1 . The surface occupied by multiplexer  34  and decoder  36  is, however, relatively low. Further, this solution assumes that the write instructions of values z always arrive over bus INST 1 . 
     FIG. 5 illustrates an alternative to the solution of FIG. 4, by means of which the programmer no longer has to take account of the position of a write instruction for a “z”-type value. An additional multiplexer  38 , also controlled by decoder  36 , precedes the instruction input of the first memory access unit  10  to select one or the other of the two instructions INST 1  and INST 2 . When one or the other of instructions INST 1  and INST 2  is a write instruction for a value z, decoder  36  detects it and positions multiplexers  34  and  38  to duplicate this instruction on both memory access units  10 . 
     A problem arises when a write instruction for a “z”-type value and another memory access instruction arrive at the same time. It is not possible to have them executed at the same time by both units  10 . The DSP programmer or the compiler could make sure that both accesses are assigned to distinct cycles. 
     The embodiment of FIG. 5, however, frees the programmer or the compiler from this constraint. For this purpose, decoder  36  is provided to detect the presence over buses INST 1  and INST 2  of two simultaneous memory accesses, one of which is a writing of a value z. Decoder  36  then activates a signal ST indicating a latency of one cycle, and performs two successive positionings of multiplexers  34  and  38 . In the first position, for example, the multiplexers transmit, to units  10 , two copies of the write instruction of value z. In the next position, the multiplexers transmit the other instruction of access to the corresponding unit  10 . Preferably, the other unit  10  then receives a null statement (NOP), but this is difficult to implement without providing additional circuits. Actually, this other unit can receive again the write instruction of value z, which causes the writing twice in a row of the same value at the same memory location, that is, the state of the memory remains unchanged. 
     Of course, the present invention is likely to have various alterations, modifications, and improvements which will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be part of this disclosure, and are intended to be within the spirit and the scope of the present invention. Accordingly, the foregoing description is by way of example only and is not intended to be limiting. The present invention is limited only as defined in the following claims and the equivalents thereto.