DE4403791A1 - Data processing system - Google Patents

Abstract

The invention relates to a data processing installation with a working memory addressable by a controller which can be switched to its various memory areas by signals. To make the switchover as simple as possible, each working memory area (e.g. A3) has in its program storage field (e.g. P3) at least one global function (F3) which can be called from at least one other working memory area (e.g. A1). In each working memory area (e.g. A1) there is at least one predetermined function (F1) from which a transfer can be made to an identical function as a simulation function (F2). A changeover routine (e.g. U1) is linked on the one hand to the simulation function (F2) of the same working memory (e.g. A1) and on the other to a changeover routine (e.g. U2) of the other working memory (e.g. A3) in which the global function (F1) allocated to said simulation function (F3) is stored. A shared changeover module is allocated to all the working memory areas (A1 to A4).

Description

The invention relates to data processing system with an addressable by a controller Main memory in which the corresponding to the address of the processor in several RAM divided memory by signals in its memory Working areas is switchable, the program spec part of each working memory area closed system forms.

In known data processing systems of this type the construction of the known data processing system with divided memory because chosen with regard to the size of the addressable used there RAM of the controller itself is not sufficient. The working memory of the known data processing system is therefore in several working memory areas with each because several program memory parts (EPROMs) and each because a data storage part (RAM) divided. To order switch from the program memory part of a working memory area in the program memory part of another Memory area are address lines with port pins connected.

The invention has for its object in a Data processing system with one in several workplaces memory areas divided a simple Switching option to suggest which use allowed by standardized software systems.  

To solve this task contains a data processing processing plant of the type specified in the beginning according to the program memory part of each working memory at least one global function is saved, the at least one from each program memory part additional memory area can be called; in pro part of the gram memory of each working area is min at least a function is given, from which to an iden table function as a simulation function in each same program memory part is jumpable, and in the Pro part of each working memory area a switching routine is available, which on the one hand with the Simulation function of the same program memory part and on the other hand with the switching routine of the program memory part of the further memory area linked in which the one assigned to this simulation function Global function is filed; all program memory len is assigned a common switch module.

An essential advantage of the data ver work system is that a switch from the program memory part of a working memory area on a program memory part of another work memory area is made by program steps, via simulation functions and switching routines expire. The simulation function and also the shift routine remains both for the calling function as well as for the global function called "invisible". The program memory part can each RAM area a self-contained Represent system that compiles, links and compiles separately is located. It can thus be used, for example a device of selective protection technology protection functions assigned program packages without changing the ver  integrate different memory areas so that existing programs for various under different protective functions in the invention Data processing system easily combined with each other can be renated. On the other hand, there is no problem the possibility of individual program memory parts Programs allocated to memory areas on a to transfer another device.

For example, it is from W. Diehl's book "Microprocessors and Microcomputers" 3rd edition, 1980, Pages 157 to 159 known the entire area of a Subdivide memory into pages, however the subdivision takes place here with indirect addresses to be able to work.

The variables can be used in the data ver work system addressable in different ways his. It is considered advantageous if for the Program memory parts of the working memory areas inter essential (global) variables in a common data memory section for all working memory areas on the same ben physical address. It is special expedient that all global variables in one module are summarized for all memory areas is identical and with respect to the variables on a ge common address is set.

Furthermore, it is considered advantageous if the data memory area of the working memory apart from the common Men data storage part for memory area spec fish variables and all global variables Module has other data storage parts, the over Drivers are responsive. From the other data storage  sharing can be addressed directly; the rest on the other hand, it should be possible to address the drivers.

To explain the invention is in

Fig. 1 is a representation of the division of the working memory of the data processing system according to the invention and in

Fig. 2 shows the functional principle of the program memory parts switching of the working memory.

In the case of the exemplary embodiment dealt with, it is assumed that a controller, for example a Siemens 80C166 processor, is used in the data processing system, which can operate a memory with a volume of 256 kbytes. The program code and the data must therefore be accommodated in this 256 kbyte. Since the main memory A used (cf. FIG. 1) has a considerably higher memory capacity than 256 kbytes, the total main memory A is divided into four main memory areas A1 to A4. Each working memory area A1 or A2, A3 and A4 contains a program memory part (EPROM) P1 or P2, P3 and P4 and a data memory part D1 or D2, D3 or D4 (RAM / EEPROM); in addition, a common data storage part D5 is provided. The distribution of the entire working memory is freely selectable except for the areas marked B and C in FIG. 1. The areas B and C are determined by the controller.

Each of the four program memory parts P1 to P4 comprises 128 Kbyte. Each program memory part P1 to P4 contains one self-contained system that compiles separately, linked and located. Selective for one device  Protection technology can, for example, in the program memory section P1 the operating system, in the program memory part P2 the Program code for an overcurrent protection function and in Program memory part P3 the function of a switch Ver sager protection must be stored as program code; the pro P4 can store the program code z. B. for one Differential protection included.

To further illustrate the switching of a per a working memory area program storage part on a program storage part of another work garbage ches is hereinafter with respect to FIGS. Taken 2, in which from the memory A of FIG. 1, only the Pro program memory parts P1 and P3 of the work memory areas A1 and A3 are shown. It is assumed here that after a series of function calls, the data processing system in the program memory part P1 of the working memory area A1 comes to a predetermined function F1, which is not further defined in this program memory part. There is therefore a jump S1 to a simulation function F2 which is identical to a function F3 to be called. The simulation function F2 calls the switchover routine U1 with a transfer parameter which contains a fixedly processed function and address area number of the destination, which is the global function F3; The simulation function F2 is defined by this global function F3. The switching routine U1 saves this information, shifts the number of the currently set working memory area, in the present case the working memory A1, to the system stack, blocks all interrupts and switches the number of wait states to the maximum value. There is now a switchover, which means that the working memory area A3 is immediately accessed. The prerequisite for this is that at the time of locating the individual working memory areas, the address routing of the switchover routine U1 with the switchover routines of the other working memory areas A2 to A4, and also the switchover routine U2 of the working area memory A3, has been ensured. After the old state of the wait states and the interrupt has been restored, the number of the global function F3 to be executed is evaluated in the working memory area A3 or in its program memory part P3. This table serves a table that jumps to global function F3.

After the global function F3 in memory Rich A3 has been processed to normal Return command to the further switching routine U2 jumped back. The switching routine U2 gets the In formation from which working memory area (here Ar Working memory area A1) was switched over by the system stack; all interrupts are also blocked and the number of wait states is switched to the maximum value. After this switchover, the switchover routine U1 the original states of In in the working memory area A1 terrupt release and number of wait states poses. The switching routine U1 changes back to the Simulation function F2, in which at this point only is returned to the default function F1.

There is a for all working memory areas A1 to A4 common. Range switching module, the one on the left must be linked. This module is for everyone Memory areas A1 to A4 are identical and will be at compilation or system generation with one memory-specific compiler switch translated,  that is, the respective switching module will work memory area specific from a standardized order switching module formed.

As mentioned above, the data store points area of the working memory A four data storage parts D1, D2, D3, D4 and a common data storage part D5 on. Also with regard to these storage parts a data processing system according to the invention circuit, however this switching is from the program Memory parts switchover independent and must be done separately respectively. In the data processing according to the invention are global variables in a separate module in the system common data storage part D5 summarized and at Locates placed on a defined address. This module is identical for all memory areas A1 to A4.

Global variable that is only within a data store some D1 to D4 should be known (for example stati cal variable), must be in one for each data store part D1 to D4 separate area.

In the illustrated case, each data storage part comprises D1 up to D4 64 kByte. Are in the data storage part D1 EEPROM (low byte) and NV-RAM (high byte). The dates Memory parts D2 to D4 are formed by normal RAMs. The common data storage part D5 is independent of the set data storage parts D1 to D4 always available. This area includes in the illustrated embodiment Example 58.5 kByte.

Data in the data storage part D1 is accessed about special drivers. The same applies to the data of the data storage parts D2 and D3, which in a device of  Selective protection, for example for fault write buffer right are served. The addressing of these areas is over another special driver possible. On the data the data storage parts D4 and D5 can return immediately be gripped.

The switching of the individual data storage parts takes place through a driver routine in which a transfer parameter specifies which part is switched to.

Claims (5)

1. Data processing system with a memory addressable by a controller, in which

• the working memory divided into a plurality of working memory areas according to the addressing ability of the processor can be switched over by signals in its working memory areas, each working memory area forming a self-contained system,

characterized in that

• - The program memory part (z. B. P3) of each working memory area (z. B. A3) contains at least one global function (F3) stored, which from a program memory part (z. B. P1) each has at least one additional working memory area (z B. A1) can be called up,
• - In the program memory section (e.g. P1) of each working memory area (e.g. A1) at least one function (F1) is specified, from which an identical function as a simulation function (F2) is in each case in the same program memory section (e.g. P1) is jumpable,
• - In the program memory section (e.g. P1) of each working memory area (e.g. A1) there is a switchover routine (e.g. U1) which, on the one hand, works with the simulation function (F2) of the same program memory section (e.g. P1 ) and on the other hand is linked to the switchover routine (e.g. U2) of the program memory part (e.g. P3) of the other working memory area (e.g. A3) in which the global function (F3) assigned to this simulation function (F2) is filed and
• - All program memory parts (P1 to P4) a common switch module is assigned.

2. Data processing system according to claim 1, characterized in that

• - For the program memory parts (P1 to P4) of the working memory areas (A1 to A4) interesting (global) variables in a common data storage part (D5) for all working memory areas (A1 to A4) are at the same physical address.

3. Data processing system according to claim 2, characterized in that

• - All global variables are summarized in a separate module
• - is identical for all working memory areas (A1 to A4) and is assigned to a defined address with regard to the variables.

4. Data processing system according to one of the preceding claims, characterized in that

• - The data storage area of the main memory (A), in addition to the common data storage part (D5) for working memory area-specific variables and the module which is unique to all global variables, has further data storage parts (D1 to D4) which, apart from a data storage part (D4), can be addressed by drivers.