DK142635B - PROCEDURE FOR CYCLING TRANSFER OF DATA IN PROGRAM MANAGED DATA PROCESSING SYSTEMS - Google Patents

Description

(11) PUBLICATION NOTICE 1 ^ 2635 DENMARK (51) Int. Cl.3 6 06 F 9/00 H 04 L 11/00 '(21) Application No 5O7O / T2 (22) Filed on 20 · Jun · 1972 (24) Running day 20 Jun. 1972 (44) The application submitted and "

the petition published on '· · * yoU

DIRECTORATE OF

PATENT AND TRADE MARKET (30) Priority requested from it

Jun 24 1971, 2151449, DE

(71) SIEMENS SHARE COMPANY, Berlin and Munich, 8 Munich 2, Wittels = "oacherplatz 2, DE.

(72) Inventor: Anton Kammeri, 8051 Groebenzell, Weiherweg 5 # DE: Alois

Schwarz, 8 MuencHen 25 # Lindenschmitstrasøe 5a # DE: Gerhard Jaskulke, 606 Dachau, Pollnstrasse 14, DE. ^ (74) Plenipotentiary in the proceedings:

International Patent Bureau · (54) Procedure for cycle-wise transfer of data in program-controlled data = * processing facilities.

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a method of cyclically failing to transmit data in program controlled data processing systems, in particular program controlled connection establishment systems, between a connecting unit to which arriving and departing wires are connected, and at least one central storage unit over a transmission unwinding controller located in the connecting unit. contains a first storage area with spend cells permanently attached to the arriving wires and contains criteria for processing arriving information, a second storage area for recording data to be entered based on the assessment of the contents of a spend cell, a third storage area for recording commands determined for the connection unit formed by program-controlled processing of this entered data in a program controller, and a fourth storage area with substitution cells, each of which storage areas are individually addressable by area starting addresses.

2 142635 In a known data processing plant of this kind, the processing unit to which the arriving and departing connections are connected, as well as all other processing units in such a system, cyclically with a central storage unit. The request of a storage cycle occurs in the manner that upon occurrence of information on an oncoming connection, a cycle request is produced and at the same time an identification of the connection that presents the request is performed. On the basis of the identification, an attaching cell is attached in the central storage unit to each arriving connection, which contains certain criteria for controlling the further processing of this information. For example, if the arriving information is to be transmitted to a specific outgoing connection, the spend cell contains, in addition to address information which characterizes a particular outgoing connection, a so-called through-out criterion, when it is determined that it is found that the information offered over the arriving connection must be transferred to the one in the connecting unit identified, desired outgoing connection.

As an example of such a data processing system, FIG. 1 shows the basic structure of a connection establishment system. Incoming and outgoing connections are connected to a connection unit LE. This includes a system connection unit SAE, input and output code converters ECW and ACW and at least one transmission execution controller UEAS, over which the connection unit connects to a central storage unit SP. In accordance with the tasks to be performed, program-controlled operations are carried out in the system, with all necessary data and programs contained in the central storage unit.

To illustrate the principle operation of such a connection establishment, it can be assumed that on arrival an information occurs in the form of a polarity change, which must be transmitted to a particular outgoing connection. Upon receipt of the polarity change in the connection unit, the system connection means SA associated with the incoming connection is identified by means of the input encoder ECW, and at the same time a cycle request to the central storage unit SP is directed over the transmission settling unit UEAS. On the basis of the address provided by the identification at the particular attachment cell attached to the requesting connection in the storage unit, access to this attachment cell is obtained. During the signaling process, this address cell inserts the address of the desired outgoing connection. At the same time, the delivery cell contains a criterion, e.g. in the form of a set bit, by means of which it can be ascertained that it is a through connection and that the arriving information must be transmitted to the outgoing connection. When reading out the spend cell, the address reaches the transmission execution controller where it is made available to the output encoder ACW, which then identifies the desired outgoing connection and transmits the information, ie. the polarity shift, to this one.

3 1A 2 6 3 5

In the operation described above, it is assumed that an address for identifying the desired outgoing connection is already inscribed in the delivery cell, which means that it is a gene-linked connection. Only in the case of pure information transfer between an arriving and a departing connection, an operation takes place in this simple way. However, both program-controlled operations must always be carried out during the construction and degradation of a connection and during the connection. Thus, it is necessary that incoming information is identified and evaluated as part of certain connection control criteria and that programs are initiated as a result. In addition, information must be provided which is sent at specific times over certain outgoing connections. By way of example, it is pointed out that information occurring over a connection that is in the idle state must be ascertained and assessed as a connection request criterion, and that subsequent incoming information must be ascertained and evaluated as parts of signage.

In order to achieve a more system-correct processing of information occurring over incoming connections, it has already been proposed that in the spend cells in connection with each operation taking place in the system, program control be entered, which is read out by the transmission resolution controller in the line connection unit below, cycle assigned to the respective cell, and is assessed for processing the information that occurs on the connection associated with that cell. Depending on a first criterion made available in this way, the incoming information on an oncoming connection can be entered into specific storage areas of the storage unit, the so-called notepad storage or the so-called special notepad storage. The release of the information entered can then be done at specified time distances by a program controller; in this way, the extreme real-time claims are significantly mitigated. Depending on another criterion, a substitute block can be accessed in the storage unit, thereby providing the opportunity to build and operate circular or conference connections. Finally, on the basis of a third criterion, the information received over an incoming connection is transmitted immediately to the outgoing connection determined at the address contained in the delivery cell. In addition, according to this proposal, it is possible to enter commands in a designated storage area designated as command block storage in the central storage unit and read out this storage area during a scan operation initiated at specified intervals by means of the transmission run control unit. The commands thus read out can again be entered as so-called quotations together with a time indication of the time of their execution as so-called wake commands in the notepad storage.

All of the above operations are continuously cycled, which means that for data input as well as data delivery from the devices that control the data traffic, cycle requests are addressed to the central storage unit. Especially when, on the basis of criteria read out from the storage unit, further processing of information is required, a number of cycles may be required for this, which in certain circumstances must follow immediately after one another. This means that the next cycle request from the transmission settlement controller can only take place when the data submitted from the storage after the completion of a storage operation has been transferred to the transmission settlement controller and evaluated therein.

This means that relatively large voids arise between the individual cycles by which the data traffic between the transmission settlement controller and the storage is conducted. This is illustrated by the example of FIG. 2. The top line of this figure shows the bearing rate TP, which has a pulse distance Τ '. This rate serves as the basic rate for traffic between the individual system units. With the clock pulse to time 0, a cycle request ZAO occurs, with which data EO to be entered into the storage unit, ie. so-called entry data with an address and word information is offered to the repository. The feed selection and the feed itself comprise two clock pulses. With the clock pulse for time 4, the actual storage cycle ZO is assigned with which the storage operation takes place. Two clock pulses are required for this. At time 6, the delivery selection begins, and at time 8, the delivered date AO is transmitted to the transmission resolution controller. However, a subsequent cycle request can now only take place after the WAO word delivery in the transmission execution controller. Since the wording comprises two clock pulses and in the example of FIG. 2 is not completed until time 14, the next cycle request may not occur until that time. In this connection, it does not matter whether the second cycle request is an independent request (a) or one of the contents of the storage cell (b) which is read out with the first cycle ZO. With the second cycle request ZA1, input data E1 is again offered, and the next cycle Z1 is assigned to time 18. From this example, it appears that between the two storage cycles a void of 5T is created. The reason for the occurrence of these voids lies in the fact that the transmission settlement controller has to wait for the ongoing storage word delivery in order to possibly be able to place cycle requests in the immediate vicinity. Thus, even if the storage itself is capable of receiving cycle requests with a distance of at least 27%, the cycle requests will in fact occur at a distance of 57 ". Thus, the maximum cycle frequency of the storage is utilized only 30%. In connection with the real-time claims made to a This disadvantage is of particular importance when the memory data read out with a preceding cycle is deduced from consecutive cycle requests.

In the present invention, it is intended to avoid these disadvantages in adapting the working method of the connecting unit, in particular the transmission winding system of the connection unit, to the working speed of the central storage unit.

According to the invention, this is achieved by providing the input data provided with a cycle request from the transmission unwinding controller in the connection unit and containing an address indication for a storage area, furthermore as tag data reaching a cycle buffer storage associated with the transmission winding controller. storage data, which with the assigned cycle is read from the addressed storage area, and Hamman with his storage data is provided with an assessment link associated with the transmission settlement control unit, and that further processing of the arriving information is done in accordance with the assessment of the stored storage data in such a way. that the information is either transmitted to an outgoing connection or at least one additional throughput is initiated, whereby the data needed to carry out additional throughput is stored in a side cycle buffer associated with the transmission execution control unit. decelerate until a re-cycled request initiates transfer to a free step in the cycle buffer storage.

For example, the tag data entered in the cycle buffer storage may e.g. represent the address of a spend cell, the address of a cell in the listing block store or in the special listing block store, or the address of a cell in the client block store. In addition, via a fixed address encoder, direct access to certain cells in the command block storage, the so-called direct command cells, can be obtained. In all these cases, the input data offered by the storage device offered by the cycle unit is also available to the cycle buffer storage and is stored in storage here until the word delivery from the storage unit. This, as explained in more detail below, enables a cycle operation without void.

Through the introduction of a central assessment operation for which the data supplied by the storage unit is available, it is possible to determine that a first cycle is followed by additional so-called side cycles, the data of which is transferred, among other things, from the cycle buffer storage to the side cycle buffer storage. Since this in turn places cycle demands, it is possible to give these cycle requests a prescribed priority. In this connection, it is an advantage that cycle requests generated for the settlement of first-order side cycles are given higher priority over cycle demands generated for the settlement of main cycles, which are in turn followed by side cycles.

The method of the invention is not only limited to cycle demands triggered by polarity shifts on arriving connections, but can be used with the same advantages when arriving on channels, e.g. In synchronous operation, information occurs in the form of 10-bit microtelegrams which are transmitted in parallel within the connection establishment.

In the following, a detailed description of the invention will be given with reference to FIG. 3-6, where FIG. Figure 3 is a block diagram illustrating the principle structure of an exemplary embodiment; 4 is a time diagram of cycle operation without void; FIG. 5 individual operations which are carried out in the form of main cycles and derived secondary cycles of the first and second order, and fig. 6 is a time diagram for stock cycle operation without void, illustrating some important main and side cycles.

The block diagram of FIG. 3, the parts of the transmission unwinding controller UEAS necessary for understanding the invention are contained in a connector unit LE. The information coming from the input converter ECW is available over data supply devices DE. This information is offered to an address selection device AdAW, a word selection device WAW and a selection device MTAW for micro telegrams. Over an address dispatch register AdAR and a word dispatch register WAR, this information is available to the storage unit SP. For distribution of cycle demands, there is a cycle selection controller ZAWS, which has access to a cycle controller ZS, from which the cycle requirements reach the storage unit SP. The storage data provided from the storage unit reaches a word entry register WER and is available here for an assessment device BW. and a data delivery device DA. The latter has access to the output converter ACW, over which the outgoing connections can be reached. The transmission resolution controller UEAS also contains a fixed address encoder FA, a timer UZG and counters BBSZ, NBSZ and SNBSZ for addressing the command block store, the notepad block and the special note block store. The cycle buffer storage present for recording data K is denoted by ZP and the side cycle buffer storage determined for the data for cycles is denoted by NP. . This makes it possible to store data from three or four consecutive cycles. In addition to a series-coupled step arrangement, it is also possible within the scope of the invention to have other types of step arrangements. Thus, the cycle and / or side cycle buffer storage can also be connected in parallel, with data being input over a free stage of the parallel steps over an input switch, and data from an output switch being read out from the lowest stage buffer storage stage. The transmission resolution control unit UEAS also contains an operation input controller AbES and an operation output controller AbS, from which cycle requests can also be made to carry out certain operations caused by commands Bfl-Bfn.

In the following description of the operation of the embodiment, reference is made simultaneously to FIG. 4. Assuming that both cycle buffer stored ZP and side cycle buffer stored NP are empty upon occurrence of a first cycle request, ZAO in FIG. 4, to the time 0, the input data EG offered to the storage unit UEAS to the storage unit is entered as tag data K in the cycle buffer storage ZP's lowest free step, ie. the step ZPO. This operation is completed until time 4 so that a cycle request issued at that time can be taken into account immediately, in the example cycle request ZA1. The input data E1 offered with the cycle request ZA1 is now entered as shown in FIG. 4 as the tag data K in the cycle buffer storage ZP's next step ZP1. The input data E2 provided with a third cycle request ZA2, followed at time 8, is entered as tag data K in the cycle buffer storage ZP's third step ZP2.

Since the storage operation performed with the first cycle ZO, meanwhile, is completed with the word delivery WAO, so that the corresponding label data in the first stage ZPO intermediate stored tag data is no longer needed, the tag data standing in the following steps ZP1 and ZP2 can each be shifted one step. In FIG.

4, this shift occurs until time 13. However, since the cycle buffer storage can simultaneously perform only one function, the recording of the offered label data takes place only after displacement of the intermediate stored tube data. 1 FIG. 4, this is indicated by clearing cycle buffer storage ZP's last step ZP2 to time 13 (0 ZP2), while the input data E3 offered with a fourth cycle request ZA3 is first recorded as tag data K in cycle storage ZP's released step ZP2 until time 15. continuity when the tag data contained in the first step ZPO after a word delivery is no longer needed. This may cause a temporal shift between the time of entry of data at the buffer buffer storage ZP's input and the inclusion of these data as label data, but since the magnitude of this shift constantly corresponds only to the distance between two consecutive clock phases, there is no void in the cycle operation. In FIG. 4 further shows that the cycles ZO, Z1, Z2, etc. follow immediately after each other, which means that a storage cycle operation without void is ensured.

It has already been noted that the further processing of an information is determined depending on the storage data read out from the storage unit and that for this purpose a further cycle must be carried out for this purpose. In this context, it is appropriate to talk about first and second order master and side bikes. The term "main bicycle" means all bicycles that are initiated from the connection side by information, e.g. polarity shifts and microtelegrams, from information sources in the transmission resolution controller, e.g. timers, are initiated at specific times and from the stock side are initiated by certain operational requirements. First-order side cycles are understood to mean all cycles derived from data read out with a master cycle. The second-order side cycles are understood to mean all cycles derived from the first-order side cycles. A main cycle finds e.g.

8 U2635 when an incoming connection occurs with an information, e.g. in the form of a polarity shift. From the information provided over the data supply device DE to identify the oncoming connection, the storage address is formed in the transmission settlement control unit UEAS. In the case of a connection over which information is received in the form of a polarity change, the storage address contains information for identification of the oncoming connection. In the case of a connection over which information is received in the form of micro-telegrams, the storage address contains information about this data stream. For these indications, the term "internal wiring number" is used below. This is always supplemented with a block start address that indicates the current location of the storage area in the storage unit that is to function. This address is available to the address selection device AdAW and the address release register AdAR for both the storage unit SP and in the form of label data K cycle buffer stored ZP. At the same time, the cycle request is transmitted to the storage unit over the cycle selection controller ZAWS and the cycle controller ZS. After assigning the storage cycle, the addressed spend cell in the storage unit is read out from the transmission settlement control unit. The obtained storage data is available on the word entry register WER for the assessment link BW. On the basis of the criteria for the information processing, which constitute a component of this storage data, it is determined whether the information is to be transmitted to the desired outgoing connection or whether further operations and consequently side cycles are required. For example, a first-order page cycle is required if the arriving information on the basis of the read-out storage data is found to be call or signaling information. In this case, the information is entered together with the time of occurrence, the internal line number and the type of information in a cell in the listing block whose address is entered by the listing block counter NBSZ in the transmission settlement controller UEAS. If it is stated in the assessment link BW that a subsequent side cycle must be run, the labeled data stored in the cycle buffer stored in the lowest free step in the side cycle buffer stored NP, which in turn over the cycle selection controller ZAWS and cycle controller ZS, creates a cycle request. The input data offered by the transmission unit tire unit output registers AdAR and WAR to the storage unit SP offered simultaneously with this cycle request are again available as tag data for the cycle buffer storage ZP, where they are stored in storage for delivery of the storage data read out with the assigned cycle.

Similar to the described first-order page cycle, with which an arriving information is entered into the so-called listing block store, other first-order side cycles are also run. An example may be mentioned a side cycle with which a substitution is carried out. Also in this case, depending on a criterion which, as part of the storage data read out with a main cycle, 9 142635 is available to the assessment link, that in another cycle, which is then run as the first order side cycle, the information that is made available from the spend cell, a substitution block must be reached in the storage unit. Label data K from the cycle buffer stored ZP and the address information provided by the storage for the substitution block are entered into the side cycle buffer stored NP and made available to the storage unit with a subsequent cycle request. The entry of an arriving information into a special listing block store also takes place in this way, ie with the settlement of a first-order side cycle. In this case, the address is made available by a special listing agent SNBSZ via the address dispatch register AdAR.

For example, a second-order page cycle derived from the second-order page cycle occurs when it reads out the cell contents of a cell in the listing block store to which access is obtained with a 1st-order page cycle. cell is not yet processed (cell content t 0). In this case, an unprocessed information in the storage unit would be disturbed by overwriting so that it would be lost. In order to prevent this, an additional cycle derived from the 1st order side cycle is initiated, based on the assessment link BW, in which the read cell contents are available. a second-order side cycle. At the same time, the command switch BW transmits a command to the central operating output controller AbS, Bf2 in fig. 3, with which a cycle request is made to the storage unit. With the cycle assignment, a special operation request is issued to the storage unit which is read from a program controller not shown here and leads to premature completion of the listing block storage.

The same operation also occurs when it is determined that a cell in the listing block store will be overwritten, even in this case when a command, Bf3 in FIG. 3, up to the operation request controller AbS.

The number of possible first and second order bicycles is, of course, not limited to the examples described. For example, first-order side cycles may also be run for deletion of delivery cells, while, for example, second-order side cycles may also be run within the scope of a substitution to read subsequent substitution cells.

1 FIG. 5, the main and side cycles, HZ and NZ, triggered by an information received on an incoming connection are combined. Upon arrival of the information (FL / MT), as shown at the top of fig. 5 always a main cycle. Depending on the content of the load cell read, a first-order side cycle can be run for data entry in the notepad stored N or special notepad stored SN or for a substitution operation SU. If a cell (+ 0) is overwritten at the entry into the notepad or special notepad, a second-order page cycle is performed. In this connection, x denotes the address of the particular listing block counter NBSZ or SNBSZ of the cell in question.

U2635 ίο

With second-order side cycles, operations SS that are necessary for the substitution operation can be further performed.

For the running of the bikes, regardless of whether they are main bikes, first-order side bikes or second-order side bikes, it does not matter whether they request information from a cycle on the connections as polarity shifts or as micro telegrams.

However, in addition to the operations initiated by information on the connections, the method according to the invention also permits the execution of operations triggered by time entries or command words in the system and thereby ensures storage operation without idle. Thus, for example, a main cycle (UZ in Fig. 5) can be run by a time entry in the storage unit. This is done in the event of an immediate time change in the timer UZG by a cycle request to the storage unit over the cycle selection controller ZAWS and the cycle controller ZS. At the same time, the information about the time indication is available to the storage unit over the word selection device WAW and the word output register WAR. In the embodiment of FIG. 3 only one timer UZG is shown. However, it is possible at any time to use multiple timers and through this e.g. achieve a rough and a fine timeframe.

As mentioned, after recording a time in the storage unit, the command biocache is searched. The initiation of such a scan operation can always take place only after a time change; however, the operation is always conducted as an operation independent of the timing. This has the advantage that timing insertion operations can be run as main cycles which are certainly not followed by side cycles and thus cannot lead to overcapacity of the side cycle buffer storage and whose cycle requests can therefore also be treated with higher priority. By contrast, a master cycle within a scan operation may, as will be seen in the following explanation, follow after 1st order side cycles.

For example, if if such a scan operation is initiated, all cells in the command block store are read out one after the other, for which purpose the coramand block store counter BBSZ in the transmission run control unit delivers the storage addresses which, as tag data K, are also entered in the cycle buffer storage ZP. The readout of the command block storage cells takes place with master cycles. When comparing the timers set to the timer with the timings accompanying a command, it is determined whether the command should be executed (positive time comparison) or whether execution should be done later (negative time comparison). In positive time comparison, the command contained in the command block store is executed in accordance with certain criteria representing part of the storage data. In addition, in a positive time comparison triggered readout process, a first-order time cycle is initiated, with which the command block deleted. The corresponding data for the side cycle is transferred from the cycle buffer stored ZP to the id cycle buffer stored NP, which in the manner described provides a cycle request for the side cycle being run. Also, the entry of the read command into the listing block store, e.g. such as the so-called wake-up note for the transmitter or receiver direction, takes place within the framework of a first-order side cycle. This can, if a not yet processed listing in the listing block store would be overwritten, as noted in the assessment cabling BW, is followed by a second cycle side cycle with which a request for premature completion of the listing block store is initiated. In FIG. 5, the cycle sequences appearing in command block readout are combined. With a master cycle Bx, where x represents the address given by the command block storage counter BBSZ on the command block storage cell, this cell is read out and at positive time comparison (ZV +) the command is executed, e.g. transferring a polarity shift to a particular outgoing connection. 1. Order side cycles LOB (command cell deletion) and WEB (alarm entry) are run by positive time comparison, whereby the command block storage cell is deleted through the LOB time cycle and the contents of the command block storage cell through the WEB time cycle are entered in the notepad storage as alarm listing. In addition to the entry in the listing block store, if a cell in it would be overwritten, a 2nd order time cycle UNx will be run, where x represents the address given by the listing block counter NBSZ on the overwritten cell in the block listing. As a further 1st-order time cycle is shown in FIG. 5 also shown the time cycle NAB which is started when a command block is read in the command block memory, which means that the command block memory is completely searched.

It has already been mentioned that, based on the storage SF, in certain cases, operational requests are issued, through which the transmission settlement control unit UEAS is triggered to read out certain fixed address cells in the storage unit, the so-called direct command cells. Also, the associated cycles are run according to the invention as main cycles and derived from 1st or 2nd order side cycles with the help of the cycle buffer storage, the side cycle buffer storage and the assessment coupling and the operation input controller AbES. In the operation input control unit AbES, a request originating from the storage unit for processing a direct command cell in the storage unit is detected and transmitted to the operational request control unit as a command, e.g. as the command -Bf4 in FIG. 3. In the case of direct-command cells, these are fixed-address cells, the fixed-address encoder FA is caused by the operation request controller AbS to simultaneously transmit the address of the direct-command cell to the storage unit, which address is also available for the cycle buffer storage as tag data. With the readout of the direct command cell, whose storage data over the word input register WER reaches the transmission execution controller, the commands in question are executed, e.g. broadcasting a polarity shift on a particular outgoing connection. This operation is performed as shown in FIG. 5 always as a main cycle DZ. This master cycle deletes both the contents of the direct command cell and the request that triggered the read operation. The insertion of the command word read from the direct command cell into the notepad storage takes place within the framework of a 1st order page cycle. In FIG. 5, this operation is denoted by WED. In addition, if a cell in this listing is overwritten when entering the listing block storage, the aforementioned operation UNx as a second-order side cycle is again initiated. For the storage data read out by the direct command cell, additional first-order side cycles can be run in addition to the described first-order side cycle.

As an example, reference is made here to side cycles with which particular information such as the position of an internal register (operation VAD in Fig. 5) or an error word (operation FWD in Fig. 5) is inscribed in a storage cell.

In FIG. 6 is a diagram for cycle operation without void utilizing the first and second order side cycles derived from main cycles. The input data offered with a cycle request ZA is denoted by E, the assigned cycles with Z and the stored storage data with WA. Each of these designations is followed by a number to indicate the temporal order. If tag data K is recorded in the cycle buffer storage, the corresponding step in the cycle buffer storage is indicated at that location. If it is found on the basis of the wording that a side cycle must • occur, this is shown in fig. 6 is indicated by an indication of the corresponding step in the page cycle buffer storage. The vertically dotted and dashed lines indicate that, at the relevant times, a shift occurs in cycle buffer stored ZP and side cycle buffer stored NP, respectively. At the lower end of these lines, the possible offsets are indicated.

The offsets that do not occur at a particular time are given in parentheses.

Assuming that neither the cycle buffer stored ZP nor the side cycle buffer stored NP is coated to time 0, the input data EO provided with the cycle buffer ZAO is recorded in the first stage ZPO of the cycle buffer storage. The input data E1 associated with the second cycle request ZA1 is then entered into the second stage ZP1 of the cycle buffer storage, and the input data E2 provided with the third cycle request ZA2 is entered into the third stage ZP2 of the cycle buffer storage. Immediately after the wording WAO, a shift can occur in the cycle buffer storage. This removes the tag data contained in the second step to the first step (ZP1- »ZP0) and the tag data contained in the third step is shifted to the second step (trin2-» · ΖΡ1). In the thus released third step ZP2, a 0 (0 - ZP2) is introduced. Thus, with the fourth cycle request ZA3, the input data E3 offered one beat phase later can be entered in the last buffer of the cycle buffer storage 13 U2635 step ZP2. If it is determined on the basis of the wording WAO that a page cycle must take place, the data entry in the page cycle buffer storage first step NPO takes place. The same operation is performed on the basis of the wording WA1. In this case, the data entry in the next free step of the page cycle buffer NPI occurs, After the word WA1 a shift of tag data again occurs in the cycle buffer storage, so that the input data E4 provided by the page cycle buffer ZA4 can be transferred as the last data of the tag buffer Z2 to the cycle data. The data stored in the first cycle NPO's first stage NPO is no longer needed, so a shift here also occurs.

In this case, only the information stored in the second step NPI is actually stored to the first step NPO (NPI - NPO). With the word delivery WA2, on the basis of which a page cycle execution is also detected, the data entry takes place in the lowest free steps of the page cycle buffer storage, ie. the second step NPI.

With the release of the first stage ZPO of the cycle buffer storage, the described shear operation is repeated so that the cycle requests ZA5, ZA6 and ZA7 which are to be run as 1st order side cycles can be processed sequentially from the id cycle cycle storage. The offered input data E5, E6 and E7 are entered into the cycle buffer storage ZP's last step ZP2 upon release thereof. Until the input data E7 offered through the cycle request ZA7 is recorded, the corresponding information is retained in the side cycle buffer storage and more specifically in the first step NPO. Only until this time does the next displacement occur in the side cycle buffer storage (NPI -> NPO; NP2 - »NP1). Then, in the page cycle buffer storage at the word delivery WA2, the acquired data is available in the first step NPO. The cycle request ZA8 needed to execute this side cycle results in the described manner in that the corresponding input data E8 with the release of the step ZP2, in which a 0 is introduced at the last displacement in the cycle buffer storage. After this input data E8 is offered, an offset (NP1 -> NPO) again occurs in the side cycle buffer storage. The data recorded in the page cycle buffer storage based on the word feed WA3 is now available in the first cycle NPO of the page cycle buffer storage and leads to the issuing of a cycle request ZA9. The input data thus offered is recorded as tag data in the cycle buffer storage and further advanced one step for each shear operation. Assuming that out of the word deliveries WA4-WA9, only the storage data provided with the word WA7 triggers an additional page cycle, one, e.g. simultaneously with the cycling request ZA5, cycling request ZA10 occurring. The side cycle derived from the word delivery WA7, which is to be regarded as a second order side cycle, causes the input data Eli offered by the cycle request ZA11 to reach the final stage of the cycle buffer storage ZP2 as described.

Since, in the event that a main cycle has to derive several side cycles 14 of the 1st order, data relating to all these cycles must be included in the page cycle buffer storage, it is required that these side cycles are requested and assigned in sequence. In the example of FIG. 6 this is evident from the successive, idle-free allocation on the basis of cycle demands ZA5, ZA6 and ZA7. For this reason, a specific priority is attached to the individual cycle requests, which are ascertained and evaluated in the cycle selection controller. For example, at the same time as the cycling request ZA5, the onset cycling request ZA10 must at least wait until the side cycles ZA5, ZA6 and ZA7 are wound up. Also, as indicated in FIG.

6, there is another short delay until the completion of these cycle requests. In principle, cycle requirements for side cycles have a very high priority and displace in the cycle selection controller such main cycles, which in turn can cause additional side cycles. Only main bikes that cannot be followed by side bikes, e.g. the aforementioned cycles for introducing timing may have a higher priority than the side cycles. In spite of this intervention of main bikes with higher priority to avoid overcrowding of the side cycle buffer storage, it is advantageous to build this stock with more, e.g. four steps.

Referring to FIG. 6 it is described that from one main cycle three side cycles of the first order can be derived and that the data belonging to these side cycles can be jointly stored in one step of the side cycle buffer storage. In this case, the central register for each page cycle buffer storage stage must contain for each page cycle a page cycle code, the internal line number, a word information, e.g. information about the polarity and a storage address. As a general rule, of these data alone the page cycle code is always different. The other data is always the same. Therefore, a variable six-digit page cycle code is advantageously selected which is controlled by a counting operation in a two-digit counter and sequentially sets the combinations for the individual page cycles. The double digit counter position is determined by the transmission unwinding controller at the side cycle recording and after each side cycle is reduced by 1 until the counter position 00 is indicated at the end of the side cycle series.

Claims (9)

15 142635 A method of cyclically transmitting data in program-controlled data processing systems, in particular program-controlled connection establishment systems, between a connecting unit to which arriving and departing wires are connected, and at least one central storage unit over a transmission unit's control unit located in the connection unit, where the central storage unit contains a storage area with connecting cells permanently attached to the arriving wires and containing criteria for processing arriving information, a second storage area for recording data to be inscribed on the basis of the assessment of the contents of a connecting cell, a third storage area for recording the connection unit specific commands formed by program-controlled processing of this inscribed data in a program controller, and a fourth storage area with substitution cells, each of which storage areas are individually addressable by area-starting addresses, characterized in that they input data (E) which is provided with a cycle request issued by the transmission resolution controller (UEAS) in the connection unit (LE) and contains the storage address (SP) and an address indication for a storage area, furthermore as the tag data (K) reaches a cycle associated with the transmission resolution controller (UEAS) (ZP), in which they are held in-between until the storage data (WA) is released, so that the assigned cycle is read from the addressed storage area, and together with this storage data is provided an assessment link (BW) associated with the Transmission Settlement Control Unit (UW). ), and that further processing of the arriving information is done depending on the assessment of the stored data data in such a way that the information is either transmitted to an outgoing connection or at least one additional throughput is initiated, where they are needed to carry out additional throughput. data is stored in a single transmission transmission control unit (UEAS) associated side cycle buffer storage (NP) until a re-cycled request initiates transfer to a free step in the cycle buffer storage (ZP). A method according to claim 1, characterized in that a multi-stage buffer layer, such as cyclic buffer storage (ZP) and side cycle buffer storage, is used. one or three series or parallel coupled steps consisting of cycle or side cycle buffer storage, in which the lowest free stage the data determined for insertion into cycles or side cycle buffer storage is entered, which data as the processing is shifted towards the lowest stage of the cycle or side cycle buffer storage (ZPO, NPO) , and that the data contained in the cycle or side cycle buffer storage (ZPO, NPO) data is available for subsequent processing. Method according to claim 1, characterized in that the information received asynchronously or synchronously received over the arriving connections and for generating cycle requests is constituted by polarity changes or micro-telegrams, that in the case of cyclation requests triggered by arriving micro-telegrams, the address portion of the input cells determined for the spend cells is formed by an information for identification of the data channel, and in the case of cycle requests triggered by arriving polarity shifts, the address portion of the input data is formed by an internal line number to identify the arriving connection, in both cases together with a block start address. Method according to Claim 1, characterized in that the address part of the input data (E) defined for the command, listing or special note block storage is formed from the position of an address counter (BBSZ, NBSZ, SNBSZ) and in each case a block start address. Process according to claims 1-4, characterized in that the cycle requests from the arriving connections, from information sources present in the transmission settlement control unit (UEAS) and from the storage unit (SP) lead to the settlement of main cycles, the cycle requests derived from these. of first-order side cycles and the derived cycle demands for running 2nd-order side cycles, and that the first-order side cycles created for higher-order cycle cycles have a higher priority over those for main cycles leading to additional side cycles, formed cycle challenges. The method according to claims 1-5, characterized in that, by ascertaining at least one side cycle following the main cycle, in addition to the tag data (K), the number of side cycles and their nature also reaches a free step in the side cycle buffer storage (NP). The method according to claim 6, characterized in that the information about successive page cycles in the page cycle buffer storage is formed in the form of a, preferably six digit, page cycle code and stored in a register present for each step, the counter cycle code counter position of the page cycle transfer depending on the execution of the page cycle. side cycle is reduced by 1. Method according to claims 1-7, characterized in that with the main cycle (FL, MT in Fig. 5) which is assigned by a cycle request originating from an arriving connection, the feeder cell contents are dispensed and that an information entry operation is entered in the notepad storage or the special listing block store while simultaneously recording the timing of the information occurring on the basis of the assessment of the spend cell content to be executed as a substitution sequence (SU in Fig. 5) is performed as a first-order side cycle. Method according to claim 8, characterized in that in the assessment coupling (BW), when performing an order of the first order, in which an insertion into the notepad or special notepad (N, SN) takes place, an assessment of the old content is made. in that storage cell, and if that storage cell is not empty (# 0), a page cycle is run