DE2850416A1 - DATA PROCESSING SYSTEM FOR SELECTIVE RESETTING OF AN INPUT/OUTPUT SYSTEM - Google Patents

Description

Applicant: International Business Machines

Corporation, Arinonk, N.Y. 10504 '

heb-om

Data processing system for selective resetting of an input / output system

The invention relates to a data processing system with a novel selective resetting of an input / output system. Such resets are generally used to turn off and reset input / output channels and peripheral devices connected to it. Such a reset of peripheral equipment also ended a reservation of such devices or other assignments between peripheral devices and the associated channels.

Normally, an I / O system reset of this type is initiated manually when error correction procedures that work automatically or automatically (for example, re-performing an operation) are not sufficient. This type of reset generally affects all available channels and the peripheral devices connected to them. This manual operation and the lack of any selection can seriously affect processing efficiency.

Another difficulty encountered with such I / O system resets is that assignments between channels and connectable peripheral devices, such as reserve settings or reservations, are also terminated by this reset. Such reservations of peripheral devices have become known, for example, in the IBM System / 360. The termination of such an assignment makes such a reserved device possible for the access of another, loosely coupled and independently monitored system before this

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'Allocation with reservation can be restored in the system that initiated the reset. The consequence of this ! is that doing so can compromise the integrity of shared data.

Another difficulty with an I / O system reset is that the reset can fail when The I / O channel cannot forward the reset signal to the interface for the peripheral devices. One Another difficulty is that in a group with a number of channels that are time-division multiplexed cooperate with a single control unit, the failure of either the control unit or any channel the group, can fail the entire group, and also perform the I / O system reset blocked.

Summary of the invention

The present invention provides a possible mode of operation for program control to perform a related I / O system reset selective for one channel and one I / O interface. Program restrictions close the Use of this operating mode with those peripheral devices and / or control units that have unprotected reserve positions (or other assignments) of devices. This operating mode is only used by monitoring programs and only through programs that ensure the separation of other, loosely coupled systems before the reset is initiated, thereby protecting reservation settings and other device assignments. This will ensure the integrity, i. H. maintain the inventory of shared data in reserved peripheral devices, to which other systems also have access. After the reset has been carried out and the The program causes reserve positions and other assignments to also switch off the others in the meantime

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Systems get going again. This restoring possibility ί is partly in an auxiliary processor which performs a central processing unit, the program instructions, bottom '- supports. This auxiliary processor can be structured in such a way that
that the reset is carried out asynchronously, ie
after executing a program command that causes the reset
indicates. As a result, the load on the efficiency of the central processing unit is reduced. The auxiliary processor effects independent control of the channel! I / O interface lines that send the reset signal to the _; to transmit peripheral devices assigned to each channel, ie i the signals "Op. Out." and "Supp. Ausg." Therefore i cannot perform a reset either through a stuck channel or through a stuck _; Group of jointly controlled channels are blocked. ^:

, Description of the Prior Art j

pie program-controlled generation of a system reset ■

is not a whole new process. In the US patent!

For example, 3 787 891 is a signal processor command

[wrote through which an I / O system reset ι

is effected. The execution of the command causes the ' ) i

, exchange of command and status information between ■ interconnected processors. Such commands i can be used to initiate a program reset in a system that accepts this command and click on | this way I / O system resets in channels ι that are connected to the system that this command
records. However, such provisions are not selective
(they do not designate individual channels) and thus have an effect
this command resets everyone on this system
connected channels. In addition, the command can be related to
may not be feasible on peripheral devices connected to a blocked channel.

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The present invention works more effectively because the ! Resetting is only issued to a selectively marked channel I and an I / O interface and only through one 'small auxiliary processor that is carried out immediately {controls the precisely designated I / O interface, regardless of the operating conditions of the connected channel.

jA very important feature of the invention is that That the in reserved or assigned peripheral devices, to which other loosely coupled systems also have access,! lying data are protected in their inventory. This The feature of the invention will now become apparent from the following description of an exemplary embodiment in connection with the {attached drawings more clearly visible. I.

jln the drawings show
Figs. 1-5 different difficulties caused by the

Invention to be supplied to a solution

can,

6 shows a block diagram of a system constructed according to the invention,

Fig. 7 the format of the program command "delete channel"

for initiating selective I / O system resets according to the invention,

8 shows the mode of operation of a central unit

the interpretation of the command "delete channel" according to FIG. 7,

9 shows the logical organization of the auxiliary processor

in Fig. 6 for performing the selective I / O system reset and

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Figs. 10-12 show how the instruction shown in FIG. 7 is used and how the reserved peripheral devices (i.e. how the data is ensured) in relation to other, loosely coupled (independently monitored) Processor systems.

Single description

Introduction to Difficulties :

First of all, the network of a data processing system shown in FIG. 1 will be considered. Central units (CPÜ): 1 and 2 are multiple with the different I / O channels 3 - 6 '-. tied together. Channels 3-6 are connected to the various control units (CU) 7-11. The control units i, in turn, are connected to many peripheral devices, some of which are shown at 12-18.

In particular, the control units 9 and 10 are connected to both channels 4 and 5, so that the ^{peripheral devices connected to these control units 1 can be} connected to either the CPU 1 or the CPU 2. Such a connection is normally made possible by a two-channel switch such as that provided in the IBM System / 360. The systems assigned to CPU 1 and 2 are loosely coupled to one another, ie the monitoring programs for these central units are relatively independent of one another.

It is now assumed that a non-selective program reset with respect to the CPU 2 is initiated (usually this is done manually by operating a switch or a push button on the control panel). This will apply a CPU reset to CPU 2, whereupon an I / O system reset will be applied to channels 5 and 6 will. Channels 5 and 6 in turn generate system

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; reset signals at their respective I / O interfaces and thus reset the control units 9-11 and the associated peripheral devices 14-18. This applies to both for the IBM System / 360 as well as for the System / 370.

This has the consequence that the entire network, which is indicated by hatching in FIG. 1, is again in operation must be set and that all processing operations in this network must be initiated again. Be it ; at the moment believed that the difficulty because of the 'program reset is limited to the control unit indicated by the label "Actual Blocking "is marked in Fig. 1, and that the monitoring program of the CPU 2 can be made aware of this, for example by an I / O interruption and a [limited writing out of the error from channel 6. If the program had the opportunity to respond directly to the To perform channel 6 directed I / O system reset, then only channel 6, control unit 11, and the peripheral ! Devices 16-18 reset, while channel 5 and! Control units 9 and 10 and peripheral devices 14 and ! would not be affected. It is obvious that 'The reprocessing of data required by the deferral could be significantly reduced if One takes into account that one control unit can often have hundreds of peripheral devices assigned to it. It one can readily see that there is a program-controlled selective I / O system reset among these ! circumstances would be extremely useful.

Another aspect of the difficulty is shown in FIG. For the sake of simplicity, this figure shows a memory with direct access 40, which can be switched via the control unit 41 and the channels 42 and 43 to one another _;

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coupled (independently monitored) data processing systems
can be connected to the central units 44 and
45 are assigned, the two systems also with
System A and System B are to be designated.

Assume that the memory 40 is direct access
in FIG. 2 by a device reservation for system A.
should be reserved. This device reservation is a special one, via a channel and a control unit in one
System issued command that causes the so-called
and marked device appears to be occupied in relation to other, loosely coupled systems until the
reserving system issued a special trip command
has been.

As can be seen from FIG. 3, a non-selective effect
Program reset in system A a CPU reset in
the CPU 44 and an I / O system reset on channel 42. The
I / O system reset causes channel 42 to send a system reset signal to all connected control units,
including the control unit 41, so that the corresponding control units are all connected to the channel 42
. 'Reset peripheral devices. The provisions of these devices naturally terminated the corresponding device reservations, so that peripheral devices, such as, for. B. the memory 40 'j for both systems that work with the CPU 44 and the CPU 45! work, appear attainable. But this can _:

'System cooperating with CPU 45 (CPU B) and channel 43 j i j

^! in peripheral devices such as B. the memory 40 lying j

j!

■ Use and / or change data. Thus, as through | the last process step in Fig. 3 indicated by i

I '

jthis provision of the stock of this data in relation to '.

jboth systems may be affected. Therefore, if the ι

! system A then its reservation of peripheral devices, ■

| Like 40, for example, could make sure again, so could >

but the integrity of the data used by this system i

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ι cannot be guaranteed for the time prior to the reset.

^! Another problem with reserved devices and control units is the fixed assignment of lines. Reserved! Control units and certain other control units, e.g. B. | the IBM 3830 Storage Controller when in search mode

is designed to have an exclusive assignment to a channel leading to a particular assigned channel ! Maintain leadership. If such a control unit {controlled by another channel during this fixed assignment it emits a "busy" signal and therefore appears unreachable. Reserved devices and other devices set up in this way, such as the IBM 333G disk storage device with the associated control unit 3830 have similar exclusive fixed assignments to a particular channel and control unit and leave no connection about another way too.

Peripheral devices that have such a fixed line assignment have, respond to normal system reset signals only if these signals are on the permanently assigned route arrive. Therefore, when a channel fails due to a difficulty associated with the operability of the associated one peripheral devices are not influenced (e.g. by a internal channel failure or an external stuck on an I / O interface), and therefore a system reset signal cannot pass on to the associated I / O interface, then the permanently assigned peripheral devices can actually isolated and thus unusable, although they would be accessible by other means when restored.

This description of the difficulties leads to the suggestion that that a new type of I / O reset is required, firstly selective for a specific channel and an I / O interface can be directed, secondly, which can be called under the control of the monitoring program

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(so that reservations protected and alternative paths _selectively; can be established), and thirdly with respect to the hearing züge- ■ I / O interface and the peripheral device even
can be performed when the designated channel has failed. The present invention fulfills all of these needs. '

Figs. Figures 4 and 5 show another aspect of the I / O system reset. The I / O processing system 60 exists
from a group of six channels 61 that are time-division multiplexed; Operate together with a microprocessor control 62. ' Each channel has a separate I / O interface and a network; work of connected, associated control units and peripheral devices. These are indicated at 64. The whole ^; iGroup of channels is assigned to a central data processing system ₍ ! system with a central unit 66. This has to ji>

Consequence that a blockage (sticking) the failure of the

whole group and thus also the provision

the group prevented. j

ι i

Blocking by a single channel is shown in Fig. 5. 'The central processing unit 70 tries to do an I / O system return Position for a blocked or stuck channel 72
usually this type of reset requires the channel on both output lines of the I / O interface for "Op. Out." and "Supp. Ausg." a
supplies low potential. Will this be done by the channel in
Done properly, this will cause
all control units and thus all assigned to this
Devices connected to the interface.
If, however, as in FIG. 5, a channel is blocked or
got stuck, he may not be able to do this
Operation with respect to the two output lines of the
I / O interface. If also a group
of channels that are under a common microprogram

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ι. . ■

Control is working, then all channels of this group can be blocked against a control of their corresponding jOutput lines of the I / O interfaces for "Op. Out." ^! and "Supp. Ausg." (Fig. 5) be blocked.

[The invention is also intended to eliminate this difficulty that an additional logic is provided, which is independent of the operating status of the channel at the individual I / O interfaces the output signals "Op. Ausg." and "Supp. Ausg." suppressed.

I The system and the method according to the invention are now described in Described in more detail in connection with a block diagram and flow charts of FIGS. 6-12. The actually executed logic circuit can of course vary according to the circuit technology and microprogram control used

fail. It is obvious to the person skilled in the art that ι
! Buffer memory, registers, gate circuits and clocking as well as sequential controls for the circuits described here can be set up in the usual way with various modifications.

Referring to Figs. 6 and 7, the program controlled selective I / O system downgrade is accomplished by the interaction of a CPU carried out with an auxiliary processor 82 (SVP). The reset is carried out by a program command "Delete channel" (CLRCH) which has the format shown in FIG. This command is only carried out by the CPU if the CPU performs its monitoring function, d. H. only as a step in a monitoring program and only if the reservations are protected, as will be described below. Bits 16-32 of the command identify a channel and thus implicitly the assigned I / O interface. The command causes the CPU 80 to send a signal to the auxiliary processor 82 outputs, which identifies the channel to be reset and the interface to be reset. This auxiliary j

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'processor 82 then outputs a condition code signal to the CPU 80, which indicates the status of the processing of the flagged ! Specifying provision.

If the channel marked in this way is actually available, then the auxiliary processor 82 emits the condition code 0 and carries out the required signaling with regard to the marked channel and the associated interface. Is | the channel marked actually not available, \ the auxiliary processor outputs the condition code 3 and leads j no further operation by. After recording the conditional

.codes, the CPU makes the execution of the command "Channel!

! Delete "a. J

■ When performing the reset operation (in conjunction with, The subprocessor transmits the return of the condition code O) first and second reset signals related to the channel 84 identified by the command. The first reset

Control signal arrives via line 83, FIG. 6, to the designated Channel and resets it. The second reset signal is applied to logic gates via line 85 (FIG. 6) transmit the channel 84 with its two! output lines for "Op. Ausg." and "Supp. Ausg.", lines 86 and 87, connects. These gates are indicated at 88 and 89 and are reset by the second reset or blocking signal on line 85 effectively blocked. This has the consequence that the two output signals for a so be held at the same time at low potential for a long time, so that the system reset becomes obvious (at least 6 microseconds) and thus the system reset signal to the peripheral device connected to the corresponding interface.

This sequence carried out by the auxiliary processor when carrying out the delivery of reset signals can either

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! asynchronously or synchronously with regard to the return of the loading!

be conditional codes (i.e. in relation to the termination of the,

! Execution of the corresponding command "Delete channel" by:

The CPU 80) "ι

Referring to Fig. 7, the format of the "Delete Channel" command is similar to the well-known S format. The first
16 bits represent the operation code (OP) in hexadecimal j representation. The last 16 bits determine the address:

j of the channel and the interface that are being deferred!

[should. The shift argument, represented by the bits
20 - 32 of the instruction, to the bits 20 - added, register definition contained represented by the bits - 31 of in the ^main! 16-19 of the command. Who is thereby; The bits 20 - 23 provided represent the address (identifier>!) of the channel to be reset and thus also of the assigned interface.

The first 8 bits of the opcode are identical to the corresponding bits of the channel test command. Bits 8-15
this command is run by the processors in the IBM system
/ 370 is ignored, as this is necessary for the execution of the
"Delete channel" command are not set up. Such
Processors interpret the command "delete channel" as
usual command "Channel Check" and thus execute the
Function "Channel Check" through, ie feel the status of the
by the channels marked to 16-23 and save a corresponding status code. Processors, however
are set up for the execution of the "Delete channel" command, e.g. B. the CPU 80, interpret the operation code as a "channel delete" command and carry out the assigned reset, ie conditionally transmit reset signals
an auxiliary processor logic, such as e.g. B. the auxiliary processor 82,
and record the associated condition code.

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Figs. Figures 8 and 9 show the logic required to interpret the Clear Channel (CLRCH) command in the CPU Circuitry and the interface required in auxiliary processor 82 to perform the reset operation. Block 90 (FIG. 8) is intended to represent a normal instruction decoder such as that used in the IBM System / 370 in FIG Central processing unit is provided, an additional coding output line 92 being present for the command CLRCH. above the output line 92 is driven by signal driver stages 94, via line 96 an associated interrupt signal to the auxiliary processor 82.

The interrupt acceptance control 98 in the auxiliary processor, which can respond to various interrupts taking into account a priority , responds to this interrupt signal and sends the information identifying the channel (determined by bits 16-23 of the command) from the CPU 80 via line 100 to register 102 in auxiliary processor 82. The acceptance of the interruption also switches on the coding logic 104, which converts the jcode identifying the channel in the register 102 into a status signal 106 which controls the logical AND element 108. The AND gate 108 then controls the reset signal generator 110 with respect to the particular channel X (channel 84, FIG. 6) and with respect to the associated I / O interface (IFx) and thus makes the system reset externally (via lines "Op The decoder 104 has an output line for each channel of the system and controls an associated AND element, such as the AND element 108, with respect to a reset signal generator 110 connected to it.

The AND gate 108 is also controlled by an output signal of a latch circuit 112 indicating the X status, wherein for each output of the decoder 104, i. H.

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a bistable locking circuit is provided for each channel. The interlock circuit 112 shows that
! actual existence of the particular / assigned channel
I (X) in the system. The channel marked in this way is available
! Available, then the assigned interlock circuit
112 is set and causes the associated AND element 1O8,
the reset signal generator 110 and the signal lines 116,
j118 that the reset signals are transmitted via line 116 and the interface via line 118 to the designated channel. The interface reset signal blocks
! at the assigned I / O interface for at least 6 micro; Seconds the signals "Op. Out." and "Supp. Out."
As a result, these I / O interface lines! will hold overall for at least 6 microseconds at a low potential 'and the reasonable at this interface, closed peripheral devices, the system reset Toggle show \. I.

AND gate 108 and latch circuit 112 control j

condition code generator 120 which is supplied via line 122;

outputs a condition code to the CPU 80. This code becomes j

and is available for the monitoring program!

Disposal that issued the command "Delete channel". I.

When this condition code occurs, it means that i

the command "delete channel" has been carried out. j

In the preferred embodiment, the condition code is
a 2-bit code, which in itself has four different conditions
or is able to display states, but in the present case
is only used as an indicator for two conditions. Condition 0 is used to indicate that the I / O system reset is being performed for the particular channel
can be. Condition codes 1 and 2 are now used in this
Case not used. Condition code 3 (interlock circuit
112 deferred) represents that the designated channel
is not operating in the system (actually not

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Is available)

The resetting causes all interface lines coming from outside I to the designated intersection; ! place after a j determined by the outer cable length

! delay fall off. j

ι Ε

Use of the command "delete channel" in relation to reser- j

fourth peripheral devices ί

. j

■ Figs. 10 and 11 show how the "Delete Channel" command in the |

I!

■ System A with respect to reserved peripheral devices {is set to which this may be transferred independently j ■ monitored system B could have access (see also FIG. 2). j

As indicated at 198 (FIG. 11), system A can use the , CPU 200, auxiliary processor 202, and multiple channels, including on channel 204 (FIG. 10) detect a fault in the I / O line associated with i-channel 204. Such a [Error can be caused by either an I / O interruption or limited channel expression in the system A supervisory program from channel 204 (if channel 204 is operational) or by a machine test interrupt from auxiliary processor 202 (if the Channel disturbed and the auxiliary processor has the ability to detect such a disturbance). !

Before the command "clear channel" is given with respect to channel 204 (step 206 in FIG. 11), the monitoring program of system A initiates the shutdown of system B (at 208 shown in FIG. 10), possibly to the peripheral connected to channel 204 and reserved for system A. Device has access. Such a shutdown is via the link 210 (Fig. 10) between the two systems ensured. The link 210 can be fully electronic Connection (channel to channel or direct control) between the two systems or can also be for one

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manual intervention be set up, for example, a light on the control panel of the system A signal that the Operation indicates that system B must now be switched off manually. This shutdown is indicated at 212 .

After the command "delete channel" with selective I / O system reset with respect to channel 204 (step 206 in FIG. 11) is performed, the reservations and other associations between system A and the peripheral devices connected to the channel are restored (they had been released by resetting), as indicated at 214 (FIG. 11). Then the switched off Systems such as B. the system B, as at 216 (Fig. 11) via the link 210 turned on again. Both Systems can then resume their normal, independent operation, as indicated at 218 (Fig. 11) is indicated. The shutdown of system B prevented system B from maintaining the intact inventory of the System A has compromised data in use after the reset step 206 and before it was powered back on 214.

Use of the Delete Channel command in general

Fig. 12 shows in detail how the reset with the "Delete channel" command by monitoring control programs is used. The program has two discrete sequences for access to the command "delete channel" (CLRCH) assigned reset operation. The sequence 280 relates to the renewed start-up after difficulties that became apparent through I / O interruptions, while sequence 284 provides the restart after difficulties, which resulted from interruptions in machine tests. I / O interruptions are indicated by specific channels and thus give exactly the I / O channel ah, which is a reset

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requires. Machine check interruptions are made by processors requested, such as the auxiliary processor (SVP 82 in Fig. 9) and do not require any special identification of an I / O line or the indication that a I / O line needs to be reset.

At flow 280, the operation to be performed when a CLRCH reset is required depends on the Status of the reserved peripheral devices. This status is checked at 286 and if there are no reserve positions are present, the program continues at 290 immediately after the CLRCH command is issued. When reservations ; (or other assignments) are in effect at point 286, then! the program branches to 292 and thereby switches off of other (possibly interfering) systems (or processors) before issuing the CLRCH command at 290 for a Provision is submitted.

After the command CLRCH has been issued at 290, the program continues to a branch point 294 and branches (There according to the status of the I / O channel assigned to the reset. The status of the reusability ! this channel can, if it is not

The status information given in the interruption is displayed by (processing of the commands "Channel Check" (TCH) and / or ! "Check I / O" (TIO) of the System / 370 must be determined for this channel. The condition for resetting the channel is at 296 as "channels not available" or at 300 as "channels available" and the program branches at 302 depending on the status of the reserve positions determined at 286

If reserve positions or other fixed assignments were in effect before the reset, the program tries to these reserves either via the same I / O channel or via a different channel (if the same channel is not used

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Is available and another channel is available), whereupon the effectiveness of this attempted operation is checked at 308. If this attempt was successful, then the program restarted the I / O procedures associated with the reset channel, as shown in 'he ± 310, and switched the previously shut down (program step 292) systems back on at 312. If no reservations were in effect prior to the reset, then immediately after the test at 302 the program will attempt a new start of the I / O procedures affected by the reset (via the same channel, and if this attempt is unsuccessful , via another channel, if one is available). After step, the program continues with other operations (other than the resets). If the I / O restart is unsuccessful at 310 !, the program will display a permanent error before continuing. If the test at 308 shows that the reinstatement of the reserves was unsuccessful, then at 314 the program puts the system on hold. From there you have to intervene manually before the system can be put into operation again.

In program sequence 284 supplies for machine test interruption the program executes a number of channel check instructions (TCH) at 320 and determines at 322 whether there are any particular channels have failed in a group (e.g. 61, Fig. 5). (If the determination at 322 indicates that there are no channels failed, the program continues with its normal sequence and determines the cause of the interruption, since it has been effectively recognized that the cause of the interruption is not in the channels or in the I / O lines are in place, so there is no need to reset. On the other hand, if the determination at 322 den Indicates failure of a channel, then at 3 24 by the

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Program a sequence of CLRCH provisions for those affected Group of channels carried out. These resets are made sequentially by the auxiliary processor 82 (FIG. 9) carried out. If an uncorrectable error was found at 326, then the service processor may the I / O controls 62 (FIG. 4) are brought back into operation by an initial microprogram load operation before the Program continues with functions 294 to 314. At 326, becomes an initial load operation for a microprogram then there is a 30 second delay at 328 inserted before the program can continue with functions 294-314.

It can now be seen that with the new program command CLRCH and the associated program restrictions when using According to FIG. 12, a reset option is created which, firstly, allows a system reset to take place immediately and is selectively directed to a particular channel and the associated I / O interface, secondly the ! Is subject to control by a monitoring program and ■ can therefore only be used if reserve positions ! have been protected (by switching off possibly interfering systems) and only if the I / O lines (the original lines or, if necessary and (available, replacement lines) for reconnection and List of the reserves are available, and thirdly, even! Then carried out in relation to the specific I / O interface if the particular channel has failed. i

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Claims (1)

28? 0 £ eat PATENT PROVISIONS Data processing system with several input / output channels each with an I / O interface circuit for connection to control units and peripheral devices and a program-controlled central unit, characterized in that that for one by a special reset command (CLRCH) of the monitoring program of the central unit (1,2) initiable selective resetting of a channel (3, 4, 5, 6) and the associated interface circuit an auxiliary or service processor (SVP; 82) for recording (9S) decoding (104) and forwarding (110) a selective reset signal is provided. * Data processing system according to claim 1, characterized marked, that in the auxiliary processor a test circuit (106, 108) is provided for the availability of the channel to be deferred and that a code generator (120) for the generation of one of the central unit the actual availability (0) or non-availability (3) of the code indicating the channel to be deferred is provided. 3. Data processing system according to claim 1, characterized marked, that the reset signal at each I / O interface is represented by the fact that the between the Channel and the I / O interface extending lines (86, 87) for a predetermined short time low potential and that between the auxiliary processor and each of the I / O channels a control line (83) is provided which on the coming from the reset signal generator (110), PO 977 013 8Q982S / 06SS ORIGINAL INSPECTED reset signal transmitted after channel (X) the temporary blocking of both output lines (86, 87) cancels. 4. Data processing system according to claim 1, characterized marked, that the command triggering the reset signal (CLRCH) Can only be used with the proviso that if peripheral devices (12 - 18) are in reserve, these to ensure the integrity of data against access by other, loosely coupled systems it is possible to protect such other systems from resetting the disturbed channel in this case can be switched off. 5. Data processing system according to claim 1 -4, characterized in that that the auxiliary processor (SVP, 82) in the event of a fault in one Channel from a group (61) of channels the central unit (66) by a machine test interruption able to switch on and that then a series of reset commands (CLRCH) for this group of channels is able to generate, so that thereby a recovery of the system from this disturbed Working method can be initiated. 6. Data processing system according to claims 1-5 with a number of central processing units, which have additional, after other I / O units and interfaces leading lines are loosely coupled with each other and independent of each other by monitoring programs are monitored, and with associated peripheral units accessible to the loosely coupled central units Devices, whereby some of these devices are used for a central PO 977 013 §09825 / 06 Si 2850418 unit can only be reserved, and this reservation by the central unit via a quick release operation or an I / O system reset can be terminated, characterized in that in such a, a reservation of a peripheral Device containing system that does the I / O system reset causing reset signal can only be generated after the systems that use this device before resetting the disturbed channel connected to the reserved device can be switched off, the reset signal only identifying this I / O channel and that following the resetting of the channel after successful restoration of the reservation of the I / O channel can be switched on again and the other systems that have been switched off can be switched on again. PO 977 013 903 3/0 65 5