JPH0776949B2 - Optical channel subsystem - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to an optical channel subsystem, and in particular, it divides the function of a channel device into two, a central side and an input / output device side,
In the optical channel subsystem that increases the distance between the central processing unit and the input / output device by connecting them with the serial transmission line of the optical cable, the response to the connection request from the input / output device is performed without delay. The present invention relates to a technique for efficiently processing instructions.

[Prior art]

The optical channel subsystem separates the function of the channel device into two parts, the central side and the input / output device side, and connects them with a serial transmission line of an optical cable, so that the distance between the central processing unit and the input / output device is increased. It will be transformed. In such an optical channel subsystem, two devices, a center channel device installed nearer to the channel control device on the center side and a remote channel device installed closer to the input / output device, are connected to the serial transmission line of the optical cable. Connect with 1
One system is configured to realize the function of the channel device. Therefore, in this optical channel subsystem, the state of the channel is stored in the center channel device installed closer to the channel control device, and the state inquiry and the input / output device from the central processing unit at the time of the input / output command are performed. It responds to the connection request from. In this system, the center channel device closer to the channel controller stores the channel status, so there is no delay in the response to the status inquiry from the central processing unit side at the time of an I / O command. In response to a connection request from a device, the connection request is reported to the center channel device on the channel controller side via an optical cable, and the connection is executed after receiving a permission response. The response is delayed.

As one solution to this, there is a proposal of Japanese Patent Application No. 61-154018 “Channel control system” by the present applicant. This is to transmit the channel state in the center channel device to a remote channel device by a data transmission frame so that the remote channel device side holds the channel state.

[Problems to be solved by the invention]

In an optical channel subsystem that realizes a channel device function for transferring data to and from an input / output device by two devices, a center channel device and a remote channel device, which are connected to each other by optical cables and installed at two separate points, the input / output device side If the remote channel device installed in the device detects a connection request (specifically, a REQUEST IN signal) from the I / O device, it reports the connection request to the center channel device installed on the channel controller side, and The connection with the input / output device is executed after receiving the connection permission from the device (specifically, the SELECT OUT signal is returned). This is because the center channel device side holds the busy state of the optical channel subsystem so that the response to the state inquiry at the time of the input / output command from the central processing unit side is not delayed. If the busy condition of the channel is maintained on the remote channel device side, the response to the status inquiry from the channel control device is delayed due to the signal delay time of several km of the optical cable, resulting in a delay in the processing time of I / O commands. Will end up.

Thus, in the optical channel subsystem, in response to a connection request from the input / output device, this connection request is reported to the center channel device, the state of the center channel device is set to the busy state, and the channel control device sends it. The configuration is such that the startup command is not accepted before the connection with the input / output device is executed.

Therefore, in such an optical channel subsystem, the response to the connection request from the input / output device requires at least one round trip communication between the center channel device and the remote channel device via the optical cable, The response to the connection request of the I / O device is delayed by the time corresponding to the signal delay time of the optical cable (the optical cable of the optical channel subsystem normally extends over several km and this signal delay time is several tens of μs), and There was a problem that the data transfer performance deteriorates.

An object of the present invention is to provide an optical channel subsystem that does not delay the processing time of an input / output command and does not delay the response to a connection request from an input / output device.

The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

[Means for solving problems]

To achieve the above object, in the present invention, the channel device between the channel control device and the input / output device is divided into two devices, a center channel device close to the channel control device and a remote channel device close to the input / output device. Separate them, connect them with a serial transmission line of an optical cable, and transfer the interface operation with the input / output device between the center channel device and the remote channel device as a frame coded into one functional unit. In the optical channel subsystem to perform, while the remote channel device is connected to the I / O device, the center channel device is provided with a means for responding to the status inquiry from the channel control device with a busy state and a remote channel device. Connection permission for I / O device connection requests reported through the remote channel device A means for instructing is provided, and the remote channel device is connected to the input / output device upon receiving the connection request of the input / output device and reporting the connection request to the center channel device and receiving the connection permission from the center channel device. When there is a new connection request from the input / output device at the time when the connection between the means for executing and the input / output device is disconnected, when reporting the disconnection to the center channel device, A means for reporting to the center channel device that there is a new connection request from the input / output device, and means for executing a new connection with the input / output device without receiving connection permission from the center channel device is provided. The main feature is that.

[Action]

According to the above means, in the optical channel subsystem,
When there is a connection request from the input / output device, the remote channel device reports the connection request to the center channel device, the center channel device receives the report of the connection request, becomes busy, and issues a connection permission to the remote channel device. Upon receiving the connection permission, the remote channel device executes the connection with the input / output device. When the remote channel device loses its connection with the I / O device, it first checks whether or not the connection request from the new I / O device has risen, and if so, the connection with the previous I / O device has been lost. However, the I / O device then reports to the center channel device that there is a new connection request, and without waiting for the connection request from the center channel device,
Make a new connection with the I / O device. Therefore, it is possible to respond to the connection request from the input / output device without delay. On the other hand, when the center channel device receives a report from the remote channel device that the connection with the input / output device has been disconnected, the center channel device also reports information indicating whether or not a new connection request is received from the input / output device. Check if
If the information is also reported, the remote channel device keeps busy and determines that the remote I / O device has started to execute connection processing for a new I / O device, and does not issue a connection permission instruction to the remote channel device. Therefore, in response to the status inquiry from the channel controller, the busy status from the center channel device can be reported, and the processing of the input / output command is not delayed.

Example of Invention

An embodiment of the present invention will be specifically described below with reference to FIG.

FIG. 1 is a block diagram showing a schematic configuration of an optical channel subsystem according to an embodiment of the present invention.

This optical channel subsystem, as shown in FIG.
A center channel device (hereinafter abbreviated as CCH) 200, a remote channel device (hereinafter abbreviated as RCH) 300, an optical cable 2000, and an optical cable 2001 are configured as main components. The CCH 200 and the RCH 300 are coupled by an optical signal, the CCH 200 is electrically connected to a channel controller (hereinafter, abbreviated as CHC) 100, and the RCH 300 is an input / output device (hereinafter, abbreviated as I / O) 400. It is electrically connected by a standard input / output interface.

Now when RCH300 is connected with I / O400, OPLIN line 300
1 is on. At this time, the state display bit 202 in the CCH 200 is in the on state, indicating the busy state. When the OPLIN line 3001 is turned off, this
It means that the connection with / O400 has been lost.
Input to the control unit 301 via the PLIN reception circuit 305. The control unit 301 checks the REQIN acceptance circuit 304 to see if the REQIN line 3000 of the new connection request on the I / O interface is on. If there is no connection request,
Bit 7 of byte 1 of the ACP frame shown in FIG. 2 (A)
Is set to "0", and if there is a connection request, the bit is set to "1", an ACP frame is sent out through the optical cable 2000 via the optical frame sending circuit 302 and is reported to the CCH 200.

The CCH 200 receives the ACP frame by the optical frame receiving circuit 203 and inputs it to the control unit 201. When the control unit 201 receives the ACP frame, it examines the code of the frame byte 0, recognizes that it is an ACP frame, and examines bit 7 of byte 1. If the bit is "0" in the ACP frame, the status display bit 202 is turned off and the busy status is released. If bit 7 of byte 1 of the ACP frame is "1", the status indication bit 202 remains on and remains busy.

In response to the status inquiry from the central processing unit side, CHC100
Asks for the status of CCH200 via line 1000, the control unit
201 examines status indication bit 202 and responds to CHC 100 via line 1001 as to whether the channel is busy.

Now, the RCH300 uses the ACP frame of FIG. 2 (A) as the CCH200.
When the bit 7 of byte 1 is reported as “0” when reporting to, the REQIN acceptance circuit 304 waits for a new connection request. When a connection request is received, the control unit 301 causes the second
The REQ frame shown in the figure (B) is sent to the CCH 200. When the control unit 201 of the CCH 200 receives the REQ frame, if there is an activation command from the CHC 100 on the line 1000, it does not respond to the REQ frame, and transmits an activation instruction frame corresponding to each command to the optical frame. It is sent to the control unit 301 of the RCH 300 via the circuit 204, the optical cable 2001, and the optical frame receiving circuit 303. If there is no activation command for CHC100 twisted line 1000, RE
In response to the Q frame, the SEL frame shown in FIG. 2 (C) is sent to the control unit 301. In any case, the status display bit 202 is turned on and is in a busy state.

In the RCH300, when the SEL frame is accepted, the control unit 301
SELOUT signal 3002 to I / O400 via SELOUT sending circuit 306
To execute the connection processing of I / O400.

By the way, the RCH 300 CCHs the ACP frame shown in FIG.
When bit 7 of byte 1 is reported as “1” when reporting to the 200, the SELOUT sending circuit 306 immediately responds to the SELOUT signal 3002 without waiting for the reception of the SEL frame from the CHC 200, and the following I Execute / O400 connection processing.

Figure 3 shows the RCH300 corresponding to the I / O interface operation.
5 is a timing chart showing a transfer sequence of each frame performed between the CCH 200 and the CCH 200. The operation will be described with reference to FIG.

In the RCH, when the connection with the I / O is broken and OPLIN = 0, the RCH sends an ACP frame to the CCH and reports it. The ACP
When the CCH receives the frame, it changes the state from the busy state to the idle state. When the next connection request is generated from I / O and REQIN = 1, RCH sends a REQ frame to CCH. Upon receiving the REQ frame, the CCH changes its state to the busy state and sends the SEL frame to the RCH. When the RCH receives the SEL frame, SELOUT =
1 is sent to I / O and connection is permitted. SELOUT = 1 for I / O
After receiving, the I / O with REQIN = 1 increased can be connected to RCH, and OPLIN = 1.

By the way, now that the data transfer of one I / O has finished, the OPL
When IN = 0 and the connection with this I / O is broken, the next connection request already exists in another I / O, and if REQIN = 1, the RCH changes the ACP frame to CCH. When transmitting and reporting, the REQIN byte of the CTL byte of the ACP frame is reported as “1”, and SELOUT = 1 and REQIN = 1 increased without waiting for the response of the SEL frame from CCH. Make a connection with. When the CCH receives an ACP frame, bit 7 of byte 1 of the ACP frame (CTL byte
If the REQIN bit) is “1”, the status is kept busy and no SEL frame is sent to the RCH.

In this way, the data transfer of one I / O is completed and OPLIN =
It becomes 0, and when the connection with this I / O is cut off, if the next connection request already exists in another I / O and REQIN = 1, do not wait for the response of the SEL frame. , REQIN
Execute the connection with the I / O for which 1 is raised. Therefore, the exchange of frames is reduced, the influence of the delay of the signal on the optical cable is reduced, and the connection request (REQI
The connection response (SELOUT) to N) will be performed without delay. That is, in the conventional optical channel subsystem, the connection response (SELOUT) may be delayed until the response is returned to the connection request (REQIN) from the I / O due to the exchange of frames on the optical cable. However, according to the present invention, since there is no such frame exchange and there is no influence of the signal delay on the optical cable, there is no delay in the connection response to the connection request. The delay due to the optical cable becomes larger as the length of the optical cable becomes longer, and becomes several tens of μs in the optical cable of several km, and the effect of using the present invention is great when the remote channel device is installed at a long distance from the center channel device. The state of the optical channel subsystem can be obtained by referring to the CCH side, and the response to the state inquiry from the channel control device is naturally not affected by the delay due to the optical cable.

The present invention has been specifically described above based on the embodiments,
It is needless to say that the present invention is not limited to the above-mentioned embodiments and can be variously modified without departing from the scope of the invention.

〔The invention's effect〕

As described above, according to the present invention, in the data transfer between the center channel device and the remote channel device, the number of response times of the interface is reduced, so that there is no frame exchange and there is no delay in the signal on the optical cable. Since there is no effect, there is no delay in the connection response to the connection request.

[Brief description of drawings]

FIG. 1 is a block diagram showing a schematic configuration of an optical channel subsystem according to an embodiment of the present invention, and FIG. 2 is a diagram showing a space between a center channel device and a remote channel device of an optical channel subsystem according to an embodiment of the present invention. FIG. 3 is a timing chart showing a frame transfer sequence between the center channel device and the remote channel device. In the figure, 100 ... Channel control device, 200 ... Center channel device, 300 ... Remote channel device, 400 ... Input / output device, 2000, 2001 ... Optical cable, 202 ... Status display bit, 204, 302 ... Optical frame Sending circuit, 203, 303 ... Optical frame receiving circuit, 304 ... REQIN acceptance circuit, 305 ... O
PLIN acceptance circuit, 306 ... SELOUT transmission circuit.

Claims (1)

[Claims] 1. A channel device between a channel control device and an input / output device, a center channel device close to the channel control device, and a remote channel device close to the input / output device.
It is separated into two devices, and they are connected by a serial transmission line of optical cable, and the interface operation with the input / output device is mutually encoded between the center channel device and the remote channel device as a frame coded into one functional unit. In the optical channel subsystem for transfer, while the remote channel device is connected to the input / output device, the center channel device has a means for responding to the status inquiry from the channel control device with a busy state and a remote device. A means is provided for instructing the remote channel device to permit connection in response to the input / output device connection request reported via the channel device, and the remote channel device is connected to the center channel device upon receiving the input / output device connection request Connect the I / O device with the means for reporting the request and the connection permission from the center channel device. When there is a new connection request from the input / output device at the time when the connection between the means for executing and the input / output device is disconnected, when reporting the disconnection to the center channel device, A means for reporting to the center channel device that there is a new connection request from the input / output device, and means for executing a new connection with the input / output device without receiving connection permission from the center channel device is provided. An optical channel subsystem characterized in that