JPH0410652B2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Technical Field of the Invention The present invention is a system in which data in units of data blocks required by an input/output device is requested from a host device in advance and stored in a data buffer, and then stored sequentially. The present invention relates to a data buffer control method for an input/output device that transfers data in blocks of data to the input/output device.

(b) Background of the technology As the use of information processing devices has become more sophisticated and complex, there has been a demand for the development of magnetic tape devices that can be used for various purposes. There are also streaming magnetic tape devices that use motors with long inertia when stopped.

When writing information with this streaming magnetic tape device, in order to prepare for writing information within the specified data block interval (IBG) range, data for multiple data blocks is stored in a data buffer and the difference in transfer speed is corrected. Efforts such as these are necessary.

It is desired to realize various data processing methods that can process data at normal processing speed by taking advantage of the characteristics of the streaming magnetic tape device and data buffer described above.

(c) Prior Art and Problems A conventional data buffer control method will be explained using a streaming magnetic tape device as an example with reference to the drawings.

Figure 1 is a block diagram of a conventional data buffer.
FIG. 2 shows examples of data recording by a streaming magnetic tape device.

In the figure, 1 is a data buffer section, 2 is a streaming magnetic tape section, 3 is a data buffer input counter, 4 is a data buffer output counter,
Reference numeral 5 in FIG. 2 indicates a magnetic tape.

Note that a to d are data blocks, a' to c' are data block intervals (hereinafter abbreviated as IBG), e is the motion locus of the magnetic tape 5, f is the stop position of the magnetic tape 5, and the rise in the reverse running direction. Similarly, points g and g indicate the stopping position of the magnetic tape 5 and the rising point in the forward running direction, and h indicates the speed of the magnetic tape 5, respectively. Furthermore, the lengths of data blocks (~) a~d are in variable length format.

The data buffer section 1 is a multi-block buffer that can store a plurality of data blocks. Data in block units is transferred in advance from a host device (not shown), stored, and processed by the streaming magnetic tape section 2. At the same time, the start address and block length of the block are recorded in the management table within the data buffer section 1. A data buffer input counter 3 counts data blocks (~) a to d transferred to the data buffer section 1 under data transfer control with a host device (not shown), and a data buffer output counter 4 counts data blocks (~) a to d transferred to the streaming magnetic tape section 2. The data blocks (~) a~d transferred from the data buffer section 1 are counted.

After writing data block (ii)b to the magnetic tape 5, the data block (iii) that should already be stored is
If the transfer from the host device (not shown) of data block c becomes slow for some reason and writing preparations cannot be made between IBGb' of data block (ii)b and data block (iii)c, the magnetic tape 5 The operation trajectory e is turned around at point f and positioned at the start position of point g, and when the transfer of data block (iii) c is completed and stored in the data buffer section 1, the streaming magnetic tape section 2 starts from point g and writes again. and writes data block (iii)c. While data block (iii)c is being written, data block (iv)d and subsequent blocks are preemptively stored in data buffer 1.

Also, when an error occurs in writing any of the data blocks (~) a to d and a retry is performed, the program automatically returns to the position before the target data block (~) a to d and tries again.

In conventional data block prefetching, the relationship between the free capacity of data buffer 1 and the length of the data block to be prefetched is not particularly taken into account. When this happens, the host device and the data buffer are in a connected state, and in this state, data blocks from the data buffer are sent to the input/output device, emptying the data buffer, and the remaining data is transferred from the host device again.
This continues until the transmission of the interrupted data block is completed. That is, during this time, the host device is tied to the data buffer and input/output device, causing other input/output devices to wait for a long time. Moreover, if an error occurs in the current write,
When error retry is executed by repeating the operation trajectories e, f, and g, the data transfer time to the data buffer unit 1 of the host device (not shown) becomes even longer.
There is a problem in that service to other input/output devices (not shown) connected to the same host device (not shown) may be interrupted for a long time.

(d) Purpose of the Invention The purpose of the present invention is to provide a novel data buffer control method for an input/output device that eliminates the above-mentioned drawbacks. In particular, the data block length controlled by individual software is often a fixed length. Focusing on this, we have developed a data buffer control method for input/output devices that quickly transfers data blocks so that other input/output devices connected to the same host device do not have to wait for a long time during data block transfer. The aim is to realize this.

(e) Structure of the Invention According to the present invention, when data is transferred from a host device to an input/output device, an input/output device is required in a data buffer provided to compensate for a difference in data transfer speed. In a configuration in which multiple data block units of data are requested and stored in advance from the host device, and the stored data block units of data are sequentially transferred to the input/output device, the data buffer section has a , an empty data block length counting circuit that calculates an empty data block length corresponding to the difference between the number of data blocks input to the data buffer from the host device and the number of data blocks output from the data buffer to the input/output device; A latest data block length counting circuit for calculating the data block length of the data block last input to the data buffer is provided, and when the output of the empty data block length counting circuit is equal to or greater than the output of the latest data block length counting circuit. This is achieved by a data buffer control method for an input/output device characterized by sending a transfer request for the next data block to a higher-level device.

(f) Examples of the invention The present invention will be explained below with reference to the drawings.

FIG. 3 shows an embodiment of a streaming magnetic tape device according to the present invention.

In the figure, 6 is a subtraction circuit, 7 is a latest data block length counting circuit, 8 is an empty data block length counting circuit, and 9 is a comparison circuit.

In this embodiment, a data buffer input counter 3 counts data blocks (~) a to d that are transferred to a data buffer section 1 under data transfer control with a host device (not shown), and transferred to a streaming magnetic tape section 2. a data buffer output counter 4 that counts the data blocks (~) a to d to be processed; a subtraction circuit 6 that calculates the difference between the output of the data buffer input counter 3 and the output of the data buffer output counter 4; The latest data block length counting circuit 7 receives the latest data block information from 1, counts the last stored data block length, and outputs it to the comparison circuit 9.The latest data block length counting circuit 7 receives the latest data block information from 1 and outputs it to the comparison circuit 9. Comparing the output information of the empty data block length counting circuit 8, the latest data block length counting circuit 7, and the empty data block length counting circuit 8, which count the block length,
It consists of a comparison circuit 9 which outputs a signal only when the output of the empty data block length counting circuit 8 is equal to or greater than the output of the latest data block length counting circuit 7.

Next, the operation of this embodiment will be explained with reference to FIGS. 1 to 3.

Current data block (ii) b and data block (iii) c
is stored in the data buffer unit 1, and when data block (ii)b finishes being transferred to the streaming magnetic tape unit 2 for writing, the information in the data buffer input counter 3 and data buffer output counter 4 is empty via the subtraction circuit 6. It is output to the data block length counting circuit 8. On the other hand, from the management table in the data buffer section 1, information on the data block (iii)c last stored in the data buffer section 1 is outputted to the latest data block length counting circuit 7.

The latest data block length counting circuit 7 calculates data block (iii)c from the input data block (iii)c information.
The empty data block length counting circuit 8 counts the empty data block length of the data buffer section 1 based on the input information and outputs it to the comparing circuit 9. The comparator circuit 9 compares and counts whether the free data block length of the data buffer section 1 is greater than or equal to the data block length of data block (iii)c, and outputs a signal to the data transfer control section (not shown) to the host device. Then, a transfer request for the next data block is sent, and while data block (ii)b is being written, data block (iv)d is transferred from the host device (not shown).

If data blocks are transferred from a host device (not shown) under the above conditions, generally the lengths of each data block will not be extremely different, so it is possible to Since section 1 is full, other input/output devices (not shown) connected to the same host device (not shown) are not kept waiting.

(g) Effects of the invention As described above, the present invention includes a counter that counts the length of a data block, updates the content of the counter to the latest data block length every time the transfer of the data block input to the data buffer is completed, When the remaining capacity value of the data buffer is greater than the counter value of the last data block stored in the data buffer,
By requesting the higher-level device to transfer a new data block, data block transfer is performed in units of data blocks so that other input/output devices connected to the same higher-level device do not have to wait for a long time during data block transfer. This has the effect of providing a method for quickly controlling the data buffer of an input/output device.

[Brief explanation of drawings]

Figure 1 is a block diagram of a conventional data buffer.
FIG. 2 shows an example of data recording in a streaming magnetic tape device, and FIG. 3 shows an embodiment of the streaming magnetic tape device according to the present invention. In the figure, 1 is a data buffer section, 2 is a streaming magnetic tape section, 3 is a data buffer input counter, 4 is a data buffer output counter,
5 is a magnetic tape, 6 is a subtraction circuit, 7 is a latest data block length counting circuit, 8 is an empty data block length counting circuit, and 9 is a comparison circuit.

Claims (1)

[Claims] 1 When data is transferred from a host device to an input/output device, the data in multiple data block units required by the input/output device is first transferred to a data buffer provided to compensate for differences in data transfer speeds. In a configuration in which data is requested to a host device and stored, and data in stored data block units is sequentially transferred to an input/output device, the data buffer section stores the number of data blocks input from the host device to the data buffer. and the number of data blocks output from the data buffer to the input/output device, an empty data block length counting circuit that calculates the empty data block length corresponding to the difference, and a data block length counting circuit that calculates the empty data block length corresponding to the difference between the data block number and the number of data blocks output from the data buffer to the input/output device. A latest data block length counting circuit is provided to calculate the length of the latest data block, and when the output of the empty data block length counting circuit is equal to or greater than the output of the latest data block length counting circuit, a transfer request for the next data block is sent to the host device. A data buffer control method for an input/output device, characterized in that: