JPS6359644A - Semiconductor filing device - Google Patents

Abstract

PURPOSE:To make only unsaved data which is under a prescribed number save when a power source is disconnected by stopping an access for a while to save in order that a host device does not execute a write in the data if the write of the data is executed in a semiconductor memory by the prescribed number. CONSTITUTION:When a data save/restoration mechanism 12 scans on a control storage 11 and a flag which shows that the data is written in the semiconductor memory 5 reaches the prescribed number, the data is made to save from the semiconductor 5 to a nonvolatile storage device by the prescribed number. Therefore at the time of receiving a power source disconnection signal from a power source disconnection/throw-in entry control circuit 6, it is needless that all the contents of the semiconductor memory 5 is made to save. At this time it is necessary only that only unsaved data, which is naturally under the prescribed number, is made to save, so that the power source can be disconnected in a short saving time.

Description

[Detailed Description of the Invention] [Summary] Since semiconductor file devices use volatile semiconductor memory, the contents of the semiconductor memory are saved when the power is turned off. However, since this saving takes time, it is necessary to When a certain number of data have been written, temporary access is blocked and saved so that a host device does not write to this data, and only unsaved data of a specified number or less need be saved when the power is turned off.

[Industrial application field]

The present invention relates to a semiconductor file device that is used in an information processing system and enables high-speed access, and more particularly to a semiconductor file device that saves data at high speed when the information processing system is powered off.

By using a semiconductor memory for its storage element, a semiconductor file device does not require any mechanical operation to write/read target data, unlike file devices using magnetic disk devices. The access speed is several dozen times faster.

However, since the semiconductor memory used in this semiconductor file device is a volatile element, data disappears when the power is turned off.

Therefore, in order to create a file device that does not lose data, before turning off the power to the file device, save the data in memory to a non-volatile storage device such as a micro disk, and store the data in the non-volatile storage device when the power is turned on next time. A function to restore data evacuated from the sexual storage device to memory, that is,
Data backup/restore functionality is required.

By the way, when data is saved using this data save/restore function, it is desirable that the time required for the save is short.

[Conventional technology]

FIG. 5 is a block diagram showing an example of a semiconductor file device.

The central processing unit 1 sends input/output commands to the input/output control circuit 4 of the semiconductor file device 3 via the channel 2 to read data from the semiconductor memory 5 or write data to the semiconductor memory 5.

A power-off signal or a power-on signal is input to the power-off/on-on control circuit 6 from the information processing system.

When the power supply cutoff control circuit 6 receives the power cutoff signal, it notifies the input/output control circuit 4 to block access from channel 2, and also instructs the data save/restore mechanism 7 to perform the data save operation. Instruct to start.

The data save/restore mechanism 7 reads and saves data stored in the semiconductor memory 5 into a built-in nonvolatile storage device. Then, when this saving process is completed, the data saving/restoring mechanism 7 notifies the power-off/on control circuit 6.

The power-off/on-on control circuit 6 turns off the power to the semiconductor file device in response to this notification.

Normally, the non-volatile storage device built into the data evacuation/restoration mechanism 7 is a micro disk or the like that has low storage cost and long access time, so the data evacuation process takes only a few minutes to 10 minutes. I need.

[Problem that the invention seeks to solve]

In a semiconductor file device such as the one described above, data saving is started after receiving a power-off instruction from an external source, so the power cannot be turned off immediately, and the data saving time is long. Since the power to other devices, such as the central processing unit, is cut off immediately, there is a problem in that even if an abnormal state occurs during data saving, it cannot be notified.

[Means for solving problems]

FIG. 1 is a block diagram of a circuit showing one embodiment of the present invention.

5 and 6 are the same as in FIG. 10 controls access from the host device 8 to the semiconductor memory 5, and when the host device 8 issues a data write instruction to the semiconductor memory 5, the data save/restore mechanism 12 must ensure that the data at the corresponding address is not being saved. For example, it is an input/output control circuit that sets the address of the data in the control memory 11 and a flag indicating that the data has been written.

11 is the address of the data written from the host device 8 to the semiconductor memory 5, and the fact that the data was written;
Is there a system that stores a flag indicating that the data is being saved? 111 memory.

12, the input/output control circuit 10 controls the control record f! When the control memory 11 is not being accessed, the control memory 11 is constantly scanned, and when it detects that the number of flags indicating that data has been written has reached the specified number, the flag indicating that data is being saved is sent. This is a data save/restore mechanism that prevents the host device 8 from accessing this data and then saves the data.

[Effect]

The data save/restore mechanism 12 scans the control memory 11 and
When the flag indicating that data has been written to the semiconductor memory 5 reaches a predetermined number, the power supply cut-on control circuit 6 sends a command to save the predetermined number of data from the semiconductor memory 5 to the nonvolatile storage device. When a power-off signal is received, there is no need to save all the contents of the semiconductor memory 5, and only the unsaved data, which is naturally less than the specified number, needs to be saved at that time, so the power can be turned off in a short saving time. You can.

〔Example〕

2 is a diagram illustrating an example of the contents of the control memory 11, FIG. 3 is a flowchart illustrating the operation of the input/output control circuit 10, and FIG. 4 is a flowchart illustrating the operation of the data save/restore mechanism 12. It is.

As shown in FIG. 3, the input/output control circuit 10 of the semiconductor file device 9 monitors data writing among file accesses issued from the host device 8, and in the case of a data write request, sends the data to the data save/restore mechanism 12. is notified via the signal line 13 that the control storage 11 will be accessed.

The input/output control circuit 10 accesses the control memory 11 and checks the flag of the address of the semiconductor memory 5 to which the host device 8 requests writing. As shown in FIG. 2, the contents of the control memory 11 are stored as a table of flags and memory addresses.

This flag consists of 2 bits, for example, “(11)”
If so, it indicates the address of the data for which data saving has been completed or data has not been written, and is “10”.
” indicates a data address where data has been written or an address where data has been updated and data has not been saved yet, and “11” indicates a data address where data is being saved. shows.

When the flag of the corresponding address in the control memory is "11", the input/output control circuit 10 sends a device busy signal to the host device 8 to prevent the host device 80 from accessing the semiconductor memory 5.

If the flag of the corresponding address is "10" ((11)), the flag is set to "10", the memory address is written, and data is written into the semiconductor memory 5. The above operation is repeated until the data writing is completed. When the data writing is completed, the input/output control circuit 10 notifies the data save/restore mechanism 12 of the completion of access to the control memory 11, and also requests the data write request. Return to monitoring.

The data save/restore mechanism 12 monitors the access notification from the input/output control circuit 10 to the control memory t011 as shown in FIG. Count the number of flags present.

It is checked whether the table scan of the control memory 11 has completed one cycle, and once the table has been scanned, it is checked whether there is a specified number of "10" flags.

If there is no specified number of “10” flags, the input/output control circuit 10
When there is an access notification, scanning of the control memory 11 is stopped and the input/output control circuit 10 waits for the access to the control memory 11 to be completed. When the access is released, the scanning of the control memory 11 is continued again, and the control memory 11 is
After one round of table scanning, the number of flags that are "10" is checked again.

When the number of flags reaches the specified number, the flags of the memory addresses whose flags are "10" are changed to "11" in table order.
”, the data at the corresponding memory address is read from the semiconductor memory 5 and saved in the built-in nonvolatile storage device.

Once the data has been saved, the flag for the corresponding memory address is set to “
(11)", then set the lag to "11" (same as above) for the data at the memory address that is "10", and then start saving. When the saving is complete, set this flag to "(11)". ”.

When the specified number of data have been saved, the data save/restore mechanism 12 returns to the operation of monitoring access notifications from the input/output control circuit IO.

When the data save/restore mechanism 12 receives a power cutoff signal from the power cutoff/on control circuit 6, the data save/restore mechanism 12 detects "
The data at the memory address "1O" is read out from the semiconductor memory 5 and saved, and when this is completed, the power-off/on control circuit 6 is notified.

〔Effect of the invention〕

As explained above, the present invention does not require the data save/restore mechanism to save all the data on the semiconductor memory when the power is turned off, and only needs to save a small amount of data that is less than the specified number. It is possible to shorten the waiting time.

[Brief explanation of drawings]

FIG. 1 is a block diagram of a circuit showing an embodiment of the present invention, FIG. 2 is a diagram explaining an example of the contents of control memory, FIG. 3 is a flowchart explaining the operation of the input/output control circuit, and FIG. 5 is a flowchart explaining the operation of the data save/restore mechanism, and FIG. 5 is a block diagram showing an example of a semiconductor file device. 3.9 is a semiconductor file device, 4.10 is an input/output control circuit, 5 is a semiconductor memory, 6
7.12 is a data save/restore mechanism; and 8 is a host device. ZuL Rumor T5Q Month 6 Lee Kinihiki is a Vibrator Show 1i Giant Eat Rib 0n 2G Ko Article Half, out of prefecture Fai) Kototo 1's Ikkou Kinjo Bro 720 Pregnancy 5
mouth

Claims (1)

[Claims] By an arbitrary address specified by the host device (8),
A semiconductor memory (5) capable of writing/reading a predetermined amount of data, the address of the data written to the semiconductor memory (5) from the host device (8), and the fact that the data has been written. and a control memory (11) that stores a flag indicating that the data is being saved; and when an instruction to write data to the semiconductor memory (5) is input from the host device (8), the control memory ( 11) is an input/output control circuit (10) that stores the address of the data and a flag indicating that the data has been written, and the control memory (11) is scanned to confirm that the data has been written. a data save/restore mechanism (12) that detects that the number of flags indicating that data has reached a specified number, sets a flag indicating that data is being saved in the control memory (11), and saves the data. When a data write request to the semiconductor memory (5) is input from the host device (8), the input/output control circuit (10)
executes the write request excluding the address where the data is being saved, and the data save/restore mechanism (12)
When the number of flags indicating that data writing has been performed in 1) reaches a specified number, the data is saved from the semiconductor memory (5) by setting the data saving flag, so that when the power is turned off, the specified number of A semiconductor file device characterized in that the following unsaved data is saved.