JPH05113858A - Printer device including nonvolatile memory - Google Patents

Abstract

PURPOSE:To provide a proper data arrangement so that the frequency of access to some addresses is one-sided and to prevent the nonvolatile memory from becoming short in life by taking a self-analysis when the device state of the printer device is recorded in the nonvolatile memory. CONSTITUTION:The memory is divided into two parts and while an area corresponding to data one to one is assigned to the memory fixation part 9, data which are high in access frequency are previously registered in a registration table 4; and the frequency of the data is counted to secure a storage area corresponding to the frequency in the memory expansion part 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a printer device having a non-volatile memory for storing printer control information even after the power is turned off.

[0002]

2. Description of the Related Art Heretofore, as printers of this kind have become multifunctional, the amount of data relating to the status of the devices has tended to increase.
It is necessary to keep the control information even after the power of the device is turned off, and since the same information is frequently used many times, an expensive non-volatile memory has been used as the means.

[0003]

The non-volatile memory used in the above-mentioned conventional printer device has a limit to the number of times each address can be accessed, and needs to be replaced periodically. Therefore, when the access frequency to the specific address is extremely high, the life peculiar to the non-volatile memory almost depends on the access frequency to the specific address.

An object of the present invention is to enable even access to a non-volatile memory even when there is a significant difference in the update frequency for different stored information, and as a result to maximize the life of the memory. Another object of the present invention is to provide a non-volatile memory control device for a printer that enables the above.

The printer non-volatile memory control device of the present invention is a storage means for storing the frequency with which the control information of the printer device is used, and a means for registering information to be stored in advance when storing the use frequency. A means for managing the address configuration of the storage means, a means for controlling access to the storage means, a means for counting the frequency of use, and a necessary and sufficient storage area as an area for storing the frequency of use. And a mechanism for suppressing a decrease in the life of the storage means caused by the deviation of the data update frequency.

[0006]

By means of the above-mentioned means, among the control information relating to the device state, information having a high access frequency to the memory is registered in advance in the registration table, and the access frequency of the data is counted for a certain period of time. For all data,
A memory fixing unit is used for data storage, and the registration data is stored in the frequency counter storage area. After a certain period of time, the frequency ratio of each data to the whole is calculated from the obtained frequency, and the additional memory storage area is allocated according to the frequency based on that value, whereby the memory allocation can be optimized.

[0007]

Embodiments of the present invention will now be described with reference to the drawings. Unless otherwise specified, the term "memory" refers to a non-volatile memory.

FIG. 1 is a block diagram of a printer device including a non-volatile memory control device for a printer according to the present invention. 2 and 3 show the internal arrangement of areas in the non-volatile memory 5. The printer device 8 includes a print drive unit 7 that prints print data sent from an external device on a sheet, a printer control unit 1 that manages and controls the operation of the print drive unit and the entire device, and a printer even after power-off. A printer device including a non-volatile memory having a non-volatile memory 5 for holding control information of the device, in addition to these, a frequency counter storage area 13 for storing a frequency at which the control information of the printer is used; In storing the frequency of use, a registration table 4 for registering target information in advance, a memory management unit 2 for managing the address configuration of the storage unit, an access analysis unit 3 for controlling access to the storage unit, and Memory management unit 2 for counting the frequency of use, and memory management unit 2 for allocating a necessary and sufficient storage area for storing the frequency of use Are al configuration.

Next, the operation of this embodiment will be described. Of the various control information in the printer device, the printer control unit 1
Data which is controlled by the controller and is changed when a change occurs in the device state and which needs to be stored even after the power is turned off is stored in the nonvolatile memory 5. Management is performed by the management unit 2, and access is controlled by the memory access analysis unit 3 by a method described later.

The internal arrangement of the non-volatile memory 5 shown in FIGS. 2 and 3 is used by dividing the same area into two. In the memory fixing unit 9, each data is arranged in a fixed area regardless of the memory use mode and regardless of the access frequency. The memory area used in the conventional printer device corresponds to the memory fixing unit 9.

On the other hand, the memory expansion unit 10 has a different purpose of use depending on the state of the device. Normally, the memory expansion unit 10 includes an additional memory storage area 11 that plays a supplementary role of the memory fixing unit 9 and a storage area access data 12 that specifies an address of the additional memory storage area 11 (hereinafter, referred to as a normal mode). Called).

For the sake of simplicity, it is assumed here that the data areas (A0, B0, C0, ...) Concerning the device status information have the same size. Information (A, C, ...) Of these unique device data, which is frequently accessed to the memory
Is registered in the registration table 4 in advance, and an area corresponding to the frequency of use is arranged in the additional memory storage area 11. For example, for the frequent data A, A1, A2, ..., An _{- 1} in the additional memory storage area 11 of the memory expansion unit 10 are allocated in addition to the area A0 specific to the memory fixed unit 9.

It is the above-mentioned memory management unit 2 that determines how much capacity is to be allocated in which area.

Next, the access frequency of each data registered in the registration table 4 is counted for a certain period (hereinafter referred to as a count mode). That is, after the data stored in the additional memory storage area 11 is transferred to the corresponding memory fixing unit 9, the additional memory storage area 11 and the storage area access data in the normal mode are managed according to the management of the memory management unit 2. 12 is released and used again as a frequency counter storage area 13 for a different purpose as shown in FIG. For all data, the memory fixing unit 9 is used for data storage, and the frequency of the registered data (A, C, ...) Of the registration table 4 is counted and stored in the frequency counter storage area 13. After a certain period of time, the frequency ratio of each data to the whole is calculated from the obtained frequency, the additional memory storage area 11 corresponding to the frequency is allocated based on the calculated value, and the mode returns to the normal mode. Even when the frequency ratio changes with time, the memory mode can be optimized by shifting to the count mode at regular intervals and rearranging the additional memory storage area 11 according to the frequency ratio. Become.

FIG. 4 shows a memory expansion unit 10 (A1, A2, ...) In addition to the memory fixing unit 9 (A0) in the normal mode.
A _n-1 ) is used to describe the method of storing the data A. When the device is powered on, all the data in the nonvolatile memory 5 is transferred to the work area 14 on the RAM 6.
(FIG. 4 (a)). After that, the reading of data including the storage area access data 12 is limited to only the work area 14 rather than directly accessing the nonvolatile memory 5. This makes it possible to reduce the number of accesses to the non-volatile memory 5 itself. The access analysis unit 3 recognizes the area (A0 to A _n-1 ) related to the data A based on the storage area access data 12, and searches for the effective data 15 in the area.

Dummy data 16, which is a special value that the valid data 15 never takes, is stored in the n-1 areas other than the valid data 15, and the storage position of the valid data 15 is searched by searching the data itself. Can be grasped.

At the time of writing, the valid data located at A0 moves to the next address A1, and dummy data is also stored at A0 (FIG. 4 (b)). At the time of the next writing, the storage position of valid data shifts to A2. In this way, when writing, n areas are sequentially slid and accessed, so that access to specific addresses is dispersed.

The operation of the printer controller 1 will be described with reference to FIGS. This flowchart relates to a series of processes from the power-on of the device to the power-off. When the power is turned on, the contents stored in the nonvolatile memory 5 are read into the RAM work area 14 in step S1. Unless the power is turned off in step S2, the subsequent processing is continued. In step S3, the current memory use mode is determined. If the condition for shifting to the count mode is recognized in step S4 in the normal mode, the memory management unit 2 (FIG. 7) is called in step S5, and the nonvolatile memory 5 has the memory internal arrangement shown in FIG. Then, in step S6, a process for changing to the count mode is performed. If it is not the condition for changing to the count mode in step S4, step S7
A data access request to the non-volatile memory 5 is determined in step S8, and if there is a request, memory access analysis processing is performed in step S8. At this time, the access location is detected from the existing position of the storage area access data 12 in FIG. 2 and the valid data 15 in FIG. 3, and then step S9.
To actually perform access processing.

Next, in the count mode in step S3, as shown in FIG. 6, if the change condition to the normal mode is recognized in step S10, the memory management unit 2 (FIG. 7) is called in step S11. , Non-volatile memory 5
Has the memory internal arrangement shown in FIG. Then, in step S12, the mode is changed to the normal mode. When the data access request is determined in step S13 instead of the condition for the normal mode in step S10, the count to the frequency counter storage area 13 and the data access to the memory fixing unit 9 are performed in step S14.

FIG. 7 shows steps S5 and S5.
11 is a flowchart showing an operation of the memory management unit 2 called in 11. When the count mode is changed in step S16, the additional memory storage area 1 is added in step S17.
1 and the storage area access data 12 are released, and the frequency extension storage area 13 is newly added to the memory expansion unit 10.
To place. In step S17, if the valid data 15
However, if it exists in the additional memory storage area 11, it is necessary to write to the corresponding area of the memory fixing unit 9 as described above.

When the mode is changed to the normal mode in step S16, the frequency count storage area 13 is released in step S19, and the additional memory storage area 11 and the storage area access data 12 are arranged in the memory expansion section 10. Furthermore,
In step S20, based on the access frequency of each data,
The memory expansion unit 10 calculates the size of the additional memory storage area 11 to be distributed to each data. In FIG. 2, the data A has an n-1 unit, and the data C has an m-1 unit. At the same time, in step S21, the storage area access data 12 is arranged to store the address where the additional memory storage area 11 arranged as described above exists.

[0022]

As described above, according to the present invention, it is possible to access the nonvolatile memory evenly even when the update frequencies of different stored information are significantly different, and as a result, the nonvolatile memory can be accessed. It has the effect of extending the life to the maximum.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a printer device of the present invention.

FIG. 2 is a diagram showing an internal configuration of a nonvolatile memory 5 over time in an embodiment of a printer nonvolatile memory control device of the present invention (normal mode).

FIG. 3 is a diagram in which the frequency counter storage area 13 is configured by changing the purpose of use of the nonvolatile memory 5 in one embodiment of the printer nonvolatile memory control device of the present invention (count mode).

FIG. 4 is a diagram showing a storage system of data A using a memory fixed part and an expanded part in a normal mode in one embodiment of a printer nonvolatile memory control device of the present invention.

FIG. 5 is a flowchart showing the operation of the printer control unit 1 in one embodiment of the printer non-volatile memory control device of the present invention.

FIG. 6 is a flowchart showing the operation of the printer control unit 1 in one embodiment of the printer non-volatile memory control device of the present invention.

7 is a flowchart showing the operation of the memory management unit 2 called in step S5 shown in FIG. 5 and step S11 shown in FIG. 6 in an embodiment of the printer non-volatile memory control device of the present invention.

[Explanation of symbols]

 1 printer control unit 2 memory management unit 3 access analysis unit 4 registration table 5 non-volatile memory 6 RAM 7 print drive unit 8 printer device 9 memory fixed unit 10 memory expansion unit 11 additional memory storage area 12 storage area access data 13 frequency counter storage Area 14 Work area 15 Effective data 16 Dummy data

Claims (1)

[Claims] 1. A unit for printing print data sent from an external device on a sheet, a unit for managing and controlling the operation of the print drive unit and the entire unit, and holding control information of the printer unit even after power-off. In a printer device including a non-volatile memory having means for storing, a storage unit that stores the frequency with which the control information of the printer is used; and a unit that registers information to be stored in advance when storing the use frequency. A means for managing the address configuration of the storage means, a means for controlling access to the storage means, a means for counting the frequency of use, and a storage area necessary and sufficient for storing the frequency of use And a printer device including a non-volatile memory.