FR2580836A1 - Device for storage of information contained in a computer from a source in a high-level interpreted language - Google Patents

Abstract

This device for storage of information contained in a computer 14 from a source in a high-level interpreted language, comprises means for storage of information consisting of integrated-circuit memories 16, 18 controlled by addressing means 20 driven by the said computer. These integrated-circuit memories consist of random-access memories, for example of the RAM type and/or read-only memories, for example of the PROM type.

Description

 The present invention relates to devices for storing information contained in a computer and it relates more particularly to a device for storing information on memories with integrated circuits from a source in advanced interpreted language.

 The development of computer machines has led since their appearance. to develop a large number of devices capable of saving the information transmitted, produced or managed by these machines.

 These devices, grouped under the term of memories, can be described according to different criteria characteristic of their ability more or less limited in time or more or less dependent on external conditions, to retain information.

 Technological progress has made it possible to develop magnetic media (tape, cassette, floppy disk) as well as circuits capable of retaining magnetic information (toroids) and then electronic random access memory (RAM) media. or read only memory (ROM, PROM. REPROM, EEPROM).

 However, some of these storage devices have drawbacks. In fact, magnetic media are non-volatile but are sensitive to electromagnetic disturbances. Flash memory media are volatile which requires a permanent power supply and these media are particularly sensitive to electrical disturbances.

 It should be noted that the read-only memory media are non-volatile and have good insensitivity to external disturbances.

Until now, storage on a non-volatile memory circuit (PROM. REPROM, etc.) was only used for programs written directly in machine language or compiled. Now, the use of a compiled Basic compiled language,
Fortran, Cobol, Pascal) is only possible on certain high-performance machines and is generally not possible on so-called family or mass-market computers.

Writing a program in machine language (assembler) can be done directly but requires an installation called development system. These systems are expensive (several hundred thousand francs) and require a relatively long learning time,
This investment therefore generally appears disproportionate for light or episodic applications.

 The object of the invention is therefore to solve the problems mentioned above by offering the user of computer systems a means of storing information (programs or data) written in advanced interpreted language (Basic, Logo, Forth , etc.) on non-volatile memory circuits (ROM, PROM.

EPROM, EEPROM) or volatile (RAM).

 To this end, the subject of the invention is a device for storing information contained in a computer, from a source in interpreted advanced language, - ca-ractêrisê eh ;; # - what the storage means consist of memories with integrated circuits controlled by addressing means controlled by said computer.

 It therefore makes it possible to overcome all the drawbacks linked to the use of magnetic storage systems, floppy disks or cassettes, because as we know. this type of magnetic support is also sensitive to atmospheric conditions (humidity, temperature, dust) and requires packaging and handling precautions. In addition, this type of medium can be destroyed by radio-electromagnetic interference and the access times to information stored on magnetic media are relatively long.

The invention will be better understood with the aid of the description which will follow, given solely by way of example and made with reference to the appended drawings, in which
- Fla.1 represents a block diagram of a first embodiment of a device according to the invention;
- Fig.2 shows a block diagram of a second embodiment of a device according to the invention; and
- Fig.3 shows a block diagram of a third embodiment of a device according to the invention.

As can be seen in Fig.1, a serial data output line 1, for example of the RS 232 type from a computer 2 is connected to the input of a read only memory programmer 3. This programmer 3 develops a read-only memory 4 for example of the type
PROM.

 The output of this memory 4 is then connected to an omnibus data line 5 of the computer 2. A clock 6 generated by the computer 2 is connected to the input of a counter 7, the output of which is connected to the terminals d memory addressing 4.

 The operation of such a device is as follows.

The object of the invention is to save and allow the reading of information in an integrated circuit memory using for example a computer of the type T07-70 manufactured by the Company
THOMSON. For reasons of understanding the invention. it is first of all necessary to describe the principles of reading and saving information presented for example in the form of a file, on a cassette storage device. On a cassette, the files are stored sequentially, that is to say that they follow one after the other. For these reasons. there is therefore no direct access to the file,
The loading of the information constituted for example by a program, forces the computer to scroll the cassette until it encounters the file in question.

Each file (data or programs) is stored in blocks of 255 bytes. The information recorded on the cassette therefore takes the form of a series of blocks. Each block is separated by control codes which are
- file start code (for the first
block)
- block start code
- end of block code
- end of file code (for the last
block)
So when you save a program on cassette, the computer starts by writing the file start code followed by the file name. He then comes to write block by block, the file (data or programs) that we want to save, each block being preceded by its block start code and followed by the block end code. This operation is repeated until the end of the file. When the last block has been saved, the computer writes the end of file code.

 When loading a file, the computer reads the bytes emitted by the cassette player, As soon as it encounters a file start code. they notify the user that they have found a file. Next :. it comes to read the file block by block, checking the presence of the control codes associated with each block. As soon as the computer has read the end of file code, 15 programs are loaded.

 It should be noted that if a control code is incorrect, an error message is issued. In this case the file is not loaded.

 It should also be noted that the management of this exchange protocol is carried out for example by the basic interpreter -from the computer and from one computer to another. the principle is the same although the control codes may vary.

 If we now refer to the operation of the device according to the invention, it can be seen that the principle of saving and reading a file on ROM is to be compared to that which has just been described. Indeed, we keep the same protocol as the cassette management protocol. We will therefore store in read-only memory, the same thing as what we would have stored on cassette.

 To do this, we will go through a temporary RAM area. Indeed, the file constituting a source in interpreted advanced language, which one writes, is already in RAM memory in the computer, but the written codes are not compatible with the cassette exchange protocol; for example, it does not include control codes. We will therefore transform the existing codes in RAM memory into codes representing the cassette management protocol. That is to say that we will perform according to a known process inherent in the structure of the computer. a division into blocks and add to these blocks, the control codes.

 The result of this operation is then placed in an area of random access memory RAM buffer. The content of this .live memory is then transferred to the read only memory programmer 3 as indicated in Fiv.1, via the serial data output line 1. The transfer format used is for example the format PPX.

 This operation therefore makes it possible to transfer the file that we want to store, from a working memory area of the computer to a memory area where the computer does not work, while adding control codes to it and by cutting into different blocks so as to transfer it to the storage device via the serial data output line. The formatting of the blocks for storage in the memory is ensured by the programmer. Thus the content of memory 4 will be the same as what would have been placed on the cassette. When rereading, the Basic interpreter will therefore find a code that can be used directly. This re-reading is carried out via the omnibus data line 5. The read-only memory is then addressed via the counter 7 receiving a clock signal generated by the computer, via line 6. This reading is 'therefore performs sequentially. so that the computer comes to read byte by byte, the contents of memory 94.

 The counter 7 therefore provides both for reading and for reading, by its address outputs.

la- simulation for the computer of the scrolling of a magnetic support.

It should be noted that the memory programmer 3 is a programmer suitable for the type of memory used. So for example, for a REPRQM type ROM, this programmer is a PP39 manufactured by the company STAG,
As can be seen in Fig. 2 which shows a second embodiment of the invention, a clock output 8 of a computer 9 is connected to the input of a counter-10 whose output is connected to RAM it type RAM.

 An omnibus data line 12 is connected to the data omnibus line of the computer 9 and to the data terminals of the memory 11. The operation of such a device is as follows.

 The computer 9 increments the counter 10 which delivers, at its output, addresses to the memory 11. It should be noted that the saving of data in the memory is carried out from the conventional transmission of data on the omnibus line of the 'computer-. During the re-reading, the computer comes to read the byte sto cke at the location pointed by the address delivered by the counter 10.

 The block diagram in Fig.3 represents a combination of the two devices described above. Indeed, a serial output for example RS 232.

13 of a computer 14 is connected to the input of a read only memory programmer 15 which prepares a read only memory 16 for example of the PROM type. An omnibus data line 17 is then connected to the output of this memory 16 and to the data omnibus line of the computer 14. A random access memory 18, for example of the RAM type, is also connected by its data output terminals to the omnibus line 17 as well as its terminals, for data entry.

 An output terminal 19 of the computer clock 14 is connected to the input of a counter 20 whose address outputs are connected to the read only memory 16 and to the random access memory 18 via '' an omnibus line of address 21.

 It is noted that an output 22 of the computer 14 is connected to a terminal of the read only memory 16 and to a terminal of the random access memory 18. This output 22 makes it possible to select the memory which will be connected to the computer, The operation of this device is an operation corresponding to what has been described for the preceding devices when the corresponding memory has been selected.

 Thus it is possible to store directly via the omnibus data line of a computer, data in a random access memory of the RAM type and to re-read this memory, or to store via the data output line serial, data in a PROM type ROM.

It can therefore be seen that the device according to the invention makes it possible to store on an integrated circuit. for example. a program written beforehand in an advanced interpreted language. which allows a rapid evaluation of the choices and a very flexible development of the program in real time,
In addition, when the memory addressing counter reaches the stop, the addressing starts again from the zero address; thus the storage and the reading are sequential and circular contrary to the functioning of a cassette player where it is necessary to rewind the tape to start from the beginning.

 The use of integrated circuits as storage means is particularly suitable for systems working in harsh environment, subject to electrical disturbances. shocks, etc., for example. for a consultation station in use in a public place.

Claims (6)

 1. Device for storing information contained in a computer, from a source in interpreted advanced language. characterized in that the storage means consist of memories with integrated circuits (4: 11; 16,18) controlled by addressing means (7; 10; 20) controlled by said computer (2: 9: 14)  2. Storage device according to claim 1, characterized in. that said integrated circuit memories consist of read-only memories (4:16) whose data inputs are connected to the output of a read-only memory programmer (3:15). the input of this programmer being connected to the serial data output line (1; 13) of said computer (2; 14). and the data outputs of the read only memories being then connected to the data bus line (5; 17) of said computer.  3. Storage device according to claim 2. characterized in that the addressing means consist of a counter (7:20) whose input is connected to a clock output (6; 19) generated by said computer (2:14) and the outputs of which are connected to the addressing terminals of said read-only memories (4; 16).  4. Storage device according to claim 1, characterized in that the memories with integrated circuits consist of random access memories (11; 18) whose data terminals are connected to the omnibus line (12; 17) of data of said computer (9; 14).  5. Storage device according to claim 4, characterized in that the addressing means consist of a counter (10; 20), the tree of which is connected to a clock output (8; 19) generated by said computer ( 9:14) and whose outputs are connected to the addressing terminals of said random access memories (11,18).  6. Storage device according to any one of the preceding claims. characterized in that said integrated circuit memories consist of random access memories (18) and read-only memories (16) whose outputs are selectively connected to the data bus line (17) of said computer (14).