DE3513038A1 - Method and arrangement for converting data words into code words - Google Patents

Abstract

To convert data words (D1), which, for example, are allocated to characters (Z1, Z2) and associated attributes (A1, A2) which can be displayed on a screen, into code words (CW1) such as, for example, ASCII characters, a first and a second converter (U1, U2) are provided. The first converter (U1) classifies the data words (D1) allocated to the characters into various groups (G0, G1, G2) and allocates a group code (GK1) to each group (G0, G1, G2). In addition, it adds to the data words (D1) predetermined numerical values in dependence on the respective group (G0, G1, G2), in order to generate the code words. The second converter (U2) in each case allocates code word sequences (CF1) to the attributes (A1, A2). A comparator (VG) only outputs the group code (GK1) and/or a codeword sequence (CF1) when these have changed. <IMAGE>

Description

Method and arrangement for converting data words into

Code words The invention relates to a method for converting of data words in code words according to the preamble of the claim 1. Furthermore, the invention also relates to an arrangement for implementation of the procedure.

In the case of a representation or transmission of in the form of data words Stored characters often encountered the problem that for playback or Transmission the data words are represented according to a predetermined code have to. Such a predetermined code is, for example, the internationally agreed one ASCII code consisting of seven binary characters. If, for example, in a display unit the screen content in a memory in the form of data words with eight each Binary character is stored and attributes associated with the character are also stored which indicate the type and / or color in which the characters are to be displayed, the data words assigned to the characters and the attributes must be entered in the corresponding Code words are implemented.

The characters can be, for example, alphanumeric characters, be graphical characters or a special character set, for example is common for the "On-Screen Text" service. The attributes can be, for example indicate whether the corresponding characters are flashing, half-light, underlined or in a certain color or background color should be displayed.

The invention is therefore based on the object of a method and to specify an arrangement with which the implementation of the data words can be carried out in a simple manner in the code words is possible.

According to the invention, the object in the method is that mentioned at the beginning Kind by the process steps specified in the characterizing part of claim 1 solved.

The characters are divided into the various groups, for example such that a first character set indicates the alphanumeric characters, a second Character set indicating graphic characters and a third character set the characters of the Contains "onscreen text" service. The group identifier indicating the affiliation of the characters for the various groups are preferably control characters the code words formed as ASCII characters. Using an adder become either positive or negative for the data words of the different groups Numerical values preferably added as hexadecimal numbers to the number of binary characters of the data words in terms of the number of binary characters of the code words and um the control characters are not represented by characters from the alphanumeric character set to prove. After the implementation of the characters, these are possibly put together stored with the group identifier in the memory, preferably a Comparator is provided, which the group identifier of consecutive Compares data words with each other and only then puts a group identifier in the memory stores if this is from the group identifier of the previous data word is different.

The attributes are each converted into a code word sequence, with preferably three code words each of these Codeword follow the same and begin with an ESCAPE character and a code word of this code word sequence is assigned to a data word of an attribute in each case. Here, too, it is useful using the comparator, the code word sequence of an attribute with the code word to compare a preceding attribute and only then the code word sequence to be stored in the memory if this differs from that of the previous one Attribute is different.

The characters and the attributes preferably constitute a screen content which is stored in a frame buffer and by a known per se Function "Windowget" is generated. In this case the data words have eight binary characters and these are converted into code words with seven binary characters, preferably are assigned to the internationally agreed ASCII code.

A preferred embodiment of an arrangement for performing the Method contains a converter that divides the data words into the various groups divides, generates the group identifier and the corresponding data words Numerical values added. For converting the data words assigned to the attributes Another converter is used, which assigns the code word sequences to the data words. Around not the corresponding group identifier and code word sequence for each character To have to store in a memory, a comparator is provided that the group identifier compares each character with that of the previous character and only if there is a change outputs the group identifier to the memory and / or an attribute for each associated code word sequence compares this with that of the preceding attribute and also only sends a code word sequence to the memory in the event of a change.

The following are the method and arrangement according to the invention explained in more detail using a drawing.

The drawing shows a functional diagram of an arrangement for implementation of the procedure.

In a character memory ZS there are characters in the form of data words D1 stored by hexadecimal numbers. For example, a graphic character is Z1 by the hexadecimal number 90 and an alphanumeric character "A" as character Z2 stored by the hexadecimal number 21. In an attribute memory AS are the Attributes A1 and A2 belonging to the characters Z1 and Z2 are also saved as hexadecimal numbers, for example CO and 30. The hexadecimal numbers represent data words D2 and the hexadecimal number CO means, for example, a flashing display, while the hexadecimal number 30 means a half-light display. The data words D1 are divided into a plurality of groups according to the characters, for example divided into three groups GO to G2, the group GO comprising alphanumeric characters, the group G1 graphic characters and the group G2 characters for the "screen text" service includes. The data words D1 are coded in such a way that the group GO contains the data words D1 with the hexadecimal numbers 00 to 5F, the group G1 the data words D1 with the hexadecimal numbers 60 to BF and the group G2 the data words D1 with the Includes hexadecimal numbers CO to FF.

A converter U1 contains an allocator Z, which is a data word D1 in Depending on which group it belongs to, a corresponding group identifier CKl in the form of hexadecimal numbers OF, OE or 10 is assigned. These hexadecimal numbers have the binary value 0 in their most significant digit, so that they also start with seven Binary characters instead of eight as with usual hexadecimal numbers co- dated can be. The same applies to code word sequences CFl and code words CW, which also only have seven binary characters, as guaranteed in all cases is that the most significant binary character of the hexadecimal number is 0.

The character Z1 with the hexadecimal number 90 belongs to group G1, since 90 is between 60 and BF. The allocator Z therefore outputs the numerical value OE, as group identifier GK1 via a comparator VG as group identifier GK2 is delivered to the memory SP and is stored there. The adder AD Adds the hexadecimal value -40 to the hexadecimal number 90 and it becomes that Code word CW generated with the numerical value 50, which is also stored in the memory SP will. By adding the numerical value -40, i. H. by subtracting the numerical value 40 it is ensured that the most significant binary character in the code word CW is O, so that it can also be stored in the memory SP with seven binary characters. Corresponding applies to the subtraction of the numerical value AO for data words D1 of group G2.

The attribute Al assigned to the characters Z1 has the hexadecimal Numerical value CO, which is fed to converter U2 as data word D2 with eight binary characters will. This generates a code word sequence CF1, which consists of four code words each with seven binary characters is formed, whereby the first code word with the numerical value 1B a control signal "ESCAPE" means, the second code word a character (c) with the Numerical value 5B and the fourth code word means a character (m) with the numerical value 6D. The third code word with the numerical value C3 also has only seven binary characters and its meaning corresponds to the data word with the numerical value CO.

If the next character is also a graphic chen occurs which is represented by the same attribute, the allocator Z generates again a group identifier GK1 with the numerical value OE. However, the comparator VG provides determines that the previous group identifier GK1 was the same and therefore it generates no group identifier GK2. In a corresponding manner, the comparator VG determines that the code word sequence CFl is the same as the code word sequence CFl in the previous one Attribute Al and er therefore does not generate a new code word sequence CF2. From the data word D1 itself, however, the numerical value 40 is subtracted to the corresponding code word CW to generate. This now immediately follows the preceding code word in the memory SP CW. If the next character is again a graphic character, this one but has a different attribute, no new group identifier GK2 is generated, however, a new code word sequence CF2 and again the corresponding code word CW for the sign.

If the graphic characters are followed by an alphanumeric character Z2, for example with the hexadecimal number 21, is recognized by the allocator Z that this character Z2 is contained in the first group GO and it therefore generates a device identifier GK1 with the numerical value OF. The comparator VG determines that this group identifier CKl is different from the previous group identifier GK1 with the numerical value OE and he gives the new group identifier as a group identifier GK2 to the memory SP. The adder AD adds the numerical value to the numerical value 21 20 and as the code word CW, the numerical value 41 is thus represented by seven binary characters in the Memory SP saved.

The attribute A2 with the numerical value 30 belongs to the numerical value Z2. This arrives as data word D2 to converter U2, which generates a code word sequence CFl, which now has the numerical value 32 as the third code word, which is for example is assigned to the half-light representation of the character Z2. Since this attribute A2 is different from the preceding attribute, the comparator VG generates the code word sequence CF2, which is now stored in the memory SP.

If after the character Z2 there are other alphanumeric characters with the same Attribute following are displayed in a corresponding manner as in the case of the representation of the graphic Character neither the group identifier GK1 or GK2 nor the code words CFl or CF2 only generates the corresponding code words CW and that as long as until the group and / or the attribute changes.

As already mentioned, the characters stored in the memory SP each formed from seven binary characters, although they are represented as hexadecimal numbers are. However, since the most significant binary character has the binary value O, you can the characters are displayed in accordance with the internationally agreed ASCII code and are output from the memory as code words CW1. You can now connect to a Screen control or a printer control are issued to the appropriate Display or print out characters in the intended type of representation. It is It is also possible to send the code words CWl over one transmission link to another Output unit to be transmitted and there the characters in the corresponding type of representation to spend.

By adding the numerical values 20, -40 and -AO is in each case ensures that the most significant binary character is the one formed from eight binary characters Data words D1 has the binary value 0 and are thus stripped off for the code word CW can.

10 claims 1 figure

Claims (10)

Claims 1. Method for converting data words into code words, in which the data words and the code words are each binary coded and a different one Number of binary characters and in which the data words have different characters are assigned, the following process steps are assigned: a) the data words (D1) are divided into a plurality of groups (GO, G1, G2), the different types of characters are assigned, b) for each group (GO, G1, G2) a group identifier (GK1, GK2) is generated, c) the data words (D1) constant numerical values are added depending on the respective group (GO, G1, G2), to generate the corresponding code words (CW), d) the group identifier (GK1, GK2) and the code words (CW) are stored. 2. The method according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the group identifier (GK1) of two consecutive characters with each other can be compared and only if a group identifier (GK1) is changed this is saved. 3. The method of claim 1 or claim 2, d a -d u r c h g e k It is indicated that the characters represented by the data words (D1) (Z1, Z2) Attributes (Al, A2) are assigned in the form of further data words (D2) and that these data words (D2) are each converted into a code word sequence (CF1, CF2) and together with the code words (CW) and the group identifier (GK1, GK2) get saved. 4. The method according to claim 3, d a d u r c h g e -k e n n z e i c h n e t that the attributes (A1, A2) of consecutive characters (Z1, Z2) are compared with one another and that only when an attribute is changed (Al, A2) the code word sequence (CF1, CF2) is stored. 5. The method according to any one of claims 1 to 4, d a -d u r c h g e does not indicate that the characters (Z1, Z2) and the attributes (A1, A2) form a Screen content are assigned. 6. The method according to any one of claims 1 to 5, d a -d u r c h g e it is not indicated that the data words (D1) and the further data words (D2) each have eight binary characters and the code words (CW) as ASCII characters are formed with seven binary characters each. 7. The method according to any one of claims 1 to 6, d a -d u r c h g e it does not indicate that the numerical values are added to the data words (D1) are designed in such a way that the code words (CW) are taken into account the most significant digit have the desired number of binary characters. 8. Arrangement for performing the method according to claim 1, d a d u r c h e k e n n n n z e i c h n e t that a first converter (U1) is provided that corresponds to the data words (D1) of the characters (Z1, Z2) of the various groups (GO, G1, G2) each assigns the group code (GK1) and that of the data words (D1) the various numerical values depending on the respective group (GO, G1, G2) added to obtain the code words (CW) and that a memory (SP) is provided is, in which the code words (CW) and the group codes (GK1, GK2) can be stored are. 9. The arrangement according to claim 8, d a d u r c h g e -k e n n z e i c h n e t that a second converter (U2) is provided, which consists of the respective Attributes (A1, A2) assigned further data words (D2) the code word sequences (CF1, CF2) generated. 10. An arrangement according to claim 8 or claim 9, d a -d u r c h g e it is not indicated that a comparator (VG) is provided for the group codes (GK1) of successive data words (D1) compares with one another and only when the group code (GK1) changes, it saves it in the memory (SP) and / or the code word sequences (CF1) of successive further data words (D2) compares with each other and only if the code word sequence (CF1) is changed these stores in the memory (SP).