SE434095B - INDICATOR FOR SUCCESSIVE INDICATION OF TEXT PAGE - Google Patents

Description

7800861-2 partial characters near the left edge of the indicator. This problem is solved with the device according to the present invention in that partial characters are exchanged for spaces of corresponding width. The result is an uneven left edge, but the characters are co-oriented vertically as they would be printed. The device according to the present invention is furthermore designed in such a way that both characters with proportional width and characters with standard width can be easily handled. For this purpose, a scale bar, which consists of characters and symbols with standard width, can be indicated together with text, which consists of characters with proportional width. The indication of a corresponding segment of the scale line in standard-width characters and symbols gives the operator a page position reference, which is equivalent to the scale of a standard typewriter.

According to the invention there is provided a device which performs automatic segmentation of both lines of text and a line of scales, which are to be indicated. The segmentation depends on the position of a cursor in one of the lines of the text. The device is designed to handle both standard wide and proportionally wide characters.

Each row starting from the row containing the cursor is entered sequentially in a row buffer. After entering the first line, a segment containing the cursor is selected. This segment is entered in a new buffer for indication. Thereafter, the corresponding segment of each subsequent row, including the scale row, is selected and entered into the new buffer for indication. After moving the cursor to a location outside the left or right edge of the indicator, the operation is repeated beginning with the entry of the cursor row in the row buffer. The appearance of a partial sign near the left edge of a segment results in a space filling for indication.

The above and other objects, features and advantages of the invention, as defined in the following claims, appear from the following, more detailed description of a preferred embodiment, which is illustrated in the accompanying drawings.

Fig. 1 is a schematic representation of a partial page of stored text to be indicated, edited and printed on a sheet.

Fig. 2a is a schematic representation of an indication of a horizontal segment of the text shown in Fig. 1.

Fig. 2b is a schematic representation of an indication of another horizontal segment of the text in Fig. 1, which partially overlaps the first segment in Fig. 2a. Fig. 2c is a schematic representation of an indication of yet another horizontal segment of the text in Fig. 1, which partially overlaps the second segment in Fig. 2b.

Fig. 3 is a block diagram showing the overall device of the present invention.

Fig. H shows the arrangement included in the indication control logic block in FIG. 3 ".

Fig. 5 shows the arrangement included in the cursor logic block according to Fig. H.

Fig. 6 shows the arrangement included in the segmentation logic block according to Fig. H.

Fig. 7 shows the arrangement present in the shell logic block according to Fig. H.

Fig. 8 shows the arrangement included in the row move logic block in Fig. H.

Fig. 9 shows the arrangement included in the tab logic block in Figs.

To clarify the invention, the function will be described first.

Fig. 1 shows a partial text page. It is assumed that this text page is stored in a text buffer. The cursor, mode, dimension, and appropriate control codes are also stored in the text buffer along with the displayed alphanumeric characters and spaces. The dimension can be stored in the form of the location of the left and right margins in relation to a zero typing line position. The zero write line position is the leftmost pressure position on a pressure device that comes into use. The location of the cursor is the working point for editing purposes. The cursor has been displayed as the highlighted and underlined letter 'K§' in the word OF on the first line. This is just an example. In reality, it is just a selected character, generated by an "enlightenment" bit in the character bit group. For example, if eight bits form the character byte, seven bits can be used for the character itself and one for enlightenment in a well-known manner. The mode can be set by instructing the proportional character distribution and the standard character distribution of ten or twelve units, respectively. When the term proportional distribution is used hereinafter, it is intended to include step feed for proportionally or varying wide characters, spaces, etc. The term standard distribution is intended to include step feed for standard or equivalent wide characters, spaces, etc. utilized control codes can be many, e.g. carriage return, line end, tabulation, etc. 7800861-2 Another assumption that is made is that the text shown in Fig. 1 should finally be printed on a sheet after editing. If this text has a dimension width that exceeds the width of the display device that is being used, the display of the text for editing purposes must take place in segments. This means that the text must scroll horizontally.

For efficient use of the indicator, the indication of the first segment will start at the left edge of the indicator. Therefore, the left margin space between the left edge of the sheet and the left margin will not be indicated. This is illustrated in Fig. 2a, where the first of three indication segments is shown. Furthermore, it is assumed here that the text consists of proportionally distributed characters and spaces.

When deciding which segments to indicate, the lowest segment that contains the cursor is selected. Since "0" in OF in Fig. 1 is the cursor position and can be indicated in the first segment, this segment is indicated as shown in Fig. 2a. The segment widths are different for proportional and standard separation, and they are defined in step feed units. This will be described in more detail later.

Referring to Figs. 2a, 2b and 2c, the segments overlap to some extent. This overlap gives the operator a reference to text in adjacent segments. As soon as a segment is selected, the operation remains there until the cursor moves either to the right or left to a position that is outside the current segment. When the cursor moves to the left to the outside of the second segment, automatic segmentation takes place and the first segment is indicated. If the cursor is moved to the right and to the outside of the second segment, automatic segmentation takes place again and the third segment is indicated.

If - with reference to Fig. 2b in connection with Fig. 1 - the cursor should be "D" in DRAWING, it can be indicated in either the second or the third segment. In this case, the second segment is selected as illustrated in Fig. 2b. If the cursor were "a" on the second row in Fig. 1, it can only be indicated in the third segment as shown in Fig. 2c.

With renewed reference to Figs. 2a, 2b and 2c, a scale row containing abbreviated step feed numbers and points, tab marks and a right margin rectangle is shown. The arrangement and technique for creating this line will be more clearly illustrated later in the description. Here it should only be important to note that the beginning of the scale indication corresponds to the left margin of the sheet to be printed. For example, if Fig. 1 represents a printed sheet with a left margin (LM) of twenty step feed units to the right of the left edge, the indicated scale begins with "2." This gives the operator a visual indication of the position of the indicated segment relative to the side or the sheet to be finally printed.

With further reference to Fig. 2c, a part of the character "H" is shown dashed near the left edge. This will not be indicated. Instead, a space I is filled, and the first character indicated on the line becomes the character "E" in the position shown. This is explained in more detail later.

Fig. 3 of the drawings is a block diagram generally illustrating the entire device of the present invention. Particular details in some of the components of the device are given in connection with later figures. Data including codes representing the text shown in Fig. 1 are first extracted from or generated by the data input and form means 1. These means may be a keyboard, a data transmission line, etc. The data generated by the data input and form means 1 , includes character codes, space codes, control codes, mode and measurement codes, cursor codes, tab codes, etc. Each of these codes is fed via line 3 and stored in the text storage buffer 2. The storage locations in the buffer 2 are determined by the address indicator M6. The control codes from the means 1, e.g. the cursor, the text endpoint, etc., are also fed via line 5 and stored in text storage register block B. Register block Ä contains decoding, addressing and advancing means for effecting storage therein of these control codes.

The text storage buffer 2 can be an electronic dynamic equipotential register, a memory with constant access time, etc. Control codes, denoting left and right margin locations, and standard and proportional (PSM) separation modes are fed on line T and stored in output parameter register block 6. Register block 6 contains decoding, addressing and forwarding means for performing storage therein of these control codes. The reason why control codes are stored in register blocks h and 6 except in buffer 2 is that you want to ensure their availability in time, when they are needed in other parts of the device. The control codes stored in the output parameter register block 6 are fed on the line 9 to the character generator 8 and on the line 11 to the indication control logic 10.

The control codes stored in register block h are fed on line RS to logic 10. Line start location codes are fed on line 12 to line start register block 13 for storage therein. Register block 13 contains decoding, addressing and advancing means for effecting storage therein of the row start codes. x 7800861-2 The row start location codes are fed on line lä to the indication control logic 10.

If the data input and shaping means 1 is a keyboard connected to a printer with step feed and tab bar, there is an associated address pointer 15 for addressing the printer's carriage space and the step feed and tab bar (tab stop set) 16 during carriage movement. The address indicator 15 is used to store the tabs.

When a number of lines are to be indicated from text codes stored in the text storage buffer 2, the indication control logic 10 addresses the text storage buffer 2 on line 19. This is to locate the beginning of the line containing the cursor. Codes which form the cursor line are then output from the buffer 2 on the line 20 to the control logic 10. For each code read into the logic 10, addressing of the step feed latch memory (EOS) 21 takes place on the line 22. This means determining - in the case of a character - the step feed thereof depending on the separation mode entered on the line ll. The step feed for the character is output from EOS 21 on line 23 to control logic 10. Each character (and space) code that forms this line is then fed on line 29 and written into the line or intermediate buffer 2% at a location determined by the address pointer 25. Only character (and space) codes are stored in the buffer 2h.

The control of the direct memory access unit (DMA) 26 addresses the buffer 2h on the line 28. The DMA 26 controls the writing and later the output of characters in and from the intermediate buffer 2ü via the line 30. Also here no control codes or character codes with cursor bits "to" are stored in the buffer 2h during accumulation of character codes for text lines.

The DMA 26 control to cause the raw segment of the scale row to be indicated takes place on line 27 from the indication control logic 10. DMA 26 addresses scale image -ROS 31 on line 33. The scale image or line information, which consists of character and symbol codes, is then fed on line 32. .

This information is then passed on line 30 and stored in the buffer 2ü at locations addressed by the pointer 28. After the accumulation of codes for each row including the scale row, the DMA 26 codes are passed on the line 35 and stored in the new buffer 3h at locations determined by the address pointer 36.

After the output of the cursor character code from the text storage buffer 2 to the indication control logic 10, the new buffer cursor location goes via the line 38 and is stored in the cursor register 37. This identifies the cursor character code when input to the character generator 8 from the new buffer 3%. The result is an illuminated 7800861-2 sign on the ketode ray tube (CRT) hp screen. The marker register 37 is connected to the teek generator 8 via the line M0.

The address line 119 and the data line 123 are used to connect the line shift logic part of the indication control logic 10 to the new buffer 3h.

This is clearer in connection with Figs. R and 8.

With the first row segment, which contains the cursor stored in the new buffer 3%, the corresponding segment of subsequent rows to be indicated is sequentially determined by the indication control logic 10. DMA 26 in turn causes these segments to be entered in the new buffer 3%. After entering all the corresponding segments (of all rows to be indicated) in the new buffer 3%, the corresponding segment of the scale row is determined and entered in the new buffer. Other operations are performed on the scale bar, which are described in detail later.

The segments of the rows to be indicated have now been formed and stored in the new buffer 3ü. The character ~ (and scale bar symbol) codes forming these segments are now output on line 39 to the character generator 8. The characters are generated and fed on the line h1 to the video control circuit H2. Then they are fed on the line H3 to the display device kb. The device here may be a cathode ray tube (CRT), a gas panel, etc.

Fig. H of the drawings shows what is included in the indication control logic block 10 in Fig. 3. At the beginning of the operation, a register NS is set for the number of the current line via the line hö on the cursor line number. The output signal from register RS goes via line ÄT to register multiplex circuit H5, which addresses row start register l3 (Fig. 3) on line R9 to locate the beginning of the cursor line. The result on line lh goes to the counter 50 for the position of the current text. This is used to address the text storage buffer 2 on line 19 to locate the cursor row. The output value from the text storage buffer 2 is the first data code of the cursor line (characters, etc.), and this code is fed on the line 20 to the register 51 for current data. This code is in turn fed to the line 52 of the decoder 53 to determine if it is a line end code, tab code, reverse feed code, text character or space. This code is also fed on the line 22 to the step feed EOS 21. The step feed for the code is - if it is a reverse feed or a text character or a space - fed on the line 23 to the character feed register 5h.

The step feed is input to the adder 55 on the line 56. The output signal from the adder 55 goes to the register 57 for the current total ateg supply along the line 58. A reverse feed code on the line 22 gives rise to a subtraction operation in the adder 55. The register ST stores it current sum of step feed units from the left margin. This operation continues for each character, space, and reverse feed code until either a tab code or a line end code appears on line 20.

It should be noted that the adder 55 consists of sequential logic rather than combination logic. Thus, the output signal on line 58 is not updated until it is affected by an input signal on line 502 from AND circuit 132.

The inputs to the AND circuit 129 are adder clock pulses from the clock 500 on line 503 and other signals on line 128. Until an updated input signal is applied to line 58, adder 55 will accumulate step feed sums as the characters are fed on line 20.

The code output signal from the register S1 for current data is also supplied on line 67 to AND circuit 68. The second input signal to circuit 68 comes on line 32 from AND circuit 33. The inputs to AND circuit 33 are "non-reverse step" on line 69 , "non-tabulation" on line 125 and "non-line end" on line 126. When an active signal is fed on line 32, the code appearing on line 67 is fed on line 127 to the output data storage register 70. From the register 70 the code is fed on the line 29 and is written in the intermediate buffer 2b This writing takes place in the buffer 2ü after the supply of both a "non-reverse feed" signal on the line 69 and a write data signal on the line 72 to the AND circuit 73. The output signal from the AND circuit 73 goes via line the input Yh to the output data memory TO to effect the input of the code stored in the memory 70 on the line 29. "The location of the cursor is stored in the cursor register 37 (Fig. 3). This location value is output on line 61 to the comparator unit 62. In unit 62 a comparison is made with the current code position, which is addressed in the buffer 2. The value of the current code position is stored in the counter 50, which is stepped by a signal on line 80 for each code is addressed on line 19. The value stored in counter 50 is fed on line 63 to unit 62. When similarity occurs, indicating that the values on lines 61 and 63 match, an output signal appears on line 6Ä. This signal is then fed to the fill line 65 to cause the cursor step feed register 66 to be filled with the step feed value stored in register 57. This value includes the value of the cursor character. Register 57 is connected to register 66 by line 60. The value in register 66 is then fed on line 91 to the segmentation logic block 90. The logic block 90 is used to determine the segment including the cursor to be indicated. This will be described in more detail 7800861-2 in detail in connection with Fig. 6.

The output signal from the unit 62 also goes on line 81 to AND circuit 82. The second input signal to AND circuit 82 comes on line 83 from intermediate buffer pointer counter 78. Counter 78 is a reset upward counter. The counter 78 is set via the line 79 to the starting location of the intermediate buffer 2h, when the beginning of the line is triggered from the buffer 2. The counter 78 is incremented for each character code by a signal which is applied to either the write tab data line 109 or the text line 75. is counted in the counter 78, at each particular time the address of the character entered in the buffer 2ü. The lines 75 and 109 are connected to the OR circuit 76, which in turn is connected to the counter 78 via the upward line 77.

The appearance of a signal on the uplink 77 for a character code appearing on the line 20 results. in that the counter 78 advances by one. The reverse feed code, which appears on line 20, results in the counter 78 being back-stepped with a result of an upward signal being fed through the reverse feed line 113.

After a comparison signal appears on line 81, the sum in counter 78 will be fed via AND gate circuit 82 and passed along line Bh to marker logic block 85. The function and construction of block 85 will be described more clearly in connection with Fig. 5. Now it is sufficient to art other inputs to block 85 arrive via lines 89 and 93.

An up signal appears on line 89, when there is both an indication on line 87 that the end of the current line has been stored in the buffer 2h and an indication on line 86 that the operation includes the marker line. These signals are applied to the AND circuit 88. The input current on line 93 to block 85 comes from the output of block 90 via line 92. The output of block 85 goes via line 38.

When a tab code appears on line 20, it is stored in register 51. It then goes via line 52 to decoder 53 for decoding. The tab code is also fed on line 22 to the lock-out memory 21. No step feed for a tab is stored in the memory 21. Therefore, a zero output signal goes via line 23 to the character step feed register 58. A zero also goes in turn on line 56 to the adder reindeer 55. The value remains the same in the adder 55 and is fed on line 58 to the "current total step feed" circuit 57 as above. The output signal therefrom goes on line 111 to AND circuit 506. The second input signal to AND circuit 506 is the tabulation on line 50k from the decoder 53. The output signal from AND circuit 506 goes on line 507 to the tab logic 78. The tab logic 110 is described in more detail in connection with Fig. 9. However, logic 110 addresses the tab stop set shown in Fig. 3 on line 18 and retrieves data on line 17. This refers to determining the sum of step feeders for the next tab setting. Once this sum of units has been determined, an output signal from the tab logic 110 on line III goes to the adder 55. It should again be observed that the tabs are not stored in the buffer 2b. The step feed unit sum is fed on line l11 to the adder 55. The adder 55 is stepped for the number of intervals of a step feed unit to be fed into the buffer 2ü for the tab code reading. The contents of the adder 55 are then fed on line 58 to register 57. At this time, the tab logic 110 causes signals to be fed on the write tab data line 109 to the OR circuit 76 and then on line 77 to advance the intermediate buffer pointer 78 to the desired number of characters.

Each time the buffer buffer pointer 78 is advanced, the logic 110 outputs a space code on line 12h to the output data memory 70. The buffer buffer pointer 78 is reset via line 25 at a point corresponding to the next set tab for writing additional characters which form the line.

The output signal from the segmentation logic block 90 on line 92 goes via line 9% to the head logic block 95. Other inputs to the head logic block {95 refer to the locations of the left and right margins on lines 96 and 97. É These are derived from line ll in Fig. 3. Another input signal to the logic block 95 comes from the output data memory 70 on the line 98. Furthermore, the block 95 has communication in two directions via lines 17 and 15 with the tab stop set 16 in Fig. 3. An output signal from the logic logic 95 goes via the line 99 to the intermediate buffer pointer 78. Remaining output signals from the logic 95 go via lines 100, 101 and 102 to stop, write and read registers 103, 10k and 105. The output signals from the stop, write and lock registers 103-105 go via lines 106, 107 and 108 to DMA 26. Block 95 will be discussed in more detail in connection with Fig. 7. The occurrence of a reverse feed code results in an upward signal being fed on line 113 to the intermediate buffer pointer counter 78. if the pointer is reversed 25. The next incoming character code on line 29 to the buffer 2h is then overwritten by the character code before the reverse feed code. Likewise, the current total step feed sum in register 57 is regulated depending on the reading of step feed ROS 21 for the reverse feed code. 7800861-2 ll The output signal from the segmentation logic block 90 on the line 92 also goes on the line llh to the row shift logic block 115. Another input signal to the logic 115 goes on the line 116 from the output data memory TO. An output signal from the logic 115 goes via the line 117 to the counter TB. The logic 115 is also connected to the HOS 21 via lines 22 and 23. Another input signal to the logic 115 is "current line number" on the line 118. Other outputs from the line move logic go via the address line 119 and the data line 123 to the new buffer 3% and on lines 120, 121, 122 to stop, write and read registers 103, 10h and 105. It should be noted here that DMA 26 is not used in the transfer of data on line 123 to new buffer Bh. Block 115 is described in more detail with reference to Fig. 8.

Fig. 5 of the drawings shows what is included in marker logic block 85 according to Fig. H. The input signals to the marker logic are: "marker row ready" on line 89, "marker address in intermediate buffer" on line 8h and "starting point for current segment from the left margin" on line 9ü. The aforementioned signal on line öü forms an input signal to the cursor pointer register 60. The signal on line 9h is an input signal to an adder 131. Referring to Fig. Ä, this signal is obtained from the segmentation logic block 90. The value stored in the intermediate buffer start address register 130 is a constant , which corresponds to the value of the first character memory location in the buffer 2h. This value can be representative of the location of the left margin setting. This value is fed to the adder 131 on the line 132 to be summed with the "start of the current segment from the left margin" value, which comes on the line 9ü. The sum of the values of lines 9k and 132 is subtracted by the subtractor 133 from the value stored in the cursor pointer register 60. The value thus obtained is fed on the line 13h to the cursor shift register 135. The value contained in the cursor shift register is the value from the beginning of the segment, which is processed.

This value is then fed on line 136 to AND circuit 137. The second input signal to AND circuit 137 passes through line 89 and indicates that the cursor * line has been completed. The value in register 135 is then fed on line 38 and stored in the marker register 37 (Fig. 3).

Next, reference is made to Fig. 6, which illustrates what is included in the segmentation logic block 90 according to Fig. Ä. It should be pointed out that the segmentation logic has an input signal on line 91. This input signal is the value of the number of step feed units from the left margin to the cursor position. The value is input to the divider 1h0 and divided by a constant, which is stored and kept in the constant register lül. The kbnstant is fed to the divider 1hO on the line 78001861-2 12 lh2. Referring to the constant table in the upper right corner of the drawing, the value of the constant C1 is five step feed units. This constant is the step feed value for spaces, symbols and all numbers. In addition, it is the value of shell symbols, when the operations apply to proportional separation.

Furthermore, this value is the average number of step feed units for each character in proportional separation. The divider lb0 is designed to output only whole numbers. In practice, every residue is left unattended. The integer output signal from the divider lü0 is fed on the line lü3 to the cursor value register lhh. Given the proportional separation, this integer would be an equivalent number of 5 step feed characters from the left margin. For standard separation, this integer would be the exact number of characters from the left margin.

The output signal from the cursor value register lhh goes on line lh5 to the comparator units lh6, lhï, lhß and lh9. Other inputs to the units lh6-lh9 come from the constant registers C2-C9 with the reference numerals 150-157, when these are activated by the constant selector gate circuits 159-162. Registers 150-157 contain the step feed unit value shown in the table in the upper right corner of the drawing. These values are fed to constant selector gates 159-162. These gates are arranged to pass the value contained in the constant registers 150, 152, 15h and 156 to comparator units lü6-lh9, when the function relates to standard separation. When the operation is proportional separation (PSM), a signal is fed on line 158 to these gates to cause the value contained in registers 151, 153, 155 and 157 to be fed to the comparator units lh6-lh9.

For example, as for the constant selector gate 159, it may consist of AND gate circuits for each register bit with an input signal from each bit in register 150 and an inverted input signal from line 158. The outputs from these register AND gate circuits go to additional OR gate circuits and then to the comparator unit. lh6. Other inputs to these additional OR gates would come from other AND gates with inputs from line 158 and register 151.

The comparison in the comparator units lh6-lÄ9 takes place with the cursor character value from register lhh on line lh5 and the selected set of registers 150-157.

* With renewed reference to the comparator unit lh6, if the character sum fed on line 1ü5 is less than or equal to the constant value from the selected one of registers 150 and l51, an output signal is fed along the S1 line 163. If the character value on line lb5 is greater than the input constant value, the output signal from the comparator lü6 on the line l6ü goes to the AND gate 165. 7800861-2 13 If an output signal comes from the comparator lh6 on the S1 line 163, it goes to the OR circuit 177. The output signal from the circuit 177 is a "new first segment "(N81) signal on line 178 to OR circuit 179. It should be noted that the operation after the power supply is turned on begins in the first segment. If a signal is fed on line 178, the function remains in segment 1. the output of the ELLsrMn etch 179 goes along the "bis o" (Bo) line 189 to the "new segment number" register 190. This register has two bits for storage. of the segment number in binary form.

Upon return to the AND circuit 165, an output signal will be applied to the S12 line 167, when the cursor character care on the line 1h5 is less than or equal to the input constant from the selected one of the constant registers C3 and C7.

An output signal on the S12 line 167 is supplied to the AND gates 199 and 201.

Whether an output signal appears on line 200 or line 202 depends on the up or down inputs to AND circuits 199 and 201 together with the LS1 line 196 and the LS2 line 197. The LS1 and LS2 inputs originate from the decoder 195. If taken, that the function originally applied to the first segment, the first segment number would be stored in register 193 and an output signal would appear on the LSI line 196. The supply of the last segment number from register 193 to the decoder 195 takes place on line 19k. With the LS1 signal active on line 196 and the S12 signal active on line 167, an active signal is supplied via the AND circuit 199, via the line 200, through the OR circuit 177 and via the N81 line 178. This would result in a single was fed via the BO line 180 to the "new segment number" register 190. In this case, the operation remains in the first segment. Since the previously selected segment was the first, the output signal from register 190 goes via line 191 to register 193, and the output signal from decoder 195 goes via LS1 line 196. The output signal from register 193 goes via line 19% to decoder 195 each time a new picture generated for indication. When a new picture is to be generated, a new picture signal is fed on the line 192. What has been said above applies to output signals on either of the lines S1 and S12 with the operation remaining in the first segment.

As for standard separation, the cursor, if present between the left margin, which has a constant value of zero, and C2, which has a constant value 62, will be placed exclusively in the first segment. If the cursor is located between C2 and G3, it can be either the first or the second segment. As pointed out above, segmentation does not occur unless the cursor is moved and allowed to enter one of the segments. For a cursor position between 0 and 83 step feed units from the left margin, the working segment will therefore be the first segment. If the cursor is moved to the bra, it will be located exclusively in the second segment. If the cursor is moved to 87, it can be located in either the second or third segment.

In this case, the function will take place in the lowest segment, which is the second segment. Although not specifically pointed out, it has been assumed above that forward feed takes place. The rules are the same for reverse step feeding, when the cursor is reverse step.

The output signal from the read-out memory 211 goes via the line 212 to the register 213. For the first segment the output signal becomes zero, for the second segment it becomes 62 and for the third segment 86. This presupposes function with standard separation. Corresponding values are shown in the constant table for proportional separation. The contents of register 213 are fed on line 92 to the cursor logic block 85, the shell logic block 95 and the redshift logic block 115 in Fig. H. from the constant registers C3 and C7, an output signal is supplied via line 168 to the OCK circuit 170. An "up" signal on line S2 line 171 does not appear until an output signal exists on line 169 from comparator 1h8. The output signal on line 169 from comparator 1h8 indicates that the cursor character value from register lüh is less than or equal to the selected constant stored or stored in registers lšü and 155. When an output signal appears on line S2 line 171, it is fed to OR- - gate circuit 182. This indicates that the operation should be exclusively in the second segment. The output of the OR gate circuit 182 is a "new second segment" (NS2) signal, which is fed on line 183 to the OR circuit_lßh. The output of the OR circuit lßh goes on the bit-1 (B1) line 185 to the "new segment number" register 190. If the previous operation took place in the first segment, the output of the decoder 195 would be on the KLS1 line 196. This is due to on the up-output signal on the BO line 180, which will be described later.

When the operation begins in the second segment, the output signal goes from the register 190 on the line 191 to the register 193, which has the task of preserving the last segment number. This occurs when a new image signal is applied to line 192. The new image signal on line 192 occurs due to the fact that a new image must be generated for the second segment. The second segment number from register 193 is fed on line 19A to decoder 195.

For the second segment, the output signal comes from the decoder 195 on the line LS2 197 and goes to the AND gates 201 and 203. There are no outputs from the AND circuits 201 and 203, since the inputs S12 and S23 are passive.

If the output signal from comparator lh8 indicates that the cursor character value lhh on line lh5 is greater than one of the constants Ch and C8 selected by gate circuit 161, an output signal on line 172 is fed to AND gate gate 17%. For an "up" -S 23 output from the AND circuit 17h on line 175, there must be an "up" output on line 173 from comparator 1b9. This occurs when the cursor character value on lines 1ü5 is less than or equal to the selected constant from registers 156 and 157. The outputs from registers 156 and 157 are supplied to the constant selector gate circuit 162. When an output signal occurs on line S23 ~ 1 line 175, it is supplied to the two AND gate circuits 203 and 205. Since the last segment was the second segment and an output signal appeared from the decoder 195 on the LSZ line 197, the AND gate 203 is the applicable gate. The output signal from the AND circuit 203 goes on line 20% to the OR gate circuit 182. The output signal from the OR circuit 182 goes on the NS2 or "new second segment" line 183 to the OR circuit 18h. The output signal from the OR circuit 161 »is on the bit line 185 for operation to continue in the second segment.

When the cursor moves further to the right, an output signal finally appears on the S3 line 176. This is fed to the OR circuit 186. The output signal from the OR circuit 186 goes via the "new third segment" (N83) lines 187 and 188 to OR circuits 18k and 179. The output signals from the OR circuits l8h and 179 so via lines 185 and 180 to register 190. Register 190 is a two bit register and has four states (00, 01, 10 and 11). The 00 state is an invalid state (or not used). The up-out signals on lines 180 and 185 cause a state to be stored in register 190, which is representative of the third segment. When operation begins in the third segment, an output signal is present on the LS3 line 198 from the decoder 195, and this output signal is supplied to the 0CH circuit 205.

If the cursor is fed back to a point where it may be present in either segment 2 or 3, a signal on the S23 line 175 is fed to the AND circuits 203 and 205. The other input signal to the AND circuit 203 is passive. The output signal from the AND circuit 205 is "up" and goes on line 206 to the OR circuit 186. The output signal from the OR circuit 186 goes on the N33 lines 187 and 188 to the OR circuits 18k and 179. The one outputs from the OR circuit circuits 179 and 18k are fed 7800861-26 16 on lines 180 and 185 to actually input a third into register 190. This means that register 190 is set to one of the states described above. The function remains in the third segment. From the above it appears that after either forward or backward stepping of the cursor, no segmentation takes place until the cursor crosses a segment in either direction.

Reference is made to Fig. 7, which illustrates what is included in scale logic block 95 according to Fig. H. This arrangement is first used for reading the scale image starting at the left margin from the scale image readout memory 31 in Fig. 3 and writing it in the intermediate buffer 2%. Thereafter, the arrangement causes the correct segment of the channel image to be read out from the intermediate buffer and written in the new buffer 3Ä. To begin with, the left margin location, expressed in a character value, is entered via line 96 in the adder 232. To this value is added a value stored in the scale image display register 230. The value stored in the register 230 is the location which is addressed in the scale image read-out memory 31. This place value can be assumed to be a zero. The output signal from the scale image register 230 is fed on line 231 to adder 232. The sum output signal from adder 232 is fed on line 233 to AND circuit 236. This determines the point in scale image ROS 31 where reading by DMA 26 is to begin. The second input signal to the AND circuit 236 comes via the shift selector line 2h9. When the input signal on line 2h9 is "up", the sum from the adder 232 via line 102 is fed to DMA 26. Before any signal is fed on line 2h9, the stop point in ROS 31 must be determined and the write point in intermediate buffer 2h determined. After all points have been determined, the reading of the scale image will begin at a point corresponding to the left margin, and the rest of the scale image will be written in the intermediate buffer 2h.

Next, it must be determined where somewhere in the intermediate buffer 2h the beginning of the scaling line is to be written. Block 270 is a register which contains a constant, which is the initial address of the intermediate buffer. This can be assumed to be zero. This address is fed on line 275 to AND circuit 239. When a move selection signal is fed on line 2A9, the initial address in intermediate buffer 2h will be output on line 101 to DMA 26. This controls the writing of the correct beginning of the scale image in the intermediate buffer.

The point at which the reading of ROS 31 is to stop is determined by the value stored in constant register 2ü7. This value is input to the AND circuit Zhh on line 263. There are now input signals to gate circuits 236, 239 and 2üh. An input signal is now fed on the moving selection line 2h9, and output signals are fed via the lines 102, 101 and 100 to DMA 26. The scale image is now output from ROS 31 and written in the buffer 2h. 7800861-2 17 The shell logic is controlled by a sequencing state counter 616, which receives an input signal via line 615 from the OR circuit 61k. This input signal controls the rake by causing it to switch to the next state. The DMA - ready line 600 is connected to the OR circuit 6lh and controls the transition between states 0.0 and 0.1 and states 1.1 and 0.0. See the sequence still table in the upper right corner. The DMA-ready line 600 receives its signal from the DMA 26, which signal has the task of indicating the completion of a read and write operation. The output signals from the sequence state counter 616 on the CLK1 line 605 and the CLK2 line 606 are supplied to the EXELLER circuit 607. The output signal from the EXELLER circuit 607 goes via the line 608 to the inverter 609. The output signal from the inverter 609 appears on the shift selection line 2h9. The CLK2 line 606 also goes to the inverter 610. The output signal from the inverter 610 goes via the line 611 to the AND circuit 612. The other input signal to the AND circuit 612 goes via the CLK1 line 605. The output signal from the AND circuit 612 goes via the line 613. Other inputs to the OR circuit 61% are on "selection RM" (right ~ margin1) ~ line 617, and an output signal is on line 618 from comparator 250. The signal on line 618 indicates the completion of the tab setting operation and controls the transition between states 0.1 and 1.1. The "Selection RM" line 617 controls the transition from state 0.1 to state 1.0.

After the scale image has been written in the intermediate buffer 2h, a right-margin code is written in this buffer. After the scale is placed in the intermediate buffer 2h, an "up" signal is fed on the line ZÄ5 to the AND circuit 235. A right-margin code generated by the code generator 259 is fed on the line 2h6 to the AND circuit 235.

This code is then fed on line 260 and entered into register 258 for entry into buffer 2h. The writing position in the buffer 2h must be determined for the right margin. The right margin space is input on line 97 to the subtractor 261. From here, the left margin space is subtracted, which is input on line 96.

The output signal from the subtractor 261 goes on line 27h to the adder 262.

This output signal is the measured value. The second input to the adder 262 is a constant on line 71 from the "initial address in the buffer" 270. This constant can be assumed to be zero. The sum output signal from adder 262 is supplied on line 602 to pointer gate unit 601. This unit controls the address output on line 60k to "current data pointer" counter 257. Counter 257 is set at the address of the location where the right margin symbol is desired in intermediate buffer 2ü . The counter 257 controls the addressing of the buffer 2h via line 99- 7800861-2 - 18 After the right margin symbol has been output to the intermediate buffer 2ü, a scan operation starts for setting the tabs over the correct scale symbols, which are read from ROS 31. The counter 257 is set via line 60k on the address of the beginning of the buffer 2h at the start of the scan operation. The output signal of the gate circuit 601 via line 60ü is determined by the output signal from the initial address in the intermediate buffer register 270 via line 272. This input signal is used by the pointer gate unit 601, since the input signal on selector RM line 603 is passive.

As a character code in buffer 2Ä is read, the pointer 257 steps to the next character code location. This increment is caused by signals fed on line 253. In connection with the increment of pointer 257, the tab address selector 255 for addressing the tab stop set 16 via the line 14 is incremented. When a set tab is addressed, an output signal appears on line 17. This output signal is used to activate the tab bit in the character or symbol code which is addressed and loaded into the "current intermediate buffer data" register 258.

The shell symbol or character - including the previously mentioned tab bit - is then fed on line 98 and written eat into the buffer 2h. This operation continues until the end of the tab stop set 16 is reached. The value representative of this location is a constant and is stored in the "tab end location" register 2ü8. The value is fed on line 2h9 to comparator 250. The second input signal to this comparator comes on line 256 from the tab address selector 255. The output signal from comparator 250 goes via line 251 to inverter 252 and then on lines 253 and 25k. Until At the end of set 16, "up" outputs are supplied via lines 253 and 25%. When the end of the set 16 is reached, the selector 255 and the pointer 257 are no longer stepped, the scale row stored in the buffer 2Ä has now been formed by inserting tab settings and the right margin. í At this time, the sequence state counter has changed to l, l.

In order to determine the segment of the shaped shell row to be entered in the new buffer, the current-segment-initial value of line 9h - is fed to the adder 268. The value is added to the value of the initial address in the intermediate buffer, which is stored. in the constant register 270. The output signal from the register 270 is fed to the adder 268 on the line 2h6. The sum output signal from the adder 268 is supplied on the line 269 to the AND circuit 236. This determines the starting point for a reading of the scale line in the intermediate buffer 2ü in order to transfer a segment of the scale line to the new buffer 3ü. The stop point for reading in the intermediate buffer 2h is determined by the output signal from the adder 2ü2. To this adder the sum output signal is fed from the adder 268 on the line 23k. The second input signal to the adder 2h2 is a segment length constant, stored in constant registers 2b0. This is fed on the Qhl line. The constant stored in register 2h0 is large enough to cover each segment length.

The sum output signal from the adder 2h2 is fed on the line 2h3 to the AND circuit 2hh. This determines the read stop point in the intermediate buffer 2%, which is to be read by DMA 26.

The write point for writing the scale row segment in the new buffer 3h is determined by the constant, which is stored in the scale row address in the new buffer register 237. For practical reasons, this is considered. be zero. Thus, when the AND circuits 236, 239 and 2bh have input signals denoting the read and stop points in the buffer 2h as well as the write point in the new buffer 3%, a move selection signal appears on the line 2h9. This results in output signals being fed on the read line 102, the write line l01 and the stop line 100 to DMA 26. The correct segment of the scaling line is now entered in the new buffer 3%.

Next, reference is made to Fig. 8, where the circuits included in the row-moving logic block 115 in Fig. Ä are illustrated. In general, the purpose of this block is to read out a blessing stored in the intermediate buffer 2%, and to load it in a suitable manner. place in the new buffer Sh. If the segment being processed is to the right of the first segment and the function is proportional separation (PSM), there is a prospect that a character will overlap the left edge of the segment. In practice, a partial sign will be present at the beginning of the segment.

In this case, a space will be filled in at the beginning of the segment for the partial character. This space filler is located in the new buffer and up to the point of the first full character in the segment.

After entering and forming a row of character codes in the intermediate buffer 2h, the reading of the row begins with the first character code. This line is the current line. The first character code location is determined by the "current buffer location" counter 303, which is reset on line 30% at the beginning of the operation.

This controls the address pointer 117. When the pointer 117 addresses a character code, the addressed code on line 111 is output to the "current data" register 300. The output signal from register 300 goes on line 301 to the comparator 302.

This output signal is also fed on the line 22 to the step feed ROS 21 for determining the step feed. The step input output from ROS 21 goes via line 23 to the "current character step feed" register 311. The output signal from register 311 goes on line 312 to adder 313. The other input signal to adder 7800861-2 203 comes on line 316 from the "current total step night register 315". If the first character has just been read from the buffer 2h, a zero appears on the line 316. The sum in the adder 316 is then delivered on the line 3lh for storage in the register 315. The register 315 will thus contain the step feed unit value from the beginning of the buffer 2Ä. It should be noted that the adder 313 is similar to the adder 55 in Fig. H.: This means that it is sequential rather than combining in nature. The output signal on line 3lü is not updated until it is affected by an input signal 8 on line 550 from AND circuit 551. The inputs to AND circuit 551 are the adder clock signal on line 501 and the character change on line 128. The adder clock input on line 501 comes from adder clock 500 in Fig. Ä. Until an updated input signal appears on line 550, there is no output signal on line 3lh. Adder 313 continues to accumulate step feed values as character codes are fed on line 116.

The output signal from register 315 is fed on line 317 to divider 318, where it is divided by the constant stored in constant register 32k.

The output signal from register 32k is supplied to line 325. The constant current C1, which is stored in register 32h, is five step supply units. The whole number output signal from the divider 318 goes via line 319 to the "current total character value" register 320. A character value is stored in register 320. The whole number stored in register 320 is fed via line 326 to the comparator unit 327. The other input the signal to the comparator unit 327 is "current segment initial value" on line llh. When there is a correspondence between the value of characters read from the intermediate buffer 2ü and the value of characters corresponding to the "current segment starting point", an output signal goes via line 328 to AND circuits 361, 360 and 353. The output of the comparator 327 is also fed via line 329 to inverter 330. The output signal from inverter 330 goes via line 331, which causes the address indicator 117 to stop incremental. The needle ll? now addresses the first character to be transferred to the new buffer. The address of the pointer 117 is supplied on line 35h to AND circuit 361 and then on line 122 to DMA 26. The address of pointer 117 is also supplied on line 355 to adder 358. The second input signal to adder 358 is the length of the row memory in new buffer 3h. This is fed on line 357. The sum output signal from adder 358 on line 359 is the address in the intermediate buffer where locking is to cease. A segment has now been determined. The sum on line 359 goes to AND gate 360 and then on line 120 to DMA 26. The remainder from divider 318 goes via line 321 to subtractor 322. The remainder is subtracted from constant C1, which is stored in register 32h, and fed on line 323. The output of subtractor 322 is the width of step subunits for a subset near the left of the segment. edge. The number of step feed units in the form of an output signal from the subtractor 322 is fed on line 332 to the "number of special gaps of a step feed unit for filling purposes" register 333. This number of special gaps is then fed on line 33% to "step feed unit gap value". counter 335. The output signal from counter 335 is supplied on line 336 to inverter 337. In step with each output signal from counter 335 an "up" signal is supplied on line 338 for storing a code in "space of a step feed unit" code register 3ül. The output signal from the inverter 337 is also fed on the line 339 to step back the counter 335. When this counter has been back-stepped to zero, the filling of register 3hl ceases. At this time, each space code of a step feed unit has been locked through the OR circuit 310 and via the line 123 for storage in the new buffer 3h. An "up" output signal on line 338 is also fed on line 3ü0 for stepping of the new buffer pointer 3h2. The new indicator 3h2 addresses the new buffer 3h on line ll9. A space filling has now taken place in the new buffer of 3% for the partial sign at the beginning of the segment.

The initial position of the pointer 3Ä2 for addressing the beginning of the line memory in the new buffer 3h was determined by an input signal concerning the "current line number" on the line 118. This signal on the line 118 is supplied to the multiplex circuit 3h3.

The output signal from the circuit 3h3 goes via the line 3üh to the row start pointer to the new buffer register 3h5. The output signal from register 3ü5 goes via line 3h6 to the "current line start" register 3b7. The output signal from register 3h7 goes via line 3h8 to the new pointer 3h2. The output signal from register 3hT also goes on line 3ü9 to adder 350. The second input signal to adder 350 goes via line 351 from register 333. The sum output signal from adder 350 goes on line 352 to AND circuit 353. The output signal from this AND circuit goes via line 121 to DMA 26. This determines the point at which DMA 26 should start writing the segment in the new buffer 3%. The writing of the segment begins with the first full character.

After a line end code is read and fed on line 116 to the current data unit 300, it is output on line 301 to comparator 302. The second input to comparator 302 is a line end code from register 306 on line 7800861-2 22 305. After a comparison an output signal is fed on line 307 to the line end code register 308. The line end code is then fed on line 309 to the OR circuit 310. The output signal from the OR circuit 310 is fed on line 123 to the new buffer 3h. This fulfills two functions. The first function is that if no text is present in the segment, the storage of a line end code results in the indication of an empty line. The second is that if a segment is not complete due to line breaks before the end of the segment, the operation becomes complete.

Reference is made to Fig. 9, where the arrangement in the tab logic block 110, Fig. Ä, is illustrated. During the readout of the character and control codes from the text storage buffer 2, a tab code can be read. This is not intended to be entered in the intermediate buffer Zh. Instead, a number of spaces, equivalent to the tabulation length, should be stored in the intermediate buffer. When a tab is read, the sum in the "current total step feed" register 57 (Fig. Ä) will include the sum of all characters and spaces including the tab. The tab length is obtained from the tab stop set 16. The value in register 57 is fed on line 507 to divider 385. Another input to divider 385 is a constant on line 387 from register 386. If no residue is present, the register step feed unit value on line 385 is fed to excess step feed register 389. The value in register 389 is fed on line 390 to subtractor 392, where it is subtracted from the constant 5 stored in register 386.

The output signal from register 386 to subtractor 392 goes on line 391.

The output signal from the subtractor 392 is then fed on the line 393 to the counter 39k. The value entered in the counter 39h is the number of intervals of a step feed unit, which in addition to normal intervals are needed to fill up the intermediate buffer 2h for the tabulation. This value is fed to the comparator unit 396 on the line 395. The "space of a step feed unit" values are output on the line 397, and the counter 39k is back-stepped as long as the signal from the comparator 396 is not zero.

The comparator signal on line 398 and the "step feed unit" value are fed via line 399 to the "step feed unit spacer code" encoder H00. Each time the counter 39k is reverse stepped, a space of one step supply unit is output to the AND circuit ü02. The codes output from the encoder H00 are supplied on the line H01 to the AND circuit ü02. After the application of a write tab data signal on the line h22 (which is equivalent to the line Th in Fig. Ä), "a step feed unit space" codes are carried on the line 12k to the output data memory TO.

The total current step feed for characters and spaces on line 507 is fed to divider 385 and divided by the constant 5, which is stored 7800861-2 23 in register 386. The integer output is fed on line B23 to the "current character value" register hOh. The value stored in register NOÄ is fed on line hO5 to the tab address value indicator h06. This addresses the tab stop set 116 via line 18. This address is the point where normal intervals should begin to be output to the buffer 2h. Another output signal from the register hoh is via the line ÄO7 to the subtractor H09. The remaining input signal to the subtractor h09 comes via the line hO8 from the tab address value indicator RO6.

The output signal from the pointer H06 goes via the line 18 for addressing the tab stop set 16. This is done to determine the location of the next set tab to determine the number of spaces to be stored in the intermediate buffer.

An output signal is supplied from the tab stop set 16 via line 17 to the inverter H12. The output signal from the inverter hl2 goes on the line H13 for advancing the tab address value MO6. The difference between the current character value HOÄ and the tab address value H06 is thus the value of the number of spaces to be written in the buffer 2ü for a tab. This is calculated by the subtractor h09. The input signals to the subtractor H09 come on the line ÄOT and the line h09. The output signal from the tab stop set 16 also goes via the line h11 to the subtractor H09. The output signal from the subtractor goes via the line ülü to the tab value register ül5. The output signal from register E15 goes on line H16 to the comparator BZÄ. In the comparator hâü a comparison is made with zero. The output signal from the comparator Äâh is supplied on line H17. When the output signal represents a one, an output signal goes via line h19 to the space register h20. The register h20 is filled with a space character. The output signal from register h20 goes on line H21 to AND circuit h02. After a write tab data signal is fed on line H22, the space character on line 12k is output to the output data memory. This process continues until the tab value in hl5 is equal to zero. At this point, the correct number of spaces has been output to the intermediate buffer Eb.

In summary, a device has been provided which performs automatic segmentation of both lines of text and a line of scales to be indicated. The segmentation depends on the location of a cursor in one of the lines of text. The device is designed to handle both standard wide and proportionally wide characters. Each row starting from the row containing the cursor is entered sequentially into a row buffer. After entering the first line, select a segment that contains the cursor. This segment is entered in a new buffer for indication. Thereafter, the corresponding segment in each subsequent row including the scale row is determined and is entered into the new buffer for indication. After repositioning the cursor

Claims (3)

7800861-2 21+ outside either the left or right edge of the display, the above operation is repeated starting from the entry of the cursor row in the row buffer. When a partial character appears near the left edge of a segment, space is filled in for indication. Thus, each line is indicated based on whole characters. Patent claims 1. l. Indicating device for successively indicating a text page by means of a number of segments in the horizontal direction on an indication screen, which text page comprises a number of rows of characters, symbols, etc., arranged between a right margin and a left margin, characterized by a segmentation block (90) which receives on an input channel (91) information about the position of a cursor in relation to the left margin, which marker defines a working point in the text page and which segmentation block comprises circuits for defining the boundaries of the various segments, and indicating within which segment the cursor appears and transfer circuits (2Ä, 26, 115) for transferring from a text memory (2) such text segment, where the cursor appears, to an output buffer memory (Sh) for the indication screen (Oh) to indicate said text segment, wherein the transmission circuits (115) comprise means (322, 333, Sh1) for preventing indication of parts of a character at the edge a v a segment. Indicating device according to claim 1, characterized in that the transfer circuits comprise an intermediate buffer (2h) for storing a text line of the text page to be segmented, text lines being transferred in succession from the text memory (2) to the intermediate buffer (2ü) with starting point from the line, which has said marker. Indicating device according to claims 1 and 2, characterized by an additional memory (31) for storing a shell row and means for transferring the shell row to the intermediate buffer (2h).