.TT23 LDA #128 \ Clear the top part of the screen, draw a white border, JSR TT66 \ and set the current view type in QQ11 to 128 (Short- \ range Chart) LDA #7 \ Move the text cursor to column 7 STA XC LDA #190 \ Print recursive token 30 ("SHORT RANGE CHART") and JSR NLIN3 \ draw a horizontal line at pixel row 19 to box in the \ title JSR TT14 \ Call TT14 to draw a circle with crosshairs at the \ current system's galactic coordinates JSR TT103 \ Draw small crosshairs at coordinates (QQ9, QQ10), \ i.e. at the selected system JSR TT81 \ Set the seeds in QQ15 to those of system 0 in the \ current galaxy (i.e. copy the seeds from QQ21 to QQ15) LDA #0 \ Set A = 0, which we'll use below to zero out the INWK \ workspace STA XX20 \ We're about to start working our way through each of \ the galaxy's systems, so set up a counter in XX20 for \ each system, starting at 0 and looping through to 255 LDX #24 \ First, though, we need to zero out the 25 bytes at \ INWK so we can use them to work out which systems have \ room for a label, so set a counter in X for 25 bytes .EE3 STA INWK,X \ Set the X-th byte of INWK to zero DEX \ Decrement the counter BPL EE3 \ Loop back to EE3 for the next byte until we've zeroed \ all 25 bytes \ We now loop through every single system in the galaxy \ and check the distance from the current system whose \ coordinates are in (QQ0, QQ1). We get the galactic \ coordinates of each system from the system's seeds, \ like this: \ \ x = s1_hi (which is stored in QQ15+3) \ y = s0_hi (which is stored in QQ15+1) \ \ so the following loops through each system in the \ galaxy in turn and calculates the distance between \ (QQ0, QQ1) and (s1_hi, s0_hi) to find the closest one .TT182 LDA QQ15+3 \ Set A = s1_hi - QQ0, the horizontal distance between SEC \ (s1_hi, s0_hi) and (QQ0, QQ1) SBC QQ0 BCS TT184 \ If a borrow didn't occur, i.e. s1_hi >= QQ0, then the \ result is positive, so jump to TT184 and skip the \ following two instructions EOR #&FF \ Otherwise negate the result in A, so A is always ADC #1 \ positive (i.e. A = |s1_hi - QQ0|) .TT184 CMP #20 \ If the horizontal distance in A is >= 20, then this BCS TT187 \ system is too far away from the current system to \ appear in the Short-range Chart, so jump to TT187 to \ move on to the next system LDA QQ15+1 \ Set A = s0_hi - QQ1, the vertical distance between SEC \ (s1_hi, s0_hi) and (QQ0, QQ1) SBC QQ1 BCS TT186 \ If a borrow didn't occur, i.e. s0_hi >= QQ1, then the \ result is positive, so jump to TT186 and skip the \ following two instructions EOR #&FF \ Otherwise negate the result in A, so A is always ADC #1 \ positive (i.e. A = |s0_hi - QQ1|) .TT186 CMP #38 \ If the vertical distance in A is >= 38, then this BCS TT187 \ system is too far away from the current system to \ appear in the Short-range Chart, so jump to TT187 to \ move on to the next system \ This system should be shown on the Short-range Chart, \ so now we need to work out where the label should go, \ and set up the various variables we need to draw the \ system's filled circle on the chart LDA QQ15+3 \ Set A = s1_hi - QQ0, the horizontal distance between SEC \ this system and the current system, where |A| < 20. SBC QQ0 \ Let's call this the x-delta, as it's the horizontal \ difference between the current system at the centre of \ the chart, and this system (and this time we keep the \ sign of A, so it can be negative if it's to the left \ of the chart's centre, or positive if it's to the \ right) ASL A \ Set XX12 = 104 + x-delta * 4 ASL A \ ADC #104 \ 104 is the x-coordinate of the centre of the chart, STA XX12 \ so this sets XX12 to the centre 104 +/- 76, the pixel \ x-coordinate of this system LSR A \ Move the text cursor to column x-delta / 2 + 1 LSR A \ which will be in the range 1-10 LSR A STA XC INC XC LDA QQ15+1 \ Set A = s0_hi - QQ1, the vertical distance between SEC \ this system and the current system, where |A| < 38. SBC QQ1 \ Let's call this the y-delta, as it's the vertical \ difference between the current system at the centre of \ the chart, and this system (and this time we keep the \ sign of A, so it can be negative if it's above the \ chart's centre, or positive if it's below) ASL A \ Set Y1 = 90 + y-delta * 2 ADC #90 \ STA Y1 \ 90 is the y-coordinate of the centre of the chart, \ so this sets Y1 to the centre 90 +/- 74, the pixel \ y-coordinate of this system LSR A \ Set Y = Y1 / 8, so Y contains the number of the text LSR A \ row that contains this system LSR A TAY \ Now to see if there is room for this system's label. \ Ideally we would print the system name on the same \ text row as the system, but we only want to print one \ label per row, to prevent overlap, so now we check \ this system's row, and if that's already occupied, \ the row above, and if that's already occupied, the \ row below... and if that's already occupied, we give \ up and don't print a label for this system LDX INWK,Y \ If the value in INWK+Y is 0 (i.e. the text row BEQ EE4 \ containing this system does not already have another \ system's label on it), jump to EE4 to store this \ system's label on this row INY \ If the value in INWK+Y+1 is 0 (i.e. the text row below LDX INWK,Y \ the one containing this system does not already have BEQ EE4 \ another system's label on it), jump to EE4 to store \ this system's label on this row DEY \ If the value in INWK+Y-1 is 0 (i.e. the text row above DEY \ the one containing this system does not already have LDX INWK,Y \ another system's label on it), fall through into to BNE ee1 \ EE4 to store this system's label on this row, \ otherwise jump to ee1 to skip printing a label for \ this system (as there simply isn't room) .EE4 STY YC \ Now to print the label, so move the text cursor to row \ Y (which contains the row where we can print this \ system's label) CPY #3 \ If Y < 3, then the system would clash with the chart BCC TT187 \ title, so jump to TT187 to skip showing the system DEX \ We entered the EE4 routine with X = 0, so this stores STX INWK,Y \ &FF in INWK+Y, to denote that this row is now occupied \ so we don't try to print another system's label on \ this row LDA #%10000000 \ Set bit 7 of QQ17 to switch to Sentence Case STA QQ17 JSR cpl \ Call cpl to print out the system name for the seeds \ in QQ15 (which now contains the seeds for the current \ system) .ee1 LDA XX12 \ Set X1 to the pixel x-coordinate of this system STA X1 JSR CPIX4 \ Draw a double-height mode 4 dot at (X1, Y1) .TT187 JSR TT20 \ We want to move on to the next system, so call TT20 \ to twist the three 16-bit seeds in QQ15 INC XX20 \ Increment the counter BEQ TT111-1 \ If X = 0 then we have done all 256 systems, so return \ from the subroutine (as TT111-1 contains an RTS) JMP TT182 \ Otherwise jump back up to TT182 to process the next \ systemName: TT23 [Show more] Type: Subroutine Category: Charts Summary: Show the Short-range Chart (FUNC-6)Context: See this subroutine in context in the source code Variations: See code variations for this subroutine in the different versions References: This subroutine is called as follows: * TT102 calls TT23 * TT114 calls TT23
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Subroutine CPIX4 (category: Drawing pixels)
Draw a double-height dot on the dashboard
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Label EE3 is local to this routine
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Label EE4 is local to this routine
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Subroutine NLIN3 (category: Drawing lines)
Print a title and draw a horizontal line at row 19 to box it in
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Subroutine TT103 (category: Charts)
Draw a small set of crosshairs on a chart
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Subroutine TT14 (category: Drawing circles)
Draw a circle with crosshairs on a chart
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Label TT182 is local to this routine
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Label TT184 is local to this routine
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Label TT186 is local to this routine
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Label TT187 is local to this routine
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Subroutine TT20 (category: Universe)
Twist the selected system's seeds four times
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Subroutine TT66 (category: Drawing the screen)
Clear the screen and set the current view type
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Subroutine TT81 (category: Universe)
Set the selected system's seeds to those of system 0
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Subroutine cpl (category: Universe)
Print the selected system name
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Label ee1 is local to this routine