Insat360 X3 now allows changing WiFi password

The Insta360 app has an option to change the password on the X3 camera. This may also work on other cameras, but I have not tested it. I have done a password change, but have not verified this actually did anything.

This option will cause the camera to display an authorization prompt, and once confirmed, you can type in a new WiFi password which the device will use.

I encourage ALL Insta360 camera owners to do this, as the default password is well documented and it allows anyone within WiFi range to access and download any photos/videos on the camera.

Arduino, ZigBee and motion sensor help needed.

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For a future project, I need to make use of remote triggers. These could be motion sensors, beam sensors, pressure mats, etc.

The ZigBee standard seems to be the way to go since I can find cheap consumer motion sensors that run on batteries. There also seems to be ZigBee repeaters, which allow giving the distance I need simply by plugging them in from place to place to create a mesh network.

XBee might be another option, if cheap motion sensors and repeaters are also available.

The goal is to have a central location be able to read the motion sensor status for many sensors, that could be spread out beyond walls hundreds of feet away.

Any pointers to where I might get started would be appreciated. Ideally I’d drive this all by a low-cost Arduino since the device will be used in an area where power might not be stable (and I wouldn’t want to corrupt the Linux file system on a Raspberry Pi).

Thanks…

Carl England must be stopped.

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Earlier this month, I received a message on my Sub-Etha Software Facebook page from author (and former/current CoCo programmer) Carl England:

I knew CHR$(13) was a carriage return, so this was creating a file name that contained carraige returns. What would that do?

I typed it in to find out…

How appropriate, because the first thing I said when i saw this code was “weird.”

Of course, now I have a file on my disk that would be hard to delete. Carl said just doing:

KILL A$

…would take care of it. Provided, of course, you did that after running the program, while A$ still existed. Otherwise you’d have to manually type that line again and replace the SAVE with KILL.

Fun.

Character 8 is a backspace, so I could sorta see what this was doing. “TEST” then four backspaces, then a period, then three more backspaces?

Well.

Also weird.

I could have had so much fun with this trick back when I was swapping disks with friends.

Thanks, Carl!

Exploring 1984 OS-9 on a 64K TRS-80 Color Computer – part 3

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See also: part 1, part 2 and part 3.

Welcome back to the days when an IBM Compatible PC required a floppy disk just to start up. You would boot to PC-DOS (on an actual I.B.M. machine) or MS-DOS (for a clone, like the Tandy 1000 that had just come out in 1984 as the first PC compatible for under $1000). And … then what?

Just like there wasn’t much you could do with a PC with only a DOS boot disk, having just OS-9 is rather limited as well. Beyond typing some commands, what could you do?

There was a simple line-based text editor that would let you make text files. You could then “list” the text file and have that redirected to a printer, if you had one.

I guess you could say this was very limited word processing. Just without much word processing (though the EDIT command has search and replace functions).

There was also a 6809 assembler and debugger. You could write programs in 6809 assembly language.

And that was the very first time I ever wrote an OS-9 Level 1 assembly language program, and also the first time I ever used the asm assembler. I was more familiar with the rma assembler that came out for OS-9 Level 2 on the CoCo 3.

What else? Well, just like DOS, if you wanted to do more, you’d need software. Initially, Radio Shack didn’t sell anything for OS-9 other than BASIC09. Investing in that would allow someone who knew normal BASIC to start writing programs for OS-9. (I plan to do a “Converting Color BASIC to BASIC09” series at some point.)

But it was still neat.

Multi-User

Multi-user support is great, but if you only have one keyboard it won’t get you very far. But, OS-9 came with drivers for the CoCo’s banger RS-232 port, and also a “time sharing monitor” program that could monitor such serial port and then launch the “login” program if a terminal was hooked up to such serial port.

You could plug up an RS232 terminal to the CoCo’s serial port, and then launch “tsmon /t1 &” (the ampersand made the program run in the background so the shell prompt would return immediately). Now both you at the keyboard and another user via the serial port could be using the system at the same time. (Albeit at 300 baud.)

Cool.

If that terminal was another CoCo, then a remote login might look like this:

Above, I added a new entry to the PASSWD file for “ALLEN” with a password, and made new directories /D0/USERS/ALLEN. I set that login entry to point to that directory so when I logged in, I would have been changed in to /d0/USERS/ALLEN ready to make new files there.

It’s a bit more work than this to be useful, but that’s basically the idea. It was really a game changer compared to using BASIC in ROM.

Conclusion

So what could you do with this 1984 OS-9 Level 1? Write programs in assembly, or buy BASIC09 and write programs in that langauge.

However, since text-based OS-9 applications were compatible across hardware, there were actually existing OS-9/6809 programs that could run on the CoCo. Third party software specifically for CoCo OS-9 would soon follow, which was interesting because CoCo OS-9 could do graphics.

But that’s an article for another day.

Until next time…

Exploring 1984 OS-9 on a 64K TRS-80 Color Computer – part 2

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See also: part 1, part 2 and part 3.

Obtaining a Time Machine

Since most of us will not have a 64K Radio Shack TRS-80 Color Computer laying around, as well as a disk drive and the original OS-9 floppy disks, I suppose running an emulator on your PC/Mac/Linux machine will have to suffice.

I personally use the XRoar emulator since I can run it on my Mac, Windows PC or Raspberry Pi. It allows me to emulate everything from a 1980 4K CoCo with Color BASIC 1.0, on up to a 512k CoCo 3. It has been invaluable in articles I have written, because I can quickly switch between Color, Extended and Disk BASIC systems of various versions using various amounts of RAM. There are other options available such as VCC for Windows, or the cross-platform MAME, but I do not know the specifics of how (or if) they can emulate an old 64K CoCo. (I think VCC is CoCo 3 only.)

Over at the Color Computer Archive, disk images have been preserved from the original V1.00.00 release of CoCo OS-9:

https://colorcomputerarchive.com/repo/Disks/Operating%20Systems/

I went and found the very first V1.00.00 release:

OS-9 Level 1 v01.00.00 (Tandy) (OS-9).zip

There was a later V1.01.00 update, and then an even later V2.00.00 update, but I want just just focus on what 1984 had to offer.

Inside that .zip file you will find two disk images:

OS9L1V1B.DSK – boot program (for Disk BASIC 1.0 users) and disk drive speed test utility.
OS9L1V1M.DSK – the actual OS-9 operating system itself, contained on this 156K 35-track single sided disk image.

As long as your CoCo or emulator is set to have 64K and Disk Extended Color BASIC 1.1, you can just mount the second one (OS9L1V1M.DSK) and then type “DOS” to boot in to OS-9. It will take awhile, since we are also emulating a slow floppy drive.

OS-9 Level 1 on a 64K Radio Shack TRS-80 Color Computer (emulated).

A “set time” utility is there asking for date and time — anyone here old enough to remember with early PCs all did the same thing as they booted to PC-DOS? Life before realtime clocks – the struggle was real!

Sadly, the set time utility is not Y2K compliant and will not let you enter “22” to mean 2022. You can type something like “22/7/27 8:58” but it will treat that as the year 1922.

22 means 1922. Sorry, folks living in 2022.

I should point out that, internally, it seems the clock code understood years past 2000 — but the utility did not allow you to enter them. If you set the time to just before midnight on December 31, 1999, then wait, you will see it rolls over from 1999 to the year of 19100:

The NitrOS9 project, which has created an open source update from the old OS-9, has fixed all these issues. Anyone interested in running OS-9 on a CoCo these days should be using that, but for this article, we will be sticking strictly with stock OS-9 as it existed in 1984. Which means maybe I should have entered the year to be 1984…

But I digress…

OS-9 Beginner’s Guide

I used to teach week-long courses on OS-9 for Microware, but we’ll keep this article much simpler and just look at commands and how the disk directories are set up.

As mentioned earlier, there is a “set time” utility, and in the previous screen shot you can see I used a command called “date” which will display the date. Typing it with the option of “t” added — “date t” — will display the date and add the time at the end.

If you type “dir” you will get a directory of the OS-9 disk:

OS9:DIR

 DIRECTORY OF .  00:05:38
OS9BOOT   CMDS      SYS
DEFS      STARTUP

Unlike Disk BASIC, OS-9 has a real file system that support longer filenames, upper and lowercase, subdirectories and much more. Since the CoCo VDG chip lacked true lowercase characters (lowercase existed, but would be displayed as inverted uppercase characters), by default CoCo OS-9 displays everything in uppercase even if the underlying text is using lowercase. You can type commands in upper or lowercase since the file system is not case sensative.

We see five filenames, but can’t tell if they are files or directories. There is a convention in OS-9 to make filenames lowercase, and directory names UPPERCASE. Since we can’t see the difference, we can use the option “e” on the dir command to display a longer listing:

OS9:DIR E

 DIRECTORY OF . 00:08:28
CREATED ON  OWNER   NAME
  ATTR    START      SIZE
==============================
83/06/02 1921   0  OS9BOOT
------WR       A     3032
83/06/02 1956   0  CMDS
D-EWREWR      3C      620
83/06/02 2002   0  SYS
D-EWREWR     164       A0
83/06/02 2002   0  DEFS
D-EWREWR     17F       C0
83/06/02 2003   0  STARTUP
----R-WR     15F        E

Yuck! But we’ll get to what this means in a moment. You will see the screen pauses at the end. This is a feature built-in to OS-9 and it can be turned on or off. Press SPACE and you will see the listing continues, but there wasn’t anything left other than an empty line before returning to the “OS9:” command prompt.

Looking at that listing, if we made it expand to a wider display, it becomes much easier to understand. It might look like this on a 40 or 80 column OS-9 system:

 DIRECTORY OF . 00:08:28
CREATED ON  OWNER   NAME    ATTR       START      SIZE
=====================================================
83/06/02 1921   0  OS9BOOT  ------WR       A     3032
83/06/02 1956   0  CMDS     D-EWREWR      3C      620
83/06/02 2002   0  SYS      D-EWREWR     164       A0
83/06/02 2002   0  DEFS     D-EWREWR     17F       C0
83/06/02 2003   0  STARTUP  ----R-WR     15F        E

CREATED ON – The first column is the date (YY/MM/DD) and time (HHMM) the file/directory was created.
OWNER – The second column is the owner of the file/directory. OS-9 Level 1 is a multi-user system, and each user can have its own unique user number. 0 is reserved for the administrator (super user).
NAME – The third column is the file/directory name. OS-9 Level 1 allowed filenames to be up to 28 characters long, and use upper and lowercase. Spaces are not allowed, and there are some other restrictions, like files cannot start with a number and most special characters are not allowed. But still, far more advanced than DOS was.
ATTR – Attributes of the file. This is how we can tell if something is a file or a directory. There are eight attributes, and the first is D if it is a directory, or – if it is a file. We can skip the next one, and focus on the next two sets of 3 attributes. They are “EWR” — the first three are PUBLIC Execution (for binaries), Write (writeable), and Read (readable). The next three are the same but for the OWNER. Thus, you can have a file that ONLY the user can read, or everyone can read. You can make a file that only the user can write to, but the public can read but NOT write to. The same thing for directories. Private directories could exist, usable only by the owner, or public, that other users on the system could read and/or write to.
START – This is a hexadecimal value of what logical sector the file/directory starts at on the disk system. OS-9 splits a disk up in to logical sectors of 256-bytes each. We don’t need to worry about this.
SIZE – This is the file size, also shown in hexadecimal. We see the “startup” file is E (&HE to BASIC users, or 0xE to C programmers) long – 14 bytes.

Here are what those files are:

OS9BOOT – The OS-9 boot file, which contains the kernel, device drivers, etc. This will be all the files necessary to get the system up and running to the OS9: command prompt.
CMDS – We see that this is a directory. It contains various command line utility programs.
SYS – Another directory. This one contains system text files.
DEFS – Another directory. This one has definition text files used by the assembler/compiler and such.
STARTUP – This is a text file with public Read and owner Write/Read. It is basically AUTOEXEC.BAT for OS-9.

Let’s try the “list” command on the STARTUP file, which we know is 14 bytes long:

OS9:LIST STARTUP
SETIME </TERM

The contents of the file is displayed, much like using “cat” under Linux or “type” under MS-DOS. We see the contents is one line, “SETIME </TERM” and if we counted those characters, we’d get 13 characters. The file size is 14, because it contains those thirteen characters plus a carriage return at the end of the line.

By default, OS-9 will boot and then run whatever is in this STARTUP file. This allows us to customize things if we wanted to, or remove that set time prompt completely.

Let’s see what is in the various directories.

CMDS

OS9:DIR CMDS

 DIRECTORY OF CMDS  00:26:46
ASM       ATTR      BACKUP
BINEX     BUILD     CMP
COBBLER   COPY      DATE
DCHECK    DEBUG     DEL
DELDIR    DIR       DISPLAY
DSAVE     DUMP      ECHO
EDIT      EXBIN     FORMAT
FREE      IDENT     LINK
LIST      LOAD      LOGIN
MAKDIR    MDIR      MERGE
MFREE     OS9GEN    PRINTERR
PROCS     PWD       PXD
RENAME    SAVE      SETIME
SHELL     SLEEP     TEE
TMODE     TSMON     UNLINK
VERIFY    XMODE

There is quite a bit available! We see some commands that may look familiar — like DATE (show the date), DEL (delete a file), COPY (copy a file), DIR (directory), DELDIR (delete directory), ECHO (echo text), LIST (list a file), MAKDIR (make directory), RENAME (rename a file) and so on. OS-9 has a full file system with most of the standard commands you would expect.

If you have ever used “CHKDSK” on a PC or “fsck” on Linux, you will find OS-9 DCHECK familiar. If you have ever merged files on a Linux system, MERGE will be familiar.

OS-9 is very Unix-like in design, and with Linux being based on UNIX, it will have some familiar aspects to a Linux user.

We will explore these commands later, but let’s keep looking.

SYS

OS9:DIR SYS

 DIRECTORY OF SYS  00:33:34
ERRMSG    PASSWORD  MOTD

Not much there. All three of these are text files.

ERRMSG – Contains a text listing of error messages (OS-9 will use an error number like ERROR #216, and this text file will show you that it means “PATH NAME NOT FOUND”.) You could type “LIST SYS/ERRMSG” if you wanted to see them all. You can also type the command PRINTERR to activate long error messages. Now instead of just getting “ERROR #216” it will be followed by the text description from the file. This will make error messages slower, though, since each time it will have to seek through the text file to find the entry and display it.
PASSWORD – As a multi-user system, OS-9 has a password file that can have entries for each user. You could create a password file with an entry for “admin” that would let them log in, change to the user’s “home” directory, and set their user ID to 0 (super user). Or you could make an entry for “bob” that sets his home directory somewhere else and makes him user 42, non-super user. Type “LIST SYS/PASSWORD” to see what is in there. You will see nothing is encrypted. Ah, those early days of operating systems! This file is used by the “login” command.
MOTD – Message of the Day text file. This file will be displayed to a user after they log in using the login command. We don’t see it because by default this OS-9 just boots directly to an OS9: command prompt.

DEFS

OS9:DIR DEFS

 DIRECTORY OF DEFS  00:39:53
OS9DEFS   RBFDEFS   SCFDEFS
SYSTYPE

There are text files used by the 6809 assembler. They are sorta like .h header files in C. They contain various text definitions for bit values or whatever.

OS9DEFS – Definitions for the operating system.
RBFDEFS – Definitions for the “random block file” manager (disk).
SCFDEFS – Definitions for the “sequential character file” manager (console, serial ports, etc.)
SYSTYPE – Definitions for the system.

Unless we are programming for those, we would never use these files.

So what can we do?

In the next installment, we’ll explore some of the commands, and discuss some of the things that make OS-9 very unique (and the reason why it can run as a disk-based operating system, or completely out of ROM with no file system at all).

To be continued…

Exploring 1984 OS-9 on a 64K TRS-80 Color Computer – part 1

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See also: part 1, part 2 and part 3.

NOTE: The images in this article were taken from the excellent Radio Shack Catalogs archive website: https://www.radioshackcatalogs.com/

1984 was a big year for home computers. Not only was the Apple Macintosh released with that famous 1984 Superbowl ad, but Microware’s OS-9 operating system made a debut at Radio Shack.

Des Moines-based Microware had created a product called RT/68 for the Motorola 6800 processor. It was advertised in the February 1977 issue of Byte Magazine:

This led to them working for/with Motorola to create a high performance BASIC programming language for the Motorola 6809 processor. This led to them creating an operating system to support it. That operating system was called OS-9. (I assume the 9 was chosen because of the 6809 processor.)

I do not know the details of how it happened, but at some point Tandy/Radio Shack and Microware decided to bring out a version of OS-9 for the Radio Shack TRS-80 Color Computer. It was introduced in the 1984 Radio Shack catalogs, along with a 64K version of the Color Computer that was needed to run it. (OS-9 required 64K on the CoCo, but OS-9 itself could be embedded in ROM to run on industrial equipment with as little as 4K RAM.)

OS-9 was listed in the 1984 Radio Shack catalog, as well as the two 1984 Radio Shack Computer catalogs (RSC-10 and RSC-11):

Here is how the 64K version of the Color Computer was presented in the 1984 catalog:

And this is a how OS-9 was described in the short entry of the 1984 catalog:

At the time, I remember my Radio Shack salesman telling me OS-9 was needed to make full use of the 64K in my Color Computer. The Microsoft BASIC ROMs in the CoCo were limited to using less than 32K, regardless of if you had more than that installed in your machine.

The computer catalog went in to more details on both the machine and the operating system:

New 64K CoCo in the OS-9 in the Radio Shack Computer Catalog RSC-10

OS-9 in the Radio Shack Computer Catalog RSC-10

I found it interesting that the same entry appeared in the second1984 computer catalog (RSC-11), but without the color. (I did not go through it word-for-word to see if there were any text changes, so let me know if I missed something.)

Humble beginnings! Over the next few years, CoCo OS-9 offerings would continue to grow, adding compilers like C, and eventually a more advanced OS-9 Level 2 for the CoCo 3 with an optional mouse-driven GUI.

But in 1984, there was far less you could actually do with OS-9 except write programs for it in either 6809 assembly (notice the assembler was included) or the sold-separately BASIC-09. (It was actually just “BASIC09” in the documentation, without the dash.)

I thought it might be fun to boot up this original version of CoCo OS-9 and see what all it could do.

To be continued…

Insta360 X3 filenames are different than ONE X2 filenames

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I did not expect to need to make any changes to my Insta360 ONE X2 filename article, but it looks like things have changed in the new X3 model. The files are no longer compatible (reading a ONE X2 memory car in an X3 will report corrupt files), and some of the names have been changed.

A quick one is the LRV (Low Resolution Video) files. On the ONE X2, they would be named like this:

LRV_20220925_160926_11_072.insv.mp4

You could open that in any video player, since it was an MP4 file.

But on the X3, the LRV files are named like this:

LRV_20220925_160925_11_070.lrv

With the Insta360 Studio plugin installed, my Mac recognizes them as an INSV file but cannot preview them. Just like with normal .insv files, you can add .mp4 to the end and then at least open/view them.

More to come, I expect…

Pop-Up windows in Color BASIC?

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In 1987, I wrote a simple routine to display a pop-up window on the 32-column text screen of the CoCo. I am not sure what I wrote this for, but it appears I did use this routine (or a version of it) in my TIDY DISK program a year later:

It is sometimes interesting to look back on something I did 35 years ago and see how (or if) I would do it differently today. So let’s do that.

On the Color Computer Archive site is a disk image containing two versions of this routine. The first was done on 8/8/1987, and it looks like a 1.1 was created the next day. I am pleased to see I was retaining versions back then.

Using the wonderful toolshed utility decb, I was able to get a text version of the tokenized BASic program easily:

$decb dir WNDO.DSK
Directory of: WNDO.DSK,

WNDO     BAS  0  B  1
WNDO11   BAS  0  B  1

$decb list -t WNDO.DSK,WNDO.BAS
999 END
1000 REM WINDOW SUBROUTINE
1001 REM S-START W-IDTH
1002 REM A$-TEXT L-ENGTH
1005 PRINT@S,STRING$(W+1,140)CHR$(141);:FORA=1TOL:PRINT@A*32+S,CHR$(133)STRING$(W,32)CHR$(128);:NEXTA:PRINT@32*L+S,CHR$(131)STRING$(W+1,128);:B=1
1010 FORA=W TOW-8STEP-1:IFMID$(A$,A,1)=" "THENPRINT@S+1+32*B,LEFT$(A$,A);:A$=RIGHT$(A$,LEN(A$)-A)ELSENEXTA:PRINT@S+1+32*B,A$;:GOTO1020
1015 B=B+1:GOTO1010
1020 PRINT@S+32*(L-1)+(W/2-5),"press any key";
1025 IFINKEY$=""THEN1025ELSERETURN

$ decb list -t WNDO.DSK,WNDO11.BAS
999 END
1000 REM WINDOW SUBROUTINE 1.1
1001 REM  BY ALLEN C. HUFFMAN
1002 REM      8/8, 8/9/87
1003 C=4
1005 PRINT@S,CHR$(140)STRING$(W,140)CHR$(141);:FORA=1TOL:PRINT@A*32+S,CHR$(133)STRING$(W,32)CHR$(133+16*C);:NEXTA:PRINT@32*L+S,CHR$(131)STRING$(W,131+16*C)CHR$(135+16*C);:B=1
1010 FORA=W TOW-8STEP-1:IFMID$(A$,A,1)=" "THENPRINT@S+1+32*B,LEFT$(A$,A);:A$=RIGHT$(A$,LEN(A$)-A)ELSENEXTA:PRINT@S+1+32*B,A$;:GOTO1020
1015 B=B+1:GOTO1010
1020 PRINT@S+32*(L-1)+W/2-6,"press"CHR$(128)"any"CHR$(128)"key";
1025 IFINKEY$=""THEN1025ELSERETURN

It appears the first version had help in the comments, and the second replaced that with my name and version dates. Looking at a WinMerge diff of the two versions, I see this:

It looks like I basically added color support rather than just a black drop shadow, and must have fixed a bug where width needed 1 added to it. The only other change was printing “PRESS ANY KEY” with black blocks between each word in stead of spaces. I can therefore tell I used at least this 1.1 version in my TIDY DISK program.

The subroutine requires the user to set a few variables before calling it:

S – PRINT @ position for the top left of the pop-up.
W – width of the pop-up (in characters).
L – length (height) of the pop-up (in lines).
A$ – message to display inside the pop-up. The message will be word-wrapped by the routine.

It appears I also allowed the user to set the color. In line 1003, the routine sets it to 3 (white), but the user could also set C ahead of time and then GOSUB to 1005 to bypass that line and use their own color. So I’ll add:

C – color of the drop shadow (use GOSUB 1005) if setting C.

GOSUB 1000 uses a default color, or set it yourself and GOSUB 1005. Nice.

10 C=6:S=39:W=16:L=10
20 A$="HELLO, 1987. THIS IS A COCO WINDOW POP-UP."
30 GOSUB 1005

The routine itself is not very smart. It doesn’t calculate anything. The user has to specify top left, width and height and do all that work. If you want a nicely centered box, you have to figure that out. But, if you wanted to make windows at different positions, I guess it allowed that flexibility. (I expect that’s why I wrote it this way.)

We can do better.

How many lines is it, anyway?

For most uses, a centered pop-up seems good enough. The issue is knowing how many lines the message is going to take to display after being word-wrapped. The current routine scans the string starting at “width” and moving backwards until it finds a space character. It then uses LEFT$ to print just that portion, and then trims that part off using RIGHT$.

To know how many lines it will take, we have to scan the string first to count them. Then we do it again to print them. This will slow things down, but make things easier on the user.

Anatomy of a Word Wrap

There are some good old articles here about word wrap routines, with some very fast and clever ones contributed by others (way better than mine). Check out those articles for better methods that what I am about to present.

Because I need to scan the line twice — one time to count the lines, and the second for the actual word wrap — I cannot mess with the user’s string. Instead, I’ll just use variables that sell me the Start Position (SP) within the string and End Position (EP) of the width-sized chunk I am going to scan. I’ll use a Position (P) variable and start at the end and scan backwards looking for a space. If I find one, I can count that as a line (increase the line count) and then move to the next character (to skip the space) and reset the Start Position to that. The process will repeat.

Since I do not want to duplicate code, I’ll embed the “print this section of the string” code in this routine, but use another variable to determine if I actually print it or now. I’m calling it Show (SH), and if SH=0 then it just counts, otherwise it prints as it counts each line.

It’s messy, but it works.

Here is a diagram showing the process:

When the space is located, it knows that from SP to that space position is something to print (a line).

Easy peasy.

Except it took me way too much brane power to figure this out, and I am sure it could be massively improved.

The routine will use the user’s width (W) variable to know how wide to make the box, and adjust the text space inside accordingly (W-2, leaving room for the borders).

The user can specify C for color, or if it’s not set (0) it will be assigned a color.

The starting location (S) must also be set. This is the top left of the pop-up box, in PRINT@ format (i.e. 0 is the top left of the screen, 32 is the start of the second line, etc.)

Here is what I came up with, along with a few lines at the start to test it out. It will keep displaying random sized pop-ups with the same text over and over and over. I used this to make sure it would work with the various size and color valuies.

NOTE: If you send in a width that is too narrow, it won’t work properly. Ideally I should check for that and have a minimum size. (I’ll try to add that in the final version, since I know it needs to be at least wide enough to fit “PRESS ANY KEY”.)

10 A$="THIS IS A LONG STRING THAT I WANT TO USE TO TEST WORD WRAPPING IN MY WINDOW ROUTINE."
20 W=RND(10)+20:S=48-W/2:C=RND(8)-1
30 CLS:GOSUB 1000
40 GOTO 20

999 END
1000 REM WINDOW SUBROUTINE 2.0
1001 REM  BY ALLEN C. HUFFMAN
1002 REM 8/8, 8/9/87 & 7/27/22
1993 REM    S-START W-IDTH
1004 REM    A$-TEXT C-COLOR
1005 REM
1010 IF C=0 THEN C=4
1020 SH=0:GOSUB 1120
1030 PRINT@S,CHR$(140)STRING$(W-2,140)CHR$(141);
1040 FOR A=1 TO LC+1
1050 PRINT@S+32*A,CHR$(133)STRING$(W-2,32)CHR$(133+16*C);
1060 NEXTA
1070 PRINT@S+32*(LC+1),CHR$(131)STRING$(W-2,131+16*C)CHR$(135+16*C);
1080 SH=1:GOSUB 1120
1090 PRINT@S+32*LC+W/2-7,"press"CHR$(128)"any"CHR$(128)"key";
1100 IF INKEY$="" THEN 1100 ELSE RETURN
1110 ' CALC LINE COUNT/PRINT
1120 LC=1:SP=1:LN=LEN(A$)
1130 EP=SP+W-2:P=EP
1140 IF EP>LN THEN 1190
1150 IF MID$(A$,P,1)<>" " THEN P=P-1 ELSE 1170
1160 IF P>SP THEN 1150 ELSE 1190
1170 IF SH<>0 THEN PRINT@S+32*LC+1,MID$(A$,SP,P-SP);
1180 LC=LC+1:SP=P+1:GOTO 1130
1190 IF SH<>0 THEN PRINT@S+32*LC+1,MID$(A$,SP);
1200 LC=LC+1:RETURN
1210 RETURN

One bad thing about this is all the variables I am using. And it could also be made faster by combining lines and such.

Here are some things I would like to do next:

Check for a minimum width (if W<x then W=x).
Combine lines to make it smaller and faster.
Rename variables to all start with Z.

Z? Since my subroutine uses many variables, the calling program would have to make sure to not use any of them since the subroutine would change them. Today I like the approach of starting all my subroutine variables with Z, and just noting that “Zx variables are reserved for subroutines.” That way I can use any variables I want in my main program — other than the ones that are specifically used to pass values in to the subroutine — without worrying about a conflict.

I guess that means there will be a part 2. Until then, please comment with any ideas you have on improving this.

Until next time…

My 1988 TIDYDISK program.

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I have posted some of my old programs to the Color Computer Archive site:

https://colorcomputerarchive.com/search?q=huffman

One I found interesting to revisit was my TIDY DISK program. I created it in 1988, and it appears I revised it two more times since there is a version 1.2 from 1990. (Unfortunately, I did not update the title screen so it still reads 1.1):

This program, written in BASIC, was designed to scan a floppy disk and erase any unallocated space. Much like how one can “undelete” files on a modern PC and see what was there, the same thing was possible with the old Disk BASIC disk format in the 1980s. However, privacy was not even something I was considering when I created the program.

At the time, I had a modem and was using it all the time to call in to Bulletin Board Systems (BBS). There were many places where you could download CoCo software, including pirated software. There were also disk transfer programs that could be used to send an entire disk from one user to another.

I do not recall the name of the program I used, but it was smart enough to not send “empty” data. If a granule (the CoCo disk was divided in to 68 sections called granules) was empty, the program would skip sending it. Unfortunately, if you had a disk that previously had data on that granule (from a file that was since deleted), it would send all that old “deleted” data as well. This made the transfer much longer than it needed to be.

(And believe me, sending a full disk of 156K over a 300 or 1200 baud modem seemed to take “days” back then… At least it felt like it.)

I created TIDY DISK to solve this problem.

TIDY DISK

The program was written for a CoCo 3, and it errors out on a CoCo 1 or 2. This is because I do a PEEK on startup to check for screen width. If the CoCo 3 is not in 32-column mode, I do a “WIDTH 32” command to switch back. That PEEK does not work on a CoCo 1 or 2, and thus it tries to run the non-existent “WIDTH” command and errors out. Removing that check (or doing a manual POKE 231,0 before running) allows it to run on a CoCo 1 or 2.

To understand what it does, I built in HELP screens.

Ah, humor.

The “pop up” windows I used was a BASIC routine I wrote, and I also posted that routine to the Color Computer Archive site.

When the user selected a drive, they were asked to make sure they really meant to do that:

If they answered Yes, it would begin by first reading in the allocation table information:

This was basically a table that showed which of the 68 granules were in use. This would be a real good time to explain how the Disk BASIC disk format worked, but I think I’ll save that for a standalone article. (Mostly because I do not remember. I’m not even sure how I figured this out back then!)

The process would then scan all 68 granules of the disk and write blank data to any that was not marked as allocated. This would take some time…

When complete, the program would stop. It would literally STOP, saying “BREAK IN 55”. I ended the program with the STOP command. I can’t imagine I used that command very often, and was surprised I even used it there versus “END” which would just end cleanly.

One modern use for this program would be for disk images. If you have a disk image you want to ZIP and share, ZIP will compress all the data. If there are many sectors with deleted information, that will get ZIPped right along with the actual data you want to share. Not only does it make the file larger, but someone could use a disk editor and look at all the formerly “deleted” data.

Running this on a disk image before zipping it up might still have some use.

TIDY TIDK 1.3?

If I were to update this program, here are some things I would change:

I would certainly fix the version number in the title screen.
I’d also fix it to correctly work on a CoCo 1/2.
I’d make it accept drives from 0-255, so it would work on RGB-DOS/HDB-DOS.
And I’d remove that STOP, and just have a real Quit option so the user could keep doing disks without needing to re-RUN the program each time.

Maybe some day…

But until then…

Drawing a maze level on the CoCo – part 5

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See Also: part 1, part 2, part 3, part 4 and part 5.

ASCII HEX data to maze graphics

As our spiraling trip down the rabbit hole continues, we finally return to drawing stuff instead of converting stuff.

We now have DATA statements that contain 2-byte hex numbers. Each hex number represents a byte (0-255) and each of those bytes represents 8 maze blocks on the screen.

For use in a Color BASIC program, we might want to take this HEX data and convert it in to string data (containing the final CHR$ values) for fast printing on the screen. If we were doing this in 6809 assembly, we might have the binary data contained in the executable, and convert it to a buffer that can then be copied to the screen as needed.

We’ll start with a simple (verbose) Color BASIC version. Since I am using the XRoar emulator to CLOAD this text file, I had to shorten the DATA lines a bit since they are now on higher lines, thus instead of loading “1DATA” it is loading “360DATA” taking up more bytes. I just moved some hex values to the next line.

I also adjusted my parser a bit. In my binary example, I wanted to handle binary numbers of any length. i.e, “111” would be 7, and “11111111” would be 255. To do this, I started with 0, and each time I saw a 1 I added one. For each new digit, I shifted the bits left by multiplying by 2. That way if it parsed “111” it would be “1 *2 +1 *2 +1” and so on for longer values.

For the maze, everything has to be a byte, so I took the opposite approach by starting with a bit value of 128 (representing the high bit in an 8-bit byte). Each time I found a new digit, I divided the bit value by 2 and either added it (if the new digit was a “1”, or “X” in the case of the maze) or not. That would make a maze of “XXXXXXXX” be “128 + 16 + 32 + 16 + 8 + 4 + 1” giving 255. If the maze data ran short, so the last few bytes were just “XXXX” it would be “128 + 64 + 32 + 16” which is &HF0 in hex (11110000), exactly what we want. If I had done it the other way, it would end up with 1111 (&H0F) and maze data would look like this:

GOOD:
-------- -------- ----
XXXXXXXX XXXXXXXX XXXX &HFF &HFF &HF0 -> 11111111 11111111 11110000

BAD:
-------- -------- ----
XXXXXXXX XXXXXXXX XXXX &HFF &HFF &H0F -> 11111111 11111111 00001111

I hope that makes sense. Anyway, here is the program I came up with… It will scan the hex values and build an array of strings (LN$) for each line. That way, the converted maze can be quickly printed after it has been generated once.

0 REM HEXMAZE.BAS
10 ' STRING SPACE IS MW*(MH+1)
20 CLEAR 28*32
30 ' SIZE OF MAZE IN DATA
40 MW=28:MH=31
50 ' ROOM FOR CONVERTED MAZE
60 DIM MZ$(MH):LN=0
70 CLS
80 ' READ A LINE OF HEX DATA
90 READ A$:IF A$="" THEN 340
100 ' EVERY 2 CHARS IS A HEX
110 FOR A=1 TO LEN(A$) STEP 2
120 ' COVERT HEX TO A VALUE
130 V=VAL("&H"+MID$(A$,A,2))
140 ' CONVERT BITS TO BLOCKS
150 BT=128
160 IF (V AND BT)=0 THEN B$=CHR$(128) ELSE B$=CHR$(175)
170 ' ADD BLOCK/SPACE TO STRING
180 MZ$(LN)=MZ$(LN)+B$
190 ' IF LEN >= MAZE W, NEXT
200 IF LEN(MZ$(LN))>=MW THEN 280
210 ' SHIFT BIT RIGHT
220 BT=INT(BT/2)
230 ' IF MORE BITS, REPEAT
240 IF BT>0 THEN 160
250 ' GET NEXT CHARACTER
260 GOTO 310
270 ' ELSE NEW MAZE LINE
280 PRINT MZ$(LN)
290 LN=LN+1
300 ' NEXT CHARACTER
310 NEXT
320 ' MORE LINES TO DO?
330 IF LN<MH THEN 90
340 END
350 REM MAZE AS HEX DATA
360 DATAFFFFFFF080060010BDF6FBD0BDF6FBD0BDF6FBD080000010BDBFDBD0BDBFDBD081861810FDF6FBF005F6FA0005801A0005BFDA00FDA05BF000204000FDA05BF005BFDA0005801A0005BFDA00FDBFDBF080060010BDF6FBD0BDF6FBD08C000310EDBFDB70EDBFDB7081861810BFF6FFD0BFF6FFD080000010
370 DATAFFFFFFF0,""

This program works, but it’s very slow, taking about 45 seconds to run. But, it’s verbose enough to (hopefully) explain what is going on.

By removing spaces, swapping out a integer values for faster HEX values, changing a CHR$() to a variable and adding a bit more string space, removing INT (and making one adjustment needed due to that), and combining lines, it can be sped up to just over 32 seconds.

0 REM HEXMAZE2.BAS
10 ' STRING SPACE IS MW*(MH+1)
20 CLEAR 28*32+200
30 ' SIZE OF MAZE IN DATA
40 MW=28:MH=31
50 ' ROOM FOR CONVERTED MAZE
60 DIM MZ$(MH):LN=0:BL$=CHR$(175)
70 CLS
90 READA$:IFA$=""THEN340
110 FORA=1TOLEN(A$)STEP2:V=VAL("&H"+MID$(A$,A,&H2)):BT=&H80
160 IF(V ANDBT)=0THENB$=BK$ELSEB$=BL$
180 MZ$(LN)=MZ$(LN)+B$:IFLEN(MZ$(LN))>=MW THEN280
220 BT=BT/2:IFBT>=1THEN160
260 GOTO310
280 PRINTMZ$(LN):LN=LN+1
310 NEXT:IFLN<MH THEN90
340 END
350 REM MAZE AS HEX DATA
360 DATAFFFFFFF080060010BDF6FBD0BDF6FBD0BDF6FBD080000010BDBFDBD0BDBFDBD081861810FDF6FBF005F6FA0005801A0005BFDA00FDA05BF000204000FDA05BF005BFDA0005801A0005BFDA00FDBFDBF080060010BDF6FBD0BDF6FBD08C000310EDBFDB70EDBFDB7081861810BFF6FFD0BFF6FFD080000010
370 DATAFFFFFFF0,""

And this is before translating that blocky maze into the “rounded corners” and such we want. This may be far too slow to do in BASIC since most folks don’t want to “Please wait 3.5 minutes while loading…” like a program my Commodore 64 friend once showed me. Assembly language helper routines might be needed for the impatient players out there…

Blocky to less blocky

After this code converts HEX values to maze data in a string array, we can process those strings and change the characters to have the “rounded” corners and such. Here is what I came up with, based on the original version that PEEKed and POKEed displayed bytes on the screen. This time, it’s scanning strings using MID$() and altering CHR$() values.

Side Note: Does everyone here know that, while you can’t use LEFT$ or RIGHT$ to change the left or right portion of a string, you can use MID$ to change characters? If you have A$=”1234567890″ and you want to change two characters starting at the third one, you can do MID$(A$,3,2)=”XX” and you get “12XX567890”. I’ll be using that…

Here is what I came up with… Instead of PEEKing memory, I used MID$(). It’s quite the mess, and very slow since I went back to the first version of the hex-to-maze print routine, just for clarity.

0 REM HEXMAZE3.BAS
10 ' STRING SPACE IS MW*(MH+1)
20 CLEAR 28*32
30 ' SIZE OF MAZE IN DATA
40 MW=28:MH=31
50 ' ROOM FOR CONVERTED MAZE
60 DIM MZ$(MH):LN=0
70 CLS
80 ' READ A LINE OF HEX DATA
90 READ A$:IF A$="" THEN 340
100 ' EVERY 2 CHARS IS A HEX
110 FOR A=1 TO LEN(A$) STEP 2
120 ' COVERT HEX TO A VALUE
130 V=VAL("&H"+MID$(A$,A,2))
140 ' CONVERT BITS TO BLOCKS
150 BT=128
160 IF (V AND BT)=0 THEN B$=CHR$(128) ELSE B$=CHR$(175)
170 ' ADD BLOCK/SPACE TO STRING
180 MZ$(LN)=MZ$(LN)+B$
190 ' IF LEN >= MAZE W, NEXT
200 IF LEN(MZ$(LN))>=MW THEN 280
210 ' SHIFT BIT RIGHT
220 BT=INT(BT/2)
230 ' IF MORE BITS, REPEAT
240 IF BT>0 THEN 160
250 ' GET NEXT CHARACTER
260 GOTO 310
270 ' ELSE NEW MAZE LINE
280 PRINT MZ$(LN)
290 LN=LN+1
300 ' NEXT CHARACTER
310 NEXT
320 ' MORE LINES TO DO?
330 IF LN<MH THEN 90

340 ' CONVERT LINES
350 BL$=CHR$(128):PRINT
360 FOR LN=0 TO MH-1
370 FOR C=1 TO LEN(MZ$(LN))
380 IF MID$(MZ$(LN),C,1)=BL$ THEN 510
390 V$=CHR$(175)
400 IF LN>0 THEN U$=MID$(MZ$(LN-1),C,1):UR$=MID$(MZ$(LN-1),C+1,1) ELSE U$=BL$:UR$=BL$
410 IF LN>0 THEN IF C>1 THEN UL$=MID$(MZ$(LN-1),C-1,1) ELSE ELSE UL$=BL$
420 IF C>1 THEN L$=MID$(MZ$(LN),C-1,1) ELSE L$=BL$
430 IF C<LEN(MZ$(LN)) THEN R$=MID$(MZ$(LN),C+1,1) ELSE R$=BL$
440 IF LN<MH-1 THEN D$=MID$(MZ$(LN+1),C,1) ELSE D$=BL$
450 IF LN<MH-1 THEN IF C>1 THEN DL$=MID$(MZ$(LN+1),C-1,1) ELSE ELSE DL$=BL$
460 IF LN<MH-1 THEN IF C<MW THEN DR$=MID$(MZ$(LN+1),C+1,1) ELSE ELSE DR$=BL$
470 IF U$<>BL$ THEN IF L$<>BL$ THEN GOSUB 600
480 IF U$<>BL$ THEN IF R$<>BL$ THEN GOSUB 700
490 IF D$<>BL$ THEN IF L$<>BL$ THEN GOSUB 800
500 IF D$<>BL$ THEN IF R$<>BL$ THEN GOSUB 900
510 NEXT:PRINT MZ$(LN):NEXT
520 END

600 ' UP and LEFT set
610 IF UL$<>BL$ THEN V$=CHR$(ASC(V$) AND NOT 8)
620 IF R$=BL$ THEN IF DR$=BL$ THEN IF D$=BL$ THEN V$=CHR$(ASC(V$) AND NOT 1)
630 MID$(MZ$(LN),C,1)=V$:RETURN

700 ' UP and RIGHT set
710 IF UR$<>BL$ THEN V$=CHR$(ASC(V$) AND NOT 4)
720 IF L$=BL$ THEN IF DL$=BL$ THEN IF D$=BL$ THEN V$=CHR$(ASC(V$) AND NOT 2)
730 MID$(MZ$(LN),C,1)=V$:RETURN

800 ' DOWN and LEFT set
810 IF DL$<>BL$ THEN V$=CHR$(ASC(V$) AND NOT 2)
820 IF U$=BL$ THEN IF UR$=BL$ THEN IF R$=BL$ THEN V$=CHR$(ASC(V$) AND NOT 4)
830 MID$(MZ$(LN),C,1)=V$:RETURN

900 ' DOWN and RIGHT set
910 IF DR$<>BL$ THEN V$=CHR$(ASC(V$) AND NOT 1)
920 IF L$=BL$ THEN IF UL$=BL$ THEN IF U$=BL$ THEN V$=CHR$(ASC(V$) AND NOT 8)
930 MID$(MZ$(LN),C,1)=V$:RETURN

1000 REM MAZE AS HEX DATA
1010 DATAFFFFFFF080060010BDF6FBD0BDF6FBD0BDF6FBD080000010BDBFDBD0BDBFDBD081861810FDF6FBF005F6FA0005801A0005BFDA00FDA05BF000204000FDA05BF005BFDA0005801A0005BFDA00FDBFDBF080060010BDF6FBD0BDF6FBD08C000310EDBFDB70EDBFDB7081861810BFF6FFD0BFF6FFD080000010
1020 DATAFFFFFFF0,""

Testing on the XRoar emulator shows this whole process takes about 161 seconds.

That’s so slow. Perhaps removing some of the CHR$() stuff and changing strings to values (like the originally PEEK version), skipping some of the extra IFs (like, if you are on line 0, there is no up, up left, or up right; if you are on the last line, there is no bottom, bottom left, or bottom right) and some other minor things might help…

340 ' CONVERT LINES
350 BL=128:PRINT
360 FOR LN=0 TO MH-1
365 LL=LEN(MZ$(LN))
370 FOR C=1 TO LL
380 IF ASC(MID$(MZ$(LN),C,1))=BL THEN 510
390 V=175

395 IF LN=0 THEN U=BL:UR=BL:UL=BL:GOTO 420
400 U=ASC(MID$(MZ$(LN-1),C,1)) ELSE U=BL
405 IF C<LL THEN UR=ASC(MID$(MZ$(LN-1),C+1,1)) ELSE UR=BL
410 IF C>1 THEN UL=ASC(MID$(MZ$(LN-1),C-1,1)) ELSE UL=BL

420 IF C>1 THEN L=ASC(MID$(MZ$(LN),C-1,1)) ELSE L=BL
430 IF C<LL THEN R=ASC(MID$(MZ$(LN),C+1,1)) ELSE R=BL

435 IF LN=MH-1 THEN D=BL:DL=BL:DR=BL:GOTO 470
440 D=ASC(MID$(MZ$(LN+1),C,1)) ELSE D=BL
450 IF C>1 THEN DL=ASC(MID$(MZ$(LN+1),C-1,1)) ELSE DL=BL
460 IF C<LL THEN DR=ASC(MID$(MZ$(LN+1),C+1,1)) ELSE DR=BL

470 IF U<>BL THEN IF L<>BL THEN GOSUB 600
480 IF U<>BL THEN IF R<>BL THEN GOSUB 700
490 IF D<>BL THEN IF L<>BL THEN GOSUB 800
500 IF D<>BL THEN IF R<>BL THEN GOSUB 900
510 NEXT:PRINT MZ$(LN):NEXT
515 PRINT TIMER,TIMER/60
520 END

600 ' UP and LEFT set
610 IF UL<>BL THEN V=(V AND NOT 8)
620 IF R=BL THEN IF DR=BL THEN IF D=BL THEN V=(V AND NOT 1)
630 MID$(MZ$(LN),C,1)=CHR$(V):RETURN

700 ' UP and RIGHT set
710 IF UR<>BL THEN V=(V AND NOT 4)
720 IF L=BL THEN IF DL=BL THEN IF D=BL THEN V=(V AND NOT 2)
730 MID$(MZ$(LN),C,1)=CHR$(V):RETURN

800 ' DOWN and LEFT set
810 IF DL<>BL THEN V=(V AND NOT 2)
820 IF U=BL THEN IF UR=BL THEN IF R=BL THEN V=(V AND NOT 4)
830 MID$(MZ$(LN),C,1)=CHR$(V):RETURN

900 ' DOWN and RIGHT set
910 IF DR<>BL THEN V=(V AND NOT 1)
920 IF L=BL THEN IF UL=BL THEN IF U=BL THEN V=(V AND NOT 8)
930 MID$(MZ$(LN),C,1)=CHR$(V):RETURN

Well, that brings it down to 155 seconds and that simply won’t do. There are many other optimizations to this BASIC program that could be done, and I bet we could even double the speed. But even then, that’s far too long to wait for a maze level to be drawn.

It looks like an assembly language routine might be our only option. We’ll take a break for now, but revisit this later after some discussion on assembly language. At some point. Eventually.

Until next time…