Copy screen memory to a string in Color BASIC???

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Today I was tagged in a Facebook post by MC-10 (well, and CoCo) programmer, Jim Gerrie. He shared a snipped of code he was trying to get working. The concept was to have stuff on the 32 column text screen get copied into a normal string and then be able to PRINT it back.

Jim’s post (with the code that wasn’t working) with code for the MC-10 was this:

10 CLEAR1200:DIMJ,K,A$,B$:GOSUB100
20 A$=””:K=VARPTR(A$):POKEK,255:POKEK+1,0:POKEK+2,64:B$=A$
50 CLS:PRINTB$;
60 GOTO60
100 CLS1:PRINT”THIS IS LINE ONE”
110 PRINT”THIS IS LINE TWO”
112 PRINT”THIS IS LINE THREE”
113 PRINT”THIS IS LINE FOUR”
114 PRINT”THIS IS LINE FIVE”
115 PRINT”THIS IS LINE SIX”
116 PRINT”THIS IS LINE SEVEN”
117 PRINT”THIS IS LINE EIGHT”:RETURN

Can someone explain why this program doesn’t work on my TRS-80 MC-10?! It should reassign the memory pointer of string variable A$ to the beginning of screen memory (highbyte 64 lowbyte 0) so that I can then just assign A$ to B$, which will allow me to “capture” the first 255 bytes of screen mem.

It works on the TRS-80 MODEL I/III (using its screen start at highbyte 60 lowbyte 0)!

Any help greatly appreciated.
– Jim Gerrie in the Facebook TRS-80 MC-10 Group.

I could immediately see what the program was attempting to do, and it was something that never occurred to me to try. The concept is “simple” now that I see it:

Stuff is placed on the screen (CLS, PRINT, etc.)
A string (A$) is declared (line 20) and then VARPTR is used to get the memory location of the 5-byte string descriptor for that string. At this point, A$ is zero bytes long, but it will point to somewhere inside the program memory just after the first quote in A=”” because that is where the string begins (even if it is zero bytes long).
The string descriptor is modified using POKE to change the length of the string to 255 bytes, then the start location of the string from that location inside program memory to be the start of the text screen. That was the first bug. The location being POKEd was off by one and was not modifying the string start address properly.
After this, A$ is copied into a normal string, thus saving the contents of the first string (screen memory) into the new string (in normal reserved string memory). This is where the second bug was.

Before continuing, If you need a refreshed on VARPTR, start with this article. It will show how the five byte string descriptor is used. Here is a refresh:

STRING DESCRIPTOR (5 BYTES)
0 - LENGTH OF STRING
1 - NOT USED FOR STRINGS
2 - MSB OF ADDR OF STRING IN MEMORY
3 - LSB OF ADDR OF STRING IN MEMORY
5 - ALWAYS 0 FOR A STRING

The first POKE at the address returned by VARTPR (K) was fine, setting the length to 255. But the next two pokes were at K+1 and K+2. For Color BASIC, they should have been at K+2 and K+3. Also, the values being poked were 0 and 64, which is backwards. From a quick search, the MC-10s text screen starts at the 16K mark, $4000 (16384). To verify this, I went to the online MC-10 emulator here:

https://mc-10.com

…and then did POKE 16384,42. That indeed placed an inverted “*” in the top left of the text screen.

The MC-10 is a big endian processor, so the memory location should be MSB ($40) then LSB ($00). $C0 in decimal is 64 in decimal (no HEX support on the MC-10, I don’t think). So the actual pokes to make a string start at the top left corner of the text screen should have been 64 and 0 rather than 0 and 64. (That is 64*256+0 to make 16384.)

Adjusting those POKEs to be at the proper spot in VARPTR and swapping the values to MSB/LSB was the first fix.

At that point, I still wasn’t getting it working. This was due to the initial string being a “hard coded” string in BASIC. When A$=”” was declared in BASIC, it made a string that pointed into the program space. I have not looked into why, but forcing the string to be in RAM by doing A$=””+”” was all I needed to change to make this work. (NOTE TO SELF: Explore this and understand what was different about the program-space string.)

Jim posted a corrected version for the MC-10:

0 CLEAR1200:DIMC1,M$,I$,AA$,BB$:GOSUB100:GOTO20
8 M$="":C1=VARPTR(M$):POKEC1,255:POKEC1+2,64:POKEC1+3,0:AA$=M$+""
9 M$="":C1=VARPTR(M$):POKEC1,255:POKEC1+2,65:POKEC1+3,0:BB$=M$+"":RETURN
20 GOSUB8:CLS:PRINTAA$" "BB$;
60 GOTO60
100 CLS8:PRINT"THIS IS LINE ONE"
110 PRINT"THIS IS LINE TWO"
112 PRINT"THIS IS LINE THREE"
113 PRINT"THIS IS LINE FOUR"
114 PRINT"THIS IS LINE FIVE"
115 PRINT"THIS IS LINE SIX"
116 PRINT"THIS IS LINE SEVEN"
117 PRINT"THIS IS LINE EIGHT"
118 PRINT"THIS IS LINE NINE"
119 PRINT"THIS IS LINE TEN"
120 PRINT"THIS IS LINE ELEVEN"
121 PRINT"THIS IS LINE TWELVE"
122 PRINT"THIS IS LINE THIRTEEN"
123 PRINT"THIS IS LINE FOURTEEN"
124 PRINT"THIS IS LINE FIFTEEN"
125 PRINT"THIS IS LINE SIXTEEN";:RETURN

Meanwhile, I had come up with a silly program that would create some kind of image on the CoCo screen, then capture it in two strings so it could be quickly restored later. Well, almost the entire screen — a string is limited to 255 bytes so two strings captures 510 bytes of the 32×16 screen. If one were to use this trick, it could be adjusted to capture just the number of lines on the screen needed (like, the first 5 lines, or lines 10-20, etc.).

My example looked like this:

0 'SAVESCR1.BAS
10 CLEAR511:DIMS1$,S2$
11 ' 0 = LEN OF STRING
12 ' 1 = NOT USED FOR STRING
13 ' 2 = MSB OF ADDRESS
14 ' 3 = LSB OF ADDRESS
15 ' 4 = ALWAYS 0
16 ' 1024 = 4*256+0
17 ' 1279 = 4*256+255
20 REM DRAW SCREEN
25 CLS0:C=0:FOR I=0 TO 29 STEP 2
30 SET(I*2,0,C):SET(63-I*2,30,C)
35 SET(0,30-I,C):SET(63,I,C)
40 C=C+1:IF C>7 THEN C=0
50 NEXT
55 PRINT@266,"THIS";CHR$(128)"IS";CHR$(128);"COOL";
60 'SAVE SCREEN
65 GOSUB 1000
70 'WAIT FOR KEY
75 GOSUB 5000
80 'CLEAR SCREEN
85 CLS 5
90 'WAIT FOR KEY
95 GOSUB 5000
100 'RESTORE SCREEN
105 GOSUB 2000
110 GOTO 70

999 GOTO 999

1000 ' SAVE SCREEN
1005 Z$="":K=VARPTR(Z$):POKEK,255:POKEK+2,4:POKEK+3,0:S1$=Z$+""
1010 Z$="":K=VARPTR(Z$):POKEK,255:POKEK+2,4:POKEK+3,255:S2$=Z$+""
1015 RETURN

2000 ' RESTORE SCREEN
2005 PRINT@0,S1$;S2$;:RETURN

5000 ' WAIT FOR KEY
5005 IF INKEY$="" THEN 5005
5010 RETURN

I made a “save screen” subroutine at line 1000. My program starts and makes a simple splash screen (colored pixels set around the screen and a text message in the center), then calls the save screen routine which makes a temporary Z$ then modifies it to point to the start of the text screen (1024 – so values 4*256+0) and be 255 bytes long. It then copies that string to S1$. It repeats the process for the next part of the screen, which begins at 1024+255 (1279, so 4*256+255). That is saved in S2$.

Then the main program waits for a keypress, then does a CLS 5 to erase the screen to white, then after another keypress, it calls the “restore screen” subroutine which just prints the two saved strings starting at position 0 on the top left corner of the screen.

AND IT WORKS!

Now blasting bytes to the screen can be as fast as printing a string. I can think of some interesting uses for this, such as “drawing” various levels slowly during initialization, and capturing them to strings so they can be displayed later very fast.

And that gives me an idea for an old project I was playing with some years ago.

But that will have to wait for the next installment…

ASCII Kong text data

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Just posting this so I can share the link… This was a planning file from my “ASCII Kong” program I am toying with:

  ----------------------------
12345678901234567890123456789012
         H H            BONUS
         H H             3900
         H HXXXXXXX     
  OO     H H      H
  OO.....H H      H
  XXXXXXXXXXXXXXXXXXXXXXXXXX
                         H        
    XXXXXXXXXXXXXXXXXXXXXXXXXX
       H     H                           
  XXXXXXXXXXXXXXXXXXXXXXXXXX
           H     H       H            
    XXXXXXXXXXXXXXXXXXXXXXXXXX
       H       H
  XXXXXXXXXXXXXXXXXXXXXXXXXX
    U                    H
  XXXXXXXXXXXXXXXXXXXXXXXXXXXX
12345678901234567890123456789012
  ----------------------------
-----
  @ 
 <=> 
 / \
-----
@
/=
 |\
-----
   @
  =\
 /|
-----

.----------|----------|----------
1....XX.... .XX.......
2....XX.... .XX.......
3..XXXXXX.. ..XXX.....
4.X..XX..X. .X.XXX....
5...X..X... X..X.XX...
6..X....X.. ..XX..XX..

We wanted to licensed PONG in 1993

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A few years ago, I wrote a short series about my experiences growing up during the video game revolution that started in the 1970s. I hope to finally publish this series later this year, once I have time to find related video clips and photos.

But before I get to this, I thought I’d set the mood with a bit of video game-related trivia about Sub-Etha Software…

As you may know, Sub-Etha Software was not a gaming company. We mostly did application and utility software. However, we did release a graphical adventure game and a Space Invaders-style game, and did resell some games written by others.

In May 1993, at the 2nd annual “Last” Chicago CoCoFEST!, Sub-Etha Software announced something rather silly: a PONG programming contest. (Yes, Pong — the mother of all video games, released by Atari in 1972.)

According to my Fest report of that event, awards were to be given “based on memory efficiency, speed, originality, special effects, and playability for RS-DOS, OS-9, or OSK”. The winner was to be announced in October that year at the Atlanta CoCoFest.

TODO: link to fest report somewhere

I created a small OS-9 Level 2 demo program that played Pong on a text screen, along with details about the contest.

The winner was GNOP byChris Hawks of HawkSoft. This MM/1 (OS-9/68000) program kept the ball frozen in the center of the screen, while the entire box play area scrolled around it, with the paddles having to be controlled as the whole playfield moved. This was a very original take on Pong. HawkSoft made this program available for $5.

This, alone, makes for a cute story, but there’s another tidbit I do not know if I ever shared.

In 1993, Atari Corporation was still around. Their last home computer, the Atari ST, was being discontinued while the company turned its attention to a new video game system: the Atari Jaguar. The Jaguar would debut in November that year as the first home gaming system to use 64-bit chips (back in the day when the cutting edge gaming systems were all claiming 32-bit). Although the Jaguar never really caught on, it had some phenomenal games and was, at least initially, manufactured in the USA by IBM.

But I digress.

The point is, Atari was kind of between successes at the time (and actually would cease to exist just three years later when it was “reverse merged” with a hard drive manufacturer). For some reason, I thought it might be fun to contact Atari and see if I could get permission to legally use the name “Pong” for an official Color Computer version.

That’s right. I was actually trying to license Pong for the CoCo!

I contacted Atari about this (I don’t remember how, but I expect it was via a telephone call) and I recall whoever I spoke to was open to discussing a proposal, but I never pursued it further. Admittedly, I was really just wanting permission to use the name, as Sub-Etha would not have had any resources to pay any significant licensing fee. (Actually, it’s possible I may have contacted an Atari rep via the GEnie online service since they had an active presence there back then.)

I regret not following up on this silly idea. If I had been able to work something out, the CoCo could have been forever listed on the Wikipedia page as one of the only (if not the only) “official” Pong games that ever existed not done by Atari (or whoever owns them today).

Interestingly enough, Pong did make a comeback in 2012 when Atari released a 40th anniversary “Pong World” game for iOS. This version actually started out as an entry in a Pong Indie Developers Challenge where $100,000 was up for grabs to the best new versions of Pong.

Perhaps if Sub-Etha Software had offered that kind of prize (rather than the $1 we offered the winner), we would have had more entries back in 1993.

So there you have it… Another bit of “almost was” history from Sub-Etha Software. Apparently, we had a good idea, but had it 19 years too soon and without enough money to get people interested ;-)

Somehow, though, I don’t expect even the MM/1 could have pulled off any entries as fancy as some of the finalists did in 2012.

Addendum

1993 wasn’t my last encounter with Pong… While working for RadiSys, the company that bought Microware (creator of OS-9), we were working with a CPU virtualization company on a product that would allow the real-time OS-9 to run concurrently with Linux on a multi-core CPU. The idea would be the OS-9 side could be used for intense real-time operations, while Linux could be used for application level user interfaces and such.

A Pong demo was created, that showed OS-9 running one paddle and Linux running the other. (I do not recall having anything to do with this demo, but I found it amusing enough that I posted a video of it to YouTube back in 2006.)

I don’t know if this product ever came out or was ever used, but maybe the new owners of Microware OS-9 still have some Pong code kicking around their offices somewhere… ;-)

Until next time…

More misc Sub-Etha OS-9 stuff on GitHub

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I added a few more things to my Sub-Etha Software repository on GitHub:

https://github.com/allenhuffman/SubEthaSoftware

In addition to the stuff we sold commercially, there were also some random things I wrote for use on my BBS.

SEAdvSys

When I graduated high school and moved to Lufkin, Texas in 1987, a local CoCo Kid (that was actually his handle) Tim Johns had a very unique bulletin board system. I believe it was called “The Adventure System.” When you logged in, you were greeted with a text adventure interface. You could move from room to room just like in an adventure game. If the room did not exist, it offered you a chance to create the room. There was a mailbox which was used for sending messages. Great concept!

In 1993, a Commodore 64 friend, Mark Thomas, had moved on to an Amiga. He was teaching me the C programming language and did so by creating an Adventure System program for OS-9. I found that source code and uploaded it. When I get time, I will see how much of it still works. I do recall having this as an online game on my BBS at the time, and we were all recreating the local Lufkin Mall in the game ;-)

https://github.com/allenhuffman/SubEthaSoftware/tree/main/OS-9/SEAdvSys

SEBBSList

When I first discovered BBSes in Houston, Texas in the early 1980s, there was one person – Judy Scheltema – that maintained a listing of all known BBSes in town. When I moved to Lufkin, Texas in 1987, there was no such list maintainer, so I took on the task of doing it.

At some point, I wrote a C program to help me make an online list. It allows adding, editing and deleting entries. From looking at the source code, I initially wrote it in 1993, then updated it in 1995 for my MM/1 (OSK) and even made it so it could build outside of OS-9. (Most likely on an MS-DOS C compiler I had for my Toshiba laptop.)

https://github.com/allenhuffman/SubEthaSoftware/tree/main/OS-9/SEBBSList

1992 Atlanta CoCoFest Simulator

I finally found the source code to my graphical “adventure game” which featured digitized photos from the 1992 Atlanta CoCoFest. I called it a simulator because I never completed the game version. The goal would have been to get into the fest and acquire a list of items. In the version we released, there was one puzzle (getting in to the fest) and you could go around and explore and get/drop things, but it was mostly just an exploration program rather than a game.

https://github.com/allenhuffman/SubEthaSoftware/tree/main/OS-9/1992CoCoFestSimulator

Chicago 1994 Adventure

I cannot find everything I had for this one, but it was an updated graphical adventure that used images from the 1994 Chicago CoCoFest. I have posted the source code for what I had.

https://github.com/allenhuffman/SubEthaSoftware/tree/main/OS-9/Chicago1994Adventure

Cleanup in aisle five…

At some point, I would like to see if I can build any of this old code. Some items could be made to run on a modern system (macOS terminal or PC command prompt), though the pre-ANSI K&R C would need some updating.

More to come…

Vaughn Cato’s 3-D vector maze demo source code!

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A special thanks to Vaughn Cato for allowing me to share the source code to his “toast” 3-D vector maze test program, as well as his “mapgraph” bitmap scaling test program.

I have placed all of the files on my GitHub site, including the two compiled executables (“toast” and “mapgraph”) as well as the source code he sent me and his last readme. The “toast.ar” file should be the file he sent me back in 1994 that includes all of these files.

You can find them here:

https://github.com/allenhuffman/Toast

Thanks, Vaughn!

And if you are curious to what Vaughn has been up to since 1994, he apparently continues to work with computers to make things appear on screen … Check out his Internet Movie Database entry:

https://www.imdb.com/name/nm1401781

…and be sure to look for his name when watching movies like Avatar and Lord of the Rings and such ;-)

Until next time…

Vaughn Cato’s bitmap scaling demo.

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In a follow-up to my recent post about Vaughn Cato’s 3-D vector maze test for the Radio Shack Color Computer 3, there was another bit of code he sent me: a bitmap scaling test. He created a routine that would take a bitmap graphic then render it on the screen at a different width and/or height. I forget why I was interested in this topic back then, but I do know I have blogged about “scaling” on the CoCo in recent years on this site.

Here is a video of his mapgraph test program running:

The routine appears to use 6809 assembly language and C code. The idea would be you could have a bitmap image then place it on the screen at different sizes. This demo just loops “stretching” a test pattern image, but the graphic could have been anything.

One more post to come…

I may never use a #define in C again. Except when I need to.

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I have had a few glorious weeks of C coding at my day job. It is some of the best C code I have ever written, and I am quite proud of it.

During this project, I learned something new. In the past, I would commonly use #define for values such as:

#define NONE 0
#define WARNING 1
#define ERROR 2

There might be some code somewhere that made us of those values:

void HandleError (int error)
{
   case NONE:
      // All fine.
      break;

   case WARNING:
      // Handle warning.
      break;

   case ERROR:
      // Handle error
      break;

    default:
      // Handle unknown error.
      break;
}

When you use #define like that, the C pre-processor will just do simple substitutions before compiling the code — “NONE” will become “0”. Because of this, those labels mean nothing special to the compiler — they are just numbers.

But, I had learned you could use an enum and ensure a function only allows passing the enum rather than “whatever int”:

typedef enum
{
   NONE = 0,
   WARNING = 1,
   ERROR = 2
} ErrorEnum;

Now the routine can take an “ErrorEnum” as a parameter type.

void HandleError (ErrorEnum error)
{
   case NONE:
      // All fine.
      break;

   case WARNING:
      // Handle warning.
      break;

   case ERROR:
      // Handle error
      break;

    default:
      // Handle unknown error.
      break;
}

This looks nicer, since it is clear what is being passed in (whatever “ErrorEnum” is). It does not necessarily give any extra compiler warnings if you pass in an int instead, since an enum is just an int, by default.

In C, an enum is a user-defined data type that represents a set of named values. By default, the underlying data type of an enum is int, but it can be explicitly specified to be any integral type using a colon : followed by the desired type.
– ChatGPT

Thus, the compiler I am using for this test (Visual Studio, building a C program) does not complain if I do something like this:

int error = 1;
HandleError (error);

However, I just learned of an interesting benefit to using an enum for a switch/case. The compiler can warn you if you don’t have a case for all the items in the enum!

typedef enum {
	NONE,
	WARNING,
	ERROR
} ErrorEnum;

void HandleError(ErrorEnum error)
{
	switch (error)
	{
	case NONE:
		// All fine.
		break;

	case WARNING:
		// Handle warning.
		break;

}

Building that with warnings enabled reports:

enumerator 'ERROR' in switch of enum 'ErrorEnum' is not handled	CTest

How neat! I actually ran in to this when I had added some extra error types, but a routine that converted them to a text string did not have cases for the new errors.

const char *GetErrorString (ErrorEnum error)
{
   const char *errorStringPtr = "Unknown";

   switch NONE:
      errorStringPtr = "None";
      break;
}

That is a useful warning, and it found a bug/oversight.

Because of this, I will never use #defines for things like this again. Not only does a data type look more obvious in the code, the compiler can give you extra warnings.

Until next time…

Vaughn Cato’s “Toast” 3-D maze engine for CoCo OS-9 Level 2

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Wayback in the 1990s, Vaughn Cato and I were corresponding, and somehow some topics came up about rendering a 3-D maze on the CoCo.

Vaughn wrote a demo which was called toast for reasons I no longer remember. It parsed a text file representing the maze, and would let you “walk” through it using the arrow keys. The code was written in C (though there may be some assembly helper routines in there, I haven’t checked) for the Radio Shack Color Computer 3 under the OS-9 operating system.

Here is a quick demo of what toast looked like:

Here is the maze data file:

18 16
#  ##########
#           #
#           #
########### #
          # #
          # #
          # #
          # #
          # #
          # #
      ##### ######
      #          #
      #          #
      #          #
      #          #
      ############

The readme included with this version had the following notes:

Here is the latest version of the maze program.  I think that it now
always displays the walls correctly, but let me know if you find a problem.

I have also included a demo of the bitmap scaling routine.  Just run
mapgraph to try it out.

  Until Later,
  Vaughn Cato ([deleted]@st6000.sct.edu)

I will share what mapgraph does in a future post ;-)

I plan to reach out to Vaughn and ask if he would be okay with sharing the source code for this.

Until then…

Parsing message bytes in to a C structure (and back)

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In a recent article, I discussed methods to copy variables (or structure elements) in to a packed buffer, as well as parse buffer bytes back in to variables.

Doing it manually was clunky. Using my GetPutData routines made it easier to be clunky.

But today, we’ll make it super simple and far less clunky.

Defining the message bytes

Let’s start with a simple message. It will be represented by a C structure that we’d use in the program. For example, here are the elements that might be part of a “Set Date and Time” message:

typedef struct
{
    uint16_t year;
    uint8_t month;
    uint8_t day;
    uint8_t hour;
    uint8_t minute;
    uint8_t second;
    uint8_t timeZone;
    bool isDST;
} SetDateTimeMessageStruct;

The packed message would be nine bytes and look like this:

[ 0 | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 ]
  \  /    |   |   |   |   |   |   |
  year   mon day hr  min sec tz  dst

To automate this process, a lookup table is created that represents the size of each element and the offset to where it is located within the structure.

offsetof()

Inside stddef.h is a macro that is used to calculate where in the structure’s memory a particular element exists. It is a relative offset from wherever the structure variable starts in memory. Here is an example showing offsetof():

#include <stdio.h>
#include <stdlib.h>  // for EXIT_SUCCESS
#include <stdint.h>
#include <stdbool.h>
#include <stddef.h>  // for offsetof()

typedef struct
{
    uint8_t     a;
    uint16_t    b;
    bool        c;
    uint32_t    d;
    float       e;
    double      f;
} MyStruct;

int main()
{
    MyStruct test;
    
    printf ("sizeof(test) = %ld\n", sizeof(test));
    
    printf ("a is %lu bytes at offset %lu\n",
            sizeof(test.a), offsetof(MyStruct, a));
    printf ("b is %lu bytes at offset %lu\n",
            sizeof(test.b), offsetof(MyStruct, b));
    printf ("c is %lu bytes at offset %lu\n",
            sizeof(test.c), offsetof(MyStruct, c));
    printf ("d is %lu bytes at offset %lu\n",
            sizeof(test.d), offsetof(MyStruct, d));
    printf ("e is %lu bytes at offset %lu\n",
            sizeof(test.e), offsetof(MyStruct, e));
    printf ("f is %lu bytes at offset %lu\n",
            sizeof(test.f), offsetof(MyStruct, f));

    return EXIT_SUCCESS;
}

Try it: https://onlinegdb.com/GDvhi9TLq

It produces the following output:

sizeof(test) = 24
a is 1 bytes at offset 0
b is 2 bytes at offset 2
c is 1 bytes at offset 4
d is 4 bytes at offset 8
e is 4 bytes at offset 12
f is 8 bytes at offset 16

This is an example of how elements in a structure may be padded to ensure each one starts on an even-byte in memory. ‘a’ is one byte starting at offset 0, but ‘b’ doesn’t start at 1. As a 16-bit value, it has to skip a byte and start at offset 2. There are more skipped bytes after ‘c’ at offset 4. Since the next value is a 32-bit value, it skips three bytes.

If we just wrote the structure memory out (in this architecture), it would look like this:

[ 0| 1| 2| 3| 4| 5| 6| 7| 8| 9|10|11|12|13|14|15|16|17|18|19|20|21|22|23]
  |     |     |           |           |           |
  a     b--b  c           d--d--d--d  e--e--e--e  f--f--f--f--f--f--f--f

That would waste 4 bytes in that 24 byte message. Plus, if the message were parsed by a system that had different padding/alignment requirements, they wouldn’t be able to read the buffer back in to their structure variable and get the correct data.

Using offsetof() to determine where in a structure an element exists, a lookup table could be created. A C function could be written to use that table to know where to copy the data. Here’s a rough concept:

typedef struct
{
    size_t size;   // size of structure element
    size_t offset; // offset from start of structure to that element
} ElementOffsetStruct;

MyStruct test;

ElementOffsetStruct testTable[] =
{
    { sizeof(test.a), offsetof(MyStruct, a) },
    { sizeof(test.b), offsetof(MyStruct, b) },
    { sizeof(test.c), offsetof(MyStruct, c) },
    { sizeof(test.d), offsetof(MyStruct, d) },
    { sizeof(test.e), offsetof(MyStruct, e) },
    { sizeof(test.f), offsetof(MyStruct, f) },
    { 0, 0 } // end of table
};

for (int idx=0; testTable[idx].size != 0; idx++)
{
    printf ("? is %u bytes at offset %u\n",
            testTable[idx].size, testTable[idx].offset);
}

Knowing where items are in the structure allows the specific element bytes to be copied to a buffer. Something like this:

uint8_t buffer[80];
unsigned int offset;

offset = 0;
for (int idx=0; testTable[idx].size != 0; idx++)
{
    printf ("Copy %lu bytes at structure offset %lu to buffer offset %u\n",
            testTable[idx].size, testTable[idx].offset, offset);

    memcpy (buffer + offset,
        (uint8_t*)&test + testTable[idx].offset,
        testTable[idx].size);
        
    offset = offset + testTable[idx].size; 
}

“And it’s just that easy.” Running the following test program dumps the memory contents of the C structure “test” and then writes them out to a buffer using this code and then dumps the memory contents of the buffer.

#include <stdio.h>
#include <stdlib.h>  // for EXIT_SUCCESS
#include <stdint.h>
#include <stdbool.h>
#include <stddef.h>  // for offsetof()
#include <string.h>  // for memcpy()

typedef struct
{
    uint8_t     a;
    uint16_t    b;
    bool        c;
    uint32_t    d;
    float       e;
    double      f;
} MyStruct;

typedef struct
{
    size_t size;   // size of structure element
    size_t offset; // offset from start of structure to that element
} ElementOffsetStruct;

int main()
{
    MyStruct test = { 0x11, 0x2222, true, 0x33333333, 42.42, 42.42 };
    
    ElementOffsetStruct testTable[] =
    {
        { sizeof(test.a), offsetof(MyStruct, a) },
        { sizeof(test.b), offsetof(MyStruct, b) },
        { sizeof(test.c), offsetof(MyStruct, c) },
        { sizeof(test.d), offsetof(MyStruct, d) },
        { sizeof(test.e), offsetof(MyStruct, e) },
        { sizeof(test.f), offsetof(MyStruct, f) },
        { 0, 0 } // end of table
    };
    
    for (int idx=0; idx<sizeof(test); idx++)
    {
        printf ("%02x ", ((uint8_t*)&test)[idx]);
    }
    printf ("\n");

    uint8_t buffer[80];
    unsigned int offset;
    
    offset = 0;
    for (int idx=0; testTable[idx].size != 0; idx++)
    {
        printf ("Copy %lu bytes at structure offset %lu to buffer offset %u\n",
                testTable[idx].size, testTable[idx].offset, offset);
    
        memcpy (buffer + offset,
            (uint8_t*)&test + testTable[idx].offset,
            testTable[idx].size);
            
        offset = offset + testTable[idx].size; 
    }

    for (int idx=0; idx<offset; idx++)
    {
        printf ("%02x ", buffer[idx]);
    }
    printf ("\n");

    return EXIT_SUCCESS;
}

I get the following output:

11 00 22 22 01 00 00 00 33 33 33 33 14 ae 29 42 f6 28 5c 8f c2 35 45 40 
Copy 1 bytes at structure offset 0 to buffer offset 0
Copy 2 bytes at structure offset 2 to buffer offset 1
Copy 1 bytes at structure offset 4 to buffer offset 3
Copy 4 bytes at structure offset 8 to buffer offset 4
Copy 4 bytes at structure offset 12 to buffer offset 8
Copy 8 bytes at structure offset 16 to buffer offset 12
11 22 22 01 33 33 33 33 14 ae 29 42 f6 28 5c 8f c2 35 45 40

As I discovered when I figured this out, there are a few gotchas. First, the sample code here requires the structure variable to exist. This is because the macro sizeof() needs to have something to work on to determine the size:

sizeof(test.a)

I asked ChatGPT about this, and it provided me a clever workaround that worked on the structure itself rather than a variable:

sizeof(((MyStruct*)0)->a)

Looking at that, I think I get how it works. First, it is taking a memory location of 0 and casting that to be a pointer to a MyStruct. No such structure exists at memory 0, but you can cast a pointer to anywhere (even 0) as any kind of pointer you want. (Actually using a pointer that point to 0 would be bad, however.)

Then, it gets the offset of the “a” element from the structure we pretend is located at memory location 0. Let’s break that apart a bit:

sizeof(                 )
       (            )->a
        (MyStruct*)0

And this is enough to allow creating a table based on a structure, and not on a variable declared using that structure.

typedef struct
{
    uint8_t u8;
    uint32_t u32;
} SmallStruct;

ElementOffsetStruct smallTable[] =
{
    { sizeof(((SmallStruct*)0)->u8), offsetof(SmallStruct, u8) },
    { sizeof(((SmallStruct*)0)->u32), offsetof(SmallStruct, u32) },
    { 0, 0 }
};

This would allow an easy way to define the structure and a table of offsets for later use. I’d probably make the table structure const since it won’t need to change.

With this framework figured out, a reverse function could be done that would copy bytes from a buffer in to the correct offset inside the structure.

unsigned int offset;
    
offset = 0;
for (int idx=0; testTable[idx].size != 0; idx++)
{
    printf ("Copy %lu bytes at buffer offset %u to structure offset %lu\n",
            testTable[idx].size, offset, testTable[idx].offset);
    
    memcpy ((uint8_t*)&test + testTable[idx].offset,
            buffer + offset,
           testTable[idx].size);
            
    offset = offset + testTable[idx].size; 
}

And now, by creating a structure and a table of size/offsets, any structure can be written to a buffer, or decoded from a buffer.

Too. Much. Typing.

For the final touch, macros can be made to simplify building the table.

#define ENTRY(s, v) { sizeof(((s*)0)->v), offsetof(s, v) }
#define ENTRYEND    {0, 0}

Now, instead of having to type all that gibberish out, the table can be simplified:

ElementOffsetStruct testTable[] =
{
    ENTRY(MyStruct, a),
    ENTRY(MyStruct, b),
    ENTRY(MyStruct, c),
    ENTRY(MyStruct, d),
    ENTRY(MyStruct, e),
    ENTRY(MyStruct, f),
    ENTRYEND
};

And this is just what I have posted to my GitHub:

https://github.com/allenhuffman/StructureToFromBuffer

You can find a short README there that explains the two functions and how to use them. It greatly simplifies the process of creating message buffers or parsing them in to C structures that can easily be used in a program.

If you try it and find it useful, please let me know.

Until then…

The last time I saw Steve Bjork…

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On this date (4/10) in 2023, Steve Bjork passed away. I still haven’t quite come to grips with him being gone. The last time I saw him was during a visit to California in 2018. He and his wife joined us for the day at Knott’s Berry Farm. I regret not visiting again when I was in California in 2022 — but I guess I am not the only one that lost touch with folks during the Covid era.

Steve was not real fond of being in photos, which may be why I cannot find any of him from that visit … but he is in this one ;-)

Regrets are easy to accomplish.

I miss my friend. Now that there has been some time since I learned of his passing, I will try to share some stories of my Adventures with Steve.

Until then…