hertz and floats and doubles and integers

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This post is an indirect follow-up to an earlier post I made about floating point numbers and the frequency 902.1 Mhz. If you check out that original posting, there was a follow-up to it as well.

My day job is maintaining software that runs solid-state microwave generators. As such, it deals with frequencies such as 902.1 MHz or 902100000 Hz. The Windows-based generator control software initially used 32-bit floating point values to represent frequencies in MHz, such as:

float start_frequency_mhz = 902.0;
float end_frequency_mhz = 928.0;

The user interface would round frequencies to the nearest 100,000 Hz, such as 902.1 MHz or 915.4 MHz. This allowed the limitations of a 32-bit floating point to not be a problem.

Limitations of 32-bit floating point

As discussed in my 902.1 posts referenced at the start of this post, certain values cannot be represented as a 32-bit floating point. 902.1 turns into 902.099976, for example:

float mhz = 902.1;
    
printf ("mhz = %f\n", mhz);

Comparing floating point values as one would compare integers may not work as expected:

float mhz = 902.1;
if (mhz == 902.1)
{
    printf ("mhz IS 902.1\n");
}
else
{
    printf ("mhz is NOT 902.1\n");
}

Running that on a 32-bit compiler will print the message:

mhz is NOT 902.1

But if you change the variable type from float to double (64-bit floating point), that gives it enough precision for this to work:

double mhz = 902.1; // changed from float to double
printf ("mhz = %f\n", mhz);
if (mhz == 902.1)
{
    printf ("mhz IS 902.1\n");
}
else
{
    printf ("mhz is NOT 902.1\n");
}

Running that will print:

mhz IS 902.1

So, yeah. Folks who don’t do much with floating point may find this surprising. I sure did when I first learned it.

Floating point is great if you have it…

Few of the embedded systems I have programmed on were using CPUs with hardware floating point. Instead, any floating point calculations were done using a software library. Bringing in floating point library code made the program grow larger. This is not optimal when dealing with systems with limited program memory. It also made the code slower, which was not optimal on systems with slower processors.

While the Windows program, running on a modern 64-bit CPU, could use floating point easily, the embedded firmware, running on 16-bit CPUs, was written to use integers for smaller code size and faster operation. (No, of course this is not the case on every system. This is just an example you are reading on some random blog on the internet…)

Instead of trying to represent a frequency as MHz in floating point, the firmware would use a 32-bit integer as hz.

float f_mhz = 902.1; // on 64-bit Windows system
uint32_t hz = 902100000; // on 16-bit firmware

When I explain this to someone who is unfamiliar of “the problems with floating point,” I show them quick examples like this. For fun (everybody needs a hobby), tonight I wrote up a longer example that prints out the frequencies of 902 MHz to 928 MHz (matching the L-Band RF frequency used by the microwave systems at my work) in steps of .1 MHz.

The example then converts that frequency value to a float and a double, then converts each back to a 32-bit unsigned integer and prints them all out.

Some comparisons are done (float compared to double, and float converted to 32-bit integer compared to double converted to 32-bit integer) with the output marking values that differ as floating points (“F”) and/or unsigned integers (“U”).

#include <inttypes.h>   // for PRIu32
#include <stdio.h>      // for printf()
#include <stdlib.h>     // for EXIT_SUCCESS
#define MHZ_TO_HZ(f)        ((f) * 1000000UL)
#define HZ_TO_MHZ(f)        ((f) / 1000000.0)
#define FREQUENCY_START_HZ  902000000
#define FREQUENCY_END_HZ    928000000
#define FREQUENCY_STEPS_HZ     100000
int main()
{
    printf ("mhz    float       uint32_t   double      uint32_t   ==?\n"
            "-----  ----------  ---------  ----------  ---------  ---\n"
           );
           
    for (uint32_t hz=FREQUENCY_START_HZ; hz <= FREQUENCY_END_HZ; 
         hz+=FREQUENCY_STEPS_HZ)
    {
        float       mhz_as_float = HZ_TO_MHZ(hz);
        double      mhz_as_double = HZ_TO_MHZ(hz);
        
        uint32_t    mhz_float_as_u32 = MHZ_TO_HZ(mhz_as_float);
        uint32_t    mhz_double_as_u32 = MHZ_TO_HZ(mhz_as_double);
        
        printf ("%.1f  %f  %9" PRIu32 "  %f  %9" PRIu32 "  ",
                HZ_TO_MHZ(hz),
                mhz_as_float, mhz_float_as_u32,
                mhz_as_double, mhz_double_as_u32
               );
    
        // Do floating points match?
        if (mhz_as_float != mhz_as_double)
        {
            printf ("F");
        }
        else
        {
            printf (" ");
        }
    
        // Do converted U32s match?
        if (mhz_float_as_u32 != mhz_double_as_u32)
        {
            printf (" U");
        }
    
        printf ("\n");
    }
    return EXIT_SUCCESS;
}

And here is the output:

mhz    float       uint32_t   double      uint32_t   ==?
-----  ----------  ---------  ----------  ---------  ---
902.0  902.000000  902000000  902.000000  902000000   
902.1  902.099976  902099968  902.100000  902100000  F U
902.2  902.200012  902200000  902.200000  902200000  F
902.3  902.299988  902299968  902.300000  902300000  F U
902.4  902.400024  902400000  902.400000  902400000  F
902.5  902.500000  902499968  902.500000  902500000    U
902.6  902.599976  902600000  902.600000  902600000  F
902.7  902.700012  902700032  902.700000  902700000  F U
902.8  902.799988  902800000  902.800000  902800000  F
902.9  902.900024  902900032  902.900000  902900000  F U
903.0  903.000000  903000000  903.000000  903000000   
903.1  903.099976  903099968  903.100000  903100000  F U
903.2  903.200012  903200000  903.200000  903200000  F
903.3  903.299988  903299968  903.300000  903300000  F U
903.4  903.400024  903400000  903.400000  903400000  F
903.5  903.500000  903500032  903.500000  903500000    U
903.6  903.599976  903600000  903.600000  903600000  F
903.7  903.700012  903700032  903.700000  903700000  F U
903.8  903.799988  903800000  903.800000  903800000  F
903.9  903.900024  903900032  903.900000  903900000  F U
904.0  904.000000  904000000  904.000000  904000000   
904.1  904.099976  904099968  904.100000  904100000  F U
904.2  904.200012  904200000  904.200000  904200000  F
904.3  904.299988  904299968  904.300000  904300000  F U
904.4  904.400024  904400000  904.400000  904400000  F
904.5  904.500000  904499968  904.500000  904500000    U
904.6  904.599976  904600000  904.600000  904600000  F
904.7  904.700012  904700032  904.700000  904700000  F U
904.8  904.799988  904800000  904.800000  904800000  F
904.9  904.900024  904900032  904.900000  904900000  F U
905.0  905.000000  905000000  905.000000  905000000   
905.1  905.099976  905099968  905.100000  905100000  F U
905.2  905.200012  905200000  905.200000  905200000  F
905.3  905.299988  905299968  905.300000  905300000  F U
905.4  905.400024  905400000  905.400000  905400000  F
905.5  905.500000  905500032  905.500000  905500000    U
905.6  905.599976  905600000  905.600000  905600000  F
905.7  905.700012  905700032  905.700000  905700000  F U
905.8  905.799988  905800000  905.800000  905800000  F
905.9  905.900024  905900032  905.900000  905900000  F U
906.0  906.000000  906000000  906.000000  906000000   
906.1  906.099976  906099968  906.100000  906100000  F U
906.2  906.200012  906200000  906.200000  906200000  F
906.3  906.299988  906299968  906.300000  906300000  F U
906.4  906.400024  906400000  906.400000  906400000  F
906.5  906.500000  906499968  906.500000  906500000    U
906.6  906.599976  906600000  906.600000  906600000  F
906.7  906.700012  906700032  906.700000  906700000  F U
906.8  906.799988  906800000  906.800000  906800000  F
906.9  906.900024  906900032  906.900000  906900000  F U
907.0  907.000000  907000000  907.000000  907000000   
907.1  907.099976  907099968  907.100000  907100000  F U
907.2  907.200012  907200000  907.200000  907200000  F
907.3  907.299988  907299968  907.300000  907300000  F U
907.4  907.400024  907400000  907.400000  907400000  F
907.5  907.500000  907500032  907.500000  907500000    U
907.6  907.599976  907600000  907.600000  907600000  F
907.7  907.700012  907700032  907.700000  907700000  F U
907.8  907.799988  907800000  907.800000  907800000  F
907.9  907.900024  907900032  907.900000  907900000  F U
908.0  908.000000  908000000  908.000000  908000000   
908.1  908.099976  908099968  908.100000  908100000  F U
908.2  908.200012  908200000  908.200000  908200000  F
908.3  908.299988  908299968  908.300000  908300000  F U
908.4  908.400024  908400000  908.400000  908400000  F
908.5  908.500000  908499968  908.500000  908500000    U
908.6  908.599976  908600000  908.600000  908600000  F
908.7  908.700012  908700032  908.700000  908700000  F U
908.8  908.799988  908800000  908.800000  908800000  F
908.9  908.900024  908900032  908.900000  908900000  F U
909.0  909.000000  909000000  909.000000  909000000   
909.1  909.099976  909099968  909.100000  909100000  F U
909.2  909.200012  909200000  909.200000  909200000  F
909.3  909.299988  909299968  909.300000  909300000  F U
909.4  909.400024  909400000  909.400000  909400000  F
909.5  909.500000  909500032  909.500000  909500000    U
909.6  909.599976  909600000  909.600000  909600000  F
909.7  909.700012  909700032  909.700000  909700000  F U
909.8  909.799988  909800000  909.800000  909800000  F
909.9  909.900024  909900032  909.900000  909900000  F U
910.0  910.000000  910000000  910.000000  910000000   
910.1  910.099976  910099968  910.100000  910100000  F U
910.2  910.200012  910200000  910.200000  910200000  F
910.3  910.299988  910299968  910.300000  910300000  F U
910.4  910.400024  910400000  910.400000  910400000  F
910.5  910.500000  910499968  910.500000  910500000    U
910.6  910.599976  910600000  910.600000  910600000  F
910.7  910.700012  910700032  910.700000  910700000  F U
910.8  910.799988  910800000  910.800000  910800000  F
910.9  910.900024  910900032  910.900000  910900000  F U
911.0  911.000000  911000000  911.000000  911000000   
911.1  911.099976  911099968  911.100000  911100000  F U
911.2  911.200012  911200000  911.200000  911200000  F
911.3  911.299988  911299968  911.300000  911300000  F U
911.4  911.400024  911400000  911.400000  911400000  F
911.5  911.500000  911500032  911.500000  911500000    U
911.6  911.599976  911600000  911.600000  911600000  F
911.7  911.700012  911700032  911.700000  911700000  F U
911.8  911.799988  911800000  911.800000  911800000  F
911.9  911.900024  911900032  911.900000  911900000  F U
912.0  912.000000  912000000  912.000000  912000000   
912.1  912.099976  912099968  912.100000  912100000  F U
912.2  912.200012  912200000  912.200000  912200000  F
912.3  912.299988  912299968  912.300000  912300000  F U
912.4  912.400024  912400000  912.400000  912400000  F
912.5  912.500000  912499968  912.500000  912500000    U
912.6  912.599976  912600000  912.600000  912600000  F
912.7  912.700012  912700032  912.700000  912700000  F U
912.8  912.799988  912800000  912.800000  912800000  F
912.9  912.900024  912900032  912.900000  912900000  F U
913.0  913.000000  913000000  913.000000  913000000   
913.1  913.099976  913099968  913.100000  913100000  F U
913.2  913.200012  913200000  913.200000  913200000  F
913.3  913.299988  913299968  913.300000  913300000  F U
913.4  913.400024  913400000  913.400000  913400000  F
913.5  913.500000  913500032  913.500000  913500000    U
913.6  913.599976  913600000  913.600000  913600000  F
913.7  913.700012  913700032  913.700000  913700000  F U
913.8  913.799988  913800000  913.800000  913800000  F
913.9  913.900024  913900032  913.900000  913900000  F U
914.0  914.000000  914000000  914.000000  914000000   
914.1  914.099976  914099968  914.100000  914100000  F U
914.2  914.200012  914200000  914.200000  914200000  F
914.3  914.299988  914299968  914.300000  914300000  F U
914.4  914.400024  914400000  914.400000  914400000  F
914.5  914.500000  914499968  914.500000  914500000    U
914.6  914.599976  914600000  914.600000  914600000  F
914.7  914.700012  914700032  914.700000  914700000  F U
914.8  914.799988  914800000  914.800000  914800000  F
914.9  914.900024  914900032  914.900000  914900000  F U
915.0  915.000000  915000000  915.000000  915000000   
915.1  915.099976  915099968  915.100000  915100000  F U
915.2  915.200012  915200000  915.200000  915200000  F
915.3  915.299988  915299968  915.300000  915300000  F U
915.4  915.400024  915400000  915.400000  915400000  F
915.5  915.500000  915500032  915.500000  915500000    U
915.6  915.599976  915600000  915.600000  915600000  F
915.7  915.700012  915700032  915.700000  915700000  F U
915.8  915.799988  915800000  915.800000  915800000  F
915.9  915.900024  915900032  915.900000  915900000  F U
916.0  916.000000  916000000  916.000000  916000000   
916.1  916.099976  916099968  916.100000  916100000  F U
916.2  916.200012  916200000  916.200000  916200000  F
916.3  916.299988  916299968  916.300000  916300000  F U
916.4  916.400024  916400000  916.400000  916400000  F
916.5  916.500000  916499968  916.500000  916500000    U
916.6  916.599976  916600000  916.600000  916600000  F
916.7  916.700012  916700032  916.700000  916700000  F U
916.8  916.799988  916800000  916.800000  916800000  F
916.9  916.900024  916900032  916.900000  916900000  F U
917.0  917.000000  917000000  917.000000  917000000   
917.1  917.099976  917099968  917.100000  917100000  F U
917.2  917.200012  917200000  917.200000  917200000  F
917.3  917.299988  917299968  917.300000  917300000  F U
917.4  917.400024  917400000  917.400000  917400000  F
917.5  917.500000  917500032  917.500000  917500000    U
917.6  917.599976  917600000  917.600000  917600000  F
917.7  917.700012  917700032  917.700000  917700000  F U
917.8  917.799988  917800000  917.800000  917800000  F
917.9  917.900024  917900032  917.900000  917900000  F U
918.0  918.000000  918000000  918.000000  918000000   
918.1  918.099976  918099968  918.100000  918100000  F U
918.2  918.200012  918200000  918.200000  918200000  F
918.3  918.299988  918299968  918.300000  918300000  F U
918.4  918.400024  918400000  918.400000  918400000  F
918.5  918.500000  918499968  918.500000  918500000    U
918.6  918.599976  918600000  918.600000  918600000  F
918.7  918.700012  918700032  918.700000  918700000  F U
918.8  918.799988  918800000  918.800000  918800000  F
918.9  918.900024  918900032  918.900000  918900000  F U
919.0  919.000000  919000000  919.000000  919000000   
919.1  919.099976  919099968  919.100000  919100000  F U
919.2  919.200012  919200000  919.200000  919200000  F
919.3  919.299988  919299968  919.300000  919300000  F U
919.4  919.400024  919400000  919.400000  919400000  F
919.5  919.500000  919500032  919.500000  919500000    U
919.6  919.599976  919600000  919.600000  919600000  F
919.7  919.700012  919700032  919.700000  919700000  F U
919.8  919.799988  919800000  919.800000  919800000  F
919.9  919.900024  919900032  919.900000  919900000  F U
920.0  920.000000  920000000  920.000000  920000000   
920.1  920.099976  920099968  920.100000  920100000  F U
920.2  920.200012  920200000  920.200000  920200000  F
920.3  920.299988  920299968  920.300000  920300000  F U
920.4  920.400024  920400000  920.400000  920400000  F
920.5  920.500000  920499968  920.500000  920500000    U
920.6  920.599976  920600000  920.600000  920600000  F
920.7  920.700012  920700032  920.700000  920700000  F U
920.8  920.799988  920800000  920.800000  920800000  F
920.9  920.900024  920900032  920.900000  920900000  F U
921.0  921.000000  921000000  921.000000  921000000   
921.1  921.099976  921099968  921.100000  921100000  F U
921.2  921.200012  921200000  921.200000  921200000  F
921.3  921.299988  921299968  921.300000  921300000  F U
921.4  921.400024  921400000  921.400000  921400000  F
921.5  921.500000  921500032  921.500000  921500000    U
921.6  921.599976  921600000  921.600000  921600000  F
921.7  921.700012  921700032  921.700000  921700000  F U
921.8  921.799988  921800000  921.800000  921800000  F
921.9  921.900024  921900032  921.900000  921900000  F U
922.0  922.000000  922000000  922.000000  922000000   
922.1  922.099976  922099968  922.100000  922100000  F U
922.2  922.200012  922200000  922.200000  922200000  F
922.3  922.299988  922299968  922.300000  922300000  F U
922.4  922.400024  922400000  922.400000  922400000  F
922.5  922.500000  922499968  922.500000  922500000    U
922.6  922.599976  922600000  922.600000  922600000  F
922.7  922.700012  922700032  922.700000  922700000  F U
922.8  922.799988  922800000  922.800000  922800000  F
922.9  922.900024  922900032  922.900000  922900000  F U
923.0  923.000000  923000000  923.000000  923000000   
923.1  923.099976  923099968  923.100000  923100000  F U
923.2  923.200012  923200000  923.200000  923200000  F
923.3  923.299988  923299968  923.300000  923300000  F U
923.4  923.400024  923400000  923.400000  923400000  F
923.5  923.500000  923500032  923.500000  923500000    U
923.6  923.599976  923600000  923.600000  923600000  F
923.7  923.700012  923700032  923.700000  923700000  F U
923.8  923.799988  923800000  923.800000  923800000  F
923.9  923.900024  923900032  923.900000  923900000  F U
924.0  924.000000  924000000  924.000000  924000000   
924.1  924.099976  924099968  924.100000  924100000  F U
924.2  924.200012  924200000  924.200000  924200000  F
924.3  924.299988  924299968  924.300000  924300000  F U
924.4  924.400024  924400000  924.400000  924400000  F
924.5  924.500000  924499968  924.500000  924500000    U
924.6  924.599976  924600000  924.600000  924600000  F
924.7  924.700012  924700032  924.700000  924700000  F U
924.8  924.799988  924800000  924.800000  924800000  F
924.9  924.900024  924900032  924.900000  924900000  F U
925.0  925.000000  925000000  925.000000  925000000   
925.1  925.099976  925099968  925.100000  925100000  F U
925.2  925.200012  925200000  925.200000  925200000  F
925.3  925.299988  925299968  925.300000  925300000  F U
925.4  925.400024  925400000  925.400000  925400000  F
925.5  925.500000  925500032  925.500000  925500000    U
925.6  925.599976  925600000  925.600000  925600000  F
925.7  925.700012  925700032  925.700000  925700000  F U
925.8  925.799988  925800000  925.800000  925800000  F
925.9  925.900024  925900032  925.900000  925900000  F U
926.0  926.000000  926000000  926.000000  926000000   
926.1  926.099976  926099968  926.100000  926100000  F U
926.2  926.200012  926200000  926.200000  926200000  F
926.3  926.299988  926299968  926.300000  926300000  F U
926.4  926.400024  926400000  926.400000  926400000  F
926.5  926.500000  926499968  926.500000  926500000    U
926.6  926.599976  926600000  926.600000  926600000  F
926.7  926.700012  926700032  926.700000  926700000  F U
926.8  926.799988  926800000  926.800000  926800000  F
926.9  926.900024  926900032  926.900000  926900000  F U
927.0  927.000000  927000000  927.000000  927000000   
927.1  927.099976  927099968  927.100000  927100000  F U
927.2  927.200012  927200000  927.200000  927200000  F
927.3  927.299988  927299968  927.300000  927300000  F U
927.4  927.400024  927400000  927.400000  927400000  F
927.5  927.500000  927500032  927.500000  927500000    U
927.6  927.599976  927600000  927.600000  927600000  F
927.7  927.700012  927700032  927.700000  927700000  F U
927.8  927.799988  927800000  927.800000  927800000  F
927.9  927.900024  927900032  927.900000  927900000  F U
928.0  928.000000  928000000  928.000000  928000000

In the last column, F means that the float (32-bit) floating point and the double (64-bit) floating point do not match. U means the float (32-bit) converted to 32-bit integer does not match the double (64-bit) converted to integer.

All this to say, as I am beginning to experiment with new routines dealing with frequencies, I am creating all of them to handle those frequencies as Hz using 32-bit unsigned integers. This will allow these routines to also work well on embedded systems that lack floating point hardware, as well as ensure any weird “902.1” issues won’t cause someone else to waste hours of their time dealing with some math that is slightly off. . .

To be continued…

Color BASIC, Juan Castro and “forbidden” variables

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Over the years I have shared many tidbits about Color BASIC.

This is another one.

A recent post by Juan Castro to the Groups.IO Color Computer mailing list caught my attention, mostly because he called me out by name in the subject line:

https://groups.io/g/ColorComputer/message/312

Color BASIC variable name limits

As a reminder, Color BASIC allows 1 or 2 character variable names. They must start with a letter (A-Z) and the second character can be either letter (A-Z) or number (A-0). BUT, the BASIC interpreter does let you type longer names for variables, but it only honors the first two characters. Here is a screenshot from a past blog post here (which I’d link to if I was not so lazy):

Color BASIC variables may be very long, but only the first two characters are used.

This is a reminder that, if you try to use variables longer than two characters, you have to make sure you always keep the first two characters unique since “LONGVARIABLE” and “LOST” and “LO” are all the same variable to BASIC.

…but not all variable name limits are the same.

To break the rule I just said, in Color BASIC, some variable names are forbidden. A forbidden variable is one you cannot use because it is already reserved for a keyword or token. For example, FOR is a keyword:roar

FOR I=1 TO 10
PRINT I
NEXT I

Because of this, even though BASIC only honors the first two characters of a variable name, you still cannot use “FOR” as a variable.

FOR=42
?SN ERROR

But you can use “FO”, since that is not long enough to be recognized as a BASIC token or keyword.

FO=42
PRINT FO
42

There are a number of two-character tokens, such as “TO” in the FOR/NEXT statement (“FOR I=1 TO 10”), and “AS” in the Disk BASIC FIELD statement (“FIELD #1,5 AS A$”), as well as “FN” which is used in DEF FN.

AS=42
?SN ERROR

FN=42
?SN ERROR

TO=42
?SN ERROR

This means if you wrote something for Color BASIC or Extended Color BASIC that uses “AS” as a variable, that would not work under Disk Extended Color BASIC.

BASIC ignores spaces

In recent years, someone pointed me to the fact that when scanning a BASIC line (either type in directly or when parsing a line of code in a program), spaces get ignored by the scanner. This means:

N M = 42
PRINT N M
42

That one surprised me when I learned it. This is probably why, when printing two variables, a semicolon is required between them:

N = 10
M = 20
PRINT N;M
10  20

And if you had done this (remember to CLEAR between these tests so variables are erased each time):

N = 10
M = 20
NM = 30
PRINT N M
30
PRINT N;M;N M
10  20  30

By the way, if you have ever wondered about that space printed in front of numeric variables when you do things like “PRINT X”, I covered why this happens in an earlier blog and included a simple patch to BASIC that removes that feature.

How to turn a forbidden variable into a non-forbidden one for fun and profit

Well, Juan Casto showed that using this “BASIC ignores spaces” quirk as a way to use forbidden variables. From his post:

Now it seems obvious. BASIC’s interpreter looks for keywords like “FOR” and will not recognize “F O R” or “FO R” as that token. The detokenizer honors the spaces.

But when it comes to variables, the spaces are ignored by the parser, so “T O” will not match as a token for “TO”, but will be processed as a variable “TO”.

Go figure.

Admittedly, space in two-character variable names look silly, but now I can finally update my old *ALLRAM* BBS to use the variable “TO$” for who a message is to:

FR$="ALLEN HUFFMAN"
T O$="JUAN CASTRO"
SB$="THAT'S REALLY COOL"

Though why would you want to do that… (Please click on that link. That’s a web domain I own… ;)

Not invented here

I suspect this was discovered by the early pioneers of BASIC, likely soon after the original Color Computer was released in 1980. If you know of a reference to this behavior from some early newsletter or magazine article, please let me know.

And as to Juan … thanks for sending me down a BASIC rabbit hole again…

Until next time…

SPI and interrupts and PIC24

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How did this ever work: SPI and interrupts

Over the years, I have posted about things that fall into the category of “how did this ever work?” I think I need to make an actual WordPress Category on this blog for these items, and I will do so with this post.

Every embedded programming job I have had came with a bunch of pre-existing code that “worked.” There are always new features to be added, and bugs to be fixed, but overall things were already at an “it works, ship it” state.

And every embedded programming job I have had came with code that “works” but decided to not work later, leading me down a rabbit hole of code exploring to understand what it did and why it was suddenly did not.

This was often followed by finding a problem in the code that made me wonder how it ever worked in the first place.

SPI and interrupts on the PIC24 processor

This post is not specifically about SPI and interrupts on the PIC24 processor. I just happened to run into this particular issue in that environment.

On the seven hardware systems I maintain code for, there are various devices such as ADC, DAC, EEPROM, attenuators, phase shifters, frequency synthesizers, etc. that are hooked up to the CPU using I/O, I2C or SPI bus.

In the code main loop, the firmware reads or writes to these devices as needed, such as sampling RF detectors or making adjustments to power control attenuators.

Recently, we were testing a pulse modulation mode (PWM) where the RF signal is turning on and off. When on, the power is measured (detector read) inside an interrupt that was tied to the PWM signal. This code has been in place since before I joined 6+ years ago and, other than some bugs and enhancements along the way, “it works.”

However, this SPI code ended up being the cause of some odd problems that initially looked like I2C communications were failing. Our Windows-based host program that communicated over I2C would start having communication faults with the boards running firmware.

After a few days of Whac-A-Mole(tm) trying to rework things that could be problematic, I finally learned the root cause of the issue:

SPI and interrupts

The main loop was doing SPI operations (in our case, using the CCS PCD compiler and its API calls such as spi_init, spi_xfer, etc.). One of those SPI operations was for reading RF detectors. When PWM mode was enabled, the an interrupt service routine would be enabled and the main loop RF detectors reads would shut off and we would begin reading the RF detectors inside the interrupt routine as each pulse happened.

When a SPI operation happens, the code may need to reconfigure the SPI hardware between MODE 0 and MODE 1 transfers, for example, or to change the baud rate.

If the main code configured the SPI hardware for a specific mode and baud then began doing some SPI transfers and the pulse occurred, code would jump into the interrupt routine which might have to reconfigure the hardware differently and then read the detectors. Upon completion, execution returned back to the main loop and the SPI hardware could be in the wrong mode to complete that transaction.

Bad things would happen.

But why now?

The original code allowed pulsing at 100 Hz to 1000 Hz. This meant than 100 to 1000 times a second there was a chance that the SPI hardware could get messed up by the interrupt code. Yet, if we saw this happen, it was infrequent enough to be noticed.

At some point, I modified the code to support 10,000 Hz. This meant there was now 10,000 times a second that the problem could happen.

Over the years we had seen some issues at 10,000 Hz, including what we thought was RF interference causing communication problems (and solved through a hardware modification). Since this mode was rarely used, the true depth of the issue was never experienced.

“It works.”

Simple solutions…

A very simple solution was added which appears to have eliminated this issue completely. Some functions where added that could be called from the main loop code around any access to the SPI hardware. Here is a pseudo-code example of what I added:

volatile int g_spi_lock = 1;

void spi_claim (void)
{
    interrupts_disable (INT_EXT0); // Disable PWM interrupt.

    g_spi_lock = 1; // Flag SPI in use.

    interrupts_enable (INT_EXT0); // Re-enable PWM interrupt.
}

void spi_release (void)
{
    interrupts_disable (INT_EXT0); // Disable PWM interrupt.

    g_spi_lock = 0; // Flag SPI available.

    interrupts_enable (INT_EXT0); // Re-enable PWM interrupt.
}

Then, inside the interrupt service routine, that code could simply check that flag and skip reading at that pulse, knowing it would just catch the next one (I said this was the simple fix, not the best fix):

void pwm_isr (void)
{
    if (0 == g_spi_lock) // SPI is free.
    {
        // Do SPI stuff…
    }
}

Then all I had to do was add the claim and release around all the non-ISR SPI code…

spi_claim ();

output_high (chip_select_pin);
spi_init (xxx);
msb = spi_xfer (xxx);
lab = spi_xfer (xxx);
output_low (chip_select_pin);

spi_release ();

“And just like that,” the problems all went away. Many of the problems we had been unaware of since some — like doing an EEPROM read — were typically not done while a system was running with RF enabled and pulsing active. Once I learned what the problem was, I could recreate it within seconds just by doing various things that caused SPI activity while in PWM mode. ;-)

That was my quick-and-dirty first, but you may know a better one. If you feel like sharing it in a comment, please do so.

But the question remains…

How did this ever work?

Once the bug was understood, recreating it was simple. Yet, this code has been in use for years and “it worked.”

My next task is going to be reviewing all the other firmware projects and seeing if any of them do any type of SPI or I2C stuff from an interrupt that could mess up similar code happening from the main loop.

And I bet I find some.

In code that “just works” and has been working for years.

Until next time…

Interfacing assembly with BASIC via DEFUSR, part 8

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See also: part 1, part 2, part 3, part 4, part 5, part 6, part 7 and part 8.

Just when I thought I was out, they pull me back in.

In part 3 I showed a simple assembly language routine that would uppercase a string.

In part 5, this routine was made more better by contributions from commenters.

Today, I revisit this code and update it to use “what I now know” (thank you, Sean Conner) about being able to pass strings into a USR function without using VARPTR.

First, here is the code from part 5:

* UCASE.ASM v1.01
* by Allen C. Huffman of Sub-Etha Software
* www.subethasoftware.com / alsplace@pobox.com
*
* 1.01 a bit smaller per Simon Jonassen
*
* DEFUSRx() uppercase output function
*
* INPUT:   VARPTR of a string
* RETURNS: # chars processed
*
* EXAMPLE:
*   CLEAR 200,&H3F00
*   DEFUSR0=&H3F00
*   A$="Print this in uppercase."
*   PRINT A$
*   A=USR0(VARPTR(A$))
*
ORGADDR     EQU     $3f00

GIVABF      EQU     $B4F4   * 46324
INTCNV      EQU     $B3ED   * 46061
CHROUT      EQU     $A002

            opt	    6809    * 6809 instructions only
            opt	    cd      * cycle counting

            org     ORGADDR

start       jsr     INTCNV  * get passed in value in D
            tfr     d,x     * move value (varptr) to X
            ldy     2,x     * load string addr to Y
            beq     null    * exit if strlen is 0
            ldb     ,x      * load string len to B
            ldx     #0      * clear X (count of chars conv)

loop        lda     ,y+	    * get next char, inc Y
;	        lda     ,y      * load char in A
            cmpa    #'a     * compare to lowercase A
            blt     nextch  * if less, no conv needed
            cmpa    #'z     * compare to lowercase Z
            bgt     nextch  * if greater, no conv needed
lcase       suba    #32     * subtract 32 to make uppercase
            leax    1,x     * inc count of chars converted
nextch      jsr     [CHROUT] * call ROM output character routine
;           leay    1,y     * increment Y pointer
cont        decb            * decrement counter
            bne	    loop    * not done yet
;           beq     exit    * if 0, go to exit
;           bra     loop    * go to loop

exit        tfr     x,d     * move chars conv count to D
            jmp     GIVABF  * return to caller

null        ldd     #-1     * load -2 as error
return      jmp     GIVABF  * return to caller

* lwasm --decb -o ucase2.bin ucase2.asm -l
* lwasm --decb -f basic -o ucase2.bas ucase2.asm -l
* lwasm --decb -f ihex -o ucase2.hex ucase2.asm -l
* decb copy -2 -r ucase2.bin ../Xroar/dsk/DRIVE0.DSK,UCASE2.BIN

In the header comment you can see an example of the usage, and that it involved using VARPTR on a string to get the string’s descriptor location in memory, then pass that address into the USR function.

Did you ever register CoCo software?

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In a Discord discussion with Wayne Campbell, the topic of software registrations came up. Did you ever register any CoCo stuff?

Here is the one we sent out with our stuff…

            /) Sub-Etha Software Registration/Information Sheet (\

       Information aquired from this questionaire will be used for product
       registration, free software drawings, and informational mail outs.


Product ........... ___________________________________  Serial # ___________


Name .............. _________________________________________________________

Address ........... _________________________________________________________

City, State, Zip .. _________________________________________________________

Telephone Number .. ( ______ ) ______ - ________


Computer(s)         Memory              Storage             Monitor
[_] CoCo 1/2        [_] 64K/Less        [_] Cassette        [_] Television
[_] CoCo 3          [_] 128K            [_] Disk Drive      [_] Clr Composite
[_] MM/1            [_] 512K            [_] Hard Drive      [_] RGB Color

Other(s) .......... __________________________________________________________


Expansion
[_] RS-232 Pak      [_] MultiPak        [_] ______________  [_] ______________


Accessories
[_] Printer ....... ___________________ [_] Modem ......... __________________
                    (Type)                                  (Baud)


What do you use your computer for?
[_] Word Processing [_] Businesss       [_] Games/Fun       [_] Telecom
[_] Programming     [_] Home Apps.      [_] Music/MIDI      [_] Graphics

[_] Other(s) ...... __________________________________________________________


Which Operating System/Language(s) do you use?
[_] RS-DOS          [_] Basic           [_] Assembly        [_] 'C'
[_] OS-9/OSK/Etc.   [_] Basic09         [_] OS9 Assembly    [_] Pascal

[_] Other(s) ...... __________________________________________________________


What type of software would you like to see for the CoCo or OS-9?

______________________________________________________________________________

______________________________________________________________________________

______________________________________________________________________________

Sub-Etha Software -/- P.O. Box 152442 -/- Lufkin, TX  75915 -/- (815) 748-6638

The next time I go through my Sub-Etha Software archives, I am going to see if I can find any of these that folks actually sent in.

CoCo Disk BASIC disk structure – part 4

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I did a thing.

I wrote a BASIC program which will create 68 files named “0.TXT” to “67.TXT”. Each file is 2304 bytes so it takes up a full granule. (That is not really important. It just helps makes things obvious if you look at the disk with a hex editor and want to know which file is at which sector.)

After making these files, it uses code from some of my other examples to scan through the directory and display it (FILEGRAN.BAS code, shown later in this post) and then it scans the directory and prints which granule each 1-gran file is using.

I can start with a freshly formatted disk then run this program and see where RS-DOS put each file.

Will it match the order RS-DOS used when making one huge file that takes up all 68 grans? Let’s find out…

10 '68FILES.BAS
20 PRINT "RUN THIS ON A BLANK DISK."
30 INPUT "DRIVE #";DR
40 'SWITCH TO THAT DRIVE
50 DRIVE DR
60 'GOTO 140
70 'MAKE FILES 0-67
80 FOR G=0 TO 67
90 F$=MID$(STR$(G),2)+".TXT"
100 PRINT "MAKING ";F$;
110 OPEN "O",#1,F$
120 CLOSE #1:PRINT
130 NEXT
140 'FILEGRAN.BAS
150 'DIR WITHOUT FILE SIZES
160 CLEAR 512:DIM SP$(1)
170 ' S - SECTOR NUMBER
180 FOR S=3 TO 11
190 ' SP$(0-1) - SECTOR PARTS
200 DSKI$ DR,17,S,SP$(0),SP$(1)
210 ' P - PART OF SECTOR
220 FOR P=0 TO 1
230 ' E - DIR ENTRY (4 P/SECT.)
240 FOR E=0 TO 3
250 ' GET 32 BYTE DIR ENTRY
260 DE$=MID$(SP$(P),1+E*32,32)
270 ' FB - FIRST BYTE OF NAME
280 FB=ASC(LEFT$(DE$,1))
290 ' SKIP DELETED FILES
300 IF FB=0 THEN 440
310 ' WHEN 255, DIR IS DONE
320 IF FB=255 THEN 470
330 ' PRINT NAME AND EXT.
340 'PRINT LEFT$(DE$,8);TAB(9);MID$(DE$,9,3);
350 ' FIRST TWO CHARS ONLY
360 PRINT LEFT$(DE$,2);"-";
361 'PRINT #-2,LEFT$(DE$,2);",";
370 ' FILE TYPE
380 'PRINT TAB(13);ASC(MID$(DE$,12,1));
390 ' BINARY OR ASCII
400 'IF ASC(MID$(DE$,13,1))=0 THEN PRINT "B"; ELSE PRINT "A";
410 ' STARTING GRANULE
420 PRINT USING("##  ");ASC(MID$(DE$,14,1));
421 'PRINT #-2,ASC(MID$(DE$,14,1))
430 CL=CL+1:IF CL=5 THEN CL=0:PRINT
440 NEXT
450 NEXT
460 NEXT
470 END

I modified this program to output to the printer (PRINT #-2) and then capture that output in the Xroar emulator in a text file. That gave me data which I put in a spreadsheet.

Next, I used a second program on a freshly formatted disk to create one big file fully filling up the disk. (The very last PRINT to the file will create a ?DF ERROR, which I now think is a bug. It should not do that until I try to write the next byte, I think.)

10 '1BIGFILE.BAS
20 PRINT"RUN THIS ON A BLANK DISK."
30 INPUT "DRIVE #";DR
40 'SWITCH TO THAT DRIVE
50 DRIVE DR
60 'MAKE ONE BIG 68 GRAN FILE
70 OPEN "O",#1,"1BIGFILE.TXT"
80 FOR G=0 TO 67
90 PRINT G;
100 T$=STRING$(128,G)
110 FOR T=1 TO 18
120 PRINT ".";
130 PRINT #1,T$;
140 NEXT
150 PRINT
160 NEXT
170 CLOSE #1
180 END

I ran another test program which would read the directory, then print out the granule chain of each file on the disk.

10 ' FILEGRAN.BAS
20 '
30 ' 0.0 2025-11-20 BASED ON FILEINFO.BAS
40 '
50 ' E$(0-1) - SECTOR HALVES
60 ' FT$ - FILE TYPE STRINGS
70 '
80 CLEAR 1500:DIM E$(1),FT$(3)
90 FT$(0)="BPRG":FT$(1)="BDAT":FT$(2)="M/L ":FT$(3)="TEXT "
100 '
110 ' DIR HOLDS UP TO 72 ENTRIES
120 '
130 ' NM$ - NAME
140 ' EX$ - EXTENSION
150 ' FT - FILE TYPE (0-3)
160 ' AF - ASCII FLAG (0/255)
170 ' FG - FIRST GRANULE #
180 ' BU - BYTES USED IN LAST SECTOR
190 ' SZ - FILE SIZE
200 ' GM - GRANULE MAP
210 '
220 DIM NM$(71),EX$(71),FT(71),AF(71),FG(71),BU(71),SZ(71),GM(67)
230 '
240 INPUT "DRIVE";DR
250 '
260 ' FILE ALLOCATION TABLE
270 ' 68 GRANULE ENTRIES
280 '
290 DIM FA(67)
300 DSKI$ DR,17,2,G$,Z$:Z$=""
310 FOR G=0 TO 67
320 FA(G)=ASC(MID$(G$,G+1,1))
330 NEXT
340 '
350 ' READ DIRECTORY
360 '
370 DE=0
380 FOR S=3 TO 11
390 DSKI$ DR,17,S,E$(0),E$(1)
400 '
410 ' PART OF SECTOR
420 '
430 FOR P=0 TO 1
440 '
450 ' ENTRY WITHIN SECTOR PART
460 '
470 FOR E=0 TO 3
480 '
490 ' DIR ENTRY IS 32 BYTES
500 '
510 E$=MID$(E$(P),E*32+1,32)
520 '
530 ' NAME IS FIRST 8 BYTES
540 '
550 NM$(DE)=LEFT$(E$,8)
560 '
570 ' EXTENSION IS BYTES 9-11
580 '
590 EX$(DE)=MID$(E$,9,3)
600 '
610 ' FILE TYPE IS BYTE 12
620 '
630 FT(DE)=ASC(MID$(E$,12,1))
640 '
650 ' ASCII FLAG IS BYTE 13
660 '
670 AF(DE)=ASC(MID$(E$,13,1))
680 '
690 ' FIRST GRANUAL IS BYTE 14
700 '
710 FG(DE)=ASC(MID$(E$,14,1))
720 '
730 ' BYTES USED IN LAST SECTOR
740 ' ARE IN BYTES 15-16
750 '
760 BU(DE)=ASC(MID$(E$,15,1))*256+ASC(MID$(E$,16,1))
770 '
780 ' IF FIRST BYTE IS 255, END
790 ' OF USED DIR ENTRIES
800 '
810 IF LEFT$(NM$(DE),1)=CHR$(255) THEN 1500
820 '
830 ' IF FIRST BYTE IS 0, FILE
840 ' WAS DELETED
850 '
860 IF LEFT$(NM$(DE),1)=CHR$(0) THEN 1480
870 '
880 ' SHOW DIRECTORY ENTRY
890 '
900 PRINT NM$(DE);TAB(9);EX$(DE);"  ";FT$(FT(DE));" ";
910 IF AF(DE)=0 THEN PRINT"BIN"; ELSE PRINT "ASC";
920 '
930 ' CALCULATE FILE SIZE
940 ' SZ - TEMP SIZE
950 ' GN - TEMP GRANULE NUM
960 ' SG - SECTORS IN LAST GRAN
970 ' GC - GRANULE COUNT
980 '
990 SZ=0:GN=FG(DE):SG=0:GC=0
1000 '
1010 ' GET GRANULE VALUE
1020 ' GV - GRAN VALUE
1030 '
1040 GV=FA(GN):GM(GC)=GN:GC=GC+1
1050 '
1060 ' IF TOP TWO BITS SET (C0
1070 ' OR GREATER), IT IS THE
1080 ' LAST GRANULE OF THE FILE
1090 ' SG - SECTORS IN GRANULE
1100 '
1110 IF GV>=&HC0 THEN SG=(GV AND &H1F):GOTO 1280
1120 '
1130 ' IF NOT, MORE GRANS
1140 ' ADD GRANULE SIZE
1150 '
1160 SZ=SZ+2304
1170 '
1180 ' MOVE ON TO NEXT GRANULE
1190 '
1200 GN=GV
1210 GOTO 1040
1220 '
1230 ' DONE WITH GRANS
1240 ' CALCULATE SIZE
1250 '
1260 ' FOR EMPTY FILES
1270 '
1280 IF SG>0 THEN SG=SG-1
1290 '
1300 ' FILE SIZE IS SZ PLUS
1310 ' 256 BYTES PER SECTOR
1320 ' IN LAST GRAN PLUS
1330 ' NUM BYTES IN LAST SECT
1340 '
1350 SZ(DE)=SZ+(SG*256)+BU(DE)
1360 PRINT " ";SZ(DE)
1370 '
1380 ' SHOW GRANULE MAP
1390 '
1400 C=0:PRINT "  ";
1410 FOR I=0 TO GC-1
1420 PRINT USING"##";GM(I);
1430 C=C+1:IF C=10 THEN PRINT:PRINT "  ";:C=0 ELSE PRINT " ";
1440 NEXT:PRINT
1450 '
1460 ' INCREMENT DIR ENTRY
1470 '
1480 DE=DE+1
1490 NEXT:NEXT:NEXT
1500 END
1510 ' SUBETHASOFTWARE.COM

Since there is only one big file on this disk, fully filling it, it only has one 68-entry granule chain to print. I modified the code to PRINT#-2 these values to the virtual printer so I could then copy the numbers into the same spreadsheet:

 68 Files  Big File
FILE  GRAN  GRAN
0     32    32
1     33    33
2     34    34
3     35    35
4     30    36
5     31    37
6     36    38
7     37    39
8     28    40
9     29    41
10    38    42
11    39    43
12    26    44
13    27    45
14    40    46
15    41    47
16    24    48
17    25    49
18    42    50
19    43    51
20    22    52
21    23    53
22    44    54
23    45    55
24    20    56
25    21    57
26    46    58
27    47    59
28    18    60
29    19    61
30    48    62
31    49    63
32    16    64
33    17    65
34    50    66
35    51    67
36    14    30
37    15    31
38    52    28
39    53    29
40    12    26
41    13    27
42    54    24
43    55    25
44    10    22
45    11    23
46    56    20
47    57    21
48     8    18
49     9    19
50    58    16
51    59    17
52     6    14
53     7    15
54    60    12
55    61    13
56     4    10
57     5    11
58    62    8
59    63    9
60     2    6
61     3    7
62    64    4
63    65    5
64     0    2
65     1    3
66    66    0
67    67    1

Now it seems clearly obvious that RS-DOS does something different when making a new file, versus what it does when expanding an existing file into a new granule.

I wanted a way to visualize this so, of course, I wrote a program to help me create a full ASCII representation of the granules, then edited the rest by hand.

                           68    1 Big
                           Files File
Track  0 +------------+
         | Granule  0 |    64    66
         | Granule  1 |    65    67
Track  1 +------------+
         | Granule  2 |    60    64
         | Granule  3 |    61    65
Track  2 +------------+
         | Granule  4 |    56    62
         | Granule  5 |    57    63
Track  3 +------------+
         | Granule  6 |    52    60
         | Granule  7 |    53    61
Track  4 +------------+
         | Granule  8 |    48    58
         | Granule  9 |    49    59
Track  5 +------------+
         | Granule 10 |    44    56
         | Granule 11 |    45    57
Track  6 +------------+
         | Granule 12 |    40    54
         | Granule 13 |    41    55
Track  7 +------------+
         | Granule 14 |    36    52
         | Granule 15 |    37    53
Track  8 +------------+
         | Granule 16 |    32    50
         | Granule 17 |    33    51
Track  9 +------------+
         | Granule 18 |    28    48
         | Granule 19 |    29    49
Track 10 +------------+
         | Granule 20 |    24    46
         | Granule 21 |    25    47
Track 11 +------------+
         | Granule 22 |    20    44
         | Granule 23 |    21    45
Track 12 +------------+
         | Granule 24 |    16    42
         | Granule 25 |    17    43
Track 13 +------------+
         | Granule 26 |    12    40
         | Granule 27 |    13    41
Track 14 +------------+
         | Granule 28 |    8     38
         | Granule 29 |    9     39
Track 15 +------------+
         | Granule 30 |    4     36
         | Granule 31 |    5     37
Track 16 +------------+
         | Granule 32 |    0     0 <- both start the same
         | Granule 33 |    1     1
Track 17 +------------+
         | FAT &      |
         | Directory  |
Track 18 +------------+
         | Granule 34 |    2     2
         | Granule 35 |    3     3
Track 19 +------------+
         | Granule 36 |    6     4 <- then big file continues
         | Granule 37 |    7     5    writing to the end
Track 20 +------------+
         | Granule 38 |    10    6
         | Granule 39 |    11    7
Track 21 +------------+
         | Granule 40 |    14    8
         | Granule 41 |    15    9
Track 22 +------------+
         | Granule 42 |    18    10
         | Granule 43 |    19    11
Track 23 +------------+
         | Granule 44 |    22    12
         | Granule 45 |    23    13
Track 24 +------------+
         | Granule 46 |    26    14
         | Granule 47 |    27    15
Track 25 +------------+
         | Granule 48 |    30    16
         | Granule 49 |    31    17
Track 26 +------------+
         | Granule 50 |    34    18
         | Granule 51 |    35    19
Track 27 +------------+
         | Granule 52 |    38    20
         | Granule 53 |    39    21
Track 28 +------------+
         | Granule 54 |    42    22
         | Granule 55 |    43    23
Track 29 +------------+
         | Granule 56 |    46    24
         | Granule 57 |    47    25
Track 30 +------------+
         | Granule 58 |    50    26
         | Granule 59 |    51    27
Track 31 +------------+
         | Granule 60 |    54    28
         | Granule 61 |    55    29
Track 32 +------------+
         | Granule 62 |    58    30
         | Granule 63 |    59    31
Track 33 +------------+
         | Granule 64 |    62    32
         | Granule 65 |    63    33
Track 34 +------------+
         | Granule 66 |    66    34
         | Granule 67 |    67    35 <- then big file continues
         +------------+                at Track 16

Interesting! For small files, it alternates tracks starting before Track 17 (FAT/Directory) then after, repeating. For a big file, it starts like that before Track 17, then after and continues to the end of Track 35, then goes before Track 17 and works back to the start of the disk.

Do I understand the sequence correctly?

To be continued…

DS-69 digitizer revisited

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The Micro Works Digisector DS-69 / DS-68B digitizers were really cool tech in the 1980s. Looking back, I got to play with video digitizers, the Super Voice speech synthesizer that could “sing”, and even the E.A.R.S. “electronic audio recognition system” for voice commands. All of this on my Radio Shack Color Computer 3 in the late 1980s.

How many decades did it take for this tech to become mainstream in our phones or home assistants? We did it first ;-)

The DS-69 could capture 128×128 or 256×56 photos with 16 grey levels (4-bit greyscale). It also had a mode where it would capture 64 grey scales, though there was no viewer for this and I cannot find any attempts I made to use this mode.

I did, however, find some BASIC which I *think* I wrote that attempted to read a .PIX file and print it out to a printer using different ASCII characters to represent 16 different levels of grey. For example, a space would be bright white at level 0, and a “#” might be the darkest at level 15.

First, GREYTEST.BAS just tried to print blocks using these characters. I was testing.

5 DIM GR(15):FORA=0TO15:READGR(A):NEXT
10 PRINT#-2,"Grey Scale Printer Test:":PRINT#-2
15 FORA=0TO10:FORB=0TO15:PRINT#-2,STRING$(5,GR(B));:NEXT:PRINT#-2:NEXT
99 END
100 REM * Grey Scale Characters (0-15)
105 DATA 32,46,58,45,105,43,61,84,86,37,38,83,65,36,77,20

I asked the Google search engine, and its Gemini A.I. answered:

Dec.  ASCII
Value Character
----- ---------------------------
32    Space (invisible character)
46    . (period or full stop)
58    : (colon)
45    - (hyphen or minus sign)
105   i (lowercase i)
43    + (plus sign)
61    = (equals sign)
84    T (uppercase T)
86    V (uppercase V)
37    % (percent sign)
38    & (ampersand)
83    S (uppercase S)
65    A (uppercase A)
36    $ (dollar sign)
77    M (uppercase M)
20    NAK (Negative Acknowledge - a non-printable control character)

I must have been manually counting how many “dots” made up the characters and sorting them. I recall starting with the HPRINT font data in ROM (which is what my MiniBanners program used) to count the set dots in each letter, but the printer fonts would be different so I expect this table came from trial and error.

The 20 NAK (non printable) is an odd one, so I wonder if my printer DID print something for that – like a solid block graphic.

Proving memory is not always faulty, I also found TEST.BAS which appeared to open a .PIX file and print it out using this code:

0 POKE150,44:PRINT#-2,CHR$(27)CHR$(33)CHR$(27)CHR$(77)CHR$(27)CHR$(64)CHR$(15)
1 PRINT#-2
5 DIM GR(15):FORA=0TO15:READGR(A):NEXT
10 OPEN"D",#1,"SMILE.PIX",1:FIELD#1,1ASA$
11 PRINTLOF(1)
15 FORA=1TO64:PRINTA:FORB=0TO127:GET#1,A+B*64:GR=ASC(A$)
20 PRINT#-2,CHR$(GR(GR AND15));
25 NEXT:PRINT#-2:NEXT:CLOSE
99 END
100 REM * Grey Scale Characters (0-15)
105 DATA 32,46,58,47,62,63,61,84,86,37,38,90,65,69,77,35

I see line 10 opens the file with DIRECT mode with a field size of 1 assigned to string variable A$. This means doing a GET #1,X (where X is a byte offset in the file) would get that byte into A$ so I could get the ASCii value of it (0-15) and use that to know which character to print.

I have no idea if this worked… So let’s give it a try.

I see the program print “8192”, which is the Length Of File. A 128×128 image of bytes would be 16384 in size, so I am guessing each byte has two pixels in it, each 4-bits.

I see I am ANDing off the upper bits in line 20. It looks like I am throwing away every other pixel since no attempt I made to read those other 4-bits. This is likely because this was printing on an 80 column printer, which would not print 128 characters on a line. Instead, 64 would fit.

And, wow! It actually works! I had to reduce the font size down for it to display in the WordPress blog, but here is the output. Step back from the monitor if you can’t see it.

################################################################################################################################
################################################################################################################################
///////////::/:/:::.:::::..:.:: ::/.:://///>>=%V%%V%TT===>>>//?>::.. :. .  .. . :.. . ::: . :::.:::::::://:::/:::://////////////
///////:////:://::::.::::...:::.::////>/>?=%EAEMAMEEEMEAAME&%VT=?>//::::.  .: . .::.. :::.. .. .::::::::.//:://///////////>/////
//////://///:://::::.:::::.:::://>/??TV%%&EMMMMMEEMMMMMAEMMEEAA&ZVT=?>::.. .: . ...   :::...:.:.::::.:::..:::////://////////////
///////:///:::./.::...:::::////??V%AEEMM##MM###MMMMMMMMMMEAEMMMEEZZZ&V=>//:::    :... :::  .:::.::..:::::/::////////////////////
//////:://::::/:::::   :::///?T%AAM#MMMM#M########M#MMM#MMAEMAEMMAAA&ZZ&V=/:: .  :..   :: . ..:.::  :::::/:::////://////////////
/////:::://:::./ .:. :.::?/?T%ZEMEMMMMM###########M#MM##M#MMMAAAEEMEEMMAZZZT>/:. :: .  :  . ... :: :::::.:::::://://////////////
/////:::::::::.. ::. ./?>?T&AAEMMMMMMM#MM########MMMMMMM###MMMAAAAAAEMMMMMEA&=//:::   ... .  .:..   .:::...::::/:://////////////
/////::::.:::::   :: :?=T%MEEEEMMMMMMMMMM#####M#MMMEAEAMM##MMMMMEEEAAEMMEM#MAMT>/:::.  .: .  .. .    ::... :::::/:::////:///////
/://::::...::. . .::>=V%AEMEAEEMMEMMEMEMMMMM#M#MEEAZZ&%&ZEEMMAEMMMMMMMMMMMMMMEAZT>//:. .  .  . ..    :::.. :::.::::://:::///////
:::::::::. .:.   :?TT&AEEEZAEEEEZEZZZEEMEEEMMMM#MAAZ&&V&V&ZAMMMAMM###MMMM#M#MEMAAT?//: :. .  .  .    :::.  ::...:::/:/:::////://
:::. :::   :: .:/?T%&EM#AAEMMAEZA&ZAZZEAAZAMMMMMMAAAZAVVVV%&AM#MMEMM##MMM####MMMAZ%>//::  .  .  . .  :::.. :. ..:::::/:::///:://
:::: :::   ::.:>?VZAEMMAZEMMEAAAZZAZAZEAAEAAZEAMEMAA&&%VVVV&AMM#MMMMM#######M###M&V?//::: .  .  .    :: .  :... :::::/:::///:://
.::. .:.    ::/?%AAAMMEAEMMEMAAZAAAZAAEAAZZ%%%ZAEEAA&Z&%V%%&AAM#MMMMM#######MM#M#ZTV>//:: .   . .    ..:   :. . :::::/:::////://
.:.  .:: . .:/>%EEAEMEEE#MMMMAAAEAZZZEA&ZZZVVVVZZAZAZAZZ%V&&AMEMMM##MM#M######M#MM&T?//:::.  .  .    ...   :... :::::::::///:://
.::.. .: . .:=VZMZEMEMMMM#MEEAAMAZZ&AA%&&Z%TVTTV&&&&ZEEZZZV&ZA#MMMM#############MEZ=T>/::/.  .  .    :: .  :..../:::./:::/.::::/
.::.  .. .  :T%MEAMEEMMMMMEMAAEA&%%ZZ%VV&&TTTTTTTV&&ZAEAZAE&&ZAEMM########M#M#M#MMMM&?/::/.  .  .    .:    :. . .:: ..:::///:::/
 ..   .: .  /T&EZEEMMMMMMMEAZEZ%VV&&&%VVZVTTTTTTTTVT%&EAMEEMAZAME#M#M######MMMM##MMMZT?/:/. ..  .    .:    :.   :.:..::::///::/:
 ..   .. .  :T&&&EMMMMM##MMEMA&%VVTVTVT%%VTTTTTTTT=TTTVZZAMMME&VTTTVZEM#ZAM########MM%?///:...  .    ...   .... .:: ..::::..:::/
 :.    .   .:T&&AEAMM#####MME%V%VVTTTTTT%VTTTTTTTTTTTTV%TVV&VV=.  .>=T%ZMZAEM##MMMMMZ&VV?///::  .    .:    ::   :.:  ::::/:/:::/
 :..  .  .  :?%&AM#MM#####EMZVVTVTTTTTTVV&TTTTTTTTT%&VTTTTTTTTTTTTTTTTTT%&EEE#####MMA&%T?///:::..    :.    :. . :::: .:::://:::/
 :.    .   ../=VZMM#######MEAAEZ%VTTTVVVV%%VVTT=T=TTTTTTTT=>TTTTTTTTTTVTT&TT&E######MEV=/////::.:.   :: .  :. . .::.:.:::://:::/
 :.   .. ...::/VZMM#######E%TTTTVVTTTTVTTTTTEVT===ZTTTVTV%? ?VZZ%V%&VVVT=VTTTTZM#######MZVTT=>::::   :.    :: . ..: ..:::::::://
 .. . .. . ..: =ZMM##VZEEEZ&TVVTTTTTTTVTTTVV&M#TZE#%TTTV%ZV&EEEATTTTTTTTTVTTTTT&MEAAEE#M#MZTT?>?>//:.::.   ::.. ..:   :::/.::::/
 :.   .     :..?&E###MMM#MZ%VTTTTT/ .=T&V&V%%EZT=T%ATTTTTTTTTT=TTTTTTTTTTVTTT=TVZMEAZZZEM##M&=>/:/::.:: .  :: .  .: .::::::/:://
 :.   .   .....>%M#M##M##MZ%TTVVZZAEA##ZVTTV&ET=>>=%ETTTTTTTTTTTTT===TTT=%TTTTTTZEE&&&%A&###M%=>>///::::.  :: .  .: . ::::/::://
 :    ..    :::=VZ#M#####MZTTVV%VTTTTTVVTTV%&ZT===?=TA%T=TTTT=====??=TTTVVTTTTTV&AAAEZZVVAMM#E&T>///:::.  :::   ..: ..::://::://
 :.    :    .://VA#M#####E%TTTTTTTTTTT=TTTTTATT=>=?=??%Z%TTTT==??>/??TV%TTTTTTTTAE#MAAE&VE###EA&?///:::.   :: . ..: ..:::::/:://
 : .  .  . ....>VE#M####METTTTTTTTT==TTTTTTZZTT==>?=?T==TZZZV=TV%%%EZ%TTT=TTTTTTV&%%&ZAZZ####EAZT>///::.. ::. . ..: . :::.:::://
.:     : .  .::V&M#######ATTTTTTTTT===?==VAE%T==>??=??==TTTTTTT======TTT=T=TTTTTTTVVTT&EM###M#EAV>///:::. :::    .: .:::://:/://
 :.   .. . .::=&E########EETTTTTTTT===T%&T%%TVVTTTVVZE%==TTTTT=T=?====?====TTTTTT=?TTTTAMMMMEMAZVT??//://:::: .  .. ..:::..::://
.: .  .: .::/?%MM##MMM#MMMZ%Z%ZZ&ZEAZ%TVTTTVV%MA%VV&TV&VVTTTTTVTTTT=TTTTTTTTTTTT==???TVEMMM#MMAVT=///////.::: . ..: ..:::///:://
.:   ..:.:>TVZMM###EEAMMM#A%TTTTTTTTTTTTTVTV%V%T%VVTTTT====?==TVTTTTTTTTTTTTTT=VT==TT%AM####EAZ?>/////////:::..  .:...::://::://
.: . .:::/?T%E#####E&AEMEMMZTTVTTVTTTTTTTVVTTVTTTTTTT=????=?>=TTTTTTTTTTTT=TTTTZ###########M&&V?>/////://:::::. ..: ..:::.:::://
.:. ..::/=%AAM######A&A#MMMEVTVTVTTTTTTVTTTTVTTTT===?=?===?====TVVTT==??====?=TZ#########MMMZ%?>/////:::..::: ....:.. :::./::://
.:...::/TV&V&M#######MMMMMME%TVVVVTTTTVTTTTTVVV%%VVVV%%%%%%VZ&ZMM&TT==?>===T?=VE##########ME%=//////::::: ::: ::... ..:::///:::/
.::/:/>=T=>TZM##M#M#######EMZVVT%VTTTTTV&&ZZAVTTT?//=>/?//?/??TZV%T==???===TTT%#############ET>/////::::..::: : .::.. :::.:/:://
:::////////TTAMMEMM######MMMM%VVVTTTTTTT&##AVT==>>>?===T==V=&TTT=T===>?====TTTEM#########EMM#V?/////:::::.::: : :.:..:::://::://
:://////////=TZMM#M###########%VVTTT=T=TTTTVVTTTVVVTTTTTTTTTTTTT==?=?>?T==TTTAM#########MMMZA&=>>///::::..::....::: .::::///:///
//////////>>TVE###############E%VVTTTT==T=TTTTTTTTTTTTTTTTTTT===>>??===?=TTT&M###########MMEAAT>>///:::::/:::...:::...:::/:::///
/////////>=TZM#################AVVTTTTTTT==TTTTTTTT=T??===?T===>>>>?=TTT=TV&Z###########MMMEAAV?>///:::::::::::.:::../:::://:://
////////?T%EM###M###############MVVTTTTTTTTTTTT=TTTT==???=>=>?>>>>?==TTTT%&&E######M###M##MEMA&?>////::/./::::..::: ./:::///////
///>>>>=V&AM##MMM################MZ%TTVTTTTTTT==?==???>///?>/??>??===TVV%Z&VA########MEMMMM#ME&T>>///::://:::::/::: .::::///:://
/>>>>?TV%EM#MME&M##################MZVVVTTT==T==>=?>/>>/>>?>/>=T=TTTTVV&&%%%E###########M#M###M&=>///::/:::::::/:::../:::///////
/>/>?TVA%AMMME%&M###################EZ%VTTTTTT==?=?>??>?????=TTTVVV&&%&%%VV%M##################AV>////:://:::::/:::::/:/:///:///
///=TV%%VMMEM&TZM###################EZA%V%VVVTTTTT=TTTT==TTTTVVVVV&&&&VVTT&AM##################M%?////:///::::/:::::./::////////
>??TVV%T%MEAA%VZA###################EA%%&Z%%VVV%TVTVTTTTVV&&VVV%%&Z&%%VVT%AM###############M###M%?/////////::///::::./:::///////
==TVT%TV%MMAEVV&A###################MA&V&%%VVVVVTVVVTV%VVV%&V%%%&&%%TVVV%AAM##############MM##MEV?////////:::///:::/./:::///////
TVV%V&VAMMMMMVVZE########MMMM########MA%%%VVVV%%VVVVTV%V%V&&&Z&%V%VTTVVVZM#M#############MMM#ME&=>/////////::///:::////::///////
TV%&ZZEAM####MM############MMM#######MMZ&%VVVVVV%VVV%%&VV&&&%%V%VTTTT%ZAE#####M##MMMM####MMMMA&T>>/>///////::///:::::///////////
T%V&&MAMM####################M########MEZ&%VVVTTVVVVT&VVV%%%%VVTTTVV&AEM###M###############MMAVT>>/>/////////////>>?????>///////
T&%&&EAM################################EA&VVVVTTVVTTTTVTVTVVTTTVV%AAMM##################MMMEA%TT?===TTT===TVTTTTTTVTTTTTTTT=?>>
TVVT%&EEM##############################MMEZ&%VVTTVVTTTTVVTTTTTVVV%ZAM#M#M################MMMMM##MMEZZ%%V%%VVVVTTTTVTTTTVVTVTTTVT
TVVV%V&AM#M#M###########################MEAZ&%%TVTVTTTTTVVTTV%VT%EMEEMMMM######################MMMAZZAAZAZ&&V%VVTTVTTTTTVTTTTTVT
T&VT%V%&ZM####M#M#######################MMZZ&%%%%VVVTVVVVVVVTTVV&EEEAMEME####M####################M#MMMMEEAEZ&&ZTTVTTVTTVTVTTTVT
TVVT%VTVVZM#MMMMMM#MM################MMMMMMA%&&ZVTVVVVTVVTTTTTVZAEAAZAAEEMM######################M#####MEAAAMEZZTTVTTTTTVTTTTTVT
TV%T%TTVV%EMMM###MMMMMM#MMMEMEEEMEMMM###MMEEZV&VVTVTTTTTTTTTTTV&V&ZAZEMMMM########################MMEMMMMEMMMMZ%TVVTTTTTTTTVTTVV
TVVT%TTVT%ZM###M#M##MMMAAAAZAAEZEEEMEMM#MEAMZZ%%TVTTTTTTTTTTTVVV&ZZAZMM#######################MM####MMMMEMEMMZ%TTTVT==T=TTTVTTVT
TVVV%VVVV%&AMEEEE#EMM#MMM#MMMMEEAAMEEMMMMMAAEZ&&TVVTTTTTVTTTTVV&%&ZEMMM#############MMMM#######MMMMMMMMEAAAZE%TVTTTTTTT==TTTTTTT
TVTV%TVVV%EAEEAAAZEAZEEEEEEAAEAEZAAEAMMEAEAAAZ%VTTTTTTTTTTTTTVVT%&EE################MMM########MMMEEMMEE%%VTVVTTTTVT==T==TTTTTTT
V%V%%TV%VZMMMAMMEEZZAZAMAA&&Z&AEEMEAEEEAZAZ&&%TTTTTTTTTTVTTT%%%V&AE#MM########MMM#M##MMM########MMMAAA%VVTTTVTTTTTTTT====TTVTTTT
################################################################################################################################
################################################################################################################################

And here is a screenshot of it, if that did not work:

Well that’s neat. I wonder what I did with this.

Until next time…

Tackling the Logiker 2025 Vintage Computing Christmas Challenge – part 1

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See Also: Prologue and part 1.

Rules to the Challenge

❄️ Vintage Computing Christmas Challenge 2025 ❄️ – Logiker

The Pattern

Observations

Since this is a symmetrical pattern, if we can figure out how to draw one quadrant, we can draw the others.
The pattern is 19 characters wide, which contains a center column of asterisks, and a left and right column that are spaces except for the center row of asterisks.
“As if they had planned it,” this means the pattern in each quadrants is 8 characters, matching the number of bits in a byte.

I typed it up to figure out what the bit pattern would be. (Actually, I typed up a bit of it, then pasted that into Copilot and had it tell me the bit pattern.)

.        *
.------*- = 2
.-*-*---* = 81
.--**---- = 48
.-***--*- = 114
.----*--* = 9
.-----*-- = 4
.*-*---*- = 162
.-*-*---* = 81
*******************

That’s a mess, but in the left the “.” would represent the blank space down the left side up to the row of 19 asterisks. After that is the 8-bit pattern with “-” representing a space in the pattern (0 bit) and the “*” representing the asterisk (1 bit).

This let me quickly cobble together a proof-of-concept:

1 READ V
2 A$=STRING$(19,32):MID$(A$,10,1)="*"
3 FOR B=0 TO 7
4 IF V AND 2^B THEN MID$(A$,9-B,1)="*":MID$(A$,B+11,1)="*"
5 NEXT
6 PRINT A$:A$(L)=A$
7 L=L+1:IF L<8 THEN 1
8 PRINT STRING$(18,42)
9 FOR B=7 TO 0 STEP -1:PRINT A$(B):NEXT
10 DATA 2,81,48,114,9,4,162,81

Line 10 are the 8 rows of byte data for a quadrant of the snowflake.
Line 1 reads the first value from the DATA statement.
Line 2 builds a string of 19 spaces, then sets the character at position 10 (in the center) to an asterisk. Every row has this character set.
Line 3 begins a loop representing each bit in the byte (0-7).
Line 4 checks the read DATA value and ANDs it with the bit value (2 to the power of the the FOR/NEXT loop value). If it is set, the appropriate position in the left side of the string is set to an asterisk, and then the same is done for the right side. To mirror, the left side is center-minus-bit, and the right side is center-plus-bit.
Line 5 is the NEXT to continue doing the rest of the bits.
Line 6 prints the completed string, then stores that string in an A$() array. L has not been used yet so it starts at 0.
Line 7 increments L, and as long as it is still ess than 8 (0-7 for the first eight lines of the pattern) it goes back to line 1 to continue with the next DATA statement.
Line 8 once 8 lines have been done, the center row of 19 asterisks is printed.
Line 9 is a loop to print out the A$() lines we saved, backwards. As they were built in line 6, they went from 0 to 7. Now we print them backwards 7 to 0.

…and there we have a simple way to make this pattern, slowly:

On a CoCo 3, adding a WIDTH 40 or WIDTH 80 before it would show the full pattern:

My example program can be made much smaller by packing lines together and removing unnecessary spaces. One minor optimization I already did was doing the bits from 0 to 7 which removed the need to use “STEP -1” if counting backwards. Beyond that, this is the raw proof-of-concept idea of using bytes.

Other options folks have used in past challenges included rune-length type encoding (DATA showing how many spaces, then how many asterisks, to make the pattern) so that probably is worth investigating to see if it helps here.

Then, of course, someone will probably figure out a math pattern to make this snowflake.

What thoughts do you have?

CoCo Disk BASIC disk structure – part 3

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

A correction, and discovering the order RS-DOS writes things…

A correction from part 2… This example program had “BIN” and “ASC” mixed up. 0 should represent BINary files, and 255 for ASCii files. I fixed it in line 920. (I will try to edit/fix the original post when I get a moment.)

10 ' FILEINFO.BAS
20 '
30 ' 0.0 2023-01-25 ALLENH
40 ' 0.1 2023-01-26 ADD DR
50 ' 0.2 2023-01-27 MORE COMMENTS
55 ' 0.3 2025-11-18 BIN/ASC FIX
60 '
70 ' E$(0-1) - SECTOR HALVES
80 ' FT$ - FILE TYPE STRINGS
90 '
100 CLEAR 1500:DIM E$(1),FT$(3)
110 FT$(0)="BPRG":FT$(1)="BDAT":FT$(2)="M/L ":FT$(3)="TEXT "
120 '
130 ' DIR HOLDS UP TO 72 ENTRIES
140 '
150 ' NM$ - NAME
160 ' EX$ - EXTENSION
170 ' FT - FILE TYPE (0-3)
180 ' AF - ASCII FLAG (0/255)
190 ' FG - FIRST GRANULE #
200 ' BU - BYTES USED IN LAST SECTOR
210 ' SZ - FILE SIZE
220 '
230 DIM NM$(71),EX$(71),FT(71),AF(71),FG(71),BU(71),SZ(71)
240 '
250 INPUT "DRIVE";DR
260 '
270 ' FILE ALLOCATION TABLE
280 ' 68 GRANULE ENTRIES
290 '
300 DIM FA(67)
310 DSKI$ DR,17,2,G$,Z$:Z$=""
320 FOR G=0 TO 67
330 FA(G)=ASC(MID$(G$,G+1,1))
340 NEXT
350 '
360 ' READ DIRECTORY
370 '
380 DE=0
390 FOR S=3 TO 11
400 DSKI$ DR,17,S,E$(0),E$(1)
410 '
420 ' PART OF SECTOR
430 '
440 FOR P=0 TO 1
450 '
460 ' ENTRY WITHIN SECTOR PART
470 '
480 FOR E=0 TO 3
490 '
500 ' DIR ENTRY IS 32 BYTES
510 '
520 E$=MID$(E$(P),E*32+1,32)
530 '
540 ' NAME IS FIRST 8 BYTES
550 '
560 NM$(DE)=LEFT$(E$,8)
570 '
580 ' EXTENSION IS BYTES 9-11
590 '
600 EX$(DE)=MID$(E$,9,3)
610 '
620 ' FILE TYPE IS BYTE 12
630 '
640 FT(DE)=ASC(MID$(E$,12,1))
650 '
660 ' ASCII FLAG IS BYTE 13
670 '
680 AF(DE)=ASC(MID$(E$,13,1))
690 '
700 ' FIRST GRANUAL IS BYTE 14
710 '
720 FG(DE)=ASC(MID$(E$,14,1))
730 '
740 ' BYTES USED IN LAST SECTOR
750 ' ARE IN BYTES 15-16
760 '
770 BU(DE)=ASC(MID$(E$,15,1))*256+ASC(MID$(E$,16,1))
780 '
790 ' IF FIRST BYTE IS 255, END
800 ' OF USED DIR ENTRIES
810 '
820 IF LEFT$(NM$(DE),1)=CHR$(255) THEN 1390
830 '
840 ' IF FIRST BYTE IS 0, FILE
850 ' WAS DELETED
860 '
870 IF LEFT$(NM$(DE),1)=CHR$(0) THEN 1370
880 '
890 ' SHOW DIRECTORY ENTRY
900 '
910 PRINT NM$(DE);TAB(9);EX$(DE);"  ";FT$(FT(DE));" ";
920 IF AF(DE)=0 THEN PRINT"BIN"; ELSE PRINT "ASC";
930 '
940 ' CALCULATE FILE SIZE
950 ' SZ - TEMP SIZE
960 ' GN - TEMP GRANULE NUM
970 ' SG - SECTORS IN LAST GRAN
980 '
990 SZ=0:GN=FG(DE):SG=0
1000 '
1010 ' GET GRANULE VALUE
1020 ' GV - GRAN VALUE
1030 '
1040 GV=FA(GN)
1050 '
1060 ' IF TOP TWO BITS SET (C0
1070 ' OR GREATER), IT IS THE
1080 ' LAST GRANULE OF THE FILE
1090 ' SG - SECTORS IN GRANULE
1100 '
1110 IF GV>=&HC0 THEN SG=(GV AND &H1F):GOTO 1280
1120 '
1130 ' ELSE, MORE GRANS
1140 ' ADD GRANULE SIZE
1150 '
1160 SZ=SZ+2304
1170 '
1180 ' MOVE ON TO NEXT GRANULE
1190 '
1200 GN=GV
1210 GOTO 1040
1220 '
1230 ' DONE WITH GRANS
1240 ' CALCULATE SIZE
1250 '
1260 ' FOR EMPTY FILES
1270 '
1280 IF SG>0 THEN SG=SG-1
1290 '
1300 ' FILE SIZE IS SZ PLUS
1310 ' 256 BYTES PER SECTOR
1320 ' IN LAST GRAN PLUS
1330 ' NUM BYTES IN LAST SECT
1340 '
1350 SZ(DE)=SZ+(SG*256)+BU(DE)
1360 PRINT " ";SZ(DE)
1370 DE=DE+1
1380 NEXT:NEXT:NEXT
1390 END
1400 ' SUBETHASOFTWARE.COM

To test this routine, I created a program that let me type a file size (in bytes) and then it would make a .TXT file with that size as the filename (i.e, for 3000 bytes, it makes “3000.TXT”) and then I could run it through this program and see if everything matched.

It opens a file with the size as the filename, then writes out “*” characters to fill the file. This will be painfully slow for large files. If you want to make it much faster, share your work in a comment.


10 ' MAKEFILE.BAS
20 '
30 ' 0.0 2025-11-18 ALLENH
40 '
50 INPUT "FILE SIZE";SZ
60 F$=MID$(STR$(SZ),2)+".TXT"
70 OPEN "O",#1,F$
80 FOR A=1 TO SZ:PRINT #1,"*";:NEXT
90 CLOSE #1
100 DIR
110 GOTO 50
120 ' SUBETHASOFTWARE.COM

I was able to use this program in the Xroar emulator to create files of known sizes so I could verify the FILEINFO.BAS program was doing the proper thing.

It seems to be, so let’s move on…

A funny thing happened on the way to the disk…

I have been digging in to disk formats (OS-9 and RS-DOS) lately, and learning more things I wish I knew “back in the day.” For instance, I was curious how RS-DOS allocates granules (see part 1) when adding files to the disk. I wrote a test program that would write out 2304-byte blocks of data (the size of a granule) full of the number of the block. i.e., for the first write, I’d write 2304 0’s, then 2304 1’s and so on. My simple program looks like this:

10 'GRANULES.BAS
20 OPEN "O",#1,"GRANULES.TXT"
30 FOR G=0 TO 67
40 PRINT G;
50 T$=STRING$(128,G)
60 FOR T=1 TO 18
65 PRINT ".";
70 PRINT #1,T$;
80 NEXT
90 PRINT
100 NEXT
110 CLOSE #1

I ran this on a freshly formatted disk and let it fill the whole thing up. The very last write errors with a ?DF ERROR (disk full) so it never makes it to the close. I guess you can’t write that last byte without an error?

Now I should be able to look a the bytes on the disk and see where the 0’s went, the 15’s went, and so on, and see the order RS-DOS allocated those granules.

I made a simple test program for this:

0 'GRANDUMP.BAS
10 CLEAR 512
20 FOR G=0 TO 67
30 T=INT((G)/2):IF T>16 THEN T=T+1
40 IF INT(G/2)*2=G THEN S1=10:S2=18 ELSE S1=1:S2=9
50 'PRINT "GRANULE";G;TAB(13);"T";T;TAB(20);"S";S1;"-";S2
54 DSKI$0,T,S1,A$,B$
55 PRINT "GRANULE";G;ASC(A$)
60 NEXT G

Ignore the commented out stuff. Initially I was just getting it to convert a granule to Track/Sectors with code to skip Track 17 (FAT/Directory). And, to be honest, I had an AI write this and I just modified it ;-)

I then modified it to PRINT#-2 to the printer, and ran it in Xroar with the printer redirected to a text file. That gave me the following output:

GRANULE 0  67
GRANULE 1  66
GRANULE 2  65
GRANULE 3  64
GRANULE 4  63
GRANULE 5  62
GRANULE 6  61
GRANULE 7  60
GRANULE 8  59
GRANULE 9  58
GRANULE 10  57
GRANULE 11  56
GRANULE 12  55
GRANULE 13  54
GRANULE 14  53
GRANULE 15  52
GRANULE 16  51
GRANULE 17  50
GRANULE 18  49
GRANULE 19  48
GRANULE 20  47
GRANULE 21  46
GRANULE 22  45
GRANULE 23  44
GRANULE 24  43
GRANULE 25  42
GRANULE 26  41
GRANULE 27  40
GRANULE 28  39
GRANULE 29  38
GRANULE 30  37
GRANULE 31  36
GRANULE 32  1 
GRANULE 33  0 
GRANULE 34  3 
GRANULE 35  2 
GRANULE 36  5 
GRANULE 37  4 
GRANULE 38  7 
GRANULE 39  6 
GRANULE 40  9 
GRANULE 41  8 
GRANULE 42  11
GRANULE 43  10
GRANULE 44  13
GRANULE 45  12
GRANULE 46  15
GRANULE 47  14
GRANULE 48  17
GRANULE 49  16
GRANULE 50  19
GRANULE 51  18
GRANULE 52  21
GRANULE 53  20
GRANULE 54  23
GRANULE 55  22
GRANULE 56  25
GRANULE 57  24
GRANULE 58  27
GRANULE 59  26
GRANULE 60  29
GRANULE 61  28
GRANULE 62  31
GRANULE 63  30
GRANULE 64  33
GRANULE 65  32
GRANULE 66  35
GRANULE 67  34

Now I can see the order that RS-DOS allocates data on an empty disk.

The number in the third column represents the value of the bytes written to that 2304 granule. When I see “GRANULE 67” contains “34” as data, I know it was the 35th (numbers 0-34) granule written out.

Granules 0-33 are on tracks 0-16, then track 17 is skipped, then the remaining granules 34-67 are on tracks 18-34.

You can see that RS-DOS initially writes the data close to track 17, reducing the time it takes to seek from the directory to the file data. This makes sense, though as a teen, I guess I had some early signs of O.C.D. because I thought the directory should be at the start of the disk, and not in the middle ;-)

I brought this data into a spreadsheet, then sorted it by the “data” value (column 3). This let me see the order that granules are allocated (written to). I will add some comments:

GRANULE	33	0 <- first went to gran 33
GRANULE	32	1 <- second went to gran 32

...then it starts writing after Track 17...

GRANULE	35	2 <- third went to gran 35
GRANULE	34	3 <- fourth went to gran 34
GRANULE	37	4
GRANULE	36	5
GRANULE	39	6
GRANULE	38	7
GRANULE	41	8
GRANULE	40	9
GRANULE	43	10
GRANULE	42	11
GRANULE	45	12
GRANULE	44	13
GRANULE	47	14
GRANULE	46	15
GRANULE	49	16
GRANULE	48	17
GRANULE	51	18
GRANULE	50	19
GRANULE	53	20
GRANULE	52	21
GRANULE	55	22
GRANULE	54	23
GRANULE	57	24
GRANULE	56	25
GRANULE	59	26
GRANULE	58	27
GRANULE	61	28
GRANULE	60	29
GRANULE	63	30
GRANULE	62	31
GRANULE	65	32
GRANULE	64	33
GRANULE	67	34
GRANULE	66	35

...now that it has written to the final Track 35 (gran 66-67)...

GRANULE	31	36 <- before Track 17 and the original writes.
GRANULE	30	37
GRANULE	29	38
GRANULE	28	39
GRANULE	27	40
GRANULE	26	41
GRANULE	25	42
GRANULE	24	43
GRANULE	23	44
GRANULE	22	45
GRANULE	21	46
GRANULE	20	47
GRANULE	19	48
GRANULE	18	49
GRANULE	17	50
GRANULE	16	51
GRANULE	15	52
GRANULE	14	53
GRANULE	13	54
GRANULE	12	55
GRANULE	11	56
GRANULE	10	57
GRANULE	9	58
GRANULE	8	59
GRANULE	7	60
GRANULE	6	61
GRANULE	5	62
GRANULE	4	63
GRANULE	3	64
GRANULE	2	65
GRANULE	1	66
GRANULE	0	67 <- last write at the very first gran

And down the rabbit hole I go. Again. I have tasked an A.I. with creating some simple scripts to manipulate RS-DOS disk images (just for fun; the toolshed “decb” command already exists and works great and does more). While I understood the basic structure for an RS-DOS disk, I did not understand “how” RS-DOS actually allocated those granules. Now I have some insight. Perhaps I can make my tools replicate writing in the same way that RS-DOS itself does.

Look for a part 4. I have some more experiments to share.

To be continued…

Do you want to build a snow flake? Logiker 2025!

2 Replies

The 2025 edition of the Logiker programming challenge has been announced via a YouTube video:

This year’s pattern is a snowflake, and I am very curious to see the approaches people come up with in BASIC to do this. I have some ideas, but none of them seem small.

This 19×19 image won’t fit on a CoCo’s 32×16 screen, but the challenge allows it to scroll off as long as it was printed to match. Using the 40/80 column screen on the CoCo 3 would work well.

Here is the info page for the challenge:

https://logiker.com/Vintage-Computing-Christmas-Challenge-2025

I somehow completely missed out on last year’s challenge, which was a present box, so maybe I’ll find some time to experiment with this one. I’ve never “entered” the challenge, but have blogged attempts here.

Are you in? Let’s get coding!