float to fixed conversion with different scaling factors

Can anyone please let me know What will be the difference between these approcahes when I convert fixed to float and float to fixed.

a) ```int a=32767; float b = 32765*(1/32767) // 16 bit scaling factor int c = b*32767;```

b) ```int a=32767; float b = 32765*(1/1.0) // scaling factor=1 int c = b*1;```

a) ```int a=32767; float b = 32765*(1/0x80000) // 24 bit scaling factor int c = b*(0x80000);```

If my machine uses Q23 fixed point representation, which should I use ?

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Let me know if anyone has some idea. –  Viks Aug 20 '10 at 17:11
What's this `32765` anyway? In hex it is `0xfffd` so this is completely unexpected to me. Why don't you take `0x10000` instead? –  Roland Illig Oct 16 '10 at 13:34

I didn't find any detailed information about the "Q23 fixed point representation" that your machine uses, so I made up my own definition, wrote some conversion routines and tested them for some few values:

``````#include <limits.h>
#include <stdio.h>
#include <stdlib.h>

/**
* q23 is a fixed-point two's-complement type:
* - 1 bit sign,
* - 8 bit integer part,
* - 23 bit fraction part.
*
* long is assumed to be 32 bit two's complement without padding bits.
*/
typedef long q23;

static q23
cvt_float_to_q23(float f) {
return f * (1 << 23);
}

static float
cvt_q23_to_float(q23 x) {
return ((float) x) / (1 << 23);
}

/*
* Here starts the testing code.
*/

static unsigned errors = 0;

static void
assert_q23_is(q23 fixed, float f) {
if (cvt_q23_to_float(fixed) != f) {
fprintf(stderr, "E: cvt_q23_to_float(%08lx) expected %.10f, got %.10f\n",
fixed, f, cvt_q23_to_float(fixed));
errors++;
}
}

static void
assert_float_is(float f, q23 fixed) {
if (cvt_float_to_q23(f) != fixed) {
fprintf(stderr, "E: cvt_float_to_q23(%f) expected %08lx, got %08lx\n",
f, fixed, cvt_float_to_q23(f));
errors++;
}
}

static void
assert_equals(q23 fixed, float f) {
assert_q23_is(fixed, f);
assert_float_is(f, fixed);
}

int
main() {
/* Some values have equivalent representation. */
assert_equals(LONG_MIN, -256.0f);
assert_equals(LONG_MIN / 2, -128.0f);
assert_equals(0, 0.0f);
assert_equals(LONG_MAX / 2 + 1, 128.0f);

/* There will be a fixpoint ... */
assert_float_is(1.0 / 3, 0x002aaaaa);
assert_q23_is(0x002aaaaa, 0.3333332539f);

/* float only has 24 bits of precision */
assert_equals(0x2aaaaac0, 256.0 / 3);

if (errors == 0) {
printf("ok\n");
return EXIT_SUCCESS;
}
return EXIT_FAILURE;
}
``````

Some remarks:

• If you need saturated rounding you have to implement that yourself by checking the argument to `cvt_float_to_q23`.
• There will be rounding errors everywhere, and they are inevitable. Be sure to handle them appropriately.
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