Givens:

Lets assume 1 <= c <= 120,

**original equation: 0.02035*c*c - 2.4038*c**

then -70.98586 < f(c) < 4.585

--> `-71 <= result <= 5`

rounding f(c) to nearest `int32_t`

.

Arguments A = 0.02035 and B = 2.4038

A & B may change a bit with subsequent compiles, but not at run-time.

Allow coder to input values like 0.02035 & 2.4038. The key components shown here and by others it to scale the factors like 0.02035 to by some power-of-2, do the equation (simplified into the form (A*c - B)*c) and the scale the result back.

Important features:

1 When determining A and B, insure the compile time floating point multiplication and final conversion occurs via a round and not a truncation. With positive values, the `+ 0.5`

achieves that. Without a rounded answer `UD_A*UD_Scaling`

could end up just under a whole number and truncate away 0.999999 when converting to the `int32_t`

2 Instead of doing expensive division at run-time, we do >> (right shift). By adding half the divisor (as suggested by @Joe Hass), before the division, we get a nicely rounded answer. It is important *not* to code in `/`

here as `some_signed_int / 4`

and `some_signed_int >> 2`

do not round the same way. With 2's complement, `>>`

truncates toward `INT_MIN`

whereas `/`

truncates toward 0.

```
#define UD_A (0.02035)
#define UD_B (2.4038)
#define UD_Shift (24)
#define UD_Scaling ((int32_t) 1 << UD_Shift)
#define UD_ScA ((int32_t) (UD_A*UD_Scaling + 0.5))
#define UD_ScB ((int32_t) (UD_B*UD_Scaling + 0.5))
for (int32_t val = 1; val <= 120; val++) {
int32_t result = ((UD_A*val - UD_B)*val + UD_Scaling/2) >> UD_Shift;
printf("%" PRId32 "%" PRId32 "\n", val, result);
}
```

Example differences:

```
val, OP equation, OP code, This code
1, -2.38345, -3, -2
54, -70.46460, -71, -70
120, 4.58400, 4, 5
```

This is a new answer. My old +1 answer deleted.

`c`

? I want to judge how many bits you can work with.5more comments