# Rounding up integer without using float, double, or division

Its an embedded platform thats why such restrictions.

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

Did this:

int32_t val = 112; // this value is arbitrary
int32_t result = (val*((val * 0x535A8) - 0x2675F70));
result = result>>24;

The precision is still poor. When we multiply val*0x535A8 Is there a way we can further improve the precision by rounding up, but without using any float, double, or division.

• How long are your longest integers? Do you have a maximum value for the input c? I want to judge how many bits you can work with. Commented Jan 17, 2014 at 17:24
• The maximum value I would be using is 120 (for C). The integers can be 32 bit long. Commented Jan 17, 2014 at 17:29
• What precision do you want? The calculation you are doing basically casts a fairly precise fixed-point value to an integer, and the largest possible value of the integer is just 4.
– user1619508
Commented Jan 17, 2014 at 17:45
• What is the minimum value for c? Commented Jan 17, 2014 at 19:38
• For only 120 input values, you could easily use a lookup table. Commented Jan 17, 2014 at 20:17

The problem is not precision. You're using plenty of bits.

I suspect the problem is that you're comparing two different methods of converting to int. The first is a cast of a double, the second is a truncation by right-shifting.

Converting floating point to integer simply drops the fractional part, leading to a round towards zero; right-shifting does a round down or floor. For positive numbers there's no difference, but for negative numbers the two methods will be 1 off from each other. See an example at http://ideone.com/rkckuy and some background reading at Wikipedia.

Your original code is easy to fix:

int32_t result = (val*((val * 0x535A8) - 0x2675F70));
if (result < 0)
result += 0xffffff;
result = result>>24;

See the results at http://ideone.com/D0pNPF

You might also just decide that the right shift result is OK as is. The conversion error isn't greater than it is for the other method, just different.

Edit: If you want to do rounding instead of truncation the answer is even easier.

int32_t result = (val*((val * 0x535A8) - 0x2675F70));
result = (result + (1L << 23)) >> 24;

I'm going to join in with some of the others in suggesting that you use a constant expression to replace those magic constants with something that documents how they were derived.

static const int32_t a = (int32_t)(0.02035 * (1L << 24) + 0.5);
static const int32_t b = (int32_t)(2.4038 * (1L << 24) + 0.5);
int32_t result = (val*((val * a) - b));
• BTW: In an embedded environment, 16-bit int is prevalent. Suggest ((int32_t) 1 << 24) to prevent UB and provide maximum portability. (or at least (1L << 24)). Commented Jan 18, 2014 at 16:12

How about just scaling your constants by 10000. The maximum number you then get is 2035*120*120 - 24038*120 = 26419440, which is far below the 2^31 limit. So maybe there is no need to do real bit-tweaking here.

As noted by Joe Hass, your problem is that you shift your precision bits into the dustbin.

Whether shifting your decimals by 2 or by 10 to the left does actually not matter. Just pretend your decimal point is not behind the last bit but at the shifted position. If you keep computing with the result, shifting by 2 is likely easier to handle. If you just want to output the result, shift by powers of ten as proposed above, convert the digits and insert the decimal point 5 characters from the right.

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

• Except for the addition of UD_Scaling/2 here I don't see how this differs from the code in the question. If you look at the hex constants you'll see that they're exactly the ones you're calculating. Commented Jan 17, 2014 at 22:50
• @Mark Ransom Good point. Hmmm. The OP method used to calculate the constants is not shown. Here it is explicit - good for future ref. The values like 0.02035, I assume, may change between complies but are in the ballpark. Without knowing OP's method, OP's scaled constants and the ones here may differ should A or B change. OP's cursorily states "The precision is poor". If OP is always doing the same scaling as I, aside from the UD_Scaling/2, there is not more precision available. The answers only vary from -71 to 5 in integer steps and the UD_Scaling/2 gets the best int32_t answer. Commented Jan 18, 2014 at 0:21

If you r input uses max 7 bits and you have 32 bit available then your best bet is to shift everything by as many bits as possible and work with that:

int32_t result;
result = (val * (int32_t)(0.02035 * 0x1000000)) - (int32_t)(2.4038 * 0x1000000);
result >>= 8; // make room for another 7 bit multiplication
result *= val;
result >>= 16;

Constant conversion will be done by an optimising compiler at compile time.

• I didnt quite understand this answer @Sergey. By shifting everything, arent we going to lose the precision. Honestly, I didnt understand the answer. Can you explain a bit more? Commented Jan 17, 2014 at 19:10
• @UnderDog Precision = number of bits you work with. float has a precision of 23 bits, double of 52 bits. By shifting the integers to the maximum values we use the full precision of 32 bit integers. Since the result is an integer we need to shift the result back to the right amount. Commented Jan 19, 2014 at 21:13