Imagine I have two unsigned bytes b and x. I need to calculate bsub as b - x and badd as b + x. However, I don't want underflow/overflow occur during these operations. For example (pseudo-code):

b = 3; x = 5;
bsub = b - x; // bsub must be 0, not 254


b = 250; x = 10;
badd = b + x; // badd must be 255, not 4

The obvious way to do this includes branching:

bsub = b - min(b, x);
badd = b + min(255 - b, x);

I just wonder if there are any better ways to do this, i.e. by some hacky bit manipulations?

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    y ^ ((x ^ y) & -(x < y)) for int types evaluates min(x, y) without branching. This could form part of an eventual solution, based on what you have so far. – Bathsheba Nov 2 '15 at 15:41
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    Perhaps Clamped Increment Integer? is helpful. – Shafik Yaghmour Nov 2 '15 at 15:46
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    Is this a C or a C++ question? Please choose one. – fuz Nov 2 '15 at 16:02
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    @AlanCampbell it is called Saturating Arithmetic. – Shafik Yaghmour Nov 3 '15 at 2:53
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    Do you need it to be portable? Because if you're looking at a specific architecture, then there's probably a nice single instruction. I know ARM has saturating vector addition and subtraction for bytes. On X86 the _mm_adds_epi8 intrinsic will do a saturating add of 16 bytes in a single instruction. – porglezomp Nov 3 '15 at 4:30

11 Answers 11


The article Branchfree Saturating Arithmetic provides strategies for this:

Their addition solution is as follows:

u32b sat_addu32b(u32b x, u32b y)
    u32b res = x + y;
    res |= -(res < x);

    return res;

modified for uint8_t:

uint8_t  sat_addu8b(uint8_t x, uint8_t y)
    uint8_t res = x + y;
    res |= -(res < x);

    return res;

and their subtraction solution is:

u32b sat_subu32b(u32b x, u32b y)
    u32b res = x - y;
    res &= -(res <= x);

    return res;

modified for uint8_t:

uint8_t sat_subu8b(uint8_t x, uint8_t y)
    uint8_t res = x - y;
    res &= -(res <= x);

    return res;
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    @user1969104 that may be the case but as the comment in the article indicates, that is solved by casting to unsigned before applying unary minus. In practicality it is unlikely you will have to deal with anything else but two's complement. – Shafik Yaghmour Nov 3 '15 at 4:09
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    This may be a good C answer, but isn't a very good C++ answer. – Yakk - Adam Nevraumont Nov 3 '15 at 18:46
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    @Yakk What makes this a "bad" C++ answer? These are basic mathematical operations, and I don't see how it would be interpreted as C only, or bad C++. – JPhi1618 Nov 3 '15 at 19:54
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    @JPhi1618 A better C++ answer might be template<class T>struct sat{T t;}; with overloaded operators that saturate? Proper use of namespaces. Mostly sugar. – Yakk - Adam Nevraumont Nov 3 '15 at 19:59
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    @Yakk, Ah, ok. I just saw this as a minimal example that the OP could adapt as needed. I wouldn't expect to see that complete of an implementation. Thanks for clarifying. – JPhi1618 Nov 3 '15 at 20:02

A simple method is to detect overflow and reset the value accordingly as below

bsub = b - x;
if (bsub > b)
    bsub = 0;

badd = b + x;
if (badd < b)
    badd = 255;

GCC can optimize the overflow check into a conditional assignment when compiling with -O2.

I measured how much optimization comparing with other solutions. With 1000000000+ operations on my PC, this solution and that of @ShafikYaghmour averaged 4.2 seconds, and that of @chux averaged 4.8 seconds. This solution is more readable as well.

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    @user694733 It's not optimized away, it's optimized into a conditional assignment depending on the carry flag. – fuz Nov 2 '15 at 16:00
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    Yes user694733 is right. It is optimized into a conditional assignment. – user1969104 Nov 2 '15 at 16:02
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    This is by far the most readable, which is a nice bonus. – Ypnypn Nov 2 '15 at 23:13
  • This would not work for all cases, for example badd: b = 155 x =201, than badd = 156, and that is bigger than b. You would need to compare the result to the min() or max() of the two variables, depending on the operation – Cristian F Nov 17 '15 at 13:59
  • @CristianF How do you calculate 155+201 = 156? I think it needs to be 155+201 = 356%256 = 100. I do not think min(), max() is needed in any combination of b, x values. – user1969104 Nov 17 '15 at 14:36

For subtraction:

diff = (a - b)*(a >= b);


sum = (a + b) | -(a > (255 - b))


// sum = (a + b)*(a <= (255-b)); this fails
// sum = (a + b) | -(a <= (255 - b)) falis too

Thanks to @R_Kapp

Thanks to @NathanOliver

This exercise shows the value of simply coding.

sum = b + min(255 - b, a);
  • For sum perhaps (a + b) | -(a <= (255 - b))? – R_Kapp Nov 2 '15 at 15:58
  • You could do sum = ((a + b) | (!!((a + b) & ~0xFF) * 0xFF)) & 0xFF, assuming sizeof(int) > sizeof(unsigned char), but this looks so complex that I don't know if you would gain anything with it (other than headache). – user694733 Nov 2 '15 at 16:17
  • @user694733 Yes and maybe even (a+b+1)*(a <= (255-b)) - 1. – chux - Reinstate Monica Nov 2 '15 at 16:20
  • @NathanOliver Thanks for the oversight - the telling aspect of this is that the sub was easy as the limit was 0. But other limits pose complications and follow user2079303 comment. – chux - Reinstate Monica Nov 2 '15 at 16:22
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    @user1969104 OP was not clear on "better" (code space vs. speed performance) nor target platform nor compiler. Speed assessment makes most sense in the context of the un-posted larger problem. – chux - Reinstate Monica Nov 2 '15 at 16:51

If you are using a recent enough version of gcc or clang (maybe also some others) you could use built-ins to detect overflow.

if (__builtin_add_overflow(a,b,&c))
  c = UINT_MAX;
  • This is the best answer. Using compiler built-ins instead of bit magic is not only faster, it is also clearer and makes the code more maintainable. – Cephalopod Nov 3 '15 at 9:48
  • Thank you, @erebos. I'll definitely try this on platforms where it is available. – Oleg Nov 3 '15 at 12:38
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    I can not get gcc to generate brachless code with this one, which is a bit disappointing. The especially unfortunate thing here is that clang uses different names for these. – Shafik Yaghmour Nov 3 '15 at 17:58
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    @Cephalopod And it's completely non-crossplatform, heck most likely doesn't even work on another compiler. Not a good solution for the 21st century. – Ela782 Nov 4 '15 at 14:38
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    @Ela782 It's exactly the other way around: built-ins are not a good solution for the 20th century. Welcome to the future! – Cephalopod Nov 4 '15 at 19:40

For addition:

unsigned temp = a+b;  // temp>>8 will be 1 if overflow else 0
unsigned char c = temp | -(temp >> 8);

For subtraction:

unsigned temp = a-b;  // temp>>8 will be 0xFF if neg-overflow else 0
unsigned char c = temp & ~(temp >> 8);

No comparison operators or multiplies required.


If you are willing to use assembly or intrinsics, I think I have an optimal solution.

For subtraction:

We can use the sbb instruction

In MSVC we can use the intrinsic function _subborrow_u64 (also available in other bit sizes).

Here is how it is used:

// *c = a - (b + borrow)
// borrow_flag is set to 1 if (a < (b + borrow))
borrow_flag = _subborrow_u64(borrow_flag, a, b, c);

Here is how we could apply it to your situation

uint64_t sub_no_underflow(uint64_t a, uint64_t b){
    uint64_t result;
    borrow_flag = _subborrow_u64(0, a, b, &result);
    return result * !borrow_flag;

For addition:

We can use the adcx instruction

In MSVC we can use the intrinsic function _addcarry_u64 (also available in other bit sizes).

Here is how it is used:

// *c = a + b + carry
// carry_flag is set to 1 if there is a carry bit
carry_flag = _addcarry_u64(carry_flag, a, b, c);

Here is how we could apply it to your situation

uint64_t add_no_overflow(uint64_t a, uint64_t b){
    uint64_t result;
    carry_flag = _addcarry_u64(0, a, b, &result);
    return !carry_flag * result - carry_flag;

I don't like this one as much as the subtraction one, but I think it is pretty nifty.

If the add overflows, carry_flag = 1. Not-ing carry_flag yields 0, so !carry_flag * result = 0 when there is overflow. And since 0 - 1 will set the unsigned integral value to its max, the function will return the result of the addition if there is no carry and return the max of the chosen integral value if there is carry.

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    You might want to mention that this answer is for a specific instruction-set architecture (x86?) and will require reimplementing for each target architecture (SPARC, MIPS, ARM, etc) – Toby Speight Mar 4 at 18:43

what about this:

bsum = a + b;
bsum = (bsum < a || bsum < b) ? 255 : bsum;

bsub = a - b;
bsub = (bsub > a || bsub > b) ? 0 : bsub;
  • I fixed the (obvious?) typo, but I still don't think this is correct. – Bathsheba Nov 2 '15 at 15:46
  • you are right will fix issue. – user4580220 Nov 2 '15 at 15:47
  • This also includes branching. – fuz Nov 2 '15 at 15:49
  • I will delete this answer just a quick question in assembly without optimization what is difference between ternary operator and if/else statement? – user4580220 Nov 2 '15 at 15:57
  • @GRC There is no difference. – fuz Nov 2 '15 at 15:59

All can be done in unsigned byte arithmetic

// Addition without overflow
return (b > 255 - a) ? 255 : a + b

// Subtraction without underflow
return (b > a) ? 0 : a - b;
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    This is actually one of the best solutions. All the others making the substraction or addition before are actually creating an undefined behavior in C++, resulting in the compiler being able to do whatever it wants. In practice you can mostly predict what will happen, but still. – Adrien Hamelin Nov 7 '15 at 13:13

If you want to do this with two bytes, use the simplest code possible.

If you want to do this with twenty billion bytes, check what vector instructions are available on your processor and whether they can be used. You might find that your processor can do 32 of these operations with a single instruction.


You could also use the safe numerics library at Boost Library Incubator. It provides drop-in replacements for int, long, etc... which guarantee that you'll never get an undetected overflow, underflow, etc.

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    Providing an example of how to use the library would make this a better answer. In addition, do they provide a brachless guarantee? – Shafik Yaghmour Nov 2 '15 at 16:59
  • The library has extensive documentation and examples. But the end of the day it's as easy as including the appropriate header and substituting safe<int> for int. – Robert Ramey Nov 3 '15 at 17:35
  • branchless? I guess you man branchless. The library uses template metaprogramming to include run time checks only when necessary. For example unsigned char times unsigned char will result in unsigned int. This can never overflow so no checking at all need be done. On the other hand, unsigned times unsigned can overflow so it has to be checked at runtime. – Robert Ramey Nov 3 '15 at 17:38

If you will call those methods a lot, the fastest way would be not bit manipulation but probably a look-up table. Define an array of length 511 for each operation. Example for minus (subtraction)

static unsigned char   maxTable[511];
memset(maxTable, 0, 255);           // If smaller, emulates cutoff at zero
maxTable[255]=0;                    // If equal     - return zero
for (int i=0; i<256; i++)
    maxTable[255+i] = i;            // If greater   - return the difference

The array is static and initialized only once. Now your subtraction can be defined as inline method or using pre-compiler:

#define MINUS(A,B)    maxTable[A-B+255];

How it works? Well you want to pre-calculate all possible subtractions for unsigned chars. The results vary from -255 to +255, total of 511 different result. We define an array of all possible results but because in C we cannot access it from negative indices we use +255 (in [A-B+255]). You can remove this action by defining a pointer to the center of the array.

const unsigned char *result = maxTable+255;
#define MINUS(A,B)    result[A-B];

use it like:

bsub  = MINUS(13,15); // i.e 13-15 with zero cutoff as requested

Note that the execution is extremely fast. Only one subtraction and one pointer deference to get the result. No branching. The static arrays are very short so they will be fully loaded into CPU's cache to further speed up the calculation

Same would work for addition but with a bit different table (first 256 elements will be the indices and last 255 elements will be equal to 255 to emulate the cutoff beyond 255.

If you insist on bits operation, the answers that use (a>b) are wrong. This still might be implemented as branching. Use the sign-bit technique

// (num1>num2) ? 1 : 0
#define        is_int_biggerNotEqual( num1,num2) ((((__int32)((num2)-(num1)))&0x80000000)>>31)

Now you can use it for calculation of subtraction and addition.

If you want to emulate the functions max(), min() without branching use:

inline __int32 MIN_INT(__int32 x, __int32 y){   __int32 d=x-y; return y+(d&(d>>31)); }              

inline __int32 MAX_INT(__int32 x, __int32 y){   __int32 d=x-y; return x-(d&(d>>31)); }

My examples above use 32 bits integers. You can change it to 64, though I believe that 32 bits calculations run a bit faster. Up to you

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    It likely will not, actually: first, of course, loading up the table is slow. Bit operations take 1 cycle, loading from memory takes approximately 80 ns; even from the L1 cache we're in the range of 20 ns, which is almost 7 cycles on a 3GHz CPU. – edmz Nov 2 '15 at 17:53
  • You are not entirely correct. LUT method will take a few sycles but bit manipulation is not a single cycle as well. There are a few sequential actions. For example, only calculating the MAX() requires 2 subtractions, and logical operation and one shift right. And don't forget the integer promotion/demotion – DanielHsH Nov 2 '15 at 17:59
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    I meant to say that single bitwise operations take 1 cycle, naturally assuming register operands. With the code that Shafik showed, clang outputs 4 elementary instructions. Also (x > y), is branchless. – edmz Nov 2 '15 at 18:09
  • First, (x > y) might use branching. You don't know on which architecture you are running. I tend to agree that it is possibly branchless on Intel architecture. Most smartphones are not Intel. That is also the reason that you cannot know how many assembly instructions there will be. Try my solution on your PC. I am interested in hearing the results. – DanielHsH Nov 2 '15 at 18:20
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    L1 cache is much much faster than 20 ns, it's in the order of maybe 4 processor cycles. And will likely be using an otherwise unused execution unit, and be fully pipelined anyway. Measure it. And 20ns is 60 cycles in a 3 GHz CPU. – gnasher729 Nov 3 '15 at 1:42

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