Note that your compiler may already give you what you want if you code
value = min (value, 255). This may be translated into a
MIN instruction if it exists, or into a comparison followed by conditional move, such as the
CMOVcc instruction on x86.
The following code assumes two's complement representation of integers, which is usually a given today. The conversion from Boolean to integer should not involve branching under the hood, as modern architectures either provide instructions that can directly be used to form the mask (e.g.
SETcc on x86 and
ISETcc on NVIDIA GPUs), or can apply predication or conditional moves. If all of those are lacking, the compiler may emit a branchless instruction sequence based on arithmetic right shift to construct a mask, along the lines of Boann's answer. However, there is some residual risk that the compiler could do the wrong thing, so when in doubt, it would be best to disassemble the generated binary to check.
int value, mask;
mask = 0 - (value > 255); // mask = all 1s if value > 255, all 0s otherwise
value = (255 & mask) | (value & ~mask);
On many architectures, use of the ternary operator
?: can also result in a branchless instruction sequences. The hardware may support select-type instructions which are essentially the hardware equivalent of the ternary operator, such as
ICMP on NVIDIA GPUs. Or it provides
CMOV (conditional move) as in x86, or predication as on ARM, both of which can be used to implement branch-less code for ternary operators. As in the previous case, one would want to examine the disassembled binary code to be absolutely sure the resulting code is without branches.
value = (value > 255) ? 255 : value;
In case of floating-point operands, modern floating-point units typically provide
FMAX instructions which map straight to the C/C++ standard math functions
fmax() may be translated into a comparison followed by a conditional move. Again, it would be prudent to examine the generated code to make sure it is branchless.
value = fmax (fmin (value, 1.0), 0.0);