Generally, addition or multiplication of a value with integer type with a value of floating-point type is performed by first converting the integer to floating-point and then by performing the arithmetic operation. If the integer value cannot be exactly represented in the floating-point format, then error is introduced even before the operation is performed. With the small integers in your example, this is not an issue.

The arithmetic operation will introduce error if the exact mathematical result is not representable in the floating-point type. There are two ways in which the results might not be representable:

- One is that the number of bits (or digits generally, when not using binary floating-point) needed to represent the significand (fraction portion) do not fit in the floating-point format.
- Another is that the magnitude of the result exceeds the range of the floating-point format, resulting in overflow or underflow.

Your examples do not approach the magnitudes where overflow or underflow occur, so I will not discuss them here.

Assuming you are using IEEE-754 32-bit binary floating-point, which is commonly used for `float`

in C implementations, the significand is 24 bits. So anytime you perform an operation whose result requires more than 24 bits to represent, you get an error. This 24-bit span is measured from the highest set bit in a number to its lowest set bit.

For example, 1111.11111111111111111111_{2} requires 24 bits to represent. If you add 10000_{2} to it, the exact mathematical result is 11111.11111111111111111111_{2}. This requires 25 bits, so it does not fit, so the floating-point implementation must round the exact mathematical result to a representable result. (In the common round-to-nearest mode with this particular value, it rounds the low bit up, causing a carry through all the bits, producing 100000_{2}.)

Now you can get some sense of what operations will have errors. If you add two numbers of different magnitudes, some of the low bits of the smaller number will be “pushed out” of the result. If any of those bits are not zero, then information is lost, an error occurs. Additionally, the result might cross a power-of-two boundary, where its highest bit is higher than the highest bit of either of the input values. This pushes another bit out of the significand. For example, if we add 1000 to 1111.11111111111111111111_{2}, the exact mathematical result is 10111.11111111111111111111_{2}. This requires 25 bits, so the low bit is rounded, producing 11000_{2}.

Suppose you have two numbers that require *a* and *b* bits in their significands. When you multiply them, the exact mathematical result requires *a*+*b*–1 or *a*+*b* bits, depending on whether there is a “carry” that produces a new high bit. For example, 11_{2}•111_{2} = 10101_{2}, two bits times three bits produces five bits. Or 1.001_{2}•1.01_{2} = 1.01101_{2}, four bits times three bits produces six bits. So multiplications by integers can produce rounding errors.

Multiplying by powers of two never produces rounding errors in this way, although it can cause overflow or underflow.