When you perform a single operation in properly implemented floating point and the rounding mode is round-to-nearest (the most common), the error is at most one-half the distance between representable numbers. This is because, in round-to-nearest mode, operations return the representable result that is nearest to the exact mathematical result. (This is called “correct rounding”.)

This includes operations such as converting numerals (such as “0.000001” or “1e-5”) to floating point. However, some operations, notably library routines for complicated operations such as sine or logarithm, typically do not always return correctly rounded results (due to the difficulty of doing so). Thus, you must check the specifications for your implementation before relying on error bounds.

32-bit IEEE 754 floating point uses a sign bit, eight exponent bits (representing normal exponents [of 2] from -126 to 127), and 23 explicit significand bits. (The proper term is significand. A mantissa is a fractional part of a logarithm.) The full significand has 24 bits because there is an implicit leading one (except for subnormal numbers, below 2^{-126} in magnitude). Thus, the distance between a representable number and the next higher representable number is 2^{-23} times the value of the leading one bit. That value is, of course, the highest power of two that is not greater than the number. (E.g., for 5, the leading bit has value 4, so the least significant bit has value 4•2^{-23} = 2^{-21}. Thus, if an exact mathematical result of a single operation would be around 5, the maximum error would be 2^{-22}.)

When you perform multiple operations, the error is hugely dependent upon the operations performed and the values involved. Careful analysis must be performed to determine error bounds. Depending on the operations, it is possible for errors to combine and to be magnified, so that errors can even become infinite.

Note that if you attempt to add 0.000001 100,000 times, you will have two kinds of errors. First, 0.000001 is not exactly representable in binary floating point, so there is an error in the operation of converting that numeral to floating point. Second, each addition may have a rounding error.

You also mention maintaining identical information in different processes. This is a separate, although overlapping, problem from bounding error. If the processes are running on identical platforms, it might not be difficult to keep them synchronized, by making them all perform identical operations with identical data, using identical hardware and libraries. This is because floating-point errors are generally not random; performing the same operations on the same data will always return the same results. (Some problem may occur when hardware or library behavior is not fully specified and is permitted to depend on unrelated data, although this tends to be more of a theoretical concern than a problem in practice.) Note that identical platforms means completely identical. Something as small as using a different version of the otherwise same library can produce different results.

If processes are running on different platforms, it can be difficult to keep them synchronized. Even if running with software compiled from identical sources, the compiler may implement the high-level language using different choices of floating-point operations. Among the most notorious is using more precision than the high-level language requires, which some languages permit.

Clause 11 of the IEEE 754-2008 standard has information about producing reproducible floating-point results. Computing platforms might not provide the necessary guarantees to support this.