### Don't compare FPU decimal string fractions for equality

The problem is that the equality comparison of a floating or double value with a decimal constant that contains a fraction is rarely successful.

Very few decimal string fractions have exact values in the binary FP representation, so equality comparisons are usually doomed.^{*}

To answer your exact question, the `2`

is coming from a slightly different conversion of the decimal string fraction into the `Float`

format. Because the fraction cannot be represented exactly, it's possible that two computations will consider different amounts of precision in intermediate calculations and ultimately end up rounding the result to a 52-bit IEEE 754 double precision mantissa differently. It hardly matters because there *is* no exact representation anyway, but one is probably more wrong than the other.

In particular, your `1876.8`

cannot be represented exactly by an FP object, in fact, between 0.01 and 0.99, only 0.25, 0.50, and 0.75 have exact binary representations. All the others, include 1876.8, repeat forever and are rounded to 52 bits. This is about half of the reason that BigDecimal even exists. (The other half of the reason is the fixed precision of FP data: sometimes you need more.)

So, the result that you get when comparing an actual machine value with a decimal string constant depends on every single bit in the binary fraction ... down to 1/2^{52} ... and even then requires rounding.

If there is anything even the slightest bit (hehe, *bit,* sorry) imperfect about the process that produced the number, or the input conversion code, or anything else involved, they won't look exactly equal.

An argument could even be made that the comparison *should* always fail because no IEEE-format FPU can even represent that number exactly. They really are not equal, even though they look like it. On the left, your decimal string has been converted to a binary string, and most of the numbers just don't convert exactly. On the right, it's still a decimal string.

So don't mix floats with BigDecimal, just compare one BigDecimal with another BigDecimal. (Even when both operands *are* floats, testing for equality requires great care or a fuzzy test. Also, don't trust every formatted digit: output formatting will carry remainders way off the right side of the fraction, so you don't generally start seeing zeroes, you will just see garbage values.)

^{*The problem: machine numbers are x/2n, but decimal constants are x/(2n * 5m). Your value as sign, exponent, and mantissa is the infinitely repeating 0 10000001001 1101010100110011001100110011001100110011001100110011... Ironically, FP arithmetic is perfectly precise and equality comparisons work perfectly well when the value has no fraction.}