0.1 + 0.2 == 0.3
> false
0.1 + 0.2
> 0.30000000000000004
Any ideas why this happens?
Any ideas why this happens? 


Binary floating point math is like this. In most programming languages, it is based on the IEEE 754 standard. JavaScript uses 64bit floating point representation, which is the same as Java's For
In contrast, the rational number
The constants A fairly comprehensive treatment of floatingpoint arithmetic issues is What Every Computer Scientist Should Know About FloatingPoint Arithmetic. For an easiertodigest explanation, see floatingpointgui.de. 


A Hardware Designer's PerspectiveI believe I should add a hardware designer’s perspective to this since I design and build floating point hardware. Knowing the origin of the error may help in understanding what is happening in the software, and ultimately, I hope this helps explain the reasons for why floating point errors happen, and seem to accumulate over time. 1. OverviewFrom an engineering perspective, most floating point operations will have some element of error since the hardware that does the floating point computations is only required to have an error of less than one half of one unit in the last place. Therefore, much hardware will stop at a precision that's only necessary to yield an error of less than one half of one unit in the last place for a single operation which is especially problematic in floating point division. What constitutes a single operation depends upon how many operands the unit takes. For most, it is two, but some units take 3 or more operands. Because of this, there is no guarantee that repeated operations will result in a desirable error since the errors add up over time. 2. StandardsMost processors follow the IEEE754 standard but some use denormalized, or different standards . For example, there is a denormalized mode in IEEE754 which allows representation of very small floating point numbers at the expense of precision. The following however, will cover the normalized mode of IEEE754 which is the typical mode of operation. In the IEEE754 standard, hardware designers are allowed any value of error/epsilon as long as it's less than one half of one unit in the last place, and the result only has to be less than one half of one unit in the last place for one operation. This explains why when there are repeated operations, the errors add up. For IEEE754 double precision, this is the 54th bit, since 53 bits are used to represent the numeric part (normalized), also called the mantissa, of the floating point number (e.g. the 5.3 in 5.3e5). The next sections go into more detail on the causes of hardware error on various floating point operations. 3. Cause of Rounding Error in DivisionThe main cause of the error in floating point division, are the division algorithms used to calculate the quotient. Most computer systems calculate division using multiplication by an inverse, mainly in Z=X/Y, Z = X * (1/Y). Division is computed iteratively i.e. each cycle computes some bits of the quotient until the desired precision is reached, which for IEEE754 is anything with an error of less than one unit in the last place. The table of reciprocals of Y (1/Y) is known as the quotient selection table (QST) in slow division, and the size in bits of the quotient selection table is usually the width of the radix, or number of bits of the quotient computed in each iteration, plus a few guard bits. For the IEEE754 standard, double precision (64bit), it would be the size of the radix of the divider, plus a few guard bits k, where k>=2. So for example, a typical Quotient Selection Table for a divider that computes 2 bits of the quotient at a time (radix 4) would be 2+2= 4 bits (plus a few optional bits). 3.1 Division Rounding Error: Approximation of Reciprocal What reciprocals are in the quotient selection table depend on the division method: slow division such as SRT division, or fast division such as Goldschmidt division; each entry is modified according to the division algorithm in an attempt to yield the lowest possible error. In any case though, all reciprocals are approximations of the actual reciprocal, and introduce some element of error. Both slow division and fast division methods calculate the quotient iteratively, i.e. some number of bits of the quotient are calculated each step, then the result is subtracted from the dividend, and the divider repeats the steps until the error is less than one half of one unit in the last place. Slow division methods calculate a fixed number of digits of the quotient in each step and are usually less expensive to build, and fast division methods calculate a variable number of digits per step and are usually more expensive to build. The most important part of the division methods is that most of them rely upon repeated multiplication by an approximation of a reciprocal, so they are prone to error. 4. Rounding Errors in Other Operations: TruncationAnother cause of the rounding errors in all operations are the different modes of truncation of the final answer that IEEE754 allows. There's truncate, roundtowardszero, roundtonearest (default), rounddown, and roundup. All methods introduce an element of error of less than one half of one unit in the last place for a single operation. Over time and repeated operations, truncation also adds cumulatively to the resultant error. This truncation error, is especially problematic in exponentiation, which involves some form of repeated multiplication. 5. Repeated OperationsSince the hardware that does the floating point calculations only needs to yield a result with an error of less than one half of one unit in the last place for a single operation, the error will grow over repeated operations if not watched. This is the reason that in computations that require a bounded error, mathematicians use methods such as using the roundtonearest even digit in the last place of IEEE754, because over time, the errors are more likely to cancel each other out, and Interval Arithmetic combined with variations of the IEEE 754 rounding modes to predict rounding errors, and correct them. Because of its low relative error compared to other rounding modes, round to nearest even digit (in the last place), is the default rounding mode of IEEE754. Note that the default rounding mode, roundtonearest even digit in the last place, guarantees an error of less than one half of one unit in the last place for one operation. Using the truncation, roundup, and round down alone may result in an error that is greater than one half of one unit in the last place, but less than one unit in the last place, so these modes are not recommended unless they are used in Interval Arithmetic. 6. SummaryIn short, the fundamental reason for the errors in floating point operations is a combination of the truncation in hardware, and the truncation of a reciprocal in the case of division. Since the IEEE754 standard only requires an error of less than one half of one unit in the last place for a single operation, the floating point errors over repeated operations will add up unless corrected. 


Floating point rounding errors. 0.1 cannot be represented as accurately in base2 as in base10 due to the missing prime factor of 5. Just as 1/3 takes an infinite number of digits to represent in decimal, but is "0.1" in base3, 0.1 takes an infinite number of digits in base2 where it does not in base10. And computers don't have an infinite amount of memory. 


When you convert .1 or 1/10 to base 2 (binary) you get a repeating pattern after the decimal point, just like trying to represent 1/3 in base 10. The value is not exact, and therefore you can't do exact math with it using normal floating point methods. 


Most answers here address this question in very dry, technical terms. I'd like to address this in terms that normal human beings can understand. Imagine that you are trying to slice up pizzas. You have a robotic pizza cutter that can cut pizza slices exactly in half. It can halve a whole pizza, or it can halve an existing slice, but in any case, the halving is always exact. That pizza cutter has very fine movements, and if you start with a whole pizza, then halve that, and continue halving the smallest slice each time, you can do the halving 53 times before the slice is too small for even its highprecision abilities. At that point, you can no longer halve that very thin slice, but must either include or exclude it as is. Now, how would you piece all the slices in such a way that would add up to onetenth (0.1) or onefifth (0.2) of a pizza? Really think about it, and try working it out. You can even try to use a real pizza, if you have a mythical precision pizza cutter at hand. :) Most experienced programmers, of course, know the real answer, which is that there is no way to piece together an exact tenth or fifth of the pizza using those slices, no matter how finely you slice them. You can do a pretty good approximation, and if you add up the approximation of 0.1 with the approximation of 0.2, you get a pretty good approximation of 0.3, but it's still just that, an approximation. For doubleprecision numbers (which is the precision that allows you to halve your pizza 53 times), the numbers immediately less and greater than 0.1 are 0.09999999999999999167332731531132594682276248931884765625 and 0.1000000000000000055511151231257827021181583404541015625. The latter is quite a bit closer to 0.1 than the former, so a numeric parser will, given an input of 0.1, favour the latter. (The difference between those two numbers is the "smallest slice" that we must decide to either include, which introduces an upward bias, or exclude, which introduces a downward bias. The technical term for that smallest slice is an ulp.) In the case of 0.2, the numbers are all the same, just scaled up by a factor of 2. Again, we favour the value that's slightly higher than 0.2. Notice that in both cases, the approximations for 0.1 and 0.2 have a slight upward bias. If we add enough of these biases in, they will push the number further and further away from what we want, and in fact, in the case of 0.1 + 0.2, the bias is high enough that the resulting number is no longer the closest number to 0.3. In particular, 0.1 + 0.2 is really 0.1000000000000000055511151231257827021181583404541015625 + 0.200000000000000011102230246251565404236316680908203125 = 0.3000000000000000444089209850062616169452667236328125, whereas the number closest to 0.3 is actually 0.299999999999999988897769753748434595763683319091796875. P.S. Some programming languages also provide pizza cutters that can split slices into exact tenths. Although such pizza cutters are uncommon, if you do have access to one, you should use it when it's important to be able to get exactly onetenth or onefifth of a slice. 


In addition to the other correct answers, you may want to consider scaling your values to avoid problems with floatingpoint arithmetic. For example:
... instead of:
The expression As a practical example, to avoid floatingpoint problems where accuracy is paramount, it is recommended^{1} to handle money as an integer representing the number of cents: ^{1} Douglas Crockford: JavaScript: The Good Parts: Appendix A  Awful Parts (page 105). 


A solution to tidy up the unsightly overflow
Using 'toPrecision(12)' leaves trailing zeros which 'parseFloat()' removes. Assume it is accurate to plus/minus one on the least significant digit. 


My answer is quite long, so I've split it into three sections. Since the question is about floating point mathematics, I've put the emphasis on what the machine actually does. I've also made it specific to double (64 bit) precision, but the argument applies equally to any floating point arithmetic. Preamble A IEEE 754 doubleprecision binary floatingpoint format (binary64) number represents a number of the form
in 64 bits:
^{1}  IEEE 754 allows for the concept of a signed zero  ^{2}  This is not the case for denormal numbers, which have an offset exponent of zero (and an implied Turning a double precision number to binary Many online converters exist to convert a double precision floating point number to binary (e.g. at binaryconvert.com), but here is some sample C# code to obtain the IEEE 754 representation for a double precision number (I separate the three parts with colons (
Getting to the point: the original question (Skip to the bottom for the TL;DR version) @CatoJohnston (the question asker) asked why 0.1 + 0.2 != 0.3. Written in binary (with colons separating the three parts), the IEEE 754 representations of the values are:
Note that the mantissa is composed of recurring digits of Converting the exponents to decimal, removing the offset, and readding the implied
To add two numbers, the exponent needs to be the same, i.e.:
Since the sum is not of the form 2^{n} * 1.{bbb} we increase the exponent by one and shift the decimal (binary) point to get:
There are now 53 bits in the mantissa (the 53rd is in square brackets in the line above), so the final bit is rounded away from zero to 52 bits:
TL;DR Writing
Converted back to decimal, these values are:
The difference is exactly 2^{54}, which is ~5.5511151231258 × 10^{17}  insignificant (for many applications) when compared to the original values. Comparing the last few bits of a floating point number is inherently dangerous, as anyone who reads the famous "What Every Computer Scientist Should Know About FloatingPoint Arithmetic" (which covers all the major parts of this answer) will know. Most calculators use additional guard digits to get around this problem, which is how 


My workaround:
precision refers to the number of digits you want to preserve after the decimal point during addition. 


Floating point rounding error. From What Every Computer Scientist Should Know About FloatingPoint Arithmetic:






I found a solution you can use this function to parse floats correctly also you can set your own precision



Did you try the duct tape solution? Try to determine when errors occur and fix them with short if statements, it's not pretty but for some problems it is the only solution and this is one of them.
I had the same problem in a scientific simulation project in c#, and I can tell you that if you ignore the butterfly effect it's gonna turn to a big fat dragon and bite you in the a** 


Those weird numbers appear because computers use binary(base 2) number system for calculation purposes, while we use decimal(base 10). There are a majority of fractional numbers that cannot be represented precisely either in binary or in decimal or both. Result  A rounded up (but precise) number results. 


A lot of good answers was been posted. But short answer is that not all decimal numbers are the binary representation of floating point numbers. For example, the number "0.2" will be represented as "0.200000003" in single precision in IEEE754 float point standart. 


For those reading through this thread looking to get precision to a specific number of decimal places and not numbers, instead of num.toPrecision(2) you can use num.toFixed(2). 


To cut a long story short... For those who are using JAVA and having problems like that: Use 


Some statistics related to this famous double precision question. I used this code. When adding all values (a+b) using a step of 0.1 (from 0.1 to 100) we have ~15% chance of precision error. Here are some examples (for full .txt results here):
When subtracting all values (ab where a>b) using a step of 0.1 (from 100 to 0.1) we have ~34% chance of precision error. Here are some examples (for full .txt results here):
*I was surprised with these 15% and 34%.. they are huge, so always use BigDecimal when precision is of big importance. With 2 decimal digits (step 0.01) the situation worsens a bit more (18% and 36%). 


Took from PHP doc: http://php.net/manual/en/language.types.float.php#language.types.float.comparison



http://jsfiddle.net/ozbob/y4rak722/5/
kudos shared with to @Funkodebat 


Given that nobody has mentioned this... Some high level languages such as Python and Java come with tools to overcome binary floating point limitations. For example:
Neither of these solutions is perfect (especially if we look at performances, or if we require a very high precision), but still they solve a great number of problems with binary floating point arithmetic. 


The kind of floatingpoint math that can be implemented in a digital computer necessarily uses an approximation of the real numbers and operations on them. (The standard version runs to hundreds of pages of documentation and has a committee to deal with its errata and further refinement.) This approximation is a mixture of approximations of different kinds, each of which can either be ignored or carefully accounted for due to its specific manner of deviation from exactitude. It also involves a number of explicit exceptional cases at both the hardware and software levels that most people walk right past while pretending not to notice. If you need infinite precision (using the number π, for example, instead of one of its many shorter standins), you should write or use a symbolic math program instead. But if you're okay with the idea that sometimes floatingpoint math is fuzzy in value and logic and errors can accumulate quickly, and you can write your requirements and tests to allow for that, then your code can frequently get by with what's in your FPU. 


Thank you for your interest in this question.
Because it has attracted lowquality answers, posting an answer now requires 10 reputation on this site.
Would you like to answer one of these unanswered questions instead?