What difference does it make when i use float and decimal data types in mysql. Which is ideal for using.

This is what I found when I had this doubt.
The decimal did exactly what's supposed to do on this cases, it truncated the rest, thus losing the 1/3 part. So for sums the decimal is better, but for divisions the float is better, up to some point, of course. I mean, using DECIMAL will not give you a "fail proof arithmetic" in any means. Hope this helps. 


A "float" in most environments is a binary floatingpoint type. It can accurately store base2 values (to a certain point), but cannot accurately store many base10 (decimal) values. Floats are most appropriate for scientific calculations. They're not appropriate for most businessoriented math, and inappropriate use of floats will bite you. Many decimal values can't be exactly represented in base2. Decimals store base10 numbers. Decimal is an good type for most business math (but any builtin "money" type is more appropriate for financial calculations), where the range of values exceeds that provided by integer types, and fractional values are needed. Decimals, as the name implies, are designed for base10 numbers  they can accurately store decimal values (again, to a certain point). 


Not just specific to MySQL, the difference between float and decimal types is the way that they represent fractional values. Floating point types represent fractions in binary, which can only represent values as 


decimal is for fixed quantities like money where you want a specific number of decimal places. Floats are for storing ... floating point precision numbers. 


MySQL recently changed they way they store the DECIMAL type. In the past they stored the characters (or nybbles) for each digit comprising an ASCII (or nybble) representation of a number  vs  a two's complement integer, or some derivative thereof. The current storage format for DECIMAL is a series of 1,2,3,or 4byte integers whose bits are concatenated to create a two's complement number with an implied decimal point, defined by you, and stored in the DB schema when you declare the column and specify it's DECIMAL size and decimal point position. By way of example, if you take a 32bit int you can store any number from 0  4,294,967,295. That will only reliably cover 999,999,999, so if you threw out 2 bits and used (1<<30 1) you'd give up nothing. Covering all 9digit numbers with only 4 bytes is more efficient than covering 4 digits in 32 bits using 4 ASCII characters, or 8 nybble digits. (a nybble is 4bits, allowing values 015, more than is needed for 09, but you can't eliminate that waste by going to 3 bits, because that only covers values 07) The example used on the MySQL online docs uses DECIMAL(18,9) as an example. This is 9 digits ahead of and 9 digits behind the implied decimal point, which as explained above requires the following storage. As 18 8bit chars: 144 bits As 18 4bit nybbles: 72 bits As 2 32bit integers: 64 bits Currently DECIMAL supports a max of 65 digits, as DECIMAL(M,D) where the largest value for M allowed is 65, and the largest value of D allowed is 30. So as not to require chunks of 9 digits at a time, integers smaller than 32bits are used to add digits using 1,2 and 3 byte integers. For some reason that defies logic, signed, instead of unsigned ints were used, and in so doing, 1 bit gets thrown out, resulting in the following storage capabilities. For 1,2 and 4 byte ints the lost bit doesn't matter, but for the 3byte int it's a disaster because an entire digit is lost due to the loss of that single bit. With an 7bit int: 0  99 With a 15bit int: 0  9,999 With a 23bit int: 0  999,999 (0  9,999,999 with a 24bit int) 1,2,3 and 4bit ints are concatenated together to form a "bit pool" DECIMAL uses to represent the number precisely as a two's complement integer. The decimal point is NOT stored, it is implied. This means that no ASCII to int conversions are required of the DB engine to convert the "number" into something the CPU recognizes as a number. No rounding, no conversion errors, it's a real number the CPU can manipulate. Calculations on this arbitrarily large integer must be done in software, as there is no hardware support for this kind of number, but these libraries are very old and highly optimized, having been written 50 years ago to support IBM 370 Fortran arbitrary precision floating point data. They're still a lot slower than fixedsized integer algebra done with CPU integer hardware, or floating point calculations done on the FPU. In terms of storage efficiency, because the exponent of a float is attached to each and every float, specifying implicitly where the decimal point is, it is massively redundant, and therefore inefficient for DB work. In a DB you already know where the decimal point is to go up front, and every row in the table that has a value for a DECIMAL column need only look at the 1 & only specification of where that decimal point is to be placed, stored in the schema as the arguments to a DECIMAL(M,D) as the implication of the M and the D values. The many remarks found here about which format is to be used for various kinds of applications are correct, so I won't belabor the point. I took the time to write this here because whoever is maintaining the linked MySQL online documentation doesn't understand any of the above and after rounds of increasingly frustrating attempts to explain it to them I gave up. A good indication of how poorly they understood what they were writing is the very muddled and almost indecipherable presentation of the subject matter. As a final thought, if you have need of highprecision floating point computation, there've been tremendous advances in floating point code in the last 20 years, and hardware support for 96bit and Quadruple Precision float are right around the corner, but there are good arbitrary precision libraries out there if manipulation of the stored value is important. 


Here's a similar question and answer that may help you 


Float: A small (singleprecision) floatingpoint number. Allowable values are 3.402823466E+38 to 1.175494351E38,0, and 1.175494351E38 to 3.402823466E+38. These are the theoretical limits, based on the IEEE standard. The actual range might be slightly smaller depending on your hardware or operating system. DECIMAL: A packed “exact” fixedpoint number. M is the total number of digits (the precision) and D is the number of digits after the decimal point (the scale). The decimal point and (for negative numbers) the “” sign are not counted inM. If D is 0, values have no decimal point or fractional part. The maximum number of digits (M) for DECIMAL is 65. The maximum number of supported decimals (D) is 30. If D is omitted, the default is 0. If M is omitted, the default is 10. 


If you are after performance and not precision, you should note that calculations with floats are much faster than decimals 





in float when set value to integer print 10 but in decimal 11 

