# stringstream setprecision and floating point formatting

``````double value = 02369.000133699;//acutally stored as 2369.000133698999900
const std::uint32_t left = std::uint32_t(std::abs(value) <  1 ? 1: (1 + std::log10(std::abs(value))));

std::ostringstream out;
out << std::setprecision(std::numeric_limits<T>::digits10 - left ) << std::fixed << value;
std::string str = out.str(); //str = "2369.00013369900"

std::ostringstream out2;
out2 << std::setprecision(std::numeric_limits<T>::digits10 ) << std::fixed << value;
std::string str2 = out2.str(); // str2 = "2369.000133698999900"
``````

I'm wondering how std::stringstream/precision works for formatting floating-point number. It seems that if precision argument is superior to `16` minus number of non-fractional digits, this lead to a formatting of form `"2369.000133698999900"` instead of a "nice" `"2369.00013369900"`

how `std::stringstream` know that `8999900` must be resume to one `9` even if I don"t tell it to do the rounding on the `8` (like passing `12` as argument to the `setprecision` function) ?but don't do it for argument superior to 12

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Formatting binary floating points as decimal values is fairly tricky. The underlying problem is that binary floating points cannot represent decimal values accurately. Even a simple number like 0.1 cannot be represented exactly using binary floating points. That is, the actual value represented is slightly different. When using clever algorithms for reading ("Bellerophon") and formatting ("Dragon4"; these are the names from the original papers and there are improvements of both algorithms which are used in practice) floating point numbers be used to transport decimal values. However, when asking the algorithm to format more decimal digits than it can actually hold, i.e., more than `std::numeric_limits<T>::digits10`, it will happily do so, [partially] revealing the value it is actually storing.