[Edit Oct 2021]

Next versions of C (C23) may "make `DECIMAL_DIG`

obsolescent".

I recommend you consider alternatives.

What is the difference between `DECIMAL_DIG`

and `LDBL_DIG`

(?)

`DECIMAL_DIG`

concerns *widest floating point type* to *decimal text* to *widest floating point type* conversions.

`LDBL_DIG`

concerns *decimal text* to `long double`

to *decimal text* conversions.

First: **Narrow the problem**

`DECIMAL_DIG`

(available since C99) applies to the *widest* floating point type. With C11, 3 type specific macros `FLT_DECIMAL_DIG`

, `DBL_DECIMAL_DIG`

, `LDBL_DECIMAL_DIG`

mean the same thing except they apply to the corresponding type, rather than the *widest* one.

To simplify the problem, let us compare `LDBL_DECIMAL_DIG`

to `LDBL_DIG`

as they both deal with the same type: `long double`

.

*decimal text representation* --> `long double`

--> *decimal text representation*.

`LDBL_DIG`

is the maximum significant digits of text that in this *round-trip* always result in the same starting value.

`long double`

--> *decimal text representation* --> `long double`

.

`LDBL_DECIMAL_DIG`

is the number of significant digits of text needed in this *round-trip* to always result in the same starting `long double`

value.

If the floating point type used a base 10 presentation, `LDBL_DIG`

and `LDBL_DECIMAL_DIG`

would have the same value. Yet most C implementations use a binary base 2 instead of 10: `FLT_RADIX == 2`

.

The follows avoids a deep mathematical technical explanation.

`long double`

can not represent every possible value that *decimal text representation* does. The latter can be `s = "0.1234567890123456789012345678901234567890"`

and common `long double`

can not represent that *exactly*. Converting `s`

into `long double`

and back to text is not expected to return the same result.

```
char *s = "0.1234567890123456789012345678901234567890";
long double ld = strtold(s, (char **)NULL);
printf("%.40Le\n", ld);
// typical output v -- different
// 1.2345678901234567890132180073559098332225e-01
```

If we limit text input to `LDBL_DIG`

*significant* digits though, code will always succeed for all values of `long double`

- round trip successfully.

```
s = "0.123456789012345678";
ld = strtold(s, (char **)NULL);
printf("%d\n%.*Le\n", LDBL_DIG, LDBL_DIG - 1, ld);
// 18
// 1.23456789012345678e-01
```

This post Printf width specifier to maintain precision of floating-point value details the use of `xxx_DECIMAL_DIG`

family of macros. It shows the number of significant digits need to print a floating-point value to text and then convert back to a FP value and always get the same result.

Note: `xxx_DECIMAL_DIG >= xxx_DIG`

.

`LDBL_DIG - 1`

used above rather than `LDBL_DIG`

as `%.*Le`

prints a leading digit and then the specified precision number of digits. The total significant digit count should be `LDBL_DIG`

.

Further info to answer Are the definitions I quoted wrong or not?

First definition is close, yet not complete.

`LDBL_DIG`

refers to text --> `long double`

--> text needs.

`LDBL_DIG`

OP's: "number of decimal digits that can be represented without losing precision for long double."

C Spec: "number of decimal digits, *q*, such that any floating-point number with *q* decimal digits can be rounded into a floating-point number with *p* radix *b* digits and back again without change to the *q* decimal digits,"

q = floor((p-1)*log_{10}b)

With OP's machine, `long double`

has p == 64 and b == 2 --> q == 18

Thus a decimal number with up to 18 significant digits, as text, can be converted to a `long double`

and then back to an 18 digit number, in *text* and always get the starting text value - for the normal `long double`

range.

`DECIMAL_DIG`

Second definition is amiss.

`DECIMAL_DIG`

refers to `long double`

--> *text* --> `long double`

needs.

OP's definition speaks of *text* to `long double`

to *text*.

OP's: "number of decimal digits that can be converted to long double and back without losing precision."

C Spec: "number of decimal digits, *n*, such that any floating-point number in the widest supported floating type with *p*_{max} radix *b* digits can be rounded to a floating-point number with *n* decimal digits and back again without change to the value,"

n = ceil(1 + p_{max}*log_{10}b)

With OP's machine, has p == 64 and b == 2 --> n == 21

Thus `long double`

s need to be converted to a decimal numbers with at least 21 significant digits, as text, to be convert back to the same `long double`

- for the normal `long double`

range.