I recommend @Jens Gustedt hexadecimal solution: use %a.

OP wants “print with maximum precision (or at least to the most significant decimal)”.

A simple example would be to print one seventh as in:

```
#include <float.h>
int Digs = DECIMAL_DIG;
double OneSeventh = 1.0/7.0;
printf("%.*e\n", Digs, OneSeventh);
// 1.428571428571428492127e-01
```

But let's dig deeper ...

Mathematically, the answer is "0.142857 142857 142857 ...", but we are using finite precision floating point numbers.
Let's assume IEEE 754 double-precision binary.
So the `OneSeventh = 1.0/7.0`

results in the value below. Also shown are the preceding and following representable `double`

floating point numbers.

```
OneSeventh before = 0.1428571428571428 214571170656199683435261249542236328125
OneSeventh = 0.1428571428571428 49212692681248881854116916656494140625
OneSeventh after = 0.1428571428571428 769682682968777953647077083587646484375
```

Printing the *exact* decimal representation of a `double`

has limited uses.

C has 2 families of macros in `<float.h>`

to help us.

The first set is the number of *significant* digits to print in a string in decimal so when scanning the string back,
we get the original floating point. There are shown with the C spec's *minimum* value and a *sample* C11 compiler.

```
FLT_DECIMAL_DIG 6, 9 (float) (C11)
DBL_DECIMAL_DIG 10, 17 (double) (C11)
LDBL_DECIMAL_DIG 10, 21 (long double) (C11)
DECIMAL_DIG 10, 21 (widest supported floating type) (C99)
```

The second set is the number of *significant* digits a string may be scanned into a floating point and then the FP printed, still retaining the same string presentation. There are shown with the C spec's *minimum* value and a *sample* C11 compiler. I believe available pre-C99.

```
FLT_DIG 6, 6 (float)
DBL_DIG 10, 15 (double)
LDBL_DIG 10, 18 (long double)
```

The first set of macros seems to meet OP's goal of *significant* digits. But that *macro* is not always available.

```
#ifdef DBL_DECIMAL_DIG
#define OP_DBL_Digs (DBL_DECIMAL_DIG)
#else
#ifdef DECIMAL_DIG
#define OP_DBL_Digs (DECIMAL_DIG)
#else
#define OP_DBL_Digs (DBL_DIG + 3)
#endif
#endif
```

The "+ 3" was the crux of my previous answer.
Its centered on if knowing the round-trip conversion string-FP-string (set #2 macros available C89), how would one determine the digits for FP-string-FP (set #1 macros available post C89)? In general, add 3 was the result.

Now how many *significant* digits to print is known and driven via `<float.h>`

.

To print N *significant* decimal digits one may use various formats.

With `"%e"`

, the *precision* field is the number of digits *after* the lead digit and decimal point.
So `- 1`

is in order. Note: This `-1`

is not in the initial `int Digs = DECIMAL_DIG;`

```
printf("%.*e\n", OP_DBL_Digs - 1, OneSeventh);
// 1.4285714285714285e-01
```

With `"%f"`

, the *precision* field is the number of digits *after* the decimal point.
For a number like `OneSeventh/1000000.0`

, one would need `OP_DBL_Digs + 6`

to see all the *significant* digits.

```
printf("%.*f\n", OP_DBL_Digs , OneSeventh);
// 0.14285714285714285
printf("%.*f\n", OP_DBL_Digs + 6, OneSeventh/1000000.0);
// 0.00000014285714285714285
```

Note: Many are use to `"%f"`

. That displays 6 digits after the decimal point; 6 is the display default, not the precision of the number.

recommending that one uses an assumption out of air instead of taking the portable approach?`printf( "%f", val );`

which is already portable, efficient, and the default.maximum precisionby default if no precision is specified?`double`

. As your`double`

gets extremely large (very far from 1.0), it actually getsless accuratein the decimal portion (value portion less than 1.0). So you can't really have a satisfactory answer here, because your question has a false assumption in it (namely that all`float`

s/`double`

s are created equal)minimumvalues.5more comments