My answer on the main question: "Is there a floating point value of x, for which x-x == 0 is false?" is: at least floating point implementation on Intel processors makes **NO** arithmetic underflow in "+" and "-" operations and so you will be not able to find an x for which x-x == 0 is false. The same is true for **all processors which supports IEEE 754-2008** (see references bellow).

My short answer on another your question: if (x-y == 0) is exactly so safe as if (x == y), so assert(x-x == 0) is OK, because **no arithmetic underflow will be produced** in x-x or (x-y).

The reason is following. A float/double number will be hold in memory in the form mantissa and binary exponent. In the standard case mantissa is normalized: it is >= 0.5 and < 1. In `<float.h>`

you can find some constants from IEEE floating point standard. Interesting now for us are only following

```
#define DBL_MIN 2.2250738585072014e-308 /* min positive value */
#define DBL_MIN_10_EXP (-307) /* min decimal exponent */
#define DBL_MIN_EXP (-1021) /* min binary exponent */
```

But not everybody knows, that you can have double numbers **less then** DBL_MIN. If you makes arithmetical operations with numbers under DBL_MIN, this number will be *NOT* normalized and so you works with this numbers like with integers (operation with mantissa only) without any "round errors".

**Remark**: I personally try not use words "round errors", because there are **no errors** in arithmetical computer operations. These operation are only not the same as +,-,* and / operations with the same computer numbers like floating number. There are **deterministic operations** on the subset of floating point numbers which can be saved in the form (mantissa,exponent) with well defined number of bits for each. Such subset of floats we can named as *computer floating number*. So the result of *classical floating point operation* will be *projected* back to the computer floating number set. Such projecting operation is deterministic, and have a lot of features like if x1 >= x2 then x1*y >= x2*y.

Sorry for the long remark and back to our subject.

To show exactly what we have if we operate with numbers less then DBL_MIN I wrote a small program in C:

```
#include <stdio.h>
#include <float.h>
#include <math.h>
void DumpDouble(double d)
{
unsigned char *b = (unsigned char *)&d;
int i;
for (i=1; i<=sizeof(d); i++) {
printf ("%02X", b[sizeof(d)-i]);
}
printf ("\n");
}
int main()
{
double x, m, y, z;
int exp;
printf ("DBL_MAX=%.16e\n", DBL_MAX);
printf ("DBL_MAX in binary form: ");
DumpDouble(DBL_MAX);
printf ("DBL_MIN=%.16e\n", DBL_MIN);
printf ("DBL_MIN in binary form: ");
DumpDouble(DBL_MIN);
// Breaks the floating point number x into its binary significand
// (a floating point value between 0.5(included) and 1.0(excluded))
// and an integral exponent for 2
x = DBL_MIN;
m = frexp (x, &exp);
printf ("DBL_MIN has mantissa=%.16e and exponent=%d\n", m, exp);
printf ("mantissa of DBL_MIN in binary form: ");
DumpDouble(m);
// ldexp() returns the resulting floating point value from
// multiplying x (the significand) by 2
// raised to the power of exp (the exponent).
x = ldexp (0.5, DBL_MIN_EXP); // -1021
printf ("the number (x) constructed from mantissa 0.5 and exponent=DBL_MIN_EXP (%d) in binary form: ", DBL_MIN_EXP);
DumpDouble(x);
y = ldexp (0.5000000000000001, DBL_MIN_EXP);
m = frexp (y, &exp);
printf ("the number (y) constructed from mantissa 0.5000000000000001 and exponent=DBL_MIN_EXP (%d) in binary form: ", DBL_MIN_EXP);
DumpDouble(y);
printf ("mantissa of this number saved as double will be displayed by printf(%%.16e) as %.16e and exponent=%d\n", m, exp);
y = ldexp ((1 + DBL_EPSILON)/2, DBL_MIN_EXP);
m = frexp (y, &exp);
printf ("the number (y) constructed from mantissa (1+DBL_EPSILON)/2 and exponent=DBL_MIN_EXP (%d) in binary form: ", DBL_MIN_EXP);
DumpDouble(y);
printf ("mantissa of this number saved as double will be displayed by printf(%%.16e) as %.16e and exponent=%d\n", m, exp);
z = y - x;
m = frexp (z, &exp);
printf ("z=y-x in binary form: ");
DumpDouble(z);
printf ("z will be displayed by printf(%%.16e) as %.16e\n", z);
printf ("z has mantissa=%.16e and exponent=%d\n", m, exp);
if (x == y)
printf ("\"if (x == y)\" say x == y\n");
else
printf ("\"if (x == y)\" say x != y\n");
if ((x-y) == 0)
printf ("\"if ((x-y) == 0)\" say \"(x-y) == 0\"\n");
else
printf ("\"if ((x-y) == 0)\" say \"(x-y) != 0\"\n");
}
```

This code produced following output:

```
DBL_MAX=1.7976931348623157e+308
DBL_MAX in binary form: 7FEFFFFFFFFFFFFF
DBL_MIN=2.2250738585072014e-308
DBL_MIN in binary form: 0010000000000000
DBL_MIN has mantissa=5.0000000000000000e-001 and exponent=-1021
mantissa of DBL_MIN in binary form: 3FE0000000000000
the number (x) constructed from mantissa 0.5 and exponent=DBL_MIN_EXP (-1021) in binary form: 0010000000000000
the number (y) constructed from mantissa 0.5000000000000001 and exponent=DBL_MIN_EXP (-1021) in binary form: 0010000000000001
mantissa of this number saved as double will be displayed by printf(%.16e) as 5.0000000000000011e-001 and exponent=-1021
the number (y) constructed from mantissa (1+DBL_EPSILON)/2 and exponent=DBL_MIN_EXP (-1021) in binary form: 0010000000000001
mantissa of this number saved as double will be displayed by printf(%.16e) as 5.0000000000000011e-001 and exponent=-1021
z=y-x in binary form: 0000000000000001
z will be displayed by printf(%.16e) as 4.9406564584124654e-324
z has mantissa=5.0000000000000000e-001 and exponent=-1073
"if (x == y)" say x != y
"if ((x-y) == 0)" say "(x-y) != 0"
```

So we can see, that if we work with numbers less then DBL_MIN, they will be not normalized (see `0000000000000001`

). We are working with these numbers like with integers and without any "errors". Thus if we assign `y=x`

then `if (x-y == 0)`

is exactly so safe as `if (x == y)`

, and `assert(x-x == 0)`

works OK. In this example, z = 0.5 * 2 ^(-1073) = 1 * 2 ^(-1072). This number is really the smallest number which can we have saved in double. All arithmetical operation with numbers less DBL_MIN works like with integer multiplied with 2 ^(-1072).

So I has **no underflow** problems on my Windows 7 computer with Intel processor. **If somebody have another processor it would be interesting to compare our results**.

Have somebody an idea how one can produce arithmetic underflow with - or + operations? My experiments looks like so, that it is impossible.

**EDITED**: I modified the code a little for better readability of the code and the messages.

**ADDED LINKS**: My experiments shows, that http://grouper.ieee.org/groups/754/faq.html#underflow is absolutely correct on my Intel Core 2 CPU. The way how it will be calculated produce *no underflow* in "+" and "-" floating point operations. My results are independent on Strict (/fp:strict) or Precise (/fp:precise) Microsoft Visual C compiler switches (see http://msdn.microsoft.com/en-us/library/e7s85ffb%28VS.80%29.aspx and http://msdn.microsoft.com/en-us/library/Aa289157)

**ONE MORE (PROBABLY THE LAST ONE) LINK AND MY FINAL REMARK**: I found a good reference http://en.wikipedia.org/wiki/Subnormal_numbers, where is described the same what I written before. Including of denormal numbers or denormalized numbers (now often called subnormal numbers for example in In IEEE 754-2008) follow to following statment:

“Denormal numbers provide the
guarantee that addition and
subtraction of floating-point numbers
never underflows; two nearby
floating-point numbers always have a
representable non-zero difference.
Without gradual underflow, the
subtraction a−b can underflow and
produce zero even though the values
are not equal.”

So all my results **must** be correct on any processor which supports IEEE 754-2008.