Thanks to recent post on the official newsgroup by Oleksandr Rasputinov, now I have learned two undocumented functions which control the tolerance of `Equal`

and `SameQ`

: `$EqualTolerance`

and `$SameQTolerance`

. In *Mathematica* version 5 and earlier these functions live in the `Experimental``

context and are well documented: $EqualTolerance, $SameQTolerance. Starting from version 6, they are moved to the `Internal``

context and become undocumented but still work and even have built-in diagnostic messages which appear when one try to assign them illegal values:

```
In[1]:= Internal`$SameQTolerance = a
During evaluation of In[2]:= Internal`$SameQTolerance::tolset:
Cannot set Internal`$SameQTolerance to a; value must be a real
number or +/- Infinity.
Out[1]= a
```

Citing Oleksandr Rasputinov:

Internal`$EqualTolerance ... takes a
machine real value indicating the
number of decimal digits' tolerance
that should be applied, i.e.
Log[2]/Log[10] times the number of
least significant bits one wishes to
ignore.

In this way, setting `Internal`$EqualTolerance`

to zero will force `Equal`

to consider numbers equal only when they are identical in all binary digits (not considering out-of-`Precision`

digits):

```
In[2]:= Block[{Internal`$EqualTolerance = 0},
1.0000000000000021 == 1.0000000000000022]
Out[2]= False
In[5]:= Block[{Internal`$EqualTolerance = 0},
1.00000000000000002 == 1.000000000000000029]
Block[{Internal`$EqualTolerance = 0},
1.000000000000000020 == 1.000000000000000029]
Out[5]= True
Out[6]= False
```

Note the following case:

```
In[3]:= Block[{Internal`$EqualTolerance = 0},
1.0000000000000020 == 1.0000000000000021]
RealDigits[1.0000000000000020, 2] === RealDigits[1.0000000000000021, 2]
Out[3]= True
Out[4]= True
```

In this case both numbers have `MachinePrecision`

which effectively is

```
In[5]:= $MachinePrecision
Out[5]= 15.9546
```

(`53*Log[10, 2]`

). With such precision these numbers are identical in all binary digits:

```
In[6]:= RealDigits[1.0000000000000020` $MachinePrecision, 2] ===
RealDigits[1.0000000000000021` $MachinePrecision, 2]
Out[6]= True
```

Increasing precision to 16 makes them different arbitrary-precision numbers:

```
In[7]:= RealDigits[1.0000000000000020`16, 2] ===
RealDigits[1.0000000000000021`16, 2]
Out[7]= False
In[8]:= Row@First@RealDigits[1.0000000000000020`16,2]
Row@First@RealDigits[1.0000000000000021`16,2]
Out[9]= 100000000000000000000000000000000000000000000000010010
Out[10]= 100000000000000000000000000000000000000000000000010011
```

But unfortunately `Equal`

still fails to distinguish them:

```
In[11]:= Block[{Internal`$EqualTolerance = 0},
{1.00000000000000002`16 == 1.000000000000000021`16,
1.00000000000000002`17 == 1.000000000000000021`17,
1.00000000000000002`18 == 1.000000000000000021`18}]
Out[11]= {True, True, False}
```

There is an infinite number of such cases:

```
In[12]:= Block[{Internal`$EqualTolerance = 0},
Cases[Table[a = SetPrecision[1., n];
b = a + 10^-n; {n, a == b, RealDigits[a, 2] === RealDigits[b, 2],
Order[a, b] == 0}, {n, 15, 300}], {_, True, False, _}]] // Length
Out[12]= 192
```

Interestingly, sometimes `RealDigits`

returns identical digits while `Order`

shows that internal representations of expressions are not identical:

```
In[13]:= Block[{Internal`$EqualTolerance = 0},
Cases[Table[a = SetPrecision[1., n];
b = a + 10^-n; {n, a == b, RealDigits[a, 2] === RealDigits[b, 2],
Order[a, b] == 0}, {n, 15, 300}], {_, _, True, False}]] // Length
Out[13]= 64
```

But it seems that opposite situation newer happens:

```
In[14]:=
Block[{Internal`$EqualTolerance = 0},
Cases[Table[a = SetPrecision[1., n];
b = a + 10^-n; {n, a == b, RealDigits[a, 2] === RealDigits[b, 2],
Order[a, b] == 0}, {n, 15, 3000}], {_, _, False, True}]] // Length
Out[14]= 0
```

`SameQ`

be ok? Maybe after truncating to the number of digits that you want to keep.`1.00000000000000000022 === 1.00000000000000000021`

. You will see that it is not OK. :(`100===1.00000000000000000021`

100`===`

drops digit -- thenumericalalgorithmsgroup.blogspot.com/2011/02/…1more comment