On the documentation page for Equal we read that

Approximate numbers with machine precision or higher are considered equal if they differ in at most their last seven binary digits (roughly their last two decimal digits).

Here are examples (32 bit system; for 64 bit system add some more zeros in the middle):

In[1]:= 1.0000000000000021 == 1.0000000000000022
1.0000000000000021 === 1.0000000000000022

Out[1]= True

Out[2]= True

I'm wondering is there a "normal" analog of the Equal function in Mathematica that does not drop last 7 binary digits?

  • Would SameQ be ok? Maybe after truncating to the number of digits that you want to keep.
    – Simon
    Feb 13, 2011 at 11:49
  • @Simon Try 1.00000000000000000022 === 1.00000000000000000021. You will see that it is not OK. :( Feb 13, 2011 at 12:15
  • A guess...perhaps Mathematica doesn't consider last digit to be a significant digit at default precision. You could use backtick notation to indicate that precision is high enough to make all digits significant -- 1.00000000000000000022100===1.00000000000000000021100 Feb 13, 2011 at 20:14
  • @Alexey - that's why I said you'd have to truncate to the number of digits that you want to compare.
    – Simon
    Feb 13, 2011 at 21:27
  • 2
    @Alexey btw, hardware floating point can give non-deterministic results, perhaps that's the reason === drops digit -- thenumericalalgorithmsgroup.blogspot.com/2011/02/… Mar 3, 2011 at 22:19

7 Answers 7


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]
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:

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

Try this:

realEqual[a_, b_] := SameQ @@ RealDigits[{a, b}, 2, Automatic]

The choice of base 2 is crucial to ensure that you are comparing the internal representations.

In[54]:= realEqual[1.0000000000000021, 1.0000000000000021]
Out[54]= True

In[55]:= realEqual[1.0000000000000021, 1.0000000000000022]
Out[55]= False

In[56]:= realEqual[
         , 1.000000000000000000000000000000000000000000000000000000000000000023
Out[56]= False
In[12]:= MyEqual[x_, y_] := Order[x, y] == 0

In[13]:= MyEqual[1.0000000000000021, 1.0000000000000022]

Out[13]= False

In[14]:= MyEqual[1.0000000000000021, 1.0000000000000021]

Out[14]= True

This tests if two object are identical, since 1.0000000000000021 and 1.000000000000002100 differs in precision they won't be considered as identical.

  • Precision in Mathematica is separate from digits shown. E.g., 1.0116 and 1.0100016 have the same precision.
    – Timo
    Feb 13, 2011 at 20:47
  • @Timo: Precision[1.0000000000000021] is MachinePrecision (1.0000000000000021`) but Precision[1.000000000000002100] is 18 (1.000000000000002100`18). The representation does affect the internal representation. Try FullForm[] them.
    – kennytm
    Feb 13, 2011 at 20:52
  • @Kenny: And yet both 1.1 and 1.10000 are MachinePrecision ;-). My interpretation of the OP is that he wants to compare numerical values, not just what the numbers look like (SameQ@@ToString/@{#1,#2}& would suffice for that, or indeed your Order[]).
    – Timo
    Feb 13, 2011 at 21:02
  • @Timo: That's because 1.1 and 1.100000 have less than ~16 digits which can be represented by MachinePrecision (IEEE double).
    – kennytm
    Feb 13, 2011 at 21:07
  • Order -- good idea! A nice simple, built-in function. Granted, it does not ignore trailing zeroes but, in general, comparing close numbers with different precisions is a tricky business. It frequently requires detailed numerical analysis, informed by the specific application. If you want that level of control, then a RealDigits solution like @Timo's will likely be required. But I like the simplicity of Order, letting Mathematica's ordering policy handle the gnarly cases. +1
    – WReach
    Feb 14, 2011 at 0:47

I'm not aware of an already defined operator. But you may define for example:

longEqual[x_, y_] := Block[{$MaxPrecision = 20, $MinPrecision = 20},
                            Equal[x - y, 0.]]  

Such as:

longEqual[1.00000000000000223, 1.00000000000000223]
longEqual[1.00000000000000223, 1.00000000000000222]


If you want to generalize for an arbitrary number of digits, you can do for example:

longEqual[x_, y_] :=
   $MaxPrecision =  Max @@ StringLength /@ ToString /@ {x, y},
   $MinPrecision =  Max @@ StringLength /@ ToString /@ {x, y}},
   Equal[x - y, 0.]]

So that your counterexample in your comment also works.


  • 1
    Thank you. But adding more zeros always breaks this approach: longEqual[1.\ 0000000000000000000000000000000000000000000000000000000000000000000000\ 0000000000000000000000000023, \ 1.00000000000000000000000000000000000000000000000000000000000000000000\ 000000000000000000000000000022] Feb 13, 2011 at 17:01
  • 1
    It works better but fails when at least one of the numbers ends with NumberMark: longEqual[1.0000000000000223`, 1.0000000000000222] Feb 13, 2011 at 18:20
  • @Alexey If you want to preserve precision you should use 1.55 and not 1. alone Feb 13, 2011 at 18:38

I propose a strategy that uses RealDigits to compare the actual digits of the numbers. The only tricky bit is stripping out trailing zeroes.

trunc = {Drop[First@#, Plus @@ First /@ {-Dimensions@First@#, 
         Last@Position[First@#, n_?(# != 0 &)]}], Last@#} &@ RealDigits@# &;
exactEqual = SameQ @@ trunc /@ {#1, #2} &;

In[1]  := exactEqual[1.000000000000000000000000000000000000000000000000000111,
Out[1] := True
In[2]  := exactEqual[1.000000000000000000000000000000000000000000000000000111,
Out[2] := False

I think that you really have to specify what you want... there's no way to compare approximate real numbers that will satisfy everyone in every situation.

Anyway, here's a couple more options:

In[1]:= realEqual[lhs_,rhs_,tol_:$MachineEpsilon] := 0==Chop[lhs-rhs,tol]

In[2]:= Equal[1.0000000000000021,1.0000000000000021]
Out[2]= True
Out[3]= True

In[4]:= Equal[1.0000000000000022,1.0000000000000021]
Out[4]= True
Out[5]= False

As the precision of both numbers gets higher, then they can always be distinguished if you set tol high enough.

Note that the subtraction is done at the precision of the lowest of the two numbers. You could make it happen at the precision of the higher number (which seems a bit pointless) by doing something like

maxEqual[lhs_, rhs_] := With[{prec = Max[Precision /@ {lhs, rhs}]}, 
  0 === Chop[SetPrecision[lhs, prec] - SetPrecision[rhs, prec], 10^-prec]]

maybe using the minimum precision makes more sense

minEqual[lhs_, rhs_] := With[{prec = Min[Precision /@ {lhs, rhs}]}, 
  0 === Chop[SetPrecision[lhs, prec] - SetPrecision[rhs, prec], 10^-prec]]

One other way to define such function is by using SetPrecision:

MyEqual[a_, b_] := SetPrecision[a, Precision[a] + 3] == SetPrecision[b, Precision[b] + 3]

This seems to work in the all cases but I'm still wondering is there a built-in function. It is ugly to use high-level functions for such a primitive task...

  • 1
    It only works if Precision is the same as the length of your number, which very often is not the case. MyEqual[1.1113, 1.111000013] -> True.
    – Timo
    Feb 13, 2011 at 20:18
  • @Alexey Popkov: Instead of setting precision, I like to set a tolerable percentage of deviation from the TRUE value. For example, let us suppose that I have a true value for xT=245 and a false value xF=250, but I want to set xT=xF because the percentage deviation from the True value is only 2% and I want to tolerate this deviation and accept the equality like in significance test. I have a very large number of equations to tolerate but I do not know how to set this tolerance level for my system of equations. Can you help me to solve this problem? thanks. Sep 15, 2019 at 13:19
  • @TugrulTemel I suggest you to create a specific question on the dedicated site, with detailed description and examples of what you wish to achieve. Sep 15, 2019 at 14:12
  • @AlexeyPopkov: Yes, I will do that right now. thanks for your prompt reply. Regards, Tugrul Sep 15, 2019 at 15:23

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