# How can I set the level of precision for Raku's sqrt?

With Perl, one could use `bignum` to set the level of precision for all operators. As in:

``````use bignum ( p => -50 );

print sqrt(20);    # 4.47213595499957939281834733746255247088123671922305
``````

With Raku I have no problems with rationals since I can use `Rat` / `FatRat`, but I don't know how to use a longer level of precision for sqrt

``````say 20.sqrt # 4.47213595499958
``````
• Here is a non-answer: 1) You can change the printed precision with `sprintf`. But this does not increase the actual precision – `say sprintf('%.50f', 20.sqrt)` prints `4.47213595499958000000000000000000000000000000000000`. I am not aware of a way to change the actual precision of the `Num` type in Raku, though I'd certainly be interested in learning otherwise. Thanks for the interesting question. – codesections Aug 19 at 10:19
• How does Perl's `bignum` do that? If it's just altering the printed precision, see @codesections' comment above. If it's altering the computed precision, what numerical techniques/library is it using? – raiph Aug 19 at 12:20
• @raiph, I don't know about the inners workings in perl, but I believe that is not just a simple printed precission, as I can set a precissión of `10,000` and the extra digits are not 'zeroed'. Not to mention that it takes a lot to compute (7 seconds for a sqrt(20) with 10,000 digits of precision) – Julio Aug 19 at 12:55
• OK, so I checked perl's internals. `Math::BigInt::Calc;` provides a `_sqrt` method for bigints that reads `square-root of \$x in place. Compute a guess of the result (by rule of thumb), then improve it via Newton's method.`. That `_sqrt` method is called on the package `Math::BigFloat` by the `bsqrt` method. That `bsqrt` method does (amon other things): `sqrt(2) = 1.4 because sqrt(2*100) = 1.4*10; so we can increase the accuracy of the result by multiplying the input by 100 and then divide the integer result of sqrt(input) by 10. Rounding afterwards returns the real result.` – Julio Aug 19 at 16:09
• Links to sources (see my previous comment): Math::BigInt::Calc and Math::BigFloat – Julio Aug 19 at 16:12

As stated on Elizabeth's answer, `sqrt` returns a `Num` type, thus it has limited precision. See Elizabeth's answer for more detail.

For that reason I created a raku class: BigRoot, which uses newton's method and `FatRat` types to calculate the roots. You may use it like this:

``````use BigRoot;

# Can change precision level (Default precision is 30)
BigRoot.precision = 50;

my \$root2 = BigRoot.newton's-sqrt: 2;
# 1.41421356237309504880168872420969807856967187537695

say \$root2.WHAT;
# (FatRat)

# Can use other root numbers
say BigRoot.newton's-root: root => 3, number => 30;
# 3.10723250595385886687766242752238636285490682906742

# Numbers can be Int, Rational and Num:
say BigRoot.newton's-sqrt: 2.123;
# 1.45705181788431944566113502812562734420538186940001

# Can use other rational roots
say BigRoot.newton's-root: root => FatRat.new(2, 3), number => 30;
# 164.31676725154983403709093484024064018582340849939498

# Results are rounded:

BigRoot.precision = 8;
say BigRoot.newton's-sqrt: 2;
# 1.41421356

BigRoot.precision = 7;
say BigRoot.newton's-sqrt: 2;
# 1.4142136
``````

In general it seems to be pretty fast (at least compared to Perl's bigfloat)

Benchmarks:

``````|---------------------------------------|-------------|------------|
|  sqrt with 10_000 precision digits    |    Raku     |    Perl    |
|---------------------------------------|-------------|------------|
|  20000000000                          |    0.714    |   3.713    |
|---------------------------------------|-------------|------------|
|  200000.1234                          |    1.078    |   4.269    |
|---------------------------------------|-------------|------------|
|  π                                    |    0.879    |   3.677    |
|---------------------------------------|-------------|------------|
|  123.9/12.29                          |    0.871    |   9.667    |
|---------------------------------------|-------------|------------|
|  999999999999999999999999999999999    |    1.208    |   3.937    |
|---------------------------------------|-------------|------------|
|  302187301.3727 / 123.30219380928137  |    1.528    |   7.587    |
|---------------------------------------|-------------|------------|
|  2 + 999999999999 ** 10               |    2.193    |   3.616    |
|---------------------------------------|-------------|------------|
|  91200937373737999999997301.3727 / π  |    1.076    |   7.419    |
|---------------------------------------|-------------|------------|
``````

If want to implement your own `sqrt` using newton's method, this the basic idea behind it:

``````sub newtons-sqrt(:\$number, :\$precision) returns FatRat {
my FatRat \$error = FatRat.new: 1, 10 ** (\$precision + 1);
my FatRat \$guess = (sqrt \$number).FatRat;
my FatRat \$input = \$number.FatRat;
my FatRat \$diff = \$input;

while \$diff > \$error {
my FatRat \$new-guess = \$guess - ((\$guess ** 2 - \$input) / (2 * \$guess));
\$diff = abs(\$new-guess - \$guess);
\$guess = \$new-guess;
}

return \$guess.round: FatRat.new: 1, 10 ** \$precision;
}
``````
• I'm pretty sure this will only work for small integers. In my tests it works great for 10,000 digits of the square root of `2`, is OK for `20`, but is awfully slow for `200`. – raiph Aug 23 at 17:18
• Hi @raiph, I made some improvements. It seems that the slow bigger ints issue was because of my poor choice for the first guess number (which was `number/2`) I knew it was not very accurate, but I expected the algorithm to cath the real number 'soon'. But that was not the case for bigger numbers, since the bigger the number, the bigger is the difference from `number/2` to the final sqrt. So now I'm using raku's original sqrt as the first guess and now there is no difference from small numbers to big ones. I also changed the code to being able to accept a Rational number aswell. – Julio Aug 23 at 22:39
• \o/ Smokin'! How large is "large numbers"? What about a 20,000 digit integer or a `FatRat` with a random 1,000 digit numerator and denominator? I guess the main thing is that the iterative aspect does no division, and instead just addition and subtraction of integers, plus one integer square. – raiph Aug 23 at 23:07
• @ElizabethMattijsen Sure! I was planning to add a module for this. Perhaps make it more generic to allow for any type of root, not just square roots. Perhaps even higher precision constants such `pi`, `e`, ... would be welcome. Do you think we have any chance a module like this would make into core? If so, what changes what we need to do? – Julio Aug 27 at 11:43
• I finally created the module, thank you for your suggestions and hints – Julio Sep 9 at 16:30

In Rakudo, `sqrt` is implemented using the `sqrt_n` NQP opcode. Which indicates it only supports native nums (because of the `_n` suffix). Which implies limited precision.

Internally, I'm pretty sure this just maps to the sqrt functionality of one of the underlying math libraries that MoarVM uses.

I guess what we need is an ecosystem module that would export a `sqrt` function based on `Rational` arithmetic. That would give you the option to use higher precision `sqrt` implementations at the expense of performance. Which then in turn, might turn out to be interesting enough to integrate in core.

• I'm pretty sure a rational `sqrt` would almost never help, and would usually make things a lot worse. ❶ Per math, a rational `sqrt` can't help with any irrational numbers (which would of course be stored as `Num`s) and can't return an accurate result for almost all rational numbers, even using `FatRat`s. ❷ Most `Num`s where float precision matters are already inaccurate, so converting them to `Rational` equivalents wouldn't help. ❸ For the sorts of numbers where precision of floats (`Num`s) matters, using a rational `sqrt` would almost always be pathologically slow. – raiph Aug 19 at 12:29
• @raiph I tried a rational sqrt (using newthon's method) and It is pretty fast (at least compared to Perl's bigfloat) – Julio Aug 23 at 13:17
• Heh. I will leave my original comment up as yet another reminder to myself and others of just how wrong I can be. (I was right about the math but thoroughly wrong about the computer science / reality.) – raiph Aug 24 at 0:12