# Why is math.sqrt massively slower than exponentiation?

I can't believe what I just measured:

``````python3 -m timeit -s "from math import sqrt" "sqrt(2)"
5000000 loops, best of 5: 42.8 nsec per loop

python3 -m timeit "2 ** 0.5"
50000000 loops, best of 5: 4.93 nsec per loop
``````

This goes against any intuition... it shoud be exactly the opposite!

Python 3.8.3 on macOS Catalina

Python 3 is precomputing the value of `2 ** 0.5` at compile time, since both operands are known at that time. The value of `sqrt`, however, is not known at compile time, so the computation necessarily occurs at run time.

You aren't timing how long it takes to compute `2 ** 0.5`, but just the time it takes to load a constant.

A fairer comparison would be

``````\$ python3 -m timeit -s "from math import sqrt" "sqrt(2)"
5000000 loops, best of 5: 50.7 nsec per loop
\$ python3 -m timeit -s "x = 2" "x**0.5"
5000000 loops, best of 5: 56.7 nsec per loop
``````

I'm not sure if there is a way to show unoptimized byte code. Python starts by parsing source code into an abstract syntax tree (AST):

``````>>> ast.dump(ast.parse("2**0.5"))
'Module(body=[Expr(value=BinOp(left=Num(n=2), op=Pow(), right=Num(n=0.5)))])'
``````

Update: This particular optimization is now applied directly to the abstract syntax tree, so the byte code is generated directly from something like

``````Module(body=Num(n= 1.4142135623730951))
``````

The `ast` module doesn't appear to apply the optimization.

The compiler takes the AST and generates unoptimized byte code; in this case, I believe it would look (based on the output of `dis.dis("2**x")` and `dis.dis("x**0.5")`) like

``````LOAD_CONST       0  (2)
BINARY_POWER
RETURN_VALUE
``````

The raw byte code is then subject to modification by the peephole optimzizer, which can reduce these 4 instructions to 2, as shown by the `dis` module.

The compiler then generates byte code from the AST.

``````>>> dis.dis("2**0.5")
2 RETURN_VALUE
``````

[While the following paragraph was originally written with the idea of optimizing byte code in mind, the reasoning applies to optimizing the AST as well.]

Since nothing at runtime affects how the two `LOAD_CONST` and following `BINARY_POWER` instruction are evaluated (for example, there are no name lookups), the peephole optimizer can take this sequence of byte codes, perform the computation of `2**0.5` itself, and replace the first three instructions with a single `LOAD_CONST` instruction that loads the result immediately.

• Yep! Makes a lot of sense! Thanks! Jun 17 '20 at 14:34
• This optimization actually happens at AST level in recent Python versions (see `Python/ast_opt.c`), so "unoptimized" bytecode isn't actually generated any more. Jun 23 '20 at 22:40
• Ah, OK, I'd seen references to doing optimizations at at the AST level, but thought it was a future enhancement since the `ast` module doesn't (yet) take advantage of it. Jun 24 '20 at 12:13

To enhance chepner's answer, here's a proof:

``````Python 3.5.3 (default, Sep 27 2018, 17:25:39)
[GCC 6.3.0 20170516] on linux
>>> import dis
>>> dis.dis('2 ** 0.5')
3 RETURN_VALUE
``````

vs.

``````>>> dis.dis('sqrt(2)')
6 CALL_FUNCTION            1 (1 positional, 0 keyword pair)
9 RETURN_VALUE
``````
``````>>> dis.dis('44442.3123 ** 0.5')
2 RETURN_VALUE
``````

I do not believe, that `44442.3123 ** 0.5` is precomputed at compile time. We should better check the AST of code.

``````>>> import ast
>>> import math
>>> code = ast.parse("2**2")
>>> ast.dump(code)
'Module(body=[Expr(value=BinOp(left=Num(n=2), op=Pow(), right=Num(n=2)))])'
>>> code = ast.parse("math.sqrt(3)")
>>> ast.dump(code)
• `ast.parse` simply doesn't perform the peephole optimization. (I believe the optimizer uses the byte code generated from the parse tree as its input.) Jun 23 '20 at 21:54