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):
'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
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
LOAD_CONST 0 (2)
LOAD_CONST 1 (0.5)
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
The compiler then generates byte code from the AST.
1 0 LOAD_CONST 0 (1.4142135623730951)
[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.