# Schwartzian Transform will not obvious faster if list count greater than 1M

I did a little test. Think we got millions strings like "Testor_00_pg_1_8.7127", and sort them by three number in string. I did a comparison between Schwartzian Transform and plain sort.

The plain sort:

``````sub test_sub_orig{
return sort {
my (\$a1,\$a2,\$a3)=(\$a=~/_(\d+)_pg_(\d+)_(\d+\.\d+)/i);
my (\$b1,\$b2,\$b3)=(\$b=~/_(\d+)_pg_(\d+)_(\d+\.\d+)/i);
\$a1 <=> \$b1 or \$b2 <=> \$a2 or \$a3 <=> \$b3;
} @_;
}
``````

The Schwartzian Transform:

``````sub test_sub_trans{
return map {
\$_->
}
sort {
\$a-> <=> \$b-> or
\$b-> <=> \$a-> or
\$a-> <=> \$b->
}
map {
\$_=~/_(\d+)_pg_(\d+)_(\d+\.\d+)/i;
[\$_, \$1, \$2, \$3 ]
} @_;
}
``````

And below is my result: The X-axis is the count of strings. The orange line is Schwartzian Transform's "Fast multiple" than plain sort, then dark grey line is Schwartzian Transform's time cost.

I wonder, why string count greater than 1M, get a such great efficiency degrade?

**And, why we get largest multiple when count is small not larger? **

• 1) The cost of sorting is proprtional to N log N, so an upward curve is expected no matter what. 2) I don't know what you mean by "fast multiple". Goolging that doesn't seem to produce anything meaningful. 3) ST uses a lot of memory, which could lead to swapping, which would greatly slow down a program. – ikegami May 9 at 21:11
• Note that this should be faster. See also the Sort::Key modules. – ikegami May 9 at 21:15
• @ikegami , forgive my poor english skill. If A func could executes 10 times/s, and B func could executes 30 times/s, then "fast multiple" of B to A is (30/10-1)=2.0; – cyler123 May 10 at 9:35
• Yuck. Don't compare rates. Compare times – ikegami May 10 at 9:40