I saw the question Why does Process.fork make stuff slower in Ruby on OS X? and was able to determine that Process.fork does not actually make tasks, in general, slower.

However, it does seem to make Time.utc, in particular, much slower.

require 'benchmark'

def do_stuff
  50000.times { Time.utc(2016) }

puts "main: #{Benchmark.measure { do_stuff }}"

Process.fork do
  puts "fork: #{Benchmark.measure { do_stuff }}"

Here are some results:

main:   0.100000   0.000000   0.100000 (  0.103762)
fork:   0.530000   3.210000   3.740000 (  3.765203)

main:   0.100000   0.000000   0.100000 (  0.104218)
fork:   0.540000   3.280000   3.820000 (  3.858817)

main:   0.100000   0.000000   0.100000 (  0.102956)
fork:   0.520000   3.280000   3.800000 (  3.831084)

One clue might be that the above takes place on OS X, whereas on Ubuntu, there doesn't seem to be a difference:

main:   0.100000   0.070000   0.170000 (  0.166505)
fork:   0.090000   0.070000   0.160000 (  0.169578)

main:   0.090000   0.080000   0.170000 (  0.167889)
fork:   0.100000   0.060000   0.160000 (  0.169160)

main:   0.100000   0.070000   0.170000 (  0.170839)
fork:   0.100000   0.070000   0.170000 (  0.176146)

Can anyone explain this oddity?

Further investigation:

@tadman suggested that it might be a bug in the macOS / OS X time code, so I wrote a similar test in Python:

from timeit import timeit
from os import fork

print timeit("datetime.datetime.utcnow()", setup="import datetime")

if fork() == 0:
  print timeit("datetime.datetime.utcnow()", setup="import datetime")

Again, on Ubuntu, the benchmarks are the same for the forked/main processes. On OS X, however, the forked process is now slightly faster than the main process, which is the opposite of the behavior in Ruby.

This leads me to believe that the source of the "fork penalty" is in the Ruby implementation and not in the OS X time implementation.

  • 1
    Is it a penalty per fork layer, like would it be double if in another sub-fork? Does that penalty go away if the parent process exits? Does this apply inside of threads?
    – tadman
    Dec 27, 2016 at 23:41
  • @tadman Cool questions. It is not a penalty per fork layer; the next-level fork has the exact same execution time as the first fork. I'll check the rest of the scenarios if I can.
    – user513951
    Dec 27, 2016 at 23:42
  • 1
    I'm observing the same behaviour as you with Ruby 2.3.3 on macOS 10.12, but can't reproduce it on Fedora. This is likely an issue with the time code on macOS, so it might be worth filing a bug report. I believe this is isolated to time-related functions for some reason.
    – tadman
    Dec 27, 2016 at 23:51
  • @tadman Subsequent deeper layers of forking all experience the exact same penalty, and the penalty does not change depending on whether the parent process exits or not. Regarding Fedora: that matches the Ubuntu behavior I mentioned, so I would expect all Linux distros to avoid the penalty encountered on macOS / OS X.
    – user513951
    Dec 27, 2016 at 23:53
  • 1
    I can also reproduce this behavior on Ruby 2.0.0p648 on OSX 10.12.1 compared to Ruby 2.0.0p598 on CentOS 7.2.1511. What's more, it consistently differs by year in Time.utc. 1972-2017: slow (5s). 1970-1971: medium (2.5s). 1950-1969, 2018-2040: fast (0.1s, no difference). No difference in other code like File.exists? (syscalls) or large string concat (heavy allocations). I have no idea what to make of this. Dec 28, 2016 at 19:20

1 Answer 1


As it turns out, the slowdown is due in approximately equal measure to two function calls in time.c, in the function gmtime_with_leapsecond. The two functions are tzset and localtime_r.

That discovery led me to the question Why is tzset() a lot slower after forking on Mac OS X?, of which the current question might reasonably be said to be a duplicate.

There are two answers there, neither accepted, which point to root causes involving either

  • the "async-signal-safe"-ness of tzset and localtime/localtime_r, or
  • Apple's use of a passive notification registry that invalidates when fork'd.

The fact that the slowdown only occurs in years with no known leap seconds (as discovered by user that other guy) is obviously due to the fact that Ruby doesn't call gmtime_with_leapsecond when it knows that the year has no leap seconds.

I'm not sure why there is no such slowdown in Python. One possible explanation is that my test script using fork and utcnow may not be creating a child process that calls tzset or localtime/localtime_r.

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