Commit Graph

15 Commits (d28dd09e23c17d82c3eedd5de64c94bebcf290f5)

Author SHA1 Message Date
Alex Willmer b1fd6038bf ansible_mitogen: Remove Python 2.4 and 2.5 backward compatibility fallbacks
Because ansible_mitogen >= 0.3 supports Ansible >= 2.10 and Ansible 2.10
requires supports Python >= 2.7 on controllers and Python >= 2.6 on targets
these are dead weight.

See
- https://docs.ansible.com/ansible/latest/reference_appendices/release_and_maintenance.html#ansible-core-support-matrix
- tox.ini
2 months ago
Alex Willmer 31b3a4eb4a ansible_mitogen: Standardise __future__ imports to match Ansible
Some modules additionally enable unicode_literals (which Ansible doesn't do).
I've chosen not to change that, for now.
3 years ago
David Wilson d6329f3446 Merge devel/290 @ 79b979ec8544ef5d8620c64068d4a42fabf50415 5 years ago
David Wilson f78a5f08c6 issue #605: ansible: share a sem_t instead of a pthread_mutex_t
The previous version quite reliably causes worker deadlocks within 10
minutes running:

    # 100 times:
    - import_playbook: integration/async/runner_one_job.yml
    # 100 times:
    - import_playbook: integration/module_utils/adjacent_to_playbook.yml

via .ci/soak/mitogen.sh with PLAYBOOK= set to the above playbook.

Attaching to the worker with gdb reveals it in an instruction
immediately following a futex() call, which likely returned EINTR due to
attaching gdb. Examining the pthread_mutex_t state reveals it to be
completely unlocked.

pthread_mutex_t on Linux should have zero trouble living in shmem, so
it's not clear how this deadlock is happening. Meanwhile POSIX
semaphores are explicitly designed for cross-process use and have a
completely different internal implementation, so try those instead. 1
hour of soaking reveals no deadlock.

This is about avoiding managing a lockable temporary file on disk to
contain our counter, and somehow communicating a reference to it into
subprocesses (despite the subprocess module closing inherited fds, etc),
somehow deleting it reliably at exit, and somehow avoiding concurrent
Ansible runs stepping on the same file. For now ctypes is still less
pain.

A final possibility would be to abandon a shared counter and instead
pick a CPU based on the hash of e.g. the new child's process ID. That
would likely balance equally well, and might be worth exploring when
making this code work on BSD.
5 years ago
David Wilson 0f23a90d50 ansible: log affinity assignments 5 years ago
David Wilson bf1f3682aa ansible: pin per-CPU muxes to their corresponding CPU
This slightly breaks the old scheme, in that CPU 1 may now end up with a
mux and the top-level process pinned to it.
5 years ago
David Wilson 1aceacf89e [stream-refactor] replace old detach_popen() reference 5 years ago
David Wilson 3ff6123483 issue #557: support correct cpu_set_t size 6 years ago
David Wilson 8f9c67daf1 ansible: refactor affinity class and add abstract tests. 6 years ago
David Wilson 1f77d24bec Update copyright year everywhere. 6 years ago
David Wilson a2ae4ed696 SyntaxError. 6 years ago
David Wilson a9d48a8fdc ansible: don't pin controller if <4 cores. 6 years ago
David Wilson 4531338b12 ansible: document and make affinity stuff portable to non-Linux
Portable as in does nothing for the time at least for now.
6 years ago
David Wilson de5c050707 ansible: fix affinity.py test failure on 2 cores. 6 years ago
David Wilson c6d5aa29ba ansible: new multiplexer/workers configuration
Following on from 152effc26c9a5918cb7ead7a97fe7fa7f81b6764,

* Pin mux to CPU 0
* Pin top-level CPU 1
* Pin workers sequentially to CPU 2..n

Nets 19.5% improvement on issue_140__thread_pileup.yml when targetting
64 Docker containers on the same 8 core/16 thread machine.

Before (prior to last scheme, no affinity at all):

    2294528.731458      task-clock (msec)         #    6.443 CPUs utilized
        10,429,745      context-switches          #    0.005 M/sec
         2,049,618      cpu-migrations            #    0.893 K/sec
         8,258,952      page-faults               #    0.004 M/sec
 5,532,719,253,824      cycles                    #    2.411 GHz                      (83.35%)
 3,267,471,616,230      instructions              #    0.59  insn per cycle
                                                  #    1.22  stalled cycles per insn  (83.35%)
   662,006,455,943      branches                  #  288.515 M/sec                    (83.33%)
    39,453,895,977      branch-misses             #    5.96% of all branches          (83.37%)

     356.148064576 seconds time elapsed

After:

    2226463.958975      task-clock (msec)         #    7.784 CPUs utilized
         9,831,466      context-switches          #    0.004 M/sec
           180,065      cpu-migrations            #    0.081 K/sec
         5,082,278      page-faults               #    0.002 M/sec
 5,592,548,587,259      cycles                    #    2.512 GHz                      (83.35%)
 3,135,038,855,414      instructions              #    0.56  insn per cycle
                                                  #    1.32  stalled cycles per insn  (83.32%)
   636,397,509,232      branches                  #  285.833 M/sec                    (83.30%)
    39,135,441,790      branch-misses             #    6.15% of all branches          (83.35%)

     286.036681644 seconds time elapsed
6 years ago