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Date:   January 5, 2006
Author: Daniel Stenberg

       Status of project Hiper - high performance libcurl modifications
       ================================================================

What is Hiper

  You won't find such a description in this document. See
  http://curl.haxx.se/libcurl/hiper/ for further details.

Live Progress Info

  During my work, I've posted occational updates on the curl-library mailing
  list but more importantly done frequent updates of
  http://curl.haxx.se/libcurl/hiper/schedule.html

Schedule

  I took time off my regular job during Decemember 2005 and the first week of
  January 2006 to work on hiper full-time.

Step 1 - Measure the Existing Solution

  I started full-time work on project Hiper on December 1st 2005. I began by
  putting together a test application that used the existing API to allow me
  to properly and with accuracy measure execution and transfer speeds when
  doing a large amount of transfers.

  I soon discovered that it was impossible to do any sensible measurements by
  using live and actual URLs since the transfers were too unrelialble and
  uncontrolled. I then enhanced the current HTTP server in the curl test suite
  and made that support a large amount of transfers and some extra magic
  "commands" that would make the server either just sit "idle" or "stream"
  (continuously sending data in a never-ending stream). I then wrote up two
  files using the curl test suite file format and by acessing the properly
  formatted URLs on my localhost the HTTP server would either run "idle" or
  run "stream".

  Having this working, I patched libcurl to always only recv() a single byte
  off the network each time, just to make sure that the time spent on reading
  data is constant and never very long.

  I adjusted the test application (actually called 'hiper') to create Y idle
  transfers and Z stream transfers, had it run for N seconds and then quit and
  produce a summary on stdout. Now I got very solid and repeatable results. I
  started to run repeated tests and save the results when I ran into the
  dreaded 1024 socket maximum limit.

  One side of the problem is that the fd_set type only allows 1024 file
  descriptors (on my Linux), which I had to solve by simply making my own type
  with room for more connections and do ugly typecasts in the code. The other
  side of the problem is that user applications have a limit imposed by the
  system on the maximum amount of file descriptors it can have open and I had
  to work around that by writing a special tool that runs setuid root that
  increases the limit, downgrades to a normal user again and then run the
  command line of your choice. This second approach has to be used for both
  'hiper' and the test HTTP server. (You need to build the HTTP server with
  CURL_SWS_FORK_ENABLED defined to have it do forks since it isn't desirable
  to do so when running the normal curl tests.)

  Now I could run my test program without problems. I decided to run the tests
  with 1 stream connection and a varying amount of idle ones. I did 1001,
  2001, 3001, 5001 and 9001 connections and measured how long select() and
  curl_multi_perform() (including the curl_multi_fdset() call) would take in
  average, over a period of 20 seconds. I ran each test 5-6 times and I used
  the average time of all the runs.

  The times in number of microseconds:

    Connections  multi_perform  select
    1001         3504           951
    2001         7606           1988
    3001         11045          2715
    5001         16406          4024
    9001         32147          8030

  Test system
    CPU:     Athlon XP 2800 
    RAM:     1 GB
    Linux:   2.6
    glibc:   2.3.5
    libcurl: 7.15.1

  The only reason I stopped at 9001 connections is that my test machine ran
  out of avaiable memory by then as I ran the test server on the same machine,
  and I didn't want to risk the test result accuracy by having it start using
  the swap during the tests.

  It means that at 9000 connections we spend 40ms for each socket action, even
  when only one socket ever have action.

  With these 32000 microseconds curl_multi_perform() takes for 9000
  connections, it loops 18000 laps which makes less than 2 microseconds per
  lap. (Of course counting time/laps is an oversimplification, but anyway.)
  Hopefully we should achieve less than 10 microseconds for each call to
  curl_multi_socket() for an active connection.

  The timing graph displayed on the libevent site (duplicated on the hiper
  project page) suggests that libevent is pretty much fixed at 50 microseconds
  (although I don't know what test box was used in their testing, we can
  compare the select()-times from my tests and see that they are at least
  resonably close).

  Summing up, the current ~40 ms spent at 9000 connections could then possibly
  be lowered to something around 60 us!

Step 2 - Implement curl_multi_socket API

  Most of the design decisions and debates about this new API have already
  been held on the curl-library mailing list a long time ago so I had a basic
  idea on what approach to use. The main ideas of the new API are simply:

   1 - The application can use whatever event system it likes as it gets info
       from libcurl about what file descriptors libcurl waits for what action
       on. (The previous API returns fd_sets which is very select()-centric).

   2 - When the application discovers action on a single socket, it calls
       libcurl and informs that there was action on this particular socket and
       libcurl can then act on that socket/transfer only and not care about
       any other transfers. (The previous API always had to scan through all
       the existing transfers.)

  The idea is that curl_multi_socket() calls a given callback with information
  about what socket to wait for what action on, and the callback only gets
  called if the status of that socket has changed.

  In the API draft from before, we have a timeout argument on a per socket
  basis and we also allowed curl_multi_socket() to pass in an 'easy handle'
  instead of socket to allow libcurl to shortcut a lookup and work on the
  affected easy handle right away. Both these turned out to be bad ideas.

  The timeout argument was removed from the socket callback since after much
  thinking I came to the conclusion that we really don't want to handle
  timeouts on a per socket basis. We need it on a per transfer (easy handle)
  basis and thus we can't provide it in the callbacks in a nice way. Instead,
  we have to offer a curl_multi_timeout() that returns the largest amount of
  time we should wait before we call the "timeout action" of libcurl, to
  trigger the proper internal timeout action on the affected transfer. To get
  this to work, I added a struct to each easy handle in which we store an
  "expire time" (if any). The structs are then "splay sorted" so that we can
  add and remove times from the linked list and yet somewhat swiftly figure
  out 1 - how long time there is until the next timer expires and 2 - which
  timer (handle) should we take care of now. Of course, the upside of all this
  is that we get a curl_multi_timeout() that should also work with old-style
  applications that use curl_multi_perform().

  The easy handle argument was removed fom the curl_multi_socket() function
  because having it there would require the application to do a socket to easy
  handle conversion on its own. I find it very unlikely that applications
  would want to do that and since libcurl would need such a lookup on its own
  anyway since we didn't want to force applications to do that translation
  code (it would be optional), it seemed like an unnecessary option. I also
  realized that when we use underlying libraries such as c-ares (for DNS
  asynch resolving) there might in fact be more than one transfer waiting for
  action on the same socket and thus it makes the lookup even tricker and even
  less likely to ever get done by applications. Instead I created an internal
  "socket to easy handles" hash table that given a socket (file descriptor)
  returns a list of easy handles that waits for some action on that socket.

  To make libcurl be able to report plain sockets in the socket callback, I
  had to re-organize the internals of the curl_multi_fdset() etc so that the
  conversion from sockets to fd_sets for that function is only done in the
  last step before the data is returned. I also had to extend c-ares to get a
  function that can return plain sockets, as that library too returned only
  fd_sets and that is no longer good enough. The changes done to c-ares have
  been committed and are available in the c-ares CVS repository destined to be
  included in the upcoming c-ares 1.3.1 release.

  The 'shiper' tool is the test application I wrote that uses the new
  curl_multi_socket() in its current state. It seems to be working and it uses
  the API as it is documented and supposed to work. It is still using
  select(), because I needed that during development (like until I had the
  socket hash implemented etc) and because I haven't yet learned how to use
  libevent or similar.

  The hiper/shiper tools are very simple and initiates lots of connections and
  have them running for the test period and then kills them all.

  Since I wasn't done with the implementation until early January I haven't
  had time to run very many measurements and checks, but I have done a few
  runs with up to a few hundred connections (with a single active one). The
  curl_multi_socket() invoke then takes 3-6 microseconds in average (using the
  read-only-1-byte-at-a-time hack). If this number does increase a lot when we
  add connections, it certainly matches my in my opinion very ambitious goal.
  We are now below the 60 microseconds "per socket action" goal. It is
  destined to be somewhat higher the more connections we have since the hash
  table gets more populated and the splay tree will grow etc.

  Some tests at 7000 and 9000 connections showed that the socket hash lookup
  is somewhat of a bottle neck. Its current implementation may be a bit too
  limiting. It simply has a fixed-size array, and on each entry in the array
  it has a linked list with entries. So the hash only checks which list to
  scan through. The code I had used so for used a list with merely 7 slots (as
  that is what the DNS hash uses) but with 7000 connections that would make an
  average of 1000 nodes in each list to run through. I upped that to 97 slots
  (I believe a prime is suitable) and noticed a significant speed increase.  I
  need to reconsider the hash implementation or use a rather large default
  value like this. At 9000 connections I was still below 10us per call.

Status Right Now

  The curl_multi_socket() API is implemented according to how it is
  documented. The man pages for curl_multi_socket and curl_multi_timeout are
  both committed to CVS and are available online for easy browsing:

    http://curl.haxx.se/libcurl/c/curl_multi_socket.html
    http://curl.haxx.se/libcurl/c/curl_multi_timeout.html

  The hiper-5.patch I made available early morning January 5th, 2006 should
  apply fine on a recent CVS checkout (at the time of this writing curl 7.15.1
  is the latest public curl release but the hiper patch does not apply fine on
  that).

What is Left for the curl_multi_socket API

  1 - More measuring with more extreme number of connections

  2 - More testing with actual URLs and complete from start to end transfers.

  I'm quite sure we don't set expire times all over in the code properly, so
  there is bound to be some timeout bugs left.

  What it really takes is for me to commit the code and to make an official
  release with it so that we get people "out there" to help out testing it.

What is Left for project Hiper

  1 - Add HTTP pipelining support

  2 - Add a zero (or at least close to zero) copy interface

  Neither of these points have been planned or detailed exactly how they will
  be implemented.

Roadmap Ahead

  I plan and hope to return to full-time hiper work later on this spring or
  possibly summer to continue where I pause now. Of course some spare time
  might also be spent until then to get us moving forward.

---------------------------------------------------------------------------

April 11, 2006

 While sitting staring on my screen trying to write up a *nice* sample script
 using libevent, it strikes me that since libevent is pretty much based around
 its structs that you setup for each event/file descriptor, my application
 wants to figure out the correct struct that is associted with the file
 descriptor that libcurl provides in the socket callback.

 This feels like an operation most applications will need when using the
 multi_socket API, so it feels like I should better try to figure out a decent
 way to offer this basic functionality already in libcurl - and the fact that
 we already have the file descriptors in a hash we can probably just as well
 extend it somewhat and store some custom pointers as well.

 We need to offer the app a way to set a private pointer to be associated with
 the particular file descriptor, and then be able to provide that pointer on
 subsequent callback calls.

---------------------------------------------------------------------------

April 20, 2006

 I was wrong when I previously claimed we could have more than one easy handle
 using the same socket. I've cleaned up and simplified code now to adjust to
 this.

---------------------------------------------------------------------------

July 9, 2006

 TODO: We need to alter how we use c-ares for getting info about its sockets,
 as c-ares now provides a callback approach very similar to how libcurl is
 about to work.

 I'm adding a function called curl_multi_assign() that will set a private
 pointer added to the internal libcurl hash table for the particular socket
 passed in to this function:

 CURLMcode curl_multi_assign(CURLM *multi_handle,
                             curl_socket_t sockfd,
                             void *sockp);

 'sockp' being a custom pointer set by the application to be associated with
 this socket. The socket has to be already existing and in-use by libcurl,
 like having already called the callback telling about its existance.

 The set hashp pointer will then be passed on to the callback in upcoming
 calls when this same socket is used (in the brand new 'socketp' argument).