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Nathan

I just exaggerated the response times to clarify that any program needs
resources
and adding the total requirement will give you the throughput.

5250 and RPG seems fast - but a SQL process is a SQL process and the process
takes exactly the same time regardless of the program language of the
requester.

In regards to memory - who cares today? and besides that one instance of
node,js
may server 1.000 concurrent stateless users so the memory usages should be
divided with 1,000 if you want to compare it to one active stateful 5250
users
memory footprint.

In regards to open sockets, in traditional HTTP there are no open sockets
unless they
are waiting for at response - you need websockets for that.

But actually this isn't a discussion about 5250 vs. HTTP it is a discussion
about the
backend for HTTP and they all share the same protocol and thereby the same
challenges.


On Sun, Mar 18, 2018 at 3:10 PM, Nathan Andelin <nandelin@xxxxxxxxx> wrote:

Please see my inline response.

On Sun, Mar 18, 2018 at 5:39 AM, Henrik Rützou <hr@xxxxxxxxxxxx> wrote:

Nathan,



first of all, HTTP doesn’t maintain open connections in a session like
fashion, it opens a connection when a request comes, processes it and
close
the connection.


The designers of Node.js make a point that the one thread that manages the
event loop is the only thread that "opens" sockets and maintains a list of
all the "descriptors" that are returned, whereas other HTTP servers launch
a new thread for each each open socket. They claim that Node.js therefore
uses less resources and is thus more "scalable" than other HTTP servers.
They claim that Node.js can thus maintain more connections than other HTTP
servers, because it uses just one thread. That's the context for their
definition of "scalability".



In general, if we talk about RPG/CGI one QZSRCGI job may serve hundreds
of
“active concurrent” users in a stateless environment and so can node.js.


Yes, and I wasn't suggesting otherwise. I was just explaining the rational
for the Node.js scalability claim. That ALL connections are made to sockets
that are managed by a single Node.js thread. That is quite a narrow
definition of "scalability". And different than how the term "scalability"
has been used traditionally.


“stateless” is different than “stateful” like 5250 sessions but in terms
of
server resources that are no difference. 10,000 5250 users may have
10,000
jobs but most of the time their jobs are idle waiting for I/O that
doesn’t
require server resources.


Yes, I understand that stateless is the opposite of stateful. Idle
processes (Jobs) may not be consuming CPU. But the consume memory. And that
is the basis of Node's scalability claim in regard to maintaining thousands
of open sockets in a single thread. That's not to say that all of the open
sockets have accepted clients at the same time.


If all 10,000 5250 users press enter at the same time, you would see very
long response times because all their jobs would become active at the
same
time but in the real world most jobs do nothing.


The average response time would depend on the number of cores the server
has. The IBM i platform would automatically utilize all the cores, which is
a different type of scalability than the one that Node.js is known for.
Again, the basis for Node's scalability claim is the number of sockets that
can be maintained overall - not that a Node instance scales to utilize all
available cores. I hope that the difference is clear.

Do the math, if every 5250 requests took 1 sec of server resources the last
5250 user would have to wait approx. 3 hours to get an answer.


A 5250 request would likely consume about a millisecond (rather than 1
second) of CPU time. If the server had 64 cores the math suggests that the
overall response time would be 10,000 divided by 1000 divided by 64 = 15.6
(milliseconds).


It is correct that node.js runs single treaded but here kick ASYNC/AWAIT
in
because many of the asynchrony modules is able to run in other treads
while
the main tread in node.js continues to process other requests.


The "other threads" you are referring to is called the Node.js thread pool,
which is used for things that require "blocking", such as file I/O. The
default is to configure 4 threads in that pool. There is generally good
reason to not go above that number. But rather to activate more than one
Node.js instance, and use a load-balancer to route requests to other
instances.

In other words, when you fire a SQL statement against DB2 this runs in
another job (and thereby uses other free resources on the system) while
node.js continues to process other pending requests.


I agree.


In order to get the maximum out of node you are also able to cluster the
one tread into a number of treads running in a single instance of node.js
and thereby spread the processes over a given number of cores in your
system. This will scale the performance of nodes to a (maximum of number
of
cores * single tread performance) while the system isn’t brought down
because each node.js tread still will compete with other processes on the
system for core resources.


That is like starting a pool of PHP server instances, or a pool of Java web
application server instances. Most shops limit the number of server
instances to the number of CPU cores or core threads. These types of jobs
consume a lot of memory. Each Job is essentially hosting a virtual machine
and a language runtime environment.

A 5250 Job that runs in the same address space and utilizes the same
language environment as the IBM i native virtual machine, which may support
10,000 of those types of Jobs without any problem. You'd probably want to
limit the number of Node.js Jobs to the number of available core threads.

I have made an example that shown how node.js can take full advantage of
all available cores and resources on my I7 4 core/8 logical core 4,5Ghz
machine. It comes with a little **warning** because I had to install
water
cooling to run the test with a reasonable CPU package temperature.



http://powerext.com/nodeCluster.PNG



Interesting, your screen shot indicates that you're running 8 instances of
Node.js, the same number as your logical CPU cores.
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