This patch provides the final building block for E-UTRAN IP Throughput KPI.
It continues

    d102ffaa (drb: Start of the package)
    5bf7dc1c (amari.{drb,xlog}: Provide aggregated DRB statistics in the form of synthetic x.drb_stats message)
    499a7c1b (amari.kpi: Teach LogMeasure to handle x.drb_stats messages)

Quoting those patches

    The scheme to compute E-UTRAN IP Throughput is thus as follows: poll eNB at
    100Hz frequency for `ue_get[stats]` and retrieve information about per-UE/QCI
    streams and the number of transport blocks dl/ul-ed to the UE in question
    during that 10ms frame. Estimate `tx_time` taking into account
    the number of transmitted transport blocks. And estimate whether eNB is congested or
    not based on `dl_use_avg`/`ul_use_avg` taken from `stats`. For the latter we
    also need to poll for `stats` at 100Hz frequency and synchronize
    `ue_get[stats]` and `stats` requests in time so that they both cover the same
    time interval of particular frame.

    Then organize the polling process to provide aggregated statistics in the form of
    new `x.drb_stats` message, and teach `xamari xlog` to save that messages to
    `enb.xlog` together with `stats`.

    Then further adjust `amari.kpi.LogMeasure` and generic `kpi.Measurement`
    and `kpi.Calc` to handle DRB-related data.						<-- NOTE

So here we implement that last noted step:

We add Calc.eutran_ip_throughput() whose implementation is relatively
straightforward as the hard part is done by amari.drb and amari.kpi - in the
Calc we basically need to only divide provided DRB.IPVolDl / DRB.IPTimeDl.

This patch provides next building block for E-UTRAN IP Throughput KPI
and continues

    d102ffaa (drb: Start of the package)
    5bf7dc1c (amari.{drb,xlog}: Provide aggregated DRB statistics in the form of synthetic x.drb_stats message)

Quoting those patches

    The scheme to compute E-UTRAN IP Throughput is thus as follows: poll eNB at
    100Hz frequency for `ue_get[stats]` and retrieve information about per-UE/QCI
    streams and the number of transport blocks dl/ul-ed to the UE in question
    during that 10ms frame. Estimate `tx_time` taking into account
    the number of transmitted transport blocks. And estimate whether eNB is congested or
    not based on `dl_use_avg`/`ul_use_avg` taken from `stats`. For the latter we
    also need to poll for `stats` at 100Hz frequency and synchronize
    `ue_get[stats]` and `stats` requests in time so that they both cover the same
    time interval of particular frame.

    Then organize the polling process to provide aggregated statistics in the form of
    new `x.drb_stats` message, and teach `xamari xlog` to save that messages to
    `enb.xlog` together with `stats`.

    Then further adjust `amari.kpi.LogMeasure`						<-- NOTE
    and generic `kpi.Measurement` and `kpi.Calc` to handle DRB-related data.

So here we implement the noted step:

We teach LogMeasure to take x.drb_stats messages into account and update IP
Throughput related fields in appropriate Measurement from x.drb_stats
data.

This process is relatively straightforward besides one place: for stable
output E-UTRAN IP Throughput is required to be computed without taking
into account last TTI of every sample. We don't have that level of
details since all we have is total amount of transmitted bytes in a
burst and estimation of how long in time the burst is. Thus we can only
provide an estimation for the E-UTRAN IP Throughput as follows:

    DRB.IPVol and DRB.IPTime are collected to compute throughput.

    thp = ΣB*/ΣT*  where B* is tx'ed bytes in the sample without taking last tti into account
                   and   T* is time of tx also without taking that sample's tail tti.

    we only know ΣB (whole amount of tx), ΣT and ΣT* with some error.

    -> thp can be estimated to be inside the following interval:

             ΣB            ΣB
            ───── ≤ thp ≤ ─────           (1)
            ΣT_hi         ΣT*_lo

    the upper layer in xlte.kpi will use the following formula for
    final throughput calculation:

                  DRB.IPVol
            thp = ──────────              (2)
                  DRB.IPTime

    -> set DRB.IPTime and its error to mean and δ of ΣT_hi and ΣT*_lo
    so that (2) becomes (1).

for this to work we also need to introduce new fields to Measurement
that represent error of DRB.IPTime. The hope is that introduction is
temporary and should be removed once we rework DRB stats to provide B*
and T* directly.

We added LogMeasure in 71087f67 (amari.kpi: New package with driver for
Amarisoft LTE stack to retrieve KPI-related measurements from logs) and
its original logic is to read `stats` messages and to create Measurement
that covers [Sx, Sx+1) only after seeing Sx+1.

However in the next patch we will need to also take into account other
smaller messages besides stats, and for that messages we need
being-prepared Measurement to already exist to be able to amend it with
partial data we see. So we need to rework the process to create
Measurement that will cover [Sx, Sx+1) right after seeing Sx without
waiting for Sx+1 to come in.

This patch does that.

Along the way it unifies how events and stats are handled. Previously
events and stats were handled via different objects and the code had many
scattered places that tried to handle cases like event-event,
event-stats, stats-event and stats-stats. And for all those cases the
intent was that we still want to emit corresponding Measurement for all
of them, even if maybe if all NA data besides timestamps. Thus it does
not make sense to split events and stats into different flows - as we can
handle all combinations by considering just one flow of "stats or
events". This simplifies logic and removes several sporadic branches
of code to emit M(ø) around events. It also discovers several places
where we were not emitting such M(ø) even though the intent was to do
so. All this is fixed now with updated tests.

This patch provides next building block for E-UTRAN IP Throughput KPI
and continues d102ffaa (drb: Start of the package). Quoting that patch

    The scheme to compute E-UTRAN IP Throughput is thus as follows: poll eNB at
    100Hz frequency for `ue_get[stats]` and retrieve information about per-UE/QCI
    streams and the number of transport blocks dl/ul-ed to the UE in question
    during that 10ms frame. Estimate `tx_time` taking into account
    the number of transmitted transport blocks. And estimate whether eNB is congested or
    not based on `dl_use_avg`/`ul_use_avg` taken from `stats`. For the latter we
    also need to poll for `stats` at 100Hz frequency and synchronize
    `ue_get[stats]` and `stats` requests in time so that they both cover the same
    time interval of particular frame.

    Then organize the polling process to provide aggregated statistics in the form of	<-- NOTE
    new `x.drb_stats` message, and teach `xamari xlog` to save that messages to		<-- NOTE
    `enb.xlog` together with `stats`.							<-- NOTE

    Then further adjust `amari.kpi.LogMeasure` and generic
    `kpi.Measurement` and `kpi.Calc` to handle DRB-related data.

So here we implement the noted step:

- add drv._x_stats_srv server that polls eNB at 100Hz rate, uses Sampler
  to extract bursts and aggregates information about those bursts.

- teach xlog to organize servers for synthetic messages and communicate
  with them, and register drv._x_stats_srv as such server to handle
  generation of x.drb_stats message.

An utility class to compute avg/std incrementally.

Thanks to https://www.johndcook.com/blog/standard_deviation/ for the
recipe of how to do it.

This package will be used to implement E-UTRAN IP Throughput KPI.

In hereby patch we add `drb.Sampler` that extracts samples of
transmission bursts from `ue_get[stats]` observations.

Let's go through what E-UTRAN IP Throughput KPI is and how it motivates
functionality provided by this patch.

Overview of E-UTRAN IP Throughput computation
---------------------------------------------

This KPI is defined in TS 32.450 [1] and aggregates transmission volume and
time over bursts of transmissions from an average UE point of view. It should be
particularly noted that only the time, during which transmission is going on,
should be accounted. For example if an UE receives 10KB over 4ms burst and the rest of
the time there is no transmission to it during, say, 1 minute, the downlink IP
Throughput for that UE over the minute is 20Mbit/s (= 8·10KB/4ms), not 1.3Kbit/s (= 8·10KB/60s).
This KPI basically shows what would be the speed to e.g. download a response for
HTTP request issued from a mobile.

[1] https://www.etsi.org/deliver/etsi_ts/132400_132499/132450/16.00.00_60/ts_132450v160000p.pdf#page=13

To compute IP Throughput we thus need to know Σ of transmitted amount
of bytes, and Σ of the time of all transmission bursts.

Σ of the bytes is relatively easy to get. eNB already provides close values in
overall `stats` and in per-UE `ue_get[stats]` messages. However there is no
anything readily available out-of-the box for Σ of bursts transmission time.
Thus we need to measure the time of transmission bursts ourselves somehow.

It turns out that with current state of things the only practical way to
measure it to some degree is to poll eNB frequently with `ue_get[stats]` and
estimate transmission time based on δ of `ue_get` timestamps.

Let's see how frequently we need to poll to get to reasonably accuracy of resulting throughput.

A common situation for HTTP requests issued via LTE is that response content
downloading time takes only few milliseconds. For example I used chromium
network profiler to access various sites via internet tethered from my phone
and saw that for many requests response content downloading time was e.g. 4ms,
5ms, 3.2ms, etc. The accuracy of measuring transmission time should be thus in
the order of millisecond to cover that properly. It makes a real difference for
reported throughput, if say a download sample with 10KB took 4ms, or it took
e.g. "something under 100ms". In the first case we know that for that sample
downlink throughput is 2500KB/s, while in the second case all we know is that
downlink throughput is "higher than 100KB/s" - a 25 times difference and not
certain. Similarly if we poll at 10ms rate we would get that throughput is "higher
than 1000KB/s" - a 2.5 times difference from actual value. The accuracy of 1
millisecond coincides with TTI time and with how downlink/uplink transmissions
generally work in LTE.

With the above the scheme to compute IP Throughput looks to be as
follows: poll eNB at 1000Hz rate for `ue_get[stats]`, process retrieved
information into per-UE and per-QCI streams, detect bursts on each UE/QCI pair,
and aggregate `tx_bytes` and `tx_time` from every burst.

It looks to be straightforward, but 1000Hz polling will likely create
non-negligible additional load on the system and disturb eNB itself
introducing much jitter and harming its latency requirements. That's probably
why eNB actually rate-limits WebSocket requests not to go higher than 100Hz -
the frequency 10 times less compared to what we need to get to reasonable
accuracy for IP throughput.

Fortunately there is additional information that provides a way to improve
accuracy of measured `tx_time` even when polled every 10ms at 100Hz rate:
that additional information is the number of transmitted transport blocks to/from
an UE. If we know that during 10ms frame it was e.g. 4 transport blocks transmitted
to the UE, that there were no retransmissions *and* that eNB is not congested, we can
reasonably estimate that it was actually a 4ms transmission. And if eNB is
congested we can still say that transmission time is somewhere in `[4ms, 10ms]`
interval because transmitting each transport block takes 1 TTI. Even if
imprecise that still provides some information that could be useful.

Also 100Hz polling turns to be acceptable from performance point of view and
does not disturb the system much. For example on the callbox machine the process,
that issues polls, takes only about 3% of CPU load and only on one core, and
the CPU usage of eNB does not practically change and its reported tx/rx latency
does not change as well. For sure, there is some disturbance, but it appears to
be small. To have a better idea of what rate of polling is possible, I've made
an experiment with the poller accessing my own websocket echo server quickly
implemented in python. Both the poller and the echo server are not optimized,
but without rate-limiting they could go to 8000Hz frequency with reaching 100%
CPU usage of one CPU core. That 8000Hz is 80x times more compared to 100Hz
frequency actually allowed by eNB. This shows what kind of polling
frequency limit the system can handle, if absolutely needed, and that 100Hz
turns out to be not so high a frequency. Also the Linux 5.6 kernel, installed
on the callbox from Fedora32, is configured with `CONFIG_HZ=1000`, which is
likely helping here.

Implementation overview
~~~~~~~~~~~~~~~~~~~~~~~

The scheme to compute E-UTRAN IP Throughput is thus as follows: poll eNB at
100Hz frequency for `ue_get[stats]` and retrieve information about per-UE/QCI
streams and the number of transport blocks dl/ul-ed to the UE in question
during that 10ms frame. Estimate `tx_time` taking into account
the number of transmitted transport blocks. And estimate whether eNB is congested or
not based on `dl_use_avg`/`ul_use_avg` taken from `stats`. For the latter we
also need to poll for `stats` at 100Hz frequency and synchronize
`ue_get[stats]` and `stats` requests in time so that they both cover the same
time interval of particular frame.

Then organize the polling process to provide aggregated statistics in the form of
new `x.drb_stats` message, and teach `xamari xlog` to save that messages to
`enb.xlog` together with `stats`.  Then further adjust `amari.kpi.LogMeasure`
and generic `kpi.Measurement` and `kpi.Calc` to handle DRB-related data.

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

In this patch we provide first building block - `Sampler` that extracts bursts
of data transmissions from stream of `ue_get[stats]` observations.

Even though main idea behind `Sampler` is relatively straightforward, several
aspects deserves to be noted:

1. information about transmitted bytes and corresponding transmitted transport
   blocks is emitted by eNB not synchronized in time. The reason here is that,
   for example, for DL a block is transmitted via PDCCH+PDSCH during one TTI, and
   then the base station awaits HARQ ACK/NACK. That ACK/NACK comes later via
   PUCCH or PUSCH. The time window in between original transmission and
   reception of the ACK/NACK is 4 TTIs for FDD and 4-13 TTIs for TDD (*).
   And Amarisoft LTEENB updates counters for dl_total_bytes and dl_tx at
   different times:

       ue.erab.dl_total_bytes      - right after sending data on  PDCCH+PDSCH
       ue.cell.{dl_tx,dl_retx}     - after receiving ACK/NACK via PUCCH|PUSCH

   this way an update to dl_total_bytes might be seen in one frame (= 10·TTI),
   while corresponding update to dl_tx/dl_retx might be seen in either same, or
   next, or next-next frame.

   We bring `δ(tx_bytes)` and `#tx_tb` in sync ourselves via _BitSync.

   (*) see e.g. Figure 8.1 in "An introduction to LTE, 2nd ed."

2. when we see multiple transmissions related to UE on different QCIs, we
   cannot directly use corresponding number of transport blocks to estimate
   transmissions times because we do not know how eNB scheduler placed those
   transmissions onto resource map. So without additional information we can only
   estimate corresponding lower and upper bounds.

We will soon need to run 2 threads:

- one with the main logger, and
- another one to serve requests for synthetic x.drb_stats queries

Both main and the second thread will be run via sync.WorkGroup to cancel
each other in case of failure somewhere. So since WorkGroup.wait(),
similarly to all pygolang operations, is not interrupted by signals(*),
we need to wire ctx to be passed through all operations and manage to
cancel that context on SIGINT/SIGTERM.

This patch:

1. adjusts xlog to wire ctx through all call chains and moves ._xlog1()
   to be run in the thread.
2. adjusts amari.Conn to take ctx as argument on all operations and
   react reasonably on that ctx cancel. We need to do it here because
   xlog uses Conn internally.
3. adjusts xamari main driver to setup root context that is canceled on
   SIGINT/SIGTERM similarly e.g. to how nxdtest does it in
   nexedi/nxdtest@b0cf277d .

(*) see nexedi/pygolang@e18adbab for details.

We will soon add more levels of trying to this part of the code and
linear defers are easier to follow compared to many levels of try/except
nesting.

We will soon need this to know at runtime the address of eNB service
attached by Conn to establish another connection attached to the same eNB.

Previously for Measurement fields with .QCI or .CAUSE suffix we had only
the .sum value and no per-QCI nor per-CAUSE values. In other words
support for QCI and CAUSE was stub. In this patch we add support for
QCI: every field X.QCI is now automatically expanded into X[256] array
and X.sum . For convenience we also provide X.<qci> aliases that alias
X[qci]. For example field DRB.IPVolDl.9 aliases 9'th element of
DRB.IPVolDl array.

We will need QCI support for E-UTRAN IP Throughput KPI which is required
to provide resulting values for every QCI individually.

CAUSE support remains stub for now.

There was a thinko that led to returning 0 instead of NA when there are
not .QCI or .CAUSE fields except .sum . Without added fix, e.g.

	Σqci(Measurement(), 'ERAB.EstabInitAttNbr.QCI')

was returning 0 instead of NA.

-> Fix it.

    DRB.IPThpVol   ->  DRB.IPVol	(no "Thp" inside)
    DRB.IPThpTime  ->  DRB.IPTime	(no "Thp" inside

TS 32.450 and TS 32.425 defines those names as in corrected variants -
please see corresponding references in the code for details.

It was my thinko in dc1d5481 (kpi: Start of the package) to use "Thp" in
the names.

We were not caring about that and so previously e.g. NA(np.int16) was
giving int instead of np.int16 .

Fix it.

Before this patch it was complaining:

    (xlte3.venv) kirr@deca:~/src/wendelin/xlte$ check-manifest
    lists of files in version control and sdist do not match!
    missing from sdist:
      demo/kpidemo.ipynb
      demo/kpidemo.py
      xlte.py
    suggested MANIFEST.in rules:
      include *.py
      recursive-include demo *.ipynb
      recursive-include demo *.py

Noticed during !2 review.

Make `python setup.py sdist` include CHANGELOG.rst in the tar.gz.
Without it, installing from the released tar.gz will fail because
setup.py expects to read CHANGELOG.rst to generate the long description.

/reviewed-by @kirr
/reviewed-on !2

Fix off-by-one error in `amari.xlog.LogSpec.parse` which truncated the last
character of options, e.g. `stats[rf]/60s` would parse option `r` instead of `rf`.

/reviewed-by @kirr
/reviewed-on !1

Fix `amari.Conn._send_msg` to include the arguments in the message sent.
Without it, logspec options such as `stats[samples,rf]/60s` are ignored.

/reviewed-by @kirr
/reviewed-on !1

Add JupyterLab notebook that shows how to build KPI-computing pipeline
and to compute the KPIs. The notebook comes with extensive comments
describing every step. Please see those comments for details.

Add demo program that shows how to build KPI-computing pipeline and to
compute the KPIs. It can be used e.g. as follows:

    $ ./demo/kpidemo.py 60 https://lab.nexedi.com/kirr/misc/raw/162307b9/lte/20221211-overload.xlog

The program comes with extensive comments describing every step.
Please see those comments for details.

The next patch will also add analogous JupyterLab notebook.

kpi.Calc is calculator to compute KPIs. It can be instantiated on
MeasurementLog and time interval over which to perform computations.
It currently implements calculations for only one "E-RAB Accessibility KPI".

Please see added docstrings and tests for details.

The next patch will also add demo program that uses all kpi.Calc and
other parts of KPI-computation pipeline to build and visualize E-RAB
Accessibility from real data.

amari.kpi: New package with driver for Amarisoft LTE stack to retrieve KPI-related measurements from logs

amari.kpi provides LogMeasure that takes enb.xlog (TODO and enb.log) as
input, and produces kpi.Measurements on output.

    enb.xlog     ─────────
    ─────────>  │   Log   │
                │         │ ────> []kpi.Measurement
    ─────────>  │ Measure │
    enb.log      ─────────

We read log data organizing periods around stats queries, and for now we
build Measurement from stats' counters. To do so we take δ(stats_prev, stat)
and process it mapping Amarisoft counters to 3GPP ones specified by
kpi.Measurement.

We emit measurement X after reading stats X+2 - i.e. we emit measurement
for a period after reading data covering _next_ period. It is organized
this way to account for init/fini correction:

             fini adjust
            -------------
           '             '
     Sx    v     Sx+1    '   Sx+2
  ────|───────────|───────────|────
       Measurement Measurement
            X          X+1

This approach has following limitations:

- for most of the counters there is no direct mapping in between
  Amarisoft and 3GPP. For example we currently use s1_erab_setup_request for
  ERAB.EstabAddAtt.sum, but this mapping is not strictly correct and will
  break if corresponding S1 E-RAB SETUP REQUEST message contains multiple
  ERABs. The code has corresponding FIXME marks where such approximations
  are used.

- it is not possible to implement init/fini correction precisely. From
  aggregated statistics we only get total amount for a fini value for a
  period - without knowing which part of it corresponds to init events
  from previous period, and which part to init events from current one.
  With that it is only possible to make a reasonable guess and try to
  preserve statistical properties, but not more. See m_initfini in the
  code for details.

- it is possible to handle eNB with single cell only. This limitation
  comes from the fact that in Amarisoft LTE stack S1-related counters
  come as "globals" ones, while e.g. RRC-related counters are "per-cell".
  It is thus not possible to see how much S1 connection establishments
  are associated with one particular cell if there are several of them.

TODO also parse enb.log to fix those issues.

xlog.Reader could be used to parse and read back data previously saved
by xlog. In the next patch we will use it in Amarisoft driver for KPI
measurements.

Start the package to process measurements and compute KPIs from them.

In this patch we add kpi.Measurement - a central part to represent
measurement results in intermediate generic form. kpi.Measurement will
be used by both KPI calculator, and by drivers for particular LTE stacks
to provide their KPI-related data in this uniform common format.

kpi.Measurement also establishes semantic for such measurement results
to be followed by drivers. The semantic is stated in kpi.Measurement
docstring and in comment for every field. Also in particular, according
to TS 32.401 and common sense, measurement data are required to be
correctly accounted for initiation/termination events to avoid
discrepancies. Quoting kpi.Measurement documentation:

    Important note (init/fini correction):

      Termination events should be counted in the same granularity period, where
      corresponding initiation event occurred, even if termination event happens
      _after_ granularity period covering the initiation event. For example in the
      following illustration "ConnEstab Success" event should be counted in the
      same granularity period 1 as "ConnEstab Initiate" event:

                     -----------------------
                    '                       '
            | p e r ' i o d 1       | p e r ' i o d 2    |
            |       '               |       v            |
        ────'───────x───────────────'───────x────────────'────────────>
                ConnEstab               ConnEstab                time
                Initiate                 Success

      This preserves invariant that N(initiations) is always ≥ N(results) and
      goes in line with what TS 32.401 4.3.2 "Perceived accuracy -> Same period
      for the same two events" requires.

kpi.Measurement comes accompanied by kpi.MeasurementLog which in essence
is array of kpi.Measurements.

We will use kpi.Measurement and kpi.MeasurementLog in later patches to
both provide Amarisoft-specific data in this common format, and to
compute KPIs from it.

Upon rotation we want to emit trailing part to the old file, and emit
new header into new log file. All this is custom and cannot be handled
reliably when rotation is done by external tool.

Document kind of messages and events that could be emitted by xlog.

The messages come from Amarisoft software directly, but events are
xlog-specific and without proper documentation it is easy to miss what
they are and which information and semantic they carry.

The time emitted in messages by Amarisoft is in seconds. It also makes
sense to emit meta/event times in seconds as well for uniformity.

This is backward-incompatible change, but it should be ok at this early time.

xlog logging is kind of slow - usually it comes once per several seconds
or once per minute. And without flushing many entries can remain sitting
up in the file buffer in userspace without being conveyed to OS kernel.
Which is not very convenient because in such situation we cannot make good
use of tools like `tail -f`.

Since flushing is relatively cheap operation - it is just one write
syscall - let's do it after every emitted line. The write syscall does
not force data to be synced to disk, so it should not slow things down,
but make it convenient to have latest logs right away in the filesystem
view.

Conn multiplexes many requests/responses over single WebSocket
connection. To do so it organizes dedicated receive thread that
continuously receives messages from underlying websocket connection and
dispatches received replies back to threads that issued corresponding requests.

An rx timeout in that receive thread is thus not something unexpected -
it can happen e.g. if there is simply no requests sent. But I missed
that in 61ad9032 (amari: Add functionality to interoperate with an
Amarisoft LTE service via WebSocket) and implicitly did not ignored such
global rx timeout. As the result `amari xlog` does not work properly if
period of requests is greater than timeout value, for example:

        $ xamari xlog ws://localhost:9001 ue_get/30s
        {"meta": {"event": "start", "time": 1670588996.0623107, "generator": "xlog ws://localhost:9001 ue_get[]/30.0s"}}
        {"meta": {"event": "service attach", "time": 1670588996.1852894, "srv_name": "ENB", "srv_type": "ENB", "srv_version": "2022-12-01"}}
        {"message":"config_get", ...}
  note  {"message":"ue_get","ue_list":[],"message_id":2,"time":3045.323,"utc":1670588996.423}
  ----> {"meta": {"event": "service detach", "time": 1670589026.3569217, "srv_name": "ENB", "srv_type": "ENB", "srv_version": "2022-12-01", "reason": "timed out"}}
        {"meta": {"event": "service attach", "time": 1670589029.485363, "srv_name": "ENB", "srv_type": "ENB", "srv_version": "2022-12-01"}}
        {"message":"config_get", ...}
        {"message":"ue_get","ue_list":[],"message_id":2,"time":3078.606,"utc":1670589029.706}
        ...

-> Fix it by ignoring global rx timeout.

NOTE: we must also add manual handling of per-request timeout when
waiting for corresponding reply. If we don't do that a situation where
particular reply does not come back, but replies for other requests are
coming back ok, will never be detected.

Here is how fixed version works now:

        $ xamari xlog ws://localhost:9001 ue_get/30s
        {"meta": {"event": "start", "time": 1670589223.0339117, "generator": "xlog ws://localhost:9001 ue_get[]/30.0s"}}
        {"meta": {"event": "service attach", "time": 1670589223.1970558, "srv_name": "ENB", "srv_type": "ENB", "srv_version": "2022-12-01"}}
        {"message":"config_get", ...}
        {"message":"ue_get","ue_list":[],"message_id":2,"time":3272.292,"utc":1670589223.391}
        {"message":"ue_get","ue_list":[],"message_id":3,"time":3302.274,"utc":1670589253.373}
        {"message":"ue_get","ue_list":[],"message_id":4,"time":3332.266,"utc":1670589283.365}
        ...

Note that ue_get messages are coming sequentially and there is no
"service detach" event, that was artificially popping up due to wrong
timeout handling.

For example with `stats/100s` stats query is emitted every 100 seconds,
but currently it will be first emitted only after waiting for 100
seconds after `xamari xlog` startup, or after reconnection to eNB if eNB
itself was restarted. And this way it will be hard to interpret obtained
numbers in relation to last 100s time interval.

-> Start emitting queries right after reconnection / xlog start, so that
we see the values as observed at the beginning, and can compare result
of further queries to them.

`xamari xlog` can be used to maintin extra log for an Amarisoft LTE
service: in addition to native logs, xlog contains results of periodic
queries done via WebSocket. For example with the following aguments

	xamari xlog <wsuri>  stats/10s ue_get/3s erab_get/3s

xlog will emit results of stats query - every 10 seconds, results from
ue_get query - every 3 seconds, and similarly for erab_get query.

The results are saved into xlog in JSON Lines format for easy future
processing. For the reference below is a copy of corresponding help
entries:

    xlte$ xamari help xlog
    Usage: xamari xlog [OPTIONS] <wsuri> <logspec>+
    Maintain extra log for a service.

    The service is queried periodically according to logspec and results are saved
    in JSON format to a file (see 'xamari help jsonlog').

    <wsuri> is URI (see 'xamari help websock') of an Amarisoft-service.
    <logspec> is specification of what to log. It has the following parts:

        <query>[<options>]/<period>

    The query specifies a message, that should be used to query service. For
    example "stats", "ue_get", "erab_get", ... Query part is mandatory.

    Options specifies additional flags for the query. Options part can be omitted.

    Period specifies periodicity of how often the service should be queried.
    Period is optional and defaults to 60 seconds.

    Example for <logspec>+:

        stats[samples,rf]/30s  ue_get[stats]  erab_get/10s  qos_flow_get

    Options:

        -h  --help            show this help

    xlte$ xamari help jsonlog
    Some commands produce logs with JSON entries. Such logs are organized with JSON
    Lines format(*) with each entry occupying one line.

    Logs in JSON Lines format are handy to exchange in between programs, and with
    corresponding tools, e.g. jq(+), they can be also displayed in human-readable
    form and inspected quickly.

    (*) https://jsonlines.org/
    (+) https://stedolan.github.io/jq/

Example output:

(xlte3.venv) kirr@deca:~/src/wendelin/xlte$ xamari xlog ws://localhost:9001 ue_get/3s erab_get/3s
{"meta": {"event": "start", "time": "Wed, 19 Oct 2022 15:05:50 -0000", "generator": "xlog ws://localhost:9001 ue_get[]/3.0s erab_get[]/3.0s"}}
{"meta": {"event": "service attach", "time": "Wed, 19 Oct 2022 15:05:51 -0000", "srv_name": "ENB", "srv_type": "ENB", "srv_version": "2022-09-16"}}
{"message":"config_get","version":"2022-09-16","type":"ENB","name":"ENB","license_id":"d9a961c166d2d4b15249fc559cdec925efbbe942d73b143aff","license_user":"rapid.space","logs":{"layers":{"PHY":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"MAC":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"RLC":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"PDCP":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"RRC":{"level":"debug","max_size":1,"key":false,"crypto":false,"payload":false},"NAS":{"level":"debug","max_size":1,"key":false,"crypto":false,"payload":false},"S1AP":{"level":"debug","max_size":1,"key":false,"crypto":false,"payload":false},"NGAP":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"GTPU":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"X2AP":{"level":"debug","max_size":1,"key":false,"crypto":false,"payload":false},"XnAP":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"M2AP":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"LPPa":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"NRPPa":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false},"TRX":{"level":"error","max_size":0,"key":false,"crypto":false,"payload":false}},"bcch":false,"mib":false,"signal":false,"cch":false,"rep":false,"dci_size":false,"csi":false,"cell_meas":false,"count":8192,"rotate":250000000,"path":"/var/log/lte"},"tai":9610.092,"global_enb_id":{"plmn":"00101","enb_id_type":"macro","enb_id":107216,"enb_name":"enb1a2d0"},"cells":{"1":{"n_antenna_dl":2,"n_antenna_ul":2,"n_layer_dl":2,"n_layer_ul":1,"gain":0,"ul_disabled":false,"rf_port":0,"dl_qam":256,"ul_qam":64,"ecgi":{"plmn":"00101","eci":27447297},"n_id_cell":1,"n_rb_dl":100,"n_rb_ul":100,"dl_earfcn":38350,"ul_earfcn":38350,"band":39,"dl_freq":1890000000,"ul_freq":1890000000,"mode":"TDD","uldl_config":2,"sp_config":7,"prach_sequence_index":204,"dl_cyclic_prefix":"normal","ul_cyclic_prefix":"normal","prach_config_index":4,"prach_freq_offset":11,"delta_pucch_shift":2,"n_rb_cqi":1,"n_cs_an":0,"pucch_allocation":[{"type":"2/2a/2b","rbs":1,"n":6}],"pucch_ack_nack_start":11,"pucch_reserved_rbs":[0,0,22,0,0,0,0,22,0,0],"sr_resource_count":44,"cqi_resource_count":48,"srs_resources":{"offsets":16,"freqs":20,"total":640},"gbr":{"dl_limit":7123840,"ul_limit":1797120},"tac":1,"plmn_list":[{"plmn":"00101","reserved":false}]}},"rx_channels":[{"gain":9,"freq":1890,"port":0},{"gain":9,"freq":1890,"port":0}],"tx_channels":[{"gain":60,"freq":1890,"port":0},{"gain":60,"freq":1890,"port":0}],"rf_ports":[{"sample_rate":30720000}],"message_id":1,"time":9610.087}
{"message":"ue_get","ue_list":[],"message_id":2,"time":9613.347}
{"message":"erab_get","erab_list":[],"timestamp":9613704,"message_id":3,"time":9613.704}
{"message":"ue_get","ue_list":[],"message_id":4,"time":9616.355}
{"message":"erab_get","erab_list":[],"timestamp":9616618,"message_id":5,"time":9616.618}
{"message":"ue_get","ue_list":[],"message_id":6,"time":9619.272}
{"message":"erab_get","erab_list":[],"timestamp":9619547,"message_id":7,"time":9619.547}
{"message":"ue_get","ue_list":[],"message_id":8,"time":9622.319}
{"message":"erab_get","erab_list":[],"timestamp":9622588,"message_id":9,"time":9622.588}
{"message":"ue_get","ue_list":[],"message_id":10,"time":9625.263}
{"message":"erab_get","erab_list":[],"timestamp":9625663,"message_id":11,"time":9625.663}
{"message":"ue_get","ue_list":[],"message_id":12,"time":9628.403}
{"message":"erab_get","erab_list":[],"timestamp":9628725,"message_id":13,"time":9628.725}
{"message":"ue_get","ue_list":[],"message_id":14,"time":9631.381}
{"message":"erab_get","erab_list":[],"timestamp":9631798,"message_id":15,"time":9631.798}
{"message":"ue_get","ue_list":[],"message_id":16,"time":9634.303}
{"message":"erab_get","erab_list":[],"timestamp":9634596,"message_id":17,"time":9634.596}
{"message":"ue_get","ue_list":[],"message_id":18,"time":9637.268}
{"message":"erab_get","erab_list":[],"timestamp":9637568,"message_id":19,"time":9637.568}

    (below an UE registers with eNB)

{"message":"ue_get","ue_list":[{"enb_ue_id":8,"mme_ue_id":107,"rnti":68,"cells":[{"cell_id":1}]}],"message_id":20,"time":9640.296}
{"message":"erab_get","erab_list":[{"erab_id":5,"qci":9,"dl_total_bytes":0,"ul_total_bytes":0,"enb_ue_id":8}],"timestamp":9640831,"message_id":21,"time":9640.831}
{"message":"ue_get","ue_list":[{"enb_ue_id":8,"mme_ue_id":107,"rnti":68,"cells":[{"cell_id":1}]}],"message_id":22,"time":9643.268}
{"message":"erab_get","erab_list":[{"erab_id":5,"qci":9,"dl_total_bytes":0,"ul_total_bytes":0,"enb_ue_id":8}],"timestamp":9643555,"message_id":23,"time":9643.555}
{"message":"ue_get","ue_list":[{"enb_ue_id":8,"mme_ue_id":107,"rnti":68,"cells":[{"cell_id":1}]}],"message_id":24,"time":9646.326}
{"message":"erab_get","erab_list":[{"erab_id":5,"qci":9,"dl_total_bytes":0,"ul_total_bytes":0,"enb_ue_id":8}],"timestamp":9646850,"message_id":25,"time":9646.85}
{"message":"ue_get","ue_list":[],"message_id":26,"time":9649.287}
{"message":"erab_get","erab_list":[],"timestamp":9649646,"message_id":27,"time":9649.646}
^CTraceback (most recent call last):
  File "/home/kirr/src/wendelin/venv/xlte3.venv/bin/xamari", line 33, in <module>
    sys.exit(load_entry_point('xlte', 'console_scripts', 'xamari')())
  File "/home/kirr/src/wendelin/xlte/amari/xamari.py", line 130, in main
    return command_module.main(argv)
  File "/home/kirr/src/wendelin/xlte/amari/xlog.py", line 275, in main
    xlog(wsuri, logspecv)
  File "/home/kirr/src/wendelin/xlte/amari/xlog.py", line 108, in xlog
    xl.xlog1()
  File "/home/kirr/src/wendelin/venv/xlte3.venv/lib/python3.9/site-packages/decorator.py", line 232, in fun
    return caller(func, *(extras + args), **kw)
  File "/home/kirr/src/wendelin/venv/xlte3.venv/lib/python3.9/site-packages/golang/__init__.py", line 103, in _
    return f(*argv, **kw)
  File "/home/kirr/src/wendelin/xlte/amari/xlog.py", line 157, in xlog1
    xl._xlog1(conn)
  File "/home/kirr/src/wendelin/xlte/amari/xlog.py", line 208, in _xlog1
    time.sleep(δtsleep)
KeyboardInterrupt

- amari.connect() connects to a service and returns Conn.
- Conn can be used to issue requests, receive replies and (TODO) event
  notifications. Several requests could be issued simultaneously and
  handled in parallel.

Only main driver framework here without actual subcommands.

Based on similar main driver from Zodbtools:

https://lab.nexedi.com/nexedi/zodbtools/blob/master/zodbtools/zodb.py

So that import xlte.abc resolves to xlte/abc.py

Based on similar top-level import redirector from wendelin.core
See nexedi/wendelin.core@e870781d for
context and links in added code for further details.

Stub setup.py, README/CHANGELOG, .gitignore.

Follow standard GPL3 + wide exception for Free and Open-source software.
See https://www.nexedi.com/licensing for details.

The project to implement assorted functionality related to LTE.

In particular I intend for it to be the place where KPI-related
functionality will live.