License is missing in meson build files. This has been added using
SPDX identifiers and licensed under LGPL-2.1+.

Add VRF support to the daemon. When the device we are activating is a
VRF or a VRF's slave, put routes in the table specified by the VRF
connection.

Also, introduce a VRF device type in libnm.

Add new VRF setting and connection types to libnm-core and support
them in nmcli.

No longer use GDBusObjectMangaerClient and gdbus-codegen generated classes
for the NMClient cache. Instead, use GDBusConnection directly and a
custom implementation (NMLDBusObject) for caching D-Bus' ObjectManager
data.

CHANGES
-------

- This is a complete rework. I think the previous implementation was
difficult to understand. There were unfixed bugs and nobody understood
the code well enough to fix them. Maybe somebody out there understood the
code, but I certainly did not. At least nobody provided patches to fix those
issues. I do believe that this implementation is more straightforward and
easier to understand. It removes a lot of layers of code. Whether this claim
of simplicity is true, each reader must decide for himself/herself. Note
that it is still fairly complex.

- There was a lingering performance issue with large number of D-Bus
objects. The patch tries hard that the implementation scales well. Of
course, when we cache N objects that have N-to-M references to other,
we still are fundamentally O(N*M) for runtime and memory consumption (with
M being the number of references between objects). But each part should behave
efficiently and well.

- Play well with GMainContext. libnm code (NMClient) is generally not
thread safe. However, it should work to use multiple instances in
parallel, as long as each access to a NMClient is through the caller's
GMainContext. This follows glib's style and effectively allows to use NMClient
in a multi threaded scenario. This implies to stick to a main context
upon construction and ensure that callbacks are only invoked when
iterating that context. Also, NMClient itself shall never iterate the
caller's context. This also means, libnm must never use g_idle_add() or
g_timeout_add(), as those enqueue sources in the g_main_context_default()
context.

- Get ordering of messages right. All events are consistently enqueued
in a GMainContext and processed strictly in order. For example,
previously "nm-object.c" tried to combine signals and emit them on an
idle handler. That is wrong, signals must be emitted in the right order
and when they happen. Note that when using GInitable's synchronous initialization
to initialize the NMClient instance, NMClient internally still operates fully
asynchronously. In that case NMClient has an internal main context.

- NMClient takes over most of the functionality. When using D-Bus'
ObjectManager interface, one needs to handle basically the entire state
of the D-Bus interface. That cannot be separated well into distinct
parts, and even if you try, you just end up having closely related code
in different source files. Spreading related code does not make it
easier to understand, on the contrary. That means, NMClient is
inherently complex as it contains most of the logic. I think that is
not avoidable, but it's not as bad as it sounds.

- NMClient processes D-Bus messages and state changes in separate steps.
First NMClient unpacks the message (e.g. _dbus_handle_properties_changed()) and
keeps track of the changed data. Then we update the GObject instances
(_dbus_handle_obj_changed_dbus()) without emitting any signals yet. Finally,
we emit all signals and notifications that were collected
(_dbus_handle_changes_commit()). Note that for example during the initial
GetManagedObjects() reply, NMClient receive a large amount of state at once.
But we first apply all the changes to our GObject instances before
emitting any signals. The result is that signals are always emitted in a moment
when the cache is consistent. The unavoidable downside is that when you receive
a property changed signal, possibly many other properties changed
already and more signals are about to be emitted.

- NMDeviceWifi no longer modifies the content of the cache from client side
during poke_wireless_devices_with_rf_status(). The content of the cache
should be determined by D-Bus alone and follow what NetworkManager
service exposes. Local modifications should be avoided.

- This aims to bring no API/ABI change, though it does of course bring
various subtle changes in behavior. Those should be all for the better, but the
goal is not to break any existing clients. This does change internal
(albeit externally visible) API, like dropping NM_OBJECT_DBUS_OBJECT_MANAGER
property and NMObject no longer implementing GInitableIface and GAsyncInitableIface.

- Some uses of gdbus-codegen classes remain in NMVpnPluginOld, NMVpnServicePlugin
and NMSecretAgentOld. These are independent of NMClient/NMObject and
should be reworked separately.

- While we no longer use generated classes from gdbus-codegen, we don't
need more glue code than before. Also before we constructed NMPropertiesInfo and
a had large amount of code to propagate properties from NMDBus* to NMObject.
That got completely reworked, but did not fundamentally change. You still need
about the same effort to create the NMLDBusMetaIface. Not using
generated bindings did not make anything worse (which tells about the
usefulness of generated code, at least in the way it was used).

- NMLDBusMetaIface and other meta data is static and immutable. This
avoids copying them around. Also, macros like NML_DBUS_META_PROPERTY_INIT_U()
have compile time checks to ensure the property types matches. It's pretty hard
to misuse them because it won't compile.

- The meta data now explicitly encodes the expected D-Bus types and
makes sure never to accept wrong data. That would only matter when the
server (accidentally or intentionally) exposes unexpected types on
D-Bus. I don't think that was previously ensured in all cases.
For example, demarshal_generic() only cared about the GObject property
type, it didn't know the expected D-Bus type.

- Previously GDBusObjectManager would sometimes emit warnings (g_log()). Those
probably indicated real bugs. In any case, it prevented us from running CI
with G_DEBUG=fatal-warnings, because there would be just too many
unrelated crashes. Now we log debug messages that can be enabled with
"LIBNM_CLIENT_DEBUG=trace". Some of these messages can also be turned
into g_warning()/g_critical() by setting LIBNM_CLIENT_DEBUG=warning,error.
Together with G_DEBUG=fatal-warnings, this turns them into assertions.
Note that such "assertion failures" might also happen because of a server
bug (or change). Thus these are not common assertions that indicate a bug
in libnm and are thus not armed unless explicitly requested. In our CI we
should now always run with LIBNM_CLIENT_DEBUG=warning,error and
G_DEBUG=fatal-warnings and to catch bugs. Note that currently
NetworkManager has bugs in this regard, so enabling this will result in
assertion failures. That should be fixed first.

- Note that this changes the order in which we emit "notify:devices" and
"device-added" signals. I think it makes the most sense to emit first
"device-removed", then "notify:devices", and finally "device-added"
signals.
This changes behavior for commit 52ae28f6e5bf ('libnm: queue
added/removed signals and suppress uninitialized notifications'),
but I don't think that users should actually rely on the order. Still,
the new order makes the most sense to me.

- In NetworkManager, profiles can be invisible to the user by setting
"connection.permissions". Such profiles would be hidden by NMClient's
nm_client_get_connections() and their "connection-added"/"connection-removed"
signals.
Note that NMActiveConnection's nm_active_connection_get_connection()
and NMDevice's nm_device_get_available_connections() still exposes such
hidden NMRemoteConnection instances. This behavior was preserved.

NUMBERS
-------

I compared 3 versions of libnm.

  [1] 962297f9085d, current tip of nm-1-20 branch
  [2] 4fad8c7c642e, current master, immediate parent of this patch
  [3] this patch

All tests were done on Fedora 31, x86_64, gcc 9.2.1-1.fc31.
The libraries were build with

  $ ./contrib/fedora/rpm/build_clean.sh -g -w test -W debug

Note that RPM build already stripped the library.

---

N1) File size of libnm.so.0.1.0 in bytes. There currently seems to be a issue
  on Fedora 31 generating wrong ELF notes. Usually, libnm is smaller but
  in these tests it had large (and bogus) ELF notes. Anyway, the point
  is to show the relative sizes, so it doesn't matter).

  [1] 4075552 (102.7%)
  [2] 3969624 (100.0%)
  [3] 3705208 ( 93.3%)

---

N2) `size /usr/lib64/libnm.so.0.1.0`:

          text             data              bss                dec               hex   filename
  [1]  1314569 (102.0%)   69980 ( 94.8%)   10632 ( 80.4%)   1395181 (101.4%)   1549ed   /usr/lib64/libnm.so.0.1.0
  [2]  1288410 (100.0%)   73796 (100.0%)   13224 (100.0%)   1375430 (100.0%)   14fcc6   /usr/lib64/libnm.so.0.1.0
  [3]  1229066 ( 95.4%)   65248 ( 88.4%)   13400 (101.3%)   1307714 ( 95.1%)   13f442   /usr/lib64/libnm.so.0.1.0

---

N3) Performance test with test-client.py. With checkout of [2], run

```
prepare_checkout() {
    rm -rf /tmp/nm-test && \
    git checkout -B test 4fad8c7c642e && \
    git clean -fdx && \
    ./autogen.sh --prefix=/tmp/nm-test && \
    make -j 5 install && \
    make -j 5 check-local-clients-tests-test-client
}
prepare_test() {
    NM_TEST_REGENERATE=1 NM_TEST_CLIENT_BUILDDIR="/data/src/NetworkManager" NM_TEST_CLIENT_NMCLI_PATH=/usr/bin/nmcli python3 ./clients/tests/test-client.py -v
}
do_test() {
  for i in {1..10}; do
      NM_TEST_CLIENT_BUILDDIR="/data/src/NetworkManager" NM_TEST_CLIENT_NMCLI_PATH=/usr/bin/nmcli python3 ./clients/tests/test-client.py -v || return -1
  done
  echo "done!"
}
prepare_checkout
prepare_test
time do_test
```

  [1]  real 2m14.497s (101.3%)     user 5m26.651s (100.3%)     sys  1m40.453s (101.4%)
  [2]  real 2m12.800s (100.0%)     user 5m25.619s (100.0%)     sys  1m39.065s (100.0%)
  [3]  real 1m54.915s ( 86.5%)     user 4m18.585s ( 79.4%)     sys  1m32.066s ( 92.9%)

---

N4) Performance. Run NetworkManager from build [2] and setup a large number
of profiles (551 profiles and 515 devices, mostly unrealized). This
setup is already at the edge of what NetworkManager currently can
handle. Of course, that is a different issue. Here we just check how
long plain `nmcli` takes on the system.

```
do_cleanup() {
    for UUID in $(nmcli -g NAME,UUID connection show | sed -n 's/^xx-c-.*:\([^:]\+\)$/\1/p'); do
        nmcli connection delete uuid "$UUID"
    done
    for DEVICE in $(nmcli -g DEVICE device status | grep '^xx-i-'); do
        nmcli device delete "$DEVICE"
    done
}

do_setup() {
    do_cleanup
    for i in {1..30}; do
        nmcli connection add type bond autoconnect no con-name xx-c-bond-$i ifname xx-i-bond-$i ipv4.method disabled ipv6.method ignore
        for j in $(seq $i 30); do
            nmcli connection add type vlan autoconnect no con-name xx-c-vlan-$i-$j vlan.id $j ifname xx-i-vlan-$i-$j vlan.parent xx-i-bond-$i  ipv4.method disabled ipv6.method ignore
        done
    done
    systemctl restart NetworkManager.service
    sleep 5
}

do_test() {
    perf stat -r 50 -B nmcli 1>/dev/null
}

do_test
```

  [1]

   Performance counter stats for 'nmcli' (50 runs):

              456.33 msec task-clock:u              #    1.093 CPUs utilized            ( +-  0.44% )
                   0      context-switches:u        #    0.000 K/sec
                   0      cpu-migrations:u          #    0.000 K/sec
               5,900      page-faults:u             #    0.013 M/sec                    ( +-  0.02% )
       1,408,675,453      cycles:u                  #    3.087 GHz                      ( +-  0.48% )
       1,594,741,060      instructions:u            #    1.13  insn per cycle           ( +-  0.02% )
         368,744,018      branches:u                #  808.061 M/sec                    ( +-  0.02% )
           4,566,058      branch-misses:u           #    1.24% of all branches          ( +-  0.76% )

             0.41761 +- 0.00282 seconds time elapsed  ( +-  0.68% )

  [2]

   Performance counter stats for 'nmcli' (50 runs):

              477.99 msec task-clock:u              #    1.088 CPUs utilized            ( +-  0.36% )
                   0      context-switches:u        #    0.000 K/sec
                   0      cpu-migrations:u          #    0.000 K/sec
               5,948      page-faults:u             #    0.012 M/sec                    ( +-  0.03% )
       1,471,133,482      cycles:u                  #    3.078 GHz                      ( +-  0.36% )
       1,655,275,369      instructions:u            #    1.13  insn per cycle           ( +-  0.02% )
         382,595,152      branches:u                #  800.433 M/sec                    ( +-  0.02% )
           4,746,070      branch-misses:u           #    1.24% of all branches          ( +-  0.49% )

             0.43923 +- 0.00242 seconds time elapsed  ( +-  0.55% )

  [3]

   Performance counter stats for 'nmcli' (50 runs):

              352.36 msec task-clock:u              #    1.027 CPUs utilized            ( +-  0.32% )
                   0      context-switches:u        #    0.000 K/sec
                   0      cpu-migrations:u          #    0.000 K/sec
               4,790      page-faults:u             #    0.014 M/sec                    ( +-  0.26% )
       1,092,341,186      cycles:u                  #    3.100 GHz                      ( +-  0.26% )
       1,209,045,283      instructions:u            #    1.11  insn per cycle           ( +-  0.02% )
         281,708,462      branches:u                #  799.499 M/sec                    ( +-  0.01% )
           3,101,031      branch-misses:u           #    1.10% of all branches          ( +-  0.61% )

             0.34296 +- 0.00120 seconds time elapsed  ( +-  0.35% )

---

N5) same setup as N4), but run `PAGER= /bin/time -v nmcli`:

  [1]

        Command being timed: "nmcli"
        User time (seconds): 0.42
        System time (seconds): 0.04
        Percent of CPU this job got: 107%
        Elapsed (wall clock) time (h:mm:ss or m:ss): 0:00.43
        Average shared text size (kbytes): 0
        Average unshared data size (kbytes): 0
        Average stack size (kbytes): 0
        Average total size (kbytes): 0
        Maximum resident set size (kbytes): 34456
        Average resident set size (kbytes): 0
        Major (requiring I/O) page faults: 0
        Minor (reclaiming a frame) page faults: 6128
        Voluntary context switches: 1298
        Involuntary context switches: 1106
        Swaps: 0
        File system inputs: 0
        File system outputs: 0
        Socket messages sent: 0
        Socket messages received: 0
        Signals delivered: 0
        Page size (bytes): 4096
        Exit status: 0

  [2]
        Command being timed: "nmcli"
        User time (seconds): 0.44
        System time (seconds): 0.04
        Percent of CPU this job got: 108%
        Elapsed (wall clock) time (h:mm:ss or m:ss): 0:00.44
        Average shared text size (kbytes): 0
        Average unshared data size (kbytes): 0
        Average stack size (kbytes): 0
        Average total size (kbytes): 0
        Maximum resident set size (kbytes): 34452
        Average resident set size (kbytes): 0
        Major (requiring I/O) page faults: 0
        Minor (reclaiming a frame) page faults: 6169
        Voluntary context switches: 1849
        Involuntary context switches: 142
        Swaps: 0
        File system inputs: 0
        File system outputs: 0
        Socket messages sent: 0
        Socket messages received: 0
        Signals delivered: 0
        Page size (bytes): 4096
        Exit status: 0

  [3]

        Command being timed: "nmcli"
        User time (seconds): 0.32
        System time (seconds): 0.02
        Percent of CPU this job got: 102%
        Elapsed (wall clock) time (h:mm:ss or m:ss): 0:00.34
        Average shared text size (kbytes): 0
        Average unshared data size (kbytes): 0
        Average stack size (kbytes): 0
        Average total size (kbytes): 0
        Maximum resident set size (kbytes): 29196
        Average resident set size (kbytes): 0
        Major (requiring I/O) page faults: 0
        Minor (reclaiming a frame) page faults: 5059
        Voluntary context switches: 919
        Involuntary context switches: 685
        Swaps: 0
        File system inputs: 0
        File system outputs: 0
        Socket messages sent: 0
        Socket messages received: 0
        Signals delivered: 0
        Page size (bytes): 4096
        Exit status: 0

---

N6) same setup as N4), but run `nmcli monitor` and look at `ps aux` for
  the RSS size.

      USER       PID %CPU %MEM    VSZ   RSS TTY      STAT START   TIME COMMAND
  [1] me     1492900 21.0  0.2 461348 33248 pts/10   Sl+  15:02   0:00 nmcli monitor
  [2] me     1490721  5.0  0.2 461496 33548 pts/10   Sl+  15:00   0:00 nmcli monitor
  [3] me     1495801 16.5  0.1 459476 28692 pts/10   Sl+  15:04   0:00 nmcli monitor

We don't need such data duplicated. The build setup should
have only one configuration_data() for patching such values.

Now we only have one global, immutable data_conf dictionary with
configuration values. Note that none of the users of data_conf uses all
entries, but as the entries are basically only dependent on the
meson/configure option and valid for the entire project, this simplifies
to handling.

Note that D-Bus is fundamentally asynchronous. Doing blocking calls
on top of D-Bus is odd, especially for libnm's NMClient. That is because
NMClient essentially is a client-side cache of the objects from the D-Bus
interface. This cache should be filled exclusively by (asynchronous) D-Bus
events (PropertiesChanged). So, making a blocking D-Bus call means to wait
for a response and return it, while queuing all messages that are received
in the meantime.
Basically there are three ways how a synchronous API on NMClient could behave:

 1) the call just calls g_dbus_connection_call_sync(). This means
    that libnm sends a D-Bus request via GDBusConnection, and blockingly
    waits for the response. All D-Bus messages that get received in the
    meantime are queued in the GMainContext that belongs to NMClient.
    That means, none of these D-Bus events are processed until we
    iterate the GMainContext after the call returns. The effect is,
    that NMClient (and all cached objects in there) are unaffected by
    the D-Bus request.
    Most of the synchronous API calls in libnm are of this kind.
    The problem is that the strict ordering of D-Bus events gets
    violated.
    For some API this is not an immediate problem. Take for example
    nm_device_wifi_request_scan(). The call merely blockingly tells
    NetworkManager to start scanning, but since NetworkManager's D-Bus
    API does not directly expose any state that tells whether we are
    currently scanning, this out of order processing of the D-Bus
    request is a small issue.
    The problem is more obvious for nm_client_networking_set_enabled().
    After calling it, NM_CLIENT_NETWORKING_ENABLED is still unaffected
    and unchanged, because the PropertiesChanged signal from D-Bus
    is not yet processed.
    This means, while you make such a blocking call, NMClient's state
    does not change. But usually you perform the synchronous call
    to change some state. In this form, the blocking call is not useful,
    because NMClient only changes the state after iterating the GMainContext,
    and not after the blocking call returns.

 2) like 1), but after making the blocking g_dbus_connection_call_sync(),
    update the NMClient cache artificially. This is what
    nm_manager_check_connectivity() does, to "fix" bgo#784629.
    This also has the problem of out-of-order events, but it kinda
    solves the problem of not changing the state during the blocking
    call. But it does so by hacking the state of the cache. I think
    this is really wrong because the state should only be updated from
    the ordered stream of D-Bus messages (PropertiesChanged signal and
    similar). When libnm decides to modify the state, there may be already
    D-Bus messages queued that affect this very state.

 3) instead of calling g_dbus_connection_call_sync(), use the
    asynchronous g_dbus_connection_call(). If we would use a sepaate
    GMainContext for all D-Bus related calls, we could ensure that
    while we block for the response, we iterate that internal main context.
    This might be nice, because all events are processed in order and
    after the blocking call returns, the NMClient state is up to date.
    The are problems however: current blocking API does not do this,
    so it's a significant change in behavior. Also, it might be
    unexpected to the user that during the blocking call the entire
    content of NMClient's cache might change and all pointers to the
    cache might be invalidated. Also, of course NMClient would invoke
    signals for all the changes that happen.
    Another problem is that this would be more effort to implement
    and it involves a small performance overhead for all D-Bus related
    calls (because we have to serialize all events in an internal
    GMainContext first and then invoke them on the caller's context).
    Also, if the users wants this behavior, they could implement it themself
    by running libnm in their own GMainContext. Note that libnm might
    have bugs to make that really working, but that should be fixed
    instead of adding such synchrnous API behavior.

Read also [1], for why blocking calls are wrong.

[1] https://smcv.pseudorandom.co.uk/2008/11/nonblocking/

So, all possible behaviors for synchronous API have severe behavioural
issues.  Mark all this API as deprecated. Also, this serves the purpose of
identifying blocking D-Bus calls in libnm.

Note that "deprecated" here does not really mean that the API is going
to be removed. We don't break API. The user may:

  - continue to use this API. It's deprecated, awkward and discouraged,
    but if it works, by all means use it.

  - use asynchronous API. That's the only sensible way to use D-Bus.
    If libnm lacks a certain asynchronous counterpart, it should be
    added.

  - use GDBusConnection directly. There really isn't anything wrong
    with D-Bus or GDBusConnection. This deprecated API is just a wrapper
    around g_dbus_connection_call_sync(). You may call it directly
    without feeling dirty.

---

The only other remainging API is the synchronous GInitable call for
NMClient. That is an entirely separate beast and not particularly
wrong (from an API point of view).

Note that synchronous API in NMSecretAgentOld, NMVpnPluginOld and
NMVpnServicePlugin as not deprecated here. These types are not part
of the D-Bus cache and while they have similar issues, it's less severe
because they have less state.

the `doc_module` variable has been removed. It was created because
its used in the autotools build file but actually `libnm_name`
variable can be used easily.

Different objects used in the documentation target have been grouped
together.

The content file `version.xml` is now added properly.

Functions derived from generators as `configure_file`,
`custom_target` and `i18n.merge_file` can use placeholders like
`@BASENAME@` that removes the extension from the input filename
string.

The output string has been replaced by this placeholder that
allows in some cases the use of less variables.

What's actually needed here is an explaination of how the license
applies along with the explanation where to find the full text.

Also, the libnm documentation was lacking the licensing information
altogether. Fix fixes it too.

gtkdoc-scan supports regular expressions in the --ignore-decorators
command-line option. Since it is easier to use a regexp than grepping
macros from a source file, revert the ugly solution from commit
2d941dc95a1d ('build: fix errors when building with gtk-doc 1.32').