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Recent changes in the INET Framework
====================================
INET-4.5 (April 2023) - Stable
------------------------------
This is a new minor stable release within the INET 4.x branch. The main feature
of this release is the ability to concurrently run multiple simulations within
the same process (requires OMNeT++ 7.0 preview 2 or later), along with an extended
Ethernet cut-through switching functionality.
There are also a number of small improvements, and several bug fixes. Some changes
are backward incompatible, so existing models may need to be updated. This version
requires OMNeT++ 6.0 or later.
For a complete list of all added, removed, and changed folders, NED modules, packet
chunks, packet tags, statistics, C++ classes, and signals please refer to the ChangeLog
file in the src folder.
Notable backward incompatible changes are the following:
1. Ethernet cut-through switching
The Ethernet cut-through switching implementation has been extended to work
with all TSN traffic filtering and TSN traffic shaping methods. Previously
it was not possible to combine these features. For a packet that was forwarded
using cut-through switching, the otherwise configured traffic shaping and
traffic filtering methods in the switch were completely bypassed.
The new implementation allows processing the incomplete packet in the switch
while the packet buffer is being filled up by the incoming interface. All
Ethernet headers are available and the packet length is known, so traffic
filtering and traffic shaping can take place the same way it does for
store-and-forward packets.
For more information, see the showcase at:
https://inet.omnetpp.org/docs/showcases/tsn/cutthroughswitching/doc/index.html
This change doesn't require the modification of simulation models, but it may
significantly change the statistical results of simulations that use traffic
filtering or traffic shaping with cut-through switching.
2. Clock model
The RandomDriftOscillator module has been refactored to have a more useful
parameterization. The module has an initial random drift rate parameter that
represents the inaccuracy of device production. Besides, the module uses a
random walk process for an additional drift rate change that represents the
voltage and temperature dependent inaccuracy of the device.
Please note that the gPTP time synchronization change (described later) makes
the RandomDriftOscillator module more useful than the previously widely used
ConstantDriftOscillator module because the first time synchronization can now
completely eliminate the effects of a constant drift.
This change requires the modification of simulation models that use the
RandomDriftOscillator module because the parameterization has been changed.
3. Time-Sensitive Networking
The credit-based shaper has been changed to stop accumulating credits when the
corresponding time-aware shaper (same traffic category) transmission gate is
closed. Additionally, the credit-based shaper can also stop accumulating
credits when the implicit guard band of the time-aware shaper is active.
The time-aware shaper already provides an implicit guard band before each time
a gate is closing according to the gate schedule. This guard band is defined
by the following rule: no packet is allowed to pass the gate unless the packet
can be transmitted completely before the gate closes.
This change doesn't require the modification of simulation models, but it may
significantly change the statistical results of simulations that use both the
credit-based shaper and the time-aware shaper for the same traffic category.
4. Running simulations concurrently (experimental)
INET has been changed to support running multiple simulations concurrently
within a single process. Previously this was not possible, partly because
OMNeT++ itself didn't support concurrent simulation execution, but also
because INET contained several global variables. Please note that this is
an experimental feature in both OMNeT++ and INET.
In order to provide this feature, global variables have been either eliminated,
or replaced with simulation shared variables, or marked with the 'const'
qualifier signifying that their values cannot be changed, or marked with the
'OPP_THREAD_LOCAL' macro to store their values separately for each thread.
This change may require the modification of simulation models if they directly
access some of the modified global variables. Additionally, simulation models
that have their own global variables must be updated to support running
simulations concurrently.
This feature requires using OMNeT++ 7.0 preview 2 or later. For more information,
see the https://omnetpp.org/download/preview page.
Notable backward compatible changes are the following:
1. Clock model
The clock model has been extended with an oscillator compensation parameter.
This parameter can be used to reduce the effect of an inaccurate oscillator
on clock time. Time synchronization mechanisms can often estimate the clock
speed differences and set this parameter to reduce the clock time difference
that would arise over time from clocks running at different speeds.
2. IEEE 802.1-AS (gPTP)
The gPTP time synchronization protocol has been extended to also compensate
for a drifting oscillator. Previously time synchronization only set the clock
time but it didn't account for the clock speed differences between the master
and the slave clock.
This change can result in an order of magnitude smaller maximum clock time
difference between the master and slave clocks over the period of two time
synchronization events.
3. Queueing model
The behavior of complex queueing models depends among others on the execution
order of timers. Previously the scheduling priority for such timers were not
configurable, so the user could not control the order of their execution. This
limitation could prevent getting the desired behavior from the combination
of certain modules. For example, a packet server may need to wait for all
gates to open or close before using the scheduler to process the next packet
at the same simulation time.
Several queueing modules have been extended with additional parameters to
control the scheduling priority of timers. This gives fine grained control
over the order of timer events, that affects how the modules can be combined
into more complex behavior.
Additionally, the active packet source and packet sink modules that generate
or consume traffic periodically have been extended with initial offset parameters.
4. IEEE 802.11
The 802.11 model contains several policy modules that can be replaced by the
user to customize the model behavior. For example, the fragmentation policy
decides when and how frames should be fragmented. Unfortunately, previously
several policy modules were not replaceable using only INI file parameter
assignments. This limitation has been fixed.
All policy submodules have been replaced with submodules having parameterized
module types and corresponding module interfaces, making it easy to replace
policy submodules using only INI files. Additionally, the documentation of
several 802.11 modules and module interfaces have been refined.
5. Protocol element
The generic protocol elements library have been extended with a protocol
independent cut-through implementation. The new modules provide an example
of how this mechanism can be implemented and allows teaching and researching
this topic.
6. Notable bug fixes and other changes
The protocol encapsulation requests and protocol dispatching mechanism between
applications, IP, Ethernet, and other protocols have been refactored to use a
uniform implementation through utility functions. This provides the user with
a more flexible network node architecture where the protocol encapsulation can
be decided on a per packet basis.
Fixed exponent in the calculation of dielectric obstacle loss.
Fixed getReceptionStartTimeVariables method of Z3GateScheduleConfigurator.
Fixed processing of Ethernet control frames.
Fixed emitting linkBrokenSignal when transmitted packet is not acknowledged.
The IPv4NetworkConfigurator log output has been improved.
INET-4.4 (May 2022) - Stable
----------------------------
This is a new minor stable release of the INET 4.x branch. The highlight of this
release is the implementation of several Time-Sensitive Networking (TSN) features.
Also, INET is now fully licensed under LGPL (see later for details).
Experimental Python support has been added for running simulations concurrently
and optionally on an SSH cluster. This is mostly useful for running parameter
studies, automated testing and optimizing parameters.
There are also a number of small improvements, and several bug fixes. Some changes
are backward incompatible, so existing models may need to be updated. This version
requires OMNeT++ 6.0 or later.
For a complete list of all added, removed, and changed folders, NED modules, packet
chunks, packet tags, statistics, C++ classes, and signals please refer to the ChangeLog
file in the src folder.
Notable backward incompatible changes are the following:
1. Network interfaces
The queue modules are placed back inside the network interface compound module
as direct submodules, reverting back a previous change in INET 4.2 version.
In the INET 3.x versions, the network interface queue submodules were part
of the network interface compound modules, and they were directly connected
to other submodules within the network interface using connections and gates.
This structure was not ideal when a packet could be immediately served by the
MAC layer, because the queue recorded a zero simulation time increase in the
queue length. The problem was especially difficult to get around when compound
packet queues were used. In order to fix this issue, we decided to move the
MAC layer queues (as simple submodules) under the MAC layer compound module.
Having this structure allowed the MAC modules to completely bypass the queue
modules if the queueing of the packet was not necessary.
Unfortunately, this change turned out to be bad for various reasons. The most
important is that the queue needs to communicate with the module it is connected
to. For example, a complex compound queue which can delay packets needs to notify
the connected module, in this case of the MAC module, when a packet becomes ready
to be pulled. So once again, we decided to move the queues back where they were
before, outside of the MAC modules. Of course, the original queue length hazard
problem still had to be solved, but as it turned out that problem had to be solved
anyway.
This change may require the modification of simulation models, because the queue
module parameter assignments (referring to the old module positions) may have no
effect any more. This change can break existing simulations silently producing
different results.
2. Network nodes
The addition of Time-Sensitive Networking features required to further extend
the network node architecture by adding a separate bridging layer compound
module between the L2 and L3 layers. This new module is optional and it can
be present in both Ethernet switches and standard hosts.
The VLAN policy module has been moved into the new bridging layer in order
to correctly combine with the TSN stream features.
This change requires updating the VLAN policy module parameter assignments,
otherwise simulations may silently produce different results.
3. Packet filter expressions
Several INET modules (packet filters, packet classifiers, packet schedulers,
various visualizers, etc.) use packet filter expressions to differentiate
packets. In earlier INET versions, the packet filter expressions were limited
to only access certain parts of the packet: name, length, kind, one protocol
header at a time. Perhaps the most important such limitation was that it was
not really possible to combine conditions for different protocol headers.
The new packet filter expression syntax is more general while it retains the
often useful simple pattern matching mechanism for packet names. The generic
NED expression syntax supports the more complicated cases, where filtering for
packet content and packet meta-data is needed. It also allows the combination
of conditions for different protocol headers that was not possible before.
This change may require the modification of simulation models, because packet
filter expressions are not backward compatible. This change can break existing
simulations silently producing different results.
The User's Guide contains a separate chapter describing the packet filter
expressions with several examples.
4. Signals and statistics
Several signals and statistics have been renamed and several others are split
into multiple different ones. This change was necessary in order to have a
more coherent naming and also to have more fine-grained results. The most
important affected modules are the flow measurement recorder and the queueing
model elements. See the ChangeLog file under the src folder for more details.
This change may require the modification of analysis files, because the results
may be different. This change can break existing analysis files silently producing
different diagrams.
Notable backward compatible changes are the following:
1. Time-Sensitive Networking
Several new modules have been added to provide new features of Time-Sensitive
Networking.
An existing implementation of the gPTP time synchronization protocol has been
ported and merged into the INET framework. The protocol has been extended with
the support of multiple time synchronization domains. The clock model has been
extended to allow changing the active time domain to simulate failover. Please
note that the actual mechanism that detects the time synchronization failure
is not yet provided, so right now only manual failover can be simulated.
The new traffic shaping feature provides modules for time-aware shaping,
credit-based shaping, asynchronous shaping, and also various combinations
of them. These modules are usually part of the network interfaces in the
complex queueing mechanism of Time-Sensitive Networking.
The per-stream filtering feature provides modules for token-bucket-based
traffic metering, transmission eligibility time calculation, and a form
of statistical traffic metering. These modules are usually part of the
ingress traffic filter of the bridging layer.
The frame replication and elimination feature provides modules for stream
identification, stream splitting/merging, and stream encoding/decoding as
part of the bridging layer.
All of the above TSN features are described in detail in the User's Guide
and the respective NED files. Besides, there are several new showcases that
demonstrate the individual TSN features and a few combinations.
2. Ethernet model
The old Ethernet (non-TSN) network interface infrastructure has been changed.
The FCS protocol header insertion has been moved from the Ethernet MAC layer
module to the Ethernet protocol layer module. The Ethernet protocol layer was
already separated from the network interface and moved to separate module in
network nodes in the previous INET version. This change makes it possible to
use the old and the new TSN capable Ethernet models interchangeably.
3. Link-layer network-wide automatic configuration
Several new network-wide automatic configurator modules have been added.
One such network configurator module configures all MAC address tables (aka.
MAC forwarding information databases) automatically in all Ethernet switches
by discovering the network topology and finding the shortest paths between
all network node pairs. This configurator can be used instead of manually
configuring the Ethernet switches or instead of using an automatic spanning
tree protocol such as STP or RSTP.
There are several newly added gate scheduling configurators. They can configure
the gate schedules of time-aware shapers for all traffic categories in all
network interfaces of all network nodes. The resulting schedules are such that
the required end-to-end latency and jitter limits are met for all configured
streams. The following gate scheduling configurators are available:
- simple eager configurator
- Z3 SAT-solver-based configurator (requires installation of external library)
- TSNsched-based configurator (requires installation of external tool)
Another network level configurator that is used in Time-Sensitive Networking
is the stream redundancy configurator. This module configures the stream merger
and stream splitter modules in all network nodes such that all redundant traffic
paths are used. The redundant streams make the network resilient to various
node and/or link failures.
Finally, there is the so called failure protection configurator that is used
in Time-Sensitive Networking. This module configures the network using the
stream redundancy, and optionally the gate scheduling configurators, to meet
the complex node and/or link failure protection requirements of all traffic
streams by figuring out the necessary redundant paths.
4. Processing delay
A simple packet processing delay mechanism has been added to the TSN network
interface and also to the bridging layer. This allows one to simulate a very
simple packet processing delay for incoming and outgoing packets, and also for
packets that are forwarded by the bridging layer.
5. Queueing model and protocol elements
The queueing model have been extended with various token bucket meters and
classifiers. The model also allows one to create chained token buckets where
the overflowing tokens go to another bucket. Meters simply attach meta data
to packets while classifiers push packets to different gates, both based
on the state of the token buckets. These modules are currently used in TSN
per-stream traffic filtering.
Several new generic protocol support elements have been added. There are several
new modules, currently used in TSN frame replication, for stream identification,
stream splitting/merging, stream encoding/decoding. There are a few other new
modules, currently used in TSN asynchronous shaping, for transmission eligibility
time metering, filtering, and queueing.
A new interactive packet gate has been added that allows the user to directly
control the gate's open/closed state from Qtenv and experiment interactively.
Please note that in OMNeT++ 6.0 version of Qtenv the simulation may stop more
than once in the same event. This is called pause points, and it happens every
time a packet is passed from one module to another using to queueing model
elements, the protocol support modules, or the INET packet processing API.
6. Applications
A new simple out-of-band clock synchronizer application has been added. This
module can be used to synchronize clocks in the whole network without actually
sending any time synchronization packets.
New IEEE 802.2 LLC protocol-specific applications have been added. These allow
to send IEEE 802.2 LLC packets directly from the application layer.
7. Packet chunks, tags and serializers
New packet chunks have been added for the IEEE 802.1r protocol.
Several new packet tags have been added: PcpReq/PcpInd, StreamReq/StreamInd,
SequenceNumberReq/SequenceNumberInd, ResidenceTimeTag, EligibilityTimeTag,
CreditGateTag, EnapsulationProtocolReq/EnapsulationProtocolInd. The purpose
and usage of these tags can be found at the relevant modules.
New packet chunk serializers have been added for the IEEE 802.1as and IEEE
802.1r tags. This allows recording of PCAP traces in TSN simulations.
8. Signals and statistics
Several new signals and statistics have been added. The most notable newly
added statistics are the measurement of the transmission duration, the signal
propagation time, and the packet residence time. The latter being the duration
the packet spends in individual network nodes. For a complete list of signal
and statistic changes see the ChangeLog in the src folder.
9. Project features
Several new project features have been added. The IEEE 802.1as and the IEEE
802.1r features are used in Time-Sensitive Networking. Another feature is
added for the Microsoft Z3 SAT-solver-based gate schedule configurator, it
requires the installation of an external library.
Finally, there is a new feature for an automatic simulation model self documenter.
This feature allows one to observe the simulations while they are running and
to collect several categories of information about what the simulation modules
are doing. The result can be automatically included in the generated NED
documentation.
10. Visualization
New visualizers have been added that display some aspects of the Time-Sensitive
Networking configuration. One visualizer displays the gate schedule for the
time-aware shapers for multiple network interfaces in multiple network nodes.
Another visualizer displays the redundant traffic paths configured in the
stream splitting and stream merging components.
11. Examples
Several new Time-Sensitive Networking specific examples have been added
under the showcases/tsn folder. The new examples cover the topic of time
synchronization, traffic shaping, gate scheduling, per-stream filtering,
frame replication, frame preemption, cut-through switching, and several
combinations of these features.
Another set of new examples, found under the showcases/measurement folder,
have been added to demonstrate how to do some widely used communication
network measurements. There are examples for datarate, throughput,
utilization, end-to-end delay, jitter, queueing time, residence time,
transmission time, propagation time and various packet-flow-specific
measurements.
12. Experimental Python support
A new experimental Python package has been added that allows the automation
of running and testing multiple simulations concurrently and also optionally
on an SSH cluster. The automated testing covers smoke, fingerprint, sanitizer,
statistical, and several other tests. The inet_python_repl shell script starts
the Python interpreter and loads the required OMNeT++/INET Python packages.
The main entry points are run_simulations, run_smoke_tests, run_fingerprint_tests,
and several other run_* functions, there's also an optimize_simulation_parameters
function. There are also shell scripts (called inet_run_*) that can be used in
the simulation folders directly.
This package will be officially supported in the next OMNeT++/INET release.
13. Documentation
The User's Guide has been extended with new chapters. One new chapter is
about the new Time-Sensitive Networking features. It gives an overview of
the available modules and how to use them. Another new chapter is about the
new packet filter expression syntax. It gives a brief description of the
syntax and provides several examples.
14. Licensing and code formatting
The whole INET Framework has been re-licensed under the LGPL. The vast majority
of INET components were already licensed under LGPL. All other components that
were not, and where we could not reach the original authors, or they did not
agree with the new license, have been moved into a separate INET-GPL project.
As of today, the new INET-GPL project (https://github.com/inet-framework/inet-gpl)
contains the following old INET components:
- TCP NSC
- packetdrill
- HTB queue and scheduler
- HTTP tools
All source files have been changed with respect to license headers. The longer
license header variants have been replaced with a standard one-liner SPX license
reference.
15. Notable bug fixes and other changes
Fixed packet level region tag updating when packet contents are changed.
Fixed copying region tags in fragmentation, defragmentation, aggregation, and deaggregation.
Fixed the hazards in queue length statistics that allowed the length to go
below 0 or above the queue capacity for zero simulation time.
Fixed the utilization result filter that incorrectly calculated 1-utilization.
Fixed several memory leaks and other problems found by the sanitizer.
There were several other minor bug fixes some of which are documented on Github.
The VoIP stream modules have been updated to the latest development library.
INET-4.3 (January 2021) - Stable
--------------------------------
This is a new minor stable release of the INET 4.x branch. The highlights of this
release are the infrastructure for Time-Sensitive Networking protocols, the EIGRP
routing protocol and DCTCP congestion control.
For TSN support, a new modular Ethernet MAC and PHY layer model has been added
which provides Ethernet frame preemption, Ethernet cut-through switching, a gating
mechanism for packet queueing, and a clock model which also models clock drifting.
New API level features include intra-node packet streaming, inter-node transmission
update support, bit level packet data identity tracking, and the ability to define
and measure packet flows.
There are also a number of small improvements, and several bug fixes. Some changes
are backward incompatible, so existing models may need to be updated. This version
requires OMNeT++ 6.0 preview 10 or later.
For a complete list of all added, removed, and changed folders, NED modules, packet
chunks, packet tags, statistics, C++ classes, and signals please refer to src/ChangeLog.
Notable backward incompatible changes are the following:
1. Packet API
The packet tag, chunk tag and chunk region tag APIs have been changed to
store all tags using shared pointers. Moreover, the vectors containing said
tags have also been changed to be stored using shared pointers. These shared
data structures are automatically copied behind the scenes when they are
modified, and they are also shared among multiple packets.
The reasoning is that packets are copied quite often, so this operation must
be very efficient both in terms of space and time. Often the copied packet is
not modified with respect to the attached tags, so it makes sense to share these
data structures. The previous packet API already shared the packet data between
copies, but it didn't share the attached tags.
Internally, the class TagSet has been replaced with another class, SharedTagSet,
and similarly, the class RegionTagSet has been replaced with SharedRegionTagSet.
This change requires the modification of simulation models, because tags are
now returned as shared pointers. Moreover, a different method must be called,
namely the ones with the 'ForUpdate' suffix, to modify existing tags. Due to
this copy-on-write semantics, this change can also break existing user code.
2. Ethernet
Several modules which had an abbreviated Ether in their names have been renamed
to have the complete word, Ethernet, in their names instead. This change affects
many names: EthernetSwitch, EthernetMac, EthernetLink, EthernetSignal, etc.
The Ethernet switch relay functionality provided by the MacRelayUnit and
Ieee8021dRelay modules have been refactored. The most prominent change is that
these modules no longer work on Ethernet frames only. They simply expect the
packets to contain the necessary metadata such as the incoming interface
indication (InterfaceInd) and the source and destination MAC address indication
(MacAddressInd) in order to operate.
A new WireJunction module has been added which replaces the functionality of
the old EtherBus and EtherHub modules. This module represents a generic wiring
hub, and simply broadcasts messages (packets, frames, signals) received on one
port to all other ports, mimicking the propagation of wired electrical signals.
The physical signal class hierarchy has been refactored, the old Signal class
has been split into a generic wireless signal, called WirelessSignal, and
a generic wired signal, called WiredSignal, both subclassed from Signal.
The renames may break existing simulations but they are easy to follow. The
MAC relay changes are internal to network nodes and may only break Ethernet
extension models. All the other changes are likely to produce compilation
errors.
3. IEEE 802.1q support
The old 802.1q support has been removed from the default EthernetInterface,
because it unnecessarily complicated the network interface and it was not
extensible.
The LinkLayerNodeBase base module has been extended with separate and optional
Ethernet and IEEE 802.1q protocol layers, where protocol modules have on instance
per network node. This results in a different structure from the default one
where the Ethernet protocol is part of the network interface. The advantage is
that various additional IEEE 802 protocols such as 802 LLC, 802 SNAP, 802.1q
and 802.1ae are better composable this way.
Several small layered protocol models and infrastructure components have been
added to support these IEEE 802 protocols. These include among others protocol
header inserters and checkers, protocol printers and dissectors, etc.
This change may break simulations that used the old IEEE 802.1q support. They
must be carefully investigated and updated to use the new model instead.
4. VLAN support
The VLAN support has been completely refactored to use separate modules for
filtering and mapping VLAN indications and requests on packets according to
a user-configurable policy. The new VlanIndFilter and VlanReqMapper modules
are part of a VLAN policy module of Ethernet switches by default.
This change may cause simulations to ignore certain parameters which are
expected to affect virtual interfaces and thus break existing simulations.
5. Virtual interfaces
The vlan submodule vector of network nodes inherited from LinkLayerNodeBase
has been renamed to virt. The original name suggested misleadingly that this
set of network interfaces were meant to be used exclusively for VLAN, but that
is not the case. The virtual interfaces, called VirtualInterface, can be used
for all kinds of protocol parameterization such as changing the source MAC
address.
This change may cause simulations to ignore certain parameters which are
expected to affect virtual interfaces.
6. Registering protocols and services
There was some confusion with respect to the expected module gates in the
arguments of the registerService() and registerProtocol() methods. Following
the OSI terminology, the registerService() method now takes the requestIn
and indicationOut gates, the registerProtocol() method takes the requestOut
and indicationIn gates as arguments. This change has been followed with
all affected modules.
Unfortunately, this change may break existing code silently, although not
very likely. The registration calls may provide the incorrect gates to the
MessageDispatcher modules, which in turn will dispatch the packets to the
wrong modules or not at all. Luckily, in the latter case, an error will be
thrown and the simulation terminates.
7. Mobility
All methods in the IMobility interface that returned a Coord or a Quaternion
data structure by value have been changed to return a const reference instead.
These methods, especially the getCurrentPosition() method, may be called quite
often, so avoiding the copying of said data structures increases performance.
This change can be followed easily by implementations, because in most cases
the values were already stored in the mobility modules. This change is not
expected to break existing models silently.
8. Radio medium analog model
Similarly to the IMobility interface change, several methods that returned
or received as an argument a Coord or a Quaternion data structure by value
has been changed to return or receive a const reference instead. Again, these
methods may be called quite often in wireless network simulations, so avoiding
the copying of these data structures increases performance.
This change has very little effect on the implementations, since in most cases
the values were already stored in the related object with a large enough dynamic
extent. This change is not expected to break existing models silently.
9. Queueing model
The IPacketQueue interface has been changed to use explicit enqueuePacket()
and dequeuePacket() methods instead of relying on the generic pushPacket()
and pullPacket().
This change required to updated all existing MAC models to use the new API.
Other 3rd party MAC modules have to be updated accordingly.
10. Renames
Several folders in the physicallayer folder have been moved below the newly
added wired and wireless folders, and renamed. Besides, all support modules have
been moved one level deeper into the common folders. This change helps new
users to find existing physical layer technologies more easily, because they
have their own folders right inside the wired and wireless folders. This change
separates the largely independent wired and wireless physical layer support
modules and implementations.
Similary to the above, several folders in the visualizer folder have been
moved below the newly added canvas and osg folders. This change is required
in order to be able to add separate features for canvas (2D) and OSG (3D)
visualizations.
The InterfaceEntry module that represents network interfaces has been renamed
to NetworkInterface. The old name was a left-over from the time when this
class was really an integral part of the InterfaceTable module. This is no
longer the case, thus the renaming makes perfect sense.
The Protocol::ieee8022 global protocol variable has been renamed, and split
into Protocol::ieee8022llc and Protocol::ieee8022snap.
The queueing API has been updated to reflect the new push/pull duality in
the naming convention as opposed to the old push/pop duality. For example,
the old packetPopped signal has been renamed to packetPulled, and the old
popPacket() method in the IPassivePacketSource has been renamed to pullPacket().
The IPacketQueueingElement C++ interface and the corresponding base class,
called PacketQueueingElementBase, has been renamed to IPacketProcessor and
PacketProcessorBase, respectively. The reason is that, although these classes
are part of the queueing API, they are more general and their original name
didn't capture this fact. Also, in several protocol implementations deriving
classes from the classes with the original names looked really weird.
All integral C++ type alias have been replaced with the standard variants.
For example, the int64 type alias has been replaced with int64_t.
These changes mostly result in NED errors and C++ compilation errors in the
simulation models which are affected, and they are easy to follow.
11. Removed models
The NetAnimTrace module has been removed. The visualization functionality it
provided has been replaced with the much more versatile and feature rich
visualizer modules.
The PacketDump class, which was used to provide a very basic human readable
string representation of the packet content, has been removed. The packet
printer API is a much more versatile and widely parameterizable way of
printing packets, and there's no reason to have two different ways of doing
the same thing.
The EtherBus module has been removed because it has been completely replaced
with the generic WireJunction module.
The Ieee8021qEncap module has been removed. This module was used in the Ethernet
network interfaces to provide IEEE 802.1q protocol support and VLAN networking.
These changes break existing simulation models with a compile time or runtime
error.
Notable backward compatible changes are the following:
1. Packet API
The Packet API has been extended with several new replace and update methods.
The replace methods allow replacing arbitrary parts of the packet content with
a single method call. The update methods allow updating arbitrary parts of the
packet content in place with a single method call. Similarly to the completeness
of these methods, the remove and insert methods have also been further extended.
Moreover, the Packet API has been extended with a packet level region tag
support. This allows attaching region tags to the data of packets similarly
to how chunks already allowed this. The main difference is that when data
is attached to chunks, then it must be in a form that can be shared among
multiple packets which share the same chunk throughout the network. For
example, the creation timestamp of coherent data fragments is such a data.
In contrast, the queueing time of coherent data fragments belongs to the
individual packets, and must be separately updated for different paths the
same data takes in the network.
The chunk API has been extended with a bit-level identity tracking of data.
In other words, it is now possible to determine if the data that shows up at
two different locations in the network, independently of whether these locations
are in the same network node or not, and also independently of how the data
is represented (field-based or binary), is the same data or not. This feature,
for example, is useful for end-to-end delay measurements and more accurate
path visualization.
A new chunk class, called EncryptedChunk, has been added to allow storing
encrypted data in a packet without actually encrypting the data. Internally,
the new chunk uses a shared reference to the encrypted chunk and the length
of the encrypted binary representation.
Efficient parsim support has been added to all classes of the Packet API,
including the Packet class itself, all chunk classes, and all tags.
The PacketProtocolTag has been extended with an extra front and back offset
that further specifies where the actual protocol is to be found within the
packet data. This feature is primarily useful to keep the associated protocol
of the packet up to date even while the packet is being constructed within a
protocol module. Doing so allows the packet printer and packet dissector to
understand a partially encapsulated, incomplete packet.
2. Clock model
Several new modules have been added to support the modeling of hardware clocks
and the related clock drift phenomena. The new modules can be found in a new
top level folder called clock. The clock model is an optional feature that
can be most conveniently used via the ClockUserModuleBase and ClockUserModuleMixin
classes.
Several modules have been extended with optional clock support: UdpBasicApp,
InterpacketGapInserter, TransmitterBase, PeriodicGate, etc. This feature has
been documented in the User's Guide.
3. Ethernet
A completely new modular Ethernet model has been added to the linklayer and
physicallayer folders. The three most prominent new features that are directly
supported are the Ethernet frame preemption, Ethernet cut-through switching,
and the gating mechanism in the Ethernet queues.
The new model contains of several smaller modules that allow the user to
combine them in more ways than before and also to customize their behavior.
The main purpose of this change was to provide support for Ethernet
Time-Sensitive Networking (TSN) features.
Following the changes in the OMNeT++ cDatarateChannel API, both existing
Ethernet MAC models that used the old forceTransmissionFinishTime() API have
been updated to use the new transmission update mechanism instead.
4. PPP
Similarly to the change in the Ethernet model, the PPP protocol implementation
has been changed to use the new transmission update API in place of the old
forceTransmissionFinishTime().
5. TCP
A new congestion control algorithm, called DCTCP, has been added by Marcel
Marek. Also, related to this change, the ECN support has been enhanced to be
customizable by congestion control algorithms.
6. Enhanced Interior Gateway Routing Protocol (EIGRP)
A new model of the routing protocol EIGRP with support for IPv4 and IPv6 has
been ported from ANSAINET 3.4.0 to INET. This is a large addition that adds a
lot of modules, some new network node types, and it also comes with several new
examples.
This model was contributed by Vladimir Vesely, Jan Bloudicek, Vit Rek, and Jan
Zavrel from the Brno University of Technology.
7. Packet flows and timing measurements
The concept of packet flows has been added to provide support for advanced timing
measurements. A packet flow is a logical classification of packets, identified
by a name, over the whole network and over the duration of the whole simulation.
Packets may have a PacketFlow tag attached to a region of data which describes
flow membership.
This feature allows making timing measurements between two or more arbitrary
end points in the network. The measurement can separate queueing time, processing
time, propagation time, transmission time, etc. on a per-bit basis efficiently.
It is also possible to collect all packet events (e.g queueing, processing,
transmission, propagation) and do arbitrary computations again on a per-bit
basis. This feature is provided by the FlowMeasurementStarter and FlowMeasurementRecorder
modules. The measurement data are collected on packets in various time tags
(e.g. QueueingTimeTag), which are updated by all related modules (e.g. PacketQueue).
8. Queueing model
The synchronous packet processing API has been extended with the support of
packet streaming between modules. This feature allows two modules within the
same network node to communicate synchronously (without sending asynchronous
messages) and process a packet bit by bit over a nonzero amount of time. The
related methods are called pushPacketStart(), pushPacketEnd(), pushPacketProgress(),
pullPacketStart(), pullPacketEnd(), and pullPacketProgress().
Several queueing model base classes have been refined and somewhat refactored
in order to better support the new feature. Also, many queueing model elements
have been extended with direct packet streaming support.
A few new queueing model elements have also been added that provide support
for the gating mechanism of Time-Sensitive Networking and for the preemption
mechanism of Ethernet. Some notable examples are PacketGate, PeriodicGate,
PreemptingServer, PreemptableStreamer, etc.
9. PCAP
The PCAP support has been extended with the more modern PCAPng file format.
This is the new default output file format for the PcapRecorder module. The
support for recording PCAP files has been extended to the network, network
node, and network interface level. The new format allows recording the network
interface and packet direction (outbound/inbound) for frames and also supports
mixing packet formats, making it possible to record the traffic of potentially
the whole network into a single file.
10. Socket processing
Several new modular socket command and packet processing components have been
added for Ethernet and IEEE 802.2 LLC protocols. There are modules for handling
the opening, configuration, and closing commands for sockets, others for maintaining
a table of open sockets (which can also be inspected in the runtime user interface),
and some for processing and duplicating the incoming packets for all open sockets.
11. Protocol elements library
Many small generic and reusable protocol implementation support components
have been added. These components include, among others, generic components for
packet fragmentation and defragmentation, aggregation and deaggregation, CRC and
FCS insertion and checking, and physical layer wired transmitter and receiver
models.
12. Visualizer
A new packet flow visualizer has been added, called PacketFlowCanvasVisualizer
and its OSG variant PacketFlowOsgVisualizer. They have also been included in
the integrated visualizer modules. The new visualizers display the packet flow
paths as polylines along with some basic statistics. This visualizer relies on
the newly introduced packet flow concept.
The spectrum and spectrogram visualization of the MediumCanvasVisualizer has
been further enhanced with better options and a more efficient implementation.
13. Printing formatted output
Support for producing formatted log output has been added with the new EV_FIELD
and other EV_ macros. The default str() method in several Packet API classes
(e.g. Packet, various Chunks, Signal) have been enhanced to provide better
textual representation in the log.
The IPrintableObject C++ interface has been moved to the common folder. It
has also been extended with template support for printing objects without
having to repeat a lot of code and with using the default shift operator.
14. Features (.oppfeatures)
Several new OMNeT++ features have been added and some old features have been
split. These changes can be found in the IDE on the INET project properties:
- Clock
- Clock examples
- EIGRP routing
- EIGRP routing examples
- Emulation showcase
- IEEE 802.1ae
- IEEE 802.1q
- IEEE 802.2
- Internet protocol examples
- Open MP support
- Physical layer common
- Physical layer wired common
- Physical layer wireless common
- Protocol support
- Protocol tutorial
- Queueing library
- Queueing tutorial
- Unit disk radio
- Virtual interface
- Visualization OSG (3D)
- Visualization OSG (3D) showcases
- Visualization canvas (2D)
- Visualization canvas (2D) showcases
- Visualization common
- Wireless noise source
15. Examples
Several new examples have been added:
- clock drift
- Ethernet frame preemption
- Ethernet cut-through switching
- gating mechanism in Ethernet queueing
- modular Ethernet interface
- DCTCP congestion algorithm
- timing measurement along packet flows
- video streaming using network emulation
- signal power spectral density visualization
A few examples have been substantially changed to follow other changes:
- IEEE 802.1d
- virtual LAN
16. Testing
The fingerprint testing script has been extended with support for computing
multiple different fingerprints and a separate fingerprint calculator option.
The updated fingerprint tests contain four separate fingerprint values for
each example simulation:
- detailed model behavior
- complete network byte order packet data and timing at the network level
- complete network packet length and timing at the network level
- graphics in the runtime user interface.
Several new fingerprint, module, and unit tests have been added for the new
clock model, the protocol support modules, and the new formatted output.
17. Documentation
A new chapter about the newly added clock model has been added to the User's
Guide. The Collecting Results chapter has been completed and also extended
with a new section that describes how to do timing measurements along packet
flows. The queueing model and emulation chapters of the User's Guide has been
updated to reflect the changes in the queueing model of this release.
18. Bug fixes
A bug in the TCP Nagle's algorithm has been fixed, see #558.
A bug related to using the latest avcodec libraries (e.g. Ubuntu 20.10) in
the VoIP streaming applications has been fixed.
The C++ numeric type selection/promotion support for unit specific binary
operators has been fixed to follow what C++ does with the standard types.
19. Code cleanup and formatting
The whole source tree has been cleaned up with respect to C++ code formatting,
indentation, header guards, whitespace, and so on. Moreover, all copyright
headers in the C++ source files have been updated to use the official GPL-2
and GPL-3 formats as suggested.
All markers (TBD, XXX, etc.) in the source code has been unified to use one
of the standard TODO, FIXME, and KLUDGE markers. These have well-defined
meaning and it makes finding them easier.
20. Other notable changes
A few new multi-dimensional mathematical functions have been added that can
be useful to represent signal power density in the physical layer. These new
functions are the Rasterized2DFunction, PeriodicallyInterpolated2DFunction,
LeftCurryingFunction and RightCurryingFunction.
In several places the std::min and std::max calls have been replaced with
inet::minnan, inet::maxnan that properly propagate NaN values.
The IProtocolRegistrationListener interfaces have been extended to allow
registering a protocol group or any protocol as a fallback for a service or
protocol available at a module gate.