2022-12-10 20:33:23 +01:00
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# Overview over combov2's and ComboCtl's architecture
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ComboCtl is the core driver. It uses Kotlin Multiplatform and is written in a platform agnostic
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way. The code is located in `comboctl/`, and is also available in [its own separate repository]
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(https://github.com/dv1/ComboCtl). That separate repository is kept in sync with the ComboCtl
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copy in AndroidAPS as much as possible, with some notable changes (see below). "combov2" is the
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name of the AndroidAPS driver. In short: combov2 = ComboCtl + extra AndroidAPS integration code.
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## Directory structure
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The directory structure of the local ComboCtl itself is:
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* `comboctl/src/commonMain/` : The platform agnostic portion of ComboCtl. The vast majority of
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ComboCtl's logic is contained there.
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* `comboctl/src/androidMain/` : The Android specific code. This in particular contains
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implementations of the Bluetooth interfaces that are defined in `commonMain/`.
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* `comboctl/src/jvmTest/` : Unit tests. This subdirectory is called `jvmTest` because in the
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ComboCtl repository, there is also a `jvmMain/` subdirectory, and the unit tests are run
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with the JVM.
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The AndroidAPS specific portion of the driver is located in `src/`. This connects ComboCtl with
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AndroidAPS. In particular, this is where the `ComboV2Plugin` class is located. That's the main
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entrypoint for the combov2 driver plugin.
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## Basic description of how ComboCtl communicates with the pump
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ComboCtl uses Kotlin coroutines. It uses [the Default dispatcher](https://kotlinlang.
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org/api/kotlinx.coroutines/kotlinx-coroutines-core/kotlinx.coroutines/-dispatchers/-default.html),
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with [a limitedParallelism](https://kotlinlang.org/api/kotlinx.
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coroutines/kotlinx-coroutines-core/kotlinx.coroutines/-coroutine-dispatcher/limited-parallelism.html)
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constraint to prevent actual parallelism, that is, to not let coroutine jobs run on multiple
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threads concurrently. Coroutines are used in ComboCtl to greatly simplify the communication steps,
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which normally require a number of state machines to be implemented manually. Stackless coroutines
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like Kotlin's essentially are automatically generated state machines under the hood, and this is
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what they are used for here. Enabling parallelism is not part of such a state machine. Furthermore,
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communication with the Combo does not benefit from parallelism.
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The communication code in ComboCtl is split in higher level operations (in its `Pump` class) and
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lower level ones (in its `PumpIO` class). `Pump` instantiates `PumpIO` internally, and focuses on
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implementing functionality like reading basal profiles, setting TBRs etc. `PumpIO` implements the
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building blocks for these higher level operations. In particular, `PumpIO` has an internal
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coroutine scope that is used for sending data to the Combo and for running a "heartbeat" loop.
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That "heartbeat" is a message that needs to be regularly sent to the Combo (unless other data is
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sent to the Combo in time, like a command to press a button). If nothing is sent to a Combo for
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some time, it will eventually disconnect. For this reason, that heartbeat loop is necessary.
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PumpIO also contains the code for performing the pump pairing.
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Going further down a level, `TransportLayer` implements the IO code to generate packets for the
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Combo and parse packets coming from the Combo. This includes code for authenticating outgoing
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packets and for checking incoming ones. `TransportLayer` also contains the `IO` subclass, which
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actually transfers packets to and receives data from the Combo.
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One important detail to keep in mind about the `IO` class is that it enforces a packet send
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interval of 200 ms. That is: The time between packet transmission is never shorter than 200 ms
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(it is OK to be longer). The interval is important, because the Combo has a ring buffer for the
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packet it receives, and transmitting packets to the Combo too quickly causes an overflow and a
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subsequent error in the Combo, which then terminates the connection.
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The Combo can run in three modes. The first one is the "service" mode, which is only briefly
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used for setting up the connection. Immediately after the connection is established, the pump
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continues in the "command" or "remote terminal" (abbr. "RT") mode. The "command" mode is what the
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remote control of the Combo uses for its direct commands (that is, delivering bolus and retrieving
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the latest changes / activities from the history). The "remote terminal" mode replicates the LCD
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on the pump itself along with the 4 Combo buttons.
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Only a few operations are possible in the command mode. In particular, the driver uses the bolus
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delivery command from the command mode, the command to retrieve a history delta, and the command
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for getting the pump's current date and time. But everything else (getting basal profile, setting
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TBR, getting pump status...) is done in the remote terminal mode, by emulating a user pressing
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buttons. This unfortunately means that these operations are performed slowly, but there is no
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other choice.
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## Details about long-pressing RT buttons
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As part of operations like reading the pump's profile, an emulated long RT button press is sometimes
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used. Such long presses cause more rapid changes compared to multiple short button presses. A
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button press is "long" when the emulated user "holds down" the button, while a short button press
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equals pressing and immediately releasing the emulated button.
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The greater speed of long button presses comes with a drawback though: "Overshoots" can happen. For
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example, if long button pressing is used for adjusting a quantity on screen, then the quantity may
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still get incremented/decremented after the emulated user "released" the button. It is therefore
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necessary to check the quantity on screen, and finetune it with short button presses afterwards
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if necessary.
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## Idempotent and non-idempotent high level commands
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A command is _idempotent_ if it can be repeated if the connection to the pump was lost. Most
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commands are idempotent. For example, reading the basal profile can be repeated if during the
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initial basal profile retrieval the connection was lost (for example because the user walked away
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from the pump). After a few attempts to repeat the command, an error is produced (to avoid an
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infinite loop).
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Currently, there is only one non-idempotent command: Delivering a bolus. This one _cannot_ be
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repeated, otherwise there is a high risk of infusing too much insulin. Instead, in case of a
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connection failure, the delivering bolus command fails immediately and is not automatically
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attempted again.
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## Automatic datetime adjustments and timezone offset handling
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ComboCtl automatically adjusts the date and time of the Combo. This is done through the RT mode,
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since there is no command-mode command to _set_ the current datetime (but there is one for
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_getting_ the current datetime). But since the Combo cannot store a timezone offset (it only stores
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localtime), the timezone offset that has been used so far is stored in a dedicated field in the
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pump state store that ComboCtl uses. DST changes and timezone changes can be tracked properly with
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this logic.
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The pump's current datetime is always retrieved (through the command mode) every time a connection
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is established to it, and compared to the system's current datetime. If these two differ too much,
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the pump's datetime is automatically adjusted. This keeps the pump's datetime in sync.
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## Notes about how TBRs are set
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TBRs are set through the remote terminal mode. The driver assumes that the Combo is configured
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to use 15-minute TBR duration steps sizes and a TBR percentage maximum of 500%. There is code
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in the driver to detect if the maximum is not set to 500%. If AndroidAPS tries to set a percentage
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that is higher than the actually configured maximum, then eventually, an error is reported.
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:warning: The duration step size cannot be detected by the driver. The user _must_ make sure that
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the step size is configured to 15 minutes.
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## Pairing with a Combo and the issue with pump queue connection timeouts
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When pairing, the pump queue's internal timeout is likely to be reached. Essentially, the queue
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tries to connect to the pump right after the driver was selected in the configuration. But
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a connection cannot be established because the pump is not yet paired.
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When the queue attempts to connect to the pump, it "thinks" that if the connect procedure does not
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complete after 120 seconds, then the driver must be stuck somehow. The queue then hits a timeout.
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The assumption about 120s is correct if the Combo is already paired (a connection should be set up
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in far less time than 120s). But if it is currently being paired, the steps involved can take
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about 2-3 minutes.
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For this reason, the driver automatically requests a pump update - which connects to the pump -
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once pairing is done.
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## Changes to ComboCtl in the local copy
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The code in `comboctl/` is ComboCtl minus the `jvmMain/` code, which contains code for the Linux
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platform. This includes C++ glue code to the BlueZ stack. Since none of this is useful to
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AndroidAPS, it is better left out, especially since it consists of almost 9000 lines of code.
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Also, the original `comboctl/build.gradle.kts` files is replaced by `comboctl/build.gradle`, which
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is much simpler, and builds ComboCtl as a kotlin-android project, not a Kotlin Multiplatform one.
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This simplifies integration into AndroidAPS, and avoids multiplatform problems (after all,
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Kotlin Multiplatform is still marked as an alpha version feature).
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2023-01-02 19:10:46 +01:00
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The `comboctl/src/androidMain/AndroidManifest.xml` file also differs in that the `ComboCtl` version
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contains `package="info.nightscout.comboctl.android"` in its `<manifest>` tag, while the AndroidAPS
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version doesn't.
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2022-12-10 20:33:23 +01:00
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When updating ComboCtl, it is important to keep these differences in mind.
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Differences between the copy in `comboctl/` and the original ComboCtl code must be kept as little
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as possible, and preferably be transferred to the main ComboCtl project. This helps with keeping the
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`comboctl/` copy and the main project in sync since transferring changes then is straightforward.
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