18903: pkg/tinyusb: add tinyUSB netdev driver r=dylad a=gschorcht
### Contribution description
This PR adds the tinyUSB netdev driver.
The tinyUSB netdev driver is part of the tinyUSB package and is enabled by module `tinyusb_netdev`. It is available for boards that provide the `tinyusb_device` feature.
**Please note** Since the tinyUSB package is distinct from (and incompatible with) the USB stack provided around USBUS in RIOT (see USB), the tinyUSB netdev driver cannot be used together with with any USBUS device class.
The tinyUSB netdev driver uses Ethernet over USB and supports the following protocols:
- CDC ECM (Ethernet Control Model)
- CDC NCM (Network Control Model)
- RNDIS (Microsoft Remote NDIS)
While Linux and macOS support all these protocols, Microsoft Windows only supports the RNDIS protocol and since Windows version 11 also the CDC NCM protocol. macOS supports the RNDIS protocol since version 10.15 (Catalina).
Which protocol is used is selected by the corresponding pseudomodules `tinyusb_class_net_cdc_ecm`, `tinyusb_class_net_cdc_ncm` and `tinyusb_class_net_rndis`.
The CDC ECM protocol (`tinyusb_class_net_cdc_ecm`) and the RNDIS protocol (`tinyusb_class_net_rndis`) can be used simultaneously to support all operating systems, for example :
```
USEMODULE='tinyusb_netdev tinyusb_class_net_rndis tinyusb_class_net_cdc_ecm' \
BOARD=... make -C ... flash
```
In this case, the CDC ECM protocol is the default protocol and the RNDIS protocol the alternative protocol defined as second device configuration. The CDC NCM protocol cannot be used together with the CDC ECM or the RNDIS protocol.
This PR includes PR #18983 for now to be compilable.
Comparison with USBUS CDC ECM (`nucleo-f767zi` board):
```
text data bss dec hex filename
65916 596 18728 85240 14cf8 tests_pkg_tinyusb_netdev.elf
```
```
text data bss dec hex filename
63120 544 15444 79108 13504 tests_usbus_cdc_ecm.elf
```
### Testing procedure
Use a board that is supported by tinyUSB. Compile and flash the test application for each protocol:
1. RNDIS
```
BOARD=... make -j8 -C tests/pkg_tinyusb_netdev flash
```
2. CDC ECM
```
CLASS=tinyusb_class_net_cdc_ecm BOARD=... make -j8 -C tests/pkg_tinyusb_netdev flash
```
3. CDC NCM
```
CLASS=tinyusb_class_net_cdc_ncm BOARD=... make -j8 -C tests/pkg_tinyusb_netdev flash
```
For each test, a network interface should be added on the host. Use command `ifconfig` on USB device and on the host and check that both have a link local address. In syslog there should be an output like the following:
<details>
```
Nov 13 18:14:46 gunny8 kernel: [4611465.480025] usb 1-2.2: new full-speed USB device number 28 using xhci_hcd
Nov 13 18:14:47 gunny8 kernel: [4611465.581641] usb 1-2.2: New USB device found, idVendor=1209, idProduct=7d01, bcdDevice= 1.00
Nov 13 18:14:47 gunny8 kernel: [4611465.581646] usb 1-2.2: New USB device strings: Mfr=1, Product=2, SerialNumber=3
Nov 13 18:14:47 gunny8 kernel: [4611465.581650] usb 1-2.2: Product: nucleo-f767zi
Nov 13 18:14:47 gunny8 kernel: [4611465.581653] usb 1-2.2: Manufacturer: RIOT-os.org
Nov 13 18:14:47 gunny8 kernel: [4611465.581654] usb 1-2.2: SerialNumber: 6591620BCB270283
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:usb0 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:usb0 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.1066] manager: (usb0): new Ethernet device (/org/freedesktop/NetworkManager/Devices/528)
Nov 13 18:14:47 gunny8 kernel: [4611465.594604] rndis_host 1-2.2:1.0 usb0: register 'rndis_host' at usb-0000:00:14.0-2.2, RNDIS device, fa:db:7c:1b:58:80
Nov 13 18:14:47 gunny8 mtp-probe: checking bus 1, device 28: "/sys/devices/pci0000:00/0000:00:14.0/usb1/1-2/1-2.2"
Nov 13 18:14:47 gunny8 mtp-probe: bus: 1, device: 28 was not an MTP device
Nov 13 18:14:47 gunny8 systemd-udevd[17796]: link_config: autonegotiation is unset or enabled, the speed and duplex are not writable.
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:usb0 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 kernel: [4611465.643852] rndis_host 1-2.2:1.0 enp0s20f0u2u2: renamed from usb0
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:usb0 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00001002
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.1833] device (usb0): interface index 508 renamed iface from 'usb0' to 'enp0s20f0u2u2'
Nov 13 18:14:47 gunny8 upowerd[2845]: unhandled action 'bind' on /sys/devices/pci0000:00/0000:00:14.0/usb1/1-2/1-2.2/1-2.2:1.1
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2037] device (enp0s20f0u2u2): state change: unmanaged -> unavailable (reason 'managed', sys-iface-state: 'external')
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 vmnetBridge: Adding interface enp0s20f0u2u2 index:508
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2075] device (enp0s20f0u2u2): carrier: link connected
Nov 13 18:14:47 gunny8 upowerd[2845]: unhandled action 'bind' on /sys/devices/pci0000:00/0000:00:14.0/usb1/1-2/1-2.2/1-2.2:1.0
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2129] settings: (enp0s20f0u2u2): created default wired connection 'Kabelgebundene Verbindung 2'
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <warn> [1668359687.2142] device (enp0s20f0u2u2): connectivity: "/proc/sys/net/ipv4/conf/enp0s20f0u2u2/rp_filter" is set to "1". This might break connectivity checking for IPv4 on this device
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2151] device (enp0s20f0u2u2): state change: unavailable -> disconnected (reason 'none', sys-iface-state: 'managed')
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 upowerd[2845]: unhandled action 'bind' on /sys/devices/pci0000:00/0000:00:14.0/usb1/1-2/1-2.2
Nov 13 18:14:47 gunny8 systemd-udevd[17796]: link_config: autonegotiation is unset or enabled, the speed and duplex are not writable.
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2403] policy: auto-activating connection 'Kabelgebundene Verbindung 2' (0b1ae45e-c76e-3efb-a2cd-138ca2b2a59c)
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2414] device (enp0s20f0u2u2): Activation: starting connection 'Kabelgebundene Verbindung 2' (0b1ae45e-c76e-3efb-a2cd-138ca2b2a59c)
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2419] device (enp0s20f0u2u2): state change: disconnected -> prepare (reason 'none', sys-iface-state: 'managed')
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2429] device (enp0s20f0u2u2): state change: prepare -> config (reason 'none', sys-iface-state: 'managed')
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2440] device (enp0s20f0u2u2): state change: config -> ip-config (reason 'none', sys-iface-state: 'managed')
Nov 13 18:14:47 gunny8 NetworkManager[24229]: <info> [1668359687.2445] dhcp4 (enp0s20f0u2u2): activation: beginning transaction (timeout in 45 seconds)
Nov 13 18:14:47 gunny8 vmnetBridge: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 vmnet-natd: RTM_NEWLINK: name:enp0s20f0u2u2 index:508 flags:0x00011043
Nov 13 18:14:47 gunny8 avahi-daemon[1464]: Joining mDNS multicast group on interface enp0s20f0u2u2.IPv6 with address fe80::dba4:adb8:9ffe:d93e.
Nov 13 18:14:47 gunny8 avahi-daemon[1464]: New relevant interface enp0s20f0u2u2.IPv6 for mDNS.
Nov 13 18:14:47 gunny8 avahi-daemon[1464]: Registering new address record for fe80::dba4:adb8:9ffe:d93e on enp0s20f0u2u2.*.
Nov 13 18:14:47 gunny8 kernel: [4611465.895046] userif-1: sent link down event.
Nov 13 18:14:47 gunny8 kernel: [4611465.895052] userif-1: sent link up event.
```
</details>
Ping from and to the host.
### Issues/PRs references
Depends on PR https://github.com/RIOT-OS/RIOT/pull/18983
Co-authored-by: Gunar Schorcht <gunar@schorcht.net>
There are a number of tests included in RIOT. They are located in the
tests folder. These tests
allow basic functionality to be verified as well as provide an example of
usage.
Running automated tests
Some tests can be performed automatically. The test automation scripts are
defined in the <test_application>/tests/ folder. They are written in python
and interact through the serial (typically UART) with the test application code running on a
board to do the validation. It is recommended to flash the board with the
test just before running it because some platforms cannot be reset while
testing.
Running single test
From the test application directory run:
BOARD=<board_of_your_choice> make flash test
An automated way of knowing if a test is available is to execute the
'test/available' target from the test application directory.
It executes without error if tests run by 'make test' are present.
make test/available
Running all test for particular board
If you would like execute all tests for given board, you could use dedicated
script compile_and_test_for_board.py
Running tests that require a preliminary manual configuration
Some tests need active monitoring or manual setup steps but still have some
automated scripts. The test automation scripts are defined in the
<test_application>/tests-with-config/ folder.
For running them, follow the setup or analysis documentation and use the
test-with-config target.
Running tests that require root privileges
Some tests require root privileges to launch their automated script. In this
case, the test automation scripts are defined in the
<test_application>/tests-as-root/ folder.
For running them, follow the setup or analysis documentation and use the
test-as-root target.
Cleaning intermediate files
After test execution intermediate files are not automatically deleted.
Execution of multiple tests, especially all for particular board could generate
many files. For example, after execution of all test for stm32f469i-disco board
(more than 230 tests) around 7.5 GB of intermediate files are created.
There are few methods for cleaning intermediate files.
If you would like to clean intermediate file only for particular board you should
go to main RIOT directory and execute one from these commands:
If you would like to clean intermediate files for all boards go to main RIOT
directory and use this command.
@warning This command cleans all local files, for example, pkg downloads and
locally generared docs.
make distclean
Implementing automated tests
The goal is to be able to run all tests in a sequential way for as many targets
as possible.
As some board can't be reset without a manual trigger tests should be implemented
with some kind of synchronization. This can be done in two ways:
use test_utils_interactive_sync when uart input/output does not need to be
disabled for the test. This is enabled by default.
set up the test in a loop so the test script will be able so sync with some kind
of start condition in the test.
The module for the first option is test_utils_interactive_sync and is set as a
default module in Makefile.tests_common. It can be disabled by setting in the
application makefile DISABLE_MODULE += test_utils_interactive_sync. The python
test script will adapt to it automatically.
When using the shell module, test_utils_interactive_sync will use the shell
itself to synchronize, and will not use test_utils_interactive_sync(); function
to synchronize. Some times you will want to synchronize before the start of the
script and use test_utils_interactive_sync(); function (e.g.:
tests/ps_schedstatistics). For these cases
you can disable test_utils_interactive_sync_shell module in the application
Makefile: DISABLE_MODULE += test_utils_interactive_sync_shell.
Automated Tests Guidelines
When using pexpect$ is useless for matching the end of a line, instead use
\r\n(pexpect end-of-line).
Beware of + and * at the end of patterns. These patterns will always get
a minimal match (non-greedy).(pexpect end-of-patterns)
This can be an issue when matching groups and using the matched groups to verify
some kind of behavior since * could return an empty match and + only a subset.
This is especially prevalent since printf() is buffered so the output might not
arrive in a single read to pexpect.
To avoid this make sure to match a non-ambiguous character at the end of the
pattern like \r\n, \s, \), etc..
don't:
child.expect(r'some string: (\d+)')
do:
child.expect(r'some string: (\d+)\r\n')
child.expect(r'some string: (\d+)\s')
child.expect(r'some string: (\d+) ,')
Use expect() instead of assert()
In order to make a test application functional in all cases, use expect()
instead of assert(). The former works like the latter, but will still be
compiled in if NDEBUG is defined. This is useful to keep a test application
working even when compiling with -DNDEBUG, allowing for the code-under-test to
be compiled with that flag. Otherwise, the application would force compiling
all tested code with assertions enabled.
expect() is defined in the header test_utils/expect.h.
Interaction through the uart
Tests implemented with testrunner use the cleanterm target that
provides an interaction without adding extra text output or input handling.
It can currently be expected to have unmodified line based interaction with the
board.
The expected behavior is verified with the test in tests/test_tools.
Tests cannot rely on having on all boards and terminal programs:
unbuffered input
allowing sending special characters like ctrl+c/ctrl+d
0fb6a09598