17810: drivers/slipdev: implement sleep states r=benpicco a=benpicco
18348: sys/net/gnrc/pktbuf_static: make use of alignas() r=maribu a=maribu
### Contribution description
Since we are now using C11, we can make use of `alignas()` provided by `<stdalign.h>` to make the alignment code easier to read.
### Testing procedure
I didn't expect this to change binaries, but is safes 4 bytes. `elf_diff` shows that the compiler (at least GCC 11.3.0) was not able to detect that `gnrc_pktbuf_static_buf` was just an alias for `_pktbuf_buf`. That makes sense since it would be hard without LTO to rule out external writes to `gnrc_pktbuf_static_buf`, unless one would have added a `const` (to the pointer, not to the data the pointer points to).
The [output of `elf_diff`](https://mari-bu.de/pr_18348_gnrc_pktbuf_static_elf_diff.html) looks otherwise quite unscary.
Also:
```
$ make BOARD=nucleo-f767zi -C tests/unittests/ tests-pktbuf flash test
make: Entering directory '/home/maribu/Repos/software/RIOT/tests/unittests'
Building application "tests_unittests" for "nucleo-f767zi" with MCU "stm32".
[...]
Welcome to pyterm!
Type '/exit' to exit.
READY
s
START
.............................................
OK (45 tests)
make: Leaving directory '/home/maribu/Repos/software/RIOT/tests/unittests'
```
### Issues/PRs references
None
19120: CI: seperate check-labels and check-commits workflows r=maribu a=kaspar030
Co-authored-by: Benjamin Valentin <benjamin.valentin@ml-pa.com>
Co-authored-by: Marian Buschsieweke <marian.buschsieweke@ovgu.de>
Co-authored-by: Kaspar Schleiser <kaspar@schleiser.de>
19106: core/lib: Add macros/utils.h header r=aabadie a=maribu
### Contribution description
The macros CONCAT(), MIN(), and MAX() are defined over and over again in RIOT's code base. This de-duplicates the code by moving the macros to a common place.
### Testing procedure
Generated binaries don't change, as this only a de-duplication of macros that doesn't change their definition.
### Issues/PRs references
None
Co-authored-by: Marian Buschsieweke <marian.buschsieweke@ovgu.de>
The macros CONCAT(), MIN(), and MAX() are defined over and over again in
RIOT's code base. This de-duplicates the code by moving the macros to a
common place.
18752: nanocoap_sock: deprecate nanocoap_get() r=benpicco a=benpicco
19100: cpu/esp_common: allow configuration of UART0 r=benpicco a=gschorcht
### Contribution description
This PR
- fixes the issue for ESP32 SoCs that UART0 signals can't be routed to arbitrary GPIOs and
- allows the configuration of the UART device used by the bootloader.
The UART interface and its configuration used by the STDIO are defined in RIOT using the define `STDIO_UART_DEV` and the configuration of the corresponding UART device in `periph_conf.h`.
However, the bootloader compiled directly in ESP-IDF uses its own definitions `CONFIG_ESP_CONSOLE_UART_*` for the UART configuration. To be able to use a consistent UART configuration in RIOT and the bootloader, e.g. to see the output of the 2nd stage bootloader, these `CONFIG_ESP_CONSOLE_UART_*` can be defined via a set of KConfig variables in RIOT (not yet implemented in Kconfig):
- `CONSOLE_CONFIG_UART_NUM` defines the UART device to be used by the bootloader and by `STDIO_UART_DEV`
- `CONSOLE_CONFIG_UART_RX` and `CONSOLE_CONFIG_UART_TX` define the GPIOs to be used by the bootloader and should be the GPIOs as defined in `periph_conf.h` for the corresponding UART device.
### Testing procedure
Any ESP32 node should still work with `stdio_uart` and the default configuration. To test an alternative configuration, use
```
CFLAGS='-DUART1_TXD=5 -DUART1_RXD=4 -DCONFIG_CONSOLE_UART_NUM=1 -DCONFIG_CONSOLE_UART_TX=5 -DCONFIG_CONSOLE_UART_RX=4' USEMODULE=esp_log_startup BOARD=esp32-wroom-32 make -C tests/shell flash
```
The bootloader output and the STDIO should be routed to UART1 at GPIO4 and GPIO5.
### Issues/PRs references
Prerequisite for PR ##18863
19104: tests/periph_uart: only exclude STDIO_UART_DEV if stdio_uart is used r=benpicco a=benpicco
Co-authored-by: Benjamin Valentin <benjamin.valentin@ml-pa.com>
Co-authored-by: Gunar Schorcht <gunar@schorcht.net>
Co-authored-by: Benjamin Valentin <benjamin.valentin@bht-berlin.de>
18773: nanocoap_sock: fix handling empty ACKs with separate response r=maribu a=benpicco
Co-authored-by: Benjamin Valentin <benjamin.valentin@ml-pa.com>
Co-authored-by: Benjamin Valentin <benjamin.valentin@bht-berlin.de>
19037: sys/usb, pkg/tinyusb: move USB board reset from highlevel STDIO to CDC ACM r=dylad a=gschorcht
### Contribution description
The USB board reset function `usb_board_reset_coding_cb` can be used on any CDC-ACM interface, even if the CDC ACM interface is not used as high-level STDIO. Therefore, this PR provides the following changes:
- The call of the board reset function `usb_board_reset_coding_cb` from USBUS stack has been moved from the STDIO CDC ACM implementation to the CDC ACM implementation and is thus a feature of any USBUS CDC ACM interface which does not necessarily have to be used as highlevel STDIO.
- The call of the board reset function `usb_board_reset_coding_cb` from tinyUSB stack been moved from module `tinyusb_stdio_cdc_acm` to module `tinyusb_contrib` and is compiled in if the `tinyusb_class_cdc` module is used together the `tinyusb_device` module. Thus, it is now a feature of the tinyUSB CDC ACM interface, which does not necessarily have to be used as highlevel STDIO.
- The `usb_board_reset` module defines the `usb_board_reset_in_bootloader` function as a weak symbol to be used when reset in bootloader if no real implementation of this function is compiled in and the `riotboot_reset` module is not used. It only prints an error message that the reset in bootloader is not supported. This is necessary if the module `usb_board_reset` is used to be able to restart the board with an application via a USB CDC ACM interface, but the board's bootloader does not support the reset in bootloader feature.
- A test application has been added that either uses the highlevel STDIO `stdio_acm_cdc` or creates a CDC-ACM interface to enable board resets via USB. If the `usbus_dfu` module is used, it also initializes the DFU interface to be able to work together with the `riotboot_dfu` bootloader.
### Testing procedure
1. Use a board with a bootloader that supports the reset in bootloader via USB, but don't use the highlevel STDIO to check that it works with `usbus_cdc_acm`, for example:
```python
USEMODULE=stdio_uart BOARD=arduino-mkr1000 make -C tests/usb_board_reset flash
```
After reset in application with command
```python
stty -F /dev/ttyACM0 raw ispeed 600 ospeed 600 cs8 -cstopb ignpar eol 255 eof 255
```
command `dmesg` should give an output like the following with RIOT's test VID/PID:
```python
dmesg
[1745182.057403] usb 1-4.1.2: new full-speed USB device number 69 using xhci_hcd
[1745182.160386] usb 1-4.1.2: New USB device found, idVendor=1209, idProduct=7d01, bcdDevice= 1.00
[1745182.160390] usb 1-4.1.2: New USB device strings: Mfr=3, Product=2, SerialNumber=4
[1745182.160392] usb 1-4.1.2: Product: arduino-mkr1000
[1745182.160393] usb 1-4.1.2: Manufacturer: RIOT-os.org
[1745182.160395] usb 1-4.1.2: SerialNumber: 6B6C2CA5229020D8
[1745182.170982] cdc_acm 1-4.1.2:1.0: ttyACM0: USB ACM device
```
After reset in bootloader with command
```python
stty -F /dev/ttyACM0 raw ispeed 1200 ospeed 1200 cs8 -cstopb ignpar eol 255 eof 255
```
command `dmesg` should give an output like the following with vendor VID/PID:
```python
[1746220.443792] usb 1-4.1.2: new full-speed USB device number 70 using xhci_hcd
[1746220.544705] usb 1-4.1.2: New USB device found, idVendor=2341, idProduct=024e, bcdDevice= 2.00
[1746220.544708] usb 1-4.1.2: New USB device strings: Mfr=0, Product=0, SerialNumber=0
[1746220.553471] cdc_acm 1-4.1.2:1.0: ttyACM0: USB ACM device
```
2. Test the same as in 1., but this time use the highlevel STDIO to check that there is no regression and it still works with `stdio_cdc_acm`, for example:
```python
BOARD=arduino-mkr1000 make -C tests/usb_board_reset flash
```
3. Use a board that supports `riotboot_dfu` but doesn't use the highlevel STDIO and flash the `riotboot_dfu` bootloader, for example:
```python
BOARD=stm32f429i-disc1 make -C bootloaders/riotboot_dfu flash term
```
Once the bootloader is flashed, command `dfu-util --list` should give something like the following:
```python
Found DFU: [1209:7d02] ver=0100, devnum=14, cfg=1, intf=0, path="1-2", alt=1, name="RIOT-OS Slot 1", serial="6591620BCB270283"
Found DFU: [1209:7d02] ver=0100, devnum=14, cfg=1, intf=0, path="1-2", alt=0, name="RIOT-OS Slot 0", serial="6591620BCB270283"
```
If the output gives only
```python
Found Runtime: [1209:7d00] ver=0100, devnum=123, cfg=1, intf=0, path="1-2", alt=0, name="RIOT-OS bootloader", serial="6591620BCB270283"
```
an application is already running in DFU Runtime mode. Use `dfu-util -e` to restart it in bootloader DFU mode.
Then flash the test application, for example:
```python
FEATURES_REQUIRED=riotboot USEMODULE='usbus_dfu riotboot_reset' \
BOARD=stm32f429i-disc1 make -C tests/usbus_board_reset PROGRAMMER=dfu-util riotboot/flash-slot0
```
Once the test application is flashed, command `dfu-util --list` should give:
```python
Found Runtime: [1209:7d00] ver=0100, devnum=123, cfg=1, intf=0, path="1-2", alt=0, name="RIOT-OS bootloader", serial="6591620BCB270283"
```
Now, use command
```python
stty -F /dev/ttyACM1 raw ispeed 600 ospeed 600 cs8 -cstopb ignpar eol 255 eof 255
```
to restart the board in application. Command `dfu-util --list` should give again the following:
```python
Found Runtime: [1209:7d00] ver=0100, devnum=123, cfg=1, intf=0, path="1-2", alt=0, name="RIOT-OS bootloader", serial="6591620BCB270283"
```
That is, the application is running in DFU Runtime mode. Then use command
```python
stty -F /dev/ttyACM1 raw ispeed 1200 ospeed 1200 cs8 -cstopb ignpar eol 255 eof 255
```
to restart the board in bootloader DFU mode. Command `dfu-util --list` should now give the following:
```python
Found DFU: [1209:7d02] ver=0100, devnum=50, cfg=1, intf=0, path="1-2", alt=1, name="RIOT-OS Slot 1", serial="7D156425A950A8EB"
Found DFU: [1209:7d02] ver=0100, devnum=50, cfg=1, intf=0, path="1-2", alt=0, name="RIOT-OS Slot 0", serial="7D156425A950A8EB"
```
That is, the bootloader is in DFU mode and another application can be flash.
4. After a hard reset of the board under 3., try the commands `reboot` and `bootloader`.
5. To check the same for tinyUSB, use the existing tinyUSB application with a CDC ACM interface and add module `usb_board_reset`, for example:
```python
USEMODULE=usb_board_reset BOARD=stm32f429i-disc1 make -C tests/pkg_tinyusb_cdc_msc flash term
```
After flashing, it should be possible to restart the application with command:
```python
stty -F /dev/ttyACM1 raw ispeed 600 ospeed 600 cs8 -cstopb ignpar eol 255 eof 255
```
When using command
```python
stty -F /dev/ttyACM1 raw ispeed 1200 ospeed 1200 cs8 -cstopb ignpar eol 255 eof 255
```
the following error message should be shown in terminal
```python
[cdc-acm] reset in bootloader is not supported
```
### Issues/PRs references
Co-authored-by: Gunar Schorcht <gunar@schorcht.net>
The board reset function can be used on any CDC ACM interface. It is not necessary that the tinyUSB CDC ACM STDIO is used. Therefore, the board reset function is now a feature of the CDC ACM interface that don't require any other functionality.
Definition of a function as weak symbol for reset in bootloader which prints an error message if no real implementation is compiled in and
the module `riotboot_reset` is not used. This is required if the module `usb_board_reset` is used to restart the board with an application via an USB CDC ACM interface, but the board's bootloader does not support a reset in the bootloader.
The board reset function `usb_board_reset_coding_cb` can be used on any CDC ACM interface. It is not necessary that the highlevel STDIO is used. Therefore, the call of the board reset function `usb_board_reset_coding_cb` has been moved from the USBUS STDIO CDC ACM implementation to USBUS CDC ACM implementation and is thus a feature of the USBUS CDC ACM interface that don't require any other functionality.
In `dac_util_map(...)` the expression `((value - min) * UINT16_MAX)` was
cast to a 16 bit unsigned, then divided by `(max - min)`. This means
that anytime `(value - min) != 0` the numerator was truncated prior to
being divided and then returned.
This patch modifies the expression so that the downcast to 16 bits is
performed as the last operation.
STM32F2/4/7 MCUs use sectors instead of pages, where the minimum sector size is defined by FLASHPAGE_MIN_SECTOR_SIZE, which is 16KB or 32KB (the first sector) depending on the CPU_MODEL. In this case SLOT0_OFFSET must be a multiple of the minimum sector size to cover a whole sector.
