Since cpu retention dma use rc fast as clk source, so rc_fast_digi
will be enabled when we config to pd cpu. And cpu retention does not
need rc fast keep on during light sleep. So, if we use rc_fast_digi
to determine whether rc fast can be powered down, then cpu and and
rc fast cannot pd at the same time.
As heap block may be allocated into multiple non-continuous chunks, to
reserve enough memory for dma/internal usage, we do the malloc in the
step of max available block.
Some users have requested this feature.
In order to avoid complete refactoring or introducing more code complexity, a design choice to create temporary files without blank lines is made.
Additionally, an extension check is added and there are multiple smaller code style and structure improvements.
Closes https://github.com/espressif/esp-idf/issues/8421
When working in continuous mode, hardware will continuously trigger
ADC to do conversions. On esp32s2, 2 bytes will be generated per
conversion. Prior to this commit, driver assumes 4 bytes per conversion
(on s2). This commit fixed this issue.
Prior to this change, esp32s3 ADC continuous mode output resolution is 13 bits.
This commit correct the `adc_digi_output_data_t` on esp32s3. Correct
output bits should be 12 bits. Corresponding definition in `soc_caps.h`
is also updated.
Was: Backtrace: N:M N:M N:M ...
Now: Backtrace:N:MN:M N:M ...
The problem with the new format is that it is hard to parse and
breaks the parser that is used by PlatformIO. The old format
is much more reasonable. I do not see how the pattern in IDFDUT.py
can work with the new format, due to the missing space after the :
The "FreeRTOS Event Groups" main task will only wait a single tick for the created
tasks to set their response bits. This short delay may not be sufficent if the tick
frequency is high.
This commit updates the test so that
- the main task waits indefinitely for all the response bits to be set.
- created tasks are cleand up by the main task
FreeRTOS synchronization primitives (e.g., queues, eventgroups) use various event lists (i.e., task lists) to track what
tasks are blocked on a current primitive. Usually these event lists are accessed via one of the event lists functions
(such as vTask[PlaceOn|RemoveFrom]UnorderedEventList()), which in turn ensure that the global task list spinlock
(xTaskQueueMutex) is taken when accessing these lists.
However, some functions in event_groups.c manually traverse their event lists. Thus if a tick interrupt occurs on
another core during traversal and that tick interrupt unblocks a task on the event list being traversed, the event list
will be corrupted.
This commit modifies the following event_groups.c functions so that they take the global task list lock before
traversing their event list.
- xEventGroupSetBits()
- vEventGroupDelete()