This is a defensive change to make the transceiver code easier to reason
about, and to avoid the possibility of races such as that seen in #1042.
Previously, set_transceiver_mode() was called in the vendor request
handler for the SET_TRANSCEIVER_MODE request, as well in the callback
for a USB configuration change. Both these calls are made from the USB0
ISR, so could interrupt the rx_mode(), tx_mode() and sweep_mode()
functions at any point. It was hard to tell if this was safe.
Instead, set_transceiver_mode() has been removed, and its work is split
into three parts:
- request_transceiver_mode(), which is safe to call from ISR context.
All this function does is update the requested mode and increment a
sequence number. This builds on work already done in PR #1029, but
the interface has been simplified to use a shared volatile structure.
- transceiver_startup(), which transitions the transceiver from an idle
state to the configuration required for a specific mode, including
setting up the RF path, configuring the M0, adjusting LEDs and UI etc.
- transceiver_shutdown(), which transitions the transceiver back to an
idle state.
The *_mode() functions that implement the transceiver modes now call
transceiver_startup() before starting work, and transceiver_shutdown()
before returning, and all this happens in the main thread of execution.
As such, it is now guaranteed that all the steps involved happen in a
consistent order, with the transceiver starting from an idle state, and
being returned to an idle state before control returns to the main loop.
For consistency of interface, an off_mode() function has been added to
implement the behaviour of the OFF transceiver mode. Since the
transceiver is already guaranteed to be in an idle state when this is
called, the only work required is to set the UI mode and wait for a new
mode request.
This fixes bug #1042, which occured when an RX->OFF->RX sequence
happened quickly enough that the loop in rx_mode() did not see the
change. As a result, the enable_baseband_streaming() call at the start
of that function was not repeated for the new RX operation, so RX
progress stalled.
To solve this, the vendor request handler now increments a sequence
number when it changes the transceiver mode. Instead of the RX loop
checking whether the transceiver mode is still RX, it now checks whether
the current sequence number is the same as when it was started. If not,
there must have been at least one mode change, so the loop exits, and
the main loop starts the necessary loop for the new mode. The same
behaviour is implemented for the TX and sweep loops.
For this approach to be reliable, we must ensure that when deciding
which mode and sequence number to use, we take both values from the same
set_transceiver_mode request.
To achieve this, we briefly disable the USB0 interrupt to stop the
vendor request handler from running whilst reading the mode and sequence
number together. Then the loop dispatch proceeds using those pre-read
values.
These variables are already placed together; this commit just groups
them into a struct and declares this in a new header.
This commit should not result in any change to the firmware binary.
Only the names of symbols are changed.
Previously, a USB vendor request could interrupt in the middle of
set_freq and make conflicting changes, leaving the HackRF in an
undefined state.
fixes#772
