This is to solve a potential problem while feeding to printer's drive gears - while disengaging the Idler, the Pulley was still rotating to avoid grinding the filament (printer is pulling it).
Other filaments could have moved a bit when the Idler's bearings ran over them while the Pulley was still rotating slowly -> the filament could have been moved into the Selector's path causing trouble (especially when not used in the print).
Therefore, the Idler disengages partially now - moves into an intermediate position between the slots.
Then, the Pulley is completely stopped and after that the Idler does a full disengage like before.
Substitute documentation to reference AvrGcc by default, which locks gcc
to the dependency folder.
AnyAvrGcc is inteded to use any system/external gcc version (as the name
implies).
Remove fixed version in AnyAvrGcc.cmake
Update build.py to use current avr-gcc version defined in bootstrap.py
Attempt to change MM-control-01.hex to MMU2SR-<project version> like in buddy releases
We cannot get a constexpr definition of the register addresses, and any
reinterpret cast is currently illegal for a constexpr in c++17.
Change the SPI0, TIFR and TIMSK to volatile const pointers instead.
SPI0 has volatile members instead of marking the entire struct as
volatile, which is probably not a good idea as it technically drops the
volatile from the original pointer.
It looks like we don't have to reset the whole ToolChange state machine when resolving an error with the middle button (Retry) - but jump straight into the feeding phase.
The reasons are multiple:
- If an error happens during the unload phase, it is handled separately in the UnloadFilament state machine
- If an error happens during the feeding phase, the unload has been already successfully completed.
And when restarted from the very beginning, the ToolChange does the last retract sequence from the UnloadFilament phase
-> that is not healthy, because the filament gets pushed away from the Pulley and causes another error.
Sets the UI module into a mode when the printer is in charge of processing the buttons (from all sources).
That means the MMU will detect its buttons but it will not react upon them.
This mode is important for error recovery when the printer needs to do some stuff before the MMU (like preheating the nozzle).
It looks we have some kind of leak when filament sensor state is not completely coherent with FINDA state.
This is yet to be discovered and fixed with some unit tests.
If the MMU receives a command LoadFilament with a slot number SL we reject
the command to avoid moving the selector (effectively cutting the piece of filament present in FINDA).
That includes the scenario when the selector is standing at the very same slot SL, because the filament could be held by the printer (i.e. loaded in the nozzle).
There is one special case though - same slot AND filament load state == InSelector (it MUST NOT be anywhere farther)
Using U_mm inside a compilation unit will force the compiler to generate
a runtime copy of the function, and we don't want that.
But there seems also to be an optimization problem with gcc <= 7.x where
even when declaring an inline function constexpr, if called enough
times, the compiler will choose _not_ to evaluate the function at
compile time and thus avoid our compile-time float->integer
conversions...
For this reason, split the body of the function in two parts: the actual
function that uses AxisUnits at runtime for calling motion.PlanMove, and
a wrapper that forces the conversion. By marking this function as
always_inline, the body is correctly evaluated at compile time at each
call site.
It turned out FINDA needs running timer to perform BlockingInit() correctly.
Therefore setup() was split into setup() (no IRQ) and setup2() (IRQ enabled).
Then, finally, the check for FINDA state became reliable upon start of the FW.
D.R.racer
Alex Voinea
3d-gussner
Yuri D'Elia
VintagePC