lpc23xx has 3 sleep modes and one idle mode.
`PM_NUM_MODES` must only count the idle modes.
In practise, this makes no difference since `mode 3` (IDLE) is
the `default` case in `pm_set()` anyway.
The lpc23xx MCU has up to three I2C interfaces.
This adds a driver for it.
The peripheral works in interrupt mode, each change of the state machine
will generate an interrupt.
The response to the states are laid out in the data sheet.
This replaces the old driver that was removed in c560e28eb6
The function would always return `true` after early boot, so it
is not very useful for applications.
Now it will only (but always) return true when we woke from Deep Sleep
*after* early boot. This makes it behave the same ways as the function
of the same name on SAME54.
Rename the existing function to cpu_backup_ram_is_initialized() to better
match it's semantics.
Both architectures are variants of the ARM architecture and use the same
toolchain.
There is no reason to have such wildly different defaults.
This results in some tests passing that would crash before:
- [x] `tests/pkg_libcose`
- [x] `tests/pkg_qdsa`
- [x] `tests/pkg_relic`
- [x] `tests/pkg_tweetnacl`
- [x] `tests/pthread_tls`
`THREAD_EXTRA_STACKSIZE_PRINTF_FLOAT` is not used anywhere in RIOT
anymore, so just drop it.
lpc23xx has 2k of battery RAM that is retained in Deep Power Down mode.
To not overwrite that data it must only be initialized on Power On Reset.
However, RSIR looks the same when waking up from Deep Power Down as it does
on the power-on case.
So use 4 bytes of the backup RAM to keep a signature that is only valid if
memory was retained (no power-on Reset).
A small change to the linker script is required so two sections can be
placed into flash.
The 10 bit DAC on the lpc23xx is very simple.
It only has one channel and can only be mapped to a single pin (P0.26).
After setting the pin mode to DAC no further configuration in needed.
puf_sram only relies on an uninitialized chunk of memory.
This means to enable it we just have to hook up puf_sram_init().
All memory after __bss_end should be uninitialized at startup, so
just use that.
Enable IDLE and Deep Powerdown mode.
IDLE is pretty straightforward - insteady of busy waiting, the CPU will
enter an idle state from which it will resume on any event.
Deep Power Down shuts off the entite system except for the battery backup
power domain.
That means the CPU will reset on resume and can be woken by e.g. RTC.
SLEEP and POWERDOWN disable the PLL and the PLL and Flash respectively.
This requires some proper wake-up handling.
Since this turned out to be a major time sink and those modes are never
currently never used in RIOT outside of tests, I left this as an exercise
for a future reader.
This converts the hard-coded UART driver to the new ways.
- allow the board to configure the RX & TX pins
- allow for more than one UART
- allow setting the baudrate
- implement poweron()/poweroff() functions
Currently the cpu/lpc2387 init code hard-codes a 16 MHz
external oscillator.
Instead, calculate the PLL multiplier based on the board define
and also allow to run without an external oscillator.
At the time of configuration, the pthread-reaper uses '164' bytes of
stack when 'idle' stack is only '160'. By having double it gives some
margin.
ps
pid | name | state Q | pri | stack ( used) | base addr | current
1 | idle | pending Q | 15 | 160 ( 128) | 0x4000007c | 0x4000009c
2 | main | running Q | 7 | 2560 ( 1232) | 0x4000011c | 0x4000095c
3 | pthread-reaper | bl rx _ | 0 | 320 ( 164) | 0x40000bac | 0x40000c48
| SUM | | | 3040 ( 1524)
- Fixed documentation
- Use bitwise operation instead of multiplication and addition in `GPIO_PIN()`
- Allow GPIOs to be configured as input via `gpio_init()`
- Fixed bugs in `gpio_init_mux`:
- `0x01 << ((pin & 31) * 2)` was used before to generate the bitmask, but
this would shift by 62 to the left. Correct is `0x01 << ((pin & 15) * 2)`
(See [datasheet](https://www.nxp.com/docs/en/user-guide/UM10211.pdf) at
pages 156ff)
- Only one of the two bits was cleared previously
- Changed strategy to access GPIO pins:
- Previous strategy:
- Set all bits in FIOMASK except the one for the pin to control to
disable access to them
- Set/clear/read all pins in the target GPIO port (but access to all but
the target pin is ignored because of the applied FIOMASK)
- New strategy:
- Set/clear/read only the target pin
- Advantages:
- Only one access to a GPIO register instead of two
- Proven approach: Access to GPIOs on lpc2387 is mostly done by
accessing the GPIO registers directy (e.g. see the sht11 driver).
Those accesses never touch the FIOMASK register
- No unwanted side effects: Disabling all but one pin in a GPIO port
without undoing that seems not to be a good idea
- removed ISR_STACKSIZE define where unused (set to 0)
- removed thread_arch_isr_stack_usage(), thread_arch_isr_stack_start(),
and/or thread_arch_isr_stack_pointer() where not implemented
