This is a minor optimisation to the mcr20a-rf-driver code:
Note that function parameter is pointer. The code is more readable when 'NULL' instead of using '0'.
When dealing with EEPROMs without a 16 bit adressing, the current
implementation does not work, as it writes a 16 bit address to the chip.
This may cause undefined behaviour.
This change adds a new constructor argument to enable this new eight-bit
mode. It defaults to false to not break existing code.
This constructor argument should actually never be necessary to manually
set, except when dealing with cheap devices.
This is a minor optimisation to the mcr20a-rf-driver code:
1. The function parameter is 'uint8_t *byteArray', (byteArray == NULL) instead of using (byteArray == 0). The code is more readable.
When reading a data block, the returned error codes from the I2C subsystem
are different from normal single byte operations. We have to verify that
the read-function for multiple bytes does return zero, because it
returns "readBytes != expectedLength".
Additionally, sync before trying to read from the eeprom as slow devices
may not yet be ready to return data, especially with low-priced ones
used with fast controllers.
At these locations, psa_key_attribute variables are used without
initialisation. The function getting it (psa_get_key_attributes),
is freeing attributes->domain_parameters, which can contain random
address from the stack.
Signed-off-by: Gabor Abonyi <gabor.abonyi@arm.com>
This is a special case since targets do not provide by default GPIO pin-maps.
This extension is required for FPGA GPIO tests - if some pins have limitations (e.g. fixed pull-up) we need to skip these pins while testing.
To do that we were adding a dummy pin-map with commented out pins that can't be tested because of the limitations.
This solution is redundant and the proposition is to provide a list of restricted gpio pins if required (by default weak implementation is provided with an empty list).
This mechanism will be backward compatible, so the old method with dummy gpio pinmap will also work. The switch from dummy pin-maps to pinmap_gpio_restricted_pins() will be performed in separate commits/PRs.
Substantiation for this is that the STDIO UART peripheral is used by Mbed, so it should never be tested.
Also solve the potential problem with accidenty skipped peripherals in FPGA testing. Currently, we have a one `pinmap_restricted_peripherals()` function for all interfaces (UART, I2C, SPI, etc.).
The problem can be encountered if different interfaces have the same peripheral ids (e.g. `UART_0` = 0, `SPI_0` = 0). In this case, if `UART_0` is on the restricted list, then SPI tests will be also skipped for `SPI_0`.
The good news is that usually, the peripheral ids are the base addresses of the peripheral's register set, but we can't rely on this. It is also good that `pinmap_restricted_peripherals()` at this moment is only required for STDIO UART (Nuvoton and STM).
To solve this issue we will change name of `pinmap_restricted_peripherals()` to `pinmap_uart_restricted_peripherals()`, make STDIO UART restricted by default for all targets and update FPGA test utilily functions to use `pinmap_uart_restricted_peripherals()` to skip only uart peripherals.
In the future if needed we can consider to add support to restrict peripherals of other interfaces(SPI, I2C, etc).
Martin Kojtal
Veijo Pesonen
Anna Bridge
Arto Kinnunen
Stephan Brunner
David Lin
jeromecoutant
Przemyslaw Stekiel
Gabor Abonyi