flipperzero-firmware/wiki/fw/api/SPI-Devices-API.md
coreglitch 942bbfaefe
Core api concept (#144)
* add input debounce code from old fw

* exampl of input api

* change input API to get/release

* revert input API to read

* pointer instead of instance

* add input API description

* add display API

* rewrite display names

* migrate to valuemanager

* add LED API

* add closing brakets

* add sound api

* fix led api

* basic api

* rename API pages

* change pubsub implementation

* move FURI AC -> flapp, add valuemutex example, add valuemanager implementation

* pubsub usage example

* user led example

* update example

* simplify input

* add composed display

* add SPI/GPIO and CC1101 bus

* change cc1101 api

* spi api and devices

* spi api and devices

* move SPI to page, add GPIO

* not block pin open

* backlight API and more

* add minunit tests

* fix logging

* ignore unexisting time service on embedded targets

* fix warning, issue with printf

* Deprecate furi_open and furi_close (#167)

Rename existing furi_open and furi_close to deprecated version

* add exitcode

* migrate to printf

* indicate test by leds

* add testing description

* rename furi.h

* wip basic api

* add valuemutex, pubsub, split files

* add value expanders

* value mutex realization and tests

* valuemutex test added to makefile

* do not build unimplemented files

* fix build furmware target f2

* redesigned minunit tests to allow testing in separate files

* test file for valuemutex minunit testing

* minunit partial test valuemutex

* local cmsis_os2 mutex bindings

* implement furi open/create, tests

* migrate concurrent_access to ValueMutex

* add spi header

* Lib: add mlib submodule.

Co-authored-by: rusdacent <rusdacentx0x08@gmail.com>
Co-authored-by: DrZlo13 <who.just.the.doctor@gmail.com>
2020-10-13 11:22:43 +03:00

130 lines
3.3 KiB
Markdown

# SPI
HAL struct `SPI_HandleTypeDef*` used for handling SPI info.
For transmit/receive data use `spi_xfer` function:
```C
bool spi_xfer(
SPI_HandleTypeDef* spi,
uint8_t* tx_data, uint8_t* rx_data, size_t len,
PubSubCallback cb, void* ctx);
```
* `tx_data` and `rx_data` size must be equal (and equal `len`)
* `cb` called after spi operation is completed, `(NULL, ctx)` passed to callback.
Blocking verison:
```C
inline static bool spi_xfer_block(SPI_HandleTypeDef* spi, uint8_t* tx_data, uint8_t* rx_data, size_t len) {
semaphoreInfo s;
osSemaphore block = createSemaphoreStatic(s);
if(!spi_xfer(spi, tx_data, rx_data, len, RELEASE_SEMAPHORE, (void*)block)) {
osReleaseSemaphore(block);
return false;
}
osWaitSemaphore(block);
return false;
}
```
## SPI Bus
Common implementation of SPI bus: serial interface + CS pin
```C
typedef struct {
GpioPin* cs; ///< CS pin
ValueMutex* spi; ///< <SPI_HandleTypeDef*>
} SpiBus;
```
## SPI device
For dedicated work with one device there is `SpiDevice` entity. It contains ValueMutex around SpiBus: after you acquire device you can acquire spi to work with it (don't forget SPI bus is shared around many device, release it after every transaction as quick as possible).
```C
typedef struct {
ValueMutex* bus; ///< <SpiBus*>
} SpiDevice;
```
## SPI IRQ device
Many devices (like CC1101 and NFC) present as SPI bus and IRQ line. For work with it there is special entity `SpiIrqDevice`. Use `subscribe_pubsub` for subscribinq to irq events.
```C
typedef struct {
ValueMutex* bus; ///< <SpiBus*>
PubSub* irq;
} SpiIrqDevice;
```
## Display device
Special implementation of SPI bus: serial interface + CS, Res, D/I lines.
```C
typedef struct {
GpioPin* cs; ///< CS pin
GpioPin* res; ///< reset pin
GpioPin* di; ///< D/I pin
ValueMutex* spi; ///< <SPI_HandleTypeDef*>
} DisplayBus;
```C
typedef struct {
ValueMutex* bus; ///< <DisplayBus*>
} DisplayDevice;
```
# SPI devices (F2)
* `/dev/sdcard` - SD card SPI, `SpiDevice`
* `/dev/cc1101_bus` - Sub-GHz radio (CC1101), `SpiIrqDevice`
* `/dev/nfc` - NFC (ST25R3916), `SpiIrqDevice`
* `/dev/display` - `DisplayDevice`
* `/dev/spiext` - External SPI (warning! Lock PA4, PA5, PA6, PA7)
### Application example
```C
// Be careful, this function called from IRQ context
void handle_irq(void* _arg, void* _ctx) {
}
void cc1101_example() {
SpiIrqDevice* cc1101_device = open_input("/dev/cc1101_bus");
if(cc1101_device == NULL) return; // bus not available, critical error
subscribe_pubsub(cc1101_device->irq, handle_irq, NULL);
{
// acquire device as device bus
SpiBus* spi_bus = acquire_mutex(cc1101_device->bus, 0);
if(spi_bus == NULL) {
printf("Device busy\n");
// wait for device
spi_bus = acquire_mutex_block(cc1101_device->bus);
}
// make transaction
uint8_t request[4] = {0xDE, 0xAD, 0xBE, 0xEF};
uint8_t response[4];
{
SPI_HandleTypeDef* spi = acquire_mutex_block(spi_bus->spi);
gpio_write(spi_bus->cs, false);
spi_xfer_block(spi, request, response, 4);
gpio_write(spi_bus->cs, true);
release_mutex(cc1101_device->spi, spi);
}
// release device (device bus)
release_mutex(cc1101_device->bus, spi_bus);
}
}
```