flipperzero-firmware/core/api-basic/valuemutex.h

#pragma once

#include "flipper.h"

/*
== ValueMutex ==

The most simple concept is ValueMutex.
It is wrapper around mutex and value pointer.
You can take and give mutex to work with value and read and write value.
*/

typedef struct {
    void* value;
    size_t size;
    osMutexId_t mutex;
} ValueMutex;

/*
Creates ValueMutex.
*/
bool init_mutex(ValueMutex* valuemutex, void* value, size_t size);

/*
Call for work with data stored in mutex.
Returns pointer to data if success, NULL otherwise.
*/
void* acquire_mutex(ValueMutex* valuemutex, uint32_t timeout);

/*
Helper: infinitly wait for mutex
*/
static inline void* acquire_mutex_block(ValueMutex* valuemutex) {
    return acquire_mutex(valuemutex, osWaitForever);
}

/*
Release mutex after end of work with data.
Call `release_mutex` and pass ValueData instance and pointer to data.
*/
bool release_mutex(ValueMutex* valuemutex, void* value);

/*
Instead of take-access-give sequence you can use `read_mutex` and `write_mutex` functions.
Both functions return true in case of success, false otherwise.
*/
bool read_mutex(ValueMutex* valuemutex, void* data, size_t len, uint32_t timeout);

bool write_mutex(ValueMutex* valuemutex, void* data, size_t len, uint32_t timeout);

inline static bool write_mutex_block(ValueMutex* valuemutex, void* data, size_t len) {
    return write_mutex(valuemutex, data, len, osWaitForever);
}

inline static bool read_mutex_block(ValueMutex* valuemutex, void* data, size_t len) {
    return read_mutex(valuemutex, data, len, osWaitForever);
}

/*

Usage example

```C
// MANIFEST
// name="example-provider-app"
// stack=128

void provider_app(void* _p) {
    // create record with mutex
    uint32_t example_value = 0;
    ValueMutex example_mutex;
    // call `init_mutex`.
    if(!init_mutex(&example_mutex, (void*)&example_value, sizeof(uint32_t))) {
        printf("critical error\n");
        flapp_exit(NULL);
    }

    if(furi_create("provider/example", (void*)&example_mutex)) {
        printf("critical error\n");
        flapp_exit(NULL);
    }

    // we are ready to provide record to other apps
    flapp_ready();

    // get value and increment it
    while(1) {
        uint32_t* value = acquire_mutex(&example_mutex, OsWaitForever);
        if(value != NULL) {
            value++;
        }
        release_mutex(&example_mutex, value);

        osDelay(100);
    }
}

// MANIFEST
// name="example-consumer-app"
// stack=128
// require="example-provider-app"
void consumer_app(void* _p) {
    // this app run after flapp_ready call in all requirements app

    // open mutex value
    ValueMutex* counter_mutex = furi_open("provider/example");
    if(counter_mutex == NULL) {
        printf("critical error\n");
        flapp_exit(NULL);
    }

    // continously read value every 1s
    uint32_t counter;
    while(1) {
        if(read_mutex(counter_mutex, &counter, sizeof(counter), OsWaitForever)) {
            printf("counter value: %d\n", counter);
        }

        osDelay(1000);
    }
}
```
*/
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 08:22:43 +00:00			`#pragma once`

			`#include "flipper.h"`

			`/*`
			`== ValueMutex ==`

			`The most simple concept is ValueMutex.`
			`It is wrapper around mutex and value pointer.`
			`You can take and give mutex to work with value and read and write value.`
			`*/`

			`typedef struct {`
			`void* value;`
			`size_t size;`
			`osMutexId_t mutex;`
			`} ValueMutex;`

			`/*`
			`Creates ValueMutex.`
			`*/`
			`bool init_mutex(ValueMutex* valuemutex, void* value, size_t size);`

			`/*`
			`Call for work with data stored in mutex.`
			`Returns pointer to data if success, NULL otherwise.`
			`*/`
			`void* acquire_mutex(ValueMutex* valuemutex, uint32_t timeout);`

			`/*`
			`Helper: infinitly wait for mutex`
			`*/`
			`static inline void* acquire_mutex_block(ValueMutex* valuemutex) {`
			`return acquire_mutex(valuemutex, osWaitForever);`
			`}`

			`/*`
			`Release mutex after end of work with data.`
			Call `release_mutex` and pass ValueData instance and pointer to data.
			`*/`
			`bool release_mutex(ValueMutex* valuemutex, void* value);`

			`/*`
			Instead of take-access-give sequence you can use `read_mutex` and `write_mutex` functions.
			`Both functions return true in case of success, false otherwise.`
			`*/`
			`bool read_mutex(ValueMutex* valuemutex, void* data, size_t len, uint32_t timeout);`

			`bool write_mutex(ValueMutex* valuemutex, void* data, size_t len, uint32_t timeout);`

			`inline static bool write_mutex_block(ValueMutex* valuemutex, void* data, size_t len) {`
			`return write_mutex(valuemutex, data, len, osWaitForever);`
			`}`

			`inline static bool read_mutex_block(ValueMutex* valuemutex, void* data, size_t len) {`
			`return read_mutex(valuemutex, data, len, osWaitForever);`
			`}`

			`/*`

			`Usage example`

			```C
			`// MANIFEST`
			`// name="example-provider-app"`
			`// stack=128`

			`void provider_app(void* _p) {`
			`// create record with mutex`
			`uint32_t example_value = 0;`
			`ValueMutex example_mutex;`
			// call `init_mutex`.
			`if(!init_mutex(&example_mutex, (void*)&example_value, sizeof(uint32_t))) {`
			`printf("critical error\n");`
			`flapp_exit(NULL);`
			`}`

			`if(furi_create("provider/example", (void*)&example_mutex)) {`
			`printf("critical error\n");`
			`flapp_exit(NULL);`
			`}`

			`// we are ready to provide record to other apps`
			`flapp_ready();`

			`// get value and increment it`
			`while(1) {`
			`uint32_t* value = acquire_mutex(&example_mutex, OsWaitForever);`
			`if(value != NULL) {`
			`value++;`
			`}`
			`release_mutex(&example_mutex, value);`

			`osDelay(100);`
			`}`
			`}`

			`// MANIFEST`
			`// name="example-consumer-app"`
			`// stack=128`
			`// require="example-provider-app"`
			`void consumer_app(void* _p) {`
			`// this app run after flapp_ready call in all requirements app`

			`// open mutex value`
			`ValueMutex* counter_mutex = furi_open("provider/example");`
			`if(counter_mutex == NULL) {`
			`printf("critical error\n");`
			`flapp_exit(NULL);`
			`}`

			`// continously read value every 1s`
			`uint32_t counter;`
			`while(1) {`
			`if(read_mutex(counter_mutex, &counter, sizeof(counter), OsWaitForever)) {`
			`printf("counter value: %d\n", counter);`
			`}`

			`osDelay(1000);`
			`}`
			`}`
			```
			`*/`