POSIX Threads Support

Overview

ESP-IDF is based on FreeRTOS but offers a range of POSIX-compatible APIs that allow easy porting of third party code. This includes support for common parts of the POSIX Threads “pthreads” API.

POSIX Threads are implemented in ESP-IDF as wrappers around equivalent FreeRTOS features. The runtime memory or performance overhead of using the pthreads API is quite low, but not every feature available in either pthreads or FreeRTOS is available via the ESP-IDF pthreads support.

Pthreads can be used in ESP-IDF by including standard pthread.h header, which is included in the toolchain libc. An additional ESP-IDF specific header, esp_pthread.h, provides additional non-POSIX APIs for using some ESP-IDF features with pthreads.

C++ Standard Library implementations for std::thread, std::mutex, std::condition_variable, etc. are implemented using pthreads (via GCC libstdc++). Therefore, restrictions mentioned here also apply to the equivalent C++ standard library functionality.

RTOS Integration

Unlike many operating systems using POSIX Threads, ESP-IDF is a real-time operating system with a real-time scheduler. This means that a thread will only stop running if a higher priority task is ready to run, the thread blocks on an OS synchronization structure like a mutex, or the thread calls any of the functions sleep, vTaskDelay(), or usleep.

Note

If calling a standard libc or C++ sleep function, such as usleep defined in unistd.h, then the task will only block and yield the CPU if the sleep time is longer than one FreeRTOS tick period. If the time is shorter, the thread will busy-wait instead of yielding to another RTOS task.

By default all POSIX Threads have the same RTOS priority, but it is possible to change this by calling a custom API.

Standard features

The following standard APIs are implemented in ESP-IDF.

Refer to standard POSIX Threads documentation, or pthread.h, for details about the standard arguments and behaviour of each function. Differences or limitations compared to the standard APIs are noted below.

Thread APIs

• pthread_create() - The attr argument is supported for setting stack size and detach state only. Other attribute fields are ignored. - Unlike FreeRTOS task functions, the start_routine function is allowed to return. A “detached” type thread is automatically deleted if the function returns. The default “joinable” type thread will be suspended until pthread_join() is called on it.

• pthread_join()

• pthread_detach()

• pthread_exit()

• sched_yield()

• pthread_self() - An assert will fail if this function is called from a FreeRTOS task which is not a pthread.

• pthread_equal()

Thread Attributes

• pthread_attr_init()

• pthread_attr_destroy() - This function doesn’t need to free any resources and instead resets the attr structure to defaults (implementation is same as pthread_attr_init()).

• pthread_attr_getstacksize() / pthread_attr_setstacksize()

• pthread_attr_getdetachstate() / pthread_attr_setdetachstate()

Once

• pthread_once()

Static initializer constant PTHREAD_ONCE_INIT is supported.

Note

This function can be called from tasks created using either pthread or FreeRTOS APIs

Mutexes

POSIX Mutexes are implemented as FreeRTOS Mutex Semaphores (normal type for “fast” or “error check” mutexes, and Recursive type for “recursive” mutexes). This means that they have the same priority inheritance behaviour as mutexes created with xSemaphoreCreateMutex().

• pthread_mutex_init()

• pthread_mutex_destroy()

• pthread_mutex_lock()

• pthread_mutex_timedlock()

• pthread_mutex_trylock()

• pthread_mutex_unlock()

• pthread_mutexattr_init()

• pthread_mutexattr_destroy()

• pthread_mutexattr_gettype() / pthread_mutexattr_settype()

Static initializer constant PTHREAD_MUTEX_INITIALIZER is supported, but the non-standard static initializer constants for other mutex types are not supported.

Note

These functions can be called from tasks created using either pthread or FreeRTOS APIs

Condition Variables

• pthread_cond_init() - The attr argument is not implemented and is ignored.

• pthread_cond_destroy()

• pthread_cond_signal()

• pthread_cond_broadcast()

• pthread_cond_wait()

• pthread_cond_timedwait()

Static initializer constant PTHREAD_COND_INITIALIZER is supported.

• The resolution of pthread_cond_timedwait() timeouts is the RTOS tick period (see CONFIG_FREERTOS_HZ). Timeouts may be delayed up to one tick period after the requested timeout.

Note

These functions can be called from tasks created using either pthread or FreeRTOS APIs

Read/Write Locks

• pthread_rwlock_init() - The attr argument is not implemented and is ignored.

• pthread_rwlock_destroy()

• pthread_rwlock_rdlock()

• pthread_rwlock_wrlock()

• pthread_rwlock_unlock()

Static initializer constant PTHREAD_RWLOCK_INITIALIZER is supported.

Note

These functions can be called from tasks created using either pthread or FreeRTOS APIs. Note also that the current pthread reader-writer-locks implementation is based on the condition variable API. The performance is not optimal when locking only for a minimal amount of time like e.g. accessing a simple variable. In these cases with minimal locking time, a simple mutex might be faster.

Thread-Specific Data

• pthread_key_create() - The destr_function argument is supported and will be called if a thread function exits normally, calls pthread_exit(), or if the underlying task is deleted directly using the FreeRTOS function vTaskDelete().

• pthread_key_delete()

• pthread_setspecific() / pthread_getspecific()

Note

These functions can be called from tasks created using either pthread or FreeRTOS APIs

Note

There are other options for thread local storage in ESP-IDF, including options with higher performance. See Thread Local Storage.

Not Implemented

The pthread.h header is a standard header and includes additional APIs and features which are not implemented in ESP-IDF. These include:

• pthread_cancel() returns ENOSYS if called.

• pthread_condattr_init() returns ENOSYS if called.

Other POSIX Threads functions (not listed here) are not implemented and will produce either a compiler or a linker error if referenced from an ESP-IDF application. If you identify a useful API that you would like to see implemented in ESP-IDF, please open a feature request on GitHub <https://github.com/espressif/esp-idf/issues> with the details.

ESP-IDF Extensions

The API esp_pthread_set_cfg() defined in the esp_pthreads.h header offers custom extensions to control how subsequent calls to pthread_create() will behave. Currently the following configuration can be set:

• Default stack size of new threads, if not specified when calling pthread_create() (overrides CONFIG_PTHREAD_TASK_STACK_SIZE_DEFAULT).

• RTOS priority of new threads (overrides CONFIG_PTHREAD_TASK_PRIO_DEFAULT).

• FreeRTOS task name for new threads (overrides CONFIG_PTHREAD_TASK_NAME_DEFAULT)

This configuration is scoped to the calling thread (or FreeRTOS task), meaning that esp_pthread_set_cfg() can be called independently in different threads or tasks. If the inherit_cfg flag is set in the current configuration then any new thread created will inherit the creator’s configuration (if that thread calls pthread_create() recursively), otherwise the new thread will have the default configuration.

Examples

• system/pthread demonstrates using the pthreads API to create threads

• cxx/pthread demonstrates using C++ Standard Library functions with threads

API Reference

Header File

• components/pthread/include/esp_pthread.h

Functions

esp_pthread_cfg_t esp_pthread_get_default_config(void)

Creates a default pthread configuration based on the values set via menuconfig.

Returns

A default configuration structure.

esp_err_t esp_pthread_set_cfg(const esp_pthread_cfg_t *cfg)

Configure parameters for creating pthread.

This API allows you to configure how the subsequent pthread_create() call will behave. This call can be used to setup configuration parameters like stack size, priority, configuration inheritance etc.

If the ‘inherit’ flag in the configuration structure is enabled, then the same configuration is also inherited in the thread subtree.

Note

Passing non-NULL attributes to pthread_create() will override the stack_size parameter set using this API

Parameters

cfg – The pthread config parameters

Returns

• ESP_OK if configuration was successfully set

• ESP_ERR_NO_MEM if out of memory

• ESP_ERR_INVALID_ARG if stack_size is less than PTHREAD_STACK_MIN

esp_err_t esp_pthread_get_cfg(esp_pthread_cfg_t *p)

Get current pthread creation configuration.

This will retrieve the current configuration that will be used for creating threads.

Parameters

p – Pointer to the pthread config structure that will be updated with the currently configured parameters

Returns

• ESP_OK if the configuration was available

• ESP_ERR_NOT_FOUND if a configuration wasn’t previously set

esp_err_t esp_pthread_init(void)

Initialize pthread library.

Structures

struct esp_pthread_cfg_t

pthread configuration structure that influences pthread creation

Public Members

size_t stack_size

The stack size of the pthread.

size_t prio

The thread’s priority.

bool inherit_cfg

Inherit this configuration further.

const char *thread_name

The thread name.

int pin_to_core

The core id to pin the thread to. Has the same value range as xCoreId argument of xTaskCreatePinnedToCore.

Macros

PTHREAD_STACK_MIN

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