Move multicore_lockout victim initialzied tracking to pico_multicore (#1427)

* Move multicore_lockout victim initialzied tracking to pico_multicore via new  multicore_lockout_victim_is_initialzied method, so user initialization of the multicore_lockout independent of pico_flash will work
3 files changed
tree: 9905eff8966d151308f7c437e24c590e2772c60e
  1. .github/
  2. cmake/
  3. docs/
  4. external/
  5. lib/
  6. src/
  7. test/
  8. tools/
  9. .gitignore
  10. .gitmodules
  11. CMakeLists.txt
  12. CONTRIBUTING.md
  13. LICENSE.TXT
  14. pico_sdk_init.cmake
  15. pico_sdk_version.cmake
  16. README.md
README.md

Raspberry Pi Pico SDK

The Raspberry Pi Pico SDK (henceforth the SDK) provides the headers, libraries and build system necessary to write programs for the RP2040-based devices such as the Raspberry Pi Pico in C, C++ or assembly language.

The SDK is designed to provide an API and programming environment that is familiar both to non-embedded C developers and embedded C developers alike. A single program runs on the device at a time and starts with a conventional main() method. Standard C/C++ libraries are supported along with C level libraries/APIs for accessing all of the RP2040's hardware include PIO (Programmable IO).

Additionally the SDK provides higher level libraries for dealing with timers, synchronization, USB (TinyUSB) and multi-core programming along with various utilities.

The SDK can be used to build anything from simple applications, to fully fledged runtime environments such as MicroPython, to low level software such as RP2040's on-chip bootrom itself.

Additional libraries/APIs that are not yet ready for inclusion in the SDK can be found in pico-extras.

Documentation

See Getting Started with the Raspberry Pi Pico for information on how to setup your hardware, IDE/environment and for how to build and debug software for the Raspberry Pi Pico and other RP2040-based devices.

See Connecting to the Internet with Raspberry Pi Pico W to learn more about writing applications for your Raspberry Pi Pico W that connect to the internet.

See Raspberry Pi Pico C/C++ SDK to learn more about programming using the SDK, to explore more advanced features, and for complete PDF-based API documentation.

See Online Raspberry Pi Pico SDK API docs for HTML-based API documentation.

Example code

See pico-examples for example code you can build.

Getting the latest SDK code

The master branch of pico-sdk on GitHub contains the latest stable release of the SDK. If you need or want to test upcoming features, you can try the develop branch instead.

Quick-start your own project

These instructions are extremely terse, and Linux-based only. For detailed steps, instructions for other platforms, and just in general, we recommend you see Raspberry Pi Pico C/C++ SDK

  1. Install CMake (at least version 3.13), and GCC cross compiler

    sudo apt install cmake gcc-arm-none-eabi libnewlib-arm-none-eabi libstdc++-arm-none-eabi-newlib
    
  2. Set up your project to point to use the Raspberry Pi Pico SDK

    • Either by cloning the SDK locally (most common) :

      1. git clone this Raspberry Pi Pico SDK repository

      2. Copy pico_sdk_import.cmake from the SDK into your project directory

      3. Set PICO_SDK_PATH to the SDK location in your environment, or pass it (-DPICO_SDK_PATH=) to cmake later.

      4. Setup a CMakeLists.txt like:

        cmake_minimum_required(VERSION 3.13)
        
        # initialize the SDK based on PICO_SDK_PATH
        # note: this must happen before project()
        include(pico_sdk_import.cmake)
        
        project(my_project)
        
        # initialize the Raspberry Pi Pico SDK
        pico_sdk_init()
        
        # rest of your project
        
        
    • Or with the Raspberry Pi Pico SDK as a submodule :

      1. Clone the SDK as a submodule called pico-sdk

      2. Setup a CMakeLists.txt like:

        cmake_minimum_required(VERSION 3.13)
        
        # initialize pico-sdk from submodule
        # note: this must happen before project()
        include(pico-sdk/pico_sdk_init.cmake)
        
        project(my_project)
        
        # initialize the Raspberry Pi Pico SDK
        pico_sdk_init()
        
        # rest of your project
        
        
    • Or with automatic download from GitHub :

      1. Copy pico_sdk_import.cmake from the SDK into your project directory

      2. Setup a CMakeLists.txt like:

        cmake_minimum_required(VERSION 3.13)
        
        # initialize pico-sdk from GIT
        # (note this can come from environment, CMake cache etc)
        set(PICO_SDK_FETCH_FROM_GIT on)
        
        # pico_sdk_import.cmake is a single file copied from this SDK
        # note: this must happen before project()
        include(pico_sdk_import.cmake)
        
        project(my_project)
        
        # initialize the Raspberry Pi Pico SDK
        pico_sdk_init()
        
        # rest of your project
        
        
    • Or by cloning the SDK locally, but without copying pico_sdk_import.cmake:

      1. git clone this Raspberry Pi Pico SDK repository

      2. Setup a CMakeLists.txt like:

        cmake_minimum_required(VERSION 3.13)
        
        # initialize the SDK directly
        include(/path/to/pico-sdk/pico_sdk_init.cmake)
        
        project(my_project)
        
        # initialize the Raspberry Pi Pico SDK
        pico_sdk_init()
        
        # rest of your project
        
        
  3. Write your code (see pico-examples or the Raspberry Pi Pico C/C++ SDK documentation for more information)

    About the simplest you can do is a single source file (e.g. hello_world.c)

    #include <stdio.h>
    #include "pico/stdlib.h"
    
    int main() {
        setup_default_uart();
        printf("Hello, world!\n");
        return 0;
    }
    

    And add the following to your CMakeLists.txt:

    add_executable(hello_world
        hello_world.c
    )
    
    # Add pico_stdlib library which aggregates commonly used features
    target_link_libraries(hello_world pico_stdlib)
    
    # create map/bin/hex/uf2 file in addition to ELF.
    pico_add_extra_outputs(hello_world)
    

    Note this example uses the default UART for stdout; if you want to use the default USB see the hello-usb example.

  4. Setup a CMake build directory. For example, if not using an IDE:

    $ mkdir build
    $ cd build
    $ cmake ..
    

    When building for a board other than the Raspberry Pi Pico, you should pass -DPICO_BOARD=board_name to the cmake command above, e.g. cmake -DPICO_BOARD=pico_w .. to configure the SDK and build options accordingly for that particular board.

    Doing so sets up various compiler defines (e.g. default pin numbers for UART and other hardware) and in certain cases also enables the use of additional libraries (e.g. wireless support when building for PICO_BOARD=pico_w) which cannot be built without a board which provides the requisite functionality.

    For a list of boards defined in the SDK itself, look in this directory which has a header for each named board.

  5. Make your target from the build directory you created.

    $ make hello_world
    
  6. You now have hello_world.elf to load via a debugger, or hello_world.uf2 that can be installed and run on your Raspberry Pi Pico via drag and drop.