Circle is a C++ bare metal programming environment for the Raspberry Pi. It should be usable on most existing models (see "Support Status" below). Circle provides several ready-tested C++ classes and add-on libraries, which can be used to control different hardware features of the Raspberry Pi. Together with Circle there are delivered several sample programs, which demonstrate the use of its classes. Circle can be used to create 32-bit or 64-bit bare metal applications.
Circle includes bigger (optional) third-party C-libraries for specific purposes in addon/ now. This is the reason why GitHub rates the project as a C-language-project. The main Circle libraries are written in C++ using classes instead. That's why it is called a C++ programming environment.
This release offers a significantly improved implementation of the TCP/IP network stack. It supports TCP congestion control according to RFC 5681 with Fast Retransmit and Fast Recovery. Also the unnecessary copying of frames and data in the stack is largely prevented. This improves throughput very much, especially when a Raspberry Pi with 100 MBps Ethernet is connected to a Gigabit network.
The socket API is nearly unchanged, but the new MSG_MORE flag can be specified, when calling CSocket::Send() on TCP sockets, which prevents the immediate delivery of received data on the receiver side, when more data follows. CSocket::Bind() can be called with port 0 to bind to an ephemeral port, which can be requested using CSocket::GetOwnPort(). CSocket::SendTo() without preceding Bind() or Connect() is allowed too, which automatically assigns an ephemeral port.
Circle supports the extended C++ standard library support (LLVM libc++ port) in the circle-stdlib project in several ways (e.g. with the new STDLIB_SUPPORT=4 level).
The recommended toolchain to build Circle applications is now based on GCC 15.2.Rel1. See the link in the Build section! Circle is built with -std=c++17 by default now. There are options for selecting C++14 (previous default) and C++20 for the configure tool, beside the new --kernel-max-size, --clang and --kasan options. Enter ./configure --help for more info!
The recommended firmware has been updated in boot/.
More new features:
- A
CDeviceinstance can have property strings for vendor, product, serial number and function (e.g. the USB interface) now. These strings are assigned for all USB- and for NVMe devices, and can be used to distinguish devices of the same class.CDeviceNameService::ListDevices()can show these properties. - The system option
USE_GPIO_MANAGER_FIQhas been added. When an application needs multiple FIQ-triggered GPIO interrupt pins, the classCGPIOPinFIQcannot be used. It is also not possible to useCGPIOPinFIQtogether with the classCGPIOManagerto handle more GPIO pins with IRQ. Now one can define this option to enableCGPIOManagerand all GPIO pins, which use an interrupt, to use the FIQ to reduce GPIO interrupt latency. The GPIO interrupt handler will run atFIQ_LEVELthen. CGPIOClock::StartRate()can use fractional dividers on Raspberry 1-4. Before only integer dividers were supported. Now automatically a fractional divider will be used with MASH 1, if necessary.- The class
CPipe(an unidirectional inter-process communication channel using a FIFO) and the methodsCMutex::TryAcquire()andCSemaphore::DownWithTimeout()have been added to the scheduler library.CSemaphoreobjects can have the initial count of zero now. test/pipe demonstratesCPipe. - Sound devices allow writing and reading samples in the
SoundFormatFloat32now. Samples must be of the data typefloatin the range [-1.0 .. 1.0] in this case. sample/34-sounddevices and test/sound-controller can be configured to use this. - The class
CPWMSoundBaseDevicesupports the M/S PWM mode, which is also the default now. This should lead to a better audio quality and suppresses hum, when the PWM signal is delivered via the GPIO header. - The class
CEMMCDevicein addon/SDCard supports external SDIO breakout boards at GPIO22-27 now as device "emmc2" and "SD2:" in FatFs. This does work with the EMMC host only (not withUSE_SDHOST). On the Raspberry Pi 4 and CM4 the class can be instantiated twice with different device selector parameter specified to the constructor. - A
CSSD1309Displaygraphics-mode driver for the SSD1309 128x64 OLED display controller (I2C and SPI) has been added to addon/display. - A
CMCP23017driver for the MCP23017 16-bit I2C GPIO expander has been added to the addon/gpio. - The MPU-6050 driver in addon/sensor has been extended and returns a scaled acceleration and gyroscope output now. The acceleration and gyroscope range and digital low-pass filter bandwidth can be configured. The sample adds a graphics mode.
- The serial bootloader images are much smaller now and are able to load kernel images of up to about 8 MB.
A number of fixes have been applied:
CGPIOClock::Stop()was operating on the wrong clock. This caused a stop of the UART clock, when GPIOClock2 was started.CMachineInfo::GetClockRate()now favors the firmware functionGET_CLOCK_RATE_MEASUREDoverGET_CLOCK_RATE, which reported a wrong Core clock rate, whenCCPUThrottlewas used. The reported value is rounded to the closest MHz value.- The cmdline.txt option
wm8960tune=has been added as a workaround. Add the given value to the fractional (K) part of PLL1 input/output frequency ratio (treated as 24-digit binary number) of the WM8960 Codec to suppress clicks/pops (range -10000 to 10000, default 0). - There have been multiple issues with the handling of TCP FIN packets, which were leading to a delayed termination of connections.
- There was a problem found in the scheduler using KASan, which was accessing a task object after deleting it.
Only the features with a "x" or other info are currently supported on the Raspberry Pi 5.
Circle supports the following features:
| Group | Features | Raspberry Pi 5 |
|---|---|---|
| C++ build environment | AArch32 and AArch64 support | AArch64 only |
| Basic library functions (e.g. new and delete) | x | |
| Enables all CPU caches using the MMU | x | |
| Interrupt support (IRQ and FIQ) | IRQ only | |
| Multi-core support (Raspberry Pi 2, 3 and 4) | x | |
| Cooperative non-preemptive scheduler | x | |
| CPU clock rate management | x | |
| Clang/LLVM support (experimental) | x | |
| Debug support | Kernel logging to screen, UART and/or syslog server | x |
| C-assertions with stack trace | x | |
| Hardware exception handler with stack trace | x | |
| GDB support using rpi_stub (Raspberry Pi 2 and 3) | ||
| Serial bootloader (by David Welch) included | x | |
| Software profiling support (single-core) | x | |
| QEMU support | ||
| Kernel Address Sanitizer support | x | |
| SoC devices | GPIO pins (with interrupt, Act LED) and clocks | x |
| Frame buffer (screen driver with escape sequences) | limited | |
| UART(s) (Polling and interrupt driver) | x | |
| System timer (with kernel timers) | x | |
| Platform DMA controller | DMA40 only | |
| RP1 platform DMA controller (Raspberry Pi 5 only) | x | |
| EMMC SD card interface driver | x | |
| SDHOST SD card interface driver (Raspberry Pi 1-3) | ||
| PWM output (2 channels) | 4 channels | |
| PWM sound output (on headphone jack) | with adapter | |
| I2C master(s) and slave | masters only | |
| SPI0 master (Polling and DMA driver) | x | |
| SPI1 auxiliary master (Polling) | ||
| SPI3-6 masters of Raspberry Pi 4 (Polling) | SPI1-3 and 5 | |
| SMI master | ||
| I2S sound output and input | x | |
| HDMI sound output (without VCHIQ) | x | |
| Hardware random number generator | x | |
| Watchdog device | x | |
| Official Raspberry Pi touch screen (v1 only) | ||
| VCHIQ interface and audio service drivers | ||
| BCM54213PE Gigabit Ethernet NIC of Raspberry Pi 4 | ||
| MACB / GEM Gigabit Ethernet NIC of Raspberry Pi 5 | x | |
| Wireless LAN access | x | |
| Driver for XPT2046-based touch screens | x | |
| NVMe SSD driver for Raspberry Pi 5 (experimental) | x | |
| USB | Host controller interface (HCI) drivers | x |
| Standard hub driver (USB 2.0 only) | x | |
| HID class device drivers (keyboard, mouse, gamepad) | x | |
| Driver for on-board Ethernet device (SMSC951x) | ||
| Driver for on-board Ethernet device (LAN7800) | ||
| Driver for CDC Ethernet devices (RTL815x, QEMU) | ||
| Driver for USB mass storage devices (bulk only) | x | |
| Driver for USB floppy disk devices (experimental) | x | |
| Driver for USB audio streaming devices (RPi 4 only) | x | |
| Drivers for different USB serial devices | x | |
| Audio class MIDI input support | x | |
| Touchscreen driver (digitizer mode) | x | |
| Printer driver | x | |
| MIDI gadget driver | ||
| Serial CDC gadget driver | ||
| Mass-storage device gadget driver | ||
| File systems | Internal FAT driver (limited function) | x |
| FatFs driver (full function, by ChaN) | x | |
| TCP/IP networking | Protocols: ARP, IP, ICMP, IGMP, UDP, TCP | x |
| Clients: DHCP, DNS, NTP, HTTP, Syslog, MQTT, mDNS | x | |
| Servers: HTTP, TFTP | x | |
| BSD-like C++ socket API | x | |
| Graphics | OpenGL ES 1.1 and 2.0, OpenVG 1.1, EGL 1.4 | |
| (not on Raspberry Pi 4) | ||
| uGUI (by Achim Doebler) | ||
| LVGL (by LVGL Kft) | x | |
| 2D graphics class in base library | x | |
| Not supported | Bluetooth |
This table lists the support status for the different Raspberry Pi models. Not listed models are not supported.
| Model | Status | Remarks |
|---|---|---|
| Raspberry Pi Model A | Should work | |
| Raspberry Pi Model B R1 | Should work | |
| Raspberry Pi Model B R2 | Tested | |
| Raspberry Pi Model A+ | Tested | |
| Raspberry Pi Model B+ | Tested | |
| Raspberry Pi Zero | Tested | |
| Raspberry Pi Zero W | Tested | |
| Raspberry Pi Zero 2 W | Tested | WLAN unknown for new revision |
| Raspberry Pi 2 Model B | Tested | |
| Raspberry Pi 3 Model B | Tested | |
| Raspberry Pi 3 Model A+ | Tested | |
| Raspberry Pi 3 Model B+ | Tested | |
| Raspberry Pi 4 Model B | Tested | |
| Raspberry Pi 400 | Tested | |
| Raspberry Pi 5 | Tested | With BCM2712 C1 and D0 steppings |
| Raspberry Pi 500 | Unknown | |
| Compute Module | Reported to work | Unknown which devices work |
| Compute Module 3 | Should work | |
| Compute Module 3+ | Reported to work | WLAN unknown |
| Compute Module 4 | Tested | WLAN unknown |
| Compute Module 4S | Unknown | |
| Compute Module 5 | Reported to work | Unknown which devices work |
| Compute Module Zero | Reported to work |
For building 64-bit applications (AArch64) see the next section.
Circle does not support 32-bit applications on the Raspberry Pi 5.
This describes building on PC Linux. See the file doc/windows-build.txt for information about building on Windows. If building for the Raspberry Pi 1 you need a toolchain for the ARM1176JZF core (with EABI support). For Raspberry Pi 2/3/4 you need a toolchain with Cortex-A7/-A53/-A72 support. A toolchain, which works for all of these, can be downloaded here. Circle has been tested with the version 15.2.Rel1 (arm-gnu-toolchain-15.2.rel1-x86_64-arm-none-eabi.tar.xz) from this website. This is the recommended toolchain for AArch32 builds.
First edit the file Rules.mk and set the Raspberry Pi version (RASPPI, 1, 2, 3 or 4) and the PREFIX of your toolchain commands. Alternatively you can create a Config.mk file (which is ignored by git) and set the Raspberry Pi version and the PREFIX variable to the prefix of your compiler like this (don't forget the dash at the end):
RASPPI = 1
PREFIX = arm-none-eabi-
The following table gives support for selecting the right RASPPI value:
| RASPPI | Target | Models | Optimized for |
|---|---|---|---|
| 1 | kernel.img | A, B, A+, B+, Zero, (CM) | ARM1176JZF-S |
| 2 | kernel7.img | 2, 3, Zero 2, (CM3) | Cortex-A7 |
| 3 | kernel8-32.img | 3, Zero 2, (CM3) | Cortex-A53 |
| 4 | kernel7l.img | 4B, 400, CM4 | Cortex-A72 |
For a binary distribution you should do one build with RASPPI = 1, one with RASPPI = 2 and one build with RASPPI = 4 and include the created files kernel.img, kernel7.img and kernel7l.img. Optionally you can do a build with RASPPI = 3 and add the created file kernel8-32.img to provide an optimized version for the Raspberry Pi 3.
The configuration file Config.mk can be created using the configure tool too. Please enter ./configure -h for help on using it!
There are a number of configurable system options in the file include/circle/sysconfig.h. Please have a look into this file to learn, how you can configure Circle for your purposes. Some hardware configurations may require modifications to these options (e.g. using USB on the CM4).
Then go to the build root of Circle and do:
./makeall clean
./makeall
By default only the Circle libraries are built. To build a sample program after makeall go to its subdirectory and do make.
You can also build Circle on the Raspberry Pi itself (set PREFIX = (empty)) on Raspbian but you need some method to put the kernel.img file onto the SD(HC) card. With an external USB card reader on model B+ or Raspberry Pi 2/3/4 model B (4 USB ports) this should be no problem.
Circle supports building 64-bit applications, which can be run on the Raspberry Pi 3, 4 or 5. There are also Raspberry Pi 2 versions and the Raspberry Pi Zero 2, which are based on the BCM2837 SoC. These Raspberry Pi versions can be used too (with RASPPI = 3).
The recommended toolchain to build 64-bit applications with Circle can be downloaded here. Circle has been tested with the version 15.2.Rel1 (arm-gnu-toolchain-15.2.rel1-x86_64-aarch64-none-elf.tar.xz) from this website. This is the recommended toolchain for AArch64 builds.
There are distro-provided toolchains on certain Linux platforms (e.g. g++-aarch64-linux-gnu on Ubuntu or gcc-c++-aarch64-linux-gnu on Fedora), which may work with Circle and can be a quick way to use it, but you have to test this by yourself. If you encounter problems (e.g. no reaction at all, link failure with external library) using a distro-provided toolchain, please try the recommended toolchain (see above) first, before reporting an issue.
First edit the file Rules.mk and set the Raspberry Pi architecture (AARCH, 32 or 64) and the PREFIX64 of your toolchain commands. The RASPPI variable has to be set to 3, 4 or 5 for AARCH = 64. Alternatively you can create a Config.mk file (which is ignored by git) and set the Raspberry Pi architecture and the PREFIX64 variable to the prefix of your compiler like this (don't forget the dash at the end):
AARCH = 64
RASPPI = 3
PREFIX64 = aarch64-none-elf-
The configuration file Config.mk can be created using the configure tool too. Please enter ./configure -h for help on using it!
Then go to the build root of Circle and do:
./makeall clean
./makeall
By default only the Circle libraries are built. To build a sample program after makeall go to its subdirectory and do make.
Copy the Raspberry Pi firmware (from boot/ directory, do make there to get them) files along with the kernel*.img (from sample/ subdirectory) to a SD(HC) card with FAT file system.
It is now always recommended to copy the file config32.txt (for 32-bit mode) or config64.txt (for 64-bit mode) from the boot/ directory to the SD(HC) card and to rename it to config.txt there. These files are especially required to enable FIQ use on the Raspberry Pi 4. Furthermore the additional file armstub7-rpi4.bin (for 32-bit mode) or armstub8-rpi4.bin (for 64-bit mode) is required on the SD card then. Please see boot/README for information on how to build these files.
Finally put the SD(HC) card into the Raspberry Pi.
- include: The common header files, most class headers are in the include/circle/ subdirectory.
- lib: The Circle class implementation and support files (other libraries are in subdirectories of lib/).
- sample: Several sample applications using Circle in different subdirectories. The main function is implemented in the CKernel class.
- addon: Contains contributed libraries and samples (has to be build manually).
- app: Place your own applications here. If you have own libraries put them into app/lib/.
- boot: Do make in this directory to get the Raspberry Pi firmware files required to boot.
- doc: Additional documentation files.
- test: Several test programs, which test different features of Circle.
- tools: Tools for building Circle and for using Circle more comfortable (e.g. a serial bootloader).
The following C++ classes were added to Circle:
Scheduler library
- CPipe: Unidirectional interprocess communication channel using a FIFO
- CPipeFile: Read or Write endpoint of a CPipe channel
Net library
- CNetBuffer: Generic frame/packet buffer for network protocol handling
- CNetBufferQueue: FIFO queue for CNetBuffer objects
- CReassemblyQueue: Reassembly queue for the TCP receiver
The available Circle classes are listed in the file doc/classes.txt. If you have Doxygen installed on your computer you can build a class documentation in doc/html/ using:
./makedoc
At the moment there are only a few classes described in detail for Doxygen.
- Standard library support
- Dynamic memory management and the "new" operator
- DMA buffer requirements
- Serial bootloader support
- Multi-core support
- USB plug-and-play
- Debugging support
- JTAG debugging
- SWD debugging (Raspberry Pi 5)
- QEMU support
- Eclipse IDE support
- About real-time applications
- cmdline.txt options
- Screen escape sequences
- Keyboard escape sequences
- Clang support
- Memory layout
- Naming conventions
- Address sanitizer
- Known issues
Raspberry Pi is a trademark of Raspberry Pi Ltd.
Linux is a trademark of Linus Torvalds.
PS3 and PS4 are registered trademarks of Sony Computer Entertainment Inc.
Windows, Xbox 360 and Xbox One are trademarks of the Microsoft group of companies.
Nintendo Switch is a trademark of Nintendo.
Khronos and OpenVG are trademarks of The Khronos Group Inc.
OpenGL ES is a trademark of Silicon Graphics Inc.
The micro:bit brand belongs to the Micro:bit Educational Foundation.
HDMI is a registered trademark of HDMI Licensing Administrator, Inc.