SiFive Freedom E SDK README
This repository, maintained by SiFive Inc, makes it easy to get started developing
software for the Freedom E and Freedom S Embedded RISC-V Platforms. This SDK
is intended to work on any target supported by SiFive's distributions of the
RISC-V GNU Toolchain.
Documentation for Freedom E SDK is available here
Freedom E SDK was recently transitioned to using the Freedom Metal compatibility
library. If you're looking for the old Freedom E SDK, software examples, and
board support files, you can find those on the v1_0 branch.
What is Freedom Metal?
Freedom Metal (Documentation)
is a library developed by SiFive for writing portable software for all of SiFive's
RISC-V IP, RISC-V FPGA evaluation images, and development boards. Programs written
against the Freedom Metal API are intended to build and run for all SiFive RISC-V
targets. This makes Freedom Metal suitable for writing portable tests, bare metal
application programming, and as a hardware abstraction layer for porting
operating systems to RISC-V.
Contents
Freedom Metal Compatibility Library
- Board Support Packages (found under
bsp/)- Supported Targets:
- SiFive HiFive 1
- sifive-hifive1
- SiFive HiFive 1 Rev B
- sifive-hifive1-revb
- SiFive HiFive Unleashed
- sifive-hifive-unleashed
- SiFive Freedom E310 Arty
- freedom-e310-arty
- QEMU Emulation of the SiFive E31
- qemu-sifive-e31
- QEMU Emulation of the SiFive S51
- qemu-sifive-s51
- QEMU Emulation of the SiFive U54
- qemu-sifive-u54
- QEMU Emulation of the SiFive U54MC
- qemu-sifive-u54mc
- SiFive HiFive 1
- The board support files for the Freedom Metal library are located entirely
within a single target directory inbsp/<target>/. For example, the HiFive 1
board support files for Freedom Metal are entirely withinbsp/sifive-hifive1/
and consist of the following:- design.dts
- The DeviceTree description of the target. This file is used to parameterize
the Freedom Metal library to the target device. It is included as reference
so that users of Freedom Metal are aware of what features and peripherals
are available on the target.
- The DeviceTree description of the target. This file is used to parameterize
- metal.h
- The Freedom Metal machine header which is used internally to Freedom Metal
to instantiate structures to support the target device.
- The Freedom Metal machine header which is used internally to Freedom Metal
- metal.%.lds
- Generated linker scripts for the target. The different scripts allow
for different memory configurations.
- Generated linker scripts for the target. The different scripts allow
- openocd.cfg (for development board and FPGA targets)
- Used to configure OpenOCD for flashing and debugging the target device.
- settings.mk
- Used to set
-marchand-mabiarguments to the RISC-V GNU Toolchain.
- Used to set
- design.dts
- Supported Targets:
- A Few Example Programs (found under
software/)- empty
- An empty project. Serves as a good starting point for your own program.
- hello
- Prints "Hello, World!" to stdout, if a serial device is present on the target.
- sifive-welcome
- Prints a welcome message and interacts with the LEDs.
- return-pass
- Returns status code 0 indicating program success.
- return-fail
- Returns status code 1 indicating program failure.
- example-itim
- Demonstrates how to statically link application code into the Instruction
Tightly Integrated Memory (ITIM) if an ITIM is present on the target.
- Demonstrates how to statically link application code into the Instruction
- software-interrupt
- Demonstrates how to register a handler for and trigger a software interrupt
- timer-interrupt
- Demonstrates how to register a handler for and trigger a timer interrupt
- local-interrupt
- Demonstrates how to register a handler for and trigger a local interrupt
- example-pmp
- Demonstrates how to configure a Physical Memory Protection (PMP) region
- example-spi
- Demonstrates how to use the SPI API to transfer bytes to a peripheral
- dhrystone
- "Dhrystone" Benchmark Program by Reinhold P. Weicker
- coremark
- "CoreMark" Benchmark Program that measures the performance of embedded
microcrontrollers (MCU)
- "CoreMark" Benchmark Program that measures the performance of embedded
- cflush
- A simple example demo how to use cflush (Data) L1 and use FENCE to ensure flush
complete.
- A simple example demo how to use cflush (Data) L1 and use FENCE to ensure flush
- example-rtc
- Demonstrates how to use the RTC API to start a Real-Time Clock, set a compare
value, and handle an interrupt when the clock matches the compare value.
- Demonstrates how to use the RTC API to start a Real-Time Clock, set a compare
- example-watchdog
- Demonstrates how to use the Watchdog API to set a watchdog timer to trigger an
interrupt on timeout.
- Demonstrates how to use the Watchdog API to set a watchdog timer to trigger an
- example-user-mode
- Demonstrates how to drop to user mode privilege level.
- example-user-syscall
- Demonstrates how to register a handler for the "syscall from user mode" exception,
drop to the user mode privilege level, and then issue a syscall.
- Demonstrates how to register a handler for the "syscall from user mode" exception,
- plic-interrupts
- A simple example demonstrating how PLIC interrupts get uses on an Arty board.
- test-coreip
- Assembly test code which executes instructions and checks for expected results.
The tests are designed to work on SiFive CPU designs in RTL simulation or on the
Arty FPGA board.
- Assembly test code which executes instructions and checks for expected results.
- clic-vector-interrupts
- A simple example demonstrating how to use CLIC non vector interrupts
- clic-selective-vector-interrupts
- A simple example demonstrating how to use CLIC selective vector interrupts
- clic-hardware-vector-interrupts
- A simple example demonstrating the use of CLIC hardware vector interrupts
- empty
Setting up the SDK
Prerequisites
To use this SDK, you will need the following software available on your machine:
- GNU Make
- Git
- RISC-V GNU Toolchain
- RISC-V QEMU 4.1.0 (for use with the qemu-sifive-* simulation targets)
- RISC-V OpenOCD (for use with development board and FPGA targets)
- Segger J-LINK (for use with certain development boards)
Install the RISC-V Toolchain and OpenOCD
The RISC-V GNU Toolchain and OpenOCD are available from the SiFive Website at
For OpenOCD and/or RISC-V GNU Toolchain, download the .tar.gz for your platform,
and unpack it to your desired location. Then, use the RISCV_PATH and
RISCV_OPENOCD_PATH variables when using the tools:
cp openocd-<date>-<platform>.tar.gz /my/desired/location/
cp riscv64-unknown-elf-gcc-<date>-<platform>.tar.gz /my/desired/location
cd /my/desired/location
tar -xvf openocd-<date>-<platform>.tar.gz
tar -xvf riscv64-unknown-elf-gcc-<date>-<platform>.tar.gz
export RISCV_OPENOCD_PATH=/my/desired/location/openocd
export RISCV_PATH=/my/desired/location/riscv64-unknown-elf-gcc-<date>-<version>
Install RISC-V QEMU 4.1.0
The RISC-V QEMU Emulator is available from the SiFive Website at
Download the .tar.gz for your platform and unpack it to your desired location.
Then, add QEMU to your path:
cp riscv-qemu-<version>-<date>-<platform>.tar.gz /my/desired/location
tar -xvf riscv-qemu-<version>-<date>-<platform>.tar.gz
export PATH=$PATH:/my/desired/location/riscv-qemu-<version>-<date>-<platform>/bin
Install Segger J-Link Software
Some targets supported by Freedom E SDK (like the SiFive HiFive1 Rev B) use
Segger J-Link OB for programming and debugging. If you intend to use these
targets, install the Segger J-Link Software and Documentation Pack for your
machine:
Segger J-Link Software Downloads
Cloning the Repository
This repository can be cloned by running the following commands:
git clone --recursive https://github.com/sifive/freedom-e-sdk.git
cd freedom-e-sdk
The --recursive option is required to clone the git submodules included in the
repository. If at first you omit the --recursive option, you can achieve
the same effect by updating submodules using the command:
git submodule update --init --recursive
Updating your SDK
If you'd like to update your SDK to the latest version:
git pull origin master
git submodule update --init --recursive
Using the Tools
Building an Example
To compile a bare-metal RISC-V program:
make [PROGRAM=hello] [TARGET=sifive-hifive1] [CONFIGURATION=debug] software
The square brackets in the above command indicate optional parameters for the
Make invocation. As you can see, the default values of these parameters tell
the build script to build the hello example for the sifive-hifive1 target
with the debug configuration. If, for example, you wished to build the
timer-interrupt example for the S51 Arty FPGA Evaluation target,
with the release configuration, you would instead run the command
make PROGRAM=timer-interrupt TARGET=coreip-s51-arty CONFIGURATION=release software
Building an Benchmark Program
Building a benchmark program is slightly special in that certain section is
required to be loaded in specific memory region. A specialize linker file has
been created for its optimal run.
make PROGRAM=dhrystone TARGET=coreip-e31-arty LINK_TARGET=ramrodata software
Uploading to the Target Board
make [PROGRAM=hello] [TARGET=sifive-hifive1] [CONFIGURATION=debug] upload
Debugging a Target Program
make [PROGRAM=hello] [TARGET=sifive-hifive1] [CONFIGURATION=debug] debug
Cleaning a Target Program Build Directory
make [PROGRAM=hello] [TARGET=sifive-hifive1] [CONFIGURATION=debug] clean
Create a Standalone Project
You can export a program to a standalone project directory using the standalone
target. The resulting project will be locked to a specific TARGET. Note
that this functionality is only supported for Freedom Metal programs, not the
Legacy Freedom E SDK.
STANDALONE_DEST is a required argument to provide the desired project location.
make [PROGRAM=hello] [TARGET=sifive-hifive1] [INCLUDE_METAL_SOURCES=1] STANDALONE_DEST=/path/to/desired/location standalone
Run make help for more commands.
For More Information
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