Equipment :
In following examples, static address for PC is 192.168.0.1.
It can be modified with $ sudo ifconfig [Eth_name] 192.168.0.1
NOTE : ssh must be activated on RPI
$ ssh rpi@192.168.0.2
Graphical mode :
$ ssh -X rpi@192.168.0.2
Copy PC –> RPI
$ scp file_to_copy rpi@192.168.0.2:/home/rpi
Copy Files PC <–> RPI
$ scp file_to_copy rpi@192.168.0.2:/home/rpi
filezilla:
Host : 192.168.0.2
Username : rpi
Password :
Port : 22
RPI (via ssh)
$ sudo nano /etc/ssh/sshd_config
PermitRootLogin yes
$ sudo service ssh restart
PC
$ ssh-keygen -t rsa
# entry for passphrase
$ ssh-copy-id -i ~/.ssh/id_rsa.pub rpi@192.168.0.2
$ nano /etc/wpa_supplicant/wpa_supplicant.conf
ctrl_interface=DIR=/var/run/wpa_supplicant GROUP=netdev
update_config=1
country=FR
network={
ssid="eduroam"
disabled=0
auth_alg=OPEN
ssid="eduroam"
scan_ssid=1
key_mgmt=WPA-EAP
proto=WPA RSN
pairwise=CCMP TKIP
eap=PEAP
identity="[your_id]" # Edit this,
anonymous_identity="anonymous@enib.fr"
password="[your_pw]" # and this.
phase1="peaplabel=0"
phase2="auth=MSCHAPV2"
}
Considering the following helloworld.cpp file :
#include <iostream>
#include <unistd.h>
using namespace std;
int main (void)
{
int i = 0;
cout << "Hello RPi Development World !"<< endl;
cout << "Hello RPI Development World Again !" << endl;
while(1)
{
cout << "I'm in the While loop and the value of variable i is: " << i << endl;
i++;
usleep(1000000); //wait for 1 seconds
}
return 0;
}
let’s copy it on the target :
$ scp helloworld.cpp rpi@192.168.0.2:/home/rpi
RPI side (via SSH)
The RPI compiler is of course ARM type :
$ gcc -v
Target: aarch64-linux-gnu
gcc version 11.3.0
$ g++ -v
Target: aarch64-linux-gnu
gcc version 11.3.0
We compile, we execute :
$ g++ helloworld.cpp -o helloworld
$ chmod +x helloworld
$ ./helloworld
Hello RPi Development World !
Hello RPI Development World Again !
I'm in the While loop and the value of variable i is: 0
I'm in the While loop and the value of variable i is: 1
I'm in the While loop and the value of variable i is: 2
...
Now let’s see how to create the RPI program on the PC.
Interest:
An evidence : The PC has a compilation toolchain for Pentium.
$ gcc -v
Target: x86_64-linux-gnu
Installation
the easiest way :
$ sudo apt-get install g++-aarch64-linux-gnu
NOTE : alternatively you can download and build yourself your own compiler, or download a pre built version at linaro.org or developer.arm.com ( be aware of compiling issues due to compiler versions ).
$ aarch64-linux-gnu-g++ -v
Using built-in specs.
COLLECT_GCC=aarch64-linux-gnu-g++
COLLECT_LTO_WRAPPER=/usr/lib/gcc-cross/aarch64-linux-gnu/11/lto-wrapper
Target: aarch64-linux-gnu
Configured with: ../src/configure -v --with-pkgversion='Ubuntu 11.3.0-1ubuntu1~22.04.1' --with-bugurl=file:///usr/share/doc/gcc-11/README.Bugs --enable-languages=c,ada,c++,go,d,fortran,objc,obj-c++,m2 --prefix=/usr --with-gcc-major-version-only --program-suffix=-11 --enable-shared --enable-linker-build-id --libexecdir=/usr/lib --without-included-gettext --enable-threads=posix --libdir=/usr/lib --enable-nls --with-sysroot=/ --enable-clocale=gnu --enable-libstdcxx-debug --enable-libstdcxx-time=yes --with-default-libstdcxx-abi=new --enable-gnu-unique-object --disable-libquadmath --disable-libquadmath-support --enable-plugin --enable-default-pie --with-system-zlib --enable-libphobos-checking=release --without-target-system-zlib --enable-multiarch --enable-fix-cortex-a53-843419 --disable-werror --enable-checking=release --build=x86_64-linux-gnu --host=x86_64-linux-gnu --target=aarch64-linux-gnu --program-prefix=aarch64-linux-gnu- --includedir=/usr/aarch64-linux-gnu/include --with-build-config=bootstrap-lto-lean --enable-link-serialization=2
Thread model: posix
Supported LTO compression algorithms: zlib zstd
gcc version 11.3.0 (Ubuntu 11.3.0-1ubuntu1~22.04.1)
PC Side
$ aarch64-linux-gnu-g++ helloworld.cpp -o helloworld
$ file helloworld
helloworld: ELF 64-bit LSB pie executable, ARM aarch64, version 1 (SYSV), dynamically linked, interpreter /lib/ld-linux-aarch64.so.1, BuildID[sha1]=89972f3af5d332f669cca9824f2177149492904d, for GNU/Linux 3.7.0, not stripped
$ chmod +x helloworld
$ scp helloworld rpi@192.168.0.2:/home/pi
RPI Side (via SSH)
$ ./helloworld
Hello RPi Development World !
Hello RPI Development World Again !
I'm in the While loop and the value of variable i is: 0
I'm in the While loop and the value of variable i is: 1
I'm in the While loop and the value of variable i is: 2
So this is exactly the same for a simple hello world.
Makefile version :
It gets complicated ; let’s consider the opencv library.
The executable creation must be done with RPI opencv libs ( not the PC ones).
opencv installation
$ sudo apt-get update && sudo apt-get upgrade
$ sudo apt-get install libcv-dev python-opencv libopencv-dev opencv-doc
A solution could be copying RPI libs on the PC in order to create a minimal file system.
This supposes dealing with dependances and update links to get relative paths.
An other solution, more elegant, is mounting the RPI file system through ssh thanks to sshfs.
Installation
$ sudo apt-get install sshfs
$ sudo addgroup fuse
$ sudo usermod -a -G fuse kerhoas
$ mkdir ~/rpi-mnt
$ sudo nano /etc/fuse.conf
user_allow_other
Utilisation
$ sshfs rpi@192.168.0.2:/ ~/rpi-mnt -o transform_symlinks -o allow_other
$ ls rpi-mnt
bin debian-binary etc lib man mnt proc run srv tmp var
boot dev home lost+found media opt root sbin sys usr
This is the RPI file system ; it is mounted in PC rpi_mnt directory
Compilation
WORKSPACE_TSI_OPENCV_CROSS.zip
let’s have à look to the Makefile:
# A lancer au préalable :
# sshfs rpi@192.168.0.2:/ ~/rpi-mnt -o transform_symlinks -o allow_other
CPP= aarch64-linux-gnu-g++
CC= aarch64-linux-gnu-gcc
# Path to RPI file system ( via sshfs )
RPI_FS = /home/kerhoas/rpi-mnt
#=======================================================================
SYSROOT = --sysroot=$(RPI_FS)
CFLAGS = -Wall
EXEC_NAME = test_opencv
INCLUDES = -I$(RPI_FS)/usr/include/opencv4 -I$(RPI_FS)/usr/include/aarch64-linux-gnu -I/Includes.hpp -I/base.hpp -I/image.hpp -I/video.hpp -I/base.hpp
LIBS = -lopencv_core -lopencv_highgui -lopencv_ml -lopencv_video -lopencv_features2d -lopencv_calib3d -lopencv_objdetect -lopencv_flann -lopencv_imgcodecs -lopencv_imgproc -lopencv_videoio
LIBSDIR= -L$(RPI_FS)/usr/include/opencv4 -L$(RPI_FS)/usr/include/x86_64-linux-gnu -L$(RPI_FS)/usr/lib64
# pour compiler des libraries appelées par des libraries :
# XLINKER = -Xlinker -rpath-link=$(RPI_FS)/lib/aarch64-linux-gnu
# XLINKER += -Xlinker -rpath-link=$(RPI_FS)/usr/lib/aarch64-linux-gnu
# XLINKER += -Xlinker -rpath-link=$(RPI_FS)/opt/vc/lib
# XLINKER += -Xlinker -rpath-link=$(RPI_FS)/usr/include/opencv4
#=======================================================================
OBJ_FILES = main.o base.o image.o video.o
INSTALL_DIR = .
all : $(EXEC_NAME)
clean :
rm $(EXEC_NAME) $(OBJ_FILES)
$(EXEC_NAME) : $(OBJ_FILES)
$(CPP) $(SYSROOT) -g $(LIBSDIR) -o $(EXEC_NAME) $(OBJ_FILES) $(LIBS)
%.o: %.cpp
$(CPP) $(CFLAGS) -g $(INCLUDES) -o $@ -c $<
%.o: %.c
$(CC) $(CFLAGS) -g $(INCLUDES) -o $@ -c $<
install :
scp $(EXEC_NAME) rpi@192.168.0.2:/home/rpi
#=======================================================================
Notes :
let’s go:
$ export RPI_FS=~/rpi-mnt
$ make
aarch64-linux-gnu-g++ --sysroot=/home/kerhoas/rpi-mnt -I/home/kerhoas/rpi-mnt/usr/include/opencv4 -I/home/kerhoas/rpi-mnt/usr/include/aarch64-linux-gnu -I/Includes.hpp -I/base.hpp -Wall -g -o main.o -c main.cpp
aarch64-linux-gnu-g++ --sysroot=/home/kerhoas/rpi-mnt -I/home/kerhoas/rpi-mnt/usr/include/opencv4 -I/home/kerhoas/rpi-mnt/usr/include/aarch64-linux-gnu -I/Includes.hpp -I/base.hpp -Wall -g -o base.o -c base.cpp
aarch64-linux-gnu-g++ -Wall --sysroot=/home/kerhoas/rpi-mnt -g -L/home/kerhoas/rpi-mnt/usr/lib/aarch64-linux-gnu/ -L/home/kerhoas/rpi-mnt/lib/aarch64-linux-gnu/ -L/home/kerhoas/rpi-mnt/usr/lib64 -o test_opencv main.o base.o -lopencv_core -lopencv_highgui -lopencv_ml -lopencv_video -lopencv_features2d -lopencv_calib3d -lopencv_objdetect -lopencv_flann -lopencv_imgcodecs -lopencv_imgproc -lopencv_videoio
$ make install
scp test_opencv pi@192.168.0.2:/home/pi
test_opencv 100% 398KB 19.7MB/s 00:00
Test on Target
$ ssh -X rpi@192.168.0.2
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NOTE :
The same project for a native compiling :
Ok we compiled, but how to debug our program ( other than with printf) ?
RPI side
$ sudo apt-get install gdbserver
PC side
$ sudo apt-get install gdb-multiarch
you can get it in installations.html ( 1. IDE Eclipse / Tdb )
RPI side
$ gdbserver 192.168.0.1:2345 test_opencv B
Process test_opencv created; pid = 1514
Listening on port 2345
PC side
In the project directory, create a .tdbinit file :
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RPI side
$ gdbserver 192.168.0.1:2345 test_opencv B
Process test_opencv created; pid = 1514
Listening on port 2345
PC side
$ stm32cubeide
Eclipse:
Toogle breakpoint at the main beginning. After loading program, press F8 ( continue ), you should go to the breakpoint.
Each time you debug, don’t forget to execute gdbserver on raspberry pi.