I've updated from the old 3.12.61 kernel to the latest stable 4.4.14 kernel. If you have used the old kernel you'll have to run "update.sh" as described below in the build section.
This is a port of Linux and buildroot to the OWON SDS7102 oscilloscope. The CPU part of the scope is a Samsung S3C2416 system on a chip (SoC) with a bit of memory and a connection to a Xilinx Spartan 6 FPGA which performs most of the signal processing.
I have written a long series of blog posts about how I have reverse engineered the scope and ported Linux to it. The first blog post in the series is here.
Status so far:
Linux boots on the scope together with a buildroot based ramdisk and supports most of the hardware connected to the SoC:
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LCD display is functional
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USB host (full speed) is functional
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USB slave (full speed and high speed) is functional
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Ethernet (10/100 MBit) is functional. I haven't been able to get the hsspi driver to work so it uses the bitbanging spi-gpio driver for the moment. This will use a lot of CPU and limit the ethernet performance.
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The VGA output does not work. The Chrontel VGA controller has to be configured first.
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It's possible to configure the FPGA from the SoC using the Xilinx Slave Serial protocol. The SoC DDR2 memory bus is supposed to provide a high speed bus to the FPGA from the Soc but is not working yet. Three of the GPIO pins used for configuration can be used to communicate with the FPGA when the bitstream has been loaded. This is slow but works.
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I've made some progress on getting the SoC bus and DDR memory controller on the FPGA working. The SoC bus is readonly and for the moment I can't use the SoC bus and the DDR controller in the same FPGA image at the same time (they use the same clock and I need to figure out how to share the clock between them).
This project depends on a couple of other projects. The biggest ones are the following:
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A Linux distribution and all the tools that comes with it. I'm using Linux Mint 17.3, but any modern distribution should do. You'll have to install this on your own and make sure that gcc, make, git and some other things are installed. I don't know exactly what is needed but the build will fail and you'll have to figure it out if that happens.
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You will need about 5.5 gigabytes of free disk space. About 2.5 gigabytes for buildroot, 2.5 gigabytes for the Linux kernel and couple of hundred megabytes for all the rest, downloads in the dl directory, myhdl, rhea and a few more things.
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buildroot provides an ARM toolchain and a ramdisk with useful tools. buildroot is branched from the tag "2015.05" of the Busybox git repository. Buildroot in turn includes hudreds of other projects such as busybox and uclibc that are very useful on an embedded system.
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The Linux kernel provides most of the hardware support. It is branched from the tag "v4.4.14" of the Linux stable git repository. This was the newest longtime kernel in the stable tree at the moment.
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MyHDL is a Python based hardware description language (HDL) which is used some FPGA images that are used for testing. It is branched from the master at that time from the MyHDL git repository.
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Rhea is a collection of MyHDL cores and tools. It is mostly used for some build scripts that produce Spartan 6 bitstream images from my MyHDL test programs. It is branched from the master at that time from the Rhea git repository.
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If you want to rebuild the FPGA image you will need the Xilinx ISE Design Sofware for Linux.
buildroot, linux, myhdl and rhea are automatically downloaded when you run the build script.
Xilinx has a free version of the Xilinx ISE called WebPACK which can be used to synthesize the FPGA image. Download it from their web site. You will need a Xilinx account and a free license key to be able to use it. Install ISE according to their instructions.
Source the settings script and make sure that you can run the ISE desktop. On my Linux machine ISE 14.7 is installed in /opt/Xilinx and run the following commands:
. /opt/Xilinx/14.7/ISE_DS/settings64.sh
ise
If everything works as it should this should start the ISE Project Navigator. If you haven't installed the license key yet, ISE will complain about that.
To get a copy of this project, clone it from github with:
git clone https://github.com/wingel/sds7102.git
cd sds7102
If you have cloned this repository before you might have old versions. To get the latest version, run the following script:
./update.sh
I've just updated the Linux kernel to 4.4.14, if you were using the old 3.12 kernel you will have to remove the .config file in the Linux directory:
rm linux/.config
Use the following command to download all dependencies (such as the Linux kernel) and then build everything:
./build.sh
On my machine, an Intel i7-2600 with 32Gbytes of RAM and a Samsung 850 EVO SSD, a clean build from scratch takes about 10 minutes.
If you have sourced the Xilinx ISE settings file, the build script will automatically detect that the XILINX environment variable is set and synthesize a FPGA image from source, otherwise it will use the prebuilt image from "misc/sds7102.bin".
Since synthesizing an FPGA image takes a long time the script will only do it once even if the FPGA sources have changed. If you want to resynthesize the FPGA image, remove "fpga/myhdl/wishbone/xilinx/sds7102.bin" and run "build.sh" again.
If you are working on the Linux drivers or the applications you can rebuild only those parts by running make in the respective directories.
cd apps
make
cd drivers
make
I'm using ccache to speed up repeated builds. This is because I like to do a "git clean -fdx" followed by "./build.sh" to see if everything builds correctly from scratch. I have placed the ccache directory under the .git directory so that it won't be removed when I do the "git clean". If you have changed the compiler options in buildroot (for example the ABI or floating point options) and want to make sure that the new compiler is used, you can remove the ccache directory:
rm -rf .git/ccache
For the moment you will need a JTAG adapter that works with openocd to load Linux on the SDS7102. I use a Bus Blaster MIPS just because I had one lying around.
You will need to connect your JTAG adapter to the JTAG pads on the main board on the SDS7102. I have written a bit about how to do it here.
It's also a very good idea to be able to see the output from the serial console which I've written a bit about here
I use a FTDI FT-232R-3V3 cable which I've connected to the serial port. In that case the colors of the wires shown in the picture in my blog post match the colors of the wires on the FTDI cable.
Since Linux is loaded into RAM this does not affect the OWON firmware in flash. You can just power off and on the scope to use the normal firmware. There is of course a risk that a bug in the kernel will mess up the flash, or if you manage to somehow use the MTD devices in Linux to write to flash memory, but I haven't managed to mess up my scope so far.
To load Linux, modify the first line of the script host/boot-jtag.sh to match your JTAG adapter and if you have built everything as shown above you should be able to just run the script to download Linux into RAM on the SDS7102 and execute it:
./host/boot-jtag.sh
If you are successful you should see something like this on the serial console and the Linux penguin should show up on the display of the scope. If it fails, try again.
SamSung MCU S3C2440
Program Ver 1.0(2006613)
FCLK = 400000000Hz, USB Crystal Type : 12M
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* LOADBOOT *
* *
* LILLIPUT *
* (2004) *
****************************
Boot to load (Y/N)?
Wait for Enter . . . . . . . . . . . . . . . . . . . . . . .
******************************
LILLIPUT
Uncompressing Linux... done, booting the kernel.
Warning: Neither atags nor dtb found
Booting Linux on physical CPU 0x0
Linux version 3.12.61+ (wingel@zoo) (gcc version 4.8.4 (Buildroot 2015.05) ) #1 Fri Jul 15 18:50:24 CEST 2016
CPU: ARM926EJ-S [41069265] revision 5 (ARMv5TEJ), cr=00053177
TODO I really should make the display the default console so that you can just connect a keyboard to the USB port and use the scope as a small Linux computer.
If you have an ethernet cable connected the scope will request an IP address using DHCP and you should be able to log into the scope using ssh. My scope ends up on IP 192.168.1.42, so this is how I do it:
the default password is "root".
Run the initialization script:
./init-sds.sh
This loads a couple of device drivers and loads the FPGA image.
If any GPIO pins on the SoC change a message will be printed to the console with information about what has changed.
To watch for changes on the FPGA pins, run the "activity" application which reads the edge counters from the FPGA.
fpga.ko is a driver which can be used to load an FPGA image into the Xilinx FPGA. To load an FPGA image, first insmod the kernel module and copy the FPGA .bin or .bit file to /dev/fpga:
insmod fpga.ko
cat sds7102.bin >/dev/fpga
This is done if you run the init-sds.sh script.
gpios.ko is the device driver I used to find GPIO pins on the SoC. Just insmod the kernel module and it will print a message to the console when one of the GPIO pins that are listed in the source has changed state.
insmod gpios.ko
This is also done if you run the init-sds.sh script.
regs.ko is a device driver for accessing registes in my FPGA image using a SPI-like bus which uses three of the pins that are normally used for configuring the FPGA.
insmod regs.ko
This is also done if you run the init-sds.sh script.
activity is an application that reads out the edge counter for the pins of the FPGA and prints it every second:
./activity
sds-server is an application which is used by the host tools to access resources on the scope. It can currently modify GPIO pins (using the /sys/class/gpio interface in the Linux kernel) and access registers on the FPGA. To see how it works, look at the source or host/sds.py.
The firmware can now capture samples from the ADC and control the analog frontend. This means that you can make a capture without ever having to boot the OWON firmware. To do that, run the capture application on a Linux PC:
./host/capture.py root@scope-ip-address
The capture application will log onto the scope using ssh and run the "sds-server" application which gives acess to the registers and the GPIOs on the scope. Unless you have set up public key login as described below you will have to enter the password for the scope, "root". If everything goes well you should get a screen showing a waveform. You can play around with the settings in capture.py to see how they affect the capture. You'll need the data sheets for the components in the AFE to know how to change some of the values.
It's possible to trace the SoC bus signals using host/trace_soc.py. Run it like this:
./host/trace_soc.py root@scope-ip-address
It will write a called "soc.vcd" will be visualised with gtkwave:
gtkwave soc.vcd
There is some code called "soc_frob" in drivers/regs.c which tries to generate test patterns on the SoC bus.
Sometimes it can be useful to use ISE to synthesize an image from sds7102.v and sds7102.ucf created by image.py. There is an ISE project in fpga/ise/wishbone with symlinks to the MyHDL generated files. After running "image.py" to generate those files, open the ise/wishbone project in ISE and synthesize the normal way. This way you can look at the floorplan and other things that are hard to do outside of ISE.
The scope will generate a new ssh host key every time it boots which can be a bit frustrating since ssh will warn about it changing. To work around that I have the following lines in my $HOME/.ssh/config which tells ssh not to check the host keys, to log in as the root user and also adds a symbolic name for the IP address:
Host sds
HostName 192.168.1.42
User root
UserKnownHostsFile /dev/null
StrictHostKeyChecking no
After this I can just log onto the scope like this:
ssh sds
Another thing you can do is to set up public key authentication on the scope so that you don't have to type a password every time you log in.
If you haven't done so before, use "ssh-keygen" to create a new ssh key. Then add the key to the list of users that are authorized to log in using public key authentication in the template for the ramdisk:
cat $HOME/.ssh/id_rsa.pub >>overlay/root/.ssh/authorized_keys
and then rebuild the image with:
./build.sh
Boot the new image and you should automatically be logged in when you ssh to the scope.