CTU CAN FD is soft IP-Core written in VHDL which supports ISO and NON-ISO versions of CAN FD protocol.
CTU CAN FD is NOT a prototype. RTL is compliant with ISO 1198-1:2015. It is tested by ISO 16845-1 2016 sequence in regression run every day.
RTL is implemented with VHDL-93, synthesizable with most FPGA and ASIC flows. TB is implemented with VHDL 2008.
CTU CAN FD RTL and TB are published under following license :
Commercial usage of RTL and TB requires authors consent.
Linux driver for CTU CAN FD is published under GPLv2 license.
The CAN protocol is developed by Robert Bosch GmbH and protected by patents. Anybody who wants to implement this IP core on silicon or FPGA for commercial purposes has to obtain CAN protocol license from Bosch.
RTL design of CTU CAN FD is independent from vendor specific libraries or macros. It is fully-synchronous design (single clock domain).
FPGA / ASIC target can be selected by top level generic. ASIC target implements clock gating for memories to achieve low dynamic power consumption. Additionally, clock enables are used frequently to allow inferred clock gating on ASIC. Last but not least, RTL is DFT insertion ready and contains additional support for manufacturing testability.
Architecture of CTU CAN FD is described in:
Functional description of CTU CAN FD is described in:
CTU CAN FD has its own VIP (verification IP) with ISO 16845-1 2016 compliance sequence, which is easy to integrate to other system level test-bench. In addition to ISO 11898-1 compliance, all other features of CTU CAN FD are verified.
There are 3 types of tests available:
- Feature tests (open-source)
- Reference tests (open-source)
- Compliance tests (only binary open-source, source code available upon agreement).
TB has extensive PSL functional coverage, see regression coverage in:
GCov is used to collect (rudimentary) code coverage. See regression coverage in:
Detailed description of test-bench and CTU CAN FD VIP is in:
CTU CAN FD is also simulated on post-synthesis gate-level netlist with UNISIM library (unit delay simulation).
All tests are automated into several regression runs:
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Fast ASIC - No randomization (DUT configuration for ASIC)
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Fast FPGA - No randomization (DUT configuration for FPGA)
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Compliance short - Runs majority of ISO 11845-1 compliance test sequence
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Nightly - Randomized (DUT configuration for ASIC), all DUT configurations are tested (buffer counts, sizes, generics...)
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Compliance typ - Runs all ISO 11845-1 tests with "typical" bit-rate on CAN bus.
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Compliance max - Runs all ISO 11845-1 tests with "maximal" bit-rate on CAN bus.
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Gate level simple - Runs most of feature tests on gate level netlist as DUT
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Gate level compliance - Runs most of ISO 11845-1 tests on gate level netlist as DUT.
Short summary of results from last regression (including all test types) can be downloaded from:
Regression summary
Detailed logs are available in zipped format in "Delivery package" at: .
CTU CAN FD has been synthesized into Xilinx and Intel FPGAs on several FPGA families (Zynq, Cyclone IV/V, Spartan). BRAMs are inferred for TX and RX buffers memories. Maximal reachable frequency is around 100 MHz on Cyclone V/IV and Xilinx Zynq devices.
Daily CI pipeline executes example synthesis on Xilinx Zynq device with 3 different device configurations:
2 TXT Buffers, 32 word RX Buffer, no frame filters
Results: Area
Timing
4 TXT Buffers, 128 word RX Buffer, only one bit filter
Results: Area
Timing
8 TXT Buffers, 4096 word RX Buffer, all frame filters
Results: Area
Timing
Note that design is constrained to 100 MHz with no timing violations, combinatorial loops or latches inferred (FPGA config without clock gate is used). These results together with gate level simulations (see "Test-bench" above), provide good indicator of high-quality RTL design.
Download delivery package ("public" directory) from: . Package is created by daily regression on master branch.
Delivery package contains:
- RTL design
- Tesbench (VIP + Feature and Reference Tests)
- Binary of compliance test library.
- Documentation (Datasheet, System Architecture, Testbench)
- Regression results (with Compliance test results)
- Functional coverage results from regression
- Synthesis constraints + results of Synthesis benchmarks.
RTL CAN be easily integrated with help of document.
VIP can be easily integrated into other test-bench with help of document. Note that running compliance tests requires access to Compliance test library which is only available with commercial agreement.
If you like the design, and would like to use-it, let us know. We are looking for co-operation, especially on ISO certification which is a big step which we would need partners for. Please, respect the license, and dont use the design in your commercial device without asking first.
To simulate CTU CAN FD, following tools are used:
GHDL, VHDL simulator:
GHDL.
GTKWave, Waveform viewer:
GTKWave
Vunit, VHDL unit test framework, with modifications allowing to start GTKWave interactively when simulation run starts:
Vunit.
Python 3 and following modules: pyvcd attrs jinja2 parsy pyyaml click yattag json2html
There is a docker image which contains all dependencies needed available at:
Simulation docker.
CTU CAN FD has SocketCAN Linux driver which is described in:
Driver consists from 3 parts:
- Network
- Platform
- PCI
Driver has been tested on three boards:
Operation up to 5 Mbits was tested (depending on physical layer transceiver type).
Linux driver was debugged and tested manually against Kvaser devices, CANoe and other CAN FD controllers. Regular communication and handling of Error states were debugged manually. Automated test for latest IP core version version is run daily at CTU FEE. It pulls latest CTU CAN FD RTL and integrates them into respective Xilinx Zynq FPGA project, compiles latest SocketCAN driver and runs CAN/CAN FD communication (500 Kbit/s Nominal bit rate, 4 Mbit Data bit rate) with randomly generated frames between CTU CAN FDs and FD tolerant SJA1000. Results can be found at:..
However, there are no written tests for the driver itself (apart from compiling it without error and passing Linux kernels checkpatch which is required for pipeline to pass). In future QEMU + VPCIE + GHDL cosimulation is planned.
The CTU CAN FD IP core functional model is part of QEMU mainline. QEMU CAN documentation docs/can.txt describes CTU CAN FD emulation setup.
There are several options for further development:
- Integrations of Linux driver to mainline Linux
- Linux driver testing (QEMU + VPCIE)
- Splitting design into two clock domains
- Support of TTCAN protocol
- Support of CAN XL protocol
- Other features