1 | Embedded systems (SoC and MPSoC) became an inevitable evolution in the microelectronic industry. |
---|
2 | Due to the exploding fabrication costs, the ASIC technology (Application Specific Integrated Circuit) |
---|
3 | is not an option for SMEs (Small and Medium Enterprises). |
---|
4 | Fortunately, the new FPGA (Field Programmable Gate Array) components, |
---|
5 | such as the Virtex5 family from \xilinx, or the Stratix4 family from \altera can implement a complete |
---|
6 | multi-processor architecture on a single device. |
---|
7 | But the design of embedded system is a long and complex task that requires expertise in software, |
---|
8 | software/hardware partionning, operating system, hardware design, VHDL/Verilog modeling. |
---|
9 | Only very few SMEs have these multiple expertises and are present on the embedded system market. |
---|
10 | Furthermore, even small design services in the big companies are facing the same issue. |
---|
11 | \begin{center}\begin{minipage}{.8\linewidth}\textit{ |
---|
12 | The major objective of COACH is to provide to system designers, an affordable |
---|
13 | open-source framework to design embedded systems on FPGA devices. |
---|
14 | }\end{minipage}\end{center} |
---|
15 | %Current design methodologies provide quite low-level abstraction capabilities, and |
---|
16 | %there is an urgent need to leverage system level exploration through the use of a high-level |
---|
17 | %specification of the application and design space exploration tools. |
---|
18 | %The first system oriented approaches are appearing, among which those |
---|
19 | %based on C/C++ and SystemC are the most popular, but few of them are specifically targetting FPGAs. |
---|
20 | %%% |
---|
21 | \parlf |
---|
22 | The COACH project will propose a new design flow based on a small number of architectural templates. |
---|
23 | An architectural template is a generic, parameterized architecture, relying on a predefined library |
---|
24 | of IP cores. |
---|
25 | Besides using a specific collection of general purpose IP cores (such as processors cores, |
---|
26 | embedded memory controllers, system bus controllers, I/O and peripheral controllers), each architectural |
---|
27 | template can be enriched by dedicated hardware coprocessors, obtained by high level synthesis (HLS) tools. |
---|
28 | During this project, the COACH partners will develop three different architectural templates: |
---|
29 | \begin{enumerate} |
---|
30 | \item An \altera architectural template based on the \altera IP core library, |
---|
31 | the AVALON system bus and the NIOS processor. |
---|
32 | \item A \xilinx architectural template based on the \xilinx IP core library, the |
---|
33 | \xilinxbus system bus and the \xilinxcpu processor. |
---|
34 | \item A Neutral architectural template based on the SoCLib IP core library and the VCI/OCP |
---|
35 | communication infrastructure. |
---|
36 | \end{enumerate} |
---|
37 | %The proposed design flow starts from a high level description of the application, specified as a set of |
---|
38 | %parallel tasks written in C, without any assumption on the hardware or software implementation |
---|
39 | %of these tasks. It lets the system |
---|
40 | %designer in charge of expressing the coarse grain parallelism of the application, gives the designer |
---|
41 | %the possibility to explore various mapping of the application on the selected template architecture, |
---|
42 | %and offers a high predictability of results with respect to cost and performance objectives. |
---|
43 | %\\ |
---|
44 | %When this interactive, system level, design space exploration is completed (converging to |
---|
45 | %a specific mapping on a specific version of the selected architectural template), the rest of the flow |
---|
46 | %is fully automated: the synthesizable VHDL models for the various hardware components, as well as the binary |
---|
47 | %code for the software running on the embedded processors, and the bit-stream to program the target FPGA |
---|
48 | %will be automatically generated by the COACH tools. |
---|
49 | %% |
---|
50 | %\parlf |
---|
51 | %The strength of the COACH approach is the strong integration of the high-level synthesis tools |
---|
52 | %in a platform based design flow supporting virtual prototyping and design space exploration. |
---|
53 | %Most building blocks already exist (resulting from previous projects): the GAUT |
---|
54 | %or UGH synthesis tools, the DNA embedded operating systems, the ASIP technology, |
---|
55 | %the DSX exploration tool, the MWMR hardware/software communication middleware, the BEE parallelization tool, |
---|
56 | %as well as the SoCLib library of SystemC simulation models. |
---|
57 | %They must now be enhanced and integrated in a consistent design flow: this will |
---|
58 | %be done in Magillem framework thanks to the IP-XACT standard. |
---|
59 | %%The five academic laboratories worked very closely during more than one year (one monthly meeting |
---|
60 | %%in Paris from january 2009 to february 2010, to analyse the issues of interfacing and integrating |
---|
61 | %%those various technologies, and to define the detailed architecture of the proposed design flow. |
---|
62 | %%%% |
---|
63 | \parlf |
---|
64 | In HPC (High Performance Computing), the targeted application is an existing one |
---|
65 | running on a PC. |
---|
66 | The COACH framework helps designer to accelerate it by migrating critical parts into a |
---|
67 | SoC embedded into an FPGA device plugged to the PC PCI/X bus. |
---|
68 | \begin{center}\begin{minipage}{.8\linewidth}\label{HPC:definition}\textit{ |
---|
69 | The second objective of COACH is to extend the framework for HPC applications. |
---|
70 | }\end{minipage}\end{center} |
---|
71 | This will allow SMEs to enter HPC market for the applications that are |
---|
72 | unadapted to the current GPU based solutions. |
---|
73 | \parlf |
---|
74 | Coach generates SoC which is part of larger system. Thus it's important to take in account the existing industrial design flow. For this reason COACH will use the IP-XACT IEEE 1685 standard for packaging these generated SoC. |
---|
75 | \begin{center}\begin{minipage}{.8\linewidth}\textit{ |
---|
76 | The third objective of COACH is to facilitate the integration of generated SoC in global system design flow. |
---|
77 | }\end{minipage}\end{center} |
---|
78 | %%% |
---|