I want to speed up computing of some math algorithms working on financial instrument's prices. Is this FPGA something appropriate? How does it compare with other FPGA? Should I stick to CUDA maybe rather than bother with FPGA (but still I would like to learn gate programming so I am keen to buy it). Is this right choice or are there better price/quality choices? How much complicated programs it can handle? Can I use C++ libraries (like QuantLib) and compile the code into the chip?

Nexys 2 1200K FPGA Xilinx Spartan-3E

info: http://kamami.pl/index.php?ukey=product&productID=59726

Key Features:

Xilinx Spartan-3E FPGA 1200K gate
USB2 port providing board power, device configuration, and high-speed data transfers
Works with ISE/Webpack and EDK
16MB fast Micron PSDRAM
16MB Intel StrataFlash Flash R
Xilinx Platform Flash ROM
High-efficiency switching power supplies (good for battery-powered applications
50MHz oscillator, plus a socket for a second oscillator
75 FPGA I/O's routed to expansion connectors (one high-speed Hirose FX2 connector with 43 signals and four 2x6 Pmod connectors)
All I/O signals are ESD and short-circuit protected, ensuring a long operating life in any environment.
On-board I/O includes eight LEDs, four-digit seven-segment display, four pushbuttons, eight slide switches
Ships in a DVD case with a high-speed USB2 cable

is there a similar tool available for C++? http://blogs.msdn.com/b/satnam_singh/archive/2010/10/15/compiling-c-programs-into-fpga-circuits-factorial-example.aspx

it seems there are such tools: http://www.fpgarelated.com/usenet/fpga/show/21843-1.php

can I convert to Verilog or VHDL C++ code that uses external C++ library?

closed as off topic by ethrbunny, Robert Crovella, talonmies, Blastfurnace, Graviton Mar 1 '13 at 9:57

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  • Understand the problem and the bottleneck. Then see if a hardware solution is viable. If you are trying to minimize latency (as financial people seem to be) then you'll get best performance from the highest-end, fastest speed-grade Virtex. As an educational tool, that board will be fine though. – Martin Thompson Feb 25 '13 at 16:03

It's a good one to learn but I doubt you will get anywhere near a decent CUDA card on floating point performance (note that the Spartan-3 is several generations out of date by now).

And no, you can't take a C++ library and compile it into an FGPA design.

  • thanks, so what do you do when you want to put into an FPGA something that you have implemented i.e. in C++? do you have to translate everything by yourself into HDL? – 4pie0 Feb 22 '13 at 13:10
  • or should I look rather for microcontroller? – 4pie0 Feb 22 '13 at 14:33
  • A microcontroller is on a completely different floating point throughput scale (if it does floating point at all). Even your CPU would be faster, not to mention the GPU. – tera Feb 22 '13 at 22:01
  • And if you want performance, you cannot avoid reconsidering what the library does and reimplementing it in a HDL. There are some tools for that (google for systemC, autoESL or FCUDA), but you can't expect to just feed arbitrary C++ code to them and have it work, let alone run faster than on a GPU with CUDA). – tera Feb 22 '13 at 22:11
  • well, links attached in my question shows there exist such tools. here is more about it: 1 , 2 – 4pie0 Feb 23 '13 at 16:49

I've found a nice source of info here: 1 , 2

and here:

“We’re now seeing vendors embracing the full power of the chip,” states Perrett.

“Traditionally they offered developers a blank canvas, then they adopted an approach whereby various cores were added, like MegaWizard from Altera and CORE Gen from Xilinx, which were well-known, well-established constructs around things like FIFO (first-in-first-out). That was great because you could build a design quite easily using this ‘Lego’. But what it didn’t really do was offer a multi-faceted algorithm development platform. Yes, you had ANDs, ORs and other arithmetic operators, but trying to build up logical or algorithmic expressions using individual components can end up being quite weighty and not really optimised. So to do anything clever like standard deviation, you were basically on your own and had to develop it yourself.”

That situation is now changing, according to Perrett.

“What we’re seeing now is an encapsulation of some of these algorithms offered by the vendors themselves,” he says. “Which means that in the future firms like ours can look at offering out algorithm development, either as a professional services undertaking or via our own API, which customers can hook into as part of the EMS platform.”

Doing things like standard deviation can involve floating point processing, which is an area where FPGAs have traditionally been weak, although FPGA chip vendors like Altera have been doing a lot of work in their tool chain to support floating point development, using IEEE 754, the floating point format for math coprocessors.

However, according to Ron Huizen, Vice President of Technology at BittWare, a provider of FPGA computing systems, doing floating point designs in FPGAs can still be a time consuming development, which is why his firm has come up with an alternative approach.

“Floating point in FPGA can provide a tremendous amount of performance, but it is not that easy to do for complex algorithms”, states Huizen. “So we’ve invested in what we call a floating point co-processor for FPGA, the Anemone, which is actually a small, very low power, many-core, C-programmable processor designed to sit beside an FPGA so you can offload floating point to it and write C code to control it. That way you can optimize the more straightforward parts of your algorithms in pure FPGA, and leave the complex parts, or those that change often, in C on the programmable co-processor”.

This differs from most other approaches, according to Huizen.

“Other people have gone down the route of having the programmable processor as the centre with the FPGA on the periphery, but because we work primarily in FPGA, we see it the other way around. We’ve deliberately made this co-processor small, low power and very high performance because we don’t care about all the other interfaces, that’s what the FPGA itself is for. If you look at a typical Texas Instruments co-processor, it’s a big, power-hungry chip that has PCIe, 10GbE and all these interfaces built in, whereas all we have is a very small chip with external ports that connect to the FPGA and then have 16 cores that just run flat-out. So we get 24 gigaFLOPS in under 1 watt of total core power.

“The guys who are doing the pure network interface stuff probably don’t care as much about floating point as the ones who are doing hardware acceleration and risk analysis”, suggests Huizen, “but for people trying to put their big algorithms on the FPGA, there are some things that are still hard to do in FPGA. So with this approach, where there’s a lot of decision-making going on or if there are things that change very often, they can put that into C code and run it in the Anemone co-processor instead.

“We’re seeing a lot of interest in this from people in the finance space, because it means they can do the decisions in the FPGA space instead of sending them up into the Intel CPU over the PCIe bus, where there’s latency and Linux has to deal with it. By having the Anemone processor sitting directly aside the FPGA, they can put some decision-making down there and have it close to the hardware but still write it in C code”, says Huizen, “They’ve recognized that the Anemone coprocessor is really 16 little RISC engines that can run any code, it doesn’t have to be floating point based. So essentially you get to run 16 control threads in parallel with no context switching.”

another solution: http://www.bittware.com/products-services-value-add-products-for-fpga/anemone104-co-processor-for-fpgas

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