GitHub - CHIMEFRB/ch_vdif_assembler: a multithreaded, real-time acqusition system for CHIME high-speed data.

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.gitignore		.gitignore
Makefile		Makefile
Makefile.local.example		Makefile.local.example
README		README
TODO		TODO
assembler_nerve_center.cpp		assembler_nerve_center.cpp
assembler_thread.cpp		assembler_thread.cpp
ch_vdif_assembler.hpp		ch_vdif_assembler.hpp
ch_vdif_assembler.py		ch_vdif_assembler.py
ch_vdif_assembler_cython.hpp		ch_vdif_assembler_cython.hpp
ch_vdif_assembler_cython.pyx		ch_vdif_assembler_cython.pyx
ch_vdif_assembler_internals.hpp		ch_vdif_assembler_internals.hpp
ch_vdif_assembler_kernels.hpp		ch_vdif_assembler_kernels.hpp
ch_vdif_assembler_pxd.pxd		ch_vdif_assembler_pxd.pxd
compare-to-liam-code.py		compare-to-liam-code.py
disk_reader_thread.cpp		disk_reader_thread.cpp
disk_writer_thread.cpp		disk_writer_thread.cpp
index_vdif_waterfalls.py		index_vdif_waterfalls.py
misc.cpp		misc.cpp
network_thread.cpp		network_thread.cpp
peek-at-kernels.cpp		peek-at-kernels.cpp
processing_thread.cpp		processing_thread.cpp
rfi_histogrammer.cpp		rfi_histogrammer.cpp
run-vdif-assembler.cpp		run-vdif-assembler.cpp
show-moose-acquisitions.py		show-moose-acquisitions.py
sim_thread.cpp		sim_thread.cpp
test-kernels.cpp		test-kernels.cpp
test-timestamp-unwrapper.cpp		test-timestamp-unwrapper.cpp
time-kernels.cpp		time-kernels.cpp
timing_thread.cpp		timing_thread.cpp
toy-python-assembler.py		toy-python-assembler.py
unit_testing_thread.cpp		unit_testing_thread.cpp
waterfall_plotter.cpp		waterfall_plotter.cpp

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ch_vdif_assembler: a multithreaded, real-time acqusition system for CHIME high-speed data.

This version (v2) is fast enough to keep up with a real-time
6.4 Gbps network capture, but using assembly language kernels
seems to be necessary! (see ch_vdif_assembler_kernels.hpp).

Unforuntately it's likely that as new processing tasks are
added, it may be necessary to add new assembly language kernels
if we want to run in real time. My plan is to keep doing this
on an ad hoc basis until we hopefully converge to a set of
kernels which is general enough to cover all practical cases.

This version also supports running multiple processing tasks,
which will be run in different threads. (E.g. waterfall_plotter
+ FRB search + GPU-based pulsar backend.) It can also stream
data to disk, or buffer data and save it to disk if one of the
processing tasks sets a trigger.

A few features from v1 are currently missing (most notably rfi
masks) but I hope to reinstate them soon!

A performance puzzle: the assembly-language-kernel-enabled
assembler runs 5 times faster on moose (3.5 GHz Haswell-E,
gcc 4.4.7) than on my desktop (2.4 GHz Haswell, gcc 4.8.3)!
This seems worth understanding and fixing, but I haven't gotten
to the bottom of it yet. In the meantime, if you use moose
you should be fine, but you may find poor performance on other
machines. For a performance test, do ./run-vdif-assembler -t.
This gives ~13 Gbps on moose and 2.5 Gbps on my desktop, where
6.4 Gbps is the minimum needed to keep up with a real-time
network capture.

INSTALLATION
------------

- You'll need the following prerequisites. Boost is no longer
needed but you'll need a newish C++ compiler with C++11 support.
- python
- numpy
- cython
- libpng
- libhdf5

- Create a file Makefile.local as described in comments in
Makefile.local.example. You can probably start with
cp Makefile.local.example Makefile.local'
and then edit a little from there

- You should now be able to compile with
make
make install

- To try it out, run the executable
./run-vdif-assembler
and follow the instructions!

WRITING EXTENSIONS
------------------

To integrate C++ code with ch_vdif_assembler, you'll want to
define a subclass of the virtual base class vdif_processor. For
a lot more detail, see comments in ch_vdif_assembler.hpp or
an example C++ class in waterfall_plotter.cpp.

There's also a python interface which will probably never be fast
enough for realtime processing, but may be useful for prototyping
code using captured data on disk.