README - Georgia Tech Smoothing and Mapping library
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What is GTSAM ?
GTSAM is a library of C++ classes that implement smoothing and
mapping (SAM) in robotics and vision, using factor graphs and Bayes
networks as the underlying computing paradigm rather than sparse
matrices. A set of MATLAB mex wrappers is also included.
GTSAM is not (yet) open source: See COPYING & LICENSE
Please see USAGE for an example on how to use GTSAM.
The code is organized according to the following directory structure:
3rdparty local copies of third party libraries - Eigen3 and CCOLAMD
base provides some base Math and data structures, as well as test-related utilities
geometry points, poses, tensors, etc
inference core graphical model inference such as factor graphs, junction trees, Bayes nets, Bayes trees
linear inference specialized to Gaussian linear case, GaussianFactorGraph etc...
nonlinear non-linear factor graphs and non-linear optimization
slam SLAM and visual SLAM application code
All of the above contain code and tests, and build local shared libraries that are then
bundled in a top-level shared library libgtsam.la. After this is built, you can also run
the more involved tests, which test the entire library:
tests more involved tests that depend on slam
Finally, there are some local libraries built needed in the rest of the code:
CppUnitLite unit test library
doc documentation
m4 local M4 macros
Important Installation Notes Specific to GTSAM
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1)
GTSAM requires the following libraries to be installed on your system:
- BOOST version 1.40 or greater (install through Linux repositories or MacPorts)
2)
GTSAM makes extensive use of debug assertions, even for checking input of
the functions you will call. These assertions are disabled when NDEBUG is
defined. Thus, we strongly recommend compiling GTSAM and your own code without
this symbol during debugging.
After debugging, GTSAM will run much faster when compiled with NDEBUG defined,
so that debug checks are disabled.
Another useful debugging symbol is _GLIBCXX_DEBUG, which enables debug checks
and safe containers in the standard C++ library and makes problems much easier
to find.
NOTE: The native Snow Leopard g++ compiler/library contains a bug that makes
it impossible to use _GLIBCXX_DEBUG. MacPorts g++ compilers do work with it though.
3)
Putting the above together, here are some sample ./configure commands for
compiling gtsam:
For Debugging (native Snow Leopard g++ compiler):
./configure CXXFLAGS="-fno-inline -g -Wall" \
LDFLAGS="-fno-inline -g -Wall"
For Debugging (Linux or MacPorts g++ compilers):
./configure CXXFLAGS="-fno-inline -g -Wall -D_GLIBCXX_DEBUG" \
LDFLAGS="-fno-inline -g -Wall"
For Performance:
./configure CXXFLAGS="-DNDEBUG -O3" LDFLAGS="-O3" --with-toolbox=$HOME/toolbox/
After that (this would be for an in-source build, see next for out-of-source):
$ make
$ make check (optional, runs unit tests)
$ make install
Out-of-source build:
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The above will put object files and executables in the source directories. If you like, it is
very easy to configure the libraries to put all these in a parallel build tree so they do not
clutter the source tree. To do this, instead of running configure in the gtsam directory itself,
run it in sub-directory of choice, e.g., starting out in the main GTSAM folder:
$] mkdir build
$] cd build
$] ../configure ..... (command as above)
$] make install
Built-in Unit Tests:
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There is one more optional step in which you can invoke the unit tests included in the gtsam libraries.
$] make check
By verifying all the test results are positive, you can make sure that the functionalities of the GTSAM
libraries are correct.
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