docs/source/solving_faqs.rst - ceres-solver - Git at Google

 .. _chapter-solving_faqs:

 .. default-domain:: cpp

 .. cpp:namespace:: ceres

 =======
 Solving
 =======

 #. How do I evaluate the Jacobian for a solved problem?

    Using :func:`Problem::Evaluate`.

 #. How do I choose the right linear solver?

    When using the ``TRUST_REGION`` minimizer, the choice of linear
    solver is an important decision. It affects solution quality and
    runtime. Here is a simple way to reason about it.

    1. For small (a few hundred parameters) or dense problems use
       ``DENSE_QR``.

    2. For general sparse problems (i.e., the Jacobian matrix has a
       substantial number of zeros) use
       ``SPARSE_NORMAL_CHOLESKY``. This requires that you have
       ``SuiteSparse`` or ``CXSparse`` installed.

    3. For bundle adjustment problems with up to a hundred or so
       cameras, use ``DENSE_SCHUR``.

    4. For larger bundle adjustment problems with sparse Schur
       Complement/Reduced camera matrices use ``SPARSE_SCHUR``. This
       requires that you build Ceres with support for ``SuiteSparse``,
       ``CXSparse`` or Eigen's sparse linear algebra libraries.

       If you do not have access to these libraries for whatever
       reason, ``ITERATIVE_SCHUR`` with ``SCHUR_JACOBI`` is an
       excellent alternative.

    5. For large bundle adjustment problems (a few thousand cameras or
       more) use the ``ITERATIVE_SCHUR`` solver. There are a number of
       preconditioner choices here. ``SCHUR_JACOBI`` offers an
       excellent balance of speed and accuracy. This is also the
       recommended option if you are solving medium sized problems for
       which ``DENSE_SCHUR`` is too slow but ``SuiteSparse`` is not
       available.

       .. NOTE::

         If you are solving small to medium sized problems, consider
         setting ``Solver::Options::use_explicit_schur_complement`` to
         ``true``, it can result in a substantial performance boost.

       If you are not satisfied with ``SCHUR_JACOBI``'s performance try
       ``CLUSTER_JACOBI`` and ``CLUSTER_TRIDIAGONAL`` in that
       order. They require that you have ``SuiteSparse``
       installed. Both of these preconditioners use a clustering
       algorithm. Use ``SINGLE_LINKAGE`` before ``CANONICAL_VIEWS``.

 #. Use :func:`Solver::Summary::FullReport` to diagnose performance problems.

    When diagnosing Ceres performance issues - runtime and convergence,
    the first place to start is by looking at the output of
    ``Solver::Summary::FullReport``. Here is an example

    .. code-block:: bash

      ./bin/bundle_adjuster --input ../data/problem-16-22106-pre.txt

      iter      cost      cost_change  |gradient|   |step|    tr_ratio  tr_radius  ls_iter  iter_time  total_time
         0  4.185660e+06    0.00e+00    2.16e+07   0.00e+00   0.00e+00  1.00e+04       0    7.50e-02    3.58e-01
         1  1.980525e+05    3.99e+06    5.34e+06   2.40e+03   9.60e-01  3.00e+04       1    1.84e-01    5.42e-01
         2  5.086543e+04    1.47e+05    2.11e+06   1.01e+03   8.22e-01  4.09e+04       1    1.53e-01    6.95e-01
         3  1.859667e+04    3.23e+04    2.87e+05   2.64e+02   9.85e-01  1.23e+05       1    1.71e-01    8.66e-01
         4  1.803857e+04    5.58e+02    2.69e+04   8.66e+01   9.93e-01  3.69e+05       1    1.61e-01    1.03e+00
         5  1.803391e+04    4.66e+00    3.11e+02   1.02e+01   1.00e+00  1.11e+06       1    1.49e-01    1.18e+00

      Ceres Solver v1.12.0 Solve Report
      ----------------------------------
                                           Original                  Reduced
      Parameter blocks                        22122                    22122
      Parameters                              66462                    66462
      Residual blocks                         83718                    83718
      Residual                               167436                   167436

      Minimizer                        TRUST_REGION

      Sparse linear algebra library    SUITE_SPARSE
      Trust region strategy     LEVENBERG_MARQUARDT

                                              Given                     Used
      Linear solver                    SPARSE_SCHUR             SPARSE_SCHUR
      Threads                                     1                        1
      Linear solver threads                       1                        1
      Linear solver ordering              AUTOMATIC                22106, 16

      Cost:
      Initial                          4.185660e+06
      Final                            1.803391e+04
      Change                           4.167626e+06

      Minimizer iterations                        5
      Successful steps                            5
      Unsuccessful steps                          0

      Time (in seconds):
      Preprocessor                            0.283

        Residual evaluation                   0.061
        Jacobian evaluation                   0.361
        Linear solver                         0.382
      Minimizer                               0.895

      Postprocessor                           0.002
      Total                                   1.220

      Termination:                   NO_CONVERGENCE (Maximum number of iterations reached.)

   Let us focus on run-time performance. The relevant lines to look at
   are


    .. code-block:: bash

      Time (in seconds):
      Preprocessor                            0.283

        Residual evaluation                   0.061
        Jacobian evaluation                   0.361
        Linear solver                         0.382
      Minimizer                               0.895

      Postprocessor                           0.002
      Total                                   1.220


   Which tell us that of the total 1.2 seconds, about .3 seconds was
   spent in the linear solver and the rest was mostly spent in
   preprocessing and jacobian evaluation.

   The preprocessing seems particularly expensive. Looking back at the
   report, we observe

    .. code-block:: bash

      Linear solver ordering              AUTOMATIC                22106, 16

   Which indicates that we are using automatic ordering for the
   ``SPARSE_SCHUR`` solver. This can be expensive at times. A straight
   forward way to deal with this is to give the ordering manually. For
   ``bundle_adjuster`` this can be done by passing the flag
   ``-ordering=user``. Doing so and looking at the timing block of the
   full report gives us

    .. code-block:: bash

      Time (in seconds):
      Preprocessor                            0.051

        Residual evaluation                   0.053
        Jacobian evaluation                   0.344
        Linear solver                         0.372
      Minimizer                               0.854

      Postprocessor                           0.002
      Total                                   0.935


   The preprocessor time has gone down by more than 5.5x!.
	.. _chapter-solving_faqs:

	.. default-domain:: cpp

	.. cpp:namespace:: ceres

	=======
	Solving
	=======

	#. How do I evaluate the Jacobian for a solved problem?

	Using :func:`Problem::Evaluate`.

	#. How do I choose the right linear solver?

	When using the ``TRUST_REGION`` minimizer, the choice of linear
	solver is an important decision. It affects solution quality and
	runtime. Here is a simple way to reason about it.

	1. For small (a few hundred parameters) or dense problems use
	``DENSE_QR``.

	2. For general sparse problems (i.e., the Jacobian matrix has a
	substantial number of zeros) use
	``SPARSE_NORMAL_CHOLESKY``. This requires that you have
	``SuiteSparse`` or ``CXSparse`` installed.

	3. For bundle adjustment problems with up to a hundred or so
	cameras, use ``DENSE_SCHUR``.

	4. For larger bundle adjustment problems with sparse Schur
	Complement/Reduced camera matrices use ``SPARSE_SCHUR``. This
	requires that you build Ceres with support for ``SuiteSparse``,
	``CXSparse`` or Eigen's sparse linear algebra libraries.

	If you do not have access to these libraries for whatever
	reason, ``ITERATIVE_SCHUR`` with ``SCHUR_JACOBI`` is an
	excellent alternative.

	5. For large bundle adjustment problems (a few thousand cameras or
	more) use the ``ITERATIVE_SCHUR`` solver. There are a number of
	preconditioner choices here. ``SCHUR_JACOBI`` offers an
	excellent balance of speed and accuracy. This is also the
	recommended option if you are solving medium sized problems for
	which ``DENSE_SCHUR`` is too slow but ``SuiteSparse`` is not
	available.

	.. NOTE::

	If you are solving small to medium sized problems, consider
	setting ``Solver::Options::use_explicit_schur_complement`` to
	``true``, it can result in a substantial performance boost.

	If you are not satisfied with ``SCHUR_JACOBI``'s performance try
	``CLUSTER_JACOBI`` and ``CLUSTER_TRIDIAGONAL`` in that
	order. They require that you have ``SuiteSparse``
	installed. Both of these preconditioners use a clustering
	algorithm. Use ``SINGLE_LINKAGE`` before ``CANONICAL_VIEWS``.

	#. Use :func:`Solver::Summary::FullReport` to diagnose performance problems.

	When diagnosing Ceres performance issues - runtime and convergence,
	the first place to start is by looking at the output of
	``Solver::Summary::FullReport``. Here is an example

	.. code-block:: bash

	./bin/bundle_adjuster --input ../data/problem-16-22106-pre.txt

	iter cost cost_change \|gradient\| \|step\| tr_ratio tr_radius ls_iter iter_time total_time
	0 4.185660e+06 0.00e+00 2.16e+07 0.00e+00 0.00e+00 1.00e+04 0 7.50e-02 3.58e-01
	1 1.980525e+05 3.99e+06 5.34e+06 2.40e+03 9.60e-01 3.00e+04 1 1.84e-01 5.42e-01
	2 5.086543e+04 1.47e+05 2.11e+06 1.01e+03 8.22e-01 4.09e+04 1 1.53e-01 6.95e-01
	3 1.859667e+04 3.23e+04 2.87e+05 2.64e+02 9.85e-01 1.23e+05 1 1.71e-01 8.66e-01
	4 1.803857e+04 5.58e+02 2.69e+04 8.66e+01 9.93e-01 3.69e+05 1 1.61e-01 1.03e+00
	5 1.803391e+04 4.66e+00 3.11e+02 1.02e+01 1.00e+00 1.11e+06 1 1.49e-01 1.18e+00

	Ceres Solver v1.12.0 Solve Report
	----------------------------------
	Original Reduced
	Parameter blocks 22122 22122
	Parameters 66462 66462
	Residual blocks 83718 83718
	Residual 167436 167436

	Minimizer TRUST_REGION

	Sparse linear algebra library SUITE_SPARSE
	Trust region strategy LEVENBERG_MARQUARDT

	Given Used
	Linear solver SPARSE_SCHUR SPARSE_SCHUR
	Threads 1 1
	Linear solver threads 1 1
	Linear solver ordering AUTOMATIC 22106, 16

	Cost:
	Initial 4.185660e+06
	Final 1.803391e+04
	Change 4.167626e+06

	Minimizer iterations 5
	Successful steps 5
	Unsuccessful steps 0

	Time (in seconds):
	Preprocessor 0.283

	Residual evaluation 0.061
	Jacobian evaluation 0.361
	Linear solver 0.382
	Minimizer 0.895

	Postprocessor 0.002
	Total 1.220

	Termination: NO_CONVERGENCE (Maximum number of iterations reached.)

	Let us focus on run-time performance. The relevant lines to look at
	are


	.. code-block:: bash

	Time (in seconds):
	Preprocessor 0.283

	Residual evaluation 0.061
	Jacobian evaluation 0.361
	Linear solver 0.382
	Minimizer 0.895

	Postprocessor 0.002
	Total 1.220


	Which tell us that of the total 1.2 seconds, about .3 seconds was
	spent in the linear solver and the rest was mostly spent in
	preprocessing and jacobian evaluation.

	The preprocessing seems particularly expensive. Looking back at the
	report, we observe

	.. code-block:: bash

	Linear solver ordering AUTOMATIC 22106, 16

	Which indicates that we are using automatic ordering for the
	``SPARSE_SCHUR`` solver. This can be expensive at times. A straight
	forward way to deal with this is to give the ordering manually. For
	``bundle_adjuster`` this can be done by passing the flag
	``-ordering=user``. Doing so and looking at the timing block of the
	full report gives us

	.. code-block:: bash

	Time (in seconds):
	Preprocessor 0.051

	Residual evaluation 0.053
	Jacobian evaluation 0.344
	Linear solver 0.372
	Minimizer 0.854

	Postprocessor 0.002
	Total 0.935



	The preprocessor time has gone down by more than 5.5x!.