dpg_bvp:
  Discontinuous Petrov Galerkin method for a boundary
  value problem on the unit interval.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 1 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.112480
   L^2 distance b/w least-sqr and exact soln   =0.534374
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 2 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.094746
   L^2 distance b/w least-sqr and exact soln   =0.293308
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 3 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.074605
   L^2 distance b/w least-sqr and exact soln   =0.191247
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 4 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.054980
   L^2 distance b/w least-sqr and exact soln   =0.125293
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 5 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.037973
   L^2 distance b/w least-sqr and exact soln   =0.079687
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 6 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.024618
   L^2 distance b/w least-sqr and exact soln   =0.048586
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 7 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.015007
   L^2 distance b/w least-sqr and exact soln   =0.028246
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 8 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.008618
   L^2 distance b/w least-sqr and exact soln   =0.015621
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
Solving linear variational problem.
Calling FFC just-in-time (JIT) compiler, this may take some time.
Solving linear variational problem.
  Computations with degree 9 done:
   L^2 distance b/w projection and PG solution =0.000000
   L^2 distance b/w PG soln and exact soln     =0.004670
   L^2 distance b/w least-sqr and exact soln   =0.008211
Computations complete.
Do you want to visualize some solutions? [1/0]1
   Saved figure to dpg_bvp.pdf
To view figure, visit http://127.0.0.1:8000
Press Ctrl+C to stop WebAgg server
^CServer is stopped
Do you want to save solutions to Matlab? [1/0]1
   Saved solution values to dpg_bvp.mat
   with variables: PGsol (PG solution values)
                   LSsol (LS solution values)
                   Proj  (L^2 projection's values)
                   Exact (exact solution values)
                   x     (abscissae).

dpg_bvp:
  Normal end of execution.