diff --git a/src/fortran/cantilever.F90 b/src/fortran/cantilever.F90
index 949f418..6aa042a 100644
--- a/src/fortran/cantilever.F90
+++ b/src/fortran/cantilever.F90
@@ -163,8 +163,8 @@ PROGRAM CANTILEVEREXAMPLE
   WRITE(*,'("Scaling type: ", i3)') ScalingType
 
   !Get the number of computational nodes and this computational node number
-  CALL cmfe_ComputationalNumberOfNodesGet(NumberOfComputationalNodes,Err)
-  CALL cmfe_ComputationalNodeNumberGet(ComputationalNodeNumber,Err)
+  CALL cmfe_ComputationalNumberOfNodesGet(numberOfComputationalNodes,err)
+  CALL cmfe_ComputationalNodeNumberGet(computationalNodeNumber,err)
 
   NumberOfDomains=NumberOfComputationalNodes
 
diff --git a/src/python/cantilever.py b/src/python/cantilever.py
index bdcf7e1..c5bf187 100644
--- a/src/python/cantilever.py
+++ b/src/python/cantilever.py
@@ -45,8 +45,9 @@
     numberOfXi = 3
 
 # Get the number of computational nodes and this computational node number
-numberOfComputationalNodes = iron.ComputationalNumberOfNodesGet()
-computationalNodeNumber = iron.ComputationalNodeNumberGet()
+computationEnvironment = iron.ComputationEnvironment()
+numberOfComputationalNodes = computationEnvironment.NumberOfWorldNodesGet()
+computationalNodeNumber = computationEnvironment.WorldNodeNumberGet()
 
 # Create a 3D rectangular cartesian coordinate system
 coordinateSystem = iron.CoordinateSystem()
@@ -240,7 +241,7 @@
 linearSolver = iron.Solver()
 problem.SolversCreateStart()
 problem.SolverGet([iron.ControlLoopIdentifiers.NODE],1,nonLinearSolver)
-nonLinearSolver.outputType = iron.SolverOutputTypes.PROGRESS
+nonLinearSolver.outputType = iron.SolverOutputTypes.MONITOR
 nonLinearSolver.NewtonJacobianCalculationTypeSet(iron.JacobianCalculationTypes.FD)
 nonLinearSolver.NewtonAbsoluteToleranceSet(1e-14)
 nonLinearSolver.NewtonSolutionToleranceSet(1e-14)