Meaning of the annotations for the proof of each method: - loop: the method seems to be part of a loop or recursion - inherits: the method seems to call a method that possibly diverges - may_diverge: proved the existence of at least a diverging execution - local_polyh: proved to terminate by using a local linear ranking function for the binary unfolding with polyhedra - local_bds: proved to terminate by using local linear ranking functions for the binary unfolding with bounded difference shapes - local_sct: proved to terminate via the size change termination principle with monotonicity constraints - global_lex_aff_rnkfn: proved to terminate by using a global lexicographic affine ranking function - finite_unfoldings: proved to terminate since there is a finite number of undoldings * numerical: the ranking function uses numerical variables or fields * structural: the ranking function uses reference variables or fields These methods do not introduce divergence: [loop,numerical,local_bds] TaylorSeriesRec.cos(int,int):int [loop,numerical,local_bds] TaylorSeriesRec.exp(int,int):int [loop,numerical,structural,local_polyh] TaylorSeriesRec.main(java.lang.String[]):void [loop,numerical,local_bds] TaylorSeriesRec.power(int,int):int [loop,numerical,local_bds] TaylorSeriesRec.fact(int):int [loop,numerical,local_bds] TaylorSeriesRec.sin(int,int):int There is at least a diverging computation for these methods: none Nothing is known about these methods: none Methods that might introduce divergence: 0/6 ( 0.00%) Methods that do might introduce or inherit divergence: 0/6 ( 0.00%) Methods that definitely terminate: 6/6 (100.00%) There are no warnings