This paper presents an attempt of examining the irregularities appearing in a complicated A^1Π state of the CH^+ molecule with their reasons provided. By using the experimental data for the A^1Π-X^1Σ^+ bands system of the ^{12}CH^+ ion radical, it was proved that the vibrational and rotational quanta of the upper state reveal the same unusual behaviour, i.e. very clear nonlinear dependence on vibrational quantum number (v'≥3) of the upper state. Therefore, upper vibrational levels (v'≥3) of the A^1Π state cannot be determined by means of the equilibrium constants calculated in the previous works. Due to so far unidentified A^1Π state perturbations, the reduction of the wave numbers to the rovibronic parameters was carried out by means of individual, band-by-band analysis method, using with this end in view the nonlinear least squares method introduced by Curl and Dane, and Watson. This method allowed one to make already calculated constants of the rovibronic structure of regular lower state X^1Σ^+ of A-X system independent of possible perturbations appearing in the upper state of A^1Π of this system. It also enabled one to calculate for the first time the real (perturbed) term values for the A^1Π (v' =0, 1, 2, and 3) state of the ^{12}CH^+ ion molecule. These values suggest that rotational irregularities in the A^1Π state examined are negligibly small. In order to confirm the nonexistence of rotational perturbations in the A^1Π (v' =0, 1, 2, and 3) state, up to the observed J_max level, appropriate graphs of functions f_x(J) and g_x(J) introduced by Gerö and Kovács, where x = Q, PR, and overline{PR}, were drawn. Also, their course was analysed in detail.