This paper analyzes the photoluminescence excitation and emission spectra of fluoride phosphors doped with Mn4+: KNaSiF6:Mn4+, Rb2GeF6:Mn4+, and Na3HTiF8:Mn4+ under high pressure conditions. From the optical spectra, the pressure-dependent energies of optically active 4T2, 4T1, and 2E crystal field subterms of Mn4+ have been determined in the 0-30 GPa pressure range. A strong blueshift of the 4T2 and 4T1 subterms was found, as expected from the Tanabe-Sugano diagram for Mn4+ (d3). At the same time, the 2E emitting state exhibited a redshift under pressure - an effect opposite to the prediction of the Tanabe-Sugano diagram. This is a manifestation of the pressure-driven nephelauxetic effect, governed by pressure induced changes of Racah parameters, which demonstrates the necessity of taking into account the Racah parameters for a correct description of Mn4+ emission under pressure. The high pressure experimental data allowed to determine the pressure dependence of crystal field strength parameter Dq and Racah parameters B and C. Finally, obtaining the pressure dependence of Dq and Racah parameters allowed to calculate the full energy structure of the d3 configuration of Mn4+ in KNaSiF6, Rb2GeF6, and Na3HTiF8 in the pressure range of 0-30 GPa. The calculations reproduced the redshift of the 2E emitting state under pressure, as well as gave the pressure shift direction and magnitude for all crystal field subterms of Mn4+ up to 50 000 cm-1 (i.e. the equivalent of the Tanabe-Sugano diagram for high-pressure experiments). The approach presented in this paper can be easily extended for calculating the energy structure of materials doped with isoelectronic Cr3+ as well as other transition metal ions.