Layering for geomodeling

The invention claimed is: 1 . A process comprising one or more iterations of a computer-implemented method of geomodeling, the method comprising: providing a pseudo-stratigraphic grid representing a reservoir having geological units, the pseudo-stratigraphic grid having pillars, each pillar including respective cells, each geological unit being represented by a respective portion of the pseudo-stratigraphic grid and having a respective top, a respective base, and a respective stratigraphic style; for at least one geological unit: computing a top 2D map representing the respective top and a base 2D map representing the respective base; defining a gridding constraint depending on the respective stratigraphic style; and for each cell of the respective portion, calculating a respective local stratigraphic layering index based on the top 2D map, on the base 2D map, on the gridding constraint and on the respective stratigraphic style; providing, for each cell of the respective portion, a respective initial stratigraphic layering index; and replacing the respective initial stratigraphic layering index; wherein: at least one of the top and the base has a first region and a second region complementary to the first region, at least one of the top and the base 2D map outputs, for each cell of at least one of the top and the base, a respective local stratigraphic value, base, and the computing of at least one of the top and the base 2D map includes: for each first cell of the first region, determining a respective first stratigraphic layering index based on the respective initial stratigraphic layering index; and for each second pillar intercepted by the second region, determining a respective second stratigraphic layering value by interpolating first stratigraphic layering values; the process further comprising performing one or more physical actions on a geological environment based on a result of the one or more iterations of the method. 2 . The process of claim 1 , wherein the at least one geological unit comprises several geological units that form the reservoir, the method further comprising determining, for each cell of the pseudo-stratigraphic grid, a respective global stratigraphic layering index based on the respective local stratigraphic layering index and on a global recombination scheme. 3 . The process of claim 1 , wherein the second region presents a discontinuity. 4 . The process of claim 3 , wherein the geological structure is a fault or an unconformity. 5 . The process of claim 4 , wherein the method comprises detecting faulted cells of the top or the base based on topology of the pseudo-stratigraphic grid. 6 . The process of claim 1 , wherein the respective stratigraphic style is a true iso-proportional style. 7 . The process of claim 1 , wherein at least one of the top 2D map and the base 2D map each output, for each pillar intercepting the at least one geological unit, a respective value, base of a vertical positioning measure, the calculating including: establishing a respective pseudo relative depositional time based on a comparison between a respective value of the vertical positioning measure at the cell and the respective value outputted by at least one of the first and base 2D map; and converting the respective pseudo relative depositional time into the respective local stratigraphic layering index based on at least one of the gridding constraint and a comparison between the top 2D map and the base 2D map; the establishing and the converting being performed further based on the respective stratigraphic style. 8 . The process of claim 7 , wherein at least one of: (i) the respective stratigraphic style is a true iso-proportional style or an iso-proportional with geometrical option style and (ii) the gridding constraint is a target number of cells, the converting including multiplying the target number of cells with the respective pseudo relative depositional time. 9 . The process of claim 7 , wherein at least one of: (i) the respective stratigraphic style is a follow-top style or a follow-base style, and (ii) the gridding constraint is a target cell thickness, the converting including multiplying a max of the difference between the top 2D map and the base 2D map with the respective pseudo relative depositional time, divided by the target cell thickness. 10 . A non-transitory data storage medium having recorded thereon a computer program comprising instructions for performing a computer-implemented method of geomodeling, the method comprising: providing a pseudo-stratigraphic grid representing a reservoir having geological units, the pseudo-stratigraphic grid having pillars, each pillar including respective cells, each geological unit being represented by a respective portion of the pseudo-stratigraphic grid and having a respective top, a respective base, and a respective stratigraphic style; for at least one geological unit: computing a top 2D map representing the respective top and a base 2D map representing the respective base; defining a gridding constraint depending on the respective stratigraphic style; and for each cell of the respective portion, calculating a respective local stratigraphic layering index based on the top 2D map, on the base 2D map, on the gridding constraint and on the respective stratigraphic style; providing, for each cell of the respective portion, a respective initial stratigraphic layering index; and replacing the respective initial stratigraphic layering index: wherein: at least one of the top and the base has a first region and a second region complementary to the first region, at least one of the top and the base 2D map outputs, for each cell of at least one of the top and the base, a respective local stratigraphic value, and the computing of at least one of the top and the base 2D map includes: for each first cell of the first region, determining a respective first stratigraphic layering index based on the respective initial stratigraphic layering index; and for each second pillar intercepted by the second region, determining a respective second stratigraphic layering value by interpolating first stratigraphic layering values; the non-transitory data storage medium being configured to be used in a process, the process comprising performing one or more iterations of the method and performing one or more physical actions on a geological environment based on a result of the one or more iterations of the method. 11 . The data storage medium of claim 10 , wherein the at least one geological unit comprises several geological units that form the reservoir, the method further comprising determining, for each cell of the pseudo-stratigraphic grid, a respective global stratigraphic layering index based on the respective local stratigraphic layering index and on a global recombination scheme. 12 . The data storage medium of claim 10 , wherein the second region presents a discontinuity; and wherein the geological structure is a fault or an unconformity; and wherein the method comprises detecting faulted cells of the top or the base based on topology of the pseudo-stratigraphic grid. 13 . A system comprising a processor coupled to a memory, the memory having recorded thereon a computer program comprising instructions for performing a computer-implemented method of geomodeling, the method comprising: providing a pseudo-stratigraphic grid representing a reservoir having geological units, the pseudo-stratigraphic grid having pillars, each pillar including respective cells, each geological unit being represented by a respective portion of the pseudo-stratigraph