Three-dimensional subsurface formation evaluation using projection-based area operations

What is claimed is: 1. A method of evaluating a subsurface formation, the method comprising, using at least one processing unit of a data processing system: defining a subsurface structure within a plurality of cells of a three-dimensional model of the subsurface formation using a plurality of geometric primitives; calculating a combined area of the plurality of geometric primitives within at least a subset of the plurality of cells by summing areas of individual geometric primitives within each of the subset of cells, including determining an area of a first geometric primitive among the plurality of geometric primitives within a first cell in the subset of cells by projecting the first geometric primitive onto three orthogonal XY, ZX and YZ planes respectively aligned with faces of the first cell to define respective first, second and third projections and calculating two-dimensional areas of each of the first, second and third projections, wherein the first cell is a regular cubic cell, and wherein determining the area of the first geometric primitive further includes clipping the first geometric primitive in response to determining that the first geometric primitive is partially disposed within the first cell; determining a subsurface structure parameter for the subsurface structure from the calculated combined area of the plurality of geometric primitives; and running a computer-implemented simulation for the subsurface formation or generating a visualization of at least a portion of the subsurface formation in a computer-implemented graphical tool using the determined subsurface structure parameter. 2. The method of claim 1 , wherein each of the plurality of geometric primitives is a triangular element. 3. The method of claim 2 , wherein determining the area of the first geometric primitive further includes squaring the areas of each of the first, second and third projections, summing the squared areas and determining a square root of the summed squared areas. 4. The method of claim 1 , wherein the subsurface structure is selected from the group consisting of a fracture network, a fault and a horizon. 5. The method of claim 1 , wherein defining the subsurface structure includes defining a fracture network, and wherein determining the subsurface structure parameter from the calculated combined area of the plurality of geometric primitives includes determining a fracture abundance parameter for the fracture network from the calculated combined area of the plurality of geometric primitives. 6. The method of claim 5 , further comprising determining areas for one or more additional geometric primitives at least partially disposed within the first cell, wherein determining the fracture abundance parameter includes determining a fracture density within the first cell by dividing a sum of the determined areas for all geometric primitives at least partially disposed within the first cell by a volume of the first cell. 7. The method of claim 5 , wherein calculating the combined area of the plurality of geometric primitives within the subset of the plurality of cells further includes: organizing the plurality of geometric primitives within a spatially-organized data structure stored in a memory of the data processing system; and accessing the spatially-organized data structure when summing areas of individual geometric primitives within each of the subset of cells to determine which of the plurality of geometric primitives are at least partially within each of the subset of cells. 8. The method of claim 7 , wherein the spatially-organized data structure includes an octree. 9. The method of claim 5 , wherein defining the fracture network within the plurality of cells includes: generating the plurality of geometric primitives; and creating an observation grid bounding a volume around the plurality of geometric primitives. 10. The method of claim 5 , wherein determining the fracture abundance parameter includes determining a fracture density within each of the subset of cells by dividing the summed areas of individual geometric primitives therein by a volume thereof. 11. The method of claim 5 , wherein determining the fracture abundance parameter includes determining a directly-calculated P 32 fracture density within each of the subset of cells by dividing the summed areas of individual geometric primitives therein by a volume thereof. 12. The method of claim 5 , further comprising running a fluid flow simulation using the determined fracture abundance parameter to estimate fluid flow through the fracture network. 13. The method of claim 12 , further comprising performing an oilfield operation based upon a result of the fluid flow simulation. 14. The method of claim 13 , wherein performing the oilfield operation based upon a result of the fluid flow simulation includes: determining a well trajectory using the result of the fluid flow simulation; and drilling a well using the determined well trajectory. 15. The method of claim 5 , further comprising generating in a computer-implemented graphical tool a visualization of at least a portion of the fracture network and of the fracture abundance parameter. 16. An apparatus, comprising: at least one processing unit; and program code configured upon execution by the at least one processing unit to evaluate a subsurface formation by: defining a subsurface structure within a plurality of cells of a three-dimensional model of the subsurface formation using a plurality of geometric primitives; calculating a combined area of the plurality of geometric primitives within at least a subset of the plurality of cells by summing areas of individual geometric primitives within each of the subset of cells, including determining an area of a first geometric primitive among the plurality of geometric primitives within a first cell in the subset of cells by projecting the first geometric primitive onto three orthogonal XY, ZX and YZ planes respectively aligned with faces of the first cell to define respective first, second and third projections and calculating two-dimensional areas of each of the first, second and third projections, wherein the first cell is a regular cubic cell, and wherein determining the area of the first geometric primitive further includes clipping the first geometric primitive in response to determining that the first geometric primitive is partially disposed within the first cell; determining a subsurface structure parameter for the subsurface structure from the calculated combined area of the plurality of geometric primitives; and running a computer-implemented simulation for the subsurface formation or generating a visualization of at least a portion of the subsurface formation in a computer-implemented graphical tool using the determined subsurface structure parameter. 17. A program product, comprising: a non-transitory computer readable medium; and program code stored on the computer readable medium and configured upon execution by at least one processing unit to evaluate fracture abundance in a subsurface formation by: defining a subsurface structure within a plurality of cells of a three-dimensional model of the subsurface formation using a plurality of geometric primitives; calculating a combined area of the plurality of geometric primitives within at least a subset of the plurality of cells by summing areas of individual geometric primitives within each of the subset of cells, including determining an area of a first geometric primitive among the plurality of geometric primitives within a first cell in the subset