ref: 6a9a0cd8f6ee83e6fbd3424c337bacfb8e90502a
dir: /grid.h/
/* * (c) Lambros Lambrou 2008 * * Code for working with general grids, which can be any planar graph * with faces, edges and vertices (dots). Includes generators for a few * types of grid, including square, hexagonal, triangular and others. */ #ifndef PUZZLES_GRID_H #define PUZZLES_GRID_H #include "puzzles.h" /* for random_state */ /* Useful macros */ #define SQ(x) ( (x) * (x) ) /* ---------------------------------------------------------------------- * Grid structures: * A grid is made up of faces, edges and dots. These structures hold * the incidence relationships between these types. For example, an * edge always joins two dots, and is adjacent to two faces. * The "grid_xxx **" members are lists of pointers which are dynamically * allocated during grid generation. * A pointer to a face/edge/dot will always point somewhere inside one of the * three lists of the main "grid" structure: faces, edges, dots. * Could have used integer offsets into these lists, but using actual * pointers instead gives us type-safety. */ /* Need forward declarations */ typedef struct grid_face grid_face; typedef struct grid_edge grid_edge; typedef struct grid_dot grid_dot; struct grid_face { int index; /* index in grid->faces[] where this face appears */ int order; /* Number of edges, also the number of dots */ grid_edge **edges; /* edges around this face */ grid_dot **dots; /* corners of this face */ /* * For each face, we optionally compute and store its 'incentre'. * The incentre of a triangle is the centre of a circle tangent to * all three edges; I generalise the concept to arbitrary polygons * by defining it to be the centre of the largest circle you can fit * anywhere in the polygon. It's a useful thing to know because if * you want to draw any symbol or text in the face (e.g. clue * numbers in Loopy), that's the place it will most easily fit. * * When a grid is first generated, no face has this information * computed, because it's fiddly to do. You can call * grid_find_incentre() on a face, and it will fill in ix,iy below * and set has_incentre to indicate that it's done so. */ bool has_incentre; int ix, iy; /* incentre (centre of largest inscribed circle) */ }; struct grid_edge { grid_dot *dot1, *dot2; grid_face *face1, *face2; /* Use NULL for the infinite outside face */ int index; /* index in grid->edges[] where this edge appears */ }; struct grid_dot { int index; /* index in grid->dots[] where this dot appears */ int order; grid_edge **edges; grid_face **faces; /* A NULL grid_face* means infinite outside face */ /* Position in some fairly arbitrary (Cartesian) coordinate system. * Use large enough values such that we can get away with * integer arithmetic, but small enough such that arithmetic * won't overflow. */ int x, y; }; typedef struct grid { /* Arrays of all the faces, edges, dots that are in the grid. * The arrays themselves are dynamically allocated, and so is each object * inside them. num_foo indicates the number of things actually stored, * and size_foo indicates the allocated size of the array. */ int num_faces, size_faces; grid_face **faces; int num_edges, size_edges; grid_edge **edges; int num_dots, size_dots; grid_dot **dots; /* Cache the bounding-box of the grid, so the drawing-code can quickly * figure out the proper scaling to draw onto a given area. */ int lowest_x, lowest_y, highest_x, highest_y; /* A measure of tile size for this grid (in grid coordinates), to help * the renderer decide how large to draw the grid. * Roughly the size of a single tile - for example the side-length * of a square cell. */ int tilesize; /* We really don't want to copy this monstrosity! * A grid is immutable once generated. */ int refcount; } grid; /* Grids are specified by type: GRID_SQUARE, GRID_KITE, etc. */ #define GRIDGEN_LIST(A) \ A(SQUARE,square) \ A(HONEYCOMB,honeycomb) \ A(TRIANGULAR,triangular) \ A(SNUBSQUARE,snubsquare) \ A(CAIRO,cairo) \ A(GREATHEXAGONAL,greathexagonal) \ A(KAGOME,kagome) \ A(OCTAGONAL,octagonal) \ A(KITE,kites) \ A(FLORET,floret) \ A(DODECAGONAL,dodecagonal) \ A(GREATDODECAGONAL,greatdodecagonal) \ A(GREATGREATDODECAGONAL,greatgreatdodecagonal) \ A(COMPASSDODECAGONAL,compassdodecagonal) \ A(PENROSE_P2,penrose_p2_kite) \ A(PENROSE_P3,penrose_p3_thick) \ A(HATS,hats) \ A(SPECTRES,spectres) \ /* end of list */ #define ENUM(upper,lower) GRID_ ## upper, typedef enum grid_type { GRIDGEN_LIST(ENUM) GRID_TYPE_MAX } grid_type; #undef ENUM const char *grid_validate_params(grid_type type, int width, int height); /* Free directly after use if non-NULL. Will never contain an underscore * (so clients can safely use that as a separator). */ char *grid_new_desc(grid_type type, int width, int height, random_state *rs); const char *grid_validate_desc(grid_type type, int width, int height, const char *desc); grid *grid_new(grid_type type, int width, int height, const char *desc); void grid_free(grid *g); grid_edge *grid_nearest_edge(grid *g, int x, int y); void grid_compute_size(grid_type type, int width, int height, int *tilesize, int *xextent, int *yextent); void grid_find_incentre(grid_face *f); #endif /* PUZZLES_GRID_H */