ref: 6a9a0cd8f6ee83e6fbd3424c337bacfb8e90502a
dir: /dsf.c/
/* * dsf.c: some functions to handle a disjoint set forest, * which is a data structure useful in any solver which has to * worry about avoiding closed loops. */ #include <assert.h> #include <limits.h> #include <string.h> #include "puzzles.h" #define DSF_INDEX_MASK (UINT_MAX >> 1) #define DSF_FLAG_CANONICAL (UINT_MAX & ~(UINT_MAX >> 1)) #define DSF_MAX (DSF_INDEX_MASK + 1) struct DSF { /* * Size of the dsf. */ size_t size; /* * Main array storing the data structure. * * If n is the canonical element of an equivalence class, * parent_or_size[n] holds the number of elements in that class, * bitwise-ORed with DSF_FLAG_CANONICAL. * * If n is not the canonical element, parent_or_size[n] holds the * index of another element nearer to the root of the tree for * that class. */ unsigned *parent_or_size; /* * Extra storage for flip tracking. * * If n is not a canonical element, flip[n] indicates whether the * sense of this element is flipped relative to parent_or_size[n]. * * If n is a canonical element, flip[n] is unused. */ unsigned char *flip; /* * Extra storage for minimal-element tracking. * * If n is a canonical element, min[n] holds the index of the * smallest value in n's equivalence class. * * If n is not a canonical element, min[n] is unused. */ unsigned *min; }; static DSF *dsf_new_internal(int size, bool flip, bool min) { DSF *dsf; assert(0 < size && size <= DSF_MAX && "Bad dsf size"); dsf = snew(DSF); dsf->size = size; dsf->parent_or_size = snewn(size, unsigned); dsf->flip = flip ? snewn(size, unsigned char) : NULL; dsf->min = min ? snewn(size, unsigned) : NULL; dsf_reinit(dsf); return dsf; } DSF *dsf_new(int size) { return dsf_new_internal(size, false, false); } DSF *dsf_new_flip(int size) { return dsf_new_internal(size, true, false); } DSF *dsf_new_min(int size) { return dsf_new_internal(size, false, true); } void dsf_reinit(DSF *dsf) { size_t i; /* Every element starts as the root of an equivalence class of size 1 */ for (i = 0; i < dsf->size; i++) dsf->parent_or_size[i] = DSF_FLAG_CANONICAL | 1; /* If we're tracking minima then every element is also its own min */ if (dsf->min) for (i = 0; i < dsf->size; i++) dsf->min[i] = i; /* No need to initialise dsf->flip, even if it exists, because * only the entries for non-root elements are meaningful, and * currently there are none. */ } void dsf_copy(DSF *to, DSF *from) { assert(to->size == from->size && "Mismatch in dsf_copy"); memcpy(to->parent_or_size, from->parent_or_size, to->size * sizeof(*to->parent_or_size)); if (to->flip) { assert(from->flip && "Copying a non-flip dsf to a flip one"); memcpy(to->flip, from->flip, to->size * sizeof(*to->flip)); } if (to->min) { assert(from->min && "Copying a non-min dsf to a min one"); memcpy(to->min, from->min, to->size * sizeof(*to->min)); } } void dsf_free(DSF *dsf) { if (dsf) { sfree(dsf->parent_or_size); sfree(dsf->flip); sfree(dsf->min); sfree(dsf); } } static inline size_t dsf_find_root(DSF *dsf, size_t n) { while (!(dsf->parent_or_size[n] & DSF_FLAG_CANONICAL)) n = dsf->parent_or_size[n]; return n; } static inline void dsf_path_compress(DSF *dsf, size_t n, size_t root) { while (!(dsf->parent_or_size[n] & DSF_FLAG_CANONICAL)) { size_t prev = n; n = dsf->parent_or_size[n]; dsf->parent_or_size[prev] = root; } assert(n == root); } int dsf_canonify(DSF *dsf, int n) { size_t root; assert(0 <= n && n < dsf->size && "Overrun in dsf_canonify"); root = dsf_find_root(dsf, n); dsf_path_compress(dsf, n, root); return root; } void dsf_merge(DSF *dsf, int n1, int n2) { size_t r1, r2, s1, s2, root; assert(0 <= n1 && n1 < dsf->size && "Overrun in dsf_merge"); assert(0 <= n2 && n2 < dsf->size && "Overrun in dsf_merge"); assert(!dsf->flip && "dsf_merge on a flip dsf"); /* Find the root elements */ r1 = dsf_find_root(dsf, n1); r2 = dsf_find_root(dsf, n2); if (r1 == r2) { /* Classes are already the same, so we have a common root */ root = r1; } else { /* Classes must be merged */ /* Decide which one to use as the overall root, based on size */ s1 = dsf->parent_or_size[r1] & DSF_INDEX_MASK; s2 = dsf->parent_or_size[r2] & DSF_INDEX_MASK; if (s1 > s2) { dsf->parent_or_size[r2] = root = r1; } else { dsf->parent_or_size[r1] = root = r2; } dsf->parent_or_size[root] = (s1 + s2) | DSF_FLAG_CANONICAL; if (dsf->min) { /* Update the min of the merged class */ unsigned m1 = dsf->min[r1], m2 = dsf->min[r2]; dsf->min[root] = m1 < m2 ? m1 : m2; } } /* Path-compress both paths from n1 and n2 so they point at the new root */ dsf_path_compress(dsf, n1, root); dsf_path_compress(dsf, n2, root); } bool dsf_equivalent(DSF *dsf, int n1, int n2) { return dsf_canonify(dsf, n1) == dsf_canonify(dsf, n2); } int dsf_size(DSF *dsf, int n) { size_t root = dsf_canonify(dsf, n); return dsf->parent_or_size[root] & DSF_INDEX_MASK; } static inline size_t dsf_find_root_flip(DSF *dsf, size_t n, unsigned *flip) { *flip = 0; while (!(dsf->parent_or_size[n] & DSF_FLAG_CANONICAL)) { *flip ^= dsf->flip[n]; n = dsf->parent_or_size[n]; } return n; } static inline void dsf_path_compress_flip(DSF *dsf, size_t n, size_t root, unsigned flip) { while (!(dsf->parent_or_size[n] & DSF_FLAG_CANONICAL)) { size_t prev = n; unsigned flip_prev = flip; n = dsf->parent_or_size[n]; flip ^= dsf->flip[prev]; dsf->flip[prev] = flip_prev; dsf->parent_or_size[prev] = root; } assert(n == root); } int dsf_canonify_flip(DSF *dsf, int n, bool *inverse) { size_t root; unsigned flip; assert(0 <= n && n < dsf->size && "Overrun in dsf_canonify_flip"); assert(dsf->flip && "dsf_canonify_flip on a non-flip dsf"); root = dsf_find_root_flip(dsf, n, &flip); dsf_path_compress_flip(dsf, n, root, flip); *inverse = flip; return root; } void dsf_merge_flip(DSF *dsf, int n1, int n2, bool inverse) { size_t r1, r2, s1, s2, root; unsigned f1, f2; assert(0 <= n1 && n1 < dsf->size && "Overrun in dsf_merge_flip"); assert(0 <= n2 && n2 < dsf->size && "Overrun in dsf_merge_flip"); assert(dsf->flip && "dsf_merge_flip on a non-flip dsf"); /* Find the root elements */ r1 = dsf_find_root_flip(dsf, n1, &f1); r2 = dsf_find_root_flip(dsf, n2, &f2); if (r1 == r2) { /* Classes are already the same, so we have a common root */ assert((f1 ^ f2 ^ inverse) == 0 && "Inconsistency in dsf_merge_flip"); root = r1; } else { /* Classes must be merged */ /* Decide which one to use as the overall root, based on size */ s1 = dsf->parent_or_size[r1] & DSF_INDEX_MASK; s2 = dsf->parent_or_size[r2] & DSF_INDEX_MASK; if (s1 > s2) { dsf->parent_or_size[r2] = root = r1; dsf->flip[r2] = f1 ^ f2 ^ inverse; f2 ^= dsf->flip[r2]; } else { root = r2; dsf->parent_or_size[r1] = root = r2; dsf->flip[r1] = f1 ^ f2 ^ inverse; f1 ^= dsf->flip[r1]; } dsf->parent_or_size[root] = (s1 + s2) | DSF_FLAG_CANONICAL; if (dsf->min) { /* Update the min of the merged class */ unsigned m1 = dsf->min[r1], m2 = dsf->min[r2]; dsf->min[root] = m1 < m2 ? m1 : m2; } } /* Path-compress both paths from n1 and n2 so they point at the new root */ dsf_path_compress_flip(dsf, n1, root, f1); dsf_path_compress_flip(dsf, n2, root, f2); } int dsf_minimal(DSF *dsf, int n) { size_t root; assert(dsf->min && "dsf_minimal on a non-min dsf"); root = dsf_canonify(dsf, n); return dsf->min[root]; }