#include "./deorummolae.h" #include #include #include "./esaxx/sais.hxx" /* Used for quick SA-entry to file mapping. Each file is padded to size that is a multiple of chunk size. */ #define CHUNK_SIZE 64 /* Length of substring that is considered to be covered by dictionary string. */ #define CUT_MATCH 6 /* Minimal dictionary entry size. */ #define MIN_MATCH 24 /* Non tunable definitions. */ #define CHUNK_MASK (CHUNK_SIZE - 1) #define COVERAGE_SIZE (1 << (LOG_MAX_FILES - 6)) /* File coverage: every bit set to 1 denotes a file covered by an isle. */ typedef std::array Coverage; static int popcount(uint64_t u) { return __builtin_popcountll(u); } /* Condense terminators and pad file entries. */ static void rewriteText(std::vector* text) { int terminator = text->back(); int prev = terminator; size_t to = 0; for (size_t from = 0; from < text->size(); ++from) { int next = text->at(from); if (next < 256 || prev < 256) { text->at(to++) = next; if (next >= 256) terminator = next; } prev = next; } text->resize(to); if (text->empty()) text->push_back(terminator); while (text->size() & CHUNK_MASK) text->push_back(terminator); } /* Reenumerate terminators for smaller alphabet. */ static void remapTerminators(std::vector* text, int* next_terminator) { int prev = -1; int x = 256; for (size_t i = 0; i < text->size(); ++i) { int next = text->at(i); if (next < 256) { // Char. // Do nothing. } else if (prev < 256) { // Terminator after char. next = x++; } else { // Terminator after terminator. next = prev; } text->at(i) = next; prev = next; } *next_terminator = x; } /* Combine all file entries; create mapping position->file. */ static void buildFullText(std::vector>* data, std::vector* full_text, std::vector* file_map, std::vector* file_offset, int* next_terminator) { file_map->resize(0); file_offset->resize(0); full_text->resize(0); for (size_t i = 0; i < data->size(); ++i) { file_offset->push_back(full_text->size()); std::vector& file = data->at(i); rewriteText(&file); full_text->insert(full_text->end(), file.begin(), file.end()); file_map->insert(file_map->end(), file.size() / CHUNK_SIZE, i); } if (false) remapTerminators(full_text, next_terminator); } /* Build longest-common-prefix based on suffix array and text. TODO: borrowed -> unknown efficiency. */ static void buildLcp(std::vector* text, std::vector* sa, std::vector* lcp, std::vector* invese_sa) { int size = static_cast(text->size()); lcp->resize(size); int k = 0; lcp->at(size - 1) = 0; for (int i = 0; i < size; ++i) { if (invese_sa->at(i) == size - 1) { k = 0; continue; } int j = sa->at(invese_sa->at(i) + 1); // Suffix which follow i-th suffix. while (i + k < size && j + k < size && text->at(i + k) == text->at(j + k)) { ++k; } lcp->at(invese_sa->at(i)) = k; if (k > 0) --k; } } /* Isle is a range in SA with LCP not less than some value. When we raise the LCP requirement, the isle sunks and smaller isles appear instead. */ typedef struct { int lcp; int l; int r; Coverage coverage; } Isle; /* Helper routine for `cutMatch`. */ static void poisonData(int pos, int length, std::vector>* data, std::vector* file_map, std::vector* file_offset, int* next_terminator) { size_t f = file_map->at(pos / CHUNK_SIZE); pos -= file_offset->at(f); std::vector& file = data->at(f); int l = (length == CUT_MATCH) ? CUT_MATCH : 1; for (int j = 0; j < l; j++, pos++) { if (file[pos] >= 256) continue; if (file[pos + 1] >= 256) { file[pos] = file[pos + 1]; } else if (pos > 0 && file[pos - 1] >= 256) { file[pos] = file[pos - 1]; } else { file[pos] = (*next_terminator)++; } } } /* Remove substrings of a given match from files. Substrings are replaced with unique terminators, so next iteration SA would not allow to cross removed areas. */ static void cutMatch(std::vector>* data, int index, int length, std::vector* sa, std::vector* lcp, std::vector* invese_sa, int* next_terminator, std::vector* file_map, std::vector* file_offset) { while (length >= CUT_MATCH) { int i = index; while (lcp->at(i) >= length) { i++; poisonData( sa->at(i), length, data, file_map, file_offset, next_terminator); } while (true) { poisonData( sa->at(index), length, data, file_map, file_offset, next_terminator); if (index == 0 || lcp->at(index - 1) < length) break; index--; } length--; index = invese_sa->at(sa->at(index) + 1); } } size_t DM_generate(uint8_t* dictionary, size_t dictionary_size_limit, size_t num_samples, const size_t* sample_sizes, const uint8_t* sample_data) { { uint64_t tmp = 0; if (popcount(tmp - 1u) != 64) { fprintf(stderr, "64-bit platform is required\n"); return 0; } } /* Could use 256 + '0' for easier debugging. */ int next_terminator = 256; std::vector> data; size_t offset = 0; if (num_samples > MAX_FILES) num_samples = MAX_FILES; for (size_t n = 0; n < num_samples; ++n) { size_t next_offset = offset + sample_sizes[n]; data.push_back( std::vector(sample_data + offset, sample_data + next_offset)); offset = next_offset; data.back().push_back(next_terminator++); } /* Most arrays are allocated once, and then just resized to smaller and smaller sizes. */ std::vector full_text; std::vector file_map; std::vector file_offset; std::vector sa; std::vector invese_sa; std::vector lcp; std::vector isles; std::vector output_data; size_t total = 0; size_t total_cost = 0; size_t best_cost; Isle best_isle; int min_count = num_samples; while (true) { size_t max_match = dictionary_size_limit - total; buildFullText(&data, &full_text, &file_map, &file_offset, &next_terminator); sa.resize(full_text.size()); saisxx(full_text.data(), sa.data(), static_cast(full_text.size()), next_terminator); invese_sa.resize(full_text.size()); for (int i = 0; i < full_text.size(); ++i) invese_sa[sa[i]] = i; buildLcp(&full_text, &sa, &lcp, &invese_sa); /* Do not rebuild SA/LCP, just use different selection. */ retry: best_cost = 0; best_isle = {0, 0, 0, {{0}}}; isles.resize(0); isles.push_back(best_isle); for (int i = 0; i < static_cast(lcp.size()); ++i) { int l = i; Coverage cov = {{0}}; int f = file_map[sa[i] / CHUNK_SIZE]; cov[f >> 6] = ((uint64_t)1) << (f & 63); while (lcp[i] < isles.back().lcp) { Isle& top = isles.back(); top.r = i; l = top.l; for (size_t x = 0; x < cov.size(); ++x) cov[x] |= top.coverage[x]; int count = 0; for (size_t x = 0; x < cov.size(); ++x) count += popcount(cov[x]); int effective_lcp = top.lcp; /* Restrict (last) dictionary entry length. */ if (effective_lcp > max_match) effective_lcp = max_match; int cost = count * effective_lcp; if (cost > best_cost && count >= min_count && effective_lcp >= MIN_MATCH) { best_cost = cost; best_isle = top; best_isle.lcp = effective_lcp; } isles.pop_back(); for (size_t x = 0; x < cov.size(); ++x) { isles.back().coverage[x] |= cov[x]; } } if (lcp[i] > isles.back().lcp) isles.push_back({lcp[i], l, 0, {{0}}}); for (size_t x = 0; x < cov.size(); ++x) { isles.back().coverage[x] |= cov[x]; } } /* When saturated matches do not match length restrictions, lower the saturation requirements. */ if (best_cost == 0 || best_isle.lcp < MIN_MATCH) { if (min_count >= 8) { min_count = (min_count * 7) / 8; goto retry; } break; } /* Save the entry. */ fprintf(stderr, "Savings: %zu+%zu, dictionary: %zu+%d\n", total_cost, best_cost, total, best_isle.lcp); memcpy( dictionary + total, full_text.data() + sa[best_isle.l], best_isle.lcp); total += best_isle.lcp; total_cost += best_cost; cutMatch(&data, best_isle.l, best_isle.lcp, &sa, &lcp, &invese_sa, &next_terminator, &file_map, &file_offset); if (total >= dictionary_size_limit) break; } return total; }