/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * $Id$ * * Copyright (C) 2005 by Miika Pekkarinen * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include "thread.h" #include "kernel.h" #include "system.h" #include "logf.h" #include "string.h" #include "usb.h" #include "dircache.h" #include "metadata.h" #include "id3.h" #include "settings.h" #include "splash.h" #include "lang.h" #include "tagcache.h" #include "buffer.h" #include "atoi.h" #include "crc32.h" /* Tag Cache thread. */ static struct event_queue tagcache_queue; static long tagcache_stack[(DEFAULT_STACK_SIZE + 0x4000)/sizeof(long)]; static const char tagcache_thread_name[] = "tagcache"; /* Previous path when scanning directory tree recursively. */ static char curpath[MAX_PATH*2]; static long curpath_size = sizeof(curpath); /* Used when removing duplicates. */ static char *tempbuf; /* Allocated when needed. */ static long tempbufidx; /* Current location in buffer. */ static long tempbuf_size; /* Buffer size (TEMPBUF_SIZE). */ static long tempbuf_left; /* Buffer space left. */ static long tempbuf_pos; /* Tags we want to get sorted (loaded to the tempbuf). */ static const int sorted_tags[] = { tag_artist, tag_album, tag_genre, tag_composer, tag_title }; /* Uniqued tags (we can use these tags with filters and conditional clauses). */ static const int unique_tags[] = { tag_artist, tag_album, tag_genre, tag_composer }; /* Numeric tags (we can use these tags with conditional clauses). */ static const int numeric_tags[] = { tag_year, tag_tracknumber, tag_length, tag_bitrate }; /* When thread initialization and memory allocation has been made. */ static bool tagcache_init_done = false; /* Progress indicator while committing the cache. */ static int init_step; /* Queue commands. */ enum tagcache_queue { Q_STOP_SCAN = 0, Q_START_SCAN, Q_FORCE_UPDATE, }; /* Tag database structures. */ /* Variable-length tag entry in tag files. */ struct tagfile_entry { short tag_length; short idx_id; char tag_data[0]; }; /* Fixed-size tag entry in master db index. */ struct index_entry { long tag_seek[TAG_COUNT]; long flag; }; /* Header is the same in every file. */ struct tagcache_header { long magic; long datasize; long entry_count; }; #ifdef HAVE_TC_RAMCACHE /* Header is created when loading database to ram. */ struct ramcache_header { struct tagcache_header h; struct index_entry *indices; char *tags[TAG_COUNT]; int entry_count[TAG_COUNT]; }; static struct ramcache_header *hdr; static bool ramcache = false; static long tagcache_size = 0; #endif /** * Full tag entries stored in a temporary file waiting * for commit to the cache. */ struct temp_file_entry { long tag_offset[TAG_COUNT]; short tag_length[TAG_COUNT]; long data_length; }; struct tempbuf_id { int id; struct tempbuf_id *next; }; struct tempbuf_searchidx { struct tempbuf_id *id; long idx_id; char *str; int seek; }; /* Used when building the temporary file. */ static int cachefd = -1, filenametag_fd; static int total_entry_count = 0; static int data_size = 0; static int processed_dir_count; bool tagcache_is_numeric_tag(int type) { int i; for (i = 0; i < (int)(sizeof(numeric_tags)/sizeof(numeric_tags[0])); i++) { if (type == numeric_tags[i]) return true; } return false; } bool tagcache_is_unique_tag(int type) { int i; for (i = 0; i < (int)(sizeof(unique_tags)/sizeof(unique_tags[0])); i++) { if (type == unique_tags[i]) return true; } return false; } bool tagcache_is_sorted_tag(int type) { int i; for (i = 0; i < (int)(sizeof(sorted_tags)/sizeof(sorted_tags[0])); i++) { if (type == sorted_tags[i]) return true; } return false; } #ifdef HAVE_TC_RAMCACHE static struct index_entry *find_entry_ram(const char *filename, const struct dircache_entry *dc) { static long last_pos = 0; int counter = 0; int i; /* Check if we tagcache is loaded into ram. */ if (!ramcache) return NULL; if (dc == NULL) dc = dircache_get_entry_ptr(filename); if (dc == NULL) { logf("tagcache: file not found."); return NULL; } try_again: if (last_pos > 0) i = last_pos; else i = 0; for (; i < hdr->h.entry_count; i++) { if (hdr->indices[i].tag_seek[tag_filename] == (long)dc) { last_pos = MAX(0, i - 3); return &hdr->indices[i]; } if (++counter == 100) { yield(); counter = 0; } } if (last_pos > 0) { last_pos = 0; goto try_again; } return NULL; } #endif static struct index_entry *find_entry_disk(const char *filename, bool retrieve) { static struct index_entry idx; static long last_pos = -1; long pos_history[POS_HISTORY_COUNT]; long pos_history_idx = 0; struct tagcache_header tch; bool found = false; struct tagfile_entry tfe; int masterfd, fd = filenametag_fd; char buf[MAX_PATH]; int i; int pos = -1; if (fd < 0) { last_pos = -1; return NULL; } check_again: if (last_pos > 0) lseek(fd, last_pos, SEEK_SET); else lseek(fd, sizeof(struct tagcache_header), SEEK_SET); while (true) { pos = lseek(fd, 0, SEEK_CUR); for (i = pos_history_idx-1; i >= 0; i--) pos_history[i+1] = pos_history[i]; pos_history[0] = pos; if (read(fd, &tfe, sizeof(struct tagfile_entry)) != sizeof(struct tagfile_entry)) { break ; } if (tfe.tag_length >= (long)sizeof(buf)) { logf("too long tag"); close(fd); last_pos = -1; return NULL; } if (read(fd, buf, tfe.tag_length) != tfe.tag_length) { logf("read error #2"); close(fd); last_pos = -1; return NULL; } if (!strcasecmp(filename, buf)) { last_pos = pos_history[pos_history_idx]; found = true; break ; } if (pos_history_idx < POS_HISTORY_COUNT - 1) pos_history_idx++; } /* Not found? */ if (!found) { if (last_pos > 0) { last_pos = -1; logf("seek again"); goto check_again; } //close(fd); return NULL; } if (!retrieve) { /* Just return a valid pointer without a valid entry. */ return &idx; } /* Found. Now read the index_entry (if requested). */ masterfd = open(TAGCACHE_FILE_MASTER, O_RDONLY); if (masterfd < 0) { logf("open fail"); return NULL; } if (read(fd, &tch, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || tch.magic != TAGCACHE_MAGIC) { logf("header error"); return NULL; } for (i = 0; i < tch.entry_count; i++) { if (read(masterfd, &idx, sizeof(struct index_entry)) != sizeof(struct index_entry)) { logf("read error #3"); close(fd); return NULL; } if (idx.tag_seek[tag_filename] == pos) break ; } close(masterfd); /* Not found? */ if (i == tch.entry_count) { logf("not found!"); return NULL; } return &idx; } static long tagcache_get_seek(const struct tagcache_search *tcs, int tag, int idxid) { struct index_entry idx; #ifdef HAVE_TC_RAMCACHE if (tcs->ramsearch) { if (hdr->indices[idxid].flag & FLAG_DELETED) return false; return hdr->indices[idxid].tag_seek[tag]; } #endif lseek(tcs->masterfd, idxid * sizeof(struct index_entry) + sizeof(struct tagcache_header), SEEK_SET); if (read(tcs->masterfd, &idx, sizeof(struct index_entry)) != sizeof(struct index_entry)) { logf("read error #3"); return -4; } return idx.tag_seek[tag]; } long tagcache_get_numeric(const struct tagcache_search *tcs, int tag) { if (!tagcache_is_numeric_tag(tag)) return -1; return tagcache_get_seek(tcs, tag, tcs->idx_id); } static bool check_against_clause(long numeric, const char *str, const struct tagcache_search_clause *clause) { switch (clause->type) { case clause_is: if (clause->numeric) return numeric == clause->numeric_data; else return !strcasecmp(clause->str, str); case clause_gt: return numeric > clause->numeric_data; case clause_gteq: return numeric >= clause->numeric_data; case clause_lt: return numeric < clause->numeric_data; case clause_lteq: return numeric <= clause->numeric_data; case clause_contains: return (strcasestr(str, clause->str) != NULL); case clause_begins_with: return (strcasestr(str, clause->str) == str); case clause_ends_with: /* Not supported yet */ return false; } return false; } static bool build_lookup_list(struct tagcache_search *tcs) { struct index_entry entry; int i; tcs->seek_list_count = 0; #ifdef HAVE_TC_RAMCACHE if (tcs->ramsearch) { int j; for (i = tcs->seek_pos; i < hdr->h.entry_count; i++) { if (tcs->seek_list_count == SEEK_LIST_SIZE) break ; /* Skip deleted files. */ if (hdr->indices[i].flag & FLAG_DELETED) continue; /* Go through all filters.. */ for (j = 0; j < tcs->filter_count; j++) { if (hdr->indices[i].tag_seek[tcs->filter_tag[j]] != tcs->filter_seek[j]) break ; } if (j < tcs->filter_count) continue ; /* Go through all conditional clauses. */ for (j = 0; j < tcs->clause_count; j++) { int seek = hdr->indices[i].tag_seek[tcs->clause[j]->tag]; char *str = NULL; struct tagfile_entry *entry; if (!tagcache_is_numeric_tag(tcs->clause[j]->tag)) { entry = (struct tagfile_entry *)&hdr->tags[tcs->clause[j]->tag][seek]; str = entry->tag_data; } if (!check_against_clause(seek, str, tcs->clause[j])) break ; } if (j < tcs->clause_count) continue ; /* Add to the seek list if not already there. */ for (j = 0; j < tcs->seek_list_count; j++) { if (tcs->seek_list[j] == hdr->indices[i].tag_seek[tcs->type]) break ; } /* Lets add it. */ if (j == tcs->seek_list_count) { tcs->seek_list[tcs->seek_list_count] = hdr->indices[i].tag_seek[tcs->type]; tcs->seek_list_count++; } } tcs->seek_pos = i; return tcs->seek_list_count > 0; } #endif lseek(tcs->masterfd, tcs->seek_pos * sizeof(struct index_entry) + sizeof(struct tagcache_header), SEEK_SET); while (read(tcs->masterfd, &entry, sizeof(struct index_entry)) == sizeof(struct index_entry)) { if (tcs->seek_list_count == SEEK_LIST_SIZE) break ; /* Go through all filters.. */ for (i = 0; i < tcs->filter_count; i++) { if (entry.tag_seek[tcs->filter_tag[i]] != tcs->filter_seek[i]) break ; } tcs->seek_pos++; if (i < tcs->filter_count) continue ; /* Check for conditions. */ for (i = 0; i < tcs->clause_count; i++) { struct tagfile_entry tfe; int seek = entry.tag_seek[tcs->clause[i]->tag]; char str[64]; memset(str, 0, sizeof str); if (!tagcache_is_numeric_tag(tcs->clause[i]->tag)) { int fd = tcs->idxfd[tcs->clause[i]->tag]; lseek(fd, seek, SEEK_SET); read(fd, &tfe, sizeof(struct tagfile_entry)); if (tfe.tag_length >= (int)sizeof(str)) { logf("Too long tag read!"); break ; } read(fd, str, tfe.tag_length); } if (!check_against_clause(seek, str, tcs->clause[i])) break ; } if (i < tcs->clause_count) continue ; /* Add to the seek list if not already there. */ for (i = 0; i < tcs->seek_list_count; i++) { if (tcs->seek_list[i] == entry.tag_seek[tcs->type]) break ; } /* Lets add it. */ if (i == tcs->seek_list_count) { tcs->seek_list[tcs->seek_list_count] = entry.tag_seek[tcs->type]; tcs->seek_list_count++; } } return tcs->seek_list_count > 0; } bool tagcache_search(struct tagcache_search *tcs, int tag) { struct tagcache_header h; char buf[MAX_PATH]; int i; if (tcs->valid) tagcache_search_finish(tcs); memset(tcs, 0, sizeof(struct tagcache_search)); if (tagcache_get_commit_step() > 0) return false; tcs->position = sizeof(struct tagcache_header); tcs->fd = -1; tcs->type = tag; tcs->seek_pos = 0; tcs->seek_list_count = 0; tcs->filter_count = 0; tcs->valid = true; tcs->masterfd = -1; for (i = 0; i < TAG_COUNT; i++) tcs->idxfd[i] = -1; #ifndef HAVE_TC_RAMCACHE tcs->ramsearch = false; #else tcs->ramsearch = ramcache; if (tcs->ramsearch) { tcs->entry_count = hdr->entry_count[tcs->type]; } else #endif { if (tagcache_is_numeric_tag(tcs->type)) return true; snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, tcs->type); tcs->fd = open(buf, O_RDONLY); if (tcs->fd < 0) { logf("failed to open index"); return false; } tcs->idxfd[tcs->type] = tcs->fd; /* Check the header. */ if (read(tcs->fd, &h, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || h.magic != TAGCACHE_MAGIC) { logf("incorrect header"); return false; } tcs->masterfd = open(TAGCACHE_FILE_MASTER, O_RDONLY); if (tcs->masterfd < 0) { logf("open fail"); return false; } if (read(tcs->masterfd, &h, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || h.magic != TAGCACHE_MAGIC) { logf("header error"); close(tcs->masterfd); tcs->masterfd = -1; return false; } } return true; } bool tagcache_search_add_filter(struct tagcache_search *tcs, int tag, int seek) { if (tcs->filter_count == TAGCACHE_MAX_FILTERS) return false; if (!tagcache_is_unique_tag(tag) || tagcache_is_numeric_tag(tag)) return false; tcs->filter_tag[tcs->filter_count] = tag; tcs->filter_seek[tcs->filter_count] = seek; tcs->filter_count++; return true; } bool tagcache_search_add_clause(struct tagcache_search *tcs, struct tagcache_search_clause *clause) { if (tcs->clause_count >= TAGCACHE_MAX_CLAUSES) { logf("Too many clauses"); return false; } if (!tagcache_is_numeric_tag(clause->tag) && tcs->idxfd[clause->tag] < 0) { char buf[MAX_PATH]; snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, clause->tag); tcs->idxfd[clause->tag] = open(buf, O_RDONLY); } tcs->clause[tcs->clause_count] = clause; tcs->clause_count++; return true; } bool tagcache_get_next(struct tagcache_search *tcs) { static char buf[MAX_PATH]; struct tagfile_entry entry; if (!tcs->valid) return false; if (tcs->fd < 0 && !tagcache_is_numeric_tag(tcs->type) #ifdef HAVE_TC_RAMCACHE && !tcs->ramsearch #endif ) return false; /* Searching not supported for numeric tags yet. */ if (tagcache_is_numeric_tag(tcs->type)) return false; /* Relative fetch. */ if (tcs->filter_count > 0 || tcs->clause_count > 0) { /* Check for end of list. */ if (tcs->seek_list_count == 0) { /* Try to fetch more. */ if (!build_lookup_list(tcs)) return false; } tcs->seek_list_count--; /* Seek stream to the correct position and continue to direct fetch. */ if (!tcs->ramsearch) lseek(tcs->fd, tcs->seek_list[tcs->seek_list_count], SEEK_SET); else tcs->position = tcs->seek_list[tcs->seek_list_count]; } /* Direct fetch. */ #ifdef HAVE_TC_RAMCACHE if (tcs->ramsearch) { struct tagfile_entry *ep; if (tcs->entry_count == 0) { tcs->valid = false; return false; } tcs->entry_count--; tcs->result_seek = tcs->position; if (tcs->type == tag_filename) { dircache_copy_path((struct dircache_entry *)tcs->position, buf, sizeof buf); tcs->result = buf; tcs->result_len = strlen(buf) + 1; return true; } ep = (struct tagfile_entry *)&hdr->tags[tcs->type][tcs->position]; tcs->position += sizeof(struct tagfile_entry) + ep->tag_length; tcs->result = ep->tag_data; tcs->result_len = ep->tag_length; tcs->idx_id = ep->idx_id; if (!tagcache_is_unique_tag(tcs->type)) tcs->result_seek = tcs->idx_id; return true; } else #endif { tcs->result_seek = lseek(tcs->fd, 0, SEEK_CUR); if (read(tcs->fd, &entry, sizeof(struct tagfile_entry)) != sizeof(struct tagfile_entry)) { /* End of data. */ tcs->valid = false; return false; } } if (entry.tag_length > (long)sizeof(buf)) { tcs->valid = false; logf("too long tag"); return false; } if (read(tcs->fd, buf, entry.tag_length) != entry.tag_length) { tcs->valid = false; logf("read error"); return false; } tcs->result = buf; tcs->result_len = entry.tag_length; tcs->idx_id = entry.idx_id; if (!tagcache_is_unique_tag(tcs->type)) tcs->result_seek = tcs->idx_id; return true; } bool tagcache_retrieve(struct tagcache_search *tcs, int idxid, char *buf, long size) { struct tagfile_entry tfe; long seek; seek = tagcache_get_seek(tcs, tcs->type, idxid); if (seek < 0) { logf("Retrieve failed"); return false; } #ifdef HAVE_TC_RAMCACHE if (tcs->ramsearch) { if (tcs->type == tag_filename) { dircache_copy_path((struct dircache_entry *)seek, buf, size); } else { struct tagfile_entry *ep; ep = (struct tagfile_entry *)&hdr->tags[tcs->type][seek]; strncpy(buf, ep->tag_data, size-1); } return true; } #endif if (tcs->idxfd[tcs->type] < 0) { char fn[MAX_PATH]; snprintf(fn, sizeof fn, TAGCACHE_FILE_INDEX, tcs->type); tcs->idxfd[tcs->type] = open(fn, O_RDONLY); } if (tcs->idxfd[tcs->type] < 0) { logf("File not open!"); return false; } lseek(tcs->idxfd[tcs->type], seek, SEEK_SET); if (read(tcs->idxfd[tcs->type], &tfe, sizeof(struct tagfile_entry)) != sizeof(struct tagfile_entry)) { logf("read error"); return false; } if (tfe.tag_length >= size) { logf("too small buffer"); return false; } if (read(tcs->idxfd[tcs->type], buf, tfe.tag_length) != tfe.tag_length) { logf("read error #2"); return false; } buf[tfe.tag_length] = '\0'; return true; } #if 0 static bool tagcache_delete(const char *filename) { struct index_entry *entry; entry = find_entry_disk(filename, true); if (entry == NULL) { logf("not found: %s", filename); return false; } } void tagcache_modify(struct tagcache_search *tcs, int type, const char *text) { struct tagentry *entry; if (tcs->type != tag_title) return ; /* We will need reserve buffer for this. */ if (tcs->ramcache) { struct tagfile_entry *ep; ep = (struct tagfile_entry *)&hdr->tags[tcs->type][tcs->result_seek]; tcs->seek_list[tcs->seek_list_count]; } entry = find_entry_ram( } #endif void tagcache_search_finish(struct tagcache_search *tcs) { int i; if (tcs->fd >= 0) { close(tcs->fd); tcs->fd = -1; tcs->idxfd[tcs->type] = -1; } if (tcs->masterfd >= 0) { close(tcs->masterfd); tcs->masterfd = -1; } for (i = 0; i < TAG_COUNT; i++) { if (tcs->idxfd[i] >= 0) { close(tcs->idxfd[i]); tcs->idxfd[i] = -1; } } tcs->ramsearch = false; tcs->valid = false; } #ifdef HAVE_TC_RAMCACHE static struct tagfile_entry *get_tag(const struct index_entry *entry, int tag) { return (struct tagfile_entry *)&hdr->tags[tag][entry->tag_seek[tag]]; } static long get_tag_numeric(const struct index_entry *entry, int tag) { return entry->tag_seek[tag]; } bool tagcache_fill_tags(struct mp3entry *id3, const char *filename) { struct index_entry *entry; /* Find the corresponding entry in tagcache. */ entry = find_entry_ram(filename, NULL); if (entry == NULL || !ramcache) return false; id3->title = get_tag(entry, tag_title)->tag_data; id3->artist = get_tag(entry, tag_artist)->tag_data; id3->album = get_tag(entry, tag_album)->tag_data; id3->genre_string = get_tag(entry, tag_genre)->tag_data; id3->composer = get_tag(entry, tag_composer)->tag_data; id3->year = get_tag_numeric(entry, tag_year); id3->tracknum = get_tag_numeric(entry, tag_tracknumber); id3->bitrate = get_tag_numeric(entry, tag_bitrate); if (id3->bitrate == 0) id3->bitrate = 1; return true; } #endif static inline void write_item(const char *item) { int len = strlen(item) + 1; data_size += len; write(cachefd, item, len); } inline void check_if_empty(char **tag) { if (tag == NULL || *tag == NULL || *tag[0] == '\0') *tag = ""; } #define CRC_BUF_LEN 8 #ifdef HAVE_TC_RAMCACHE static void add_tagcache(const char *path, const struct dircache_entry *dc) #else static void add_tagcache(const char *path) #endif { struct track_info track; struct temp_file_entry entry; bool ret; int fd; char tracknumfix[3]; char *genrestr; //uint32_t crcbuf[CRC_BUF_LEN]; if (cachefd < 0) return ; /* Check if the file is supported. */ if (probe_file_format(path) == AFMT_UNKNOWN) return ; /* Check if the file is already cached. */ #ifdef HAVE_TC_RAMCACHE if (ramcache) { if (find_entry_ram(path, dc)) return ; } else #endif { if (find_entry_disk(path, false)) return ; } fd = open(path, O_RDONLY); if (fd < 0) { logf("open fail: %s", path); return ; } memset(&track, 0, sizeof(struct track_info)); memset(&entry, 0, sizeof(struct temp_file_entry)); memset(&tracknumfix, 0, sizeof(tracknumfix)); ret = get_metadata(&track, fd, path, false); close(fd); if (!ret) return ; genrestr = id3_get_genre(&track.id3); check_if_empty(&track.id3.title); check_if_empty(&track.id3.artist); check_if_empty(&track.id3.album); check_if_empty(&genrestr); check_if_empty(&track.id3.composer); entry.tag_length[tag_filename] = strlen(path) + 1; entry.tag_length[tag_title] = strlen(track.id3.title) + 1; entry.tag_length[tag_artist] = strlen(track.id3.artist) + 1; entry.tag_length[tag_album] = strlen(track.id3.album) + 1; entry.tag_length[tag_genre] = strlen(genrestr) + 1; entry.tag_length[tag_composer] = strlen(track.id3.composer) + 1; entry.tag_offset[tag_filename] = 0; entry.tag_offset[tag_title] = entry.tag_offset[tag_filename] + entry.tag_length[tag_filename]; entry.tag_offset[tag_artist] = entry.tag_offset[tag_title] + entry.tag_length[tag_title]; entry.tag_offset[tag_album] = entry.tag_offset[tag_artist] + entry.tag_length[tag_artist]; entry.tag_offset[tag_genre] = entry.tag_offset[tag_album] + entry.tag_length[tag_album]; entry.tag_offset[tag_composer] = entry.tag_offset[tag_genre] + entry.tag_length[tag_genre]; entry.data_length = entry.tag_offset[tag_composer] + entry.tag_length[tag_composer]; /* Numeric tags */ entry.tag_offset[tag_year] = track.id3.year; entry.tag_offset[tag_tracknumber] = track.id3.tracknum; entry.tag_offset[tag_length] = track.id3.length; entry.tag_offset[tag_bitrate] = track.id3.bitrate; if (entry.tag_offset[tag_tracknumber] <= 0) { const char *p = strrchr(path, '.'); if (p == NULL) p = &path[strlen(path)-1]; while (*p != '/') { if (isdigit(*p) && isdigit(*(p-1))) { tracknumfix[1] = *p--; tracknumfix[0] = *p; break; } p--; } if (tracknumfix[0] != '\0') entry.tag_offset[tag_tracknumber] = atoi(tracknumfix); else entry.tag_offset[tag_tracknumber] = -1; } write(cachefd, &entry, sizeof(struct temp_file_entry)); write_item(path); write_item(track.id3.title); write_item(track.id3.artist); write_item(track.id3.album); write_item(genrestr); write_item(track.id3.composer); total_entry_count++; } static void remove_files(void) { int i; char buf[MAX_PATH]; remove(TAGCACHE_FILE_MASTER); for (i = 0; i < TAG_COUNT; i++) { if (tagcache_is_numeric_tag(i)) continue; snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, i); remove(buf); } } static bool tempbuf_insert(char *str, int id, int idx_id) { struct tempbuf_searchidx *index = (struct tempbuf_searchidx *)tempbuf; int len = strlen(str)+1; /* Insert it to the buffer. */ tempbuf_left -= len + sizeof(struct tempbuf_id); if (tempbuf_left - 4 < 0 || tempbufidx >= TAGFILE_MAX_ENTRIES-1) return false; index[tempbufidx].id = (struct tempbuf_id *)&tempbuf[tempbuf_pos]; #ifdef TAGCACHE_STRICT_ALIGN /* Make sure the entry is long aligned. */ if ((long)index[tempbufidx].id & 0x03) { int fix = 4 - ((long)index[tempbufidx].id & 0x03); tempbuf_left -= fix; tempbuf_pos += fix; index[tempbufidx].id = (struct tempbuf_id *)(( (long)index[tempbufidx].id & ~0x03) + 0x04); } #endif index[tempbufidx].id->id = id; index[tempbufidx].id->next = NULL; index[tempbufidx].idx_id = idx_id; tempbuf_pos += sizeof(struct tempbuf_id); index[tempbufidx].seek = -1; index[tempbufidx].str = &tempbuf[tempbuf_pos]; memcpy(index[tempbufidx].str, str, len); tempbuf_pos += len; tempbufidx++; return true; } static bool tempbuf_unique_insert(char *str, int id) { struct tempbuf_searchidx *index = (struct tempbuf_searchidx *)tempbuf; struct tempbuf_id *idp; int i; unsigned crc32; unsigned *crcbuf = (unsigned *)&tempbuf[tempbuf_size-4]; crc32 = crc_32(str, strlen(str), 0xffffffff); /* Check if the crc does not exist -> entry does not exist for sure. */ for (i = 0; i < tempbufidx; i++) { if (*(crcbuf--) == crc32) { if (!strcasecmp(str, index[i].str)) { tempbuf_left -= sizeof(struct tempbuf_id); if (tempbuf_left - 4 < 0) return false; idp = index[i].id; while (idp->next != NULL) idp = idp->next; idp->next = (struct tempbuf_id *)&tempbuf[tempbuf_pos]; #if TAGCACHE_STRICT_ALIGN /* Make sure the entry is long aligned. */ if ((long)idp->next & 0x03) { int fix = 4 - ((long)idp->next & 0x03); tempbuf_left -= fix; tempbuf_pos += fix; idp->next = (struct tempbuf_id *) (((long)idp->next & ~0x03) + 0x04); } #endif idp = idp->next; idp->id = id; idp->next = NULL; tempbuf_pos += sizeof(struct tempbuf_id); return true; } } } /* Insert and quit. */ *crcbuf = crc32; tempbuf_left -= 4; return tempbuf_insert(str, id, -1); } static int compare(const void *p1, const void *p2) { struct tempbuf_searchidx *e1 = (struct tempbuf_searchidx *)p1; struct tempbuf_searchidx *e2 = (struct tempbuf_searchidx *)p2; /* if (!strncasecmp("the ", e1, 4)) e1 = &e1[4]; if (!strncasecmp("the ", e2, 4)) e2 = &e2[4]; */ return strncasecmp(e1->str, e2->str, MAX_PATH); } static int tempbuf_sort(int fd) { struct tempbuf_searchidx *index = (struct tempbuf_searchidx *)tempbuf; struct tagfile_entry fe; int i; int length; #ifdef TAGCACHE_STRICT_ALIGN int fix; #endif qsort(index, tempbufidx, sizeof(struct tempbuf_searchidx), compare); for (i = 0; i < tempbufidx; i++) { index[i].seek = lseek(fd, 0, SEEK_CUR); length = strlen(index[i].str) + 1; fe.tag_length = length; fe.idx_id = index[i].idx_id; #ifdef TAGCACHE_STRICT_ALIGN /* Make sure the entry is long aligned. */ if (index[i].seek & 0x03) { logf("tempbuf_sort: alignment error!"); return -3; } fix = (sizeof(struct tagfile_entry) + length) & 0x03; if (fix) fix = 4-fix; fe.tag_length += fix; #endif if (write(fd, &fe, sizeof(struct tagfile_entry)) != sizeof(struct tagfile_entry)) { logf("tempbuf_sort: write error #1"); return -1; } if (write(fd, index[i].str, length) != length) { logf("tempbuf_sort: write error #2"); return -2; } #ifdef TAGCACHE_STRICT_ALIGN /* Write some padding. */ if (fix) write(fd, "XXX", fix); #endif } return i; } inline static struct tempbuf_searchidx* tempbuf_locate(int id) { struct tempbuf_searchidx *index = (struct tempbuf_searchidx *)tempbuf; struct tempbuf_id *idp; static int last_id = 0; int i; try_again: if (last_id >= tempbufidx) last_id = 0; /* Check if string already exists. */ /* FIXME: This check is extremely slow, O(n^2) */ for (i = last_id; i < tempbufidx; i++) { idp = index[i].id; while (idp != NULL) { if (idp->id == id) return &index[i]; idp = idp->next; } } if (last_id) goto try_again; return NULL; } inline static int tempbuf_find_location(int id) { struct tempbuf_searchidx *entry; entry = tempbuf_locate(id); if (entry == NULL) return -1; return entry->seek; } static bool build_numeric_index(int index_type, struct tagcache_header *h, int tmpfd) { struct tagcache_header tch; struct index_entry idx; int masterfd; int masterfd_pos; long *databuf = (long *)tempbuf; int max_entries; int i; max_entries = tempbuf_size / sizeof(long); if (h->entry_count >= max_entries) { logf("not enough space!"); return false; } logf("Building numeric index: %d", index_type); /* Walk through the temporary file. */ lseek(tmpfd, sizeof(struct tagcache_header), SEEK_SET); for (i = 0; i < h->entry_count; i++) { struct temp_file_entry entry; if (read(tmpfd, &entry, sizeof(struct temp_file_entry)) != sizeof(struct temp_file_entry)) { logf("read fail #1"); return false; } /* Insert data in buffer. */ databuf[i] = (long)entry.tag_offset[index_type]; /* Skip to next. */ lseek(tmpfd, entry.data_length, SEEK_CUR); } /* Update the entries in index. */ masterfd = open(TAGCACHE_FILE_MASTER, O_RDWR); if (masterfd < 0) { logf("No master file found!"); return false; } if (read(masterfd, &tch, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || tch.magic != TAGCACHE_MAGIC) { logf("header error"); close(masterfd); return false; } masterfd_pos = lseek(masterfd, tch.entry_count * sizeof(struct index_entry), SEEK_CUR); if (masterfd_pos == filesize(masterfd)) { logf("we can't append!"); close(masterfd); return false; } for (i = 0; i < h->entry_count; i++) { int loc = lseek(masterfd, 0, SEEK_CUR); if (read(masterfd, &idx, sizeof(struct index_entry)) != sizeof(struct index_entry)) { logf("read fail #2"); close(masterfd); return false; } idx.tag_seek[index_type] = databuf[i]; /* Write back the updated index. */ lseek(masterfd, loc, SEEK_SET); if (write(masterfd, &idx, sizeof(struct index_entry)) != sizeof(struct index_entry)) { logf("write fail"); close(masterfd); return false; } } close(masterfd); return true; } static bool build_index(int index_type, struct tagcache_header *h, int tmpfd) { int i; struct tagcache_header tch; struct index_entry idxbuf[IDX_BUF_DEPTH]; int idxbuf_pos; char buf[MAX_PATH]; int fd = -1, masterfd; bool error = false; int init; int masterfd_pos; logf("Building index: %d", index_type); tempbufidx = 0; tempbuf_pos = TAGFILE_MAX_ENTRIES * sizeof(struct tempbuf_searchidx); tempbuf_left = tempbuf_size - tempbuf_pos; if (tempbuf_left < 0) { logf("Buffer way too small!"); return false; } /* Open the index file, which contains the tag names. */ snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, index_type); fd = open(buf, O_RDWR); if (fd >= 0) { /* Read the header. */ if (read(fd, &tch, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || tch.magic != TAGCACHE_MAGIC) { logf("header error"); close(fd); return false; } /** * If tag file contains unique tags (sorted index), we will load * it entirely into memory so we can resort it later for use with * chunked browsing. */ if (tagcache_is_sorted_tag(index_type)) { logf("loading tags..."); for (i = 0; i < tch.entry_count; i++) { struct tagfile_entry entry; int loc = lseek(fd, 0, SEEK_CUR); if (read(fd, &entry, sizeof(struct tagfile_entry)) != sizeof(struct tagfile_entry)) { logf("read error"); close(fd); return false; } if (entry.tag_length >= (int)sizeof(buf)) { logf("too long tag"); close(fd); return false; } if (read(fd, buf, entry.tag_length) != entry.tag_length) { logf("read error #2"); close(fd); return false; } /** * Save the tag and tag id in the memory buffer. Tag id * is saved so we can later reindex the master lookup * table when the index gets resorted. */ tempbuf_insert(buf, loc + TAGFILE_MAX_ENTRIES, entry.idx_id); yield(); } logf("done"); } else tempbufidx = tch.entry_count; } else { /** * Creating new index file to store the tags. No need to preload * anything whether the index type is sorted or not. */ fd = open(buf, O_WRONLY | O_CREAT | O_TRUNC); if (fd < 0) { logf("%s open fail", buf); return false; } tch.magic = TAGCACHE_MAGIC; tch.entry_count = 0; tch.datasize = 0; if (write(fd, &tch, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header)) { logf("header write failed"); close(fd); return false; } } /* Loading the tag lookup file as "master file". */ logf("Loading index file"); masterfd = open(TAGCACHE_FILE_MASTER, O_RDWR); if (masterfd < 0) { logf("Creating new index"); masterfd = open(TAGCACHE_FILE_MASTER, O_WRONLY | O_CREAT | O_TRUNC); if (masterfd < 0) { logf("Failure to create index file"); close(fd); return false; } /* Write the header (write real values later). */ tch = *h; tch.entry_count = 0; tch.datasize = 0; write(masterfd, &tch, sizeof(struct tagcache_header)); init = true; masterfd_pos = lseek(masterfd, 0, SEEK_CUR); } else { /** * Master file already exists so we need to process the current * file first. */ init = false; if (read(masterfd, &tch, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || tch.magic != TAGCACHE_MAGIC) { logf("header error"); close(fd); close(masterfd); return false; } /** * If we reach end of the master file, we need to expand it to * hold new tags. If the current index is not sorted, we can * simply append new data to end of the file. * However, if the index is sorted, we need to update all tag * pointers in the master file for the current index. */ masterfd_pos = lseek(masterfd, tch.entry_count * sizeof(struct index_entry), SEEK_CUR); if (masterfd_pos == filesize(masterfd)) { logf("appending..."); init = true; } } /** * Load new unique tags in memory to be sorted later and added * to the master lookup file. */ if (tagcache_is_sorted_tag(index_type)) { lseek(tmpfd, sizeof(struct tagcache_header), SEEK_SET); /* h is the header of the temporary file containing new tags. */ logf("inserting new tags..."); for (i = 0; i < h->entry_count; i++) { struct temp_file_entry entry; if (read(tmpfd, &entry, sizeof(struct temp_file_entry)) != sizeof(struct temp_file_entry)) { logf("read fail #1"); error = true; goto error_exit; } /* Read data. */ if (entry.tag_length[index_type] >= (long)sizeof(buf)) { logf("too long entry!"); error = true; goto error_exit; } lseek(tmpfd, entry.tag_offset[index_type], SEEK_CUR); if (read(tmpfd, buf, entry.tag_length[index_type]) != entry.tag_length[index_type]) { logf("read fail #3"); error = true; goto error_exit; } if (tagcache_is_unique_tag(index_type)) error = !tempbuf_unique_insert(buf, i); else error = !tempbuf_insert(buf, i, tch.entry_count + i); if (error) { logf("insert error"); goto error_exit; } /* Skip to next. */ lseek(tmpfd, entry.data_length - entry.tag_offset[index_type] - entry.tag_length[index_type], SEEK_CUR); yield(); } logf("done"); /* Sort the buffer data and write it to the index file. */ lseek(fd, sizeof(struct tagcache_header), SEEK_SET); i = tempbuf_sort(fd); if (i < 0) goto error_exit; logf("sorted %d tags", i); /** * Now update all indexes in the master lookup file. */ logf("updating indices..."); lseek(masterfd, sizeof(struct tagcache_header), SEEK_SET); for (i = 0; i < tch.entry_count; i += idxbuf_pos) { int j; int loc = lseek(masterfd, 0, SEEK_CUR); idxbuf_pos = MIN(tch.entry_count - i, IDX_BUF_DEPTH); if (read(masterfd, idxbuf, sizeof(struct index_entry)*idxbuf_pos) != (int)sizeof(struct index_entry)*idxbuf_pos) { logf("read fail #2"); error = true; goto error_exit ; } lseek(masterfd, loc, SEEK_SET); for (j = 0; j < idxbuf_pos; j++) { idxbuf[j].tag_seek[index_type] = tempbuf_find_location( idxbuf[j].tag_seek[index_type]+TAGFILE_MAX_ENTRIES); if (idxbuf[j].tag_seek[index_type] < 0) { logf("update error: %d/%d", i+j, tch.entry_count); error = true; goto error_exit; } yield(); } /* Write back the updated index. */ if (write(masterfd, idxbuf, sizeof(struct index_entry)*idxbuf_pos) != (int)sizeof(struct index_entry)*idxbuf_pos) { logf("write fail"); error = true; goto error_exit; } } logf("done"); } /** * Walk through the temporary file containing the new tags. */ // build_normal_index(h, tmpfd, masterfd, idx); logf("updating new indices..."); lseek(masterfd, masterfd_pos, SEEK_SET); lseek(tmpfd, sizeof(struct tagcache_header), SEEK_SET); lseek(fd, 0, SEEK_END); for (i = 0; i < h->entry_count; i += idxbuf_pos) { int j; idxbuf_pos = MIN(h->entry_count - i, IDX_BUF_DEPTH); if (init) { memset(idxbuf, 0, sizeof(struct index_entry)*IDX_BUF_DEPTH); } else { int loc = lseek(masterfd, 0, SEEK_CUR); if (read(masterfd, idxbuf, sizeof(struct index_entry)*idxbuf_pos) != (int)sizeof(struct index_entry)*idxbuf_pos) { logf("read fail #2"); error = true; break ; } lseek(masterfd, loc, SEEK_SET); } /* Read entry headers. */ for (j = 0; j < idxbuf_pos; j++) { if (!tagcache_is_sorted_tag(index_type)) { struct temp_file_entry entry; struct tagfile_entry fe; if (read(tmpfd, &entry, sizeof(struct temp_file_entry)) != sizeof(struct temp_file_entry)) { logf("read fail #1"); error = true; break ; } /* Read data. */ if (entry.tag_length[index_type] >= (int)sizeof(buf)) { logf("too long entry!"); logf("length=%d", entry.tag_length[index_type]); logf("pos=0x%02x", lseek(tmpfd, 0, SEEK_CUR)); error = true; break ; } lseek(tmpfd, entry.tag_offset[index_type], SEEK_CUR); if (read(tmpfd, buf, entry.tag_length[index_type]) != entry.tag_length[index_type]) { logf("read fail #3"); logf("offset=0x%02x", entry.tag_offset[index_type]); logf("length=0x%02x", entry.tag_length[index_type]); error = true; break ; } /* Write to index file. */ idxbuf[j].tag_seek[index_type] = lseek(fd, 0, SEEK_CUR); fe.tag_length = entry.tag_length[index_type]; fe.idx_id = tch.entry_count + i + j; write(fd, &fe, sizeof(struct tagfile_entry)); write(fd, buf, fe.tag_length); tempbufidx++; /* Skip to next. */ lseek(tmpfd, entry.data_length - entry.tag_offset[index_type] - entry.tag_length[index_type], SEEK_CUR); } else { /* Locate the correct entry from the sorted array. */ idxbuf[j].tag_seek[index_type] = tempbuf_find_location(i + j); if (idxbuf[j].tag_seek[index_type] < 0) { logf("entry not found (%d)"); error = true; break ; } } } /* Write index. */ if (write(masterfd, idxbuf, sizeof(struct index_entry)*idxbuf_pos) != (int)sizeof(struct index_entry)*idxbuf_pos) { logf("tagcache: write fail #4"); error = true; break ; } yield(); } logf("done"); /* Finally write the uniqued tag index file. */ if (tagcache_is_sorted_tag(index_type)) { tch.magic = TAGCACHE_MAGIC; tch.entry_count = tempbufidx; tch.datasize = lseek(fd, 0, SEEK_END) - sizeof(struct tagcache_header); lseek(fd, 0, SEEK_SET); write(fd, &tch, sizeof(struct tagcache_header)); } else { tch.magic = TAGCACHE_MAGIC; tch.entry_count = tempbufidx; tch.datasize = lseek(fd, 0, SEEK_CUR) - sizeof(struct tagcache_header); lseek(fd, 0, SEEK_SET); write(fd, &tch, sizeof(struct tagcache_header)); } error_exit: close(fd); close(masterfd); return !error; } static bool commit(void) { struct tagcache_header header, header_old; int i, len, rc; int tmpfd; int masterfd; logf("committing tagcache"); tmpfd = open(TAGCACHE_FILE_TEMP, O_RDONLY); if (tmpfd < 0) { logf("nothing to commit"); return true; } /* Load the header. */ len = sizeof(struct tagcache_header); rc = read(tmpfd, &header, len); if (header.magic != TAGCACHE_MAGIC || rc != len) { logf("incorrect header"); close(tmpfd); remove_files(); remove(TAGCACHE_FILE_TEMP); return false; } if (header.entry_count == 0) { logf("nothing to commit"); close(tmpfd); remove(TAGCACHE_FILE_TEMP); return true; } /* Try to steal every buffer we can :) */ #ifdef HAVE_TC_RAMCACHE if (tempbuf_size == 0 && tagcache_size > 0) { ramcache = false; tempbuf = (char *)(hdr + 1); tempbuf_size = tagcache_size - sizeof(struct ramcache_header); } #endif #ifdef HAVE_DIRCACHE if (tempbuf_size == 0) { /* Try to steal the dircache buffer. */ tempbuf = dircache_steal_buffer(&tempbuf_size); } #endif /* And finally fail if there are no buffers available. */ if (tempbuf_size == 0) { logf("delaying commit until next boot"); close(tmpfd); return false; } logf("commit %d entries...", header.entry_count); /* Now create the index files. */ init_step = 0; for (i = 0; i < TAG_COUNT; i++) { init_step++; if (tagcache_is_numeric_tag(i)) { build_numeric_index(i, &header, tmpfd); } else if (!build_index(i, &header, tmpfd)) { logf("tagcache failed init"); remove_files(); init_step = 0; return false; } } close(tmpfd); init_step = 0; /* Update the master index headers. */ masterfd = open(TAGCACHE_FILE_MASTER, O_RDWR); if (masterfd < 0) { logf("failed to open master index"); return false; } if (read(masterfd, &header_old, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || header_old.magic != TAGCACHE_MAGIC) { logf("incorrect header"); close(masterfd); remove_files(); return false; } header.entry_count += header_old.entry_count; header.datasize += header_old.datasize; lseek(masterfd, 0, SEEK_SET); write(masterfd, &header, sizeof(struct tagcache_header)); close(masterfd); logf("tagcache committed"); remove(TAGCACHE_FILE_TEMP); #ifdef HAVE_DIRCACHE /* Rebuild the dircache, if we stole the buffer. */ dircache_build(0); #endif #ifdef HAVE_TC_RAMCACHE /* Reload tagcache. */ if (tagcache_size > 0 && !ramcache) tagcache_start_scan(); #endif return true; } static void allocate_tempbuf(void) { /* Yeah, malloc would be really nice now :) */ tempbuf = (char *)(((long)audiobuf & ~0x03) + 0x04); tempbuf_size = (long)audiobufend - (long)audiobuf - 4; audiobuf += tempbuf_size; } static void free_tempbuf(void) { if (tempbuf_size == 0) return ; audiobuf -= tempbuf_size; tempbuf = NULL; tempbuf_size = 0; } #ifdef HAVE_TC_RAMCACHE static bool allocate_tagcache(void) { int rc, len; int fd; hdr = NULL; fd = open(TAGCACHE_FILE_MASTER, O_RDONLY); if (fd < 0) { logf("no tagcache file found."); return false; } /* Load the header. */ hdr = (struct ramcache_header *)(((long)audiobuf & ~0x03) + 0x04); memset(hdr, 0, sizeof(struct ramcache_header)); len = sizeof(struct tagcache_header); rc = read(fd, &hdr->h, len); close(fd); if (hdr->h.magic != TAGCACHE_MAGIC || rc != len) { logf("incorrect header"); remove_files(); hdr = NULL; return false; } hdr->indices = (struct index_entry *)(hdr + 1); /** * Now calculate the required cache size plus * some extra space for alignment fixes. */ tagcache_size = hdr->h.datasize + 128 + TAGCACHE_RESERVE + sizeof(struct index_entry) * hdr->h.entry_count + sizeof(struct ramcache_header) + TAG_COUNT*sizeof(void *); logf("tagcache: %d bytes allocated.", tagcache_size); logf("at: 0x%04x", audiobuf); audiobuf += (long)((tagcache_size & ~0x03) + 0x04); return true; } static bool load_tagcache(void) { struct tagcache_header *tch; long bytesleft = tagcache_size; struct index_entry *idx; int rc, fd; char *p; int i; /* We really need the dircache for this. */ if (!dircache_is_enabled()) return false; logf("loading tagcache to ram..."); fd = open(TAGCACHE_FILE_MASTER, O_RDONLY); if (fd < 0) { logf("tagcache open failed"); return false; } if (read(fd, &hdr->h, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || hdr->h.magic != TAGCACHE_MAGIC) { logf("incorrect header"); return false; } lseek(fd, sizeof(struct tagcache_header), SEEK_SET); idx = hdr->indices; /* Load the master index table. */ for (i = 0; i < hdr->h.entry_count; i++) { rc = read(fd, idx, sizeof(struct index_entry)); if (rc != sizeof(struct index_entry)) { logf("read error #1"); close(fd); return false; } bytesleft -= sizeof(struct index_entry); if (bytesleft < 0 || ((long)idx - (long)hdr->indices) >= tagcache_size) { logf("too big tagcache."); close(fd); return false; } idx++; } close(fd); /* Load the tags. */ p = (char *)idx; for (i = 0; i < TAG_COUNT; i++) { struct tagfile_entry *fe; char buf[MAX_PATH]; if (tagcache_is_numeric_tag(i)) continue ; //p = ((void *)p+1); p = (char *)((long)p & ~0x03) + 0x04; hdr->tags[i] = p; snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, i); fd = open(buf, O_RDONLY); if (fd < 0) { logf("%s open fail", buf); return false; } /* Check the header. */ tch = (struct tagcache_header *)p; rc = read(fd, tch, sizeof(struct tagcache_header)); p += rc; if (rc != sizeof(struct tagcache_header) || tch->magic != TAGCACHE_MAGIC) { logf("incorrect header"); close(fd); return false; } for (hdr->entry_count[i] = 0; hdr->entry_count[i] < tch->entry_count; hdr->entry_count[i]++) { yield(); fe = (struct tagfile_entry *)p; rc = read(fd, fe, sizeof(struct tagfile_entry)); if (rc != sizeof(struct tagfile_entry)) { /* End of lookup table. */ logf("read error"); close(fd); return false; } /* We have a special handling for the filename tags. */ if (i == tag_filename) { const struct dircache_entry *dc; if (fe->tag_length >= (long)sizeof(buf)-1) { logf("too long filename"); close(fd); return false; } rc = read(fd, buf, fe->tag_length); if (rc != fe->tag_length) { logf("read error #3"); close(fd); return false; } dc = dircache_get_entry_ptr(buf); if (dc == NULL) { logf("Entry no longer valid."); logf("-> %s", buf); /* FIXME: Properly delete the entry. */ hdr->indices[hdr->entry_count[i]].flag |= FLAG_DELETED; continue ; } hdr->indices[hdr->entry_count[i]].tag_seek[tag_filename] = (long)dc; continue ; } bytesleft -= sizeof(struct tagfile_entry) + fe->tag_length; if (bytesleft < 0) { logf("too big tagcache."); close(fd); return false; } p = fe->tag_data; rc = read(fd, fe->tag_data, fe->tag_length); p += rc; if (rc != fe->tag_length) { logf("read error #4"); logf("rc=0x%04x", rc); // 0x431 logf("len=0x%04x", fe->tag_length); // 0x4000 logf("pos=0x%04x", lseek(fd, 0, SEEK_CUR)); // 0x433 logf("i=0x%02x", i); // 0x00 close(fd); return false; } } close(fd); } logf("tagcache loaded into ram!"); return true; } #endif static bool check_dir(const char *dirname) { DIRCACHED *dir; int len; int success = false; dir = opendir_cached(dirname); if (!dir) { logf("tagcache: opendir_cached() failed"); return false; } /* Recursively scan the dir. */ while (queue_empty(&tagcache_queue)) { struct dircache_entry *entry; entry = readdir_cached(dir); if (entry == NULL) { success = true; break ; } if (!strcmp(entry->d_name, ".") || !strcmp(entry->d_name, "..")) continue; yield(); len = strlen(curpath); snprintf(&curpath[len], curpath_size - len, "/%s", entry->d_name); processed_dir_count++; if (entry->attribute & ATTR_DIRECTORY) check_dir(curpath); else #ifdef HAVE_TC_RAMCACHE add_tagcache(curpath, dir->internal_entry); #else add_tagcache(curpath); #endif curpath[len] = '\0'; } closedir_cached(dir); return success; } static void build_tagcache(void) { struct tagcache_header header; bool ret; char buf[MAX_PATH]; curpath[0] = '\0'; data_size = 0; total_entry_count = 0; processed_dir_count = 0; logf("updating tagcache"); cachefd = open(TAGCACHE_FILE_TEMP, O_RDONLY); if (cachefd >= 0) { logf("skipping, cache already waiting for commit"); close(cachefd); return ; } cachefd = open(TAGCACHE_FILE_TEMP, O_RDWR | O_CREAT | O_TRUNC); if (cachefd < 0) { logf("master file open failed"); return ; } snprintf(buf, sizeof buf, TAGCACHE_FILE_INDEX, tag_filename); filenametag_fd = open(buf, O_RDONLY); if (filenametag_fd >= 0) { if (read(filenametag_fd, &header, sizeof(struct tagcache_header)) != sizeof(struct tagcache_header) || header.magic != TAGCACHE_MAGIC) { logf("header error"); close(filenametag_fd); filenametag_fd = -1; } } cpu_boost(true); /* Scan for new files. */ memset(&header, 0, sizeof(struct tagcache_header)); write(cachefd, &header, sizeof(struct tagcache_header)); //strcpy(curpath, "/Best"); ret = check_dir("/"); /* Write the header. */ header.magic = TAGCACHE_MAGIC; header.datasize = data_size; header.entry_count = total_entry_count; lseek(cachefd, 0, SEEK_SET); write(cachefd, &header, sizeof(struct tagcache_header)); close(cachefd); if (filenametag_fd >= 0) { close(filenametag_fd); filenametag_fd = -1; } if (!ret) { logf("Aborted."); cpu_boost(false); return ; } /* Commit changes to the database. */ if (commit()) { remove(TAGCACHE_FILE_TEMP); logf("tagcache built!"); } cpu_boost(false); } #ifdef HAVE_TC_RAMCACHE static void load_ramcache(void) { if (!hdr) return ; cpu_boost(true); /* At first we should load the cache (if exists). */ ramcache = load_tagcache(); if (!ramcache) { hdr = NULL; remove_files(); } cpu_boost(false); } #endif static void tagcache_thread(void) { struct event ev; bool check_done = false; /* If the previous cache build/update was interrupted, commit * the changes first in foreground. */ cpu_boost(true); allocate_tempbuf(); commit(); free_tempbuf(); cpu_boost(false); tagcache_init_done = true; while (1) { queue_wait_w_tmo(&tagcache_queue, &ev, HZ); switch (ev.id) { case Q_START_SCAN: check_done = false; break ; case Q_FORCE_UPDATE: //remove_files(); build_tagcache(); break ; #ifdef HAVE_TC_RAMCACHE case SYS_TIMEOUT: if (check_done || !dircache_is_enabled()) break ; if (!ramcache && global_settings.tagcache_ram) load_ramcache(); if (ramcache) build_tagcache(); check_done = true; break ; #endif case Q_STOP_SCAN: break ; case SYS_POWEROFF: break ; #ifndef SIMULATOR case SYS_USB_CONNECTED: logf("USB: TagCache"); usb_acknowledge(SYS_USB_CONNECTED_ACK); usb_wait_for_disconnect(&tagcache_queue); break ; #endif } } } int tagcache_get_progress(void) { int total_count = -1; #ifdef HAVE_DIRCACHE if (dircache_is_enabled()) { total_count = dircache_get_entry_count(); } else { if (hdr && ramcache) total_count = hdr->h.entry_count; } #endif if (total_count < 0) return -1; return processed_dir_count * 100 / total_count; } int tagcache_get_processes_entrycount(void) { return processed_dir_count; } void tagcache_start_scan(void) { queue_post(&tagcache_queue, Q_START_SCAN, 0); } bool tagcache_force_update(void) { queue_post(&tagcache_queue, Q_FORCE_UPDATE, 0); gui_syncsplash(HZ*2, true, str(LANG_TAGCACHE_FORCE_UPDATE_SPLASH)); return false; } void tagcache_stop_scan(void) { queue_post(&tagcache_queue, Q_STOP_SCAN, 0); } #ifdef HAVE_TC_RAMCACHE bool tagcache_is_ramcache(void) { return ramcache; } #endif void tagcache_init(void) { tagcache_init_done = false; init_step = 0; #ifdef HAVE_TC_RAMCACHE /* Allocate space for the tagcache if found on disk. */ allocate_tagcache(); #endif queue_init(&tagcache_queue); create_thread(tagcache_thread, tagcache_stack, sizeof(tagcache_stack), tagcache_thread_name); } bool tagcache_is_initialized(void) { return tagcache_init_done; } int tagcache_get_commit_step(void) { return init_step; }