/* * Copyright (c) 2008 The DragonFly Project. All rights reserved. * * This code is derived from software contributed to The DragonFly Project * by Matthew Dillon * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name of The DragonFly Project nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific, prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include "hammer.h" #include #include #define FLAG_TOOFARLEFT 0x0001 #define FLAG_TOOFARRIGHT 0x0002 #define FLAG_BADTYPE 0x0004 #define FLAG_BADCHILDPARENT 0x0008 #define FLAG_BADMIRRORTID 0x0010 static struct { struct hammer_base_elm base; int limit; /* # of fields to test */ int filter; /* filter type (default -1) */ int obfuscate; /* obfuscate direntry name */ int indent; /* use depth indentation */ zone_stat_t stats; } opt; static __inline void print_btree(hammer_off_t node_offset); static __inline void print_subtree(hammer_btree_elm_t elm); static void print_btree_node(hammer_off_t node_offset, hammer_tid_t mirror_tid, hammer_btree_elm_t lbe); static int test_node_count(hammer_node_ondisk_t node, char *badmp); static void print_btree_elm(hammer_node_ondisk_t node, hammer_off_t node_offset, hammer_btree_elm_t elm, hammer_btree_elm_t lbe, const char *ext); static int get_elm_flags(hammer_node_ondisk_t node, hammer_off_t node_offset, hammer_btree_elm_t elm, hammer_btree_elm_t lbe); static int test_lr(hammer_btree_elm_t elm, hammer_btree_elm_t lbe); static int test_rbn_lr(hammer_btree_elm_t elm, hammer_btree_elm_t lbe); static void print_bigblock_fill(hammer_off_t offset); static const char *check_data_crc(hammer_btree_elm_t elm, const char **whichp); static hammer_crc_t get_inode_crc(hammer_btree_leaf_elm_t leaf, const char **whichp); static hammer_crc_t get_buf_crc(hammer_btree_leaf_elm_t leaf, const char **whichp); static void print_record(hammer_btree_elm_t elm); static int init_btree_search(const char *arg); static int test_btree_search(hammer_btree_elm_t elm); static __inline int test_btree_match(hammer_btree_elm_t elm); static int test_btree_out_of_range(hammer_btree_elm_t elm); static void hexdump_record(const void *ptr, int length, const char *hdr); static int num_bad_node = 0; static int num_bad_elm = 0; static int num_bad_rec = 0; static int depth; static const char* _indents[] = { "", "\t", "\t\t", "\t\t\t", "\t\t\t\t", "\t\t\t\t\t", "\t\t\t\t\t\t", "\t\t\t\t\t\t\t", "\t\t\t\t\t\t\t\t", "\t\t\t\t\t\t\t\t\t", /* deep enough */ }; #define INDENT _indents[opt.indent ? depth : 0] void hammer_cmd_show(const char *arg, int filter, int obfuscate, int indent) { volume_info_t volume; hammer_volume_ondisk_t ondisk; zone_stat_t stats = NULL; volume = get_root_volume(); ondisk = volume->ondisk; print_blockmap(volume); if (VerboseOpt) stats = hammer_init_zone_stat_bits(); bzero(&opt, sizeof(opt)); opt.filter = filter; opt.obfuscate = obfuscate; opt.indent = indent; opt.stats = stats; if (init_btree_search(arg) > 0) { printf("arg=\"%s\"", arg); if (opt.limit > 0) printf(" lo=%08x", opt.base.localization); if (opt.limit > 1) printf(" objid=%016jx", (uintmax_t)opt.base.obj_id); if (opt.limit > 2) printf(" rt=%02x", opt.base.rec_type); if (opt.limit > 3) printf(" key=%016jx", (uintmax_t)opt.base.key); if (opt.limit > 4) printf(" tid=%016jx", (uintmax_t)opt.base.create_tid); printf("\n"); } print_btree(ondisk->vol0_btree_root); if (stats) { hammer_print_zone_stat(stats); hammer_cleanup_zone_stat(stats); } if (num_bad_node || VerboseOpt) printf("%d bad nodes\n", num_bad_node); if (num_bad_elm || VerboseOpt) printf("%d bad elms\n", num_bad_elm); if (num_bad_rec || VerboseOpt) printf("%d bad records\n", num_bad_rec); } static __inline void print_btree(hammer_off_t node_offset) { depth = -1; print_btree_node(node_offset, HAMMER_MAX_TID, NULL); assert(depth == -1); } static __inline void print_subtree(hammer_btree_elm_t elm) { hammer_btree_internal_elm_t i = &elm->internal; print_btree_node(i->subtree_offset, i->mirror_tid, elm); } static void print_btree_node(hammer_off_t node_offset, hammer_tid_t mirror_tid, hammer_btree_elm_t lbe) { buffer_info_t buffer = NULL; hammer_node_ondisk_t node; hammer_btree_elm_t elm; int i; char badc = ' '; /* good */ char badm = ' '; /* good */ const char *ext; depth++; node = get_buffer_data(node_offset, &buffer, 0); if (node == NULL) { badc = 'B'; badm = 'I'; } else { if (!hammer_crc_test_btree(HammerVersion, node)) badc = 'B'; if (node->mirror_tid > mirror_tid) { badc = 'B'; badm = 'M'; } if (test_node_count(node, &badm) == -1) { badc = 'B'; assert(badm != ' '); } } if (badm != ' ' || badc != ' ') /* not good */ ++num_bad_node; printf("%s%c%c NODE %016jx ", INDENT, badc, badm, (uintmax_t)node_offset); printf("cnt=%02d p=%016jx type=%c depth=%d mirror=%016jx", node->count, (uintmax_t)node->parent, (node->type ? node->type : '?'), depth, (uintmax_t)node->mirror_tid); printf(" fill="); print_bigblock_fill(node_offset); printf(" {\n"); if (opt.stats) hammer_add_zone_stat(opt.stats, node_offset, sizeof(*node)); for (i = 0; i < node->count; ++i) { elm = &node->elms[i]; ext = NULL; if (opt.limit) { switch (node->type) { case HAMMER_BTREE_TYPE_INTERNAL: if (!test_btree_out_of_range(elm)) ext = "*"; break; case HAMMER_BTREE_TYPE_LEAF: if (test_btree_match(elm)) ext = "*"; break; } } print_btree_elm(node, node_offset, elm, lbe, ext); } if (node->type == HAMMER_BTREE_TYPE_INTERNAL) { assert(i == node->count); /* boundary */ elm = &node->elms[i]; print_btree_elm(node, node_offset, elm, lbe, NULL); } printf("%s }\n", INDENT); if (node->type == HAMMER_BTREE_TYPE_INTERNAL) { for (i = 0; i < node->count; ++i) { elm = &node->elms[i]; if (opt.limit && opt.filter) { if (test_btree_out_of_range(elm)) continue; } if (elm->internal.subtree_offset) { print_subtree(elm); /* * Cause show to do normal iteration after * seeking to the lo:objid:rt:key:tid * by default */ if (opt.limit && opt.filter == -1) /* default */ opt.filter = 0; } } } rel_buffer(buffer); depth--; } static int test_node_count(hammer_node_ondisk_t node, char *badmp) { hammer_node_ondisk_t parent_node; buffer_info_t buffer = NULL; int maxcount; maxcount = hammer_node_max_elements(node->type); if (maxcount == -1) { *badmp = 'U'; return(-1); } else if (node->count > maxcount) { *badmp = 'C'; return(-1); } else if (node->count == 0) { parent_node = get_buffer_data(node->parent, &buffer, 0); if (parent_node->count != 1) { *badmp = 'C'; rel_buffer(buffer); return(-1); } rel_buffer(buffer); } return(0); } static __inline int is_root_btree_beg(uint8_t type, int i, hammer_btree_elm_t elm) { /* * elm->base.btype depends on what the original node had * so it could be anything but HAMMER_BTREE_TYPE_NONE. */ return (type == HAMMER_BTREE_TYPE_INTERNAL && i == 0 && elm->base.localization == HAMMER_MIN_ONDISK_LOCALIZATION && elm->base.obj_id == (int64_t)HAMMER_MIN_OBJID && elm->base.key == (int64_t)HAMMER_MIN_KEY && elm->base.create_tid == 1 && elm->base.delete_tid == 1 && elm->base.rec_type == HAMMER_MIN_RECTYPE && elm->base.obj_type == 0 && elm->base.btype != HAMMER_BTREE_TYPE_NONE); } static __inline int is_root_btree_end(uint8_t type, int i, hammer_btree_elm_t elm) { return (type == HAMMER_BTREE_TYPE_INTERNAL && i != 0 && elm->base.localization == HAMMER_MAX_ONDISK_LOCALIZATION && elm->base.obj_id == HAMMER_MAX_OBJID && elm->base.key == HAMMER_MAX_KEY && elm->base.create_tid == HAMMER_MAX_TID && elm->base.delete_tid == 0 && elm->base.rec_type == HAMMER_MAX_RECTYPE && elm->base.obj_type == 0 && elm->base.btype == HAMMER_BTREE_TYPE_NONE); } static void print_btree_elm(hammer_node_ondisk_t node, hammer_off_t node_offset, hammer_btree_elm_t elm, hammer_btree_elm_t lbe, const char *ext) { char flagstr[8] = { 0, '-', '-', '-', '-', '-', '-', 0 }; char deleted; char rootelm; const char *label; const char *p; const char *which; int flags; int i = ((char*)elm - (char*)node) / (int)sizeof(*elm) - 1; flags = get_elm_flags(node, node_offset, elm, lbe); flagstr[0] = flags ? 'B' : 'G'; if (flags & FLAG_TOOFARLEFT) flagstr[2] = 'L'; if (flags & FLAG_TOOFARRIGHT) flagstr[3] = 'R'; if (flags & FLAG_BADTYPE) flagstr[4] = 'T'; if (flags & FLAG_BADCHILDPARENT) flagstr[5] = 'C'; if (flags & FLAG_BADMIRRORTID) flagstr[6] = 'M'; if (flagstr[0] == 'B') ++num_bad_elm; /* * Check if elm is derived from root split */ if (is_root_btree_beg(node->type, i, elm)) rootelm = '>'; else if (is_root_btree_end(node->type, i, elm)) rootelm = '<'; else rootelm = ' '; if (elm->base.delete_tid) deleted = 'd'; else deleted = ' '; if (node->type == HAMMER_BTREE_TYPE_INTERNAL && node->count == i) label = "RBN"; else label = "ELM"; printf("%s%s %s %2d %c ", INDENT, flagstr, label, i, hammer_elm_btype(elm)); printf("lo=%08x objid=%016jx rt=%02x key=%016jx tid=%016jx\n", elm->base.localization, (uintmax_t)elm->base.obj_id, elm->base.rec_type, (uintmax_t)elm->base.key, (uintmax_t)elm->base.create_tid); printf("%s %c del=%016jx ot=%02x", INDENT, (rootelm == ' ' ? deleted : rootelm), (uintmax_t)elm->base.delete_tid, elm->base.obj_type); switch(node->type) { case HAMMER_BTREE_TYPE_INTERNAL: printf(" suboff=%016jx mirror=%016jx", (uintmax_t)elm->internal.subtree_offset, (uintmax_t)elm->internal.mirror_tid); if (ext) printf(" %s", ext); break; case HAMMER_BTREE_TYPE_LEAF: switch(elm->base.btype) { case HAMMER_BTREE_TYPE_RECORD: printf(" dataoff=%016jx/%d", (uintmax_t)elm->leaf.data_offset, elm->leaf.data_len); p = check_data_crc(elm, &which); printf(" %scrc=%08x", which, elm->leaf.data_crc); if (p) { printf(" error=%s", p); ++num_bad_rec; } printf(" fill="); print_bigblock_fill(elm->leaf.data_offset); if (QuietOpt < 2) print_record(elm); if (opt.stats) { hammer_add_zone_stat(opt.stats, elm->leaf.data_offset, elm->leaf.data_len); } break; default: printf(" badtype=%d", elm->base.btype); break; } if (ext) printf(" %s", ext); break; } printf("\n"); } static int get_elm_flags(hammer_node_ondisk_t node, hammer_off_t node_offset, hammer_btree_elm_t elm, hammer_btree_elm_t lbe) { hammer_off_t child_offset; int flags = 0; int i = ((char*)elm - (char*)node) / (int)sizeof(*elm) - 1; switch(node->type) { case HAMMER_BTREE_TYPE_INTERNAL: child_offset = elm->internal.subtree_offset; if (elm->internal.mirror_tid > node->mirror_tid) flags |= FLAG_BADMIRRORTID; if (i == node->count) { if (child_offset != 0) flags |= FLAG_BADCHILDPARENT; switch(elm->base.btype) { case HAMMER_BTREE_TYPE_NONE: flags |= test_rbn_lr(elm, lbe); break; default: flags |= FLAG_BADTYPE; break; } } else { if (child_offset == 0) { flags |= FLAG_BADCHILDPARENT; } else { buffer_info_t buffer = NULL; hammer_node_ondisk_t subnode; subnode = get_buffer_data(child_offset, &buffer, 0); if (subnode == NULL) flags |= FLAG_BADCHILDPARENT; else if (subnode->parent != node_offset) flags |= FLAG_BADCHILDPARENT; rel_buffer(buffer); } switch(elm->base.btype) { case HAMMER_BTREE_TYPE_INTERNAL: case HAMMER_BTREE_TYPE_LEAF: flags |= test_lr(elm, lbe); break; default: flags |= FLAG_BADTYPE; break; } } break; case HAMMER_BTREE_TYPE_LEAF: if (elm->leaf.data_offset == 0) flags |= FLAG_BADCHILDPARENT; if (elm->leaf.data_len == 0) flags |= FLAG_BADCHILDPARENT; if (node->mirror_tid == 0 && !(node->parent == 0 && node->count == 2)) { flags |= FLAG_BADMIRRORTID; } if (elm->base.create_tid && node->mirror_tid && elm->base.create_tid > node->mirror_tid) { flags |= FLAG_BADMIRRORTID; } if (elm->base.delete_tid && node->mirror_tid && elm->base.delete_tid > node->mirror_tid) { flags |= FLAG_BADMIRRORTID; } switch(elm->base.btype) { case HAMMER_BTREE_TYPE_RECORD: flags |= test_lr(elm, lbe); break; default: flags |= FLAG_BADTYPE; break; } break; default: flags |= FLAG_BADTYPE; break; } return(flags); } /* * Taken from /usr/src/sys/vfs/hammer/hammer_btree.c. */ static int hammer_btree_cmp(hammer_base_elm_t key1, hammer_base_elm_t key2) { if (key1->localization < key2->localization) return(-5); if (key1->localization > key2->localization) return(5); if (key1->obj_id < key2->obj_id) return(-4); if (key1->obj_id > key2->obj_id) return(4); if (key1->rec_type < key2->rec_type) return(-3); if (key1->rec_type > key2->rec_type) return(3); if (key1->key < key2->key) return(-2); if (key1->key > key2->key) return(2); if (key1->create_tid == 0) { if (key2->create_tid == 0) return(0); return(1); } if (key2->create_tid == 0) return(-1); if (key1->create_tid < key2->create_tid) return(-1); if (key1->create_tid > key2->create_tid) return(1); return(0); } static int test_lr(hammer_btree_elm_t elm, hammer_btree_elm_t lbe) { if (lbe) { hammer_btree_elm_t rbe = lbe + 1; if (hammer_btree_cmp(&elm->base, &lbe->base) < 0) return(FLAG_TOOFARLEFT); if (hammer_btree_cmp(&elm->base, &rbe->base) >= 0) return(FLAG_TOOFARRIGHT); } return(0); } static int test_rbn_lr(hammer_btree_elm_t rbn, hammer_btree_elm_t lbe) { if (lbe) { hammer_btree_elm_t rbe = lbe + 1; if (hammer_btree_cmp(&rbn->base, &lbe->base) < 0) return(FLAG_TOOFARLEFT); if (hammer_btree_cmp(&rbn->base, &rbe->base) > 0) return(FLAG_TOOFARRIGHT); } return(0); } static void print_bigblock_fill(hammer_off_t offset) { struct hammer_blockmap_layer1 layer1; struct hammer_blockmap_layer2 layer2; int fill; int error; blockmap_lookup_save(offset, &layer1, &layer2, &error); printf("z%d:v%d:%d:%d:%lu=", HAMMER_ZONE_DECODE(offset), HAMMER_VOL_DECODE(offset), HAMMER_BLOCKMAP_LAYER1_INDEX(offset), HAMMER_BLOCKMAP_LAYER2_INDEX(offset), offset & HAMMER_BIGBLOCK_MASK64); if (error) { printf("B%d", error); } else { fill = layer2.bytes_free * 100 / HAMMER_BIGBLOCK_SIZE; printf("%d%%", 100 - fill); } } /* * Check the generic crc on a data element. Inodes record types are * special in that some of their fields are not CRCed. * * Also check that the zone is valid. */ static const char * check_data_crc(hammer_btree_elm_t elm, const char **whichp) { hammer_crc_t crc; *whichp = ""; if (elm->leaf.data_offset == 0 || elm->leaf.data_len == 0) return("ZO"); /* zero offset or length */ switch (elm->leaf.base.rec_type) { case HAMMER_RECTYPE_INODE: if (elm->leaf.data_len != sizeof(struct hammer_inode_data)) return("BI"); /* bad inode size */ crc = get_inode_crc(&elm->leaf, whichp); break; default: crc = get_buf_crc(&elm->leaf, whichp); break; } if (crc == 0) return("Bx"); /* bad crc */ if (crc != elm->leaf.data_crc) return("BX"); /* bad crc */ return(NULL); /* success */ } static hammer_crc_t get_inode_crc(hammer_btree_leaf_elm_t leaf, const char **whichp) { buffer_info_t data_buffer = NULL; hammer_crc_t crc; char *ptr; ptr = get_buffer_data(leaf->data_offset, &data_buffer, 0); if (HammerVersion >= HAMMER_VOL_VERSION_SEVEN) { crc = iscsi_crc32(ptr, HAMMER_INODE_CRCSIZE); if (crc == leaf->data_crc) { *whichp = "i"; goto end; } } crc = crc32(ptr, HAMMER_INODE_CRCSIZE); if (crc == leaf->data_crc) { *whichp = "o"; goto end; } *whichp = ""; end: rel_buffer(data_buffer); return(crc); } typedef uint32_t (*crc32_ext_fn)(const void *, size_t, uint32_t); static hammer_crc_t __get_buf_crc(hammer_btree_leaf_elm_t leaf, crc32_ext_fn f) { buffer_info_t data_buffer = NULL; hammer_off_t buf_offset; hammer_crc_t crc = 0; int32_t buf_len, len; char *ptr; buf_offset = leaf->data_offset; buf_len = leaf->data_len; while (buf_len) { ptr = get_buffer_data(buf_offset, &data_buffer, 0); len = HAMMER_BUFSIZE - ((int)buf_offset & HAMMER_BUFMASK); if (len > buf_len) len = (int)buf_len; assert(len <= HAMMER_BUFSIZE); crc = f(ptr, len, crc); buf_len -= len; buf_offset += len; } rel_buffer(data_buffer); return(crc); } static hammer_crc_t get_buf_crc(hammer_btree_leaf_elm_t leaf, const char **whichp) { hammer_crc_t crc; if (HammerVersion >= HAMMER_VOL_VERSION_SEVEN) { crc = __get_buf_crc(leaf, iscsi_crc32_ext); if (crc == leaf->data_crc) { *whichp = "i"; goto end; } } crc = __get_buf_crc(leaf, crc32_ext); if (crc == leaf->data_crc) { *whichp = "o"; goto end; } *whichp = ""; end: return(crc); } static void print_config(char *cfgtxt) { char *token; printf("\n%s%17s", INDENT, ""); printf("config text=\"\n"); if (cfgtxt != NULL) { while((token = strsep(&cfgtxt, "\r\n")) != NULL) { if (strlen(token)) { printf("%s%17s %s\n", INDENT, "", token); } } } printf("%s%17s \"", INDENT, ""); } static void print_record(hammer_btree_elm_t elm) { buffer_info_t data_buffer; hammer_off_t data_offset; int32_t data_len; hammer_data_ondisk_t data; char *str1 = NULL; char *str2 = NULL; data_offset = elm->leaf.data_offset; data_len = elm->leaf.data_len; assert(data_offset != 0); assert(data_len != 0); data_buffer = NULL; data = get_buffer_data(data_offset, &data_buffer, 0); assert(data != NULL); switch(elm->leaf.base.rec_type) { case HAMMER_RECTYPE_UNKNOWN: printf("\n%s%17s", INDENT, ""); printf("unknown"); break; case HAMMER_RECTYPE_INODE: printf("\n%s%17s", INDENT, ""); printf("inode size=%jd nlinks=%jd", (intmax_t)data->inode.size, (intmax_t)data->inode.nlinks); printf(" mode=%05o uflags=%08x caps=%02x", data->inode.mode, data->inode.uflags, data->inode.cap_flags); printf(" pobjid=%016jx ot=%02x\n", (uintmax_t)data->inode.parent_obj_id, data->inode.obj_type); printf("%s%17s", INDENT, ""); printf(" ctime=%016jx mtime=%016jx atime=%016jx", (uintmax_t)data->inode.ctime, (uintmax_t)data->inode.mtime, (uintmax_t)data->inode.atime); if (data->inode.ext.symlink[0]) { printf(" symlink=\"%s\"", data->inode.ext.symlink); } break; case HAMMER_RECTYPE_DIRENTRY: data_len -= HAMMER_ENTRY_NAME_OFF; printf("\n%s%17s", INDENT, ""); printf("dir-entry objid=%016jx lo=%08x", (uintmax_t)data->entry.obj_id, data->entry.localization); if (!opt.obfuscate) { printf(" name=\"%*.*s\"", data_len, data_len, data->entry.name); } break; case HAMMER_RECTYPE_FIX: switch(elm->leaf.base.key) { case HAMMER_FIXKEY_SYMLINK: data_len -= HAMMER_SYMLINK_NAME_OFF; printf("\n%s%17s", INDENT, ""); printf("fix-symlink name=\"%*.*s\"", data_len, data_len, data->symlink.name); break; } break; case HAMMER_RECTYPE_PFS: printf("\n%s%17s", INDENT, ""); printf("pfs sync_beg_tid=%016jx sync_end_tid=%016jx\n", (uintmax_t)data->pfsd.sync_beg_tid, (uintmax_t)data->pfsd.sync_end_tid); hammer_uuid_to_string(&data->pfsd.shared_uuid, &str1); hammer_uuid_to_string(&data->pfsd.unique_uuid, &str2); printf("%17s", ""); printf(" shared_uuid=%s\n", str1); printf("%17s", ""); printf(" unique_uuid=%s\n", str2); printf("%17s", ""); printf(" mirror_flags=%08x label=\"%s\"", data->pfsd.mirror_flags, data->pfsd.label); if (data->pfsd.snapshots[0]) printf(" snapshots=\"%s\"", data->pfsd.snapshots); free(str1); free(str2); break; case HAMMER_RECTYPE_SNAPSHOT: printf("\n%s%17s", INDENT, ""); printf("snapshot tid=%016jx label=\"%s\"", (uintmax_t)data->snap.tid, data->snap.label); break; case HAMMER_RECTYPE_CONFIG: if (VerboseOpt > 2) { char *p = strdup(data->config.text); print_config(p); free(p); } break; case HAMMER_RECTYPE_DATA: if (VerboseOpt > 3) { printf("\n"); hexdump_record(data, data_len, "\t\t "); } break; case HAMMER_RECTYPE_EXT: case HAMMER_RECTYPE_DB: if (VerboseOpt > 2) { printf("\n"); hexdump_record(data, data_len, "\t\t "); } break; default: assert(0); break; } rel_buffer(data_buffer); } /* * HAMMER userspace only supports buffer size upto HAMMER_BUFSIZE * which is 16KB. Passing record data length larger than 16KB to * hexdump(3) is invalid even if the leaf node elm says >16KB data. */ static void hexdump_record(const void *ptr, int length, const char *hdr) { int data_len = length; if (data_len > HAMMER_BUFSIZE) /* XXX */ data_len = HAMMER_BUFSIZE; hexdump(ptr, data_len, hdr, 0); if (length > data_len) printf("%s....\n", hdr); } static __inline __always_inline unsigned long _strtoul(const char *p, int base) { unsigned long retval; errno = 0; /* clear */ retval = strtoul(p, NULL, base); if (errno == ERANGE && retval == ULONG_MAX) { err(1, "strtoul"); /* not reached */ } return retval; } static __inline __always_inline unsigned long long _strtoull(const char *p, int base) { unsigned long long retval; errno = 0; /* clear */ retval = strtoull(p, NULL, base); if (errno == ERANGE && retval == ULLONG_MAX) { err(1, "strtoull"); /* not reached */ } return retval; } static int init_btree_search(const char *arg) { char *s, *p; int i = 0; bzero(&opt.base, sizeof(opt.base)); opt.limit = 0; if (arg == NULL) return(-1); if (strcmp(arg, "none") == 0) return(-1); s = strdup(arg); if (s == NULL) return(-1); while ((p = s) != NULL) { if ((s = strchr(s, ':')) != NULL) *s++ = 0; if (++i == 1) { opt.base.localization = _strtoul(p, 16); } else if (i == 2) { opt.base.obj_id = _strtoull(p, 16); } else if (i == 3) { opt.base.rec_type = _strtoul(p, 16); } else if (i == 4) { opt.base.key = _strtoull(p, 16); } else if (i == 5) { opt.base.create_tid = _strtoull(p, 16); break; } } opt.limit = i; free(s); return(i); } static int test_btree_search(hammer_btree_elm_t elm) { hammer_base_elm_t base1 = &elm->base; hammer_base_elm_t base2 = &opt.base; int limit = opt.limit; if (base1->localization < base2->localization) return(-5); if (base1->localization > base2->localization) return(5); if (limit == 1) return(0); /* ignore below */ if (base1->obj_id < base2->obj_id) return(-4); if (base1->obj_id > base2->obj_id) return(4); if (limit == 2) return(0); /* ignore below */ if (base1->rec_type < base2->rec_type) return(-3); if (base1->rec_type > base2->rec_type) return(3); if (limit == 3) return(0); /* ignore below */ if (base1->key < base2->key) return(-2); if (base1->key > base2->key) return(2); if (limit == 4) return(0); /* ignore below */ if (base1->create_tid == 0) { if (base2->create_tid == 0) return(0); return(1); } if (base2->create_tid == 0) return(-1); if (base1->create_tid < base2->create_tid) return(-1); if (base1->create_tid > base2->create_tid) return(1); return(0); } static __inline int test_btree_match(hammer_btree_elm_t elm) { if (test_btree_search(elm) == 0) return(1); return(0); } static int test_btree_out_of_range(hammer_btree_elm_t elm) { if (test_btree_search(elm) > 0) return(1); /* conditions < this elm */ if (opt.limit >= 5) { if (test_btree_search(elm + 1) <= 0) return(1); /* next elm <= conditions */ } else { if (test_btree_search(elm + 1) < 0) return(1); /* next elm < conditions */ } return(0); } /* * Dump the UNDO FIFO */ void hammer_cmd_show_undo(void) { volume_info_t volume; hammer_blockmap_t rootmap; hammer_off_t scan_offset; hammer_fifo_any_t head; hammer_fifo_head_t hdr; buffer_info_t data_buffer = NULL; zone_stat_t stats = NULL; volume = get_root_volume(); rootmap = &volume->ondisk->vol0_blockmap[HAMMER_ZONE_UNDO_INDEX]; print_blockmap(volume); if (VerboseOpt) stats = hammer_init_zone_stat_bits(); scan_offset = HAMMER_ENCODE_UNDO(0); while (scan_offset < rootmap->alloc_offset) { head = get_buffer_data(scan_offset, &data_buffer, 0); hdr = &head->head; printf("%016jx ", scan_offset); switch(hdr->hdr_type) { case HAMMER_HEAD_TYPE_PAD: printf("PAD(%d)", hdr->hdr_size); break; case HAMMER_HEAD_TYPE_DUMMY: printf("DUMMY(%d)\tseq=%08x", hdr->hdr_size, hdr->hdr_seq); break; case HAMMER_HEAD_TYPE_UNDO: printf("UNDO(%u)\tseq=%08x offset=%016jx bytes=%d", hdr->hdr_size, hdr->hdr_seq, (uintmax_t)head->undo.undo_offset, head->undo.undo_data_bytes); break; case HAMMER_HEAD_TYPE_REDO: printf("REDO(%u)\tseq=%08x offset=%016jx bytes=%d " "objid=%016jx flags=%08x lo=%08x", hdr->hdr_size, hdr->hdr_seq, (uintmax_t)head->redo.redo_offset, head->redo.redo_data_bytes, (uintmax_t)head->redo.redo_objid, head->redo.redo_flags, head->redo.redo_localization); break; default: printf("%04x(%d)\tseq=%08x", hdr->hdr_type, hdr->hdr_size, hdr->hdr_seq); break; } if (scan_offset == rootmap->first_offset) printf(" >"); if (scan_offset == rootmap->next_offset) printf(" <"); printf("\n"); if (stats) hammer_add_zone_stat(stats, scan_offset, hdr->hdr_size); if ((hdr->hdr_size & HAMMER_HEAD_ALIGN_MASK) || hdr->hdr_size == 0 || hdr->hdr_size > HAMMER_UNDO_ALIGN - ((u_int)scan_offset & HAMMER_UNDO_MASK)) { printf("Illegal size field, skipping to " "next boundary\n"); scan_offset = HAMMER_UNDO_DOALIGN(scan_offset); } else { scan_offset += hdr->hdr_size; } } rel_buffer(data_buffer); if (stats) { hammer_print_zone_stat(stats); hammer_cleanup_zone_stat(stats); } }