/*- * Copyright (c) 2013, 2014, 2015 Spectra Logic Corporation * All rights reserved. * * 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, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * substantially similar to the "NO WARRANTY" disclaimer below * ("Disclaimer") and any redistribution must be conditioned upon * including a substantially similar Disclaimer requirement for further * binary redistribution. * * NO WARRANTY * 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 MERCHANTIBILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * HOLDERS OR CONTRIBUTORS BE LIABLE FOR 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 DAMAGES. * * Authors: Ken Merry (Spectra Logic Corporation) */ #include __FBSDID("$FreeBSD$"); #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Called at the start of each XML element, and includes the list of * attributes for the element. */ void mt_start_element(void *user_data, const char *name, const char **attr) { int i; struct mt_status_data *mtinfo; struct mt_status_entry *entry; mtinfo = (struct mt_status_data *)user_data; if (mtinfo->error != 0) return; mtinfo->level++; if ((u_int)mtinfo->level >= (sizeof(mtinfo->cur_sb) / sizeof(mtinfo->cur_sb[0]))) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s: too many nesting levels, %zd max", __func__, sizeof(mtinfo->cur_sb) / sizeof(mtinfo->cur_sb[0])); return; } mtinfo->cur_sb[mtinfo->level] = sbuf_new_auto(); if (mtinfo->cur_sb[mtinfo->level] == NULL) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s: Unable to allocate sbuf", __func__); return; } entry = malloc(sizeof(*entry)); if (entry == NULL) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s: unable to allocate %zd bytes", __func__, sizeof(*entry)); return; } bzero(entry, sizeof(*entry)); STAILQ_INIT(&entry->nv_list); STAILQ_INIT(&entry->child_entries); entry->entry_name = strdup(name); mtinfo->cur_entry[mtinfo->level] = entry; if (mtinfo->cur_entry[mtinfo->level - 1] == NULL) { STAILQ_INSERT_TAIL(&mtinfo->entries, entry, links); } else { STAILQ_INSERT_TAIL( &mtinfo->cur_entry[mtinfo->level - 1]->child_entries, entry, links); entry->parent = mtinfo->cur_entry[mtinfo->level - 1]; } for (i = 0; attr[i] != NULL; i+=2) { struct mt_status_nv *nv; int need_nv; need_nv = 0; if (strcmp(attr[i], "size") == 0) { entry->size = strtoull(attr[i+1], NULL, 0); } else if (strcmp(attr[i], "type") == 0) { if (strcmp(attr[i+1], "int") == 0) { entry->var_type = MT_TYPE_INT; } else if (strcmp(attr[i+1], "uint") == 0) { entry->var_type = MT_TYPE_UINT; } else if (strcmp(attr[i+1], "str") == 0) { entry->var_type = MT_TYPE_STRING; } else if (strcmp(attr[i+1], "node") == 0) { entry->var_type = MT_TYPE_NODE; } else { need_nv = 1; } } else if (strcmp(attr[i], "fmt") == 0) { entry->fmt = strdup(attr[i+1]); } else if (strcmp(attr[i], "desc") == 0) { entry->desc = strdup(attr[i+1]); } else { need_nv = 1; } if (need_nv != 0) { nv = malloc(sizeof(*nv)); if (nv == NULL) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s: error allocating %zd bytes", __func__, sizeof(*nv)); } bzero(nv, sizeof(*nv)); nv->name = strdup(attr[i]); nv->value = strdup(attr[i+1]); STAILQ_INSERT_TAIL(&entry->nv_list, nv, links); } } } /* * Called on XML element close. */ void mt_end_element(void *user_data, const char *name) { struct mt_status_data *mtinfo; char *str; mtinfo = (struct mt_status_data *)user_data; if (mtinfo->error != 0) return; if (mtinfo->cur_sb[mtinfo->level] == NULL) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s: no valid sbuf at level %d (name %s)", __func__, mtinfo->level, name); return; } sbuf_finish(mtinfo->cur_sb[mtinfo->level]); str = strdup(sbuf_data(mtinfo->cur_sb[mtinfo->level])); if (str == NULL) { mtinfo->error = 1; snprintf(mtinfo->error_str, sizeof(mtinfo->error_str), "%s can't allocate %zd bytes for string", __func__, sbuf_len(mtinfo->cur_sb[mtinfo->level])); return; } if (strlen(str) == 0) { free(str); str = NULL; } if (str != NULL) { struct mt_status_entry *entry; entry = mtinfo->cur_entry[mtinfo->level]; switch(entry->var_type) { case MT_TYPE_INT: entry->value_signed = strtoll(str, NULL, 0); break; case MT_TYPE_UINT: entry->value_unsigned = strtoull(str, NULL, 0); break; default: break; } } mtinfo->cur_entry[mtinfo->level]->value = str; sbuf_delete(mtinfo->cur_sb[mtinfo->level]); mtinfo->cur_sb[mtinfo->level] = NULL; mtinfo->cur_entry[mtinfo->level] = NULL; mtinfo->level--; } /* * Called to handle character strings in the current element. */ void mt_char_handler(void *user_data, const XML_Char *str, int len) { struct mt_status_data *mtinfo; mtinfo = (struct mt_status_data *)user_data; if (mtinfo->error != 0) return; sbuf_bcat(mtinfo->cur_sb[mtinfo->level], str, len); } void mt_status_tree_sbuf(struct sbuf *sb, struct mt_status_entry *entry, int indent, void (*sbuf_func)(struct sbuf *sb, struct mt_status_entry *entry, void *arg), void *arg) { struct mt_status_nv *nv; struct mt_status_entry *entry2; if (sbuf_func != NULL) { sbuf_func(sb, entry, arg); } else { sbuf_printf(sb, "%*sname: %s, value: %s, fmt: %s, size: %zd, " "type: %d, desc: %s\n", indent, "", entry->entry_name, entry->value, entry->fmt, entry->size, entry->var_type, entry->desc); STAILQ_FOREACH(nv, &entry->nv_list, links) { sbuf_printf(sb, "%*snv: name: %s, value: %s\n", indent + 1, "", nv->name, nv->value); } } STAILQ_FOREACH(entry2, &entry->child_entries, links) mt_status_tree_sbuf(sb, entry2, indent + 2, sbuf_func, arg); } void mt_status_tree_print(struct mt_status_entry *entry, int indent, void (*print_func)(struct mt_status_entry *entry, void *arg), void *arg) { if (print_func != NULL) { struct mt_status_entry *entry2; print_func(entry, arg); STAILQ_FOREACH(entry2, &entry->child_entries, links) mt_status_tree_print(entry2, indent + 2, print_func, arg); } else { struct sbuf *sb; sb = sbuf_new_auto(); if (sb == NULL) return; mt_status_tree_sbuf(sb, entry, indent, NULL, NULL); sbuf_finish(sb); printf("%s", sbuf_data(sb)); sbuf_delete(sb); } } /* * Given a parameter name in the form "foo" or "foo.bar.baz", traverse the * tree looking for the parameter (the first case) or series of parameters * (second case). */ struct mt_status_entry * mt_entry_find(struct mt_status_entry *entry, char *name) { struct mt_status_entry *entry2; char *tmpname = NULL, *tmpname2 = NULL, *tmpstr = NULL; tmpname = strdup(name); if (tmpname == NULL) goto bailout; /* Save a pointer so we can free this later */ tmpname2 = tmpname; tmpstr = strsep(&tmpname, "."); /* * Is this the entry we're looking for? Or do we have further * child entries that we need to grab? */ if (strcmp(entry->entry_name, tmpstr) == 0) { if (tmpname == NULL) { /* * There are no further child entries to find. We * have a complete match. */ free(tmpname2); return (entry); } else { /* * There are more child entries that we need to find. * Fall through to the recursive search off of this * entry, below. Use tmpname, which will contain * everything after the first period. */ name = tmpname; } } /* * Recursively look for further entries. */ STAILQ_FOREACH(entry2, &entry->child_entries, links) { struct mt_status_entry *entry3; entry3 = mt_entry_find(entry2, name); if (entry3 != NULL) { free(tmpname2); return (entry3); } } bailout: free(tmpname2); return (NULL); } struct mt_status_entry * mt_status_entry_find(struct mt_status_data *status_data, char *name) { struct mt_status_entry *entry, *entry2; STAILQ_FOREACH(entry, &status_data->entries, links) { entry2 = mt_entry_find(entry, name); if (entry2 != NULL) return (entry2); } return (NULL); } void mt_status_entry_free(struct mt_status_entry *entry) { struct mt_status_entry *entry2, *entry3; struct mt_status_nv *nv, *nv2; STAILQ_FOREACH_SAFE(entry2, &entry->child_entries, links, entry3) { STAILQ_REMOVE(&entry->child_entries, entry2, mt_status_entry, links); mt_status_entry_free(entry2); } free(entry->entry_name); free(entry->value); free(entry->fmt); free(entry->desc); STAILQ_FOREACH_SAFE(nv, &entry->nv_list, links, nv2) { STAILQ_REMOVE(&entry->nv_list, nv, mt_status_nv, links); free(nv->name); free(nv->value); free(nv); } free(entry); } void mt_status_free(struct mt_status_data *status_data) { struct mt_status_entry *entry, *entry2; STAILQ_FOREACH_SAFE(entry, &status_data->entries, links, entry2) { STAILQ_REMOVE(&status_data->entries, entry, mt_status_entry, links); mt_status_entry_free(entry); } } void mt_entry_sbuf(struct sbuf *sb, struct mt_status_entry *entry, char *fmt) { switch(entry->var_type) { case MT_TYPE_INT: if (fmt != NULL) sbuf_printf(sb, fmt, (intmax_t)entry->value_signed); else sbuf_printf(sb, "%jd", (intmax_t)entry->value_signed); break; case MT_TYPE_UINT: if (fmt != NULL) sbuf_printf(sb, fmt, (uintmax_t)entry->value_unsigned); else sbuf_printf(sb, "%ju", (uintmax_t)entry->value_unsigned); break; default: if (fmt != NULL) sbuf_printf(sb, fmt, entry->value); else sbuf_printf(sb, "%s", entry->value); break; } } void mt_param_parent_print(struct mt_status_entry *entry, struct mt_print_params *print_params) { if (entry->parent != NULL) mt_param_parent_print(entry->parent, print_params); if (((print_params->flags & MT_PF_INCLUDE_ROOT) == 0) && (strcmp(entry->entry_name, print_params->root_name) == 0)) return; printf("%s.", entry->entry_name); } void mt_param_parent_sbuf(struct sbuf *sb, struct mt_status_entry *entry, struct mt_print_params *print_params) { if (entry->parent != NULL) mt_param_parent_sbuf(sb, entry->parent, print_params); if (((print_params->flags & MT_PF_INCLUDE_ROOT) == 0) && (strcmp(entry->entry_name, print_params->root_name) == 0)) return; sbuf_printf(sb, "%s.", entry->entry_name); } void mt_param_entry_sbuf(struct sbuf *sb, struct mt_status_entry *entry, void *arg) { struct mt_print_params *print_params; print_params = (struct mt_print_params *)arg; /* * We don't want to print nodes. */ if (entry->var_type == MT_TYPE_NODE) return; if ((print_params->flags & MT_PF_FULL_PATH) && (entry->parent != NULL)) mt_param_parent_sbuf(sb, entry->parent, print_params); sbuf_printf(sb, "%s: %s", entry->entry_name, entry->value); if ((print_params->flags & MT_PF_VERBOSE) && (entry->desc != NULL) && (strlen(entry->desc) > 0)) sbuf_printf(sb, " (%s)", entry->desc); sbuf_printf(sb, "\n"); } void mt_param_entry_print(struct mt_status_entry *entry, void *arg) { struct mt_print_params *print_params; print_params = (struct mt_print_params *)arg; /* * We don't want to print nodes. */ if (entry->var_type == MT_TYPE_NODE) return; if ((print_params->flags & MT_PF_FULL_PATH) && (entry->parent != NULL)) mt_param_parent_print(entry->parent, print_params); printf("%s: %s", entry->entry_name, entry->value); if ((print_params->flags & MT_PF_VERBOSE) && (entry->desc != NULL) && (strlen(entry->desc) > 0)) printf(" (%s)", entry->desc); printf("\n"); } int mt_protect_print(struct mt_status_data *status_data, int verbose) { struct mt_status_entry *entry; const char *prot_name = MT_PROTECTION_NAME; struct mt_print_params print_params; snprintf(print_params.root_name, sizeof(print_params.root_name), MT_PARAM_ROOT_NAME); print_params.flags = MT_PF_FULL_PATH; if (verbose != 0) print_params.flags |= MT_PF_VERBOSE; entry = mt_status_entry_find(status_data, __DECONST(char *,prot_name)); if (entry == NULL) return (1); mt_status_tree_print(entry, 0, mt_param_entry_print, &print_params); return (0); } int mt_param_list(struct mt_status_data *status_data, char *param_name, int quiet) { struct mt_status_entry *entry; struct mt_print_params print_params; char root_name[20]; snprintf(root_name, sizeof(root_name), "mtparamget"); strlcpy(print_params.root_name, root_name, sizeof(print_params.root_name)); print_params.flags = MT_PF_FULL_PATH; if (quiet == 0) print_params.flags |= MT_PF_VERBOSE; if (param_name != NULL) { entry = mt_status_entry_find(status_data, param_name); if (entry == NULL) return (1); mt_param_entry_print(entry, &print_params); return (0); } else { entry = mt_status_entry_find(status_data, root_name); STAILQ_FOREACH(entry, &status_data->entries, links) mt_status_tree_print(entry, 0, mt_param_entry_print, &print_params); } return (0); } static struct densities { int dens; int bpmm; int bpi; const char *name; } dens[] = { /* * Taken from T10 Project 997D * SCSI-3 Stream Device Commands (SSC) * Revision 11, 4-Nov-97 * * LTO 1-6 definitions obtained from the eighth edition of the * IBM TotalStorage LTO Ultrium Tape Drive SCSI Reference * (July 2007) and the second edition of the IBM System Storage LTO * Tape Drive SCSI Reference (February 13, 2013). * * IBM 3592 definitions obtained from second edition of the IBM * System Storage Tape Drive 3592 SCSI Reference (May 25, 2012). * * DAT-72 and DAT-160 bpi values taken from "HP StorageWorks DAT160 * tape drive white paper", dated June 2007. * * DAT-160 / SDLT220 density code (0x48) conflict information * found here: * * http://h20564.www2.hp.com/hpsc/doc/public/display?docId=emr_na-c01065117&sp4ts.oid=429311 * (Document ID c01065117) */ /*Num. bpmm bpi Reference */ { 0x1, 32, 800, "X3.22-1983" }, { 0x2, 63, 1600, "X3.39-1986" }, { 0x3, 246, 6250, "X3.54-1986" }, { 0x5, 315, 8000, "X3.136-1986" }, { 0x6, 126, 3200, "X3.157-1987" }, { 0x7, 252, 6400, "X3.116-1986" }, { 0x8, 315, 8000, "X3.158-1987" }, { 0x9, 491, 37871, "X3.180" }, { 0xA, 262, 6667, "X3B5/86-199" }, { 0xB, 63, 1600, "X3.56-1986" }, { 0xC, 500, 12690, "HI-TC1" }, { 0xD, 999, 25380, "HI-TC2" }, { 0xF, 394, 10000, "QIC-120" }, { 0x10, 394, 10000, "QIC-150" }, { 0x11, 630, 16000, "QIC-320" }, { 0x12, 2034, 51667, "QIC-1350" }, { 0x13, 2400, 61000, "X3B5/88-185A" }, { 0x14, 1703, 43245, "X3.202-1991" }, { 0x15, 1789, 45434, "ECMA TC17" }, { 0x16, 394, 10000, "X3.193-1990" }, { 0x17, 1673, 42500, "X3B5/91-174" }, { 0x18, 1673, 42500, "X3B5/92-50" }, { 0x19, 2460, 62500, "DLTapeIII" }, { 0x1A, 3214, 81633, "DLTapeIV(20GB)" }, { 0x1B, 3383, 85937, "DLTapeIV(35GB)" }, { 0x1C, 1654, 42000, "QIC-385M" }, { 0x1D, 1512, 38400, "QIC-410M" }, { 0x1E, 1385, 36000, "QIC-1000C" }, { 0x1F, 2666, 67733, "QIC-2100C" }, { 0x20, 2666, 67733, "QIC-6GB(M)" }, { 0x21, 2666, 67733, "QIC-20GB(C)" }, { 0x22, 1600, 40640, "QIC-2GB(C)" }, { 0x23, 2666, 67733, "QIC-875M" }, { 0x24, 2400, 61000, "DDS-2" }, { 0x25, 3816, 97000, "DDS-3" }, { 0x26, 3816, 97000, "DDS-4" }, { 0x27, 3056, 77611, "Mammoth" }, { 0x28, 1491, 37871, "X3.224" }, { 0x40, 4880, 123952, "LTO-1" }, { 0x41, 3868, 98250, "DLTapeIV(40GB)" }, { 0x42, 7398, 187909, "LTO-2" }, { 0x44, 9638, 244805, "LTO-3" }, { 0x46, 12725, 323215, "LTO-4" }, { 0x47, 6417, 163000, "DAT-72" }, /* * XXX KDM note that 0x48 is also the density code for DAT-160. * For some reason they used overlapping density codes. */ #if 0 { 0x48, 6870, 174500, "DAT-160" }, #endif { 0x48, 5236, 133000, "SDLTapeI(110)" }, { 0x49, 7598, 193000, "SDLTapeI(160)" }, { 0x4a, 0, 0, "T10000A" }, { 0x4b, 0, 0, "T10000B" }, { 0x4c, 0, 0, "T10000C" }, { 0x4d, 0, 0, "T10000D" }, { 0x51, 11800, 299720, "3592A1 (unencrypted)" }, { 0x52, 11800, 299720, "3592A2 (unencrypted)" }, { 0x53, 13452, 341681, "3592A3 (unencrypted)" }, { 0x54, 19686, 500024, "3592A4 (unencrypted)" }, { 0x55, 20670, 525018, "3592A5 (unencrypted)" }, { 0x58, 15142, 384607, "LTO-5" }, { 0x5A, 15142, 384607, "LTO-6" }, { 0x71, 11800, 299720, "3592A1 (encrypted)" }, { 0x72, 11800, 299720, "3592A2 (encrypted)" }, { 0x73, 13452, 341681, "3592A3 (encrypted)" }, { 0x74, 19686, 500024, "3592A4 (encrypted)" }, { 0x75, 20670, 525018, "3592A5 (encrypted)" }, { 0x8c, 1789, 45434, "EXB-8500c" }, { 0x90, 1703, 43245, "EXB-8200c" }, { 0, 0, 0, NULL } }; const char * mt_density_name(int density_num) { struct densities *sd; /* densities 0 and 0x7f are handled as special cases */ if (density_num == 0) return ("default"); if (density_num == 0x7f) return ("same"); for (sd = dens; sd->dens != 0; sd++) if (sd->dens == density_num) break; if (sd->dens == 0) return ("UNKNOWN"); return (sd->name); } /* * Given a specific density number, return either the bits per inch or bits * per millimeter for the given density. */ int mt_density_bp(int density_num, int bpi) { struct densities *sd; for (sd = dens; sd->dens; sd++) if (sd->dens == density_num) break; if (sd->dens == 0) return (0); if (bpi) return (sd->bpi); else return (sd->bpmm); } int mt_density_num(const char *density_name) { struct densities *sd; size_t l = strlen(density_name); for (sd = dens; sd->dens; sd++) if (strncasecmp(sd->name, density_name, l) == 0) break; return (sd->dens); } /* * Get the current status XML string. * Returns 0 on success, -1 on failure (with errno set, and *xml_str == NULL). */ int mt_get_xml_str(int mtfd, unsigned long cmd, char **xml_str) { size_t alloc_len = 32768; struct mtextget extget; int error; *xml_str = NULL; for (;;) { bzero(&extget, sizeof(extget)); *xml_str = malloc(alloc_len); if (*xml_str == NULL) return (-1); extget.status_xml = *xml_str; extget.alloc_len = alloc_len; error = ioctl(mtfd, cmd, (caddr_t)&extget); if (error == 0 && extget.status == MT_EXT_GET_OK) break; free(*xml_str); *xml_str = NULL; if (error != 0 || extget.status != MT_EXT_GET_NEED_MORE_SPACE) return (-1); /* The driver needs more space, so double and try again. */ alloc_len *= 2; } return (0); } /* * Populate a struct mt_status_data from the XML string via mt_get_xml_str(). * * Returns XML_STATUS_OK on success. * If XML_STATUS_ERROR is returned, errno may be set to indicate the reason. * The caller must check status_data->error. */ int mt_get_status(char *xml_str, struct mt_status_data *status_data) { XML_Parser parser; int retval; bzero(status_data, sizeof(*status_data)); STAILQ_INIT(&status_data->entries); parser = XML_ParserCreate(NULL); if (parser == NULL) { errno = ENOMEM; return (XML_STATUS_ERROR); } XML_SetUserData(parser, status_data); XML_SetElementHandler(parser, mt_start_element, mt_end_element); XML_SetCharacterDataHandler(parser, mt_char_handler); retval = XML_Parse(parser, xml_str, strlen(xml_str), 1); XML_ParserFree(parser); return (retval); }