/* $NetBSD: rf_configure.c,v 1.23 2006/03/19 01:57:11 dan Exp $ */ /* * Copyright (c) 1995 Carnegie-Mellon University. * All rights reserved. * * Author: Mark Holland * * Permission to use, copy, modify and distribute this software and * its documentation is hereby granted, provided that both the copyright * notice and this permission notice appear in all copies of the * software, derivative works or modified versions, and any portions * thereof, and that both notices appear in supporting documentation. * * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. * * Carnegie Mellon requests users of this software to return to * * Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU * School of Computer Science * Carnegie Mellon University * Pittsburgh PA 15213-3890 * * any improvements or extensions that they make and grant Carnegie the * rights to redistribute these changes. */ /*************************************************************** * * rf_configure.c -- code related to configuring the raidframe system * * configuration is complicated by the fact that we want the same * driver to work both in the kernel and at user level. In the * kernel, we can't read the configuration file, so we configure * by running a user-level program that reads the config file, * creates a data structure describing the configuration and * passes it into the kernel via an ioctl. Since we want the config * code to be common between the two versions of the driver, we * configure using the same two-step process when running at * user level. Of course, at user level, the config structure is * passed directly to the config routine, rather than via ioctl. * * This file is not compiled into the kernel, so we have no * need for KERNEL ifdefs. * **************************************************************/ #include #ifndef lint __RCSID("$NetBSD: rf_configure.c,v 1.23 2006/03/19 01:57:11 dan Exp $"); #endif #include #include #include #include #include #include #include #include #include "rf_configure.h" RF_LayoutSW_t *rf_GetLayout(RF_ParityConfig_t parityConfig); char *rf_find_non_white(char *p); char *rf_find_white(char *p); #define RF_MIN(a,b) (((a) < (b)) ? (a) : (b)) #define RF_ERRORMSG(s) printf((s)) #define RF_ERRORMSG1(s,a) printf((s),(a)) #define RF_ERRORMSG2(s,a,b) printf((s),(a),(b)) int distSpareYes = 1; int distSpareNo = 0; /* The mapsw[] table below contains all the various RAID types that might be supported by the kernel. The actual supported types are found in sys/dev/raidframe/rf_layout.c. */ static RF_LayoutSW_t mapsw[] = { /* parity declustering */ {'T', "Parity declustering", rf_MakeLayoutSpecificDeclustered, &distSpareNo}, /* parity declustering with distributed sparing */ {'D', "Distributed sparing parity declustering", rf_MakeLayoutSpecificDeclustered, &distSpareYes}, /* declustered P+Q */ {'Q', "Declustered P+Q", rf_MakeLayoutSpecificDeclustered, &distSpareNo}, /* RAID 5 with rotated sparing */ {'R', "RAID Level 5 rotated sparing", rf_MakeLayoutSpecificNULL, NULL}, /* Chained Declustering */ {'C', "Chained Declustering", rf_MakeLayoutSpecificNULL, NULL}, /* Interleaved Declustering */ {'I', "Interleaved Declustering", rf_MakeLayoutSpecificNULL, NULL}, /* RAID level 0 */ {'0', "RAID Level 0", rf_MakeLayoutSpecificNULL, NULL}, /* RAID level 1 */ {'1', "RAID Level 1", rf_MakeLayoutSpecificNULL, NULL}, /* RAID level 4 */ {'4', "RAID Level 4", rf_MakeLayoutSpecificNULL, NULL}, /* RAID level 5 */ {'5', "RAID Level 5", rf_MakeLayoutSpecificNULL, NULL}, /* Evenodd */ {'E', "EvenOdd", rf_MakeLayoutSpecificNULL, NULL}, /* Declustered Evenodd */ {'e', "Declustered EvenOdd", rf_MakeLayoutSpecificDeclustered, &distSpareNo}, /* parity logging */ {'L', "Parity logging", rf_MakeLayoutSpecificNULL, NULL}, /* end-of-list marker */ {'\0', NULL, NULL, NULL} }; RF_LayoutSW_t * rf_GetLayout(RF_ParityConfig_t parityConfig) { RF_LayoutSW_t *p; /* look up the specific layout */ for (p = &mapsw[0]; p->parityConfig; p++) if (p->parityConfig == parityConfig) break; if (!p->parityConfig) return (NULL); return (p); } static int rf_search_file_for_start_of(const char *string, char *buf, int len, FILE * fp); static int rf_get_next_nonblank_line(char *buf, int len, FILE * fp, const char *errmsg); /* * called from user level to read the configuration file and create * a configuration control structure. This is used in the user-level * version of the driver, and in the user-level program that configures * the system via ioctl. */ int rf_MakeConfig(char *configname, RF_Config_t *cfgPtr) { int numscanned, val, r, c, retcode, aa, bb, cc; char buf[256], buf1[256], *cp; RF_LayoutSW_t *lp; FILE *fp; bzero((char *) cfgPtr, sizeof(RF_Config_t)); fp = fopen(configname, "r"); if (!fp) { printf("Can't open config file %s\n", configname); return (-1); } rewind(fp); if (rf_search_file_for_start_of("array", buf, 256, fp)) { printf("Unable to find start of \"array\" params in config file %s\n", configname); retcode = -1; goto out; } rf_get_next_nonblank_line(buf, 256, fp, "Config file error (\"array\" section): unable to get numRow and numCol\n"); /* * wackiness with aa, bb, cc to get around size problems on * different platforms */ numscanned = sscanf(buf, "%d %d %d", &aa, &bb, &cc); if (numscanned != 3) { printf("Config file error (\"array\" section): unable to get numRow, numCol, numSpare\n"); retcode = -1; goto out; } cfgPtr->numRow = (RF_RowCol_t) aa; cfgPtr->numCol = (RF_RowCol_t) bb; cfgPtr->numSpare = (RF_RowCol_t) cc; /* debug section is optional */ for (c = 0; c < RF_MAXDBGV; c++) cfgPtr->debugVars[c][0] = '\0'; rewind(fp); if (!rf_search_file_for_start_of("debug", buf, 256, fp)) { for (c = 0; c < RF_MAXDBGV; c++) { if (rf_get_next_nonblank_line(buf, 256, fp, NULL)) break; cp = rf_find_non_white(buf); if (!strncmp(cp, "START", strlen("START"))) break; (void) strlcpy(&cfgPtr->debugVars[c][0], cp, sizeof(cfgPtr->debugVars[c])); } } rewind(fp); strlcpy(cfgPtr->diskQueueType, "fifo", sizeof(cfgPtr->diskQueueType)); cfgPtr->maxOutstandingDiskReqs = 1; /* scan the file for the block related to disk queues */ if (rf_search_file_for_start_of("queue", buf, 256, fp)) { RF_ERRORMSG2("[No disk queue discipline specified in config file %s. Using %s.]\n", configname, cfgPtr->diskQueueType); } else { if (rf_get_next_nonblank_line(buf, 256, fp, NULL)) { RF_ERRORMSG2("[No disk queue discipline specified in config file %s. Using %s.]\n", configname, cfgPtr->diskQueueType); } } /* the queue specifier line contains two entries: 1st char of first * word specifies queue to be used 2nd word specifies max num reqs * that can be outstanding on the disk itself (typically 1) */ if (sscanf(buf, "%255s %d", buf1, &val) != 2) { RF_ERRORMSG1("Can't determine queue type and/or max outstanding reqs from line: %s", buf); RF_ERRORMSG2("Using %s-%d\n", cfgPtr->diskQueueType, cfgPtr->maxOutstandingDiskReqs); } else { char *ch; bcopy(buf1, cfgPtr->diskQueueType, RF_MIN(sizeof(cfgPtr->diskQueueType), strlen(buf1) + 1)); for (ch = buf1; *ch; ch++) { if (*ch == ' ') { *ch = '\0'; break; } } cfgPtr->maxOutstandingDiskReqs = val; } rewind(fp); if (rf_search_file_for_start_of("disks", buf, 256, fp)) { RF_ERRORMSG1("Can't find \"disks\" section in config file %s\n", configname); retcode = -1; goto out; } for (r = 0; r < cfgPtr->numRow; r++) { for (c = 0; c < cfgPtr->numCol; c++) { if (rf_get_next_nonblank_line( &cfgPtr->devnames[r][c][0], 50, fp, NULL)) { RF_ERRORMSG2("Config file error: unable to get device file for disk at row %d col %d\n", r, c); retcode = -1; goto out; } } } /* "spare" section is optional */ rewind(fp); if (rf_search_file_for_start_of("spare", buf, 256, fp)) cfgPtr->numSpare = 0; for (c = 0; c < cfgPtr->numSpare; c++) { if (rf_get_next_nonblank_line(&cfgPtr->spare_names[c][0], 256, fp, NULL)) { RF_ERRORMSG1("Config file error: unable to get device file for spare disk %d\n", c); retcode = -1; goto out; } } /* scan the file for the block related to layout */ rewind(fp); if (rf_search_file_for_start_of("layout", buf, 256, fp)) { RF_ERRORMSG1("Can't find \"layout\" section in configuration file %s\n", configname); retcode = -1; goto out; } if (rf_get_next_nonblank_line(buf, 256, fp, NULL)) { RF_ERRORMSG("Config file error (\"layout\" section): unable to find common layout param line\n"); retcode = -1; goto out; } c = sscanf(buf, "%d %d %d %c", &aa, &bb, &cc, &cfgPtr->parityConfig); cfgPtr->sectPerSU = (RF_SectorNum_t) aa; cfgPtr->SUsPerPU = (RF_StripeNum_t) bb; cfgPtr->SUsPerRU = (RF_StripeNum_t) cc; if (c != 4) { RF_ERRORMSG("Unable to scan common layout line\n"); retcode = -1; goto out; } lp = rf_GetLayout(cfgPtr->parityConfig); if (lp == NULL) { RF_ERRORMSG1("Unknown parity config '%c'\n", cfgPtr->parityConfig); retcode = -1; goto out; } retcode = lp->MakeLayoutSpecific(fp, cfgPtr, lp->makeLayoutSpecificArg); out: fclose(fp); if (retcode < 0) retcode = errno = EINVAL; else errno = retcode; return (retcode); } /* used in architectures such as RAID0 where there is no layout-specific * information to be passed into the configuration code. */ int rf_MakeLayoutSpecificNULL(FILE *fp, RF_Config_t *cfgPtr, void *ignored) { cfgPtr->layoutSpecificSize = 0; cfgPtr->layoutSpecific = NULL; return (0); } int rf_MakeLayoutSpecificDeclustered(FILE *configfp, RF_Config_t *cfgPtr, void *arg) { int b, v, k, r, lambda, norotate, i, val, distSpare; char *cfgBuf, *bdfile, *p, *smname; char buf[256], smbuf[256]; FILE *fp; distSpare = *((int *) arg); /* get the block design file name */ if (rf_get_next_nonblank_line(buf, 256, configfp, "Can't find block design file name in config file\n")) return (EINVAL); bdfile = rf_find_non_white(buf); if (bdfile[strlen(bdfile) - 1] == '\n') { /* strip newline char */ bdfile[strlen(bdfile) - 1] = '\0'; } /* open bd file, check validity of configuration */ if ((fp = fopen(bdfile, "r")) == NULL) { RF_ERRORMSG1("RAID: config error: Can't open layout table file %s\n", bdfile); return (EINVAL); } if (fgets(buf, 256, fp) == NULL) { RF_ERRORMSG1("RAID: config error: Can't read layout from layout table file %s\n", bdfile); fclose(fp); return (EINVAL); } i = sscanf(buf, "%u %u %u %u %u %u", &b, &v, &k, &r, &lambda, &norotate); if (i == 5) norotate = 0; /* no-rotate flag is optional */ else if (i != 6) { RF_ERRORMSG("Unable to parse header line in block design file\n"); fclose(fp); return (EINVAL); } /* set the sparemap directory. In the in-kernel version, there's a * daemon that's responsible for finding the sparemaps */ if (distSpare) { if (rf_get_next_nonblank_line(smbuf, 256, configfp, "Can't find sparemap file name in config file\n")) { fclose(fp); return (EINVAL); } smname = rf_find_non_white(smbuf); if (smname[strlen(smname) - 1] == '\n') { /* strip newline char */ smname[strlen(smname) - 1] = '\0'; } } else { smbuf[0] = '\0'; smname = smbuf; } /* allocate a buffer to hold the configuration info */ cfgPtr->layoutSpecificSize = RF_SPAREMAP_NAME_LEN + 6 * sizeof(int) + b * k; cfgBuf = (char *) malloc(cfgPtr->layoutSpecificSize); if (cfgBuf == NULL) { fclose(fp); return (ENOMEM); } cfgPtr->layoutSpecific = (void *) cfgBuf; p = cfgBuf; /* install name of sparemap file */ for (i = 0; smname[i]; i++) *p++ = smname[i]; /* pad with zeros */ while (i < RF_SPAREMAP_NAME_LEN) { *p++ = '\0'; i++; } /* * fill in the buffer with the block design parameters * and then the block design itself */ *((int *) p) = b; p += sizeof(int); *((int *) p) = v; p += sizeof(int); *((int *) p) = k; p += sizeof(int); *((int *) p) = r; p += sizeof(int); *((int *) p) = lambda; p += sizeof(int); *((int *) p) = norotate; p += sizeof(int); while (fscanf(fp, "%d", &val) == 1) *p++ = (char) val; fclose(fp); if (p - cfgBuf != cfgPtr->layoutSpecificSize) { RF_ERRORMSG2("Size mismatch creating layout specific data: is %d sb %d bytes\n", (int) (p - cfgBuf), (int) (6 * sizeof(int) + b * k)); return (EINVAL); } return (0); } /**************************************************************************** * * utilities * ***************************************************************************/ /* finds a non-white character in the line */ char * rf_find_non_white(char *p) { for (; *p != '\0' && (*p == ' ' || *p == '\t'); p++); return (p); } /* finds a white character in the line */ char * rf_find_white(char *p) { for (; *p != '\0' && (*p != ' ' && *p != '\t'); p++); return (p); } /* * searches a file for a line that says "START string", where string is * specified as a parameter */ static int rf_search_file_for_start_of(const char *string, char *buf, int len, FILE *fp) { char *p; while (1) { if (fgets(buf, len, fp) == NULL) return (-1); p = rf_find_non_white(buf); if (!strncmp(p, "START", strlen("START"))) { p = rf_find_white(p); p = rf_find_non_white(p); if (!strncmp(p, string, strlen(string))) return (0); } } } /* reads from file fp into buf until it finds an interesting line */ int rf_get_next_nonblank_line(char *buf, int len, FILE *fp, const char *errmsg) { char *p; int l; while (fgets(buf, len, fp) != NULL) { p = rf_find_non_white(buf); if (*p == '\n' || *p == '\0' || *p == '#') continue; l = strlen(buf)-1; while (l>=0 && (buf[l]==' ' || buf[l]=='\n')) { buf[l]='\0'; l--; } return (0); } if (errmsg) RF_ERRORMSG1("%s", errmsg); return (1); } /* * Allocates an array for the spare table, and initializes it from a file. * In the user-level version, this is called when recon is initiated. * When/if I move recon into the kernel, there'll be a daemon that does * an ioctl into raidframe which will block until a spare table is needed. * When it returns, it will read a spare table from the file system, * pass it into the kernel via a different ioctl, and then block again * on the original ioctl. * * This is specific to the declustered layout, but doesn't belong in * rf_decluster.c because it uses stuff that can't be compiled into * the kernel, and it needs to be compiled into the user-level sparemap daemon. * */ void * rf_ReadSpareTable(RF_SparetWait_t *req, char *fname) { int i, j, numFound, linecount, tableNum, tupleNum, spareDisk, spareBlkOffset; char buf[1024], targString[100], errString[100]; RF_SpareTableEntry_t **table; FILE *fp; /* allocate and initialize the table */ table = malloc(req->TablesPerSpareRegion * sizeof(RF_SpareTableEntry_t *)); if (table == NULL) { fprintf(stderr, "rf_ReadSpareTable: Unable to allocate table\n"); return (NULL); } for (i = 0; i < req->TablesPerSpareRegion; i++) { table[i] = malloc(req->BlocksPerTable * sizeof(RF_SpareTableEntry_t)); if (table[i] == NULL) { fprintf(stderr, "rf_ReadSpareTable: Unable to allocate table\n"); return (NULL); /* XXX should cleanup too! */ } for (j = 0; j < req->BlocksPerTable; j++) table[i][j].spareDisk = table[i][j].spareBlockOffsetInSUs = -1; } /* 2. open sparemap file, sanity check */ if ((fp = fopen(fname, "r")) == NULL) { fprintf(stderr, "rf_ReadSpareTable: Can't open sparemap file %s\n", fname); return (NULL); } if (rf_get_next_nonblank_line(buf, 1024, fp, "Invalid sparemap file: can't find header line\n")) { fclose(fp); return (NULL); } if (buf[strlen(buf) - 1] == '\n') buf[strlen(buf) - 1] = '\0'; snprintf(targString, sizeof(targString), "fdisk %d\n", req->fcol); snprintf(errString, sizeof(errString), "Invalid sparemap file: can't find \"fdisk %d\" line\n", req->fcol); while (1) { rf_get_next_nonblank_line(buf, 1024, fp, errString); if (!strncmp(buf, targString, strlen(targString))) break; } /* no more blank lines or comments allowed now */ linecount = req->TablesPerSpareRegion * req->TableDepthInPUs; for (i = 0; i < linecount; i++) { numFound = fscanf(fp, " %d %d %d %d", &tableNum, &tupleNum, &spareDisk, &spareBlkOffset); if (numFound != 4) { fprintf(stderr, "Sparemap file prematurely exhausted after %d of %d lines\n", i, linecount); fclose(fp); return (NULL); } table[tableNum][tupleNum].spareDisk = spareDisk; table[tableNum][tupleNum].spareBlockOffsetInSUs = spareBlkOffset * req->SUsPerPU; } fclose(fp); return ((void *) table); }