fis-gtm/sr_unix/mupip_endiancvt.c

1370 lines
47 KiB
C

/****************************************************************
* *
* Copyright 2006, 2011 Fidelity Information Services, Inc *
* *
* This source code contains the intellectual property *
* of its copyright holder(s), and is made available *
* under a license. If you do not know the terms of *
* the license, please stop and do not read further. *
* *
****************************************************************/
#include "mdef.h"
#include "gtm_fcntl.h"
#include "gtm_unistd.h"
#include "gtm_socket.h"
#include "gtm_inet.h"
#include "gtm_stdio.h"
#include "gtm_string.h"
#include "gtm_sem.h"
#include <sys/wait.h>
#include <stddef.h>
#include <errno.h>
#include "gtm_time.h"
#ifdef __MVS__
#include "gtm_zos_io.h"
#include <sys/time.h>
#endif
#include "gdsroot.h"
#include "v15_gdsroot.h" /* for v15_trans_num */
#include "gtm_facility.h"
#include "fileinfo.h"
#include "gdsbt.h"
#include "gdsfhead.h"
#include "gdsblk.h"
#include "filestruct.h"
#include "jnl.h"
#include "gdsbml.h"
#include "cli.h"
#include "iosp.h"
#include "copy.h"
#include "error.h"
#include "gtmio.h"
#include "iotimer.h"
#include "iotcpdef.h"
#include "iotcproutine.h"
#include "gt_timer.h"
#include "stp_parms.h"
#include "gtm_stat.h"
#include "eintr_wrappers.h"
#include "util.h"
#include "gtm_caseconv.h"
#include "io.h"
#include "is_proc_alive.h"
#include "mu_rndwn_file.h"
#include "mupip_exit.h"
#include "mu_gv_cur_reg_init.h"
#include "mupip_endiancvt.h"
#include "gtmmsg.h"
#include "wcs_sleep.h"
#include "ftok_sems.h"
#include "gvcst_lbm_check.h" /* gvcst_blk_ever_allocated */
#include "shmpool.h"
#include "min_max.h"
#include "spec_type.h" /* collation info */
#ifdef GTM_CRYPT
#include "gtmcrypt.h"
#endif
GBLREF gd_region *gv_cur_region;
LITREF char *gtm_dbversion_table[];
error_def(ERR_BADTAG);
error_def(ERR_DBRDONLY);
error_def(ERR_ENDIANCVT);
error_def(ERR_IOEOF);
error_def(ERR_MUNOACTION);
error_def(ERR_MUNOFINISH);
error_def(ERR_MUPCLIERR);
error_def(ERR_MUSTANDALONE);
error_def(ERR_NOENDIANCVT);
error_def(ERR_TEXT);
#define NOTCURRDBFORMAT "database format is not the current version"
#define NOTCURRMDBFORMAT "minor database format is not the current version"
#define NOTFULLYUPGRADED "some blocks are not upgraded to the current version"
#define KILLINPROG "kills in progress"
#define ABANDONED_KILLS "abandoned kills present"
#define GTCMSERVERACTIVE "a GT.CM server accessing the database"
#define RECOVINTRPT "recovery was interrupted"
#define DBCREATE "database creation in progress"
#define DBCORRUPT "the database is corrupted"
#define MAX_CONF_RESPONSE 30
GTMCRYPT_ONLY(
boolean_t is_encrypted = FALSE;
gtmcrypt_key_t encr_key_handle;
char source_file_name[MAX_FN_LEN + 1];
)
typedef struct
{ /* adapted from dbcertify.h */
unsigned int top; /* Offset to top of the key */
unsigned int end; /* End of the current key */
unsigned int gvn_len; /* Length of key */
unsigned char *key; /* Pointer to the key */
} end_gv_key;
typedef struct
{
int db_fd;
int outdb_fd; /* FD_INVALID if inplace */
boolean_t inplace; /* update in place */
boolean_t endian_native; /* original database */
uint4 tot_blks;
int bsize; /* GDS block size */
int4 startvbn; /* in DISK_BLOCK_SIZE units */
block_id last_blk_cvt; /* highest block converted so far not lbm */
struct /* used by find_dtblk related routines */
{
char *buff;
char *dtrbuff; /* keep the DT root */
block_id blkid;
boolean_t native; /* records are native endian */
boolean_t dtrnative; /* records in dtrbuff are native endian */
int count; /* number of times needed */
} dtblk;
} endian_info;
void endian_header(sgmnt_data *new, sgmnt_data *old, boolean_t new_is_native);
int4 endian_process(endian_info *info, sgmnt_data *new_data, sgmnt_data *old_data);
void endian_cvt_blk_hdr(blk_hdr_ptr_t blkhdr, boolean_t new_is_native, boolean_t make_empty);
void endian_cvt_blk_recs(endian_info *info, char *new_block, blk_hdr_ptr_t blkhdr, int blknum);
char *endian_read_dbblk(endian_info *info, block_id blk_to_get);
void endian_find_key(endian_info *info, end_gv_key *gv_key, char *rec_p, int rec_len, int blk_levl);
boolean_t endian_match_key(end_gv_key *gv_key1, int blk_levl, end_gv_key *key2);
block_id endian_find_dtblk(endian_info *info, end_gv_key *gv_key);
/* If we acquired standalone access, we need to release it before we exit. Ideally, mupip_exit_handler should take care of doing
* it. But, since we free up memory allocated to gv_cur_region before exiting out of this module, db_ipcs_reset done in mupip_exit
* will cause invalid memory references since standalone_reg (used by db_ipcs_reset) is a pointer to gv_cur_region. One solution
* would be to do gv_cur_region free up AFTER db_ipcs_reset in mupip_exit_handler but since various code path sets gv_cur_region,
* the implication of such a change is not clear at this point.
*/
#define DO_STANDALONE_CLNUP_IF_NEEDED(ENDIAN_NATIVE) \
{ \
DEBUG_ONLY(GBLREF gd_region *standalone_reg;) \
\
if (ENDIAN_NATIVE) \
{ /* release standalone access */ \
assert(gv_cur_region == standalone_reg); \
db_ipcs_reset(gv_cur_region); \
mu_gv_cur_reg_free(); \
} \
}
void mupip_endiancvt(void)
{
char db_name[MAX_FN_LEN + 1], *t_name;
sgmnt_data *old_data, *new_data;
int4 status, save_errno;
int rc;
uint4 swap_uint4;
enum db_ver swap_dbver;
enum mdb_ver swap_mdbver;
trans_num curr_tn;
block_id blk_num;
uint4 cli_status;
int i, db_fd, outdb_fd, mastermap_size;
unsigned short n_len, outdb_len, t_len;
boolean_t outdb_specified, endian_native, swap_boolean, got_standalone, override_specified;
char outdb[MAX_FN_LEN + 1], conf_buff[MAX_CONF_RESPONSE + 1], *response;
char *errptr, *check_error, *mastermap;
char *from_endian, *to_endian;
endian32_struct endian_check;
endian_info info;
GTMCRYPT_ONLY(
int crypt_status;
)
ZOS_ONLY(int realfiletag;)
if (CLI_PRESENT == (cli_status = cli_present("OUTDB")))
{
outdb_specified = TRUE;
outdb_len = SIZEOF(outdb) - 1;
if (!cli_get_str("OUTDB", outdb, &outdb_len))
mupip_exit(ERR_MUPCLIERR);
} else
outdb_specified = FALSE;
n_len = SIZEOF(db_name) - 1;
if (cli_get_str("DATABASE", db_name, &n_len) == FALSE)
mupip_exit(ERR_MUPCLIERR);
OPENFILE(db_name, (!outdb_specified ? O_RDWR : O_RDONLY), db_fd);
if (FD_INVALID == db_fd)
{
save_errno = errno;
util_out_print("Error accessing database file !AD. Aborting endiancvt.", TRUE, n_len, db_name);
errptr = (char *)STRERROR(save_errno);
util_out_print("open : !AZ", TRUE, errptr);
mupip_exit(save_errno);
}
#ifdef __MVS__
if (-1 == gtm_zos_tag_to_policy(db_fd, TAG_BINARY, &realfiletag))
TAG_POLICY_GTM_PUTMSG(db_name, realfiletag, TAG_BINARY, errno);
#endif
old_data = (sgmnt_data *)malloc(SIZEOF(sgmnt_data));
LSEEKREAD(db_fd, 0, old_data, SIZEOF(sgmnt_data), save_errno);
if (0 != save_errno)
{
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
util_out_print("Error reading database file !AD header. Aborting endiancvt.", TRUE, n_len, db_name);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("read : !AZ", TRUE, errptr);
mupip_exit(save_errno);
} else
mupip_exit(ERR_IOEOF);
}
if (MEMCMP_LIT(&old_data->label[0], GDS_LABEL))
{
util_out_print("Database file !AD has an unrecognizable format", TRUE, n_len, db_name);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
mupip_exit(ERR_MUNOACTION);
}
override_specified = (CLI_PRESENT == (cli_status = cli_present("OVERRIDE")));
check_error = NULL;
endian_check.word32 = (uint4)old_data->minor_dbver;
#ifdef BIGENDIAN
if (!endian_check.shorts.big_endian)
#else
if (!endian_check.shorts.little_endian)
#endif
{
endian_native = FALSE; /* nobody can be using the db */
/* do checks after swapping fields */
assert(SIZEOF(int4) == SIZEOF(old_data->desired_db_format));
/* If OVERRIDE is specified, skip checking for those fields that are not critical for the integrity of the db.
* Any field that indicates the db is potentially damaged cannot be overridden.
*/
if (!override_specified)
{
swap_mdbver = (enum mdb_ver)GTM_BYTESWAP_32(old_data->minor_dbver);
if (GDSMVCURR != swap_mdbver)
{
check_error = NOTCURRMDBFORMAT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->kill_in_prog);
if (0 != swap_uint4)
{
check_error = KILLINPROG;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->abandoned_kills);
if (0 != swap_uint4)
{
check_error = ABANDONED_KILLS;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->rc_srv_cnt);
if (0 != swap_uint4)
{
check_error = GTCMSERVERACTIVE;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
}
swap_dbver = (enum db_ver)GTM_BYTESWAP_32(old_data->desired_db_format);
if (GDSVCURR != swap_dbver)
{
check_error = NOTCURRDBFORMAT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
assert(SIZEOF(int4) == SIZEOF(old_data->fully_upgraded));
swap_boolean = GTM_BYTESWAP_32(old_data->fully_upgraded);
if (!swap_boolean)
{
check_error = NOTFULLYUPGRADED;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->recov_interrupted);
if (0 != swap_uint4)
{
check_error = RECOVINTRPT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->createinprogress);
if (0 != swap_uint4)
{
check_error = DBCREATE;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
swap_uint4 = GTM_BYTESWAP_32(old_data->file_corrupt);
if (0 != swap_uint4)
{
check_error = DBCORRUPT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
} else
{
endian_native = TRUE; /* need to get standalone */
mu_gv_cur_reg_init();
strcpy((char *)gv_cur_region->dyn.addr->fname, db_name);
gv_cur_region->dyn.addr->fname_len = n_len;
got_standalone = STANDALONE(gv_cur_region);
if (FALSE == got_standalone)
{
mu_gv_cur_reg_free();
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
gtm_putmsg(VARLSTCNT(4) MAKE_MSG_TYPE(ERR_MUSTANDALONE, ERROR), 2, n_len, db_name);
mupip_exit(ERR_MUNOACTION);
}
if (gv_cur_region->read_only && !outdb_specified)
{
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
gtm_putmsg(VARLSTCNT(4) ERR_DBRDONLY, 2, n_len, db_name);
mupip_exit(ERR_MUNOACTION);
}
if (!override_specified)
{
if (GDSMVCURR != old_data->minor_dbver)
{
check_error = NOTCURRMDBFORMAT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->kill_in_prog)
{
check_error = KILLINPROG;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->abandoned_kills)
{
check_error = ABANDONED_KILLS;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->rc_srv_cnt)
{
check_error = GTCMSERVERACTIVE;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
}
if (GDSVCURR != old_data->desired_db_format)
{
check_error = NOTCURRDBFORMAT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (!old_data->fully_upgraded)
{
check_error = NOTFULLYUPGRADED;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->recov_interrupted)
{
check_error = RECOVINTRPT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->createinprogress)
{
check_error = DBCREATE;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (0 != old_data->file_corrupt)
{
check_error = DBCORRUPT;
gtm_putmsg(VARLSTCNT(6) ERR_NOENDIANCVT, 4, n_len, db_name, LEN_AND_STR(check_error));
}
if (!check_error && !outdb_specified)
{
if (JNL_ENABLED(old_data))
{
/* report what we are doing ERR_JNLSTATE */
util_out_print("!_Journaling was enabled - now closed",TRUE);
old_data->jnl_state = jnl_closed;
}
if (REPL_ENABLED(old_data))
{
/* report what we are doing ERR_REPLSTATE */
util_out_print("!_Replication was enabled - now closed",TRUE);
old_data->repl_state = repl_closed;
}
}
}
if (check_error)
{
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
mupip_exit(ERR_MUNOACTION);
}
/* Once the header is read, make a note whether the db is encrypted or not. If encrypted, get the
* needed key information also. We need to get the key information here as the code path of endiancvt
* doesn't go through db_init (which gets the key information in the usual cases). */
# ifdef GTM_CRYPT
is_encrypted = endian_native ? old_data->is_encrypted : GTM_BYTESWAP_32(old_data->is_encrypted);
if (is_encrypted)
{
INIT_PROC_ENCRYPTION(crypt_status);
/* If the encryption init failed in db_init, the below MACRO should return an error.
* Depending on the error returned, report the error.*/
GTMCRYPT_GETKEY(old_data->encryption_hash, encr_key_handle, crypt_status);
if (0 != crypt_status)
{
GC_GTM_PUTMSG(crypt_status, db_name);
mupip_exit(crypt_status);
}
strcpy(source_file_name, db_name);
}
# endif
from_endian = endian_check.shorts.big_endian ? "BIG" : "LITTLE";
to_endian = endian_check.shorts.big_endian ? "LITTLE" : "BIG";
util_out_print("Converting database file !AD from !AZ endian to !AZ endian on a !AZ endian system", TRUE,
n_len, db_name, from_endian, to_endian, ENDIANTHIS);
if (!outdb_specified)
{
util_out_print("Converting in place - database will be damaged by an abnormal termination", TRUE);
util_out_print("You must have a backup before proceeding", TRUE);
} else
util_out_print("Converting to new file !AD", TRUE, outdb_len, outdb);
util_out_print("Proceed [yes/no] ?", TRUE);
response = util_input(conf_buff, MAX_CONF_RESPONSE, stdin, TRUE);
if (NULL == response || ('Y' != conf_buff[0] && 'y' != conf_buff[0]))
{
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
mupip_exit(ERR_MUNOACTION);
}
new_data = (sgmnt_data *)malloc(SIZEOF(sgmnt_data));
memcpy(new_data, old_data, SIZEOF(sgmnt_data));
new_data->file_corrupt = endian_native ? GTM_BYTESWAP_32(TRUE) : TRUE;
info.db_fd = db_fd;
info.inplace = !outdb_specified;
info.endian_native = info.dtblk.native = info.dtblk.dtrnative = endian_native;
info.tot_blks = info.bsize = info.startvbn = info.last_blk_cvt = 0;
info.dtblk.buff = info.dtblk.dtrbuff = NULL;
info.dtblk.blkid = -1; /* invalid block number */
info.dtblk.count = 0;
endian_header(new_data, old_data, !endian_native); /* convert file header fields */
if (outdb_specified)
{
OPENFILE3(outdb, O_RDWR | O_CREAT | O_EXCL, 0666, outdb_fd);
if (FD_INVALID == outdb_fd)
{ /* error */
save_errno = errno;
util_out_print("Error creating converted databasae file !AD. Aborting endiancvt.", TRUE, outdb_len, outdb);
errptr = (char *)STRERROR(save_errno);
util_out_print("open : !AZ", TRUE, errptr);
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(new_data);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
mupip_exit(save_errno);
}
#ifdef __MVS__
if (-1 == gtm_zos_set_tag(outdb_fd, TAG_BINARY, TAG_NOTTEXT, TAG_DONTFORCE, &realfiletag))
TAG_POLICY_GTM_PUTMSG(outdb, realfiletag, TAG_BINARY, errno);
#endif
new_data->file_corrupt = endian_native ? GTM_BYTESWAP_32(TRUE) : TRUE;
LSEEKWRITE(outdb_fd, 0, new_data, SIZEOF(sgmnt_data), save_errno);
if (0 != save_errno)
{
free(new_data);
free(old_data);
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
util_out_print("Error writing converted database file !AD header. Aborting endiancvt.", TRUE,
outdb_len, outdb);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("write : !AZ", TRUE, errptr);
mupip_exit(save_errno);
} else
{
util_out_print("write : unexpected error", TRUE);
mupip_exit(ERR_MUNOFINISH);
}
}
/* read master bit map from old file */
mastermap_size = endian_native ? old_data->master_map_len : new_data->master_map_len;
mastermap = malloc(mastermap_size);
LSEEKREAD(db_fd, SGMNT_HDR_LEN, mastermap, mastermap_size, save_errno);
if (0 != save_errno)
{
free(new_data);
free(old_data);
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
util_out_print("Error reading database file !AD master map. Aborting endiancvt.", TRUE,
n_len, db_name);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("read : !AZ", TRUE, errptr);
mupip_exit(save_errno);
} else
mupip_exit(ERR_IOEOF);
}
/* write master bit map to new file */
LSEEKWRITE(outdb_fd, SGMNT_HDR_LEN, mastermap, mastermap_size, save_errno);
if (0 != save_errno)
{
free(new_data);
free(old_data);
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
util_out_print("Error writing converted database file !AD master map. Aborting endiancvt.", TRUE,
outdb_len, outdb);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("write : !AZ", TRUE, errptr);
mupip_exit(save_errno);
} else
{
util_out_print("write : unexpected error", TRUE);
mupip_exit(ERR_MUNOFINISH);
}
}
} else
outdb_fd = FD_INVALID;
info.outdb_fd = outdb_fd;
status = endian_process(&info, new_data, old_data);
if (0 != status)
{
/* db_ipcs_reset in the macro below works even with the now converted opposite endian header since it just sets
* csd->s{e|h}mid to INVALIDS{E|H}MID and zeroes s{e|h}m_ctime.
*/
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(new_data);
free(old_data);
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
if (outdb_specified)
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
mupip_exit(ERR_MUNOFINISH); /* endian_process issued specific message */
}
new_data->file_corrupt = endian_native ? GTM_BYTESWAP_32(FALSE) : FALSE;
LSEEKWRITE(outdb_specified ? outdb_fd : db_fd, 0, new_data, SIZEOF(sgmnt_data), save_errno);
if (0 != save_errno)
{
free(new_data);
free(old_data);
if (outdb_specified)
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
util_out_print("Error writing!AZ database file !AD header. Aborting endiancvt.", TRUE,
outdb_specified ? "new" : "", outdb_specified ? outdb_len : n_len, outdb_specified ? outdb : db_name);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("write : !AZ", TRUE, errptr);
mupip_exit(save_errno);
} else
{
util_out_print("write : unexpected error", TRUE);
mupip_exit(ERR_MUNOFINISH);
}
}
DO_STANDALONE_CLNUP_IF_NEEDED(endian_native);
free(new_data);
free(old_data);
GTM_FSYNC((outdb_specified ? outdb_fd : db_fd), rc);
if (-1 == rc)
{
save_errno = errno;
assert(FALSE);
if (-1 != save_errno)
{
errptr = (char *)STRERROR(save_errno);
util_out_print("fsync : !AZ : !AZ", TRUE, (outdb_specified ? "outdb_fd" : "db_fd"), errptr);
mupip_exit(save_errno);
} else
{
util_out_print("fsync : !AZ : unexpected error", TRUE, (outdb_specified ? "outdb_fd" : "db_fd"));
mupip_exit(ERR_MUNOFINISH);
}
}
CLOSEFILE_RESET(db_fd, rc); /* resets "db_fd" to FD_INVALID */
if (outdb_specified)
CLOSEFILE_RESET(outdb_fd, rc); /* resets "outdb_fd" to FD_INVALID */
/* Display success message only after all data has been synced to disk and the file descriptors closed */
gtm_putmsg(VARLSTCNT(7) ERR_ENDIANCVT, 5, n_len, db_name, from_endian, to_endian, ENDIANTHIS);
mupip_exit(SS_NORMAL);
}
#define SWAP_SD4(FIELD) new->FIELD = GTM_BYTESWAP_32(old->FIELD)
#define SWAP_SD4_CAST(FIELD, castType) new->FIELD = (castType)GTM_BYTESWAP_32(old->FIELD)
#define SWAP_SD8(FIELD) new->FIELD = GTM_BYTESWAP_64(old->FIELD)
void endian_header(sgmnt_data *new, sgmnt_data *old, boolean_t new_is_native)
{
int n;
time_t ctime;
SWAP_SD4(blk_size);
SWAP_SD4(master_map_len);
SWAP_SD4(bplmap);
SWAP_SD4(start_vbn);
assert(SIZEOF(int4) == SIZEOF(old->acc_meth)); /* enum */
SWAP_SD4_CAST(acc_meth, enum db_acc_method);
SWAP_SD4(max_bts);
SWAP_SD4(n_bts);
SWAP_SD4(bt_buckets);
SWAP_SD4(reserved_bytes);
SWAP_SD4(max_rec_size);
SWAP_SD4(max_key_size);
SWAP_SD4(lock_space_size);
SWAP_SD4(extension_size);
SWAP_SD4(def_coll);
SWAP_SD4(def_coll_ver);
assert(SIZEOF(int4) == SIZEOF(old->std_null_coll)); /* boolean_t */
SWAP_SD4(std_null_coll);
SWAP_SD4(null_subs);
SWAP_SD4(free_space);
SWAP_SD4(mutex_spin_parms.mutex_hard_spin_count); /* gdsbt.h */
SWAP_SD4(mutex_spin_parms.mutex_sleep_spin_count);
SWAP_SD4(mutex_spin_parms.mutex_spin_sleep_mask);
SWAP_SD4(max_update_array_size);
SWAP_SD4(max_non_bm_update_array_size);
/* SWAP_SD4(file_corrupt); is set in main routine */
assert(SIZEOF(int4) == SIZEOF(old->minor_dbver)); /* enum */
SWAP_SD4_CAST(minor_dbver, enum mdb_ver);
SWAP_SD4(jnl_checksum);
SWAP_SD4(wcs_phase2_commit_wait_spincnt);
/* SWAP_SD4(createinprogress); checked above as FALSE so no need */
assert(SIZEOF(int4) == SIZEOF(old->creation_time4));
time(&ctime);
assert(SIZEOF(ctime) >= SIZEOF(int4));
new->creation_time4 = (int4)ctime;/* Take only lower order 4-bytes of current time */
if (!new_is_native)
SWAP_SD4(creation_time4);
assert(SIZEOF(gtm_int64_t) == SIZEOF(old->max_tn)); /* trans_num */
SWAP_SD8(max_tn);
SWAP_SD8(max_tn_warn);
SWAP_SD8(last_inc_backup);
SWAP_SD8(last_com_backup);
SWAP_SD8(last_rec_backup);
assert(SIZEOF(int4) == SIZEOF(old->last_inc_bkup_last_blk)); /* block_id */
SWAP_SD4(last_inc_bkup_last_blk);
SWAP_SD4(last_com_bkup_last_blk);
SWAP_SD4(last_rec_bkup_last_blk);
SWAP_SD4(reorg_restart_block);
SWAP_SD4(owner_node); /* should be zero when not open */
new->image_count = 0; /* should be zero when db is not open so reset it unconditionally */
new->freeze = 0; /* should be zero when db is not open so reset it unconditionally */
SWAP_SD4(kill_in_prog);
SWAP_SD4(abandoned_kills);
SWAP_SD8(tn_upgrd_blks_0);
SWAP_SD8(desired_db_format_tn);
SWAP_SD8(reorg_db_fmt_start_tn);
SWAP_SD4(reorg_upgrd_dwngrd_restart_block);
SWAP_SD4(blks_to_upgrd);
SWAP_SD4(blks_to_upgrd_subzero_error);
assert(SIZEOF(int4) == SIZEOF(old->desired_db_format)); /* enum */
SWAP_SD4_CAST(desired_db_format, enum db_ver);
SWAP_SD4(fully_upgraded); /* should be TRUE */
assert(new->fully_upgraded);
/* Since the source database is fully upgraded and since all RECYCLED blocks will be marked as FREE, we are guaranteed
* there are NO V4 format block that is too full to be upgraded to V5 format (i.e. will cause DYNUPGRDFAIL error).
*/
new->db_got_to_v5_once = TRUE; /* should be TRUE */
SWAP_SD8(trans_hist.curr_tn);
SWAP_SD8(trans_hist.early_tn);
SWAP_SD8(trans_hist.last_mm_sync);
SWAP_SD8(trans_hist.mm_tn);
SWAP_SD4(trans_hist.lock_sequence);
SWAP_SD4(trans_hist.ccp_jnl_filesize);
SWAP_SD4(trans_hist.total_blks);
SWAP_SD4(trans_hist.free_blocks);
SWAP_SD4(flush_time[0]);
SWAP_SD4(flush_time[1]);
SWAP_SD4(flush_trigger);
SWAP_SD4(n_wrt_per_flu);
SWAP_SD4(wait_disk_space);
SWAP_SD4(defer_time);
new->wc_blocked = FALSE; /* is relevant only when database shared memory is up so reset it unconditionally */
SWAP_SD4(reserved_for_upd);
SWAP_SD4(avg_blks_per_100gbl);
SWAP_SD4(pre_read_trigger_factor);
SWAP_SD4(writer_trigger_factor);
/* Solaris complains about swapping -1
assert(INVALID_SEMID == GTM_BYTESWAP_32(INVALID_SEMID));
assert(INVALID_SHMID == GTM_BYTESWAP_32(INVALID_SHMID));
*/
assert(-1 == INVALID_SEMID);
assert(-1 == INVALID_SHMID);
if (new_is_native)
{ /* Since we have standalone access, reset volatile fields in the database file header */
new->semid = INVALID_SEMID;
new->shmid = INVALID_SHMID;
new->gt_sem_ctime.ctime = 0;
new->gt_shm_ctime.ctime = 0;
memset(new->machine_name, 0, MAX_MCNAMELEN);
}
/* Convert GVSTATS information */
# define TAB_GVSTATS_REC(COUNTER,TEXT1,TEXT2) SWAP_SD8(gvstats_rec.COUNTER);
# include "tab_gvstats_rec.h"
# undef TAB_GVSTATS_REC
SWAP_SD4(staleness[0]);
SWAP_SD4(staleness[1]);
SWAP_SD4(ccp_tick_interval[0]);
SWAP_SD4(ccp_tick_interval[1]);
SWAP_SD4(ccp_quantum_interval[0]);
SWAP_SD4(ccp_quantum_interval[1]);
SWAP_SD4(ccp_response_interval[0]);
SWAP_SD4(ccp_response_interval[1]);
SWAP_SD4(ccp_jnl_before);
SWAP_SD4(clustered);
SWAP_SD4(unbacked_cache);
/* RC server related fields sb zero when not active */
SWAP_SD4(rc_srv_cnt);
SWAP_SD4(dsid);
SWAP_SD4(rc_node);
assert(SIZEOF(gtm_int64_t) == SIZEOF(old->reg_seqno)); /* seq_num */
SWAP_SD8(reg_seqno);
SWAP_SD8(pre_multisite_resync_seqno);
/* Note some of the following names were added or renamed in V5.1 but
should be of no issue for V5.0 builds since we will be swapping
unused fields.
*/
SWAP_SD8(zqgblmod_tn);
SWAP_SD8(zqgblmod_seqno);
new->repl_state = repl_closed;
if (!new_is_native)
SWAP_SD4(repl_state);
SWAP_SD4(multi_site_open);
SWAP_SD8(dualsite_resync_seqno);
for (n = 0; n < ARRAYSIZE(old->tp_cdb_sc_blkmod); n++)
new->tp_cdb_sc_blkmod[n] = 0;
SWAP_SD4(jnl_alq);
SWAP_SD4(jnl_deq);
SWAP_SD4(jnl_buffer_size);
SWAP_SD4(jnl_before_image);
new->jnl_state = jnl_closed;
if (!new_is_native)
SWAP_SD4(jnl_state);
SWAP_SD4(jnl_file_len);
SWAP_SD4(autoswitchlimit);
SWAP_SD4(epoch_interval);
SWAP_SD4(alignsize);
SWAP_SD4(jnl_sync_io);
SWAP_SD4(yield_lmt);
assert(SIZEOF(gtm_int64_t) == SIZEOF(old->intrpt_recov_resync_seqno));
SWAP_SD8(intrpt_recov_resync_seqno);
assert(SIZEOF(int4) == SIZEOF(old->intrpt_recov_tp_resolve_time));
SWAP_SD4(intrpt_recov_tp_resolve_time);
SWAP_SD4(recov_interrupted);
SWAP_SD4(intrpt_recov_jnl_state);
SWAP_SD4(intrpt_recov_repl_state);
SWAP_SD4(is_encrypted);
#define TAB_BG_TRC_REC(A,B) new->B##_cntr = (bg_trc_rec_cntr) 0; new->B##_tn = (bg_trc_rec_tn) 0;
#include "tab_bg_trc_rec.h"
#undef TAB_BG_TRC_REC
#define TAB_DB_CSH_ACCT_REC(A,B,C) new->A.cumul_count = new->A.curr_count = 0;
#include "tab_db_csh_acct_rec.h"
#undef TAB_DB_CSH_ACCT_REC
SWAP_SD4_CAST(creation_db_ver, enum db_ver);
SWAP_SD4_CAST(creation_mdb_ver, enum mdb_ver);
SWAP_SD4_CAST(certified_for_upgrade_to, enum db_ver);
/* next_upgrd_warn isn't valid since the database is fully_upgraded
and the latch values differ by platform and since we don't know where
the db will be used, we will ignore it.
*/
}
int4 endian_process(endian_info *info, sgmnt_data *new_data, sgmnt_data *old_data)
{ /* returns 0 for success
This routine based on mubinccpy and dbcertify_scan_phase
*/
int4 startvbn;
int save_errno, bsize, lbmap_cnt, lbm_status;
int buff_native, buff_old, buff_new;
int mm_offset, lm_offset;
int4 bplmap;
uint4 totblks, lbm_done, busy_done, recycled_done, free_done, last_blk_written;
off_t dbptr;
block_id blk_num;
boolean_t new_is_native;
char *blk_buff[2], *lbmap_buff[2], *errptr;
# ifdef GTM_CRYPT
int crypt_blk_size, crypt_status;
blk_hdr_ptr_t bp_new, bp_native;
boolean_t blk_needs_encryption;
# endif
if (info->endian_native)
{ /* use fields from old header */
bplmap = old_data->bplmap;
totblks = old_data->trans_hist.total_blks;
lbmap_cnt = (totblks + bplmap - 1) / bplmap;
bsize = old_data->blk_size;
startvbn = old_data->start_vbn;
buff_native = buff_old = 0;
new_is_native = FALSE;
buff_new = 1;
} else
{ /* use swapped fields from new header */
bplmap = new_data->bplmap;
totblks = new_data->trans_hist.total_blks;
lbmap_cnt = (totblks + bplmap - 1) / bplmap;
bsize = new_data->blk_size;
startvbn = new_data->start_vbn;
buff_native = buff_new = 1;
new_is_native = TRUE;
buff_old = 0;
}
dbptr = (startvbn - 1) * DISK_BLOCK_SIZE;
info->tot_blks = totblks;
info->bsize = bsize;
info->startvbn = startvbn;
blk_buff[0] = malloc(bsize);
blk_buff[1] = malloc(bsize);
lbmap_buff[0] = malloc(bsize);
lbmap_buff[1] = malloc(bsize);
blk_num = last_blk_written = lbm_done = busy_done = recycled_done = free_done = 0;
for (mm_offset = 0; (mm_offset < lbmap_cnt) && (blk_num < totblks); ++mm_offset)
{ /* for each local bit map */
assert(0 == (blk_num % bplmap)); /* check proper local bit map alignment */
LSEEKREAD(info->db_fd, dbptr, lbmap_buff[buff_old], bsize, save_errno);
if (0 != save_errno)
{
free(blk_buff[0]);
free(lbmap_buff[0]);
free(blk_buff[1]);
free(lbmap_buff[1]);
errptr = (char *)STRERROR(save_errno);
util_out_print("Error reading local bit map block !UL : !AZ", TRUE, blk_num, errptr);
return save_errno;
}
memcpy(lbmap_buff[buff_new], lbmap_buff[buff_old], bsize);
endian_cvt_blk_hdr((blk_hdr_ptr_t)lbmap_buff[buff_new], new_is_native, FALSE);
assert(LCL_MAP_LEVL == ((blk_hdr_ptr_t)lbmap_buff[buff_native])->levl);
/* set all recycled bits to free to avoid trouble if pre GDSV5 */
/* lm_offset 0 is the local bit map itself */
for (lm_offset = 1; lm_offset < bplmap && (blk_num + lm_offset) < totblks; lm_offset++)
{
GET_BM_STATUS(lbmap_buff[buff_new], lm_offset, lbm_status);
if (BLK_RECYCLED == lbm_status)
{
SET_BM_STATUS(lbmap_buff[buff_new], lm_offset, BLK_FREE);
recycled_done++;
} else if (BLK_FREE == lbm_status)
free_done++; /* count before changing recycled to free */
else if (BLK_MAPINVALID == lbm_status)
GTMASSERT;
}
LSEEKWRITE(info->inplace ? info->db_fd : info->outdb_fd, dbptr, lbmap_buff[buff_new], bsize, save_errno);
if (0 != save_errno)
{
free(blk_buff[0]);
free(lbmap_buff[0]);
free(blk_buff[1]);
free(lbmap_buff[1]);
errptr = (char *)STRERROR(save_errno);
util_out_print("Error writing local bit map block !UL : !AZ", TRUE, blk_num, errptr);
return save_errno;
}
last_blk_written = blk_num;
lbm_done++;
/* lm_offset 0 is the local bit map itself */
for (lm_offset = 1, dbptr += bsize, blk_num++;
(blk_num < totblks) && (lm_offset < bplmap);
lm_offset++, dbptr += bsize, blk_num++)
{ /* for each local bit map entry - there will only be busy or free blocks in the (new) database */
GET_BM_STATUS(lbmap_buff[buff_new], lm_offset, lbm_status);
if (BLK_BUSY == lbm_status)
{
LSEEKREAD(info->db_fd, dbptr, blk_buff[buff_old], bsize, save_errno);
if (0 != save_errno)
{
free(blk_buff[0]);
free(lbmap_buff[0]);
free(blk_buff[1]);
free(lbmap_buff[1]);
errptr = (char *)STRERROR(save_errno);
util_out_print("Error reading block !UL : !AZ", TRUE, blk_num, errptr);
return save_errno;
}
memcpy(blk_buff[buff_new], blk_buff[buff_old], bsize);
# ifdef GTM_CRYPT
if (is_encrypted)
{
ASSERT_ENCRYPTION_INITIALIZED;
bp_new = (blk_hdr_ptr_t)blk_buff[buff_new];
bp_native = (blk_hdr_ptr_t)blk_buff[buff_native];
if (new_is_native)
endian_cvt_blk_hdr(bp_new, new_is_native, BLK_RECYCLED == lbm_status);
assert((bp_new->bsiz <= bsize) && (bp_new->bsiz >= SIZEOF(*bp_new)));
crypt_blk_size = MIN(bsize, bp_new->bsiz) - (SIZEOF(*bp_new));
blk_needs_encryption = BLK_NEEDS_ENCRYPTION(bp_new->levl, crypt_blk_size);
if (blk_needs_encryption)
{
GTMCRYPT_DECODE_FAST(encr_key_handle,
(char *)(bp_new + 1),
crypt_blk_size,
NULL,
crypt_status);
if (0 != crypt_status)
{
GC_GTM_PUTMSG(crypt_status, source_file_name);
return crypt_status;
}
}
if (!new_is_native)
endian_cvt_blk_hdr(bp_new,
new_is_native,
BLK_RECYCLED == lbm_status);
endian_cvt_blk_recs(info, (char *)bp_new, bp_native, blk_num);
if (blk_needs_encryption)
{
GTMCRYPT_ENCODE_FAST(encr_key_handle,
(char *)(bp_new + 1),
crypt_blk_size,
NULL,
crypt_status);
if (0 != crypt_status)
{
GC_GTM_PUTMSG(crypt_status, source_file_name);
return crypt_status;
}
}
} else
{
# endif
endian_cvt_blk_hdr((blk_hdr_ptr_t)blk_buff[buff_new],
new_is_native, BLK_RECYCLED == lbm_status);
endian_cvt_blk_recs(info, blk_buff[buff_new],
(blk_hdr_ptr_t)blk_buff[buff_native], blk_num);
# ifdef GTM_CRYPT
}
# endif
LSEEKWRITE(info->inplace ? info->db_fd : info->outdb_fd, dbptr, blk_buff[buff_new], bsize,
save_errno);
if (0 != save_errno)
{
free(blk_buff[0]);
free(lbmap_buff[0]);
free(blk_buff[1]);
free(lbmap_buff[1]);
errptr = (char *)STRERROR(save_errno);
util_out_print("Error writing block !UL : !AZ", TRUE, blk_num, errptr);
return save_errno;
}
last_blk_written = info->last_blk_cvt = blk_num;
if (BLK_BUSY == lbm_status)
busy_done++;
}
}
}
if (last_blk_written < totblks)
{ /* need to create last disk block */
memset(blk_buff[0], 0, DISK_BLOCK_SIZE);
dbptr = ((off_t)(startvbn - 1) * DISK_BLOCK_SIZE) + ((off_t)totblks * bsize);
LSEEKWRITE(info->inplace ? info->db_fd : info->outdb_fd, dbptr, blk_buff[0], DISK_BLOCK_SIZE, save_errno);
if (0 != save_errno)
{
free(blk_buff[0]);
free(lbmap_buff[0]);
free(blk_buff[1]);
free(lbmap_buff[1]);
errptr = (char *)STRERROR(save_errno);
util_out_print("Error writing last block : !AZ", TRUE, errptr);
return save_errno;
}
}
free(lbmap_buff[0]);
free(lbmap_buff[1]);
free(blk_buff[0]);
free(blk_buff[1]);
if (NULL != info->dtblk.buff)
{
free(info->dtblk.buff);
info->dtblk.buff = NULL;
info->dtblk.blkid = -1;
}
if (NULL != info->dtblk.dtrbuff)
{
free(info->dtblk.dtrbuff);
info->dtblk.dtrbuff = NULL;
}
return 0;
}
void endian_cvt_blk_hdr(blk_hdr_ptr_t blkhdr, boolean_t new_is_native, boolean_t make_empty)
{ /* convert fields in block header */
uint4 v15bsiz, v15levl, bsiz;
v15_trans_num v15tn;
trans_num tn;
unsigned short bver;
v15bsiz = blkhdr->bver;
blkhdr->bver = GTM_BYTESWAP_16(blkhdr->bver);
if (new_is_native)
v15bsiz = blkhdr->bver; /* now it is native endian */
if (SIZEOF(v15_blk_hdr) <= v15bsiz)
{ /* old format block so it must be recycled and not upgraded */
assert(FALSE); /* should have been changed to FREE above */
assert(make_empty);
v15levl = ((v15_blk_hdr *)blkhdr)->levl;
v15tn = ((v15_blk_hdr *)blkhdr)->tn;
assert(SIZEOF(char) == SIZEOF(blkhdr->levl)); /* no need to swap */
blkhdr->levl = v15levl;
bver = GDSV5;
bsiz = SIZEOF(v15_blk_hdr);
if (!new_is_native)
{
tn = ((v15_blk_hdr *)blkhdr)->tn; /* expand while native; */
blkhdr->tn = GTM_BYTESWAP_64(tn);
bsiz = GTM_BYTESWAP_32(bsiz);
bver = GTM_BYTESWAP_16(bver);
} else
{
v15tn = GTM_BYTESWAP_32(v15tn);
blkhdr->tn = v15tn; /* expand while native */
}
blkhdr->bver = bver;
blkhdr->bsiz = bsiz;
return;
}
assert(SIZEOF(char) == SIZEOF(blkhdr->levl)); /* no need to swap */
if (make_empty)
blkhdr->bsiz = new_is_native ? SIZEOF(blk_hdr) : GTM_BYTESWAP_32(SIZEOF(blk_hdr));
else
blkhdr->bsiz = GTM_BYTESWAP_32(blkhdr->bsiz);
blkhdr->tn = GTM_BYTESWAP_64(blkhdr->tn);
return;
}
char *endian_read_dbblk(endian_info *info, block_id blk_to_get)
{
off_t blkoff;
int save_errno;
boolean_t blk_is_native;
char *buff;
GTMCRYPT_ONLY(
int req_dec_blk_size;
char *inbuf;
blk_hdr_ptr_t bp;
int crypt_status;
)
if (DIR_ROOT == blk_to_get)
{
if (NULL == info->dtblk.dtrbuff)
{ /* need to really get it */
info->dtblk.dtrbuff = malloc(info->bsize);
buff = info->dtblk.dtrbuff;
} else /* already have it */
return info->dtblk.dtrbuff;
} else
{
if (NULL == info->dtblk.buff)
{
info->dtblk.buff = malloc(info->bsize);
info->dtblk.blkid = -1; /* invalid */
} else if (blk_to_get == info->dtblk.blkid)
return info->dtblk.buff; /* already have it */
buff = info->dtblk.buff;
}
blkoff = ((info->startvbn - 1) * DISK_BLOCK_SIZE) + (blk_to_get * info->bsize);
LSEEKREAD(info->db_fd, blkoff, buff, info->bsize, save_errno);
if (0 != save_errno)
{
return NULL;
}
if (info->inplace && info->last_blk_cvt >= blk_to_get)
blk_is_native = !info->endian_native; /* already converted */
else
blk_is_native = info->endian_native; /* still original endian */
if (!blk_is_native)
endian_cvt_blk_hdr((blk_hdr_ptr_t)buff, TRUE, FALSE);
# ifdef GTM_CRYPT
if (is_encrypted)
{
bp = (blk_hdr_ptr_t)buff;
assert((bp->bsiz <= info->bsize) && (bp->bsiz >= SIZEOF(*bp)));
req_dec_blk_size = MIN(info->bsize, bp->bsiz) - (SIZEOF(*bp));
if (BLOCK_REQUIRE_ENCRYPTION(is_encrypted, bp->levl, req_dec_blk_size))
{
ASSERT_ENCRYPTION_INITIALIZED;
inbuf = (char *)(bp + 1);
GTMCRYPT_DECODE_FAST(encr_key_handle, inbuf, req_dec_blk_size, NULL, crypt_status);
if (0 != crypt_status)
{
GC_GTM_PUTMSG(crypt_status, NULL);
return NULL;
}
}
}
# endif
if (DIR_ROOT == blk_to_get)
info->dtblk.dtrnative = blk_is_native;
else
{
info->dtblk.blkid = blk_to_get;
info->dtblk.native = blk_is_native;
}
return buff;
}
void endian_find_key(endian_info *info, end_gv_key *targ_gv_key, char *rec_p, int rec_len, int blk_levl)
{ /* find the key for the record and set targ_gv_key */
int cmpc;
unsigned char *targ_key;
char *rec_key;
if (BSTAR_REC_SIZE == rec_len && 0 < blk_levl)
{ /* no key for star key records */
targ_gv_key->end = 0;
return;
}
cmpc = ((rec_hdr_ptr_t)rec_p)->cmpc;
targ_key = targ_gv_key->key + cmpc;
rec_key = rec_p + SIZEOF(rec_hdr);
while (TRUE)
{
for (; *rec_key; ++targ_key, ++rec_key)
*targ_key = *rec_key;
if (0 == *(rec_key + 1))
{ /* end of key since two nulls */
*targ_key++ = 0; /* end the target key */
*targ_key = 0; /* with two as well */
targ_gv_key->end = (unsigned int)(targ_key - targ_gv_key->key);
break;
}
/* Else, copy subscript separator char and keep scanning */
*targ_key++ = *rec_key++;
assert((rec_key - rec_p) < rec_len);
}
assert(cmpc <= targ_gv_key->end);
return;
}
boolean_t endian_match_key(end_gv_key *gv_key1, int blk_levl, end_gv_key *gv_key2)
{
unsigned char *key1, *key2;
int key1_len, key2_len, key_len;
key1 = gv_key1->key;
key2 = gv_key2->key;
key1_len = gv_key1->end + 1;
if (1 == key1_len && 0 < blk_levl)
return TRUE; /* a star key record is greater than the second key */
assert(1 < key1_len);
key2_len = gv_key2->end + 1;
assert(1 < key2_len); /* should never look for star key */
key_len = MIN(key1_len, key2_len);
for (; key_len; key1++, key2++, key_len--)
{
if (*key1 != *key2)
break;
}
if ((0 == key_len && key1_len >= key2_len) || (0 != key_len && *key1 > *key2))
return TRUE;
return FALSE;
}
/* find the directory tree leaf block for a key to check if a level zero
block is in the DT or GVT. The need for this should be rare so little
attempt is made at efficiency other than caching the DT root block
since it is the start of all searches.
*/
block_id endian_find_dtblk(endian_info *info, end_gv_key *gv_key)
{
block_id blk_to_get, blk_ptr;
int save_errno, rec_len, blk_levl, ptroffset;
boolean_t blk_is_native;
char *buff, *blk_top, *rec_p;
unsigned short us_rec_len;
end_gv_key found_gv_key;
unsigned char found_gv_key_buff[MAX_KEY_SZ + 1];
info->dtblk.count++;
found_gv_key.key = found_gv_key_buff;
found_gv_key.end = found_gv_key.top = found_gv_key.gvn_len = 0;
blk_to_get = DIR_ROOT;
buff = endian_read_dbblk(info, blk_to_get); /* will use dtrbuff after first time */
if (!buff)
return -1;
blk_is_native = info->dtblk.dtrnative;
while (TRUE)
{
blk_top = buff + ((blk_hdr_ptr_t)buff)->bsiz;
blk_levl = ((blk_hdr_ptr_t)buff)->levl;
rec_p = buff + SIZEOF(blk_hdr);
while (rec_p < blk_top)
{
GET_USHORT(us_rec_len, &((rec_hdr *)rec_p)->rsiz);
if (!blk_is_native)
us_rec_len = GTM_BYTESWAP_16(us_rec_len);
rec_len = us_rec_len;
if (0 >= rec_len)
return -1;
if (0 != blk_levl && BSTAR_REC_SIZE == rec_len)
{ /* down to the next level */
GET_ULONG(blk_ptr, rec_p + SIZEOF(rec_hdr));
if (!blk_is_native)
blk_ptr = GTM_BYTESWAP_32(blk_ptr);
if (blk_ptr > info->tot_blks)
return -1; /* past end of database */
blk_to_get = blk_ptr;
break;
}
endian_find_key(info, &found_gv_key, rec_p, rec_len, blk_levl);
if (endian_match_key(&found_gv_key, blk_levl, gv_key))
{
if (0 == blk_levl)
return blk_to_get; /* found dtleaf block we are looking for */
ptroffset = found_gv_key.end - ((rec_hdr *)rec_p)->cmpc + 1;
GET_ULONG(blk_ptr, (rec_p + SIZEOF(rec_hdr) + ptroffset));
if (!blk_is_native)
blk_ptr = GTM_BYTESWAP_32(blk_ptr);
if (blk_ptr > info->tot_blks)
return -1; /* past end of database */
blk_to_get = blk_ptr;
break;
}
rec_p = rec_p + rec_len;
}
if (0 == blk_levl)
return -1; /* we didn't find what should have been there */
buff = endian_read_dbblk(info, blk_to_get);
if (!buff)
return -1;
blk_is_native = info->dtblk.native;
}
}
void endian_cvt_blk_recs(endian_info *info, char *new_block, blk_hdr_ptr_t blkhdr, int blknum)
{ /* convert records in new_block, could be data, index, or directory
use converted header fields from blkhdr which is in native format */
int rec1_len, rec1_gvn_len, rec2_cmpc, rec2_len;
int blk_levl;
rec_hdr *recp;
block_id ptr2blk, ptr2blk_swap, dtblk;
boolean_t new_is_native, have_dt_blk;
unsigned short us_rec_len, us_rec_len_swap;
unsigned char *rec1_ptr, *rec2_ptr, *blk_top, *key_top, *tmp_ptr;
boolean_t have_gvtleaf;
end_gv_key gv_key;
if (SIZEOF(v15_blk_hdr) <= blkhdr->bver)
return; /* pre V5 version so ignore records */
new_is_native = !info->endian_native;
blk_levl = blkhdr->levl;
blk_top = (unsigned char *)new_block + blkhdr->bsiz;
rec1_ptr = (unsigned char *)new_block + SIZEOF(blk_hdr);
GET_USHORT(us_rec_len, &((rec_hdr *)rec1_ptr)->rsiz);
rec1_len = new_is_native ? GTM_BYTESWAP_16(us_rec_len) : us_rec_len;
/* May not need this whole thing, just do what dump_record does
and check if block_id follows keys - but what if data is 4 chars */
/* need to check there really is a 2nd record */
rec2_ptr = rec1_ptr + rec1_len;
if (rec2_ptr < blk_top)
rec2_cmpc = ((rec_hdr *)rec2_ptr)->cmpc;
else
rec2_cmpc = -1; /* no second record */
/* Determine type of block (DT lvl 0, DT lvl !0, GVT lvl 0, GVT lvl !0)
Rules for checking (from dbcertify_scan_phase.c):
1) If compression count of 2nd record is zero, it *must* be a directory tree block. This is a fast path
check to avoid doing the strlen in the second check.
2) If compression count of second record is less than or equal to the length of the global variable name,
then this must be a directory tree block. The reason this check works is a GVT index or data block
would have same GVN in the 2nd record as the first so the compression count would be a minimum of
(length(GVN) + 1). The "+ 1" is for the terminating null of the GVN.
dbcertify only cares about too full blocks so the above rules may not apply in all other cases.
endian cvt only care about index (levl > 0), dtleaf, or gvtleaf.
*/
have_dt_blk = FALSE;
if (0 == rec2_cmpc)
have_dt_blk = TRUE;
else
{
rec1_gvn_len = STRLEN((char *)rec1_ptr + SIZEOF(rec_hdr));
if (-1 != rec2_cmpc && rec2_cmpc <= rec1_gvn_len)
have_dt_blk = TRUE;
}
if (have_dt_blk)
have_gvtleaf = FALSE; /* Could be dtleaf, dtindex, or dtroot but not gvtleaf */
else if (-1 != rec2_cmpc)
{ /* more than one record */
if (0 == blk_levl)
have_gvtleaf = TRUE; /* gdsblk_gvtleaf only sure if more than one record */
else /* ambiguous whether gvtroot or gvtindex */
have_gvtleaf = FALSE;
} else if (blk_levl)
have_gvtleaf = FALSE; /* gdsblk_gvtindex at least not leaf */
else
{ /* only one record and level is 0 */
/* if subscripts at level 0, it must be gvtleaf */
/* find key_top to check if it has four bytes of data which look like a valid pointer */
/* note dtleaf may have collation info after the pointer */
for (key_top = rec1_ptr + SIZEOF(rec_hdr); *key_top && key_top < (rec1_ptr + rec1_len); key_top++)
;
if (*++key_top)
have_gvtleaf = TRUE; /* gdsblk_gvtleaf subscript so must be */
else if (SIZEOF(block_id) <= ((rec1_ptr + rec1_len) - ++key_top) &&
(SIZEOF(block_id) + MAX_SPEC_TYPE_LEN) >= ((rec1_ptr + rec1_len) - key_top))
{ /* record value long enough for block_id but not longer than block_id plus collation information */
GET_LONG(ptr2blk, key_top);
if (new_is_native)
ptr2blk = GTM_BYTESWAP_32(ptr2blk);
if (ptr2blk <= info->tot_blks)
{ /* might be a pointer so need to check the hard way */
gv_key.key = rec1_ptr + SIZEOF(rec_hdr);
gv_key.top = gv_key.end = gv_key.gvn_len = (unsigned int)(key_top - gv_key.key - 1);
dtblk = endian_find_dtblk(info, &gv_key);
if (dtblk != blknum)
have_gvtleaf = TRUE; /* blknum is not DT level 0 */
else
have_gvtleaf = FALSE; /* DT level 0 has pointers */
} else /* points after last block so not a block_id */
have_gvtleaf = TRUE; /* gdsblk_gvtleaf should be data */
} else
have_gvtleaf = TRUE; /* gdsblk_gvtleaf too short for pointer or too long with collation info */
}
for (; rec1_ptr < blk_top; rec1_ptr += rec1_len)
{
GET_USHORT(us_rec_len, &((rec_hdr *)rec1_ptr)->rsiz);
us_rec_len_swap = GTM_BYTESWAP_16(us_rec_len);
PUT_USHORT(&((rec_hdr *)rec1_ptr)->rsiz, us_rec_len_swap);
rec1_len = new_is_native ? us_rec_len_swap : us_rec_len;
/* clear left over char after cmpc */
recp = (rec_hdr *)rec1_ptr;
tmp_ptr = &recp->cmpc + 1;
assert(SIZEOF(rec_hdr) > (tmp_ptr - rec1_ptr));
*tmp_ptr = 0;
if (!have_gvtleaf)
{ /* fix up pointers as well */
key_top = rec1_ptr + SIZEOF(rec_hdr);
if (BSTAR_REC_SIZE != rec1_len || 0 == blk_levl)
{ /* find pointer after subscripts */
for ( ; key_top < (rec1_ptr + rec1_len); )
if (!*key_top++ && !*key_top++)
break; /* 2 nulls is end of subscripts */
} else
assert((key_top + SIZEOF(block_id) == blk_top) || blk_levl); /* must be last if not leaf */
assert((key_top + SIZEOF(block_id)) <= (rec1_ptr + rec1_len));
GET_LONG(ptr2blk, key_top);
ptr2blk_swap = GTM_BYTESWAP_32(ptr2blk);
PUT_LONG(key_top, ptr2blk_swap);
#ifdef DEBUG
if (new_is_native)
ptr2blk = ptr2blk_swap;
assert(ptr2blk <= info->tot_blks);
#endif
}
}
}