Initial IBM OpenAFS 1.0 tree

[openafs.git] / src / venus / kdump.c

/*
 * Copyright (C)  1999  Transarc Corporation.  All rights reserved.
 *
 */

#ifdef __linux__
#define _CFS_HEADER_
#define _AFFS_FS_I
#define _NFS_FS_I
#define _SYSV_FS_SB
#define _AFFS_FS_SB
#define _NFS_FS_SB
#define __LINUX_UFS_FS_SB_H
#define _SYSV_FS_I
#define _LINUX_CODA_FS_I
#define _LINUX_NTFS_FS_SB_H
#define _LINUX_NTFS_FS_I_H
struct sysv_sb_info {};
struct affs_sb_info {};
struct ufs_sb_info {};
struct nfs_sb_info {};
struct nfs_inode_info {};
struct sysv_inode_info {};
struct coda_inode_info{};
struct affs_inode_info {};
struct nfs_lock_info {};
struct ntfs_sb_info{};
struct ntfs_inode_info{};
#include <linux/types.h>
#define u32 unsigned int
#define s32 int
#define u16 unsigned short
#define _SYS_TYPES_H
#define __KERNEL__
#endif

/* This tells afs.h to pick up afs_args from the dest tree. */
#define KDUMP_KERNEL

#include <afs/param.h>

#include <stdio.h>
#include <stdlib.h>     /* for malloc() */
#include <string.h>

/*
 * Need to include <netdb.h> before _KERNEL is defined since on IRIX 6.5
 * <netdb.h> includes <netinet/in.h>, which in turn declares inet_addr()
 * if _KERNEL is defined.  This declaration conflicts with that in
 * <arpa/inet.h>.
 */
#if     ! defined(AFS_AIX_ENV)
#include <netdb.h>
#endif

/* For AFS_SGI61_ENV and a 64 bit OS, _KMEMUSER should be defined on the
 * compile line for kdump.o in the Makefile. This lets us pick up
 * app32_ptr_t from types.h when included from afs/param.h.
 */
#ifdef AFS_SGI62_ENV
#define _KERNEL 1
#endif

#ifndef AFS_OSF_ENV
#include <sys/param.h>
#endif

#ifndef AFS_LINUX20_ENV
#include <nlist.h>
#endif

#ifdef AFS_HPUX_ENV
#include <a.out.h>
#endif

#include <afs/stds.h>
#include <sys/types.h>

#if defined(AFS_OSF_ENV)
#define KERNEL
#define UNIX_LOCKS
#define _KERNEL 1
#ifdef  _KERN_LOCK_H_
#include FFFFF
#endif
#include <sys/time.h>
#include <kern/lock.h>
#include <sys/vnode.h>
#include <arch/alpha/pmap.h>

/*
 * beginning with DUX 4.0A, the system header files define the macros
 *
 * KSEG_TO_PHYS()
 * IS_KSEG_VA()
 * IS_SEG1_VA()
 *
 * to be calls to the kernel functions
 *
 * kseg_to_phys()
 * is_kseg_va()
 * is_seg1_va()
 * 
 * when _KERNEL is defined, and expressions otherwise.  Since need
 * to define _KERNEL, we redefine these kernel functions as macros
 * for the expressions that we would have gotten if _KERNEL had not
 * been defined.  Yes, this duplicates code from the header files, but
 * there's no simple way around it.
 */

#define kseg_to_phys(addr) ((vm_offset_t)(addr) - UNITY_BASE)
#define is_kseg_va(x)   (((unsigned long)(x) & SEG1_BASE) == UNITY_BASE)
#define is_seg1_va(x)   (((unsigned long)(x) & SEG1_BASE) == SEG1_BASE)

#undef  KERNEL
#undef  _KERNEL
#endif

#ifdef  AFS_SUN5_ENV            /*XXXXX*/
#include <sys/t_lock.h>
struct vnode foo;
#ifdef  AFS_SUN54_ENV
#else
#ifdef  AFS_SUN52_ENV
typedef struct stat_mutex       stat_mutex_t;
#define kmutex_t                stat_mutex_t
#else
typedef struct adaptive_mutex2  adaptive_mutex2_t;
#define kmutex_t        adaptive_mutex2_t
#endif
#endif
#endif

#ifdef AFS_SGI53_ENV
#define _KERNEL 1
#include <sys/sema.h>
#ifndef AFS_SGI62_ENV
#undef _KERNEL 1
#endif
#endif

#include <sys/file.h>

#ifdef AFS_SGI62_ENV
#include <sys/fcntl.h>
#ifndef L_SET
#define L_SET 0
#endif
#endif

#include <sys/param.h>

#ifndef AFS_SGI64_ENV
#include <sys/user.h>
#endif

#ifndef AFS_LINUX20_ENV
#include <sys/socket.h>
#endif

/*
 * On SGIs, when _KERNEL is defined, <netinet/in.h> declares inet_addr()
 * in a way that conflicts with the declaration in <arpa/inet.h>.
 *
 * Here we bring in <netinet/in.h> without _KERNEL defined and restore
 * _KERNEL afterwards if needed.
 *
 * A better solution might be to straighten out which #includes are
 * sensitive to _KERNEL on SGIs....
 */
#if defined(AFS_SGI_ENV) && defined(_KERNEL)
# undef _KERNEL
# include <netinet/in.h>        /* struct in_addr */
# define _KERNEL 1
#else
# include <netinet/in.h>        /* struct in_addr */
#endif

#include <arpa/inet.h>          /* inet_ntoa() */

#if defined(AFS_SGI_ENV) || defined(AFS_OSF_ENV)
#ifdef  AFS_SGI_ENV
#include <sys/vnode.h>
#endif /* AFS_SGI_ENV */
#else
#ifdef  AFS_MACH_ENV
#include <vfs/vfs.h>
#include <vfs/vnode.h>
#include <sys/inode.h>
#else /* AFS_MACH_ENV */
#include "sys/vfs.h"
#ifdef AFS_LINUX20_ENV
#define UIO_MAXIOV 1 /* don't care */
#if __GLIBC_MINOR__ == 0
#include <iovec.h>
#endif
/*#define _TIME_H*/
/*#define _SYS_UIO_H */
#define _LINUX_SOCKET_H
#undef INT_MAX
#undef UINT_MAX
#undef LONG_MAX
#undef ULONG_MAX
#define _LINUX_TIME_H
#define _LINUX_FCNTL_H
#define _I386_STATFS_H
struct timezone {
    int a,b;
};
typedef struct timeval {
    int tv_sec;
    int tv_usec;
} timeval_t; /* Needed here since KERNEL defined. */
#define _LINUX_BYTEORDER_LITTLE_ENDIAN_H
#include <linux/version.h>
#include <linux/fs.h>
#include <afs/osi_vfs.h>
#else /* AFS_LINUX20_ENV */
#ifdef AFS_HPUX110_ENV
#define KERNEL
#define _KERNEL 1
/* Declare following so sys/vnode.h will compile with KERNEL defined */
#define FILE FILe
typedef enum _spustate {        /* FROM /etc/conf/h/_types.h */
        SPUSTATE_NONE = 0,      /* must be 0 for proper initialization */
        SPUSTATE_IDLE,          /* spu is idle */
        SPUSTATE_USER,          /* spu is in user mode */
        SPUSTATE_SYSTEM,        /* spu is in system mode */
        SPUSTATE_UNKNOWN,       /* utility code for NEW_INTERVAL() */
        SPUSTATE_NOCHANGE       /* utility code for NEW_INTERVAL() */
} spustate_t;
#define k_off_t off_t
#include "sys/vnode.h"
#undef KERNEL
#undef _KERNEL
#else  /* AFS_HPUX110_ENV */
#include "sys/vnode.h"
#endif /* else AFS_HPUX110_ENV */
#endif /* else AFS_LINUX20_ENV */
#ifdef  AFS_HPUX_ENV
#include "sys/inode.h"
#else
#ifndef AFS_AIX_ENV
#ifdef  AFS_SUN5_ENV
#include "sys/fs/ufs_inode.h"
#else
#ifndef AFS_LINUX20_ENV
#include "ufs/inode.h"
#endif
#endif
#endif
#endif
#endif /* AFS_MACH_ENV */
#include <signal.h>
#endif

/* AFS includes */
#ifdef AFS_AIX41_ENV
/* This definition is in rx_machdep.h, currently only for AIX 41 */
#define RX_ENABLE_LOCKS
/* The following two defines are from rx_machdep.h and are used in rx_
 * structures.
 */
#define afs_kmutex_t int
#define afs_kcondvar_t int
#endif /* AFS_AIX41_ENV */


#ifdef AFS_SUN5_ENV

#define RX_ENABLE_LOCKS

/**
  * Removed redefinitions of afs_kmutex_t and afs_kcondvar_t and included
  * the system header files in which they are defined
  */
#include <sys/mutex.h>
#include <sys/condvar.h>
typedef kmutex_t afs_kmutex_t;
typedef kcondvar_t afs_kcondvar_t;
#endif /* AFS_SUN5_ENV */

#ifdef AFS_DUX40_ENV
#define RX_ENABLE_LOCKS
typedef struct {
     unsigned long lock;
     void *owner;
} afs_kmutex_t;
typedef int afs_kcondvar_t;
#endif /* AFS_DUX40_ENV */

#ifdef AFS_HPUX110_ENV
#define RX_ENABLE_LOCKS
typedef struct {
        void  *s_lock;
        int     count;
        long sa_fill1;
        void *wait_list;
        void *sa_fill2[2];
        int sa_fill2b[2];
        long  sa_fill2c[3];
        int sa_fill2d[16];
        int order;
        int sa_fill3;
} afs_kmutex_t;
typedef char *afs_kcondvar_t;
#endif /* AFS_HPUX110_ENV */

#ifdef AFS_SGI65_ENV
#define RX_ENABLE_LOCKS 1
typedef struct {
    __psunsigned_t opaque1;
    void *opaque2;
} afs_kmutex_t;
typedef struct {
    __psunsigned_t opaque;
} afs_kcondvar_t;
#endif /* AFS_SGI65_ENV */

#ifdef AFS_LINUX20_ENV
#include <asm/atomic.h>
#include <asm/semaphore.h>
#define RX_ENABLE_LOCKS 1
typedef struct {
    struct semaphore opaque1;
    int opaque2;
} afs_kmutex_t;
typedef void *afs_kcondvar_t;
#endif /* AFS_LINUX20_ENV */

#include <afs/exporter.h>
#include <afs/nfsclient.h>
/*#include "afs/osi.h"*/

typedef struct {
    int tv_sec;
    int tv_usec;
} osi_timeval_t; /* Needed here since KERNEL defined. */

/*#include "afs/volerrors.h"*/
#ifdef AFS_LINUX20_ENV
#define _SYS_TIME_H
#endif

#include <afs/afsint.h>
#include "../vlserver/vldbint.h"
#include "../afs/lock.h"

#define KERNEL

#ifndef notdef
#define AFS34
#define AFS33
#define AFS32a
#else
#define AFS32
#endif


#ifdef AFS_SGI61_ENV
extern off64_t lseek64();
#define KDUMP_SIZE_T size_t
#else /* AFS_SGI61_ENV */
#define KDUMP_SIZE_T int
#endif /* AFS_SGI61_ENV */

#include "../afs/afs.h"         /* XXXX Getting it from the obj tree XXX */
#include "../afs/afs_axscache.h" /* XXXX Getting it from the obj tree XXX */
#include <afs/afs_stats.h>

#include <afs/cmd.h>
#include <rx/rx.h>


#undef  KERNEL

#if defined(AFS_OSF_ENV) && !defined(v_count)
#define v_count         v_usecount
#endif

#ifdef  AFS_OSF_ENV
#define KERNELBASE      0x80000000
#define coreadj(x)      ((int)x - KERNELBASE)
#endif

#if defined(AFS_SGI_ENV)
#define UNIX "/unix"
#else
#if     defined(AFS_HPUX100_ENV)
#define UNIX "/stand/vmunix"
#else
#ifdef  AFS_HPUX_ENV
#define UNIX  "/hp-ux"
#else
#ifdef  AFS_SUN5_ENV
#define UNIX  "/dev/ksyms"
#else
#define UNIX  "/vmunix"
#endif
#endif  /* AFS_HPUX_ENV */
#endif  /* AFS_HPUX100_ENV */
#endif  /* AFS_SGI_ENV */

#if     defined(AFS_SUN5_ENV)
#define CORE "/dev/mem"
#else
#define CORE "/dev/kmem"
#endif

/* Forward declarations */
void print_Conns();
void print_cbHash();
void print_DindexTimes();
void print_DdvnextTbl();
void print_DdcnextTbl();
void print_DindexFlags();
void print_buffers();
void print_allocs();
void kread(int kmem,off_t loc,void *buf,KDUMP_SIZE_T len);
void print_exporter();
void print_nfsclient();
void print_unixuser();
void print_cell();
void print_server();
void print_conns();
void print_conn();
void print_volume();
void print_venusfid();
void print_vnode();
void print_vcache();
void print_dcache();
void print_bkg();
void print_vlru();
void print_dlru();
void print_callout();
void print_dnlc();
void print_global_locks();
void print_global_afs_resource();
void print_global_afs_cache();
void print_rxstats();
void print_rx();
void print_services();
#ifdef KDUMP_RX_LOCK
void print_peertable_lock();
void print_conntable_lock();
void print_calltable_lock();
#endif
void print_peertable();
void print_conntable();
void print_calltable();
void print_eventtable();
void print_upDownStats();
void print_cmperfstats();
void print_cmstats();




#ifndef AFS_KDUMP_LIB
extern struct cmd_syndesc *cmd_CreateSyntax();
#endif
extern int errno;
int opencore();

/* Note: this should agree with the definition in afs_buffer.c */
#if     defined(AFS_OSF_ENV)
#define AFS_USEBUFFERS  1
#endif

struct buffer {
#ifdef AFS_SGI62_ENV
    ino64_t fid[1];
#else
    afs_int32 fid[1];
#endif
    afs_int32 page;
    afs_int32 accesstime;
    struct buffer *hashNext;
    char *data;
    char lockers;
    char b_dirty;
    char hashIndex;
#if AFS_USEBUFFERS
    struct buf *bufp;
#endif
    afs_rwlock_t lock;          /* the lock for this structure */
};


#if     defined(AFS_HPUX_ENV) && defined(__LP64__)
#define afs_nlist nlist64
#define AFSNLIST(N, C) nlist64((N), (C))
#else   /* defined(AFS_HPUX_ENV) && defined(__LP64__) */
#ifdef AFS_SGI61_ENV
#ifdef AFS_32BIT_KERNEL_ENV
#define afs_nlist nlist
#define AFSNLIST(N, C) nlist((N), (C))
#else
#define afs_nlist nlist64
#define AFSNLIST(N, C) nlist64((N), (C))
#endif /* AFS_32BIT_KERNEL_ENV */
#else /* AFS_SGI61_ENV */
#ifdef AFS_LINUX20_ENV
struct afs_nlist {
    char *n_name;
    unsigned long n_value;
};
#else /* AFS_LINUX20_ENV */
#define afs_nlist nlist
#endif /* AFS_LINUX20_ENV */
#define AFSNLIST(N, C) nlist((N), (C))
#endif /* AFS_SGI61_ENV */
#endif  /* defined(AFS_HPUX_ENV) && defined(__LP64__) */

char *obj = UNIX, *core = CORE;
int kmem;

int Dcells = 0, Dusers = 0, Dservers = 0, Dconns = 0, Dvols = 0, Ddvols = 0, mem = 0;
int Dvstats = 0, Ddstats = 0, Dnfs = 0, Dglobals = 0, Dstats = 0, Dlocks = 0, Dall = 1;
int Dindextimes = 0, Dindexflags = 0, Dvnodes = 0, Dbuffers=0, DCallbacks = 0, Dallocs=0, UserLevel=0;
int DdvnextTbl = 0, DdcnextTbl = 0;
int Nconns = 0, Drxstats = 0, Drx = 0, Dbkg=0, Dvlru=0, Ddlru=0, Dcallout=0;
int Ddnlc = 0;
int Dgcpags = 0;

#if     defined(AFS_SUN5_ENV)
#include <string.h>
#include <sys/types.h>
#include <sys/signal.h>
#include <sys/elf.h>
#include <libelf.h>
#include <sys/elf_M32.h>
#ifndef AFS_SUN54_ENV
typedef ulong_t k_fltset_t;             /* XXXXXXXXXXX */
#endif  /* !AFS_SUN54_ENV */
#include <sys/proc.h>
#include <sys/file.h>
#define _NLIST_H                        /* XXXXXXXXXXXXX */
#include <kvm.h>
kvm_t *kd;
#endif  /* defined(AFS_SUN5_ENV) */

/* Pretty Printers - print real IP addresses and the like if running
 * in interpret_mode.
 */
int pretty = 1;

char *PrintIPAddr(int addr)
{
    static char str[32];
    struct in_addr in_addr;

    if (pretty) {
       if (addr == 1) {
          strcpy(str, "local");
       } else {
          in_addr.s_addr = addr;
          (void) strcpy(str, inet_ntoa(in_addr));
       }
    } else {
       (void) sprintf(str, "%x", addr);
    }
    return (char*)str;
}

#ifdef AFS_LINUX20_ENV
/* Find symbols in a live kernel. */
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

#define KSYMS "/proc/ksyms"

/* symlist_t contains all the kernel symbols. Forcing a 64 byte array is
 * a bit wasteful, but simple.
 */
#define MAXNAMELEN 64
typedef struct symlist {
    char s_name[MAXNAMELEN];
    int s_value;
} symlist_t;

#define KSYM_ALLOC_STEP 128
#define KSYM_ALLOC_BASE 1024
symlist_t *ksyms = NULL;
int nksyms = 0;
int availksyms = 0;

#define MAXLINE 1024

int compare_strings(const void *a, const void *b)
{
    symlist_t *syma = (symlist_t*)a;
    symlist_t *symb = (symlist_t*)b;
    return strcmp(syma->s_name, symb->s_name);
}

/* Read in all the kernel symbols */
void read_ksyms(void)
{
    FILE *fp;
    char line[MAXLINE];
    char *p, *q;

    if (ksyms)
        return;

    fp = fopen(KSYMS, "r");
    if (fp == NULL) {
        printf("Can't open %s, exiting.\n", KSYMS);
        exit(1);
    }

    availksyms = KSYM_ALLOC_BASE;
    ksyms = (symlist_t*)malloc(availksyms * sizeof(symlist_t));
    if (!ksyms) {
        printf("Can't malloc %d elements for symbol list.\n", availksyms);
        exit(1);
    }

    /* proc is organized as <addr> <name> <module> */
    while (fgets(line, MAXLINE, fp)) {
        if (nksyms >= availksyms) {
            availksyms += KSYM_ALLOC_STEP;
            ksyms = (symlist_t*)realloc(ksyms, availksyms * sizeof(symlist_t));
            if (!ksyms) {
                printf("Failed to realloc %d symbols.\n", availksyms);
                exit(1);
            }
        }
        ksyms[nksyms].s_value = (int)strtoul(line, &p, 16);
        p++;
        q = strchr(p, '\t');
        if (q) *q = '\0';
        if (strlen(p) >= MAXLINE) {
            printf("Symbol '%s' too long, ignoring it.\n", p);
            continue;
        }
        (void) strcpy(ksyms[nksyms].s_name, p);
        nksyms++;
    }

    /* Sort them in lexical order */
    qsort(ksyms, nksyms, sizeof(symlist_t), compare_strings);
} 



/* find_symbol returns 0 if not found, otherwise value for symbol */
int find_symbol(char *name)
{
    symlist_t *tmp;
    symlist_t entry;

    if (!ksyms)
        read_ksyms();

    (void) strcpy(entry.s_name, name);
    tmp = (symlist_t*)bsearch(&entry, ksyms, nksyms, sizeof(symlist_t),
                              compare_strings);

    return tmp ? tmp->s_value : 0;
}

/* nlist fills in values in list until a null name is found. */
int nlist(void *notused, struct afs_nlist *nlp)
{
    for ( ; nlp->n_name && *nlp->n_name; nlp++)
        nlp->n_value = find_symbol(nlp->n_name);

    return 0;
}

#endif

#if     defined(AFS_SUN5_ENV)
#ifdef  _LP64
Elf64_Sym       *tbl;
#else
Elf32_Sym       *tbl;   /* symbol tbl */
#endif
char *tblp;     /* ptr to symbol tbl */
int scnt = 0;

#ifdef  _LP64
Elf64_Sym *symsrch(s)
    char *s;
{
    Elf64_Sym *sp;
#else
Elf32_Sym *symsrch(s)
    char *s;
{
    Elf32_Sym *sp;
#endif  /** _LP64 **/
    char *name;
    unsigned char type;

    for (sp = tbl; sp < &tbl[scnt]; sp++) {
#ifdef _LP64
        type = ELF64_ST_TYPE(sp->st_info);
#else
        type = ELF32_ST_TYPE(sp->st_info);
#endif  /** _LP64 **/
        if (((type == STB_LOCAL) || (type == STB_GLOBAL) ||
             (type == STB_WEAK)) && ((afs_uint32)sp->st_value >= 0x10000)) {
            name = tblp + sp->st_name;
            if (!strcmp(name, s)) 
                return (sp);
        }
    }
    return (0);
}

#endif  /*defined(AFS_SUN5_ENV)*/


#ifndef AFS_KDUMP_LIB
static cmdproc(as, arock)
register struct cmd_syndesc *as;
afs_int32 arock; {
    register afs_int32 code = 0;

    if (as->parms[0].items) { /* -kobj */
        obj = as->parms[0].items->data;
    } 
    if (as->parms[1].items) { /* -kcore */
        core = as->parms[1].items->data;
    } 
    if (as->parms[2].items) { /* -cells */
        Dcells = 1, Dall = 0;
    } 
    if (as->parms[3].items) { /* -users */
        Dusers = 1, Dall = 0;
    } 
    if (as->parms[4].items) { /* -servers */
        Dservers = 1, Dall = 0;
    } 
    if (as->parms[5].items) { /* -conns */
        Dconns = 1, Dall = 0;
    } 
    if (as->parms[6].items) { /* -volumes */
        Dvols = 1, Dall = 0;
    } 
    if (as->parms[7].items) { /* -dvolumes */
        Ddvols = 1, Dall = 0;
    } 
    if (as->parms[8].items) { /* -vstats */
        Dvstats = 1, Dall = 0;
    } 
    if (as->parms[9].items) { /* -dstats */
        Ddstats = 1, Dall = 0;
    } 
    if (as->parms[10].items) { /* -nfstats */
        Dnfs = 1, Dall = 0;
    } 
    if (as->parms[11].items) { /* -globals */
        Dglobals = 1, Dall = 0;
    } 
    if (as->parms[12].items) { /* -stats */
        Dstats = 1, Dall = 0;
    } 
    if (as->parms[13].items) { /* -locks */
        Dlocks = 1, Dall = 0;
    } 
    if (as->parms[14].items) { /* -mem */
        mem = 1;
    } 
    if (as->parms[15].items) { /* -rxstats */
        Drxstats = 1, Dall = 0;
    } 
    if (as->parms[16].items) { /* -rx */
        Drx = 1, Dall = 0;
    } 
    if (as->parms[17].items) { /* -timestable */
        Dindextimes = 1, Dall = 0;
    } 
    if (as->parms[18].items) { /* -flagstable */
        Dindexflags = 1, Dall = 0;
    } 
    if (as->parms[19].items) { /* -cbhash */
        DCallbacks = 1, Dall = 0;
    } 
    if (as->parms[20].items) { /* -vnodes */
        Dvnodes = 1, Dall = 0;
    } 
    if (as->parms[21].items) { /* -buffers */
        Dbuffers = 1, Dall = 0;
    } 
    if (as->parms[22].items) { /* -allocedmem */
        Dallocs = 1, Dall = 0;
    } 
    if (as->parms[23].items) { /* -user */
        UserLevel = 1;
    } 
    if (as->parms[24].items) { /* -bkg */
        Dbkg = 1, Dall = 0;
    } 
    if (as->parms[25].items) { /* -vlru */
        Dvlru = 1, Dall = 0;
    } 
    if (as->parms[26].items) { /* -callout */
        Dcallout = 1, Dall = 0;
    } 
    if (as->parms[27].items) { /* -dnlc */
        Ddnlc = 1, Dall = 0;
    } 
    if (as->parms[28].items) { /* -dlru */
        Ddlru = 1, Dall = 0;
    }

    if (as->parms[29].items) { /* -raw */
        pretty = 0;
    }

    if (as->parms[30].items) { /* -gcpags */
        Dgcpags = 1, Dall = 0;
    }

    if (as->parms[31].items) { /* -dhash */
        DdvnextTbl = 1, DdcnextTbl = 1, Dall = 0;
    }

    code = kdump();
    return code;
}

#include "AFS_component_version_number.c"

main(argc, argv)
int argc;
char **argv; {
    register struct cmd_syndesc *ts;
    register afs_int32 code;

#ifdef  AFS_AIX32_ENV
    struct sigaction nsa;
    
    sigemptyset(&nsa.sa_mask);
    nsa.sa_handler = SIG_DFL;
    nsa.sa_flags = SA_FULLDUMP;
    sigaction(SIGSEGV, &nsa, NULL);
#endif

    ts = cmd_CreateSyntax((char *) 0, cmdproc, 0, "Read internal cache manager structs");
    cmd_AddParm(ts, "-kobj", CMD_SINGLE, CMD_OPTIONAL, "kernel object (default /vmunix)");
    cmd_AddParm(ts, "-kcore", CMD_SINGLE, CMD_OPTIONAL, "kernel core image (default /dev/kmem)");
    cmd_AddParm(ts, "-cells", CMD_FLAG, CMD_OPTIONAL, "cell state");
    cmd_AddParm(ts, "-users", CMD_FLAG, CMD_OPTIONAL, "users state");
    cmd_AddParm(ts, "-servers", CMD_FLAG, CMD_OPTIONAL, "servers state");
    cmd_AddParm(ts, "-conns", CMD_FLAG, CMD_OPTIONAL, "conns state");
    cmd_AddParm(ts, "-volumes", CMD_FLAG, CMD_OPTIONAL, "incore volume state");
    cmd_AddParm(ts, "-dvolumes", CMD_FLAG, CMD_OPTIONAL, "disk volume state");
    cmd_AddParm(ts, "-vstats", CMD_FLAG, CMD_OPTIONAL, "stat file state");
    cmd_AddParm(ts, "-dstats", CMD_FLAG, CMD_OPTIONAL, "file data state");
    cmd_AddParm(ts, "-nfstats", CMD_FLAG, CMD_OPTIONAL, "nfs translator state");
    cmd_AddParm(ts, "-globals", CMD_FLAG, CMD_OPTIONAL, "general global state");
    cmd_AddParm(ts, "-stats", CMD_FLAG, CMD_OPTIONAL, "general cm performance state");
    cmd_AddParm(ts, "-locks", CMD_FLAG, CMD_OPTIONAL, "global cm related locks state");
    cmd_AddParm(ts, "-mem", CMD_FLAG, CMD_OPTIONAL, "core represents the physical mem (i.e. /dev/mem) and not virtual");
    cmd_AddParm(ts, "-rxstats", CMD_FLAG, CMD_OPTIONAL, "general rx statistics");
    cmd_AddParm(ts, "-rx", CMD_FLAG, CMD_OPTIONAL, "all info about rx");
    cmd_AddParm(ts, "-timestable", CMD_FLAG, CMD_OPTIONAL, "dcache LRU info table");
    cmd_AddParm(ts, "-flagstable", CMD_FLAG, CMD_OPTIONAL, "dcache flags info table");
    cmd_AddParm(ts, "-cbhash", CMD_FLAG, CMD_OPTIONAL, "vcache hashed by cbExpires");
    cmd_AddParm(ts, "-vnodes", CMD_FLAG, CMD_OPTIONAL, "afs vnodes");
    cmd_AddParm(ts, "-buffers", CMD_FLAG, CMD_OPTIONAL, "afs dir buffer cache");
    cmd_AddParm(ts, "-allocedmem", CMD_FLAG, CMD_OPTIONAL, "allocated memory");
    cmd_AddParm(ts, "-user", CMD_FLAG, CMD_OPTIONAL, "core is from a user-level program");
    cmd_AddParm(ts, "-bkg", CMD_FLAG, CMD_OPTIONAL, "background daemon info");
    cmd_AddParm(ts, "-vlru", CMD_FLAG, CMD_OPTIONAL, "vcache lru list");
    cmd_AddParm(ts, "-callout", CMD_FLAG, CMD_OPTIONAL, "callout info (aix only)");
    cmd_AddParm(ts, "-dnlc", CMD_FLAG, CMD_OPTIONAL, "DNLC table,freelist,trace");
    cmd_AddParm(ts, "-dlru", CMD_FLAG, CMD_OPTIONAL, "dcache lru list");


    cmd_AddParm(ts, "-raw", CMD_FLAG, CMD_OPTIONAL, "show raw values");
    cmd_AddParm(ts, "-gcpags", CMD_FLAG, CMD_OPTIONAL, "PAG garbage collection info");
    cmd_AddParm(ts, "-dhash", CMD_FLAG, CMD_OPTIONAL, "show dcache hash chains");

    code = cmd_Dispatch(argc, argv);
    return code;
}
#endif /* !AFS_KDUMP_LIB */

#ifdef  AFS_AIX_ENV
#ifndef AFS_KDUMP_LIB
Knlist(sp, cnt, size) 
struct afs_nlist *sp;
int cnt, size;
{
    register int code;

    if (UserLevel)
        code = nlist(obj, sp);
    else
        code = knlist(sp, cnt, size);
    return code;
}
#endif /*AFS_KDUMP_LIB */
#endif

int
findsym( char *sname, off_t *offset )
{
#if     defined(AFS_SUN5_ENV)
#ifdef  _LP64
        Elf64_Sym *ss_ans;
#else
        Elf32_Sym *ss_ans;
#endif
        ss_ans = symsrch(sname);
        if (!ss_ans) {
            printf("(WARNING) Couldn't find %s in %s. Proceeding..\n",
                    sname, obj);
            *offset = 0;
            return 0;
        }
        *offset = ss_ans->st_value;
        return 1;
#else   /* defined(AFS_SUN5_ENV) */
#if     defined(AFS_AIX_ENV)
        if (!UserLevel) {
            struct afs_nlist nl;
            nl.n_name = sname;
            if (Knlist(&nl, 1, sizeof nl) == -1 ) {
                printf("(WARNING) knlist: couldn't find %s. Proceeding...",
                        sname); 
                *offset = 0;
                return 0;
            }
            *offset = nl.n_value;
            return 1;
        }
#endif  /* defined(AFS_AIX_ENV) */
        {
            struct afs_nlist request[2];

            memset(request, 0, sizeof request);
            request[0].n_name = sname;
            if (AFSNLIST(obj, request) < 0) {
                fprintf(stderr, "nlist(%s, %s) failure: %d (%s)\n",
                        obj, sname,
                        errno, strerror(errno));
                exit(1);
            }

#if     defined(AFS_OSF_ENV)
            if (mem) {
                long X;

                X = coreadj(request[0].n_value);
                request[0].n_value = X;
            }
#endif  /* defined(AFS_OSF_ENV) */

            *offset = request[0].n_value;           
            if (!request[0].n_value) {
                printf("(WARNING) Couldn't find %s in %s. Proceeding..\n",
                        sname, obj);
                return 0;
            }
            return 1;
        }
#endif  /* defined(AFS_SUN5_ENV) */
}

#define CBHTSIZE 128

kdump()
{
    int cell, cnt, cnt1;
#ifndef AFS_KDUMP_LIB

    kmem = opencore(core);

#endif /* AFS_KDUMP_LIB */

#ifdef KDUMP_RX_LOCK
    /* Test to see if kernel is using RX_ENABLE_LOCKS in rx structs. */
#ifdef AFS_SGI53_ENV
#ifdef AFS_SGI64_ENV
    use_rx_lock = 1; /* Always using fine gain locking. */
#else
    use_rx_lock = (sysmp(MP_NPROCS) > 1) ? 1 : 0;
#endif
#endif /* AFS_SGI53_ENV */
#endif /* KDUMP_RX_LOCK */

    if (Dcells || Dall) {
        print_cells(1); /* Handle the afs_cells structures */
    }

    if (Dusers || Dall) {
        print_users(1); /* Handle the afs_users structs */
    }   

    if (Dservers || Dall) {
        print_servers(1);/* Handle the afs_servers structs */
    }

    if (Dconns) {
        print_Conns(1); /* Handle the afs_servers structs */
    }

    if (Dvols || Dall) {
        print_volumes(1);       /* Handle the afs_volumes structs */
    }

    if (Ddvols || Dall) {
        printf("\n\nIGNORE reading the 'volumeinfo' file for now (NOT IMPORTANT)!\n");
    }

    if (DCallbacks || Dall) {
        print_cbHash(1);      /* Handle the cbHashT table of queued vcaches */
    }

    if (Dvstats || Dall || Dvnodes) {
        print_vcaches(1);       /* Handle the afs_vcaches structs */
    }

    if (Ddstats || Dall) {
        print_dcaches(1);
    }

    if (Dindextimes || Dall) {
        print_DindexTimes(1);   
    }

    if (Dindexflags || Dall) {
        print_DindexFlags(1);   
    }

    if (DdvnextTbl || Dall) {
        print_DdvnextTbl(1);    
    }

    if (DdcnextTbl || Dall) {
        print_DdcnextTbl(1);    
    }

    if (Dbuffers || Dall) {
        print_buffers(1);
    }

    if (Dnfs || Dall) {
        print_nfss(1);
    }

    if (Dstats || Dall) {
        off_t symoff;
        struct afs_CMStats afs_cmstats;
        struct afs_stats_CMPerf afs_cmperfstats;

        printf("\n\nPrinting count references to cm-related functions..\n\n");
        findsym( "afs_cmstats", &symoff);
        kread(kmem, symoff, (char *) &afs_cmstats, sizeof afs_cmstats);
        print_cmstats(&afs_cmstats);
        printf("\n\nPrinting some cm struct performance stats..\n\n");
        findsym( "afs_stats_cmperf", &symoff);
        kread(kmem, symoff, (char *) &afs_cmperfstats, sizeof afs_cmperfstats);
        print_cmperfstats(&afs_cmperfstats);

    }
    if (Dlocks || Dall) {
        print_global_locks(kmem);
    }
    if (Dglobals || Dall) {
        printf("\n\nPrinting Misc afs globals...\n");
        print_global_afs_resource(kmem);
        print_global_afs_cache(kmem);
    }
    if (Dbkg || Dall) {
        print_bkg(kmem);
    }
    if (Dvlru || Dall) {
        print_vlru(kmem);
    }
    if (Ddlru || Dall) {
        print_dlru(kmem);
    }
    if (Drxstats || Dall) {
        print_rxstats(kmem);
    }    
    if (Drx || Dall) {
        print_rx(kmem);
    }
#ifndef AFS_KDUMP_LIB
    if (Dallocs || Dall) {
        print_allocs(1);
    }
#endif
    if (Dcallout || Dall) {
        print_callout(kmem);
    }
    if (Ddnlc || Dall) {
        print_dnlc(kmem);
    }
    if (Dgcpags || Dall) {
        print_gcpags(1);
    }
    return 0;
}

int Sum_cellnames=0, Sum_userstp=0, Sum_volnames=0, Sum_exps=0, Sum_nfssysnames=0;
int Sum_vcachemvids=0, Sum_vcachelinkData=0, Sum_vcacheacc=0, Sum_vcachelocks=0;

int print_cells(pnt)
int pnt;
{
    off_t symoff;
    struct cell *cells, cle, *clentry = &cle, *clep; 
    long j=0, cell;
    struct afs_q CellLRU, lru, *vu = &lru, *tq, *uq;
    u_long lru_addr;

    if (pnt) printf("\n\nPrinting Cells' LRU list...\n");
    findsym( "CellLRU", &symoff);
    kread(kmem, symoff, (char *) &CellLRU, sizeof CellLRU);
    lru_addr = (u_long)symoff;
    for (tq = CellLRU.next; (u_long)tq != lru_addr; tq = uq) {
        clep = QTOC(tq);
        kread(kmem, (off_t)tq, (char *)vu, sizeof CellLRU);
        uq = vu->next;
        kread(kmem, (off_t)clep, (char *) clentry, sizeof *clentry);
        print_cell(kmem, clentry, clep, pnt);
        j++;
    }
    if (pnt) printf("... found %d 'afs_cells' entries\n", j);
    return j;
}

int print_users(pnt)
int pnt;
{
    off_t symoff;
    struct unixuser *afs_users[NUSERS], ue,*uentry= &ue, *uep;
    int i, j;

    if (pnt) printf("\n\nPrinting 'afs_users' structures...\n");
    findsym( "afs_users", &symoff);
    kread(kmem, symoff, (char *) afs_users, sizeof afs_users);
    for (i=0,j=0; i < NUSERS; i++) {
        for (uep = afs_users[i]; uep; uep = uentry->next, j++) {
            kread(kmem, (off_t) uep, (char *)uentry, sizeof *uentry);
            print_unixuser(kmem, uentry, uep, pnt);
        }
    }
    if (pnt) printf("... found %d 'afs_users' entries\n", j);
    return j;
}

struct server **serversFound = NULL;
afs_int32 NserversFound = 0;
#define SF_ALLOCATION_STEP 500

int add_found_server(sep)
struct server *sep;
{
    static afs_int32 NserversAllocated = 0;
    static afs_int32 failed = 0;

    if (failed)
        return -1;

    if (NserversFound >= NserversAllocated) {
        NserversAllocated += SF_ALLOCATION_STEP;
        if (!serversFound) {
            serversFound =
                (struct server **)malloc(NserversAllocated
                                        * sizeof(struct server *));
        } else {
            serversFound =
                (struct server **)realloc((char*)serversFound,
                                         NserversAllocated
                                         * sizeof(struct server *));
        }
        if (!serversFound) {
            printf("Can't allocate %lu bytes for list of found servers.\n",
                NserversAllocated *  sizeof(struct server *));  
            failed = 1;
            NserversFound = 0;
            return -1;
        }
    }
    serversFound[NserversFound++] = sep;
    return 0;
}

int find_server(sep)
struct server *sep;
{
    int i;

    for (i=0; i<NserversFound; i++) {
        if (sep == serversFound[i])
            return 1;
    }
    return 0;
}
        
int print_servers(pnt)
int pnt;
{
    off_t symoff;
    struct server *afs_servers[NSERVERS], se, *sentry = &se, *sep;
    struct srvAddr *afs_srvAddrs[NSERVERS], sa, *sap;
    afs_int32 i, nServers, nSrvAddrs, nSrvAddrStructs;
    afs_int32 afs_totalServers, afs_totalSrvAddrs;
    int failed = 0;
    int chainCount[NSERVERS];

    if (pnt) {
        bzero((char*)chainCount, sizeof(chainCount));
        printf("\n\nPrinting 'afs_servers' structures...\n");
    }
    findsym( "afs_servers", &symoff);
    kread(kmem, symoff, (char *) afs_servers, NSERVERS * sizeof(long));
    for (i=0, nServers=0; i < NSERVERS; i++) {
        if (pnt)
            printf(" --- Chain %d ---\n", i);
        for (sep = afs_servers[i]; sep; sep = sentry->next, nServers++) {
            kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
            if (pnt && !failed) {
                if (add_found_server(sep)<0)
                    failed = 1;
            }
            if (pnt)
                chainCount[i]++;
            if (Dconns || Dall || !pnt)
                print_server(kmem, sentry, sep, 1, pnt);
            else
                print_server(kmem, sentry, sep, 0, pnt);
        }
    }
    if (pnt) {
        if (Dconns || Dall)
            printf("... found %d 'afs_servers' entries (total conns = %d)\n",
                   nServers, Nconns);
        else
            printf("... found %d 'afs_servers' entries\n", nServers);
        printf("Chain lengths:\n");
        for (i=0; i<NSERVERS; i++) {
            printf("%2d: %5d\n", i, chainCount[i]);
        }
    }
    Dconns = 0;


    /* Verify against afs_totalServers. */
    if (pnt) {
        bzero((char*)chainCount, sizeof(chainCount));
        if (findsym( "afs_totalServers", &symoff)) {
            kread(kmem, symoff, (char*)&afs_totalServers, sizeof(afs_int32));
            if (afs_totalServers != nServers) {
                printf("ERROR: afs_totalServers = %d, differs from # of servers in hash table.\n", afs_totalServers);
            }
            else {
                printf("afs_totalServers = %d, matches hash chain count.\n", afs_totalServers);
            }
        }
        
        printf("\n\nPrinting 'afs_srvAddr' structures...\n");
        if (findsym( "afs_srvAddrs", &symoff)) {
            kread(kmem, symoff, (char *) afs_srvAddrs,
                  NSERVERS * sizeof(long));
            nSrvAddrStructs = 0;
            for (i=0, nSrvAddrs=0; i < NSERVERS; i++) {
                printf(" --- Chain %d ---\n", i);
                for (sap = afs_srvAddrs[i]; sap; sap = sa.next_bkt) {
                    kread(kmem, (off_t) sap, (char *)&sa,
                          sizeof(sa));
                    printf("%lx: sa_ip=%s, sa_port=%d, sa_iprank=%d, sa_flags=%x, conns=%lx, server=%lx, nexth=%lx\n",
                           sap, PrintIPAddr(sa.sa_ip), sa.sa_portal, sa.sa_iprank,
                           sa.sa_flags, sa.conns, sa.server, sa.next_bkt);
                    if (sap != (struct srvAddr*)sa.server) {
                        /* only count ones not in a server struct. */
                        nSrvAddrStructs ++;
                    }
                    nSrvAddrs ++;
                    chainCount[i]++;
                    if (!failed) {
                        if (!find_server(sa.server)) {
                            kread(kmem, (off_t)sa.server, (char *)sentry,
                                  sizeof *sentry);
                            printf("ERROR: Server missing from hash chain: server=%lx, server->next=%lx\n",
                                   sa.server, sentry->next);
                            print_server(kmem, sentry, sa.server, 1, pnt);
                            printf("----------------------------------------------------\n");
                        }
                    }

                }
            }
            printf("... found %d 'afs_srvAddr' entries, %d alloc'd (not in server struct)\n",
                   nSrvAddrs, nSrvAddrStructs);
            printf("Chain lengths:\n");
            for (i=0; i<NSERVERS; i++) {
                printf("%2d: %5d\n", i, chainCount[i]);
            }
            if (findsym( "afs_totalSrvAddrs", &symoff)) {
                kread(kmem, symoff, (char*)&afs_totalSrvAddrs, sizeof(afs_int32));
                if (afs_totalSrvAddrs != nSrvAddrStructs) {
                    printf("ERROR: afs_totalSrvAddrs = %d, differs from number of alloc'd srvAddrs in hash table.\n", afs_totalSrvAddrs);
                }
                else {
                    printf("afs_totalSrvAddrs = %d, matches alloc'd srvAddrs in hash chain count.\n", afs_totalSrvAddrs);
                }
            }
        }
    }
    return nServers;
}


void
print_Conns(pnt)
int pnt;
{
    off_t symoff;
    struct server *afs_servers[NSERVERS], se, *sentry = &se, *sep;
    afs_int32 i, j;

    if (pnt) printf("\n\nPrinting all 'afs_conns' to  the servers...\n");
    findsym( "afs_servers", &symoff);
    kread(kmem, symoff, (char *) afs_servers, sizeof afs_servers);
    for (i=0, j=0; i < NSERVERS; i++) {
        for (sep = afs_servers[i]; sep; sep = sentry->next, j++) {
            kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
            print_server(kmem, sentry, sep, 2, pnt);
        }
    }
    if (pnt) printf("... found %d 'afs_conns' entries\n", Nconns);
}


int print_volumes(pnt)
int pnt;
{
    off_t symoff;
    struct volume *afs_volumes[NVOLS], ve, *ventry = &ve, *vep;
    afs_int32 i, j;

    if (pnt) printf("\n\nPrinting 'afs_volumes' structures...\n");
    findsym( "afs_volumes", &symoff);
    kread(kmem, symoff, (char *) afs_volumes, NVOLS * sizeof(long));
    for (i=0, j=0; i < NVOLS; i++) {
        for (vep = afs_volumes[i]; vep; vep = ventry->next, j++) {
            kread(kmem, (off_t) vep, (char *)ventry, sizeof *ventry);
            print_volume(kmem, ventry, vep, pnt);
        }
    }
    if (pnt) printf("... found %d 'afs_volumes' entries\n", j);
    return (j);
}

void print_cbHash(pnt)
int pnt;
{
    off_t symoff;
    struct afs_q cbHashT[CBHTSIZE];
    afs_int32 i, j;

    if (pnt) printf("\n\nPrinting 'cbHashT' table...\n");
    findsym( "cbHashT", &symoff);
    kread(kmem, symoff, (char *) cbHashT, sizeof cbHashT);
    for (i=0; i < CBHTSIZE; i++) {
        if (pnt) printf("%lx: %x %x\n", (long)symoff+8*i, cbHashT[i].prev, cbHashT[i].next);
    }
    if (pnt) printf("... that should be %d callback hash entries\n", i);
}

int print_vcaches(pnt)
int pnt;
{
    off_t symoff;
    struct vcache *afs_vhashTable[VCSIZE], Ve, *Ventry = &Ve, *Vep;
    afs_int32 i, j;

    if (pnt) printf("\n\nPrinting afs_vcaches structures...\n");
    if (pnt) printf("print_vcaches: sizeof(struct vcache) = %ld\n", (long) sizeof(struct vcache));
    findsym( "afs_vhashT", &symoff);
    kread(kmem, symoff, (char *) afs_vhashTable, sizeof afs_vhashTable);
    for (i=0, j=0; i < VCSIZE; i++) {
        if (pnt)
            printf("Printing hash chain %d...\n", i);
        for (Vep = afs_vhashTable[i]; Vep; Vep = Ventry->hnext, j++) {
            kread(kmem, (off_t) Vep, (char *)Ventry, sizeof *Ventry);
            if (Dvstats || Dall || !pnt) 
                print_vcache(kmem, Ventry, Vep, pnt);
            if (Dvnodes || Dall) 
                print_vnode(kmem, Ventry, Vep, pnt);
        }
    }
    if (pnt) printf("... found %d 'afs_vcaches' entries\n", j);
    return j;
}

int print_dcaches(pnt)
int pnt;
{
    off_t symoff;
    long table, *ptr;
    struct dcache dc, *dcp = &dc, *dp;
    afs_int32 i, j, count;
    struct afs_q dlru;

    /* Handle the afs_dcaches structs */
    if (pnt) printf("\n\nPrinting afs_dcache related structures...\n");
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    findsym( "afs_indexTable", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    ptr = (long *) malloc(count * sizeof(long));
    kread(kmem, table, (char *) ptr, count * sizeof(long));
    for (i=0, j=0; i < count; i++) {
        if (dp = (struct dcache *)ptr[i]) {
            if (pnt) printf("afs_indexTable[%d] %x: ", i, dp);
            kread(kmem, (off_t) dp, (char *)dcp, sizeof *dcp);
            print_dcache(kmem, dcp, dp, pnt);
            j++;
        }
    }
    if (pnt) printf("... found %d 'dcache' entries\n", j);
    findsym( "afs_DLRU", &symoff);
    kread(kmem, symoff, (char *) &dlru, sizeof(struct afs_q));
    if (pnt) printf("DLRU next=0x%x, prev=0x%x\n", dlru.next, dlru.prev);
    free(ptr);
    
    return j;
}


void print_DindexTimes(pnt)
int pnt;
{
    off_t symoff;
    long table;
    afs_hyper_t *ptr;
    afs_int32 temp, * indexTime = &temp; 
    afs_int32 i, j, count;

    /* Handle the afs_indexTimes array */
    if (pnt) printf("\n\nPrinting afs_indexTimes[]...\n");
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    findsym( "afs_indexTimes", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    ptr = (afs_hyper_t *) malloc(count * sizeof(afs_hyper_t));
    kread(kmem, table, (char *) ptr, count * sizeof(afs_hyper_t));
    for (i=0, j=0; i < count; i++) {
        if (pnt) printf("afs_indexTimes[%d]\t%10d.%d\n", i,
                        ptr[i].high, ptr[i].low);
/*      if (dp = (struct dcache *)ptr[i]) {
        printf("afs_indexTable[%d] %lx: ", i, dp);
        kread(kmem, (off_t) dp, (char *)dcp, sizeof *dcp);
        print_dcache(kmem, dcp, dp);
        }
*/
        j++;
    }
    if (pnt) printf("afs_indexTimes has %d entries\n", j);
    free(ptr);
}


void print_DdvnextTbl(pnt)
int pnt;
{
    off_t symoff;
    long table;
    afs_int32 *ptr;
    afs_int32 temp, * indexTime = &temp; 
    afs_int32 i, j, count;

    /* Handle the afs_dvnextTbl arrays */
    if (pnt) printf("\n\nPrinting afs_dvnextTbl[]...\n");
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    findsym( "afs_dvnextTbl", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    ptr = (afs_int32 *) malloc(count * sizeof(afs_int32));
    kread(kmem, table, (char *) ptr, count * sizeof(afs_int32));
    for (i=0, j=0; i < count; i++) {
        if (pnt) printf("afs_dvnextTbl[%d]\t%d\n", i, ptr[i]);
        j++;
    }
    if (pnt) printf("afs_dvnextTbl has %d entries\n", j);
    free(ptr);
}


void print_DdcnextTbl(pnt)
int pnt;
{
    off_t symoff;
    long table;
    afs_int32 *ptr;
    afs_int32 temp, * indexTime = &temp; 
    afs_int32 i, j, count;

    /* Handle the afs_dcnextTbl arrays */
    if (pnt) printf("\n\nPrinting afs_dcnextTbl[]...\n");
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    findsym( "afs_dcnextTbl", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    ptr = (afs_int32 *) malloc(count * sizeof(afs_int32));
    kread(kmem, table, (char *) ptr, count * sizeof(afs_int32));
    for (i=0, j=0; i < count; i++) {
        if (pnt) printf("afs_dcnextTbl[%d]\t%d\n", i, ptr[i]);
        j++;
    }
    if (pnt) printf("afs_dcnextTbl has %d entries\n", j);
    free(ptr);
}


void print_DindexFlags(pnt)
int pnt;
{
    off_t symoff;
    afs_int32 count;
    long table;
    unsigned char *flags;
    afs_int32 temp, * indexTime = &temp; 
    afs_int32 i, j;

    /* Handle the afs_indexFlags array */
    if (pnt) printf("\n\nPrinting afs_indexFlags[]...\n");
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    findsym( "afs_indexFlags", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    flags = (unsigned char *) malloc(count * sizeof(char));
    kread(kmem, table, flags, count * sizeof(char));
    for (i=0, j=0; i < count; i++) {
        if (pnt) printf("afs_indexFlags[%d]\t%4u\n", i, flags[i]);
        j++;
    }
    if (pnt) printf("afs_indexFlags has %d entries\n", j);
    free(flags);
}


void print_buffers(pnt)
int pnt;
{
    off_t symoff;
    long table;
    afs_int32 count;
    unsigned char *buffers;
    struct buffer *bp;
    afs_int32 i, j;

    if (pnt) printf("\n\nPrinting 'buffers' table...\n");
    findsym( "Buffers", &symoff);
    kread(kmem, symoff, (char *) &table, sizeof(long));
    findsym( "nbuffers", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(int));
    buffers = (unsigned char *) malloc(count * sizeof(struct buffer));  
    kread(kmem, table, buffers, count * sizeof(struct buffer));
    bp = (struct buffer *)buffers;
    for (i=0, j=0; i < count; i++, bp++) {
#ifdef AFS_SGI62_ENV
        if (pnt) printf("Buffer #%d:\tfid=%llu page=%d, accTime=%d,\n\tHash=%x, data=%x, lockers=%x, dirty=%d, hashI=%d\n",
                 i, bp->fid[0], bp->page, bp->accesstime,
                 bp->hashNext, bp->data, bp->lockers, bp->b_dirty, bp->hashIndex);
#else
        if (pnt) printf("Buffer #%d:\tfid=%lu page=%d, accTime=%d,\n\tHash=%x, data=%x, lockers=%x, dirty=%d, hashI=%d\n",
                 i, bp->fid[0], bp->page, bp->accesstime,
                 bp->hashNext, bp->data, bp->lockers, bp->b_dirty, bp->hashIndex);
#endif
        j++;
    }
    if (pnt) printf("\n\t   ... that should be %d buffer entries\n", i);
}


int print_nfss(pnt)
int pnt;
{
    off_t symoff;
    struct afs_exporter *exp_entry, ex, *exp = &ex, *exp1;
    struct nfsclientpag  *afs_nfspags[NNFSCLIENTS], e, *entry = &e, *ep;
    long i, j, cell;

    /* Handle the afs_exporter structures */
    if (pnt) printf("\n\nPrinting 'afs_exporters' link list...\n");
    findsym( "root_exported", &symoff);
    kread(kmem, symoff, (char *) &cell, sizeof(long));
    for (exp1 = (struct afs_exporter *) cell, j=0; exp1; exp1 = exp->exp_next, j++) {
        kread(kmem, (off_t)exp1, (char *) exp, sizeof *exp);
        if (pnt) printf("AFS_EXPORTER(%x): \n", exp1);
        print_exporter(kmem, exp, exp1, pnt);
        Sum_exps++;
    }
    if (pnt) printf("... found %d 'afs_exporters' entries\n", j);

    /* Handle the afs_nfsclientpags structs */
    if (pnt) printf("\n\nPrinting 'afs_nfsclientpags' structures...\n");
    if (!findsym( "afs_nfspags", &symoff))
        return 0;
    kread(kmem, symoff, (char *) afs_nfspags, sizeof afs_nfspags);
    for (i=0,j=0; i < NNFSCLIENTS; i++) {
        for (ep = afs_nfspags[i]; ep; ep = entry->next, j++) {
            kread(kmem, (off_t) ep, (char *) entry, sizeof *entry);
            print_nfsclient(kmem, entry, ep, pnt);
        }
    }
    if (pnt) printf("... found %d 'afs_nfsclientpags' entries\n", j);
    return j;
}

#if defined(AFS_GLOBAL_SUNLOCK) && !defined(AFS_HPUX_ENV) && !defined(AFS_AIX41_ENV)
typedef struct event {
    struct event *next;         /* next in hash chain */
    char *event;                /* lwp event: an address */
    int refcount;               /* Is it in use? */
    kcondvar_t cond;            /* Currently associated condition variable */
    int seq;                    /* Sequence number: this is incremented
                                   by wakeup calls; wait will not return until
                                   it changes */
} event_t;
#endif


#ifdef AFS_LINUX22_ENV
/* This is replicated from LINUX/osi_alloc.c */
#define MEM_SPACE sizeof(int)

#define KM_TYPE 1
#define VM_TYPE 2
struct osi_linux_mem {
    int mem_next; /* types are or'd into low bits of next */
    char data[1];
};
#define MEMTYPE(A) ((A) & 0x3)
#define MEMADDR(A) ((struct osi_linux_mem*)((A) & (~0x3)))
#define PR_MEMTYPE(A) ((MEMTYPE(A) == KM_TYPE) ? "phys" : "virt")
void print_alloced_memlist(void)
{
    off_t symoff;
    struct osi_linux_mem *memp, memlist, next;
    off_t next_addr;
    int count;
    int n = 0;

    findsym( "afs_linux_memlist_size", &symoff);
    kread(kmem, symoff, (char*) &count, sizeof count);
    findsym( "afs_linux_memlist", &symoff);
    kread(kmem, symoff, (char*) &memp, sizeof memp);
    if (memp) {
        kread(kmem, (int)memp, (char*) &next, sizeof next);
    }
    else {
        memset(&next, 0, sizeof next);
    }
    printf("Allocated memory list: %d elements\n", count);
    printf("%20s %4s %10s\n", "Address", "Type", "Next");
    printf("%20lx %4s %10x\n", (long)((char*)memp) + MEM_SPACE,
           PR_MEMTYPE(next.mem_next), next.mem_next);
    n = 1;
    while (next_addr = (off_t) MEMADDR(next.mem_next)) {
        n  ++;
        memlist = next;
        kread(kmem, next_addr, (char*) &next, sizeof next);
        printf("%20lx %4s %10x\n", (long) next_addr+MEM_SPACE,
               PR_MEMTYPE(next.mem_next), next.mem_next);
    }
    printf("Found %d elements in allocated memory list, expected %d\n",
           n, count);
}
#endif

void print_allocs(pnt)
int pnt;
{
    off_t symoff;
    long count, i, j, k, l, m, n, T=0, tvs;
    struct afs_CMStats afs_cmstats;
    struct afs_stats_CMPerf afs_cmperfstats;

    findsym( "afs_cmstats", &symoff);
    kread(kmem, symoff, (char *) &afs_cmstats, sizeof afs_cmstats);
    findsym( "afs_stats_cmperf", &symoff);
    kread(kmem, symoff, (char *) &afs_cmperfstats, sizeof afs_cmperfstats);

    T += MAXSYSNAME;
    printf("\n\n%20s:\t%8d bytes\n", "Sysname area", MAXSYSNAME);

    Sum_cellnames=0;
    i = print_cells(0);
    j = (i * sizeof(struct cell)) + Sum_cellnames;
    T += j;
    printf("%20s:\t%8d bytes\t[%d cells/%d bytes each + %d bytes for cell names]\n", "Cell package", j, i, sizeof(struct cell), Sum_cellnames);

    Sum_userstp=0;
    i = print_users(0);
    j = (i * sizeof(struct unixuser)) + Sum_userstp;
    T += j;
    printf("%20s:\t%8d bytes\t[%d users/%d bytes each + %d bytes for secret tokens]\n", "User package", j, i, sizeof(struct unixuser), Sum_userstp);

    i = print_servers(0);
    j = (i * sizeof(struct server));
    T += j;
    printf("%20s:\t%8d bytes\t[%d servers/%d bytes each]\n", "Server package", j, i, sizeof(struct server));
    j = (Nconns * sizeof(struct conn));
    T += j;
    printf("%20s:\t%8d bytes\t[%d conns/%d bytes each]\n", "Connection package", j, Nconns, sizeof(struct conn));
    
    i = (AFS_NCBRS * sizeof(struct afs_cbr)) * (j = afs_cmperfstats.CallBackAlloced);
    T += i;
    if (i)
    printf("%20s:\t%8d bytes\t[%d cbs/%d bytes each]\n", "Server CB free pool", i, (j * AFS_NCBRS), sizeof(struct afs_cbr));

    Sum_volnames=0;
    i = print_volumes(0);
    j = (MAXVOLS * sizeof(struct volume)) + Sum_volnames;
    T += j;
    printf("%20s:\t%8d bytes\t[%d volumes/%d bytes each + %d bytes for volnames - %d active entries]\n", "Volume package", j, MAXVOLS, sizeof(struct volume), Sum_volnames, i);

    Sum_vcachemvids = Sum_vcachelinkData = Sum_vcacheacc = Sum_vcachelocks = 0;
    tvs = i = print_vcaches(0);
    j = (i * sizeof(struct vcache));
/*    T += j;*/
/*    printf("%20s:\t%d bytes\t[%d vcaches/%d bytes each]\n", "Vcache package", j, i, sizeof(struct vcache));*/
#ifdef  AFS_AIX32_ENV
    i = (tvs + Sum_vcachemvids + Sum_vcachelinkData + Sum_vcachelocks) * AFS_SMALLOCSIZ;
    printf("%20s:\t%8d bytes\t[%d act gnodes, %d mount pnts, %d symbolic links, %d unix locks]\n", 
           "[VC use of sml fp]*",i, tvs, Sum_vcachemvids, Sum_vcachelinkData, Sum_vcachelocks);
#else
    i = (Sum_vcachemvids + Sum_vcachelinkData + Sum_vcachelocks) * AFS_SMALLOCSIZ;
    printf("%20s:\t8%d bytes\t[%d mount pnts, %d symbolic links, %d unix locks]\n", 
           "[VC use of sml fp]*",i, Sum_vcachemvids, Sum_vcachelinkData, Sum_vcachelocks);
#endif

#define NAXSs (1000 / sizeof(struct axscache))
#ifdef  AFS32
    i = (NAXSs * sizeof(struct axscache));
    T += i;
    printf("%20s:\t%8d bytes\t[%d access used by vcaches/%d bytes each]\n", "ACL List free pool", i, Sum_vcacheacc, sizeof(struct axscache));
#else
    {
    struct axscache *xp, xpe, *nxp = &xpe;

    findsym( "afs_xaxscnt", &symoff);
    kread(kmem, symoff, (char *) &i, sizeof i);
    j = i * (NAXSs * sizeof(struct axscache));
    T += j;
    printf("%20s:\t%8d bytes\t[%d access used by vcaches/%d bytes each - %d blocks of %d]\n", "ACL List free pool", j, Sum_vcacheacc, sizeof(struct axscache), i, (NAXSs * sizeof(struct axscache)));
    }
#endif

#ifdef  AFS32
    i = print_dcaches(0);
    j = (i * sizeof(struct dcache));
    T += j;
    printf("%20s:\t%8d bytes\t[%d dcaches/%d bytes each - ONLY USED COUNTED]\n", "Dcache package", j, i, sizeof(struct dcache));
#else
    findsym( "afs_dcentries", &symoff);
    kread(kmem, symoff, (char *) &i, sizeof i);
    j = (i * sizeof(struct dcache));
    T += j;
    printf("%20s:\t%8d bytes\t[%d dcaches/%d bytes each]\n", "Dcache package", j, i, sizeof(struct dcache));
#endif
    findsym( "afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &i, sizeof i);
    findsym( "afs_cacheStats", &symoff);
    kread(kmem, symoff, (char *) &j, sizeof j);

    k = (j * sizeof(struct vcache));
    printf("%20s:\t%8d bytes\t[%d free vcaches/%d bytes each - %d active entries]\n", "Vcache free list", k, j, sizeof(struct vcache), tvs);
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Dcache Index Table", i * 4, i, 4);
#ifndef AFS32
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Dcache Index Times", i * 8, i, 8);
#else
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Dcache Index Times", i * 4, i, 4);
#endif
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Dcache Index Flags", i, i, 1);
/*    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Dcache free list", i, i, 1);*/
#ifndef AFS32
    T += k + (i*4)+ (i*8) + i;
#else
    T += k + (i*4)+ (i*4) + i;
#endif

    i = (j = afs_cmperfstats.bufAlloced) * sizeof(struct buffer);
    T += i;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Buffer package", i, j, sizeof(struct buffer));
#if     !AFS_USEBUFFERS
#define AFS_BUFFER_PAGESIZE 2048
    i = j * AFS_BUFFER_PAGESIZE;
    T += i;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Xtra Buffer pkg area", i, j, AFS_BUFFER_PAGESIZE);
#endif

    Sum_exps = 0;
    Sum_nfssysnames = 0;
    i = print_nfss(0);
    k = Sum_exps * sizeof(struct afs_exporter);
    T += k;
    if (k)
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Xlator Exporter list", k, Sum_exps, sizeof(struct afs_exporter));

    j = (i * sizeof(struct nfsclientpag)) + Sum_nfssysnames;
    T += j;
    if (j)
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each + %d for remote sysnames]\n", "Xlator Nfs clnt pkg", j, i, sizeof(struct nfsclientpag), Sum_nfssysnames);

    i = (j = afs_cmperfstats.LargeBlocksAlloced) * AFS_LRALLOCSIZ;
    T += i;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each - %d active entries]\n", "Large Free Pool", 
           i, j, AFS_LRALLOCSIZ, afs_cmperfstats.LargeBlocksActive);

    i = (j = afs_cmperfstats.SmallBlocksAlloced) * AFS_SMALLOCSIZ;
    T += i;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each - %d active entries]\n", "Small Free Pool", 
           i, j, AFS_SMALLOCSIZ, afs_cmperfstats.SmallBlocksActive);

#if defined(AFS_GLOBAL_SUNLOCK) && !defined(AFS_HPUX_ENV) && !defined(AFS_AIX41_ENV)
    findsym( "afs_evhashcnt", &symoff);
    kread(kmem, symoff, (char *) &j, sizeof j);
    i = (j * sizeof(event_t));
    T += i;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "afs glock Event Pool", i, j, sizeof(event_t));
/*    printf("XXXXXXX Count event queue allocs!!!! XXXXXX\n");*/

#endif
    i = j =0;
    if (findsym( "rxevent_nFree", &symoff))
        kread(kmem, symoff, (char *) &j, sizeof j);
    if (findsym( "rxevent_nPosted", &symoff))
        kread(kmem, symoff, (char *) &i, sizeof i);
    k = (i + j) * sizeof(struct rxevent);
    if (k) {
        T += k;
        printf("%20s:\t%8d bytes\t[%d free, %d posted/%d bytes each]\n", "Rx event pkg", 
               k, j, i, sizeof(struct rxevent));
    } else {
        T += (k = 20 * sizeof(struct rxevent));
        printf("%20s:\t%8d bytes\t[%d entries/%d bytes each - THIS IS MIN ALLOC/NOT ACTUAL]\n", "Rx event pkg", 
               k, 20, sizeof(struct rxevent));
    }

    findsym("rx_nFreePackets", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
/*
    findsym("rx_initSendWindow", &symoff);
    kread(kmem, symoff, (char *) &i, sizeof i);
*/
    i=0;
    findsym("rx_nPackets", &symoff);
    kread(kmem, symoff, (char *) &j, sizeof j);
    k = (j + i + 2) * sizeof(struct rx_packet);
    T += k;
    printf("%20s:\t%8d bytes\t[%d free packets/%d bytes each]\n", "Rx packet freelist", 
           k, count, sizeof(struct rx_packet));
#define rx_hashTableSize 256    /* XXX */
    i = (rx_hashTableSize*sizeof(struct rx_connection *));
    j = (rx_hashTableSize*sizeof(struct rx_peer *));
    k = i + j;
    T += k;
    printf("%20s:\t%8d bytes\t[%d entries/%d bytes each]\n", "Rx conn/peer tables", 
           k, rx_hashTableSize, sizeof(struct rx_connection *));

    findsym( "rxi_Alloccnt", &symoff);
    kread(kmem, symoff, (char *) &j, sizeof j);
    findsym( "rxi_Allocsize", &symoff);
    kread(kmem, symoff, (char *) &i, sizeof i);
    T += i;
    printf("%20s:\t%8d bytes\t[%d outstanding allocs]\n", "RX misc allocs", i, j);


    j = afs_cmperfstats.OutStandingMemUsage;
    printf("\n\n%20s:\t%8d bytes\n", "Mem used by afs", j);
    printf("%20s:\t%8d bytes\n", "Accounted-for mem", T);
    printf("%20s:\t%8d bytes\n", "Non acc'd-for mem", j - T);

    printf("\n\nNOTE:\n\tAll [...]* entries above aren't counted towards the total mem since they're redundant\n");

#ifdef AFS_LINUX22_ENV
    if (pnt)
        print_alloced_memlist();
#endif
}

#if     defined(sparc)
int readmem(kmem, buf, vad, len)
    int kmem, len;
#ifdef AFS_SUN57_ENV
    uintptr_t vad;
#else
    int vad;
#endif          /** AFS_SUN57_ENV **/
    char *buf;
{
    int newlen;
    if (( newlen = kvm_kread(kd, vad, buf, len) ) != len) {
        printf("Couldn't process dumpfile with supplied namelist %s\n", obj);
        exit(1);
    }
}
#endif

#ifdef  AFS_OSF_ENV
static read_addr(int fd, unsigned long addr, unsigned long *val) {
    if (lseek(fd, addr, SEEK_SET) == -1) return(0);
    if (read(fd, val, sizeof(long)) != sizeof(long)) return(0);
    return(1);
}

static pt_entry_t *ptes = NULL;
static addr_to_offset(unsigned long addr, unsigned long *ret, int fd)
{
    off_t symoff;
    pt_entry_t pte, *val;  
    char *str, *ptr;

    if (IS_SEG1_VA(addr)){
        if(ptes == NULL){
            int i, loc;
            unsigned long loc1, loc2[2];
            findsym ("kernel_pmap", &symoff);
            loc1 = coreadj(symoff);
            /*printf("ptes=%lx -> %lx\n", symoff, loc1);*/
            if (lseek(fd, loc1, L_SET/*0*/) != loc1) {
                perror("lseek");
                exit(1);
            }
            if ((i = read(fd, (char *)&loc1, sizeof(long))) != sizeof(long)) {
                printf("Read of kerne_map failed\n");
                return; /*exit(1);*/
            }
            loc = loc1;
            /*printf("loc1 %lx -> %lx\n",  loc1, loc);*/
            if (lseek(fd, loc, L_SET/*0*/) != loc) {
                perror("lseek");
                exit(1);
            }
            if ((i = read(fd, (char *)loc2, 2*sizeof(long))) != 2*sizeof(long)) {
                printf("Read of kerne_map failed\n");
                return; /*exit(1);*/
            }
            ptes = (pt_entry_t *) loc2[1];
            /*printf("ptes=%lx\n", ptes);*/

        }
        if(!addr_to_offset((unsigned long) (ptes + LEVEL1_PT_OFFSET(addr)), (unsigned long *) &val, fd)) return(0);
        if(!read_addr(fd, (unsigned long) val, (unsigned long *) &pte)) return(0);
        val = ((pt_entry_t *) PTETOPHYS(&pte)) + LEVEL2_PT_OFFSET(addr);
        if(!read_addr(fd, (unsigned long) val, (unsigned long *) &pte)) return(0);
        val = ((pt_entry_t *) PTETOPHYS(&pte)) + LEVEL3_PT_OFFSET(addr);
        if(!read_addr(fd, (unsigned long) val, (unsigned long *) &pte)) return(0);
        *ret = PTETOPHYS(&pte) + (addr & ((1 << PGSHIFT) - 1));      
        return(1);
    } else if(IS_KSEG_VA(addr)) {
        *ret = KSEG_TO_PHYS(addr);
        return(1);
    } else {
        return(0);
    }
}
#endif

#ifndef AFS_KDUMP_LIB
void kread(int kmem,off_t loc,void *buf,KDUMP_SIZE_T len)
{
    int i;

    bzero(buf,len);

#ifdef  AFS_OSF_ENV
    if (mem) {
        unsigned long ret;
        i = addr_to_offset(loc, &ret, kmem);
        if (i == 1) 
            loc = ret;
        else {
            unsigned long loc1;
            loc1 = coreadj(loc);
            loc = loc1;
        }
    }
#else
#if     defined(sparc)
#ifndef AFS_SUN5_ENV
    if (mem) {
#endif
        readmem(kmem, buf, (off_t)loc, len);    
        return;
#ifndef AFS_SUN5_ENV
    }
#endif
#endif
#endif
#if     ! defined(AFS_SUN5_ENV)
#if defined(AFS_SGI61_ENV) && !defined(AFS_32BIT_KERNEL_ENV)
    if (lseek64(kmem, loc, L_SET/*0*/) != loc)
#else
    if (lseek(kmem, loc, L_SET/*0*/) != loc)
#endif
        {
            perror("lseek");
            exit(1);
        }
    if ((i = read(kmem, buf, len)) != len) {
        printf("WARNING: Read failed: ");
        if (sizeof(loc) > sizeof(long)) {
            printf("loc=%llx", loc);
        } else {
            printf("loc=%lx", (long) loc);
        }
        printf(", buf=%lx, len=%ld, i=%d, errno=%d\n",
               (long) buf, (long) len, i, errno);
        return; /*exit(1);*/
    }
#endif
}
#endif /* AFS_KDUMP_LIB */

#ifdef  AFS_SUN5_ENV

/**
  * When examining the dump of a 64 bit kernel, we use this function to
  * read symbols. The function opencore() calls this or rdsymbols() using
  * the macro RDSYMBOLS
  */

rdsymbols() {

    FILE        *fp;
    Elf         *efd;
    Elf_Scn     *cn = NULL;
#ifdef  _LP64
    Elf64_Shdr  *shdr;
    Elf64_Sym   *stbl, *p1, *p2;
    Elf64_Shdr * ( * elf_getshdr)(Elf_Scn *) = elf64_getshdr;
#else
    Elf32_Shdr *shdr;
    Elf32_Sym   *stbl, *p1, *p2;
    Elf32_Shdr * ( * elf_getshdr)(Elf_Scn *) = elf32_getshdr;
#endif
    Elf_Data    *dp = NULL, *sdp = NULL;

    int         nsyms, i, fd;

    if (!(fp = fopen(obj, "r"))) {
        printf("Can't open %s (%d)\n", core, errno);    
        exit(1);        
    }
    
    fd = fileno(fp);
    lseek(fd, 0L, 0);
    if ((efd = elf_begin(fd, ELF_C_READ, 0)) == NULL) {
        printf("Can't elf begin (%d)\n", errno);
        exit(1);
    }
    while (cn = elf_nextscn(efd, cn)) {
        if ((shdr = elf_getshdr(cn)) == NULL) {
            elf_end(efd);       
            printf("Can't read section header (%d)\n", errno);
            exit(1);
        }
        if (shdr->sh_type == SHT_SYMTAB)
            break;
    }   
    dp = elf_getdata(cn, dp);
    p1 = stbl = (void *) dp->d_buf;
    nsyms = dp->d_size / sizeof(*stbl);
    cn = elf_getscn(efd, shdr->sh_link);
    sdp = elf_getdata(cn, sdp);
    tblp = malloc(sdp->d_size);
    memcpy(tblp, sdp->d_buf, sdp->d_size);
    p2 = tbl = malloc(nsyms * sizeof(*stbl));
    for (i = 0, scnt = 0; i < nsyms; i++, p1++, p2++) {
        p2->st_name = p1->st_name;
        p2->st_value = p1->st_value;
        p2->st_size = p1->st_size;
        p2->st_info = p1->st_info;
        p2->st_shndx = p1->st_shndx;
        scnt++;
    }
    elf_end(efd);
    close(fd);
}

#endif          /** AFS_SUN5_ENV **/


int opencore(core)
    char *core;
{
#ifdef AFS_KDUMP_LIB
    return 0;
#else /* AFS_KDUMP_LIB */
    int fd;

#if     defined(sparc)
#ifndef AFS_SUN5_ENV
    if (mem) {
#endif

        if ((kd = kvm_open(obj, core, NULL, O_RDONLY, "crash")) == NULL) {
            printf("Can't open kvm - core file %s\n", core);    
            exit(1);
        }

#ifndef AFS_SUN5_ENV
      } else
#endif
#ifdef  AFS_SUN5_ENV
    rdsymbols();
#endif
#endif /* sparc */

  {
    if ((fd = open(core, O_RDONLY)) < 0) {
        perror(core);
        exit(1);
    }
    return fd;
  }
#endif /* AFS_KDUMP_LIB */
}


void print_exporter(kmem, exporter, ptr, pnt)
    int kmem, pnt;
    struct afs_exporter *exporter, *ptr;
{
    if (pnt) {
        printf("\tstates=%x, type=%x, *data=%lx\n", 
               exporter->exp_states, exporter->exp_type, exporter->exp_data);
        printf("\texp_stats (calls=%d, rejectedcalls=%d, nopag=%d, invalidpag=%d)\n", 
               exporter->exp_stats.calls, exporter->exp_stats.rejectedcalls, 
               exporter->exp_stats.nopag, exporter->exp_stats.invalidpag);
    }
}


void print_nfsclient(kmem, ep, ptr, pnt)
    int kmem, pnt;
    struct nfsclientpag *ep, *ptr;
{
    char sysname[100];

    if (ep->sysname) {
        kread(kmem, (off_t) ep->sysname, sysname, (KDUMP_SIZE_T)30);
        Sum_nfssysnames += MAXSYSNAME;
    }
    if (pnt) printf("%lx: uid=%d, host=%x, pag=%x, @sys=%s, lastt=%d, ref=%d\n",
           ptr, ep->uid, ep->host , ep->pag, (ep->sysname ? sysname : "nil"),
           ep->lastcall, ep->refCount);
}


#if     defined(AFS_SUN5_ENV)
pmutex(sp, mp)
char *sp;
kmutex_t *mp;
{
#ifdef  AFS_SUN54_ENV

#else
    struct stat_mutex *smp = (struct stat_mutex *)mp;

    printf("%s mutex: %x %x\n", sp, smp->m_stats_lock, smp->m_type);
#endif
}

#endif

void print_unixuser(kmem, uep, ptr, pnt)
    int kmem, pnt;
    struct unixuser *uep, *ptr;
{
    Sum_userstp += uep->stLen;
    if (pnt) {
       printf("%lx: uid=x%x, cell=%x, vid=%d, refc=%d, states=%x, tokTime=%d, tikLen=%d\n",
              ptr, uep->uid, uep->cell, uep->vid, uep->refCount, uep->states,
              uep->tokenTime, uep->stLen);
       printf("\tstp=%lx, clearTok[Han=x%x, x<%x,%x,%x,%x,%x,%x,%x,%x>, vid=%d, Bt=%d, Et=%d], exporter=%lx\n", 
              uep->stp, uep->ct.AuthHandle, 
              uep->ct.HandShakeKey[0], uep->ct.HandShakeKey[1], uep->ct.HandShakeKey[2],
              uep->ct.HandShakeKey[3], uep->ct.HandShakeKey[4], uep->ct.HandShakeKey[5],
              uep->ct.HandShakeKey[6], uep->ct.HandShakeKey[7], uep->ct.ViceId,
              uep->ct.BeginTimestamp, uep->ct.EndTimestamp, uep->exporter);
    }
}

void print_cell(kmem, clep, ptr, pnt)
    int kmem, pnt;
    struct cell *clep, *ptr;
{
    int i;
    char cellName[100];
    struct in_addr in;


    kread(kmem, (off_t) clep->cellName, cellName, (KDUMP_SIZE_T)40);
    cellName[40] = 0;
    Sum_cellnames += strlen(cellName)+1;
    if (pnt) {
        printf("%lx: cell=%s, cellname=%s, states=%x, cindex=%d fsport=%d vlport=%d\n", ptr,
               PrintIPAddr(clep->cell), cellName, clep->states, clep->cellIndex,
               clep->fsport, clep->vlport);
#ifdef  AFS33
        if (clep->lcellp)
            printf("\tlinked cellp %lx\n", clep->lcellp);
#endif
        printf("\tCell's servers: ");
        for (i=0; i<MAXCELLHOSTS; i++) {
            if (pretty && (clep->cellHosts[i] == 0)) break;
            printf("[%lx] ", clep->cellHosts[i]);
        }
        printf("\n");
    }
}


void print_server(kmem, sep, ptr, conns, pnt)
    int kmem, conns, pnt;
    struct server *sep, *ptr;
{
    struct srvAddr sa, *sap = &sa, *sap1;
    int j, mh=0, cnt;

    if (conns != 2 && pnt) {
        printf("%lx: cell=%lx, addr=%lx, flags=0x%x, actTime=%x, lastDownS=%x, numDownIn=%d, sumofDownt=%d\n", 
               ptr, sep->cell, sep->addr,  sep->flags,
               sep->activationTime, sep->lastDowntimeStart, sep->numDowntimeIncidents,
               sep->sumOfDowntimes);
        if (sep->flags & SRVR_MULTIHOMED) {
            if (pnt) {
                printf("\tuuid=[%x,%x,%x,%x,%x,%x,%x,%x,%x,%x,%x]  addr_uniquifier=%x\n",
                       sep->sr_uuid.time_low, sep->sr_uuid.time_mid, sep->sr_uuid.time_hi_and_version,
                       sep->sr_uuid.clock_seq_hi_and_reserved, sep->sr_uuid.clock_seq_low, sep->sr_uuid.node[0],
                       sep->sr_uuid.node[1], sep->sr_uuid.node[2], sep->sr_uuid.node[3], sep->sr_uuid.node[4],
                       sep->sr_uuid.node[5], sep->sr_addr_uniquifier);
            }
            mh = 1;
        }
        for (j=0, cnt=1, sap1 = sep->addr; sap1; sap1 = sap->next_sa, j++, cnt++) {
            kread(kmem, (off_t)sap1, (char *)sap, sizeof(*sap));
            if (pnt) {
                if (mh) {
                    printf("\t   #%d ip-addr(%lx): [sa_ip=%s, sa_port=%d, sa_iprank=%d, sa_flags=%x, conns=%lx, server=%lx, next_bkt=%lx]\n",
                           cnt, sap1, PrintIPAddr(sap->sa_ip), sap->sa_portal,
                           sap->sa_iprank, sap->sa_flags, sap->conns, 
                           sap->server, sap->next_bkt);
                } else {
                    printf("\t[sa_ip=%s, sa_port=%d, sa_iprank=%d, sa_flags=%x, conns=%lx, server=%lx, nexth=%lx]\n",
                           PrintIPAddr(sap->sa_ip), sap->sa_portal, sap->sa_iprank, 
                           sap->sa_flags, sap->conns, sap->server,
                           sap->next_bkt);
                }
            }
        }
    }
    if (sep->cbrs && pnt) {
        struct afs_cbr cba, *cbsap = &cba, *cbsap1;

        printf(" Callbacks to be returned:\n");
        for (j=0, cbsap1 = sep->cbrs; cbsap1; cbsap1 = cbsap->next, j++) {
            kread(kmem, (off_t)cbsap1, (char *)cbsap, sizeof(*cbsap));
            printf("     #%2d) %lx [v=%d, n=%d, u=%d]\n", j, cbsap1,
                   cbsap->fid.Volume, cbsap->fid.Vnode, cbsap->fid.Unique);
        }
    }
    if (conns) {
        for (j=0, sap1 = sep->addr; sap1; sap1 = sap->next_sa, j++) {
            kread(kmem, (off_t)sap1, (char *)sap, sizeof(*sap));
            print_conns(kmem, sap1, sap->conns, conns, pnt);
        }
    } else
        if (pnt) printf("\n");
}


void print_conns(kmem, srv, conns, Con, pnt)
    int kmem, Con, pnt;
    struct srvAddr *srv;
    struct conn *conns;
{
    struct conn *cep, ce, *centry= &ce;
    int i = 1;

    cep = (struct conn *)conns;
    if (pnt && Con != 2) {
        if (cep)
            printf("\tRPC connections for server %lx:\n", srv);
        else
            printf("\tNO RPC connections for server %x\n", srv);
    }
    for (; cep; cep = centry->next, Nconns++, i++) {
        if (pnt && Con != 2)
            printf("\t   #%d> ", i);
        kread(kmem, (off_t)cep, (char *) centry, sizeof *centry);
        print_conn(kmem, centry, cep, pnt);
    }
}


void print_conn(kmem, conns, ptr, pnt)
    int kmem, pnt;
    struct conn *conns, *ptr;
{
    if (!pnt) return;
    printf("%lx: user=%lx, rx=%lx, srvr=%lx, ref=%d, port=%d, forceC=%d\n",
           ptr, conns->user, conns->id, conns->srvr, conns->refCount, 
           conns->port, conns->forceConnectFS);

}


void print_volume(kmem, vep, ptr, pnt)
    int kmem, pnt;
    struct volume *vep, *ptr;
{
    int i;
    afs_int32 *loc;
    char Volname[100];



   loc = (afs_int32 *)&vep->lock;
   if (vep->name) {
        kread(kmem, (off_t) vep->name, Volname, (KDUMP_SIZE_T)40);
        Sum_volnames += strlen(Volname)+1;
    }
    if (!pnt) return;
    printf("%lx: cell=%x, vol=%d, name=%s, roVol=%d, backVol=%d\n",
           ptr, vep->cell, vep->volume, (vep->name ? Volname:"nil"), vep->roVol, vep->backVol);
#ifdef  AFS33
    printf("\trwVol=%d, AcTime=%d, copyDate=%d, expTime=%d, vtix=%d, refC=%d, states=%x\n",
           vep->rwVol, vep->accessTime, vep->copyDate, vep->expireTime,
           vep->vtix, vep->refCount, vep->states);
#else
    printf("\trwVol=%d, AcTime=%d, copyDate=%d, vtix=%d, refC=%d, states=%x\n",
           vep->rwVol, vep->accessTime, vep->copyDate, vep->vtix, vep->refCount, vep->states);
#endif
    printf("\tVolume's statuses: ");
    for (i=0; i < MAXHOSTS && vep->serverHost[i]; i++)
        printf("[%d] ", vep->status[i]);
    printf("\n");

    printf("\tVolume's servers: ");
    for (i=0; i < MAXHOSTS && vep->serverHost[i]; i++)
        printf("[%lx] ", vep->serverHost[i]);
    printf("\n");

    print_venusfid("\tdotdot", &vep->dotdot);
    printf("\n");

    print_venusfid("\tmtpnt", &vep->mtpoint);
    printf("\n");

#ifdef  AFS33
    if (vep->rootVnode)
        printf("\trootVnode = %d, rootUnique = %d\n", vep->rootVnode, vep->rootUnique);
#endif
    printf("\tlock=0x%x\n", *loc);
}


void print_venusfid(string, vid)
    char *string;
    struct VenusFid *vid;
{
    printf("%s(c=%x, v=%d, n=%d, u=%d)", 
           string, vid->Cell, vid->Fid.Volume, vid->Fid.Vnode, vid->Fid.Unique);
}


void print_vnode(kmem, vep, ptr, pnt)
    int kmem, pnt;
    struct vnode *vep, *ptr;
{
#ifdef AFS_AIX_ENV
    struct gnode gnode;
    struct gnode *save_gnode;
#endif /* AFS_AIX_ENV */

    if (!pnt) return;
    printf("\n");
#ifdef AFS_AIX_ENV
    save_gnode = vep->v_gnode;
    kread(kmem, (off_t) save_gnode, (char *)&gnode, sizeof(struct gnode));
    vep->v_gnode = &gnode;
#endif /* AFS_AIX_ENV */

#ifdef  AFS_SUN5_ENV
    printf("%x: v_type=%d, v_flag=%d, v_count=%d, \n",
           ptr, vep->v_type, vep->v_flag, vep->v_count);
    printf("\tv_v_stream=%x, v_pages=0x%x, v_mountdhere=%d, v_rdev=%d, v_vfsp=0x%x, v_filocks=0x%x\n",
           vep->v_stream, vep->v_pages, vep->v_vfsmountedhere, vep->v_rdev, vep->v_vfsp, vep->v_filocks);
    pmutex("\tVnode", &vep->v_lock);
    printf("\tCond v: 0x%x\n", vep->v_cv);
#endif
#ifdef AFS_AIX_ENV
    vep->v_gnode = save_gnode;
#endif /* AFS_AIX_ENV */
#ifdef AFS_SGI65_ENV
#if defined(AFS_32BIT_KERNEL_ENV)
    printf("%lx: v_mreg=0x%lx", ptr, vep->v_mreg);
#else
    printf("%llx: v_mreg=0x%llx", ptr, vep->v_mreg);
#endif
    printf(", v_mregb=0x%lx\n", vep->v_mregb);
#endif
#ifdef AFS_LINUX22_ENV
    /* Print out the stat cache and other inode info. */
    printf("\ti_ino=%d, i_mode=%x, i_nlink=%d, i_uid=%d, i_gid=%d, i_size=%d\n",
           vep->i_ino, vep->i_mode, vep->i_nlink, vep->i_uid, vep->i_gid,
           vep->i_size);
    printf("\ti_atime=%u, i_mtime=%u, i_ctime=%u, i_version=%u, i_nrpages=%u\n",
           vep->i_atime, vep->i_mtime, vep->i_ctime, vep->i_version,
           vep->i_nrpages);
    printf("\ti_op=0x%x, i_dev=0x%x, i_rdev=0x%x, i_sb=0x%x\n",
           vep->i_op, vep->i_dev, vep->i_rdev, vep->i_sb);
    printf("\ti_sem: count=%d, waking=%d, wait=0x%x\n",
           vep->i_sem.count, vep->i_sem.waking, vep->i_sem.wait);
    printf("\ti_hash=0x%x:0x%x, i_list=0x%x:0x%x, i_dentry=0x%x:0x%x\n",
           vep->i_hash.prev, vep->i_hash.next,
           vep->i_list.prev, vep->i_list.next,
           vep->i_dentry.prev, vep->i_dentry.next);
#endif /* AFS_LINUX22_ENV */
}

void print_vcache(kmem, vep, ptr, pnt)
    int kmem, pnt;
    struct vcache *vep, *ptr;
{
    long *loc, j=0;
    char *cloc;
    struct VenusFid vid;
    struct axscache acc, *accp = &acc, *acp;
    struct SimpleLocks sl, *slcp = &sl, *slp;
    char linkchar;

    if (vep->mvid) {
        kread(kmem, (off_t) vep->mvid, (char *)&vid, sizeof(struct VenusFid));
        Sum_vcachemvids++;
    }
    if (vep->linkData) 
        Sum_vcachelinkData++;
    loc = (long *)&vep->lock;

    if (pnt) {  
        if (!Dvnodes) printf("\n");
#ifdef  AFS33
        printf("%lx: refC=%d, pv=%d, pu=%d, flushDv=%d.%d, mapDV=%d.%d, ",
               ptr, vep->vrefCount, vep->parentVnode, vep->parentUnique, 
               vep->flushDV.high, vep->flushDV.low, 
               vep->mapDV.high, vep->mapDV.low);
        printf("truncPos=%d,\n\tcallb=x%lx, cbE=%d, opens=%d, XoW=%d, ",
               vep->truncPos, vep->callback, vep->cbExpires, vep->opens, 
               vep->execsOrWriters);
        printf("flcnt=%d, mvstat=%d\n",
               vep->flockCount, vep->mvstat);
        printf("\tstates=x%x, ", vep->states);
#ifdef  AFS_SUN5_ENV
        printf("vstates=x%x, ", vep->vstates);
#endif  /* AFS_SUN5_ENV */
        printf("dchint=%x, anyA=0x%x\n", vep->h1.dchint, vep->anyAccess);
        printf("\tquick[dc=%x, stamp=%x, f=%x, min=%d, len=%d]\n",
               vep->quick.dc, vep->quick.stamp, vep->quick.f,
               vep->quick.minLoc, vep->quick.len);
        printf("\tmstat[len=%d, DV=%d.%d, Date=%d, Owner=%d, Group=%d, Mode=0%o, linkc=%d]\n",
               vep->m.Length, vep->m.DataVersion.high, 
               vep->m.DataVersion.low, vep->m.Date, vep->m.Owner,
               vep->m.Group, vep->m.Mode, vep->m.LinkCount);
#else /* AFS33 */
        printf("%x: refC=%d, pv=%d, pu=%d, flushDv=%d, mapDV=%d, truncPos=%d\n",
               ptr, vep->vrefCount, vep->parentVnode, vep->parentUnique, vep->flushDV,
               vep->mapDV, vep->truncPos);
        printf("\tcallb=x%x, cbE=%d, opens=%d, XoW=%d, flcnt=%d, mvstat=%d\n",
               vep->callback, vep->cbExpires, vep->opens, vep->execsOrWriters,
               vep->flockCount, vep->mvstat);
        printf("\tstates=x%x, dchint=%x, anyA=0x%x\n",
               vep->states, vep->h1.dchint, vep->anyAccess);
        printf("\tmstat[len=%d, DV=%d, Date=%d, Owner=%d, Group=%d, Mode=%d, linkc=%d]\n",
               vep->m.Length, vep->m.DataVersion, vep->m.Date, vep->m.Owner,
               vep->m.Group, vep->m.Mode, vep->m.LinkCount);
#endif /* AFS33 */
#ifdef  AFS_AIX32_ENV
    loc = (afs_int32 *)&vep->pvmlock;
    printf("\tpvmlock=x%x, segid=%X, credp=%lx\n", *loc, vep->segid, vep->credp);
#endif
    printf("\tlock [wait=%x excl=%x readers=%x #waiting=%x last_reader=%d writer=%d src=%d]\n", 
           vep->lock.wait_states, vep->lock.excl_locked, vep->lock.readers_reading,
           vep->lock.num_waiting, vep->lock.pid_last_reader, vep->lock.pid_writer,
           vep->lock.src_indicator);
    print_venusfid("\tfid", &vep->fid);
    if (vep->mvid) {
        printf(" ");
        print_venusfid("mvid", &vid);
    }
    printf("\n");
    }
    if (vep->Access) {
        if (pnt) printf("\tAccess Link list: %x\n", vep->Access);
        for (j=0, acp = vep->Access; acp; acp = accp->next, j++) {
            kread(kmem, (off_t) acp, (char *)accp, sizeof(*accp));
            Sum_vcacheacc++;
            if (pnt) printf("\t   %lx: %d) uid=0x%x, access=0x%x, next=%lx\n", acp, j, accp->uid, accp->axess, accp->next);
        }
    }
    if (vep->slocks) {
        if (pnt) printf("\tLocking Link list: %lx\n", vep->slocks);
    }
#ifdef  AFS33
    if (pnt) printf("\tCallbacks queue prev= %lx next= %lx\n",
                    vep->callsort.prev, vep->callsort.next);
#endif
    printf("\tvlruq.prev=%lx, vlruq.next=%lx\n",
           vep->vlruq.prev, vep->vlruq.next);

    /* For defect 7733 - Print linkData field for symlinks */
    if (pnt) {
           if (vep->linkData) {
                cloc = (char *)vep->linkData;
                printf("\tSymlink information = '");
                while(1) {
                    kread(kmem, (off_t) cloc, &linkchar, (KDUMP_SIZE_T)1);
                    cloc++;
                    if (linkchar == '\0') {
                        printf("'\n");
                        break;
                    } else {
                        printf("%c", linkchar);
                    }
                }
           }
    }
#ifdef AFS_LINUX22_ENV
    printf("\tflushcnt=%d, mapcnt=%d\n", vep->flushcnt, vep->mapcnt);
#endif
}


void print_dcache(kmem, dcp, dp, pnt)
    int kmem, pnt;
    struct dcache *dcp, *dp;
{
    if (!pnt) return;
    printf("%lx: ", dp);
    print_venusfid(" fid", &dcp->f.fid);
    printf("refcnt=%d, flags=%x, validPos=%d\n",
           dcp->refCount, dcp->flags, dcp->validPos);

#ifdef  AFS33
    printf("\tf.modtime=%d, f.versNo=%d.%d\n",
           dcp->f.modTime, 
           dcp->f.versionNo.high, dcp->f.versionNo.low);
#else
    printf("\tf.hvn=%d, f.hcn=%d, f.modtime=%d, f.versNo=%d\n",
           dcp->f.hvNextp, dcp->f.hcNextp, dcp->f.modTime, dcp->f.versionNo);
#endif
#ifdef AFS_SGI62_ENV
    printf("\tf.chunk=%d, f.inode=%lld, f.chunkBytes=%d, f.states=%x, stamp=%x\n",
           dcp->f.chunk, dcp->f.inode, dcp->f.chunkBytes, dcp->f.states, 
           dcp->stamp);
#else
    printf("\tf.chunk=%d, f.inode=%d, f.chunkBytes=%d, f.states=%x, stamp=%x\n",
           dcp->f.chunk, dcp->f.inode, dcp->f.chunkBytes, dcp->f.states, 
           dcp->stamp);
#endif
    printf("\tlruq.prev=%lx, lruq.next=%lx, index=%d, ihint=%x\n",
           dcp->lruq.prev, dcp->lruq.next, dcp->index, dcp->ihint);
}

void print_bkg(kmem)
    int kmem;
{
    off_t symoff;
    struct brequest afs_brs[NBRS], ue,*uentry= &ue, *uep;
    afs_int32 count, i, j;
    short scount;

    printf("\n\nPrinting some background daemon info...\n\n");
    findsym ("afs_brsWaiters", &symoff);
    kread(kmem, symoff, (char *) &scount, sizeof scount);
    printf("Number of processes waiting for bkg daemon %d\n", scount);
    findsym ("afs_brsDaemons", &symoff);
    kread(kmem, symoff, (char *) &scount, sizeof scount);
    printf("Number of free bkg daemons %d\n", scount);
    findsym ("afs_brs", &symoff);
    kread(kmem, symoff, (char *) afs_brs, sizeof afs_brs);
    printf("Print the current bkg process table\n");    
    for (i=0,j=0; i < NBRS; i++, j++) {
/*      kread(kmem, (off_t) afs_brs[i], (char *)uentry, sizeof *uentry);*/
        uentry = &afs_brs[i];
        if (uentry->refCount == 0) break;
        printf("[%d] vcache=0x%lx, cred=0x%lx, code=%d, refCount=%d, opcode=%d, flags=%x [%lx, %lx, %lx, %lx]\n",
               i, uentry->vnode, uentry->cred, uentry->code, uentry->refCount, uentry->opcode, uentry->flags,
               uentry->parm[0], uentry->parm[1], uentry->parm[2], uentry->parm[3]);

    }
    printf("... found %d active 'afs_brs' entries\n", j);
}

void print_vlru(kmem)
    int kmem;
{
    off_t symoff;
    struct vcache Ve, *Ventry = &Ve, *Vep, *tvc;
    struct afs_q VLRU, vlru, *vu = &vlru, *tq, *uq;
    u_long vlru_addr, l1, l2, l3;
    afs_int32 count, i, j=0, maxvcount, vcount, nvnode;
    short scount;

    printf("\n\nPrinting vcache VLRU info (oldest first)...\n\n");
    findsym( "afs_cacheStats", &symoff);
    kread(kmem, symoff, (char *) &maxvcount, sizeof maxvcount);
#ifdef  AFS_OSF_ENV
    findsym ("afs_maxvcount", &symoff);
    kread(kmem, symoff, (char *) &maxvcount, sizeof maxvcount);
    findsym ("afs_vcount", &symoff);
    kread(kmem, symoff, (char *) &vcount, sizeof vcount);
    findsym ("max_vnodes", &symoff);
    kread(kmem, symoff, (char *) &nvnode, sizeof nvnode);
    printf("max number of vcache entries = %d\n", maxvcount);
    printf("number of vcaches in use = %d\n", vcount);
    printf("total number of system vnode entries = %d\n", nvnode);
#endif
    findsym ("VLRU", &symoff);
    kread(kmem, symoff, (char *) &VLRU, sizeof VLRU);
    vlru_addr = (u_long)symoff;
    for (tq = VLRU.prev; (u_long)tq != vlru_addr; tq = uq) {
        tvc = QTOV(tq);
        kread(kmem, (off_t)tq, (char *)vu, sizeof VLRU);
        uq = vu->prev;
        kread(kmem, (off_t)tvc, (char *)Ventry, sizeof *Ventry);
        print_vcache(kmem, Ventry, tvc, 1);
        j++;
    }
    printf("... found %d active vcache entries in the VLRU\n", j);
}

void print_dlru(kmem)
    int kmem;
{
    off_t symoff;
    struct dcache Ve, *Ventry = &Ve, *Vep, *tdc;
    struct afs_q DLRU, dlru, *vu = &dlru, *tq, *uq;
    u_long dlru_addr, l1, l2, l3;
    afs_int32 count, i, j=0, maxvcount, vcount, nvnode;
    short scount;

    printf("\n\nPrinting vcache DLRU info...\n\n");
    findsym ("afs_DLRU", &symoff);
    kread(kmem, symoff, (char *) &DLRU, sizeof DLRU);
    dlru_addr = (u_long)symoff;
    for (tq = DLRU.prev; (u_long)tq != dlru_addr; tq = uq) {
        tdc = (struct dcache *) tq;
        kread(kmem, (off_t)tq, (char *)vu, sizeof DLRU);
        uq = vu->prev;
        kread(kmem, (off_t)tdc, (char *)Ventry, sizeof *Ventry);
        print_dcache(kmem, Ventry, tdc, 1);
        j++;
    }
    printf("... found %d active dcache entries in the DLRU\n\n\n", j);

    findsym("afs_freeDSList", &symoff);
    kread(kmem, symoff, (char *) &dlru_addr, sizeof dlru_addr);
    printf("\tfreeDSList link list starts at 0x%x\n", dlru_addr);
    j=0;
    for (tdc = (struct dcache *)dlru_addr; tdc; tdc = (struct dcache *)Ventry->lruq.next) {
        kread(kmem, (off_t)tdc, (char *)Ventry, sizeof *Ventry);
        print_dcache(kmem, Ventry, tdc, 1);
        j++;
/*      printf("%3d) %x\n", j, tdc);*/
    }
    printf("... found %d dcache entries in the freeDSList\n", j);
}

int print_gcpags(pnt)
int pnt;
{
    off_t symoff;
    afs_int32 afs_gcpags;
    afs_int32 afs_gcpags_procsize;

    if (pnt) printf("\n\nPrinting GCPAGS structures...\n");

    findsym( "afs_gcpags", &symoff);
    kread(kmem, symoff, (char*)&afs_gcpags, sizeof afs_gcpags);

    findsym( "afs_gcpags_procsize", &symoff);
    kread(kmem, symoff, (char*)&afs_gcpags_procsize, sizeof afs_gcpags_procsize);

    printf("afs_gcpags=%d\n", afs_gcpags);
    printf("afs_gcpags_procsize=%d\n", afs_gcpags_procsize);

    return 0;
}


#ifdef  AFS_AIX_ENV
#include <sys/syspest.h>/* to define the assert and ASSERT macros       */
#include <sys/timer.h>  /* For the timer related defines                */
#include <sys/intr.h>   /* for the serialization defines                */
#include <sys/malloc.h> /* for the parameters to xmalloc()              */

struct  tos     {
        struct  tos     *toprev;        /* previous tos in callout table*/
        struct  tos     *tonext;        /* next tos in callout table    */
        struct  trb     *trb;           /* this timer request block     */
        afs_int32       type;
        long    p1;
};

struct  callo   {
        int     ncallo;         /* number of callout table elements     */
        struct  tos     *head;  /* callout table head element           */
};
#endif

void print_callout(kmem)
    int kmem;
{
    off_t symoff;
#ifndef AFS_AIX_ENV
    printf("\n\nCallout table doesn't exist for this system\n");
#else
    struct callo Co, *Coe = &Co, *Cop;
    struct tos To, *Toe = &To, *tos;
    struct trb Trb, *Trbe = &Trb, *trb;
    register int i =0;


    printf("\n\nPrinting callout table info...\n\n");
    findsym ("afs_callo", &symoff);
    kread(kmem, symoff, (char *) &Co, sizeof Co);
    printf("Number of callouts %d\n", Co.ncallo);
    if (Co.ncallo > 0) {
        printf("Count\tType\taddr\tfunc\tdata\n");
        for (tos = Co.head; tos != NULL; tos = Toe->tonext)  {
            i++;
            kread(kmem, (off_t) tos, (char *) &To, sizeof To);
            kread(kmem, (off_t) Toe->trb, (char *) &Trb, sizeof Trb);
            printf("%d\t%d\t%x\t%x\t%x\n", i, Toe->type, Toe->p1, Trbe->tof, Trbe->func_data);
        }
    }
#endif
}

void print_dnlc(kmem)
    int kmem;
{
  struct nc * nameHash[256];

}


void print_global_locks(kmem)
    int kmem;
{
    off_t symoff;
    afs_int32 count;
    int i;
    static struct {
      char *name;
    } locks[] = {     { "afs_xvcache" },
                        { "afs_xdcache" },
                        { "afs_xserver" },
                        { "afs_xvcb" },
                        { "afs_xbrs" },
                        { "afs_xcell" },
                        { "afs_xconn" },
                        { "afs_xuser" },
                        { "afs_xvolume" },
#ifndef AFS_AIX_ENV
                        { "osi_fsplock" },
#endif
                        { "osi_flplock" },
                        { "afs_xcbhash" },
                        { "afs_xinterface" },

                        { 0 },
                        };


    printf("\n\nPrinting afs global locks...\n\n");
    for (i=0; locks[i].name; i++) { 
      findsym( locks[i].name, &symoff);
      kread(kmem, symoff, (char *) &count, sizeof count);
      printf("%s = 0x%x\n", locks[i].name, count);
    }
}


void print_global_afs_resource(kmem)
    int kmem;
{
    off_t symoff;
    char sysname[100];
    afs_int32 count;
    long addr;

    printf("\n\nPrinting some general resource related globals...\n\n");
    findsym ("afs_setTimeHost",&symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_setTimeHost = 0x%x\n", count);
    findsym("afs_volCounter", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_volCounter = 0x%x\n", count);
    findsym("afs_cellindex", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_cellIndex = 0x%x\n", count);
    findsym("afs_marinerHost", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_marinerHost = 0x%x\n", count);
    findsym("afs_sysname", &symoff);
    kread(kmem, symoff, (char *) &addr, sizeof addr);
#ifdef  AFS_HPUX_ENV
    printf("\tafs_sysname = %d\n", addr);
#else
    kread(kmem, (off_t)addr, sysname, (KDUMP_SIZE_T)30);
    printf("\tafs_sysname = %s\n", sysname);
#endif
#ifdef AFS_SGI65_ENV
    findsym("afs_ipno", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tCPU BOARD = IP%d\n", count);
#endif
}


void print_global_afs_cache(kmem)
    int kmem;
{
    off_t symoff;
    char sysname[100];
    afs_int32 count;
#ifdef AFS_SGI62_ENV
    ino64_t inode;
#endif    
#ifndef AFS32
    afs_hyper_t h;
#endif

    printf("\n\nPrinting some general cache related globals...\n\n");
    findsym("afs_mariner", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_mariner = 0x%x\n", count);
#ifndef AFS_OSF_ENV
    findsym("freeVCList", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_freeVCList = 0x%x XXX\n", count);
#endif
    findsym("afs_freeDCList", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tfreeDCList = 0x%x\n", count);
    findsym("afs_freeDCCount", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tfreeDCCount = 0x%x (%d)\n", count, count);
    findsym("afs_discardDCList", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tdiscardDCList = 0x%x\n", count);
    findsym("afs_discardDCCount", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tdiscardDCCount = 0x%x (%d)\n", count, count);
    findsym("afs_freeDSList", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tfreeDSList= 0x%x XXXX\n", count);
#ifdef AFS_SGI62_ENV
    findsym("cacheInode", &symoff);
    kread(kmem, symoff, (char *) &inode, sizeof inode);
    printf("\tcacheInode = 0x%llx (%lld)\n", inode, inode);
    findsym("volumeInode", &symoff);
    kread(kmem, symoff, (char *) &inode, sizeof inode);
    printf("\tvolumeInode = 0x%llx (%lld)\n", inode, inode);
#else
    findsym("cacheInode", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tcacheInode = 0x%x (%d)\n", count, count);
    findsym("volumeInode", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tvolumeInode = 0x%x (%d)\n", count, count);
#endif
    findsym("cacheDiskType", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tcacheDiskType = 0x%x (%d)\n", count, count);
#ifndef AFS32
    findsym("afs_indexCounter", &symoff);
    kread(kmem, symoff, (char *) &h, sizeof (struct afs_hyper_t));
    printf("\tafs_indexCounter = 0x%X.%X (%d.%d)\n", h.high, h.low, h.high, h.low);
#endif
    findsym("afs_cacheFiles", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_cacheFiles = 0x%x (%d)\n", count, count);
    findsym("afs_cacheBlocks", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_cacheBlocks = 0x%x (%d)\n", count, count);
    findsym("afs_cacheStats", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_cacheStats = 0x%x (%d)\n", count, count);
    findsym("afs_blocksUsed", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_blocksUsed = 0x%x (%d)\n", count, count);
    findsym("afs_blocksDiscarded", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_blocksDiscarded = 0x%x (%d)\n", count, count);
    findsym("afs_fsfragsize", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_fsfragsize = 0x%x\n", count);
    findsym("afs_WaitForCacheDrain", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_WaitForCacheDrain = 0x%x (%d)\n", count, count);
    findsym("afs_CacheTooFull", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\tafs_CacheTooFull = 0x%x (%d)\n", count, count);


    if (findsym("pagCounter", &symoff)) {
        kread(kmem, symoff, (char *) &count, sizeof count);
        printf("\tpagCounter = 0x%x (%d)\n", count, count);
    } else {
        printf("Ignoring pagCounter\n");
    }
}


void print_rxstats(kmem)
    int kmem;
{
    off_t symoff;
    char sysname[100];
    afs_int32 count, i;
    struct rx_stats rx_stats;

    printf("\n\nPrinting some general RX stats...\n\n");
    findsym("rx_stats", &symoff);
    kread(kmem, symoff, (char *) &rx_stats, sizeof rx_stats);
    printf("\t\tpacketRequests = %d\n", rx_stats.packetRequests);
    printf("\t\tnoPackets[%d] = %d\n", RX_PACKET_CLASS_RECEIVE,
           rx_stats.receivePktAllocFailures);
    printf("\t\tnoPackets[%d] = %d\n", RX_PACKET_CLASS_SEND,
           rx_stats.sendPktAllocFailures);
    printf("\t\tnoPackets[%d] = %d\n", RX_PACKET_CLASS_SPECIAL,
           rx_stats.specialPktAllocFailures);
    printf("\t\tnoPackets[%d] = %d\n", RX_PACKET_CLASS_RECV_CBUF,
           rx_stats.receiveCbufPktAllocFailures);
    printf("\t\tnoPackets[%d] = %d\n", RX_PACKET_CLASS_SEND_CBUF,
           rx_stats.sendCbufPktAllocFailures);
    printf("\t\tsocketGreedy = %d\n", rx_stats.socketGreedy);
    printf("\t\tbogusPacketOnRead = %d\n", rx_stats.bogusPacketOnRead);
    printf("\t\tbogusHost = %d\n", rx_stats.bogusHost);
    printf("\t\tnoPacketOnRead = %d\n", rx_stats.noPacketOnRead);
    printf("\t\tnoPacketBuffersOnRead = %d\n", rx_stats.noPacketBuffersOnRead);
    printf("\t\tselects = %d\n", rx_stats.selects);
    printf("\t\tsendSelects = %d\n", rx_stats.sendSelects);
    for (i=0; i < RX_N_PACKET_TYPES; i++)
        printf("\t\tpacketsRead[%d] = %d\n", i, rx_stats.packetsRead[i]);
    printf("\t\tdataPacketsRead = %d\n", rx_stats.dataPacketsRead);
    printf("\t\tackPacketsRead = %d\n", rx_stats.ackPacketsRead);
    printf("\t\tdupPacketsRead = %d\n", rx_stats.dupPacketsRead);
    printf("\t\tspuriousPacketsRead = %d\n", rx_stats.spuriousPacketsRead);
    for (i=0; i < RX_N_PACKET_TYPES; i++)
        printf("\t\tpacketsSent[%d] = %d\n", i, rx_stats.packetsSent[i]);
    printf("\t\tackPacketsSent = %d\n", rx_stats.ackPacketsSent);
    printf("\t\tpingPacketsSent = %d\n", rx_stats.pingPacketsSent);
    printf("\t\tabortPacketsSent = %d\n", rx_stats.abortPacketsSent);
    printf("\t\tbusyPacketsSent = %d\n", rx_stats.busyPacketsSent);
    printf("\t\tdataPacketsSent = %d\n", rx_stats.dataPacketsSent);
    printf("\t\tdataPacketsReSent = %d\n", rx_stats.dataPacketsReSent);
    printf("\t\tdataPacketsPushed = %d\n", rx_stats.dataPacketsPushed);
    printf("\t\tignoreAckedPacket = %d\n", rx_stats.ignoreAckedPacket);
    printf("\t\ttotalRtt = %d sec, %d usec\n", rx_stats.totalRtt.sec, rx_stats.totalRtt.usec);
    printf("\t\tminRtt = %d sec, %d usec\n", rx_stats.minRtt.sec, rx_stats.minRtt.usec);
    printf("\t\tmaxRtt = %d sec, %d usec\n", rx_stats.maxRtt.sec, rx_stats.maxRtt.usec);
    printf("\t\tnRttSamples = %d\n", rx_stats.nRttSamples);
    printf("\t\tnServerConns = %d\n", rx_stats.nServerConns);
    printf("\t\tnClientConns = %d\n", rx_stats.nClientConns);
    printf("\t\tnPeerStructs = %d\n", rx_stats.nPeerStructs);
    printf("\t\tnCallStructs = %d\n", rx_stats.nCallStructs);
    printf("\t\tnFreeCallStructs = %d\n", rx_stats.nFreeCallStructs);
    printf("\t\tnetSendFailures  = %d\n", rx_stats.netSendFailures);
    printf("\t\tfatalErrors      = %d\n", rx_stats.fatalErrors);
}


void print_rx(kmem)
    int kmem;
{
    off_t symoff;
    char sysname[100], c;
    afs_int32 count, i, ar[100];
    short sm;
    struct rx_stats rx_stats;

    printf("\n\nPrinting some RX globals...\n\n");
    findsym("rx_extraQuota", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trx_extraQuota = %d\n", count);
    findsym("rx_extraPackets", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trx_extraPackets = %d\n", count);
    findsym("rx_stackSize", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trx_stackSize = %d\n", count);
    findsym("rx_connDeadTime", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_connDeadTime = %d\n", count);
    findsym("rx_idleConnectionTime", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_idleConnectionTime = %d\n", count);

    findsym("rx_idlePeerTime", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trx_idlePeerTime = %d\n", count);

    findsym("rx_initSendWindow", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trx_initSendWindow = %d\n", count);

    findsym("rxi_nSendFrags", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);
    printf("\trxi_nSendFrags = %d\n", count);

    findsym("rx_nPackets", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_nPackets = %d\n", count);
    findsym("rx_nFreePackets", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_nFreePackets = %d\n", count);
    findsym("rx_socket", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_socket = 0x%x\n", count);
    findsym("rx_port", &symoff);
    kread(kmem, symoff, (char *) &sm, sizeof sm);

    printf("\trx_Port = %d\n", sm);
    findsym("rx_packetQuota", &symoff);
    kread(kmem, symoff, (char *) ar, sizeof ar);

    for (i=0; i < RX_N_PACKET_CLASSES; i++)
        printf("\trx_packetQuota[%d] = %d\n", i, ar[i]);
    findsym("rx_nextCid", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_nextCid = 0x%x\n", count);
    findsym("rx_epoch", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trx_epoch = 0u%u\n", count);
    findsym("rx_waitingForPackets", &symoff);
    kread(kmem, symoff, (char *) &c, sizeof(c));

    printf("\trx_waitingForPackets = %x\n", (int)c);
    findsym("rxi_nCalls", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trxi_nCalls = %d\n", count);
    findsym("rxi_dataQuota", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trxi_dataQuota = %d\n", count);
#ifdef  AFS_AIX_ENV
    if (findsym("rxi_Alloccnt", &symoff)) {
        kread(kmem, symoff, (char *) &count, sizeof count);
        printf("\trxi_Alloccnt = %d\n", count);
    }

    if (findsym("rxi_Allocsize", &symoff)) {
        kread(kmem, symoff, (char *) &count, sizeof count);
        printf("\trxi_Allocsize = %d\n", count);
    }
#endif
    findsym("rxi_availProcs", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trxi_availProcs = %d\n", count);
    findsym("rxi_totalMin", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trxi_totalMin = %d\n", count);
    findsym("rxi_minDeficit", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof count);

    printf("\trxi_minDeficit = %d\n", count);
    print_services(kmem);
#ifdef KDUMP_RX_LOCK
    if (use_rx_lock) {
        print_peertable_lock(kmem);
        print_conntable_lock(kmem);
        print_calltable_lock(kmem);
    }
    else {
        print_peertable(kmem);
        print_conntable(kmem);
        print_calltable(kmem);
    }
#else
    print_peertable(kmem);
    print_conntable(kmem);
    print_calltable(kmem);
#endif
    print_eventtable(kmem);
    print_rxstats(kmem);
}


void print_services(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_service *rx_services[RX_MAX_SERVICES], se, *sentry = &se, *sep;
    char sysname[100];
    afs_int32 count, i, j;

    findsym("rx_services", &symoff);
    kread(kmem, symoff, (char *) rx_services, RX_MAX_SERVICES * sizeof(long));

    printf("\n\nPrinting all 'rx_services' structures...\n");
    for (i=0, j=0; i < RX_MAX_SERVICES; i++) {
        if (rx_services[i]) {
            j++;
            kread(kmem, (off_t) rx_services[i], (char *)sentry, sizeof *sentry);
            kread(kmem, (off_t) sentry->serviceName, sysname,
                  (KDUMP_SIZE_T)40);        
            printf("\t%lx: serviceId=%d, port=%d, serviceName=%s, socket=0x%x\n",
                   rx_services[i], sentry->serviceId, sentry->servicePort, sysname, sentry->socket);
            printf("\t\tnSecObj=%d, nReqRunning=%d, maxProcs=%d, minProcs=%d, connDeadTime=%d, idleDeadTime=%d\n",
                   sentry->nSecurityObjects, sentry->nRequestsRunning, sentry->maxProcs, sentry->minProcs,
                   sentry->connDeadTime, sentry->idleDeadTime);
        }
    }
    printf("... found %d 'rx_services' entries in the table\n", j);
}


#ifdef KDUMP_RX_LOCK
void print_peertable_lock(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_peer_rx_lock *rx_peerTable[256], se, *sentry = &se, *sep;
    long count, i, j;

    findsym("rx_peerHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));
    if (!count) {
        printf("No 'rx_peer' structures found.\n");
        return;
    }
    
    kread(kmem, count, (char *) rx_peerTable, 256 * sizeof(long));
    printf("\n\nPrinting all 'rx_peer' structures...\n");
    for (i=0, j=0; i < 256; i++) {
        for (sep = rx_peerTable[i]; sep; sep = sentry->next, j++) {
            kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
            printf("\t%lx: next=0x%lx, host=0x%x, ",
                   sep, sentry->next, sentry->host);
            printf("ifMTU=%d, natMTU=%d, maxMTU=%d\n", sentry->ifMTU,
                   sentry->natMTU, sentry->maxMTU);
            printf("\t\trtt=%d:%d, timeout(%d:%d), nSent=%d, reSends=%d\n",
                   sentry->rtt, sentry->rtt_dev,
                   sentry->timeout.sec, sentry->timeout.usec,
                   sentry->nSent, sentry->reSends);
            printf("\t\trefCount=%d, port=%d, idleWhen=0x%x\n", 
                   sentry->refCount, sentry->port, sentry->idleWhen);
            printf("\t\tCongestionQueue (0x%x:0x%x), inPacketSkew=0x%x, outPacketSkew=0x%x\n",
                   sentry->congestionQueue.prev, sentry->congestionQueue.next, 
                   sentry->inPacketSkew, sentry->outPacketSkew);
            printf("\t\tpeer_lock=%d\n", sentry->peer_lock);
        }
    }
    printf("... found %d 'rx_peer' entries in the table\n", j);
}

#endif /* KDUMP_RX_LOCK */
void print_peertable(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_peer *rx_peerTable[256], se, *sentry = &se, *sep;
    long count, i, j;

    findsym("rx_peerHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));

    kread(kmem, count, (char *) rx_peerTable, 256 * sizeof(long));
    printf("\n\nPrinting all 'rx_peer' structures...\n");
    for (i=0, j=0; i < 256; i++) {
        for (sep = rx_peerTable[i]; sep; sep = sentry->next, j++) {
            kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
            printf("\t%lx: next=0x%lx, host=0x%x, ",
                   sep, sentry->next, sentry->host);
            printf("ifMTU=%d, natMTU=%d, maxMTU=%d\n", sentry->ifMTU,
                   sentry->natMTU, sentry->maxMTU);
            printf("\t\trtt=%d:%d, timeout(%d:%d), nSent=%d, reSends=%d\n",
                   sentry->rtt, sentry->rtt_dev,
                   sentry->timeout.sec, sentry->timeout.usec,
                   sentry->nSent, sentry->reSends);
            printf("\t\trefCount=%d, port=%d, idleWhen=0x%x\n", 
                   sentry->refCount, sentry->port, sentry->idleWhen);
            printf("\t\tCongestionQueue (0x%x:0x%x), inPacketSkew=0x%x, outPacketSkew=0x%x\n",
                   sentry->congestionQueue.prev, sentry->congestionQueue.next, 
                   sentry->inPacketSkew, sentry->outPacketSkew);
#ifdef RX_ENABLE_LOCKS
            printf("\t\tpeer_lock=%d\n", sentry->peer_lock);
#endif /* RX_ENABLE_LOCKS */
        }
    }
    printf("... found %d 'rx_peer' entries in the table\n", j);
}


#ifdef KDUMP_RX_LOCK
void print_conntable_lock(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_connection_rx_lock *rx_connTable[256], se, *sentry = &se;
    struct rx_connection_rx_lock *sep;
    long count, i, j;

    findsym("rx_connHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));
    if (!count) {
        printf("No 'rx_connection' structures found.\n");
        return;
    }

    kread(kmem, count, (char *) rx_connTable, 256 * sizeof(long));
    printf("\n\nPrinting all 'rx_connection' structures...\n");
    for (i=0, j=0; i < 256; i++) {
       for (sep = rx_connTable[i]; sep; sep = sentry->next, j++) {
          kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
          printf("\t%lx: next=0x%lx, peer=0x%lx, epoch=0x%x, cid=0x%x, ackRate=%d\n",
                 sep, se.next, se.peer, se.epoch, se.cid, se.ackRate);
          printf("\t\tcall[%x=%d, %x=%d, %x=%d, %x=%d]\n",
                 se.call[0], se.callNumber[0],
                 se.call[1], se.callNumber[1],
                 se.call[2], se.callNumber[2],
                 se.call[3], se.callNumber[3]);
          printf("\t\ttimeout=%d, flags=0x%x, type=0x%x, serviceId=%d, service=0x%lx, refCount=%d\n",
                 se.timeout, se.flags, se.type, se.serviceId, se.service, se.refCount);
          printf("\t\tserial=%d, lastSerial=%d, secsUntilDead=%d, secsUntilPing=%d, secIndex=%d\n",
                 se.serial, se.lastSerial, se.secondsUntilDead,
                 se.secondsUntilPing, se.securityIndex);
          printf("\t\terror=%d, secObject=0x%lx, secData=0x%lx, secHeaderSize=%d, secmaxTrailerSize=%d\n", 
                 se.error, se.securityObject, se.securityData,
                 se.securityHeaderSize, se.securityMaxTrailerSize);
          printf("\t\tchallEvent=0x%lx, lastSendTime=0x%x, maxSerial=%d, hardDeadTime=%d\n", 
                 se.challengeEvent, se.lastSendTime, 
                 se.maxSerial, se.hardDeadTime);
          if (se.flags & RX_CONN_MAKECALL_WAITING)
            printf("\t\t***** Conn in RX_CONN_MAKECALL_WAITING state *****\n");
          printf("\t\tcall_lock=%d, call_cv=%d, data_lock=%d, refCount=%d\n",
                 se.conn_call_lock, se.conn_call_cv, se.conn_data_lock,
                 se.refCount);
        }
    }
    printf("... found %d 'rx_connection' entries in the table\n", j);
}
#endif /* KDUMP_RX_LOCK */

void print_conntable(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_connection *rx_connTable[256], se, *sentry = &se, *sep;
    long count, i, j;

    findsym("rx_connHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));

    kread(kmem, count, (char *) rx_connTable, 256 * sizeof(long));
    printf("\n\nPrinting all 'rx_connection' structures...\n");
    for (i=0, j=0; i < 256; i++) {
       for (sep = rx_connTable[i]; sep; sep = sentry->next, j++) {
          kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
          printf("\t%lx: next=0x%lx, peer=0x%lx, epoch=0x%x, cid=0x%x, ackRate=%d\n",
                 sep, se.next, se.peer, se.epoch, se.cid, se.ackRate);
          printf("\t\tcall[%x=%d, %x=%d, %x=%d, %x=%d]\n",
                 se.call[0], se.callNumber[0],
                 se.call[1], se.callNumber[1],
                 se.call[2], se.callNumber[2],
                 se.call[3], se.callNumber[3]);
          printf("\t\ttimeout=%d, flags=0x%x, type=0x%x, serviceId=%d, service=0x%lx, refCount=%d\n",
                 se.timeout, se.flags, se.type, se.serviceId, se.service, se.refCount);
          printf("\t\tserial=%d, lastSerial=%d, secsUntilDead=%d, secsUntilPing=%d, secIndex=%d\n",
                 se.serial, se.lastSerial, se.secondsUntilDead,
                 se.secondsUntilPing, se.securityIndex);
          printf("\t\terror=%d, secObject=0x%lx, secData=0x%lx, secHeaderSize=%d, secmaxTrailerSize=%d\n", 
                 se.error, se.securityObject, se.securityData,
                 se.securityHeaderSize, se.securityMaxTrailerSize);
          printf("\t\tchallEvent=0x%lx, lastSendTime=0x%x, maxSerial=%d, hardDeadTime=%d\n", 
                 se.challengeEvent, se.lastSendTime, 
                 se.maxSerial, se.hardDeadTime);
          if (se.flags & RX_CONN_MAKECALL_WAITING)
            printf("\t\t***** Conn in RX_CONN_MAKECALL_WAITING state *****\n");
#ifdef RX_ENABLE_LOCKS
          printf("\t\tcall_lock=%d, call_cv=%d, data_lock=%d, refCount=%d\n",
                 se.conn_call_lock, se.conn_call_cv, se.conn_data_lock,
                 se.refCount);
#endif /* RX_ENABLE_LOCKS */
        }
    }
    printf("... found %d 'rx_connection' entries in the table\n", j);
}


#ifdef KDUMP_RX_LOCK
void print_calltable_lock(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_connection_rx_lock *rx_connTable[256], se;
    struct rx_connection_rx_lock *sentry = &se;
    struct rx_connection_rx_lock *sep;
    long count, i, j, k;

    findsym("rx_connHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));
    if (!count) {
        printf("No 'rx_call' structures found.\n");
        return;
    }

    kread(kmem, count, (char *) rx_connTable, 256 * sizeof(long));
    printf("\n\nPrinting all active 'rx_call' structures...\n");
    for (i=0, j=0; i < 256; i++) {
        for (sep = rx_connTable[i]; sep; sep = se.next) {
            kread(kmem, (off_t) sep, (char *)sentry, sizeof *sentry);
            for (k = 0; k < RX_MAXCALLS; k++) {
                struct rx_call_rx_lock ce, *centry = &ce;
                struct rx_call_rx_lock *call = se.call[k];
                if (call) {
                    j++;
                    kread(kmem, (off_t) call, (char *)centry, sizeof *centry);
                    printf("\t%lx: conn=0x%lx, qiheader(0x%lx:0x%lx), tq(0x%lx:0x%lx), rq(0x%lx:0x%lx)\n",
                           call, centry->conn, centry->queue_item_header.prev, centry->queue_item_header.next,
                           centry->tq.prev, centry->tq.next, centry->rq.prev, centry->rq.next);
                    printf("\t\t: curvec=%d, curpos=%d, nLeft=%d, nFree=%d, currPacket=0x%lx, callNumber=0x%x\n",
                           centry->curvec, centry->curpos, centry->nLeft, centry->nFree, centry->currentPacket, centry->callNumber);
                    printf("\t\t: channel=%d, state=0x%x, mode=0x%x, flags=0x%x, localStatus=0x%x, remStatus=0x%x\n",               
                           centry->channel, centry->state, centry->mode, centry->flags, centry->localStatus,
                           centry->remoteStatus);
                    printf("\t\t: error=%d, timeout=0x%x, rnext=0x%x, rprev=0x%x, rwind=0x%x, tfirst=0x%x, tnext=0x%x\n",
                           centry->error, centry->timeout, centry->rnext, centry->rprev, centry->rwind, centry->tfirst,
                           centry->tnext);
                    printf("\t\t: twind=%d, resendEvent=0x%lx, timeoutEvent=0x%lx, keepAliveEvent=0x%lx, delayedAckEvent=0x%lx\n",
                           centry->twind, centry->resendEvent, centry->timeoutEvent, centry->keepAliveEvent, 
                           centry->delayedAckEvent);
                    printf("\t\t: lastSendTime=0x%x, lastReceiveTime=0x%x, lastAcked=0x%x, startTime=0x%x, startWait=0x%x\n",
                           centry->lastSendTime, centry->lastReceiveTime, centry->lastAcked, centry->startTime, centry->startWait);
                    if (centry->flags & RX_CALL_WAIT_PROC)
                        printf("\t\t******** Call in RX_CALL_WAIT_PROC state **********\n");
                    if (centry->flags & RX_CALL_WAIT_WINDOW_ALLOC)
                        printf("\t\t******** Call in RX_CALL_WAIT_WINDOW_ALLOC state **********\n");
                    if (centry->flags & RX_CALL_READER_WAIT)
                        printf("\t\t******** Conn in RX_CALL_READER_WAIT state **********\n");
                    if (centry->flags & RX_CALL_WAIT_PACKETS)
                        printf("\t\t******** Conn in RX_CALL_WAIT_PACKETS state **********\n");
                    printf("\t\t: lock=0x%x, cv_twind=0x%x, cv_rq=0x%x, refCount=%d\n",
                           centry->lock, centry->cv_twind, centry->cv_rq,
                           centry->refCount);
                    printf("\t\t: MTU=%d\n", centry->MTU);
                }
            }
        }
    }
    printf("... found %d 'rx_call' entries in the table\n", j);
}
#endif /* KDUMP_RX_LOCK */

void print_calltable(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_connection *rx_connTable[256], se, *sentry = &se, *sep;
    long count, i, j, k;

    findsym("rx_connHashTable", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(long));

    kread(kmem, count, (char *) rx_connTable, 256 * sizeof(long));
    printf("\n\nPrinting all active 'rx_call' structures...\n");
    for (i=0, j=0; i < 256; i++) {
        for (sep = rx_connTable[i]; sep; sep = se.next) {
            kread(kmem, (off_t)sep, (char *)sentry, sizeof *sentry);
            for (k = 0; k < RX_MAXCALLS; k++) {
                struct rx_call ce, *centry = &ce, *call = se.call[k];
                if (call) {
                    j++;
                    kread(kmem, (off_t)call, (char *)centry, sizeof *centry);
                    printf("\t%lx: conn=0x%lx, qiheader(0x%lx:0x%lx), tq(0x%lx:0x%lx), rq(0x%lx:0x%lx)\n",
                           call, centry->conn, centry->queue_item_header.prev, centry->queue_item_header.next,
                           centry->tq.prev, centry->tq.next, centry->rq.prev, centry->rq.next);
                    printf("\t\t: curvec=%d, curpos=%d, nLeft=%d, nFree=%d, currPacket=0x%lx, callNumber=0x%x\n",
                           centry->curvec, centry->curpos, centry->nLeft, centry->nFree, centry->currentPacket, centry->callNumber);
                    printf("\t\t: channel=%d, state=0x%x, mode=0x%x, flags=0x%x, localStatus=0x%x, remStatus=0x%x\n",               
                           centry->channel, centry->state, centry->mode, centry->flags, centry->localStatus,
                           centry->remoteStatus);
                    printf("\t\t: error=%d, timeout=0x%x, rnext=0x%x, rprev=0x%x, rwind=0x%x, tfirst=0x%x, tnext=0x%x\n",
                           centry->error, centry->timeout, centry->rnext, centry->rprev, centry->rwind, centry->tfirst,
                           centry->tnext);
                    printf("\t\t: twind=%d, resendEvent=0x%lx, timeoutEvent=0x%lx, keepAliveEvent=0x%lx, delayedAckEvent=0x%lx\n",
                           centry->twind, centry->resendEvent, centry->timeoutEvent, centry->keepAliveEvent, 
                           centry->delayedAckEvent);
                    printf("\t\t: lastSendTime=0x%x, lastReceiveTime=0x%x, lastAcked=0x%x, startTime=0x%x, startWait=0x%x\n",
                           centry->lastSendTime, centry->lastReceiveTime, centry->lastAcked, centry->startTime, centry->startWait);
                    if (centry->flags & RX_CALL_WAIT_PROC)
                        printf("\t\t******** Call in RX_CALL_WAIT_PROC state **********\n");
                    if (centry->flags & RX_CALL_WAIT_WINDOW_ALLOC)
                        printf("\t\t******** Call in RX_CALL_WAIT_WINDOW_ALLOC state **********\n");
                    if (centry->flags & RX_CALL_READER_WAIT)
                        printf("\t\t******** Conn in RX_CALL_READER_WAIT state **********\n");
                    if (centry->flags & RX_CALL_WAIT_PACKETS)
                        printf("\t\t******** Conn in RX_CALL_WAIT_PACKETS state **********\n");
#ifdef RX_ENABLE_LOCKS
                    printf("\t\t: lock=0x%x, cv_twind=0x%x, cv_rq=0x%x, refCount=%d\n",
                           centry->lock, centry->cv_twind, centry->cv_rq,
                           centry->refCount);
#endif /* RX_ENABLE_LOCKS */
                    printf("\t\t: MTU=%d\n", centry->MTU);
                }
            }
        }
    }
    printf("... found %d 'rx_call' entries in the table\n", j);
}

void print_eventtable(kmem)
    afs_int32 kmem;
{
    off_t symoff;
    struct rx_queue epq;
    struct rx_queue evq;
    char *epend, *evend;
    afs_int32 count, i, j=0, k=0;

#if ! defined(AFS_HPUX_ENV) && ! defined(AFS_AIX_ENV)
    findsym("rxevent_nFree", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(afs_int32));
    printf("\n\n\trxevent_nFree = %d\n", count);

    findsym("rxevent_nPosted", &symoff);
    kread(kmem, symoff, (char *) &count, sizeof(afs_int32));
    printf("\trxevent_nPosted = %d\n", count);
#endif
}

/*
 * print_upDownStats
 *
 * Print the up/downtime stats for the given class of server records
 * provided.
 */
void print_upDownStats(a_upDownP)
    struct afs_stats_SrvUpDownInfo *a_upDownP;  /*Ptr to server up/down info*/

{ /*print_upDownStats*/

    /*
     * First, print the simple values.
     */
    printf("\t\t%10d numTtlRecords\n",          a_upDownP->numTtlRecords);
    printf("\t\t%10d numUpRecords\n",           a_upDownP->numUpRecords);
    printf("\t\t%10d numDownRecords\n",         a_upDownP->numDownRecords);
    printf("\t\t%10d sumOfRecordAges\n",        a_upDownP->sumOfRecordAges);
    printf("\t\t%10d ageOfYoungestRecord\n",    a_upDownP->ageOfYoungestRecord);
    printf("\t\t%10d ageOfOldestRecord\n",      a_upDownP->ageOfOldestRecord);
    printf("\t\t%10d numDowntimeIncidents\n",   a_upDownP->numDowntimeIncidents);
    printf("\t\t%10d numRecordsNeverDown\n",    a_upDownP->numRecordsNeverDown);
    printf("\t\t%10d maxDowntimesInARecord\n",  a_upDownP->maxDowntimesInARecord);
    printf("\t\t%10d sumOfDowntimes\n",         a_upDownP->sumOfDowntimes);
    printf("\t\t%10d shortestDowntime\n",       a_upDownP->shortestDowntime);
    printf("\t\t%10d longestDowntime\n",        a_upDownP->longestDowntime);

    /*
     * Now, print the array values.
     */
    printf("\t\tDowntime duration distribution:\n");
    printf("\t\t\t%8d: 0 min .. 10 min\n",  a_upDownP->downDurations[0]);
    printf("\t\t\t%8d: 10 min .. 30 min\n", a_upDownP->downDurations[1]);
    printf("\t\t\t%8d: 30 min .. 1 hr\n",   a_upDownP->downDurations[2]);
    printf("\t\t\t%8d: 1 hr .. 2 hr\n",     a_upDownP->downDurations[3]);
    printf("\t\t\t%8d: 2 hr .. 4 hr\n",     a_upDownP->downDurations[4]);
    printf("\t\t\t%8d: 4 hr .. 8 hr\n",     a_upDownP->downDurations[5]);
    printf("\t\t\t%8d: > 8 hr\n",           a_upDownP->downDurations[6]);

    printf("\t\tDowntime incident distribution:\n");
    printf("\t\t\t%8d: 0 times\n",        a_upDownP->downIncidents[0]);
    printf("\t\t\t%8d: 1 time\n",         a_upDownP->downDurations[1]);
    printf("\t\t\t%8d: 2 .. 5 times\n",   a_upDownP->downDurations[2]);
    printf("\t\t\t%8d: 6 .. 10 times\n",  a_upDownP->downDurations[3]);
    printf("\t\t\t%8d: 10 .. 50 times\n", a_upDownP->downDurations[4]);
    printf("\t\t\t%8d: > 50 times\n",     a_upDownP->downDurations[5]);
} /*print_upDownStats*/


void print_cmperfstats(perfP)
    struct afs_stats_CMPerf *perfP;
{
    struct afs_stats_SrvUpDownInfo *upDownP;    /*Ptr to server up/down info*/

    printf("\t%10d numPerfCalls\n",             perfP->numPerfCalls);
    printf("\t%10d epoch\n",                    perfP->epoch);
    printf("\t%10d numCellsVisible\n",          perfP->numCellsVisible);
    printf("\t%10d numCellsContacted\n",        perfP->numCellsContacted);
    printf("\t%10d dlocalAccesses\n",           perfP->dlocalAccesses);
    printf("\t%10d vlocalAccesses\n",           perfP->vlocalAccesses);
    printf("\t%10d dremoteAccesses\n",          perfP->dremoteAccesses);
    printf("\t%10d vremoteAccesses\n",          perfP->vremoteAccesses);
    printf("\t%10d cacheNumEntries\n",          perfP->cacheNumEntries);
    printf("\t%10d cacheBlocksTotal\n",         perfP->cacheBlocksTotal);
    printf("\t%10d cacheBlocksInUse\n",         perfP->cacheBlocksInUse);
    printf("\t%10d cacheBlocksOrig\n",          perfP->cacheBlocksOrig);
    printf("\t%10d cacheMaxDirtyChunks\n",      perfP->cacheMaxDirtyChunks);
    printf("\t%10d cacheCurrDirtyChunks\n",     perfP->cacheCurrDirtyChunks);
    printf("\t%10d dcacheHits\n",               perfP->dcacheHits);
    printf("\t%10d vcacheHits\n",               perfP->vcacheHits);
    printf("\t%10d dcacheMisses\n",             perfP->dcacheMisses);
    printf("\t%10d vcacheMisses\n",             perfP->vcacheMisses);
    printf("\t%10d cacheFlushes\n",             perfP->cacheFlushes);
    printf("\t%10d cacheFilesReused\n",         perfP->cacheFilesReused);
    printf("\t%10d vcacheXAllocs\n",            perfP->vcacheXAllocs);
    printf("\t%10d dcacheXAllocs\n",            perfP->dcacheXAllocs);

    printf("\t%10d bufAlloced\n",               perfP->bufAlloced);
    printf("\t%10d bufHits\n",                  perfP->bufHits);
    printf("\t%10d bufMisses\n",                perfP->bufMisses);
    printf("\t%10d bufFlushDirty\n",            perfP->bufFlushDirty);

    printf("\t%10d LargeBlocksActive\n",        perfP->LargeBlocksActive);
    printf("\t%10d LargeBlocksAlloced\n",       perfP->LargeBlocksAlloced);
    printf("\t%10d SmallBlocksActive\n",        perfP->SmallBlocksActive);
    printf("\t%10d SmallBlocksAlloced\n",       perfP->SmallBlocksAlloced);
    printf("\t%10d MediumBlocksActive\n",       perfP->MediumBlocksActive);
    printf("\t%10d MediumBlocksAlloced\n",      perfP->MediumBlocksAlloced);
    printf("\t%10d OutStandingMemUsage\n",      perfP->OutStandingMemUsage);
    printf("\t%10d OutStandingAllocs\n",        perfP->OutStandingAllocs);
    printf("\t%10d CallBackAlloced\n",          perfP->CallBackAlloced);
    printf("\t%10d CallBackFlushes\n",          perfP->CallBackFlushes);
    printf("\t%10d CallBackLoops\n",            perfP->cbloops);

    printf("\t%10d srvRecords\n",               perfP->srvRecords);
    printf("\t%10d srvNumBuckets\n",            perfP->srvNumBuckets);
    printf("\t%10d srvMaxChainLength\n",        perfP->srvMaxChainLength);
    printf("\t%10d srvRecordsHWM\n",            perfP->srvRecordsHWM);
    printf("\t%10d srvMaxChainLengthHWM\n",     perfP->srvMaxChainLengthHWM);

    printf("\t%10d sysName_ID\n",               perfP->sysName_ID);
    printf("\t%10d osi_Read_EFAULTS\n",         perfP->osiread_efaults);

    printf("\tFile Server up/downtimes, same cell:\n");
    print_upDownStats(&(perfP->fs_UpDown[0]));

    printf("\tFile Server up/downtimes, diff cell:\n");
    print_upDownStats(&(perfP->fs_UpDown[1]));

    printf("\tVL Server up/downtimes, same cell:\n");
    print_upDownStats(&(perfP->vl_UpDown[0]));

    printf("\tVL Server up/downtimes, diff cell:\n");
    print_upDownStats(&(perfP->vl_UpDown[1]));
}


void print_cmstats(cmp)
    struct afs_CMStats *cmp;
{
    printf("\t%10d afs_init\n",         cmp->callInfo.C_afs_init);
    printf("\t%10d gop_rdwr\n",         cmp->callInfo.C_gop_rdwr);
    printf("\t%10d aix_gnode_rele\n",         cmp->callInfo.C_aix_gnode_rele);
    printf("\t%10d gettimeofday\n",         cmp->callInfo.C_gettimeofday);
    printf("\t%10d m_cpytoc\n",         cmp->callInfo.C_m_cpytoc);
    printf("\t%10d aix_vattr_null\n",         cmp->callInfo.C_aix_vattr_null);
    printf("\t%10d afs_gn_frunc\n",         cmp->callInfo.C_afs_gn_ftrunc);
    printf("\t%10d afs_gn_rdwr\n",         cmp->callInfo.C_afs_gn_rdwr);
    printf("\t%10d afs_gn_ioctl\n",         cmp->callInfo.C_afs_gn_ioctl);
    printf("\t%10d afs_gn_locktl\n",         cmp->callInfo.C_afs_gn_lockctl);
    printf("\t%10d afs_gn_readlink\n",         cmp->callInfo.C_afs_gn_readlink);
    printf("\t%10d afs_gn_readdir\n",         cmp->callInfo.C_afs_gn_readdir);
    printf("\t%10d afs_gn_select\n",         cmp->callInfo.C_afs_gn_select);
    printf("\t%10d afs_gn_strategy\n",         cmp->callInfo.C_afs_gn_strategy);
    printf("\t%10d afs_gn_symlink\n",         cmp->callInfo.C_afs_gn_symlink);
    printf("\t%10d afs_gn_revoke\n",         cmp->callInfo.C_afs_gn_revoke);
    printf("\t%10d afs_gn_link\n",         cmp->callInfo.C_afs_gn_link);
    printf("\t%10d afs_gn_mkdir\n",         cmp->callInfo.C_afs_gn_mkdir);
    printf("\t%10d afs_gn_mknod\n",         cmp->callInfo.C_afs_gn_mknod);
    printf("\t%10d afs_gn_remove\n",         cmp->callInfo.C_afs_gn_remove);
    printf("\t%10d afs_gn_rename\n",         cmp->callInfo.C_afs_gn_rename);
    printf("\t%10d afs_gn_rmdir\n",         cmp->callInfo.C_afs_gn_rmdir);
    printf("\t%10d afs_gn_fid\n",         cmp->callInfo.C_afs_gn_fid);
    printf("\t%10d afs_gn_lookup\n",         cmp->callInfo.C_afs_gn_lookup);
    printf("\t%10d afs_gn_open\n",         cmp->callInfo.C_afs_gn_open);
    printf("\t%10d afs_gn_create\n",         cmp->callInfo.C_afs_gn_create);
    printf("\t%10d afs_gn_hold\n",         cmp->callInfo.C_afs_gn_hold);
    printf("\t%10d afs_gn_rele\n",         cmp->callInfo.C_afs_gn_rele);
    printf("\t%10d afs_gn_unmap\n",         cmp->callInfo.C_afs_gn_unmap);
    printf("\t%10d afs_gn_access\n",         cmp->callInfo.C_afs_gn_access);
    printf("\t%10d afs_gn_getattr\n",         cmp->callInfo.C_afs_gn_getattr);
    printf("\t%10d afs_gn_setattr\n",         cmp->callInfo.C_afs_gn_setattr);
    printf("\t%10d afs_gn_fclear\n",         cmp->callInfo.C_afs_gn_fclear);
    printf("\t%10d afs_gn_fsync\n",         cmp->callInfo.C_afs_gn_fsync);
    printf("\t%10d phash\n",         cmp->callInfo.C_pHash);
    printf("\t%10d DInit\n",         cmp->callInfo.C_DInit);
    printf("\t%10d DRead\n",         cmp->callInfo.C_DRead);
    printf("\t%10d FixupBucket\n",         cmp->callInfo.C_FixupBucket);
    printf("\t%10d afs_newslot\n",         cmp->callInfo.C_afs_newslot);
    printf("\t%10d DRelease\n",         cmp->callInfo.C_DRelease);
    printf("\t%10d DFlush\n",         cmp->callInfo.C_DFlush);
    printf("\t%10d DFlushEntry\n",         cmp->callInfo.C_DFlushEntry);
    printf("\t%10d DVOffset\n",         cmp->callInfo.C_DVOffset);
    printf("\t%10d DZap\n",         cmp->callInfo.C_DZap);
    printf("\t%10d DNew\n",         cmp->callInfo.C_DNew);
    printf("\t%10d afs_RemoveVCB\n",         cmp->callInfo.C_afs_RemoveVCB);
    printf("\t%10d afs_NewVCache\n",         cmp->callInfo.C_afs_NewVCache);
    printf("\t%10d afs_FlushActiveVcaches\n",         cmp->callInfo.C_afs_FlushActiveVcaches);
    printf("\t%10d afs_VerifyVCache\n",         cmp->callInfo.C_afs_VerifyVCache);
    printf("\t%10d afs_WriteVCache\n",         cmp->callInfo.C_afs_WriteVCache);
    printf("\t%10d afs_GetVCache\n",         cmp->callInfo.C_afs_GetVCache);
    printf("\t%10d afs_StuffVcache\n",         cmp->callInfo.C_afs_StuffVcache);
    printf("\t%10d afs_FindVCache\n",         cmp->callInfo.C_afs_FindVCache);
    printf("\t%10d afs_PutDCache\n",         cmp->callInfo.C_afs_PutDCache);
    printf("\t%10d afs_PutVCache\n",         cmp->callInfo.C_afs_PutVCache);
    printf("\t%10d CacheStoreProc\n",         cmp->callInfo.C_CacheStoreProc);
    printf("\t%10d afs_FindDcache\n",         cmp->callInfo.C_afs_FindDCache);
    printf("\t%10d afs_TryToSmush\n",         cmp->callInfo.C_afs_TryToSmush);
    printf("\t%10d afs_AdjustSize\n",         cmp->callInfo.C_afs_AdjustSize);
    printf("\t%10d afs_CheckSize\n",         cmp->callInfo.C_afs_CheckSize);
    printf("\t%10d afs_StoreWarn\n",         cmp->callInfo.C_afs_StoreWarn);
    printf("\t%10d CacheFetchProc\n",         cmp->callInfo.C_CacheFetchProc);
    printf("\t%10d UFS_CacheStoreProc\n",         cmp->callInfo.C_UFS_CacheStoreProc);
    printf("\t%10d UFS_CacheFetchProc\n",         cmp->callInfo.C_UFS_CacheFetchProc);
    printf("\t%10d afs_GetDCache\n",         cmp->callInfo.C_afs_GetDCache);
    printf("\t%10d afs_SimpleVStat\n",         cmp->callInfo.C_afs_SimpleVStat);
    printf("\t%10d afs_ProcessFS\n",         cmp->callInfo.C_afs_ProcessFS);
    printf("\t%10d afs_InitCacheInfo\n",         cmp->callInfo.C_afs_InitCacheInfo);
    printf("\t%10d afs_InitVolumeInfo\n",         cmp->callInfo.C_afs_InitVolumeInfo);
    printf("\t%10d afs_InitCacheFile\n",         cmp->callInfo.C_afs_InitCacheFile);
    printf("\t%10d afs_CacheInit\n",         cmp->callInfo.C_afs_CacheInit);
    printf("\t%10d afs_GetDSlot\n",         cmp->callInfo.C_afs_GetDSlot);
    printf("\t%10d afs_WriteThroughDSlots\n",         cmp->callInfo.C_afs_WriteThroughDSlots);
    printf("\t%10d afs_MemGetDSlot\n",         cmp->callInfo.C_afs_MemGetDSlot);
    printf("\t%10d afs_UFSGetDSlot\n",         cmp->callInfo.C_afs_UFSGetDSlot);
    printf("\t%10d afs_StoreDCache\n",         cmp->callInfo.C_afs_StoreDCache);
    printf("\t%10d afs_StoreMini\n",         cmp->callInfo.C_afs_StoreMini);
    printf("\t%10d afs_StoreAllSegments\n",         cmp->callInfo.C_afs_StoreAllSegments);
    printf("\t%10d afs_InvalidateAllSegments\n",         cmp->callInfo.C_afs_InvalidateAllSegments);
    printf("\t%10d afs_TruncateAllSegments\n",         cmp->callInfo.C_afs_TruncateAllSegments);
    printf("\t%10d afs_CheckVolSync\n",         cmp->callInfo.C_afs_CheckVolSync);
    printf("\t%10d afs_wakeup\n",         cmp->callInfo.C_afs_wakeup);
    printf("\t%10d afs_CFileOpen\n",         cmp->callInfo.C_afs_CFileOpen);
    printf("\t%10d afs_CFileTruncate\n",         cmp->callInfo.C_afs_CFileTruncate);
    printf("\t%10d afs_GetDownD\n",         cmp->callInfo.C_afs_GetDownD);
    printf("\t%10d afs_WriteDCache\n",         cmp->callInfo.C_afs_WriteDCache);
    printf("\t%10d afs_FlushDCache\n",         cmp->callInfo.C_afs_FlushDCache);
    printf("\t%10d afs_GetDownDSlot\n",         cmp->callInfo.C_afs_GetDownDSlot);
    printf("\t%10d afs_FlushVCache\n",         cmp->callInfo.C_afs_FlushVCache);
    printf("\t%10d afs_GetDownV\n",         cmp->callInfo.C_afs_GetDownV);
    printf("\t%10d afs_QueueVCB\n",         cmp->callInfo.C_afs_QueueVCB);
    printf("\t%10d afs_call\n",         cmp->callInfo.C_afs_call);
    printf("\t%10d afs_syscall_call\n",         cmp->callInfo.C_afs_syscall_call);
    printf("\t%10d afs_syscall_icreate\n",         cmp->callInfo.C_afs_syscall_icreate);
    printf("\t%10d afs_syscall_iopen\n",         cmp->callInfo.C_afs_syscall_iopen);
    printf("\t%10d afs_syscall_iincdec\n",         cmp->callInfo.C_afs_syscall_iincdec);
    printf("\t%10d afs_syscall_ireadwrite\n",         cmp->callInfo.C_afs_syscall_ireadwrite);
    printf("\t%10d afs_syscall\n",         cmp->callInfo.C_afs_syscall);
    printf("\t%10d lpioctl\n",         cmp->callInfo.C_lpioctl);
    printf("\t%10d lsetpag\n",         cmp->callInfo.C_lsetpag);
    printf("\t%10d afs_CheckInit\n",         cmp->callInfo.C_afs_CheckInit);
    printf("\t%10d ClearCallback\n",         cmp->callInfo.C_ClearCallBack);
    printf("\t%10d SRXAFSCB_GetCE\n",         cmp->callInfo.C_SRXAFSCB_GetCE);
    printf("\t%10d SRXAFSCB_GetLock\n",         cmp->callInfo.C_SRXAFSCB_GetLock);
    printf("\t%10d SRXAFSCB_CallBack\n",         cmp->callInfo.C_SRXAFSCB_CallBack);
    printf("\t%10d SRXAFSCB_InitCallBackState\n",         cmp->callInfo.C_SRXAFSCB_InitCallBackState);
    printf("\t%10d SRXAFSCB_Probe\n",         cmp->callInfo.C_SRXAFSCB_Probe);
    printf("\t%10d afs_Chunk\n",         cmp->callInfo.C_afs_Chunk);
    printf("\t%10d afs_ChunkBase\n",         cmp->callInfo.C_afs_ChunkBase);
    printf("\t%10d afs_ChunkOffset\n",         cmp->callInfo.C_afs_ChunkOffset);
    printf("\t%10d afs_ChunkSize\n",         cmp->callInfo.C_afs_ChunkSize);
    printf("\t%10d afs_ChunkToBase\n",         cmp->callInfo.C_afs_ChunkToBase);
    printf("\t%10d afs_ChunkToSize\n",         cmp->callInfo.C_afs_ChunkToSize);
    printf("\t%10d afs_SetChunkSize\n",         cmp->callInfo.C_afs_SetChunkSize);
    printf("\t%10d afs_config\n",         cmp->callInfo.C_afs_config);
    printf("\t%10d mem_freebytes\n",         cmp->callInfo.C_mem_freebytes);
    printf("\t%10d mem_getbytes\n",         cmp->callInfo.C_mem_getbytes);
    printf("\t%10d afs_Daemon\n",         cmp->callInfo.C_afs_Daemon);
    printf("\t%10d afs_CheckRootVolume\n",         cmp->callInfo.C_afs_CheckRootVolume);
    printf("\t%10d BPath\n",         cmp->callInfo.C_BPath);
    printf("\t%10d BPrefetch\n",         cmp->callInfo.C_BPrefetch);
    printf("\t%10d BStore\n",         cmp->callInfo.C_BStore);
    printf("\t%10d afs_BBusy\n",         cmp->callInfo.C_afs_BBusy);
    printf("\t%10d afs_BQueue\n",         cmp->callInfo.C_afs_BQueue);
    printf("\t%10d afs_BRelease\n",         cmp->callInfo.C_afs_BRelease);
    printf("\t%10d afs_BackgroundDaemon\n",         cmp->callInfo.C_afs_BackgroundDaemon);
    printf("\t%10d exporter_add\n",         cmp->callInfo.C_exporter_add);
    printf("\t%10d exporter_find\n",         cmp->callInfo.C_exporter_find);
    printf("\t%10d afs_gfs_kalloc\n",         cmp->callInfo.C_afs_gfs_kalloc);
    printf("\t%10d afs_gfs_kfree\n",         cmp->callInfo.C_afs_gfs_kfree);
    printf("\t%10d gop_lookupname\n",         cmp->callInfo.C_gop_lookupname);
    printf("\t%10d afs_uniqtime\n",         cmp->callInfo.C_afs_uniqtime);
    printf("\t%10d gfs_vattr_null\n",         cmp->callInfo.C_gfs_vattr_null);
    printf("\t%10d afs_lock\n",         cmp->callInfo.C_afs_lock);
    printf("\t%10d afs_unlock\n",         cmp->callInfo.C_afs_unlock);
    printf("\t%10d afs_update\n",         cmp->callInfo.C_afs_update);
    printf("\t%10d afs_gclose\n",         cmp->callInfo.C_afs_gclose);
    printf("\t%10d afs_gopen\n",         cmp->callInfo.C_afs_gopen);
    printf("\t%10d afs_greadlink\n",         cmp->callInfo.C_afs_greadlink);
    printf("\t%10d afs_select\n",         cmp->callInfo.C_afs_select);<