/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2009 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ /* Copyright (c) 1984, 1986, 1987, 1988, 1989 AT&T */ /* All Rights Reserved */ #define _SYSCALL32 /* make 32-bit compat headers visible */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "ramdata.h" #include "print.h" #include "proto.h" #include "systable.h" void grow(private_t *, int nbyte); #define GROW(nb) if (pri->sys_leng + (nb) >= pri->sys_ssize) grow(pri, (nb)) /*ARGSUSED*/ void prt_nov(private_t *pri, int raw, long val) /* print nothing */ { } /*ARGSUSED*/ void prt_dec(private_t *pri, int raw, long val) /* print as decimal */ { GROW(24); if (data_model == PR_MODEL_ILP32) pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%d", (int)val); else pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%ld", val); } /*ARGSUSED*/ void prt_uns(private_t *pri, int raw, long val) /* print as unsigned decimal */ { GROW(24); if (data_model == PR_MODEL_ILP32) pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%u", (int)val); else pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%lu", val); } /* print as unsigned decimal, except for -1 */ void prt_un1(private_t *pri, int raw, long val) { if ((int)val == -1) prt_dec(pri, raw, val); else prt_uns(pri, raw, val); } /*ARGSUSED*/ void prt_oct(private_t *pri, int raw, long val) /* print as octal */ { GROW(24); if (data_model == PR_MODEL_ILP32) pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%#o", (int)val); else pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "%#lo", val); } /*ARGSUSED*/ void prt_hex(private_t *pri, int raw, long val) /* print as hexadecimal */ { GROW(20); if (data_model == PR_MODEL_ILP32) pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "0x%.8X", (int)val); else pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "0x%.8lX", val); } /* print as hexadecimal (half size) */ /*ARGSUSED*/ void prt_hhx(private_t *pri, int raw, long val) { GROW(20); if (data_model == PR_MODEL_ILP32) pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "0x%.4X", (int)val); else pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "0x%.4lX", val); } /* print as decimal if small, else hexadecimal */ /*ARGSUSED*/ void prt_dex(private_t *pri, int raw, long val) { if (val & 0xff000000) prt_hex(pri, 0, val); else prt_dec(pri, 0, val); } /* print long long offset */ /*ARGSUSED*/ void prt_llo(private_t *pri, int raw, long val1, long val2) { int hival; int loval; #ifdef _LONG_LONG_LTOH hival = (int)val2; loval = (int)val1; #else hival = (int)val1; loval = (int)val2; #endif if (hival == 0) { prt_dex(pri, 0, loval); } else { GROW(18); pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "0x%.8X%.8X", hival, loval); } } void escape_string(private_t *pri, const char *s) { /* * We want to avoid outputting unprintable characters that may * destroy the user's terminal. So we do one pass to find any * unprintable characters, size the array appropriately, and * then walk each character by hand. Those that are unprintable * are replaced by a hex escape (\xNN). We also escape quotes for * completeness. */ int i, unprintable, quotes; size_t len = strlen(s); for (i = 0, unprintable = 0, quotes = 0; i < len; i++) { if (!isprint(s[i])) unprintable++; if (s[i] == '"') quotes++; } GROW(len + 3 * unprintable + quotes + 2); pri->sys_string[pri->sys_leng++] = '"'; for (i = 0; i < len; i++) { if (s[i] == '"') pri->sys_string[pri->sys_leng++] = '\\'; if (isprint(s[i])) { pri->sys_string[pri->sys_leng++] = s[i]; } else { pri->sys_leng += sprintf(pri->sys_string + pri->sys_leng, "\\x%02x", (uint8_t)s[i]); } } pri->sys_string[pri->sys_leng++] = '"'; } void prt_stg(private_t *pri, int raw, long val) /* print as string */ { char *s = raw? NULL : fetchstring(pri, (long)val, PATH_MAX); if (s == NULL) prt_hex(pri, 0, val); else escape_string(pri, s); } /* print as string returned from syscall */ void prt_rst(private_t *pri, int raw, long val) { char *s = (raw || pri->Errno)? NULL : fetchstring(pri, (long)val, PATH_MAX); if (s == NULL) prt_hex(pri, 0, val); else { GROW((int)strlen(s) + 2); pri->sys_leng += snprintf(pri->sys_string + pri->sys_leng, pri->sys_ssize - pri->sys_leng, "\"%s\"", s); } } /* print contents of readlink() buffer */ void prt_rlk(private_t *pri, int raw, long val) { char *s = (raw || pri->Errno || pri->Rval1 <= 0)? NULL : fetchstring(pri, (long)val, (pri->Rval1 > PATH_MAX)? PATH_MAX : (int)pri->Rval1); if (s == NULL) prt_hex(pri, 0, val); else { GROW((int)strlen(s) + 2); pri->sys_leng += snprintf(pri->sys_string + pri->sys_leng, pri->sys_ssize - pri->sys_leng, "\"%s\"", s); } } void prt_ioc(private_t *pri, int raw, long val) /* print ioctl code */ { const char *s = raw? NULL : ioctlname(pri, (int)val); if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } void prt_ioa(private_t *pri, int raw, long val) /* print ioctl argument */ { const char *s; /* cheating -- look at the ioctl() code */ switch (pri->sys_args[1]) { /* kstat ioctl()s */ case KSTAT_IOC_READ: case KSTAT_IOC_WRITE: #ifdef _LP64 if (data_model == PR_MODEL_ILP32) prt_stg(pri, raw, val + offsetof(kstat32_t, ks_name[0])); else #endif prt_stg(pri, raw, val + offsetof(kstat_t, ks_name[0])); break; /* streams ioctl()s */ case I_LOOK: prt_rst(pri, raw, val); break; case I_PUSH: case I_FIND: prt_stg(pri, raw, val); break; case I_LINK: case I_UNLINK: case I_SENDFD: prt_dec(pri, 0, val); break; case I_SRDOPT: if (raw || (s = strrdopt(val)) == NULL) prt_dec(pri, 0, val); else outstring(pri, s); break; case I_SETSIG: if (raw || (s = strevents(pri, val)) == NULL) prt_hex(pri, 0, val); else outstring(pri, s); break; case I_FLUSH: if (raw || (s = strflush(val)) == NULL) prt_dec(pri, 0, val); else outstring(pri, s); break; /* tty ioctl()s */ case TCSBRK: case TCXONC: case TCFLSH: case TCDSET: prt_dec(pri, 0, val); break; default: prt_hex(pri, 0, val); break; } } void prt_fcn(private_t *pri, int raw, long val) /* print fcntl code */ { const char *s = raw? NULL : fcntlname(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_s86(private_t *pri, int raw, long val) /* print sysi86 code */ { const char *s = raw? NULL : si86name(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_uts(private_t *pri, int raw, long val) /* print utssys code */ { const char *s = raw? NULL : utscode(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_msc(private_t *pri, int raw, long val) /* print msgsys command */ { const char *s = raw? NULL : msgcmd(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_msf(private_t *pri, int raw, long val) /* print msgsys flags */ { const char *s = raw? NULL : msgflags(pri, (int)val); if (s == NULL) prt_oct(pri, 0, val); else outstring(pri, s); } void prt_smc(private_t *pri, int raw, long val) /* print semsys command */ { const char *s = raw? NULL : semcmd(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_sef(private_t *pri, int raw, long val) /* print semsys flags */ { const char *s = raw? NULL : semflags(pri, (int)val); if (s == NULL) prt_oct(pri, 0, val); else outstring(pri, s); } void prt_shc(private_t *pri, int raw, long val) /* print shmsys command */ { const char *s = raw? NULL : shmcmd(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_shf(private_t *pri, int raw, long val) /* print shmsys flags */ { const char *s = raw? NULL : shmflags(pri, (int)val); if (s == NULL) prt_oct(pri, 0, val); else outstring(pri, s); } void prt_sfs(private_t *pri, int raw, long val) /* print sysfs code */ { const char *s = raw? NULL : sfsname(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_opn(private_t *pri, int raw, long val) /* print open code */ { const char *s = raw? NULL : openarg(pri, val); if (s == NULL) prt_oct(pri, 0, val); else outstring(pri, s); } void prt_sig(private_t *pri, int raw, long val) /* print signal name plus flags */ { const char *s = raw? NULL : sigarg(pri, (int)val); if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } /* print signal name, masked with SIGNO_MASK */ void prt_six(private_t *pri, int raw, long val) { const char *s = raw? NULL : sigarg(pri, (int)val & SIGNO_MASK); if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } void prt_act(private_t *pri, int raw, long val) /* print signal action value */ { const char *s; if (raw) s = NULL; else if (val == (int)SIG_DFL) s = "SIG_DFL"; else if (val == (int)SIG_IGN) s = "SIG_IGN"; else if (val == (int)SIG_HOLD) s = "SIG_HOLD"; else s = NULL; if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } void prt_smf(private_t *pri, int raw, long val) /* print streams message flags */ { switch (val) { case 0: prt_dec(pri, 0, val); break; case RS_HIPRI: if (raw) prt_hhx(pri, 0, val); else outstring(pri, "RS_HIPRI"); break; default: prt_hhx(pri, 0, val); break; } } void prt_plk(private_t *pri, int raw, long val) /* print plock code */ { const char *s = raw? NULL : plockname(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_mtf(private_t *pri, int raw, long val) /* print mount flags */ { const char *s = raw? NULL : mountflags(pri, val); if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } void prt_mft(private_t *pri, int raw, long val) /* print mount file system type */ { if (val >= 0 && val < 256) prt_dec(pri, 0, val); else if (raw) prt_hex(pri, 0, val); else prt_stg(pri, raw, val); } #define ISREAD(code) \ ((code) == SYS_read || (code) == SYS_pread || (code) == SYS_pread64 || \ (code) == SYS_recv || (code) == SYS_recvfrom) #define ISWRITE(code) \ ((code) == SYS_write || (code) == SYS_pwrite || \ (code) == SYS_pwrite64 || (code) == SYS_send || (code) == SYS_sendto) /* print contents of read() or write() I/O buffer */ void prt_iob(private_t *pri, int raw, long val) { const lwpstatus_t *Lsp = pri->lwpstat; int syscall = Lsp->pr_what; int fdp1 = pri->sys_args[0] + 1; ssize_t nbyte = ISWRITE(syscall)? pri->sys_args[2] : (pri->Errno? 0 : pri->Rval1); int elsewhere = FALSE; /* TRUE iff dumped elsewhere */ char buffer[IOBSIZE]; pri->iob_buf[0] = '\0'; if (Lsp->pr_why == PR_SYSEXIT && nbyte > IOBSIZE) { if (ISREAD(syscall)) elsewhere = prismember(&readfd, fdp1); else elsewhere = prismember(&writefd, fdp1); } if (nbyte <= 0 || elsewhere) prt_hex(pri, 0, val); else { int nb = nbyte > IOBSIZE? IOBSIZE : (int)nbyte; if (Pread(Proc, buffer, (size_t)nb, (long)val) != nb) prt_hex(pri, 0, val); else { pri->iob_buf[0] = '"'; showbytes(buffer, nb, pri->iob_buf + 1); (void) strlcat(pri->iob_buf, (nb == nbyte)? (const char *)"\"" : (const char *)"\"..", sizeof (pri->iob_buf)); if (raw) prt_hex(pri, 0, val); else outstring(pri, pri->iob_buf); } } } #undef ISREAD #undef ISWRITE void prt_idt(private_t *pri, int raw, long val) /* print idtype_t, waitid() arg */ { const char *s = raw? NULL : idtype_enum(pri, val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_wop(private_t *pri, int raw, long val) /* print waitid() options */ { const char *s = raw? NULL : woptions(pri, (int)val); if (s == NULL) prt_oct(pri, 0, val); else outstring(pri, s); } void prt_whn(private_t *pri, int raw, long val) /* print lseek() whence argument */ { const char *s = raw? NULL : whencearg(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /*ARGSUSED*/ void prt_spm(private_t *pri, int raw, long val) /* print sigprocmask argument */ { const char *s = NULL; if (!raw) { switch (val) { case SIG_BLOCK: s = "SIG_BLOCK"; break; case SIG_UNBLOCK: s = "SIG_UNBLOCK"; break; case SIG_SETMASK: s = "SIG_SETMASK"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } const char * mmap_protect(private_t *pri, long arg) { char *str = pri->code_buf; if (arg & ~(PROT_READ|PROT_WRITE|PROT_EXEC)) return ((char *)NULL); if (arg == PROT_NONE) return ("PROT_NONE"); *str = '\0'; if (arg & PROT_READ) (void) strlcat(str, "|PROT_READ", sizeof (pri->code_buf)); if (arg & PROT_WRITE) (void) strlcat(str, "|PROT_WRITE", sizeof (pri->code_buf)); if (arg & PROT_EXEC) (void) strlcat(str, "|PROT_EXEC", sizeof (pri->code_buf)); return ((const char *)(str + 1)); } const char * mmap_type(private_t *pri, long arg) { char *str = pri->code_buf; size_t used; #define CBSIZE sizeof (pri->code_buf) switch (arg & MAP_TYPE) { case MAP_SHARED: used = strlcpy(str, "MAP_SHARED", CBSIZE); break; case MAP_PRIVATE: used = strlcpy(str, "MAP_PRIVATE", CBSIZE); break; default: used = snprintf(str, CBSIZE, "%ld", arg&MAP_TYPE); break; } arg &= ~(_MAP_NEW|MAP_TYPE); if (arg & ~(MAP_FIXED|MAP_RENAME|MAP_NORESERVE|MAP_ANON|MAP_ALIGN| MAP_TEXT|MAP_INITDATA)) (void) snprintf(str + used, sizeof (pri->code_buf) - used, "|0x%lX", arg); else { if (arg & MAP_FIXED) (void) strlcat(str, "|MAP_FIXED", CBSIZE); if (arg & MAP_RENAME) (void) strlcat(str, "|MAP_RENAME", CBSIZE); if (arg & MAP_NORESERVE) (void) strlcat(str, "|MAP_NORESERVE", CBSIZE); if (arg & MAP_ANON) (void) strlcat(str, "|MAP_ANON", CBSIZE); if (arg & MAP_ALIGN) (void) strlcat(str, "|MAP_ALIGN", CBSIZE); if (arg & MAP_TEXT) (void) strlcat(str, "|MAP_TEXT", CBSIZE); if (arg & MAP_INITDATA) (void) strlcat(str, "|MAP_INITDATA", CBSIZE); } return ((const char *)str); #undef CBSIZE } void prt_mpr(private_t *pri, int raw, long val) /* print mmap()/mprotect() flags */ { const char *s = raw? NULL : mmap_protect(pri, val); if (s == NULL) prt_hhx(pri, 0, val); else outstring(pri, s); } void prt_mty(private_t *pri, int raw, long val) /* print mmap() mapping type flags */ { const char *s = raw? NULL : mmap_type(pri, val); if (s == NULL) prt_hhx(pri, 0, val); else outstring(pri, s); } /*ARGSUSED*/ void prt_mcf(private_t *pri, int raw, long val) /* print memcntl() function */ { const char *s = NULL; if (!raw) { switch (val) { case MC_SYNC: s = "MC_SYNC"; break; case MC_LOCK: s = "MC_LOCK"; break; case MC_UNLOCK: s = "MC_UNLOCK"; break; case MC_ADVISE: s = "MC_ADVISE"; break; case MC_LOCKAS: s = "MC_LOCKAS"; break; case MC_UNLOCKAS: s = "MC_UNLOCKAS"; break; case MC_HAT_ADVISE: s = "MC_HAT_ADVISE"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_mad(private_t *pri, int raw, long val) /* print madvise() argument */ { const char *s = NULL; if (!raw) { switch (val) { case MADV_NORMAL: s = "MADV_NORMAL"; break; case MADV_RANDOM: s = "MADV_RANDOM"; break; case MADV_SEQUENTIAL: s = "MADV_SEQUENTIAL"; break; case MADV_WILLNEED: s = "MADV_WILLNEED"; break; case MADV_DONTNEED: s = "MADV_DONTNEED"; break; case MADV_FREE: s = "MADV_FREE"; break; case MADV_ACCESS_DEFAULT: s = "MADV_ACCESS_DEFAULT"; break; case MADV_ACCESS_LWP: s = "MADV_ACCESS_LWP"; break; case MADV_ACCESS_MANY: s = "MADV_ACCESS_MANY"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_mc4(private_t *pri, int raw, long val) /* print memcntl() (4th) argument */ { if (val == 0) prt_dec(pri, 0, val); else if (raw) prt_hhx(pri, 0, val); else { char *s = NULL; #define CBSIZE sizeof (pri->code_buf) /* cheating -- look at memcntl func */ switch (pri->sys_args[2]) { case MC_ADVISE: prt_mad(pri, 0, val); return; case MC_SYNC: if ((val & ~(MS_SYNC|MS_ASYNC|MS_INVALIDATE)) == 0) { *(s = pri->code_buf) = '\0'; if (val & MS_SYNC) (void) strlcat(s, "|MS_SYNC", CBSIZE); if (val & MS_ASYNC) (void) strlcat(s, "|MS_ASYNC", CBSIZE); if (val & MS_INVALIDATE) (void) strlcat(s, "|MS_INVALIDATE", CBSIZE); } break; case MC_LOCKAS: case MC_UNLOCKAS: if ((val & ~(MCL_CURRENT|MCL_FUTURE)) == 0) { *(s = pri->code_buf) = '\0'; if (val & MCL_CURRENT) (void) strlcat(s, "|MCL_CURRENT", CBSIZE); if (val & MCL_FUTURE) (void) strlcat(s, "|MCL_FUTURE", CBSIZE); } break; } #undef CBSIZE if (s == NULL || *s == '\0') prt_hhx(pri, 0, val); else outstring(pri, ++s); } } void prt_mc5(private_t *pri, int raw, long val) /* print memcntl() (5th) argument */ { char *s; #define CBSIZE sizeof (pri->code_buf) if (val == 0) prt_dec(pri, 0, val); else if (raw || (val & ~VALID_ATTR)) prt_hhx(pri, 0, val); else { s = pri->code_buf; *s = '\0'; if (val & SHARED) (void) strlcat(s, "|SHARED", CBSIZE); if (val & PRIVATE) (void) strlcat(s, "|PRIVATE", CBSIZE); if (val & PROT_READ) (void) strlcat(s, "|PROT_READ", CBSIZE); if (val & PROT_WRITE) (void) strlcat(s, "|PROT_WRITE", CBSIZE); if (val & PROT_EXEC) (void) strlcat(s, "|PROT_EXEC", CBSIZE); if (*s == '\0') prt_hhx(pri, 0, val); else outstring(pri, ++s); } #undef CBSIZE } void prt_ulm(private_t *pri, int raw, long val) /* print ulimit() argument */ { const char *s = NULL; if (!raw) { switch (val) { case UL_GFILLIM: s = "UL_GFILLIM"; break; case UL_SFILLIM: s = "UL_SFILLIM"; break; case UL_GMEMLIM: s = "UL_GMEMLIM"; break; case UL_GDESLIM: s = "UL_GDESLIM"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_rlm(private_t *pri, int raw, long val) /* print get/setrlimit() argument */ { const char *s = NULL; if (!raw) { switch (val) { case RLIMIT_CPU: s = "RLIMIT_CPU"; break; case RLIMIT_FSIZE: s = "RLIMIT_FSIZE"; break; case RLIMIT_DATA: s = "RLIMIT_DATA"; break; case RLIMIT_STACK: s = "RLIMIT_STACK"; break; case RLIMIT_CORE: s = "RLIMIT_CORE"; break; case RLIMIT_NOFILE: s = "RLIMIT_NOFILE"; break; case RLIMIT_VMEM: s = "RLIMIT_VMEM"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_cnf(private_t *pri, int raw, long val) /* print sysconfig code */ { const char *s = raw? NULL : sconfname(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_inf(private_t *pri, int raw, long val) /* print sysinfo code */ { const char *s = NULL; if (!raw) { switch (val) { case SI_SYSNAME: s = "SI_SYSNAME"; break; case SI_HOSTNAME: s = "SI_HOSTNAME"; break; case SI_RELEASE: s = "SI_RELEASE"; break; case SI_VERSION: s = "SI_VERSION"; break; case SI_MACHINE: s = "SI_MACHINE"; break; case SI_ARCHITECTURE: s = "SI_ARCHITECTURE"; break; case SI_ARCHITECTURE_32:s = "SI_ARCHITECTURE_32"; break; case SI_ARCHITECTURE_64:s = "SI_ARCHITECTURE_64"; break; case SI_ARCHITECTURE_K: s = "SI_ARCHITECTURE_K"; break; case SI_HW_SERIAL: s = "SI_HW_SERIAL"; break; case SI_HW_PROVIDER: s = "SI_HW_PROVIDER"; break; case SI_SRPC_DOMAIN: s = "SI_SRPC_DOMAIN"; break; case SI_SET_HOSTNAME: s = "SI_SET_HOSTNAME"; break; case SI_SET_SRPC_DOMAIN: s = "SI_SET_SRPC_DOMAIN"; break; case SI_PLATFORM: s = "SI_PLATFORM"; break; case SI_ISALIST: s = "SI_ISALIST"; break; case SI_DHCP_CACHE: s = "SI_DHCP_CACHE"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_ptc(private_t *pri, int raw, long val) /* print pathconf code */ { const char *s = raw? NULL : pathconfname(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_fui(private_t *pri, int raw, long val) /* print fusers() input argument */ { const char *s = raw? NULL : fuiname(val); if (s == NULL) prt_hhx(pri, 0, val); else outstring(pri, s); } void prt_lwf(private_t *pri, int raw, long val) /* print lwp_create() flags */ { char *s; if (val == 0) prt_dec(pri, 0, val); else if (raw || (val & ~(LWP_DAEMON|LWP_DETACHED|LWP_SUSPENDED))) prt_hhx(pri, 0, val); else { #define CBSIZE sizeof (pri->code_buf) s = pri->code_buf; *s = '\0'; if (val & LWP_DAEMON) (void) strlcat(s, "|LWP_DAEMON", CBSIZE); if (val & LWP_DETACHED) (void) strlcat(s, "|LWP_DETACHED", CBSIZE); if (val & LWP_SUSPENDED) (void) strlcat(s, "|LWP_SUSPENDED", CBSIZE); outstring(pri, ++s); #undef CBSIZE } } void prt_itm(private_t *pri, int raw, long val) /* print [get|set]itimer() arg */ { const char *s = NULL; if (!raw) { switch (val) { case ITIMER_REAL: s = "ITIMER_REAL"; break; case ITIMER_VIRTUAL: s = "ITIMER_VIRTUAL"; break; case ITIMER_PROF: s = "ITIMER_PROF"; break; #ifdef ITIMER_REALPROF case ITIMER_REALPROF: s = "ITIMER_REALPROF"; break; #endif } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_mod(private_t *pri, int raw, long val) /* print modctl() code */ { const char *s = NULL; if (!raw) { switch (val) { case MODLOAD: s = "MODLOAD"; break; case MODUNLOAD: s = "MODUNLOAD"; break; case MODINFO: s = "MODINFO"; break; case MODRESERVED: s = "MODRESERVED"; break; case MODSETMINIROOT: s = "MODSETMINIROOT"; break; case MODADDMAJBIND: s = "MODADDMAJBIND"; break; case MODGETPATH: s = "MODGETPATH"; break; case MODGETPATHLEN: s = "MODGETPATHLEN"; break; case MODREADSYSBIND: s = "MODREADSYSBIND"; break; case MODGETMAJBIND: s = "MODGETMAJBIND"; break; case MODGETNAME: s = "MODGETNAME"; break; case MODSIZEOF_DEVID: s = "MODSIZEOF_DEVID"; break; case MODGETDEVID: s = "MODGETDEVID"; break; case MODSIZEOF_MINORNAME: s = "MODSIZEOF_MINORNAME"; break; case MODGETMINORNAME: s = "MODGETMINORNAME"; break; case MODGETFBNAME: s = "MODGETFBNAME"; break; case MODEVENTS: s = "MODEVENTS"; break; case MODREREADDACF: s = "MODREREADDACF"; break; case MODLOADDRVCONF: s = "MODLOADDRVCONF"; break; case MODUNLOADDRVCONF: s = "MODUNLOADDRVCONF"; break; case MODREMMAJBIND: s = "MODREMMAJBIND"; break; case MODDEVT2INSTANCE: s = "MODDEVT2INSTANCE"; break; case MODGETDEVFSPATH_LEN: s = "MODGETDEVFSPATH_LEN"; break; case MODGETDEVFSPATH: s = "MODGETDEVFSPATH"; break; case MODDEVID2PATHS: s = "MODDEVID2PATHS"; break; case MODSETDEVPOLICY: s = "MODSETDEVPOLICY"; break; case MODGETDEVPOLICY: s = "MODGETDEVPOLICY"; break; case MODALLOCPRIV: s = "MODALLOCPRIV"; break; case MODGETDEVPOLICYBYNAME: s = "MODGETDEVPOLICYBYNAME"; break; case MODLOADMINORPERM: s = "MODLOADMINORPERM"; break; case MODADDMINORPERM: s = "MODADDMINORPERM"; break; case MODREMMINORPERM: s = "MODREMMINORPERM"; break; case MODREMDRVCLEANUP: s = "MODREMDRVCLEANUP"; break; case MODDEVEXISTS: s = "MODDEVEXISTS"; break; case MODDEVREADDIR: s = "MODDEVREADDIR"; break; case MODDEVEMPTYDIR: s = "MODDEVEMPTYDIR"; break; case MODDEVNAME: s = "MODDEVNAME"; break; case MODGETDEVFSPATH_MI_LEN: s = "MODGETDEVFSPATH_MI_LEN"; break; case MODGETDEVFSPATH_MI: s = "MODGETDEVFSPATH_MI"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_acl(private_t *pri, int raw, long val) /* print acl() code */ { const char *s = NULL; if (!raw) { switch (val) { case GETACL: s = "GETACL"; break; case SETACL: s = "SETACL"; break; case GETACLCNT: s = "GETACLCNT"; break; case ACE_GETACL: s = "ACE_GETACL"; break; case ACE_SETACL: s = "ACE_SETACL"; break; case ACE_GETACLCNT: s = "ACE_GETACLCNT"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_aio(private_t *pri, int raw, long val) /* print kaio() code */ { const char *s = NULL; char buf[32]; if (!raw) { switch (val & ~AIO_POLL_BIT) { case AIOREAD: s = "AIOREAD"; break; case AIOWRITE: s = "AIOWRITE"; break; case AIOWAIT: s = "AIOWAIT"; break; case AIOCANCEL: s = "AIOCANCEL"; break; case AIONOTIFY: s = "AIONOTIFY"; break; case AIOINIT: s = "AIOINIT"; break; case AIOSTART: s = "AIOSTART"; break; case AIOLIO: s = "AIOLIO"; break; case AIOSUSPEND: s = "AIOSUSPEND"; break; case AIOERROR: s = "AIOERROR"; break; case AIOLIOWAIT: s = "AIOLIOWAIT"; break; case AIOAREAD: s = "AIOAREAD"; break; case AIOAWRITE: s = "AIOAWRITE"; break; /* * We have to hardcode the values for the 64-bit versions of * these calls, because defines them to be identical * when compiled 64-bit. If our target is 32-bit, we still need * to decode them correctly. */ case 13: s = "AIOLIO64"; break; case 14: s = "AIOSUSPEND64"; break; case 15: s = "AUIOERROR64"; break; case 16: s = "AIOLIOWAIT64"; break; case 17: s = "AIOAREAD64"; break; case 18: s = "AIOAWRITE64"; break; case 19: s = "AIOCANCEL64"; break; /* * AIOFSYNC doesn't correspond to a syscall. */ case AIOWAITN: s = "AIOWAITN"; break; } if (s != NULL && (val & AIO_POLL_BIT)) { (void) strlcpy(buf, s, sizeof (buf)); (void) strlcat(buf, "|AIO_POLL_BIT", sizeof (buf)); s = (const char *)buf; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_aud(private_t *pri, int raw, long val) /* print auditsys() code */ { const char *s = NULL; if (!raw) { switch (val) { case BSM_GETAUID: s = "BSM_GETAUID"; break; case BSM_SETAUID: s = "BSM_SETAUID"; break; case BSM_GETAUDIT: s = "BSM_GETAUDIT"; break; case BSM_SETAUDIT: s = "BSM_SETAUDIT"; break; case BSM_GETUSERAUDIT: s = "BSM_GETUSERAUDIT"; break; case BSM_SETUSERAUDIT: s = "BSM_SETUSERAUDIT"; break; case BSM_AUDIT: s = "BSM_AUDIT"; break; case BSM_AUDITON: s = "BSM_AUDITON"; break; case BSM_AUDITCTL: s = "BSM_AUDITCTL"; break; case BSM_GETKERNSTATE: s = "BSM_GETKERNSTATE"; break; case BSM_SETKERNSTATE: s = "BSM_SETKERNSTATE"; break; case BSM_GETPORTAUDIT: s = "BSM_GETPORTAUDIT"; break; case BSM_REVOKE: s = "BSM_REVOKE"; break; case BSM_AUDITSTAT: s = "BSM_AUDITSTAT"; break; case BSM_GETAUDIT_ADDR: s = "BSM_GETAUDIT_ADDR"; break; case BSM_SETAUDIT_ADDR: s = "BSM_SETAUDIT_ADDR"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_cor(private_t *pri, int raw, long val) /* print corectl() subcode */ { const char *s = NULL; if (!raw) { switch (val) { case CC_SET_OPTIONS: s = "CC_SET_OPTIONS"; break; case CC_GET_OPTIONS: s = "CC_GET_OPTIONS"; break; case CC_SET_GLOBAL_PATH: s = "CC_SET_GLOBAL_PATH"; break; case CC_GET_GLOBAL_PATH: s = "CC_GET_GLOBAL_PATH"; break; case CC_SET_PROCESS_PATH: s = "CC_SET_PROCESS_PATH"; break; case CC_GET_PROCESS_PATH: s = "CC_GET_PROCESS_PATH"; break; case CC_SET_GLOBAL_CONTENT: s = "CC_SET_GLOBAL_CONTENT"; break; case CC_GET_GLOBAL_CONTENT: s = "CC_GET_GLOBAL_CONTENT"; break; case CC_SET_PROCESS_CONTENT: s = "CC_SET_PROCESS_CONTENT"; break; case CC_GET_PROCESS_CONTENT: s = "CC_GET_PROCESS_CONTENT"; break; case CC_SET_DEFAULT_PATH: s = "CC_SET_DEFAULT_PATH"; break; case CC_GET_DEFAULT_PATH: s = "CC_GET_DEFAULT_PATH"; break; case CC_SET_DEFAULT_CONTENT: s = "CC_SET_DEFAULT_CONTENT"; break; case CC_GET_DEFAULT_CONTENT: s = "CC_GET_DEFAULT_CONTENT"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_cco(private_t *pri, int raw, long val) /* print corectl() options */ { char *s; if (val == 0) prt_dec(pri, 0, val); else if (raw || (val & ~CC_OPTIONS)) prt_hhx(pri, 0, val); else { #define CBSIZE sizeof (pri->code_buf) s = pri->code_buf; *s = '\0'; if (val & CC_GLOBAL_PATH) (void) strlcat(s, "|CC_GLOBAL_PATH", CBSIZE); if (val & CC_PROCESS_PATH) (void) strlcat(s, "|CC_PROCESS_PATH", CBSIZE); if (val & CC_GLOBAL_SETID) (void) strlcat(s, "|CC_GLOBAL_SETID", CBSIZE); if (val & CC_PROCESS_SETID) (void) strlcat(s, "|CC_PROCESS_SETID", CBSIZE); if (val & CC_GLOBAL_LOG) (void) strlcat(s, "|CC_GLOBAL_LOG", CBSIZE); if (*s == '\0') prt_hhx(pri, 0, val); else outstring(pri, ++s); #undef CBSIZE } } void prt_ccc(private_t *pri, int raw, long val) /* print corectl() content */ { core_content_t ccc; if (Pread(Proc, &ccc, sizeof (ccc), val) != sizeof (ccc)) prt_hex(pri, 0, val); else if (!raw && proc_content2str(ccc, pri->code_buf, sizeof (pri->code_buf)) >= 0) outstring(pri, pri->code_buf); else prt_hhx(pri, 0, (long)ccc); } void prt_rcc(private_t *pri, int raw, long val) /* print corectl() ret. cont. */ { core_content_t ccc; if (pri->Errno || Pread(Proc, &ccc, sizeof (ccc), val) != sizeof (ccc)) prt_hex(pri, 0, val); else if (!raw && proc_content2str(ccc, pri->code_buf, sizeof (pri->code_buf)) >= 0) outstring(pri, pri->code_buf); else prt_hhx(pri, 0, (long)ccc); } void prt_cpc(private_t *pri, int raw, long val) /* print cpc() subcode */ { const char *s = NULL; if (!raw) { switch (val) { case CPC_BIND: s = "CPC_BIND"; break; case CPC_SAMPLE: s = "CPC_SAMPLE"; break; case CPC_INVALIDATE: s = "CPC_INVALIDATE"; break; case CPC_RELE: s = "CPC_RELE"; break; case CPC_EVLIST_SIZE: s = "CPC_EVLIST_SIZE"; break; case CPC_LIST_EVENTS: s = "CPC_LIST_EVENTS"; break; case CPC_ATTRLIST_SIZE: s = "CPC_ATTRLIST_SIZE"; break; case CPC_LIST_ATTRS: s = "CPC_LIST_ATTRS"; break; case CPC_IMPL_NAME: s = "CPC_IMPL_NAME"; break; case CPC_CPUREF: s = "CPC_CPUREF"; break; case CPC_USR_EVENTS: s = "CPC_USR_EVENTS"; break; case CPC_SYS_EVENTS: s = "CPC_SYS_EVENTS"; break; case CPC_NPIC: s = "CPC_NPIC"; break; case CPC_CAPS: s = "CPC_CAPS"; break; case CPC_ENABLE: s = "CPC_ENABLE"; break; case CPC_DISABLE: s = "CPC_DISABLE"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void outstring(private_t *pri, const char *s) { int len = strlen(s); GROW(len); (void) strcpy(pri->sys_string + pri->sys_leng, s); pri->sys_leng += len; } void grow(private_t *pri, int nbyte) /* reallocate format buffer if necessary */ { while (pri->sys_leng + nbyte >= pri->sys_ssize) pri->sys_string = my_realloc(pri->sys_string, pri->sys_ssize *= 2, "format buffer"); } void prt_clc(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch (val) { case CL_INITIALIZE: s = "CL_INITIALIZE"; break; case CL_CONFIG: s = "CL_CONFIG"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_clf(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch (pri->sys_args[0]) { case CL_CONFIG: switch (pri->sys_args[1]) { case CL_NODEID: s = "CL_NODEID"; break; case CL_HIGHEST_NODEID: s = "CL_HIGHEST_NODEID"; break; } break; case CL_INITIALIZE: switch (pri->sys_args[1]) { case CL_GET_BOOTFLAG: s = "CL_GET_BOOTFLAG"; break; } break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } void prt_sqc(private_t *pri, int raw, long val) /* print sigqueue() si_code */ { const char *s = NULL; if (!raw) { switch ((int)val) { case SI_QUEUE: s = "SI_QUEUE"; break; case SI_TIMER: s = "SI_TIMER"; break; case SI_ASYNCIO: s = "SI_ASYNCIO"; break; case SI_MESGQ: s = "SI_MESGQ"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * print priocntlsys() (key, value) pair key. */ void print_pck(private_t *pri, int raw, long val) { const char *s = NULL; char clname[PC_CLNMSZ]; if ((pri->sys_args[2] != PC_GETXPARMS && pri->sys_args[2] != PC_SETXPARMS) || val == 0 || raw) { prt_dec(pri, 0, val); return; } if (pri->sys_args[3] == NULL) { if (val == PC_KY_CLNAME) { s = "PC_KY_CLNAME"; outstring(pri, s); } else prt_dec(pri, 0, val); return; } if (Pread(Proc, &clname, PC_CLNMSZ, pri->sys_args[3]) != PC_CLNMSZ) { prt_dec(pri, 0, val); return; } if (strcmp(clname, "TS") == 0) { switch (val) { case TS_KY_UPRILIM: s = "TS_KY_UPRILIM"; break; case TS_KY_UPRI: s = "TS_KY_UPRI"; break; default: break; } } else if (strcmp(clname, "IA") == 0) { switch (val) { case IA_KY_UPRILIM: s = "IA_KY_UPRILIM"; break; case IA_KY_UPRI: s = "IA_KY_UPRI"; break; case IA_KY_MODE: s = "IA_KY_MODE"; break; default: break; } } else if (strcmp(clname, "RT") == 0) { switch (val) { case RT_KY_PRI: s = "RT_KY_PRI"; break; case RT_KY_TQSECS: s = "RT_KY_TQSECS"; break; case RT_KY_TQNSECS: s = "RT_KY_TQNSECS"; break; case RT_KY_TQSIG: s = "RT_KY_TQSIG"; break; default: break; } } else if (strcmp(clname, "FSS") == 0) { switch (val) { case FSS_KY_UPRILIM: s = "FSS_KY_UPRILIM"; break; case FSS_KY_UPRI: s = "FSS_KY_UPRI"; break; default: break; } } else if (strcmp(clname, "FX") == 0) { switch (val) { case FX_KY_UPRILIM: s = "FX_KY_UPRILIM"; break; case FX_KY_UPRI: s = "FX_KY_UPRI"; break; case FX_KY_TQSECS: s = "FX_KY_TQSECS"; break; case FX_KY_TQNSECS: s = "FX_KY_TQNSECS"; break; default: break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * print priocntlsys() fourth argument. */ /*ARGSUSED*/ void prt_pc4(private_t *pri, int raw, long val) { /* look at pricntlsys function */ if ((pri->sys_args[2] != PC_GETXPARMS && pri->sys_args[2] != PC_SETXPARMS)) prt_hex(pri, 0, val); else if (val) prt_stg(pri, 0, val); else prt_dec(pri, 0, val); } /* * print priocntlsys() (key, value) pairs (5th argument). */ /*ARGSUSED*/ void prt_pc5(private_t *pri, int raw, long val) { pc_vaparms_t prms; pc_vaparm_t *vpp = &prms.pc_parms[0]; uint_t cnt; /* look at pricntlsys function */ if ((pri->sys_args[2] != PC_GETXPARMS && pri->sys_args[2] != PC_SETXPARMS) || val == 0) { prt_dec(pri, 0, 0); return; } if (Pread(Proc, &prms, sizeof (prms), val) != sizeof (prms)) { prt_hex(pri, 0, val); return; } if ((cnt = prms.pc_vaparmscnt) > PC_VAPARMCNT) return; for (; cnt--; vpp++) { print_pck(pri, 0, vpp->pc_key); outstring(pri, ", "); prt_hex(pri, 0, (long)vpp->pc_parm); outstring(pri, ", "); } prt_dec(pri, 0, PC_KY_NULL); } /* * Print processor set id, including logical expansion of "special" ids. */ void prt_pst(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch ((psetid_t)val) { case PS_NONE: s = "PS_NONE"; break; case PS_QUERY: s = "PS_QUERY"; break; case PS_MYID: s = "PS_MYID"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print meminfo() argument. */ /*ARGSUSED*/ void prt_mif(private_t *pri, int raw, long val) { struct meminfo minfo; #ifdef _LP64 if (data_model == PR_MODEL_ILP32) { struct meminfo32 minfo32; if (Pread(Proc, &minfo32, sizeof (struct meminfo32), val) != sizeof (struct meminfo32)) { prt_dec(pri, 0, pri->sys_args[1]); /* addr_count */ outstring(pri, ", "); prt_hex(pri, 0, val); return; } /* * arrange the arguments in the order that user calls with */ prt_hex(pri, 0, minfo32.mi_inaddr); outstring(pri, ", "); prt_dec(pri, 0, pri->sys_args[1]); /* addr_count */ outstring(pri, ", "); prt_hex(pri, 0, minfo32.mi_info_req); outstring(pri, ", "); prt_dec(pri, 0, minfo32.mi_info_count); outstring(pri, ", "); prt_hex(pri, 0, minfo32.mi_outdata); outstring(pri, ", "); prt_hex(pri, 0, minfo32.mi_validity); return; } #endif if (Pread(Proc, &minfo, sizeof (struct meminfo), val) != sizeof (struct meminfo)) { prt_dec(pri, 0, pri->sys_args[1]); /* addr_count */ outstring(pri, ", "); prt_hex(pri, 0, val); return; } /* * arrange the arguments in the order that user calls with */ prt_hex(pri, 0, (long)minfo.mi_inaddr); outstring(pri, ", "); prt_dec(pri, 0, pri->sys_args[1]); /* addr_count */ outstring(pri, ", "); prt_hex(pri, 0, (long)minfo.mi_info_req); outstring(pri, ", "); prt_dec(pri, 0, minfo.mi_info_count); outstring(pri, ", "); prt_hex(pri, 0, (long)minfo.mi_outdata); outstring(pri, ", "); prt_hex(pri, 0, (long)minfo.mi_validity); } /* * Print so_socket() 1st argument. */ /*ARGSUSED*/ void prt_pfm(private_t *pri, int raw, long val) { /* Protocol Families have same names as Address Families */ if ((ulong_t)val < MAX_AFCODES) { outstring(pri, "PF_"); outstring(pri, afcodes[val]); } else { prt_dec(pri, 0, val); } } /* * Print so_socket() 2nd argument. */ /*ARGSUSED*/ void prt_skt(private_t *pri, int raw, long val) { const char *s; if ((ulong_t)val <= MAX_SOCKTYPES && (s = socktype_codes[val]) != NULL) outstring(pri, s); else prt_dec(pri, 0, val); } /* * Print so_socket() 3rd argument. */ /*ARGSUSED*/ void prt_skp(private_t *pri, int raw, long val) { const char *s; /* cheating -- look at the protocol-family */ switch (pri->sys_args[0]) { case PF_INET6: case PF_INET: case PF_NCA: if ((s = ipprotos((int)val)) != NULL) { outstring(pri, s); break; } /* FALLTHROUGH */ default: prt_dec(pri, 0, val); break; } } /* * Print so_socket() 5th argument. */ /*ARGSUSED*/ void prt_skv(private_t *pri, int raw, long val) { switch (val) { case SOV_STREAM: outstring(pri, "SOV_STREAM"); break; case SOV_DEFAULT: outstring(pri, "SOV_DEFAULT"); break; case SOV_SOCKSTREAM: outstring(pri, "SOV_SOCKSTREAM"); break; case SOV_SOCKBSD: outstring(pri, "SOV_SOCKBSD"); break; case SOV_XPG4_2: outstring(pri, "SOV_XPG4_2"); break; default: prt_dec(pri, 0, val); break; } } /* * Print setsockopt()/getsockopt() 2nd argument. */ /*ARGSUSED*/ void prt_sol(private_t *pri, int raw, long val) { if (val == SOL_SOCKET) { outstring(pri, "SOL_SOCKET"); } else if (val == SOL_ROUTE) { outstring(pri, "SOL_ROUTE"); } else { const struct protoent *p; struct protoent res; char buf[NSS_BUFLEN_PROTOCOLS]; if ((p = getprotobynumber_r(val, &res, (char *)buf, sizeof (buf))) != NULL) outstring(pri, p->p_name); else prt_dec(pri, 0, val); } } const char * sol_optname(private_t *pri, long val) { #define CBSIZE sizeof (pri->code_buf) if (val >= SO_SNDBUF) { switch (val) { case SO_SNDBUF: return ("SO_SNDBUF"); case SO_RCVBUF: return ("SO_RCVBUF"); case SO_SNDLOWAT: return ("SO_SNDLOWAT"); case SO_RCVLOWAT: return ("SO_RCVLOWAT"); case SO_SNDTIMEO: return ("SO_SNDTIMEO"); case SO_RCVTIMEO: return ("SO_RCVTIMEO"); case SO_ERROR: return ("SO_ERROR"); case SO_TYPE: return ("SO_TYPE"); case SO_PROTOTYPE: return ("SO_PROTOTYPE"); case SO_ALLZONES: return ("SO_ALLZONES"); case SO_EXCLBIND: return ("SO_EXCLBIND"); case SO_DOMAIN: return ("SO_DOMAIN"); default: (void) snprintf(pri->code_buf, CBSIZE, "0x%lx", val); return (pri->code_buf); } } else { char *s = pri->code_buf; size_t used = 1; long val2; *s = '\0'; val2 = val & ~(SO_DEBUG|SO_ACCEPTCONN|SO_REUSEADDR|SO_KEEPALIVE| SO_DONTROUTE|SO_BROADCAST|SO_USELOOPBACK|SO_LINGER| SO_OOBINLINE|SO_DGRAM_ERRIND|SO_RECVUCRED); if (val2) used = snprintf(s, CBSIZE, "|0x%lx", val2); if (val & SO_DEBUG) used = strlcat(s, "|SO_DEBUG", CBSIZE); if (val & SO_ACCEPTCONN) used = strlcat(s, "|SO_ACCEPTCONN", CBSIZE); if (val & SO_REUSEADDR) used = strlcat(s, "|SO_REUSEADDR", CBSIZE); if (val & SO_KEEPALIVE) used = strlcat(s, "|SO_KEEPALIVE", CBSIZE); if (val & SO_DONTROUTE) used = strlcat(s, "|SO_DONTROUTE", CBSIZE); if (val & SO_BROADCAST) used = strlcat(s, "|SO_BROADCAST", CBSIZE); if (val & SO_USELOOPBACK) used = strlcat(s, "|SO_USELOOPBACK", CBSIZE); if (val & SO_LINGER) used = strlcat(s, "|SO_LINGER", CBSIZE); if (val & SO_OOBINLINE) used = strlcat(s, "|SO_OOBINLINE", CBSIZE); if (val & SO_DGRAM_ERRIND) used = strlcat(s, "|SO_DGRAM_ERRIND", CBSIZE); if (val & SO_RECVUCRED) used = strlcat(s, "|SO_RECVUCRED", CBSIZE); if (used >= CBSIZE || val == 0) (void) snprintf(s + 1, CBSIZE-1, "0x%lx", val); return ((const char *)(s + 1)); } #undef CBSIZE } const char * route_optname(private_t *pri, long val) { switch (val) { case RT_AWARE: return ("RT_AWARE"); default: (void) snprintf(pri->code_buf, sizeof (pri->code_buf), "0x%lx", val); return (pri->code_buf); } } const char * tcp_optname(private_t *pri, long val) { switch (val) { case TCP_NODELAY: return ("TCP_NODELAY"); case TCP_MAXSEG: return ("TCP_MAXSEG"); case TCP_KEEPALIVE: return ("TCP_KEEPALIVE"); case TCP_NOTIFY_THRESHOLD: return ("TCP_NOTIFY_THRESHOLD"); case TCP_ABORT_THRESHOLD: return ("TCP_ABORT_THRESHOLD"); case TCP_CONN_NOTIFY_THRESHOLD: return ("TCP_CONN_NOTIFY_THRESHOLD"); case TCP_CONN_ABORT_THRESHOLD: return ("TCP_CONN_ABORT_THRESHOLD"); case TCP_RECVDSTADDR: return ("TCP_RECVDSTADDR"); case TCP_ANONPRIVBIND: return ("TCP_ANONPRIVBIND"); case TCP_EXCLBIND: return ("TCP_EXCLBIND"); case TCP_INIT_CWND: return ("TCP_INIT_CWND"); case TCP_KEEPALIVE_THRESHOLD: return ("TCP_KEEPALIVE_THRESHOLD"); case TCP_KEEPALIVE_ABORT_THRESHOLD: return ("TCP_KEEPALIVE_ABORT_THRESHOLD"); case TCP_CORK: return ("TCP_CORK"); default: (void) snprintf(pri->code_buf, sizeof (pri->code_buf), "0x%lx", val); return (pri->code_buf); } } const char * sctp_optname(private_t *pri, long val) { switch (val) { case SCTP_RTOINFO: return ("SCTP_RTOINFO"); case SCTP_ASSOCINFO: return ("SCTP_ASSOCINFO"); case SCTP_INITMSG: return ("SCTP_INITMSG"); case SCTP_NODELAY: return ("SCTP_NODELAY"); case SCTP_AUTOCLOSE: return ("SCTP_AUTOCLOSE"); case SCTP_SET_PEER_PRIMARY_ADDR: return ("SCTP_SET_PEER_PRIMARY_ADDR"); case SCTP_PRIMARY_ADDR: return ("SCTP_PRIMARY_ADDR"); case SCTP_ADAPTATION_LAYER: return ("SCTP_ADAPTATION_LAYER"); case SCTP_DISABLE_FRAGMENTS: return ("SCTP_DISABLE_FRAGMENTS"); case SCTP_PEER_ADDR_PARAMS: return ("SCTP_PEER_ADDR_PARAMS"); case SCTP_DEFAULT_SEND_PARAM: return ("SCTP_DEFAULT_SEND_PARAM"); case SCTP_EVENTS: return ("SCTP_EVENTS"); case SCTP_I_WANT_MAPPED_V4_ADDR: return ("SCTP_I_WANT_MAPPED_V4_ADDR"); case SCTP_MAXSEG: return ("SCTP_MAXSEG"); case SCTP_STATUS: return ("SCTP_STATUS"); case SCTP_GET_PEER_ADDR_INFO: return ("SCTP_GET_PEER_ADDR_INFO"); case SCTP_ADD_ADDR: return ("SCTP_ADD_ADDR"); case SCTP_REM_ADDR: return ("SCTP_REM_ADDR"); default: (void) snprintf(pri->code_buf, sizeof (pri->code_buf), "0x%lx", val); return (pri->code_buf); } } const char * udp_optname(private_t *pri, long val) { switch (val) { case UDP_CHECKSUM: return ("UDP_CHECKSUM"); case UDP_ANONPRIVBIND: return ("UDP_ANONPRIVBIND"); case UDP_EXCLBIND: return ("UDP_EXCLBIND"); case UDP_RCVHDR: return ("UDP_RCVHDR"); case UDP_NAT_T_ENDPOINT: return ("UDP_NAT_T_ENDPOINT"); default: (void) snprintf(pri->code_buf, sizeof (pri->code_buf), "0x%lx", val); return (pri->code_buf); } } /* * Print setsockopt()/getsockopt() 3rd argument. */ /*ARGSUSED*/ void prt_son(private_t *pri, int raw, long val) { /* cheating -- look at the level */ switch (pri->sys_args[1]) { case SOL_SOCKET: outstring(pri, sol_optname(pri, val)); break; case SOL_ROUTE: outstring(pri, route_optname(pri, val)); break; case IPPROTO_TCP: outstring(pri, tcp_optname(pri, val)); break; case IPPROTO_UDP: outstring(pri, udp_optname(pri, val)); break; case IPPROTO_SCTP: outstring(pri, sctp_optname(pri, val)); break; default: prt_dec(pri, 0, val); break; } } /* * Print utrap type */ /*ARGSUSED*/ void prt_utt(private_t *pri, int raw, long val) { const char *s = NULL; #ifdef __sparc if (!raw) { switch (val) { case UT_INSTRUCTION_DISABLED: s = "UT_INSTRUCTION_DISABLED"; break; case UT_INSTRUCTION_ERROR: s = "UT_INSTRUCTION_ERROR"; break; case UT_INSTRUCTION_PROTECTION: s = "UT_INSTRUCTION_PROTECTION"; break; case UT_ILLTRAP_INSTRUCTION: s = "UT_ILLTRAP_INSTRUCTION"; break; case UT_ILLEGAL_INSTRUCTION: s = "UT_ILLEGAL_INSTRUCTION"; break; case UT_PRIVILEGED_OPCODE: s = "UT_PRIVILEGED_OPCODE"; break; case UT_FP_DISABLED: s = "UT_FP_DISABLED"; break; case UT_FP_EXCEPTION_IEEE_754: s = "UT_FP_EXCEPTION_IEEE_754"; break; case UT_FP_EXCEPTION_OTHER: s = "UT_FP_EXCEPTION_OTHER"; break; case UT_TAG_OVERFLOW: s = "UT_TAG_OVERFLOW"; break; case UT_DIVISION_BY_ZERO: s = "UT_DIVISION_BY_ZERO"; break; case UT_DATA_EXCEPTION: s = "UT_DATA_EXCEPTION"; break; case UT_DATA_ERROR: s = "UT_DATA_ERROR"; break; case UT_DATA_PROTECTION: s = "UT_DATA_PROTECTION"; break; case UT_MEM_ADDRESS_NOT_ALIGNED: s = "UT_MEM_ADDRESS_NOT_ALIGNED"; break; case UT_PRIVILEGED_ACTION: s = "UT_PRIVILEGED_ACTION"; break; case UT_ASYNC_DATA_ERROR: s = "UT_ASYNC_DATA_ERROR"; break; case UT_TRAP_INSTRUCTION_16: s = "UT_TRAP_INSTRUCTION_16"; break; case UT_TRAP_INSTRUCTION_17: s = "UT_TRAP_INSTRUCTION_17"; break; case UT_TRAP_INSTRUCTION_18: s = "UT_TRAP_INSTRUCTION_18"; break; case UT_TRAP_INSTRUCTION_19: s = "UT_TRAP_INSTRUCTION_19"; break; case UT_TRAP_INSTRUCTION_20: s = "UT_TRAP_INSTRUCTION_20"; break; case UT_TRAP_INSTRUCTION_21: s = "UT_TRAP_INSTRUCTION_21"; break; case UT_TRAP_INSTRUCTION_22: s = "UT_TRAP_INSTRUCTION_22"; break; case UT_TRAP_INSTRUCTION_23: s = "UT_TRAP_INSTRUCTION_23"; break; case UT_TRAP_INSTRUCTION_24: s = "UT_TRAP_INSTRUCTION_24"; break; case UT_TRAP_INSTRUCTION_25: s = "UT_TRAP_INSTRUCTION_25"; break; case UT_TRAP_INSTRUCTION_26: s = "UT_TRAP_INSTRUCTION_26"; break; case UT_TRAP_INSTRUCTION_27: s = "UT_TRAP_INSTRUCTION_27"; break; case UT_TRAP_INSTRUCTION_28: s = "UT_TRAP_INSTRUCTION_28"; break; case UT_TRAP_INSTRUCTION_29: s = "UT_TRAP_INSTRUCTION_29"; break; case UT_TRAP_INSTRUCTION_30: s = "UT_TRAP_INSTRUCTION_30"; break; case UT_TRAP_INSTRUCTION_31: s = "UT_TRAP_INSTRUCTION_31"; break; } } #endif /* __sparc */ if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print utrap handler */ void prt_uth(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch (val) { case (long)UTH_NOCHANGE: s = "UTH_NOCHANGE"; break; } } if (s == NULL) prt_hex(pri, 0, val); else outstring(pri, s); } const char * access_flags(private_t *pri, long arg) { #define E_OK 010 char *str = pri->code_buf; if (arg & ~(R_OK|W_OK|X_OK|E_OK)) return (NULL); /* NB: F_OK == 0 */ if (arg == F_OK) return ("F_OK"); if (arg == E_OK) return ("F_OK|E_OK"); *str = '\0'; if (arg & R_OK) (void) strlcat(str, "|R_OK", sizeof (pri->code_buf)); if (arg & W_OK) (void) strlcat(str, "|W_OK", sizeof (pri->code_buf)); if (arg & X_OK) (void) strlcat(str, "|X_OK", sizeof (pri->code_buf)); if (arg & E_OK) (void) strlcat(str, "|E_OK", sizeof (pri->code_buf)); return ((const char *)(str + 1)); #undef E_OK } /* * Print access() flags. */ void prt_acc(private_t *pri, int raw, long val) { const char *s = raw? NULL : access_flags(pri, val); if (s == NULL) prt_dex(pri, 0, val); else outstring(pri, s); } /* * Print shutdown() "how" (2nd) argument */ void prt_sht(private_t *pri, int raw, long val) { if (raw) { prt_dex(pri, 0, val); return; } switch (val) { case SHUT_RD: outstring(pri, "SHUT_RD"); break; case SHUT_WR: outstring(pri, "SHUT_WR"); break; case SHUT_RDWR: outstring(pri, "SHUT_RDWR"); break; default: prt_dec(pri, 0, val); break; } } /* * Print fcntl() F_SETFL flags (3rd) argument or fdsync flag (2nd arg) */ static struct fcntl_flags { long val; const char *name; } fcntl_flags[] = { #define FC_FL(flag) { (long)flag, "|" # flag } FC_FL(FREVOKED), FC_FL(FREAD), FC_FL(FWRITE), FC_FL(FNDELAY), FC_FL(FAPPEND), FC_FL(FSYNC), FC_FL(FDSYNC), FC_FL(FRSYNC), FC_FL(FOFFMAX), FC_FL(FNONBLOCK), FC_FL(FCREAT), FC_FL(FTRUNC), FC_FL(FEXCL), FC_FL(FNOCTTY), FC_FL(FXATTR), FC_FL(FASYNC), FC_FL(FNODSYNC) #undef FC_FL }; void prt_ffg(private_t *pri, int raw, long val) { #define CBSIZE sizeof (pri->code_buf) char *s = pri->code_buf; size_t used = 1; struct fcntl_flags *fp; if (raw) { (void) snprintf(s, CBSIZE, "0x%lx", val); outstring(pri, s); return; } if (val == 0) { outstring(pri, "(no flags)"); return; } *s = '\0'; for (fp = fcntl_flags; fp < &fcntl_flags[sizeof (fcntl_flags) / sizeof (*fp)]; fp++) { if (val & fp->val) { used = strlcat(s, fp->name, CBSIZE); val &= ~fp->val; } } if (val != 0 && used <= CBSIZE) used += snprintf(s + used, CBSIZE - used, "|0x%lx", val); if (used >= CBSIZE) (void) snprintf(s + 1, CBSIZE-1, "0x%lx", val); outstring(pri, s + 1); #undef CBSIZE } void prt_prs(private_t *pri, int raw, long val) { static size_t setsize; priv_set_t *set = priv_allocset(); if (setsize == 0) { const priv_impl_info_t *info = getprivimplinfo(); if (info != NULL) setsize = info->priv_setsize * sizeof (priv_chunk_t); } if (setsize != 0 && !raw && set != NULL && Pread(Proc, set, setsize, val) == setsize) { int i; outstring(pri, "{"); for (i = 0; i < setsize / sizeof (priv_chunk_t); i++) { char buf[9]; /* 8 hex digits + '\0' */ (void) snprintf(buf, sizeof (buf), "%08x", ((priv_chunk_t *)set)[i]); outstring(pri, buf); } outstring(pri, "}"); } else { prt_hex(pri, 0, val); } if (set != NULL) priv_freeset(set); } /* * Print privilege set operation. */ void prt_pro(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch ((priv_op_t)val) { case PRIV_ON: s = "PRIV_ON"; break; case PRIV_OFF: s = "PRIV_OFF"; break; case PRIV_SET: s = "PRIV_SET"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print privilege set name */ void prt_prn(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) s = priv_getsetbynum((int)val); if (s == NULL) prt_dec(pri, 0, val); else { char *dup = strdup(s); char *q; /* Do the best we can in this case */ if (dup == NULL) { outstring(pri, s); return; } outstring(pri, "PRIV_"); q = dup; while (*q != '\0') { *q = toupper(*q); q++; } outstring(pri, dup); free(dup); } } /* * Print process flag names. */ void prt_pfl(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch ((int)val) { case PRIV_DEBUG: s = "PRIV_DEBUG"; break; case PRIV_AWARE: s = "PRIV_AWARE"; break; case PRIV_XPOLICY: s = "PRIV_XPOLICY"; break; case NET_MAC_AWARE: s = "NET_MAC_AWARE"; break; case NET_MAC_AWARE_INHERIT: s = "NET_MAC_AWARE_INHERIT"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print lgrp_affinity_{get,set}() arguments. */ /*ARGSUSED*/ void prt_laf(private_t *pri, int raw, long val) { lgrp_affinity_args_t laff; if (Pread(Proc, &laff, sizeof (lgrp_affinity_args_t), val) != sizeof (lgrp_affinity_args_t)) { prt_hex(pri, 0, val); return; } /* * arrange the arguments in the order that user calls with */ prt_dec(pri, 0, laff.idtype); outstring(pri, ", "); prt_dec(pri, 0, laff.id); outstring(pri, ", "); prt_dec(pri, 0, laff.lgrp); outstring(pri, ", "); if (pri->sys_args[0] == LGRP_SYS_AFFINITY_SET) prt_dec(pri, 0, laff.aff); } /* * Print a key_t as IPC_PRIVATE if it is 0. */ void prt_key(private_t *pri, int raw, long val) { if (!raw && val == 0) outstring(pri, "IPC_PRIVATE"); else prt_dec(pri, 0, val); } /* * Print zone_getattr() attribute types. */ void prt_zga(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch ((int)val) { case ZONE_ATTR_NAME: s = "ZONE_ATTR_NAME"; break; case ZONE_ATTR_ROOT: s = "ZONE_ATTR_ROOT"; break; case ZONE_ATTR_STATUS: s = "ZONE_ATTR_STATUS"; break; case ZONE_ATTR_PRIVSET: s = "ZONE_ATTR_PRIVSET"; break; case ZONE_ATTR_UNIQID: s = "ZONE_ATTR_UNIQID"; break; case ZONE_ATTR_POOLID: s = "ZONE_ATTR_POOLID"; break; case ZONE_ATTR_INITPID: s = "ZONE_ATTR_INITPID"; break; case ZONE_ATTR_SLBL: s = "ZONE_ATTR_SLBL"; break; case ZONE_ATTR_INITNAME: s = "ZONE_ATTR_INITNAME"; break; case ZONE_ATTR_BOOTARGS: s = "ZONE_ATTR_BOOTARGS"; break; case ZONE_ATTR_BRAND: s = "ZONE_ATTR_BRAND"; break; case ZONE_ATTR_FLAGS: s = "ZONE_ATTR_FLAGS"; break; case ZONE_ATTR_PHYS_MCAP: s = "ZONE_ATTR_PHYS_MCAP"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print a file descriptor as AT_FDCWD if necessary */ void prt_atc(private_t *pri, int raw, long val) { if (!raw && val == AT_FDCWD) outstring(pri, "AT_FDCWD"); else prt_dec(pri, 0, val); } /* * Print Trusted Networking database operation codes (labelsys; tn*) */ static void prt_tnd(private_t *pri, int raw, long val) { const char *s = NULL; if (!raw) { switch ((tsol_dbops_t)val) { case TNDB_NOOP: s = "TNDB_NOOP"; break; case TNDB_LOAD: s = "TNDB_LOAD"; break; case TNDB_DELETE: s = "TNDB_DELETE"; break; case TNDB_FLUSH: s = "TNDB_FLUSH"; break; case TNDB_GET: s = "TNDB_GET"; break; } } if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print LIO_XX flags */ void prt_lio(private_t *pri, int raw, long val) { if (raw) prt_dec(pri, 0, val); else if (val == LIO_WAIT) outstring(pri, "LIO_WAIT"); else if (val == LIO_NOWAIT) outstring(pri, "LIO_NOWAIT"); else prt_dec(pri, 0, val); } const char * door_flags(private_t *pri, long val) { door_attr_t attr = (door_attr_t)val; char *str = pri->code_buf; *str = '\0'; #define PROCESS_FLAG(flg) \ if (attr & flg) { \ (void) strlcat(str, "|" #flg, sizeof (pri->code_buf)); \ attr &= ~flg; \ } PROCESS_FLAG(DOOR_UNREF); PROCESS_FLAG(DOOR_UNREF_MULTI); PROCESS_FLAG(DOOR_PRIVATE); PROCESS_FLAG(DOOR_REFUSE_DESC); PROCESS_FLAG(DOOR_NO_CANCEL); PROCESS_FLAG(DOOR_LOCAL); PROCESS_FLAG(DOOR_REVOKED); PROCESS_FLAG(DOOR_IS_UNREF); #undef PROCESS_FLAG if (attr != 0 || *str == '\0') { size_t len = strlen(str); (void) snprintf(str + len, sizeof (pri->code_buf) - len, "|0x%X", attr); } return (str + 1); } /* * Print door_create() flags */ void prt_dfl(private_t *pri, int raw, long val) { if (raw) prt_hex(pri, 0, val); else outstring(pri, door_flags(pri, val)); } /* * Print door_*param() param argument */ void prt_dpm(private_t *pri, int raw, long val) { if (raw) prt_hex(pri, 0, val); else if (val == DOOR_PARAM_DESC_MAX) outstring(pri, "DOOR_PARAM_DESC_MAX"); else if (val == DOOR_PARAM_DATA_MIN) outstring(pri, "DOOR_PARAM_DATA_MIN"); else if (val == DOOR_PARAM_DATA_MAX) outstring(pri, "DOOR_PARAM_DATA_MAX"); else prt_hex(pri, 0, val); } /* * Print rctlsys subcodes */ void prt_rsc(private_t *pri, int raw, long val) /* print utssys code */ { const char *s = raw? NULL : rctlsyscode(val); if (s == NULL) prt_dec(pri, 0, val); else outstring(pri, s); } /* * Print getrctl flags */ void prt_rgf(private_t *pri, int raw, long val) { long action = val & (~RCTLSYS_ACTION_MASK); if (raw) prt_hex(pri, 0, val); else if (action == RCTL_FIRST) outstring(pri, "RCTL_FIRST"); else if (action == RCTL_NEXT) outstring(pri, "RCTL_NEXT"); else if (action == RCTL_USAGE) outstring(pri, "RCTL_USAGE"); else prt_hex(pri, 0, val); } /* * Print setrctl flags */ void prt_rsf(private_t *pri, int raw, long val) { long action = val & (~RCTLSYS_ACTION_MASK); long pval = val & RCTL_LOCAL_ACTION_MASK; char *s = pri->code_buf; if (raw) { prt_hex(pri, 0, val); return; } else if (action == RCTL_INSERT) (void) strcpy(s, "RCTL_INSERT"); else if (action == RCTL_DELETE) (void) strcpy(s, "RCTL_DELETE"); else if (action == RCTL_REPLACE) (void) strcpy(s, "RCTL_REPLACE"); else { prt_hex(pri, 0, val); return; } if (pval & RCTL_USE_RECIPIENT_PID) { pval ^= RCTL_USE_RECIPIENT_PID; (void) strlcat(s, "|RCTL_USE_RECIPIENT_PID", sizeof (pri->code_buf)); } if ((pval & RCTLSYS_ACTION_MASK) != 0) prt_hex(pri, 0, val); else if (*s != '\0') outstring(pri, s); else prt_hex(pri, 0, val); } /* * Print rctlctl flags */ void prt_rcf(private_t *pri, int raw, long val) { long action = val & (~RCTLSYS_ACTION_MASK); if (raw) prt_hex(pri, 0, val); else if (action == RCTLCTL_GET) outstring(pri, "RCTLCTL_GET"); else if (action == RCTLCTL_SET) outstring(pri, "RCTLCTL_SET"); else prt_hex(pri, 0, val); } /* * Print setprojrctl flags */ void prt_spf(private_t *pri, int raw, long val) { long action = val & TASK_PROJ_MASK; if (!raw && (action == TASK_PROJ_PURGE)) outstring(pri, "TASK_PROJ_PURGE"); else prt_hex(pri, 0, val); } /* * Print forkx() flags */ void prt_fxf(private_t *pri, int raw, long val) { char *str; if (val == 0) outstring(pri, "0"); else if (raw || (val & ~(FORK_NOSIGCHLD | FORK_WAITPID))) prt_hhx(pri, 0, val); else { str = pri->code_buf; *str = '\0'; if (val & FORK_NOSIGCHLD) (void) strlcat(str, "|FORK_NOSIGCHLD", sizeof (pri->code_buf)); if (val & FORK_WAITPID) (void) strlcat(str, "|FORK_WAITPID", sizeof (pri->code_buf)); outstring(pri, str + 1); } } /* * Array of pointers to print functions, one for each format. */ void (* const Print[])() = { prt_nov, /* NOV -- no value */ prt_dec, /* DEC -- print value in decimal */ prt_oct, /* OCT -- print value in octal */ prt_hex, /* HEX -- print value in hexadecimal */ prt_dex, /* DEX -- print value in hexadecimal if big enough */ prt_stg, /* STG -- print value as string */ prt_ioc, /* IOC -- print ioctl code */ prt_fcn, /* FCN -- print fcntl code */ prt_s86, /* S86 -- print sysi86 code */ prt_uts, /* UTS -- print utssys code */ prt_opn, /* OPN -- print open code */ prt_sig, /* SIG -- print signal name plus flags */ prt_act, /* ACT -- print signal action value */ prt_msc, /* MSC -- print msgsys command */ prt_msf, /* MSF -- print msgsys flags */ prt_smc, /* SMC -- print semsys command */ prt_sef, /* SEF -- print semsys flags */ prt_shc, /* SHC -- print shmsys command */ prt_shf, /* SHF -- print shmsys flags */ prt_plk, /* PLK -- print plock code */ prt_sfs, /* SFS -- print sysfs code */ prt_rst, /* RST -- print string returned by syscall */ prt_smf, /* SMF -- print streams message flags */ prt_ioa, /* IOA -- print ioctl argument */ prt_six, /* SIX -- print signal, masked with SIGNO_MASK */ prt_mtf, /* MTF -- print mount flags */ prt_mft, /* MFT -- print mount file system type */ prt_iob, /* IOB -- print contents of I/O buffer */ prt_hhx, /* HHX -- print value in hexadecimal (half size) */ prt_wop, /* WOP -- print waitsys() options */ prt_spm, /* SPM -- print sigprocmask argument */ prt_rlk, /* RLK -- print readlink buffer */ prt_mpr, /* MPR -- print mmap()/mprotect() flags */ prt_mty, /* MTY -- print mmap() mapping type flags */ prt_mcf, /* MCF -- print memcntl() function */ prt_mc4, /* MC4 -- print memcntl() (fourth) argument */ prt_mc5, /* MC5 -- print memcntl() (fifth) argument */ prt_mad, /* MAD -- print madvise() argument */ prt_ulm, /* ULM -- print ulimit() argument */ prt_rlm, /* RLM -- print get/setrlimit() argument */ prt_cnf, /* CNF -- print sysconfig() argument */ prt_inf, /* INF -- print sysinfo() argument */ prt_ptc, /* PTC -- print pathconf/fpathconf() argument */ prt_fui, /* FUI -- print fusers() input argument */ prt_idt, /* IDT -- print idtype_t, waitid() argument */ prt_lwf, /* LWF -- print lwp_create() flags */ prt_itm, /* ITM -- print [get|set]itimer() arg */ prt_llo, /* LLO -- print long long offset arg */ prt_mod, /* MOD -- print modctl() subcode */ prt_whn, /* WHN -- print lseek() whence arguiment */ prt_acl, /* ACL -- print acl() code */ prt_aio, /* AIO -- print kaio() code */ prt_aud, /* AUD -- print auditsys() code */ prt_uns, /* DEC -- print value in unsigned decimal */ prt_clc, /* CLC -- print cladm command argument */ prt_clf, /* CLF -- print cladm flag argument */ prt_cor, /* COR -- print corectl() subcode */ prt_cco, /* CCO -- print corectl() options */ prt_ccc, /* CCC -- print corectl() content */ prt_rcc, /* RCC -- print corectl() returned content */ prt_cpc, /* CPC -- print cpc() subcode */ prt_sqc, /* SQC -- print sigqueue() si_code argument */ prt_pc4, /* PC4 -- print priocntlsys() (fourth) argument */ prt_pc5, /* PC5 -- print priocntlsys() (key, value) pairs */ prt_pst, /* PST -- print processor set id */ prt_mif, /* MIF -- print meminfo() arguments */ prt_pfm, /* PFM -- print so_socket() proto-family (1st) arg */ prt_skt, /* SKT -- print so_socket() socket-type (2nd) arg */ prt_skp, /* SKP -- print so_socket() protocol (3rd) arg */ prt_skv, /* SKV -- print socket version arg */ prt_sol, /* SOL -- print [sg]etsockopt() level (2nd) arg */ prt_son, /* SON -- print [sg]etsockopt() opt-name (3rd) arg */ prt_utt, /* UTT -- print utrap type */ prt_uth, /* UTH -- print utrap handler */ prt_acc, /* ACC -- print access() flags */ prt_sht, /* SHT -- print shutdown() how (2nd) argument */ prt_ffg, /* FFG -- print fcntl() flags (3rd) argument */ prt_prs, /* PRS -- print privilege set */ prt_pro, /* PRO -- print privilege set operation */ prt_prn, /* PRN -- print privilege set name */ prt_pfl, /* PFL -- print privilege/process flag name */ prt_laf, /* LAF -- print lgrp_affinity arguments */ prt_key, /* KEY -- print key_t 0 as IPC_PRIVATE */ prt_zga, /* ZGA -- print zone_getattr attribute types */ prt_atc, /* ATC -- print AT_FDCWD or file descriptor */ prt_lio, /* LIO -- print LIO_XX flags */ prt_dfl, /* DFL -- print door_create() flags */ prt_dpm, /* DPM -- print DOOR_PARAM_XX flags */ prt_tnd, /* TND -- print trusted network data base opcode */ prt_rsc, /* RSC -- print rctlsys() subcodes */ prt_rgf, /* RGF -- print getrctl() flags */ prt_rsf, /* RSF -- print setrctl() flags */ prt_rcf, /* RCF -- print rctlsys_ctl() flags */ prt_fxf, /* FXF -- print forkx() flags */ prt_spf, /* SPF -- print rctlsys_projset() flags */ prt_un1, /* UN1 -- as prt_uns except for -1 */ prt_dec, /* HID -- hidden argument, make this the last one */ };