/* Access, formatting, & comparison routines for printing process info. Copyright (C) 1995 Free Software Foundation, Inc. Written by Miles Bader This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include #include #include #include #include #include #include #include #include "ps.h" #include "common.h" /* ---------------------------------------------------------------- */ /* Getter definitions */ typedef void (*vf)(); static int ps_get_pid(proc_stat_t ps) { return proc_stat_pid(ps); } struct ps_getter ps_pid_getter = {"pid", PSTAT_PID, (vf) ps_get_pid}; static int ps_get_thread_index(proc_stat_t ps) { return proc_stat_thread_index(ps); } struct ps_getter ps_thread_index_getter = {"thread_index", PSTAT_THREAD, (vf) ps_get_thread_index}; static ps_user_t ps_get_owner(proc_stat_t ps) { return proc_stat_owner(ps); } struct ps_getter ps_owner_getter = {"owner", PSTAT_OWNER, (vf) ps_get_owner}; static int ps_get_ppid(proc_stat_t ps) { return proc_stat_info(ps)->ppid; } struct ps_getter ps_ppid_getter = {"ppid", PSTAT_INFO, (vf) ps_get_ppid}; static int ps_get_pgrp(proc_stat_t ps) { return proc_stat_info(ps)->pgrp; } struct ps_getter ps_pgrp_getter = {"pgrp", PSTAT_INFO, (vf) ps_get_pgrp}; static int ps_get_session(proc_stat_t ps) { return proc_stat_info(ps)->session; } struct ps_getter ps_session_getter = {"session", PSTAT_INFO, (vf) ps_get_session}; static int ps_get_login_col(proc_stat_t ps) { return proc_stat_info(ps)->logincollection; } struct ps_getter ps_login_col_getter = {"login_col", PSTAT_INFO, (vf) ps_get_login_col}; static int ps_get_num_threads(proc_stat_t ps) { return proc_stat_num_threads(ps); } struct ps_getter ps_num_threads_getter = {"num_threads", PSTAT_NUM_THREADS, (vf)ps_get_num_threads}; static void ps_get_args(proc_stat_t ps, char **args_p, int *args_len_p) { *args_p = proc_stat_args(ps); *args_len_p = proc_stat_args_len(ps); } struct ps_getter ps_args_getter = {"args", PSTAT_ARGS, ps_get_args}; static int ps_get_state(proc_stat_t ps) { return proc_stat_state(ps); } struct ps_getter ps_state_getter = {"state", PSTAT_STATE, (vf) ps_get_state}; static int ps_get_vsize(proc_stat_t ps) { return proc_stat_info(ps)->taskinfo.virtual_size; } struct ps_getter ps_vsize_getter = {"vsize", PSTAT_INFO, (vf) ps_get_vsize}; static int ps_get_rsize(proc_stat_t ps) { return proc_stat_info(ps)->taskinfo.resident_size; } struct ps_getter ps_rsize_getter = {"rsize", PSTAT_INFO, (vf) ps_get_rsize}; static int ps_get_cur_priority(proc_stat_t ps) { return proc_stat_thread_sched_info(ps)->cur_priority; } struct ps_getter ps_cur_priority_getter = {"cur_priority", PSTAT_THREAD_INFO, (vf) ps_get_cur_priority}; static int ps_get_base_priority(proc_stat_t ps) { return proc_stat_thread_sched_info(ps)->base_priority; } struct ps_getter ps_base_priority_getter = {"base_priority", PSTAT_THREAD_INFO, (vf) ps_get_base_priority}; static int ps_get_max_priority(proc_stat_t ps) { return proc_stat_thread_sched_info(ps)->max_priority; } struct ps_getter ps_max_priority_getter = {"max_priority", PSTAT_THREAD_INFO, (vf) ps_get_max_priority}; static void ps_get_usr_time(proc_stat_t ps, time_value_t * tv_out) { *tv_out = proc_stat_thread_basic_info(ps)->user_time; } struct ps_getter ps_usr_time_getter = {"usr_time", PSTAT_THREAD_INFO, ps_get_usr_time}; static void ps_get_sys_time(proc_stat_t ps, time_value_t * tv_out) { *tv_out = proc_stat_thread_basic_info(ps)->system_time; } struct ps_getter ps_sys_time_getter = {"sys_time", PSTAT_THREAD_INFO, ps_get_sys_time}; static void ps_get_tot_time(proc_stat_t ps, time_value_t * tv_out) { *tv_out = proc_stat_thread_basic_info(ps)->user_time; time_value_add(tv_out, &proc_stat_thread_basic_info(ps)->system_time); } struct ps_getter ps_tot_time_getter = {"tot_time", PSTAT_THREAD_INFO, ps_get_tot_time}; static float ps_get_rmem_frac(proc_stat_t ps) { static int mem_size = 0; if (mem_size == 0) { host_basic_info_t info; error_t err = ps_host_basic_info(&info); if (err == 0) mem_size = info->memory_size; } if (mem_size > 0) return (float)proc_stat_info(ps)->taskinfo.resident_size / (float)mem_size; else return 0.0; } struct ps_getter ps_rmem_frac_getter = {"rmem_frac", PSTAT_INFO, (vf) ps_get_rmem_frac}; static float ps_get_cpu_frac(proc_stat_t ps) { return (float) proc_stat_thread_basic_info(ps)->cpu_usage / (float) TH_USAGE_SCALE; } struct ps_getter ps_cpu_frac_getter = {"cpu_frac", PSTAT_THREAD_INFO, (vf) ps_get_cpu_frac}; static int ps_get_sleep(proc_stat_t ps) { return proc_stat_thread_basic_info(ps)->sleep_time; } struct ps_getter ps_sleep_getter = {"sleep", PSTAT_THREAD_INFO, (vf) ps_get_sleep}; static int ps_get_susp_count(proc_stat_t ps) { return proc_stat_suspend_count(ps); } struct ps_getter ps_susp_count_getter = {"susp_count", PSTAT_SUSPEND_COUNT, (vf) ps_get_susp_count}; static int ps_get_proc_susp_count(proc_stat_t ps) { return proc_stat_info(ps)->taskinfo.suspend_count; } struct ps_getter ps_proc_susp_count_getter = {"proc_susp_count", PSTAT_INFO, (vf) ps_get_proc_susp_count}; static int ps_get_thread_susp_count(proc_stat_t ps) { return proc_stat_thread_basic_info(ps)->suspend_count; } struct ps_getter ps_thread_susp_count_getter = {"thread_susp_count", PSTAT_SUSPEND_COUNT, (vf) ps_get_thread_susp_count}; static ps_tty_t ps_get_tty(proc_stat_t ps) { return proc_stat_tty(ps); } struct ps_getter ps_tty_getter = {"tty", PSTAT_TTY, (vf)ps_get_tty}; static int ps_get_page_faults(proc_stat_t ps) { return proc_stat_task_events_info(ps)->faults; } struct ps_getter ps_page_faults_getter = {"page_faults", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_page_faults}; static int ps_get_cow_faults(proc_stat_t ps) { return proc_stat_task_events_info(ps)->cow_faults; } struct ps_getter ps_cow_faults_getter = {"cow_faults", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_cow_faults}; static int ps_get_pageins(proc_stat_t ps) { return proc_stat_task_events_info(ps)->pageins; } struct ps_getter ps_pageins_getter = {"pageins", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_pageins}; static int ps_get_msgs_sent(proc_stat_t ps) { return proc_stat_task_events_info(ps)->messages_sent; } struct ps_getter ps_msgs_sent_getter = {"msgs_sent", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_msgs_sent}; static int ps_get_msgs_rcvd(proc_stat_t ps) { return proc_stat_task_events_info(ps)->messages_received; } struct ps_getter ps_msgs_rcvd_getter = {"msgs_rcvd", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_msgs_rcvd}; static int ps_get_zero_fills(proc_stat_t ps) { return proc_stat_task_events_info(ps)->zero_fills; } struct ps_getter ps_zero_fills_getter = {"zero_fills", PSTAT_TASK_EVENTS_INFO, (vf) ps_get_zero_fills}; /* ---------------------------------------------------------------- */ /* some printing functions */ /* G() is a helpful macro that just returns the getter G's access function cast into a function pointer returning TYPE, as how the function should be called varies depending on the getter */ #define G(g,type)((type (*)())ps_getter_function(g)) error_t ps_emit_int(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { return ps_write_int_field(G(getter, int)(ps), width, stream, count); } error_t ps_emit_priority(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { return ps_write_int_field(MACH_PRIORITY_TO_NICE(G(getter, int)(ps)), width, stream, count); } error_t ps_emit_num_blocks(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char buf[20]; sprintf(buf, "%d", G(getter, int)(ps) / 1024); return ps_write_field(buf, width, stream, count); } int sprint_frac_value(char *buf, int value, int min_value_len, int frac, int frac_scale, int width) { int value_len; int frac_len; if (value >= 100) /* the integer part */ value_len = 3; else if (value >= 10) value_len = 2; else value_len = 1; while (value_len < min_value_len--) *buf++ = '0'; for (frac_len = frac_scale ; frac_len > 0 && (width < value_len + 1 + frac_len || frac % 10 == 0) ; frac_len--) frac /= 10; if (frac_len > 0) sprintf(buf, "%d.%0*d", value, frac_len, frac); else sprintf(buf, "%d", value); return strlen(buf); } error_t ps_emit_percent(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char buf[20]; float perc = G(getter, float)(ps) * 100; if (width == 0) sprintf(buf, "%g", perc); else if (ABS(width) > 3) sprintf(buf, "%.*f", ABS(width) - 3, perc); else sprintf(buf, "%d", (int) perc); return ps_write_field(buf, width, stream, count); } /* prints its value nicely */ error_t ps_emit_nice_int(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char buf[20]; int value = G(getter, int)(ps); char *sfx = " KMG"; int frac = 0; while (value >= 1024) { frac = ((value & 0x3FF) * 1000) >> 10; value >>= 10; sfx++; } sprintf(buf + sprint_frac_value(buf, value, 1, frac, 3, ABS(width) - 1), "%c", *sfx); return ps_write_field(buf, width, stream, count); } #define MINUTE 60 #define HOUR (60*MINUTE) #define DAY (24*HOUR) #define WEEK (7*DAY) static int sprint_long_time(char *buf, int seconds, int width) { char *p = buf; struct tscale { int length; char *sfx; char *short_sfx; } time_scales[] = { { WEEK, " week", "wk"} , { DAY, " day", "dy"} , { HOUR, " hour", "hr"} , { MINUTE," min", "m"} , { 0} }; struct tscale *ts = time_scales; while (ts->length > 0 && width > 0) { if (ts->length < seconds) { int len; int num = seconds / ts->length; seconds %= ts->length; sprintf(p, "%d%s", num, ts->sfx); len = strlen(p); width -= len; if (width < 0 && p > buf) break; p += len; } ts++; } *p = '\0'; return p - buf; } error_t ps_emit_nice_seconds(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char buf[20]; time_value_t tv; G(getter, int)(ps, &tv); if (tv.seconds == 0) { if (tv.microseconds < 500) sprintf(buf, "%dus", tv.microseconds); else strcpy(buf + sprint_frac_value(buf, tv.microseconds / 1000, 1, tv.microseconds % 1000, 3, ABS(width) - 2), "ms"); } else if (tv.seconds < MINUTE) sprint_frac_value(buf, tv.seconds, 1, tv.microseconds, 6, ABS(width)); else if (tv.seconds < HOUR) { /* 0:00.00... */ int min_len; sprintf(buf, "%d:", tv.seconds / 60); min_len = strlen(buf); sprint_frac_value(buf + min_len, tv.seconds % 60, 2, tv.microseconds, 6, ABS(width) - min_len); } else sprint_long_time(buf, tv.seconds, width); return ps_write_field(buf, width, stream, count); } static int append_fraction(char *buf, int frac, int digits, int width) { int slen = strlen(buf); int left = width - strlen(buf); if (left > 1) { buf[slen] = '.'; left--; while (digits > left) frac /= 10, digits--; sprintf(buf + slen + 1, "%0*d", digits, frac); return slen + 1 + digits; } else return slen; } error_t ps_emit_seconds(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { int max = (width == 0 ? 999 : ABS(width)); char buf[20]; time_value_t tv; G(getter, void)(ps, &tv); if (tv.seconds > DAY) sprint_long_time(buf, tv.seconds, max); else if (tv.seconds > HOUR) if (max >= 8) { /* 0:00:00.00... */ sprintf(buf, "%2d:%02d:%02d", tv.seconds / HOUR, (tv.seconds % HOUR) / MINUTE, (tv.seconds % MINUTE)); append_fraction(buf, tv.microseconds, 6, max); } else sprint_long_time(buf, tv.seconds, max); else if (max >= 5 || tv.seconds > MINUTE) { /* 0:00.00... */ sprintf(buf, "%2d:%02d", tv.seconds / MINUTE, tv.seconds % MINUTE); append_fraction(buf, tv.microseconds, 6, max); } else sprint_frac_value(buf, tv.seconds, 1, tv.microseconds, 6, max); return ps_write_field(buf, width, stream, count); } error_t ps_emit_uid(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { ps_user_t u = G(getter, ps_user_t)(ps); return ps_write_int_field(ps_user_uid(u), width, stream, count); } error_t ps_emit_uname(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { ps_user_t u = G(getter, ps_user_t)(ps); struct passwd *pw = ps_user_passwd(u); if (pw == NULL) return ps_write_int_field(ps_user_uid(u), width, stream, count); else return ps_write_field(pw->pw_name, width, stream, count); } /* prints a string with embedded nuls as spaces */ error_t ps_emit_string0(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char *s0, *p, *q; int s0len; int fwidth = ABS(width); char static_buf[200]; char *buf = static_buf; G(getter, void)(ps, &s0, &s0len); if (s0 == NULL) *buf = '\0'; else { if (s0len > sizeof static_buf) { buf = malloc(s0len + 1); if (buf == NULL) return ENOMEM; } if (fwidth == 0 || fwidth > s0len) fwidth = s0len; for (p = buf, q = s0; fwidth-- > 0; p++, q++) { int ch = *q; *p = (ch == '\0' ? ' ' : ch); } if (q > s0 && *(q - 1) == '\0') *--p = '\0'; else *p = '\0'; } { error_t err = ps_write_field(buf, width, stream, count); if (buf != static_buf) free(buf); return err; } } error_t ps_emit_string(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char *str; int len; G(getter, void)(ps, &str, &len); if (str == NULL) str = ""; else if (width != 0 && len > ABS(width)) str[ABS(width)] = '\0'; return ps_write_field(str, width, stream, count); } error_t ps_emit_tty_name(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char *name = "-"; ps_tty_t tty = G(getter, ps_tty_t)(ps); if (tty) { name = ps_tty_short_name(tty); if (name == NULL || *name == '\0') name = "?"; } return ps_write_field(name, width, stream, count); } struct state_shadow { /* If any states in STATES are set, the states in shadow are suppressed. */ int states; int shadow; }; struct state_shadow state_shadows[] = { /* Don't show sleeping thread if one is running, or the process is stopped.*/ { PSTAT_STATE_T_RUN | PSTAT_STATE_P_STOP, PSTAT_STATE_T_SLEEP | PSTAT_STATE_T_IDLE | PSTAT_STATE_T_WAIT }, /* Only show the longest sleep. */ { PSTAT_STATE_T_IDLE, PSTAT_STATE_T_SLEEP | PSTAT_STATE_T_WAIT }, { PSTAT_STATE_T_SLEEP, PSTAT_STATE_T_WAIT }, /* Turn off the per-thread stop bits when the process is stopped, as they're expected. */ { PSTAT_STATE_P_STOP, PSTAT_STATE_T_HALT | PSTAT_STATE_T_UNCLEAN }, { 0 } }; error_t ps_emit_state(proc_stat_t ps, ps_getter_t getter, int width, FILE *stream, unsigned *count) { char *tags; int raw_state = G(getter, int)(ps); int state = raw_state; char buf[20], *p = buf; struct state_shadow *shadow = state_shadows; while (shadow->states) { if (raw_state & shadow->states) state &= ~shadow->shadow; shadow++; } for (tags = proc_stat_state_tags ; state != 0 && *tags != '\0' ; state >>= 1, tags++) if (state & 1) *p++ = *tags; *p = '\0'; return ps_write_field(buf, width, stream, count); } /* ---------------------------------------------------------------- */ /* comparison functions */ /* Evaluates CALL if both s1 & s2 are non-NULL, and otherwise returns -1, 0, or 1 ala strcmp, considering NULL to be less than non-NULL. */ #define GUARDED_CMP(s1, s2, call) \ ((s1) == NULL ? (((s2) == NULL) ? 0 : -1) : ((s2) == NULL ? 1 : (call))) int ps_cmp_ints(proc_stat_t ps1, proc_stat_t ps2, ps_getter_t getter) { int (*gf)() = G(getter, int); int v1 = gf(ps1), v2 = gf(ps2); return v1 == v2 ? 0 : v1 < v2 ? -1 : 1; } int ps_cmp_floats(proc_stat_t ps1, proc_stat_t ps2, ps_getter_t getter) { float (*gf)() = G(getter, float); float v1 = gf(ps1), v2 = gf(ps2); return v1 == v2 ? 0 : v1 < v2 ? -1 : 1; } int ps_cmp_uids(proc_stat_t ps1, proc_stat_t ps2, ps_getter_t getter) { ps_user_t (*gf)() = G(getter, ps_user_t); ps_user_t u1 = gf(ps1), u2 = gf(ps2); return ps_user_uid(u1) - ps_user_uid(u2); } int ps_cmp_unames(proc_stat_t ps1, proc_stat_t ps2, ps_getter_t getter) { ps_user_t (*gf)() = G(getter, ps_user_t); ps_user_t u1 = gf(ps1), u2 = gf(ps2); struct passwd *pw1 = ps_user_passwd(u1), *pw2 = ps_user_passwd(u2); return GUARDED_CMP(pw1, pw2, strcmp(pw1->pw_name, pw2->pw_name)); } int ps_cmp_strings(proc_stat_t ps1, proc_stat_t ps2, ps_getter_t getter) { void (*gf)() = G(getter, void); char *s1, *s2; int s1len, s2len; /* Get both strings */ gf(ps1, &s1, &s1len); gf(ps2, &s2, &s2len); return GUARDED_CMP(s1, s2, strncmp(s1, s2, MIN(s1len, s2len))); } /* ---------------------------------------------------------------- */ /* `Nominal' functions -- return true for `unexciting' values. */ /* For many things, zero is not so interesting. */ bool ps_nominal_zint (proc_stat_t ps, ps_getter_t getter) { return G(getter, int)(ps) == 0; } /* Priorities are similar, but have to be converted to the unix nice scale first. */ bool ps_nominal_pri (proc_stat_t ps, ps_getter_t getter) { return MACH_PRIORITY_TO_NICE(G(getter, int)(ps)) == 0; } /* Hurd processes usually have 2 threads; XXX is there someplace we get get this number from? */ bool ps_nominal_nth (proc_stat_t ps, ps_getter_t getter) { return G(getter, int)(ps) == 2; } /* A user is nominal if it's the current user. */ bool ps_nominal_user (proc_stat_t ps, ps_getter_t getter) { static int own_uid = -1; ps_user_t u = G(getter, ps_user_t)(ps); if (own_uid < 0) own_uid = getuid(); return u->uid == own_uid; } /* ---------------------------------------------------------------- */ ps_fmt_spec_t find_ps_fmt_spec(char *name, ps_fmt_spec_t specs) { while (!ps_fmt_spec_is_end(specs)) if (strcasecmp(ps_fmt_spec_name(specs), name) == 0) return specs; else specs++; return NULL; } /* ---------------------------------------------------------------- */ struct ps_fmt_spec ps_std_fmt_specs[] = { {"PID", &ps_pid_getter, ps_emit_int, ps_cmp_ints, 0, -5}, {"TH#", &ps_thread_index_getter,ps_emit_int, ps_cmp_ints, 0, -2}, {"PPID", &ps_ppid_getter, ps_emit_int, ps_cmp_ints, 0, -5}, {"UID", &ps_owner_getter, ps_emit_uid, ps_cmp_uids, ps_nominal_user,-5}, {"User", &ps_owner_getter, ps_emit_uname, ps_cmp_unames, ps_nominal_user, 8}, {"NTh", &ps_num_threads_getter, ps_emit_int, ps_cmp_ints, ps_nominal_nth, -2}, {"PGrp", &ps_pgrp_getter, ps_emit_int, ps_cmp_ints, 0, -5}, {"Sess", &ps_session_getter, ps_emit_int, ps_cmp_ints, 0, -5}, {"LColl", &ps_login_col_getter, ps_emit_int, ps_cmp_ints, 0, -5}, {"Args", &ps_args_getter, ps_emit_string0, ps_cmp_strings,0, 0}, {"Arg0", &ps_args_getter, ps_emit_string, ps_cmp_strings,0, 0}, {"Time", &ps_tot_time_getter, ps_emit_seconds, ps_cmp_ints, 0, -8}, {"UTime", &ps_usr_time_getter, ps_emit_seconds, ps_cmp_ints, 0, -8}, {"STime", &ps_sys_time_getter, ps_emit_seconds, ps_cmp_ints, 0, -8}, {"VSize", &ps_vsize_getter, ps_emit_nice_int,ps_cmp_ints, 0, -5}, {"RSize", &ps_rsize_getter, ps_emit_nice_int,ps_cmp_ints, 0, -5}, {"Pri", &ps_cur_priority_getter,ps_emit_priority,ps_cmp_ints, ps_nominal_pri, -3}, {"BPri", &ps_base_priority_getter,ps_emit_priority,ps_cmp_ints, ps_nominal_pri, -3}, {"MPri", &ps_max_priority_getter,ps_emit_priority,ps_cmp_ints, ps_nominal_pri, -3}, {"%Mem", &ps_rmem_frac_getter, ps_emit_percent, ps_cmp_floats, 0, -4}, {"%CPU", &ps_cpu_frac_getter, ps_emit_percent, ps_cmp_floats, 0, -4}, {"State", &ps_state_getter, ps_emit_state, 0, 0, 4}, {"Sleep", &ps_sleep_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-2}, {"Susp", &ps_susp_count_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-2}, {"PSusp", &ps_proc_susp_count_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-2}, {"TSusp", &ps_thread_susp_count_getter, ps_emit_int,ps_cmp_ints, ps_nominal_zint,-2}, {"TTY", &ps_tty_getter, ps_emit_tty_name,ps_cmp_strings,0, 2}, {"PgFlts", &ps_page_faults_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {"COWFlts", &ps_cow_faults_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {"PgIns", &ps_pageins_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {"MsgIn", &ps_msgs_rcvd_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {"MsgOut", &ps_msgs_sent_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {"ZFills", &ps_zero_fills_getter, ps_emit_int, ps_cmp_ints, ps_nominal_zint,-5}, {0} };