/* g/t.c - ** ** This file is in the public domain. */ #include "all.h" #include /* u3t_push(): push on trace stack. */ void u3t_push(u3_noun mon) { u3R->bug.tax = u3nc(mon, u3R->bug.tax); } /* u3t_mean(): push `[%mean roc]` on trace stack. */ void u3t_mean(u3_noun roc) { u3R->bug.tax = u3nc(u3nc(c3__mean, roc), u3R->bug.tax); } /* u3t_drop(): drop from meaning stack. */ void u3t_drop(void) { c3_assert(_(u3du(u3R->bug.tax))); { u3_noun tax = u3R->bug.tax; u3R->bug.tax = u3k(u3t(tax)); u3z(tax); } } extern void u3_lo_tank(c3_l tab_l, u3_noun tac); #ifdef GHETTO /* _t_ghetto(): ghetto timelapse. */ void _t_ghetto(void) { static int old; static struct timeval b4, f2, d0; static c3_d b4_d; c3_w ms_w; if ( old ) { gettimeofday(&f2, 0); timersub(&f2, &b4, &d0); ms_w = (d0.tv_sec * 1000) + (d0.tv_usec / 1000); if (ms_w > 1) { #if 0 printf("%6d.%02dms: %9d ", ms_w, (int) (d0.tv_usec % 1000) / 10, ((int) (u3R->pro.nox_d - b4_d))); #else printf("%6d.%02dms ", ms_w, (int) (d0.tv_usec % 1000) / 10); #endif gettimeofday(&b4, 0); b4_d = u3R->pro.nox_d; } else { printf(" "); } } else { gettimeofday(&b4, 0); b4_d = u3R->pro.nox_d; } old = 1; } #endif /* u3t_slog(): print directly. */ void u3t_slog(u3_noun hod) { #ifdef GHETTO _t_ghetto(); #endif if ( c3y == u3du(hod) ) { u3_noun pri = u3h(hod); switch ( pri ) { case 3: printf(">>> "); break; case 2: printf(">> "); break; case 1: printf("> "); break; } u3_lo_tank(0, u3k(u3t(hod))); } u3z(hod); } /* u3t_shiv(): quick print. */ void u3t_shiv(u3_noun hod) { #ifdef GHETTO _t_ghetto(); #endif if ( c3n == u3ud(hod) ) { } else { c3_c *str_c = u3r_string(hod); printf("%s\r\n", str_c); free(str_c); } } /* u3t_heck(): profile point. */ void u3t_heck(u3_atom cog) { // Profile sampling, because it allocates on the home road, // only works on when we're not at home. // if ( &(u3H->rod_u) != u3R ) { u3a_road* rod_u; rod_u = u3R; u3R = &(u3H->rod_u); { if ( 0 == u3R->pro.day ) { u3R->pro.day = u3v_do("doss", 0); } u3R->pro.day = u3dc("pi-heck", u3a_take(cog), u3R->pro.day); } u3R = rod_u; } } /* _t_jet_label(): */ u3_weak _t_jet_label(u3a_road* rod_u, u3_noun bat) { while ( 1 ) { u3_weak cax = u3h_git(rod_u->jed.har_p, bat); if ( u3_none != cax ) { return u3h(u3t(u3t(u3h(cax)))); } if ( rod_u->par_p ) { rod_u = u3to(u3_road, rod_u->par_p); } else return u3_none; } } #if 1 /* _t_samp_process(): process raw sample data from live road. */ static u3_noun _t_samp_process(u3_road* rod_u) { u3_noun pef = u3_nul; // (list (pair path (map path ,@ud))) u3_noun muf = u3_nul; // (map path ,@ud) c3_w len_w = 0; // Accumulate a label/map stack which collapses recursive segments. // while ( rod_u ) { u3_noun don = rod_u->pro.don; while ( u3_nul != don ) { u3_noun bat = u3h(don); u3_noun lab; // Find the label from this battery, surface allocated. // { u3_noun laj = _t_jet_label(rod_u, bat); if ( u3_none == laj ) { abort(); } // lab = u3nc(u3i_string("foobar"), u3_nul); lab = u3a_take(laj); u3a_wash(laj); } // Add the label to the traced label stack, trimming recursion. // { u3_noun old; if ( u3_none == (old = u3kdb_get(u3k(muf), u3k(lab))) ) { muf = u3kdb_put(muf, u3k(lab), len_w); pef = u3nc(u3nc(lab, u3k(muf)), pef); len_w += 1; } else { u3_assure(u3a_is_cat(old)); u3z(muf); while ( len_w > (old + 1) ) { u3_noun t_pef = u3k(u3t(pef)); len_w -= 1; u3z(pef); pef = t_pef; } muf = u3k(u3t(u3h(pef))); u3z(lab); } } don = u3t(don); } rod_u = u3tn(u3_road, rod_u->par_p); } u3z(muf); // Lose the maps and save a pure label stack in original order. // { u3_noun pal = u3_nul; while ( u3_nul != pef ) { u3_noun h_pef = u3h(pef); u3_noun t_pef = u3k(u3t(pef)); pal = u3nc(u3k(u3h(h_pef)), pal); u3z(pef); pef = t_pef; } // fprintf(stderr, "sample: stack length %d\r\n", u3kb_lent(u3k(pal))); return pal; } } #endif /* u3t_samp(): sample. */ void u3t_samp(void) { u3C.wag_w &= ~u3o_debug_cpu; static int home = 0; static int away = 0; // Profile sampling, because it allocates on the home road, // only works on when we're not at home. // if ( &(u3H->rod_u) != u3R ) { home++; c3_l mot_l; u3a_road* rod_u; if ( _(u3T.mal_o) ) { mot_l = c3_s3('m','a','l'); } else if ( _(u3T.coy_o) ) { mot_l = c3_s3('c','o','y'); } else if ( _(u3T.euq_o) ) { mot_l = c3_s3('e','u','q'); } else if ( _(u3T.far_o) ) { mot_l = c3_s3('f','a','r'); } else if ( _(u3T.noc_o) ) { c3_assert(!_(u3T.glu_o)); mot_l = c3_s3('n','o','c'); } else if ( _(u3T.glu_o) ) { mot_l = c3_s3('g','l','u'); } else { mot_l = c3_s3('f','u','n'); } rod_u = u3R; u3R = &(u3H->rod_u); { u3_noun lab = _t_samp_process(rod_u); c3_assert(u3R == &u3H->rod_u); if ( 0 == u3R->pro.day ) { u3R->pro.day = u3v_do("doss", 0); } u3R->pro.day = u3dt("pi-noon", mot_l, lab, u3R->pro.day); } u3R = rod_u; } else { away++; // fprintf(stderr,"home: %06d away: %06d\r\n", home, away); } u3C.wag_w |= u3o_debug_cpu; } /* u3t_come(): push on profile stack; return yes if active push. RETAIN. */ c3_o u3t_come(u3_noun bat) { if ( (u3_nul == u3R->pro.don) || !_(u3r_sing(bat, u3h(u3R->pro.don))) ) { u3R->pro.don = u3nc(u3k(bat), u3R->pro.don); return c3y; } else return c3n; } /* u3t_flee(): pop off profile stack. */ void u3t_flee(void) { u3_noun t_don = u3k(u3t(u3R->pro.don)); u3R->pro.don = t_don; u3z(u3R->pro.don); } /* u3t_damp(): print and clear profile data. */ void u3t_damp(void) { if ( 0 != u3R->pro.day ) { u3_noun wol = u3do("pi-tell", u3R->pro.day); u3m_wall(wol); u3R->pro.day = u3v_do("doss", 0); } #if 0 if ( 0 != u3R->pro.nox_d ) { printf("knox: %llu\r\n", (u3R->pro.nox_d / 1000ULL)); u3R->pro.nox_d = 0; } #endif } /* _ct_sigaction(): profile sigaction callback. */ void _ct_sigaction(c3_i x_i) { // fprintf(stderr, "itimer!\r\n"); abort(); u3t_samp(); } /* u3t_init(): initialize tracing layer. */ void u3t_init(void) { u3T.noc_o = c3n; u3T.glu_o = c3n; u3T.mal_o = c3n; u3T.far_o = c3n; u3T.coy_o = c3n; u3T.euq_o = c3n; } /* u3t_boot(): turn sampling on. */ void u3t_boot(void) { if ( u3C.wag_w & u3o_debug_cpu ) { #if defined(U3_OS_osx) #if 1 { struct itimerval itm_v; struct sigaction sig_s; sigset_t set; sig_s.__sigaction_u.__sa_handler = _ct_sigaction; sig_s.sa_mask = 0; sig_s.sa_flags = 0; sigaction(SIGPROF, &sig_s, 0); sigemptyset(&set); sigaddset(&set, SIGPROF); if ( 0 != pthread_sigmask(SIG_UNBLOCK, &set, NULL) ) { perror("pthread_sigmask"); } itm_v.it_interval.tv_sec = 0; itm_v.it_interval.tv_usec = 10000; // itm_v.it_interval.tv_usec = 100000; itm_v.it_value = itm_v.it_interval; setitimer(ITIMER_PROF, &itm_v, 0); } #endif #elif defined(U3_OS_linux) { struct itimerval itm_v; struct sigaction sig_s; sigset_t set; sig_s.sa_handler = _ct_sigaction; sigemptyset(&(sig_s.sa_mask)); sig_s.sa_flags = 0; sigaction(SIGPROF, &sig_s, 0); sigemptyset(&set); sigaddset(&set, SIGPROF); if ( 0 != pthread_sigmask(SIG_UNBLOCK, &set, NULL) ) { perror("pthread_sigmask"); } itm_v.it_interval.tv_sec = 0; itm_v.it_interval.tv_usec = 10000; // itm_v.it_interval.tv_usec = 100000; itm_v.it_value = itm_v.it_interval; setitimer(ITIMER_PROF, &itm_v, 0); } #elif defined(U3_OS_bsd) // TODO: support profiling on bsd #else # error "port: profiling" #endif } } /* u3t_boff(): turn profile sampling off. */ void u3t_boff(void) { if ( u3C.wag_w & u3o_debug_cpu ) { #if defined(U3_OS_osx) struct sigaction sig_s; struct itimerval itm_v; sigset_t set; sigemptyset(&set); sigaddset(&set, SIGPROF); if ( 0 != pthread_sigmask(SIG_BLOCK, &set, NULL) ) { perror("pthread_sigmask"); } itm_v.it_interval.tv_sec = 0; itm_v.it_interval.tv_usec = 0; itm_v.it_value = itm_v.it_interval; setitimer(ITIMER_PROF, &itm_v, 0); sigaction(SIGPROF, &sig_s, 0); #elif defined(U3_OS_linux) // TODO: support profiling on linux #elif defined(U3_OS_bsd) // TODO: support profiling on bsd #else # error "port: profiling" #endif } }