#include "jemalloc/internal/jemalloc_preamble.h" #include "jemalloc/internal/jemalloc_internal_includes.h" #include "jemalloc/internal/assert.h" #include "jemalloc/internal/ctl.h" #include "jemalloc/internal/emitter.h" #include "jemalloc/internal/fxp.h" #include "jemalloc/internal/mutex.h" #include "jemalloc/internal/mutex_prof.h" #include "jemalloc/internal/prof_stats.h" const char *global_mutex_names[mutex_prof_num_global_mutexes] = { #define OP(mtx) #mtx, MUTEX_PROF_GLOBAL_MUTEXES #undef OP }; const char *arena_mutex_names[mutex_prof_num_arena_mutexes] = { #define OP(mtx) #mtx, MUTEX_PROF_ARENA_MUTEXES #undef OP }; #define CTL_GET(n, v, t) do { \ size_t sz = sizeof(t); \ xmallctl(n, (void *)v, &sz, NULL, 0); \ } while (0) #define CTL_LEAF_PREPARE(mib, miblen, name) do { \ assert(miblen < CTL_MAX_DEPTH); \ size_t miblen_new = CTL_MAX_DEPTH; \ xmallctlmibnametomib(mib, miblen, name, &miblen_new); \ assert(miblen_new > miblen); \ } while (0) #define CTL_LEAF(mib, miblen, leaf, v, t) do { \ assert(miblen < CTL_MAX_DEPTH); \ size_t miblen_new = CTL_MAX_DEPTH; \ size_t sz = sizeof(t); \ xmallctlbymibname(mib, miblen, leaf, &miblen_new, (void *)v, \ &sz, NULL, 0); \ assert(miblen_new == miblen + 1); \ } while (0) #define CTL_M2_GET(n, i, v, t) do { \ size_t mib[CTL_MAX_DEPTH]; \ size_t miblen = sizeof(mib) / sizeof(size_t); \ size_t sz = sizeof(t); \ xmallctlnametomib(n, mib, &miblen); \ mib[2] = (i); \ xmallctlbymib(mib, miblen, (void *)v, &sz, NULL, 0); \ } while (0) /******************************************************************************/ /* Data. */ bool opt_stats_print = false; char opt_stats_print_opts[stats_print_tot_num_options+1] = ""; int64_t opt_stats_interval = STATS_INTERVAL_DEFAULT; char opt_stats_interval_opts[stats_print_tot_num_options+1] = ""; static counter_accum_t stats_interval_accumulated; /* Per thread batch accum size for stats_interval. */ static uint64_t stats_interval_accum_batch; /******************************************************************************/ static uint64_t rate_per_second(uint64_t value, uint64_t uptime_ns) { uint64_t billion = 1000000000; if (uptime_ns == 0 || value == 0) { return 0; } if (uptime_ns < billion) { return value; } else { uint64_t uptime_s = uptime_ns / billion; return value / uptime_s; } } /* Calculate x.yyy and output a string (takes a fixed sized char array). */ static bool get_rate_str(uint64_t dividend, uint64_t divisor, char str[6]) { if (divisor == 0 || dividend > divisor) { /* The rate is not supposed to be greater than 1. */ return true; } if (dividend > 0) { assert(UINT64_MAX / dividend >= 1000); } unsigned n = (unsigned)((dividend * 1000) / divisor); if (n < 10) { malloc_snprintf(str, 6, "0.00%u", n); } else if (n < 100) { malloc_snprintf(str, 6, "0.0%u", n); } else if (n < 1000) { malloc_snprintf(str, 6, "0.%u", n); } else { malloc_snprintf(str, 6, "1"); } return false; } static void mutex_stats_init_cols(emitter_row_t *row, const char *table_name, emitter_col_t *name, emitter_col_t col_uint64_t[mutex_prof_num_uint64_t_counters], emitter_col_t col_uint32_t[mutex_prof_num_uint32_t_counters]) { mutex_prof_uint64_t_counter_ind_t k_uint64_t = 0; mutex_prof_uint32_t_counter_ind_t k_uint32_t = 0; emitter_col_t *col; if (name != NULL) { emitter_col_init(name, row); name->justify = emitter_justify_left; name->width = 21; name->type = emitter_type_title; name->str_val = table_name; } #define WIDTH_uint32_t 12 #define WIDTH_uint64_t 16 #define OP(counter, counter_type, human, derived, base_counter) \ col = &col_##counter_type[k_##counter_type]; \ ++k_##counter_type; \ emitter_col_init(col, row); \ col->justify = emitter_justify_right; \ col->width = derived ? 8 : WIDTH_##counter_type; \ col->type = emitter_type_title; \ col->str_val = human; MUTEX_PROF_COUNTERS #undef OP #undef WIDTH_uint32_t #undef WIDTH_uint64_t col_uint64_t[mutex_counter_total_wait_time_ps].width = 10; } static void mutex_stats_read_global(size_t mib[], size_t miblen, const char *name, emitter_col_t *col_name, emitter_col_t col_uint64_t[mutex_prof_num_uint64_t_counters], emitter_col_t col_uint32_t[mutex_prof_num_uint32_t_counters], uint64_t uptime) { CTL_LEAF_PREPARE(mib, miblen, name); size_t miblen_name = miblen + 1; col_name->str_val = name; emitter_col_t *dst; #define EMITTER_TYPE_uint32_t emitter_type_uint32 #define EMITTER_TYPE_uint64_t emitter_type_uint64 #define OP(counter, counter_type, human, derived, base_counter) \ dst = &col_##counter_type[mutex_counter_##counter]; \ dst->type = EMITTER_TYPE_##counter_type; \ if (!derived) { \ CTL_LEAF(mib, miblen_name, #counter, \ (counter_type *)&dst->bool_val, counter_type); \ } else { \ emitter_col_t *base = \ &col_##counter_type[mutex_counter_##base_counter]; \ dst->counter_type##_val = \ (counter_type)rate_per_second( \ base->counter_type##_val, uptime); \ } MUTEX_PROF_COUNTERS #undef OP #undef EMITTER_TYPE_uint32_t #undef EMITTER_TYPE_uint64_t } static void mutex_stats_read_arena(size_t mib[], size_t miblen, const char *name, emitter_col_t *col_name, emitter_col_t col_uint64_t[mutex_prof_num_uint64_t_counters], emitter_col_t col_uint32_t[mutex_prof_num_uint32_t_counters], uint64_t uptime) { CTL_LEAF_PREPARE(mib, miblen, name); size_t miblen_name = miblen + 1; col_name->str_val = name; emitter_col_t *dst; #define EMITTER_TYPE_uint32_t emitter_type_uint32 #define EMITTER_TYPE_uint64_t emitter_type_uint64 #define OP(counter, counter_type, human, derived, base_counter) \ dst = &col_##counter_type[mutex_counter_##counter]; \ dst->type = EMITTER_TYPE_##counter_type; \ if (!derived) { \ CTL_LEAF(mib, miblen_name, #counter, \ (counter_type *)&dst->bool_val, counter_type); \ } else { \ emitter_col_t *base = \ &col_##counter_type[mutex_counter_##base_counter]; \ dst->counter_type##_val = \ (counter_type)rate_per_second( \ base->counter_type##_val, uptime); \ } MUTEX_PROF_COUNTERS #undef OP #undef EMITTER_TYPE_uint32_t #undef EMITTER_TYPE_uint64_t } static void mutex_stats_read_arena_bin(size_t mib[], size_t miblen, emitter_col_t col_uint64_t[mutex_prof_num_uint64_t_counters], emitter_col_t col_uint32_t[mutex_prof_num_uint32_t_counters], uint64_t uptime) { CTL_LEAF_PREPARE(mib, miblen, "mutex"); size_t miblen_mutex = miblen + 1; emitter_col_t *dst; #define EMITTER_TYPE_uint32_t emitter_type_uint32 #define EMITTER_TYPE_uint64_t emitter_type_uint64 #define OP(counter, counter_type, human, derived, base_counter) \ dst = &col_##counter_type[mutex_counter_##counter]; \ dst->type = EMITTER_TYPE_##counter_type; \ if (!derived) { \ CTL_LEAF(mib, miblen_mutex, #counter, \ (counter_type *)&dst->bool_val, counter_type); \ } else { \ emitter_col_t *base = \ &col_##counter_type[mutex_counter_##base_counter]; \ dst->counter_type##_val = \ (counter_type)rate_per_second( \ base->counter_type##_val, uptime); \ } MUTEX_PROF_COUNTERS #undef OP #undef EMITTER_TYPE_uint32_t #undef EMITTER_TYPE_uint64_t } /* "row" can be NULL to avoid emitting in table mode. */ static void mutex_stats_emit(emitter_t *emitter, emitter_row_t *row, emitter_col_t col_uint64_t[mutex_prof_num_uint64_t_counters], emitter_col_t col_uint32_t[mutex_prof_num_uint32_t_counters]) { if (row != NULL) { emitter_table_row(emitter, row); } mutex_prof_uint64_t_counter_ind_t k_uint64_t = 0; mutex_prof_uint32_t_counter_ind_t k_uint32_t = 0; emitter_col_t *col; #define EMITTER_TYPE_uint32_t emitter_type_uint32 #define EMITTER_TYPE_uint64_t emitter_type_uint64 #define OP(counter, type, human, derived, base_counter) \ if (!derived) { \ col = &col_##type[k_##type]; \ ++k_##type; \ emitter_json_kv(emitter, #counter, EMITTER_TYPE_##type, \ (const void *)&col->bool_val); \ } MUTEX_PROF_COUNTERS; #undef OP #undef EMITTER_TYPE_uint32_t #undef EMITTER_TYPE_uint64_t } #define COL_DECLARE(column_name) \ emitter_col_t col_##column_name; #define COL_INIT(row_name, column_name, left_or_right, col_width, etype)\ emitter_col_init(&col_##column_name, &row_name); \ col_##column_name.justify = emitter_justify_##left_or_right; \ col_##column_name.width = col_width; \ col_##column_name.type = emitter_type_##etype; #define COL(row_name, column_name, left_or_right, col_width, etype) \ COL_DECLARE(column_name); \ COL_INIT(row_name, column_name, left_or_right, col_width, etype) #define COL_HDR_DECLARE(column_name) \ COL_DECLARE(column_name); \ emitter_col_t header_##column_name; #define COL_HDR_INIT(row_name, column_name, human, left_or_right, \ col_width, etype) \ COL_INIT(row_name, column_name, left_or_right, col_width, etype)\ emitter_col_init(&header_##column_name, &header_##row_name); \ header_##column_name.justify = emitter_justify_##left_or_right; \ header_##column_name.width = col_width; \ header_##column_name.type = emitter_type_title; \ header_##column_name.str_val = human ? human : #column_name; #define COL_HDR(row_name, column_name, human, left_or_right, col_width, \ etype) \ COL_HDR_DECLARE(column_name) \ COL_HDR_INIT(row_name, column_name, human, left_or_right, \ col_width, etype) JEMALLOC_COLD static void stats_arena_bins_print(emitter_t *emitter, bool mutex, unsigned i, uint64_t uptime) { size_t page; bool in_gap, in_gap_prev; unsigned nbins, j; CTL_GET("arenas.page", &page, size_t); CTL_GET("arenas.nbins", &nbins, unsigned); emitter_row_t header_row; emitter_row_init(&header_row); emitter_row_t row; emitter_row_init(&row); bool prof_stats_on = config_prof && opt_prof && opt_prof_stats && i == MALLCTL_ARENAS_ALL; COL_HDR(row, size, NULL, right, 20, size) COL_HDR(row, ind, NULL, right, 4, unsigned) COL_HDR(row, allocated, NULL, right, 13, uint64) COL_HDR(row, nmalloc, NULL, right, 13, uint64) COL_HDR(row, nmalloc_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, ndalloc, NULL, right, 13, uint64) COL_HDR(row, ndalloc_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, nrequests, NULL, right, 13, uint64) COL_HDR(row, nrequests_ps, "(#/sec)", right, 10, uint64) COL_HDR_DECLARE(prof_live_requested); COL_HDR_DECLARE(prof_live_count); COL_HDR_DECLARE(prof_accum_requested); COL_HDR_DECLARE(prof_accum_count); if (prof_stats_on) { COL_HDR_INIT(row, prof_live_requested, NULL, right, 21, uint64) COL_HDR_INIT(row, prof_live_count, NULL, right, 17, uint64) COL_HDR_INIT(row, prof_accum_requested, NULL, right, 21, uint64) COL_HDR_INIT(row, prof_accum_count, NULL, right, 17, uint64) } COL_HDR(row, nshards, NULL, right, 9, unsigned) COL_HDR(row, curregs, NULL, right, 13, size) COL_HDR(row, curslabs, NULL, right, 13, size) COL_HDR(row, nonfull_slabs, NULL, right, 15, size) COL_HDR(row, regs, NULL, right, 5, unsigned) COL_HDR(row, pgs, NULL, right, 4, size) /* To buffer a right- and left-justified column. */ COL_HDR(row, justify_spacer, NULL, right, 1, title) COL_HDR(row, util, NULL, right, 6, title) COL_HDR(row, nfills, NULL, right, 13, uint64) COL_HDR(row, nfills_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, nflushes, NULL, right, 13, uint64) COL_HDR(row, nflushes_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, nslabs, NULL, right, 13, uint64) COL_HDR(row, nreslabs, NULL, right, 13, uint64) COL_HDR(row, nreslabs_ps, "(#/sec)", right, 8, uint64) /* Don't want to actually print the name. */ header_justify_spacer.str_val = " "; col_justify_spacer.str_val = " "; emitter_col_t col_mutex64[mutex_prof_num_uint64_t_counters]; emitter_col_t col_mutex32[mutex_prof_num_uint32_t_counters]; emitter_col_t header_mutex64[mutex_prof_num_uint64_t_counters]; emitter_col_t header_mutex32[mutex_prof_num_uint32_t_counters]; if (mutex) { mutex_stats_init_cols(&row, NULL, NULL, col_mutex64, col_mutex32); mutex_stats_init_cols(&header_row, NULL, NULL, header_mutex64, header_mutex32); } /* * We print a "bins:" header as part of the table row; we need to adjust * the header size column to compensate. */ header_size.width -=5; emitter_table_printf(emitter, "bins:"); emitter_table_row(emitter, &header_row); emitter_json_array_kv_begin(emitter, "bins"); size_t stats_arenas_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_arenas_mib, 0, "stats.arenas"); stats_arenas_mib[2] = i; CTL_LEAF_PREPARE(stats_arenas_mib, 3, "bins"); size_t arenas_bin_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(arenas_bin_mib, 0, "arenas.bin"); size_t prof_stats_mib[CTL_MAX_DEPTH]; if (prof_stats_on) { CTL_LEAF_PREPARE(prof_stats_mib, 0, "prof.stats.bins"); } for (j = 0, in_gap = false; j < nbins; j++) { uint64_t nslabs; size_t reg_size, slab_size, curregs; size_t curslabs; size_t nonfull_slabs; uint32_t nregs, nshards; uint64_t nmalloc, ndalloc, nrequests, nfills, nflushes; uint64_t nreslabs; prof_stats_t prof_live; prof_stats_t prof_accum; stats_arenas_mib[4] = j; arenas_bin_mib[2] = j; CTL_LEAF(stats_arenas_mib, 5, "nslabs", &nslabs, uint64_t); if (prof_stats_on) { prof_stats_mib[3] = j; CTL_LEAF(prof_stats_mib, 4, "live", &prof_live, prof_stats_t); CTL_LEAF(prof_stats_mib, 4, "accum", &prof_accum, prof_stats_t); } in_gap_prev = in_gap; if (prof_stats_on) { in_gap = (nslabs == 0 && prof_accum.count == 0); } else { in_gap = (nslabs == 0); } if (in_gap_prev && !in_gap) { emitter_table_printf(emitter, " ---\n"); } if (in_gap && !emitter_outputs_json(emitter)) { continue; } CTL_LEAF(arenas_bin_mib, 3, "size", ®_size, size_t); CTL_LEAF(arenas_bin_mib, 3, "nregs", &nregs, uint32_t); CTL_LEAF(arenas_bin_mib, 3, "slab_size", &slab_size, size_t); CTL_LEAF(arenas_bin_mib, 3, "nshards", &nshards, uint32_t); CTL_LEAF(stats_arenas_mib, 5, "nmalloc", &nmalloc, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "ndalloc", &ndalloc, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "curregs", &curregs, size_t); CTL_LEAF(stats_arenas_mib, 5, "nrequests", &nrequests, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "nfills", &nfills, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "nflushes", &nflushes, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "nreslabs", &nreslabs, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "curslabs", &curslabs, size_t); CTL_LEAF(stats_arenas_mib, 5, "nonfull_slabs", &nonfull_slabs, size_t); if (mutex) { mutex_stats_read_arena_bin(stats_arenas_mib, 5, col_mutex64, col_mutex32, uptime); } emitter_json_object_begin(emitter); emitter_json_kv(emitter, "nmalloc", emitter_type_uint64, &nmalloc); emitter_json_kv(emitter, "ndalloc", emitter_type_uint64, &ndalloc); emitter_json_kv(emitter, "curregs", emitter_type_size, &curregs); emitter_json_kv(emitter, "nrequests", emitter_type_uint64, &nrequests); if (prof_stats_on) { emitter_json_kv(emitter, "prof_live_requested", emitter_type_uint64, &prof_live.req_sum); emitter_json_kv(emitter, "prof_live_count", emitter_type_uint64, &prof_live.count); emitter_json_kv(emitter, "prof_accum_requested", emitter_type_uint64, &prof_accum.req_sum); emitter_json_kv(emitter, "prof_accum_count", emitter_type_uint64, &prof_accum.count); } emitter_json_kv(emitter, "nfills", emitter_type_uint64, &nfills); emitter_json_kv(emitter, "nflushes", emitter_type_uint64, &nflushes); emitter_json_kv(emitter, "nreslabs", emitter_type_uint64, &nreslabs); emitter_json_kv(emitter, "curslabs", emitter_type_size, &curslabs); emitter_json_kv(emitter, "nonfull_slabs", emitter_type_size, &nonfull_slabs); if (mutex) { emitter_json_object_kv_begin(emitter, "mutex"); mutex_stats_emit(emitter, NULL, col_mutex64, col_mutex32); emitter_json_object_end(emitter); } emitter_json_object_end(emitter); size_t availregs = nregs * curslabs; char util[6]; if (get_rate_str((uint64_t)curregs, (uint64_t)availregs, util)) { if (availregs == 0) { malloc_snprintf(util, sizeof(util), "1"); } else if (curregs > availregs) { /* * Race detected: the counters were read in * separate mallctl calls and concurrent * operations happened in between. In this case * no meaningful utilization can be computed. */ malloc_snprintf(util, sizeof(util), " race"); } else { not_reached(); } } col_size.size_val = reg_size; col_ind.unsigned_val = j; col_allocated.size_val = curregs * reg_size; col_nmalloc.uint64_val = nmalloc; col_nmalloc_ps.uint64_val = rate_per_second(nmalloc, uptime); col_ndalloc.uint64_val = ndalloc; col_ndalloc_ps.uint64_val = rate_per_second(ndalloc, uptime); col_nrequests.uint64_val = nrequests; col_nrequests_ps.uint64_val = rate_per_second(nrequests, uptime); if (prof_stats_on) { col_prof_live_requested.uint64_val = prof_live.req_sum; col_prof_live_count.uint64_val = prof_live.count; col_prof_accum_requested.uint64_val = prof_accum.req_sum; col_prof_accum_count.uint64_val = prof_accum.count; } col_nshards.unsigned_val = nshards; col_curregs.size_val = curregs; col_curslabs.size_val = curslabs; col_nonfull_slabs.size_val = nonfull_slabs; col_regs.unsigned_val = nregs; col_pgs.size_val = slab_size / page; col_util.str_val = util; col_nfills.uint64_val = nfills; col_nfills_ps.uint64_val = rate_per_second(nfills, uptime); col_nflushes.uint64_val = nflushes; col_nflushes_ps.uint64_val = rate_per_second(nflushes, uptime); col_nslabs.uint64_val = nslabs; col_nreslabs.uint64_val = nreslabs; col_nreslabs_ps.uint64_val = rate_per_second(nreslabs, uptime); /* * Note that mutex columns were initialized above, if mutex == * true. */ emitter_table_row(emitter, &row); } emitter_json_array_end(emitter); /* Close "bins". */ if (in_gap) { emitter_table_printf(emitter, " ---\n"); } } JEMALLOC_COLD static void stats_arena_lextents_print(emitter_t *emitter, unsigned i, uint64_t uptime) { unsigned nbins, nlextents, j; bool in_gap, in_gap_prev; CTL_GET("arenas.nbins", &nbins, unsigned); CTL_GET("arenas.nlextents", &nlextents, unsigned); emitter_row_t header_row; emitter_row_init(&header_row); emitter_row_t row; emitter_row_init(&row); bool prof_stats_on = config_prof && opt_prof && opt_prof_stats && i == MALLCTL_ARENAS_ALL; COL_HDR(row, size, NULL, right, 20, size) COL_HDR(row, ind, NULL, right, 4, unsigned) COL_HDR(row, allocated, NULL, right, 13, size) COL_HDR(row, nmalloc, NULL, right, 13, uint64) COL_HDR(row, nmalloc_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, ndalloc, NULL, right, 13, uint64) COL_HDR(row, ndalloc_ps, "(#/sec)", right, 8, uint64) COL_HDR(row, nrequests, NULL, right, 13, uint64) COL_HDR(row, nrequests_ps, "(#/sec)", right, 8, uint64) COL_HDR_DECLARE(prof_live_requested) COL_HDR_DECLARE(prof_live_count) COL_HDR_DECLARE(prof_accum_requested) COL_HDR_DECLARE(prof_accum_count) if (prof_stats_on) { COL_HDR_INIT(row, prof_live_requested, NULL, right, 21, uint64) COL_HDR_INIT(row, prof_live_count, NULL, right, 17, uint64) COL_HDR_INIT(row, prof_accum_requested, NULL, right, 21, uint64) COL_HDR_INIT(row, prof_accum_count, NULL, right, 17, uint64) } COL_HDR(row, curlextents, NULL, right, 13, size) /* As with bins, we label the large extents table. */ header_size.width -= 6; emitter_table_printf(emitter, "large:"); emitter_table_row(emitter, &header_row); emitter_json_array_kv_begin(emitter, "lextents"); size_t stats_arenas_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_arenas_mib, 0, "stats.arenas"); stats_arenas_mib[2] = i; CTL_LEAF_PREPARE(stats_arenas_mib, 3, "lextents"); size_t arenas_lextent_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(arenas_lextent_mib, 0, "arenas.lextent"); size_t prof_stats_mib[CTL_MAX_DEPTH]; if (prof_stats_on) { CTL_LEAF_PREPARE(prof_stats_mib, 0, "prof.stats.lextents"); } for (j = 0, in_gap = false; j < nlextents; j++) { uint64_t nmalloc, ndalloc, nrequests; size_t lextent_size, curlextents; prof_stats_t prof_live; prof_stats_t prof_accum; stats_arenas_mib[4] = j; arenas_lextent_mib[2] = j; CTL_LEAF(stats_arenas_mib, 5, "nmalloc", &nmalloc, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "ndalloc", &ndalloc, uint64_t); CTL_LEAF(stats_arenas_mib, 5, "nrequests", &nrequests, uint64_t); in_gap_prev = in_gap; in_gap = (nrequests == 0); if (in_gap_prev && !in_gap) { emitter_table_printf(emitter, " ---\n"); } CTL_LEAF(arenas_lextent_mib, 3, "size", &lextent_size, size_t); CTL_LEAF(stats_arenas_mib, 5, "curlextents", &curlextents, size_t); if (prof_stats_on) { prof_stats_mib[3] = j; CTL_LEAF(prof_stats_mib, 4, "live", &prof_live, prof_stats_t); CTL_LEAF(prof_stats_mib, 4, "accum", &prof_accum, prof_stats_t); } emitter_json_object_begin(emitter); if (prof_stats_on) { emitter_json_kv(emitter, "prof_live_requested", emitter_type_uint64, &prof_live.req_sum); emitter_json_kv(emitter, "prof_live_count", emitter_type_uint64, &prof_live.count); emitter_json_kv(emitter, "prof_accum_requested", emitter_type_uint64, &prof_accum.req_sum); emitter_json_kv(emitter, "prof_accum_count", emitter_type_uint64, &prof_accum.count); } emitter_json_kv(emitter, "curlextents", emitter_type_size, &curlextents); emitter_json_object_end(emitter); col_size.size_val = lextent_size; col_ind.unsigned_val = nbins + j; col_allocated.size_val = curlextents * lextent_size; col_nmalloc.uint64_val = nmalloc; col_nmalloc_ps.uint64_val = rate_per_second(nmalloc, uptime); col_ndalloc.uint64_val = ndalloc; col_ndalloc_ps.uint64_val = rate_per_second(ndalloc, uptime); col_nrequests.uint64_val = nrequests; col_nrequests_ps.uint64_val = rate_per_second(nrequests, uptime); if (prof_stats_on) { col_prof_live_requested.uint64_val = prof_live.req_sum; col_prof_live_count.uint64_val = prof_live.count; col_prof_accum_requested.uint64_val = prof_accum.req_sum; col_prof_accum_count.uint64_val = prof_accum.count; } col_curlextents.size_val = curlextents; if (!in_gap) { emitter_table_row(emitter, &row); } } emitter_json_array_end(emitter); /* Close "lextents". */ if (in_gap) { emitter_table_printf(emitter, " ---\n"); } } JEMALLOC_COLD static void stats_arena_extents_print(emitter_t *emitter, unsigned i) { unsigned j; bool in_gap, in_gap_prev; emitter_row_t header_row; emitter_row_init(&header_row); emitter_row_t row; emitter_row_init(&row); COL_HDR(row, size, NULL, right, 20, size) COL_HDR(row, ind, NULL, right, 4, unsigned) COL_HDR(row, ndirty, NULL, right, 13, size) COL_HDR(row, dirty, NULL, right, 13, size) COL_HDR(row, nmuzzy, NULL, right, 13, size) COL_HDR(row, muzzy, NULL, right, 13, size) COL_HDR(row, nretained, NULL, right, 13, size) COL_HDR(row, retained, NULL, right, 13, size) COL_HDR(row, ntotal, NULL, right, 13, size) COL_HDR(row, total, NULL, right, 13, size) /* Label this section. */ header_size.width -= 8; emitter_table_printf(emitter, "extents:"); emitter_table_row(emitter, &header_row); emitter_json_array_kv_begin(emitter, "extents"); size_t stats_arenas_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_arenas_mib, 0, "stats.arenas"); stats_arenas_mib[2] = i; CTL_LEAF_PREPARE(stats_arenas_mib, 3, "extents"); in_gap = false; for (j = 0; j < SC_NPSIZES; j++) { size_t ndirty, nmuzzy, nretained, total, dirty_bytes, muzzy_bytes, retained_bytes, total_bytes; stats_arenas_mib[4] = j; CTL_LEAF(stats_arenas_mib, 5, "ndirty", &ndirty, size_t); CTL_LEAF(stats_arenas_mib, 5, "nmuzzy", &nmuzzy, size_t); CTL_LEAF(stats_arenas_mib, 5, "nretained", &nretained, size_t); CTL_LEAF(stats_arenas_mib, 5, "dirty_bytes", &dirty_bytes, size_t); CTL_LEAF(stats_arenas_mib, 5, "muzzy_bytes", &muzzy_bytes, size_t); CTL_LEAF(stats_arenas_mib, 5, "retained_bytes", &retained_bytes, size_t); total = ndirty + nmuzzy + nretained; total_bytes = dirty_bytes + muzzy_bytes + retained_bytes; in_gap_prev = in_gap; in_gap = (total == 0); if (in_gap_prev && !in_gap) { emitter_table_printf(emitter, " ---\n"); } emitter_json_object_begin(emitter); emitter_json_kv(emitter, "ndirty", emitter_type_size, &ndirty); emitter_json_kv(emitter, "nmuzzy", emitter_type_size, &nmuzzy); emitter_json_kv(emitter, "nretained", emitter_type_size, &nretained); emitter_json_kv(emitter, "dirty_bytes", emitter_type_size, &dirty_bytes); emitter_json_kv(emitter, "muzzy_bytes", emitter_type_size, &muzzy_bytes); emitter_json_kv(emitter, "retained_bytes", emitter_type_size, &retained_bytes); emitter_json_object_end(emitter); col_size.size_val = sz_pind2sz(j); col_ind.size_val = j; col_ndirty.size_val = ndirty; col_dirty.size_val = dirty_bytes; col_nmuzzy.size_val = nmuzzy; col_muzzy.size_val = muzzy_bytes; col_nretained.size_val = nretained; col_retained.size_val = retained_bytes; col_ntotal.size_val = total; col_total.size_val = total_bytes; if (!in_gap) { emitter_table_row(emitter, &row); } } emitter_json_array_end(emitter); /* Close "extents". */ if (in_gap) { emitter_table_printf(emitter, " ---\n"); } } static void stats_arena_hpa_shard_print(emitter_t *emitter, unsigned i, uint64_t uptime) { emitter_row_t header_row; emitter_row_init(&header_row); emitter_row_t row; emitter_row_init(&row); uint64_t npurge_passes; uint64_t npurges; uint64_t nhugifies; uint64_t ndehugifies; CTL_M2_GET("stats.arenas.0.hpa_shard.npurge_passes", i, &npurge_passes, uint64_t); CTL_M2_GET("stats.arenas.0.hpa_shard.npurges", i, &npurges, uint64_t); CTL_M2_GET("stats.arenas.0.hpa_shard.nhugifies", i, &nhugifies, uint64_t); CTL_M2_GET("stats.arenas.0.hpa_shard.ndehugifies", i, &ndehugifies, uint64_t); size_t npageslabs_huge; size_t nactive_huge; size_t ndirty_huge; size_t npageslabs_nonhuge; size_t nactive_nonhuge; size_t ndirty_nonhuge; size_t nretained_nonhuge; size_t sec_bytes; CTL_M2_GET("stats.arenas.0.hpa_sec_bytes", i, &sec_bytes, size_t); emitter_kv(emitter, "sec_bytes", "Bytes in small extent cache", emitter_type_size, &sec_bytes); /* First, global stats. */ emitter_table_printf(emitter, "HPA shard stats:\n" " Purge passes: %" FMTu64 " (%" FMTu64 " / sec)\n" " Purges: %" FMTu64 " (%" FMTu64 " / sec)\n" " Hugeifies: %" FMTu64 " (%" FMTu64 " / sec)\n" " Dehugifies: %" FMTu64 " (%" FMTu64 " / sec)\n" "\n", npurge_passes, rate_per_second(npurge_passes, uptime), npurges, rate_per_second(npurges, uptime), nhugifies, rate_per_second(nhugifies, uptime), ndehugifies, rate_per_second(ndehugifies, uptime)); emitter_json_object_kv_begin(emitter, "hpa_shard"); emitter_json_kv(emitter, "npurge_passes", emitter_type_uint64, &npurge_passes); emitter_json_kv(emitter, "npurges", emitter_type_uint64, &npurges); emitter_json_kv(emitter, "nhugifies", emitter_type_uint64, &nhugifies); emitter_json_kv(emitter, "ndehugifies", emitter_type_uint64, &ndehugifies); /* Next, full slab stats. */ CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.npageslabs_huge", i, &npageslabs_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.nactive_huge", i, &nactive_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.ndirty_huge", i, &ndirty_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.npageslabs_nonhuge", i, &npageslabs_nonhuge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.nactive_nonhuge", i, &nactive_nonhuge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.full_slabs.ndirty_nonhuge", i, &ndirty_nonhuge, size_t); nretained_nonhuge = npageslabs_nonhuge * HUGEPAGE_PAGES - nactive_nonhuge - ndirty_nonhuge; emitter_table_printf(emitter, " In full slabs:\n" " npageslabs: %zu huge, %zu nonhuge\n" " nactive: %zu huge, %zu nonhuge \n" " ndirty: %zu huge, %zu nonhuge \n" " nretained: 0 huge, %zu nonhuge \n", npageslabs_huge, npageslabs_nonhuge, nactive_huge, nactive_nonhuge, ndirty_huge, ndirty_nonhuge, nretained_nonhuge); emitter_json_object_kv_begin(emitter, "full_slabs"); emitter_json_kv(emitter, "npageslabs_huge", emitter_type_size, &npageslabs_huge); emitter_json_kv(emitter, "nactive_huge", emitter_type_size, &nactive_huge); emitter_json_kv(emitter, "nactive_huge", emitter_type_size, &nactive_huge); emitter_json_kv(emitter, "npageslabs_nonhuge", emitter_type_size, &npageslabs_nonhuge); emitter_json_kv(emitter, "nactive_nonhuge", emitter_type_size, &nactive_nonhuge); emitter_json_kv(emitter, "ndirty_nonhuge", emitter_type_size, &ndirty_nonhuge); emitter_json_object_end(emitter); /* End "full_slabs" */ /* Next, empty slab stats. */ CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.npageslabs_huge", i, &npageslabs_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.nactive_huge", i, &nactive_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.ndirty_huge", i, &ndirty_huge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.npageslabs_nonhuge", i, &npageslabs_nonhuge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.nactive_nonhuge", i, &nactive_nonhuge, size_t); CTL_M2_GET("stats.arenas.0.hpa_shard.empty_slabs.ndirty_nonhuge", i, &ndirty_nonhuge, size_t); nretained_nonhuge = npageslabs_nonhuge * HUGEPAGE_PAGES - nactive_nonhuge - ndirty_nonhuge; emitter_table_printf(emitter, " In empty slabs:\n" " npageslabs: %zu huge, %zu nonhuge\n" " nactive: %zu huge, %zu nonhuge \n" " ndirty: %zu huge, %zu nonhuge \n" " nretained: 0 huge, %zu nonhuge \n" "\n", npageslabs_huge, npageslabs_nonhuge, nactive_huge, nactive_nonhuge, ndirty_huge, ndirty_nonhuge, nretained_nonhuge); emitter_json_object_kv_begin(emitter, "empty_slabs"); emitter_json_kv(emitter, "npageslabs_huge", emitter_type_size, &npageslabs_huge); emitter_json_kv(emitter, "nactive_huge", emitter_type_size, &nactive_huge); emitter_json_kv(emitter, "nactive_huge", emitter_type_size, &nactive_huge); emitter_json_kv(emitter, "npageslabs_nonhuge", emitter_type_size, &npageslabs_nonhuge); emitter_json_kv(emitter, "nactive_nonhuge", emitter_type_size, &nactive_nonhuge); emitter_json_kv(emitter, "ndirty_nonhuge", emitter_type_size, &ndirty_nonhuge); emitter_json_object_end(emitter); /* End "empty_slabs" */ COL_HDR(row, size, NULL, right, 20, size) COL_HDR(row, ind, NULL, right, 4, unsigned) COL_HDR(row, npageslabs_huge, NULL, right, 16, size) COL_HDR(row, nactive_huge, NULL, right, 16, size) COL_HDR(row, ndirty_huge, NULL, right, 16, size) COL_HDR(row, npageslabs_nonhuge, NULL, right, 20, size) COL_HDR(row, nactive_nonhuge, NULL, right, 20, size) COL_HDR(row, ndirty_nonhuge, NULL, right, 20, size) COL_HDR(row, nretained_nonhuge, NULL, right, 20, size) size_t stats_arenas_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_arenas_mib, 0, "stats.arenas"); stats_arenas_mib[2] = i; CTL_LEAF_PREPARE(stats_arenas_mib, 3, "hpa_shard.nonfull_slabs"); emitter_table_row(emitter, &header_row); emitter_json_array_kv_begin(emitter, "nonfull_slabs"); bool in_gap = false; for (pszind_t j = 0; j < PSSET_NPSIZES && j < SC_NPSIZES; j++) { stats_arenas_mib[5] = j; CTL_LEAF(stats_arenas_mib, 6, "npageslabs_huge", &npageslabs_huge, size_t); CTL_LEAF(stats_arenas_mib, 6, "nactive_huge", &nactive_huge, size_t); CTL_LEAF(stats_arenas_mib, 6, "ndirty_huge", &ndirty_huge, size_t); CTL_LEAF(stats_arenas_mib, 6, "npageslabs_nonhuge", &npageslabs_nonhuge, size_t); CTL_LEAF(stats_arenas_mib, 6, "nactive_nonhuge", &nactive_nonhuge, size_t); CTL_LEAF(stats_arenas_mib, 6, "ndirty_nonhuge", &ndirty_nonhuge, size_t); nretained_nonhuge = npageslabs_nonhuge * HUGEPAGE_PAGES - nactive_nonhuge - ndirty_nonhuge; bool in_gap_prev = in_gap; in_gap = (npageslabs_huge == 0 && npageslabs_nonhuge == 0); if (in_gap_prev && !in_gap) { emitter_table_printf(emitter, " ---\n"); } col_size.size_val = sz_pind2sz(j); col_ind.size_val = j; col_npageslabs_huge.size_val = npageslabs_huge; col_nactive_huge.size_val = nactive_huge; col_ndirty_huge.size_val = ndirty_huge; col_npageslabs_nonhuge.size_val = npageslabs_nonhuge; col_nactive_nonhuge.size_val = nactive_nonhuge; col_ndirty_nonhuge.size_val = ndirty_nonhuge; col_nretained_nonhuge.size_val = nretained_nonhuge; if (!in_gap) { emitter_table_row(emitter, &row); } emitter_json_object_begin(emitter); emitter_json_kv(emitter, "npageslabs_huge", emitter_type_size, &npageslabs_huge); emitter_json_kv(emitter, "nactive_huge", emitter_type_size, &nactive_huge); emitter_json_kv(emitter, "ndirty_huge", emitter_type_size, &ndirty_huge); emitter_json_kv(emitter, "npageslabs_nonhuge", emitter_type_size, &npageslabs_nonhuge); emitter_json_kv(emitter, "nactive_nonhuge", emitter_type_size, &nactive_nonhuge); emitter_json_kv(emitter, "ndirty_nonhuge", emitter_type_size, &ndirty_nonhuge); emitter_json_object_end(emitter); } emitter_json_array_end(emitter); /* End "nonfull_slabs" */ emitter_json_object_end(emitter); /* End "hpa_shard" */ if (in_gap) { emitter_table_printf(emitter, " ---\n"); } } static void stats_arena_mutexes_print(emitter_t *emitter, unsigned arena_ind, uint64_t uptime) { emitter_row_t row; emitter_col_t col_name; emitter_col_t col64[mutex_prof_num_uint64_t_counters]; emitter_col_t col32[mutex_prof_num_uint32_t_counters]; emitter_row_init(&row); mutex_stats_init_cols(&row, "", &col_name, col64, col32); emitter_json_object_kv_begin(emitter, "mutexes"); emitter_table_row(emitter, &row); size_t stats_arenas_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_arenas_mib, 0, "stats.arenas"); stats_arenas_mib[2] = arena_ind; CTL_LEAF_PREPARE(stats_arenas_mib, 3, "mutexes"); for (mutex_prof_arena_ind_t i = 0; i < mutex_prof_num_arena_mutexes; i++) { const char *name = arena_mutex_names[i]; emitter_json_object_kv_begin(emitter, name); mutex_stats_read_arena(stats_arenas_mib, 4, name, &col_name, col64, col32, uptime); mutex_stats_emit(emitter, &row, col64, col32); emitter_json_object_end(emitter); /* Close the mutex dict. */ } emitter_json_object_end(emitter); /* End "mutexes". */ } JEMALLOC_COLD static void stats_arena_print(emitter_t *emitter, unsigned i, bool bins, bool large, bool mutex, bool extents, bool hpa) { unsigned nthreads; const char *dss; ssize_t dirty_decay_ms, muzzy_decay_ms; size_t page, pactive, pdirty, pmuzzy, mapped, retained; size_t base, internal, resident, metadata_thp, extent_avail; uint64_t dirty_npurge, dirty_nmadvise, dirty_purged; uint64_t muzzy_npurge, muzzy_nmadvise, muzzy_purged; size_t small_allocated; uint64_t small_nmalloc, small_ndalloc, small_nrequests, small_nfills, small_nflushes; size_t large_allocated; uint64_t large_nmalloc, large_ndalloc, large_nrequests, large_nfills, large_nflushes; size_t tcache_bytes, tcache_stashed_bytes, abandoned_vm; uint64_t uptime; CTL_GET("arenas.page", &page, size_t); CTL_M2_GET("stats.arenas.0.nthreads", i, &nthreads, unsigned); emitter_kv(emitter, "nthreads", "assigned threads", emitter_type_unsigned, &nthreads); CTL_M2_GET("stats.arenas.0.uptime", i, &uptime, uint64_t); emitter_kv(emitter, "uptime_ns", "uptime", emitter_type_uint64, &uptime); CTL_M2_GET("stats.arenas.0.dss", i, &dss, const char *); emitter_kv(emitter, "dss", "dss allocation precedence", emitter_type_string, &dss); CTL_M2_GET("stats.arenas.0.dirty_decay_ms", i, &dirty_decay_ms, ssize_t); CTL_M2_GET("stats.arenas.0.muzzy_decay_ms", i, &muzzy_decay_ms, ssize_t); CTL_M2_GET("stats.arenas.0.pactive", i, &pactive, size_t); CTL_M2_GET("stats.arenas.0.pdirty", i, &pdirty, size_t); CTL_M2_GET("stats.arenas.0.pmuzzy", i, &pmuzzy, size_t); CTL_M2_GET("stats.arenas.0.dirty_npurge", i, &dirty_npurge, uint64_t); CTL_M2_GET("stats.arenas.0.dirty_nmadvise", i, &dirty_nmadvise, uint64_t); CTL_M2_GET("stats.arenas.0.dirty_purged", i, &dirty_purged, uint64_t); CTL_M2_GET("stats.arenas.0.muzzy_npurge", i, &muzzy_npurge, uint64_t); CTL_M2_GET("stats.arenas.0.muzzy_nmadvise", i, &muzzy_nmadvise, uint64_t); CTL_M2_GET("stats.arenas.0.muzzy_purged", i, &muzzy_purged, uint64_t); emitter_row_t decay_row; emitter_row_init(&decay_row); /* JSON-style emission. */ emitter_json_kv(emitter, "dirty_decay_ms", emitter_type_ssize, &dirty_decay_ms); emitter_json_kv(emitter, "muzzy_decay_ms", emitter_type_ssize, &muzzy_decay_ms); emitter_json_kv(emitter, "pactive", emitter_type_size, &pactive); emitter_json_kv(emitter, "pdirty", emitter_type_size, &pdirty); emitter_json_kv(emitter, "pmuzzy", emitter_type_size, &pmuzzy); emitter_json_kv(emitter, "dirty_npurge", emitter_type_uint64, &dirty_npurge); emitter_json_kv(emitter, "dirty_nmadvise", emitter_type_uint64, &dirty_nmadvise); emitter_json_kv(emitter, "dirty_purged", emitter_type_uint64, &dirty_purged); emitter_json_kv(emitter, "muzzy_npurge", emitter_type_uint64, &muzzy_npurge); emitter_json_kv(emitter, "muzzy_nmadvise", emitter_type_uint64, &muzzy_nmadvise); emitter_json_kv(emitter, "muzzy_purged", emitter_type_uint64, &muzzy_purged); /* Table-style emission. */ COL(decay_row, decay_type, right, 9, title); col_decay_type.str_val = "decaying:"; COL(decay_row, decay_time, right, 6, title); col_decay_time.str_val = "time"; COL(decay_row, decay_npages, right, 13, title); col_decay_npages.str_val = "npages"; COL(decay_row, decay_sweeps, right, 13, title); col_decay_sweeps.str_val = "sweeps"; COL(decay_row, decay_madvises, right, 13, title); col_decay_madvises.str_val = "madvises"; COL(decay_row, decay_purged, right, 13, title); col_decay_purged.str_val = "purged"; /* Title row. */ emitter_table_row(emitter, &decay_row); /* Dirty row. */ col_decay_type.str_val = "dirty:"; if (dirty_decay_ms >= 0) { col_decay_time.type = emitter_type_ssize; col_decay_time.ssize_val = dirty_decay_ms; } else { col_decay_time.type = emitter_type_title; col_decay_time.str_val = "N/A"; } col_decay_npages.type = emitter_type_size; col_decay_npages.size_val = pdirty; col_decay_sweeps.type = emitter_type_uint64; col_decay_sweeps.uint64_val = dirty_npurge; col_decay_madvises.type = emitter_type_uint64; col_decay_madvises.uint64_val = dirty_nmadvise; col_decay_purged.type = emitter_type_uint64; col_decay_purged.uint64_val = dirty_purged; emitter_table_row(emitter, &decay_row); /* Muzzy row. */ col_decay_type.str_val = "muzzy:"; if (muzzy_decay_ms >= 0) { col_decay_time.type = emitter_type_ssize; col_decay_time.ssize_val = muzzy_decay_ms; } else { col_decay_time.type = emitter_type_title; col_decay_time.str_val = "N/A"; } col_decay_npages.type = emitter_type_size; col_decay_npages.size_val = pmuzzy; col_decay_sweeps.type = emitter_type_uint64; col_decay_sweeps.uint64_val = muzzy_npurge; col_decay_madvises.type = emitter_type_uint64; col_decay_madvises.uint64_val = muzzy_nmadvise; col_decay_purged.type = emitter_type_uint64; col_decay_purged.uint64_val = muzzy_purged; emitter_table_row(emitter, &decay_row); /* Small / large / total allocation counts. */ emitter_row_t alloc_count_row; emitter_row_init(&alloc_count_row); COL(alloc_count_row, count_title, left, 21, title); col_count_title.str_val = ""; COL(alloc_count_row, count_allocated, right, 16, title); col_count_allocated.str_val = "allocated"; COL(alloc_count_row, count_nmalloc, right, 16, title); col_count_nmalloc.str_val = "nmalloc"; COL(alloc_count_row, count_nmalloc_ps, right, 10, title); col_count_nmalloc_ps.str_val = "(#/sec)"; COL(alloc_count_row, count_ndalloc, right, 16, title); col_count_ndalloc.str_val = "ndalloc"; COL(alloc_count_row, count_ndalloc_ps, right, 10, title); col_count_ndalloc_ps.str_val = "(#/sec)"; COL(alloc_count_row, count_nrequests, right, 16, title); col_count_nrequests.str_val = "nrequests"; COL(alloc_count_row, count_nrequests_ps, right, 10, title); col_count_nrequests_ps.str_val = "(#/sec)"; COL(alloc_count_row, count_nfills, right, 16, title); col_count_nfills.str_val = "nfill"; COL(alloc_count_row, count_nfills_ps, right, 10, title); col_count_nfills_ps.str_val = "(#/sec)"; COL(alloc_count_row, count_nflushes, right, 16, title); col_count_nflushes.str_val = "nflush"; COL(alloc_count_row, count_nflushes_ps, right, 10, title); col_count_nflushes_ps.str_val = "(#/sec)"; emitter_table_row(emitter, &alloc_count_row); col_count_nmalloc_ps.type = emitter_type_uint64; col_count_ndalloc_ps.type = emitter_type_uint64; col_count_nrequests_ps.type = emitter_type_uint64; col_count_nfills_ps.type = emitter_type_uint64; col_count_nflushes_ps.type = emitter_type_uint64; #define GET_AND_EMIT_ALLOC_STAT(small_or_large, name, valtype) \ CTL_M2_GET("stats.arenas.0." #small_or_large "." #name, i, \ &small_or_large##_##name, valtype##_t); \ emitter_json_kv(emitter, #name, emitter_type_##valtype, \ &small_or_large##_##name); \ col_count_##name.type = emitter_type_##valtype; \ col_count_##name.valtype##_val = small_or_large##_##name; emitter_json_object_kv_begin(emitter, "small"); col_count_title.str_val = "small:"; GET_AND_EMIT_ALLOC_STAT(small, allocated, size) GET_AND_EMIT_ALLOC_STAT(small, nmalloc, uint64) col_count_nmalloc_ps.uint64_val = rate_per_second(col_count_nmalloc.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(small, ndalloc, uint64) col_count_ndalloc_ps.uint64_val = rate_per_second(col_count_ndalloc.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(small, nrequests, uint64) col_count_nrequests_ps.uint64_val = rate_per_second(col_count_nrequests.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(small, nfills, uint64) col_count_nfills_ps.uint64_val = rate_per_second(col_count_nfills.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(small, nflushes, uint64) col_count_nflushes_ps.uint64_val = rate_per_second(col_count_nflushes.uint64_val, uptime); emitter_table_row(emitter, &alloc_count_row); emitter_json_object_end(emitter); /* Close "small". */ emitter_json_object_kv_begin(emitter, "large"); col_count_title.str_val = "large:"; GET_AND_EMIT_ALLOC_STAT(large, allocated, size) GET_AND_EMIT_ALLOC_STAT(large, nmalloc, uint64) col_count_nmalloc_ps.uint64_val = rate_per_second(col_count_nmalloc.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(large, ndalloc, uint64) col_count_ndalloc_ps.uint64_val = rate_per_second(col_count_ndalloc.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(large, nrequests, uint64) col_count_nrequests_ps.uint64_val = rate_per_second(col_count_nrequests.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(large, nfills, uint64) col_count_nfills_ps.uint64_val = rate_per_second(col_count_nfills.uint64_val, uptime); GET_AND_EMIT_ALLOC_STAT(large, nflushes, uint64) col_count_nflushes_ps.uint64_val = rate_per_second(col_count_nflushes.uint64_val, uptime); emitter_table_row(emitter, &alloc_count_row); emitter_json_object_end(emitter); /* Close "large". */ #undef GET_AND_EMIT_ALLOC_STAT /* Aggregated small + large stats are emitter only in table mode. */ col_count_title.str_val = "total:"; col_count_allocated.size_val = small_allocated + large_allocated; col_count_nmalloc.uint64_val = small_nmalloc + large_nmalloc; col_count_ndalloc.uint64_val = small_ndalloc + large_ndalloc; col_count_nrequests.uint64_val = small_nrequests + large_nrequests; col_count_nfills.uint64_val = small_nfills + large_nfills; col_count_nflushes.uint64_val = small_nflushes + large_nflushes; col_count_nmalloc_ps.uint64_val = rate_per_second(col_count_nmalloc.uint64_val, uptime); col_count_ndalloc_ps.uint64_val = rate_per_second(col_count_ndalloc.uint64_val, uptime); col_count_nrequests_ps.uint64_val = rate_per_second(col_count_nrequests.uint64_val, uptime); col_count_nfills_ps.uint64_val = rate_per_second(col_count_nfills.uint64_val, uptime); col_count_nflushes_ps.uint64_val = rate_per_second(col_count_nflushes.uint64_val, uptime); emitter_table_row(emitter, &alloc_count_row); emitter_row_t mem_count_row; emitter_row_init(&mem_count_row); emitter_col_t mem_count_title; emitter_col_init(&mem_count_title, &mem_count_row); mem_count_title.justify = emitter_justify_left; mem_count_title.width = 21; mem_count_title.type = emitter_type_title; mem_count_title.str_val = ""; emitter_col_t mem_count_val; emitter_col_init(&mem_count_val, &mem_count_row); mem_count_val.justify = emitter_justify_right; mem_count_val.width = 16; mem_count_val.type = emitter_type_title; mem_count_val.str_val = ""; emitter_table_row(emitter, &mem_count_row); mem_count_val.type = emitter_type_size; /* Active count in bytes is emitted only in table mode. */ mem_count_title.str_val = "active:"; mem_count_val.size_val = pactive * page; emitter_table_row(emitter, &mem_count_row); #define GET_AND_EMIT_MEM_STAT(stat) \ CTL_M2_GET("stats.arenas.0."#stat, i, &stat, size_t); \ emitter_json_kv(emitter, #stat, emitter_type_size, &stat); \ mem_count_title.str_val = #stat":"; \ mem_count_val.size_val = stat; \ emitter_table_row(emitter, &mem_count_row); GET_AND_EMIT_MEM_STAT(mapped) GET_AND_EMIT_MEM_STAT(retained) GET_AND_EMIT_MEM_STAT(base) GET_AND_EMIT_MEM_STAT(internal) GET_AND_EMIT_MEM_STAT(metadata_thp) GET_AND_EMIT_MEM_STAT(tcache_bytes) GET_AND_EMIT_MEM_STAT(tcache_stashed_bytes) GET_AND_EMIT_MEM_STAT(resident) GET_AND_EMIT_MEM_STAT(abandoned_vm) GET_AND_EMIT_MEM_STAT(extent_avail) #undef GET_AND_EMIT_MEM_STAT if (mutex) { stats_arena_mutexes_print(emitter, i, uptime); } if (bins) { stats_arena_bins_print(emitter, mutex, i, uptime); } if (large) { stats_arena_lextents_print(emitter, i, uptime); } if (extents) { stats_arena_extents_print(emitter, i); } if (hpa) { stats_arena_hpa_shard_print(emitter, i, uptime); } } JEMALLOC_COLD static void stats_general_print(emitter_t *emitter) { const char *cpv; bool bv, bv2; unsigned uv; uint32_t u32v; uint64_t u64v; int64_t i64v; ssize_t ssv, ssv2; size_t sv, bsz, usz, u32sz, u64sz, i64sz, ssz, sssz, cpsz; bsz = sizeof(bool); usz = sizeof(unsigned); ssz = sizeof(size_t); sssz = sizeof(ssize_t); cpsz = sizeof(const char *); u32sz = sizeof(uint32_t); i64sz = sizeof(int64_t); u64sz = sizeof(uint64_t); CTL_GET("version", &cpv, const char *); emitter_kv(emitter, "version", "Version", emitter_type_string, &cpv); /* config. */ emitter_dict_begin(emitter, "config", "Build-time option settings"); #define CONFIG_WRITE_BOOL(name) \ do { \ CTL_GET("config."#name, &bv, bool); \ emitter_kv(emitter, #name, "config."#name, \ emitter_type_bool, &bv); \ } while (0) CONFIG_WRITE_BOOL(cache_oblivious); CONFIG_WRITE_BOOL(debug); CONFIG_WRITE_BOOL(fill); CONFIG_WRITE_BOOL(lazy_lock); emitter_kv(emitter, "malloc_conf", "config.malloc_conf", emitter_type_string, &config_malloc_conf); CONFIG_WRITE_BOOL(opt_safety_checks); CONFIG_WRITE_BOOL(prof); CONFIG_WRITE_BOOL(prof_libgcc); CONFIG_WRITE_BOOL(prof_libunwind); CONFIG_WRITE_BOOL(stats); CONFIG_WRITE_BOOL(utrace); CONFIG_WRITE_BOOL(xmalloc); #undef CONFIG_WRITE_BOOL emitter_dict_end(emitter); /* Close "config" dict. */ /* opt. */ #define OPT_WRITE(name, var, size, emitter_type) \ if (je_mallctl("opt."name, (void *)&var, &size, NULL, 0) == \ 0) { \ emitter_kv(emitter, name, "opt."name, emitter_type, \ &var); \ } #define OPT_WRITE_MUTABLE(name, var1, var2, size, emitter_type, \ altname) \ if (je_mallctl("opt."name, (void *)&var1, &size, NULL, 0) == \ 0 && je_mallctl(altname, (void *)&var2, &size, NULL, 0) \ == 0) { \ emitter_kv_note(emitter, name, "opt."name, \ emitter_type, &var1, altname, emitter_type, \ &var2); \ } #define OPT_WRITE_BOOL(name) OPT_WRITE(name, bv, bsz, emitter_type_bool) #define OPT_WRITE_BOOL_MUTABLE(name, altname) \ OPT_WRITE_MUTABLE(name, bv, bv2, bsz, emitter_type_bool, altname) #define OPT_WRITE_UNSIGNED(name) \ OPT_WRITE(name, uv, usz, emitter_type_unsigned) #define OPT_WRITE_INT64(name) \ OPT_WRITE(name, i64v, i64sz, emitter_type_int64) #define OPT_WRITE_UINT64(name) \ OPT_WRITE(name, u64v, u64sz, emitter_type_uint64) #define OPT_WRITE_SIZE_T(name) \ OPT_WRITE(name, sv, ssz, emitter_type_size) #define OPT_WRITE_SSIZE_T(name) \ OPT_WRITE(name, ssv, sssz, emitter_type_ssize) #define OPT_WRITE_SSIZE_T_MUTABLE(name, altname) \ OPT_WRITE_MUTABLE(name, ssv, ssv2, sssz, emitter_type_ssize, \ altname) #define OPT_WRITE_CHAR_P(name) \ OPT_WRITE(name, cpv, cpsz, emitter_type_string) emitter_dict_begin(emitter, "opt", "Run-time option settings"); OPT_WRITE_BOOL("abort") OPT_WRITE_BOOL("abort_conf") OPT_WRITE_BOOL("cache_oblivious") OPT_WRITE_BOOL("confirm_conf") OPT_WRITE_BOOL("retain") OPT_WRITE_CHAR_P("dss") OPT_WRITE_UNSIGNED("narenas") OPT_WRITE_CHAR_P("percpu_arena") OPT_WRITE_SIZE_T("oversize_threshold") OPT_WRITE_BOOL("hpa") OPT_WRITE_SIZE_T("hpa_slab_max_alloc") OPT_WRITE_SIZE_T("hpa_hugification_threshold") OPT_WRITE_UINT64("hpa_hugify_delay_ms") OPT_WRITE_UINT64("hpa_min_purge_interval_ms") if (je_mallctl("opt.hpa_dirty_mult", (void *)&u32v, &u32sz, NULL, 0) == 0) { /* * We cheat a little and "know" the secret meaning of this * representation. */ if (u32v == (uint32_t)-1) { const char *neg1 = "-1"; emitter_kv(emitter, "hpa_dirty_mult", "opt.hpa_dirty_mult", emitter_type_string, &neg1); } else { char buf[FXP_BUF_SIZE]; fxp_print(u32v, buf); const char *bufp = buf; emitter_kv(emitter, "hpa_dirty_mult", "opt.hpa_dirty_mult", emitter_type_string, &bufp); } } OPT_WRITE_SIZE_T("hpa_sec_nshards") OPT_WRITE_SIZE_T("hpa_sec_max_alloc") OPT_WRITE_SIZE_T("hpa_sec_max_bytes") OPT_WRITE_SIZE_T("hpa_sec_bytes_after_flush") OPT_WRITE_SIZE_T("hpa_sec_batch_fill_extra") OPT_WRITE_CHAR_P("metadata_thp") OPT_WRITE_INT64("mutex_max_spin") OPT_WRITE_BOOL_MUTABLE("background_thread", "background_thread") OPT_WRITE_SSIZE_T_MUTABLE("dirty_decay_ms", "arenas.dirty_decay_ms") OPT_WRITE_SSIZE_T_MUTABLE("muzzy_decay_ms", "arenas.muzzy_decay_ms") OPT_WRITE_SIZE_T("lg_extent_max_active_fit") OPT_WRITE_CHAR_P("junk") OPT_WRITE_BOOL("zero") OPT_WRITE_BOOL("utrace") OPT_WRITE_BOOL("xmalloc") OPT_WRITE_BOOL("experimental_infallible_new") OPT_WRITE_BOOL("tcache") OPT_WRITE_SIZE_T("tcache_max") OPT_WRITE_UNSIGNED("tcache_nslots_small_min") OPT_WRITE_UNSIGNED("tcache_nslots_small_max") OPT_WRITE_UNSIGNED("tcache_nslots_large") OPT_WRITE_SSIZE_T("lg_tcache_nslots_mul") OPT_WRITE_SIZE_T("tcache_gc_incr_bytes") OPT_WRITE_SIZE_T("tcache_gc_delay_bytes") OPT_WRITE_UNSIGNED("lg_tcache_flush_small_div") OPT_WRITE_UNSIGNED("lg_tcache_flush_large_div") OPT_WRITE_CHAR_P("thp") OPT_WRITE_BOOL("prof") OPT_WRITE_CHAR_P("prof_prefix") OPT_WRITE_BOOL_MUTABLE("prof_active", "prof.active") OPT_WRITE_BOOL_MUTABLE("prof_thread_active_init", "prof.thread_active_init") OPT_WRITE_SSIZE_T_MUTABLE("lg_prof_sample", "prof.lg_sample") OPT_WRITE_BOOL("prof_accum") OPT_WRITE_SSIZE_T("lg_prof_interval") OPT_WRITE_BOOL("prof_gdump") OPT_WRITE_BOOL("prof_final") OPT_WRITE_BOOL("prof_leak") OPT_WRITE_BOOL("prof_leak_error") OPT_WRITE_BOOL("stats_print") OPT_WRITE_CHAR_P("stats_print_opts") OPT_WRITE_BOOL("stats_print") OPT_WRITE_CHAR_P("stats_print_opts") OPT_WRITE_INT64("stats_interval") OPT_WRITE_CHAR_P("stats_interval_opts") OPT_WRITE_CHAR_P("zero_realloc") emitter_dict_end(emitter); #undef OPT_WRITE #undef OPT_WRITE_MUTABLE #undef OPT_WRITE_BOOL #undef OPT_WRITE_BOOL_MUTABLE #undef OPT_WRITE_UNSIGNED #undef OPT_WRITE_SSIZE_T #undef OPT_WRITE_SSIZE_T_MUTABLE #undef OPT_WRITE_CHAR_P /* prof. */ if (config_prof) { emitter_dict_begin(emitter, "prof", "Profiling settings"); CTL_GET("prof.thread_active_init", &bv, bool); emitter_kv(emitter, "thread_active_init", "prof.thread_active_init", emitter_type_bool, &bv); CTL_GET("prof.active", &bv, bool); emitter_kv(emitter, "active", "prof.active", emitter_type_bool, &bv); CTL_GET("prof.gdump", &bv, bool); emitter_kv(emitter, "gdump", "prof.gdump", emitter_type_bool, &bv); CTL_GET("prof.interval", &u64v, uint64_t); emitter_kv(emitter, "interval", "prof.interval", emitter_type_uint64, &u64v); CTL_GET("prof.lg_sample", &ssv, ssize_t); emitter_kv(emitter, "lg_sample", "prof.lg_sample", emitter_type_ssize, &ssv); emitter_dict_end(emitter); /* Close "prof". */ } /* arenas. */ /* * The json output sticks arena info into an "arenas" dict; the table * output puts them at the top-level. */ emitter_json_object_kv_begin(emitter, "arenas"); CTL_GET("arenas.narenas", &uv, unsigned); emitter_kv(emitter, "narenas", "Arenas", emitter_type_unsigned, &uv); /* * Decay settings are emitted only in json mode; in table mode, they're * emitted as notes with the opt output, above. */ CTL_GET("arenas.dirty_decay_ms", &ssv, ssize_t); emitter_json_kv(emitter, "dirty_decay_ms", emitter_type_ssize, &ssv); CTL_GET("arenas.muzzy_decay_ms", &ssv, ssize_t); emitter_json_kv(emitter, "muzzy_decay_ms", emitter_type_ssize, &ssv); CTL_GET("arenas.quantum", &sv, size_t); emitter_kv(emitter, "quantum", "Quantum size", emitter_type_size, &sv); CTL_GET("arenas.page", &sv, size_t); emitter_kv(emitter, "page", "Page size", emitter_type_size, &sv); if (je_mallctl("arenas.tcache_max", (void *)&sv, &ssz, NULL, 0) == 0) { emitter_kv(emitter, "tcache_max", "Maximum thread-cached size class", emitter_type_size, &sv); } unsigned arenas_nbins; CTL_GET("arenas.nbins", &arenas_nbins, unsigned); emitter_kv(emitter, "nbins", "Number of bin size classes", emitter_type_unsigned, &arenas_nbins); unsigned arenas_nhbins; CTL_GET("arenas.nhbins", &arenas_nhbins, unsigned); emitter_kv(emitter, "nhbins", "Number of thread-cache bin size classes", emitter_type_unsigned, &arenas_nhbins); /* * We do enough mallctls in a loop that we actually want to omit them * (not just omit the printing). */ if (emitter_outputs_json(emitter)) { emitter_json_array_kv_begin(emitter, "bin"); size_t arenas_bin_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(arenas_bin_mib, 0, "arenas.bin"); for (unsigned i = 0; i < arenas_nbins; i++) { arenas_bin_mib[2] = i; emitter_json_object_begin(emitter); CTL_LEAF(arenas_bin_mib, 3, "size", &sv, size_t); emitter_json_kv(emitter, "size", emitter_type_size, &sv); CTL_LEAF(arenas_bin_mib, 3, "nregs", &u32v, uint32_t); emitter_json_kv(emitter, "nregs", emitter_type_uint32, &u32v); CTL_LEAF(arenas_bin_mib, 3, "slab_size", &sv, size_t); emitter_json_kv(emitter, "slab_size", emitter_type_size, &sv); CTL_LEAF(arenas_bin_mib, 3, "nshards", &u32v, uint32_t); emitter_json_kv(emitter, "nshards", emitter_type_uint32, &u32v); emitter_json_object_end(emitter); } emitter_json_array_end(emitter); /* Close "bin". */ } unsigned nlextents; CTL_GET("arenas.nlextents", &nlextents, unsigned); emitter_kv(emitter, "nlextents", "Number of large size classes", emitter_type_unsigned, &nlextents); if (emitter_outputs_json(emitter)) { emitter_json_array_kv_begin(emitter, "lextent"); size_t arenas_lextent_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(arenas_lextent_mib, 0, "arenas.lextent"); for (unsigned i = 0; i < nlextents; i++) { arenas_lextent_mib[2] = i; emitter_json_object_begin(emitter); CTL_LEAF(arenas_lextent_mib, 3, "size", &sv, size_t); emitter_json_kv(emitter, "size", emitter_type_size, &sv); emitter_json_object_end(emitter); } emitter_json_array_end(emitter); /* Close "lextent". */ } emitter_json_object_end(emitter); /* Close "arenas" */ } JEMALLOC_COLD static void stats_print_helper(emitter_t *emitter, bool merged, bool destroyed, bool unmerged, bool bins, bool large, bool mutex, bool extents, bool hpa) { /* * These should be deleted. We keep them around for a while, to aid in * the transition to the emitter code. */ size_t allocated, active, metadata, metadata_thp, resident, mapped, retained; size_t num_background_threads; size_t zero_reallocs; uint64_t background_thread_num_runs, background_thread_run_interval; CTL_GET("stats.allocated", &allocated, size_t); CTL_GET("stats.active", &active, size_t); CTL_GET("stats.metadata", &metadata, size_t); CTL_GET("stats.metadata_thp", &metadata_thp, size_t); CTL_GET("stats.resident", &resident, size_t); CTL_GET("stats.mapped", &mapped, size_t); CTL_GET("stats.retained", &retained, size_t); CTL_GET("stats.zero_reallocs", &zero_reallocs, size_t); if (have_background_thread) { CTL_GET("stats.background_thread.num_threads", &num_background_threads, size_t); CTL_GET("stats.background_thread.num_runs", &background_thread_num_runs, uint64_t); CTL_GET("stats.background_thread.run_interval", &background_thread_run_interval, uint64_t); } else { num_background_threads = 0; background_thread_num_runs = 0; background_thread_run_interval = 0; } /* Generic global stats. */ emitter_json_object_kv_begin(emitter, "stats"); emitter_json_kv(emitter, "allocated", emitter_type_size, &allocated); emitter_json_kv(emitter, "active", emitter_type_size, &active); emitter_json_kv(emitter, "metadata", emitter_type_size, &metadata); emitter_json_kv(emitter, "metadata_thp", emitter_type_size, &metadata_thp); emitter_json_kv(emitter, "resident", emitter_type_size, &resident); emitter_json_kv(emitter, "mapped", emitter_type_size, &mapped); emitter_json_kv(emitter, "retained", emitter_type_size, &retained); emitter_json_kv(emitter, "zero_reallocs", emitter_type_size, &zero_reallocs); emitter_table_printf(emitter, "Allocated: %zu, active: %zu, " "metadata: %zu (n_thp %zu), resident: %zu, mapped: %zu, " "retained: %zu\n", allocated, active, metadata, metadata_thp, resident, mapped, retained); /* Strange behaviors */ emitter_table_printf(emitter, "Count of realloc(non-null-ptr, 0) calls: %zu\n", zero_reallocs); /* Background thread stats. */ emitter_json_object_kv_begin(emitter, "background_thread"); emitter_json_kv(emitter, "num_threads", emitter_type_size, &num_background_threads); emitter_json_kv(emitter, "num_runs", emitter_type_uint64, &background_thread_num_runs); emitter_json_kv(emitter, "run_interval", emitter_type_uint64, &background_thread_run_interval); emitter_json_object_end(emitter); /* Close "background_thread". */ emitter_table_printf(emitter, "Background threads: %zu, " "num_runs: %"FMTu64", run_interval: %"FMTu64" ns\n", num_background_threads, background_thread_num_runs, background_thread_run_interval); if (mutex) { emitter_row_t row; emitter_col_t name; emitter_col_t col64[mutex_prof_num_uint64_t_counters]; emitter_col_t col32[mutex_prof_num_uint32_t_counters]; uint64_t uptime; emitter_row_init(&row); mutex_stats_init_cols(&row, "", &name, col64, col32); emitter_table_row(emitter, &row); emitter_json_object_kv_begin(emitter, "mutexes"); CTL_M2_GET("stats.arenas.0.uptime", 0, &uptime, uint64_t); size_t stats_mutexes_mib[CTL_MAX_DEPTH]; CTL_LEAF_PREPARE(stats_mutexes_mib, 0, "stats.mutexes"); for (int i = 0; i < mutex_prof_num_global_mutexes; i++) { mutex_stats_read_global(stats_mutexes_mib, 2, global_mutex_names[i], &name, col64, col32, uptime); emitter_json_object_kv_begin(emitter, global_mutex_names[i]); mutex_stats_emit(emitter, &row, col64, col32); emitter_json_object_end(emitter); } emitter_json_object_end(emitter); /* Close "mutexes". */ } emitter_json_object_end(emitter); /* Close "stats". */ if (merged || destroyed || unmerged) { unsigned narenas; emitter_json_object_kv_begin(emitter, "stats.arenas"); CTL_GET("arenas.narenas", &narenas, unsigned); size_t mib[3]; size_t miblen = sizeof(mib) / sizeof(size_t); size_t sz; VARIABLE_ARRAY(bool, initialized, narenas); bool destroyed_initialized; unsigned i, j, ninitialized; xmallctlnametomib("arena.0.initialized", mib, &miblen); for (i = ninitialized = 0; i < narenas; i++) { mib[1] = i; sz = sizeof(bool); xmallctlbymib(mib, miblen, &initialized[i], &sz, NULL, 0); if (initialized[i]) { ninitialized++; } } mib[1] = MALLCTL_ARENAS_DESTROYED; sz = sizeof(bool); xmallctlbymib(mib, miblen, &destroyed_initialized, &sz, NULL, 0); /* Merged stats. */ if (merged && (ninitialized > 1 || !unmerged)) { /* Print merged arena stats. */ emitter_table_printf(emitter, "Merged arenas stats:\n"); emitter_json_object_kv_begin(emitter, "merged"); stats_arena_print(emitter, MALLCTL_ARENAS_ALL, bins, large, mutex, extents, hpa); emitter_json_object_end(emitter); /* Close "merged". */ } /* Destroyed stats. */ if (destroyed_initialized && destroyed) { /* Print destroyed arena stats. */ emitter_table_printf(emitter, "Destroyed arenas stats:\n"); emitter_json_object_kv_begin(emitter, "destroyed"); stats_arena_print(emitter, MALLCTL_ARENAS_DESTROYED, bins, large, mutex, extents, hpa); emitter_json_object_end(emitter); /* Close "destroyed". */ } /* Unmerged stats. */ if (unmerged) { for (i = j = 0; i < narenas; i++) { if (initialized[i]) { char arena_ind_str[20]; malloc_snprintf(arena_ind_str, sizeof(arena_ind_str), "%u", i); emitter_json_object_kv_begin(emitter, arena_ind_str); emitter_table_printf(emitter, "arenas[%s]:\n", arena_ind_str); stats_arena_print(emitter, i, bins, large, mutex, extents, hpa); /* Close "". */ emitter_json_object_end(emitter); } } } emitter_json_object_end(emitter); /* Close "stats.arenas". */ } } void stats_print(write_cb_t *write_cb, void *cbopaque, const char *opts) { int err; uint64_t epoch; size_t u64sz; #define OPTION(o, v, d, s) bool v = d; STATS_PRINT_OPTIONS #undef OPTION /* * Refresh stats, in case mallctl() was called by the application. * * Check for OOM here, since refreshing the ctl cache can trigger * allocation. In practice, none of the subsequent mallctl()-related * calls in this function will cause OOM if this one succeeds. * */ epoch = 1; u64sz = sizeof(uint64_t); err = je_mallctl("epoch", (void *)&epoch, &u64sz, (void *)&epoch, sizeof(uint64_t)); if (err != 0) { if (err == EAGAIN) { malloc_write(": Memory allocation failure in " "mallctl(\"epoch\", ...)\n"); return; } malloc_write(": Failure in mallctl(\"epoch\", " "...)\n"); abort(); } if (opts != NULL) { for (unsigned i = 0; opts[i] != '\0'; i++) { switch (opts[i]) { #define OPTION(o, v, d, s) case o: v = s; break; STATS_PRINT_OPTIONS #undef OPTION default:; } } } emitter_t emitter; emitter_init(&emitter, json ? emitter_output_json_compact : emitter_output_table, write_cb, cbopaque); emitter_begin(&emitter); emitter_table_printf(&emitter, "___ Begin jemalloc statistics ___\n"); emitter_json_object_kv_begin(&emitter, "jemalloc"); if (general) { stats_general_print(&emitter); } if (config_stats) { stats_print_helper(&emitter, merged, destroyed, unmerged, bins, large, mutex, extents, hpa); } emitter_json_object_end(&emitter); /* Closes the "jemalloc" dict. */ emitter_table_printf(&emitter, "--- End jemalloc statistics ---\n"); emitter_end(&emitter); } uint64_t stats_interval_new_event_wait(tsd_t *tsd) { return stats_interval_accum_batch; } uint64_t stats_interval_postponed_event_wait(tsd_t *tsd) { return TE_MIN_START_WAIT; } void stats_interval_event_handler(tsd_t *tsd, uint64_t elapsed) { assert(elapsed > 0 && elapsed != TE_INVALID_ELAPSED); if (counter_accum(tsd_tsdn(tsd), &stats_interval_accumulated, elapsed)) { je_malloc_stats_print(NULL, NULL, opt_stats_interval_opts); } } bool stats_boot(void) { uint64_t stats_interval; if (opt_stats_interval < 0) { assert(opt_stats_interval == -1); stats_interval = 0; stats_interval_accum_batch = 0; } else{ /* See comments in stats.h */ stats_interval = (opt_stats_interval > 0) ? opt_stats_interval : 1; uint64_t batch = stats_interval >> STATS_INTERVAL_ACCUM_LG_BATCH_SIZE; if (batch > STATS_INTERVAL_ACCUM_BATCH_MAX) { batch = STATS_INTERVAL_ACCUM_BATCH_MAX; } else if (batch == 0) { batch = 1; } stats_interval_accum_batch = batch; } return counter_accum_init(&stats_interval_accumulated, stats_interval); } void stats_prefork(tsdn_t *tsdn) { counter_prefork(tsdn, &stats_interval_accumulated); } void stats_postfork_parent(tsdn_t *tsdn) { counter_postfork_parent(tsdn, &stats_interval_accumulated); } void stats_postfork_child(tsdn_t *tsdn) { counter_postfork_child(tsdn, &stats_interval_accumulated); }