#ifndef INCLUDE_HEAP_JEMALLOC_STD_C #define INCLUDE_HEAP_JEMALLOC_STD_C #define HEAP32 1 #include "linux_heap_jemalloc.c" #undef HEAP32 #endif #undef GH #undef GHT #undef GHT_MAX #undef PFMTx // FIXME: It should be detected at runtime, not during the compilation stage #if HEAP32 #define GH(x) x##_32 #define GHT ut32 #define GHT_MAX UT32_MAX #define PFMTx PFMT32x #else #define GH(x) x##_64 #define GHT ut64 #define GHT_MAX UT64_MAX #define PFMTx PFMT64x #endif #if __linux__ // TODO: provide proper api in cbin to resolve symbols and load libraries from debug maps and such // this is, provide a programmatic api for the slow dmi command static GHT GH(je_get_va_symbol)(const char *path, const char *symname) { RListIter *iter; RBinSymbol *s; RCore *core = r_core_new (); GHT vaddr = 0LL; if (!core) { return GHT_MAX; } RBinOptions opt; r_bin_options_init (&opt, -1, 0, 0, false); if (r_bin_open (core->bin, path, &opt)) { RList *syms = r_bin_get_symbols (core->bin); if (!syms) { r_core_free (core); return GHT_MAX; } r_list_foreach (syms, iter, s) { if (!strcmp(s->name, symname)) { vaddr = s->vaddr; break; } } } r_core_free (core); return vaddr; } static int GH(je_matched)(const char *ptr, const char *str) { int ret = strncmp (ptr, str, strlen (str) - 1); return !ret; } #endif static bool GH(r_resolve_jemalloc)(RCore *core, char *symname, ut64 *symbol) { RListIter *iter; RDebugMap *map; const char *jemalloc_ver_end = NULL; ut64 jemalloc_addr = UT64_MAX; if (!core || !core->dbg || !core->dbg->maps){ return false; } r_debug_map_sync (core->dbg); r_list_foreach (core->dbg->maps, iter, map) { if (strstr (map->name, "libjemalloc.")) { jemalloc_addr = map->addr; jemalloc_ver_end = map->name; break; } } if (!jemalloc_ver_end) { eprintf ("Warning: Is jemalloc mapped in memory? (see dm command)\n"); return false; } #if __linux__ bool is_debug_file = GH(je_matched)(jemalloc_ver_end, "/usr/local/lib"); if (!is_debug_file) { eprintf ("Warning: Is libjemalloc.so.2 in /usr/local/lib path?\n"); return false; } char *path = r_str_newf ("%s", jemalloc_ver_end); if (r_file_exists (path)) { ut64 vaddr = GH(je_get_va_symbol)(path, symname); if (jemalloc_addr != GHT_MAX && vaddr != 0) { *symbol = jemalloc_addr + vaddr; free (path); return true; } } free (path); return false; #else eprintf ("[*] Resolving %s from libjemalloc.2... ", symname); // this is quite sloooow, we must optimize dmi char *va = r_core_cmd_strf (core, "dmi libjemalloc.2 %s$~[1]", symname); ut64 n = r_num_get (NULL, va); if (n && n != UT64_MAX) { *symbol = n; eprintf ("0x%08"PFMT64x"\n", n); } else { eprintf ("NOT FOUND\n"); } free (va); return true; #endif } static void GH(jemalloc_get_chunks)(RCore *core, const char *input) { ut64 cnksz; RConsPrintablePalette *pal = &r_cons_singleton ()->context->pal; if (!GH(r_resolve_jemalloc)(core, "je_chunksize", &cnksz)) { eprintf ("Fail at read symbol je_chunksize\n"); return; } r_io_read_at (core->io, cnksz, (ut8 *)&cnksz, sizeof (GHT)); switch (input[0]) { case '\0': eprintf ("need an arena_t to associate chunks"); break; case ' ': { GHT arena = GHT_MAX; arena_t *ar = R_NEW0 (arena_t); extent_node_t *node = R_NEW0 (extent_node_t), *head = R_NEW0 (extent_node_t); input += 1; arena = r_num_math (core->num, input); if (arena) { r_io_read_at (core->io, arena, (ut8 *)ar, sizeof (arena_t)); r_io_read_at (core->io, (GHT)(size_t)ar->achunks.qlh_first, (ut8 *)head, sizeof (extent_node_t)); if (head->en_addr) { PRINT_YA (" Chunk - start: "); PRINTF_BA ("0x%08"PFMT64x, (ut64)(size_t)head->en_addr); PRINT_YA (", end: "); PRINTF_BA ("0x%08"PFMT64x, (ut64)(size_t)((char *)head->en_addr + cnksz)); PRINT_YA (", size: "); PRINTF_BA ("0x%08"PFMT64x"\n", (ut64)cnksz); r_io_read_at (core->io, (ut64)(size_t)head->ql_link.qre_next, (ut8 *)node, sizeof (extent_node_t)); while (node && node->en_addr != head->en_addr) { PRINT_YA (" Chunk - start: "); PRINTF_BA ("0x%08"PFMT64x, (ut64)(size_t)node->en_addr); PRINT_YA (", end: "); PRINTF_BA ("0x%"PFMT64x, (ut64)(size_t)((char *)node->en_addr + cnksz)); PRINT_YA (", size: "); PRINTF_BA ("0x%08"PFMT64x"\n", cnksz); r_io_read_at (core->io, (ut64)(size_t)node->ql_link.qre_next, (ut8 *)node, sizeof (extent_node_t)); } } } free (ar); free (head); free (node); break; } case '*': { int i = 0; ut64 sym; GHT arenas = GHT_MAX, arena = GHT_MAX; arena_t *ar = R_NEW0 (arena_t); extent_node_t *node = R_NEW0 (extent_node_t); extent_node_t *head = R_NEW0 (extent_node_t); if (!node || !head) { eprintf ("Error calling calloc\n"); free (ar); free (node); free (head); return; } if (GH(r_resolve_jemalloc) (core, "je_arenas", &sym)) { r_io_read_at (core->io, sym, (ut8 *)&arenas, sizeof (GHT)); for (;;) { r_io_read_at (core->io, arenas + i * sizeof (GHT), (ut8 *)&arena, sizeof (GHT)); if (!arena) { break; } PRINTF_GA ("arenas[%d]: @ 0x%"PFMTx" { \n", i++, (GHT)arena); r_io_read_at (core->io, arena, (ut8 *)ar, sizeof (arena_t)); r_io_read_at (core->io, (GHT)(size_t)ar->achunks.qlh_first, (ut8 *)head, sizeof (extent_node_t)); if (head->en_addr != 0) { PRINT_YA (" Chunk - start: "); PRINTF_BA ("0x%08"PFMT64x, (ut64)(size_t)head->en_addr); PRINT_YA (", end: "); PRINTF_BA ("0x%"PFMT64x, (ut64)(size_t)((char *)head->en_addr + cnksz)); PRINT_YA (", size: "); PRINTF_BA ("0x%08"PFMT64x"\n", (ut64)cnksz); ut64 addr = (ut64) (size_t)head->ql_link.qre_next; r_io_read_at (core->io, addr, (ut8 *)node, sizeof (extent_node_t)); while (node && head && node->en_addr != head->en_addr) { PRINT_YA (" Chunk - start: "); PRINTF_BA ("0x%08"PFMT64x, (ut64)(size_t)node->en_addr); PRINT_YA (", end: "); PRINTF_BA ("0x%"PFMT64x, (ut64)(size_t)((char *)node->en_addr + cnksz)); PRINT_YA (", size: "); PRINTF_BA ("0x%"PFMT64x"\n", cnksz); r_io_read_at (core->io, (GHT)(size_t)node->ql_link.qre_next, (ut8 *)node, sizeof (extent_node_t)); } } PRINT_GA ("}\n"); } } free (ar); free (head); free (node); } break; } } static void GH(jemalloc_print_narenas)(RCore *core, const char *input) { ut64 symaddr; ut64 arenas; GHT arena = GHT_MAX; arena_t *ar = R_NEW0 (arena_t); if (!ar) { return; } arena_stats_t *stats = R_NEW0 (arena_stats_t); if (!stats) { free (ar); return; } int i = 0; GHT narenas = 0; RConsPrintablePalette *pal = &r_cons_singleton ()->context->pal; switch (input[0]) { case '\0': if (GH(r_resolve_jemalloc)(core, "narenas_total", &symaddr)) { r_io_read_at (core->io, symaddr, (ut8 *)&narenas, sizeof (GHT)); PRINTF_GA ("narenas : %"PFMT64d"\n", (ut64)narenas); } if (narenas == 0) { eprintf ("No arenas allocated.\n"); free (stats); free (ar); return; } if (narenas == GHT_MAX) { eprintf ("Cannot find narenas_total\n"); free (stats); free (ar); return; } if (GH(r_resolve_jemalloc)(core, "je_arenas", &arenas)) { r_io_read_at (core->io, arenas, (ut8 *)&arenas, sizeof (GHT)); PRINTF_GA ("arenas[%"PFMT64d"] @ 0x%"PFMT64x" {\n", (ut64)narenas, (ut64)arenas); for (i = 0; i < narenas; i++) { ut64 at = arenas + (i * sizeof (GHT)); r_io_read_at (core->io, at, (ut8 *)&arena, sizeof (GHT)); if (!arena) { PRINTF_YA (" arenas[%d]: (empty)\n", i); continue; } PRINTF_YA (" arenas[%d]: ", i); PRINTF_BA ("@ 0x%"PFMT64x"\n", at); } } PRINT_GA ("}\n"); break; case ' ': arena = r_num_math (core->num, input + 1); r_io_read_at (core->io, (GHT)arena, (ut8 *)ar, sizeof (arena_t)); PRINT_GA ("struct arena_s {\n"); #define OO(x) (ut64)(arena + r_offsetof (arena_t, x)) PRINTF_BA (" ind = 0x%x\n", ar->ind); PRINTF_BA (" nthreads: application allocation = 0x%"PFMT64x"\n", (ut64)ar->nthreads[0]); PRINTF_BA (" nthreads: internal metadata allocation = 0x%"PFMT64x"\n", (ut64)ar->nthreads[1]); PRINTF_BA (" lock = 0x%"PFMT64x"\n", OO(lock)); PRINTF_BA (" stats = 0x%"PFMT64x"\n", OO(stats)); PRINTF_BA (" tcache_ql = 0x%"PFMT64x"\n", OO(tcache_ql)); PRINTF_BA (" prof_accumbytes = 0x%"PFMT64x"x\n", (ut64)ar->prof_accumbytes); PRINTF_BA (" offset_state = 0x%"PFMT64x"\n", (ut64)ar->offset_state); PRINTF_BA (" dss_prec_t = 0x%"PFMT64x"\n",OO(dss_prec)); PRINTF_BA (" achunks = 0x%"PFMT64x"\n", OO(achunks)); PRINTF_BA (" extent_sn_next = 0x%"PFMT64x"\n", (ut64)(size_t)ar->extent_sn_next); PRINTF_BA (" spare = 0x%"PFMT64x"\n", (ut64)(size_t)ar->spare); PRINTF_BA (" lg_dirty_mult = 0x%"PFMT64x"\n", (ut64)(ssize_t)ar->lg_dirty_mult); PRINTF_BA (" purging = %s\n", r_str_bool (ar->purging)); PRINTF_BA (" nactive = 0x%"PFMT64x"\n", (ut64)(size_t)ar->nactive); PRINTF_BA (" ndirty = 0x%"PFMT64x"\n", (ut64)(size_t)ar->ndirty); PRINTF_BA (" runs_dirty = 0x%"PFMT64x"\n", OO(runs_dirty)); PRINTF_BA (" chunks_cache = 0x%"PFMT64x"\n", OO(chunks_cache)); PRINTF_BA (" huge = 0x%"PFMT64x"\n", OO(huge)); PRINTF_BA (" huge_mtx = 0x%"PFMT64x"\n", OO(huge_mtx)); PRINTF_BA (" chunks_szsnad_cached = 0x%"PFMT64x"\n", OO(chunks_szsnad_cached)); PRINTF_BA (" chunks_ad_cached = 0x%"PFMT64x"\n", OO(chunks_ad_cached)); PRINTF_BA (" chunks_szsnad_retained = 0x%"PFMT64x"\n", OO(chunks_szsnad_retained)); PRINTF_BA (" chunks_ad_cached = 0x%"PFMT64x"\n", OO(chunks_ad_retained)); PRINTF_BA (" chunks_mtx = 0x%"PFMT64x"\n", OO(chunks_mtx)); PRINTF_BA (" node_cache = 0x%"PFMT64x"\n", OO(node_cache)); PRINTF_BA (" node_cache_mtx = 0x%"PFMT64x"\n", OO(node_cache_mtx)); PRINTF_BA (" chunks_hooks = 0x%"PFMT64x"\n", OO(chunk_hooks)); PRINTF_BA (" bins = %d 0x%"PFMT64x"\n", JM_NBINS, OO(bins)); PRINTF_BA (" runs_avail = %d 0x%"PFMT64x"\n", NPSIZES, OO(runs_avail)); PRINT_GA ("}\n"); break; } free (ar); free (stats); } static void GH(jemalloc_get_bins)(RCore *core, const char *input) { int i = 0, j; ut64 bin_info; ut64 arenas; GHT arena = GHT_MAX; //, bin = GHT_MAX; arena_t *ar = NULL; arena_bin_info_t *b = NULL; RConsPrintablePalette *pal = &r_cons_singleton ()->context->pal; switch (input[0]) { case ' ': ar = R_NEW0 (arena_t); if (!ar) { break; } b = R_NEW0 (arena_bin_info_t); if (!b) { break; } if (!GH(r_resolve_jemalloc)(core, "je_arena_bin_info", &bin_info)) { eprintf ("Error resolving je_arena_bin_info\n"); R_FREE (b); break; } if (GH(r_resolve_jemalloc)(core, "je_arenas", &arenas)) { r_io_read_at (core->io, arenas, (ut8 *)&arenas, sizeof (GHT)); PRINTF_GA ("arenas @ 0x%"PFMTx" {\n", (GHT)arenas); for (;;) { r_io_read_at (core->io, arenas + i * sizeof (GHT), (ut8 *)&arena, sizeof (GHT)); if (!arena) { R_FREE (b); break; } PRINTF_YA (" arenas[%d]: ", i++); PRINTF_BA ("@ 0x%"PFMTx, (GHT)arena); PRINT_YA (" {\n"); r_io_read_at (core->io, arena, (ut8 *)ar, sizeof (arena_t)); for (j = 0; j < JM_NBINS; j++) { r_io_read_at (core->io, (GHT)(bin_info + j * sizeof (arena_bin_info_t)), (ut8*)b, sizeof (arena_bin_info_t)); PRINT_YA (" {\n"); PRINT_YA (" regsize : "); PRINTF_BA ("0x%zx\n", b->reg_size); PRINT_YA (" redzone size "); PRINTF_BA ("0x%zx\n", b->redzone_size); PRINT_YA (" reg_interval : "); PRINTF_BA ("0x%zx\n", b->reg_interval); PRINT_YA (" run_size : "); PRINTF_BA ("0x%zx\n", b->run_size); PRINT_YA (" nregs : "); PRINTF_BA ("0x%x\n", b->nregs); // FIXME: It's a structure of bitmap_info_t //PRINT_YA (" bitmap_info : "); //PRINTF_BA ("0x%"PFMT64x"\n", b->bitmap_info); PRINT_YA (" reg0_offset : "); PRINTF_BA ("0x%"PFMT64x"\n\n", (ut64)b->reg0_offset); // FIXME: It's a structure of malloc_mutex_t //PRINTF_YA (" bins[%d]->lock ", j); //PRINTF_BA ("= 0x%"PFMT64x"\n", ar->bins[j].lock); // FIXME: It's a structure of arena_run_t* //PRINTF_YA (" bins[%d]->runcur ", j); //PRINTF_BA ("@ 0x%"PFMT64x"\n", ar->bins[j].runcur); // FIXME: It's a structure of arena_run_heap_t* //PRINTF_YA (" bins[%d]->runs ", j); //PRINTF_BA ("@ 0x%"PFMTx"\n", ar->bins[j].runs); // FIXME: It's a structure of malloc_bin_stats_t //PRINTF_YA (" bins[%d]->stats ", j); //PRINTF_BA ("= 0x%"PFMTx"\n", ar->bins[j].stats); PRINT_YA (" }\n"); } PRINT_YA (" }\n"); } } PRINT_GA ("}\n"); break; } free (ar); free (b); } #if 0 static void GH(jemalloc_get_runs)(RCore *core, const char *input) { switch (input[0]) { case ' ': { int pageind; ut64 npages, chunksize_mask, map_bias, map_misc_offset, chunk, mapbits;; arena_chunk_t *c = R_NEW0 (arena_chunk_t); if (!c) { eprintf ("Error calling calloc\n"); return; } input += 1; chunk = r_num_math (core->num, input); if (!GH(r_resolve_jemalloc)(core, "je_chunk_npages", &npages)) { eprintf ("Error resolving je_chunk_npages\n"); return; } if (!GH(r_resolve_jemalloc)(core, "je_chunksize_mask", &chunksize_mask)) { eprintf ("Error resolving je_chunksize_mask\n"); return; } if (!GH(r_resolve_jemalloc)(core, "je_map_bias", &map_bias)) { eprintf ("Error resolving je_map_bias"); return; } if (!GH(r_resolve_jemalloc)(core, "je_map_misc_offset", &map_misc_offset)) { eprintf ("Error resolving je_map_misc_offset"); return; } r_io_read_at (core->io, npages, (ut8*)&npages, sizeof (GHT)); r_io_read_at (core->io, chunksize_mask, (ut8*)&chunksize_mask, sizeof (GHT)); r_io_read_at (core->io, map_bias, (ut8*)&map_bias, sizeof (GHT)); r_io_read_at (core->io, map_misc_offset, (ut8*)&map_misc_offset, sizeof (GHT)); eprintf ("map_misc_offset 0x%08"PFMT64x"\n", (ut64)map_misc_offset); r_io_read_at (core->io, chunk, (ut8 *)c, sizeof (arena_chunk_t)); mapbits = *(GHT *)&c->map_bits; eprintf ("map_bits: 0x%08"PFMT64x"\n", (ut64)mapbits); uint32_t offset = r_offsetof (arena_chunk_t, map_bits); arena_chunk_map_bits_t *dwords = (void *)calloc (sizeof (arena_chunk_map_bits_t), npages); r_io_read_at (core->io, chunk + offset, (ut8*)dwords, sizeof (arena_chunk_map_bits_t) * npages); eprintf ("map_bits @ 0x%08"PFMT64x"\n", (ut64)(chunk + offset)); arena_run_t *r = R_NEW0 (arena_run_t); if (!r) { eprintf ("Error calling calloc\n"); return; } for (pageind = map_bias; pageind < npages; pageind++) { arena_chunk_map_bits_t mapelm = dwords[pageind-map_bias]; if (mapelm.bits & CHUNK_MAP_ALLOCATED) { // ut64 elm = ((arena_chunk_map_misc_t *)((uintptr_t)chunk + (uintptr_t)map_misc_offset) + pageind-map_bias); ut64 elm = chunk + map_misc_offset + pageind-map_bias; eprintf ("\nelm: 0x%"PFMT64x"\n", elm); arena_chunk_map_misc_t *m = R_NEW0 (arena_chunk_map_misc_t); if (m) { ut64 run = elm + r_offsetof (arena_chunk_map_misc_t, run); r_io_read_at (core->io, elm, (ut8*)m, sizeof (arena_chunk_map_misc_t)); eprintf ("Small run @ 0x%08"PFMT64x"\n", (ut64)elm); r_io_read_at (core->io, run, (ut8*)r, sizeof (arena_run_t)); eprintf ("binind: 0x%08"PFMT64x"\n", (ut64)r->binind); eprintf ("nfree: 0x%08"PFMT64x"\n", (ut64)r->nfree); eprintf ("bitmap: 0x%08"PFMT64x"\n\n", (ut64)*(GHT*)r->bitmap); free (m); } } else if (mapelm.bits & CHUNK_MAP_LARGE) { ut64 run = (ut64) (size_t) chunk + (pageind << LG_PAGE); eprintf ("Large run @ 0x%08"PFMT64x"\n", run); r_io_read_at (core->io, run, (ut8*)r, sizeof (arena_run_t)); eprintf ("binind: 0x%08"PFMT64x"\n", (ut64)r->binind); eprintf ("nfree: 0x%08"PFMT64x"\n", (ut64)r->nfree); eprintf ("bitmap: 0x%08"PFMT64x"\n\n", (ut64)*(GHT*)r->bitmap); } } free (c); free (r); } break; } } #endif static int GH(cmd_dbg_map_jemalloc)(RCore *core, const char *input) { const char *help_msg[] = { "Usage:", "dmh", " # Memory map heap", "dmha", "[arena_t]", "show all arenas created, or print arena_t structure for given arena", "dmhb", "[arena_t]", "show all bins created for given arena", "dmhc", "*|[arena_t]", "show all chunks created in all arenas, or show all chunks created for a given arena_t instance", // "dmhr", "[arena_chunk_t]", "print all runs created for a given arena_chunk_t instance", "dmh?", "", "Show map heap help", NULL }; switch (input[0]) { case '?': r_core_cmd_help (core, help_msg); break; case 'a': //dmha GH(jemalloc_print_narenas) (core, input + 1); break; case 'b': //dmhb GH(jemalloc_get_bins) (core, input + 1); break; case 'c': //dmhc GH(jemalloc_get_chunks) (core, input + 1); break; /* case 'r': //dmhr GH(jemalloc_get_runs) (core, input + 1); break; */ } return 0; }