// // Copyright (C) 2008 The Android Open Source Project // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. // #include <dirent.h> #include <errno.h> #include <fcntl.h> #include <inttypes.h> #include <stdlib.h> #include <string.h> #include <sys/types.h> #include <unistd.h> #include <vector> #include <android-base/file.h> #include <android-base/stringprintf.h> #include <android-base/strings.h> #include <pagemap/pagemap.h> struct proc_info { pid_t pid; pm_memusage_t usage; uint64_t wss; int oomadj; }; static void usage(char *myname); static std::string getprocname(pid_t pid); static int getoomadj(pid_t pid); static bool getminfree(std::vector<uint64_t>* minfree, std::vector<int>* adj); static int numcmp(uint64_t a, uint64_t b); #define declare_sort(field) \ static int sort_by_ ## field (const void *a, const void *b) declare_sort(vss); declare_sort(rss); declare_sort(pss); declare_sort(uss); declare_sort(swap); declare_sort(oomadj); int (*compfn)(const void *a, const void *b); static int order; enum { MEMINFO_TOTAL, MEMINFO_FREE, MEMINFO_BUFFERS, MEMINFO_CACHED, MEMINFO_SHMEM, MEMINFO_SLAB, MEMINFO_SWAP_TOTAL, MEMINFO_SWAP_FREE, MEMINFO_ZRAM_TOTAL, MEMINFO_MAPPED, MEMINFO_VMALLOC_USED, MEMINFO_PAGE_TABLES, MEMINFO_KERNEL_STACK, MEMINFO_COUNT }; void get_mem_info(uint64_t mem[]) { char buffer[1024]; unsigned int numFound = 0; int fd = open("/proc/meminfo", O_RDONLY); if (fd < 0) { printf("Unable to open /proc/meminfo: %s\n", strerror(errno)); return; } const int len = read(fd, buffer, sizeof(buffer)-1); close(fd); if (len < 0) { printf("Empty /proc/meminfo"); return; } buffer[len] = 0; static const char* const tags[] = { "MemTotal:", "MemFree:", "Buffers:", "Cached:", "Shmem:", "Slab:", "SwapTotal:", "SwapFree:", "ZRam:", // not read from meminfo but from /sys/block/zram0 "Mapped:", "VmallocUsed:", "PageTables:", "KernelStack:", NULL }; static const int tagsLen[] = { 9, 8, 8, 7, 6, 5, 10, 9, 5, 7, 12, 11, 12, 0 }; char* p = buffer; while (*p && (numFound < (sizeof(tagsLen) / sizeof(tagsLen[0])))) { int i = 0; while (tags[i]) { if (strncmp(p, tags[i], tagsLen[i]) == 0) { p += tagsLen[i]; while (*p == ' ') p++; char* num = p; while (*p >= '0' && *p <= '9') p++; if (*p != 0) { *p = 0; p++; } mem[i] = atoll(num); numFound++; break; } i++; } while (*p && *p != '\n') { p++; } if (*p) p++; } } static uint64_t get_zram_mem_used() { #define ZRAM_SYSFS "/sys/block/zram0/" FILE *f = fopen(ZRAM_SYSFS "mm_stat", "r"); if (f) { uint64_t mem_used_total = 0; int matched = fscanf(f, "%*d %*d %" SCNu64 " %*d %*d %*d %*d", &mem_used_total); if (matched != 1) fprintf(stderr, "warning: failed to parse " ZRAM_SYSFS "mm_stat\n"); fclose(f); return mem_used_total; } f = fopen(ZRAM_SYSFS "mem_used_total", "r"); if (f) { uint64_t mem_used_total = 0; int matched = fscanf(f, "%" SCNu64, &mem_used_total); if (matched != 1) fprintf(stderr, "warning: failed to parse " ZRAM_SYSFS "mem_used_total\n"); fclose(f); return mem_used_total; } return 0; } int main(int argc, char *argv[]) { pm_kernel_t *ker; pm_process_t *proc; pid_t *pids; size_t num_procs; uint64_t total_pss; uint64_t total_uss; uint64_t total_swap; uint64_t total_pswap; uint64_t total_uswap; uint64_t total_zswap; int error; bool has_swap = false, has_zram = false; uint64_t required_flags = 0; uint64_t flags_mask = 0; int arg; size_t i; enum { WS_OFF, WS_ONLY, WS_RESET, } ws; uint64_t mem[MEMINFO_COUNT] = { }; pm_proportional_swap_t *p_swap; float zram_cr = 0.0; signal(SIGPIPE, SIG_IGN); compfn = &sort_by_pss; order = -1; ws = WS_OFF; bool oomadj = false; for (arg = 1; arg < argc; arg++) { if (!strcmp(argv[arg], "-v")) { compfn = &sort_by_vss; continue; } if (!strcmp(argv[arg], "-r")) { compfn = &sort_by_rss; continue; } if (!strcmp(argv[arg], "-p")) { compfn = &sort_by_pss; continue; } if (!strcmp(argv[arg], "-u")) { compfn = &sort_by_uss; continue; } if (!strcmp(argv[arg], "-s")) { compfn = &sort_by_swap; continue; } if (!strcmp(argv[arg], "-o")) { compfn = &sort_by_oomadj; oomadj = true; continue; } if (!strcmp(argv[arg], "-c")) { required_flags = 0; flags_mask = KPF_SWAPBACKED; continue; } if (!strcmp(argv[arg], "-C")) { required_flags = flags_mask = KPF_SWAPBACKED; continue; } if (!strcmp(argv[arg], "-k")) { required_flags = flags_mask = KPF_KSM; continue; } if (!strcmp(argv[arg], "-w")) { ws = WS_ONLY; continue; } if (!strcmp(argv[arg], "-W")) { ws = WS_RESET; continue; } if (!strcmp(argv[arg], "-R")) { order *= -1; continue; } if (!strcmp(argv[arg], "-h")) { usage(argv[0]); exit(0); } fprintf(stderr, "Invalid argument \"%s\".\n", argv[arg]); usage(argv[0]); exit(EXIT_FAILURE); } get_mem_info(mem); p_swap = pm_memusage_pswap_create(mem[MEMINFO_SWAP_TOTAL] * 1024); error = pm_kernel_create(&ker); if (error) { fprintf(stderr, "Error creating kernel interface -- " "does this kernel have pagemap?\n"); exit(EXIT_FAILURE); } error = pm_kernel_pids(ker, &pids, &num_procs); if (error) { fprintf(stderr, "Error listing processes.\n"); exit(EXIT_FAILURE); } std::vector<proc_info> procs(num_procs); for (i = 0; i < num_procs; i++) { procs[i].pid = pids[i]; procs[i].oomadj = getoomadj(pids[i]); pm_memusage_zero(&procs[i].usage); pm_memusage_pswap_init_handle(&procs[i].usage, p_swap); error = pm_process_create(ker, pids[i], &proc); if (error) { fprintf(stderr, "warning: could not create process interface for %d\n", pids[i]); continue; } switch (ws) { case WS_OFF: error = pm_process_usage_flags(proc, &procs[i].usage, flags_mask, required_flags); break; case WS_ONLY: error = pm_process_workingset(proc, &procs[i].usage, 0); break; case WS_RESET: error = pm_process_workingset(proc, NULL, 1); break; } if (error) { fprintf(stderr, "warning: could not read usage for %d\n", pids[i]); } if (ws != WS_RESET && procs[i].usage.swap) { has_swap = true; } pm_process_destroy(proc); } free(pids); if (ws == WS_RESET) exit(0); procs.erase(std::remove_if(procs.begin(), procs.end(), [](auto proc){ return proc.usage.vss == 0; }), procs.end()); qsort(procs.data(), procs.size(), sizeof(procs[0]), compfn); if (has_swap) { uint64_t zram_mem_used = get_zram_mem_used(); if (zram_mem_used) { mem[MEMINFO_ZRAM_TOTAL] = zram_mem_used/1024; zram_cr = (float) mem[MEMINFO_ZRAM_TOTAL] / (mem[MEMINFO_SWAP_TOTAL] - mem[MEMINFO_SWAP_FREE]); has_zram = true; } } printf("%5s ", "PID"); if (oomadj) { printf("%5s ", "oom"); } if (ws) { printf("%7s %7s %7s ", "WRss", "WPss", "WUss"); if (has_swap) { printf("%7s %7s %7s ", "WSwap", "WPSwap", "WUSwap"); if (has_zram) { printf("%7s ", "WZSwap"); } } } else { printf("%8s %7s %7s %7s ", "Vss", "Rss", "Pss", "Uss"); if (has_swap) { printf("%7s %7s %7s ", "Swap", "PSwap", "USwap"); if (has_zram) { printf("%7s ", "ZSwap"); } } } printf("%s\n", "cmdline"); total_pss = 0; total_uss = 0; total_swap = 0; total_pswap = 0; total_uswap = 0; total_zswap = 0; std::vector<uint64_t> lmk_minfree; std::vector<int> lmk_adj; if (oomadj) { getminfree(&lmk_minfree, &lmk_adj); } auto lmk_minfree_it = lmk_minfree.cbegin(); auto lmk_adj_it = lmk_adj.cbegin(); auto print_oomadj_totals = [&](int adj){ for (; lmk_adj_it != lmk_adj.cend() && lmk_minfree_it != lmk_minfree.cend() && adj > *lmk_adj_it; lmk_adj_it++, lmk_minfree_it++) { // Print the cumulative total line printf("%5s ", ""); // pid printf("%5s ", ""); // oomadj if (ws) { printf("%7s %6" PRIu64 "K %6" PRIu64 "K ", "", total_pss / 1024, total_uss / 1024); } else { printf("%8s %7s %6" PRIu64 "K %6" PRIu64 "K ", "", "", total_pss / 1024, total_uss / 1024); } if (has_swap) { printf("%6" PRIu64 "K ", total_swap / 1024); printf("%6" PRIu64 "K ", total_pswap / 1024); printf("%6" PRIu64 "K ", total_uswap / 1024); if (has_zram) { printf("%6" PRIu64 "K ", total_zswap / 1024); } } printf("TOTAL for oomadj < %d (%6" PRIu64 "K)\n", *lmk_adj_it, *lmk_minfree_it / 1024); } }; for (auto& proc: procs) { if (oomadj) { print_oomadj_totals(proc.oomadj); } std::string cmdline = getprocname(proc.pid); total_pss += proc.usage.pss; total_uss += proc.usage.uss; total_swap += proc.usage.swap; printf("%5d ", proc.pid); if (oomadj) { printf("%5d ", proc.oomadj); } if (ws) { printf("%6zuK %6zuK %6zuK ", proc.usage.rss / 1024, proc.usage.pss / 1024, proc.usage.uss / 1024 ); } else { printf("%7zuK %6zuK %6zuK %6zuK ", proc.usage.vss / 1024, proc.usage.rss / 1024, proc.usage.pss / 1024, proc.usage.uss / 1024 ); } if (has_swap) { pm_swapusage_t su; pm_memusage_pswap_get_usage(&proc.usage, &su); printf("%6zuK ", proc.usage.swap / 1024); printf("%6zuK ", su.proportional / 1024); printf("%6zuK ", su.unique / 1024); total_pswap += su.proportional; total_uswap += su.unique; pm_memusage_pswap_free(&proc.usage); if (has_zram) { size_t zpswap = su.proportional * zram_cr; printf("%6zuK ", zpswap / 1024); total_zswap += zpswap; } } printf("%s\n", cmdline.c_str()); } pm_memusage_pswap_destroy(p_swap); if (oomadj) { print_oomadj_totals(INT_MAX); } // Print the separator line printf("%5s ", ""); if (oomadj) { printf("%5s ", ""); } if (ws) { printf("%7s %7s %7s ", "", "------", "------"); } else { printf("%8s %7s %7s %7s ", "", "", "------", "------"); } if (has_swap) { printf("%7s %7s %7s ", "------", "------", "------"); if (has_zram) { printf("%7s ", "------"); } } printf("%s\n", "------"); // Print the total line printf("%5s ", ""); if (oomadj) { printf("%5s ", ""); } if (ws) { printf("%7s %6" PRIu64 "K %6" PRIu64 "K ", "", total_pss / 1024, total_uss / 1024); } else { printf("%8s %7s %6" PRIu64 "K %6" PRIu64 "K ", "", "", total_pss / 1024, total_uss / 1024); } if (has_swap) { printf("%6" PRIu64 "K ", total_swap / 1024); printf("%6" PRIu64 "K ", total_pswap / 1024); printf("%6" PRIu64 "K ", total_uswap / 1024); if (has_zram) { printf("%6" PRIu64 "K ", total_zswap / 1024); } } printf("TOTAL\n"); printf("\n"); if (has_swap) { printf("ZRAM: %" PRIu64 "K physical used for %" PRIu64 "K in swap " "(%" PRIu64 "K total swap)\n", mem[MEMINFO_ZRAM_TOTAL], (mem[MEMINFO_SWAP_TOTAL] - mem[MEMINFO_SWAP_FREE]), mem[MEMINFO_SWAP_TOTAL]); } printf(" RAM: %" PRIu64 "K total, %" PRIu64 "K free, %" PRIu64 "K buffers, " "%" PRIu64 "K cached, %" PRIu64 "K shmem, %" PRIu64 "K slab\n", mem[MEMINFO_TOTAL], mem[MEMINFO_FREE], mem[MEMINFO_BUFFERS], mem[MEMINFO_CACHED], mem[MEMINFO_SHMEM], mem[MEMINFO_SLAB]); return 0; } static void usage(char *myname) { fprintf(stderr, "Usage: %s [ -W ] [ -v | -r | -p | -u | -s | -h ]\n" " -v Sort by VSS.\n" " -r Sort by RSS.\n" " -p Sort by PSS.\n" " -u Sort by USS.\n" " -s Sort by swap.\n" " (Default sort order is PSS.)\n" " -R Reverse sort order (default is descending).\n" " -c Only show cached (storage backed) pages\n" " -C Only show non-cached (ram/swap backed) pages\n" " -k Only show pages collapsed by KSM\n" " -w Display statistics for working set only.\n" " -W Reset working set of all processes.\n" " -o Show and sort by oom score against lowmemorykiller thresholds.\n" " -h Display this help screen.\n", myname); } // Get the process name for a given PID. static std::string getprocname(pid_t pid) { std::string filename = android::base::StringPrintf("/proc/%d/cmdline", pid); std::string procname; if (!android::base::ReadFileToString(filename, &procname)) { // The process went away before we could read its process name. procname = "<unknown>"; } return procname; } static int getoomadj(pid_t pid) { std::string filename = android::base::StringPrintf("/proc/%d/oom_score_adj", pid); std::string oomadj; if (!android::base::ReadFileToString(filename, &oomadj)) { return -1001; } return strtol(oomadj.c_str(), NULL, 10); } static bool getminfree(std::vector<uint64_t>* minfree, std::vector<int>* adj) { std::string minfree_str; std::string adj_str; if (!android::base::ReadFileToString("/sys/module/lowmemorykiller/parameters/minfree", &minfree_str)) { return false; } if (!android::base::ReadFileToString("/sys/module/lowmemorykiller/parameters/adj", &adj_str)) { return false; } std::vector<std::string> minfree_vec = android::base::Split(minfree_str, ","); std::vector<std::string> adj_vec = android::base::Split(adj_str, ","); minfree->clear(); minfree->resize(minfree_vec.size()); adj->clear(); adj->resize(adj_vec.size()); std::transform(minfree_vec.begin(), minfree_vec.end(), minfree->begin(), [](const std::string& s) -> uint64_t { return strtoull(s.c_str(), NULL, 10) * PAGE_SIZE; }); std::transform(adj_vec.begin(), adj_vec.end(), adj->begin(), [](const std::string& s) -> int { return strtol(s.c_str(), NULL, 10); }); return true; } static int numcmp(uint64_t a, uint64_t b) { if (a < b) return -1; if (a > b) return 1; return 0; } static int snumcmp(int64_t a, int64_t b) { if (a < b) return -1; if (a > b) return 1; return 0; } #define create_sort(field, compfn) \ static int sort_by_ ## field (const void *a, const void *b) { \ return order * compfn( \ ((struct proc_info*)(a))->usage.field, \ ((struct proc_info*)(b))->usage.field \ ); \ } create_sort(vss, numcmp) create_sort(rss, numcmp) create_sort(pss, numcmp) create_sort(uss, numcmp) create_sort(swap, numcmp) static int sort_by_oomadj (const void *a, const void *b) { // Negative oomadj is higher priority, reverse the sort order return -1 * order * snumcmp( ((struct proc_info*)a)->oomadj, ((struct proc_info*)b)->oomadj ); }