// SPDX-License-Identifier: GPL-2.0 #include #include #include #include #include #include #include #include #include #include "../kselftest.h" #include "../../../../include/vdso/time64.h" #define KSM_SYSFS_PATH "/sys/kernel/mm/ksm/" #define KSM_FP(s) (KSM_SYSFS_PATH s) #define KSM_SCAN_LIMIT_SEC_DEFAULT 120 #define KSM_PAGE_COUNT_DEFAULT 10l #define KSM_PROT_STR_DEFAULT "rw" #define KSM_USE_ZERO_PAGES_DEFAULT false #define KSM_MERGE_ACROSS_NODES_DEFAULT true #define MB (1ul << 20) #define PAGE_SHIFT 12 #define HPAGE_SHIFT 21 #define PAGE_SIZE (1 << PAGE_SHIFT) #define HPAGE_SIZE (1 << HPAGE_SHIFT) #define PAGEMAP_PRESENT(ent) (((ent) & (1ull << 63)) != 0) #define PAGEMAP_PFN(ent) ((ent) & ((1ull << 55) - 1)) struct ksm_sysfs { unsigned long max_page_sharing; unsigned long merge_across_nodes; unsigned long pages_to_scan; unsigned long run; unsigned long sleep_millisecs; unsigned long stable_node_chains_prune_millisecs; unsigned long use_zero_pages; }; enum ksm_test_name { CHECK_KSM_MERGE, CHECK_KSM_UNMERGE, CHECK_KSM_ZERO_PAGE_MERGE, CHECK_KSM_NUMA_MERGE, KSM_MERGE_TIME, KSM_MERGE_TIME_HUGE_PAGES, KSM_COW_TIME }; static int ksm_write_sysfs(const char *file_path, unsigned long val) { FILE *f = fopen(file_path, "w"); if (!f) { fprintf(stderr, "f %s\n", file_path); perror("fopen"); return 1; } if (fprintf(f, "%lu", val) < 0) { perror("fprintf"); return 1; } fclose(f); return 0; } static int ksm_read_sysfs(const char *file_path, unsigned long *val) { FILE *f = fopen(file_path, "r"); if (!f) { fprintf(stderr, "f %s\n", file_path); perror("fopen"); return 1; } if (fscanf(f, "%lu", val) != 1) { perror("fscanf"); return 1; } fclose(f); return 0; } static int str_to_prot(char *prot_str) { int prot = 0; if ((strchr(prot_str, 'r')) != NULL) prot |= PROT_READ; if ((strchr(prot_str, 'w')) != NULL) prot |= PROT_WRITE; if ((strchr(prot_str, 'x')) != NULL) prot |= PROT_EXEC; return prot; } static void print_help(void) { printf("usage: ksm_tests [-h] [-a prot] [-p page_count] [-l timeout]\n" "[-z use_zero_pages] [-m merge_across_nodes] [-s size]\n"); printf("Supported :\n" " -M (page merging)\n" " -Z (zero pages merging)\n" " -N (merging of pages in different NUMA nodes)\n" " -U (page unmerging)\n" " -P evaluate merging time and speed.\n" " For this test, the size of duplicated memory area (in MiB)\n" " must be provided using -s option\n" " -H evaluate merging time and speed of area allocated mostly with huge pages\n" " For this test, the size of duplicated memory area (in MiB)\n" " must be provided using -s option\n" " -C evaluate the time required to break COW of merged pages.\n\n"); printf(" -a: specify the access protections of pages.\n" " must be of the form [rwx].\n" " Default: %s\n", KSM_PROT_STR_DEFAULT); printf(" -p: specify the number of pages to test.\n" " Default: %ld\n", KSM_PAGE_COUNT_DEFAULT); printf(" -l: limit the maximum running time (in seconds) for a test.\n" " Default: %d seconds\n", KSM_SCAN_LIMIT_SEC_DEFAULT); printf(" -z: change use_zero_pages tunable\n" " Default: %d\n", KSM_USE_ZERO_PAGES_DEFAULT); printf(" -m: change merge_across_nodes tunable\n" " Default: %d\n", KSM_MERGE_ACROSS_NODES_DEFAULT); printf(" -s: the size of duplicated memory area (in MiB)\n"); exit(0); } static void *allocate_memory(void *ptr, int prot, int mapping, char data, size_t map_size) { void *map_ptr = mmap(ptr, map_size, PROT_WRITE, mapping, -1, 0); if (!map_ptr) { perror("mmap"); return NULL; } memset(map_ptr, data, map_size); if (mprotect(map_ptr, map_size, prot)) { perror("mprotect"); munmap(map_ptr, map_size); return NULL; } return map_ptr; } static int ksm_do_scan(int scan_count, struct timespec start_time, int timeout) { struct timespec cur_time; unsigned long cur_scan, init_scan; if (ksm_read_sysfs(KSM_FP("full_scans"), &init_scan)) return 1; cur_scan = init_scan; while (cur_scan < init_scan + scan_count) { if (ksm_read_sysfs(KSM_FP("full_scans"), &cur_scan)) return 1; if (clock_gettime(CLOCK_MONOTONIC_RAW, &cur_time)) { perror("clock_gettime"); return 1; } if ((cur_time.tv_sec - start_time.tv_sec) > timeout) { printf("Scan time limit exceeded\n"); return 1; } } return 0; } static int ksm_merge_pages(void *addr, size_t size, struct timespec start_time, int timeout) { if (madvise(addr, size, MADV_MERGEABLE)) { perror("madvise"); return 1; } if (ksm_write_sysfs(KSM_FP("run"), 1)) return 1; /* Since merging occurs only after 2 scans, make sure to get at least 2 full scans */ if (ksm_do_scan(2, start_time, timeout)) return 1; return 0; } static bool assert_ksm_pages_count(long dupl_page_count) { unsigned long max_page_sharing, pages_sharing, pages_shared; if (ksm_read_sysfs(KSM_FP("pages_shared"), &pages_shared) || ksm_read_sysfs(KSM_FP("pages_sharing"), &pages_sharing) || ksm_read_sysfs(KSM_FP("max_page_sharing"), &max_page_sharing)) return false; /* * Since there must be at least 2 pages for merging and 1 page can be * shared with the limited number of pages (max_page_sharing), sometimes * there are 'leftover' pages that cannot be merged. For example, if there * are 11 pages and max_page_sharing = 10, then only 10 pages will be * merged and the 11th page won't be affected. As a result, when the number * of duplicate pages is divided by max_page_sharing and the remainder is 1, * pages_shared and pages_sharing values will be equal between dupl_page_count * and dupl_page_count - 1. */ if (dupl_page_count % max_page_sharing == 1 || dupl_page_count % max_page_sharing == 0) { if (pages_shared == dupl_page_count / max_page_sharing && pages_sharing == pages_shared * (max_page_sharing - 1)) return true; } else { if (pages_shared == (dupl_page_count / max_page_sharing + 1) && pages_sharing == dupl_page_count - pages_shared) return true; } return false; } static int ksm_save_def(struct ksm_sysfs *ksm_sysfs) { if (ksm_read_sysfs(KSM_FP("max_page_sharing"), &ksm_sysfs->max_page_sharing) || ksm_read_sysfs(KSM_FP("merge_across_nodes"), &ksm_sysfs->merge_across_nodes) || ksm_read_sysfs(KSM_FP("sleep_millisecs"), &ksm_sysfs->sleep_millisecs) || ksm_read_sysfs(KSM_FP("pages_to_scan"), &ksm_sysfs->pages_to_scan) || ksm_read_sysfs(KSM_FP("run"), &ksm_sysfs->run) || ksm_read_sysfs(KSM_FP("stable_node_chains_prune_millisecs"), &ksm_sysfs->stable_node_chains_prune_millisecs) || ksm_read_sysfs(KSM_FP("use_zero_pages"), &ksm_sysfs->use_zero_pages)) return 1; return 0; } static int ksm_restore(struct ksm_sysfs *ksm_sysfs) { if (ksm_write_sysfs(KSM_FP("max_page_sharing"), ksm_sysfs->max_page_sharing) || ksm_write_sysfs(KSM_FP("merge_across_nodes"), ksm_sysfs->merge_across_nodes) || ksm_write_sysfs(KSM_FP("pages_to_scan"), ksm_sysfs->pages_to_scan) || ksm_write_sysfs(KSM_FP("run"), ksm_sysfs->run) || ksm_write_sysfs(KSM_FP("sleep_millisecs"), ksm_sysfs->sleep_millisecs) || ksm_write_sysfs(KSM_FP("stable_node_chains_prune_millisecs"), ksm_sysfs->stable_node_chains_prune_millisecs) || ksm_write_sysfs(KSM_FP("use_zero_pages"), ksm_sysfs->use_zero_pages)) return 1; return 0; } static int check_ksm_merge(int mapping, int prot, long page_count, int timeout, size_t page_size) { void *map_ptr; struct timespec start_time; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); return KSFT_FAIL; } /* fill pages with the same data and merge them */ map_ptr = allocate_memory(NULL, prot, mapping, '*', page_size * page_count); if (!map_ptr) return KSFT_FAIL; if (ksm_merge_pages(map_ptr, page_size * page_count, start_time, timeout)) goto err_out; /* verify that the right number of pages are merged */ if (assert_ksm_pages_count(page_count)) { printf("OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_PASS; } err_out: printf("Not OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_FAIL; } static int check_ksm_unmerge(int mapping, int prot, int timeout, size_t page_size) { void *map_ptr; struct timespec start_time; int page_count = 2; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); return KSFT_FAIL; } /* fill pages with the same data and merge them */ map_ptr = allocate_memory(NULL, prot, mapping, '*', page_size * page_count); if (!map_ptr) return KSFT_FAIL; if (ksm_merge_pages(map_ptr, page_size * page_count, start_time, timeout)) goto err_out; /* change 1 byte in each of the 2 pages -- KSM must automatically unmerge them */ memset(map_ptr, '-', 1); memset(map_ptr + page_size, '+', 1); /* get at least 1 scan, so KSM can detect that the pages were modified */ if (ksm_do_scan(1, start_time, timeout)) goto err_out; /* check that unmerging was successful and 0 pages are currently merged */ if (assert_ksm_pages_count(0)) { printf("OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_PASS; } err_out: printf("Not OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_FAIL; } static int check_ksm_zero_page_merge(int mapping, int prot, long page_count, int timeout, bool use_zero_pages, size_t page_size) { void *map_ptr; struct timespec start_time; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); return KSFT_FAIL; } if (ksm_write_sysfs(KSM_FP("use_zero_pages"), use_zero_pages)) return KSFT_FAIL; /* fill pages with zero and try to merge them */ map_ptr = allocate_memory(NULL, prot, mapping, 0, page_size * page_count); if (!map_ptr) return KSFT_FAIL; if (ksm_merge_pages(map_ptr, page_size * page_count, start_time, timeout)) goto err_out; /* * verify that the right number of pages are merged: * 1) if use_zero_pages is set to 1, empty pages are merged * with the kernel zero page instead of with each other; * 2) if use_zero_pages is set to 0, empty pages are not treated specially * and merged as usual. */ if (use_zero_pages && !assert_ksm_pages_count(0)) goto err_out; else if (!use_zero_pages && !assert_ksm_pages_count(page_count)) goto err_out; printf("OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_PASS; err_out: printf("Not OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_FAIL; } static int get_next_mem_node(int node) { long node_size; int mem_node = 0; int i, max_node = numa_max_node(); for (i = node + 1; i <= max_node + node; i++) { mem_node = i % (max_node + 1); node_size = numa_node_size(mem_node, NULL); if (node_size > 0) break; } return mem_node; } static int get_first_mem_node(void) { return get_next_mem_node(numa_max_node()); } static int check_ksm_numa_merge(int mapping, int prot, int timeout, bool merge_across_nodes, size_t page_size) { void *numa1_map_ptr, *numa2_map_ptr; struct timespec start_time; int page_count = 2; int first_node; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); return KSFT_FAIL; } if (numa_available() < 0) { perror("NUMA support not enabled"); return KSFT_SKIP; } if (numa_num_configured_nodes() <= 1) { printf("At least 2 NUMA nodes must be available\n"); return KSFT_SKIP; } if (ksm_write_sysfs(KSM_FP("merge_across_nodes"), merge_across_nodes)) return KSFT_FAIL; /* allocate 2 pages in 2 different NUMA nodes and fill them with the same data */ first_node = get_first_mem_node(); numa1_map_ptr = numa_alloc_onnode(page_size, first_node); numa2_map_ptr = numa_alloc_onnode(page_size, get_next_mem_node(first_node)); if (!numa1_map_ptr || !numa2_map_ptr) { perror("numa_alloc_onnode"); return KSFT_FAIL; } memset(numa1_map_ptr, '*', page_size); memset(numa2_map_ptr, '*', page_size); /* try to merge the pages */ if (ksm_merge_pages(numa1_map_ptr, page_size, start_time, timeout) || ksm_merge_pages(numa2_map_ptr, page_size, start_time, timeout)) goto err_out; /* * verify that the right number of pages are merged: * 1) if merge_across_nodes was enabled, 2 duplicate pages will be merged; * 2) if merge_across_nodes = 0, there must be 0 merged pages, since there is * only 1 unique page in each node and they can't be shared. */ if (merge_across_nodes && !assert_ksm_pages_count(page_count)) goto err_out; else if (!merge_across_nodes && !assert_ksm_pages_count(0)) goto err_out; numa_free(numa1_map_ptr, page_size); numa_free(numa2_map_ptr, page_size); printf("OK\n"); return KSFT_PASS; err_out: numa_free(numa1_map_ptr, page_size); numa_free(numa2_map_ptr, page_size); printf("Not OK\n"); return KSFT_FAIL; } int64_t allocate_transhuge(void *ptr, int pagemap_fd) { uint64_t ent[2]; /* drop pmd */ if (mmap(ptr, HPAGE_SIZE, PROT_READ | PROT_WRITE, MAP_FIXED | MAP_ANONYMOUS | MAP_NORESERVE | MAP_PRIVATE, -1, 0) != ptr) errx(2, "mmap transhuge"); if (madvise(ptr, HPAGE_SIZE, MADV_HUGEPAGE)) err(2, "MADV_HUGEPAGE"); /* allocate transparent huge page */ *(volatile void **)ptr = ptr; if (pread(pagemap_fd, ent, sizeof(ent), (uintptr_t)ptr >> (PAGE_SHIFT - 3)) != sizeof(ent)) err(2, "read pagemap"); if (PAGEMAP_PRESENT(ent[0]) && PAGEMAP_PRESENT(ent[1]) && PAGEMAP_PFN(ent[0]) + 1 == PAGEMAP_PFN(ent[1]) && !(PAGEMAP_PFN(ent[0]) & ((1 << (HPAGE_SHIFT - PAGE_SHIFT)) - 1))) return PAGEMAP_PFN(ent[0]); return -1; } static int ksm_merge_hugepages_time(int mapping, int prot, int timeout, size_t map_size) { void *map_ptr, *map_ptr_orig; struct timespec start_time, end_time; unsigned long scan_time_ns; int pagemap_fd, n_normal_pages, n_huge_pages; map_size *= MB; size_t len = map_size; len -= len % HPAGE_SIZE; map_ptr_orig = mmap(NULL, len + HPAGE_SIZE, PROT_READ | PROT_WRITE, MAP_ANONYMOUS | MAP_NORESERVE | MAP_PRIVATE, -1, 0); map_ptr = map_ptr_orig + HPAGE_SIZE - (uintptr_t)map_ptr_orig % HPAGE_SIZE; if (map_ptr_orig == MAP_FAILED) err(2, "initial mmap"); if (madvise(map_ptr, len + HPAGE_SIZE, MADV_HUGEPAGE)) err(2, "MADV_HUGEPAGE"); pagemap_fd = open("/proc/self/pagemap", O_RDONLY); if (pagemap_fd < 0) err(2, "open pagemap"); n_normal_pages = 0; n_huge_pages = 0; for (void *p = map_ptr; p < map_ptr + len; p += HPAGE_SIZE) { if (allocate_transhuge(p, pagemap_fd) < 0) n_normal_pages++; else n_huge_pages++; } printf("Number of normal pages: %d\n", n_normal_pages); printf("Number of huge pages: %d\n", n_huge_pages); memset(map_ptr, '*', len); if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); goto err_out; } if (ksm_merge_pages(map_ptr, map_size, start_time, timeout)) goto err_out; if (clock_gettime(CLOCK_MONOTONIC_RAW, &end_time)) { perror("clock_gettime"); goto err_out; } scan_time_ns = (end_time.tv_sec - start_time.tv_sec) * NSEC_PER_SEC + (end_time.tv_nsec - start_time.tv_nsec); printf("Total size: %lu MiB\n", map_size / MB); printf("Total time: %ld.%09ld s\n", scan_time_ns / NSEC_PER_SEC, scan_time_ns % NSEC_PER_SEC); printf("Average speed: %.3f MiB/s\n", (map_size / MB) / ((double)scan_time_ns / NSEC_PER_SEC)); munmap(map_ptr_orig, len + HPAGE_SIZE); return KSFT_PASS; err_out: printf("Not OK\n"); munmap(map_ptr_orig, len + HPAGE_SIZE); return KSFT_FAIL; } static int ksm_merge_time(int mapping, int prot, int timeout, size_t map_size) { void *map_ptr; struct timespec start_time, end_time; unsigned long scan_time_ns; map_size *= MB; map_ptr = allocate_memory(NULL, prot, mapping, '*', map_size); if (!map_ptr) return KSFT_FAIL; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); goto err_out; } if (ksm_merge_pages(map_ptr, map_size, start_time, timeout)) goto err_out; if (clock_gettime(CLOCK_MONOTONIC_RAW, &end_time)) { perror("clock_gettime"); goto err_out; } scan_time_ns = (end_time.tv_sec - start_time.tv_sec) * NSEC_PER_SEC + (end_time.tv_nsec - start_time.tv_nsec); printf("Total size: %lu MiB\n", map_size / MB); printf("Total time: %ld.%09ld s\n", scan_time_ns / NSEC_PER_SEC, scan_time_ns % NSEC_PER_SEC); printf("Average speed: %.3f MiB/s\n", (map_size / MB) / ((double)scan_time_ns / NSEC_PER_SEC)); munmap(map_ptr, map_size); return KSFT_PASS; err_out: printf("Not OK\n"); munmap(map_ptr, map_size); return KSFT_FAIL; } static int ksm_cow_time(int mapping, int prot, int timeout, size_t page_size) { void *map_ptr; struct timespec start_time, end_time; unsigned long cow_time_ns; /* page_count must be less than 2*page_size */ size_t page_count = 4000; map_ptr = allocate_memory(NULL, prot, mapping, '*', page_size * page_count); if (!map_ptr) return KSFT_FAIL; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); return KSFT_FAIL; } for (size_t i = 0; i < page_count - 1; i = i + 2) memset(map_ptr + page_size * i, '-', 1); if (clock_gettime(CLOCK_MONOTONIC_RAW, &end_time)) { perror("clock_gettime"); return KSFT_FAIL; } cow_time_ns = (end_time.tv_sec - start_time.tv_sec) * NSEC_PER_SEC + (end_time.tv_nsec - start_time.tv_nsec); printf("Total size: %lu MiB\n\n", (page_size * page_count) / MB); printf("Not merged pages:\n"); printf("Total time: %ld.%09ld s\n", cow_time_ns / NSEC_PER_SEC, cow_time_ns % NSEC_PER_SEC); printf("Average speed: %.3f MiB/s\n\n", ((page_size * (page_count / 2)) / MB) / ((double)cow_time_ns / NSEC_PER_SEC)); /* Create 2000 pairs of duplicate pages */ for (size_t i = 0; i < page_count - 1; i = i + 2) { memset(map_ptr + page_size * i, '+', i / 2 + 1); memset(map_ptr + page_size * (i + 1), '+', i / 2 + 1); } if (ksm_merge_pages(map_ptr, page_size * page_count, start_time, timeout)) goto err_out; if (clock_gettime(CLOCK_MONOTONIC_RAW, &start_time)) { perror("clock_gettime"); goto err_out; } for (size_t i = 0; i < page_count - 1; i = i + 2) memset(map_ptr + page_size * i, '-', 1); if (clock_gettime(CLOCK_MONOTONIC_RAW, &end_time)) { perror("clock_gettime"); goto err_out; } cow_time_ns = (end_time.tv_sec - start_time.tv_sec) * NSEC_PER_SEC + (end_time.tv_nsec - start_time.tv_nsec); printf("Merged pages:\n"); printf("Total time: %ld.%09ld s\n", cow_time_ns / NSEC_PER_SEC, cow_time_ns % NSEC_PER_SEC); printf("Average speed: %.3f MiB/s\n", ((page_size * (page_count / 2)) / MB) / ((double)cow_time_ns / NSEC_PER_SEC)); munmap(map_ptr, page_size * page_count); return KSFT_PASS; err_out: printf("Not OK\n"); munmap(map_ptr, page_size * page_count); return KSFT_FAIL; } int main(int argc, char *argv[]) { int ret, opt; int prot = 0; int ksm_scan_limit_sec = KSM_SCAN_LIMIT_SEC_DEFAULT; long page_count = KSM_PAGE_COUNT_DEFAULT; size_t page_size = sysconf(_SC_PAGESIZE); struct ksm_sysfs ksm_sysfs_old; int test_name = CHECK_KSM_MERGE; bool use_zero_pages = KSM_USE_ZERO_PAGES_DEFAULT; bool merge_across_nodes = KSM_MERGE_ACROSS_NODES_DEFAULT; long size_MB = 0; while ((opt = getopt(argc, argv, "ha:p:l:z:m:s:MUZNPCH")) != -1) { switch (opt) { case 'a': prot = str_to_prot(optarg); break; case 'p': page_count = atol(optarg); if (page_count <= 0) { printf("The number of pages must be greater than 0\n"); return KSFT_FAIL; } break; case 'l': ksm_scan_limit_sec = atoi(optarg); if (ksm_scan_limit_sec <= 0) { printf("Timeout value must be greater than 0\n"); return KSFT_FAIL; } break; case 'h': print_help(); break; case 'z': if (strcmp(optarg, "0") == 0) use_zero_pages = 0; else use_zero_pages = 1; break; case 'm': if (strcmp(optarg, "0") == 0) merge_across_nodes = 0; else merge_across_nodes = 1; break; case 's': size_MB = atoi(optarg); if (size_MB <= 0) { printf("Size must be greater than 0\n"); return KSFT_FAIL; } case 'M': break; case 'U': test_name = CHECK_KSM_UNMERGE; break; case 'Z': test_name = CHECK_KSM_ZERO_PAGE_MERGE; break; case 'N': test_name = CHECK_KSM_NUMA_MERGE; break; case 'P': test_name = KSM_MERGE_TIME; break; case 'H': test_name = KSM_MERGE_TIME_HUGE_PAGES; break; case 'C': test_name = KSM_COW_TIME; break; default: return KSFT_FAIL; } } if (prot == 0) prot = str_to_prot(KSM_PROT_STR_DEFAULT); if (access(KSM_SYSFS_PATH, F_OK)) { printf("Config KSM not enabled\n"); return KSFT_SKIP; } if (ksm_save_def(&ksm_sysfs_old)) { printf("Cannot save default tunables\n"); return KSFT_FAIL; } if (ksm_write_sysfs(KSM_FP("run"), 2) || ksm_write_sysfs(KSM_FP("sleep_millisecs"), 0) || ksm_write_sysfs(KSM_FP("merge_across_nodes"), 1) || ksm_write_sysfs(KSM_FP("pages_to_scan"), page_count)) return KSFT_FAIL; switch (test_name) { case CHECK_KSM_MERGE: ret = check_ksm_merge(MAP_PRIVATE | MAP_ANONYMOUS, prot, page_count, ksm_scan_limit_sec, page_size); break; case CHECK_KSM_UNMERGE: ret = check_ksm_unmerge(MAP_PRIVATE | MAP_ANONYMOUS, prot, ksm_scan_limit_sec, page_size); break; case CHECK_KSM_ZERO_PAGE_MERGE: ret = check_ksm_zero_page_merge(MAP_PRIVATE | MAP_ANONYMOUS, prot, page_count, ksm_scan_limit_sec, use_zero_pages, page_size); break; case CHECK_KSM_NUMA_MERGE: ret = check_ksm_numa_merge(MAP_PRIVATE | MAP_ANONYMOUS, prot, ksm_scan_limit_sec, merge_across_nodes, page_size); break; case KSM_MERGE_TIME: if (size_MB == 0) { printf("Option '-s' is required.\n"); return KSFT_FAIL; } ret = ksm_merge_time(MAP_PRIVATE | MAP_ANONYMOUS, prot, ksm_scan_limit_sec, size_MB); break; case KSM_MERGE_TIME_HUGE_PAGES: if (size_MB == 0) { printf("Option '-s' is required.\n"); return KSFT_FAIL; } ret = ksm_merge_hugepages_time(MAP_PRIVATE | MAP_ANONYMOUS, prot, ksm_scan_limit_sec, size_MB); break; case KSM_COW_TIME: ret = ksm_cow_time(MAP_PRIVATE | MAP_ANONYMOUS, prot, ksm_scan_limit_sec, page_size); break; } if (ksm_restore(&ksm_sysfs_old)) { printf("Cannot restore default tunables\n"); return KSFT_FAIL; } return ret; }