/* SPDX-License-Identifier: GPL-2.0 */ #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "../kselftest.h" #include "cgroup_util.h" /* * This test creates two nested cgroups with and without enabling * the memory controller. */ static int test_memcg_subtree_control(const char *root) { char *parent, *child, *parent2, *child2; int ret = KSFT_FAIL; char buf[PAGE_SIZE]; /* Create two nested cgroups with the memory controller enabled */ parent = cg_name(root, "memcg_test_0"); child = cg_name(root, "memcg_test_0/memcg_test_1"); if (!parent || !child) goto cleanup; if (cg_create(parent)) goto cleanup; if (cg_write(parent, "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_create(child)) goto cleanup; if (cg_read_strstr(child, "cgroup.controllers", "memory")) goto cleanup; /* Create two nested cgroups without enabling memory controller */ parent2 = cg_name(root, "memcg_test_1"); child2 = cg_name(root, "memcg_test_1/memcg_test_1"); if (!parent2 || !child2) goto cleanup; if (cg_create(parent2)) goto cleanup; if (cg_create(child2)) goto cleanup; if (cg_read(child2, "cgroup.controllers", buf, sizeof(buf))) goto cleanup; if (!cg_read_strstr(child2, "cgroup.controllers", "memory")) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(child); cg_destroy(parent); free(parent); free(child); cg_destroy(child2); cg_destroy(parent2); free(parent2); free(child2); return ret; } static int alloc_anon_50M_check(const char *cgroup, void *arg) { size_t size = MB(50); char *buf, *ptr; long anon, current; int ret = -1; buf = malloc(size); for (ptr = buf; ptr < buf + size; ptr += PAGE_SIZE) *ptr = 0; current = cg_read_long(cgroup, "memory.current"); if (current < size) goto cleanup; if (!values_close(size, current, 3)) goto cleanup; anon = cg_read_key_long(cgroup, "memory.stat", "anon "); if (anon < 0) goto cleanup; if (!values_close(anon, current, 3)) goto cleanup; ret = 0; cleanup: free(buf); return ret; } static int alloc_pagecache_50M_check(const char *cgroup, void *arg) { size_t size = MB(50); int ret = -1; long current, file; int fd; fd = get_temp_fd(); if (fd < 0) return -1; if (alloc_pagecache(fd, size)) goto cleanup; current = cg_read_long(cgroup, "memory.current"); if (current < size) goto cleanup; file = cg_read_key_long(cgroup, "memory.stat", "file "); if (file < 0) goto cleanup; if (!values_close(file, current, 10)) goto cleanup; ret = 0; cleanup: close(fd); return ret; } /* * This test create a memory cgroup, allocates * some anonymous memory and some pagecache * and check memory.current and some memory.stat values. */ static int test_memcg_current(const char *root) { int ret = KSFT_FAIL; long current; char *memcg; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; current = cg_read_long(memcg, "memory.current"); if (current != 0) goto cleanup; if (cg_run(memcg, alloc_anon_50M_check, NULL)) goto cleanup; if (cg_run(memcg, alloc_pagecache_50M_check, NULL)) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } static int alloc_pagecache_50M(const char *cgroup, void *arg) { int fd = (long)arg; return alloc_pagecache(fd, MB(50)); } static int alloc_pagecache_50M_noexit(const char *cgroup, void *arg) { int fd = (long)arg; int ppid = getppid(); if (alloc_pagecache(fd, MB(50))) return -1; while (getppid() == ppid) sleep(1); return 0; } static int alloc_anon_noexit(const char *cgroup, void *arg) { int ppid = getppid(); if (alloc_anon(cgroup, arg)) return -1; while (getppid() == ppid) sleep(1); return 0; } /* * Wait until processes are killed asynchronously by the OOM killer * If we exceed a timeout, fail. */ static int cg_test_proc_killed(const char *cgroup) { int limit; for (limit = 10; limit > 0; limit--) { if (cg_read_strcmp(cgroup, "cgroup.procs", "") == 0) return 0; usleep(100000); } return -1; } /* * First, this test creates the following hierarchy: * A memory.min = 50M, memory.max = 200M * A/B memory.min = 50M, memory.current = 50M * A/B/C memory.min = 75M, memory.current = 50M * A/B/D memory.min = 25M, memory.current = 50M * A/B/E memory.min = 500M, memory.current = 0 * A/B/F memory.min = 0, memory.current = 50M * * Usages are pagecache, but the test keeps a running * process in every leaf cgroup. * Then it creates A/G and creates a significant * memory pressure in it. * * A/B memory.current ~= 50M * A/B/C memory.current ~= 33M * A/B/D memory.current ~= 17M * A/B/E memory.current ~= 0 * * After that it tries to allocate more than there is * unprotected memory in A available, and checks * checks that memory.min protects pagecache even * in this case. */ static int test_memcg_min(const char *root) { int ret = KSFT_FAIL; char *parent[3] = {NULL}; char *children[4] = {NULL}; long c[4]; int i, attempts; int fd; fd = get_temp_fd(); if (fd < 0) goto cleanup; parent[0] = cg_name(root, "memcg_test_0"); if (!parent[0]) goto cleanup; parent[1] = cg_name(parent[0], "memcg_test_1"); if (!parent[1]) goto cleanup; parent[2] = cg_name(parent[0], "memcg_test_2"); if (!parent[2]) goto cleanup; if (cg_create(parent[0])) goto cleanup; if (cg_read_long(parent[0], "memory.min")) { ret = KSFT_SKIP; goto cleanup; } if (cg_write(parent[0], "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_write(parent[0], "memory.max", "200M")) goto cleanup; if (cg_write(parent[0], "memory.swap.max", "0")) goto cleanup; if (cg_create(parent[1])) goto cleanup; if (cg_write(parent[1], "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_create(parent[2])) goto cleanup; for (i = 0; i < ARRAY_SIZE(children); i++) { children[i] = cg_name_indexed(parent[1], "child_memcg", i); if (!children[i]) goto cleanup; if (cg_create(children[i])) goto cleanup; if (i == 2) continue; cg_run_nowait(children[i], alloc_pagecache_50M_noexit, (void *)(long)fd); } if (cg_write(parent[0], "memory.min", "50M")) goto cleanup; if (cg_write(parent[1], "memory.min", "50M")) goto cleanup; if (cg_write(children[0], "memory.min", "75M")) goto cleanup; if (cg_write(children[1], "memory.min", "25M")) goto cleanup; if (cg_write(children[2], "memory.min", "500M")) goto cleanup; if (cg_write(children[3], "memory.min", "0")) goto cleanup; attempts = 0; while (!values_close(cg_read_long(parent[1], "memory.current"), MB(150), 3)) { if (attempts++ > 5) break; sleep(1); } if (cg_run(parent[2], alloc_anon, (void *)MB(148))) goto cleanup; if (!values_close(cg_read_long(parent[1], "memory.current"), MB(50), 3)) goto cleanup; for (i = 0; i < ARRAY_SIZE(children); i++) c[i] = cg_read_long(children[i], "memory.current"); if (!values_close(c[0], MB(33), 10)) goto cleanup; if (!values_close(c[1], MB(17), 10)) goto cleanup; if (!values_close(c[2], 0, 1)) goto cleanup; if (!cg_run(parent[2], alloc_anon, (void *)MB(170))) goto cleanup; if (!values_close(cg_read_long(parent[1], "memory.current"), MB(50), 3)) goto cleanup; ret = KSFT_PASS; cleanup: for (i = ARRAY_SIZE(children) - 1; i >= 0; i--) { if (!children[i]) continue; cg_destroy(children[i]); free(children[i]); } for (i = ARRAY_SIZE(parent) - 1; i >= 0; i--) { if (!parent[i]) continue; cg_destroy(parent[i]); free(parent[i]); } close(fd); return ret; } /* * First, this test creates the following hierarchy: * A memory.low = 50M, memory.max = 200M * A/B memory.low = 50M, memory.current = 50M * A/B/C memory.low = 75M, memory.current = 50M * A/B/D memory.low = 25M, memory.current = 50M * A/B/E memory.low = 500M, memory.current = 0 * A/B/F memory.low = 0, memory.current = 50M * * Usages are pagecache. * Then it creates A/G an creates a significant * memory pressure in it. * * Then it checks actual memory usages and expects that: * A/B memory.current ~= 50M * A/B/ memory.current ~= 33M * A/B/D memory.current ~= 17M * A/B/E memory.current ~= 0 * * After that it tries to allocate more than there is * unprotected memory in A available, * and checks low and oom events in memory.events. */ static int test_memcg_low(const char *root) { int ret = KSFT_FAIL; char *parent[3] = {NULL}; char *children[4] = {NULL}; long low, oom; long c[4]; int i; int fd; fd = get_temp_fd(); if (fd < 0) goto cleanup; parent[0] = cg_name(root, "memcg_test_0"); if (!parent[0]) goto cleanup; parent[1] = cg_name(parent[0], "memcg_test_1"); if (!parent[1]) goto cleanup; parent[2] = cg_name(parent[0], "memcg_test_2"); if (!parent[2]) goto cleanup; if (cg_create(parent[0])) goto cleanup; if (cg_read_long(parent[0], "memory.low")) goto cleanup; if (cg_write(parent[0], "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_write(parent[0], "memory.max", "200M")) goto cleanup; if (cg_write(parent[0], "memory.swap.max", "0")) goto cleanup; if (cg_create(parent[1])) goto cleanup; if (cg_write(parent[1], "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_create(parent[2])) goto cleanup; for (i = 0; i < ARRAY_SIZE(children); i++) { children[i] = cg_name_indexed(parent[1], "child_memcg", i); if (!children[i]) goto cleanup; if (cg_create(children[i])) goto cleanup; if (i == 2) continue; if (cg_run(children[i], alloc_pagecache_50M, (void *)(long)fd)) goto cleanup; } if (cg_write(parent[0], "memory.low", "50M")) goto cleanup; if (cg_write(parent[1], "memory.low", "50M")) goto cleanup; if (cg_write(children[0], "memory.low", "75M")) goto cleanup; if (cg_write(children[1], "memory.low", "25M")) goto cleanup; if (cg_write(children[2], "memory.low", "500M")) goto cleanup; if (cg_write(children[3], "memory.low", "0")) goto cleanup; if (cg_run(parent[2], alloc_anon, (void *)MB(148))) goto cleanup; if (!values_close(cg_read_long(parent[1], "memory.current"), MB(50), 3)) goto cleanup; for (i = 0; i < ARRAY_SIZE(children); i++) c[i] = cg_read_long(children[i], "memory.current"); if (!values_close(c[0], MB(33), 10)) goto cleanup; if (!values_close(c[1], MB(17), 10)) goto cleanup; if (!values_close(c[2], 0, 1)) goto cleanup; if (cg_run(parent[2], alloc_anon, (void *)MB(166))) { fprintf(stderr, "memory.low prevents from allocating anon memory\n"); goto cleanup; } for (i = 0; i < ARRAY_SIZE(children); i++) { oom = cg_read_key_long(children[i], "memory.events", "oom "); low = cg_read_key_long(children[i], "memory.events", "low "); if (oom) goto cleanup; if (i < 2 && low <= 0) goto cleanup; if (i >= 2 && low) goto cleanup; } ret = KSFT_PASS; cleanup: for (i = ARRAY_SIZE(children) - 1; i >= 0; i--) { if (!children[i]) continue; cg_destroy(children[i]); free(children[i]); } for (i = ARRAY_SIZE(parent) - 1; i >= 0; i--) { if (!parent[i]) continue; cg_destroy(parent[i]); free(parent[i]); } close(fd); return ret; } static int alloc_pagecache_max_30M(const char *cgroup, void *arg) { size_t size = MB(50); int ret = -1; long current; int fd; fd = get_temp_fd(); if (fd < 0) return -1; if (alloc_pagecache(fd, size)) goto cleanup; current = cg_read_long(cgroup, "memory.current"); if (current <= MB(29) || current > MB(30)) goto cleanup; ret = 0; cleanup: close(fd); return ret; } /* * This test checks that memory.high limits the amount of * memory which can be consumed by either anonymous memory * or pagecache. */ static int test_memcg_high(const char *root) { int ret = KSFT_FAIL; char *memcg; long high; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; if (cg_read_strcmp(memcg, "memory.high", "max\n")) goto cleanup; if (cg_write(memcg, "memory.swap.max", "0")) goto cleanup; if (cg_write(memcg, "memory.high", "30M")) goto cleanup; if (cg_run(memcg, alloc_anon, (void *)MB(100))) goto cleanup; if (!cg_run(memcg, alloc_pagecache_50M_check, NULL)) goto cleanup; if (cg_run(memcg, alloc_pagecache_max_30M, NULL)) goto cleanup; high = cg_read_key_long(memcg, "memory.events", "high "); if (high <= 0) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } /* * This test checks that memory.max limits the amount of * memory which can be consumed by either anonymous memory * or pagecache. */ static int test_memcg_max(const char *root) { int ret = KSFT_FAIL; char *memcg; long current, max; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; if (cg_read_strcmp(memcg, "memory.max", "max\n")) goto cleanup; if (cg_write(memcg, "memory.swap.max", "0")) goto cleanup; if (cg_write(memcg, "memory.max", "30M")) goto cleanup; /* Should be killed by OOM killer */ if (!cg_run(memcg, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_run(memcg, alloc_pagecache_max_30M, NULL)) goto cleanup; current = cg_read_long(memcg, "memory.current"); if (current > MB(30) || !current) goto cleanup; max = cg_read_key_long(memcg, "memory.events", "max "); if (max <= 0) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } static int alloc_anon_50M_check_swap(const char *cgroup, void *arg) { long mem_max = (long)arg; size_t size = MB(50); char *buf, *ptr; long mem_current, swap_current; int ret = -1; buf = malloc(size); for (ptr = buf; ptr < buf + size; ptr += PAGE_SIZE) *ptr = 0; mem_current = cg_read_long(cgroup, "memory.current"); if (!mem_current || !values_close(mem_current, mem_max, 3)) goto cleanup; swap_current = cg_read_long(cgroup, "memory.swap.current"); if (!swap_current || !values_close(mem_current + swap_current, size, 3)) goto cleanup; ret = 0; cleanup: free(buf); return ret; } /* * This test checks that memory.swap.max limits the amount of * anonymous memory which can be swapped out. */ static int test_memcg_swap_max(const char *root) { int ret = KSFT_FAIL; char *memcg; long max; if (!is_swap_enabled()) return KSFT_SKIP; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; if (cg_read_long(memcg, "memory.swap.current")) { ret = KSFT_SKIP; goto cleanup; } if (cg_read_strcmp(memcg, "memory.max", "max\n")) goto cleanup; if (cg_read_strcmp(memcg, "memory.swap.max", "max\n")) goto cleanup; if (cg_write(memcg, "memory.swap.max", "30M")) goto cleanup; if (cg_write(memcg, "memory.max", "30M")) goto cleanup; /* Should be killed by OOM killer */ if (!cg_run(memcg, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_read_key_long(memcg, "memory.events", "oom ") != 1) goto cleanup; if (cg_read_key_long(memcg, "memory.events", "oom_kill ") != 1) goto cleanup; if (cg_run(memcg, alloc_anon_50M_check_swap, (void *)MB(30))) goto cleanup; max = cg_read_key_long(memcg, "memory.events", "max "); if (max <= 0) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } /* * This test disables swapping and tries to allocate anonymous memory * up to OOM. Then it checks for oom and oom_kill events in * memory.events. */ static int test_memcg_oom_events(const char *root) { int ret = KSFT_FAIL; char *memcg; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; if (cg_write(memcg, "memory.max", "30M")) goto cleanup; if (cg_write(memcg, "memory.swap.max", "0")) goto cleanup; if (!cg_run(memcg, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_read_strcmp(memcg, "cgroup.procs", "")) goto cleanup; if (cg_read_key_long(memcg, "memory.events", "oom ") != 1) goto cleanup; if (cg_read_key_long(memcg, "memory.events", "oom_kill ") != 1) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } struct tcp_server_args { unsigned short port; int ctl[2]; }; static int tcp_server(const char *cgroup, void *arg) { struct tcp_server_args *srv_args = arg; struct sockaddr_in6 saddr = { 0 }; socklen_t slen = sizeof(saddr); int sk, client_sk, ctl_fd, yes = 1, ret = -1; close(srv_args->ctl[0]); ctl_fd = srv_args->ctl[1]; saddr.sin6_family = AF_INET6; saddr.sin6_addr = in6addr_any; saddr.sin6_port = htons(srv_args->port); sk = socket(AF_INET6, SOCK_STREAM, 0); if (sk < 0) return ret; if (setsockopt(sk, SOL_SOCKET, SO_REUSEADDR, &yes, sizeof(yes)) < 0) goto cleanup; if (bind(sk, (struct sockaddr *)&saddr, slen)) { write(ctl_fd, &errno, sizeof(errno)); goto cleanup; } if (listen(sk, 1)) goto cleanup; ret = 0; if (write(ctl_fd, &ret, sizeof(ret)) != sizeof(ret)) { ret = -1; goto cleanup; } client_sk = accept(sk, NULL, NULL); if (client_sk < 0) goto cleanup; ret = -1; for (;;) { uint8_t buf[0x100000]; if (write(client_sk, buf, sizeof(buf)) <= 0) { if (errno == ECONNRESET) ret = 0; break; } } close(client_sk); cleanup: close(sk); return ret; } static int tcp_client(const char *cgroup, unsigned short port) { const char server[] = "localhost"; struct addrinfo *ai; char servport[6]; int retries = 0x10; /* nice round number */ int sk, ret; snprintf(servport, sizeof(servport), "%hd", port); ret = getaddrinfo(server, servport, NULL, &ai); if (ret) return ret; sk = socket(ai->ai_family, ai->ai_socktype, ai->ai_protocol); if (sk < 0) goto free_ainfo; ret = connect(sk, ai->ai_addr, ai->ai_addrlen); if (ret < 0) goto close_sk; ret = KSFT_FAIL; while (retries--) { uint8_t buf[0x100000]; long current, sock; if (read(sk, buf, sizeof(buf)) <= 0) goto close_sk; current = cg_read_long(cgroup, "memory.current"); sock = cg_read_key_long(cgroup, "memory.stat", "sock "); if (current < 0 || sock < 0) goto close_sk; if (current < sock) goto close_sk; if (values_close(current, sock, 10)) { ret = KSFT_PASS; break; } } close_sk: close(sk); free_ainfo: freeaddrinfo(ai); return ret; } /* * This test checks socket memory accounting. * The test forks a TCP server listens on a random port between 1000 * and 61000. Once it gets a client connection, it starts writing to * its socket. * The TCP client interleaves reads from the socket with check whether * memory.current and memory.stat.sock are similar. */ static int test_memcg_sock(const char *root) { int bind_retries = 5, ret = KSFT_FAIL, pid, err; unsigned short port; char *memcg; memcg = cg_name(root, "memcg_test"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; while (bind_retries--) { struct tcp_server_args args; if (pipe(args.ctl)) goto cleanup; port = args.port = 1000 + rand() % 60000; pid = cg_run_nowait(memcg, tcp_server, &args); if (pid < 0) goto cleanup; close(args.ctl[1]); if (read(args.ctl[0], &err, sizeof(err)) != sizeof(err)) goto cleanup; close(args.ctl[0]); if (!err) break; if (err != EADDRINUSE) goto cleanup; waitpid(pid, NULL, 0); } if (err == EADDRINUSE) { ret = KSFT_SKIP; goto cleanup; } if (tcp_client(memcg, port) != KSFT_PASS) goto cleanup; waitpid(pid, &err, 0); if (WEXITSTATUS(err)) goto cleanup; if (cg_read_long(memcg, "memory.current") < 0) goto cleanup; if (cg_read_key_long(memcg, "memory.stat", "sock ")) goto cleanup; ret = KSFT_PASS; cleanup: cg_destroy(memcg); free(memcg); return ret; } /* * This test disables swapping and tries to allocate anonymous memory * up to OOM with memory.group.oom set. Then it checks that all * processes in the leaf (but not the parent) were killed. */ static int test_memcg_oom_group_leaf_events(const char *root) { int ret = KSFT_FAIL; char *parent, *child; parent = cg_name(root, "memcg_test_0"); child = cg_name(root, "memcg_test_0/memcg_test_1"); if (!parent || !child) goto cleanup; if (cg_create(parent)) goto cleanup; if (cg_create(child)) goto cleanup; if (cg_write(parent, "cgroup.subtree_control", "+memory")) goto cleanup; if (cg_write(child, "memory.max", "50M")) goto cleanup; if (cg_write(child, "memory.swap.max", "0")) goto cleanup; if (cg_write(child, "memory.oom.group", "1")) goto cleanup; cg_run_nowait(parent, alloc_anon_noexit, (void *) MB(60)); cg_run_nowait(child, alloc_anon_noexit, (void *) MB(1)); cg_run_nowait(child, alloc_anon_noexit, (void *) MB(1)); if (!cg_run(child, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_test_proc_killed(child)) goto cleanup; if (cg_read_key_long(child, "memory.events", "oom_kill ") <= 0) goto cleanup; if (cg_read_key_long(parent, "memory.events", "oom_kill ") != 0) goto cleanup; ret = KSFT_PASS; cleanup: if (child) cg_destroy(child); if (parent) cg_destroy(parent); free(child); free(parent); return ret; } /* * This test disables swapping and tries to allocate anonymous memory * up to OOM with memory.group.oom set. Then it checks that all * processes in the parent and leaf were killed. */ static int test_memcg_oom_group_parent_events(const char *root) { int ret = KSFT_FAIL; char *parent, *child; parent = cg_name(root, "memcg_test_0"); child = cg_name(root, "memcg_test_0/memcg_test_1"); if (!parent || !child) goto cleanup; if (cg_create(parent)) goto cleanup; if (cg_create(child)) goto cleanup; if (cg_write(parent, "memory.max", "80M")) goto cleanup; if (cg_write(parent, "memory.swap.max", "0")) goto cleanup; if (cg_write(parent, "memory.oom.group", "1")) goto cleanup; cg_run_nowait(parent, alloc_anon_noexit, (void *) MB(60)); cg_run_nowait(child, alloc_anon_noexit, (void *) MB(1)); cg_run_nowait(child, alloc_anon_noexit, (void *) MB(1)); if (!cg_run(child, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_test_proc_killed(child)) goto cleanup; if (cg_test_proc_killed(parent)) goto cleanup; ret = KSFT_PASS; cleanup: if (child) cg_destroy(child); if (parent) cg_destroy(parent); free(child); free(parent); return ret; } /* * This test disables swapping and tries to allocate anonymous memory * up to OOM with memory.group.oom set. Then it checks that all * processes were killed except those set with OOM_SCORE_ADJ_MIN */ static int test_memcg_oom_group_score_events(const char *root) { int ret = KSFT_FAIL; char *memcg; int safe_pid; memcg = cg_name(root, "memcg_test_0"); if (!memcg) goto cleanup; if (cg_create(memcg)) goto cleanup; if (cg_write(memcg, "memory.max", "50M")) goto cleanup; if (cg_write(memcg, "memory.swap.max", "0")) goto cleanup; if (cg_write(memcg, "memory.oom.group", "1")) goto cleanup; safe_pid = cg_run_nowait(memcg, alloc_anon_noexit, (void *) MB(1)); if (set_oom_adj_score(safe_pid, OOM_SCORE_ADJ_MIN)) goto cleanup; cg_run_nowait(memcg, alloc_anon_noexit, (void *) MB(1)); if (!cg_run(memcg, alloc_anon, (void *)MB(100))) goto cleanup; if (cg_read_key_long(memcg, "memory.events", "oom_kill ") != 3) goto cleanup; if (kill(safe_pid, SIGKILL)) goto cleanup; ret = KSFT_PASS; cleanup: if (memcg) cg_destroy(memcg); free(memcg); return ret; } #define T(x) { x, #x } struct memcg_test { int (*fn)(const char *root); const char *name; } tests[] = { T(test_memcg_subtree_control), T(test_memcg_current), T(test_memcg_min), T(test_memcg_low), T(test_memcg_high), T(test_memcg_max), T(test_memcg_oom_events), T(test_memcg_swap_max), T(test_memcg_sock), T(test_memcg_oom_group_leaf_events), T(test_memcg_oom_group_parent_events), T(test_memcg_oom_group_score_events), }; #undef T int main(int argc, char **argv) { char root[PATH_MAX]; int i, ret = EXIT_SUCCESS; if (cg_find_unified_root(root, sizeof(root))) ksft_exit_skip("cgroup v2 isn't mounted\n"); /* * Check that memory controller is available: * memory is listed in cgroup.controllers */ if (cg_read_strstr(root, "cgroup.controllers", "memory")) ksft_exit_skip("memory controller isn't available\n"); for (i = 0; i < ARRAY_SIZE(tests); i++) { switch (tests[i].fn(root)) { case KSFT_PASS: ksft_test_result_pass("%s\n", tests[i].name); break; case KSFT_SKIP: ksft_test_result_skip("%s\n", tests[i].name); break; default: ret = EXIT_FAILURE; ksft_test_result_fail("%s\n", tests[i].name); break; } } return ret; }