/* * Copyright (c) 2019, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #include #include #include #include "cgroupV1Subsystem_linux.hpp" #include "logging/log.hpp" #include "memory/allocation.hpp" #include "runtime/globals.hpp" #include "runtime/os.hpp" #include "utilities/globalDefinitions.hpp" /* * Set directory to subsystem specific files based * on the contents of the mountinfo and cgroup files. */ void CgroupV1Controller::set_subsystem_path(char *cgroup_path) { char buf[MAXPATHLEN+1]; if (_root != NULL && cgroup_path != NULL) { if (strcmp(_root, "/") == 0) { int buflen; strncpy(buf, _mount_point, MAXPATHLEN); buf[MAXPATHLEN-1] = '\0'; if (strcmp(cgroup_path,"/") != 0) { buflen = strlen(buf); if ((buflen + strlen(cgroup_path)) > (MAXPATHLEN-1)) { return; } strncat(buf, cgroup_path, MAXPATHLEN-buflen); buf[MAXPATHLEN-1] = '\0'; } _path = os::strdup(buf); } else { if (strcmp(_root, cgroup_path) == 0) { strncpy(buf, _mount_point, MAXPATHLEN); buf[MAXPATHLEN-1] = '\0'; _path = os::strdup(buf); } else { char *p = strstr(cgroup_path, _root); if (p != NULL && p == _root) { if (strlen(cgroup_path) > strlen(_root)) { int buflen; strncpy(buf, _mount_point, MAXPATHLEN); buf[MAXPATHLEN-1] = '\0'; buflen = strlen(buf); if ((buflen + strlen(cgroup_path) - strlen(_root)) > (MAXPATHLEN-1)) { return; } strncat(buf, cgroup_path + strlen(_root), MAXPATHLEN-buflen); buf[MAXPATHLEN-1] = '\0'; _path = os::strdup(buf); } } } } } } /* uses_mem_hierarchy * * Return whether or not hierarchical cgroup accounting is being * done. * * return: * A number > 0 if true, or * OSCONTAINER_ERROR for not supported */ jlong CgroupV1MemoryController::uses_mem_hierarchy() { GET_CONTAINER_INFO(jlong, this, "/memory.use_hierarchy", "Use Hierarchy is: " JLONG_FORMAT, JLONG_FORMAT, use_hierarchy); return use_hierarchy; } void CgroupV1MemoryController::set_subsystem_path(char *cgroup_path) { CgroupV1Controller::set_subsystem_path(cgroup_path); jlong hierarchy = uses_mem_hierarchy(); if (hierarchy > 0) { set_hierarchical(true); } } jlong CgroupV1Subsystem::read_memory_limit_in_bytes() { GET_CONTAINER_INFO(julong, _memory->controller(), "/memory.limit_in_bytes", "Memory Limit is: " JULONG_FORMAT, JULONG_FORMAT, memlimit); if (memlimit >= _unlimited_memory) { log_trace(os, container)("Non-Hierarchical Memory Limit is: Unlimited"); CgroupV1MemoryController* mem_controller = reinterpret_cast(_memory->controller()); if (mem_controller->is_hierarchical()) { const char* matchline = "hierarchical_memory_limit"; const char* format = "%s " JULONG_FORMAT; GET_CONTAINER_INFO_LINE(julong, _memory->controller(), "/memory.stat", matchline, "Hierarchical Memory Limit is: " JULONG_FORMAT, format, hier_memlimit) if (hier_memlimit >= _unlimited_memory) { log_trace(os, container)("Hierarchical Memory Limit is: Unlimited"); } else { return (jlong)hier_memlimit; } } return (jlong)-1; } else { return (jlong)memlimit; } } jlong CgroupV1Subsystem::memory_and_swap_limit_in_bytes() { GET_CONTAINER_INFO(julong, _memory->controller(), "/memory.memsw.limit_in_bytes", "Memory and Swap Limit is: " JULONG_FORMAT, JULONG_FORMAT, memswlimit); if (memswlimit >= _unlimited_memory) { log_trace(os, container)("Non-Hierarchical Memory and Swap Limit is: Unlimited"); CgroupV1MemoryController* mem_controller = reinterpret_cast(_memory->controller()); if (mem_controller->is_hierarchical()) { const char* matchline = "hierarchical_memsw_limit"; const char* format = "%s " JULONG_FORMAT; GET_CONTAINER_INFO_LINE(julong, _memory->controller(), "/memory.stat", matchline, "Hierarchical Memory and Swap Limit is : " JULONG_FORMAT, format, hier_memlimit) if (hier_memlimit >= _unlimited_memory) { log_trace(os, container)("Hierarchical Memory and Swap Limit is: Unlimited"); } else { return (jlong)hier_memlimit; } } return (jlong)-1; } else { return (jlong)memswlimit; } } jlong CgroupV1Subsystem::memory_soft_limit_in_bytes() { GET_CONTAINER_INFO(julong, _memory->controller(), "/memory.soft_limit_in_bytes", "Memory Soft Limit is: " JULONG_FORMAT, JULONG_FORMAT, memsoftlimit); if (memsoftlimit >= _unlimited_memory) { log_trace(os, container)("Memory Soft Limit is: Unlimited"); return (jlong)-1; } else { return (jlong)memsoftlimit; } } /* memory_usage_in_bytes * * Return the amount of used memory for this process. * * return: * memory usage in bytes or * -1 for unlimited * OSCONTAINER_ERROR for not supported */ jlong CgroupV1Subsystem::memory_usage_in_bytes() { GET_CONTAINER_INFO(jlong, _memory->controller(), "/memory.usage_in_bytes", "Memory Usage is: " JLONG_FORMAT, JLONG_FORMAT, memusage); return memusage; } /* memory_max_usage_in_bytes * * Return the maximum amount of used memory for this process. * * return: * max memory usage in bytes or * OSCONTAINER_ERROR for not supported */ jlong CgroupV1Subsystem::memory_max_usage_in_bytes() { GET_CONTAINER_INFO(jlong, _memory->controller(), "/memory.max_usage_in_bytes", "Maximum Memory Usage is: " JLONG_FORMAT, JLONG_FORMAT, memmaxusage); return memmaxusage; } char * CgroupV1Subsystem::cpu_cpuset_cpus() { GET_CONTAINER_INFO_CPTR(cptr, _cpuset, "/cpuset.cpus", "cpuset.cpus is: %s", "%1023s", cpus, 1024); return os::strdup(cpus); } char * CgroupV1Subsystem::cpu_cpuset_memory_nodes() { GET_CONTAINER_INFO_CPTR(cptr, _cpuset, "/cpuset.mems", "cpuset.mems is: %s", "%1023s", mems, 1024); return os::strdup(mems); } /* cpu_quota * * Return the number of milliseconds per period * process is guaranteed to run. * * return: * quota time in milliseconds * -1 for no quota * OSCONTAINER_ERROR for not supported */ int CgroupV1Subsystem::cpu_quota() { GET_CONTAINER_INFO(int, _cpu, "/cpu.cfs_quota_us", "CPU Quota is: %d", "%d", quota); return quota; } int CgroupV1Subsystem::cpu_period() { GET_CONTAINER_INFO(int, _cpu, "/cpu.cfs_period_us", "CPU Period is: %d", "%d", period); return period; } /* cpu_shares * * Return the amount of cpu shares available to the process * * return: * Share number (typically a number relative to 1024) * (2048 typically expresses 2 CPUs worth of processing) * -1 for no share setup * OSCONTAINER_ERROR for not supported */ int CgroupV1Subsystem::cpu_shares() { GET_CONTAINER_INFO(int, _cpu, "/cpu.shares", "CPU Shares is: %d", "%d", shares); // Convert 1024 to no shares setup if (shares == 1024) return -1; return shares; }