extern char* jobacct_cgroup_create_slurm_cg(xcgroup_ns_t* ns) { /* we do it here as we do not have access to the conf structure */ /* in libslurm (src/common/xcgroup.c) */ xcgroup_t slurm_cg; char* pre = (char*) xstrdup(slurm_cgroup_conf.cgroup_prepend); #ifdef MULTIPLE_SLURMD if (conf->node_name != NULL) { xstrsubstitute(pre, "%n", conf->node_name); } else { xfree(pre); pre = (char*) xstrdup("/slurm"); } #endif /* create slurm cgroup in the ns (it could already exist) */ if (xcgroup_create(ns, &slurm_cg, pre, getuid(), getgid()) != XCGROUP_SUCCESS) { return pre; } if (xcgroup_instantiate(&slurm_cg) != XCGROUP_SUCCESS) { error("unable to build slurm cgroup for ns %s: %m", ns->subsystems); xcgroup_destroy(&slurm_cg); return pre; } else { debug3("slurm cgroup %s successfully created for ns %s: %m", pre, ns->subsystems); xcgroup_destroy(&slurm_cg); } return pre; }
static int memcg_initialize (xcgroup_ns_t *ns, xcgroup_t *cg, char *path, uint64_t mem_limit, uid_t uid, gid_t gid, uint32_t notify) { uint64_t mlb = mem_limit_in_bytes (mem_limit); uint64_t mls = swap_limit_in_bytes (mem_limit); if (xcgroup_create (ns, cg, path, uid, gid) != XCGROUP_SUCCESS) return -1; cg->notify = notify; if (xcgroup_instantiate (cg) != XCGROUP_SUCCESS) { xcgroup_destroy (cg); return -1; } xcgroup_set_param (cg, "memory.use_hierarchy", "1"); /* when RAM space has not to be constrained and we are here, it * means that only Swap space has to be constrained. Thus set * RAM space limit to the mem+swap limit too */ if ( ! constrain_ram_space ) mlb = mls; xcgroup_set_uint64_param (cg, "memory.limit_in_bytes", mlb); /* * Also constrain kernel memory (if available). * See https://lwn.net/Articles/516529/ */ xcgroup_set_uint64_param (cg, "memory.kmem.limit_in_bytes", mlb); /* this limit has to be set only if ConstrainSwapSpace is set to yes */ if ( constrain_swap_space ) { xcgroup_set_uint64_param (cg, "memory.memsw.limit_in_bytes", mls); info ("task/cgroup: %s: alloc=%luMB mem.limit=%luMB " "memsw.limit=%luMB", path, (unsigned long) mem_limit, (unsigned long) mlb/(1024*1024), (unsigned long) mls/(1024*1024)); } else { info ("task/cgroup: %s: alloc=%luMB mem.limit=%luMB " "memsw.limit=unlimited", path, (unsigned long) mem_limit, (unsigned long) mlb/(1024*1024)); } return 0; }
static char* _system_cgroup_create_slurm_cg (xcgroup_ns_t* ns) { /* we do it here as we do not have access to the conf structure */ /* in libslurm (src/common/xcgroup.c) */ xcgroup_t slurm_cg; char* pre = (char*) xstrdup(slurm_cgroup_conf.cgroup_prepend); #ifdef MULTIPLE_SLURMD if ( conf->node_name != NULL ) xstrsubstitute(pre, "%n", conf->node_name); else { xfree(pre); pre = (char*) xstrdup("/slurm"); } #endif /* create slurm cgroup in the ns * disable notify_on_release to avoid the removal/creation * of this cgroup for each last/first running job on the node */ if (xcgroup_create(ns, &slurm_cg, pre, getuid(), getgid()) != XCGROUP_SUCCESS) { xfree(pre); return pre; } slurm_cg.notify = 0; if (xcgroup_instantiate(&slurm_cg) != XCGROUP_SUCCESS) { error("system cgroup: unable to build slurm cgroup for " "ns %s: %m", ns->subsystems); xcgroup_destroy(&slurm_cg); xfree(pre); return pre; } else { debug3("system cgroup: slurm cgroup %s successfully created " "for ns %s: %m", pre, ns->subsystems); xcgroup_destroy(&slurm_cg); } return pre; }
extern int task_cgroup_devices_create(stepd_step_rec_t *job) { int f, k, rc, gres_conf_lines, allow_lines; int fstatus = SLURM_ERROR; char **gres_name = NULL; char **gres_cgroup = NULL, **dev_path = NULL; char *allowed_devices[PATH_MAX], *allowed_dev_major[PATH_MAX]; int *gres_job_bit_alloc = NULL; int *gres_step_bit_alloc = NULL; int *gres_count = NULL; xcgroup_t devices_cg; uint32_t jobid = job->jobid; uint32_t stepid = job->stepid; uid_t uid = job->uid; uid_t gid = job->gid; List job_gres_list = job->job_gres_list; List step_gres_list = job->step_gres_list; char* slurm_cgpath ; /* create slurm root cgroup in this cgroup namespace */ slurm_cgpath = task_cgroup_create_slurm_cg(&devices_ns); if (slurm_cgpath == NULL) return SLURM_ERROR; /* build user cgroup relative path if not set (should not be) */ if (*user_cgroup_path == '\0') { if (snprintf(user_cgroup_path, PATH_MAX, "%s/uid_%u", slurm_cgpath, uid) >= PATH_MAX) { error("unable to build uid %u cgroup relative path : %m", uid); xfree(slurm_cgpath); return SLURM_ERROR; } } xfree(slurm_cgpath); /* build job cgroup relative path if no set (should not be) */ if (*job_cgroup_path == '\0') { if (snprintf(job_cgroup_path, PATH_MAX, "%s/job_%u", user_cgroup_path, jobid) >= PATH_MAX) { error("task/cgroup: unable to build job %u devices " "cgroup relative path : %m", jobid); return SLURM_ERROR; } } /* build job step cgroup relative path (should not be) */ if (*jobstep_cgroup_path == '\0') { int cc; if (stepid == SLURM_BATCH_SCRIPT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_batch", job_cgroup_path); } else if (stepid == SLURM_EXTERN_CONT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_extern", job_cgroup_path); } else { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_%u", job_cgroup_path, stepid); } if (cc >= PATH_MAX) { error("task/cgroup: unable to build job step %u.%u " "devices cgroup relative path : %m", jobid, stepid); return SLURM_ERROR; } } /* * create devices root cgroup and lock it * * we will keep the lock until the end to avoid the effect of a release * agent that would remove an existing cgroup hierarchy while we are * setting it up. As soon as the step cgroup is created, we can release * the lock. * Indeed, consecutive slurm steps could result in cgroup being removed * between the next EEXIST instanciation and the first addition of * a task. The release_agent will have to lock the root devices cgroup * to avoid this scenario. */ if (xcgroup_create(&devices_ns, &devices_cg, "", 0, 0) != XCGROUP_SUCCESS ) { error("task/cgroup: unable to create root devices cgroup"); return SLURM_ERROR; } if (xcgroup_lock(&devices_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&devices_cg); error("task/cgroup: unable to lock root devices cgroup"); return SLURM_ERROR; } info("task/cgroup: manage devices jor job '%u'", jobid); /* * collect info concerning the gres.conf file * the GRES devices paths and the GRES names */ gres_conf_lines = gres_plugin_node_config_devices_path(&dev_path, &gres_name, job->node_name); /* * create the entry for cgroup devices subsystem with major minor */ gres_cgroup = xmalloc(sizeof(char *) * gres_conf_lines); _calc_device_major(dev_path, gres_cgroup, gres_conf_lines); /* * create the entry with major minor for the default allowed devices * read from the file */ allow_lines = read_allowed_devices_file(allowed_devices); _calc_device_major(allowed_devices, allowed_dev_major, allow_lines); /* * calculate the number of gres.conf records for each gres name */ gres_count = xmalloc(sizeof(int) * gres_conf_lines); f = 0; gres_count[f] = 1; for (k = 0; k < gres_conf_lines; k++) { if ((k+1 < gres_conf_lines) && (xstrcmp(gres_name[k], gres_name[k+1]) == 0)) gres_count[f]++; if ((k+1 < gres_conf_lines) && (xstrcmp(gres_name[k], gres_name[k+1]) != 0)) { f++; gres_count[f] = 1; } } /* * create user cgroup in the devices ns (it could already exist) */ if (xcgroup_create(&devices_ns, &user_devices_cg, user_cgroup_path, getuid(), getgid()) != XCGROUP_SUCCESS) { goto error; } if (xcgroup_instantiate(&user_devices_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_devices_cg); goto error; } /* TODO * check that user's devices cgroup is consistant and allow the * appropriate devices */ /* * create job cgroup in the devices ns (it could already exist) */ if (xcgroup_create(&devices_ns, &job_devices_cg, job_cgroup_path, getuid(), getgid()) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_devices_cg); goto error; } if (xcgroup_instantiate(&job_devices_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_devices_cg); xcgroup_destroy(&job_devices_cg); goto error; } /* fetch information concerning the gres devices allocation for the job */ gres_job_bit_alloc = xmalloc(sizeof (int) * (gres_conf_lines + 10)); gres_plugin_job_state_file(job_gres_list, gres_job_bit_alloc, gres_count); /* * with the current cgroup devices subsystem design (whitelist only * supported) we need to allow all different devices that are supposed * to be allowed by* default. */ for (k = 0; k < allow_lines; k++) { info("Default access allowed to device %s", allowed_dev_major[k]); xcgroup_set_param(&job_devices_cg, "devices.allow", allowed_dev_major[k]); } /* * allow or deny access to devices according to job GRES permissions */ for (k = 0; k < gres_conf_lines; k++) { if (gres_job_bit_alloc[k] == 1) { info("Allowing access to device %s", gres_cgroup[k]); xcgroup_set_param(&job_devices_cg, "devices.allow", gres_cgroup[k]); } else { info("Not allowing access to device %s", gres_cgroup[k]); xcgroup_set_param(&job_devices_cg, "devices.deny", gres_cgroup[k]); } } /* * create step cgroup in the devices ns (it should not exists) * use job's user uid/gid to enable tasks cgroups creation by * the user inside the step cgroup owned by root */ if (xcgroup_create(&devices_ns, &step_devices_cg, jobstep_cgroup_path, uid, gid) != XCGROUP_SUCCESS ) { /* do not delete user/job cgroup as */ /* they can exist for other steps */ xcgroup_destroy(&user_devices_cg); xcgroup_destroy(&job_devices_cg); goto error; } if ( xcgroup_instantiate(&step_devices_cg) != XCGROUP_SUCCESS ) { xcgroup_destroy(&user_devices_cg); xcgroup_destroy(&job_devices_cg); xcgroup_destroy(&step_devices_cg); goto error; } if ((job->stepid != SLURM_BATCH_SCRIPT) && (job->stepid != SLURM_EXTERN_CONT)) { /* fetch information about step GRES devices allocation */ gres_step_bit_alloc = xmalloc(sizeof (int) * (gres_conf_lines + 10)); gres_plugin_step_state_file(step_gres_list, gres_step_bit_alloc, gres_count); /* * with the current cgroup devices subsystem design (whitelist * only supported) we need to allow all different devices that * are supposed to be allowed by default. */ for (k = 0; k < allow_lines; k++) { info("Default access allowed to device %s", allowed_dev_major[k]); xcgroup_set_param(&step_devices_cg, "devices.allow", allowed_dev_major[k]); } /* * allow or deny access to devices according to GRES permissions * for the step */ for (k = 0; k < gres_conf_lines; k++) { if (gres_step_bit_alloc[k] == 1) { info("Allowing access to device %s for step", gres_cgroup[k]); xcgroup_set_param(&step_devices_cg, "devices.allow", gres_cgroup[k]); } else { info("Not allowing access to device %s for step", gres_cgroup[k]); xcgroup_set_param(&step_devices_cg, "devices.deny", gres_cgroup[k]); } } } /* attach the slurmstepd to the step devices cgroup */ pid_t pid = getpid(); rc = xcgroup_add_pids(&step_devices_cg, &pid, 1); if (rc != XCGROUP_SUCCESS) { error("task/cgroup: unable to add slurmstepd to devices cg '%s'", step_devices_cg.path); fstatus = SLURM_ERROR; } else { fstatus = SLURM_SUCCESS; } error: xcgroup_unlock(&devices_cg); xcgroup_destroy(&devices_cg); xfree(gres_step_bit_alloc); xfree(gres_job_bit_alloc); xfree(gres_name); xfree(dev_path); xfree(gres_cgroup); return fstatus; }
extern int init_system_cpuset_cgroup(void) { int rc; int fstatus = SLURM_ERROR; char* cpus = NULL; size_t cpus_size; char* slurm_cgpath; xcgroup_t slurm_cg; /* read cgroup configuration */ if (read_slurm_cgroup_conf(&slurm_cgroup_conf)) return SLURM_ERROR; /* initialize cpuset cgroup namespace */ if (xcgroup_ns_create(&slurm_cgroup_conf, &cpuset_ns, "", "cpuset") != XCGROUP_SUCCESS) { error("system cgroup: unable to create cpuset namespace"); free_slurm_cgroup_conf(&slurm_cgroup_conf); return SLURM_ERROR; } /* create slurm root cg in this cg namespace */ slurm_cgpath = _system_cgroup_create_slurm_cg(&cpuset_ns); if ( slurm_cgpath == NULL ) { xcgroup_ns_destroy(&cpuset_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); return SLURM_ERROR; } /* check that this cgroup has cpus allowed or initialize them */ if (xcgroup_load(&cpuset_ns, &slurm_cg, slurm_cgpath) != XCGROUP_SUCCESS) { error("system cgroup: unable to load slurm cpuset xcgroup"); xfree(slurm_cgpath); xcgroup_ns_destroy(&cpuset_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); return SLURM_ERROR; } again: snprintf(cpuset_meta, sizeof(cpuset_meta), "%scpus", cpuset_prefix); rc = xcgroup_get_param(&slurm_cg, cpuset_meta, &cpus, &cpus_size); if (rc != XCGROUP_SUCCESS || cpus_size == 1) { if (!cpuset_prefix_set && (rc != XCGROUP_SUCCESS)) { cpuset_prefix_set = 1; cpuset_prefix = "cpuset."; goto again; } /* initialize the cpusets as it was nonexistent */ if (_xcgroup_cpuset_init(&slurm_cg) != XCGROUP_SUCCESS) { xfree(slurm_cgpath); xcgroup_destroy(&slurm_cg); xcgroup_ns_destroy(&cpuset_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); xfree(cpus); return SLURM_ERROR; } } xcgroup_destroy(&slurm_cg); xfree(cpus); /* build system cgroup relative path */ snprintf(system_cgroup_path, PATH_MAX, "%s/system", slurm_cgpath); xfree(slurm_cgpath); /* create system cgroup in the cpuset ns */ if (xcgroup_create(&cpuset_ns, &system_cpuset_cg, system_cgroup_path, getuid(),getgid()) != XCGROUP_SUCCESS) { goto error; } if (xcgroup_instantiate(&system_cpuset_cg) != XCGROUP_SUCCESS) { goto error; } if (_xcgroup_cpuset_init(&system_cpuset_cg) != XCGROUP_SUCCESS) { goto error; } free_slurm_cgroup_conf(&slurm_cgroup_conf); debug("system cgroup: system cpuset cgroup initialized"); return SLURM_SUCCESS; error: xcgroup_unlock(&system_cpuset_cg); xcgroup_destroy(&system_cpuset_cg); xcgroup_ns_destroy(&cpuset_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); return fstatus; }
extern int init_system_memory_cgroup(void) { int fstatus = SLURM_ERROR; char* slurm_cgpath; /* read cgroup configuration */ if (read_slurm_cgroup_conf(&slurm_cgroup_conf)) return SLURM_ERROR; /* initialize memory cgroup namespace */ if (xcgroup_ns_create(&slurm_cgroup_conf, &memory_ns, "", "memory") != XCGROUP_SUCCESS) { error("system cgroup: unable to create memory namespace"); free_slurm_cgroup_conf(&slurm_cgroup_conf); return SLURM_ERROR; } constrain_kmem_space = slurm_cgroup_conf.constrain_kmem_space; constrain_ram_space = slurm_cgroup_conf.constrain_ram_space; constrain_swap_space = slurm_cgroup_conf.constrain_swap_space; /* * as the swap space threshold will be configured with a * mem+swp parameter value, if RAM space is not monitored, * set allowed RAM space to 100% of the job requested memory. * It will help to construct the mem+swp value that will be * used for both mem and mem+swp limit during memcg creation. */ if ( constrain_ram_space ) allowed_ram_space = slurm_cgroup_conf.allowed_ram_space; else allowed_ram_space = 100.0; allowed_swap_space = slurm_cgroup_conf.allowed_swap_space; if ((totalram = (uint64_t) conf->real_memory_size) == 0) error ("system cgroup: Unable to get RealMemory size"); max_kmem = _percent_in_bytes(totalram, slurm_cgroup_conf.max_kmem_percent); max_ram = _percent_in_bytes(totalram, slurm_cgroup_conf.max_ram_percent); max_swap = _percent_in_bytes(totalram, slurm_cgroup_conf.max_swap_percent); max_swap += max_ram; min_ram_space = slurm_cgroup_conf.min_ram_space * 1024 * 1024; debug ("system cgroup: memory: total:%luM allowed:%.4g%%(%s), " "swap:%.4g%%(%s), max:%.4g%%(%luM) " "max+swap:%.4g%%(%luM) min:%luM " "kmem:%.4g%%(%luM %s) min:%luM", (unsigned long) totalram, allowed_ram_space, constrain_ram_space?"enforced":"permissive", allowed_swap_space, constrain_swap_space?"enforced":"permissive", slurm_cgroup_conf.max_ram_percent, (unsigned long) (max_ram/(1024*1024)), slurm_cgroup_conf.max_swap_percent, (unsigned long) (max_swap/(1024*1024)), (unsigned long) slurm_cgroup_conf.min_ram_space, slurm_cgroup_conf.max_kmem_percent, (unsigned long)(max_kmem/(1024*1024)), constrain_kmem_space?"enforced":"permissive", (unsigned long) slurm_cgroup_conf.min_kmem_space); /* * Warning: OOM Killer must be disabled for slurmstepd * or it would be destroyed if the application use * more memory than permitted * * If an env value is already set for slurmstepd * OOM killer behavior, keep it, otherwise set the * -1000 value, wich means do not let OOM killer kill it * * FYI, setting "export SLURMSTEPD_OOM_ADJ=-1000" * in /etc/sysconfig/slurm would be the same */ setenv("SLURMSTEPD_OOM_ADJ", "-1000", 0); /* create slurm root cg in this cg namespace */ slurm_cgpath = _system_cgroup_create_slurm_cg(&memory_ns); if ( slurm_cgpath == NULL ) { xcgroup_ns_destroy(&memory_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); return SLURM_ERROR; } /* build system cgroup relative path */ snprintf(system_cgroup_path, PATH_MAX, "%s/system", slurm_cgpath); xfree(slurm_cgpath); /* create system cgroup in the cpuset ns */ if (xcgroup_create(&memory_ns, &system_memory_cg, system_cgroup_path, getuid(), getgid()) != XCGROUP_SUCCESS) { goto error; } if (xcgroup_instantiate(&system_memory_cg) != XCGROUP_SUCCESS) { goto error; } if ( xcgroup_set_param(&system_memory_cg, "memory.use_hierarchy", "1") != XCGROUP_SUCCESS ) { error("system cgroup: unable to ask for hierarchical accounting" "of system memcg '%s'", system_memory_cg.path); goto error; } free_slurm_cgroup_conf(&slurm_cgroup_conf); debug("system cgroup: system memory cgroup initialized"); return SLURM_SUCCESS; error: xcgroup_unlock(&system_memory_cg); xcgroup_destroy(&system_memory_cg); xcgroup_ns_destroy(&memory_ns); free_slurm_cgroup_conf(&slurm_cgroup_conf); return fstatus; }
extern int task_cgroup_cpuset_create(stepd_step_rec_t *job) { int rc; int fstatus = SLURM_ERROR; xcgroup_t cpuset_cg; uint32_t jobid = job->jobid; uint32_t stepid = job->stepid; uid_t uid = job->uid; uid_t gid = job->gid; char* user_alloc_cores = NULL; char* job_alloc_cores = NULL; char* step_alloc_cores = NULL; char cpuset_meta[PATH_MAX]; char *cpus = NULL; size_t cpus_size; char* slurm_cgpath; xcgroup_t slurm_cg; #ifdef HAVE_NATIVE_CRAY char expected_usage[32]; #endif /* create slurm root cg in this cg namespace */ slurm_cgpath = task_cgroup_create_slurm_cg(&cpuset_ns); if (slurm_cgpath == NULL) return SLURM_ERROR; /* check that this cgroup has cpus allowed or initialize them */ if (xcgroup_load(&cpuset_ns,&slurm_cg,slurm_cgpath) != XCGROUP_SUCCESS){ error("task/cgroup: unable to load slurm cpuset xcgroup"); xfree(slurm_cgpath); return SLURM_ERROR; } again: snprintf(cpuset_meta, sizeof(cpuset_meta), "%scpus", cpuset_prefix); rc = xcgroup_get_param(&slurm_cg, cpuset_meta, &cpus, &cpus_size); if ((rc != XCGROUP_SUCCESS) || (cpus_size == 1)) { if (!cpuset_prefix_set && (rc != XCGROUP_SUCCESS)) { cpuset_prefix_set = 1; cpuset_prefix = "cpuset."; xfree(cpus); goto again; } /* initialize the cpusets as it was non-existent */ if (_xcgroup_cpuset_init(&slurm_cg) != XCGROUP_SUCCESS) { xfree(cpus); xfree(slurm_cgpath); xcgroup_destroy(&slurm_cg); return SLURM_ERROR; } } xfree(cpus); xcgroup_destroy(&slurm_cg); /* build user cgroup relative path if not set (should not be) */ if (*user_cgroup_path == '\0') { if (snprintf(user_cgroup_path, PATH_MAX, "%s/uid_%u", slurm_cgpath, uid) >= PATH_MAX) { error("task/cgroup: unable to build uid %u cgroup " "relative path : %m", uid); xfree(slurm_cgpath); return SLURM_ERROR; } } xfree(slurm_cgpath); /* build job cgroup relative path if no set (should not be) */ if (*job_cgroup_path == '\0') { if (snprintf(job_cgroup_path,PATH_MAX,"%s/job_%u", user_cgroup_path,jobid) >= PATH_MAX) { error("task/cgroup: unable to build job %u cpuset " "cg relative path : %m",jobid); return SLURM_ERROR; } } /* build job step cgroup relative path (should not be) */ if (*jobstep_cgroup_path == '\0') { int cc; if (stepid == SLURM_BATCH_SCRIPT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_batch", job_cgroup_path); } else if (stepid == SLURM_EXTERN_CONT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_extern", job_cgroup_path); } else { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_%u", job_cgroup_path, stepid); } if (cc >= PATH_MAX) { error("task/cgroup: unable to build job step %u.%u " "cpuset cg relative path: %m", jobid, stepid); return SLURM_ERROR; } } /* * create cpuset root cg and lock it * * we will keep the lock until the end to avoid the effect of a release * agent that would remove an existing cgroup hierarchy while we are * setting it up. As soon as the step cgroup is created, we can release * the lock. * Indeed, consecutive slurm steps could result in cg being removed * between the next EEXIST instantiation and the first addition of * a task. The release_agent will have to lock the root cpuset cgroup * to avoid this scenario. */ if (xcgroup_create(&cpuset_ns, &cpuset_cg, "", 0,0) != XCGROUP_SUCCESS){ error("task/cgroup: unable to create root cpuset xcgroup"); return SLURM_ERROR; } if (xcgroup_lock(&cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&cpuset_cg); error("task/cgroup: unable to lock root cpuset cg"); return SLURM_ERROR; } /* * build job and job steps allocated cores lists */ debug("task/cgroup: job abstract cores are '%s'", job->job_alloc_cores); debug("task/cgroup: step abstract cores are '%s'", job->step_alloc_cores); if (xcpuinfo_abs_to_mac(job->job_alloc_cores, &job_alloc_cores) != SLURM_SUCCESS) { error("task/cgroup: unable to build job physical cores"); goto error; } if (xcpuinfo_abs_to_mac(job->step_alloc_cores, &step_alloc_cores) != SLURM_SUCCESS) { error("task/cgroup: unable to build step physical cores"); goto error; } debug("task/cgroup: job physical cores are '%s'", job_alloc_cores); debug("task/cgroup: step physical cores are '%s'", step_alloc_cores); /* * create user cgroup in the cpuset ns (it could already exist) */ if (xcgroup_create(&cpuset_ns,&user_cpuset_cg, user_cgroup_path, getuid(), getgid()) != XCGROUP_SUCCESS) { goto error; } if (xcgroup_instantiate(&user_cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); goto error; } /* * check that user's cpuset cgroup is consistant and add the job cores */ rc = xcgroup_get_param(&user_cpuset_cg, cpuset_meta, &cpus, &cpus_size); if (rc != XCGROUP_SUCCESS || cpus_size == 1) { /* initialize the cpusets as it was non-existent */ if (_xcgroup_cpuset_init(&user_cpuset_cg) != XCGROUP_SUCCESS) { (void)xcgroup_delete(&user_cpuset_cg); xcgroup_destroy(&user_cpuset_cg); xfree(cpus); goto error; } } user_alloc_cores = xstrdup(job_alloc_cores); if ((cpus != NULL) && (cpus_size > 1)) { cpus[cpus_size-1]='\0'; xstrcat(user_alloc_cores, ","); xstrcat(user_alloc_cores, cpus); } xcgroup_set_param(&user_cpuset_cg, cpuset_meta, user_alloc_cores); xfree(cpus); /* * create job cgroup in the cpuset ns (it could already exist) */ if (xcgroup_create(&cpuset_ns,&job_cpuset_cg, job_cgroup_path, getuid(),getgid()) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); goto error; } if (xcgroup_instantiate(&job_cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); xcgroup_destroy(&job_cpuset_cg); goto error; } if (_xcgroup_cpuset_init(&job_cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); xcgroup_destroy(&job_cpuset_cg); goto error; } xcgroup_set_param(&job_cpuset_cg, cpuset_meta, job_alloc_cores); /* * create step cgroup in the cpuset ns (it should not exists) * use job's user uid/gid to enable tasks cgroups creation by * the user inside the step cgroup owned by root */ if (xcgroup_create(&cpuset_ns,&step_cpuset_cg, jobstep_cgroup_path, uid,gid) != XCGROUP_SUCCESS) { /* do not delete user/job cgroup as */ /* they can exist for other steps */ xcgroup_destroy(&user_cpuset_cg); xcgroup_destroy(&job_cpuset_cg); goto error; } if (xcgroup_instantiate(&step_cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); xcgroup_destroy(&job_cpuset_cg); xcgroup_destroy(&step_cpuset_cg); goto error; } if (_xcgroup_cpuset_init(&step_cpuset_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_cpuset_cg); xcgroup_destroy(&job_cpuset_cg); (void)xcgroup_delete(&step_cpuset_cg); xcgroup_destroy(&step_cpuset_cg); goto error; } xcgroup_set_param(&step_cpuset_cg, cpuset_meta, step_alloc_cores); /* * on Cray systems, set the expected usage in bytes. * This is used by the Cray OOM killer */ #ifdef HAVE_NATIVE_CRAY snprintf(expected_usage, sizeof(expected_usage), "%"PRIu64, (uint64_t)job->step_mem * 1024 * 1024); xcgroup_set_param(&step_cpuset_cg, "expected_usage_in_bytes", expected_usage); #endif /* attach the slurmstepd to the step cpuset cgroup */ pid_t pid = getpid(); rc = xcgroup_add_pids(&step_cpuset_cg,&pid,1); if (rc != XCGROUP_SUCCESS) { error("task/cgroup: unable to add slurmstepd to cpuset cg '%s'", step_cpuset_cg.path); fstatus = SLURM_ERROR; } else fstatus = SLURM_SUCCESS; /* validate the requested cpu frequency and set it */ cpu_freq_cgroup_validate(job, step_alloc_cores); error: xcgroup_unlock(&cpuset_cg); xcgroup_destroy(&cpuset_cg); xfree(user_alloc_cores); xfree(job_alloc_cores); xfree(step_alloc_cores); return fstatus; }
extern int task_cgroup_memory_create(stepd_step_rec_t *job) { int fstatus = SLURM_ERROR; xcgroup_t memory_cg; uint32_t jobid = job->jobid; uint32_t stepid = job->stepid; uid_t uid = job->uid; gid_t gid = job->gid; char *slurm_cgpath; /* create slurm root cg in this cg namespace */ slurm_cgpath = task_cgroup_create_slurm_cg(&memory_ns); if ( slurm_cgpath == NULL ) { return SLURM_ERROR; } /* build user cgroup relative path if not set (should not be) */ if (*user_cgroup_path == '\0') { if (snprintf(user_cgroup_path, PATH_MAX, "%s/uid_%u", slurm_cgpath, uid) >= PATH_MAX) { error("unable to build uid %u cgroup relative " "path : %m", uid); xfree(slurm_cgpath); return SLURM_ERROR; } } xfree(slurm_cgpath); /* build job cgroup relative path if no set (should not be) */ if (*job_cgroup_path == '\0') { if (snprintf(job_cgroup_path,PATH_MAX,"%s/job_%u", user_cgroup_path,jobid) >= PATH_MAX) { error("task/cgroup: unable to build job %u memory " "cg relative path : %m", jobid); return SLURM_ERROR; } } /* build job step cgroup relative path (should not be) */ if (*jobstep_cgroup_path == '\0') { int cc; if (stepid == SLURM_BATCH_SCRIPT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_batch", job_cgroup_path); } else if (stepid == SLURM_EXTERN_CONT) { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_extern", job_cgroup_path); } else { cc = snprintf(jobstep_cgroup_path, PATH_MAX, "%s/step_%u", job_cgroup_path, stepid); } if (cc >= PATH_MAX) { error("task/cgroup: unable to build job step %u.%u " "memory cg relative path : %m", jobid, stepid); return SLURM_ERROR; } } /* * create memory root cg and lock it * * we will keep the lock until the end to avoid the effect of a release * agent that would remove an existing cgroup hierarchy while we are * setting it up. As soon as the step cgroup is created, we can release * the lock. * Indeed, consecutive slurm steps could result in cg being removed * between the next EEXIST instanciation and the first addition of * a task. The release_agent will have to lock the root memory cgroup * to avoid this scenario. */ if (xcgroup_create(&memory_ns, &memory_cg, "",0,0) != XCGROUP_SUCCESS) { error("task/cgroup: unable to create root memory xcgroup"); return SLURM_ERROR; } if (xcgroup_lock(&memory_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&memory_cg); error("task/cgroup: unable to lock root memory cg"); return SLURM_ERROR; } /* * Create user cgroup in the memory ns (it could already exist) * Ask for hierarchical memory accounting starting from the user * container in order to track the memory consumption up to the * user. * We do not set any limits at this level for now. It could be * interesting to do it in the future but memcg cleanup mech * are not working well so it will be really difficult to manage * addition/removal of memory amounts at this level. (kernel 2.6.34) */ if (xcgroup_create(&memory_ns, &user_memory_cg, user_cgroup_path, getuid(),getgid()) != XCGROUP_SUCCESS) { goto error; } if (xcgroup_instantiate(&user_memory_cg) != XCGROUP_SUCCESS) { xcgroup_destroy(&user_memory_cg); goto error; } if ( xcgroup_set_param(&user_memory_cg, "memory.use_hierarchy", "1") != XCGROUP_SUCCESS ) { error("task/cgroup: unable to ask for hierarchical accounting" "of user memcg '%s'",user_memory_cg.path); xcgroup_destroy (&user_memory_cg); goto error; } /* * Create job cgroup in the memory ns (it could already exist) * and set the associated memory limits. * Disable notify_on_release for this memcg, it will be * manually removed by the plugin at the end of the step. */ if (memcg_initialize (&memory_ns, &job_memory_cg, job_cgroup_path, job->job_mem, getuid(), getgid(), 0) < 0) { xcgroup_destroy (&user_memory_cg); goto error; } /* * Create step cgroup in the memory ns (it should not exists) * and set the associated memory limits. * Disable notify_on_release for the step memcg, it will be * manually removed by the plugin at the end of the step. */ if (memcg_initialize (&memory_ns, &step_memory_cg, jobstep_cgroup_path, job->step_mem, uid, gid, 0) < 0) { xcgroup_destroy(&user_memory_cg); xcgroup_destroy(&job_memory_cg); goto error; } error: xcgroup_unlock(&memory_cg); xcgroup_destroy(&memory_cg); return fstatus; }