Consumable Resources in Slurm

Slurm, using the default node allocation plug-in, allocates nodes to jobs in exclusive mode. This means that even when all the resources within a node are not utilized by a given job, another job will not have access to these resources. Nodes possess resources such as processors, memory, swap, local disk, etc. and jobs consume these resources. The exclusive use default policy in Slurm can result in inefficient utilization of the cluster and of its nodes resources. Slurm's cons_res and cons_tres plugins are available to manage resources on a much more fine-grained basis as described below.

Using the Consumable Resource Allocation Plugin: select/cons_res

Consumable resources has been enhanced with several new resources --namely CPU (same as in previous version), Socket, Core, Memory as well as any combination of the logical processors with Memory:

CPU (CR_CPU): CPU as a consumable resource.

No notion of sockets, cores, or threads.
On a multi-core system CPUs will be cores.
On a multi-core/hyperthread system CPUs will be threads.
On a single-core system CPUs are CPUs.

Board (CR_Board): Baseboard as a consumable resource.
Socket (CR_Socket): Socket as a consumable resource.
Core (CR_Core): Core as a consumable resource.
Memory (CR_Memory) Memory only as a consumable resource. Note! CR_Memory assumes OverSubscribe=Yes
Socket and Memory (CR_Socket_Memory): Socket and Memory as consumable resources.
Core and Memory (CR_Core_Memory): Core and Memory as consumable resources.
CPU and Memory (CR_CPU_Memory) CPU and Memory as consumable resources.

In the cases where Memory is the consumable resource or one of the two consumable resources the RealMemory parameter, which defines a node's amount of real memory in slurm.conf, must be set.
srun's -E extension for sockets, cores, and threads are ignored within the node allocation mechanism when CR_CPU or CR_CPU_MEMORY is selected. It is considered to compute the total number of tasks when -n is not specified.
The job submission commands (salloc, sbatch and srun) support the options --mem=MB and --mem-per-cpu=MB permitting users to specify the maximum amount of real memory per node or per allocated required. This option is required in the environments where Memory is a consumable resource. It is important to specify enough memory since Slurm will not allow the application to use more than the requested amount of real memory. The default value for --mem is 1 MB. See the srun man page for more details.
All CR_s assume OverSubscribe=No or OverSubscribe=Force EXCEPT for CR_MEMORY which assumes OverSubscribe=Yes.
The consumable resource plugin is enabled via SelectType and SelectTypeParameters in the slurm.conf.

# Excerpt from sample slurm.conf file

SelectType=select/cons_res

Using --overcommit or -O is allowed. When the process to logical processor pinning is enabled by using an appropriate TaskPlugin configuration parameter, the extra processes will time share the allocated resources.

Using the Consumable Trackable Resource Plugin: select/cons_tres

The Consumable Trackable Resources (cons_tres) plugin provides all the same functionality provided by the Consumable Resources (cons_res) plugin. It also includes additional functionality specifically related to GPUs.
Additional parameters available for the cons_tres plugin:
- DefCpuPerGPU: Default number of CPUs allocated per GPU.
- DefMemPerGPU: Default amount of memory allocated per GPU.
Additional job submit options available for the cons_tres plugin:
- --cpus-per-gpu=: Number of CPUs for every GPU.
- --gpus=: Count of GPUs for entire job allocation.
- --gpu-bind=: Bind task to specific GPU(s).
- --gpu-freq=: Request specific GPU/memory frequencies.
- --gpus-per-node=: Number of GPUs per node.
- --gpus-per-socket=: Number of GPUs per socket.
- --gpus-per-task=: Number of GPUs per task.
- --mem-per-gpu=: Amount of memory for each GPU.
The consumable trackable resource plugin is enabled via the SelectType parameter in the slurm.conf.

# Excerpt from sample slurm.conf file
SelectType=select/cons_tres

General Comments

Slurm's default select/linear plugin is using a best fit algorithm based on number of consecutive nodes. The same node allocation approach is used with select/cons_res and select/cons_tres for consistency.
The select/cons_res and select/cons_tres plugins are enabled or disabled cluster-wide.
In the case where select/linear is enabled, the normal Slurm behaviors are not disrupted. The major change users see when using the select/cons_res or select/cons_tres plugins, is that jobs can be co-scheduled on nodes when resources permit it. Generic resources (such as GPUs) can also be tracked individually with these plugins. The rest of Slurm, such as srun and its options (except srun -s ...), etc. are not affected by this plugin. Slurm is, from the user's point of view, working the same way as when using the default node selection scheme.
The --exclusive srun option allows users to request nodes in exclusive mode even when consumable resources is enabled. See the srun man page for details.
srun's -s or --oversubscribe is incompatible with the consumable resource environment and will therefore not be honored. Since this environment's nodes are shared by default, --exclusive allows users to obtain dedicated nodes.
The --oversubscribe and --exclusive options are mutually exclusive when used at job submission. If both options are set when submitting a job, the job submission command used will fatal.

Examples of CR_Memory, CR_Socket_Memory, and CR_CPU_Memory type consumable resources

# sinfo -lNe
NODELIST     NODES PARTITION  STATE  CPUS  S:C:T MEMORY
hydra[12-16]     5 allNodes*  ...       4  2:2:1   2007

Using select/cons_res plug-in with CR_Memory

Example:
# srun -N 5 -n 20 --mem=1000 sleep 100 &  <-- running
# srun -N 5 -n 20 --mem=10 sleep 100 &    <-- running
# srun -N 5 -n 10 --mem=1000 sleep 100 &  <-- queued and waiting for resources

# squeue
JOBID PARTITION   NAME   USER ST  TIME  NODES NODELIST(REASON)
 1820  allNodes  sleep sballe PD  0:00      5 (Resources)
 1818  allNodes  sleep sballe  R  0:17      5 hydra[12-16]
 1819  allNodes  sleep sballe  R  0:11      5 hydra[12-16]

Using select/cons_res plug-in with CR_Socket_Memory (2 sockets/node)

Example 1:
# srun -N 5 -n 5 --mem=1000 sleep 100 &        <-- running
# srun -n 1 -w hydra12 --mem=2000 sleep 100 &  <-- queued and waiting for resources

# squeue
JOBID PARTITION   NAME   USER ST  TIME  NODES NODELIST(REASON)
 1890  allNodes  sleep sballe PD  0:00      1 (Resources)
 1889  allNodes  sleep sballe  R  0:08      5 hydra[12-16]

Example 2:
# srun -N 5 -n 10 --mem=10 sleep 100 & <-- running
# srun -n 1 --mem=10 sleep 100 & <-- queued and waiting for resourcessqueue

# squeue
JOBID PARTITION   NAME   USER ST  TIME  NODES NODELIST(REASON)
 1831  allNodes  sleep sballe PD  0:00      1 (Resources)
 1830  allNodes  sleep sballe  R  0:07      5 hydra[12-16]

Using select/cons_res plug-in with CR_CPU_Memory (4 CPUs/node)

Example 1:
# srun -N 5 -n 5 --mem=1000 sleep 100 &  <-- running
# srun -N 5 -n 5 --mem=10 sleep 100 &    <-- running
# srun -N 5 -n 5 --mem=1000 sleep 100 &  <-- queued and waiting for resources

# squeue
JOBID PARTITION   NAME   USER ST  TIME  NODES NODELIST(REASON)
 1835  allNodes  sleep sballe PD  0:00      5 (Resources)
 1833  allNodes  sleep sballe  R  0:10      5 hydra[12-16]
 1834  allNodes  sleep sballe  R  0:07      5 hydra[12-16]

Example 2:
# srun -N 5 -n 20 --mem=10 sleep 100 & <-- running
# srun -n 1 --mem=10 sleep 100 &       <-- queued and waiting for resources

# squeue
JOBID PARTITION   NAME   USER ST  TIME  NODES NODELIST(REASON)
 1837  allNodes  sleep sballe PD  0:00      1 (Resources)
 1836  allNodes  sleep sballe  R  0:11      5 hydra[12-16]

Example of Node Allocations Using Consumable Resource Plugin

The following example illustrates the different ways four jobs are allocated across a cluster using (1) Slurm's default allocation method (exclusive mode) and (2) a processor as consumable resource approach.

It is important to understand that the example listed below is a contrived example and is only given here to illustrate the use of CPU as consumable resources. Job 2 and Job 3 call for the node count to equal the processor count. This would typically be done because that one task per node requires all of the memory, disk space, etc. The bottleneck would not be processor count.

Trying to execute more than one job per node will almost certainly severely impact parallel job's performance. The biggest beneficiary of CPUs as consumable resources will be serial jobs or jobs with modest parallelism, which can effectively share resources. On many systems with larger processor count, jobs typically run one fewer task than there are processors to minimize interference by the kernel and daemons.

The example cluster is composed of 4 nodes (10 CPUs in total):

linux01 (with 2 processors),
linux02 (with 2 processors),
linux03 (with 2 processors), and
linux04 (with 4 processors).

The four jobs are the following:

[2] srun -n 4 -N 4 sleep 120 &
[3] srun -n 3 -N 3 sleep 120 &
[4] srun -n 1 sleep 120 &
[5] srun -n 3 sleep 120 &

The user launches them in the same order as listed above.

Using Slurm's Default Node Allocation (Non-shared Mode)

The four jobs have been launched and 3 of the jobs are now pending, waiting to get resources allocated to them. Only Job 2 is running since it uses one CPU on all 4 nodes. This means that linux01 to linux03 each have one idle CPU and linux04 has 3 idle CPUs.

# squeue
JOBID PARTITION   NAME  USER  ST  TIME  NODES NODELIST(REASON)
    3       lsf  sleep  root  PD  0:00      3 (Resources)
    4       lsf  sleep  root  PD  0:00      1 (Resources)
    5       lsf  sleep  root  PD  0:00      1 (Resources)
    2       lsf  sleep  root   R  0:14      4 xc14n[13-16]

Once Job 2 is finished, Job 3 is scheduled and runs on linux01, linux02, and linux03. Job 3 is only using one CPU on each of the 3 nodes. Job 4 can be allocated onto the remaining idle node (linux04) so Job 3 and Job 4 can run concurrently on the cluster.

Job 5 has to wait for idle nodes to be able to run.

# squeue
JOBID PARTITION   NAME  USER  ST  TIME  NODES NODELIST(REASON)
    5       lsf  sleep  root  PD  0:00      1 (Resources)
    3       lsf  sleep  root   R  0:11      3 xc14n[13-15]
    4       lsf  sleep  root   R  0:11      1 xc14n16

Once Job 3 finishes, Job 5 is allocated resources and can run.

The advantage of the exclusive mode scheduling policy is that the a job gets all the resources of the assigned nodes for optimal parallel performance. The drawback is that jobs can tie up large amount of resources that it does not use and which cannot be shared with other jobs.

Using a Processor Consumable Resource Approach

The output of squeue shows that we have 3 out of the 4 jobs allocated and running. This is a 2 running job increase over the default Slurm approach.

Job 2 is running on nodes linux01 to linux04. Job 2's allocation is the same as for Slurm's default allocation which is that it uses one CPU on each of the 4 nodes. Once Job 2 is scheduled and running, nodes linux01, linux02 and linux03 still have one idle CPU each and node linux04 has 3 idle CPUs. The main difference between this approach and the exclusive mode approach described above is that idle CPUs within a node are now allowed to be assigned to other jobs.

It is important to note that assigned doesn't mean oversubscription. The consumable resource approach tracks how much of each available resource (in our case CPUs) must be dedicated to a given job. This allows us to prevent per node oversubscription of resources (CPUs).

Once Job 2 is running, Job 3 is scheduled onto node linux01, linux02, and Linux03 (using one CPU on each of the nodes) and Job 4 is scheduled onto one of the remaining idle CPUs on Linux04.

Job 2, Job 3, and Job 4 are now running concurrently on the cluster.

# squeue
JOBID PARTITION   NAME  USER  ST  TIME  NODES NODELIST(REASON)
    5       lsf  sleep  root  PD  0:00      1 (Resources)
    2       lsf  sleep  root   R  0:13      4 linux[01-04]
    3       lsf  sleep  root   R  0:09      3 linux[01-03]
    4       lsf  sleep  root   R  0:05      1 linux04

# sinfo -lNe
NODELIST     NODES PARTITION       STATE CPUS MEMORY TMP_DISK WEIGHT FEATURES REASON
linux[01-03]     3      lsf*   allocated    2   2981        1      1   (null) none
linux04          1      lsf*   allocated    4   3813        1      1   (null) none

Once Job 2 finishes, Job 5, which was pending, is allocated available resources and is then running as illustrated below:

# squeue
JOBID PARTITION   NAME  USER  ST  TIME  NODES NODELIST(REASON)
   3       lsf   sleep  root   R  1:58      3 linux[01-03]
   4       lsf   sleep  root   R  1:54      1 linux04
   5       lsf   sleep  root   R  0:02      3 linux[01-03]
# sinfo -lNe
NODELIST     NODES PARTITION       STATE CPUS MEMORY TMP_DISK WEIGHT FEATURES REASON
linux[01-03]     3      lsf*   allocated    2   2981        1      1   (null) none
linux04          1      lsf*        idle    4   3813        1      1   (null) none

Job 3, Job 4, and Job 5 are now running concurrently on the cluster.

# squeue
JOBID PARTITION   NAME  USER  ST  TIME  NODES NODELIST(REASON)
    5       lsf  sleep  root   R  1:52      3 linux[01-03]

Job 3 and Job 4 have finished and Job 5 is still running on nodes linux[01-03].

The advantage of the consumable resource scheduling policy is that the job throughput can increase dramatically. The overall job throughput and productivity of the cluster increases, thereby reducing the amount of time users have to wait for their job to complete as well as increasing the overall efficiency of the use of the cluster. The drawback is that users do not have entire nodes dedicated to their jobs by default.

We have added the "--exclusive" option to srun (see the srun man page for more details), which allows users to specify that they would like their nodes to be allocated in exclusive mode. This is to accommodate users who might have mpi/threaded/openMP programs that will take advantage of all the CPUs on a node but only need one mpi process per node.

Last modified 19 September 2022