Benchmarking UM Version4.5 on different Architectures

Preamble

• Cluster/Parallel file systems are often a bottleneck. Timings are for writing to local disk, unless specified otherwise.
• If the model is not filesystem-bound, it is often (MPI massage) latency-bound.
• Only the master process writes output, this can lead to load-balance issues, which hinder scaling.
• Worst case message latencies for a cohort of processors are what matter for scaling. The vast majority of messages are either ~100 bytes or ~1KB in size. Latencies are reported for these key message sizes.

Emerald

• Intel Westmere E5649 (2.53GHz)
• QDR Infiniband (non-RoCE)
• GCOMv3.1

IMB ping-pong message latency
	0 bytes	128 bytes	1024 bytes
between nodes	~2.0us	~2.4us	~4.7us

FAMOUS

Domain Decomposition	Number of Cores	Model-years/day
4x3	12	~313
6x4	24	~360
12x3	36	~424

HadCM3

Domain Decomposition	Number of Cores	Model-years/day
4x3	12	~24
6x4	24	~40
12x3	36	~60

Intel SandyBridge Test System

• Test system: Quad socket, 8-core E-4650L (2.60GHz) (L for Low power)
• 20MB L3 cache
• GCOMv3.1

IMB ping-pong message latency
	0 bytes	128 bytes	1024 bytes
between sockets	~0.70us	~1.15us	~2.0us

FAMOUS

Domain Decomposition	Number of Cores	Model-years/day
4x2	8	~327
8x2	16	~450
8x4	32	~480

• The last line of this table shows a real problem scaling beyond 16 cores. Load balance? (Latencies are much better than QDR IB.)
• Would like to try to improve file writing performance and re-run.

HadCM3

Domain Decomposition	Number of Cores	Model-years/day
8x2	16	~48
8x4	32	~65

Polaris

• Intel E5-2670 @ 2.60GHz
• Infiniband: Mellanox Technologies MT27500 Family [ConnectX-3]
• Lustre

FAMOUS

Domain Decomposition	Number of Cores	Model-years/day
4x4	16	~330
8x4	32	~330

HadCM3

Domain Decomposition	Number of Cores	Model-years/day
4x4	16	~51
8x4	32	~73
16x4	64	~73