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networking:clos [2026/03/27 11:21] v1ctornetworking:clos [2026/04/07 13:26] (current) – [ROUTING] v1ctor
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-Over-subscription - is the ratio between total bandwidth offered to workloads and to total available fabric bandwidth. +Over-subscription - is the ratio between total bandwidth offered to workloads and to total available fabric bandwidth. 
 + 
 +Total Edge port count = spine ports * over-subscription * break-out ration. 
 + 
 +Example 1 - three stage Clos using 64x100 spines and leafs with over-subscription 2:1 can provide 4096 edge ports.\\ 
 + 
 +Example 2 - 5 stage butterfly using 64x100 fabrics with over-subscription 2:1 can provide 65536 edge ports. 
 + 
 +It's possible to add 7th stage, which often used for DCI.  
 + 
 + 
 +==== Optics ==== 
 + 
 +^Name^Meaning^Distance^Notes^ 
 +|SR|Short Range|Up to 100m|Multimode Fiber| 
 +|DR|Data Range/Rate|Up to 500m| SMF or MMF| 
 +|FR|Far Range|Up to 2km| SM | 
 +|LR|Long Range|Up to 10km| SM | 
 +|ER|Extended Range|Up to 40km| SM | 
 +|ZR| Zero Dispersion/Coherent| Over 80 km| SM| 
 + 
 +Number indicates number of fibers: SR8 has 8 fibers, FR4 has 4 fibers etc... 
 + 
 +==== QoS ==== 
 + 
 +In general, you don't want deep buffers in the fabric, because most applications prefer to drop traffic rather than queue it. 
 + 
 +Bufferbloat occurs when excessively large switch/router buffers absorb traffic bursts instead of dropping packets, hiding congestion signals from TCP (or other transport protocols). The result: 
 + 
 +  - Latency spikes — packets sit in deep queues for milliseconds to tens of milliseconds instead of being delivered or dropped promptly. 
 +  - Reduced throughput — TCP's congestion control reacts too late because loss signals are delayed. 
 +  - Jitter — unpredictable queue depths cause variable RTTs. 
 + 
 + 
 +==== ROUTING ==== 
 + 
 +There are three main designs: 
 +  - iBGP underlay and eBGP overlay 
 +    - Spines and Super-spines are in iBGP domain 
 +    - Each leaf has its unique ASN assigned 
 +    - Leaves establish multi-hop eBGP with each other 
 +  - eBGP underlay and iBGP overlay (Juniper way) 
 +    - All leaves share the same ASN 
 +    - Spines and super-spines are connected using eBGP 
 +    - Leaves are connected using iBGP 
 +  - eBGP for both  
 + 
 + 
 +BGP convergence challenges: 
 +  - Path hunting  
 +  - Over-flooding 
 + 
 +Solutions: 
 +  - Valley-free routing - make sure leaves are non-transit routers. One of the solutions is to apply outbound AS-path filter allowing only ''^$'' 
 + 
 +BGP Tuning options: 
 +  - MRAI (Min route advertisement interval)
networking/clos.1774610462.txt.gz · Last modified: by v1ctor