Virtual line cards in a disaggregated optical transport network switching system

What is claimed is: 1. An optical transport networking switching system comprising: an Ethernet fabric including a number M of Ethernet switches, each of the M Ethernet switches having a number N of Ethernet switch ports, each of the N Ethernet switch ports having a number P of Ethernet switch sub-ports, wherein a variable i having a value ranging from 1 to M denotes the ith Ethernet switch corresponding to one of the M Ethernet switches, a variable j having a value ranging from 1 to N denotes the jth Ethernet switch port corresponding to one of the N Ethernet switch ports, and a variable k having a value ranging from 1 to P denotes the kth Ethernet switch sub-port corresponding to one of the P Ethernet switch sub-ports, and wherein N, M, and Pare greater than one; and a plug-in universal (PIU) module having M PIU ports, wherein the ith PIU port of the M PIU ports corresponds to the ith Ethernet switch, wherein the optical transport networking switching system switches optical data units through the Ethernet fabric using the PIU modules and a virtual switch fabric associated with the PIU modules. 2. The optical transport networking switching system of claim 1 , wherein the virtual switch fabric comprise virtual line cards. 3. The optical transport networking switching system of claim 2 , wherein a virtual line card comprises a logical aggregation of the kth Ethernet switch sub-port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches. 4. The optical transport networking switching system of claim 3 , wherein the virtual line card is associated with a virtual address that is unique to the virtual line card in the virtual switch fabric. 5. The optical transport networking switching system of claim 4 , wherein each of the PIU module is associated with a media access control (MAC) address, and wherein at least a portion of the MAC address includes the virtual address of the virtual line card connected to the PIU module. 6. The optical transport networking switching system of claim 2 , wherein a virtual line card comprises a logical aggregation of a plurality of consecutive Ethernet switch sub-ports beginning with the kth Ethernet switch port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches. 7. An Ethernet fabric for optical transport networking switching, the Ethernet fabric comprising: a number M of Ethernet switches, each of the M Ethernet switches having a number N of Ethernet switch ports, each of the N Ethernet switch ports having a number P of Ethernet switch sub-ports, wherein a variable i having a value ranging from 1 to M denotes the ith Ethernet switch corresponding to one of the M Ethernet switches, a variable j having a value ranging from 1 to N denotes the jth Ethernet switch port corresponding to one of the N Ethernet switch ports, and a variable k having a value ranging from 1 to P denotes the kth Ethernet switch sub-port corresponding to one of the P Ethernet switch sub-ports, and wherein N, M, and P are greater than one, wherein the Ethernet fabric is exclusively coupled to a plurality of plug-in universal (PIU) modules each having M PIU ports including a first PIU module, wherein an ith PIU port of the first PIU module corresponds to the ith Ethernet switch, wherein the Ethernet fabric is used to switch optical data units using the PIU modules and a virtual switch fabric associated with the PIU modules. 8. The Ethernet fabric of claim 7 , wherein the virtual switch fabric comprise virtual line cards. 9. The Ethernet fabric of claim 8 , wherein a virtual line card comprises a logical aggregation of the kth Ethernet switch sub-port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches. 10. The Ethernet fabric of claim 9 , wherein the virtual line card is associated with a virtual address that is unique to the virtual line card in the virtual switch fabric. 11. The Ethernet fabric of claim 10 , wherein each of the PIU module is associated with a media access control (MAC) address, and wherein at least a portion of the MAC address includes the virtual address of the virtual line card connected to the PIU module. 12. The Ethernet fabric of claim 8 , wherein a virtual line card comprises a logical aggregation of a plurality of consecutive Ethernet switch sub-ports beginning with the kth Ethernet switch port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches. 13. A method for connecting Ethernet fabrics for optical transport networking switching, the method comprising: in an Ethernet fabric comprising a number M of Ethernet switches, each of the M Ethernet switches having a number N of Ethernet switch ports, each of the N Ethernet switch ports having a number P of Ethernet switch sub-ports, assigning a variable i having a value ranging from 1 to M to denote the ith Ethernet switch corresponding to one of the M Ethernet switches, wherein M is greater than one; assigning a variable j having a value ranging from 1 to N to denote the jth Ethernet switch port corresponding to one of the N Ethernet switch ports, and wherein N is greater than one; assigning a variable k having a value ranging from 1 to P to denote the kth Ethernet switch sub-port corresponding to one of the P Ethernet switch sub-ports, wherein P is greater than one; connecting the Ethernet fabric exclusively to a plurality of plug-in universal (PIU) modules each having M PIU ports including a first PIU module, wherein an ith PIU port of the first PIU module is connected to the ith Ethernet switch; and switching optical data units through the Ethernet fabric using the PIU modules and a virtual switch fabric associated with the PIU modules. 14. The method of claim 13 , wherein the virtual switch fabric comprise virtual line cards. 15. The method of claim 14 , further comprising: defining a virtual line card comprising a logical aggregation of the kth Ethernet switch sub-port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches; and switching the optical data units using the virtual line card. 16. The method of claim 15 , further comprising: associating the virtual line card with a virtual address that is unique to the virtual line card in the virtual switch fabric. 17. The method of claim 16 , further comprising: associating the first PIU module with a media access control (MAC) address, wherein at least a portion of the MAC address includes the virtual address of the virtual line card connected to the PIU module. 18. The method of claim 14 , further comprising: defining a virtual line card comprising a logical aggregation of a plurality of consecutive Ethernet switch sub-ports beginning with the kth Ethernet switch port of each of the corresponding Ethernet switch ports of each of the M Ethernet switches; and switching the optical data units using the virtual line card.