Multi-wavelength laser system for optical data communication links and associated methods

What is claimed is: 1. A laser light supply system for fiber-optic data communication, comprising: a laser light generator including a plurality of lasers, each of the plurality of lasers configured to generate a different wavelength of continuous wave laser light relative to others of the plurality of lasers, each of the plurality of lasers being physically separate from any device that includes a transmitter element configured to convert a data signal from an electrical domain to an optical domain by modulating any one or more of the different wavelengths of continuous wave laser light generated by the plurality of lasers, each of the plurality of lasers being physically separate from any device that includes a receiver element configured to convert a data signal from the optical domain to the electrical domain, the laser light generator directing the different wavelengths of continuous wave laser light generated by the plurality of lasers to an optical output of the laser light generator; an optical conveyance device having a first end optically connected to the optical output of the laser light generator; and an optical distribution network having an optical input connected to a second end of the optical conveyance device, the optical distribution network configured to transmit each of the different wavelengths of continuous wave laser light generated by the plurality of lasers to each of multiple transceivers, wherein each of the multiple transceivers to which the optical distribution network is connected includes a respective optical input/output that provides for optical connection of an optical fiber and that does not require optical alignment of any laser source. 2. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein physical separation of the laser light generator from the multiple transceivers to which the optical distribution network is connected, by a combination of the optical conveyance device and the optical distribution network, provides for decoupling of failure modes of the laser light generator from failure modes of the multiple transceivers to which the optical distribution network is connected. 3. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein physical separation of the laser light generator from the multiple transceivers to which the optical distribution network is connected, by a combination of the optical conveyance device and the optical distribution network, provides for independent heat management of the laser light generator relative to the multiple transceivers to which the optical distribution network is connected. 4. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein physical separation of the laser light generator from the multiple transceivers to which the optical distribution network is connected, by a combination of the optical conveyance device and the optical distribution network, provides for modification of any of the plurality of lasers of the laser light generator without disruption of a configuration of the multiple transceivers to which the optical distribution network is connected. 5. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the optical conveyance device is a single-mode optical fiber. 6. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the optical distribution network includes a plurality of optical amplifiers connected to respectively amplify the different wavelengths of continuous wave laser light generated by the plurality of lasers. 7. The laser light supply system for fiber-optic data communication as recited in claim 6 , wherein each of the plurality of lasers is configured to operate as a wavelength reference generator. 8. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the laser light generator includes a redundant laser that becomes operable in place of a failed one of the plurality of lasers, the redundant laser configured to generate the same wavelength of continuous wave laser light as the failed one of the plurality of lasers. 9. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein each of the multiple transceivers to which the optical distribution network is connected is configured to operate in a wavelength tracking mode so as to enable some amount of drift in the different wavelengths of continuous wave laser light generated by the plurality of lasers. 10. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the laser light generator is configured to maintain relative wavelength spacings between the different wavelengths of continuous wave laser light generated by the plurality of lasers as variation in temperature of the plurality of lasers causes drift in the different wavelengths of continuous wave laser light generated by the plurality of lasers. 11. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the laser light generator is disposed in an area away from other heat generating chips. 12. The laser light supply system for fiber-optic data communication as recited in claim 1 , wherein the laser light generator is positioned away from external heat generating devices, such that the laser light generator is thermally separated from the external heat generating devices. 13. A laser light supply system for fiber-optic data communication comprising: a laser light generator including a plurality of lasers, each of the plurality of lasers configured to generate a different wavelength of continuous wave laser light relative to others of the plurality of lasers, each of the plurality of lasers being physically separate from any device that includes a transmitter element configured to convert a data signal from an electrical domain to an optical domain by modulating any one or more of the different wavelengths of continuous wave laser light generated by the plurality of lasers, each of the plurality of lasers being physically separate from any device that includes a receiver element configured to convert a data signal from the optical domain to the electrical domain, the laser light generator directing the different wavelengths of continuous wave laser light generated by the plurality of lasers to an optical output of the laser light generator; an optical conveyance device having a first end optically connected to the optical output of the laser light generator; and an optical distribution network having an optical input connected to a second end of the optical conveyance device, the optical distribution network configured to transmit each of the different wavelengths of continuous wave laser light generated by the plurality of lasers to each of multiple transceivers, wherein the laser light generator is disposed at a given position within a rack in a data center, and wherein the multiple transceivers to which the optical distribution network is connected are respectively disposed at one or more other positions in the rack physically separated from the given position at which the laser light generator is disposed. 14. The laser light supply system for fiber-optic data communication as recited in claim 13 , wherein the optical conveyance device is a single-mode optical fiber. 15. The laser light supply system for fiber-optic data communication as recited in claim 13 , wherein each of the multiple transceivers to which the optical distribution network is con