System and method for network bandwidth, buffers and timing management using hybrid scheduling of traffic with different priorities and guarantees

What is claimed is: 1. A method of managing network scheduling and configuration, the method comprising: for each transmitting end station, reserving one exclusive buffer for each virtual link scheduled to be transmitted from the respective transmitting end station, wherein an exclusive buffer is reserved for the communication of frames for a traffic flow having a specified priority; for each receiving end station, reserving one or more exclusive buffers for each virtual link scheduled to be received at the respective receiving end station; for each switch, reserving one exclusive buffer for each virtual link scheduled to be received at an input port of the respective switch; determining if each respective transmitting end station, each respective receiving end station, and each respective switch has sufficient hardware capability to support the respective total number of reserved buffers; and reporting buffer infeasibility if each respective transmitting end station, each respective receiving end station, and each respective switch does not have sufficient hardware capability to support the respective total number of reserved buffers. 2. The method of claim 1 , wherein for each receiving end station, reserving one or more exclusive buffers for each virtual link scheduled to be received at the respective receiving end station comprises: reserving one or more exclusive buffers for each respective synchronization virtual link based on the number of network planes associated with the respective synchronization virtual link; and for each input port of the respective receiving end station, reserving one or more exclusive buffers for all time triggered virtual links based on a maximum buffer depth for the respective receiving end station. 3. The method of claim 1 , further comprising: for each switch, reserving one exclusive buffer for each synchronization virtual link originating at the respective switch and scheduled to be transmitted from the respective switch. 4. The method of claim 1 , further comprising: identifying a bin of a global timeline in which to schedule an unscheduled virtual link, wherein the bin is a segment of the global timeline; identifying a pre-scheduled virtual link in the bin; if a total number of ports in common between the pre-scheduled virtual link and the unscheduled virtual link is less than a maximum buffer depth and a current number of virtual links which interfere with the pre-scheduled virtual link is less than a maximum interference parameter for the pre-scheduled virtual link, scheduling transmission of the unscheduled virtual link to overlay at least a portion of the scheduled transmission of the pre-scheduled virtual link. 5. The method of claim 1 , further comprising: splitting a payload of a message corresponding to a given virtual link into a plurality of fragments, each fragment being smaller than a maximum frame size; and sending each of the plurality of fragments in a respective period of the given virtual link. 6. The method of claim 1 , further comprising: assigning each virtual link a local priority at each node along the respective routing path of each virtual link, wherein the local priority for a scheduled rate constraint virtual link and a rate constrained virtual link are assigned a priority higher than a best effort virtual link and lower than a time triggered virtual link, wherein the local priority for the scheduled rate constrained virtual link is higher than the local priority for the rate constrained virtual link, wherein the priority for the local priority for each virtual link is determined based on characteristics of each virtual link. 7. The method of claim 1 , further comprising: computing a queuing latency for a given virtual link at each respective dispatch port along the routing path for the given virtual link, wherein computing the queuing latency at each respective dispatch port comprises: identifying all virtual links having a higher priority than the given virtual link and that are routed through the same respective dispatch port as the given virtual link; identifying all virtual links having equal priority to the given virtual link and that are routed through the same respective dispatch port as the given virtual link; computing a first sum of individual message times for the identified higher priority virtual links, wherein the respective message time of each identified higher priority virtual link is multiplied by a factor indicated by a ratio of the message rate of each respective higher priority virtual link to the message rate of the given virtual link; computing a second sum of individual message times for the identified equal priority virtual links, wherein the respective message time of each equal priority virtual link is not multiplied by a factor regardless of the message rate of the respective equal priority virtual link; wherein the queuing latency at the respective dispatch port is the sum of the first sum, the second sum, and a pre-determined message transmission time representing a maximum sized message. 8. The method of claim 1 , further comprising: calculating a green zone for each respective virtual link based on timing information for the respective virtual link's producing host and consuming hosts, wherein the green zone specifics a valid time on a timeline within which the respective virtual link is to be scheduled. 9. The method of claim 8 , wherein calculating the green zone for each respective virtual link comprises comprising one of: calculating the green zone for the respective virtual link such that the green zone begins after a latest consumer keep-out zone for the respective virtual link and ends prior to the beginning of a producer keep-out zone for the respective virtual link; or calculating the green zone for the respective virtual link such that the green zone begins after the producer keep-out zone for the respective virtual link and ends prior to the beginning of the earliest consumer keep-out zone; and using the green zone as a scheduling constraint for bin scheduling, wherein a bin is a segment of the global timeline in which to schedule an unscheduled virtual link. 10. A program product comprising a processor-readable medium on which program instructions are embodied, wherein the program instructions are configured, when executed by at least one programmable processor, to cause the at least one programmable processor to: for each transmitting end station, reserve one exclusive buffer for each virtual link scheduled to be transmitted from the respective transmitting end station, wherein an exclusive buffer is reserved for the communication of frames for a traffic flow having a specified priority; for each receiving end station, reserve one or more exclusive buffers for each virtual link scheduled to be received at the respective receiving end station; for each switch, reserve one exclusive buffer for each virtual link scheduled to be received at an input port of the respective switch; determine if each respective transmitting end station, each respective receiving end station, and each respective switch has sufficient hardware capability to support the respective total number of reserved buffers; and report buffer infeasibility if each respective transmitting end station, each respective receiving end station, and each respective switch does not have sufficient hardware capability to support the respective total number of reserved buffers. 11. The program product of claim 10 , wherein for each receiving end station, the program instructions are further configured to cause the at least one programmable processor to reserve one or more exclusive buffers for each vi