Firing fraction management in skip fire engine control

What is claimed is: 1. A skip fire engine controller for a spark ignition engine having a throttle and a camshaft having a plurality of cams, the skip fire controller comprising: a lookup table embodied in a computer readable media, wherein each entry in the lookup table includes a firing fraction field that stores a firing fraction indicator indicative of a desired firing fraction associated with such entry, wherein the firing fraction indicator does not identify any specific cylinders to fire; a firing fraction determining unit arranged to determine a firing fraction suitable for delivering a requested engine output, wherein the firing fraction determining unit utilizes the lookup table to determine a desired firing fraction, wherein the firing fraction determining unit utilizes at least (i) the requested engine output, and (ii) a current engine speed as indices to select a desired firing fraction; a firing controller arranged to direct firings in a skip fire manner that delivers the desired firing fraction; and a powertrain parameter adjusting module arranged to adjust at least one engine actuator that affects mass air charge (MAC) such that the engine delivers the requested engine output at the desired firing fraction, wherein the at least one engine actuator affects at least one of cam phase, cam lift and throttle position. 2. A skip fire engine controller as recited in claim 1 wherein an additional index for the lookup table includes transmission gear. 3. A skip fire engine controller as recited in claim 1 wherein an additional index for the lookup table includes at least one selected from the group consisting of: manifold absolute pressure (MAP); manifold air temperature; a parameter indicative of mass air charge (MAC); a parameter indicative of cam position cylinder torque output; engine torque output; maximum permissible manifold pressure; vehicle speed; ambient temperature; and barometric pressure. 4. A skip fire engine controller as recited in claim 1 wherein the lookup table is a multi-dimensional lookup table that includes a plurality of logically or physically separate lookup tables. 5. A skip fire engine controller as recited in claim 1 wherein the lookup table dictates operation in an all-cylinder operational mode in selected operational states. 6. A skip fire engine controller as recited in claim 5 wherein the selected operational states for all-cylinder operation include engine speeds below a first threshold and engine speeds above a second threshold. 7. A skip fire engine controller as recited in claim 1 wherein each entry in the lookup table further includes a MAC field arranged to store a MAC indicator indicative of a desired operational mass air charge. 8. A skip fire engine controller as recited in claim 7 wherein the MAC indicator is a relative value. 9. A skip fire engine controller as recited in claim 1 wherein each entry in the lookup table further includes a second field arranged to store a value indicative of a second desired operational parameter. 10. An engine controller that includes a skip fire engine controller as recited in claim 1 wherein the engine controller is arranged to sometimes operate the engine in an all cylinder firing mode in which the output of the engine is primarily modulated based on throttle position. 11. A skip fire controller for a spark ignition engine having a, the skip fire controller comprising: a lookup table embodied in a computer readable media, the lookup table having a multiplicity of entries, each entry including a firing fraction field arranged to store an associated firing fraction indicator indicative of a desired firing fraction, wherein the firing fraction indicator does not identify any specific cylinders to fire, and wherein indices for the lookup table include, (i) a desired engine output, and (ii) a first operational power train parameter; a firing controller arranged to direct firings in a skip fire manner that delivers a desired firing fraction selected using the lookup table; and a powertrain parameter adjusting module arranged to adjust at least one engine setting that affects at least one of mass air charge (MAC) and spark timing, such that the engine delivers a requested engine output at the desired firing fraction. 12. A skip fire controller as recited in claim 11 further comprising an additional index for the lookup table based on a second operational power train parameter that is different than the first operational power train parameter. 13. A skip fire controller as recited in claim 12 wherein the first and second operational power train parameters are selected from the group consisting of: engine speed; transmission gear; manifold absolute pressure (MAP); manifold air temperature; mass air charge (MAC); cylinder torque output; cam position; maximum permissible manifold pressure; and vehicle speed. 14. A method of operating a spark ignition engine, the method comprising: determining a desired engine output in terms of a desired torque fraction, wherein the desired torque fraction is indicative of the desired engine output relative to a reference maximum available engine output; determining a desired operational firing fraction based on a lookup table that utilizes desired torque fraction as a first index and current engine speed as a second index wherein the lookup table has a multiplicity of entries, each entry including a firing fraction field arranged to store an associated firing fraction indicator indicative of a desired firing fraction, and wherein the firing fraction indicator does not identify any specific cylinders to fire; and determining a desired cylinder mass air charge (MAC) based at least in part on the determined desired operational firing fraction; directing one or more engine actuators to operate in a manner that delivers the desired mass air charge; and directing skip fire operation of the engine at the desired operational firing fraction in a manner that delivers the desired engine output; and wherein operation at the desired cylinder mass air charge and the desired operational firing fraction causes the engine to deliver the desired engine output. 15. A skip fire engine controller arranged to determine which cylinder working cycles of a spark ignition engine to fuel and fire, and which cylinder working cycles to skip, the skip fire engine controller comprising: a firing fraction determining unit arranged to dynamically determine a desired firing fraction based on a multi-dimensional lookup table, wherein indices for the multi-dimensional lookup table include i) a desired engine output; ii) a current engine speed; and iii) a current transmission gear; and a firing controller arranged to direct firings in a skip fire manner that delivers the desired firing fraction. 16. A skip fire engine controller as recited in claim 15 wherein the current engine speed index is arranged in selected ranges of engine speed. 17. A skip fire engine controller as recited in claim 15 wherein the determination of the desired firing fraction is further based on a current maximum manifold pressure that is desirable for use. 18. An engine control unit that includes a skip fire engine controller as recited in claim 15 , the engine controller unit further being arranged to sometimes operate the engine in an all cylinder firing mode in which the output of the engine is primarily modulated based on throttle position. 19. A skip fire engine controller as recited in claim 9 wherein the second field store