Cam phaser control

What is claimed is: 1. A method of controlling the phase of an adjustable phase camshaft relative to a crankshaft of an engine, wherein the adjustable phase camshaft is utilized to actuate at least one engine valve, the method comprising utilizing knowledge of at least one of: (i) firing events in a skip fire firing sequence, and (ii) dynamically determined valve actuation events, in the control of a cam phase adjustment device in a manner that maintains the phase of the adjustable phase camshaft more stable at a consistent commanded camshaft position through transitory variations in torque applied to the adjustable phase camshaft by the actuation of the at least one engine valve than would occur without such control. 2. A method as recited in claim 1 wherein the cam phase adjustment device is a cam phaser and the knowledge of at least one of the firing events and the dynamically determined valve actuation events is used in the control of hydraulic pressure within a chamber of the cam phaser. 3. A method as recited in claim 2 wherein the hydraulic pressure is varied in a manner that helps stabilize the phase of the adjustable phase camshaft through transitory variations in torque applied to the camshaft by the actuation of the at least one engine valve than would occur without the variations in hydraulic pressure. 4. A method as recited in claim 1 wherein the phase control is performed while the engine is operated in a skip fire manner with valve deactivation. 5. A method as recited in claim 4 wherein the timing of the dynamically determined valve actuation events is determined based at least in part on information regarding directed firing events and the dynamically determined valve actuation event timing is used in the control of hydraulic pressure within a cam phaser. 6. A method as recited in claim 2 further comprising: dynamically determining an estimated applied camshaft torque that accounts for camshaft torques imparted by the actuation of the at least one engine valve; and adjusting the hydraulic pressure within the chamber based at least in part on the estimated applied camshaft torque in order to counteract variations in the torque applied by the actuation of the at least one engine valve. 7. A method of dynamically tracking reactionary torque applied to a camshaft during operation of an engine, the method comprising: receiving an indication of at least one of (i) a skip fire firing sequence, and (ii) a sequence of engine events that include at least valve actuation events; and dynamically determining an estimated reactionary torque applied to the camshaft during operation of the engine, wherein the determined reactionary torque tracks and accounts for transitory torque variations imparted by the actuation of the at least one engine valve actuated by the camshaft during operation of the engine. 8. A method as recited in claim 7 wherein the estimated applied camshaft torque is used in the control of variable timing of the at least one engine valve actuated by the camshaft during operation of the engine. 9. A method as recited in claim 7 wherein the estimated applied camshaft torque is used in the control of a hydraulic pressure within a chamber of a cam phaser during engine operation. 10. A method as recited in claim 9 wherein the hydraulic pressure is varied in a manner that maintains the phase of the camshaft more stable through transitory variations in torque applied to the camshaft by the actuation of the at least one engine valve than would occur without the variations in hydraulic pressure. 11. A method as recited in claim 10 wherein the hydraulic pressure control is performed while the engine is operated in a skip fire manner with valve deactivation. 12. A cam phaser control module for controlling hydraulic pressure within a cam phaser cavity in order to control a phase of a camshaft during operation of an engine, the cam phaser control module comprising: a camshaft torque calculator arranged to dynamically determine the torque applied to a camshaft during operation of the engine; and a phaser solenoid duty cycle controller that modulates the hydraulic pressure within the cam phaser cavity over the course of an engine cycle based at least in part upon the dynamically determined torque in a manner that counteracts transient torque variations caused by actuation of valves that occur during operation of the engine over the course of the engine cycle. 13. A cam phaser control module as recited in claim 12 wherein the camshaft torque calculator is arranged to dynamically determine the torque applied to the camshaft during skip fire operation of the engine. 14. A cam phaser control module as recited in claim 13 wherein the phaser solenoid duty cycle controller is arranged to modulate the hydraulic pressure within the cam phaser cavity in a manner that helps stabilize the camshaft phase through transient variations in torque applied to the camshaft due to the actuation of valves driven by the camshaft during operation of the engine while operating at a consistent commanded camshaft position. 15. A cam phaser control module as recited in claim 12 wherein the phaser solenoid duty cycle controller is arranged to modulate the hydraulic pressure within the cam phaser cavity in a manner that helps offset transient variations in torque applied to the camshaft due to the actuation of valves driven by the camshaft while operating at a consistent commanded crankshaft position.