Methods and system for transitioning between fuel injection windows

The invention claimed is: 1. An engine fueling method, comprising: providing a first port fuel injection window defined by a first crankshaft angle and a second crankshaft angle in a cylinder cycle in response to a first port fuel injector pulse width; and providing a second port fuel injection window defined by the first crankshaft angle and a third crankshaft angle in the cylinder cycle in response to a second port fuel injector pulse width, where the first crankshaft angle occurs an actual total number of crankshaft degrees after an intake valve closing in a cylinder cycle immediately preceding the cylinder cycle, where the second crankshaft angle occurs an actual total number of crankshaft degrees before an intake valve opening for the cylinder cycle, where the third crankshaft angle occurs an actual total number of crankshaft degrees before an intake valve closing for the cylinder cycle and after the intake valve opening in the cylinder cycle, where the first crankshaft angle is a starting of the first and second port fuel injection windows, where the first port fuel injector pulse width is less than a threshold, and where the second port fuel injector pulse width is greater than the threshold. 2. The method of claim 1 , where the first port fuel injection window and the second port fuel injection window are constant and do not vary in duration, where the second crankshaft angle is an end of the first port fuel injection window, and where a duration of the first port fuel injector pulse width is a different length than the first port fuel injection window. 3. The method of claim 1 , where the third crankshaft angle is an end of the second port fuel injection window. 4. The method of claim 1 , further comprising a port fuel injector injecting fuel into a cylinder during the cylinder cycle during the first port fuel injection window. 5. The method of claim 1 , further comprising a port fuel injector injecting fuel into a cylinder during the cylinder cycle during the second port fuel injection window. 6. The method of claim 5 , where the first and second port fuel injection windows are crankshaft angular intervals where port fuel is injected to a cylinder. 7. An engine fueling method, comprising: transitioning a fuel injection mode from a first port fuel injection window defined by a first crankshaft angle at or after an intake valve closing in a cylinder cycle immediately preceding a first cylinder cycle and a second crankshaft angle at or before an intake valve opening for the first cylinder cycle to a second port fuel injection window defined by a third crankshaft angle at or after a second intake valve closing in a cylinder cycle immediately preceding a second cylinder cycle and a fourth crankshaft angle at or before a third intake valve closing during the second cylinder cycle, where the transitioning includes limiting a maximum number of port fuel injections in a third cylinder cycle to an actual total number of only one port fuel injection. 8. The method of claim 7 , where the third cylinder cycle is after the first cylinder cycle and before or during the second cylinder cycle. 9. The method of claim 7 , where a port fuel injector provides multiple fuel injections during the first port fuel injection window. 10. The method of claim 9 , where the port fuel injector provides a maximum of one fuel injection during the second port fuel injection window. 11. The method of claim 7 , further comprising directly injecting fuel to a cylinder during the first cylinder cycle. 12. The method of claim 11 , further comprising directly injecting fuel to the cylinder during the second cylinder cycle. 13. The method of claim 7 , further comprising providing a first direct fuel injection window after the first port fuel injection window for the first cylinder cycle and providing a second direct fuel injection window overlapping the second port fuel injection window. 14. A system, comprising: an engine including a port fuel injector and a direct fuel injector providing fuel to a cylinder; and a controller including executable instructions stored in non-transitory memory for adjusting a port fuel injection abort angle for the port fuel injector in response to a fuel pulse width greater than a threshold, and for transitioning a fuel injection mode from a first port fuel injection window defined by a first crankshaft angle at or after an intake valve closing in a cylinder cycle immediately preceding a first cylinder cycle and a second crankshaft angle at or before an intake valve opening for the first cylinder cycle to a second port fuel injection window defined by a third crankshaft angle at or after a second intake valve closing in a cylinder cycle immediately preceding a second cylinder cycle and a fourth crankshaft angle at or before a third intake valve closing during the second cylinder cycle, where the transitioning includes limiting a maximum number of port fuel injections in a third cylinder cycle to an actual total number of only one port fuel injection. 15. The system of claim 14 , where the port fuel injection abort angle is an engine crankshaft angle during a cylinder cycle where port fuel injection ceases even if a commanded amount of fuel has not been injected during the cylinder cycle. 16. The system of claim 14 , further comprising additional instructions to adjust the port fuel injection abort angle in response to a fuel pulse width less than the threshold.