Methods and systems for adjusting a direct fuel injector and a port fuel injector

The invention claimed is: 1. A method for an engine, comprising a controller with computer readable instructions stored in non-transitory memory for: delivering fuel to a cylinder during a combustion cycle as multiple direct injections; responsive to a fuel mass of one of the multiple direct injections being in a second region of a direct injector map describing mass of fuel injected as a function of fuel injector pulse width, updating one or more of a ratio of fuel delivered in each of the multiple direct injections and a number of the multiple direct injections and moving the fuel mass of the one of the multiple direct injections out of the second region, where the second region is positioned between a first region and a third region of the direct injector map, the first region including where no fuel is injected for a fuel injector pulse width and where a first linear relationship exists between an amount of fuel injected and the fuel injector pulse width, the second region where a non-linear relationship exists between the amount of fuel injected and the fuel injector pulse width, the third region where a second linear relationship exists between the amount of fuel injected and the fuel injector pulse width, the first, second, and third regions being distinct from each other; and responsive to the fuel mass of each of the multiple direct injections not being in the second region of the direct injector map describing mass of fuel injected as the function of fuel injector pulse width, injecting fuel in the multiple direct injections according to the direct injector map describing mass of fuel injected as the function of fuel injector pulse width. 2. The method of claim 1 , wherein direct injector variability in the second region is higher than each of the first region and the third region. 3. The method of claim 2 , wherein the updating is based on a position of the fuel mass relative to each of a first border between the first region and the second region and a second border between the second region and the third region of the direct injector map. 4. The method of claim 3 , wherein the updating includes, responsive to a distance of the fuel mass from the first border of the direct injector map being smaller than a distance of the fuel mass from the second border of the direct injector map, decreasing the fuel mass of the one of the multiple direct injections to move the fuel mass from the second region into the first region of the direct injector map while increasing the fuel mass of another one of the multiple direct injections. 5. The method of claim 4 , wherein the updating further includes, responsive to the distance of the fuel mass from the first border of the direct injector map being larger than the distance of the fuel mass from the second border of the direct injector map, increasing the fuel mass of the one of the multiple direct injections to move the fuel mass from the second region into the third region of the direct injector map while decreasing the fuel mass of another one of the multiple direct injections. 6. The method of claim 5 , wherein the increasing and decreasing is based on the number of the multiple direct injections. 7. The method of claim 1 , wherein updating the number of the multiple direct injections includes: during a first condition, decreasing the number of the multiple direct injections by merging the one of the multiple direct injections with at least another of the multiple direct injections to move the fuel mass from the second region into the third region; and during a second condition, increasing the number of the multiple direct injections by splitting the one of the multiple direct injections into a plurality of direct injections in the first region. 8. The method of claim 7 , wherein, during the first condition, an unadjusted number of the multiple direct injections is higher than a threshold number, and wherein, during the second condition, the unadjusted number of the multiple direct injections is higher than the threshold number. 9. The method of claim 1 , wherein the multiple direct injections include multiple direct injections in an intake stroke and a compression stroke of the combustion cycle, and wherein the updating further includes updating a split ratio of direct injected fuel delivered in the intake stroke relative to the compression stroke. 10. The method of claim 1 , further comprising adjusting an amount of the fuel delivered to the cylinder during the combustion cycle via port injection based on the updating. 11. A method for an engine, comprising; during a first condition, responsive to a first pulse-width signal of a single direct injection fuel pulse of a first combustion cycle lying within a second region of a direct injector map describing mass of fuel injected as a function of fuel injector pulse width, shifting to operating with multiple direct injection fuel pulses a pulse-width signal of each of the multiple direct injection fuel pulses lying outside the second region, where the second region is positioned between a first region and a third region of the direct injector map, the first region including where no fuel is injected for a fuel injector pulse width and where a first linear relationship exists between an amount of fuel injected and the fuel injector pulse width, the second region where a non-linear relationship exists between the amount of fuel injected and the fuel injector pulse width, the third region where a second linear relationship exists between the amount of fuel injected and the fuel injector pulse width, the first, second, and third regions being distinct from each other; during a second condition, responsive to a second pulse-width signal of one of multiple direct injection fuel pulses of a second combustion cycle lying within the second region of the direct injector map, shifting to operating with a single direct injection fuel pulse, a pulse-width signal of the single direct injection fuel pulse lying outside the second region; and responsive to the pulse-width signal of each of the direct injection fuel pulses not being in the second region of the direct injector map describing mass of fuel injected as the function of fuel injector pulse width, injecting fuel in the direct injection fuel pulses according to the direct injector map describing mass of fuel injected as the function of fuel injector pulse width. 12. The method of claim 11 , wherein, during the first condition, the pulse-width signal of each of the multiple direct injection fuel pulses is in the first region of the direct injector map, and wherein, during the second condition, the pulse-width signal of the single direct injection fuel pulse is in the third region of the direct injector map. 13. The method of claim 11 , wherein, during each of the first and second conditions, a total fuel mass delivered via direct injection during each of the first and second combustion cycles is maintained. 14. The method of claim 11 , further comprising, during a third condition, responsive to a pulse-width signal of one of multiple direct injection fuel pulses of a third combustion cycle lying within the second region of the direct injector map, adjusting the pulse-width signal of each of the multiple direct injection fuel pulses to shift out of the second region while maintaining a number of pulses of the multiple direct injection fuel pulses. 15. The method of claim 14 , wherein the second condition includes a higher than threshold engine speed and the third condition includes a lower than threshold engine speed or a higher than threshold engine NVH level. 16. The m