The distribution of stellar metallicities within and across galaxies is an excellent relic of the chemical evolution across cosmic time. We present a detailed analysis of spatially resolved stellar populations based on >2.6 million spatial bins from 7439 nearby galaxies in the Sloan Digital Sky Survey-IV (SDSS-IV) Mapping Nearby Galaxies at APO (MaNGA) survey. To account for accurate inclination corrections, we derive an equation for morphology-dependent determination of galaxy inclinations. Our study goes beyond the well-known global mass-metallicity relation and radial metallicity gradients by providing a statistically sound exploration of local relations between stellarmetallicity [Z/H], stellar surface mass density Sigma(star), and galactocentric distance in the global mass-morphology plane. We find a significant resolved mass density-metallicity relation r Sigma(star)ZR for galaxies of all types and masses above 10(9.8)M(circle dot). Different radial distances make an important contribution to the spread of the relation. Particularly, in low- and intermediate-mass galaxies, we find that at fixed Sigma(star) metallicity increases with radius independently of morphology. For high masses, this radial dependence is only observed in high Sigma(star) regions of spiral galaxies. This result calls for a driver of metallicity, in addition to Sigma(star) that promotes chemical enrichment in the outer parts of galaxies more strongly than in the inner parts. We discuss gas accretion, outflows, recycling, and radial migration as possible scenarios.