Current source regulation

What is claimed is: 1. A circuit, comprising: monitor circuitry that is configured to, for at least one LED (Light Emitting Diode) driver of a plurality of LED drivers: generate a signal to indicate that a voltage drop across the at least one LED driver is outside of a bounded range of voltage values, wherein the voltage drop is determined based on a drive voltage that is output by the at least one LED driver to source current to an LED that is coupled thereto and a supply voltage that is output by a power supply to each LED driver of the plurality of LED drivers, and wherein the signal represents a condition that the voltage drop across the at least one LED driver is less than or equal to a minimum voltage value of the bounded range of voltage values or a condition that the voltage drop across the at least one LED driver is greater than or equal to a maximum voltage value of the bounded range of voltage values; and controller circuitry that is configured to: receive the signal from the monitor circuitry; and based on the signal, increase or decrease magnitude of the supply voltage that is output by the power supply to force the voltage drop across the at least one LED driver to a voltage value within the bounded range of voltage values. 2. The circuit of claim 1 , wherein the monitor circuitry is configured to: generate a status signal that represents a state of the at least one LED driver selected from ON state and OFF state; and the controller circuitry is configured to: receive the status signal from monitor circuitry; and adjust the supply voltage that is output by the power supply on condition that the state of the at least one LED driver is ON state, to force the voltage drop across the at least one LED driver to within the bounded range of voltage values. 3. The circuit of claim 1 , wherein each one of the plurality of LED drivers is associated with a corresponding one pixel cell of a plurality of pixel cells that are arranged as a multi-dimensional matrix, and an instance of the monitor circuitry is included in each pixel cell of the plurality of pixel cells, and wherein the controller circuitry is configured to: receive an instance of the signal from each instance of the monitor circuitry, wherein each instance of the signal represents the condition that the voltage drop across an LED driver associated with a corresponding instance of the monitor circuitry is one of less than or equal to the minimum voltage value of the bounded range of voltage values and greater than or equal to the maximum voltage value of the bounded range of voltage values; store, in a first register, a bit for each one instance of the signal that represents the condition that an LED driver voltage drop is less than or equal to the minimum voltage value; store, in a second register, a bit for each one instance of the signal that represents the condition that an LED driver voltage drop is greater than or equal to the maximum voltage value; and adjust the supply voltage to a magnitude that is a function of numbers of bits in the first register and of numbers of bit in the second register. 4. The circuit of claim 3 , wherein the controller circuitry is configured to receive in parallel the instance of the signal from each instance of the monitor circuitry. 5. The circuit of claim 1 , wherein each one of the plurality of LED drivers is associated with a corresponding one pixel cell of a plurality of pixel cells that are arranged as a multi-dimensional matrix, and the monitor circuitry is coupled to each pixel cell of the plurality of pixel cells, and wherein the controller circuitry is configured to: for each LED driver of the plurality of LED drivers, receive an instance of the signal that represents the condition that the voltage drop is one of less than or equal to the minimum voltage value of the bounded range of voltage values and greater than or equal to the maximum voltage value of the bounded range of voltage values; store, in a first register, a bit for each one instance of the signal that represents the condition that an LED driver voltage drop is less than or equal to the minimum voltage value; store, in a second register, a bit for each one instance of the signal that represents the condition that an LED driver voltage drop is greater than or equal to the maximum voltage value; and adjust the supply voltage to a magnitude that is a function of numbers of bits in the first register and of numbers of bit in the second register. 6. The circuit of claim 5 , wherein the monitor circuitry is configured to sequentially sense the voltage drop across each LED driver of the plurality of LED drivers. 7. The circuit of claim 5 , wherein the monitor circuitry is configured to poll each pixel cell of the plurality of pixels to sense the voltage drop across a particular LED driver of the plurality of LED drivers. 8. The circuit of claim 5 , wherein the monitor circuitry is configured to select a particular pixel cell of the plurality of pixel cells in response to a command to sense the voltage drop across a corresponding LED driver of the plurality of LED drivers. 9. The circuit of claim 5 , wherein the monitor circuit is configured to select a particular pixel cell of the plurality of pixels in response to a command to sense magnitude of current supplied to a corresponding LED to determine whether said current is outside of regulation range. 10. A method, comprising: for at least one LED (Light Emitting Diode) driver of a plurality of LED drivers, determining a voltage drop across the at least one LED driver from a drive voltage that is output by the at least one LED driver to source current to an LED that is coupled thereto and a supply voltage that is output by a power supply to each LED driver of the plurality of LED drivers, wherein the voltage drop is determined as less than or equal to a minimum voltage value of a bounded range of voltage values or determined as greater than or equal to a maximum voltage value of the bounded range of voltage values; and based on the determining, increasing or decreasing magnitude of the supply voltage that is output by the power supply to force the voltage drop across the at least one LED driver to within the bounded range of voltage values. 11. The method of claim 10 , further comprising: adjusting the supply voltage that is output by the power supply on condition that a state of the at least one LED driver is ON state, to force the voltage drop across the at least one LED driver to within the bounded range of voltage values. 12. The method of claim 10 , further comprising: determining a voltage drop across each LED driver of the plurality of LED drivers; reading, from a first register, number of bits of a type in the first register, wherein each bit of the type in the first register represents an instance of an LED driver voltage drop that is less than or equal to the minimum voltage value of the bounded range of voltage values; reading, from a second register, number of bits of a type in the second register, wherein each bit of the type in the second register represents an instance of an LED driver voltage drop that is greater than or equal to the maximum voltage value of the bounded range of voltage values; and adjusting the supply voltage to a magnitude that is a function of number of bits in the first register and of number of bits in the second register. 13. The method of claim 12 , further comprising determining in parallel the voltage drop across each LED driver of the plurality of LED drivers. 14. The method of claim 12 , further comprising sequentially determining the voltag