Current sensing in a USB power control analog subsystem

What is claimed is: 1. A device comprising: a power control analog subsystem of a universal serial bus-power delivery (USB-PD) compatible device, the power control analog subsystem comprising a programmable current sensing circuit; and a current sense resistor coupled to the power control analog subsystem, wherein the power control analog subsystem is configured to concurrently compare a current flow through the current sense resistor with at least three different reference values, wherein the programmable current sensing circuit comprises: a terminal coupled to the current sense resistor; a current sense amplifier coupled to the terminal to: sense a voltage across the current sense resistor; and amplify the voltage concurrently into a plurality of analog output voltages, each based on a different gain and to indicate a level of current of a power supply voltage bus (VBUS) signal; and at least three comparators coupled to the current sense amplifier. 2. The device of claim 1 , wherein the current sense resistor is coupled between the power control analog subsystem and one of a VBUS terminal or a ground terminal, wherein the ground terminal is coupled to a ground return path of a VBUS signal. 3. The device of claim 1 , wherein the current sense amplifier further comprises: a first amplifier to amplify the voltage concurrently into a first plurality of analog output voltages; a first multiplexer coupled to the first amplifier and to select one of the first plurality of analog output voltages in response to a first gain control signal; a second amplifier to amplify the voltage concurrently into a second plurality of analog output voltages that exceed the first plurality of analog output voltages; a second multiplexer coupled to the second amplifier and to select one of the second plurality of analog output voltages in response to a second gain control signal; and a third multiplexer coupled to the first multiplexer and the second multiplexer to select the first analog output voltage from between the one of the first plurality of analog output voltages and the one of the second plurality of analog output voltages in response to an analog voltage gain selection signal. 4. The device of claim 3 , wherein the first amplifier comprises: a first resistor chain to provide a plurality of first gains, which together generate the first plurality of analog output voltages; and a first variable resistor connected in series with the first resistor chain, wherein a feedback point of connection to the first variable resistor is selected based on a first output gain trim signal; and wherein the second amplifier comprises: a second resistor chain to provide a plurality of second gains, which together generate the second plurality of analog output voltages, the plurality of second gains being greater than the plurality of first gains; and a second variable resistor connected in series with the second resistor chain, wherein a feedback point of connection to the second variable resistor is selected based on a second output gain trim signal. 5. The device of claim 3 , further comprising internal offset cancellation circuitry of the first amplifier to: translate an input offset voltage of the first amplifier to a high-frequency offset signal around a DC voltage; and filter the plurality of analog output voltages with a low pass filter, to continuously filter out the higher frequency offset signal. 6. The device of claim 1 , wherein the current sense amplifier further comprises a short circuit protection (SCP) amplifier to amplify the voltage to generate an SCP analog output voltage, and wherein the device further comprises at least a fourth comparator to: compare the SCP analog output voltage with an SCP voltage reference; and trigger an SCP system interrupt in response to the SCP analog output voltage exceeding the SCP voltage reference. 7. The device of claim 1 , wherein at least three comparators are to concurrently compare respective ones of the plurality of analog output voltages with corresponding ones of a plurality of reference voltages, the device further comprising a reference generator coupled to the current sense amplifier, wherein the reference generator is programmable to generate the plurality of reference voltages in steps of approximately 10 millivolts between approximately 0.13 volts and 2.12 volts. 8. The device of claim 1 , wherein the at least three comparators are to concurrently compare respective ones of the plurality of analog output voltages with corresponding ones of a plurality of reference voltages, the device further comprising an error amplifier coupled to the current sense amplifier, the error amplifier to: determine a difference between a second analog output voltage of the plurality of analog output voltages and a second reference voltage of the plurality of reference voltages; and amplify the difference by a transconductance of the error amplifier to generate an analog feedback signal on a feedback line coupled to a midpoint of a voltage divider that is coupled to a power supply bus carrying the VBUS signal. 9. A circuit comprising a power control analog subsystem of a universal serial bus power delivery (USB-PD) compatible device, the power control analog subsystem comprising a programmable current sensing circuit configured to: use a current sense amplifier of the programmable current sensing circuit coupled to a terminal of the programmable sensing circuit to sense a voltage across a current sense resistor coupled to the power control analog subsystem, wherein the terminal is coupled to the current sense resistor; convert the voltage into at least three different analog output voltages that are indicative of a level of current in a VBUS signal of a VBUS of the USB-PD compatible device, wherein the current sense amplifier coupled to the terminal to concurrently amplify the voltage into the at least three different analog output voltages, each based on a different gain; and concurrently compare each of the at least three different analog output voltages to respective ones of at least three different reference voltages. 10. The circuit of claim 9 , wherein the current sense resistor is coupled between the power control analog subsystem and one of a VBUS terminal or a ground terminal, wherein the ground terminal is coupled to a ground return path of the VBUS signal. 11. The circuit of claim 9 , further comprising an error amplifier coupled to the current sense amplifier, the error amplifier to: determine a difference between a first analog output voltage of the at least three different analog output voltages and a first reference voltage of the at least three reference voltages; amplify the difference to generate an analog feedback signal; and translate the analog feedback signal into a current that indirectly adjusts a voltage of the VBUS, to maintain approximately a constant current on the VBUS. 12. The circuit of claim 9 , wherein the programmable current sensing circuit further comprises a plurality of comparators coupled to the current sense amplifier, the plurality of comparators to concurrently compare respective ones of the at least three different analog output voltages with corresponding ones of the at least three different reference voltages, wherein a first comparator of the plurality of comparators is to generate a digital signal comprising a system interrupt in response to detection of a first analog output voltage of the at least three different analog output voltages exceeding a corresponding first reference voltage of the at least three different reference voltages. 13. The circuit of claim 9 ,