Digital clock-duty-cycle correction

What is claimed is: 1. A clock generator, comprising: a duty cycle correction circuit, comprising: a charge pump comprising: a current source; a first output; and a second output; wherein the charge pump is configured to: route current from the current source to the first output during a positive portion of a clock; and route current from the current source to the second output during a negative portion of the clock; and a controller configured to: compare charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles to determine which of the positive portion of the clock and the negative portion of the clock is longer; generate a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock based on which of the positive portion of the clock and the negative portion of the clock is longer; wherein the controller is configured to reset the charge accumulated from the first output and the charge accumulated from the second output by setting the first output and the second output to a same voltage prior to an initial one of the plurality of clock cycles; further comprising a multiplexer coupled to the charge pump, the multiplexer configured to route a predetermined voltage to the charge pump to reset the charge prior to the plurality of clock cycles, and to route the plurality of clock cycles to the charge pump after the charge has been reset. 2. A clock generator, comprising: a duty cycle correction circuit, comprising: a charge pump comprising: a current source; a first output; and a second output; wherein the charge pump is configured to: route current from the current source to the first output during a positive portion of a clock; and route current from the current source to the second output during a negative portion of the clock; and a controller configured to: compare charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles to determine which of the positive portion of the clock and the negative portion of the clock is longer; generate a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock based on which of the positive portion of the clock and the negative portion of the clock is longer; further comprising calibration circuitry comprising: a first inversion circuit configured to controllably invert the clock at inputs of the charge pump; a second inversion circuit configured to controllably invert a result of comparison of charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles inverted by the first inversion circuitry; wherein the controller is configured to: determine a value of offset in the clock generator based on the digital value applied to produce a 50% duty cycle while the clock is inverted and the digital value applied to produce a 50% duty cycle while the clock is not inverted. 3. The clock generator of claim 2 , wherein the calibration circuitry is configured to adjust a component of the duty cycle correction circuit to compensate for the offset. 4. A clock duty cycle correction circuit comprising: a charge pump comprising: a current source; a first current output terminal; a second current output terminal; a first clock input terminal; a second clock input terminal; and a first transistor coupled to the current source, the first clock input terminal, and the first current output terminal to connect the current source to the first output terminal based on assertion of a clock signal at the first clock input terminal; a second transistor coupled to the current source, the second clock input terminal, and the second current output terminal to connect the current source to the second output terminal based on assertion of an inverted version of the clock signal at the second clock input terminal; a reset terminal; and a reset transistor coupled to the first current output terminal, the second current output terminal, and the reset terminal to short the first current output terminal to the second current output terminal based on assertion of a reset signal at the reset terminal; and a controller configured to: compare charge accumulated from the first current output to charge accumulated from the second current output over a plurality of cycles of the clock signal to determine which of a positive portion of the clock signal and a negative portion of the clock signal is longer; and generate a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock signal based on which of the positive portion of the clock signal and the negative portion of the clock signal is longer; further comprising a multiplexer coupled to the charge pump, the multiplexer configured to route a predetermined voltage to the first clock input terminal and the second clock input terminal to reset the charge prior to the plurality of clock cycles, and to route the plurality of clock cycles to the first clock input terminal and the second clock input terminal after the charge has been reset. 5. A clock duty cycle correction circuit comprising: a charge pump comprising: a current source; a first current output terminal; a second current output terminal; a first clock input terminal; a second clock input terminal; and a first transistor coupled to the current source, the first clock input terminal, and the first current output terminal to connect the current source to the first output terminal based on assertion of a clock signal at the first clock input terminal; a second transistor coupled to the current source, the second clock input terminal, and the second current output terminal to connect the current source to the second output terminal based on assertion of an inverted version of the clock signal at the second clock input terminal; a reset terminal; and a reset transistor coupled to the first current output terminal, the second current output terminal, and the reset terminal to short the first current output terminal to the second current output terminal based on assertion of a reset signal at the reset terminal; and a controller configured to: compare charge accumulated from the first current output to charge accumulated from the second current output over a plurality of cycles of the clock signal to determine which of a positive portion of the clock signal and a negative portion of the clock signal is longer; and generate a digital value that indicates an amount of adjustment to apply to a duty cycle of the clock signal based on which of the positive portion of the clock signal and the negative portion of the clock signal is longer; further comprising: calibration circuitry comprising: a first inversion circuit configured to controllably invert the clock at inputs of the charge pump; a second inversion circuit configured to controllably invert a result of comparison of charge accumulated from the first output to charge accumulated from the second output over a plurality of clock cycles inverted by the first inversion circuitry; and wherein the controller is configured to determine a value of offset in the clock generator based on the digital value applied to produce a 50% duty cycle while the clock is inverted and the digital value applied to produce a 50% duty cycle while the clock is not inverted; and wherein the calibration circuitry is configured to compensate for the offset. 6. A method for correcting duty cycle of a clock signal, comprising: resetting charge storage elements to a same voltage prior to execution of an integration stage; during the integration stage: changing charge stored o