Controlling a casing running tool

1 . A top drive assembly, comprising: a top drive configured to be coupled to a rig; a casing running tool configured to be fluidly coupled to and driven by the top drive; and a gear assembly configured to engage the top drive and the casing running tool to transmit torque from the top drive to the casing running tool, the gear assembly configured to at least one of reverse a direction of torque between the top drive and the casing running tool or change a rotational speed between the top drive and the casing running tool. 2 . The top drive assembly of claim 1 , wherein the top drive and the casing running tool each comprise an external helix, and the gear assembly comprises one or more gear shafts configured to engage the external helixes and transmit torque from the top drive to the casing running tool. 3 . The top drive assembly of claim 2 , wherein the gear assembly comprises a plurality of gear shafts each controllable to selectively engage or disengage the external helixes, allowing the top drive to rotate at a different speed than or independently from the casing running tool. 4 . The top drive assembly of claim 2 , wherein the gear assembly comprises two gear shafts each comprising two helixes of opposite hands, the two gear shafts configured to engage and rotate the casing running tool in a direction opposite to the top drive. 5 . The top drive assembly of claim 2 , wherein the gear assembly comprises two gear shafts each comprising two helixes of common hand, one of the two helixes defining a dimension different from a dimension from the other of the two helixes such that, when engaged with the top drive and the casing running tool, the two gear shafts rotate the casing running tool at an output speed different from an input speed from the top drive. 6 . The top drive assembly of claim 5 , wherein the gear assembly comprises two other gear shafts each comprising two other helixes of common hand, one of the two helixes defining a dimension different from a dimension from the other of the two other helixes such that, when engaged with the top drive and the casing running tool, the two other gear shafts rotate the casing running tool at a second output speed different from the output speed and different from the input speed from the top drive. 7 . The top drive assembly of claim 1 , further comprising a system comprising one or more computers in one or more locations, the system configured to transmit instructions to a controller coupled to an actuator configured to move, in response to instructions from the controller, at least one of i) the gear assembly to change speed or direction of rotation of the casing running tool or ii) the casing running tool to change an angle or position of the casing running tool. 8 . The top drive assembly of claim 7 , further comprising a sensor system coupled to the casing running tool, the system configured to: determine, as a function of feedback from the sensor system, an angle of the casing running tool, compare the angle of the casing running tool to an angle of a wellbore, determine that the angle of the casing running tool is different than the angle of the wellbore, and transmit instructions to the controller to control the actuator to align the casing running tool with respect to the angle of the wellbore. 9 . The top drive assembly of claim 8 , wherein the sensor system comprises a micro-electromechanical system (MEMS) gyroscope, the angle of the casing running tool comprises an angle of a central longitudinal axis of the casing running tool, and the angle of the wellbore comprises an angle of a central longitudinal axis of the wellbore. 10 . The top drive assembly of claim 8 , wherein the casing running tool is rotationally coupled to the top drive through a flexible pipe that allows moving an angle of a central longitudinal axis of the casing running tool with respect to an angle of a central longitudinal axis of the top drive. 11 . The top drive assembly of claim 7 , further comprising a non-transitory computer-readable storage medium coupled to the system and storing instructions that, when executed by the system, causes the system to perform operations comprising: receiving feedback from one or more sensors at a powerslip coupled to a wellbore; and as a function of the sensor feedback, releasing the powerslip. 12 . A method, comprising: engaging, with a casing running tool, a wellbore tubular; rotating, by a top drive, the casing running tool to connect or disconnect the wellbore tubular to or from a second tubular; wherein the top drive is configured to transmit torque to the casing running tool through a gear assembly configured to engage the top drive and the casing running tool, and the rotating comprises transmitting torque to the casing running tool through the gear assembly to at least one of reverse a direction of torque between the top drive and the casing running tool or change a rotational speed between the top drive and the casing running tool. 13 . The method of claim 12 , further comprising aligning the casing running tool with a central longitudinal axis of a wellbore. 14 . The method of claim 13 , wherein the rotating and aligning comprise automatically rotating and aligning, as a function of feedback from sensors or other input, the casing running tool during a makeup operation or a break out operation. 15 . The method of claim 12 , wherein the gear assembly comprises a plurality of gear shafts each controllable to selectively engage or disengage external helixes of the top drive and the casing running tool, and the rotating comprises engaging and rotating two of the plurality of gear shafts by the respective external helix of the top, allowing the top drive to rotate at a different speed than or direction from the casing running tool.