Leg swing trajectories

What is claimed is: 1. A method comprising: receiving, at data processing hardware of a robot, an initial position of a leg of the robot and an initial velocity of the leg of the robot; receiving, at the data processing hardware, a touchdown location for the leg and a touchdown target time for the leg, the touchdown target time representing an amount of time until the leg of the robot should touchdown at the touchdown location; determining, by the data processing hardware, a difference between the initial position of the leg and the touchdown location; separating, by the data processing hardware, the difference between the initial position of the leg and the touchdown location into a horizontal motion component and a vertical motion component; selecting, by the data processing hardware, a horizontal motion policy from a set of horizontal motion policies to satisfy the horizontal motion component, each horizontal motion policy producing a horizontal trajectory as a function of the initial position of the leg, the initial velocity of the leg, the touchdown location of the leg, and the touchdown target time of the leg; selecting, by the data processing hardware, a vertical motion policy from a set of vertical motion policies to satisfy the vertical motion component, each vertical motion policy producing a vertical trajectory as a function of the initial position of the leg, the initial velocity of the leg, the touchdown location of the leg, and the touchdown target time of the leg; and executing, by the data processing hardware, the selected horizontal motion policy and the selected vertical motion policy to swing the leg of the robot from the initial position to the touchdown location at the touchdown target time. 2. The method of claim 1 , further comprising: determining, by the data processing hardware, a most aggressive vertical motion policy of the set of vertical motion policies, the most aggressive vertical motion policy maximizing vertical acceleration of the leg within a vertical acceleration limit of the leg and maximizing vertical velocity of the leg within a vertical velocity limit of the leg, wherein selecting the horizontal motion policy from the set of horizontal motion policies comprises evaluating each horizontal motion policy of the set of horizontal motion policies with the most aggressive vertical motion policy. 3. The method of claim 1 , wherein selecting the horizontal motion policy from the set of horizontal motion policies comprises: assigning each horizontal motion policy of the set of horizontal motion policies a tier from a plurality of tiers, each tier associated with an amount of preference for selecting the respective tier, and each tier comprising a tiebreaking parameter, the tiebreaking parameter associated with each horizontal motion policy of the set of horizontal motion policies; and selecting the horizontal motion policy from the set of horizontal motion policies based on the assigned tiers and the tiebreaking parameters. 4. The method of claim 3 , wherein the tiebreaking parameter comprises a total undesirability based on a sum of a horizontal undesirability and a vertical undesirability. 5. The method of claim 1 , wherein selecting the vertical motion policy from the set of vertical motion policies occurs after selecting the horizontal motion policy from the set of horizontal motion policies. 6. The method of claim 5 , wherein selecting the vertical motion policy from the set of vertical motion policies comprises selecting the vertical motion policy from the set of vertical motion policies associated with a minimum acceleration and a minimum velocity that satisfies the vertical motion component. 7. The method of claim 1 , further comprising: receiving, at the data processing hardware, an indication of a trip by the robot; and in response to receiving the indication of the trip by the robot, selecting, by the data processing hardware, one of: a horizontal motion policy from a second set of horizontal motion policies, the second set of horizontal motion policies associated with tripping; or a vertical motion policy from a second set of vertical motion policies, the second set of vertical motion policies associated with tripping. 8. The method of claim 1 , wherein selecting the horizontal motion policy from the set of horizontal motion policies comprises: evaluating each horizontal motion policy of the set of horizontal motion policies with a first analysis; and evaluating a sub-set of the set of horizontal motion policies with a second analysis based on the first analysis; wherein the second analysis is more detailed than the first analysis. 9. The method of claim 1 , further comprising: receiving, at the data processing hardware, the touchdown target time for each of a plurality of legs of the robot; determining, at the data processing hardware, a touchdown order of the legs based on the touchdown target time for each of the plurality of legs of the robot; and selecting, by the data processing hardware, the horizontal motion policy and the vertical motion policy for each leg in a planning order based on the touchdown order. 10. The method of claim 1 , wherein each vertical motion policy of the set of vertical motion policies comprises a maximum velocity, a maximum acceleration, and a swing height. 11. The method of claim 1 , wherein at least one horizontal motion policy of the set of horizontal motion policies comprises a lateral motion policy and a longitudinal motion policy. 12. A robot comprising: a body; legs coupled to the body and configured to maneuver the robot about an environment; data processing hardware in communication with the legs; and memory hardware in communication with the data processing hardware, the memory hardware storing instructions that when executed on the data processing hardware cause the data processing hardware to perform operations comprising: receiving an initial position of a leg of the robot and an initial velocity of the leg of the robot; receiving a touchdown location for the leg and a touchdown target time for the leg, the touchdown target time representing an amount of time until the leg of the robot should touchdown at the touchdown location; determining a difference between the initial position of the leg and the touchdown location; separating the difference between the initial position of the leg and the touchdown location into a horizontal motion component and a vertical motion component; selecting a horizontal motion policy from a set of horizontal motion policies to satisfy the horizontal motion component, each horizontal motion policy producing a horizontal trajectory as a function of the initial position of the leg, the initial velocity of the leg, the touchdown location of the leg, and the touchdown target time of the leg; selecting a vertical motion policy from a set of vertical motion policies to satisfy the vertical motion component, each vertical motion policy producing a vertical trajectory as a function of the initial position of the leg, the initial velocity of the leg, the touchdown location of the leg, and the touchdown target time of the leg; and executing the selected horizontal motion policy and the selected vertical motion policy to swing the leg of the robot from the initial position to the touchdown location at the touchdown target time. 13. The robot of claim 12 , wherein the operations further comprise: determining a most aggressive vertical motion policy of the set of vertical motion policies, the most aggressive vertical policy maximizing vertical acceleration of the leg within a vertical acceleration limit of the le