Height adjustment mechanism

What is claimed is: 1. A height adjustment mechanism, the height adjustment mechanism comprising: a first latch arm that includes a first engagement structure on a first end; a first retractor that includes a first retractor channel, a first sloped surface, and a first receiving structure that is engaged with the first engagement structure of the first latch arm such that the first latch arm extends through the first retractor channel in a first lateral direction from the first retractor; a second latch arm that includes a second engagement structure on a second end; a second retractor separated from the first retractor in a second lateral direction that is opposite the first lateral direction from the second retractor, the second retractor including a second retractor channel, a second sloped surface, and a second receiving structure that is engaged with the second engagement structure of the second latch arm such that the second latch arm extends through the second retractor channel in the second lateral direction from the second retractor; and an activator defining a cavity sized to receive upper portions of the first and second retractors, the cavity being partially defined by angled lower surfaces that are positioned outwardly relative to the first sloped surface and the second sloped surface, the activator further defining arm channels that extend through the angled lower surfaces and are sized to receive the first and second latch arms, the angled lower surfaces configured to contact the sloped surfaces of retractors disposed in the cavity. 2. The height adjustment mechanism of claim 1 , wherein the angled lower surfaces are shaped such that a translation of the activator in a longitudinal direction causes the angled lower surfaces to press against the first sloped surface and the second sloped surface to draw the first retractor and the second retractor towards one another. 3. The height adjustment mechanism of claim 1 , wherein: the activator is configurable in an inactive position in which the activator is at a first longitudinal position relative to the first retractor and the second retractor to enable outward translation of the first retractor and the second retractor; and the activator is configurable in an active position in which the activator is at a second longitudinal position relative to the first retractor and the second retractor and the angled lower surfaces contact the first sloped surface and the second sloped surface to cause inward translation of the first retractor and the second retractor. 4. The height adjustment mechanism of claim 3 , wherein: the first and the second retractors, a portion of the activator, and portions of the first and second latch arms are positioned in a mechanism cavity defined by a crossbar assembly; a portion of the first latch arm extends through a first opening at a first end of the crossbar assembly when the activator is in the inactive position; and a portion of the second latch arm extends through a second opening at a second end of the crossbar assembly when the activator is in the inactive position. 5. The height adjustment mechanism of claim 4 , wherein the activator includes a protrusion that extends from the mechanism cavity in a longitudinal direction from an upper portion of the crossbar assembly. 6. The height adjustment mechanism of claim 5 , wherein: the protrusion includes a protrusion height defined between an upper surface of the crossbar assembly and a top surface of the protrusion; the upper surface of the crossbar assembly includes an arced protrusion that includes a first end that is substantially coplanar with the upper surface and a second end that includes an arced protrusion height that is substantially coplanar to the protrusion; and the second end of the arced protrusion is positioned immediately adjacent to the protrusion. 7. The height adjustment mechanism of claim 1 , further comprising a spring, wherein: the first retractor includes a first longitudinal surface opposite the first sloped surface; the second retractor includes a second longitudinal surface opposite the second sloped surface; the spring is positioned between the first longitudinal surface and the second longitudinal surface; and the spring is configured to force the first retractor from the second retractor and to force the first retractor and the second retractor against the angled lower surfaces. 8. The height adjustment mechanism of claim 7 , further comprising: a first spring retainer positioned on the first longitudinal surface; and a second spring retainer positioned on the second longitudinal surface, wherein the first spring retainer and the second spring retainer are positioned within portions of the spring. 9. The height adjustment mechanism of claim 1 , further comprising two pins wherein: the activator includes two longitudinal pin apertures; the first and second latch arms each include a lateral pin aperture that partially overlaps one of the two longitudinal pin apertures; each of the two pins is positioned in one of the longitudinal pin apertures and one of the lateral pin apertures; and the pins limit motion of the activator to a substantially longitudinal direction and limit motion of the first and second latch arms to a substantially lateral direction. 10. A leg assembly that is pivotally connected to a frame and a table top, the leg assembly comprising: a first leg subassembly that includes a first upper leg having one or more upper latch openings on an inner surface of the first upper leg, the first upper leg defining a first cavity into which a first lower leg is retractably positioned, the first lower leg having one or more lower latch openings that are selectively aligned with the one or more upper latch openings; a second leg subassembly that includes a second upper leg having one or more upper latch openings on an inner surface of the second upper leg, the second upper leg defining a second cavity into which a second lower leg is retractably positioned, the second lower leg having one or more lower latch openings that are selectively aligned with the one or more upper latch openings; a crossbar assembly positioned laterally between the first leg subassembly and the second leg subassembly, the crossbar assembly including a first opening at a first end and a second opening at a second end; a height adjustment mechanism at least partially contained in the crossbar assembly, the height adjustment mechanism comprising: a first retractor that includes a first retractor channel, a first sloped surface, and a first receiving structure; a second retractor that includes a second retractor channel, a second sloped surface; and a second receiving structure; a first latch arm that includes a first engagement structure that is engaged with the first receiving structure of the first retractor such that the first latch arm extends through the first retractor channel in a first lateral direction from the first retractor; a second latch arm that includes a second engagement structure that is engaged with the second receiving structure of the second retractor such that the second latch arm extends through the second retractor channel in a second lateral direction opposite the first lateral direction from the second retractor; and an activator defining a cavity sized to receive upper portions of the first and second retractors, the cavity being partially defined by angled lower surfaces, the activator further defining arm channels that extend through the angled lower surfaces and are sized to receive the first and second latch arms, the activator being configurable in an inactive position to enable outward translation of the fi