Fastener driver

The invention claimed is: 1. A driver for gripping a socketed fastener head, the driver comprising: a shank; two spaced-apart cantilever beams extending from the shank and defining a longitudinal gap between them, each cantilever beam having an end and a basal segment adjacent the shank, the basal segments of the two cantilever beams being immovable relative to the shank; a sliding shim positioned in the gap, the sliding shim and the cantilever beams being configured so that movement of the sliding shim toward the ends increases outward forces on the cantilever beams for gripping the socketed fastener head; and a stop protrusion extending into the gap and configured to contact and engage with the sliding shim to prevent movement of the sliding shim beyond the stop protrusion in the direction of the ends. 2. The driver of claim 1 , wherein the socketed fastener head presents a top surface, a socket is formed in and below the top surface, and the socket presents a first substantially vertical surface and a second substantially vertical surface across the socket from the first substantially vertical surface, with the driver comprising an outward-facing surface on the end of each of the two cantilever beams, the outward-facing surfaces being oriented, when assembled to the socketed fastener head, to apply forces outward on the first and second substantially vertical surfaces in response to bending of the two cantilever beams from resting positions. 3. The driver of claim 2 , wherein the two ends are configured to abut one another when assembled to the fastener. 4. The driver of claim 2 , wherein the driver is configured such that at least a portion of the gap between the ends remains when the driver is assembled to the socketed fastener head. 5. The driver of claim 1 , wherein the ends of the cantilever beams each present a cross-section having the shape of an isosceles trapezoid. 6. The driver of claim 1 , wherein the ends of the cantilever beams each present a cross-section having a rectangular shape. 7. The driver of claim 1 , wherein each end of the two cantilever beams includes a tip and a substantially orthogonal outward-facing surface. 8. The driver of claim 1 , wherein each end of the two cantilever beams includes a tip, an outward-facing surface, and an angled entry surface between the tip and the outward facing surface configured to facilitate insertion of the driver into the socketed fastener head. 9. The driver of claim 1 , further comprising a track of translational protrusions extending inside the gap between the stop protrusion and the shank, the track of translational protrusions defining cradles therebetween for receipt of the sliding shim and incremental movement of the sliding shim with respect to the track of translational protrusions and along the gap. 10. The driver of claim 1 , wherein the gap defined by the two cantilever beams in resting positions narrows as it extends from the shank toward the ends. 11. The driver of claim 1 , wherein the sliding shim includes fins positioned on opposite sides of the gap. 12. A driver for gripping a socketed fastener head, the driver comprising: a shank; a handle fixed relative to the shank in a longitudinal direction; two spaced-apart cantilever beams fixed relative to the shank in the longitudinal direction, extending from the shank in the longitudinal direction, and defining a longitudinal gap between them, each of the two cantilever beams having a basal segment adjacent the shank and an end terminating at a tip; a sliding shim configured for translational movement relative to the cantilever beams, the sliding shim having a lateral length extending to opposite sides of the cantilever beams, a gap segment between the cantilever beams, and first and second fins positioned on the opposite sides of the cantilever beams, the first and second fins each having a thickness that is greater than a thickness of the gap segment in a direction, the direction being substantially orthogonal to the longitudinal direction and also being substantially orthogonal to the lateral direction, the greater thicknesses of the fins being configured to restrict movement of the sliding shim in the lateral direction; and a stop protrusion extending into the gap and configured to prevent movement of the sliding shim beyond the stop protrusion in the direction of the ends. 13. The driver of claim 12 , further comprising a track of translational protrusions extending inside the gap between the stop protrusion and the shank, the track of translational protrusions defining cradles therebetween for receipt of the sliding shim and incremental movement of the sliding shim with respect to the track of translational protrusions and along the gap. 14. The driver of claim 12 , wherein the gap defined by the two cantilever beams in resting positions narrows as it extends from the shank toward the open end. 15. A method for installing a fastener having a socketed head presenting a top surface and a socket formed in and below the top surface, the method comprising: providing a driver having two cantilever beams and a shank, each cantilever beam including an outward-facing surface, an end, and a basal segment adjacent the shank, the basal segments of the two cantilever beams being immovable relative to the shank; aligning the driver with a socket of the socketed fastener head; applying a force to the shank of the driver generally in the direction of the socketed fastener head causing the cantilever beams to move toward one another to permit at least partial insertion into the socket; applying a force to a sliding shim in a gap between the cantilever beams generally in the direction of the socketed fastener head to press the sliding shim in a translational movement, thereby applying a pressure on the socket; and settling the sliding shim against a stop protrusion positioned in the gap between the two cantilever beams, the stop protrusion in the gap preventing movement of the sliding shim beyond the stop protrusion in the direction of the socket. 16. The method of claim 15 , further comprising, prior to settling the sliding shim against the stop protrusion, translating the sliding shim over a translational protrusion of a track of translational protrusions extending inside the gap between the stop protrusion and the shank. 17. The method of claim 16 , further comprising settling the sliding shim in a cradle defined between the translational protrusion and a next-adjacent translational protrusion of the track of translational protrusions. 18. The method of claim 17 , comprising torqueing the driver to install the socketed fastener in a receiving surface followed by applying a force to the sliding shim generally in a direction opposite the socketed fastener head to at least partially reduce the pressure applied by the cantilever beams on the socket. 19. The method of claim 18 , wherein the force in the direction opposite the socketed fastener head moves the sliding shim out of the cradle, over the translational protrusion and away from the next-adjacent translational protrusion.