Drive guide for fastening bits

What is claimed is: 1. A drive guide for driving fastening bits comprising: a drive shaft extending along an axis, the drive shaft having a rear shank portion configured to be coupled to a power tool and a front shaft portion extending axially forward of the rear shank portion; a socket shaft extending along the axis, the socket shaft having a rear end with a coupling that non-rotationally attaches the rear end to the front shaft portion of the drive shaft and a front end having a socket open to the front end, the socket configured to receive a fastening bit; a magnet received in the socket, the magnet configured to magnetize a fastening bit received in the socket; a generally cylindrical sliding sleeve received over the socket shaft and slidable along the axis between a rear position in which a front end of the sliding sleeve is aligned with or is axially rearward of the front end of the socket shaft and a forward position in which the front end of the sliding sleeve is axially forward of the front end of the socket shaft, the sliding sleeve having a first internal diameter and a first external diameter; an internal rear stop integrally formed inside a rear end of the sliding sleeve, the internal rear stop having a second internal diameter that is less than the first internal diameter wherein the internal rear stop is formed by swaging the rear end so that the rear end has a second external diameter that is less than the first external diameter; an external rear stop on one of the drive shaft and the socket shaft, the external rear stop positioned to abut against the internal rear stop of the sliding sleeve when the sliding sleeve is in the rear position; and an external front shoulder integrally formed on the front end of the socket shaft, the external front shoulder configured to abut against the internal rear stop when the sliding sleeve is in the forward position to prevent removal of the sliding sleeve from the socket shaft in the axial forward direction. 2. The drive guide of claim 1 , wherein the front socket comprises a front hex portion for receiving a hex shaped fastening bit and a rear counterbore that receives the magnet. 3. The drive guide of claim 1 , wherein the rear stop comprises a removable clip. 4. The drive guide of claim 1 , wherein the external rear stop comprises an external rear shoulder integrally formed on one of the drive shaft and the socket shaft. 5. The drive guide of claim 1 , further comprising an O-ring disposed on the socket shaft to frictionally resist axial movement of the sliding sleeve relative to the socket shaft. 6. The drive guide of claim 5 , wherein the O-ring is disposed on the front shoulder. 7. The drive guide of claim 1 , wherein the drive shaft is formed of a paramagnetic material and the socket shaft and sleeve each are formed of non-paramagnetic metal materials. 8. The drive guide of claim 7 , wherein the drive shaft is composed of a carbon steel material, the socket shaft is composed of a stainless steel material, and the sliding sleeve is composed of one of a brass material, an aluminum material, and a stainless steel material. 9. The drive guide of claim 1 , further comprising an air gap behind the magnet. 10. The drive guide of claim 9 , wherein the air gap is cylindrical such that the magnet does not abut a rear wall of the socket. 11. A drive guide for driving fastening bits comprising: a drive shaft extending along an axis, the drive shaft having a rear shank portion configured to be coupled to a power tool and a front shaft portion extending axially forward of the rear shank portion; a socket shaft extending along the axis, the socket shaft having a rear end with a coupling that non-rotationally attaches the rear end to the front shaft portion of the drive shaft and a front end having a socket open to the front end, the socket configured to receive a fastening bit; a magnet received in the socket with an air gap behind the magnet, the magnet configured to magnetize a fastening bit received in the socket; a generally cylindrical sliding sleeve received over the socket shaft and slidable along the axis between a rear position in which a front end of the sliding sleeve is aligned with or is axially rearward of the front end of the socket shaft and a forward position in which the front end of the sliding sleeve is axially forward of the front end of the socket shaft, the sliding sleeve having a first internal diameter and a first external diameter; an internal shoulder integrally formed inside a rear end of the sliding sleeve, the internal shoulder having a second internal diameter that is less than the first internal diameter wherein the internal rear stop is formed by swaging the rear end so that the rear end has a second external diameter that is less than the first external diameter; an external rear stop on one of the drive shaft and the socket shaft, the rear stop positioned to abut against the rear end of the sliding sleeve when the sliding sleeve is in the rear position; an external front shoulder integrally formed on the front end of the socket shaft, the front shoulder configured to abut against the internal shoulder when the sliding sleeve is in the forward position to prevent removal of the sliding sleeve from the socket shaft in the axial forward direction; and an O-ring disposed on the socket shaft to frictionally resist axial movement of the sliding sleeve relative to the socket shaft, wherein the drive shaft is composed of a paramagnetic material and the socket shaft and the sliding sleeve are each composed of a non-paramagnetic material. 12. The drive guide of claim 11 , wherein the drive shaft is composed of a carbon steel material, the socket shaft is composed of a stainless steel material, and the sliding sleeve is composed of one of a brass material, an aluminum material, and a stainless steel material.