Slim hole float sub

What is claimed is: 1 . A downhole tool, comprising: a housing having an inner surface, wherein an inner groove is formed in the inner surface; a body positioned in the housing; and a plurality of retention members positioned at least partially within the inner groove, wherein the retention members initially prevent the body from moving in a downhole direction relative to the housing, and wherein the retention members are configured to yield, which allows the body to move in the downhole direction relative to the housing. 2 . The downhole tool of claim 1 , wherein the retention members are circumferentially offset from one another in the inner groove. 3 . The downhole tool of claim 1 , wherein the retention members comprise tabs, wherein each tab has an outer portion and an inner portion, wherein the outer portion is positioned within the inner groove, and wherein the inner portion is configured to contact the body. 4 . The downhole tool of claim 3 , wherein the outer portion forms a dovetail connection with the inner groove, and wherein the inner portion is configured to yield in response to a predetermined force exerted thereon by the body. 5 . The downhole tool of claim 1 , wherein the inner groove includes a slot that has a greater width than a remainder of the inner groove, and wherein the retention members are configured to be introduced radially-outward through the slot and into the inner groove. 6 . The downhole tool of claim 5 , wherein the retention members are configured to slide circumferentially within the inner groove after being introduced via the slot, and wherein the retention members are prevented from being removed from the inner groove when the retention members are misaligned with the slot. 7 . The downhole tool of claim 1 , wherein the housing defines a port extending radially therethrough, wherein the port is configured to receive the retention members therethrough, and wherein the retention members comprise balls. 8 . The downhole tool of claim 7 , wherein the body has an outer surface, wherein an outer groove is formed in the outer surface, wherein the inner groove and the outer groove are concentric, and wherein the balls are positioned at least partially within and between the inner groove and the outer groove. 9 . The downhole tool of claim 1 , wherein the housing defines a shoulder therein, and wherein the body is configured to impact the shoulder and break apart after the retention members yield. 10 . The downhole tool of claim 9 , wherein the body defines a beveled nose that is configured to fit at least partially through the shoulder prior to the body breaking apart. 11 . A casing float sub for use in a well, the casing float sub comprising: a housing having an inner surface, wherein a groove and a shoulder are formed in the inner surface, and wherein the groove includes a slot that has a greater width than a remainder of the groove; a body positioned in the housing, wherein the body defines a beveled nose that is configured to fit at least partially through the shoulder; and a plurality of tabs positioned at least partially within the groove, wherein the tabs are configured to be introduced radially-outward through the slot and into the groove, wherein the tabs are configured to slide circumferentially within the groove after being introduced via the slot such that the tabs become circumferentially offset from one another within the groove, wherein the tabs are prevented from being removed from the groove when the tabs are misaligned with the slot, wherein each tab has an outer portion and an inner portion, wherein the outer portions form dovetail connections within the groove, wherein the inner portions are configured to contact the body, wherein the inner portions initially prevent the body from moving in a downhole direction relative to the housing, wherein the inner portions are configured to yield in response to a predetermined force exerted therein by the body, which allows the body to move in the downhole direction relative to the housing, and wherein the body is configured to impact the shoulder and break apart after the inner portions yield. 12 . A method, comprising: positioning a body in a housing, wherein the housing has an inner surface, and wherein a groove is formed in the inner surface; positioning a plurality of retention members at least partially within the groove, wherein the retention members initially prevent the body from moving in a downhole direction relative to the housing; deploying the body, the housing, and the retention members into a well; and increasing a pressure of a fluid in the well, which causes the retention members to yield, and wherein the body moves relative to the housing in response to the increased pressure and the retention members yielding. 13 . The method of claim 12 , wherein positioning the retention members comprises: loading the retention members into an installation tool; positioning the installation tool, with the retention members loaded therein, into the housing; and transferring the retention members from the installation tool to the groove in the inner surface of the housing. 14 . The method of claim 13 , wherein the retention members are loaded into recesses formed in an axial end of the installation tool, and wherein the recesses are circumferentially offset from one another. 15 . The method of claim 14 , wherein positioning the retention members further comprises abutting the axial end of the installation tool with the body while the retention members are transferred. 16 . The method of claim 13 , wherein the groove includes a slot that has a greater width than a remainder of the groove, and wherein positioning the retention members further comprises rotating the housing until the slot is positioned at a bottom of the housing such that the retention members are transferred radially-outward, via gravity, through the slot and into the groove. 17 . The method of claim 13 , wherein the groove includes a slot that has a greater width than a remainder of the groove, and wherein positioning the retention members further comprises: rotating the installation tool a first time relative to the housing, which causes a first of the retention members to be transferred from the installation tool, through the slot, and into the groove; and rotating the installation tool a second time relative to the housing, which pushes the first retention member out of alignment with the slot, wherein the first retention member is prevented from being removed from the groove when the first retention member is out of alignment with the slot, and wherein rotating the installation tool a second time also causes a second of the retention members to be transferred from the installation tool, through the slot, and into the groove, such that the first and second retention members are circumferentially offset from one another in the groove. 18 . The method of claim 12 , further comprising: determining the pressure that causes the retention members to yield; and selecting a number of relatively hard retention members and a number of relatively soft retention members based on the pressure that causes the retention members to yield, wherein the retention members that are positioned within the groove comprise the number of relatively hard retention members and the number of relatively soft retention members. 19 . The method of claim 12 , wherein installing the plurality of retention members comprises: introducing the retention members thro