Horizontal flex circuit with resistance weldable cover

What is claimed is: 1. A cover comprising: a plurality of walls that defines an interior cavity within the plurality of walls; a plurality of supports that extend from one or more walls of the plurality of walls; a gap defined between first and second supports of the plurality of supports, the first and second supports extending from an edge of a first wall of the plurality of walls, the gap bound on first and second opposing sides of the gap by the first and second supports and bound by the edge of the first wall on a third side of the gap that intersects the first and second opposing sides, the gap sized and shaped to receive a portion of a flex circuit into the interior cavity; and an opening disposed in a second wall of the plurality of walls, the opening sized and shaped to receive at least a portion of a barrel, the second wall different than the first wall. 2. The cover of claim 1 , wherein each of the plurality of supports is tapered. 3. The cover of claim 1 , wherein the plurality of supports each include a welding surface. 4. The cover of claim 3 , wherein each of the plurality of supports is tapered such that a first portion of the plurality of supports is narrower than a second portion of the plurality of supports, the first portion more proximate to the welding surface than the second portion. 5. The cover of claim 3 , wherein the welding surface of each of the plurality of supports is perpendicular to each wall of the plurality of walls. 6. The cover of claim 3 , wherein the welding surface of each of the plurality of supports does not exceed one or more respective planes defined by the plurality of walls. 7. The cover of claim 1 , further comprising a filler material disposed in the gap. 8. The cover of claim 1 , wherein each of the plurality of supports extends from a portion of the one or more walls of the plurality of walls. 9. An optical subassembly comprising: a heat sink stiffener; a barrel; a flex circuit; a cover comprising: a plurality of walls that defines an interior cavity within the plurality of walls; a plurality of supports that extend from one or more walls of the plurality of walls, each of the plurality of supports welded to the heat sink stiffener; a gap defined between first and second supports of the plurality of supports, the first and second supports extending from an edge of a first wall of the plurality of walls, the gap bound on first and second opposing sides of the gap by the first and second supports and bound by the edge of the first wall on a third side of the gap that intersects the first and second opposing sides, the gap sized and shaped to receive a portion of the flex circuit into the interior cavity; and an opening disposed in a second wall of the plurality of walls, at least a portion of the barrel received into the opening, the second wall different than the first wall; wherein the flex circuit is positioned such that a portion of the flex circuit is received through the gap into the interior cavity and a portion is positioned externally. 10. The optical subassembly of claim 9 , further comprising: a laser coupled to the flex circuit; and a lens positioned between the laser and the barrel, wherein the lens and the laser are both positioned within the interior cavity. 11. The optical subassembly of claim 10 , further comprising: a driver electrically coupled to the laser; and a power detection monitor (PDM) positioned to detect power of the laser, wherein the driver and the PDM are both positioned within the interior cavity. 12. The optical subassembly of claim 11 , wherein the laser, the lens, the driver, and the PDM are positioned between a top wall of the cover and the heat sink stiffener. 13. The optical subassembly of claim 9 , wherein each of the plurality of supports includes a welding surface that is welded to the heat sink stiffener. 14. The optical subassembly of claim 13 , wherein each of the plurality of supports is tapered such that a first portion of each of the plurality of supports is narrower than a second portion of each of the plurality of supports, the first portion more proximate to the welding surface than the second portion. 15. The optical subassembly of claim 13 , wherein the welding surface of each of the plurality of supports is perpendicular to each wall of the plurality of walls. 16. The optical subassembly of claim 13 , wherein the welding surface of each of the plurality of supports does not exceed one or more respective planes defined by the plurality of walls. 17. A module comprising: a housing that defines a housing cavity; a heat sink stiffener disposed within the housing cavity; a barrel disposed within the housing cavity; a flex circuit disposed within the housing cavity; a cover disposed within the housing cavity, the cover comprising: a plurality of walls that defines an interior cavity within the plurality of walls; a plurality of supports that extend from one or more walls of the plurality of walls, each of the plurality of supports welded to the heat sink stiffener; a gap defined between first and second supports of the plurality of supports, the first and second supports extending from an edge of a first wall of the plurality of walls, the gap bound on first and second opposing sides of the gap by the first and second supports and bound by the edge of the first wall on a third side of the gap that intersects the first and second opposing sides, the gap sized and shaped to receive a portion of the flex circuit into the interior cavity; and an opening disposed in a second wall of the plurality of walls, at least a portion of the barrel received into the opening, the second wall different than the first wall; wherein the flex circuit is positioned such that at least a portion of the flex circuit is received through the gap into the interior cavity of the cover, another portion is positioned external to the cover, and the flex circuit is communicatively coupled to a host device. 18. The module of claim 17 , further comprising: a laser coupled to the flex circuit; a lens positioned between the laser and the barrel; a driver electrically coupled to the laser; and a power detection monitor (PDM) positioned to detect power of the laser, wherein the laser, the lens, the driver, and the PDM are each positioned within the interior cavity. 19. The module of claim 18 , wherein the laser, the lens, the driver, and the PDM are positioned between a top wall of the cover and the heat sink stiffener. 20. The module of claim 17 , wherein: the plurality of supports of the cover each includes a welding surface that is welded to the heat sink stiffener; each of the plurality of supports is tapered such that a first portion of each of the plurality of supports is narrower than a second portion of each of the plurality of supports, the first portion more proximate to the welding surface than the second portion; the welding surface of each of the plurality of supports is perpendicular to each wall of the plurality of walls; and the welding surface of each of the plurality of supports does not exceed one or more respective planes defined by the plurality of walls.