Shaped composite ply layups and methods for shaping composite ply layups

What is claimed is: 1. A method for forming a composite component, comprising: laying up a plurality of composite plies to form a composite ply layup; partially processing the composite ply layup to form a green state layup; machining the green state layup; machining a machined sub-assembly of one or more sub-assemblies to form a machined surface of the machined sub-assembly; assembling the green state layup with the one or more sub-assemblies; and processing the green state layup and the one or more sub-assemblies to form the composite component, wherein machining the green state layup comprises removing at least a portion of a ply of the green state layup to shape the green state layup to complement a contour of the machined sub-assembly against which the green state layup is positioned, wherein machining the green state layup defines a machined surface along the green state layup, wherein machining the machined sub-assembly comprises removing at least a portion of the machined sub-assembly to form the machined surface of the machined sub-assembly, and wherein assembling the green state layup with the machined sub-assembly comprises positioning at least a portion of the machined surface of the green state layup against at least a portion of the machined surface of the machined sub-assembly to form an assembly having an interior machined interface comprising the machined surface of the green state layup and the machined surface of the machined sub-assembly. 2. The method of claim 1 , wherein partially processing the composite ply layup comprises compacting the composite ply layup. 3. The method of claim 1 , wherein processing the green state layup and the one or more sub-assemblies comprises: autoclaving the green state layup and the one or more sub-assemblies to form an autoclaved body; firing the autoclaved body to form a fired body; and densifying the fired body to form the composite component. 4. The method of claim 1 , wherein assembling the green state layup with one or more sub-assemblies comprises positioning at least a portion of the machined surface of the green state layup against at least a portion of a non-machined surface of a sub-assembly. 5. The method of claim 1 , wherein the one or more sub-assemblies comprises a plurality of wet composite plies prior to processing the green state layup and the one or more sub-assemblies. 6. The method of claim 1 , wherein the one or more sub-assemblies comprises a second green state layup having a machined surface prior to processing the green state layup and the one or more sub-assemblies. 7. The method of claim 1 , wherein the one or more sub-assemblies comprises a plurality of compacted composite plies prior to processing the green state layup and the one or more sub-assemblies. 8. The method of claim 1 , wherein the removed portion of the ply of the green state layup is along an edge of the green state layup. 9. The method of claim 1 , wherein the removed portion of the ply of the green state layup is offset from an edge of the green state layup. 10. The method of claim 1 , wherein the plurality of composite plies forming the composite ply layup are oversized to provide machine stock for machining the green state layup to predetermined dimensions. 11. The method of claim 1 , wherein the composite component is a gas turbine engine component. 12. The method of claim 1 , wherein the composite plies are formed from a ceramic matrix composite material. 13. A method for forming a composite component, comprising: laying up a plurality of composite plies to form a ply pack; partially processing the ply pack to form a green state ply pack; machining the green state ply pack to define a machined surface along the green state ply pack; machining a cavity preform to define a machined surface along the cavity preform; assembling the green state ply pack with the cavity preform; and processing the green state ply pack and cavity preform to form the composite component, wherein the composite component is a turbine nozzle airfoil, wherein machining the cavity preform comprises removing at least a portion of the cavity preform to form the machined surface of the cavity preform, and wherein assembling the green state ply pack with the cavity preform comprises positioning at least a portion of the machined surface of the green state ply pack against at least a portion of the machined surface of the cavity preform to form an assembly having an interior machined interface, the interior machined interface comprising the machined surface of the green state ply pack and the machined surface of the cavity preform. 14. The method of claim 13 , wherein the machined surface of the green state ply pack is positioned against an aft edge of the cavity preform, wherein the cavity preform is machined to remove at least a portion of the cavity preform along the aft edge such that the aft edge forms the machined surface of the cavity preform. 15. The method of claim 13 , further comprising: assembling a plurality of composite wrap plies with the green state ply pack and the cavity preform, wherein assembling the composite wrap plies comprises wrapping the plurality of composite wrap plies around the green state ply pack and the cavity preform. 16. The method of claim 13 , wherein partially processing the ply pack comprises compacting the ply pack. 17. A method for forming a composite component, comprising: laying up a plurality of composite plies to form a composite ply layup; compacting the composite ply layup to form a green state layup; machining the green state layup; machining a machined sub-assembly of one or more sub-assemblies to form a machined surface of the machined sub-assembly; assembling the green state layup with the one or more sub-assemblies; and processing the green state layup and the one or more sub-assemblies to form the composite component, wherein machining the green state layup comprises removing at least a portion of a ply of the green state layup to define a machined surface along the green state layup, wherein machining the machined sub-assembly comprises removing at least a portion of the machined sub-assembly to form the machined surface of the machined sub-assembly, and wherein assembling the green state layup with one or more sub-assemblies comprises positioning at least a portion of the machined surface of the green state layup against at least a portion of the machined surface of the machined sub-assembly to form an assembly having an interior machined interface comprising the machined surface of the green state layup and the machined surface of the machined sub-assembly.