Assessing deflections experienced by a workpiece during computer controlled machining with a toolpath to determine stock amount

What is claimed is: 1. A computer-implemented method comprising: obtaining, in a computer-aided design or manufacturing program, a finishing toolpath specification for three dimensional geometry of a three-dimensional model of a part to be machined by a computer-controlled manufacturing system from a workpiece; generating three dimensional geometry of a model of a semi-finished structure on which a finishing operation according to the finishing toolpath specification is to be performed, wherein the three dimensional geometry of the model of the semi-finished structure has a stock allowance determined in accordance with a computer simulation of deflections experienced by the workpiece as stock material is cut during the finishing operation from the workpiece by the computer-controlled manufacturing system using the finishing toolpath specification to form the part from the workpiece; creating a semi-finishing toolpath specification for the three dimensional geometry of the model of the semi-finished structure; and providing the semi-finishing toolpath specification for use in machining the part by the computer-controlled manufacturing system by cutting away a first portion of the stock material using the semi-finishing toolpath specification to form the semi-finished structure from the workpiece, followed by performing the finishing operation of the semi-finished structure by cutting away a second portion of the stock material to form the part from the workpiece. 2. The computer-implemented method of claim 1 , wherein obtaining the finishing toolpath specification comprises creating the finishing toolpath specification based on the three dimensional model of the part and user input regarding one or more cutting conditions. 3. The computer-implemented method of claim 1 , comprising modifying the finishing toolpath specification based on the created semi-finishing toolpath specification, wherein the finishing operation uses the modified finishing toolpath specification. 4. The computer-implemented method of claim 1 , comprising: generating three dimensional geometry of a model of a roughed structure in accordance with a computer simulation of deflections experienced by the workpiece as stock material is cut from the workpiece by the computer-controlled manufacturing system using the semi-finishing toolpath specification; creating a roughing toolpath specification for the three dimensional geometry of the model of the roughed structure; and providing the roughing toolpath specification for use in machining the part by the computer-controlled manufacturing system by cutting away a third portion of the stock material using the roughing toolpath specification to form the roughed structure from the workpiece before performing the semi-finishing operation on the roughed structure. 5. The computer-implemented method of claim 1 , comprising: obtaining (i) the three dimensional model of the part, (ii) first information regarding material properties of the workpiece, (iii) second information regarding one or more cutting tools to be used by the computer-controlled manufacturing system, and (iv) cutting conditions of the finishing toolpath specification, wherein the cutting conditions include a maximum depth of cut; and performing the computer simulation of tooling forces experienced by the workpiece as stock material is cut from the workpiece by the computer-controlled manufacturing system using the finishing toolpath specification and various depths of cut that are equal to or less than the maximum depth of cut. 6. The computer-implemented method of claim 5 , wherein performing the computer simulation comprises: calculating multiple three dimensional models of the semi-finished structure, wherein each of the multiple three dimensional models has a different stock allowance; simulating machining of the part from each of the multiple three dimensional models using the one or more cutting tools of the computer-controlled manufacturing system; and selecting one of the multiple three dimensional models having a best response to the deflection forces calculated during the simulating. 7. The computer-implemented method of claim 6 , wherein performing the computer simulation comprises: selecting an initial semi-finished stock amount to indicate a first one of the multiple three dimensional models; performing numerical toolpath simulation using finite element analysis to simulate the machining of the part; assessing the deflections experienced by the workpiece in accordance with the finite element analysis of the numerical toolpath simulation; incrementally adding or removing semi-finished stock amount, based on the assessed deflections, to indicate a next one of the multiple three dimensional models; and repeating the performing the numerical toolpath simulation, the assessing the deflections, and the incrementally adding or removing the semi-finished stock amount to optimize the semi-finished stock amount. 8. The computer-implemented method of claim 6 , comprising receiving input specifying a machining preference among (i) manufacturing speed, (ii) surface finish quality, (iii) maximizing tool life, and (iv) minimizing vibration, wherein the calculating, simulating and selecting is performed in accordance with the machining preference. 9. The computer-implemented method of claim 6 , wherein calculating the multiple three dimensional models comprises calculating, for each model, a stock allowance that varies continuously along a length of the part. 10. The computer-implemented method of claim 1 , wherein the computer-controlled manufacturing system comprises one or more computer processing apparatus including at least one non-transitory computer-readable medium encoding the computer aided design or manufacturing program. 11. A system comprising: a data processing apparatus including at least one hardware processor; and a non-transitory computer-readable medium encoding instructions of a computer-aided design or manufacturing program, the instructions being configured to cause the data processing apparatus to obtain a finishing toolpath specification for three dimensional geometry of a three-dimensional model of a part to be machined by a computer-controlled manufacturing system from a workpiece; generate three dimensional geometry of a model of a semi-finished structure on which a finishing operation according to the finishing toolpath specification is to be performed, wherein the three dimensional geometry of the model of the semi-finished structure has a stock allowance determined in accordance with a computer simulation of deflections experienced by the workpiece as stock material is cut during the finishing operation from the workpiece by the computer-controlled manufacturing system using the finishing toolpath specification to form the part from the workpiece; create a semi-finishing toolpath specification for the three dimensional geometry of the model of the semi-finished structure; and provide the semi-finishing toolpath specification for use in machining the part by the computer-controlled manufacturing system by cutting away a first portion of the stock material using the semi-finishing toolpath specification to form the semi-finished structure from the workpiece, followed by performing the finishing operation of the semi-finished structure by cutting away a second portion of the stock material to form the part from the workpiece. 12. The system of claim 11 , wherein the non-transitory computer-readable medium encodes the instructions configured to cause the data processing apparatus to modify the finishing toolpath specification based on the created semi-finishing t