Distributed computing system with a synthetic data as a service scene assembly engine

The invention claimed is: 1. A system for implementing a distributed computing system scene assembly engine, the system comprising: a scene assembly engine configured to: receive a selection of a first synthetic data asset and a selection of a second synthetic data asset from a distributed synthetic data as a service (SDaaS) integrated development environment (IDE) that supports both SDaaS distributed computing service operations and SDaaS machine-learning training service operations, wherein the SDaaS distributed computing service operations are based on a service-oriented architecture that supports the SDaaS machine-learning training service operations while abstracting underlying SDaaS distributed computing service operations that are managed via an SDaaS distributed computing service, wherein the SDaaS distributed computing service operations comprise storing and retrieving source assets as synthetic data asset polygon models at varying levels of details for performing SDaaS machine-learning training service operations on the source assets, wherein a synthetic data asset is associated with asset-variation parameters and scene-variation parameters, wherein the asset-variation parameters and scene-variation parameters are programmable for machine-learning; receive values for generating a synthetic data scene, wherein the values correspond to asset-variation parameters or scene-variation parameters, wherein the values are associated with generating training datasets based on intrinsic-parameter variation and extrinsic-parameter variation, wherein intrinsic-parameter variation and extrinsic-parameter variation provide programmable machine-learning data representations of assets and scenes; and based on the values, generate the synthetic data scene using the first synthetic data asset and the second synthetic data asset. 2. The system of claim 1 , wherein the SDaaS IDE supports a machine-learning synthetic data standard comprising a file format and a dataset-training architecture. 3. The system of claim 1 , wherein the SDaaS machine learning training service operations further comprise: accessing a low polygon model synthetic data asset for a first computation operation; and accessing a high polygon model synthetic data asset for a second computation operation. 4. The system of claim 1 , further comprising a scene assembly engine client configured to: receive a query for a synthetic data asset, wherein the query is received via the SDaaS IDE; generate a query result synthetic data asset; and cause display of the synthetic data scene generated based on the query result synthetic data. 5. The system of claim 1 , wherein the scene assembly engine is further configured to generate a synthetic data scene profile comprising the first synthetic data asset, the second synthetic data asset, and the values corresponding to the asset-variation parameters or scene-variation parameters. 6. The system of claim 1 , wherein the scene assembly engine is further configured to generate the synthetic data scene based on values for scene generation received from at least two scene assembly engine clients. 7. The system of claim 1 , wherein the scene assembly engine is further configured to store the synthetic data scene in association with a scene preview and metadata. 8. One or more computer storage media storing instructions thereon for implementing a distributed computing system scene assembly engine, which, when executed by one or more processors of a computing device cause the computing device to perform actions comprising: receiving a first source asset from a first distributed Synthetic Data as a Service (SDaaS) upload interface associated with an SDaaS integrated development environment (IDE) that supports both SDaaS distributed computing service operations and SDaaS machine-learning training service operations, wherein the SDaaS distributed computing service operations are based on a service-oriented architecture that supports the SDaaS machine-learning training service operations while abstracting underlying SDaaS distributed computing service operations that are managed via an SDaaS distributed computing service, wherein the SDaaS distributed computing service operations comprise storing and retrieving source assets as synthetic data asset polygon models at varying levels of details for performing SDaaS machine-learning training service operations on the source assets, receiving a second source asset from a second a distributed SDaaS upload interface; receiving a query for a synthetic data asset, wherein the query is received via a first scene assembly engine client; accessing a query result synthetic data asset, wherein the query result synthetic data asset is associated with asset-variation parameters and scene-variation parameters, wherein the asset-variation parameters and scene-variation parameters are programmable for machine-learning; receiving a first set of values for generating a synthetic scene associated with the query result synthetic data asset, wherein the first set of values correspond to asset-variation parameters or scene-variation parameters, wherein the first set of values are associated with generating training datasets based on intrinsic-parameter variation and extrinsic-parameter variation, wherein intrinsic-parameter variation and extrinsic-parameter variation provide programmable machine-learning data representations of assets and scenes; accessing a synthetic data scene generated based on the first set of values, wherein the synthetic data scene comprises the query result synthetic data; and causing display of the synthetic data scene. 9. The media of claim 8 , wherein the SDaaS IDE supports a machine-learning synthetic data standard comprising a file format and a dataset-training architecture. 10. The media of claim 8 , wherein the actions further comprise receiving a second set of values for generating the synthetic scene, wherein the second set of values are received from a second scene assembly engine client. 11. The media of claim 10 , wherein the actions further comprise: receiving, at the first scene assembly engine client, additional values for generating the synthetic data scene via the first scene assembly engine client and the second scene assembly engine client; and causing display of the synthetic data scene generated based on the additional values. 12. The media of claim 8 , the actions further comprising: accessing a low polygon model synthetic data asset for a first computation operation; and accessing a high polygon model synthetic data asset for a second computation operation. 13. The media of claim 8 , wherein the synthetic data scene is associated with a synthetic data scene profile comprising the first synthetic data asset, the second synthetic data asset, and the values corresponding to the asset-variation parameters or scene-variation parameters. 14. The media of claim 8 , wherein causing display of the synthetic data scene comprises causing display of a scene preview and metadata. 15. A computer-implemented method for implementing a distributed computing system scene assembly engine, the method comprising: receiving a selection of a synthetic data asset from a distributed synthetic data as a service (SDaaS) integrated development environment (IDE) that supports both SDaaS distributed computing service operations and SDaaS machine-learning training service operations, wherein the SDaaS distributed computing service operations are based on a service-oriented architecture that supports the SDaaS machine-learning training service operations while abstracti