The process of generation of target assets from an input model (generation session) includes 5 stages:
We will discuss the first three stages of this process in detail.
To define the required generators, MPS examines the input model and determines which languages are used in it. Doing this job MPS doesn't make use of 'Used Languages' specified in the model properties dialog. Instead MPS examines each node in the model and gathers languages that are actually used.
From each 'used language' MPS obtains its generator module. If there are more than one generator module in a language, MPS chooses the first one (multiple generators for the same language are not fully supported in the current version of MPS). If any generator in this list depends on other generators (as specified in the 'depends on generators' property), then those generators are added to the list as well.
After MPS obtains the initial list of generators, it begins to scan the generator's templates in order to determine what languages will be used in intermediate (transient) models. The languages detected this way are handled in the same manner as the languages used in the original input model. This procedure is repeated until no more 'used languages' can be detected.
In some rare cases, MPS is unable to detect the language whose generator must be involved in the model transformation. This may happen if that language is not used in the input model or in the template code of other (detected) languages. In this case, you can explicitly specify the generator engagement via the Languages Engaged on Generation section in the input model's properties dialog (Advanced tab).
As we discussed earlier, a generator module contains generator models, and generator models contain mapping configurations. Mapping configuration (mapping for short) is a set of generator rules. It is often required that some mappings must be applied before (or not later than, or together with) some other mappings. The language developer specifies such a relationship between mappings by means of mapping constraints in the generator properties dialog (see also #Mapping Priorities and the Dividing Generation Process into Steps demo).
After MPS builds the list of involved generators, it divides all mappings into groups, according to the mapping priorities specified. All mappings for which no priority has been specified fall into the last (least-priority) group.
You can check the mapping partitioning for any (input) model by selecting Show Mapping Partitioning action in the model's popup menu.
Each group of mappings is applied in a separate generation step. The entire generation session consists of as many generation steps as there were mapping groups formed during the mapping partitioning. The generation step includes three phases:
The template-based model transformation phase consists of one or more micro-steps. The micro-step is a single-pass model transformation of input model into a transient (output) model.
While executing micro-step MPS follows the next procedure:
There is no separate stage for the application of reduction and pattern rules. Instead, every time MPS copies an input node into the output model, it attempts to find an applicable reduction (or pattern) rule. MPS performs the node copying when it is either copying a root node or executing a COPY_SRC-macro. Therefore, the reduction can occur at either stage of the model transformation.
MPS uses the same rule set (mapping group) for all micro-steps within the generation step. After a micro-step is completed and some transformations have taken place during its execution, MPS starts the next micro-step and passes the output model of the previous micro-step as input to the next micro-step. The whole generation step is considered completed if no transformations have occurred during the execution of the last micro-step, that is, when there are no more rules in the current rule set that are applicable to nodes in the current input model.
The next generation step (if any) will receive the output model of previous generation step as its input.
Intermediate models (transient models) that are the output/input of generation steps and micro-steps are normally destroyed immediately after their transformation to the next model is completed.