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This is an ongoing series of commits that are reformatting our Python code. Reformatting is done with `black`. If you end up having problems merging this commit because you have made changes to a python file, the best way to handle that is to run git checkout --ours <yourfile> and then reformat it with black. If you run into any problems, post to discourse about it and we will try to help. RFC Thread below: https://discourse.llvm.org/t/rfc-document-and-standardize-python-code-style Reviewed By: MatzeB Differential Revision: https://reviews.llvm.org/D150761 |
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model | ||
CompletionModel.cmake | ||
CompletionModelCodegen.py | ||
README.md |
Decision Forest Code Completion Model
Decision Forest
A decision forest is a collection of many decision trees. A decision tree is a full binary tree that provides a quality prediction for an input (code completion item). Internal nodes represent a binary decision based on the input data, and leaf nodes represent a prediction.
In order to predict the relevance of a code completion item, we traverse each of the decision trees beginning with their roots until we reach a leaf.
An input (code completion candidate) is characterized as a set of features, such as the type of symbol or the number of existing references.
At every non-leaf node, we evaluate the condition to decide whether to go left or right. The condition compares one feature* of the input against a constant. The condition can be of two types:
- if_greater: Checks whether a numerical feature is >= a threshold.
- if_member: Check whether the enum feature is contained in the set defined in the node.
A leaf node contains the value score. To compute an overall quality score, we traverse each tree in this way and add up the scores.
Model Input Format
The input model is represented in json format.
Features
The file features.json defines the features available to the model. It is a json list of features. The features can be of following two kinds.
Number
{
"name": "a_numerical_feature",
"kind": "NUMBER"
}
Enum
{
"name": "an_enum_feature",
"kind": "ENUM",
"enum": "fully::qualified::enum",
"header": "path/to/HeaderDeclaringEnum.h"
}
The field enum
specifies the fully qualified name of the enum.
The maximum cardinality of the enum can be 32.
The field header
specifies the header containing the declaration of the enum.
This header is included by the inference runtime.
Decision Forest
The file forest.json
defines the decision forest. It is a json list of DecisionTree.
DecisionTree is one of IfGreaterNode, IfMemberNode, LeafNode.
IfGreaterNode
{
"operation": "if_greater",
"feature": "a_numerical_feature",
"threshold": A real number,
"then": {A DecisionTree},
"else": {A DecisionTree}
}
IfMemberNode
{
"operation": "if_member",
"feature": "an_enum_feature",
"set": ["enum_value1", "enum_value2", ...],
"then": {A DecisionTree},
"else": {A DecisionTree}
}
LeafNode
{
"operation": "boost",
"score": A real number
}
Code Generator for Inference
The implementation of inference runtime is split across:
Code generator
The code generator CompletionModelCodegen.py
takes input the ${model}
dir and generates the inference library:
${output_dir}/{filename}.h
${output_dir}/{filename}.cpp
Invocation
python3 CompletionModelCodegen.py \
--model path/to/model/dir \
--output_dir path/to/output/dir \
--filename OutputFileName \
--cpp_class clang::clangd::YourExampleClass
Build System
CompletionModel.cmake
provides gen_decision_forest
method .
Client intending to use the CompletionModel for inference can use this to trigger the code generator and generate the inference library.
It can then use the generated API by including and depending on this library.
Generated API for inference
The code generator defines the Example class
inside relevant namespaces as specified in option ${cpp_class}
.
Members of this generated class comprises of all the features mentioned in features.json
.
Thus this class can represent a code completion candidate that needs to be scored.
The API also provides float Evaluate(const MyClass&)
which can be used to score the completion candidate.
Example
model/features.json
[
{
"name": "ANumber",
"type": "NUMBER"
},
{
"name": "AFloat",
"type": "NUMBER"
},
{
"name": "ACategorical",
"type": "ENUM",
"enum": "ns1::ns2::TestEnum",
"header": "model/CategoricalFeature.h"
}
]
model/forest.json
[
{
"operation": "if_greater",
"feature": "ANumber",
"threshold": 200.0,
"then": {
"operation": "if_greater",
"feature": "AFloat",
"threshold": -1,
"then": {
"operation": "boost",
"score": 10.0
},
"else": {
"operation": "boost",
"score": -20.0
}
},
"else": {
"operation": "if_member",
"feature": "ACategorical",
"set": [
"A",
"C"
],
"then": {
"operation": "boost",
"score": 3.0
},
"else": {
"operation": "boost",
"score": -4.0
}
}
},
{
"operation": "if_member",
"feature": "ACategorical",
"set": [
"A",
"B"
],
"then": {
"operation": "boost",
"score": 5.0
},
"else": {
"operation": "boost",
"score": -6.0
}
}
]
DecisionForestRuntime.h
...
namespace ns1 {
namespace ns2 {
namespace test {
class Example {
public:
void setANumber(float V) { ... }
void setAFloat(float V) { ... }
void setACategorical(unsigned V) { ... }
private:
...
};
float Evaluate(const Example&);
} // namespace test
} // namespace ns2
} // namespace ns1
CMake Invocation
Inorder to use the inference runtime, one can use gen_decision_forest
function
described in CompletionModel.cmake
which invokes CodeCompletionCodegen.py
with the appropriate arguments.
For example, the following invocation reads the model present in path/to/model
and creates
${CMAKE_CURRENT_BINARY_DIR}/myfilename.h
and ${CMAKE_CURRENT_BINARY_DIR}/myfilename.cpp
describing a class
named MyClass
in namespace fully::qualified
.
gen_decision_forest(path/to/model
myfilename
::fully::qualifed::MyClass)