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@bfwk/expression-completion

LBF Expression Completion Engine

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Expression Completion Engine

The Expression Completion Engine is a general purpose editor/validator for expressions defined by an ANTLR grammar and with input contexts described by JSON Schema.

The grammar is a superset of the legacy expression grammar (Formula.g4). In order to use a grammar for code completion it is useful to inject various rules to facilitate the discovery of a token's scope wrt completion, so there is some rule redefinition.

This uses the Javascript ANTLR4 runtime.

Development

The build target includes a code generation step, based upon the grammar (UnifiedExpression.g4), to create various grammar specific source files in a non-repository gen/ directory. The code generator is Java-based and saved in the repository in the bin/ directory. Directions for running the code generator are available on the ANTLR site.

Do NOT checkin changes to the grammar without rebuilding and testing first - the generated sources will be altered and, while not saved in the repo, might become incompatible with the other source files.

Note that we use an unchanged reference copy of the legacy parser and lexer grammars which we then munge slightly into a local copy for import into the unified grammars. The cpgrammars.sh script is the only place that is aware of these reference grammars. The rest of the build process uses locally generated versions in place. For now the legacy grammars are copied into our repo, but they could be dynamically recovered from their home repo at some point. The script might need changes to keep the locally generated grammars consistent with our local expectations (documented within the script).

Future Directions

As the grammar is expanded in subsequent releases we might want to consider the use of this code completion engine. This was not used in 232 because of difficulties rolling up the Typescript ANTLR4 runtime upon which it depends. An early cut using this is available on the branch https://git.soma.salesforce.com/BuilderFramework/builder-framework/tree/drobertson/DO-NOT-DELETE-typescript-completion-engine

How it Works

The completion engine works generally as follows:

  1. Parse the candidate expression (often incomplete or otherwise non-grammar compliant) to get a token stream
  2. Locate the token most closely "associated" with the input caret position
  3. Locate the completion candidates associated with that token
  4. Optionally apply a candidate to the expression to create a new expression with a new caret position and a "smart" substitution

Step 2. Finding the token (token-finder.ts)

We need to navigate the parse tree to find the terminal node at the caret position. Note that this does not have to be at the end of the expression - the user might have clicked into the input field or left-arrowed to a position within the current expression.

This is the bulk of the logic. This is where semantic knowledge is introduced.

In order to capture the semantic state of the expression it is necessary to "massage" the base grammar so that the parser listener is triggered at semantically useful moments. This is easiest done by introducing parser rules at appropriate points within the grammar. This allows such things as sensible completion suggestions after a dot and scoping of candidates within nested field references.

The symbol table that is built by the listener during the parse process is keyed on token. That is how the completion candidates are associated with the input token found during Step 2. The symbol table represents the aggregate semantic knowledge of the expression (wrt completion anyway) at any token position.

The current implementation strives to base itself off the legacy formula grammar without requiring changes to it that would be visible to other consumers. It does this by manipulating the parser and lexer grammars "in-place" through a number of ANTLR tricks.

Entry points

The current completion engine allows and can be configured for three parser entry points.

  1. Expressions with string interpolation (eg. 'abc{!exp1}def{!exp2}ghi')
  2. Expressions with delimiters (eg. '{!exp}') - the legacy formula grammar
  3. Raw, non-delimited expressions (eg. 'exp')

These are defined in terms of each other wrt parser and lexer rules so as much as is possible the grammar and supporting code is reused.

Grammar hacks/issues

Essential ANTLR Knowledge

There are three things you really have to understand about ANTLR to make sense of the grammar manipulations that are employed:

  1. An ANTLR import is an append operation. Everything imported is added to the end of the grammar containing the import. The order of multiple imports is important too. The appends happen in the order that the imports appear.
  2. ANTLR always honors the first definition it finds.
  3. Order of rules is very important, especially for lexer rules. If you want don't want 'true' to be treated as an identifier then you had better define TRUE before IDENT.

ANTLR tricks for local grammar manipulation

Local manipulation of the legacy grammars comes in two forms:

  1. Direct edits of the grammar files
  2. Rules overrides and new rules within the unified grammars

Direct edits are applied to the reference copies of the legacy grammars (in the reference/ directory) by shell scripts (in the scripts/ directory) to produce temporary modified legacy grammar files (in the src/ directory). These form the starting point for subsequent manipulation by the override tactics. An example of a direct edit is the removal of Java grammar embeds. These scripts are sensitive and will have to be maintained as changes to the legacy formula grammar are made. They strive not to change the underlying grammar syntax or semantic at all but rather simply aim to make the legacy grammar files usable within the unified grammar structure (pure vs combined grammars etc).

We create new rules within the unified parser and lexer grammars and override legacy rules for a number of reasons:

  1. Adding entry points and removing existing entry points (managing EOF).
  2. Overriding the behavior of the troublesome IDENT token.
  3. Adding parser rules to facilitate the construction of the symbol table in the parser listener.
  4. Adding support for string interpolation.

Modal lexer

String interpolation requires the use of a modal lexer. This has downstream consequences that affect the relationships between parser and lexer grammars. In particular, you cannot import a modal lexer into a parser grammar in ANTLR to form a combined grammar - you have to reference the tokens from a pure lexer grammar.

IDENT lexer token

The formula grammar contains a definition of the IDENT token that is inappropriate for our needs. This is an intractable problem if we were to use the legacy lexer grammar as is. This is quite a severe problem. The legacy IDENT rule consumes all parts of a qualified name (ie. 'a.b.c') including the dot separators. It also allows for otherwise questionable identifiers like 'a.1'.

For our purposes we needed to break up this lexer token and redefine the uses of IDENT to use the newly defined rules (see UnifiedLexer2.g4). This works fine, tortuous though it is, but it has the consequence that identifiers within the expression completion engine are more restrictive than those within the legacy formula grammar. This is the only grammatical inconsistency as far as I know.

Code hack for readahead (expression-completion.ts, customized-lexer.ts)

In order to get the string interpolation modal grammar to work we need a readahead mechanism. This works fine within the grammar for parsing, but we need compensation within the code to account for tokens that were read but not consumed. This is undoubtedly a hack, but at least it's isolated.

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Package last updated on 27 Sep 2021

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