An early-stage PHP parser designed for IDE usage scenarios.
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README.md

Tolerant PHP Parser

This is an early prototype of a PHP parser designed, from the beginning, for IDE usage scenarios. There is still a ton of work to be done, so at this point, this repo mostly serves as an experiment and the start of a conversation.

image

Design Goals

  • Error tolerant design (in IDE scenarios, code is, by definition, incomplete)
  • Performant (should be able to parse several MB of source code per second, to leave room for other features).
    • Memory-efficient data structures
    • Allow for incremental parsing in the future
  • Adheres to PHP language spec, supports both PHP5 and PHP7 grammars
  • Generated AST provides properties (fully representative, etc.) necessary for semantic and transformational operations, which also need to be performant. (< 100 ms UI response time, so each language server operation should be < 50 ms to leave room for all the other stuff going on in parallel.)
  • Simple and maintainable over time - parsers have a tendency to get really confusing, really fast, so readability and debug-ability is high priority.
  • Written in PHP - make it as easy as possible for the PHP community to contribute

Approach

This approach borrows heavily from the designs of Roslyn and TypeScript. However, it will likely need to be adapted because PHP doesn't necessarily offer the same runtime characteristics as .NET and JS.

To ensure a sufficient level of correctness at every step of the way, the parser should be developed using the following incremental approach:

  • Phase 1: Write lexer that does not support PHP grammar, but supports EOF and Unknown tokens. Write tests for all invariants.
  • Phase 2: Support PHP lexical grammar, lots of tests
  • Phase 3: Write a parser that does not support PHP grammar, but produces tree of Error Nodes. Write tests for all invariants.
  • Phase 4: Support PHP syntactic grammar, lots of tests
  • Phase 5: Real-world validation of correctness - benchmark against other parsers (investigate any instance of disagreement)
  • Phase 6: Real-world validation of performance - benchmark against large PHP applications
  • Phase 7: Performance optimization

This approach, however, makes a few assumptions that we should validate upfront, if possible, in order to minimize potential risk:

  • Assumption 1: This approach will work on a wide range of user development environment configurations.
  • Assumption 2: PHP can be sufficiently optimized to support aforementioned parser performance goals.
  • Assumption 3: PHP 7 grammar is a superset of PHP5 grammar.
  • Assumption 4: The PHP grammar described in php/php-langspec is complete.
  • Anything else?

Lexer

The lexer produces tokens out PHP, based on the following lexical grammar:

Tokens (Model)

Tokens take the following form:

Token: {
    Kind: Id, // the classification of the token
    FullStart: 0, // the start of the token, including trivia
    Start: 3, // the start of the token, excluding trivia
    Length: 6 // the length of the token (from FullStart)
}

Tokens (Representation)

TODO

Helper functions

In order to be as efficient as possible, we do not store full content in memory. Instead, each token is uniquely defined by four integers, and we take advantage of helper functions to extract further information.

  • GetTriviaForToken
  • GetFullTextForToken
  • GetTextForToken

Invariants

In order to ensure that the parser evolves in a healthy manner over time, we define and continuously test the set of invariants defined below:

  • The sum of the lengths of all of the tokens is equivalent to the length of the document
  • The Start of every token is always greater than or equal to the FullStart of every token.
  • A token's content exactly matches the range of the file its span specifies.
  • GetTriviaForToken + GetTextForToken == GetFullTextForToken
  • concatenating GetFullTextForToken for each token returns the document
  • GetTriviaForToken returns a string of length equivalent to (Start - FullStart)
  • GetFullTextForToken returns a string of length equivalent to Length
  • GetTextForToken returns a string of length equivalent to Length - (Start - FullStart)
  • See the code for an up-to-date list...

Parser

Node (Model)

Nodes include the following information:

Node: {
  Kind: Id,
  Parent: ParentNode,
  Children: List<Children>
}

Node (Representation)

TODO - discerning between Model and Representation (Model == How we will intaract with it, Representation == underlying data structures)

Abstract Syntax Tree

An example tree is below. The tree Nodes (represented by tokens), and Tokens (represented by squares) image

Below, we define a set of invariants. This set of invariants provides a consistent foundation that makes it easier to confidently reason about the tree as we continue to build up our understanding.

For instance, the following properties hold true about every Node (N) and Token (T).

POS(N) -> POS(FirstChild(N))
POS(T) -> T.Start
WIDTH(N) -> SUM(Child_i(N))
WIDTH(T) -> T.Width

Invariants

  • Invariants for all Tokens hold true
  • The tree contains every token
  • span of any node is sum of spans of child nodes and tokens
  • The tree length exactly matches the file length
  • Every leaf node of the tree is a token
  • Every Node contains at least one Token

Building up the Tree

Error Tokens

We define two types of Error tokens:

  • Skipped Tokens: extra token that no one knows how to deal with
  • Missing Tokens: Grammar expects a token to be there, but it does not exist
Example 1

Let's say we run the following through parseIf

if ($expression) 
{
}
function parseIf($str, $parent) {
    $n = new IfNode();
    $n->ifKeyword = eat("if");
    $n->openParen = eat("(");
    $n->expression = parseExpression();
    $n->closeParen = eat(")");
    $n->block = parseBlock();
    $n->parent = $parent;
}

This above should generate the IfNode successfully. But let's say we run the following through, which is missing a close paren token.

if ($expression // ) <- MissingToken
{
}

In this case, eat(")") will generate a MissingToken because the grammar expects a token to be there, but it does not exist.

Example 2
class A {
    function foo() {
        return;
 // } <- MissingToken

    public function bar() {

    }
}

In this case, the foo function block is not closed. A MissingToken will be similarly generated, but the logic will be a little different, in order to provide a gracefully degrading experience. In particular, the tree that we expect here looks something like this:

image

This is achieved by continually keeping track of the current ParseContext. That is to say, every time we venture into a child, that child is aware of its parent. Whenever the child gets to a token that they themselves don't know how to handle (e.g. a MethodNode doesn't know what public means), they ask their parent if they know how to handle it, and continue walking up the tree. If we've walked the entire spine, and every node is similarly confused, a SkippedToken will be generated.

In this case, however, a SkippedToken is not generated because ClassNode will know what public means. Instead, the method will say "okay, I'm done", generate a MissingToken, and public will be subsequently handled by the ClassNode.

Example 3

Building on Example 2... in the following case, no one knows how to handle an ampersand, and so this token will become a SkippedToken

class A {
    function foo() {
        return;
    & // <- SkippedToken
    }
    public function bar() {

    }
}
Example 4

There are also some instances, where the aforementioned error handling wouldn't be appropriate, and special-casing based on certain heuristics, such as whitespace, would be required.

if ($a >
    $b = new MyClass;

In this case, the user likely intended the type of $b to be MyClass. However, because under normal circumstances, parsers will ignore whitespace, the example above would produce the following tree, whic himplies that the $b assignment never happens.

SourceFileNode
- IfNode
  - OpenParen = Token
  - Expression = RelationalExpressionNode
    - Left: $a Token
    - Right: $b Token
  - CloseParen = MissingToken
- SkippedToken: '='
- ObjectCreationExpression
  - New: Token
  - ClassTypeDesignator: MyClass
  - Semicolon: Token

In our design, however, because every Token includes preceding whitespace trivia, our parser would be able to use whitespace as a heuristic to infer the user's likely intentions. So rather than handling the error by generating a skipped = token, we could instead generate a missing token for the right hand side of the RelationalExpressionNode.

Note that for this error case, it is more of an art than a science. That is to say, we would add special casing for anticipated scenarios, rather than construct some general-purpose rule.

Other notes

  • Just as it's imporant to understand the assumptions that will hold true, it is also important to understand the assumptions that will not hold true. One such non-invariant is that not every token generated by the lexer ends up in the tree.

Open Questions

Some open Qs:

  • need some examples of large PHP applications to help benchmark
  • would PHP 5 provide sufficient perf?
  • what sort of data structures do we need? Ideally we'd throw everything into a struct. Anything better?

Real world validation strategy

  • benchmark against other parsers (investigate any instance of disagreement)
  • perf benchmarks (should be able to get semantic information )