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165 lines
6.9 KiB
Markdown
165 lines
6.9 KiB
Markdown
---
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layout: developer-doc
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title: Lexer
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category: syntax
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tags: [parser, lexer]
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order: 3
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---
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# Lexer
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The lexer is the code generated by the [flexer](./flexer.md) that is actually
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responsible for lexing Enso source code. It chunks the character stream into a
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(structured) token stream in order to make later processing faster, and to
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identify blocks
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<!-- MarkdownTOC levels="2,3" autolink="true" -->
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- [Lexer Architecture](#lexer-architecture)
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- [Libraries in the Lexer Definition](#libraries-in-the-lexer-definition)
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- [Lexer Functionality](#lexer-functionality)
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- [The Lexer AST](#the-lexer-ast)
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- [Benchmarking the Lexer](#benchmarking-the-lexer)
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- [Running a Subset of the Benchmarks](#running-a-subset-of-the-benchmarks)
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- [Changing the Lexer](#changing-the-lexer)
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<!-- /MarkdownTOC -->
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## Lexer Architecture
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The structure of the flexer's code generation forces the lexer to be split into
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two parts: the definition, and the generation. As the latter is the point from
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which the lexer will be used, the second subproject is the one that is graced
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with the name `lexer`.
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### Libraries in the Lexer Definition
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The lexer generation subproject needs to be able to make the assumption that all
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imports will be in the same place (relative to the crate root). To this end, the
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definition subproject exports public modules `library` and `prelude`. These are
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re-imported and used in the generation subproject to ensure that all components
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are found at the same paths relative to the crate root.
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This does mean, however, that all imports from _within_ the current crate in the
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definition subproject must be imported from the `library` module, not from their
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paths directly from the crate root.
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## Lexer Functionality
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The lexer provides the following functionality as part of the parser.
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- It consumes the source lazily, character by character, and produces a
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structured token stream consisting of the lexer [ast](#the-lexer-ast).
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- It succeeds _any_ input, even if there are invalid constructs in the token
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stream, represented by `Invalid` tokens.
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## The Lexer AST
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In contrast to the full parser [ast](./ast.md), the lexer operates on a
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simplified AST that we call a 'structured token stream'. While most lexers
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output a linear token stream, it is very important in Enso that we encode the
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nature of _blocks_ into the token stream, hence giving it structure.
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This encoding of blocks is _crucial_ to the functionality of Enso as it ensures
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that no later stages of the parser can ignore blocks, and hence maintains them
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for use by the GUI.
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It contains the following constructs:
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- `Referent`: Referrent identifiers (e.g. `Some_Ref_Ident`).
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- `Variable`: Variable identifiers (e.g. `some_var_ident`).
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- `External`: External identifiers (e.g. `someJavaName`).
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- `Blank`: The blank name `_`.
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- `Operator`: Operator identifiers (e.g. `-->>`).
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- `Modifier`: Modifier operators (e.g. `+=`).
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- `Annotation`: An annotation (e.g. `@Tail_Call`).
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- `Number`: Numbers (`16_FFFF`).
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- `DanglingBase`: An explicit base without an associated number (e.g. `16_`).
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- `TextLine`: A single-line text literal.
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- `TextInlineBlock`: An inline block text literal.
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- `TextBlock`: A text block literal.
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- `InvalidQuote`: An invalid set of quotes for a text literal.
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- `TextSegmentRaw`: A raw text segment in which the contents should be
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interpreted literally.
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- `TextSegmentEscape:` A text segment containing an escape sequence.
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- `TextSegmentInterpolate:` A text segment containing an arbitrary interpolated
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expression.
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- `TextSegmentUnclosedInterpolate`: An unclosed interpolation text segment.
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- `Line`: A line in a block that contains tokens.
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- `BlankLine`: A line in a block that contains only whitespace.
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- `Block`: Syntactic blocks in the language.
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- `InvalidSuffix`: Invalid tokens when in a given state that would otherwise be
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valid.
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- `Unrecognized`: Tokens that the lexer doesn't recognise.
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- `DisableComment`: A standard comment that disables interpretation of the
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commented code (i.e. `#`).
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- `DocComment:` A documentation comment (e.g. `##`). Documentation syntax is
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_not_ lexed by this lexer.
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The distinction is made here between the various kinds of identifiers in order
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to keep lexing fast, but also in order to allow macros to switch on the kinds of
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identifiers.
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> The actionables for this section are:
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>
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> - Determine if we want to have separate ASTs for the lexer and the parser, or
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> not.
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## Benchmarking the Lexer
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As the lexer is the first port of call when getting an Enso program to run it
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needs to be quick. To that end, we insist on comprehensive benchmarks for any
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change made to the lexer. The lexer benchmarks are written using
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[criterion.rs](https://github.com/bheisler/criterion.rs), and include both
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examples of whole program definitions and more specific benchmark examples.
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**Baseline Commit:** `e5695e6f5d44cba4094380545036a3a5cbbf6973`
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The benchmarking process for the lexer is as follows:
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1. Check out the current _baseline commit_, listed above.
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2. In `lexer_bench_sources.rs` change the line that reads `.retain_baseline` to
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instead read `.save_baseline`. This will save the current baseline (taken on
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your machine).
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3. Run the benchmarks using `cargo bench`. Please note that running these
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benchmarks takes approximately two hours, so sufficient time should be
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allotted.
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4. Once the baseline run has completed, change the above-mentioned line back to
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`.retain_baseline`. This will disable overwriting the saved baseline, and
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will perform its regression reporting against it.
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5. Make your changes.
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6. Run the benchmark suite again. It will report any performance regressions in
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the benchmark report, measured against your saved baseline.
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Unfortunately, the use of time-based benchmarks means that we can't commit the
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baseline to the repository. There is far too much variance between machines for
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this to be useful.
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### Running a Subset of the Benchmarks
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The benchmarks are very comprehensive, running a wide range of program text
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through the lexer while replicating it out to various sizes (see
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`lexer_bench_sources.rs` for the full list). However, in order to decrease
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iteration time it can be useful to run a subset of these.
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There are two main tuning points for this:
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1. The _sizes_ of inputs being executed on.
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2. The benchmarks being executed.
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The sizes can be tuned by editing the `SIZES` array in the
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`lexer_bench_sources.rs` file. The benchmarks themselves are best tuned by
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changing the macro definitions in `lexer_time_bench.rs` to exclude certain
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benchmarks or groups of benchmarks.
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While it is _possible_ to tune the benchmarking config (`bench_config` in
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`lexer_bench_sources.rs`) to decrease benchmarking time, this is not
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recommended. The current settings are tuned to provide reliable results.
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### Changing the Lexer
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When changing the lexer the _full_ benchmark suite must be run against the
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current baseline before the changes can be merged. This suite run must use the
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provided settings for the benchmarking library, and should be performed using
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the process described above.
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