From 7c3926345004c4d679c835760dbea5438a4f9d7b Mon Sep 17 00:00:00 2001 From: Lukas Wirth Date: Sun, 21 Apr 2024 14:40:10 +0200 Subject: Allow rust files to be used linkedProjects --- src/tools/rust-analyzer/docs/dev/guide.md | 587 ++++++++++++++++++++++++++++++ 1 file changed, 587 insertions(+) create mode 100644 src/tools/rust-analyzer/docs/dev/guide.md (limited to 'src/tools/rust-analyzer/docs/dev/guide.md') diff --git a/src/tools/rust-analyzer/docs/dev/guide.md b/src/tools/rust-analyzer/docs/dev/guide.md new file mode 100644 index 00000000000..bb77aa0eaae --- /dev/null +++ b/src/tools/rust-analyzer/docs/dev/guide.md @@ -0,0 +1,587 @@ +# Guide to rust-analyzer + +## About the guide + +This guide describes the current state of rust-analyzer as of the 2024-01-01 release +(git tag [2024-01-01]). Its purpose is to document various problems and +architectural solutions related to the problem of building IDE-first compiler +for Rust. There is a video version of this guide as well - +however, it's based on an older 2019-01-20 release (git tag [guide-2019-01]): +https://youtu.be/ANKBNiSWyfc. + +[guide-2019-01]: https://github.com/rust-lang/rust-analyzer/tree/guide-2019-01 +[2024-01-01]: https://github.com/rust-lang/rust-analyzer/tree/2024-01-01 + +## The big picture + +On the highest possible level, rust-analyzer is a stateful component. A client may +apply changes to the analyzer (new contents of `foo.rs` file is "fn main() {}") +and it may ask semantic questions about the current state (what is the +definition of the identifier with offset 92 in file `bar.rs`?). Two important +properties hold: + +* Analyzer does not do any I/O. It starts in an empty state and all input data is + provided via `apply_change` API. + +* Only queries about the current state are supported. One can, of course, + simulate undo and redo by keeping a log of changes and inverse changes respectively. + +## IDE API + +To see the bigger picture of how the IDE features work, let's take a look at the [`AnalysisHost`] and +[`Analysis`] pair of types. `AnalysisHost` has three methods: + +* `default()` for creating an empty analysis instance +* `apply_change(&mut self)` to make changes (this is how you get from an empty + state to something interesting) +* `analysis(&self)` to get an instance of `Analysis` + +`Analysis` has a ton of methods for IDEs, like `goto_definition`, or +`completions`. Both inputs and outputs of `Analysis`' methods are formulated in +terms of files and offsets, and **not** in terms of Rust concepts like structs, +traits, etc. The "typed" API with Rust specific types is slightly lower in the +stack, we'll talk about it later. + +[`AnalysisHost`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide/src/lib.rs#L161-L213 +[`Analysis`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide/src/lib.rs#L220-L761 + +The reason for this separation of `Analysis` and `AnalysisHost` is that we want to apply +changes "uniquely", but we might also want to fork an `Analysis` and send it to +another thread for background processing. That is, there is only a single +`AnalysisHost`, but there may be several (equivalent) `Analysis`. + +Note that all of the `Analysis` API return `Cancellable`. This is required to +be responsive in an IDE setting. Sometimes a long-running query is being computed +and the user types something in the editor and asks for completion. In this +case, we cancel the long-running computation (so it returns `Err(Cancelled)`), +apply the change and execute request for completion. We never use stale data to +answer requests. Under the cover, `AnalysisHost` "remembers" all outstanding +`Analysis` instances. The `AnalysisHost::apply_change` method cancels all +`Analysis`es, blocks until all of them are `Dropped` and then applies changes +in-place. This may be familiar to Rustaceans who use read-write locks for interior +mutability. + +Next, let's talk about what the inputs to the `Analysis` are, precisely. + +## Inputs + +rust-analyzer never does any I/O itself, all inputs get passed explicitly via +the `AnalysisHost::apply_change` method, which accepts a single argument, a +`Change`. [`Change`] is a wrapper for `FileChange` that adds proc-macro knowledge. +[`FileChange`] is a builder for a single change "transaction", so it suffices +to study its methods to understand all the input data. + +[`Change`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-expand/src/change.rs#L10-L42 +[`FileChange`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/base-db/src/change.rs#L14-L78 + +The `change_file` method controls the set of the input files, where each file +has an integer id (`FileId`, picked by the client) and text (`Option>`). +Paths are tricky; they'll be explained below, in source roots section, +together with the `set_roots` method. The "source root" [`is_library`] flag +along with the concept of [`durability`] allows us to add a group of files which +are assumed to rarely change. It's mostly an optimization and does not change +the fundamental picture. + +[`is_library`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/base-db/src/input.rs#L38 +[`durability`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/base-db/src/change.rs#L80-L86 + +The `set_crate_graph` method allows us to control how the input files are partitioned +into compilation units -- crates. It also controls (in theory, not implemented +yet) `cfg` flags. `CrateGraph` is a directed acyclic graph of crates. Each crate +has a root `FileId`, a set of active `cfg` flags and a set of dependencies. Each +dependency is a pair of a crate and a name. It is possible to have two crates +with the same root `FileId` but different `cfg`-flags/dependencies. This model +is lower than Cargo's model of packages: each Cargo package consists of several +targets, each of which is a separate crate (or several crates, if you try +different feature combinations). + +Procedural macros are inputs as well, roughly modeled as a crate with a bunch of +additional black box `dyn Fn(TokenStream) -> TokenStream` functions. + +Soon we'll talk how we build an LSP server on top of `Analysis`, but first, +let's deal with that paths issue. + +## Source roots (a.k.a. "Filesystems are horrible") + +This is a non-essential section, feel free to skip. + +The previous section said that the filesystem path is an attribute of a file, +but this is not the whole truth. Making it an absolute `PathBuf` will be bad for +several reasons. First, filesystems are full of (platform-dependent) edge cases: + +* It's hard (requires a syscall) to decide if two paths are equivalent. +* Some filesystems are case-sensitive (e.g. macOS). +* Paths are not necessarily UTF-8. +* Symlinks can form cycles. + +Second, this might hurt the reproducibility and hermeticity of builds. In theory, +moving a project from `/foo/bar/my-project` to `/spam/eggs/my-project` should +not change a bit in the output. However, if the absolute path is a part of the +input, it is at least in theory observable, and *could* affect the output. + +Yet another problem is that we really *really* want to avoid doing I/O, but with +Rust the set of "input" files is not necessarily known up-front. In theory, you +can have `#[path="/dev/random"] mod foo;`. + +To solve (or explicitly refuse to solve) these problems rust-analyzer uses the +concept of a "source root". Roughly speaking, source roots are the contents of a +directory on a file system, like `/home/matklad/projects/rustraytracer/**.rs`. + +More precisely, all files (`FileId`s) are partitioned into disjoint +`SourceRoot`s. Each file has a relative UTF-8 path within the `SourceRoot`. +`SourceRoot` has an identity (integer ID). Crucially, the root path of the +source root itself is unknown to the analyzer: A client is supposed to maintain a +mapping between `SourceRoot` IDs (which are assigned by the client) and actual +`PathBuf`s. `SourceRoot`s give a sane tree model of the file system to the +analyzer. + +Note that `mod`, `#[path]` and `include!()` can only reference files from the +same source root. It is of course possible to explicitly add extra files to +the source root, even `/dev/random`. + +## Language Server Protocol + +Now let's see how the `Analysis` API is exposed via the JSON RPC based language server protocol. +The hard part here is managing changes (which can come either from the file system +or from the editor) and concurrency (we want to spawn background jobs for things +like syntax highlighting). We use the event loop pattern to manage the zoo, and +the loop is the [`GlobalState::run`] function initiated by [`main_loop`] after +[`GlobalState::new`] does a one-time initialization and tearing down of the resources. + +[`main_loop`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L31-L54 +[`GlobalState::new`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/global_state.rs#L148-L215 +[`GlobalState::run`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L114-L140 + + +Let's walk through a typical analyzer session! + +First, we need to figure out what to analyze. To do this, we run `cargo +metadata` to learn about Cargo packages for current workspace and dependencies, +and we run `rustc --print sysroot` and scan the "sysroot" +(the directory containing the current Rust toolchain's files) to learn about crates +like `std`. This happens in the [`GlobalState::fetch_workspaces`] method. +We load this configuration at the start of the server in [`GlobalState::new`], +but it's also triggered by workspace change events and requests to reload the +workspace from the client. + +[`GlobalState::fetch_workspaces`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/reload.rs#L186-L257 + +The [`ProjectModel`] we get after this step is very Cargo and sysroot specific, +it needs to be lowered to get the input in the form of `Change`. This happens +in [`GlobalState::process_changes`] method. Specifically + +* Create `SourceRoot`s for each Cargo package(s) and sysroot. +* Schedule a filesystem scan of the roots. +* Create an analyzer's `Crate` for each Cargo **target** and sysroot crate. +* Setup dependencies between the crates. + +[`ProjectModel`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/project-model/src/workspace.rs#L57-L100 +[`GlobalState::process_changes`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/global_state.rs#L217-L356 + +The results of the scan (which may take a while) will be processed in the body +of the main loop, just like any other change. Here's where we handle: + +* [File system changes](https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L273) +* [Changes from the editor](https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L801-L803) + +After a single loop's turn, we group the changes into one `Change` and +[apply] it. This always happens on the main thread and blocks the loop. + +[apply]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/global_state.rs#L333 + +To handle requests, like ["goto definition"], we create an instance of the +`Analysis` and [`schedule`] the task (which consumes `Analysis`) on the +threadpool. [The task] calls the corresponding `Analysis` method, while +massaging the types into the LSP representation. Keep in mind that if we are +executing "goto definition" on the threadpool and a new change comes in, the +task will be canceled as soon as the main loop calls `apply_change` on the +`AnalysisHost`. + +["goto definition"]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L767 +[`schedule`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/dispatch.rs#L138 +[The task]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/handlers/request.rs#L610-L623 + +This concludes the overview of the analyzer's programing *interface*. Next, let's +dig into the implementation! + +## Salsa + +The most straightforward way to implement an "apply change, get analysis, repeat" +API would be to maintain the input state and to compute all possible analysis +information from scratch after every change. This works, but scales poorly with +the size of the project. To make this fast, we need to take advantage of the +fact that most of the changes are small, and that analysis results are unlikely +to change significantly between invocations. + +To do this we use [salsa]: a framework for incremental on-demand computation. +You can skip the rest of the section if you are familiar with `rustc`'s red-green +algorithm (which is used for incremental compilation). + +[salsa]: https://github.com/salsa-rs/salsa + +It's better to refer to salsa's docs to learn about it. Here's a small excerpt: + +The key idea of salsa is that you define your program as a set of queries. Every +query is used like a function `K -> V` that maps from some key of type `K` to a value +of type `V`. Queries come in two basic varieties: + +* **Inputs**: the base inputs to your system. You can change these whenever you + like. + +* **Functions**: pure functions (no side effects) that transform your inputs + into other values. The results of queries are memoized to avoid recomputing + them a lot. When you make changes to the inputs, we'll figure out (fairly + intelligently) when we can re-use these memoized values and when we have to + recompute them. + +For further discussion, its important to understand one bit of "fairly +intelligently". Suppose we have two functions, `f1` and `f2`, and one input, +`z`. We call `f1(X)` which in turn calls `f2(Y)` which inspects `i(Z)`. `i(Z)` +returns some value `V1`, `f2` uses that and returns `R1`, `f1` uses that and +returns `O`. Now, let's change `i` at `Z` to `V2` from `V1` and try to compute +`f1(X)` again. Because `f1(X)` (transitively) depends on `i(Z)`, we can't just +reuse its value as is. However, if `f2(Y)` is *still* equal to `R1` (despite +`i`'s change), we, in fact, *can* reuse `O` as result of `f1(X)`. And that's how +salsa works: it recomputes results in *reverse* order, starting from inputs and +progressing towards outputs, stopping as soon as it sees an intermediate value +that hasn't changed. If this sounds confusing to you, don't worry: it is +confusing. This illustration by @killercup might help: + +step 1 + +step 2 + +step 3 + +step 4 + +## Salsa Input Queries + +All analyzer information is stored in a salsa database. `Analysis` and +`AnalysisHost` types are essentially newtype wrappers for [`RootDatabase`] +-- a salsa database. + +[`RootDatabase`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-db/src/lib.rs#L69-L324 + +Salsa input queries are defined in [`SourceDatabase`] and [`SourceDatabaseExt`] +(which are a part of `RootDatabase`). They closely mirror the familiar `Change` +structure: indeed, what `apply_change` does is it sets the values of input queries. + +[`SourceDatabase`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/base-db/src/lib.rs#L58-L65 +[`SourceDatabaseExt`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/base-db/src/lib.rs#L76-L88 + +## From text to semantic model + +The bulk of the rust-analyzer is transforming input text into a semantic model of +Rust code: a web of entities like modules, structs, functions and traits. + +An important fact to realize is that (unlike most other languages like C# or +Java) there is not a one-to-one mapping between the source code and the semantic model. A +single function definition in the source code might result in several semantic +functions: for example, the same source file might get included as a module in +several crates or a single crate might be present in the compilation DAG +several times, with different sets of `cfg`s enabled. The IDE-specific task of +mapping source code into a semantic model is inherently imprecise for +this reason and gets handled by the [`source_analyzer`]. + +[`source_analyzer`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir/src/source_analyzer.rs + +The semantic interface is declared in the [`semantics`] module. Each entity is +identified by an integer ID and has a bunch of methods which take a salsa database +as an argument and returns other entities (which are also IDs). Internally, these +methods invoke various queries on the database to build the model on demand. +Here's [the list of queries]. + +[`semantics`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir/src/semantics.rs +[the list of queries]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-ty/src/db.rs#L29-L275 + +The first step of building the model is parsing the source code. + +## Syntax trees + +An important property of the Rust language is that each file can be parsed in +isolation. Unlike, say, `C++`, an `include` can't change the meaning of the +syntax. For this reason, rust-analyzer can build a syntax tree for each "source +file", which could then be reused by several semantic models if this file +happens to be a part of several crates. + +The representation of syntax trees that rust-analyzer uses is similar to that of `Roslyn` +and Swift's new [libsyntax]. Swift's docs give an excellent overview of the +approach, so I skip this part here and instead outline the main characteristics +of the syntax trees: + +* Syntax trees are fully lossless. Converting **any** text to a syntax tree and + back is a total identity function. All whitespace and comments are explicitly + represented in the tree. + +* Syntax nodes have generic `(next|previous)_sibling`, `parent`, + `(first|last)_child` functions. You can get from any one node to any other + node in the file using only these functions. + +* Syntax nodes know their range (start offset and length) in the file. + +* Syntax nodes share the ownership of their syntax tree: if you keep a reference + to a single function, the whole enclosing file is alive. + +* Syntax trees are immutable and the cost of replacing the subtree is + proportional to the depth of the subtree. Read Swift's docs to learn how + immutable + parent pointers + cheap modification is possible. + +* Syntax trees are build on best-effort basis. All accessor methods return + `Option`s. The tree for `fn foo` will contain a function declaration with + `None` for parameter list and body. + +* Syntax trees do not know the file they are built from, they only know about + the text. + +The implementation is based on the generic [rowan] crate on top of which a +[rust-specific] AST is generated. + +[libsyntax]: https://github.com/apple/swift/tree/5e2c815edfd758f9b1309ce07bfc01c4bc20ec23/lib/Syntax +[rowan]: https://github.com/rust-analyzer/rowan/tree/100a36dc820eb393b74abe0d20ddf99077b61f88 +[rust-specific]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/syntax/src/ast/generated.rs + +The next step in constructing the semantic model is ... + +## Building a Module Tree + +The algorithm for building a tree of modules is to start with a crate root +(remember, each `Crate` from a `CrateGraph` has a `FileId`), collect all `mod` +declarations and recursively process child modules. This is handled by the +[`crate_def_map_query`], with two slight variations. + +[`crate_def_map_query`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/nameres.rs#L307-L324 + +First, rust-analyzer builds a module tree for all crates in a source root +simultaneously. The main reason for this is historical (`module_tree` predates +`CrateGraph`), but this approach also enables accounting for files which are not +part of any crate. That is, if you create a file but do not include it as a +submodule anywhere, you still get semantic completion, and you get a warning +about a free-floating module (the actual warning is not implemented yet). + +The second difference is that `crate_def_map_query` does not *directly* depend on +the `SourceDatabase::parse` query. Why would calling the parse directly be bad? +Suppose the user changes the file slightly, by adding an insignificant whitespace. +Adding whitespace changes the parse tree (because it includes whitespace), +and that means recomputing the whole module tree. + +We deal with this problem by introducing an intermediate [`block_def_map_query`]. +This query processes the syntax tree and extracts a set of declared submodule +names. Now, changing the whitespace results in `block_def_map_query` being +re-executed for a *single* module, but because the result of this query stays +the same, we don't have to re-execute [`crate_def_map_query`]. In fact, we only +need to re-execute it when we add/remove new files or when we change mod +declarations. + +[`block_def_map_query`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/nameres.rs#L326-L354 + +We store the resulting modules in a `Vec`-based indexed arena. The indices in +the arena becomes module IDs. And this brings us to the next topic: +assigning IDs in the general case. + +## Location Interner pattern + +One way to assign IDs is how we've dealt with modules: Collect all items into a +single array in some specific order and use the index in the array as an ID. The +main drawback of this approach is that these IDs are not stable: Adding a new item can +shift the IDs of all other items. This works for modules, because adding a module is +a comparatively rare operation, but would be less convenient for, for example, +functions. + +Another solution here is positional IDs: We can identify a function as "the +function with name `foo` in a ModuleId(92) module". Such locations are stable: +adding a new function to the module (unless it is also named `foo`) does not +change the location. However, such "ID" types ceases to be a `Copy`able integer and in +general can become pretty large if we account for nesting (for example: "third parameter of +the `foo` function of the `bar` `impl` in the `baz` module"). + +[`Intern` and `Lookup`] traits allows us to combine the benefits of positional and numeric +IDs. Implementing both traits effectively creates a bidirectional append-only map +between locations and integer IDs (typically newtype wrappers for [`salsa::InternId`]) +which can "intern" a location and return an integer ID back. The salsa database we use +includes a couple of [interners]. How to "garbage collect" unused locations +is an open question. + +[`Intern` and `Lookup`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-expand/src/lib.rs#L96-L106 +[interners]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-expand/src/lib.rs#L108-L122 +[`salsa::InternId`]: https://docs.rs/salsa/0.16.1/salsa/struct.InternId.html + +For example, we use `Intern` and `Lookup` implementations to assign IDs to +definitions of functions, structs, enums, etc. The location, [`ItemLoc`] contains +two bits of information: + +* the ID of the module which contains the definition, +* the ID of the specific item in the module's source code. + +We "could" use a text offset for the location of a particular item, but that would play +badly with salsa: offsets change after edits. So, as a rule of thumb, we avoid +using offsets, text ranges or syntax trees as keys and values for queries. What +we do instead is we store "index" of the item among all of the items of a file +(so, a positional based ID, but localized to a single file). + +[`ItemLoc`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/lib.rs#L209-L212 + +One thing we've glossed over for the time being is support for macros. We have +only proof of concept handling of macros at the moment, but they are extremely +interesting from an "assigning IDs" perspective. + +## Macros and recursive locations + +The tricky bit about macros is that they effectively create new source files. +While we can use `FileId`s to refer to original files, we can't just assign them +willy-nilly to the pseudo files of macro expansion. Instead, we use a special +ID, [`HirFileId`] to refer to either a usual file or a macro-generated file: + +```rust +enum HirFileId { + FileId(FileId), + Macro(MacroCallId), +} +``` + +`MacroCallId` is an interned ID that identifies a particular macro invocation. +Simplifying, it's a `HirFileId` of a file containing the call plus the offset +of the macro call in the file. + +Note how `HirFileId` is defined in terms of `MacroCallId` which is defined in +terms of `HirFileId`! This does not recur infinitely though: any chain of +`HirFileId`s bottoms out in `HirFileId::FileId`, that is, some source file +actually written by the user. + +Note also that in the actual implementation, the two variants are encoded in +a single `u32`, which are differentiated by the MSB (most significant bit). +If the MSB is 0, the value represents a `FileId`, otherwise the remaining +31 bits represent a `MacroCallId`. + +[`HirFileId`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/span/src/lib.rs#L148-L160 + +Now that we understand how to identify a definition, in a source or in a +macro-generated file, we can discuss name resolution a bit. + +## Name resolution + +Name resolution faces the same problem as the module tree: if we look at the +syntax tree directly, we'll have to recompute name resolution after every +modification. The solution to the problem is the same: We [lower] the source code of +each module into a position-independent representation which does not change if +we modify bodies of the items. After that we [loop] resolving all imports until +we've reached a fixed point. + +[lower]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/item_tree.rs#L110-L154 +[loop]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/nameres/collector.rs#L404-L437 +And, given all our preparation with IDs and a position-independent representation, +it is satisfying to [test] that typing inside function body does not invalidate +name resolution results. + +[test]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/nameres/tests/incremental.rs#L31 + +An interesting fact about name resolution is that it "erases" all of the +intermediate paths from the imports: in the end, we know which items are defined +and which items are imported in each module, but, if the import was `use +foo::bar::baz`, we deliberately forget what modules `foo` and `bar` resolve to. + +To serve "goto definition" requests on intermediate segments we need this info +in the IDE, however. Luckily, we need it only for a tiny fraction of imports, so we just ask +the module explicitly, "What does the path `foo::bar` resolve to?". This is a +general pattern: we try to compute the minimal possible amount of information +during analysis while allowing IDE to ask for additional specific bits. + +Name resolution is also a good place to introduce another salsa pattern used +throughout the analyzer: + +## Source Map pattern + +Due to an obscure edge case in completion, IDE needs to know the syntax node of +a use statement which imported the given completion candidate. We can't just +store the syntax node as a part of name resolution: this will break +incrementality, due to the fact that syntax changes after every file +modification. + +We solve this problem during the lowering step of name resolution. Along with +the [`ItemTree`] output, the lowering query additionally produces an [`AstIdMap`] +via an [`ast_id_map`] query. The `ItemTree` contains [imports], but in a +position-independent form based on [`AstId`]. The `AstIdMap` contains a mapping +from position-independent `AstId`s to (position-dependent) syntax nodes. + +[`ItemTree`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/item_tree.rs +[`AstIdMap`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-expand/src/ast_id_map.rs#L136-L142 +[`ast_id_map`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/item_tree/lower.rs#L32 +[imports]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/item_tree.rs#L559-L563 +[`AstId`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-expand/src/ast_id_map.rs#L29 + + +## Type inference + +First of all, implementation of type inference in rust-analyzer was spearheaded +by [@flodiebold]. [#327] was an awesome Christmas present, thank you, Florian! + +Type inference runs on per-function granularity and uses the patterns we've +discussed previously. + +First, we [lower the AST] of a function body into a position-independent +representation. In this representation, each expression is assigned a +[positional ID]. Alongside the lowered expression, [a source map] is produced, +which maps between expression ids and original syntax. This lowering step also +deals with "incomplete" source trees by replacing missing expressions by an +explicit `Missing` expression. + +Given the lowered body of the function, we can now run [type inference] and +construct a mapping from `ExprId`s to types. + +[@flodiebold]: https://github.com/flodiebold +[#327]: https://github.com/rust-lang/rust-analyzer/pull/327 +[lower the AST]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/body.rs +[positional ID]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/hir.rs#L37 +[a source map]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-def/src/body.rs#L84-L88 +[type inference]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/hir-ty/src/infer.rs#L76-L131 + +## Tying it all together: completion + +To conclude the overview of the rust-analyzer, let's trace the request for +(type-inference powered!) code completion! + +We start by [receiving a message] from the language client. We decode the +message as a request for completion and [schedule it on the threadpool]. This is +the place where we [catch] canceled errors if, immediately after completion, the +client sends some modification. + +In [the handler], we deserialize LSP requests into rust-analyzer specific data +types (by converting a file url into a numeric `FileId`), [ask analysis for +completion] and serialize results into the LSP. + +The [completion implementation] is finally the place where we start doing the actual +work. The first step is to collect the [`CompletionContext`] -- a struct which +describes the cursor position in terms of Rust syntax and semantics. For +example, `expected_name: Option` is the syntactic representation +for the expected name of what we're completing (usually the parameter name of +a function argument), while `expected_type: Option` is the semantic model +for the expected type of what we're completing. + +To construct the context, we first do an ["IntelliJ Trick"]: we insert a dummy +identifier at the cursor's position and parse this modified file, to get a +reasonably looking syntax tree. Then we do a bunch of "classification" routines +to figure out the context. For example, we [find an parent `fn` node], get a +[semantic model] for it (using the lossy `source_analyzer` infrastructure) +and use it to determine the [expected type at the cursor position]. + +The second step is to run a [series of independent completion routines]. Let's +take a closer look at [`complete_dot`], which completes fields and methods in +`foo.bar|`. First we extract a semantic receiver type out of the `DotAccess` +argument. Then, using the semantic model for the type, we determine if the +receiver implements the `Future` trait, and add a `.await` completion item in +the affirmative case. Finally, we add all fields & methods from the type to +completion. + +[receiving a message]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/main_loop.rs#L213 +[schedule it on the threadpool]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/dispatch.rs#L197-L211 +[catch]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/dispatch.rs#L292 +[the handler]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/rust-analyzer/src/handlers/request.rs#L850-L876 +[ask analysis for completion]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide/src/lib.rs#L605-L615 +[completion implementation]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/lib.rs#L148-L229 +[`CompletionContext`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/context.rs#L407-L441 +["IntelliJ Trick"]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/context.rs#L644-L648 +[find an parent `fn` node]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/context/analysis.rs#L463 +[semantic model]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/context/analysis.rs#L466 +[expected type at the cursor position]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/context/analysis.rs#L467 +[series of independent completion routines]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/lib.rs#L157-L226 +[`complete_dot`]: https://github.com/rust-lang/rust-analyzer/blob/2024-01-01/crates/ide-completion/src/completions/dot.rs#L11-L41 -- cgit 1.4.1-3-g733a5