diff --git a/src/diagnostics/diagnostic-codes.md b/src/diagnostics/diagnostic-codes.md index 092c8a2f..3618b43c 100644 --- a/src/diagnostics/diagnostic-codes.md +++ b/src/diagnostics/diagnostic-codes.md @@ -1,4 +1,4 @@ -# Diagnostic Codes +# Diagnostic codes We generally try to assign each error message a unique code like `E0123`. These codes are defined in the compiler in the `diagnostics.rs` files found in each crate, which basically consist of macros. The codes come in two varieties: those @@ -60,7 +60,7 @@ To actually issue the error, you can use the `struct_span_err!` macro: struct_span_err!(self.tcx.sess, // some path to the session here span, // whatever span in the source you want E0592, // your new error code - &format!("text of the error")) + fluent::example::an_error_message) .emit() // actually issue the error ``` @@ -69,8 +69,8 @@ call `.emit()`: ```rust struct_span_err!(...) - .span_label(another_span, "something to label in the source") - .span_note(another_span, "some separate note, probably avoid these") + .span_label(another_span, fluent::example::example_label) + .span_note(another_span, fluent::example::separate_note) .emit_() ``` diff --git a/src/diagnostics/diagnostic-items.md b/src/diagnostics/diagnostic-items.md index 61e3c3ae..af11eb9e 100644 --- a/src/diagnostics/diagnostic-items.md +++ b/src/diagnostics/diagnostic-items.md @@ -1,19 +1,17 @@ # Diagnostic Items - -## Background - -While writing lints it's common to check for specific types, traits and functions. This raises -the question on how to check for these. Types can be checked by their complete type path. -However, this requires hard coding paths and can lead to misclassifications in some edge cases. -To counteract this, rustc has introduced diagnostic items that are used to identify types via +While writing lints it's common to check for specific types, traits and +functions. This raises the question on how to check for these. Types can be +checked by their complete type path. However, this requires hard coding paths +and can lead to misclassifications in some edge cases. To counteract this, +rustc has introduced diagnostic items that are used to identify types via [`Symbol`]s. -## How To Find Diagnostic Items - -Diagnostic items are added to items inside `rustc`/`std`/`core` with the `rustc_diagnostic_item` -attribute. The item for a specific type can be found by opening the source code in the -documentation and looking for this attribute. Note that it's often added with the `cfg_attr` -attribute to avoid compilation errors during tests. A definition often looks like this: +## Finding diagnostic items +Diagnostic items are added to items inside `rustc`/`std`/`core` with the +`rustc_diagnostic_item` attribute. The item for a specific type can be found by +opening the source code in the documentation and looking for this attribute. +Note that it's often added with the `cfg_attr` attribute to avoid compilation +errors during tests. A definition often looks like this: ```rs // This is the diagnostic item for this type vvvvvvv @@ -21,19 +19,20 @@ attribute to avoid compilation errors during tests. A definition often looks lik struct Penguin; ``` -Diagnostic items are usually only added to traits, types and standalone functions. If the goal -is to check for an associated type or method, please use the diagnostic item of the item and -reference [*How To Use Diagnostic Items*](#how-to-use-diagnostic-items). - -## How To Add Diagnostic Items +Diagnostic items are usually only added to traits, types and standalone +functions. If the goal is to check for an associated type or method, please use +the diagnostic item of the item and reference [*How To Use Diagnostic +Items*](#how-to-use-diagnostic-items). +## Adding diagnostic items A new diagnostic item can be added with these two steps: -1. Find the target item inside the Rust repo. Now add the diagnostic item as a string via the - `rustc_diagnostic_item` attribute. This can sometimes cause compilation errors while running - tests. These errors can be avoided by using the `cfg_attr` attribute with the `not(test)` - condition (it's fine adding then for all `rustc_diagnostic_item` attributes as a preventive - manner). At the end, it should look like this: +1. Find the target item inside the Rust repo. Now add the diagnostic item as a + string via the `rustc_diagnostic_item` attribute. This can sometimes cause + compilation errors while running tests. These errors can be avoided by using + the `cfg_attr` attribute with the `not(test)` condition (it's fine adding + then for all `rustc_diagnostic_item` attributes as a preventive manner). At + the end, it should look like this: ```rs // This will be the new diagnostic item vvv @@ -44,41 +43,45 @@ A new diagnostic item can be added with these two steps: For the naming conventions of diagnostic items, please refer to [*Naming Conventions*](#naming-conventions). -2. As of February 2022, diagnostic items in code are accessed via symbols in - [`rustc_span::symbol::sym`]. To add your newly created diagnostic item simply open the - module file and add the name (In this case `Cat`) at the correct point in the list. +2. As of February 2022, diagnostic items in code are + accessed via symbols in [`rustc_span::symbol::sym`]. To add your newly + created diagnostic item simply open the module file and add the name (In + this case `Cat`) at the correct point in the list. -Now you can create a pull request with your changes. :tada: (Note that when using diagnostic -items in other projects like Clippy, it might take some time until the repos get synchronized.) +Now you can create a pull request with your changes. :tada: (Note that when +using diagnostic items in other projects like Clippy, it might take some time +until the repos get synchronized.) -## Naming Conventions +## Naming conventions +Diagnostic items don't have a set in stone naming convention yet. These are +some guidelines that should be used for the future, but might differ from +existing names: -Diagnostic items don't have a set in stone naming convention yet. These are some guidelines that -should be used for the future, but might differ from existing names: - -* Types, traits and enums are named using UpperCamelCase (Examples: `Iterator`, `HashMap`, ...) -* For type names that are used multiple times like `Writer` it's good to choose a more precise - name, maybe by adding the module to it. (Example: `IoWriter`) -* Associated items should not get their own diagnostic items, but instead be accessed indirectly - by the diagnostic item of the type they're originating from. -* Freestanding functions like `std::mem::swap()` should be named using `snake_case` with one - important (export) module as a prefix (Example: `mem_swap`, `cmp_max`) -* Modules should usually not have a diagnostic item attached to them. Diagnostic items were - added to avoid the usage of paths, using them on modules would therefore most likely to be - counterproductive. - -## How To Use Diagnostic Items +* Types, traits and enums are named using UpperCamelCase (Examples: `Iterator`, +* `HashMap`, ...) +* For type names that are used multiple times like `Writer` it's good to choose + a more precise name, maybe by adding the module to it. (Example: `IoWriter`) +* Associated items should not get their own diagnostic items, but instead be + accessed indirectly by the diagnostic item of the type they're originating + from. +* Freestanding functions like `std::mem::swap()` should be named using + `snake_case` with one important (export) module as a prefix (Example: + `mem_swap`, `cmp_max`) +* Modules should usually not have a diagnostic item attached to them. + Diagnostic items were added to avoid the usage of paths, using them on + modules would therefore most likely to be counterproductive. +## Using diagnostic items In rustc, diagnostic items are looked up via [`Symbol`]s from inside the -[`rustc_span::symbol::sym`] module. These can then be mapped to [`DefId`]s using -[`TyCtxt::get_diagnostic_item()`] or checked if they match a [`DefId`] using -[`TyCtxt::is_diagnostic_item()`]. When mapping from a diagnostic item to a [`DefId`] the method -will return a `Option`. This can be `None` if either the symbol isn't a diagnostic item -or the type is not registered, for instance when compiling with `#[no_std]`. All following -examples are based on [`DefId`]s and their usage. - -### Check For A Type +[`rustc_span::symbol::sym`] module. These can then be mapped to [`DefId`]s +using [`TyCtxt::get_diagnostic_item()`] or checked if they match a [`DefId`] +using [`TyCtxt::is_diagnostic_item()`]. When mapping from a diagnostic item to +a [`DefId`] the method will return a `Option`. This can be `None` if +either the symbol isn't a diagnostic item or the type is not registered, for +instance when compiling with `#[no_std]`. All following examples are based on +[`DefId`]s and their usage. +### Example: Checking for a type ```rust use rustc_span::symbol::sym; @@ -92,8 +95,7 @@ fn example_1(cx: &LateContext<'_>, ty: Ty<'_>) -> bool { } ``` -### Check For A Trait Implementation - +### Example: Checking for a trait implementation ```rust /// This example checks if a given [`DefId`] from a method is part of a trait /// implementation defined by a diagnostic item. @@ -110,24 +112,23 @@ fn is_diag_trait_item( ``` ### Associated Types - -Associated types of diagnostic items can be accessed indirectly by first getting the [`DefId`] -of the trait and then calling [`TyCtxt::associated_items()`]. This returns an [`AssocItems`] -object which can be used for further checks. Checkout +Associated types of diagnostic items can be accessed indirectly by first +getting the [`DefId`] of the trait and then calling +[`TyCtxt::associated_items()`]. This returns an [`AssocItems`] object which can +be used for further checks. Checkout [`clippy_utils::ty::get_iterator_item_ty()`] for an example usage of this. -### Usage In Clippy +### Usage in Clippy +Clippy tries to use diagnostic items where possible and has developed some +wrapper and utility functions. Please also refer to its documentation when +using diagnostic items in Clippy. (See [*Common tools for writing +lints*][clippy-Common-tools-for-writing-lints].) -Clippy tries to use diagnostic items where possible and has developed some wrapper and utility -functions. Please also refer to its documentation when using diagnostic items in Clippy. (See -[*Common tools for writing lints*][clippy-Common-tools-for-writing-lints].) +## Related issues +This lists some related issues. These are probably only interesting to people +who really want to take a deep dive into the topic :) -## Related Issues - -This lists some related issues. These are probably only interesting to people who really want to -take a deep dive into the topic :) - -* [rust#60966]: The Rust PR that introduced diagnostic items +* [rust#60966]: The Rust PR that introduced diagnostic items * [rust-clippy#5393]: Clippy's tracking issue for moving away from hard coded paths to diagnostic item diff --git a/src/diagnostics/error-guaranteed.md b/src/diagnostics/error-guaranteed.md index 5a9b7f33..d92ba62a 100644 --- a/src/diagnostics/error-guaranteed.md +++ b/src/diagnostics/error-guaranteed.md @@ -1,5 +1,4 @@ # `ErrorGuaranteed` - The previous sections have been about the error message that a user of the compiler sees. But emitting an error can also have a second important side effect within the compiler source code: it generates an @@ -19,7 +18,6 @@ There are some important considerations about the usage of `ErrorGuaranteed`: Thus, you should not rely on `ErrorGuaranteed` when deciding whether to emit an error, or what kind of error to emit. - * `ErrorGuaranteed` should not be used to indicate that a compilation _will emit_ an error in the future. It should be used to indicate that an error _has already been_ emitted -- that is, the [`emit()`][emit] function has @@ -30,7 +28,6 @@ There are some important considerations about the usage of `ErrorGuaranteed`: Thankfully, in most cases, it should be statically impossible to abuse `ErrorGuaranteed`. - [errorguar]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_errors/struct.ErrorGuaranteed.html [rerrors]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_errors/index.html [dsp]: https://doc.rust-lang.org/nightly/nightly-rustc/rustc_errors/struct.Handler.html#method.delay_span_bug diff --git a/src/diagnostics/lintstore.md b/src/diagnostics/lintstore.md index 489771da..39007f8d 100644 --- a/src/diagnostics/lintstore.md +++ b/src/diagnostics/lintstore.md @@ -1,104 +1,110 @@ # Lints - This page documents some of the machinery around lint registration and how we run lints in the compiler. -The [`LintStore`] is the central piece of infrastructure, around which everything -rotates. It's not available during the early parts of compilation (i.e., before -TyCtxt) in most code, as we need to fill it in with all of the lints, which can only happen after -plugin registration. +The [`LintStore`] is the central piece of infrastructure, around which +everything rotates. It's not available during the early parts of compilation +(i.e., before TyCtxt) in most code, as we need to fill it in with all of the +lints, which can only happen after plugin registration. ## Lints vs. lint passes +There are two parts to the linting mechanism within the compiler: lints and +lint passes. Unfortunately, a lot of the documentation we have refers to both +of these as just "lints." -There are two parts to the linting mechanism within the compiler: lints and lint passes. -Unfortunately, a lot of the documentation we have refers to both of these as just "lints." - -First, we have the lint declarations themselves: this is where the name and default lint level and -other metadata come from. These are normally defined by way of the [`declare_lint!`] macro, which -boils down to a static with type `&rustc_session::lint::Lint`. +First, we have the lint declarations themselves: this is where the name and +default lint level and other metadata come from. These are normally defined by +way of the [`declare_lint!`] macro, which boils down to a static with type +`&rustc_session::lint::Lint`. As of February 2022, we lint against direct declarations without the use of the macro today (although this may change in the future, as the macro is somewhat unwieldy to add new fields to, like all macros). -Lint declarations don't carry any "state" - they are merely global identifiers and descriptions of -lints. We assert at runtime that they are not registered twice (by lint name). +Lint declarations don't carry any "state" - they are merely global identifiers +and descriptions of lints. We assert at runtime that they are not registered +twice (by lint name). -Lint passes are the meat of any lint. Notably, there is not a one-to-one relationship between -lints and lint passes; a lint might not have any lint pass that emits it, it could have many, or -just one -- the compiler doesn't track whether a pass is in any way associated with a particular -lint, and frequently lints are emitted as part of other work (e.g., type checking, etc.). +Lint passes are the meat of any lint. Notably, there is not a one-to-one +relationship between lints and lint passes; a lint might not have any lint pass +that emits it, it could have many, or just one -- the compiler doesn't track +whether a pass is in any way associated with a particular lint, and frequently +lints are emitted as part of other work (e.g., type checking, etc.). ## Registration ### High-level overview +In [`rustc_interface::register_plugins`] the [`LintStore`] is created and all +lints are registered. + +There are four 'sources' of lints: -In [`rustc_interface::register_plugins`] the [`LintStore`] is created and all lints are registered. -There are four 'sources' of lints: * internal lints: lints only used by the rustc codebase -* builtin lints: lints built into the compiler and not provided by some outside source +* builtin lints: lints built into the compiler and not provided by some outside + source * plugin lints: lints created by plugins through the plugin system. -* `rustc_interface::Config`[`register_lints`]: lints passed into the compiler during construction +* `rustc_interface::Config`[`register_lints`]: lints passed into the compiler + during construction Lints are registered via the [`LintStore::register_lint`] function. This should happen just once for any lint, or an ICE will occur. -Once the registration is complete, we "freeze" the lint store by placing it in an `Lrc`. Later in -the driver, it's passed into the `GlobalCtxt` constructor where it lives in an immutable form from -then on. +Once the registration is complete, we "freeze" the lint store by placing it in +an `Lrc`. Later in the driver, it's passed into the `GlobalCtxt` constructor +where it lives in an immutable form from then on. -Lint passes are registered separately into one of the categories (pre-expansion, -early, late, late module). Passes are registered as a closure -- i.e., `impl -Fn() -> Box`, where `dyn X` is either an early or late lint pass trait -object. When we run the lint passes, we run the closure and then invoke the lint -pass methods. The lint pass methods take `&mut self` so they can keep track of state -internally. +Lint passes are registered separately into one of the categories +(pre-expansion, early, late, late module). Passes are registered as a closure +-- i.e., `impl Fn() -> Box`, where `dyn X` is either an early or late +lint pass trait object. When we run the lint passes, we run the closure and +then invoke the lint pass methods. The lint pass methods take `&mut self` so +they can keep track of state internally. #### Internal lints +These are lints used just by the compiler or plugins like `clippy`. They can be +found in `rustc_lint::internal`. -These are lints used just by the compiler or plugins like `clippy`. They can be found in -`rustc_lint::internal`. - -An example of such a lint is the check that lint passes are implemented using the -`declare_lint_pass!` macro and not by hand. This is accomplished with the +An example of such a lint is the check that lint passes are implemented using +the `declare_lint_pass!` macro and not by hand. This is accomplished with the `LINT_PASS_IMPL_WITHOUT_MACRO` lint. -Registration of these lints happens in the [`rustc_lint::register_internals`] function which is -called when constructing a new lint store inside [`rustc_lint::new_lint_store`]. +Registration of these lints happens in the [`rustc_lint::register_internals`] +function which is called when constructing a new lint store inside +[`rustc_lint::new_lint_store`]. ### Builtin Lints - These are primarily described in two places: `rustc_session::lint::builtin` and -`rustc_lint::builtin`. Often the first provides the definitions for the lints themselves, -and the latter provides the lint pass definitions (and implementations), but this is not always -true. +`rustc_lint::builtin`. Often the first provides the definitions for the lints +themselves, and the latter provides the lint pass definitions (and +implementations), but this is not always true. -The builtin lint registration happens in the [`rustc_lint::register_builtins`] function. Just like -with internal lints, this happens inside of [`rustc_lint::new_lint_store`]. +The builtin lint registration happens in the [`rustc_lint::register_builtins`] +function. Just like with internal lints, this happens inside of +[`rustc_lint::new_lint_store`]. #### Plugin lints +This is one of the primary use cases remaining for plugins/drivers. Plugins are +given access to the mutable `LintStore` during registration (which happens +inside of [`rustc_interface::register_plugins`]) and they can call any +functions they need on the `LintStore`, just like rustc code. -This is one of the primary use cases remaining for plugins/drivers. Plugins are given access -to the mutable `LintStore` during registration (which happens inside of -[`rustc_interface::register_plugins`]) and they can call any functions they need on -the `LintStore`, just like rustc code. - -Plugins are intended to declare lints with the `plugin` field set to true (e.g., by -way of the [`declare_tool_lint!`] macro), but this is purely for diagnostics and help text; -otherwise plugin lints are mostly just as first class as rustc builtin lints. +Plugins are intended to declare lints with the `plugin` field set to true +(e.g., by way of the [`declare_tool_lint!`] macro), but this is purely for +diagnostics and help text; otherwise plugin lints are mostly just as first +class as rustc builtin lints. #### Driver lints - -These are the lints provided by drivers via the `rustc_interface::Config` [`register_lints`] field, -which is a callback. Drivers should, if finding it already set, call the function currently set -within the callback they add. The best way for drivers to get access to this is by overriding the -`Callbacks::config` function which gives them direct access to the `Config` structure. +These are the lints provided by drivers via the `rustc_interface::Config` +[`register_lints`] field, which is a callback. Drivers should, if finding it +already set, call the function currently set within the callback they add. The +best way for drivers to get access to this is by overriding the +`Callbacks::config` function which gives them direct access to the `Config` +structure. ## Compiler lint passes are combined into one pass - Within the compiler, for performance reasons, we usually do not register dozens -of lint passes. Instead, we have a single lint pass of each variety -(e.g., `BuiltinCombinedModuleLateLintPass`) which will internally call all of the +of lint passes. Instead, we have a single lint pass of each variety (e.g., +`BuiltinCombinedModuleLateLintPass`) which will internally call all of the individual lint passes; this is because then we get the benefits of static over dynamic dispatch for each of the (often empty) trait methods.