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expand.rs
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expand.rs
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use std::iter;
use proc_macro2::TokenStream;
use quote::{quote, quote_spanned, ToTokens};
use syn::visit_mut::VisitMut;
use syn::{
punctuated::Punctuated, spanned::Spanned, Block, Expr, ExprAsync, ExprCall, FieldPat, FnArg,
Ident, Item, ItemFn, Pat, PatIdent, PatReference, PatStruct, PatTuple, PatTupleStruct, PatType,
Path, ReturnType, Signature, Stmt, Token, Type, TypePath,
};
use crate::{
attr::{Field, Fields, FormatMode, InstrumentArgs, Level},
MaybeItemFn, MaybeItemFnRef,
};
/// Given an existing function, generate an instrumented version of that function
pub(crate) fn gen_function<'a, B: ToTokens + 'a>(
input: MaybeItemFnRef<'a, B>,
args: InstrumentArgs,
instrumented_function_name: &str,
self_type: Option<&TypePath>,
) -> proc_macro2::TokenStream {
// these are needed ahead of time, as ItemFn contains the function body _and_
// isn't representable inside a quote!/quote_spanned! macro
// (Syn's ToTokens isn't implemented for ItemFn)
let MaybeItemFnRef {
outer_attrs,
inner_attrs,
vis,
sig,
block,
} = input;
let Signature {
output,
inputs: params,
unsafety,
asyncness,
constness,
abi,
ident,
generics:
syn::Generics {
params: gen_params,
where_clause,
..
},
..
} = sig;
let warnings = args.warnings();
let (return_type, return_span) = if let ReturnType::Type(_, return_type) = &output {
(erase_impl_trait(return_type), return_type.span())
} else {
// Point at function name if we don't have an explicit return type
(syn::parse_quote! { () }, ident.span())
};
// Install a fake return statement as the first thing in the function
// body, so that we eagerly infer that the return type is what we
// declared in the async fn signature.
// The `#[allow(..)]` is given because the return statement is
// unreachable, but does affect inference, so it needs to be written
// exactly that way for it to do its magic.
let fake_return_edge = quote_spanned! {return_span=>
#[allow(unreachable_code, clippy::diverging_sub_expression, clippy::let_unit_value)]
if false {
let __tracing_attr_fake_return: #return_type =
unreachable!("this is just for type inference, and is unreachable code");
return __tracing_attr_fake_return;
}
};
let block = quote! {
{
#fake_return_edge
#block
}
};
let body = gen_block(
&block,
params,
asyncness.is_some(),
args,
instrumented_function_name,
self_type,
);
quote!(
#(#outer_attrs) *
#vis #constness #unsafety #asyncness #abi fn #ident<#gen_params>(#params) #output
#where_clause
{
#(#inner_attrs) *
#warnings
#body
}
)
}
/// Instrument a block
fn gen_block<B: ToTokens>(
block: &B,
params: &Punctuated<FnArg, Token![,]>,
async_context: bool,
mut args: InstrumentArgs,
instrumented_function_name: &str,
self_type: Option<&TypePath>,
) -> proc_macro2::TokenStream {
// generate the span's name
let span_name = args
// did the user override the span's name?
.name
.as_ref()
.map(|name| quote!(#name))
.unwrap_or_else(|| quote!(#instrumented_function_name));
let args_level = args.level();
let level = args_level.clone();
let follows_from = args.follows_from.iter();
let follows_from = quote! {
#(for cause in #follows_from {
__tracing_attr_span.follows_from(cause);
})*
};
// generate this inside a closure, so we can return early on errors.
let span = (|| {
// Pull out the arguments-to-be-skipped first, so we can filter results
// below.
let param_names: Vec<(Ident, (Ident, RecordType))> = params
.clone()
.into_iter()
.flat_map(|param| match param {
FnArg::Typed(PatType { pat, ty, .. }) => {
param_names(*pat, RecordType::parse_from_ty(&*ty))
}
FnArg::Receiver(_) => Box::new(iter::once((
Ident::new("self", param.span()),
RecordType::Debug,
))),
})
// Little dance with new (user-exposed) names and old (internal)
// names of identifiers. That way, we could do the following
// even though async_trait (<=0.1.43) rewrites "self" as "_self":
// ```
// #[async_trait]
// impl Foo for FooImpl {
// #[instrument(skip(self))]
// async fn foo(&self, v: usize) {}
// }
// ```
.map(|(x, record_type)| {
// if we are inside a function generated by async-trait <=0.1.43, we need to
// take care to rewrite "_self" as "self" for 'user convenience'
if self_type.is_some() && x == "_self" {
(Ident::new("self", x.span()), (x, record_type))
} else {
(x.clone(), (x, record_type))
}
})
.collect();
for skip in &args.skips {
if !param_names.iter().map(|(user, _)| user).any(|y| y == skip) {
return quote_spanned! {skip.span()=>
compile_error!("attempting to skip non-existent parameter")
};
}
}
let target = args.target();
let parent = args.parent.iter();
// filter out skipped fields
let quoted_fields: Vec<_> = param_names
.iter()
.filter(|(param, _)| {
if args.skips.contains(param) {
return false;
}
// If any parameters have the same name as a custom field, skip
// and allow them to be formatted by the custom field.
if let Some(ref fields) = args.fields {
fields.0.iter().all(|Field { ref name, .. }| {
let first = name.first();
first != name.last() || !first.iter().any(|name| name == ¶m)
})
} else {
true
}
})
.map(|(user_name, (real_name, record_type))| match record_type {
RecordType::Value => quote!(#user_name = #real_name),
RecordType::Debug => quote!(#user_name = tracing::field::debug(&#real_name)),
})
.collect();
// replace every use of a variable with its original name
if let Some(Fields(ref mut fields)) = args.fields {
let mut replacer = IdentAndTypesRenamer {
idents: param_names.into_iter().map(|(a, (b, _))| (a, b)).collect(),
types: Vec::new(),
};
// when async-trait <=0.1.43 is in use, replace instances
// of the "Self" type inside the fields values
if let Some(self_type) = self_type {
replacer.types.push(("Self", self_type.clone()));
}
for e in fields.iter_mut().filter_map(|f| f.value.as_mut()) {
syn::visit_mut::visit_expr_mut(&mut replacer, e);
}
}
let custom_fields = &args.fields;
quote!(tracing::span!(
target: #target,
#(parent: #parent,)*
#level,
#span_name,
#(#quoted_fields,)*
#custom_fields
))
})();
let target = args.target();
let err_event = match args.err_args {
Some(event_args) => {
let level_tokens = event_args.level(Level::Error);
match event_args.mode {
FormatMode::Default | FormatMode::Display => Some(quote!(
tracing::event!(target: #target, #level_tokens, error = %e)
)),
FormatMode::Debug => Some(quote!(
tracing::event!(target: #target, #level_tokens, error = ?e)
)),
}
}
_ => None,
};
let ret_event = match args.ret_args {
Some(event_args) => {
let level_tokens = event_args.level(args_level);
match event_args.mode {
FormatMode::Display => Some(quote!(
tracing::event!(target: #target, #level_tokens, return = %x)
)),
FormatMode::Default | FormatMode::Debug => Some(quote!(
tracing::event!(target: #target, #level_tokens, return = ?x)
)),
}
}
_ => None,
};
// Generate the instrumented function body.
// If the function is an `async fn`, this will wrap it in an async block,
// which is `instrument`ed using `tracing-futures`. Otherwise, this will
// enter the span and then perform the rest of the body.
// If `err` is in args, instrument any resulting `Err`s.
// If `ret` is in args, instrument any resulting `Ok`s when the function
// returns `Result`s, otherwise instrument any resulting values.
if async_context {
let mk_fut = match (err_event, ret_event) {
(Some(err_event), Some(ret_event)) => quote_spanned!(block.span()=>
async move {
match async move #block.await {
#[allow(clippy::unit_arg)]
Ok(x) => {
#ret_event;
Ok(x)
},
Err(e) => {
#err_event;
Err(e)
}
}
}
),
(Some(err_event), None) => quote_spanned!(block.span()=>
async move {
match async move #block.await {
#[allow(clippy::unit_arg)]
Ok(x) => Ok(x),
Err(e) => {
#err_event;
Err(e)
}
}
}
),
(None, Some(ret_event)) => quote_spanned!(block.span()=>
async move {
let x = async move #block.await;
#ret_event;
x
}
),
(None, None) => quote_spanned!(block.span()=>
async move #block
),
};
return quote!(
let __tracing_attr_span = #span;
let __tracing_instrument_future = #mk_fut;
if !__tracing_attr_span.is_disabled() {
#follows_from
tracing::Instrument::instrument(
__tracing_instrument_future,
__tracing_attr_span
)
.await
} else {
__tracing_instrument_future.await
}
);
}
let span = quote!(
// These variables are left uninitialized and initialized only
// if the tracing level is statically enabled at this point.
// While the tracing level is also checked at span creation
// time, that will still create a dummy span, and a dummy guard
// and drop the dummy guard later. By lazily initializing these
// variables, Rust will generate a drop flag for them and thus
// only drop the guard if it was created. This creates code that
// is very straightforward for LLVM to optimize out if the tracing
// level is statically disabled, while not causing any performance
// regression in case the level is enabled.
let __tracing_attr_span;
let __tracing_attr_guard;
if tracing::level_enabled!(#level) {
__tracing_attr_span = #span;
#follows_from
__tracing_attr_guard = __tracing_attr_span.enter();
}
);
match (err_event, ret_event) {
(Some(err_event), Some(ret_event)) => quote_spanned! {block.span()=>
#span
#[allow(clippy::redundant_closure_call)]
match (move || #block)() {
#[allow(clippy::unit_arg)]
Ok(x) => {
#ret_event;
Ok(x)
},
Err(e) => {
#err_event;
Err(e)
}
}
},
(Some(err_event), None) => quote_spanned!(block.span()=>
#span
#[allow(clippy::redundant_closure_call)]
match (move || #block)() {
#[allow(clippy::unit_arg)]
Ok(x) => Ok(x),
Err(e) => {
#err_event;
Err(e)
}
}
),
(None, Some(ret_event)) => quote_spanned!(block.span()=>
#span
#[allow(clippy::redundant_closure_call)]
let x = (move || #block)();
#ret_event;
x
),
(None, None) => quote_spanned!(block.span() =>
// Because `quote` produces a stream of tokens _without_ whitespace, the
// `if` and the block will appear directly next to each other. This
// generates a clippy lint about suspicious `if/else` formatting.
// Therefore, suppress the lint inside the generated code...
#[allow(clippy::suspicious_else_formatting)]
{
#span
// ...but turn the lint back on inside the function body.
#[warn(clippy::suspicious_else_formatting)]
#block
}
),
}
}
/// Indicates whether a field should be recorded as `Value` or `Debug`.
enum RecordType {
/// The field should be recorded using its `Value` implementation.
Value,
/// The field should be recorded using `tracing::field::debug()`.
Debug,
}
impl RecordType {
/// Array of primitive types which should be recorded as [RecordType::Value].
const TYPES_FOR_VALUE: &'static [&'static str] = &[
"bool",
"str",
"u8",
"i8",
"u16",
"i16",
"u32",
"i32",
"u64",
"i64",
"f32",
"f64",
"usize",
"isize",
"NonZeroU8",
"NonZeroI8",
"NonZeroU16",
"NonZeroI16",
"NonZeroU32",
"NonZeroI32",
"NonZeroU64",
"NonZeroI64",
"NonZeroUsize",
"NonZeroIsize",
"Wrapping",
];
/// Parse `RecordType` from [Type] by looking up
/// the [RecordType::TYPES_FOR_VALUE] array.
fn parse_from_ty(ty: &Type) -> Self {
match ty {
Type::Path(TypePath { path, .. })
if path
.segments
.iter()
.last()
.map(|path_segment| {
let ident = path_segment.ident.to_string();
Self::TYPES_FOR_VALUE.iter().any(|&t| t == ident)
})
.unwrap_or(false) =>
{
RecordType::Value
}
Type::Reference(syn::TypeReference { elem, .. }) => RecordType::parse_from_ty(elem),
_ => RecordType::Debug,
}
}
}
fn param_names(pat: Pat, record_type: RecordType) -> Box<dyn Iterator<Item = (Ident, RecordType)>> {
match pat {
Pat::Ident(PatIdent { ident, .. }) => Box::new(iter::once((ident, record_type))),
Pat::Reference(PatReference { pat, .. }) => param_names(*pat, record_type),
// We can't get the concrete type of fields in the struct/tuple
// patterns by using `syn`. e.g. `fn foo(Foo { x, y }: Foo) {}`.
// Therefore, the struct/tuple patterns in the arguments will just
// always be recorded as `RecordType::Debug`.
Pat::Struct(PatStruct { fields, .. }) => Box::new(
fields
.into_iter()
.flat_map(|FieldPat { pat, .. }| param_names(*pat, RecordType::Debug)),
),
Pat::Tuple(PatTuple { elems, .. }) => Box::new(
elems
.into_iter()
.flat_map(|p| param_names(p, RecordType::Debug)),
),
Pat::TupleStruct(PatTupleStruct {
pat: PatTuple { elems, .. },
..
}) => Box::new(
elems
.into_iter()
.flat_map(|p| param_names(p, RecordType::Debug)),
),
// The above *should* cover all cases of irrefutable patterns,
// but we purposefully don't do any funny business here
// (such as panicking) because that would obscure rustc's
// much more informative error message.
_ => Box::new(iter::empty()),
}
}
/// The specific async code pattern that was detected
enum AsyncKind<'a> {
/// Immediately-invoked async fn, as generated by `async-trait <= 0.1.43`:
/// `async fn foo<...>(...) {...}; Box::pin(foo<...>(...))`
Function(&'a ItemFn),
/// A function returning an async (move) block, optionally `Box::pin`-ed,
/// as generated by `async-trait >= 0.1.44`:
/// `Box::pin(async move { ... })`
Async {
async_expr: &'a ExprAsync,
pinned_box: bool,
},
}
pub(crate) struct AsyncInfo<'block> {
// statement that must be patched
source_stmt: &'block Stmt,
kind: AsyncKind<'block>,
self_type: Option<TypePath>,
input: &'block ItemFn,
}
impl<'block> AsyncInfo<'block> {
/// Get the AST of the inner function we need to hook, if it looks like a
/// manual future implementation.
///
/// When we are given a function that returns a (pinned) future containing the
/// user logic, it is that (pinned) future that needs to be instrumented.
/// Were we to instrument its parent, we would only collect information
/// regarding the allocation of that future, and not its own span of execution.
///
/// We inspect the block of the function to find if it matches any of the
/// following patterns:
///
/// - Immediately-invoked async fn, as generated by `async-trait <= 0.1.43`:
/// `async fn foo<...>(...) {...}; Box::pin(foo<...>(...))`
///
/// - A function returning an async (move) block, optionally `Box::pin`-ed,
/// as generated by `async-trait >= 0.1.44`:
/// `Box::pin(async move { ... })`
///
/// We the return the statement that must be instrumented, along with some
/// other information.
/// 'gen_body' will then be able to use that information to instrument the
/// proper function/future.
///
/// (this follows the approach suggested in
/// https://github.com/dtolnay/async-trait/issues/45#issuecomment-571245673)
pub(crate) fn from_fn(input: &'block ItemFn) -> Option<Self> {
// are we in an async context? If yes, this isn't a manual async-like pattern
if input.sig.asyncness.is_some() {
return None;
}
let block = &input.block;
// list of async functions declared inside the block
let inside_funs = block.stmts.iter().filter_map(|stmt| {
if let Stmt::Item(Item::Fn(fun)) = &stmt {
// If the function is async, this is a candidate
if fun.sig.asyncness.is_some() {
return Some((stmt, fun));
}
}
None
});
// last expression of the block: it determines the return value of the
// block, this is quite likely a `Box::pin` statement or an async block
let (last_expr_stmt, last_expr) = block.stmts.iter().rev().find_map(|stmt| {
if let Stmt::Expr(expr) = stmt {
Some((stmt, expr))
} else {
None
}
})?;
// is the last expression an async block?
if let Expr::Async(async_expr) = last_expr {
return Some(AsyncInfo {
source_stmt: last_expr_stmt,
kind: AsyncKind::Async {
async_expr,
pinned_box: false,
},
self_type: None,
input,
});
}
// is the last expression a function call?
let (outside_func, outside_args) = match last_expr {
Expr::Call(ExprCall { func, args, .. }) => (func, args),
_ => return None,
};
// is it a call to `Box::pin()`?
let path = match outside_func.as_ref() {
Expr::Path(path) => &path.path,
_ => return None,
};
if !path_to_string(path).ends_with("Box::pin") {
return None;
}
// Does the call take an argument? If it doesn't,
// it's not gonna compile anyway, but that's no reason
// to (try to) perform an out of bounds access
if outside_args.is_empty() {
return None;
}
// Is the argument to Box::pin an async block that
// captures its arguments?
if let Expr::Async(async_expr) = &outside_args[0] {
return Some(AsyncInfo {
source_stmt: last_expr_stmt,
kind: AsyncKind::Async {
async_expr,
pinned_box: true,
},
self_type: None,
input,
});
}
// Is the argument to Box::pin a function call itself?
let func = match &outside_args[0] {
Expr::Call(ExprCall { func, .. }) => func,
_ => return None,
};
// "stringify" the path of the function called
let func_name = match **func {
Expr::Path(ref func_path) => path_to_string(&func_path.path),
_ => return None,
};
// Was that function defined inside of the current block?
// If so, retrieve the statement where it was declared and the function itself
let (stmt_func_declaration, func) = inside_funs
.into_iter()
.find(|(_, fun)| fun.sig.ident == func_name)?;
// If "_self" is present as an argument, we store its type to be able to rewrite "Self" (the
// parameter type) with the type of "_self"
let mut self_type = None;
for arg in &func.sig.inputs {
if let FnArg::Typed(ty) = arg {
if let Pat::Ident(PatIdent { ref ident, .. }) = *ty.pat {
if ident == "_self" {
let mut ty = *ty.ty.clone();
// extract the inner type if the argument is "&self" or "&mut self"
if let Type::Reference(syn::TypeReference { elem, .. }) = ty {
ty = *elem;
}
if let Type::Path(tp) = ty {
self_type = Some(tp);
break;
}
}
}
}
}
Some(AsyncInfo {
source_stmt: stmt_func_declaration,
kind: AsyncKind::Function(func),
self_type,
input,
})
}
pub(crate) fn gen_async(
self,
args: InstrumentArgs,
instrumented_function_name: &str,
) -> Result<proc_macro::TokenStream, syn::Error> {
// let's rewrite some statements!
let mut out_stmts: Vec<TokenStream> = self
.input
.block
.stmts
.iter()
.map(|stmt| stmt.to_token_stream())
.collect();
if let Some((iter, _stmt)) = self
.input
.block
.stmts
.iter()
.enumerate()
.find(|(_iter, stmt)| *stmt == self.source_stmt)
{
// instrument the future by rewriting the corresponding statement
out_stmts[iter] = match self.kind {
// `Box::pin(immediately_invoked_async_fn())`
AsyncKind::Function(fun) => {
let fun = MaybeItemFn::from(fun.clone());
gen_function(
fun.as_ref(),
args,
instrumented_function_name,
self.self_type.as_ref(),
)
}
// `async move { ... }`, optionally pinned
AsyncKind::Async {
async_expr,
pinned_box,
} => {
let instrumented_block = gen_block(
&async_expr.block,
&self.input.sig.inputs,
true,
args,
instrumented_function_name,
None,
);
let async_attrs = &async_expr.attrs;
if pinned_box {
quote! {
Box::pin(#(#async_attrs) * async move { #instrumented_block })
}
} else {
quote! {
#(#async_attrs) * async move { #instrumented_block }
}
}
}
};
}
let vis = &self.input.vis;
let sig = &self.input.sig;
let attrs = &self.input.attrs;
Ok(quote!(
#(#attrs) *
#vis #sig {
#(#out_stmts) *
}
)
.into())
}
}
// Return a path as a String
fn path_to_string(path: &Path) -> String {
use std::fmt::Write;
// some heuristic to prevent too many allocations
let mut res = String::with_capacity(path.segments.len() * 5);
for i in 0..path.segments.len() {
write!(&mut res, "{}", path.segments[i].ident)
.expect("writing to a String should never fail");
if i < path.segments.len() - 1 {
res.push_str("::");
}
}
res
}
/// A visitor struct to replace idents and types in some piece
/// of code (e.g. the "self" and "Self" tokens in user-supplied
/// fields expressions when the function is generated by an old
/// version of async-trait).
struct IdentAndTypesRenamer<'a> {
types: Vec<(&'a str, TypePath)>,
idents: Vec<(Ident, Ident)>,
}
impl<'a> VisitMut for IdentAndTypesRenamer<'a> {
// we deliberately compare strings because we want to ignore the spans
// If we apply clippy's lint, the behavior changes
#[allow(clippy::cmp_owned)]
fn visit_ident_mut(&mut self, id: &mut Ident) {
for (old_ident, new_ident) in &self.idents {
if id.to_string() == old_ident.to_string() {
*id = new_ident.clone();
}
}
}
fn visit_type_mut(&mut self, ty: &mut Type) {
for (type_name, new_type) in &self.types {
if let Type::Path(TypePath { path, .. }) = ty {
if path_to_string(path) == *type_name {
*ty = Type::Path(new_type.clone());
}
}
}
}
}
// A visitor struct that replace an async block by its patched version
struct AsyncTraitBlockReplacer<'a> {
block: &'a Block,
patched_block: Block,
}
impl<'a> VisitMut for AsyncTraitBlockReplacer<'a> {
fn visit_block_mut(&mut self, i: &mut Block) {
if i == self.block {
*i = self.patched_block.clone();
}
}
}
// Replaces any `impl Trait` with `_` so it can be used as the type in
// a `let` statement's LHS.
struct ImplTraitEraser;
impl VisitMut for ImplTraitEraser {
fn visit_type_mut(&mut self, t: &mut Type) {
if let Type::ImplTrait(..) = t {
*t = syn::TypeInfer {
underscore_token: Token![_](t.span()),
}
.into();
} else {
syn::visit_mut::visit_type_mut(self, t);
}
}
}
fn erase_impl_trait(ty: &Type) -> Type {
let mut ty = ty.clone();
ImplTraitEraser.visit_type_mut(&mut ty);
ty
}