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use proc_macro2::Span;
use quote::{quote, ToTokens};
use serde::{Deserialize, Serialize};
use std::fmt;
use super::{Docs, Ident, Param, SelfParam, TypeName};
/// A named lifetime, e.g. `'a`.
///
/// # Invariants
///
/// Cannot be `'static` or `'_`, use [`Lifetime`] to represent those instead.
#[derive(Clone, Debug, Hash, Eq, PartialEq, Serialize, PartialOrd, Ord)]
#[serde(transparent)]
pub struct NamedLifetime(Ident);
impl NamedLifetime {
pub fn name(&self) -> &Ident {
&self.0
}
}
impl<'de> Deserialize<'de> for NamedLifetime {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::Deserializer<'de>,
{
// Special `Deserialize` impl to ensure invariants.
let named = Ident::deserialize(deserializer)?;
if named.as_str() == "static" {
panic!("cannot be static");
}
Ok(NamedLifetime(named))
}
}
impl From<&syn::Lifetime> for NamedLifetime {
fn from(lt: &syn::Lifetime) -> Self {
Lifetime::from(lt).to_named().expect("cannot be static")
}
}
impl From<&NamedLifetime> for NamedLifetime {
fn from(this: &NamedLifetime) -> Self {
this.clone()
}
}
impl PartialEq<syn::Lifetime> for NamedLifetime {
fn eq(&self, other: &syn::Lifetime) -> bool {
other.ident == self.0.as_str()
}
}
impl fmt::Display for NamedLifetime {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(f, "'{}", self.0)
}
}
impl ToTokens for NamedLifetime {
fn to_tokens(&self, tokens: &mut proc_macro2::TokenStream) {
use proc_macro2::{Punct, Spacing};
Punct::new('\'', Spacing::Joint).to_tokens(tokens);
self.0.to_tokens(tokens);
}
}
/// A lifetime dependency graph used for tracking which lifetimes outlive,
/// and are outlived by, other lifetimes.
///
/// It is similar to [`syn::LifetimeDef`], except it can also track lifetime
/// bounds defined in the `where` clause.
#[derive(Clone, PartialEq, Eq, Hash, Debug)]
pub struct LifetimeEnv {
pub(crate) nodes: Vec<LifetimeNode>,
}
impl LifetimeEnv {
/// Construct an empty [`LifetimeEnv`].
///
/// To create one outside of this module, use `LifetimeEnv::from_method_item`
/// or `LifetimeEnv::from` on `&syn::Generics`.
fn new() -> Self {
Self { nodes: vec![] }
}
/// Iterate through the names of the lifetimes in scope.
pub fn names(&self) -> impl Iterator<Item = &NamedLifetime> + Clone {
self.nodes.iter().map(|node| &node.lifetime)
}
/// Returns a [`LifetimeEnv`] for a method, accounting for lifetimes and bounds
/// defined in both the impl block and the method, as well as implicit lifetime
/// bounds in the optional `self` param, other param, and optional return type.
/// For example, the type `&'a Foo<'b>` implies `'b: 'a`.
pub fn from_method_item(
method: &syn::ImplItemFn,
impl_generics: Option<&syn::Generics>,
self_param: Option<&SelfParam>,
params: &[Param],
return_type: Option<&TypeName>,
) -> Self {
let mut this = LifetimeEnv::new();
// The impl generics _must_ be loaded into the env first, since the method
// generics might use lifetimes defined in the impl, and `extend_generics`
// panics if `'a: 'b` where `'b` isn't declared by the time it finishes.
if let Some(generics) = impl_generics {
this.extend_generics(generics);
}
this.extend_generics(&method.sig.generics);
if let Some(self_param) = self_param {
this.extend_implicit_lifetime_bounds(&self_param.to_typename(), None);
}
for param in params {
this.extend_implicit_lifetime_bounds(&param.ty, None);
}
if let Some(return_type) = return_type {
this.extend_implicit_lifetime_bounds(return_type, None);
}
this
}
/// Returns a [`LifetimeEnv`] for a struct, accounding for lifetimes and bounds
/// defined in the struct generics, as well as implicit lifetime bounds in
/// the struct's fields. For example, the field `&'a Foo<'b>` implies `'b: 'a`.
pub fn from_struct_item(strct: &syn::ItemStruct, fields: &[(Ident, TypeName, Docs)]) -> Self {
let mut this = LifetimeEnv::new();
this.extend_generics(&strct.generics);
for (_, typ, _) in fields {
this.extend_implicit_lifetime_bounds(typ, None);
}
this
}
/// Traverse a type, adding any implicit lifetime bounds that arise from
/// having a reference to an opaque containing a lifetime.
/// For example, the type `&'a Foo<'b>` implies `'b: 'a`.
fn extend_implicit_lifetime_bounds(
&mut self,
typ: &TypeName,
behind_ref: Option<&NamedLifetime>,
) {
match typ {
TypeName::Named(path_type) => {
if let Some(borrow_lifetime) = behind_ref {
let explicit_longer_than_borrow =
LifetimeTransitivity::longer_than(self, borrow_lifetime);
let mut implicit_longer_than_borrow = vec![];
for path_lifetime in path_type.lifetimes.iter() {
if let Lifetime::Named(path_lifetime) = path_lifetime {
if !explicit_longer_than_borrow.contains(&path_lifetime) {
implicit_longer_than_borrow.push(path_lifetime);
}
}
}
self.extend_bounds(
implicit_longer_than_borrow
.into_iter()
.map(|path_lifetime| (path_lifetime, Some(borrow_lifetime))),
);
}
}
TypeName::Reference(lifetime, _, typ) => {
let behind_ref = if let Lifetime::Named(named) = lifetime {
Some(named)
} else {
None
};
self.extend_implicit_lifetime_bounds(typ, behind_ref);
}
TypeName::Option(typ) => self.extend_implicit_lifetime_bounds(typ, None),
TypeName::Result(ok, err, _) => {
self.extend_implicit_lifetime_bounds(ok, None);
self.extend_implicit_lifetime_bounds(err, None);
}
_ => {}
}
}
/// Add the lifetimes from generic parameters and where bounds.
fn extend_generics(&mut self, generics: &syn::Generics) {
let generic_bounds = generics.params.iter().map(|generic| match generic {
syn::GenericParam::Type(_) => panic!("generic types are unsupported"),
syn::GenericParam::Lifetime(def) => (&def.lifetime, &def.bounds),
syn::GenericParam::Const(_) => panic!("const generics are unsupported"),
});
let generic_defs = generic_bounds.clone().map(|(lifetime, _)| lifetime);
self.extend_lifetimes(generic_defs);
self.extend_bounds(generic_bounds);
if let Some(ref where_clause) = generics.where_clause {
self.extend_bounds(where_clause.predicates.iter().map(|pred| match pred {
syn::WherePredicate::Type(_) => panic!("trait bounds are unsupported"),
syn::WherePredicate::Lifetime(pred) => (&pred.lifetime, &pred.bounds),
_ => panic!("Found unknown kind of where predicate"),
}));
}
}
/// Returns the number of lifetimes in the graph.
pub fn len(&self) -> usize {
self.nodes.len()
}
/// Returns `true` if the graph contains no lifetimes.
pub fn is_empty(&self) -> bool {
self.nodes.is_empty()
}
/// `<'a, 'b, 'c>`
///
/// Write the existing lifetimes, excluding bounds, as generic parameters.
///
/// To include lifetime bounds, use [`LifetimeEnv::lifetime_defs_to_tokens`].
pub fn lifetimes_to_tokens(&self) -> proc_macro2::TokenStream {
if self.is_empty() {
return quote! {};
}
let lifetimes = self.nodes.iter().map(|node| &node.lifetime);
quote! { <#(#lifetimes),*> }
}
/// Returns the index of a lifetime in the graph, or `None` if the lifetime
/// isn't in the graph.
pub(crate) fn id<L>(&self, lifetime: &L) -> Option<usize>
where
NamedLifetime: PartialEq<L>,
{
self.nodes
.iter()
.position(|node| &node.lifetime == lifetime)
}
/// Add isolated lifetimes to the graph.
fn extend_lifetimes<'a, L, I>(&mut self, iter: I)
where
NamedLifetime: PartialEq<L> + From<&'a L>,
L: 'a,
I: IntoIterator<Item = &'a L>,
{
for lifetime in iter {
if self.id(lifetime).is_some() {
panic!(
"lifetime name `{}` declared twice in the same scope",
NamedLifetime::from(lifetime)
);
}
self.nodes.push(LifetimeNode {
lifetime: lifetime.into(),
shorter: vec![],
longer: vec![],
});
}
}
/// Add edges to the lifetime graph.
///
/// This method is decoupled from [`LifetimeEnv::extend_lifetimes`] because
/// generics can define new lifetimes, while `where` clauses cannot.
///
/// # Panics
///
/// This method panics if any of the lifetime bounds aren't already defined
/// in the graph. This isn't allowed by rustc in the first place, so it should
/// only ever occur when deserializing an invalid [`LifetimeEnv`].
fn extend_bounds<'a, L, B, I>(&mut self, iter: I)
where
NamedLifetime: PartialEq<L> + From<&'a L>,
L: 'a,
B: IntoIterator<Item = &'a L>,
I: IntoIterator<Item = (&'a L, B)>,
{
for (lifetime, bounds) in iter {
let long = self.id(lifetime).expect("use of undeclared lifetime, this is a bug: try calling `LifetimeEnv::extend_lifetimes` first");
for bound in bounds {
let short = self
.id(bound)
.expect("cannot use undeclared lifetime as a bound");
self.nodes[short].longer.push(long);
self.nodes[long].shorter.push(short);
}
}
}
}
impl fmt::Display for LifetimeEnv {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
self.to_token_stream().fmt(f)
}
}
impl ToTokens for LifetimeEnv {
fn to_tokens(&self, tokens: &mut proc_macro2::TokenStream) {
for node in self.nodes.iter() {
let lifetime = &node.lifetime;
if node.shorter.is_empty() {
tokens.extend(quote! { #lifetime, });
} else {
let bounds = node.shorter.iter().map(|&id| &self.nodes[id].lifetime);
tokens.extend(quote! { #lifetime: #(#bounds)+*, });
}
}
}
}
/// Serialize a [`LifetimeEnv`] as a map from lifetimes to their bounds.
impl Serialize for LifetimeEnv {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::Serializer,
{
use serde::ser::SerializeMap;
let mut seq = serializer.serialize_map(Some(self.len()))?;
for node in self.nodes.iter() {
/// Helper type for serializing bounds.
struct Bounds<'a> {
ids: &'a [usize],
nodes: &'a [LifetimeNode],
}
impl<'a> Serialize for Bounds<'a> {
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::Serializer,
{
use serde::ser::SerializeSeq;
let mut seq = serializer.serialize_seq(Some(self.ids.len()))?;
for &id in self.ids {
seq.serialize_element(&self.nodes[id].lifetime)?;
}
seq.end()
}
}
seq.serialize_entry(
&node.lifetime,
&Bounds {
ids: &node.shorter[..],
nodes: &self.nodes,
},
)?;
}
seq.end()
}
}
impl<'de> Deserialize<'de> for LifetimeEnv {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::Deserializer<'de>,
{
use std::collections::BTreeMap;
let m: BTreeMap<NamedLifetime, Vec<NamedLifetime>> =
Deserialize::deserialize(deserializer)?;
let mut this = LifetimeEnv::new();
this.extend_lifetimes(m.keys());
this.extend_bounds(m.iter());
Ok(this)
}
}
/// A lifetime, along with ptrs to all lifetimes that are explicitly
/// shorter/longer than it.
///
/// This type is internal to [`LifetimeGraph`]- the ptrs are stored as `usize`s,
/// meaning that they may be invalid if a `LifetimeEdges` is created in one
/// `LifetimeGraph` and then used in another.
#[derive(Clone, PartialEq, Eq, Hash, Debug)]
pub(crate) struct LifetimeNode {
/// The name of the lifetime.
pub(crate) lifetime: NamedLifetime,
/// Pointers to all lifetimes that this lives _at least_ as long as.
///
/// Note: This doesn't account for transitivity.
pub(crate) shorter: Vec<usize>,
/// Pointers to all lifetimes that live _at least_ as long as this.
///
/// Note: This doesn't account for transitivity.
pub(crate) longer: Vec<usize>,
}
/// A lifetime, analogous to [`syn::Lifetime`].
#[derive(Clone, Debug, Hash, Eq, PartialEq, Serialize, Deserialize)]
#[non_exhaustive]
pub enum Lifetime {
/// The `'static` lifetime.
Static,
/// A named lifetime, like `'a`.
Named(NamedLifetime),
/// An elided lifetime.
Anonymous,
}
impl Lifetime {
/// Returns the inner `NamedLifetime` if the lifetime is the `Named` variant,
/// otherwise `None`.
pub fn to_named(self) -> Option<NamedLifetime> {
if let Lifetime::Named(named) = self {
return Some(named);
}
None
}
/// Returns a reference to the inner `NamedLifetime` if the lifetime is the
/// `Named` variant, otherwise `None`.
pub fn as_named(&self) -> Option<&NamedLifetime> {
if let Lifetime::Named(named) = self {
return Some(named);
}
None
}
}
impl fmt::Display for Lifetime {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
match self {
Lifetime::Static => "'static".fmt(f),
Lifetime::Named(ref named) => named.fmt(f),
Lifetime::Anonymous => "'_".fmt(f),
}
}
}
impl ToTokens for Lifetime {
fn to_tokens(&self, tokens: &mut proc_macro2::TokenStream) {
match self {
Lifetime::Static => syn::Lifetime::new("'static", Span::call_site()).to_tokens(tokens),
Lifetime::Named(ref s) => s.to_tokens(tokens),
Lifetime::Anonymous => syn::Lifetime::new("'_", Span::call_site()).to_tokens(tokens),
};
}
}
impl From<&syn::Lifetime> for Lifetime {
fn from(lt: &syn::Lifetime) -> Self {
if lt.ident == "static" {
Self::Static
} else {
Self::Named(NamedLifetime((&lt.ident).into()))
}
}
}
impl From<&Option<syn::Lifetime>> for Lifetime {
fn from(lt: &Option<syn::Lifetime>) -> Self {
lt.as_ref().map(Into::into).unwrap_or(Self::Anonymous)
}
}
impl Lifetime {
/// Converts the [`Lifetime`] back into an AST node that can be spliced into a program.
pub fn to_syn(&self) -> Option<syn::Lifetime> {
match *self {
Self::Static => Some(syn::Lifetime::new("'static", Span::call_site())),
Self::Anonymous => None,
Self::Named(ref s) => Some(syn::Lifetime::new(&s.to_string(), Span::call_site())),
}
}
}
/// Collect all lifetimes that are either longer_or_shorter
pub struct LifetimeTransitivity<'env> {
env: &'env LifetimeEnv,
visited: Vec<bool>,
out: Vec<&'env NamedLifetime>,
longer_or_shorter: LongerOrShorter,
}
impl<'env> LifetimeTransitivity<'env> {
/// Returns a new [`LifetimeTransitivity`] that finds all longer lifetimes.
pub fn longer(env: &'env LifetimeEnv) -> Self {
Self::new(env, LongerOrShorter::Longer)
}
/// Returns a new [`LifetimeTransitivity`] that finds all shorter lifetimes.
pub fn shorter(env: &'env LifetimeEnv) -> Self {
Self::new(env, LongerOrShorter::Shorter)
}
/// Returns all the lifetimes longer than a provided `NamedLifetime`.
pub fn longer_than(env: &'env LifetimeEnv, named: &NamedLifetime) -> Vec<&'env NamedLifetime> {
let mut this = Self::new(env, LongerOrShorter::Longer);
this.visit(named);
this.finish()
}
/// Returns all the lifetimes shorter than the provided `NamedLifetime`.
pub fn shorter_than(env: &'env LifetimeEnv, named: &NamedLifetime) -> Vec<&'env NamedLifetime> {
let mut this = Self::new(env, LongerOrShorter::Shorter);
this.visit(named);
this.finish()
}
/// Returns a new [`LifetimeTransitivity`].
fn new(env: &'env LifetimeEnv, longer_or_shorter: LongerOrShorter) -> Self {
LifetimeTransitivity {
env,
visited: vec![false; env.len()],
out: vec![],
longer_or_shorter,
}
}
/// Visits a lifetime, as well as all the nodes it's transitively longer or
/// shorter than, depending on how the `LifetimeTransitivity` was constructed.
pub fn visit(&mut self, named: &NamedLifetime) {
if let Some(id) = self
.env
.nodes
.iter()
.position(|node| node.lifetime == *named)
{
self.dfs(id);
}
}
/// Performs depth-first search through the `LifetimeEnv` created at construction
/// for all nodes longer or shorter than the node at the provided index,
/// depending on how the `LifetimeTransitivity` was constructed.
fn dfs(&mut self, index: usize) {
// Note: all of these indexings SHOULD be valid because
// `visited.len() == nodes.len()`, and the ids come from
// calling `Iterator::position` on `nodes`, which never shrinks.
// So we should be able to change these to `get_unchecked`...
if !self.visited[index] {
self.visited[index] = true;
let node = &self.env.nodes[index];
self.out.push(&node.lifetime);
for &edge_index in self.longer_or_shorter.edges(node).iter() {
self.dfs(edge_index);
}
}
}
/// Returns the transitively reachable lifetimes.
pub fn finish(self) -> Vec<&'env NamedLifetime> {
self.out
}
}
/// A helper type for [`LifetimeTransitivity`] determining whether to find the
/// transitively longer or transitively shorter lifetimes.
enum LongerOrShorter {
Longer,
Shorter,
}
impl LongerOrShorter {
/// Returns either the indices of the longer or shorter lifetimes, depending
/// on `self`.
fn edges<'node>(&self, node: &'node LifetimeNode) -> &'node [usize] {
match self {
LongerOrShorter::Longer => &node.longer[..],
LongerOrShorter::Shorter => &node.shorter[..],
}
}
}