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use std::fmt::{self, Debug, Display, Write};
use indexmap::IndexMap;
use std::collections::hash_map::RandomState;
use crate::docs::Docs;
use crate::formatter::Formatter;
use crate::function::Function;
use crate::import::Import;
use crate::item::Item;
use crate::module::Module;
use crate::r#enum::Enum;
use crate::r#impl::Impl;
use crate::r#struct::Struct;
use crate::r#trait::Trait;
use crate::type_alias::TypeAlias;
/// Defines a scope.
///
/// A scope contains modules, types, etc...
#[derive(Debug, Clone)]
pub struct Scope {
/// Scope documentation
docs: Option<Docs>,
/// Imports
imports: IndexMap<String, IndexMap<String, Import, RandomState>, RandomState>,
/// Contents of the documentation,
items: Vec<Item>,
}
impl Default for Scope {
fn default() -> Self {
Self::new()
}
}
impl Scope {
/// Returns a new scope
pub fn new() -> Self {
Scope {
docs: None,
imports: IndexMap::with_hasher(RandomState::new()),
items: vec![],
}
}
/// Set the scope documentation.
pub fn doc(&mut self, docs: impl ToString) -> &mut Self {
self.docs = Some(Docs::new(docs));
self
}
/// Import a type into the scope.
///
/// This results in a new `use` statement being added to the beginning of
/// the scope.
pub fn import(&mut self, path: impl ToString, ty: impl ToString) -> &mut Import {
// handle cases where the caller wants to refer to a type namespaced
// within the containing namespace, like "a::B".
let ty = ty.to_string();
let ty = ty.split("::").next().unwrap_or(ty.as_str());
self.imports
.entry(path.to_string())
.or_insert(IndexMap::with_hasher(RandomState::new()))
.entry(ty.to_string())
.or_insert_with(|| Import::new(path, ty))
}
/// Push a new module definition, returning a mutable reference to it.
///
/// # Panics
///
/// Since a module's name must uniquely identify it within the scope in
/// which it is defined, pushing a module whose name is already defined
/// in this scope will cause this function to panic.
///
/// In many cases, the [`get_or_new_module`] function is preferrable, as it
/// will return the existing definition instead.
///
/// [`get_or_new_module`]: #method.get_or_new_module
pub fn new_module(&mut self, name: impl ToString) -> &mut Module {
self.push_module(Module::new(name));
match *self.items.last_mut().unwrap() {
Item::Module(ref mut v) => v,
_ => unreachable!(),
}
}
/// Returns a mutable reference to a module if it is exists in this scope.
pub fn get_module_mut<Q: ?Sized>(&mut self, name: &Q) -> Option<&mut Module>
where
String: PartialEq<Q>,
{
self.items
.iter_mut()
.filter_map(|item| match item {
&mut Item::Module(ref mut module) if module.name == *name => Some(module),
_ => None,
})
.next()
}
/// Returns a mutable reference to a module if it is exists in this scope.
pub fn get_module<Q: ?Sized>(&self, name: &Q) -> Option<&Module>
where
String: PartialEq<Q>,
{
self.items
.iter()
.filter_map(|item| match item {
Item::Module(module) if module.name == *name => Some(module),
_ => None,
})
.next()
}
/// Returns a mutable reference to a module, creating it if it does
/// not exist.
pub fn get_or_new_module<Q: ?Sized + Display>(&mut self, name: &Q) -> &mut Module
where
String: PartialEq<Q>,
{
if self.get_module(name).is_some() {
self.get_module_mut(name).unwrap()
} else {
self.new_module(name)
}
}
/// Push a module definition.
///
/// # Panics
///
/// Since a module's name must uniquely identify it within the scope in
/// which it is defined, pushing a module whose name is already defined
/// in this scope will cause this function to panic.
///
/// In many cases, the [`get_or_new_module`] function is preferrable, as it will
/// return the existing definition instead.
///
/// [`get_or_new_module`]: #method.get_or_new_module
pub fn push_module(&mut self, item: Module) -> &mut Self {
assert!(self.get_module(&item.name).is_none());
self.items.push(Item::Module(item));
self
}
/// Push a new struct definition, returning a mutable reference to it.
pub fn new_struct(&mut self, name: impl ToString) -> &mut Struct {
self.push_struct(Struct::new(name));
match *self.items.last_mut().unwrap() {
Item::Struct(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push a struct definition
pub fn push_struct(&mut self, item: Struct) -> &mut Self {
self.items.push(Item::Struct(item));
self
}
/// Push a new function definition, returning a mutable reference to it.
pub fn new_fn(&mut self, name: impl ToString) -> &mut Function {
self.push_fn(Function::new(name));
match *self.items.last_mut().unwrap() {
Item::Function(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push a function definition
pub fn push_fn(&mut self, item: Function) -> &mut Self {
self.items.push(Item::Function(item));
self
}
/// Push a new trait definition, returning a mutable reference to it.
pub fn new_trait(&mut self, name: impl ToString) -> &mut Trait {
self.push_trait(Trait::new(name));
match *self.items.last_mut().unwrap() {
Item::Trait(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push a trait definition
pub fn push_trait(&mut self, item: Trait) -> &mut Self {
self.items.push(Item::Trait(item));
self
}
/// Push a new struct definition, returning a mutable reference to it.
pub fn new_enum(&mut self, name: impl ToString) -> &mut Enum {
self.push_enum(Enum::new(name));
match *self.items.last_mut().unwrap() {
Item::Enum(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push a structure definition
pub fn push_enum(&mut self, item: Enum) -> &mut Self {
self.items.push(Item::Enum(item));
self
}
/// Push a new `impl` block, returning a mutable reference to it.
pub fn new_impl(&mut self, target: impl ToString) -> &mut Impl {
self.push_impl(Impl::new(target));
match *self.items.last_mut().unwrap() {
Item::Impl(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push an `impl` block.
pub fn push_impl(&mut self, item: Impl) -> &mut Self {
self.items.push(Item::Impl(item));
self
}
/// Push a raw string to the scope.
///
/// This string will be included verbatim in the formatted string.
pub fn raw(&mut self, val: impl ToString) -> &mut Self {
self.items.push(Item::Raw(val.to_string()));
self
}
/// Push a new `TypeAlias`, returning a mutable reference to it.
pub fn new_type_alias(&mut self, name: impl ToString, target: impl ToString) -> &mut TypeAlias {
self.push_type_alias(TypeAlias::new(name, target));
match *self.items.last_mut().unwrap() {
Item::TypeAlias(ref mut v) => v,
_ => unreachable!(),
}
}
/// Push an `TypeAlias`.
pub fn push_type_alias(&mut self, item: TypeAlias) -> &mut Self {
self.items.push(Item::TypeAlias(item));
self
}
// TODO: remove this and implement fmt::Display
//
/// Return a string representation of the scope.
#[allow(
clippy::inherent_to_string,
reason = "our formatter does not 100% match the requirements for Display"
)]
pub fn to_string(&self) -> String {
let mut ret = String::new();
self.fmt(&mut Formatter::new(&mut ret)).unwrap();
// Remove the trailing newline
if let Some(b'\n') = ret.as_bytes().last() {
ret.pop();
}
ret
}
/// Formats the scope using the given formatter.
pub fn fmt(&self, fmt: &mut Formatter<'_>) -> fmt::Result {
if let Some(ref docs) = self.docs {
docs.fmt(fmt)?;
}
self.fmt_imports(fmt)?;
if !self.imports.is_empty() {
writeln!(fmt)?;
}
for (i, item) in self.items.iter().enumerate() {
if i != 0 {
writeln!(fmt)?;
}
match *item {
Item::Module(ref v) => v.fmt(fmt)?,
Item::Struct(ref v) => v.fmt(fmt)?,
Item::Function(ref v) => v.fmt(false, fmt)?,
Item::Trait(ref v) => v.fmt(fmt)?,
Item::Enum(ref v) => v.fmt(fmt)?,
Item::Impl(ref v) => v.fmt(fmt)?,
Item::Raw(ref v) => {
writeln!(fmt, "{}", v)?;
}
Item::TypeAlias(ref v) => v.fmt(fmt)?,
}
}
Ok(())
}
fn fmt_imports(&self, fmt: &mut Formatter<'_>) -> fmt::Result {
// First, collect all visibilities
let mut visibilities = vec![];
for (_, imports) in &self.imports {
for (_, import) in imports {
if !visibilities.contains(&import.vis) {
visibilities.push(import.vis.clone());
}
}
}
let mut tys = vec![];
// Loop over all visibilities and format the associated imports
for vis in &visibilities {
for (path, imports) in &self.imports {
tys.clear();
for (ty, import) in imports {
if *vis == import.vis {
tys.push(ty);
}
}
if !tys.is_empty() {
if let Some(ref vis) = *vis {
write!(fmt, "{} ", vis)?;
}
write!(fmt, "use {}::", path)?;
if tys.len() > 1 {
write!(fmt, "{{")?;
for (i, ty) in tys.iter().enumerate() {
if i != 0 {
write!(fmt, ", ")?;
}
write!(fmt, "{}", ty)?;
}
writeln!(fmt, "}};")?;
} else if tys.len() == 1 {
writeln!(fmt, "{};", tys[0])?;
}
}
}
}
Ok(())
}
}