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rust/src/librustc_save_analysis/dump_visitor.rs
Eduard-Mihai Burtescu da0a47a081 Use NodeId/HirId instead of DefId for local variables.
2017-09-08 22:00:59 +03:00

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// Copyright 2015 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
//! Write the output of rustc's analysis to an implementor of Dump.
//!
//! Dumping the analysis is implemented by walking the AST and getting a bunch of
//! info out from all over the place. We use Def IDs to identify objects. The
//! tricky part is getting syntactic (span, source text) and semantic (reference
//! Def IDs) information for parts of expressions which the compiler has discarded.
//! E.g., in a path `foo::bar::baz`, the compiler only keeps a span for the whole
//! path and a reference to `baz`, but we want spans and references for all three
//! idents.
//!
//! SpanUtils is used to manipulate spans. In particular, to extract sub-spans
//! from spans (e.g., the span for `bar` from the above example path).
//! DumpVisitor walks the AST and processes it, and an implementor of Dump
//! is used for recording the output in a format-agnostic way (see CsvDumper
//! for an example).
use rustc::hir::def::Def as HirDef;
use rustc::hir::def_id::DefId;
use rustc::hir::map::Node;
use rustc::ty::{self, TyCtxt};
use rustc_data_structures::fx::FxHashSet;
use std::path::Path;
use syntax::ast::{self, NodeId, PatKind, Attribute, CRATE_NODE_ID};
use syntax::parse::token;
use syntax::symbol::keywords;
use syntax::visit::{self, Visitor};
use syntax::print::pprust::{path_to_string, ty_to_string, bounds_to_string, generics_to_string};
use syntax::ptr::P;
use syntax::codemap::Spanned;
use syntax_pos::*;
use {escape, generated_code, SaveContext, PathCollector, lower_attributes};
use json_dumper::{JsonDumper, DumpOutput};
use span_utils::SpanUtils;
use sig;
use rls_data::{CratePreludeData, Import, ImportKind, SpanData, Ref, RefKind,
Def, DefKind, Relation, RelationKind};
macro_rules! down_cast_data {
($id:ident, $kind:ident, $sp:expr) => {
let $id = if let super::Data::$kind(data) = $id {
data
} else {
span_bug!($sp, "unexpected data kind: {:?}", $id);
};
};
}
pub struct DumpVisitor<'l, 'tcx: 'l, 'll, O: DumpOutput + 'll> {
save_ctxt: SaveContext<'l, 'tcx>,
tcx: TyCtxt<'l, 'tcx, 'tcx>,
dumper: &'ll mut JsonDumper<O>,
span: SpanUtils<'l>,
cur_scope: NodeId,
// Set of macro definition (callee) spans, and the set
// of macro use (callsite) spans. We store these to ensure
// we only write one macro def per unique macro definition, and
// one macro use per unique callsite span.
// mac_defs: HashSet<Span>,
macro_calls: FxHashSet<Span>,
}
impl<'l, 'tcx: 'l, 'll, O: DumpOutput + 'll> DumpVisitor<'l, 'tcx, 'll, O> {
pub fn new(save_ctxt: SaveContext<'l, 'tcx>,
dumper: &'ll mut JsonDumper<O>)
-> DumpVisitor<'l, 'tcx, 'll, O> {
let span_utils = SpanUtils::new(&save_ctxt.tcx.sess);
DumpVisitor {
tcx: save_ctxt.tcx,
save_ctxt,
dumper,
span: span_utils.clone(),
cur_scope: CRATE_NODE_ID,
// mac_defs: HashSet::new(),
macro_calls: FxHashSet(),
}
}
fn nest_scope<F>(&mut self, scope_id: NodeId, f: F)
where F: FnOnce(&mut DumpVisitor<'l, 'tcx, 'll, O>)
{
let parent_scope = self.cur_scope;
self.cur_scope = scope_id;
f(self);
self.cur_scope = parent_scope;
}
fn nest_tables<F>(&mut self, item_id: NodeId, f: F)
where F: FnOnce(&mut DumpVisitor<'l, 'tcx, 'll, O>)
{
let item_def_id = self.tcx.hir.local_def_id(item_id);
if self.tcx.has_typeck_tables(item_def_id) {
let tables = self.tcx.typeck_tables_of(item_def_id);
let old_tables = self.save_ctxt.tables;
self.save_ctxt.tables = tables;
f(self);
self.save_ctxt.tables = old_tables;
} else {
f(self);
}
}
fn span_from_span(&self, span: Span) -> SpanData {
self.save_ctxt.span_from_span(span)
}
pub fn dump_crate_info(&mut self, name: &str, krate: &ast::Crate) {
let source_file = self.tcx.sess.local_crate_source_file.as_ref();
let crate_root = source_file.map(|source_file| {
let source_file = Path::new(source_file);
match source_file.file_name() {
Some(_) => source_file.parent().unwrap().display().to_string(),
None => source_file.display().to_string(),
}
});
let data = CratePreludeData {
crate_name: name.into(),
crate_root: crate_root.unwrap_or("<no source>".to_owned()),
external_crates: self.save_ctxt.get_external_crates(),
span: self.span_from_span(krate.span),
};
self.dumper.crate_prelude(data);
}
// Return all non-empty prefixes of a path.
// For each prefix, we return the span for the last segment in the prefix and
// a str representation of the entire prefix.
fn process_path_prefixes(&self, path: &ast::Path) -> Vec<(Span, String)> {
let segments = &path.segments[if path.is_global() { 1 } else { 0 }..];
let mut result = Vec::with_capacity(segments.len());
let mut segs = vec![];
for (i, seg) in segments.iter().enumerate() {
segs.push(seg.clone());
let sub_path = ast::Path {
span: seg.span, // span for the last segment
segments: segs,
};
let qualname = if i == 0 && path.is_global() {
format!("::{}", path_to_string(&sub_path))
} else {
path_to_string(&sub_path)
};
result.push((seg.span, qualname));
segs = sub_path.segments;
}
result
}
fn write_sub_paths(&mut self, path: &ast::Path) {
let sub_paths = self.process_path_prefixes(path);
for (span, _) in sub_paths {
let span = self.span_from_span(span);
self.dumper.dump_ref(Ref {
kind: RefKind::Mod,
span,
ref_id: ::null_id(),
});
}
}
// As write_sub_paths, but does not process the last ident in the path (assuming it
// will be processed elsewhere). See note on write_sub_paths about global.
fn write_sub_paths_truncated(&mut self, path: &ast::Path) {
let sub_paths = self.process_path_prefixes(path);
let len = sub_paths.len();
if len <= 1 {
return;
}
for (span, _) in sub_paths.into_iter().take(len - 1) {
let span = self.span_from_span(span);
self.dumper.dump_ref(Ref {
kind: RefKind::Mod,
span,
ref_id: ::null_id(),
});
}
}
// As write_sub_paths, but expects a path of the form module_path::trait::method
// Where trait could actually be a struct too.
fn write_sub_path_trait_truncated(&mut self, path: &ast::Path) {
let sub_paths = self.process_path_prefixes(path);
let len = sub_paths.len();
if len <= 1 {
return;
}
let sub_paths = &sub_paths[.. (len-1)];
// write the trait part of the sub-path
let (ref span, _) = sub_paths[len-2];
let span = self.span_from_span(*span);
self.dumper.dump_ref(Ref {
kind: RefKind::Type,
ref_id: ::null_id(),
span,
});
// write the other sub-paths
if len <= 2 {
return;
}
let sub_paths = &sub_paths[..len-2];
for &(ref span, _) in sub_paths {
let span = self.span_from_span(*span);
self.dumper.dump_ref(Ref {
kind: RefKind::Mod,
span,
ref_id: ::null_id(),
});
}
}
fn lookup_def_id(&self, ref_id: NodeId) -> Option<DefId> {
match self.save_ctxt.get_path_def(ref_id) {
HirDef::PrimTy(..) | HirDef::SelfTy(..) | HirDef::Err => None,
def => Some(def.def_id()),
}
}
fn process_def_kind(&mut self,
ref_id: NodeId,
span: Span,
sub_span: Option<Span>,
def_id: DefId) {
if self.span.filter_generated(sub_span, span) {
return;
}
let def = self.save_ctxt.get_path_def(ref_id);
match def {
HirDef::Mod(_) => {
let span = self.span_from_span(sub_span.expect("No span found for mod ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Mod,
span,
ref_id: ::id_from_def_id(def_id),
});
}
HirDef::Struct(..) |
HirDef::Variant(..) |
HirDef::Union(..) |
HirDef::Enum(..) |
HirDef::TyAlias(..) |
HirDef::Trait(_) => {
let span = self.span_from_span(sub_span.expect("No span found for type ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Type,
span,
ref_id: ::id_from_def_id(def_id),
});
}
HirDef::Static(..) |
HirDef::Const(..) |
HirDef::StructCtor(..) |
HirDef::VariantCtor(..) => {
let span = self.span_from_span(sub_span.expect("No span found for var ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Variable,
span,
ref_id: ::id_from_def_id(def_id),
});
}
HirDef::Fn(..) => {
let span = self.span_from_span(sub_span.expect("No span found for fn ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Function,
span,
ref_id: ::id_from_def_id(def_id),
});
}
// With macros 2.0, we can legitimately get a ref to a macro, but
// we don't handle it properly for now (FIXME).
HirDef::Macro(..) => {}
HirDef::Local(..) |
HirDef::Upvar(..) |
HirDef::SelfTy(..) |
HirDef::Label(_) |
HirDef::TyParam(..) |
HirDef::Method(..) |
HirDef::AssociatedTy(..) |
HirDef::AssociatedConst(..) |
HirDef::PrimTy(_) |
HirDef::GlobalAsm(_) |
HirDef::Err => {
span_bug!(span,
"process_def_kind for unexpected item: {:?}",
def);
}
}
}
fn process_formals(&mut self, formals: &'l [ast::Arg], qualname: &str) {
for arg in formals {
self.visit_pat(&arg.pat);
let mut collector = PathCollector::new();
collector.visit_pat(&arg.pat);
let span_utils = self.span.clone();
for &(id, ref p, ..) in &collector.collected_paths {
let hir_id = self.tcx.hir.node_to_hir_id(id);
let typ = match self.save_ctxt.tables.node_id_to_type_opt(hir_id) {
Some(s) => s.to_string(),
None => continue,
};
// get the span only for the name of the variable (I hope the path is only ever a
// variable name, but who knows?)
let sub_span = span_utils.span_for_last_ident(p.span);
if !self.span.filter_generated(sub_span, p.span) {
let id = ::id_from_node_id(id, &self.save_ctxt);
let span = self.span_from_span(sub_span.expect("No span found for variable"));
self.dumper.dump_def(false, Def {
kind: DefKind::Local,
id,
span,
name: path_to_string(p),
qualname: format!("{}::{}", qualname, path_to_string(p)),
value: typ,
parent: None,
children: vec![],
decl_id: None,
docs: String::new(),
sig: None,
attributes:vec![],
});
}
}
}
}
fn process_method(&mut self,
sig: &'l ast::MethodSig,
body: Option<&'l ast::Block>,
id: ast::NodeId,
name: ast::Ident,
vis: ast::Visibility,
span: Span) {
debug!("process_method: {}:{}", id, name);
if let Some(mut method_data) = self.save_ctxt.get_method_data(id, name.name, span) {
let sig_str = ::make_signature(&sig.decl, &sig.generics);
if body.is_some() {
self.nest_tables(id, |v| {
v.process_formals(&sig.decl.inputs, &method_data.qualname)
});
}
self.process_generic_params(&sig.generics, span, &method_data.qualname, id);
method_data.value = sig_str;
method_data.sig = sig::method_signature(id, name, sig, &self.save_ctxt);
self.dumper.dump_def(vis == ast::Visibility::Public, method_data);
}
// walk arg and return types
for arg in &sig.decl.inputs {
self.visit_ty(&arg.ty);
}
if let ast::FunctionRetTy::Ty(ref ret_ty) = sig.decl.output {
self.visit_ty(ret_ty);
}
// walk the fn body
if let Some(body) = body {
self.nest_tables(id, |v| v.nest_scope(id, |v| v.visit_block(body)));
}
}
fn process_trait_ref(&mut self, trait_ref: &'l ast::TraitRef) {
let trait_ref_data = self.save_ctxt.get_trait_ref_data(trait_ref);
if let Some(trait_ref_data) = trait_ref_data {
self.dumper.dump_ref(trait_ref_data);
}
self.process_path(trait_ref.ref_id, &trait_ref.path);
}
fn process_struct_field_def(&mut self, field: &ast::StructField, parent_id: NodeId) {
let field_data = self.save_ctxt.get_field_data(field, parent_id);
if let Some(field_data) = field_data {
self.dumper.dump_def(field.vis == ast::Visibility::Public, field_data);
}
}
// Dump generic params bindings, then visit_generics
fn process_generic_params(&mut self,
generics: &'l ast::Generics,
full_span: Span,
prefix: &str,
id: NodeId) {
for param in &generics.ty_params {
let param_ss = param.span;
let name = escape(self.span.snippet(param_ss));
// Append $id to name to make sure each one is unique
let qualname = format!("{}::{}${}",
prefix,
name,
id);
if !self.span.filter_generated(Some(param_ss), full_span) {
let id = ::id_from_node_id(param.id, &self.save_ctxt);
let span = self.span_from_span(param_ss);
self.dumper.dump_def(false, Def {
kind: DefKind::Type,
id,
span,
name,
qualname,
value: String::new(),
parent: None,
children: vec![],
decl_id: None,
docs: String::new(),
sig: None,
attributes: vec![],
});
}
}
self.visit_generics(generics);
}
fn process_fn(&mut self,
item: &'l ast::Item,
decl: &'l ast::FnDecl,
ty_params: &'l ast::Generics,
body: &'l ast::Block) {
if let Some(fn_data) = self.save_ctxt.get_item_data(item) {
down_cast_data!(fn_data, DefData, item.span);
self.nest_tables(item.id, |v| v.process_formals(&decl.inputs, &fn_data.qualname));
self.process_generic_params(ty_params, item.span, &fn_data.qualname, item.id);
self.dumper.dump_def(item.vis == ast::Visibility::Public, fn_data);
}
for arg in &decl.inputs {
self.visit_ty(&arg.ty);
}
if let ast::FunctionRetTy::Ty(ref ret_ty) = decl.output {
self.visit_ty(&ret_ty);
}
self.nest_tables(item.id, |v| v.nest_scope(item.id, |v| v.visit_block(&body)));
}
fn process_static_or_const_item(&mut self,
item: &'l ast::Item,
typ: &'l ast::Ty,
expr: &'l ast::Expr) {
self.nest_tables(item.id, |v| {
if let Some(var_data) = v.save_ctxt.get_item_data(item) {
down_cast_data!(var_data, DefData, item.span);
v.dumper.dump_def(item.vis == ast::Visibility::Public, var_data);
}
v.visit_ty(&typ);
v.visit_expr(expr);
});
}
fn process_assoc_const(&mut self,
id: ast::NodeId,
name: ast::Name,
span: Span,
typ: &'l ast::Ty,
expr: Option<&'l ast::Expr>,
parent_id: DefId,
vis: ast::Visibility,
attrs: &'l [Attribute]) {
let qualname = format!("::{}", self.tcx.node_path_str(id));
let sub_span = self.span.sub_span_after_keyword(span, keywords::Const);
if !self.span.filter_generated(sub_span, span) {
let sig = sig::assoc_const_signature(id, name, typ, expr, &self.save_ctxt);
let id = ::id_from_node_id(id, &self.save_ctxt);
let span = self.span_from_span(sub_span.expect("No span found for variable"));
self.dumper.dump_def(vis == ast::Visibility::Public, Def {
kind: DefKind::Const,
id,
span,
name: name.to_string(),
qualname,
value: ty_to_string(&typ),
parent: Some(::id_from_def_id(parent_id)),
children: vec![],
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(attrs),
sig,
attributes: lower_attributes(attrs.to_owned(), &self.save_ctxt),
});
}
// walk type and init value
self.visit_ty(typ);
if let Some(expr) = expr {
self.visit_expr(expr);
}
}
// FIXME tuple structs should generate tuple-specific data.
fn process_struct(&mut self,
item: &'l ast::Item,
def: &'l ast::VariantData,
ty_params: &'l ast::Generics) {
let name = item.ident.to_string();
let qualname = format!("::{}", self.tcx.node_path_str(item.id));
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Struct);
let (value, fields) =
if let ast::ItemKind::Struct(ast::VariantData::Struct(ref fields, _), _) = item.node
{
let include_priv_fields = !self.save_ctxt.config.pub_only;
let fields_str = fields
.iter()
.enumerate()
.filter_map(|(i, f)| {
if include_priv_fields || f.vis == ast::Visibility::Public {
f.ident.map(|i| i.to_string()).or_else(|| Some(i.to_string()))
} else {
None
}
})
.collect::<Vec<_>>()
.join(", ");
let value = format!("{} {{ {} }}", name, fields_str);
(value, fields.iter().map(|f| ::id_from_node_id(f.id, &self.save_ctxt)).collect())
} else {
(String::new(), vec![])
};
if !self.span.filter_generated(sub_span, item.span) {
let span = self.span_from_span(sub_span.expect("No span found for struct"));
self.dumper.dump_def(item.vis == ast::Visibility::Public, Def {
kind: DefKind::Struct,
id: ::id_from_node_id(item.id, &self.save_ctxt),
span,
name,
qualname: qualname.clone(),
value,
parent: None,
children: fields,
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&item.attrs),
sig: sig::item_signature(item, &self.save_ctxt),
attributes: lower_attributes(item.attrs.clone(), &self.save_ctxt),
});
}
for field in def.fields() {
self.process_struct_field_def(field, item.id);
self.visit_ty(&field.ty);
}
self.process_generic_params(ty_params, item.span, &qualname, item.id);
}
fn process_enum(&mut self,
item: &'l ast::Item,
enum_definition: &'l ast::EnumDef,
ty_params: &'l ast::Generics) {
let enum_data = self.save_ctxt.get_item_data(item);
let enum_data = match enum_data {
None => return,
Some(data) => data,
};
down_cast_data!(enum_data, DefData, item.span);
for variant in &enum_definition.variants {
let name = variant.node.name.name.to_string();
let mut qualname = enum_data.qualname.clone();
qualname.push_str("::");
qualname.push_str(&name);
match variant.node.data {
ast::VariantData::Struct(ref fields, _) => {
let sub_span = self.span.span_for_first_ident(variant.span);
let fields_str = fields.iter()
.enumerate()
.map(|(i, f)| f.ident.map(|i| i.to_string())
.unwrap_or(i.to_string()))
.collect::<Vec<_>>()
.join(", ");
let value = format!("{}::{} {{ {} }}", enum_data.name, name, fields_str);
if !self.span.filter_generated(sub_span, variant.span) {
let span = self.span_from_span(
sub_span.expect("No span found for struct variant"));
let id = ::id_from_node_id(variant.node.data.id(), &self.save_ctxt);
let parent = Some(::id_from_node_id(item.id, &self.save_ctxt));
self.dumper.dump_def(item.vis == ast::Visibility::Public, Def {
kind: DefKind::Struct,
id,
span,
name,
qualname,
value,
parent,
children: vec![],
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&variant.node.attrs),
sig: sig::variant_signature(variant, &self.save_ctxt),
attributes: lower_attributes(variant.node.attrs.clone(),
&self.save_ctxt),
});
}
}
ref v => {
let sub_span = self.span.span_for_first_ident(variant.span);
let mut value = format!("{}::{}", enum_data.name, name);
if let &ast::VariantData::Tuple(ref fields, _) = v {
value.push('(');
value.push_str(&fields.iter()
.map(|f| ty_to_string(&f.ty))
.collect::<Vec<_>>()
.join(", "));
value.push(')');
}
if !self.span.filter_generated(sub_span, variant.span) {
let span =
self.span_from_span(sub_span.expect("No span found for tuple variant"));
let id = ::id_from_node_id(variant.node.data.id(), &self.save_ctxt);
let parent = Some(::id_from_node_id(item.id, &self.save_ctxt));
self.dumper.dump_def(item.vis == ast::Visibility::Public, Def {
kind: DefKind::Tuple,
id,
span,
name,
qualname,
value,
parent,
children: vec![],
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&variant.node.attrs),
sig: sig::variant_signature(variant, &self.save_ctxt),
attributes: lower_attributes(variant.node.attrs.clone(),
&self.save_ctxt),
});
}
}
}
for field in variant.node.data.fields() {
self.process_struct_field_def(field, variant.node.data.id());
self.visit_ty(&field.ty);
}
}
self.process_generic_params(ty_params, item.span, &enum_data.qualname, item.id);
self.dumper.dump_def(item.vis == ast::Visibility::Public, enum_data);
}
fn process_impl(&mut self,
item: &'l ast::Item,
type_parameters: &'l ast::Generics,
trait_ref: &'l Option<ast::TraitRef>,
typ: &'l ast::Ty,
impl_items: &'l [ast::ImplItem]) {
if let Some(impl_data) = self.save_ctxt.get_item_data(item) {
down_cast_data!(impl_data, RelationData, item.span);
self.dumper.dump_relation(impl_data);
}
self.visit_ty(&typ);
if let &Some(ref trait_ref) = trait_ref {
self.process_path(trait_ref.ref_id, &trait_ref.path);
}
self.process_generic_params(type_parameters, item.span, "", item.id);
for impl_item in impl_items {
let map = &self.tcx.hir;
self.process_impl_item(impl_item, map.local_def_id(item.id));
}
}
fn process_trait(&mut self,
item: &'l ast::Item,
generics: &'l ast::Generics,
trait_refs: &'l ast::TyParamBounds,
methods: &'l [ast::TraitItem]) {
let name = item.ident.to_string();
let qualname = format!("::{}", self.tcx.node_path_str(item.id));
let mut val = name.clone();
if !generics.lifetimes.is_empty() || !generics.ty_params.is_empty() {
val.push_str(&generics_to_string(generics));
}
if !trait_refs.is_empty() {
val.push_str(": ");
val.push_str(&bounds_to_string(trait_refs));
}
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Trait);
if !self.span.filter_generated(sub_span, item.span) {
let id = ::id_from_node_id(item.id, &self.save_ctxt);
let span = self.span_from_span(sub_span.expect("No span found for trait"));
let children =
methods.iter().map(|i| ::id_from_node_id(i.id, &self.save_ctxt)).collect();
self.dumper.dump_def(item.vis == ast::Visibility::Public, Def {
kind: DefKind::Trait,
id,
span,
name,
qualname: qualname.clone(),
value: val,
parent: None,
children,
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&item.attrs),
sig: sig::item_signature(item, &self.save_ctxt),
attributes: lower_attributes(item.attrs.clone(), &self.save_ctxt),
});
}
// super-traits
for super_bound in trait_refs.iter() {
let trait_ref = match *super_bound {
ast::TraitTyParamBound(ref trait_ref, _) => {
trait_ref
}
ast::RegionTyParamBound(..) => {
continue;
}
};
let trait_ref = &trait_ref.trait_ref;
if let Some(id) = self.lookup_def_id(trait_ref.ref_id) {
let sub_span = self.span.sub_span_for_type_name(trait_ref.path.span);
if !self.span.filter_generated(sub_span, trait_ref.path.span) {
let span = self.span_from_span(sub_span.expect("No span found for trait ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Type,
span,
ref_id: ::id_from_def_id(id),
});
}
if !self.span.filter_generated(sub_span, trait_ref.path.span) {
let sub_span = self.span_from_span(sub_span.expect("No span for inheritance"));
self.dumper.dump_relation(Relation {
kind: RelationKind::SuperTrait,
span: sub_span,
from: ::id_from_def_id(id),
to: ::id_from_node_id(item.id, &self.save_ctxt),
});
}
}
}
// walk generics and methods
self.process_generic_params(generics, item.span, &qualname, item.id);
for method in methods {
let map = &self.tcx.hir;
self.process_trait_item(method, map.local_def_id(item.id))
}
}
// `item` is the module in question, represented as an item.
fn process_mod(&mut self, item: &ast::Item) {
if let Some(mod_data) = self.save_ctxt.get_item_data(item) {
down_cast_data!(mod_data, DefData, item.span);
self.dumper.dump_def(item.vis == ast::Visibility::Public, mod_data);
}
}
fn process_path(&mut self, id: NodeId, path: &ast::Path) {
let path_data = self.save_ctxt.get_path_data(id, path);
if generated_code(path.span) && path_data.is_none() {
return;
}
let path_data = match path_data {
Some(pd) => pd,
None => {
return;
}
};
self.dumper.dump_ref(path_data);
// Modules or types in the path prefix.
match self.save_ctxt.get_path_def(id) {
HirDef::Method(did) => {
let ti = self.tcx.associated_item(did);
if ti.kind == ty::AssociatedKind::Method && ti.method_has_self_argument {
self.write_sub_path_trait_truncated(path);
}
}
HirDef::Fn(..) |
HirDef::Const(..) |
HirDef::Static(..) |
HirDef::StructCtor(..) |
HirDef::VariantCtor(..) |
HirDef::AssociatedConst(..) |
HirDef::Local(..) |
HirDef::Upvar(..) |
HirDef::Struct(..) |
HirDef::Union(..) |
HirDef::Variant(..) |
HirDef::TyAlias(..) |
HirDef::AssociatedTy(..) => self.write_sub_paths_truncated(path),
_ => {}
}
}
fn process_struct_lit(&mut self,
ex: &'l ast::Expr,
path: &'l ast::Path,
fields: &'l [ast::Field],
variant: &'l ty::VariantDef,
base: &'l Option<P<ast::Expr>>) {
self.write_sub_paths_truncated(path);
if let Some(struct_lit_data) = self.save_ctxt.get_expr_data(ex) {
down_cast_data!(struct_lit_data, RefData, ex.span);
if !generated_code(ex.span) {
self.dumper.dump_ref(struct_lit_data);
}
for field in fields {
if let Some(field_data) = self.save_ctxt
.get_field_ref_data(field, variant) {
self.dumper.dump_ref(field_data);
}
self.visit_expr(&field.expr)
}
}
walk_list!(self, visit_expr, base);
}
fn process_method_call(&mut self, ex: &'l ast::Expr, args: &'l [P<ast::Expr>]) {
if let Some(mcd) = self.save_ctxt.get_expr_data(ex) {
down_cast_data!(mcd, RefData, ex.span);
if !generated_code(ex.span) {
self.dumper.dump_ref(mcd);
}
}
// walk receiver and args
walk_list!(self, visit_expr, args);
}
fn process_pat(&mut self, p: &'l ast::Pat) {
match p.node {
PatKind::Struct(ref _path, ref fields, _) => {
// FIXME do something with _path?
let hir_id = self.tcx.hir.node_to_hir_id(p.id);
let adt = match self.save_ctxt.tables.node_id_to_type_opt(hir_id) {
Some(ty) => ty.ty_adt_def().unwrap(),
None => {
visit::walk_pat(self, p);
return;
}
};
let variant = adt.variant_of_def(self.save_ctxt.get_path_def(p.id));
for &Spanned { node: ref field, span } in fields {
let sub_span = self.span.span_for_first_ident(span);
if let Some(f) = variant.find_field_named(field.ident.name) {
if !self.span.filter_generated(sub_span, span) {
let span =
self.span_from_span(sub_span.expect("No span fund for var ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Variable,
span,
ref_id: ::id_from_def_id(f.did),
});
}
}
self.visit_pat(&field.pat);
}
}
_ => visit::walk_pat(self, p),
}
}
fn process_var_decl(&mut self, p: &'l ast::Pat, value: String) {
// The local could declare multiple new vars, we must walk the
// pattern and collect them all.
let mut collector = PathCollector::new();
collector.visit_pat(&p);
self.visit_pat(&p);
for &(id, ref p, immut) in &collector.collected_paths {
let mut value = match immut {
ast::Mutability::Immutable => value.to_string(),
_ => String::new(),
};
let hir_id = self.tcx.hir.node_to_hir_id(id);
let typ = match self.save_ctxt.tables.node_id_to_type_opt(hir_id) {
Some(typ) => {
let typ = typ.to_string();
if !value.is_empty() {
value.push_str(": ");
}
value.push_str(&typ);
typ
}
None => String::new(),
};
// Get the span only for the name of the variable (I hope the path
// is only ever a variable name, but who knows?).
let sub_span = self.span.span_for_last_ident(p.span);
// Rust uses the id of the pattern for var lookups, so we'll use it too.
if !self.span.filter_generated(sub_span, p.span) {
let qualname = format!("{}${}", path_to_string(p), id);
let id = ::id_from_node_id(id, &self.save_ctxt);
let span = self.span_from_span(sub_span.expect("No span found for variable"));
self.dumper.dump_def(false, Def {
kind: DefKind::Local,
id,
span,
name: path_to_string(p),
qualname,
value: typ,
parent: None,
children: vec![],
decl_id: None,
docs: String::new(),
sig: None,
attributes:vec![],
});
}
}
}
/// Extract macro use and definition information from the AST node defined
/// by the given NodeId, using the expansion information from the node's
/// span.
///
/// If the span is not macro-generated, do nothing, else use callee and
/// callsite spans to record macro definition and use data, using the
/// mac_uses and mac_defs sets to prevent multiples.
fn process_macro_use(&mut self, span: Span) {
let source_span = span.source_callsite();
if self.macro_calls.contains(&source_span) {
return;
}
self.macro_calls.insert(source_span);
let data = match self.save_ctxt.get_macro_use_data(span) {
None => return,
Some(data) => data,
};
self.dumper.macro_use(data);
// FIXME write the macro def
// let mut hasher = DefaultHasher::new();
// data.callee_span.hash(&mut hasher);
// let hash = hasher.finish();
// let qualname = format!("{}::{}", data.name, hash);
// Don't write macro definition for imported macros
// if !self.mac_defs.contains(&data.callee_span)
// && !data.imported {
// self.mac_defs.insert(data.callee_span);
// if let Some(sub_span) = self.span.span_for_macro_def_name(data.callee_span) {
// self.dumper.macro_data(MacroData {
// span: sub_span,
// name: data.name.clone(),
// qualname: qualname.clone(),
// // FIXME where do macro docs come from?
// docs: String::new(),
// }.lower(self.tcx));
// }
// }
}
fn process_trait_item(&mut self, trait_item: &'l ast::TraitItem, trait_id: DefId) {
self.process_macro_use(trait_item.span);
match trait_item.node {
ast::TraitItemKind::Const(ref ty, ref expr) => {
self.process_assoc_const(trait_item.id,
trait_item.ident.name,
trait_item.span,
&ty,
expr.as_ref().map(|e| &**e),
trait_id,
ast::Visibility::Public,
&trait_item.attrs);
}
ast::TraitItemKind::Method(ref sig, ref body) => {
self.process_method(sig,
body.as_ref().map(|x| &**x),
trait_item.id,
trait_item.ident,
ast::Visibility::Public,
trait_item.span);
}
ast::TraitItemKind::Type(ref bounds, ref default_ty) => {
// FIXME do something with _bounds (for type refs)
let name = trait_item.ident.name.to_string();
let qualname = format!("::{}", self.tcx.node_path_str(trait_item.id));
let sub_span = self.span.sub_span_after_keyword(trait_item.span, keywords::Type);
if !self.span.filter_generated(sub_span, trait_item.span) {
let span = self.span_from_span(sub_span.expect("No span found for assoc type"));
let id = ::id_from_node_id(trait_item.id, &self.save_ctxt);
self.dumper.dump_def(true, Def {
kind: DefKind::Type,
id,
span,
name,
qualname,
value: self.span.snippet(trait_item.span),
parent: Some(::id_from_def_id(trait_id)),
children: vec![],
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&trait_item.attrs),
sig: sig::assoc_type_signature(trait_item.id,
trait_item.ident,
Some(bounds),
default_ty.as_ref().map(|ty| &**ty),
&self.save_ctxt),
attributes: lower_attributes(trait_item.attrs.clone(), &self.save_ctxt),
});
}
if let &Some(ref default_ty) = default_ty {
self.visit_ty(default_ty)
}
}
ast::TraitItemKind::Macro(_) => {}
}
}
fn process_impl_item(&mut self, impl_item: &'l ast::ImplItem, impl_id: DefId) {
self.process_macro_use(impl_item.span);
match impl_item.node {
ast::ImplItemKind::Const(ref ty, ref expr) => {
self.process_assoc_const(impl_item.id,
impl_item.ident.name,
impl_item.span,
&ty,
Some(expr),
impl_id,
impl_item.vis.clone(),
&impl_item.attrs);
}
ast::ImplItemKind::Method(ref sig, ref body) => {
self.process_method(sig,
Some(body),
impl_item.id,
impl_item.ident,
impl_item.vis.clone(),
impl_item.span);
}
ast::ImplItemKind::Type(ref ty) => {
// FIXME uses of the assoc type should ideally point to this
// 'def' and the name here should be a ref to the def in the
// trait.
self.visit_ty(ty)
}
ast::ImplItemKind::Macro(_) => {}
}
}
}
impl<'l, 'tcx: 'l, 'll, O: DumpOutput + 'll> Visitor<'l> for DumpVisitor<'l, 'tcx, 'll, O> {
fn visit_mod(&mut self, m: &'l ast::Mod, span: Span, attrs: &[ast::Attribute], id: NodeId) {
// Since we handle explicit modules ourselves in visit_item, this should
// only get called for the root module of a crate.
assert_eq!(id, ast::CRATE_NODE_ID);
let qualname = format!("::{}", self.tcx.node_path_str(id));
let cm = self.tcx.sess.codemap();
let filename = cm.span_to_filename(span);
let data_id = ::id_from_node_id(id, &self.save_ctxt);
let children = m.items.iter().map(|i| ::id_from_node_id(i.id, &self.save_ctxt)).collect();
let span = self.span_from_span(span);
self.dumper.dump_def(true, Def {
kind: DefKind::Mod,
id: data_id,
name: String::new(),
qualname,
span,
value: filename,
children,
parent: None,
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(attrs),
sig: None,
attributes: lower_attributes(attrs.to_owned(), &self.save_ctxt),
});
self.nest_scope(id, |v| visit::walk_mod(v, m));
}
fn visit_item(&mut self, item: &'l ast::Item) {
use syntax::ast::ItemKind::*;
self.process_macro_use(item.span);
match item.node {
Use(ref use_item) => {
match use_item.node {
ast::ViewPathSimple(ident, ref path) => {
let sub_span = self.span.span_for_last_ident(path.span);
let mod_id = match self.lookup_def_id(item.id) {
Some(def_id) => {
self.process_def_kind(item.id, path.span, sub_span, def_id);
Some(def_id)
}
None => None,
};
// 'use' always introduces an alias, if there is not an explicit
// one, there is an implicit one.
let sub_span = match self.span.sub_span_after_keyword(use_item.span,
keywords::As) {
Some(sub_span) => Some(sub_span),
None => sub_span,
};
if !self.span.filter_generated(sub_span, path.span) {
let span =
self.span_from_span(sub_span.expect("No span found for use"));
self.dumper.import(item.vis == ast::Visibility::Public, Import {
kind: ImportKind::Use,
ref_id: mod_id.map(|id| ::id_from_def_id(id)),
span,
name: ident.to_string(),
value: String::new(),
});
}
self.write_sub_paths_truncated(path);
}
ast::ViewPathGlob(ref path) => {
// Make a comma-separated list of names of imported modules.
let mut names = vec![];
let glob_map = &self.save_ctxt.analysis.glob_map;
let glob_map = glob_map.as_ref().unwrap();
if glob_map.contains_key(&item.id) {
for n in glob_map.get(&item.id).unwrap() {
names.push(n.to_string());
}
}
let sub_span = self.span
.sub_span_of_token(item.span, token::BinOp(token::Star));
if !self.span.filter_generated(sub_span, item.span) {
let span =
self.span_from_span(sub_span.expect("No span found for use glob"));
self.dumper.import(item.vis == ast::Visibility::Public, Import {
kind: ImportKind::GlobUse,
ref_id: None,
span,
name: "*".to_owned(),
value: names.join(", "),
});
}
self.write_sub_paths(path);
}
ast::ViewPathList(ref path, ref list) => {
for plid in list {
let id = plid.node.id;
if let Some(def_id) = self.lookup_def_id(id) {
let span = plid.span;
self.process_def_kind(id, span, Some(span), def_id);
}
}
self.write_sub_paths(path);
}
}
}
ExternCrate(_) => {
let alias_span = self.span.span_for_last_ident(item.span);
if !self.span.filter_generated(alias_span, item.span) {
let span =
self.span_from_span(alias_span.expect("No span found for extern crate"));
self.dumper.import(false, Import {
kind: ImportKind::ExternCrate,
ref_id: None,
span,
name: item.ident.to_string(),
value: String::new(),
});
}
}
Fn(ref decl, .., ref ty_params, ref body) =>
self.process_fn(item, &decl, ty_params, &body),
Static(ref typ, _, ref expr) =>
self.process_static_or_const_item(item, typ, expr),
Const(ref typ, ref expr) =>
self.process_static_or_const_item(item, &typ, &expr),
Struct(ref def, ref ty_params) => self.process_struct(item, def, ty_params),
Enum(ref def, ref ty_params) => self.process_enum(item, def, ty_params),
Impl(..,
ref ty_params,
ref trait_ref,
ref typ,
ref impl_items) => {
self.process_impl(item, ty_params, trait_ref, &typ, impl_items)
}
Trait(_, ref generics, ref trait_refs, ref methods) =>
self.process_trait(item, generics, trait_refs, methods),
Mod(ref m) => {
self.process_mod(item);
self.nest_scope(item.id, |v| visit::walk_mod(v, m));
}
Ty(ref ty, ref ty_params) => {
let qualname = format!("::{}", self.tcx.node_path_str(item.id));
let value = ty_to_string(&ty);
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Type);
if !self.span.filter_generated(sub_span, item.span) {
let span = self.span_from_span(sub_span.expect("No span found for typedef"));
let id = ::id_from_node_id(item.id, &self.save_ctxt);
self.dumper.dump_def(item.vis == ast::Visibility::Public, Def {
kind: DefKind::Type,
id,
span,
name: item.ident.to_string(),
qualname: qualname.clone(),
value,
parent: None,
children: vec![],
decl_id: None,
docs: self.save_ctxt.docs_for_attrs(&item.attrs),
sig: sig::item_signature(item, &self.save_ctxt),
attributes: lower_attributes(item.attrs.clone(), &self.save_ctxt),
});
}
self.visit_ty(&ty);
self.process_generic_params(ty_params, item.span, &qualname, item.id);
}
Mac(_) => (),
_ => visit::walk_item(self, item),
}
}
fn visit_generics(&mut self, generics: &'l ast::Generics) {
for param in generics.ty_params.iter() {
for bound in param.bounds.iter() {
if let ast::TraitTyParamBound(ref trait_ref, _) = *bound {
self.process_trait_ref(&trait_ref.trait_ref);
}
}
if let Some(ref ty) = param.default {
self.visit_ty(&ty);
}
}
}
fn visit_ty(&mut self, t: &'l ast::Ty) {
self.process_macro_use(t.span);
match t.node {
ast::TyKind::Path(_, ref path) => {
if generated_code(t.span) {
return;
}
if let Some(id) = self.lookup_def_id(t.id) {
if let Some(sub_span) = self.span.sub_span_for_type_name(t.span) {
let span = self.span_from_span(sub_span);
self.dumper.dump_ref(Ref {
kind: RefKind::Type,
span,
ref_id: ::id_from_def_id(id),
});
}
}
self.write_sub_paths_truncated(path);
visit::walk_path(self, path);
}
ast::TyKind::Array(ref element, ref length) => {
self.visit_ty(element);
self.nest_tables(length.id, |v| v.visit_expr(length));
}
_ => visit::walk_ty(self, t),
}
}
fn visit_expr(&mut self, ex: &'l ast::Expr) {
debug!("visit_expr {:?}", ex.node);
self.process_macro_use(ex.span);
match ex.node {
ast::ExprKind::Struct(ref path, ref fields, ref base) => {
let hir_expr = self.save_ctxt.tcx.hir.expect_expr(ex.id);
let adt = match self.save_ctxt.tables.expr_ty_opt(&hir_expr) {
Some(ty) if ty.ty_adt_def().is_some() => ty.ty_adt_def().unwrap(),
_ => {
visit::walk_expr(self, ex);
return;
}
};
let def = self.save_ctxt.get_path_def(hir_expr.id);
self.process_struct_lit(ex, path, fields, adt.variant_of_def(def), base)
}
ast::ExprKind::MethodCall(.., ref args) => self.process_method_call(ex, args),
ast::ExprKind::Field(ref sub_ex, _) => {
self.visit_expr(&sub_ex);
if let Some(field_data) = self.save_ctxt.get_expr_data(ex) {
down_cast_data!(field_data, RefData, ex.span);
if !generated_code(ex.span) {
self.dumper.dump_ref(field_data);
}
}
}
ast::ExprKind::TupField(ref sub_ex, idx) => {
self.visit_expr(&sub_ex);
let hir_node = match self.save_ctxt.tcx.hir.find(sub_ex.id) {
Some(Node::NodeExpr(expr)) => expr,
_ => {
debug!("Missing or weird node for sub-expression {} in {:?}",
sub_ex.id, ex);
return;
}
};
let ty = match self.save_ctxt.tables.expr_ty_adjusted_opt(&hir_node) {
Some(ty) => &ty.sty,
None => {
visit::walk_expr(self, ex);
return;
}
};
match *ty {
ty::TyAdt(def, _) => {
let sub_span = self.span.sub_span_after_token(ex.span, token::Dot);
if !self.span.filter_generated(sub_span, ex.span) {
let span =
self.span_from_span(sub_span.expect("No span found for var ref"));
self.dumper.dump_ref(Ref {
kind: RefKind::Variable,
span,
ref_id: ::id_from_def_id(def.struct_variant().fields[idx.node].did),
});
}
}
ty::TyTuple(..) => {}
_ => span_bug!(ex.span,
"Expected struct or tuple type, found {:?}",
ty),
}
}
ast::ExprKind::Closure(_, ref decl, ref body, _fn_decl_span) => {
let mut id = String::from("$");
id.push_str(&ex.id.to_string());
// walk arg and return types
for arg in &decl.inputs {
self.visit_ty(&arg.ty);
}
if let ast::FunctionRetTy::Ty(ref ret_ty) = decl.output {
self.visit_ty(&ret_ty);
}
// walk the body
self.nest_tables(ex.id, |v| {
v.process_formals(&decl.inputs, &id);
v.nest_scope(ex.id, |v| v.visit_expr(body))
});
}
ast::ExprKind::ForLoop(ref pattern, ref subexpression, ref block, _) |
ast::ExprKind::WhileLet(ref pattern, ref subexpression, ref block, _) => {
let value = self.span.snippet(subexpression.span);
self.process_var_decl(pattern, value);
debug!("for loop, walk sub-expr: {:?}", subexpression.node);
visit::walk_expr(self, subexpression);
visit::walk_block(self, block);
}
ast::ExprKind::IfLet(ref pattern, ref subexpression, ref block, ref opt_else) => {
let value = self.span.snippet(subexpression.span);
self.process_var_decl(pattern, value);
visit::walk_expr(self, subexpression);
visit::walk_block(self, block);
opt_else.as_ref().map(|el| visit::walk_expr(self, el));
}
ast::ExprKind::Repeat(ref element, ref count) => {
self.visit_expr(element);
self.nest_tables(count.id, |v| v.visit_expr(count));
}
// In particular, we take this branch for call and path expressions,
// where we'll index the idents involved just by continuing to walk.
_ => {
visit::walk_expr(self, ex)
}
}
}
fn visit_mac(&mut self, mac: &'l ast::Mac) {
// These shouldn't exist in the AST at this point, log a span bug.
span_bug!(mac.span, "macro invocation should have been expanded out of AST");
}
fn visit_pat(&mut self, p: &'l ast::Pat) {
self.process_macro_use(p.span);
self.process_pat(p);
}
fn visit_arm(&mut self, arm: &'l ast::Arm) {
let mut collector = PathCollector::new();
for pattern in &arm.pats {
// collect paths from the arm's patterns
collector.visit_pat(&pattern);
self.visit_pat(&pattern);
}
// This is to get around borrow checking, because we need mut self to call process_path.
let mut paths_to_process = vec![];
// process collected paths
for &(id, ref p, immut) in &collector.collected_paths {
match self.save_ctxt.get_path_def(id) {
HirDef::Local(id) => {
let mut value = if immut == ast::Mutability::Immutable {
self.span.snippet(p.span).to_string()
} else {
"<mutable>".to_string()
};
let hir_id = self.tcx.hir.node_to_hir_id(id);
let typ = self.save_ctxt
.tables
.node_id_to_type_opt(hir_id)
.map(|t| t.to_string())
.unwrap_or(String::new());
value.push_str(": ");
value.push_str(&typ);
assert!(p.segments.len() == 1,
"qualified path for local variable def in arm");
if !self.span.filter_generated(Some(p.span), p.span) {
let qualname = format!("{}${}", path_to_string(p), id);
let id = ::id_from_node_id(id, &self.save_ctxt);
let span = self.span_from_span(p.span);
self.dumper.dump_def(false, Def {
kind: DefKind::Local,
id,
span,
name: path_to_string(p),
qualname,
value: typ,
parent: None,
children: vec![],
decl_id: None,
docs: String::new(),
sig: None,
attributes:vec![],
});
}
}
HirDef::StructCtor(..) | HirDef::VariantCtor(..) |
HirDef::Const(..) | HirDef::AssociatedConst(..) |
HirDef::Struct(..) | HirDef::Variant(..) |
HirDef::TyAlias(..) | HirDef::AssociatedTy(..) |
HirDef::SelfTy(..) => {
paths_to_process.push((id, p.clone()))
}
def => error!("unexpected definition kind when processing collected paths: {:?}",
def),
}
}
for &(id, ref path) in &paths_to_process {
self.process_path(id, path);
}
walk_list!(self, visit_expr, &arm.guard);
self.visit_expr(&arm.body);
}
fn visit_path(&mut self, p: &'l ast::Path, id: NodeId) {
self.process_path(id, p);
}
fn visit_stmt(&mut self, s: &'l ast::Stmt) {
self.process_macro_use(s.span);
visit::walk_stmt(self, s)
}
fn visit_local(&mut self, l: &'l ast::Local) {
self.process_macro_use(l.span);
let value = l.init.as_ref().map(|i| self.span.snippet(i.span)).unwrap_or(String::new());
self.process_var_decl(&l.pat, value);
// Just walk the initialiser and type (don't want to walk the pattern again).
walk_list!(self, visit_ty, &l.ty);
walk_list!(self, visit_expr, &l.init);
}
fn visit_foreign_item(&mut self, item: &'l ast::ForeignItem) {
match item.node {
ast::ForeignItemKind::Fn(ref decl, ref generics) => {
if let Some(fn_data) = self.save_ctxt.get_extern_item_data(item) {
down_cast_data!(fn_data, DefData, item.span);
self.nest_tables(item.id, |v| v.process_formals(&decl.inputs,
&fn_data.qualname));
self.process_generic_params(generics, item.span, &fn_data.qualname, item.id);
self.dumper.dump_def(item.vis == ast::Visibility::Public, fn_data);
}
for arg in &decl.inputs {
self.visit_ty(&arg.ty);
}
if let ast::FunctionRetTy::Ty(ref ret_ty) = decl.output {
self.visit_ty(&ret_ty);
}
}
ast::ForeignItemKind::Static(ref ty, _) => {
if let Some(var_data) = self.save_ctxt.get_extern_item_data(item) {
down_cast_data!(var_data, DefData, item.span);
self.dumper.dump_def(item.vis == ast::Visibility::Public, var_data);
}
self.visit_ty(ty);
}
}
}
}
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