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rust/src/librustc/middle/save/mod.rs

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Dump results of analysis phase as CSV Adds the option -Zsave-analysis which will dump the results of syntax and type checking into CSV files. These can be interpreted by tools such as DXR to provide semantic information about Rust programs for code search, cross-reference, etc. Authored by Nick Cameron and Peter Elmers (@pelmers; including enums, type parameters/generics).
2014-02-05 17:31:33 +13:00
// Copyright 2012-2014 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.
//! Output a CSV file containing the output from rustc's analysis. The data is
//! primarily designed to be used as input to the DXR tool, specifically its
//! Rust plugin. It could also be used by IDEs or other code browsing, search, or
//! cross-referencing tools.
//!
//! 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).
//! Recorder is used for recording the output in csv format. FmtStrs separates
//! the format of the output away from extracting it from the compiler.
//! DxrVisitor walks the AST and processes it.
use driver::driver::CrateAnalysis;
use driver::session::Session;
use middle::def;
use middle::ty;
use middle::typeck;
use std::cell::Cell;
use std::gc::Gc;
use std::io;
use std::io::File;
use std::io::fs;
use std::os;
use syntax::ast;
use syntax::ast_util;
use syntax::ast::{NodeId,DefId};
use syntax::ast_map::NodeItem;
use syntax::attr;
use syntax::codemap::*;
use syntax::parse::token;
use syntax::parse::token::{get_ident,keywords};
use syntax::visit;
use syntax::visit::Visitor;
use syntax::print::pprust::{path_to_str,ty_to_str};
use middle::save::span_utils::SpanUtils;
use middle::save::recorder::Recorder;
use middle::save::recorder::FmtStrs;
use util::ppaux;
mod span_utils;
mod recorder;
// Helper function to escape quotes in a string
fn escape(s: String) -> String {
s.replace("\"", "\"\"")
}
// If the expression is a macro expansion or other generated code, run screaming and don't index.
fn generated_code(span: Span) -> bool {
span.expn_info.is_some() || span == DUMMY_SP
}
struct DxrVisitor<'l> {
sess: &'l Session,
analysis: &'l CrateAnalysis,
collected_paths: Vec<(NodeId, ast::Path, bool, recorder::Row)>,
collecting: bool,
span: SpanUtils<'l>,
fmt: FmtStrs<'l>,
}
impl <'l> DxrVisitor<'l> {
fn dump_crate_info(&mut self, name: &str, krate: &ast::Crate) {
// the current crate
self.fmt.crate_str(krate.span, name);
// dump info about all the external crates referenced from this crate
self.sess.cstore.iter_crate_data(|n, cmd| {
self.fmt.external_crate_str(krate.span, cmd.name.as_slice(), n);
});
self.fmt.recorder.record("end_external_crates\n");
}
// 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 spans = self.span.spans_for_path_segments(path);
// Paths to enums seem to not match their spans - the span includes all the
// variants too. But they seem to always be at the end, so I hope we can cope with
// always using the first ones. So, only error out if we don't have enough spans.
// What could go wrong...?
if spans.len() < path.segments.len() {
error!("Mis-calculated spans for path '{}'. \
Found {} spans, expected {}. Found spans:",
path_to_str(path), spans.len(), path.segments.len());
for s in spans.iter() {
let loc = self.sess.codemap().lookup_char_pos(s.lo);
error!(" '{}' in {}, line {}",
self.span.snippet(*s), loc.file.name, loc.line);
}
return vec!();
}
let mut result: Vec<(Span, String)> = vec!();
let mut segs = vec!();
for (seg, span) in path.segments.iter().zip(spans.iter()) {
segs.push(seg.clone());
let sub_path = ast::Path{span: *span, // span for the last segment
global: path.global,
segments: segs};
let qualname = path_to_str(&sub_path);
result.push((*span, qualname));
segs = sub_path.segments;
}
result
}
fn write_sub_paths(&mut self, path: &ast::Path, scope_id: NodeId) {
let sub_paths = self.process_path_prefixes(path);
for &(ref span, ref qualname) in sub_paths.iter() {
self.fmt.sub_mod_ref_str(path.span,
*span,
qualname.as_slice(),
scope_id);
}
}
// As write_sub_paths, but does not process the last ident in the path (assuming it
// will be processed elsewhere).
fn write_sub_paths_truncated(&mut self, path: &ast::Path, scope_id: NodeId) {
let sub_paths = self.process_path_prefixes(path);
let len = sub_paths.len();
if len <= 1 {
return;
}
let sub_paths = sub_paths.slice(0, len-1);
for &(ref span, ref qualname) in sub_paths.iter() {
self.fmt.sub_mod_ref_str(path.span,
*span,
qualname.as_slice(),
scope_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, scope_id: NodeId) {
let sub_paths = self.process_path_prefixes(path);
let len = sub_paths.len();
if len <= 1 {
return;
}
let sub_paths = sub_paths.slice_to(len-1);
// write the trait part of the sub-path
let (ref span, ref qualname) = sub_paths[len-2];
self.fmt.sub_type_ref_str(path.span,
*span,
qualname.as_slice());
// write the other sub-paths
if len <= 2 {
return;
}
let sub_paths = sub_paths.slice(0, len-2);
for &(ref span, ref qualname) in sub_paths.iter() {
self.fmt.sub_mod_ref_str(path.span,
*span,
qualname.as_slice(),
scope_id);
}
}
// looks up anything, not just a type
fn lookup_type_ref(&self, ref_id: NodeId) -> Option<DefId> {
if !self.analysis.ty_cx.def_map.borrow().contains_key(&ref_id) {
self.sess.bug(format!("def_map has no key for {} in lookup_type_ref",
ref_id).as_slice());
}
let def = *self.analysis.ty_cx.def_map.borrow().get(&ref_id);
match def {
def::DefPrimTy(_) => None,
_ => Some(def.def_id()),
}
}
fn lookup_def_kind(&self, ref_id: NodeId, span: Span) -> Option<recorder::Row> {
let def_map = self.analysis.ty_cx.def_map.borrow();
if !def_map.contains_key(&ref_id) {
self.sess.span_bug(span, format!("def_map has no key for {} in lookup_def_kind",
ref_id).as_slice());
}
let def = *def_map.get(&ref_id);
match def {
def::DefMod(_) |
def::DefForeignMod(_) => Some(recorder::ModRef),
def::DefStruct(_) => Some(recorder::StructRef),
def::DefTy(_) |
def::DefTrait(_) => Some(recorder::TypeRef),
def::DefStatic(_, _) |
def::DefBinding(_, _) |
def::DefArg(_, _) |
def::DefLocal(_, _) |
def::DefVariant(_, _, _) |
def::DefUpvar(_, _, _, _) => Some(recorder::VarRef),
def::DefFn(_, _) => Some(recorder::FnRef),
def::DefSelfTy(_) |
def::DefRegion(_) |
def::DefTyParamBinder(_) |
def::DefLabel(_) |
def::DefStaticMethod(_, _, _) |
Introduce VecPerParamSpace and use it to represent sets of types and parameters This involves numerous substeps: 1. Treat Self same as any other parameter. 2. No longer compute offsets for method parameters. 3. Store all generic types (both trait/impl and method) with a method, eliminating odd discrepancies. 4. Stop doing unspeakable things to static methods and instead just use the natural types, now that we can easily add the type parameters from trait into the method's polytype. 5. No doubt some more. It was hard to separate these into distinct commits. Fixes #13564
2014-05-31 18:53:13 -04:00
def::DefTyParam(..) |
Dump results of analysis phase as CSV Adds the option -Zsave-analysis which will dump the results of syntax and type checking into CSV files. These can be interpreted by tools such as DXR to provide semantic information about Rust programs for code search, cross-reference, etc. Authored by Nick Cameron and Peter Elmers (@pelmers; including enums, type parameters/generics).
2014-02-05 17:31:33 +13:00
def::DefUse(_) |
def::DefMethod(_, _) |
def::DefPrimTy(_) => {
self.sess.span_bug(span, format!("lookup_def_kind for unexpected item: {:?}",
def).as_slice());
},
}
}
fn process_formals(&mut self, formals: &Vec<ast::Arg>, qualname: &str, e:DxrVisitorEnv) {
for arg in formals.iter() {
assert!(self.collected_paths.len() == 0 && !self.collecting);
self.collecting = true;
self.visit_pat(&*arg.pat, e);
self.collecting = false;
let span_utils = self.span;
for &(id, ref p, _, _) in self.collected_paths.iter() {
let typ = ppaux::ty_to_str(&self.analysis.ty_cx,
*self.analysis.ty_cx.node_types.borrow().get(&(id as uint)));
// get the span only for the name of the variable (I hope the path is only ever a
// variable name, but who knows?)
self.fmt.formal_str(p.span,
span_utils.span_for_last_ident(p.span),
id,
qualname,
path_to_str(p).as_slice(),
typ.as_slice());
}
self.collected_paths.clear();
}
}
fn process_method(&mut self, method: &ast::Method, e:DxrVisitorEnv) {
if generated_code(method.span) {
return;
}
let mut scope_id;
// The qualname for a method is the trait name or name of the struct in an impl in
// which the method is declared in followed by the method's name.
let mut qualname = match ty::impl_of_method(&self.analysis.ty_cx,
ast_util::local_def(method.id)) {
Some(impl_id) => match self.analysis.ty_cx.map.get(impl_id.node) {
NodeItem(item) => {
scope_id = item.id;
match item.node {
ast::ItemImpl(_, _, ty, _) => {
let mut result = String::from_str("<");
result.push_str(ty_to_str(&*ty).as_slice());
match ty::trait_of_method(&self.analysis.ty_cx,
ast_util::local_def(method.id)) {
Some(def_id) => {
result.push_str(" as ");
result.push_str(
ty::item_path_str(&self.analysis.ty_cx, def_id).as_slice());
},
None => {}
}
result.append(">::")
}
_ => {
self.sess.span_bug(method.span,
format!("Container {} for method {} not an impl?",
impl_id.node, method.id).as_slice());
},
}
},
_ => {
self.sess.span_bug(method.span,
format!("Container {} for method {} is not a node item {:?}",
impl_id.node,
method.id,
self.analysis.ty_cx.map.get(impl_id.node)
).as_slice());
},
},
None => match ty::trait_of_method(&self.analysis.ty_cx,
ast_util::local_def(method.id)) {
Some(def_id) => {
scope_id = def_id.node;
match self.analysis.ty_cx.map.get(def_id.node) {
NodeItem(_) => {
let result = ty::item_path_str(&self.analysis.ty_cx, def_id);
result.append("::")
}
_ => {
self.sess.span_bug(method.span,
format!("Could not find container {} for method {}",
def_id.node, method.id).as_slice());
}
}
},
None => {
self.sess.span_bug(method.span,
format!("Could not find container for method {}",
method.id).as_slice());
},
},
};
qualname.push_str(get_ident(method.ident).get());
let qualname = qualname.as_slice();
// record the decl for this def (if it has one)
let decl_id = ty::trait_method_of_method(&self.analysis.ty_cx,
ast_util::local_def(method.id))
.filtered(|def_id| method.id != 0 && def_id.node == 0);
let sub_span = self.span.sub_span_after_keyword(method.span, keywords::Fn);
self.fmt.method_str(method.span,
sub_span,
method.id,
qualname,
decl_id,
scope_id);
self.process_formals(&method.decl.inputs, qualname, e);
// walk arg and return types
for arg in method.decl.inputs.iter() {
self.visit_ty(&*arg.ty, e);
}
self.visit_ty(&*method.decl.output, e);
// walk the fn body
self.visit_block(&*method.body, DxrVisitorEnv::new_nested(method.id));
self.process_generic_params(&method.generics,
method.span,
qualname,
method.id,
e);
}
fn process_trait_ref(&mut self,
trait_ref: &ast::TraitRef,
e: DxrVisitorEnv,
impl_id: Option<NodeId>) {
match self.lookup_type_ref(trait_ref.ref_id) {
Some(id) => {
let sub_span = self.span.sub_span_for_type_name(trait_ref.path.span);
self.fmt.ref_str(recorder::TypeRef,
trait_ref.path.span,
sub_span,
id,
e.cur_scope);
match impl_id {
Some(impl_id) => self.fmt.impl_str(trait_ref.path.span,
sub_span,
impl_id,
id,
e.cur_scope),
None => (),
}
visit::walk_path(self, &trait_ref.path, e);
},
None => ()
}
}
fn process_struct_field_def(&mut self,
field: &ast::StructField,
qualname: &str,
scope_id: NodeId) {
match field.node.kind {
ast::NamedField(ident, _) => {
let name = get_ident(ident);
let qualname = format!("{}::{}", qualname, name);
let typ = ppaux::ty_to_str(&self.analysis.ty_cx,
*self.analysis.ty_cx.node_types.borrow().get(&(field.node.id as uint)));
match self.span.sub_span_before_token(field.span, token::COLON) {
Some(sub_span) => self.fmt.field_str(field.span,
Some(sub_span),
field.node.id,
name.get().as_slice(),
qualname.as_slice(),
typ.as_slice(),
scope_id),
None => self.sess.span_bug(field.span,
format!("Could not find sub-span for field {}",
qualname).as_slice()),
}
},
_ => (),
}
}
// Dump generic params bindings, then visit_generics
fn process_generic_params(&mut self, generics:&ast::Generics,
full_span: Span,
prefix: &str,
id: NodeId,
e: DxrVisitorEnv) {
// We can't only use visit_generics since we don't have spans for param
// bindings, so we reparse the full_span to get those sub spans.
// However full span is the entire enum/fn/struct block, so we only want
// the first few to match the number of generics we're looking for.
let param_sub_spans = self.span.spans_for_ty_params(full_span,
(generics.ty_params.len() as int));
for (param, param_ss) in generics.ty_params.iter().zip(param_sub_spans.iter()) {
// Append $id to name to make sure each one is unique
let name = format!("{}::{}${}",
prefix,
escape(self.span.snippet(*param_ss)),
id);
self.fmt.typedef_str(full_span,
Some(*param_ss),
param.id,
name.as_slice(),
"");
}
self.visit_generics(generics, e);
}
fn process_fn(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
decl: ast::P<ast::FnDecl>,
ty_params: &ast::Generics,
body: ast::P<ast::Block>) {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Fn);
self.fmt.fn_str(item.span,
sub_span,
item.id,
qualname.as_slice(),
e.cur_scope);
self.process_formals(&decl.inputs, qualname.as_slice(), e);
// walk arg and return types
for arg in decl.inputs.iter() {
self.visit_ty(&*arg.ty, e);
}
self.visit_ty(&*decl.output, e);
// walk the body
self.visit_block(&*body, DxrVisitorEnv::new_nested(item.id));
self.process_generic_params(ty_params, item.span, qualname.as_slice(), item.id, e);
}
fn process_static(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
typ: ast::P<ast::Ty>,
mt: ast::Mutability,
expr: &ast::Expr)
{
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
// If the variable is immutable, save the initialising expresion.
let value = match mt {
ast::MutMutable => String::from_str("<mutable>"),
ast::MutImmutable => self.span.snippet(expr.span),
};
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Static);
self.fmt.static_str(item.span,
sub_span,
item.id,
get_ident(item.ident).get(),
qualname.as_slice(),
value.as_slice(),
ty_to_str(&*typ).as_slice(),
e.cur_scope);
// walk type and init value
self.visit_ty(&*typ, e);
self.visit_expr(expr, e);
}
fn process_struct(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
def: &ast::StructDef,
ty_params: &ast::Generics) {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
let ctor_id = match def.ctor_id {
Some(node_id) => node_id,
None => -1,
};
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Struct);
self.fmt.struct_str(item.span,
sub_span,
item.id,
ctor_id,
qualname.as_slice(),
e.cur_scope);
// fields
for field in def.fields.iter() {
self.process_struct_field_def(field, qualname.as_slice(), item.id);
self.visit_ty(&*field.node.ty, e);
}
self.process_generic_params(ty_params, item.span, qualname.as_slice(), item.id, e);
}
fn process_enum(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
enum_definition: &ast::EnumDef,
ty_params: &ast::Generics) {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
match self.span.sub_span_after_keyword(item.span, keywords::Enum) {
Some(sub_span) => self.fmt.enum_str(item.span,
Some(sub_span),
item.id,
qualname.as_slice(),
e.cur_scope),
None => self.sess.span_bug(item.span,
format!("Could not find subspan for enum {}",
qualname).as_slice()),
}
for variant in enum_definition.variants.iter() {
let name = get_ident(variant.node.name);
let name = name.get();
let qualname = qualname.clone().append("::").append(name);
let val = self.span.snippet(variant.span);
match variant.node.kind {
ast::TupleVariantKind(ref args) => {
// first ident in span is the variant's name
self.fmt.tuple_variant_str(variant.span,
self.span.span_for_first_ident(variant.span),
variant.node.id,
name,
qualname.as_slice(),
val.as_slice(),
item.id);
for arg in args.iter() {
self.visit_ty(&*arg.ty, e);
}
}
ast::StructVariantKind(ref struct_def) => {
let ctor_id = match struct_def.ctor_id {
Some(node_id) => node_id,
None => -1,
};
self.fmt.struct_variant_str(
variant.span,
self.span.span_for_first_ident(variant.span),
variant.node.id,
ctor_id,
qualname.as_slice(),
val.as_slice(),
item.id);
for field in struct_def.fields.iter() {
self.process_struct_field_def(field, qualname.as_slice(), variant.node.id);
self.visit_ty(&*field.node.ty, e);
}
}
}
}
self.process_generic_params(ty_params, item.span, qualname.as_slice(), item.id, e);
}
fn process_impl(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
type_parameters: &ast::Generics,
trait_ref: &Option<ast::TraitRef>,
typ: ast::P<ast::Ty>,
methods: &Vec<Gc<ast::Method>>) {
match typ.node {
ast::TyPath(ref path, _, id) => {
match self.lookup_type_ref(id) {
Some(id) => {
let sub_span = self.span.sub_span_for_type_name(path.span);
self.fmt.ref_str(recorder::TypeRef,
path.span,
sub_span,
id,
e.cur_scope);
self.fmt.impl_str(path.span,
sub_span,
item.id,
id,
e.cur_scope);
},
None => ()
}
},
_ => self.visit_ty(&*typ, e),
}
match *trait_ref {
Some(ref trait_ref) => self.process_trait_ref(trait_ref, e, Some(item.id)),
None => (),
}
self.process_generic_params(type_parameters, item.span, "", item.id, e);
for method in methods.iter() {
visit::walk_method_helper(self, &**method, e)
}
}
fn process_trait(&mut self,
item: &ast::Item,
e: DxrVisitorEnv,
generics: &ast::Generics,
trait_refs: &Vec<ast::TraitRef>,
methods: &Vec<ast::TraitMethod>) {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Trait);
self.fmt.trait_str(item.span,
sub_span,
item.id,
qualname.as_slice(),
e.cur_scope);
// super-traits
for trait_ref in trait_refs.iter() {
match self.lookup_type_ref(trait_ref.ref_id) {
Some(id) => {
let sub_span = self.span.sub_span_for_type_name(trait_ref.path.span);
self.fmt.ref_str(recorder::TypeRef,
trait_ref.path.span,
sub_span,
id,
e.cur_scope);
self.fmt.inherit_str(trait_ref.path.span,
sub_span,
id,
item.id);
},
None => ()
}
}
// walk generics and methods
self.process_generic_params(generics, item.span, qualname.as_slice(), item.id, e);
for method in methods.iter() {
self.visit_trait_method(method, e)
}
}
fn process_mod(&mut self,
item: &ast::Item, // The module in question, represented as an item.
e: DxrVisitorEnv,
m: &ast::Mod) {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
let cm = self.sess.codemap();
let filename = cm.span_to_filename(m.inner);
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Mod);
self.fmt.mod_str(item.span,
sub_span,
item.id,
qualname.as_slice(),
e.cur_scope,
filename.as_slice());
visit::walk_mod(self, m, DxrVisitorEnv::new_nested(item.id));
}
fn process_path(&mut self,
ex: &ast::Expr,
e: DxrVisitorEnv,
path: &ast::Path) {
if generated_code(path.span) {
return
}
let def_map = self.analysis.ty_cx.def_map.borrow();
if !def_map.contains_key(&ex.id) {
self.sess.span_bug(ex.span,
format!("def_map has no key for {} in visit_expr",
ex.id).as_slice());
}
let def = def_map.get(&ex.id);
let sub_span = self.span.span_for_last_ident(ex.span);
match *def {
def::DefLocal(id, _) |
def::DefArg(id, _) |
def::DefUpvar(id, _, _, _) |
def::DefBinding(id, _) => self.fmt.ref_str(recorder::VarRef,
ex.span,
sub_span,
ast_util::local_def(id),
e.cur_scope),
def::DefStatic(def_id,_) |
def::DefVariant(_, def_id, _) => self.fmt.ref_str(recorder::VarRef,
ex.span,
sub_span,
def_id,
e.cur_scope),
def::DefStruct(def_id) => self.fmt.ref_str(recorder::StructRef,
ex.span,
sub_span,
def_id,
e.cur_scope),
def::DefStaticMethod(declid, provenence, _) => {
let sub_span = self.span.sub_span_for_meth_name(ex.span);
let defid = if declid.krate == ast::LOCAL_CRATE {
let m = ty::method(&self.analysis.ty_cx, declid);
match provenence {
def::FromTrait(def_id) =>
Some(ty::trait_methods(&self.analysis.ty_cx, def_id)
.iter().find(|mr| mr.ident.name == m.ident.name).unwrap().def_id),
def::FromImpl(def_id) => {
let impl_methods = self.analysis.ty_cx.impl_methods.borrow();
Some(*impl_methods.get(&def_id)
.iter().find(|mr|
ty::method(
&self.analysis.ty_cx, **mr).ident.name == m.ident.name)
.unwrap())
}
}
} else {
None
};
self.fmt.meth_call_str(ex.span,
sub_span,
defid,
Some(declid),
e.cur_scope);
},
def::DefFn(def_id, _) => self.fmt.fn_call_str(ex.span,
sub_span,
def_id,
e.cur_scope),
_ => self.sess.span_bug(ex.span,
format!("Unexpected def kind while looking up path in '{}'",
self.span.snippet(ex.span)).as_slice()),
}
// modules or types in the path prefix
match *def {
def::DefStaticMethod(_, _, _) => {
self.write_sub_path_trait_truncated(path, e.cur_scope);
},
def::DefLocal(_, _) |
def::DefArg(_, _) |
def::DefStatic(_,_) |
def::DefStruct(_) |
def::DefFn(_, _) => self.write_sub_paths_truncated(path, e.cur_scope),
_ => {},
}
visit::walk_path(self, path, e);
}
fn process_struct_lit(&mut self,
ex: &ast::Expr,
e: DxrVisitorEnv,
path: &ast::Path,
fields: &Vec<ast::Field>,
base: Option<Gc<ast::Expr>>) {
if generated_code(path.span) {
return
}
let mut struct_def: Option<DefId> = None;
match self.lookup_type_ref(ex.id) {
Some(id) => {
struct_def = Some(id);
let sub_span = self.span.span_for_last_ident(path.span);
self.fmt.ref_str(recorder::StructRef,
path.span,
sub_span,
id,
e.cur_scope);
},
None => ()
}
self.write_sub_paths_truncated(path, e.cur_scope);
for field in fields.iter() {
match struct_def {
Some(struct_def) => {
let fields = ty::lookup_struct_fields(&self.analysis.ty_cx, struct_def);
for f in fields.iter() {
if generated_code(field.ident.span) {
continue;
}
if f.name == field.ident.node.name {
// We don't really need a sub-span here, but no harm done
let sub_span = self.span.span_for_last_ident(field.ident.span);
self.fmt.ref_str(recorder::VarRef,
field.ident.span,
sub_span,
f.id,
e.cur_scope);
}
}
}
None => {}
}
self.visit_expr(&*field.expr, e)
}
visit::walk_expr_opt(self, base, e)
}
fn process_method_call(&mut self,
ex: &ast::Expr,
e: DxrVisitorEnv,
args: &Vec<Gc<ast::Expr>>) {
let method_map = self.analysis.ty_cx.method_map.borrow();
let method_callee = method_map.get(&typeck::MethodCall::expr(ex.id));
let (def_id, decl_id) = match method_callee.origin {
typeck::MethodStatic(def_id) => {
// method invoked on an object with a concrete type (not a static method)
let decl_id = ty::trait_method_of_method(&self.analysis.ty_cx, def_id);
// This incantation is required if the method referenced is a trait's
// defailt implementation.
let def_id = ty::method(&self.analysis.ty_cx, def_id).provided_source
.unwrap_or(def_id);
(Some(def_id), decl_id)
}
typeck::MethodParam(mp) => {
// method invoked on a type parameter
let method = ty::trait_method(&self.analysis.ty_cx,
mp.trait_id,
mp.method_num);
(None, Some(method.def_id))
},
typeck::MethodObject(mo) => {
// method invoked on a trait instance
let method = ty::trait_method(&self.analysis.ty_cx,
mo.trait_id,
mo.method_num);
(None, Some(method.def_id))
},
};
let sub_span = self.span.sub_span_for_meth_name(ex.span);
self.fmt.meth_call_str(ex.span,
sub_span,
def_id,
decl_id,
e.cur_scope);
// walk receiver and args
visit::walk_exprs(self, args.as_slice(), e);
}
fn process_pat(&mut self, p:&ast::Pat, e: DxrVisitorEnv) {
if generated_code(p.span) {
return
}
match p.node {
ast::PatStruct(ref path, ref fields, _) => {
self.collected_paths.push((p.id, path.clone(), false, recorder::StructRef));
visit::walk_path(self, path, e);
let struct_def = match self.lookup_type_ref(p.id) {
Some(sd) => sd,
None => {
self.sess.span_bug(p.span,
format!("Could not find struct_def for `{}`",
self.span.snippet(p.span)).as_slice());
}
};
// The AST doesn't give us a span for the struct field, so we have
// to figure out where it is by assuming it's the token before each colon.
let field_spans = self.span.sub_spans_before_tokens(p.span,
token::COMMA,
token::COLON);
if fields.len() != field_spans.len() {
self.sess.span_bug(p.span,
format!("Mismatched field count in '{}', found {}, expected {}",
self.span.snippet(p.span), field_spans.len(), fields.len()
).as_slice());
}
for (field, &span) in fields.iter().zip(field_spans.iter()) {
self.visit_pat(&*field.pat, e);
if span.is_none() {
continue;
}
let fields = ty::lookup_struct_fields(&self.analysis.ty_cx, struct_def);
for f in fields.iter() {
if f.name == field.ident.name {
self.fmt.ref_str(recorder::VarRef,
p.span,
span,
f.id,
e.cur_scope);
break;
}
}
}
}
ast::PatEnum(ref path, _) => {
self.collected_paths.push((p.id, path.clone(), false, recorder::VarRef));
visit::walk_pat(self, p, e);
}
ast::PatIdent(bm, ref path, ref optional_subpattern) => {
let immut = match bm {
// Even if the ref is mut, you can't change the ref, only
// the data pointed at, so showing the initialising expression
// is still worthwhile.
ast::BindByRef(_) => true,
ast::BindByValue(mt) => {
match mt {
ast::MutMutable => false,
ast::MutImmutable => true,
}
}
};
// collect path for either visit_local or visit_arm
self.collected_paths.push((p.id, path.clone(), immut, recorder::VarRef));
match *optional_subpattern {
None => {}
Some(subpattern) => self.visit_pat(&*subpattern, e),
}
}
_ => visit::walk_pat(self, p, e)
}
}
}
impl<'l> Visitor<DxrVisitorEnv> for DxrVisitor<'l> {
fn visit_item(&mut self, item:&ast::Item, e: DxrVisitorEnv) {
if generated_code(item.span) {
return
}
match item.node {
ast::ItemFn(decl, _, _, ref ty_params, body) =>
self.process_fn(item, e, decl, ty_params, body),
ast::ItemStatic(typ, mt, expr) =>
self.process_static(item, e, typ, mt, &*expr),
ast::ItemStruct(def, ref ty_params) => self.process_struct(item, e, &*def, ty_params),
ast::ItemEnum(ref def, ref ty_params) => self.process_enum(item, e, def, ty_params),
ast::ItemImpl(ref ty_params, ref trait_ref, typ, ref methods) =>
self.process_impl(item, e, ty_params, trait_ref, typ, methods),
ast::ItemTrait(ref generics, _, ref trait_refs, ref methods) =>
self.process_trait(item, e, generics, trait_refs, methods),
ast::ItemMod(ref m) => self.process_mod(item, e, m),
ast::ItemTy(ty, ref ty_params) => {
let qualname = self.analysis.ty_cx.map.path_to_str(item.id);
let value = ty_to_str(&*ty);
let sub_span = self.span.sub_span_after_keyword(item.span, keywords::Type);
self.fmt.typedef_str(item.span,
sub_span,
item.id,
qualname.as_slice(),
value.as_slice());
self.visit_ty(&*ty, e);
self.process_generic_params(ty_params, item.span, qualname.as_slice(), item.id, e);
},
ast::ItemMac(_) => (),
_ => visit::walk_item(self, item, e),
}
}
fn visit_generics(&mut self, generics: &ast::Generics, e: DxrVisitorEnv) {
for param in generics.ty_params.iter() {
for bound in param.bounds.iter() {
match *bound {
ast::TraitTyParamBound(ref trait_ref) => {
self.process_trait_ref(trait_ref, e, None);
}
_ => {}
}
}
match param.default {
Some(ty) => self.visit_ty(&*ty, e),
None => (),
}
}
}
// We don't actually index functions here, that is done in visit_item/ItemFn.
// Here we just visit methods.
fn visit_fn(&mut self,
fk: &visit::FnKind,
fd: &ast::FnDecl,
b: &ast::Block,
s: Span,
_: NodeId,
e: DxrVisitorEnv) {
if generated_code(s) {
return;
}
match *fk {
visit::FkMethod(_, _, method) => self.process_method(method, e),
_ => visit::walk_fn(self, fk, fd, b, s, e),
}
}
fn visit_trait_method(&mut self, tm: &ast::TraitMethod, e: DxrVisitorEnv) {
match *tm {
ast::Required(ref method_type) => {
if generated_code(method_type.span) {
return;
}
let mut scope_id ;
let mut qualname = match ty::trait_of_method(&self.analysis.ty_cx,
ast_util::local_def(method_type.id)) {
Some(def_id) => {
scope_id = def_id.node;
ty::item_path_str(&self.analysis.ty_cx, def_id).append("::")
},
None => {
self.sess.span_bug(method_type.span,
format!("Could not find trait for method {}",
method_type.id).as_slice());
},
};
qualname.push_str(get_ident(method_type.ident).get());
let qualname = qualname.as_slice();
let sub_span = self.span.sub_span_after_keyword(method_type.span, keywords::Fn);
self.fmt.method_decl_str(method_type.span,
sub_span,
method_type.id,
qualname,
scope_id);
// walk arg and return types
for arg in method_type.decl.inputs.iter() {
self.visit_ty(&*arg.ty, e);
}
self.visit_ty(&*method_type.decl.output, e);
self.process_generic_params(&method_type.generics,
method_type.span,
qualname,
method_type.id,
e);
}
ast::Provided(method) => self.process_method(&*method, e),
}
}
fn visit_view_item(&mut self, i:&ast::ViewItem, e:DxrVisitorEnv) {
if generated_code(i.span) {
return
}
match i.node {
ast::ViewItemUse(ref path) => {
match path.node {
ast::ViewPathSimple(ident, ref path, id) => {
let sub_span = self.span.span_for_last_ident(path.span);
let mod_id = match self.lookup_type_ref(id) {
Some(def_id) => {
match self.lookup_def_kind(id, path.span) {
Some(kind) => self.fmt.ref_str(kind,
path.span,
sub_span,
def_id,
e.cur_scope),
None => {},
}
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_before_token(path.span, token::EQ) {
Some(sub_span) => Some(sub_span),
None => sub_span,
};
self.fmt.use_alias_str(path.span,
sub_span,
id,
mod_id,
get_ident(ident).get(),
e.cur_scope);
self.write_sub_paths_truncated(path, e.cur_scope);
}
ast::ViewPathGlob(ref path, _) => {
self.write_sub_paths(path, e.cur_scope);
}
ast::ViewPathList(ref path, ref list, _) => {
for plid in list.iter() {
match self.lookup_type_ref(plid.node.id) {
Some(id) => match self.lookup_def_kind(plid.node.id, plid.span) {
Some(kind) => self.fmt.ref_str(kind,
plid.span,
Some(plid.span),
id,
e.cur_scope),
None => (),
},
None => ()
}
}
self.write_sub_paths(path, e.cur_scope);
}
}
},
ast::ViewItemExternCrate(ident, ref s, id) => {
let name = get_ident(ident).get().to_owned();
let s = match *s {
Some((ref s, _)) => s.get().to_owned(),
None => name.to_owned(),
};
let sub_span = self.span.sub_span_after_keyword(i.span, keywords::Crate);
let cnum = match self.sess.cstore.find_extern_mod_stmt_cnum(id) {
Some(cnum) => cnum,
None => 0,
};
self.fmt.extern_crate_str(i.span,
sub_span,
id,
cnum,
name.as_slice(),
s.as_slice(),
e.cur_scope);
},
}
}
fn visit_ty(&mut self, t: &ast::Ty, e: DxrVisitorEnv) {
if generated_code(t.span) {
return
}
match t.node {
ast::TyPath(ref path, _, id) => {
match self.lookup_type_ref(id) {
Some(id) => {
let sub_span = self.span.sub_span_for_type_name(t.span);
self.fmt.ref_str(recorder::TypeRef,
t.span,
sub_span,
id,
e.cur_scope);
},
None => ()
}
self.write_sub_paths_truncated(path, e.cur_scope);
visit::walk_path(self, path, e);
},
_ => visit::walk_ty(self, t, e),
}
}
fn visit_expr(&mut self, ex: &ast::Expr, e: DxrVisitorEnv) {
if generated_code(ex.span) {
return
}
match ex.node {
ast::ExprCall(_f, ref _args) => {
// Don't need to do anything for function calls,
// because just walking the callee path does what we want.
visit::walk_expr(self, ex, e);
},
ast::ExprPath(ref path) => self.process_path(ex, e, path),
ast::ExprStruct(ref path, ref fields, base) =>
self.process_struct_lit(ex, e, path, fields, base),
ast::ExprMethodCall(_, _, ref args) => self.process_method_call(ex, e, args),
ast::ExprField(sub_ex, ident, _) => {
if generated_code(sub_ex.span) {
return
}
self.visit_expr(&*sub_ex, e);
let t = ty::expr_ty_adjusted(&self.analysis.ty_cx, &*sub_ex);
let t_box = ty::get(t);
match t_box.sty {
ty::ty_struct(def_id, _) => {
let fields = ty::lookup_struct_fields(&self.analysis.ty_cx, def_id);
for f in fields.iter() {
rustc: Improve span for error about using a method as a field. libsyntax: ExprField now contains a SpannedIdent rather than Ident. [breaking-change]
2014-06-13 22:56:42 +01:00
if f.name == ident.node.name {
Dump results of analysis phase as CSV Adds the option -Zsave-analysis which will dump the results of syntax and type checking into CSV files. These can be interpreted by tools such as DXR to provide semantic information about Rust programs for code search, cross-reference, etc. Authored by Nick Cameron and Peter Elmers (@pelmers; including enums, type parameters/generics).
2014-02-05 17:31:33 +13:00
let sub_span = self.span.span_for_last_ident(ex.span);
self.fmt.ref_str(recorder::VarRef,
ex.span,
sub_span,
f.id,
e.cur_scope);
break;
}
}
},
_ => self.sess.span_bug(ex.span,
"Expected struct type, but not ty_struct"),
}
},
ast::ExprFnBlock(decl, body) => {
if generated_code(body.span) {
return
}
let id = String::from_str("$").append(ex.id.to_str().as_slice());
self.process_formals(&decl.inputs, id.as_slice(), e);
// walk arg and return types
for arg in decl.inputs.iter() {
self.visit_ty(&*arg.ty, e);
}
self.visit_ty(&*decl.output, e);
// walk the body
self.visit_block(&*body, DxrVisitorEnv::new_nested(ex.id));
},
_ => {
visit::walk_expr(self, ex, e)
},
}
}
fn visit_mac(&mut self, _: &ast::Mac, _: DxrVisitorEnv) {
// Just stop, macros are poison to us.
}
fn visit_pat(&mut self, p: &ast::Pat, e: DxrVisitorEnv) {
self.process_pat(p, e);
if !self.collecting {
self.collected_paths.clear();
}
}
fn visit_arm(&mut self, arm: &ast::Arm, e: DxrVisitorEnv) {
assert!(self.collected_paths.len() == 0 && !self.collecting);
self.collecting = true;
for pattern in arm.pats.iter() {
// collect paths from the arm's patterns
self.visit_pat(&**pattern, e);
}
self.collecting = false;
// process collected paths
for &(id, ref p, ref immut, ref_kind) in self.collected_paths.iter() {
let value = if *immut {
self.span.snippet(p.span).into_owned()
} else {
"<mutable>".to_owned()
};
let sub_span = self.span.span_for_first_ident(p.span);
let def_map = self.analysis.ty_cx.def_map.borrow();
if !def_map.contains_key(&id) {
self.sess.span_bug(p.span,
format!("def_map has no key for {} in visit_arm",
id).as_slice());
}
let def = def_map.get(&id);
match *def {
def::DefBinding(id, _) => self.fmt.variable_str(p.span,
sub_span,
id,
path_to_str(p).as_slice(),
value.as_slice(),
""),
def::DefVariant(_,id,_) => self.fmt.ref_str(ref_kind,
p.span,
sub_span,
id,
e.cur_scope),
// FIXME(nrc) what is this doing here?
def::DefStatic(_, _) => {}
_ => error!("unexpected defintion kind when processing collected paths: {:?}", *def)
}
}
self.collected_paths.clear();
visit::walk_expr_opt(self, arm.guard, e);
self.visit_expr(&*arm.body, e);
}
fn visit_stmt(&mut self, s:&ast::Stmt, e:DxrVisitorEnv) {
if generated_code(s.span) {
return
}
visit::walk_stmt(self, s, e)
}
fn visit_local(&mut self, l:&ast::Local, e: DxrVisitorEnv) {
if generated_code(l.span) {
return
}
// The local could declare multiple new vars, we must walk the
// pattern and collect them all.
assert!(self.collected_paths.len() == 0 && !self.collecting);
self.collecting = true;
self.visit_pat(&*l.pat, e);
self.collecting = false;
let value = self.span.snippet(l.span);
for &(id, ref p, ref immut, _) in self.collected_paths.iter() {
let value = if *immut { value.to_owned() } else { "<mutable>".to_owned() };
let types = self.analysis.ty_cx.node_types.borrow();
let typ = ppaux::ty_to_str(&self.analysis.ty_cx, *types.get(&(id as uint)));
// 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.
self.fmt.variable_str(p.span,
sub_span,
id,
path_to_str(p).as_slice(),
value.as_slice(),
typ.as_slice());
}
self.collected_paths.clear();
// Just walk the initialiser and type (don't want to walk the pattern again).
self.visit_ty(&*l.ty, e);
visit::walk_expr_opt(self, l.init, e);
}
}
#[deriving(Clone)]
struct DxrVisitorEnv {
cur_scope: NodeId,
}
impl DxrVisitorEnv {
fn new() -> DxrVisitorEnv {
DxrVisitorEnv{cur_scope: 0}
}
fn new_nested(new_mod: NodeId) -> DxrVisitorEnv {
DxrVisitorEnv{cur_scope: new_mod}
}
}
pub fn process_crate(sess: &Session,
krate: &ast::Crate,
analysis: &CrateAnalysis,
odir: &Option<Path>) {
if generated_code(krate.span) {
return;
}
let (cratename, crateid) = match attr::find_crateid(krate.attrs.as_slice()) {
Some(crateid) => (crateid.name.clone(), crateid.to_str()),
None => {
info!("Could not find crate name, using 'unknown_crate'");
(String::from_str("unknown_crate"),"unknown_crate".to_owned())
},
};
info!("Dumping crate {} ({})", cratename, crateid);
// find a path to dump our data to
let mut root_path = match os::getenv("DXR_RUST_TEMP_FOLDER") {
Some(val) => Path::new(val),
None => match *odir {
Some(ref val) => val.join("dxr"),
None => Path::new("dxr-temp"),
},
};
match fs::mkdir_recursive(&root_path, io::UserRWX) {
Err(e) => sess.err(format!("Could not create directory {}: {}",
root_path.display(), e).as_slice()),
_ => (),
}
{
let disp = root_path.display();
info!("Writing output to {}", disp);
}
// Create ouput file.
let mut out_name = cratename.clone();
out_name.push_str(".csv");
root_path.push(out_name);
let output_file = match File::create(&root_path) {
Ok(f) => box f,
Err(e) => {
let disp = root_path.display();
sess.fatal(format!("Could not open {}: {}", disp, e).as_slice());
}
};
root_path.pop();
let mut visitor = DxrVisitor{ sess: sess,
analysis: analysis,
collected_paths: vec!(),
collecting: false,
fmt: FmtStrs::new(box Recorder {
out: output_file as Box<Writer>,
dump_spans: false,
},
SpanUtils {
sess: sess,
err_count: Cell::new(0)
},
cratename.clone()),
span: SpanUtils {
sess: sess,
err_count: Cell::new(0)
}};
visitor.dump_crate_info(cratename.as_slice(), krate);
visit::walk_crate(&mut visitor, krate, DxrVisitorEnv::new());
}
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