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|
//! Various diagnostics for expressions that are collected together in one pass
//! through the body using inference results: mismatched arg counts, missing
//! fields, etc.
use std::{cell::RefCell, sync::Arc};
use hir_def::{
expr::Statement, path::path, resolver::HasResolver, AssocItemId, DefWithBodyId, HasModule,
};
use hir_expand::name;
use itertools::Either;
use rustc_hash::FxHashSet;
use crate::{
db::HirDatabase,
diagnostics::match_check::{
self,
usefulness::{compute_match_usefulness, expand_pattern, MatchCheckCtx, PatternArena},
},
AdtId, InferenceResult, Interner, TyExt, TyKind,
};
pub(crate) use hir_def::{
body::{Body, BodySourceMap},
expr::{Expr, ExprId, MatchArm, Pat, PatId},
LocalFieldId, VariantId,
};
pub enum BodyValidationDiagnostic {
RecordMissingFields {
record: Either<ExprId, PatId>,
variant: VariantId,
missed_fields: Vec<LocalFieldId>,
},
ReplaceFilterMapNextWithFindMap {
method_call_expr: ExprId,
},
MismatchedArgCount {
call_expr: ExprId,
expected: usize,
found: usize,
},
RemoveThisSemicolon {
expr: ExprId,
},
MissingOkOrSomeInTailExpr {
expr: ExprId,
required: String,
},
MissingMatchArms {
match_expr: ExprId,
},
}
impl BodyValidationDiagnostic {
pub fn collect(db: &dyn HirDatabase, owner: DefWithBodyId) -> Vec<BodyValidationDiagnostic> {
let _p = profile::span("BodyValidationDiagnostic::collect");
let infer = db.infer(owner);
let mut validator = ExprValidator::new(owner, infer.clone());
validator.validate_body(db);
validator.diagnostics
}
}
struct ExprValidator {
owner: DefWithBodyId,
infer: Arc<InferenceResult>,
pub(super) diagnostics: Vec<BodyValidationDiagnostic>,
}
impl ExprValidator {
fn new(owner: DefWithBodyId, infer: Arc<InferenceResult>) -> ExprValidator {
ExprValidator { owner, infer, diagnostics: Vec::new() }
}
fn validate_body(&mut self, db: &dyn HirDatabase) {
self.check_for_filter_map_next(db);
let body = db.body(self.owner);
for (id, expr) in body.exprs.iter() {
if let Some((variant, missed_fields, true)) =
record_literal_missing_fields(db, &self.infer, id, expr)
{
self.diagnostics.push(BodyValidationDiagnostic::RecordMissingFields {
record: Either::Left(id),
variant,
missed_fields,
});
}
match expr {
Expr::Match { expr, arms } => {
self.validate_match(id, *expr, arms, db, self.infer.clone());
}
Expr::Call { .. } | Expr::MethodCall { .. } => {
self.validate_call(db, id, expr);
}
_ => {}
}
}
for (id, pat) in body.pats.iter() {
if let Some((variant, missed_fields, true)) =
record_pattern_missing_fields(db, &self.infer, id, pat)
{
self.diagnostics.push(BodyValidationDiagnostic::RecordMissingFields {
record: Either::Right(id),
variant,
missed_fields,
});
}
}
let body_expr = &body[body.body_expr];
if let Expr::Block { statements, tail, .. } = body_expr {
if let Some(t) = tail {
self.validate_results_in_tail_expr(body.body_expr, *t, db);
} else if let Some(Statement::Expr { expr: id, .. }) = statements.last() {
self.validate_missing_tail_expr(body.body_expr, *id);
}
}
}
fn check_for_filter_map_next(&mut self, db: &dyn HirDatabase) {
// Find the FunctionIds for Iterator::filter_map and Iterator::next
let iterator_path = path![core::iter::Iterator];
let resolver = self.owner.resolver(db.upcast());
let iterator_trait_id = match resolver.resolve_known_trait(db.upcast(), &iterator_path) {
Some(id) => id,
None => return,
};
let iterator_trait_items = &db.trait_data(iterator_trait_id).items;
let filter_map_function_id =
match iterator_trait_items.iter().find(|item| item.0 == name![filter_map]) {
Some((_, AssocItemId::FunctionId(id))) => id,
_ => return,
};
let next_function_id = match iterator_trait_items.iter().find(|item| item.0 == name![next])
{
Some((_, AssocItemId::FunctionId(id))) => id,
_ => return,
};
// Search function body for instances of .filter_map(..).next()
let body = db.body(self.owner);
let mut prev = None;
for (id, expr) in body.exprs.iter() {
if let Expr::MethodCall { receiver, .. } = expr {
let function_id = match self.infer.method_resolution(id) {
Some((id, _)) => id,
None => continue,
};
if function_id == *filter_map_function_id {
prev = Some(id);
continue;
}
if function_id == *next_function_id {
if let Some(filter_map_id) = prev {
if *receiver == filter_map_id {
self.diagnostics.push(
BodyValidationDiagnostic::ReplaceFilterMapNextWithFindMap {
method_call_expr: id,
},
);
}
}
}
}
prev = None;
}
}
fn validate_call(&mut self, db: &dyn HirDatabase, call_id: ExprId, expr: &Expr) {
// Check that the number of arguments matches the number of parameters.
// FIXME: Due to shortcomings in the current type system implementation, only emit this
// diagnostic if there are no type mismatches in the containing function.
if self.infer.expr_type_mismatches().next().is_some() {
return;
}
let is_method_call = matches!(expr, Expr::MethodCall { .. });
let (sig, args) = match expr {
Expr::Call { callee, args } => {
let callee = &self.infer.type_of_expr[*callee];
let sig = match callee.callable_sig(db) {
Some(sig) => sig,
None => return,
};
(sig, args.clone())
}
Expr::MethodCall { receiver, args, .. } => {
let mut args = args.clone();
args.insert(0, *receiver);
let receiver = &self.infer.type_of_expr[*receiver];
if receiver.strip_references().is_unknown() {
// if the receiver is of unknown type, it's very likely we
// don't know enough to correctly resolve the method call.
// This is kind of a band-aid for #6975.
return;
}
let (callee, subst) = match self.infer.method_resolution(call_id) {
Some(it) => it,
None => return,
};
let sig = db.callable_item_signature(callee.into()).substitute(&Interner, &subst);
(sig, args)
}
_ => return,
};
if sig.is_varargs {
return;
}
let params = sig.params();
let mut param_count = params.len();
let mut arg_count = args.len();
if arg_count != param_count {
if is_method_call {
param_count -= 1;
arg_count -= 1;
}
self.diagnostics.push(BodyValidationDiagnostic::MismatchedArgCount {
call_expr: call_id,
expected: param_count,
found: arg_count,
});
}
}
fn validate_match(
&mut self,
id: ExprId,
match_expr: ExprId,
arms: &[MatchArm],
db: &dyn HirDatabase,
infer: Arc<InferenceResult>,
) {
let (body, source_map): (Arc<Body>, Arc<BodySourceMap>) =
db.body_with_source_map(self.owner);
let match_expr_ty = if infer.type_of_expr[match_expr].is_unknown() {
return;
} else {
&infer.type_of_expr[match_expr]
};
let pattern_arena = RefCell::new(PatternArena::new());
let mut m_arms = Vec::new();
let mut has_lowering_errors = false;
for arm in arms {
if let Some(pat_ty) = infer.type_of_pat.get(arm.pat) {
// We only include patterns whose type matches the type
// of the match expression. If we had a InvalidMatchArmPattern
// diagnostic or similar we could raise that in an else
// block here.
//
// When comparing the types, we also have to consider that rustc
// will automatically de-reference the match expression type if
// necessary.
//
// FIXME we should use the type checker for this.
if (pat_ty == match_expr_ty
|| match_expr_ty
.as_reference()
.map(|(match_expr_ty, ..)| match_expr_ty == pat_ty)
.unwrap_or(false))
&& types_of_subpatterns_do_match(arm.pat, &body, &infer)
{
// If we had a NotUsefulMatchArm diagnostic, we could
// check the usefulness of each pattern as we added it
// to the matrix here.
let m_arm = match_check::MatchArm {
pat: self.lower_pattern(
arm.pat,
&mut pattern_arena.borrow_mut(),
db,
&body,
&mut has_lowering_errors,
),
has_guard: arm.guard.is_some(),
};
m_arms.push(m_arm);
if !has_lowering_errors {
continue;
}
}
}
// If we can't resolve the type of a pattern, or the pattern type doesn't
// fit the match expression, we skip this diagnostic. Skipping the entire
// diagnostic rather than just not including this match arm is preferred
// to avoid the chance of false positives.
cov_mark::hit!(validate_match_bailed_out);
return;
}
let cx = MatchCheckCtx {
module: self.owner.module(db.upcast()),
match_expr,
infer: &infer,
db,
pattern_arena: &pattern_arena,
panic_context: &|| {
use syntax::AstNode;
let match_expr_text = source_map
.expr_syntax(match_expr)
.ok()
.and_then(|scrutinee_sptr| {
let root = scrutinee_sptr.file_syntax(db.upcast());
scrutinee_sptr.value.to_node(&root).syntax().parent()
})
.map(|node| node.to_string());
format!(
"expression:\n{}",
match_expr_text.as_deref().unwrap_or("<synthesized expr>")
)
},
};
let report = compute_match_usefulness(&cx, &m_arms);
// FIXME Report unreacheble arms
// https://github.com/rust-lang/rust/blob/25c15cdbe/compiler/rustc_mir_build/src/thir/pattern/check_match.rs#L200-L201
let witnesses = report.non_exhaustiveness_witnesses;
// FIXME Report witnesses
// eprintln!("compute_match_usefulness(..) -> {:?}", &witnesses);
if !witnesses.is_empty() {
self.diagnostics.push(BodyValidationDiagnostic::MissingMatchArms { match_expr: id });
}
}
fn lower_pattern(
&self,
pat: PatId,
pattern_arena: &mut PatternArena,
db: &dyn HirDatabase,
body: &Body,
have_errors: &mut bool,
) -> match_check::PatId {
let mut patcx = match_check::PatCtxt::new(db, &self.infer, body);
let pattern = patcx.lower_pattern(pat);
let pattern = pattern_arena.alloc(expand_pattern(pattern));
if !patcx.errors.is_empty() {
*have_errors = true;
}
pattern
}
fn validate_results_in_tail_expr(&mut self, body_id: ExprId, id: ExprId, db: &dyn HirDatabase) {
// the mismatch will be on the whole block currently
let mismatch = match self.infer.type_mismatch_for_expr(body_id) {
Some(m) => m,
None => return,
};
let core_result_path = path![core::result::Result];
let core_option_path = path![core::option::Option];
let resolver = self.owner.resolver(db.upcast());
let core_result_enum = match resolver.resolve_known_enum(db.upcast(), &core_result_path) {
Some(it) => it,
_ => return,
};
let core_option_enum = match resolver.resolve_known_enum(db.upcast(), &core_option_path) {
Some(it) => it,
_ => return,
};
let (params, required) = match mismatch.expected.kind(&Interner) {
TyKind::Adt(AdtId(hir_def::AdtId::EnumId(enum_id)), ref parameters)
if *enum_id == core_result_enum =>
{
(parameters, "Ok".to_string())
}
TyKind::Adt(AdtId(hir_def::AdtId::EnumId(enum_id)), ref parameters)
if *enum_id == core_option_enum =>
{
(parameters, "Some".to_string())
}
_ => return,
};
if params.len(&Interner) > 0
&& params.at(&Interner, 0).ty(&Interner) == Some(&mismatch.actual)
{
self.diagnostics
.push(BodyValidationDiagnostic::MissingOkOrSomeInTailExpr { expr: id, required });
}
}
fn validate_missing_tail_expr(&mut self, body_id: ExprId, possible_tail_id: ExprId) {
let mismatch = match self.infer.type_mismatch_for_expr(body_id) {
Some(m) => m,
None => return,
};
let possible_tail_ty = match self.infer.type_of_expr.get(possible_tail_id) {
Some(ty) => ty,
None => return,
};
if !mismatch.actual.is_unit() || mismatch.expected != *possible_tail_ty {
return;
}
self.diagnostics
.push(BodyValidationDiagnostic::RemoveThisSemicolon { expr: possible_tail_id });
}
}
pub fn record_literal_missing_fields(
db: &dyn HirDatabase,
infer: &InferenceResult,
id: ExprId,
expr: &Expr,
) -> Option<(VariantId, Vec<LocalFieldId>, /*exhaustive*/ bool)> {
let (fields, exhaustive) = match expr {
Expr::RecordLit { path: _, fields, spread } => (fields, spread.is_none()),
_ => return None,
};
let variant_def = infer.variant_resolution_for_expr(id)?;
if let VariantId::UnionId(_) = variant_def {
return None;
}
let variant_data = variant_def.variant_data(db.upcast());
let specified_fields: FxHashSet<_> = fields.iter().map(|f| &f.name).collect();
let missed_fields: Vec<LocalFieldId> = variant_data
.fields()
.iter()
.filter_map(|(f, d)| if specified_fields.contains(&d.name) { None } else { Some(f) })
.collect();
if missed_fields.is_empty() {
return None;
}
Some((variant_def, missed_fields, exhaustive))
}
pub fn record_pattern_missing_fields(
db: &dyn HirDatabase,
infer: &InferenceResult,
id: PatId,
pat: &Pat,
) -> Option<(VariantId, Vec<LocalFieldId>, /*exhaustive*/ bool)> {
let (fields, exhaustive) = match pat {
Pat::Record { path: _, args, ellipsis } => (args, !ellipsis),
_ => return None,
};
let variant_def = infer.variant_resolution_for_pat(id)?;
if let VariantId::UnionId(_) = variant_def {
return None;
}
let variant_data = variant_def.variant_data(db.upcast());
let specified_fields: FxHashSet<_> = fields.iter().map(|f| &f.name).collect();
let missed_fields: Vec<LocalFieldId> = variant_data
.fields()
.iter()
.filter_map(|(f, d)| if specified_fields.contains(&d.name) { None } else { Some(f) })
.collect();
if missed_fields.is_empty() {
return None;
}
Some((variant_def, missed_fields, exhaustive))
}
fn types_of_subpatterns_do_match(pat: PatId, body: &Body, infer: &InferenceResult) -> bool {
fn walk(pat: PatId, body: &Body, infer: &InferenceResult, has_type_mismatches: &mut bool) {
match infer.type_mismatch_for_pat(pat) {
Some(_) => *has_type_mismatches = true,
None => {
body[pat].walk_child_pats(|subpat| walk(subpat, body, infer, has_type_mismatches))
}
}
}
let mut has_type_mismatches = false;
walk(pat, body, infer, &mut has_type_mismatches);
!has_type_mismatches
}
|