use std::collections::{HashMap, HashSet};
use crate::parser::types::{ExecutableDocument, FragmentDefinition, FragmentSpread};
use crate::validation::visitor::{RuleError, Visitor, VisitorContext};
use crate::{Name, Pos, Positioned};
struct CycleDetector<'a> {
visited: HashSet<&'a str>,
spreads: &'a HashMap<&'a str, Vec<(&'a str, Pos)>>,
path_indices: HashMap<&'a str, usize>,
errors: Vec<RuleError>,
}
impl<'a> CycleDetector<'a> {
fn detect_from(&mut self, from: &'a str, path: &mut Vec<(&'a str, Pos)>) {
self.visited.insert(from);
if !self.spreads.contains_key(from) {
return;
}
self.path_indices.insert(from, path.len());
for (name, pos) in &self.spreads[from] {
let index = self.path_indices.get(name).cloned();
if let Some(index) = index {
let err_pos = if index < path.len() {
path[index].1
} else {
*pos
};
self.errors.push(RuleError {
locations: vec![err_pos],
message: format!("Cannot spread fragment \"{}\"", name),
});
} else if !self.visited.contains(name) {
path.push((name, *pos));
self.detect_from(name, path);
path.pop();
}
}
self.path_indices.remove(from);
}
}
#[derive(Default)]
pub struct NoFragmentCycles<'a> {
current_fragment: Option<&'a str>,
spreads: HashMap<&'a str, Vec<(&'a str, Pos)>>,
fragment_order: Vec<&'a str>,
}
impl<'a> Visitor<'a> for NoFragmentCycles<'a> {
fn exit_document(&mut self, ctx: &mut VisitorContext<'a>, _doc: &'a ExecutableDocument) {
let mut detector = CycleDetector {
visited: HashSet::new(),
spreads: &self.spreads,
path_indices: HashMap::new(),
errors: Vec::new(),
};
for frag in &self.fragment_order {
if !detector.visited.contains(frag) {
let mut path = Vec::new();
detector.detect_from(frag, &mut path);
}
}
ctx.append_errors(detector.errors);
}
fn enter_fragment_definition(
&mut self,
_ctx: &mut VisitorContext<'a>,
name: &'a Name,
_fragment_definition: &'a Positioned<FragmentDefinition>,
) {
self.current_fragment = Some(name);
self.fragment_order.push(name);
}
fn exit_fragment_definition(
&mut self,
_ctx: &mut VisitorContext<'a>,
_name: &'a Name,
_fragment_definition: &'a Positioned<FragmentDefinition>,
) {
self.current_fragment = None;
}
fn enter_fragment_spread(
&mut self,
_ctx: &mut VisitorContext<'a>,
fragment_spread: &'a Positioned<FragmentSpread>,
) {
if let Some(current_fragment) = self.current_fragment {
self.spreads
.entry(current_fragment)
.or_insert_with(Vec::new)
.push((
&fragment_spread.node.fragment_name.node,
fragment_spread.pos,
));
}
}
}
#[cfg(test)]
mod tests {
use super::*;
pub fn factory<'a>() -> NoFragmentCycles<'a> {
NoFragmentCycles::default()
}
#[test]
fn single_reference_is_valid() {
expect_passes_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB }
fragment fragB on Dog { name }
{ __typename }
"#,
);
}
#[test]
fn spreading_twice_is_not_circular() {
expect_passes_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB, ...fragB }
fragment fragB on Dog { name }
{ __typename }
"#,
);
}
#[test]
fn spreading_twice_indirectly_is_not_circular() {
expect_passes_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB, ...fragC }
fragment fragB on Dog { ...fragC }
fragment fragC on Dog { name }
{ __typename }
"#,
);
}
#[test]
fn double_spread_within_abstract_types() {
expect_passes_rule!(
factory,
r#"
fragment nameFragment on Pet {
... on Dog { name }
... on Cat { name }
}
fragment spreadsInAnon on Pet {
... on Dog { ...nameFragment }
... on Cat { ...nameFragment }
}
{ __typename }
"#,
);
}
#[test]
fn does_not_false_positive_on_unknown_fragment() {
expect_passes_rule!(
factory,
r#"
fragment nameFragment on Pet {
...UnknownFragment
}
{ __typename }
"#,
);
}
#[test]
fn spreading_recursively_within_field_fails() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Human { relatives { ...fragA } },
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_directly() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragA }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_directly_within_inline_fragment() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Pet {
... on Dog {
...fragA
}
}
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_indirectly() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB }
fragment fragB on Dog { ...fragA }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_indirectly_reports_opposite_order() {
expect_fails_rule!(
factory,
r#"
fragment fragB on Dog { ...fragA }
fragment fragA on Dog { ...fragB }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_indirectly_within_inline_fragment() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Pet {
... on Dog {
...fragB
}
}
fragment fragB on Pet {
... on Dog {
...fragA
}
}
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_deeply() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB }
fragment fragB on Dog { ...fragC }
fragment fragC on Dog { ...fragO }
fragment fragX on Dog { ...fragY }
fragment fragY on Dog { ...fragZ }
fragment fragZ on Dog { ...fragO }
fragment fragO on Dog { ...fragP }
fragment fragP on Dog { ...fragA, ...fragX }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_deeply_two_paths() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB, ...fragC }
fragment fragB on Dog { ...fragA }
fragment fragC on Dog { ...fragA }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_deeply_two_paths_alt_traversal_order() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragC }
fragment fragB on Dog { ...fragC }
fragment fragC on Dog { ...fragA, ...fragB }
{ __typename }
"#,
);
}
#[test]
fn no_spreading_itself_deeply_and_immediately() {
expect_fails_rule!(
factory,
r#"
fragment fragA on Dog { ...fragB }
fragment fragB on Dog { ...fragB, ...fragC }
fragment fragC on Dog { ...fragA, ...fragB }
{ __typename }
"#,
);
}
}