// Copyright 2016 Mozilla // // Licensed under the Apache License, Version 2.0 (the "License"); you may not use // this file except in compliance with the License. You may obtain a copy of the // License at http://www.apache.org/licenses/LICENSE-2.0 // Unless required by applicable law or agreed to in writing, software distributed // under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR // CONDITIONS OF ANY KIND, either express or implied. See the License for the // specific language governing permissions and limitations under the License. extern crate combine; extern crate edn; extern crate mentat_parser_utils; extern crate mentat_query; extern crate mentat_core; use std; // To refer to std::result::Result. use std::collections::BTreeSet; use self::combine::{eof, many, many1, optional, parser, satisfy, satisfy_map, Parser, ParseResult, Stream}; use self::combine::combinator::{any, choice, or, try}; use self::mentat_core::ValueType; use self::mentat_parser_utils::{ KeywordMapParser, ResultParser, ValueParseError, }; use self::mentat_parser_utils::value_and_span::Stream as ValueStream; use self::mentat_parser_utils::value_and_span::{ Item, OfExactlyParsing, keyword_map, list, map, seq, vector, }; use self::mentat_query::{ Binding, Direction, Element, FindQuery, FindSpec, FnArg, FromValue, Limit, Order, OrJoin, OrWhereClause, NotJoin, Pattern, PatternNonValuePlace, PatternValuePlace, Predicate, QueryFunction, SrcVar, TypeAnnotation, UnifyVars, Variable, VariableOrPlaceholder, WhereClause, WhereFn, }; error_chain! { types { Error, ErrorKind, ResultExt, Result; } foreign_links { EdnParseError(edn::parse::ParseError); } errors { DuplicateVariableError { description("duplicate variable") display("duplicates in variable list") } NotAVariableError(value: edn::ValueAndSpan) { description("not a variable") display("not a variable: '{}'", value) } FindParseError(e: ValueParseError) { description(":find parse error") display(":find parse error") } WhereParseError(e: ValueParseError) { description(":where parse error") display(":where parse error") } // Not yet used. WithParseError { description(":with parse error") display(":with parse error") } InvalidInputError(value: edn::Value) { description("invalid input") display("invalid input: '{}'", value) } MissingFieldError(value: edn::Keyword) { description("missing field") display("missing field: '{}'", value) } UnknownLimitVar(var: edn::PlainSymbol) { description("limit var not present in :in") display("limit var {} not present in :in", var) } InvalidLimit(val: edn::Value) { description("limit value not valid") display("expected natural number, got {}", val) } } } pub struct Query<'a>(std::marker::PhantomData<&'a ()>); def_parser!(Query, variable, Variable, { satisfy_map(Variable::from_value) }); def_parser!(Query, source_var, SrcVar, { satisfy_map(SrcVar::from_value) }); // TODO: interning. def_parser!(Query, query_function, QueryFunction, { satisfy_map(QueryFunction::from_value) }); def_parser!(Query, fn_arg, FnArg, { satisfy_map(FnArg::from_value).or(vector().of_exactly(many::, _>(Query::fn_arg())).map(FnArg::Vector)) }); def_parser!(Query, arguments, Vec, { (many::, _>(Query::fn_arg())) }); def_parser!(Query, direction, Direction, { satisfy_map(|v: &edn::ValueAndSpan| { match v.inner { edn::SpannedValue::PlainSymbol(ref s) => { let name = s.0.as_str(); match name { "asc" => Some(Direction::Ascending), "desc" => Some(Direction::Descending), _ => None, } }, _ => None, } }) }); def_parser!(Query, order, Order, { seq().of_exactly((Query::direction(), Query::variable())) .map(|(d, v)| Order(d, v)) .or(Query::variable().map(|v| Order(Direction::Ascending, v))) }); pub struct Where<'a>(std::marker::PhantomData<&'a ()>); def_parser!(Where, pattern_value_place, PatternValuePlace, { satisfy_map(PatternValuePlace::from_value) }); def_parser!(Query, natural_number, u64, { any().and_then(|v: &edn::ValueAndSpan| { match v.inner { edn::SpannedValue::Integer(x) if (x > 0) => { Ok(x as u64) }, ref spanned => { let e = Box::new(Error::from_kind(ErrorKind::InvalidLimit(spanned.clone().into()))); Err(combine::primitives::Error::Other(e)) }, } }) }); def_parser!(Where, pattern_non_value_place, PatternNonValuePlace, { satisfy_map(PatternNonValuePlace::from_value) }); def_matches_plain_symbol!(Where, and, "and"); def_matches_plain_symbol!(Where, or, "or"); def_matches_plain_symbol!(Where, or_join, "or-join"); def_matches_plain_symbol!(Where, not, "not"); def_matches_plain_symbol!(Where, not_join, "not-join"); def_parser!(Where, rule_vars, BTreeSet, { seq() .of_exactly(many1(Query::variable()).and_then(unique_vars)) }); def_parser!(Where, or_pattern_clause, OrWhereClause, { Where::clause().map(|clause| OrWhereClause::Clause(clause)) }); def_parser!(Where, or_and_clause, OrWhereClause, { seq() .of_exactly(Where::and() .with(many1(Where::clause())) .map(OrWhereClause::And)) }); def_parser!(Where, or_where_clause, OrWhereClause, { choice([Where::or_pattern_clause(), Where::or_and_clause()]) }); def_parser!(Where, or_clause, WhereClause, { seq() .of_exactly(Where::or() .with(many1(Where::or_where_clause())) .map(|clauses| { WhereClause::OrJoin(OrJoin::new(UnifyVars::Implicit, clauses)) })) }); def_parser!(Where, or_join_clause, WhereClause, { seq() .of_exactly(Where::or_join() .with(Where::rule_vars()) .and(many1(Where::or_where_clause())) .map(|(vars, clauses)| { WhereClause::OrJoin(OrJoin::new(UnifyVars::Explicit(vars), clauses)) })) }); def_parser!(Where, not_clause, WhereClause, { seq() .of_exactly(Where::not() .with(many1(Where::clause())) .map(|clauses| { WhereClause::NotJoin( NotJoin { unify_vars: UnifyVars::Implicit, clauses: clauses, }) })) }); def_parser!(Where, not_join_clause, WhereClause, { seq() .of_exactly(Where::not_join() .with(Where::rule_vars()) .and(many1(Where::clause())) .map(|(vars, clauses)| { WhereClause::NotJoin( NotJoin { unify_vars: UnifyVars::Explicit(vars), clauses: clauses, }) })) }); def_parser!(Query, func, (QueryFunction, Vec), { (Query::query_function(), Query::arguments()) }); /// A vector containing just a parenthesized filter expression. def_parser!(Where, pred, WhereClause, { // Accept either a nested list or a nested vector here: // `[(foo ?x ?y)]` or `[[foo ?x ?y]]` vector() .of_exactly(seq() .of_exactly(Query::func() .map(|(f, args)| { WhereClause::Pred( Predicate { operator: f.0, args: args, }) }))) }); def_parser!(Query, type_anno_type, ValueType, { satisfy_map(|v: &edn::ValueAndSpan| { match v.inner { edn::SpannedValue::PlainSymbol(ref s) => { let name = s.0.as_str(); match name { "ref" => Some(ValueType::Ref), "boolean" => Some(ValueType::Boolean), "instant" => Some(ValueType::Instant), "long" => Some(ValueType::Long), "double" => Some(ValueType::Double), "string" => Some(ValueType::String), "keyword" => Some(ValueType::Keyword), "uuid" => Some(ValueType::Uuid), _ => None } }, _ => None, } }) }); /// A type annotation. def_parser!(Where, type_annotation, WhereClause, { // Accept either a nested list or a nested vector here: // `[(string ?x)]` or `[[string ?x]]` vector() .of_exactly(seq() .of_exactly((Query::type_anno_type(), Query::variable()) .map(|(ty, var)| { WhereClause::TypeAnnotation( TypeAnnotation { value_type: ty, variable: var, }) }))) }); /// A vector containing a parenthesized function expression and a binding. def_parser!(Where, where_fn, WhereClause, { // Accept either a nested list or a nested vector here: // `[(foo ?x ?y) binding]` or `[[foo ?x ?y] binding]` vector() .of_exactly( (seq().of_exactly( Query::func()), Bind::binding()) .map(|((f, args), binding)| { WhereClause::WhereFn( WhereFn { operator: f.0, args: args, binding: binding, }) })) }); def_parser!(Where, pattern, WhereClause, { vector() .of_exactly( // While *technically* Datomic allows you to have a query like: // [:find … :where [[?x]]] // We don't -- we require at least e, a. (optional(Query::source_var()), // src Where::pattern_non_value_place(), // e Where::pattern_non_value_place(), // a optional(Where::pattern_value_place()), // v optional(Where::pattern_non_value_place())) // tx .and_then(|(src, e, a, v, tx)| { let v = v.unwrap_or(PatternValuePlace::Placeholder); let tx = tx.unwrap_or(PatternNonValuePlace::Placeholder); // Pattern::new takes care of reversal of reversed // attributes: [?x :foo/_bar ?y] turns into // [?y :foo/bar ?x]. // // This is a bit messy: the inner conversion to a Pattern can // fail if the input is something like // // ```edn // [?x :foo/_reversed 23.4] // ``` // // because // // ```edn // [23.4 :foo/reversed ?x] // ``` // // is nonsense. That leaves us with a nested optional, which we unwrap here. Pattern::new(src, e, a, v, tx) .map(WhereClause::Pattern) .ok_or(combine::primitives::Error::Expected("pattern".into())) })) }); def_parser!(Where, clause, WhereClause, { choice([try(Where::pattern()), // It's either // (or-join [vars] clauses…) // or // (or clauses…) // We don't yet handle source vars. try(Where::or_join_clause()), try(Where::or_clause()), try(Where::not_join_clause()), try(Where::not_clause()), try(Where::type_annotation()), try(Where::pred()), try(Where::where_fn()), ]) }); def_parser!(Where, clauses, Vec, { // Right now we only support patterns and predicates. See #239 for more. (many1::, _>(Where::clause())) }); pub struct Find<'a>(std::marker::PhantomData<&'a ()>); def_matches_plain_symbol!(Find, period, "."); def_matches_plain_symbol!(Find, ellipsis, "..."); def_matches_plain_symbol!(Find, placeholder, "_"); def_parser!(Find, elem, Element, { Query::variable().map(Element::Variable) }); def_parser!(Find, find_scalar, FindSpec, { Find::elem().skip(Find::period()) .map(FindSpec::FindScalar) }); def_parser!(Find, find_coll, FindSpec, { vector().of_exactly(Find::elem().skip(Find::ellipsis())) .map(FindSpec::FindColl) }); def_parser!(Find, elements, Vec, { many1::, _>(Find::elem()) }); def_parser!(Find, find_rel, FindSpec, { Find::elements().map(FindSpec::FindRel) }); def_parser!(Find, find_tuple, FindSpec, { vector().of_exactly(Find::elements()) .map(FindSpec::FindTuple) }); /// Parse a stream of values into one of four find specs. /// /// `:find` must be an array of plain var symbols (?foo), pull expressions, and aggregates. For now /// we only support variables and the annotations necessary to declare which flavor of :find we /// want: /// /// /// `?x ?y ?z ` = FindRel /// `[?x ...] ` = FindColl /// `?x . ` = FindScalar /// `[?x ?y ?z]` = FindTuple def_parser!(Find, spec, FindSpec, { // Any one of the four specs might apply, so we combine them with `choice`. Our parsers consume // input, so we need to wrap them in `try` so that they operate independently. choice::<[&mut Parser; 4], _> ([&mut try(Find::find_scalar()), &mut try(Find::find_coll()), &mut try(Find::find_tuple()), &mut try(Find::find_rel())]) }); fn unique_vars(vars: Vec) -> std::result::Result, combine::primitives::Error> { let given = vars.len(); let set: BTreeSet = vars.into_iter().collect(); if given != set.len() { // TODO: find out what the variable is! let e = Box::new(Error::from_kind(ErrorKind::DuplicateVariableError)); Err(combine::primitives::Error::Other(e)) } else { Ok(set) } } def_parser!(Find, vars, BTreeSet, { many(Query::variable()).and_then(unique_vars) }); /// This is awkward, but will do for now. We use `keyword_map()` to optionally accept vector find /// queries, then we use `FindQueryPart` to collect parts that have heterogeneous types; and then we /// construct a `FindQuery` from them. def_parser!(Find, query, FindQuery, { let find_map = keyword_map_of!( ("find", Find::spec()), ("in", Find::vars()), ("limit", Query::variable().map(Limit::Variable).or(Query::natural_number().map(Limit::Fixed))), ("order", many1(Query::order())), ("where", Where::clauses()), ("with", Find::vars()) // Note: no trailing comma allowed! ); (or(keyword_map(), vector())) .of_exactly(find_map) .and_then(|(find_spec, in_vars, limit, order_clauses, where_clauses, with_vars) | -> std::result::Result> { let limit = limit.unwrap_or(Limit::None); // Make sure that if we have `:limit ?x`, `?x` appears in `:in`. let in_vars = in_vars.unwrap_or(BTreeSet::default()); if let Limit::Variable(ref v) = limit { if !in_vars.contains(v) { let e = Box::new(Error::from_kind(ErrorKind::UnknownLimitVar(v.name()))); return Err(combine::primitives::Error::Other(e)); } } Ok(FindQuery { default_source: SrcVar::DefaultSrc, find_spec: find_spec.ok_or(combine::primitives::Error::Unexpected("expected :find".into()))?, in_sources: BTreeSet::default(), // TODO in_vars: in_vars, limit: limit, order: order_clauses, where_clauses: where_clauses.ok_or(combine::primitives::Error::Unexpected("expected :where".into()))?, with: with_vars.unwrap_or(BTreeSet::default()), }) }) }); pub struct Bind<'a>(std::marker::PhantomData<&'a ()>); def_parser!(Bind, bind_scalar, Binding, { Query::variable() .skip(eof()) .map(|var| Binding::BindScalar(var)) }); def_parser!(Bind, variable_or_placeholder, VariableOrPlaceholder, { Query::variable().map(VariableOrPlaceholder::Variable) .or(Find::placeholder().map(|_| VariableOrPlaceholder::Placeholder)) }); def_parser!(Bind, bind_coll, Binding, { vector() .of_exactly(Query::variable() .skip(Find::ellipsis())) .map(Binding::BindColl) }); def_parser!(Bind, bind_rel, Binding, { vector().of_exactly( vector().of_exactly( many1::, _>(Bind::variable_or_placeholder()) .map(Binding::BindRel))) }); def_parser!(Bind, bind_tuple, Binding, { vector().of_exactly( many1::, _>(Bind::variable_or_placeholder()) .map(Binding::BindTuple)) }); def_parser!(Bind, binding, Binding, { // Any one of the four binding types might apply, so we combine them with `choice`. Our parsers // consume input, so we need to wrap them in `try` so that they operate independently. choice([try(Bind::bind_scalar()), try(Bind::bind_coll()), try(Bind::bind_tuple()), try(Bind::bind_rel())]) }); pub fn parse_find_string(string: &str) -> Result { let expr = edn::parse::value(string)?; Find::query() .parse(expr.atom_stream()) .map(|x| x.0) .map_err(|e| Error::from_kind(ErrorKind::FindParseError(e.into()))) } #[cfg(test)] mod test { extern crate combine; extern crate edn; extern crate mentat_query; use std::rc::Rc; use self::combine::Parser; use self::edn::OrderedFloat; use self::mentat_query::{ Binding, Element, FindSpec, NonIntegerConstant, Pattern, PatternNonValuePlace, PatternValuePlace, SrcVar, Variable, VariableOrPlaceholder, }; use super::*; fn variable(x: edn::PlainSymbol) -> Variable { Variable(Rc::new(x)) } fn ident_kw(kw: edn::NamespacedKeyword) -> PatternNonValuePlace { PatternNonValuePlace::Ident(Rc::new(kw)) } fn ident(ns: &str, name: &str) -> PatternNonValuePlace { ident_kw(edn::NamespacedKeyword::new(ns, name)) } #[test] fn test_pattern_mixed() { let e = edn::PlainSymbol::new("_"); let a = edn::NamespacedKeyword::new("foo", "bar"); let v = OrderedFloat(99.9); let tx = edn::PlainSymbol::new("?tx"); let input = edn::Value::Vector(vec!(edn::Value::PlainSymbol(e.clone()), edn::Value::NamespacedKeyword(a.clone()), edn::Value::Float(v.clone()), edn::Value::PlainSymbol(tx.clone()))); assert_parses_to!(Where::pattern, input, WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Placeholder, attribute: ident_kw(a), value: PatternValuePlace::Constant(NonIntegerConstant::Float(v)), tx: PatternNonValuePlace::Variable(variable(tx)), })); } #[test] fn test_pattern_vars() { let s = edn::PlainSymbol::new("$x"); let e = edn::PlainSymbol::new("?e"); let a = edn::PlainSymbol::new("?a"); let v = edn::PlainSymbol::new("?v"); let tx = edn::PlainSymbol::new("?tx"); let input = edn::Value::Vector(vec!(edn::Value::PlainSymbol(s.clone()), edn::Value::PlainSymbol(e.clone()), edn::Value::PlainSymbol(a.clone()), edn::Value::PlainSymbol(v.clone()), edn::Value::PlainSymbol(tx.clone()))); assert_parses_to!(Where::pattern, input, WhereClause::Pattern(Pattern { source: Some(SrcVar::NamedSrc("x".to_string())), entity: PatternNonValuePlace::Variable(variable(e)), attribute: PatternNonValuePlace::Variable(variable(a)), value: PatternValuePlace::Variable(variable(v)), tx: PatternNonValuePlace::Variable(variable(tx)), })); } #[test] fn test_pattern_reversed_invalid() { let e = edn::PlainSymbol::new("_"); let a = edn::NamespacedKeyword::new("foo", "_bar"); let v = OrderedFloat(99.9); let tx = edn::PlainSymbol::new("?tx"); let input = edn::Value::Vector(vec!(edn::Value::PlainSymbol(e.clone()), edn::Value::NamespacedKeyword(a.clone()), edn::Value::Float(v.clone()), edn::Value::PlainSymbol(tx.clone()))); let input = input.with_spans(); let mut par = Where::pattern(); let result = par.parse(input.atom_stream()); assert!(matches!(result, Err(_)), "Expected a parse error."); } #[test] fn test_pattern_reversed() { let e = edn::PlainSymbol::new("_"); let a = edn::NamespacedKeyword::new("foo", "_bar"); let v = edn::PlainSymbol::new("?v"); let tx = edn::PlainSymbol::new("?tx"); let input = edn::Value::Vector(vec!(edn::Value::PlainSymbol(e.clone()), edn::Value::NamespacedKeyword(a.clone()), edn::Value::PlainSymbol(v.clone()), edn::Value::PlainSymbol(tx.clone()))); // Note that the attribute is no longer reversed, and the entity and value have // switched places. assert_parses_to!(Where::pattern, input, WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Variable(variable(v)), attribute: ident("foo", "bar"), value: PatternValuePlace::Placeholder, tx: PatternNonValuePlace::Variable(variable(tx)), })); } #[test] fn test_rule_vars() { let e = edn::PlainSymbol::new("?e"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(e.clone())]); assert_parses_to!(Where::rule_vars, input, btreeset!{variable(e.clone())}); } #[test] fn test_repeated_vars() { let e = edn::PlainSymbol::new("?e"); let f = edn::PlainSymbol::new("?f"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(e.clone()), edn::Value::PlainSymbol(f.clone()),]); assert_parses_to!(|| vector().of_exactly(Find::vars()), input, btreeset!{variable(e.clone()), variable(f.clone())}); let g = edn::PlainSymbol::new("?g"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(g.clone()), edn::Value::PlainSymbol(g.clone()),]); let input = input.with_spans(); let mut par = vector().of_exactly(Find::vars()); let result = par.parse(input.atom_stream()) .map(|x| x.0) .map_err(|e| if let Some(combine::primitives::Error::Other(x)) = e.errors.into_iter().next() { // Pattern matching on boxes is rocket science until Rust Nightly features hit // stable. ErrorKind isn't Clone, so convert to strings. We could pattern match // for exact comparison here. x.downcast::().ok().map(|e| e.to_string()) } else { None }); assert_eq!(result, Err(Some("duplicates in variable list".to_string()))); } #[test] fn test_or() { let oj = edn::PlainSymbol::new("or"); let e = edn::PlainSymbol::new("?e"); let a = edn::PlainSymbol::new("?a"); let v = edn::PlainSymbol::new("?v"); let input = edn::Value::List( vec![edn::Value::PlainSymbol(oj), edn::Value::Vector(vec![edn::Value::PlainSymbol(e.clone()), edn::Value::PlainSymbol(a.clone()), edn::Value::PlainSymbol(v.clone())])].into_iter().collect()); assert_parses_to!(Where::or_clause, input, WhereClause::OrJoin( OrJoin::new(UnifyVars::Implicit, vec![OrWhereClause::Clause( WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Variable(variable(e)), attribute: PatternNonValuePlace::Variable(variable(a)), value: PatternValuePlace::Variable(variable(v)), tx: PatternNonValuePlace::Placeholder, }))]))); } #[test] fn test_or_join() { let oj = edn::PlainSymbol::new("or-join"); let e = edn::PlainSymbol::new("?e"); let a = edn::PlainSymbol::new("?a"); let v = edn::PlainSymbol::new("?v"); let input = edn::Value::List( vec![edn::Value::PlainSymbol(oj), edn::Value::Vector(vec![edn::Value::PlainSymbol(e.clone())]), edn::Value::Vector(vec![edn::Value::PlainSymbol(e.clone()), edn::Value::PlainSymbol(a.clone()), edn::Value::PlainSymbol(v.clone())])].into_iter().collect()); assert_parses_to!(Where::or_join_clause, input, WhereClause::OrJoin( OrJoin::new(UnifyVars::Explicit(btreeset!{variable(e.clone())}), vec![OrWhereClause::Clause( WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Variable(variable(e)), attribute: PatternNonValuePlace::Variable(variable(a)), value: PatternValuePlace::Variable(variable(v)), tx: PatternNonValuePlace::Placeholder, }))]))); } #[test] fn test_not() { let e = edn::PlainSymbol::new("?e"); let a = edn::PlainSymbol::new("?a"); let v = edn::PlainSymbol::new("?v"); assert_edn_parses_to!(Where::not_clause, "(not [?e ?a ?v])", WhereClause::NotJoin( NotJoin { unify_vars: UnifyVars::Implicit, clauses: vec![ WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Variable(variable(e)), attribute: PatternNonValuePlace::Variable(variable(a)), value: PatternValuePlace::Variable(variable(v)), tx: PatternNonValuePlace::Placeholder, })], })); } #[test] fn test_not_join() { let e = edn::PlainSymbol::new("?e"); let a = edn::PlainSymbol::new("?a"); let v = edn::PlainSymbol::new("?v"); assert_edn_parses_to!(Where::not_join_clause, "(not-join [?e] [?e ?a ?v])", WhereClause::NotJoin( NotJoin { unify_vars: UnifyVars::Explicit(btreeset!{variable(e.clone())}), clauses: vec![WhereClause::Pattern(Pattern { source: None, entity: PatternNonValuePlace::Variable(variable(e)), attribute: PatternNonValuePlace::Variable(variable(a)), value: PatternValuePlace::Variable(variable(v)), tx: PatternNonValuePlace::Placeholder, })], })); } #[test] fn test_find_sp_variable() { let sym = edn::PlainSymbol::new("?x"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(sym.clone())]); assert_parses_to!(|| vector().of_exactly(Query::variable()), input, variable(sym)); } #[test] fn test_find_scalar() { let sym = edn::PlainSymbol::new("?x"); let period = edn::PlainSymbol::new("."); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(sym.clone()), edn::Value::PlainSymbol(period.clone())]); assert_parses_to!(|| vector().of_exactly(Find::find_scalar()), input, FindSpec::FindScalar(Element::Variable(variable(sym)))); } #[test] fn test_find_coll() { let sym = edn::PlainSymbol::new("?x"); let period = edn::PlainSymbol::new("..."); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(sym.clone()), edn::Value::PlainSymbol(period.clone())]); assert_parses_to!(Find::find_coll, input, FindSpec::FindColl(Element::Variable(variable(sym)))); } #[test] fn test_find_rel() { let vx = edn::PlainSymbol::new("?x"); let vy = edn::PlainSymbol::new("?y"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(vx.clone()), edn::Value::PlainSymbol(vy.clone())]); assert_parses_to!(|| vector().of_exactly(Find::find_rel()), input, FindSpec::FindRel(vec![Element::Variable(variable(vx)), Element::Variable(variable(vy))])); } #[test] fn test_find_tuple() { let vx = edn::PlainSymbol::new("?x"); let vy = edn::PlainSymbol::new("?y"); let input = edn::Value::Vector(vec![edn::Value::PlainSymbol(vx.clone()), edn::Value::PlainSymbol(vy.clone())]); assert_parses_to!(Find::find_tuple, input, FindSpec::FindTuple(vec![Element::Variable(variable(vx)), Element::Variable(variable(vy))])); } #[test] fn test_natural_numbers() { let text = edn::Value::Text("foo".to_string()); let neg = edn::Value::Integer(-10); let zero = edn::Value::Integer(0); let pos = edn::Value::Integer(5); // This is terrible, but destructuring errors is frustrating. let input = text.with_spans(); let mut par = Query::natural_number(); let x = par.parse(input.atom_stream()).err().expect("an error").errors; let result = format!("{:?}", x); assert_eq!(result, "[Other(Error(InvalidLimit(Text(\"foo\")), State { next_error: None, backtrace: None }))]"); let input = neg.with_spans(); let mut par = Query::natural_number(); let x = par.parse(input.atom_stream()).err().expect("an error").errors; let result = format!("{:?}", x); assert_eq!(result, "[Other(Error(InvalidLimit(Integer(-10)), State { next_error: None, backtrace: None }))]"); let input = zero.with_spans(); let mut par = Query::natural_number(); let x = par.parse(input.atom_stream()).err().expect("an error").errors; let result = format!("{:?}", x); assert_eq!(result, "[Other(Error(InvalidLimit(Integer(0)), State { next_error: None, backtrace: None }))]"); let input = pos.with_spans(); let mut par = Query::natural_number(); assert_eq!(None, par.parse(input.atom_stream()).err()); } #[test] fn test_fn_arg_collections() { let vx = edn::PlainSymbol::new("?x"); let vy = edn::PlainSymbol::new("?y"); let input = edn::Value::Vector(vec![edn::Value::Vector(vec![edn::Value::PlainSymbol(vx.clone()), edn::Value::PlainSymbol(vy.clone())])]); assert_parses_to!(|| vector().of_exactly(Query::fn_arg()), input, FnArg::Vector(vec![FnArg::Variable(variable(vx)), FnArg::Variable(variable(vy)), ])); } #[test] fn test_bind_scalar() { let vx = edn::PlainSymbol::new("?x"); assert_edn_parses_to!(|| list().of_exactly(Bind::binding()), "(?x)", Binding::BindScalar(variable(vx))); } #[test] fn test_bind_coll() { let vx = edn::PlainSymbol::new("?x"); assert_edn_parses_to!(|| list().of_exactly(Bind::binding()), "([?x ...])", Binding::BindColl(variable(vx))); } #[test] fn test_bind_rel() { let vx = edn::PlainSymbol::new("?x"); let vy = edn::PlainSymbol::new("?y"); let vw = edn::PlainSymbol::new("?w"); assert_edn_parses_to!(|| list().of_exactly(Bind::binding()), "([[?x ?y _ ?w]])", Binding::BindRel(vec![VariableOrPlaceholder::Variable(variable(vx)), VariableOrPlaceholder::Variable(variable(vy)), VariableOrPlaceholder::Placeholder, VariableOrPlaceholder::Variable(variable(vw)), ])); } #[test] fn test_bind_tuple() { let vx = edn::PlainSymbol::new("?x"); let vy = edn::PlainSymbol::new("?y"); let vw = edn::PlainSymbol::new("?w"); assert_edn_parses_to!(|| list().of_exactly(Bind::binding()), "([?x ?y _ ?w])", Binding::BindTuple(vec![VariableOrPlaceholder::Variable(variable(vx)), VariableOrPlaceholder::Variable(variable(vy)), VariableOrPlaceholder::Placeholder, VariableOrPlaceholder::Variable(variable(vw)), ])); } #[test] fn test_where_fn() { assert_edn_parses_to!(Where::where_fn, "[(f ?x 1) ?y]", WhereClause::WhereFn(WhereFn { operator: edn::PlainSymbol::new("f"), args: vec![FnArg::Variable(Variable::from_valid_name("?x")), FnArg::EntidOrInteger(1)], binding: Binding::BindScalar(Variable::from_valid_name("?y")), })); assert_edn_parses_to!(Where::where_fn, "[(f ?x) [?y ...]]", WhereClause::WhereFn(WhereFn { operator: edn::PlainSymbol::new("f"), args: vec![FnArg::Variable(Variable::from_valid_name("?x"))], binding: Binding::BindColl(Variable::from_valid_name("?y")), })); assert_edn_parses_to!(Where::where_fn, "[(f) [?y _]]", WhereClause::WhereFn(WhereFn { operator: edn::PlainSymbol::new("f"), args: vec![], binding: Binding::BindTuple(vec![VariableOrPlaceholder::Variable(Variable::from_valid_name("?y")), VariableOrPlaceholder::Placeholder]), })); assert_edn_parses_to!(Where::where_fn, "[(f) [[_ ?y]]]", WhereClause::WhereFn(WhereFn { operator: edn::PlainSymbol::new("f"), args: vec![], binding: Binding::BindRel(vec![VariableOrPlaceholder::Placeholder, VariableOrPlaceholder::Variable(Variable::from_valid_name("?y"))]), })); } #[test] fn test_type_anno() { assert_edn_parses_to!(Where::type_annotation, "[(string ?x)]", WhereClause::TypeAnnotation(TypeAnnotation { value_type: ValueType::String, variable: Variable::from_valid_name("?x"), })); assert_edn_parses_to!(Where::clause, "[[long ?foo]]", WhereClause::TypeAnnotation(TypeAnnotation { value_type: ValueType::Long, variable: Variable::from_valid_name("?foo"), })); } }