// 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. ///! This module defines some core types that support find expressions: sources, ///! variables, expressions, etc. ///! These are produced as 'fuel' by the query parser, consumed by the query ///! translator and executor. ///! ///! Many of these types are defined as simple structs that are little more than ///! a richer type alias: a variable, for example, is really just a fancy kind ///! of string. ///! ///! At some point in the future, we might consider reducing copying and memory ///! usage by recasting all of these string-holding structs and enums in terms ///! of string references, with those references being slices of some parsed ///! input query string, and valid for the lifetime of that string. ///! ///! For now, for the sake of simplicity, all of these strings are heap-allocated. ///! ///! Furthermore, we might cut out some of the chaff here: each time a 'tagged' ///! type is used within an enum, we have an opportunity to simplify and use the ///! inner type directly in conjunction with matching on the enum. Before diving ///! deeply into this it's worth recognizing that this loss of 'sovereignty' is ///! a tradeoff against well-typed function signatures and other such boundaries. extern crate edn; extern crate mentat_core; use std::collections::{ BTreeSet, HashSet, }; use std::fmt; use std::rc::Rc; use edn::{ BigInt, DateTime, OrderedFloat, Uuid, Utc, }; pub use edn::{ NamespacedKeyword, PlainSymbol, }; use mentat_core::{ TypedValue, ValueType, }; pub type SrcVarName = String; // Do not include the required syntactic '$'. #[derive(Clone, PartialEq, Eq, Hash, PartialOrd, Ord)] pub struct Variable(pub Rc); impl Variable { pub fn as_str(&self) -> &str { self.0.as_ref().0.as_str() } pub fn to_string(&self) -> String { self.0.as_ref().0.clone() } pub fn name(&self) -> PlainSymbol { self.0.as_ref().clone() } /// Return a new `Variable`, assuming that the provided string is a valid name. pub fn from_valid_name(name: &str) -> Variable { let s = PlainSymbol::new(name); assert!(s.is_var_symbol()); Variable(Rc::new(s)) } } pub trait FromValue { fn from_value(v: &edn::ValueAndSpan) -> Option; } /// If the provided EDN value is a PlainSymbol beginning with '?', return /// it wrapped in a Variable. If not, return None. /// TODO: intern strings. #398. impl FromValue for Variable { fn from_value(v: &edn::ValueAndSpan) -> Option { if let edn::SpannedValue::PlainSymbol(ref s) = v.inner { Variable::from_symbol(s) } else { None } } } impl Variable { pub fn from_rc(sym: Rc) -> Option { if sym.is_var_symbol() { Some(Variable(sym.clone())) } else { None } } /// TODO: intern strings. #398. pub fn from_symbol(sym: &PlainSymbol) -> Option { if sym.is_var_symbol() { Some(Variable(Rc::new(sym.clone()))) } else { None } } } impl fmt::Debug for Variable { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "var({})", self.0) } } impl std::fmt::Display for Variable { fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result { write!(f, "{}", self.0) } } #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord)] pub struct QueryFunction(pub PlainSymbol); impl FromValue for QueryFunction { fn from_value(v: &edn::ValueAndSpan) -> Option { if let edn::SpannedValue::PlainSymbol(ref s) = v.inner { QueryFunction::from_symbol(s) } else { None } } } impl QueryFunction { pub fn from_symbol(sym: &PlainSymbol) -> Option { // TODO: validate the acceptable set of function names. Some(QueryFunction(sym.clone())) } } impl std::fmt::Display for QueryFunction { fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result { write!(f, "{}", self.0) } } #[derive(Clone, Debug, Eq, PartialEq)] pub enum Direction { Ascending, Descending, } /// An abstract declaration of ordering: direction and variable. #[derive(Clone, Debug, Eq, PartialEq)] pub struct Order(pub Direction, pub Variable); // Future: Element instead of Variable? #[derive(Clone, Debug, PartialEq, Eq, PartialOrd, Ord)] pub enum SrcVar { DefaultSrc, NamedSrc(SrcVarName), } impl FromValue for SrcVar { fn from_value(v: &edn::ValueAndSpan) -> Option { if let edn::SpannedValue::PlainSymbol(ref s) = v.inner { SrcVar::from_symbol(s) } else { None } } } impl SrcVar { pub fn from_symbol(sym: &PlainSymbol) -> Option { if sym.is_src_symbol() { if sym.0 == "$" { Some(SrcVar::DefaultSrc) } else { Some(SrcVar::NamedSrc(sym.plain_name().to_string())) } } else { None } } } /// These are the scalar values representable in EDN. #[derive(Clone, Debug, Eq, PartialEq)] pub enum NonIntegerConstant { Boolean(bool), BigInteger(BigInt), Float(OrderedFloat), Text(Rc), Instant(DateTime), Uuid(Uuid), } impl NonIntegerConstant { pub fn into_typed_value(self) -> TypedValue { match self { NonIntegerConstant::BigInteger(_) => unimplemented!(), // TODO: #280. NonIntegerConstant::Boolean(v) => TypedValue::Boolean(v), NonIntegerConstant::Float(v) => TypedValue::Double(v), NonIntegerConstant::Text(v) => TypedValue::String(v), NonIntegerConstant::Instant(v) => TypedValue::Instant(v), NonIntegerConstant::Uuid(v) => TypedValue::Uuid(v), } } } #[derive(Clone, Debug, Eq, PartialEq)] pub enum FnArg { Variable(Variable), SrcVar(SrcVar), EntidOrInteger(i64), IdentOrKeyword(NamespacedKeyword), Constant(NonIntegerConstant), // The collection values representable in EDN. There's no advantage to destructuring up front, // since consumers will need to handle arbitrarily nested EDN themselves anyway. Vector(Vec), } impl FromValue for FnArg { fn from_value(v: &edn::ValueAndSpan) -> Option { use edn::SpannedValue::*; match v.inner { Integer(x) => Some(FnArg::EntidOrInteger(x)), PlainSymbol(ref x) if x.is_src_symbol() => SrcVar::from_symbol(x).map(FnArg::SrcVar), PlainSymbol(ref x) if x.is_var_symbol() => Variable::from_symbol(x).map(FnArg::Variable), PlainSymbol(_) => None, NamespacedKeyword(ref x) => Some(FnArg::IdentOrKeyword(x.clone())), Instant(x) => Some(FnArg::Constant(NonIntegerConstant::Instant(x))), Uuid(x) => Some(FnArg::Constant(NonIntegerConstant::Uuid(x))), Boolean(x) => Some(FnArg::Constant(NonIntegerConstant::Boolean(x))), Float(x) => Some(FnArg::Constant(NonIntegerConstant::Float(x))), BigInteger(ref x) => Some(FnArg::Constant(NonIntegerConstant::BigInteger(x.clone()))), Text(ref x) => // TODO: intern strings. #398. Some(FnArg::Constant(NonIntegerConstant::Text(Rc::new(x.clone())))), Nil | NamespacedSymbol(_) | Keyword(_) | Vector(_) | List(_) | Set(_) | Map(_) => None, } } } // For display in column headings in the repl. impl std::fmt::Display for FnArg { fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result { match self { &FnArg::Variable(ref var) => write!(f, "{}", var), &FnArg::SrcVar(ref var) => { if var == &SrcVar::DefaultSrc { write!(f, "$") } else { write!(f, "{:?}", var) } }, &FnArg::EntidOrInteger(entid) => write!(f, "{}", entid), &FnArg::IdentOrKeyword(ref kw) => write!(f, "{}", kw), &FnArg::Constant(ref constant) => write!(f, "{:?}", constant), &FnArg::Vector(ref vec) => write!(f, "{:?}", vec), } } } impl FnArg { pub fn as_variable(&self) -> Option<&Variable> { match self { &FnArg::Variable(ref v) => Some(v), _ => None, } } } /// e, a, tx can't be values -- no strings, no floats -- and so /// they can only be variables, entity IDs, ident keywords, or /// placeholders. /// This encoding allows us to represent integers that aren't /// entity IDs. That'll get filtered out in the context of the /// database. #[derive(Clone, Debug, Eq, PartialEq)] pub enum PatternNonValuePlace { Placeholder, Variable(Variable), Entid(i64), // Will always be +ve. See #190. Ident(Rc), } impl PatternNonValuePlace { // I think we'll want move variants, so let's leave these here for now. #[allow(dead_code)] fn into_pattern_value_place(self) -> PatternValuePlace { match self { PatternNonValuePlace::Placeholder => PatternValuePlace::Placeholder, PatternNonValuePlace::Variable(x) => PatternValuePlace::Variable(x), PatternNonValuePlace::Entid(x) => PatternValuePlace::EntidOrInteger(x), PatternNonValuePlace::Ident(x) => PatternValuePlace::IdentOrKeyword(x), } } fn to_pattern_value_place(&self) -> PatternValuePlace { match *self { PatternNonValuePlace::Placeholder => PatternValuePlace::Placeholder, PatternNonValuePlace::Variable(ref x) => PatternValuePlace::Variable(x.clone()), PatternNonValuePlace::Entid(x) => PatternValuePlace::EntidOrInteger(x), PatternNonValuePlace::Ident(ref x) => PatternValuePlace::IdentOrKeyword(x.clone()), } } } impl FromValue for PatternNonValuePlace { fn from_value(v: &edn::ValueAndSpan) -> Option { match v.inner { edn::SpannedValue::Integer(x) => if x >= 0 { Some(PatternNonValuePlace::Entid(x)) } else { None }, edn::SpannedValue::PlainSymbol(ref x) => if x.0.as_str() == "_" { Some(PatternNonValuePlace::Placeholder) } else { if let Some(v) = Variable::from_symbol(x) { Some(PatternNonValuePlace::Variable(v)) } else { None } }, edn::SpannedValue::NamespacedKeyword(ref x) => Some(PatternNonValuePlace::Ident(Rc::new(x.clone()))), _ => None, } } } #[derive(Clone, Debug, Eq, PartialEq)] pub enum IdentOrEntid { Ident(Rc), Entid(i64), } /// The `v` part of a pattern can be much broader: it can represent /// integers that aren't entity IDs (particularly negative integers), /// strings, and all the rest. We group those under `Constant`. #[derive(Clone, Debug, Eq, PartialEq)] pub enum PatternValuePlace { Placeholder, Variable(Variable), EntidOrInteger(i64), IdentOrKeyword(Rc), Constant(NonIntegerConstant), } impl FromValue for PatternValuePlace { fn from_value(v: &edn::ValueAndSpan) -> Option { match v.inner { edn::SpannedValue::Integer(x) => Some(PatternValuePlace::EntidOrInteger(x)), edn::SpannedValue::PlainSymbol(ref x) if x.0.as_str() == "_" => Some(PatternValuePlace::Placeholder), edn::SpannedValue::PlainSymbol(ref x) => Variable::from_symbol(x).map(PatternValuePlace::Variable), edn::SpannedValue::NamespacedKeyword(ref x) => Some(PatternValuePlace::IdentOrKeyword(Rc::new(x.clone()))), edn::SpannedValue::Boolean(x) => Some(PatternValuePlace::Constant(NonIntegerConstant::Boolean(x))), edn::SpannedValue::Float(x) => Some(PatternValuePlace::Constant(NonIntegerConstant::Float(x))), edn::SpannedValue::BigInteger(ref x) => Some(PatternValuePlace::Constant(NonIntegerConstant::BigInteger(x.clone()))), edn::SpannedValue::Instant(x) => Some(PatternValuePlace::Constant(NonIntegerConstant::Instant(x))), edn::SpannedValue::Text(ref x) => // TODO: intern strings. #398. Some(PatternValuePlace::Constant(NonIntegerConstant::Text(Rc::new(x.clone())))), edn::SpannedValue::Uuid(ref u) => Some(PatternValuePlace::Constant(NonIntegerConstant::Uuid(u.clone()))), // These don't appear in queries. edn::SpannedValue::Nil => None, edn::SpannedValue::NamespacedSymbol(_) => None, edn::SpannedValue::Keyword(_) => None, edn::SpannedValue::Map(_) => None, edn::SpannedValue::List(_) => None, edn::SpannedValue::Set(_) => None, edn::SpannedValue::Vector(_) => None, } } } impl PatternValuePlace { // I think we'll want move variants, so let's leave these here for now. #[allow(dead_code)] fn into_pattern_non_value_place(self) -> Option { match self { PatternValuePlace::Placeholder => Some(PatternNonValuePlace::Placeholder), PatternValuePlace::Variable(x) => Some(PatternNonValuePlace::Variable(x)), PatternValuePlace::EntidOrInteger(x) => if x >= 0 { Some(PatternNonValuePlace::Entid(x)) } else { None }, PatternValuePlace::IdentOrKeyword(x) => Some(PatternNonValuePlace::Ident(x)), PatternValuePlace::Constant(_) => None, } } fn to_pattern_non_value_place(&self) -> Option { match *self { PatternValuePlace::Placeholder => Some(PatternNonValuePlace::Placeholder), PatternValuePlace::Variable(ref x) => Some(PatternNonValuePlace::Variable(x.clone())), PatternValuePlace::EntidOrInteger(x) => if x >= 0 { Some(PatternNonValuePlace::Entid(x)) } else { None }, PatternValuePlace::IdentOrKeyword(ref x) => Some(PatternNonValuePlace::Ident(x.clone())), PatternValuePlace::Constant(_) => None, } } } /* pub enum PullPattern { Constant(Constant), Variable(Variable), } pub struct Pull { pub src: SrcVar, pub var: Variable, pub pattern: PullPattern, // Constant, variable, or plain variable. } */ #[derive(Debug, Eq, PartialEq)] pub struct Aggregate { pub func: QueryFunction, pub args: Vec, } #[derive(Debug, Eq, PartialEq)] pub enum Element { Variable(Variable), Aggregate(Aggregate), /// In a query with a `max` or `min` aggregate, a corresponding variable /// (indicated in the query with `(the ?var)`, is guaranteed to come from /// the row that provided the max or min value. Queries with more than one /// `max` or `min` cannot yield predictable behavior, and will err during /// algebrizing. Corresponding(Variable), // Pull(Pull), // TODO } impl Element { /// Returns true if the element must yield only one value. pub fn is_unit(&self) -> bool { match self { &Element::Variable(_) => false, &Element::Aggregate(_) => true, &Element::Corresponding(_) => true, } } } impl From for Element { fn from(x: Variable) -> Element { Element::Variable(x) } } impl std::fmt::Display for Element { fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result { match self { &Element::Variable(ref var) => { write!(f, "{}", var) }, &Element::Aggregate(ref agg) => { match agg.args.len() { 0 => write!(f, "({})", agg.func), 1 => write!(f, "({} {})", agg.func, agg.args[0]), _ => write!(f, "({} {:?})", agg.func, agg.args), } }, &Element::Corresponding(ref var) => { write!(f, "(the {})", var) }, } } } #[derive(Clone, Debug, Eq, PartialEq)] pub enum Limit { None, Fixed(u64), Variable(Variable), } /// A definition of the first part of a find query: the /// `[:find ?foo ?bar…]` bit. /// /// There are four different kinds of find specs, allowing you to query for /// a single value, a collection of values from different entities, a single /// tuple (relation), or a collection of tuples. /// /// Examples: /// /// ```rust /// # extern crate edn; /// # extern crate mentat_query; /// # use std::rc::Rc; /// # use edn::PlainSymbol; /// # use mentat_query::{Element, FindSpec, Variable}; /// /// # fn main() { /// /// let elements = vec![ /// Element::Variable(Variable::from_valid_name("?foo")), /// Element::Variable(Variable::from_valid_name("?bar")), /// ]; /// let rel = FindSpec::FindRel(elements); /// /// if let FindSpec::FindRel(elements) = rel { /// assert_eq!(2, elements.len()); /// } /// /// # } /// ``` /// #[derive(Debug, Eq, PartialEq)] pub enum FindSpec { /// Returns an array of arrays. FindRel(Vec), /// Returns an array of scalars, usually homogeneous. /// This is equivalent to mapping over the results of a `FindRel`, /// returning the first value of each. FindColl(Element), /// Returns a single tuple: a heterogeneous array of scalars. Equivalent to /// taking the first result from a `FindRel`. FindTuple(Vec), /// Returns a single scalar value. Equivalent to taking the first result /// from a `FindColl`. FindScalar(Element), } /// Returns true if the provided `FindSpec` returns at most one result. impl FindSpec { pub fn is_unit_limited(&self) -> bool { use FindSpec::*; match self { &FindScalar(..) => true, &FindTuple(..) => true, &FindRel(..) => false, &FindColl(..) => false, } } pub fn expected_column_count(&self) -> usize { use FindSpec::*; match self { &FindScalar(..) => 1, &FindColl(..) => 1, &FindTuple(ref elems) | &FindRel(ref elems) => elems.len(), } } /// Returns true if the provided `FindSpec` cares about distinct results. /// /// I use the words "cares about" because find is generally defined in terms of producing distinct /// results at the Datalog level. /// /// Two of the find specs (scalar and tuple) produce only a single result. Those don't need to be /// run with `SELECT DISTINCT`, because we're only consuming a single result. Those queries will be /// run with `LIMIT 1`. /// /// Additionally, some projections cannot produce duplicate results: `[:find (max ?x) …]`, for /// example. /// /// This function gives us the hook to add that logic when we're ready. /// /// Beyond this, `DISTINCT` is not always needed. For example, in some kinds of accumulation or /// sampling projections we might not need to do it at the SQL level because we're consuming into /// a dupe-eliminating data structure like a Set, or we know that a particular query cannot produce /// duplicate results. pub fn requires_distinct(&self) -> bool { !self.is_unit_limited() } pub fn columns<'s>(&'s self) -> Box + 's> { use FindSpec::*; match self { &FindScalar(ref e) => Box::new(std::iter::once(e)), &FindColl(ref e) => Box::new(std::iter::once(e)), &FindTuple(ref v) => Box::new(v.iter()), &FindRel(ref v) => Box::new(v.iter()), } } } // Datomic accepts variable or placeholder. DataScript accepts recursive bindings. Mentat sticks // to the non-recursive form Datomic accepts, which is much simpler to process. #[derive(Clone, Debug, Eq, Hash, PartialEq)] pub enum VariableOrPlaceholder { Placeholder, Variable(Variable), } impl VariableOrPlaceholder { pub fn into_var(self) -> Option { match self { VariableOrPlaceholder::Placeholder => None, VariableOrPlaceholder::Variable(var) => Some(var), } } pub fn var(&self) -> Option<&Variable> { match self { &VariableOrPlaceholder::Placeholder => None, &VariableOrPlaceholder::Variable(ref var) => Some(var), } } } #[derive(Clone,Debug,Eq,PartialEq)] pub enum Binding { BindScalar(Variable), BindColl(Variable), BindRel(Vec), BindTuple(Vec), } impl Binding { /// Return each variable or `None`, in order. pub fn variables(&self) -> Vec> { match self { &Binding::BindScalar(ref var) | &Binding::BindColl(ref var) => vec![Some(var.clone())], &Binding::BindRel(ref vars) | &Binding::BindTuple(ref vars) => vars.iter().map(|x| x.var().cloned()).collect(), } } /// Return `true` if no variables are bound, i.e., all binding entries are placeholders. pub fn is_empty(&self) -> bool { match self { &Binding::BindScalar(_) | &Binding::BindColl(_) => false, &Binding::BindRel(ref vars) | &Binding::BindTuple(ref vars) => vars.iter().all(|x| x.var().is_none()), } } /// Return `true` if no variable is bound twice, i.e., each binding entry is either a /// placeholder or unique. /// /// ``` /// extern crate mentat_query; /// use std::rc::Rc; /// /// let v = mentat_query::Variable::from_valid_name("?foo"); /// let vv = mentat_query::VariableOrPlaceholder::Variable(v); /// let p = mentat_query::VariableOrPlaceholder::Placeholder; /// /// let e = mentat_query::Binding::BindTuple(vec![p.clone()]); /// let b = mentat_query::Binding::BindTuple(vec![p.clone(), vv.clone()]); /// let d = mentat_query::Binding::BindTuple(vec![vv.clone(), p, vv]); /// assert!(b.is_valid()); // One var, one placeholder: OK. /// assert!(!e.is_valid()); // Empty: not OK. /// assert!(!d.is_valid()); // Duplicate var: not OK. /// ``` pub fn is_valid(&self) -> bool { match self { &Binding::BindScalar(_) | &Binding::BindColl(_) => true, &Binding::BindRel(ref vars) | &Binding::BindTuple(ref vars) => { let mut acc = HashSet::::new(); for var in vars { if let &VariableOrPlaceholder::Variable(ref var) = var { if !acc.insert(var.clone()) { // It's invalid if there was an equal var already present in the set -- // i.e., we have a duplicate var. return false; } } } // We're not valid if every place is a placeholder! !acc.is_empty() } } } } // Note that the "implicit blank" rule applies. // A pattern with a reversed attribute — :foo/_bar — is reversed // at the point of parsing. These `Pattern` instances only represent // one direction. #[derive(Clone, Debug, Eq, PartialEq)] pub struct Pattern { pub source: Option, pub entity: PatternNonValuePlace, pub attribute: PatternNonValuePlace, pub value: PatternValuePlace, pub tx: PatternNonValuePlace, } impl Pattern { pub fn simple(e: PatternNonValuePlace, a: PatternNonValuePlace, v: PatternValuePlace) -> Option { Pattern::new(None, e, a, v, PatternNonValuePlace::Placeholder) } pub fn new(src: Option, e: PatternNonValuePlace, a: PatternNonValuePlace, v: PatternValuePlace, tx: PatternNonValuePlace) -> Option { let aa = a.clone(); // Too tired of fighting borrow scope for now. if let PatternNonValuePlace::Ident(ref k) = aa { if k.is_backward() { // e and v have different types; we must convert them. // Not every parseable value is suitable for the entity field! // As such, this is a failable constructor. let e_v = e.to_pattern_value_place(); if let Some(v_e) = v.to_pattern_non_value_place() { return Some(Pattern { source: src, entity: v_e, attribute: PatternNonValuePlace::Ident(Rc::new(k.to_reversed())), value: e_v, tx: tx, }); } else { return None; } } } Some(Pattern { source: src, entity: e, attribute: a, value: v, tx: tx, }) } } #[derive(Clone, Debug, Eq, PartialEq)] pub struct Predicate { pub operator: PlainSymbol, pub args: Vec, } #[derive(Clone, Debug, Eq, PartialEq)] pub struct WhereFn { pub operator: PlainSymbol, pub args: Vec, pub binding: Binding, } #[derive(Clone, Debug, Eq, PartialEq)] pub enum UnifyVars { /// `Implicit` means the variables in an `or` or `not` are derived from the enclosed pattern. /// DataScript regards these vars as 'free': these variables don't need to be bound by the /// enclosing environment. /// /// Datomic's documentation implies that all implicit variables are required: /// /// > Datomic will attempt to push the or clause down until all necessary variables are bound, /// > and will throw an exception if that is not possible. /// /// but that would render top-level `or` expressions (as used in Datomic's own examples!) /// impossible, so we assume that this is an error in the documentation. /// /// All contained 'arms' in an `or` with implicit variables must bind the same vars. Implicit, /// `Explicit` means the variables in an `or-join` or `not-join` are explicitly listed, /// specified with `required-vars` syntax. /// /// DataScript parses these as free, but allows (incorrectly) the use of more complicated /// `rule-vars` syntax. /// /// Only the named variables will be unified with the enclosing query. /// /// Every 'arm' in an `or-join` must mention the entire set of explicit vars. Explicit(BTreeSet), } impl WhereClause { pub fn is_pattern(&self) -> bool { match self { &WhereClause::Pattern(_) => true, _ => false, } } } #[derive(Clone, Debug, Eq, PartialEq)] pub enum OrWhereClause { Clause(WhereClause), And(Vec), } impl OrWhereClause { pub fn is_pattern_or_patterns(&self) -> bool { match self { &OrWhereClause::Clause(WhereClause::Pattern(_)) => true, &OrWhereClause::And(ref clauses) => clauses.iter().all(|clause| clause.is_pattern()), _ => false, } } } #[derive(Clone, Debug, Eq, PartialEq)] pub struct OrJoin { pub unify_vars: UnifyVars, pub clauses: Vec, /// Caches the result of `collect_mentioned_variables`. mentioned_vars: Option>, } #[derive(Clone, Debug, Eq, PartialEq)] pub struct NotJoin { pub unify_vars: UnifyVars, pub clauses: Vec, } #[derive(Clone, Debug, Eq, PartialEq)] pub struct TypeAnnotation { pub value_type: ValueType, pub variable: Variable, } #[allow(dead_code)] #[derive(Clone, Debug, Eq, PartialEq)] pub enum WhereClause { NotJoin(NotJoin), OrJoin(OrJoin), Pred(Predicate), WhereFn(WhereFn), RuleExpr, Pattern(Pattern), TypeAnnotation(TypeAnnotation), } #[allow(dead_code)] #[derive(Debug, Eq, PartialEq)] pub struct FindQuery { pub find_spec: FindSpec, pub default_source: SrcVar, pub with: BTreeSet, pub in_vars: BTreeSet, pub in_sources: BTreeSet, pub limit: Limit, pub where_clauses: Vec, pub order: Option>, // TODO: in_rules; } impl FindQuery { pub fn simple(spec: FindSpec, where_clauses: Vec) -> FindQuery { FindQuery { find_spec: spec, default_source: SrcVar::DefaultSrc, with: BTreeSet::default(), in_vars: BTreeSet::default(), in_sources: BTreeSet::default(), limit: Limit::None, where_clauses: where_clauses, order: None, } } } impl OrJoin { pub fn new(unify_vars: UnifyVars, clauses: Vec) -> OrJoin { OrJoin { unify_vars: unify_vars, clauses: clauses, mentioned_vars: None, } } /// Return true if either the `OrJoin` is `UnifyVars::Implicit`, or if /// every variable mentioned inside the join is also mentioned in the `UnifyVars` list. pub fn is_fully_unified(&self) -> bool { match &self.unify_vars { &UnifyVars::Implicit => true, &UnifyVars::Explicit(ref vars) => { // We know that the join list must be a subset of the vars in the pattern, or // it would have failed validation. That allows us to simply compare counts here. // TODO: in debug mode, do a full intersection, and verify that our count check // returns the same results. // Use the cached list if we have one. if let Some(ref mentioned) = self.mentioned_vars { vars.len() == mentioned.len() } else { vars.len() == self.collect_mentioned_variables().len() } } } } } pub trait ContainsVariables { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet); fn collect_mentioned_variables(&self) -> BTreeSet { let mut out = BTreeSet::new(); self.accumulate_mentioned_variables(&mut out); out } } impl ContainsVariables for WhereClause { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { use WhereClause::*; match self { &OrJoin(ref o) => o.accumulate_mentioned_variables(acc), &Pred(ref p) => p.accumulate_mentioned_variables(acc), &Pattern(ref p) => p.accumulate_mentioned_variables(acc), &NotJoin(ref n) => n.accumulate_mentioned_variables(acc), &WhereFn(ref f) => f.accumulate_mentioned_variables(acc), &TypeAnnotation(ref a) => a.accumulate_mentioned_variables(acc), &RuleExpr => (), } } } impl ContainsVariables for OrWhereClause { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { use OrWhereClause::*; match self { &And(ref clauses) => for clause in clauses { clause.accumulate_mentioned_variables(acc) }, &Clause(ref clause) => clause.accumulate_mentioned_variables(acc), } } } impl ContainsVariables for OrJoin { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { for clause in &self.clauses { clause.accumulate_mentioned_variables(acc); } } } impl OrJoin { pub fn dismember(self) -> (Vec, UnifyVars, BTreeSet) { let vars = match self.mentioned_vars { Some(m) => m, None => self.collect_mentioned_variables(), }; (self.clauses, self.unify_vars, vars) } pub fn mentioned_variables<'a>(&'a mut self) -> &'a BTreeSet { if self.mentioned_vars.is_none() { let m = self.collect_mentioned_variables(); self.mentioned_vars = Some(m); } if let Some(ref mentioned) = self.mentioned_vars { mentioned } else { unreachable!() } } } impl ContainsVariables for NotJoin { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { for clause in &self.clauses { clause.accumulate_mentioned_variables(acc); } } } impl ContainsVariables for Predicate { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { for arg in &self.args { if let &FnArg::Variable(ref v) = arg { acc_ref(acc, v) } } } } impl ContainsVariables for TypeAnnotation { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { acc_ref(acc, &self.variable); } } impl ContainsVariables for Binding { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { match self { &Binding::BindScalar(ref v) | &Binding::BindColl(ref v) => { acc_ref(acc, v) }, &Binding::BindRel(ref vs) | &Binding::BindTuple(ref vs) => { for v in vs { if let &VariableOrPlaceholder::Variable(ref v) = v { acc_ref(acc, v); } } }, } } } impl ContainsVariables for WhereFn { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { for arg in &self.args { if let &FnArg::Variable(ref v) = arg { acc_ref(acc, v) } } self.binding.accumulate_mentioned_variables(acc); } } fn acc_ref(acc: &mut BTreeSet, v: &T) { // Roll on, reference entries! if !acc.contains(v) { acc.insert(v.clone()); } } impl ContainsVariables for Pattern { fn accumulate_mentioned_variables(&self, acc: &mut BTreeSet) { if let PatternNonValuePlace::Variable(ref v) = self.entity { acc_ref(acc, v) } if let PatternNonValuePlace::Variable(ref v) = self.attribute { acc_ref(acc, v) } if let PatternValuePlace::Variable(ref v) = self.value { acc_ref(acc, v) } if let PatternNonValuePlace::Variable(ref v) = self.tx { acc_ref(acc, v) } } }