class OptimizingMatchTranslator extends MatchTranslator with MatchOptimizer with MatchAnalyzer with Solver
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- OptimizingMatchTranslator
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- CommonSubconditionElimination
- MatchApproximator
- TreesAndTypesDomain
- CheckableTreeAndTypeAnalysis
- PropositionalLogic
- SwitchEmission
- OptimizedCodegen
- MatchTranslator
- TreeMakerWarnings
- TreeMakers
- CodegenCore
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Instance Constructors
- new OptimizingMatchTranslator(typer: (analyzer)#Typer, selectorPos: Global.Position)
Type Members
- class Substitution extends AnyRef
- Definition Classes
- TypedSubstitution
- trait AbsVar extends AnyRef
- Definition Classes
- PropositionalLogic
- final case class And(ops: Set[Prop]) extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- final case class AtMostOne(ops: List[Sym]) extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- final case class Eq(p: Var, q: Const) extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- final case class Not(a: Prop) extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- final case class Or(ops: Set[Prop]) extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- sealed abstract class Prop extends AnyRef
- Definition Classes
- PropositionalLogic
- trait PropMap extends AnyRef
- Definition Classes
- PropositionalLogic
- trait PropTraverser extends AnyRef
- Definition Classes
- PropositionalLogic
- final case class Solution(model: Model, unassigned: List[Sym]) extends Product with Serializable
- Definition Classes
- PropositionalLogic
- final class Sym extends Prop
- Definition Classes
- PropositionalLogic
- trait TypeConstExtractor extends AnyRef
- Definition Classes
- PropositionalLogic
- trait ValueConstExtractor extends AnyRef
- Definition Classes
- PropositionalLogic
- trait VarExtractor extends AnyRef
- Definition Classes
- PropositionalLogic
- case class ConstructorExample(cls: Global.Symbol, ctorArgs: List[CounterExample]) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- class CounterExample extends AnyRef
- Definition Classes
- MatchAnalyzer
- case class ListExample(ctorArgs: List[CounterExample]) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case class NegativeExample(eqTo: MatchAnalyzer.Const, nonTrivialNonEqualTo: List[MatchAnalyzer.Const]) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case class TupleExample(ctorArgs: List[CounterExample]) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case class TypeExample(c: MatchAnalyzer.Const) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case class ValueExample(c: MatchAnalyzer.ValueConst) extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case class Test(prop: MatchApproximator.Prop, treeMaker: MatchApproximator.TreeMaker) extends Product with Serializable
- Definition Classes
- MatchApproximator
- class TreeMakersToProps extends AnyRef
- Definition Classes
- MatchApproximator
- trait AbsCodegen extends AnyRef
- Definition Classes
- CodegenCore
- trait Casegen extends AbsCodegen
- Definition Classes
- CodegenCore
- abstract class CommonCodegen extends AbsCodegen
- Definition Classes
- CodegenCore
- class ReusedCondTreeMaker extends TreeMaker
- Definition Classes
- CommonSubconditionElimination
- case class ReusingCondTreeMaker(sharedPrefix: List[CommonSubconditionElimination.Test], reusesTest: (CommonSubconditionElimination.Test) => Option[CommonSubconditionElimination.Test], toReused: (CommonSubconditionElimination.TreeMaker) => CommonSubconditionElimination.TreeMaker) extends TreeMaker with Product with Serializable
- Definition Classes
- CommonSubconditionElimination
- class RegularSwitchMaker extends SwitchMaker
- Definition Classes
- SwitchEmission
- abstract class SwitchMaker extends AnyRef
- Definition Classes
- SwitchEmission
- final case class BoundTree(binder: Global.Symbol, tree: Global.Tree) extends Product with Serializable
- Definition Classes
- MatchTranslator
- abstract class ExtractorCall extends PatternMatching.ExtractorAlignment
- Definition Classes
- MatchTranslator
- class ExtractorCallProd extends ExtractorCall
- Definition Classes
- MatchTranslator
- class ExtractorCallRegular extends ExtractorCall
- Definition Classes
- MatchTranslator
- final case class TranslationStep(makers: List[MatchTranslator.TreeMaker], subpatterns: List[BoundTree]) extends Product with Serializable
- Definition Classes
- MatchTranslator
- case class AlternativesTreeMaker(prevBinder: Global.Symbol, altss: List[List[TreeMaker]], pos: Global.Position) extends TreeMaker with NoNewBinders with Product with Serializable
- Definition Classes
- TreeMakers
- case class BodyTreeMaker(body: Global.Tree, matchPt: Global.Type) extends TreeMaker with NoNewBinders with Product with Serializable
- Definition Classes
- TreeMakers
- sealed abstract class CondTreeMaker extends FunTreeMaker
- Definition Classes
- TreeMakers
- case class EqualityTestTreeMaker(prevBinder: Global.Symbol, patTree: Global.Tree, pos: Global.Position) extends CondTreeMaker with Product with Serializable
- Definition Classes
- TreeMakers
- case class ExtractorTreeMaker(extractor: Global.Tree, extraCond: Option[Global.Tree], nextBinder: Global.Symbol)(subPatBinders: List[Global.Symbol], subPatRefs: List[Global.Tree], potentiallyMutableBinders: Set[Global.Symbol], extractorReturnsBoolean: Boolean, checkedLength: Option[Int], prevBinder: Global.Symbol, ignoredSubPatBinders: Set[Global.Symbol]) extends FunTreeMaker with PreserveSubPatBinders with Product with Serializable
Make a TreeMaker that will result in an extractor call specified by
extractor
the next TreeMaker (here, we don't know which it'll be) is chained after this one by flatMap'ing a function with bindernextBinder
over our extractor's result the function's body is determined by the next TreeMaker (furthermore, the interpretation offlatMap
depends on the codegen instance we're using).Make a TreeMaker that will result in an extractor call specified by
extractor
the next TreeMaker (here, we don't know which it'll be) is chained after this one by flatMap'ing a function with bindernextBinder
over our extractor's result the function's body is determined by the next TreeMaker (furthermore, the interpretation offlatMap
depends on the codegen instance we're using).The values for the subpatterns, as computed by the extractor call in
extractor
, are stored in local variables that re-use the symbols insubPatBinders
. This makes extractor patterns more debuggable (scala/bug#5739).- Definition Classes
- TreeMakers
- sealed abstract class FunTreeMaker extends TreeMaker
- Definition Classes
- TreeMakers
- case class GuardTreeMaker(guardTree: Global.Tree) extends TreeMaker with NoNewBinders with Product with Serializable
- Definition Classes
- TreeMakers
- sealed trait NoNewBinders extends TreeMaker
- Definition Classes
- TreeMakers
- case class NonNullTestTreeMaker(prevBinder: Global.Symbol, expectedTp: Global.Type, pos: Global.Position) extends FunTreeMaker with Product with Serializable
Make a TreeMaker that performs null check.
Make a TreeMaker that performs null check. This is called prior to extractor call.
- Definition Classes
- TreeMakers
- sealed trait PreserveSubPatBinders extends TreeMaker
- Definition Classes
- TreeMakers
- case class ProductExtractorTreeMaker(prevBinder: Global.Symbol, extraCond: Option[Global.Tree])(subPatBinders: List[Global.Symbol], subPatRefs: List[Global.Tree], mutableBinders: List[Global.Symbol], ignoredSubPatBinders: Set[Global.Symbol]) extends FunTreeMaker with PreserveSubPatBinders with Product with Serializable
An optimized version of ExtractorTreeMaker for Products.
An optimized version of ExtractorTreeMaker for Products. For now, this is hard-coded to case classes, and we simply extract the case class fields.
The values for the subpatterns, as specified by the case class fields at the time of extraction, are stored in local variables that re-use the symbols in
subPatBinders
. This makes extractor patterns more debuggable (scala/bug#5739) as well as avoiding mutation after the pattern has been matched (scala/bug#5158, scala/bug#6070)TODO: make this user-definable as follows When a companion object defines a method
def unapply_1(x: T): U_1
, but nodef unapply
ordef unapplySeq
, the extractor is considered to match any non-null value of type T the pattern is expected to have as many sub-patterns as there aredef unapply_I(x: T): U_I
methods, and the type of the I'th sub-pattern isU_I
. The same exception for Seq patterns applies: if the last extractor is of typeSeq[U_N]
, the pattern must have at least N arguments (exactly N if the last argument is annotated with: _*
). The arguments starting at N (and beyond) are taken from the sequence returned by apply_N, and it is checked that that sequence has enough elements to provide values for all expected sub-patterns.For a case class C, the implementation is assumed to be
def unapply_I(x: C) = x._I
, and the extractor call is inlined under that assumption.- Definition Classes
- TreeMakers
- case class SubstOnlyTreeMaker(prevBinder: Global.Symbol, nextBinder: Global.Symbol) extends TreeMaker with Product with Serializable
- Definition Classes
- TreeMakers
- abstract class TreeMaker extends AnyRef
- Definition Classes
- TreeMakers
- case class TrivialTreeMaker(tree: Global.Tree) extends TreeMaker with NoNewBinders with Product with Serializable
- Definition Classes
- TreeMakers
- case class TypeTestTreeMaker(prevBinder: Global.Symbol, testedBinder: Global.Symbol, expectedTp: Global.Type, nextBinderTp: Global.Type)(pos: Global.Position, extractorArgTypeTest: Boolean = false) extends CondTreeMaker with Product with Serializable
implements the run-time aspects of (§8.2) (typedPattern has already done the necessary type transformations)
implements the run-time aspects of (§8.2) (typedPattern has already done the necessary type transformations)
Type patterns consist of types, type variables, and wildcards. A type pattern T is of one of the following forms:
- A reference to a class C, p.C, or T#C. This type pattern matches any non-null instance of the given class. Note that the prefix of the class, if it is given, is relevant for determining class instances. For instance, the pattern p.C matches only instances of classes C which were created with the path p as prefix. The bottom types scala.Nothing and scala.Null cannot be used as type patterns, because they would match nothing in any case.
- A singleton type p.type. This type pattern matches only the value denoted by the path p (that is, a pattern match involved a comparison of the matched value with p using method eq in class AnyRef). // TODO: the actual pattern matcher uses ==, so that's what I'm using for now // https://github.com/scala/bug/issues/4577 "pattern matcher, still disappointing us at equality time"
- A compound type pattern T1 with ... with Tn where each Ti is a type pat- tern. This type pattern matches all values that are matched by each of the type patterns Ti.
- A parameterized type pattern T[a1,...,an], where the ai are type variable patterns or wildcards _. This type pattern matches all values which match T for some arbitrary instantiation of the type variables and wildcards. The bounds or alias type of these type variable are determined as described in (§8.3).
- A parameterized type pattern scala.Array[T1], where T1 is a type pattern. // TODO This type pattern matches any non-null instance of type scala.Array[U1], where U1 is a type matched by T1.
- Definition Classes
- TreeMakers
- type Clause = Set[Lit]
- Definition Classes
- CNF
- type Cnf = Array[Clause]
Conjunctive normal form (of a Boolean formula).
Conjunctive normal form (of a Boolean formula). A formula in this form is amenable to a SAT solver (i.e., solver that decides satisfiability of a formula).
- Definition Classes
- CNF
- type Model = Map[Sym, Boolean]
- Definition Classes
- PropositionalLogic
- type Tree = Global.Tree
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- type TseitinModel = collection.immutable.List[Lit]
- Definition Classes
- Solver
- type TseitinSearch = collection.immutable.List[(Array[Clause], List[Lit])]
- Definition Classes
- Solver
- type Type = Global.Type
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- type VarAssignment = Map[Var, (Seq[Const], Seq[Const])]
- Definition Classes
- MatchAnalyzer
- sealed abstract class Const extends AnyRef
- Definition Classes
- TreesAndTypesDomain
- sealed class TypeConst extends Const
- Definition Classes
- TreesAndTypesDomain
- sealed class ValueConst extends Const
- Definition Classes
- TreesAndTypesDomain
- class Var extends AbsVar
- Definition Classes
- TreesAndTypesDomain
- class AlreadyInCNF extends AnyRef
- Definition Classes
- CNF
- trait CnfBuilder extends AnyRef
- Definition Classes
- CNF
- trait LitApi extends AnyRef
- Definition Classes
- CNF
- trait LitModule extends AnyRef
- Definition Classes
- CNF
- final case class Solvable(cnf: Cnf, symbolMapping: SymbolMapping) extends Product with Serializable
- Definition Classes
- CNF
- class SymbolMapping extends AnyRef
- Definition Classes
- CNF
- class TransformToCnf extends CnfBuilder
Plaisted transformation: used for conversion of a propositional formula into conjunctive normal form (CNF) (input format for SAT solver).
Plaisted transformation: used for conversion of a propositional formula into conjunctive normal form (CNF) (input format for SAT solver). A simple conversion into CNF via Shannon expansion would also be possible but it's worst-case complexity is exponential (in the number of variables) and thus even simple problems could become untractable. The Plaisted transformation results in an _equisatisfiable_ CNF-formula (it generates auxiliary variables) but runs with linear complexity. The common known Tseitin transformation uses bi-implication, whereas the Plaisted transformation uses implication only, thus the resulting CNF formula has (on average) only half of the clauses of a Tseitin transformation. The Plaisted transformation uses the polarities of sub-expressions to figure out which part of the bi-implication can be omitted. However, if all sub-expressions have positive polarity (e.g., after transformation into negation normal form) then the conversion is rather simple and the pseudo-normalization via NNF increases chances only one side of the bi-implication is needed.
- Definition Classes
- CNF
- case class Lit(v: Int) extends LitApi with Product with Serializable
- Definition Classes
- Solver
Value Members
- object EmptySubstitution extends Substitution
- Definition Classes
- TypedSubstitution
- object Substitution
- Definition Classes
- TypedSubstitution
- object AnalysisBudget
- Definition Classes
- PropositionalLogic
- object And extends java.io.Serializable
- Definition Classes
- PropositionalLogic
- case object False extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- object Or extends java.io.Serializable
- Definition Classes
- PropositionalLogic
- object Sym
- Definition Classes
- PropositionalLogic
- case object True extends Prop with Product with Serializable
- Definition Classes
- PropositionalLogic
- object CounterExample
- Definition Classes
- MatchAnalyzer
- case object NoExample extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- case object WildcardExample extends CounterExample with Product with Serializable
- Definition Classes
- MatchAnalyzer
- object Test extends java.io.Serializable
- Definition Classes
- MatchApproximator
- object optimizedCodegen extends CommonCodegen
- Definition Classes
- OptimizedCodegen
- object ReusedCondTreeMaker
- Definition Classes
- CommonSubconditionElimination
- object ExtractorCall
- Definition Classes
- MatchTranslator
- object PatternBoundToUnderscore
- Definition Classes
- MatchTranslator
- object SymbolBound
- Definition Classes
- MatchTranslator
- object WildcardPattern
A conservative approximation of which patterns do not discern anything.
A conservative approximation of which patterns do not discern anything. They are discarded during the translation.
- Definition Classes
- MatchTranslator
- object TypeTestTreeMaker extends java.io.Serializable
- Definition Classes
- TreeMakers
- final def !=(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
- final def ##: Int
- Definition Classes
- AnyRef → Any
- def +(other: String): String
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toany2stringadd[OptimizingMatchTranslator] performed by method any2stringadd in scala.Predef.
- Definition Classes
- any2stringadd
- def ->[B](y: B): (OptimizingMatchTranslator, B)
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toArrowAssoc[OptimizingMatchTranslator] performed by method ArrowAssoc in scala.Predef.
- Definition Classes
- ArrowAssoc
- Annotations
- @inline()
- def /\(props: Iterable[Prop]): Prop
- Definition Classes
- PropositionalLogic
- final def ==(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
- val ArrayOfFalse: Array[Clause]
- Definition Classes
- CNF
- val EmptyModel: Map[Sym, Boolean]
- Definition Classes
- Solver → PropositionalLogic
- val NoClauses: Array[Clause]
- Definition Classes
- CNF
- val NoModel: Model
- Definition Classes
- Solver → PropositionalLogic
- val NoTseitinModel: TseitinModel
- Definition Classes
- Solver
- def \/(props: Iterable[Prop]): Prop
- Definition Classes
- PropositionalLogic
- def analyzeCases(prevBinder: Global.Symbol, cases: List[List[TreeMaker]], pt: Type, suppression: PatternMatching.Suppression): Unit
- Definition Classes
- MatchAnalyzer → TreeMakers
- def approximateMatchConservative(root: Global.Symbol, cases: List[List[TreeMaker]]): List[List[Test]]
- Definition Classes
- MatchApproximator
- final def asInstanceOf[T0]: T0
- Definition Classes
- Any
- final def caseWithoutBodyToProp(tests: List[Test]): Prop
- Attributes
- protected
- Definition Classes
- MatchApproximator
- def checkMatchVariablePatterns(cases: List[Global.CaseDef]): Unit
- Definition Classes
- TreeMakerWarnings
- def checkableType(tp: Global.Type): Global.Type
- Definition Classes
- CheckableTreeAndTypeAnalysis
- def clause(ls: IterableOnce[Lit]): Clause
- Definition Classes
- CNF
- def clause(l: Lit, l2: Lit, ls: Lit*): Clause
- Definition Classes
- CNF
- def clause(l: Lit, l2: Lit): Clause
- Definition Classes
- CNF
- def clause(l: Lit): Clause
- Definition Classes
- CNF
- def clause(): Clause
- Definition Classes
- CNF
- def clone(): AnyRef
- Attributes
- protected[lang]
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.CloneNotSupportedException]) @native()
- def cnfString(f: Array[Clause]): String
- def codegen: AbsCodegen
- Definition Classes
- OptimizedCodegen → CodegenCore
- def combineCases(scrut: Global.Tree, scrutSym: Global.Symbol, cases: List[List[TreeMaker]], pt: Global.Type, selectorPos: Global.Position, owner: Global.Symbol, matchFailGenOverride: Option[(Global.Tree) => Global.Tree], suppression: PatternMatching.Suppression): Global.Tree
- Definition Classes
- TreeMakers
- def combineExtractors(treeMakers: List[TreeMaker])(casegen: Casegen): Global.Tree
- Definition Classes
- TreeMakers
- val debugInfoEmitVars: Boolean
- Attributes
- protected
- Definition Classes
- TreeMakers
- def doCSE(prevBinder: Global.Symbol, cases: List[List[TreeMaker]], pt: Type, selectorPos: Global.Position): List[List[TreeMaker]]
a flow-sensitive, generalised, common sub-expression elimination reuse knowledge from performed tests the only sub-expressions we consider are the conditions and results of the three tests (type, type&equality, equality) when a sub-expression is shared, it is stored in a mutable variable the variable is floated up so that its scope includes all of the program that shares it we generalize sharing to implication, where b reuses a if a => b and priors(a) => priors(b) (the priors of a sub expression form the path through the decision tree)
a flow-sensitive, generalised, common sub-expression elimination reuse knowledge from performed tests the only sub-expressions we consider are the conditions and results of the three tests (type, type&equality, equality) when a sub-expression is shared, it is stored in a mutable variable the variable is floated up so that its scope includes all of the program that shares it we generalize sharing to implication, where b reuses a if a => b and priors(a) => priors(b) (the priors of a sub expression form the path through the decision tree)
- Definition Classes
- CommonSubconditionElimination
- def emitSwitch(scrut: Global.Tree, scrutSym: Global.Symbol, cases: List[List[TreeMaker]], pt: Global.Type, matchFailGenOverride: Option[(Global.Tree) => Global.Tree], unchecked: Boolean): Option[Global.Tree]
- Definition Classes
- SwitchEmission → TreeMakers
- def emitTypeSwitch(bindersAndCases: List[(Global.Symbol, List[TreeMaker])], pt: Global.Type): Option[List[Global.CaseDef]]
- Definition Classes
- SwitchEmission → TreeMakers
- def ensuring(cond: (OptimizingMatchTranslator) => Boolean, msg: => Any): OptimizingMatchTranslator
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toEnsuring[OptimizingMatchTranslator] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: (OptimizingMatchTranslator) => Boolean): OptimizingMatchTranslator
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toEnsuring[OptimizingMatchTranslator] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: Boolean, msg: => Any): OptimizingMatchTranslator
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toEnsuring[OptimizingMatchTranslator] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def ensuring(cond: Boolean): OptimizingMatchTranslator
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toEnsuring[OptimizingMatchTranslator] performed by method Ensuring in scala.Predef.
- Definition Classes
- Ensuring
- def enumerateSubtypes(tp: Global.Type, grouped: Boolean): List[List[Global.Type]]
- Definition Classes
- CheckableTreeAndTypeAnalysis
- final def eq(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
- def eqFreePropToSolvable(p: Prop): Solvable
- Definition Classes
- CNF → PropositionalLogic
- def equals(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef → Any
- def exhaustive(prevBinder: Global.Symbol, cases: List[List[TreeMaker]], pt: Type): List[String]
- Definition Classes
- MatchAnalyzer
- def expandModel(solution: Solution): List[VarAssignment]
The models we get from the DPLL solver need to be mapped back to counter examples.
The models we get from the DPLL solver need to be mapped back to counter examples. However there's no precalculated mapping model -> counter example. Even worse, not every valid model corresponds to a valid counter example. The reason is that restricting the valid models further would for example require a quadratic number of additional clauses. So to keep the optimistic case fast (i.e., all cases are covered in a pattern match), the infeasible counter examples are filtered later.
The DPLL procedure keeps the literals that do not contribute to the solution unassigned, e.g., for
(a \/ b)
only {a = true} or {b = true} is required and the other variable can have any value.This function does a smart expansion of the model and avoids models that have conflicting mappings.
For example for in case of the given set of symbols (taken from
t7020.scala
): "V2=2#16" "V2=6#19" "V2=5#18" "V2=4#17" "V2=7#20"One possibility would be to group the symbols by domain but this would only work for equality tests and would not be compatible with type tests. Another observation leads to a much simpler algorithm: Only one of these symbols can be set to true, since
V2
can at most be equal to one of {2,6,5,4,7}.- Definition Classes
- MatchAnalyzer
- def finalize(): Unit
- Attributes
- protected[lang]
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.Throwable])
- def findAllModelsFor(solvable: Solvable, owner: Global.Symbol): List[Solution]
- Definition Classes
- Solver → PropositionalLogic
- def findTseitinModelFor(clauses: Array[Clause]): TseitinModel
- Definition Classes
- Solver
- def fixerUpper(origOwner: Global.Symbol, pos: Global.Position): Global.InternalTraverser
- Attributes
- protected
- Definition Classes
- TreeMakers
- def freshName(prefix: String): Global.TermName
- Definition Classes
- CodegenCore
- def freshSym(pos: Global.Position, tp: Global.Type = NoType, prefix: String = "x"): Global.TermSymbol
- Definition Classes
- CodegenCore
- def gatherSymbols(p: Prop): Set[Sym]
- Definition Classes
- PropositionalLogic
- def gatherVariables(p: Prop): Set[Var]
- Definition Classes
- PropositionalLogic
- final def getClass(): Class[_ <: AnyRef]
- Definition Classes
- AnyRef → Any
- Annotations
- @native()
- def getSuppression(scrut: Global.Tree): PatternMatching.Suppression
- Definition Classes
- TreeMakers
- def hasModel(solvable: Solvable): Boolean
- Definition Classes
- Solver → PropositionalLogic
- def hashCode(): Int
- Definition Classes
- AnyRef → Any
- Annotations
- @native()
- final def isInstanceOf[T0]: Boolean
- Definition Classes
- Any
- val matchOwner: Global.Symbol
- Definition Classes
- MatchMonadInterface
- def modelToCounterExample(scrutVar: Var)(varAssignment: VarAssignment): Option[CounterExample]
- Definition Classes
- MatchAnalyzer
- def modelToVarAssignment(model: Model): VarAssignment
- Definition Classes
- MatchAnalyzer
- final def ne(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
- def newSynthCaseLabel(name: String): Global.MethodSymbol
- Definition Classes
- CodegenCore
- final def notify(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
- final def notifyAll(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
- def optimizeCases(prevBinder: Global.Symbol, cases: List[List[TreeMaker]], pt: Type, selectorPos: Global.Position): (List[List[TreeMaker]], List[Tree])
- Definition Classes
- MatchOptimizer → TreeMakers
- def prepareNewAnalysis(): Unit
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- def propToSolvable(p: Prop): Solvable
- Definition Classes
- PropositionalLogic
- def propagateSubstitution(treeMakers: List[TreeMaker], initial: Substitution): List[TreeMaker]
- Definition Classes
- TreeMakers
- def removeSubstOnly(makers: List[TreeMaker]): collection.immutable.List[TreeMaker]
- Definition Classes
- TreeMakers
- def removeVarEq(props: List[Prop], modelNull: Boolean = false): (Prop, List[Prop])
- Definition Classes
- PropositionalLogic
- def reportMissingCases(pos: Global.Position, counterExamples: List[String]): Unit
- Definition Classes
- MatchMonadInterface
- def reportUnreachable(pos: Global.Position): Unit
- Definition Classes
- MatchMonadInterface
- def reportWarning(message: String): Unit
- Definition Classes
- MatchAnalyzer → PropositionalLogic
- def requiresSwitch(scrut: Global.Tree, cases: List[List[TreeMaker]]): Boolean
- Definition Classes
- TreeMakers
- val selectorPos: Global.Position
- Definition Classes
- OptimizingMatchTranslator → MatchTranslator
- def showTreeMakers(cases: List[List[TreeMaker]]): Unit
- Definition Classes
- MatchApproximator
- def simplify(f: Prop): Prop
Simplifies propositional formula according to the following rules: - eliminate double negation (avoids unnecessary Tseitin variables) - flatten trees of same connectives (avoids unnecessary Tseitin variables) - removes constants and connectives that are in fact constant because of their operands - eliminates duplicate operands - convert formula into NNF: all sub-expressions have a positive polarity which makes them amenable for the subsequent Plaisted transformation and increases chances to figure out that the formula is already in CNF
Simplifies propositional formula according to the following rules: - eliminate double negation (avoids unnecessary Tseitin variables) - flatten trees of same connectives (avoids unnecessary Tseitin variables) - removes constants and connectives that are in fact constant because of their operands - eliminates duplicate operands - convert formula into NNF: all sub-expressions have a positive polarity which makes them amenable for the subsequent Plaisted transformation and increases chances to figure out that the formula is already in CNF
Complexity: DFS over formula tree
See https://www.decision-procedures.org/slides/propositional_logic-2x3.pdf
- Definition Classes
- PropositionalLogic
- final def synchronized[T0](arg0: => T0): T0
- Definition Classes
- AnyRef
- def toString(): String
- Definition Classes
- AnyRef → Any
- def translateBody(body: Global.Tree, matchPt: Global.Type): TreeMaker
- Definition Classes
- MatchTranslator
- def translateCase(scrutSym: Global.Symbol, pt: Global.Type)(caseDef: Global.CaseDef): List[TreeMaker]
The translation of
pat if guard => body
has two aspects: 1) the substitution due to the variables bound by patterns 2) the combination of the extractor calls usingflatMap
.The translation of
pat if guard => body
has two aspects: 1) the substitution due to the variables bound by patterns 2) the combination of the extractor calls usingflatMap
.2) is easy -- it looks like:
translatePattern_1.flatMap(translatePattern_2....flatMap(translatePattern_N.flatMap(translateGuard.flatMap((x_i) => success(Xbody(x_i)))))...)
this must be right-leaning tree, as can be seen intuitively by considering the scope of bound variables: variables bound by pat_1 must be visible from the function inside the left-most flatMap right up to Xbody all the way on the right 1) is tricky because translatePattern_i determines the shape of translatePattern_i+1: zoom in ontranslatePattern_1.flatMap(translatePattern_2)
for example -- it actually looks more like:translatePattern_1(x_scrut).flatMap((x_1) => {y_i -> x_1._i}translatePattern_2)
x_1
references the result (inside the monad) of the extractor corresponding topat_1
, this result holds the values for the constructor arguments, which translatePattern_1 has extracted from the object pointed to byx_scrut
. They_i
are the symbols bound bypat_1
(in order) in the scope of the remainder of the pattern, and they must thus be replaced by:- (for 1-ary unapply) x_1
- (for n-ary unapply, n > 1) selection of the i'th tuple component of
x_1
- (for unapplySeq) x_1.apply(i)
in the treemakers,
Thus, the result type of
translatePattern_i
's extractor must conform toM[(T_1,..., T_n)]
.Operationally, phase 1) is a foldLeft, since we must consider the depth-first-flattening of the transformed patterns from left to right. For every pattern ast node, it produces a transformed ast and a function that will take care of binding and substitution of the next ast (to the right).
- Definition Classes
- MatchTranslator
- def translateGuard(guard: Global.Tree): List[TreeMaker]
- Definition Classes
- MatchTranslator
- def translateMatch(match_: Global.Match): Global.Tree
NOTE: the resulting tree is not type checked, nor are nested pattern matches transformed thus, you must typecheck the result (and that will in turn translate nested matches) this could probably be optimized...
NOTE: the resulting tree is not type checked, nor are nested pattern matches transformed thus, you must typecheck the result (and that will in turn translate nested matches) this could probably be optimized...
- Definition Classes
- MatchTranslator
- def translatePattern(bound: BoundTree): List[TreeMaker]
- Definition Classes
- MatchTranslator
- def translateTry(caseDefs: List[Global.CaseDef], pt: Global.Type, pos: Global.Position): List[Global.CaseDef]
- Definition Classes
- MatchTranslator
- val typer: (analyzer)#Typer
- Definition Classes
- OptimizingMatchTranslator → CheckableTreeAndTypeAnalysis → MatchMonadInterface
- def uncheckableType(tp: Global.Type): Boolean
- Definition Classes
- CheckableTreeAndTypeAnalysis
- def uncheckedWarning(pos: Global.Position, msg: String, site: Global.Symbol): Unit
- Definition Classes
- MatchAnalyzer → PropositionalLogic
- def unreachableCase(prevBinder: Global.Symbol, cases: List[List[TreeMaker]], pt: Type): Option[Int]
- Definition Classes
- MatchAnalyzer
- def unreachableTypeSwitchCase(cases: List[Global.CaseDef]): Option[Global.CaseDef]
- Definition Classes
- SwitchEmission → TreeMakers
- def varAssignmentString(varAssignment: VarAssignment): String
- Definition Classes
- MatchAnalyzer
- final def wait(): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException])
- final def wait(arg0: Long, arg1: Int): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException])
- final def wait(arg0: Long): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws(classOf[java.lang.InterruptedException]) @native()
- def warn(pos: Global.Position, ex: Logic.PropositionalLogic.AnalysisBudget.Exception, kind: String, site: Global.Symbol): Unit
- Definition Classes
- MatchAnalyzer
- object Const
- Definition Classes
- TreesAndTypesDomain
- case object NullConst extends Const with Product with Serializable
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- object TypeConst extends TypeConstExtractor
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- object ValueConst extends ValueConstExtractor
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- object Var extends VarExtractor
- Definition Classes
- TreesAndTypesDomain → PropositionalLogic
- object Lit extends LitModule with java.io.Serializable
Deprecated Value Members
- def formatted(fmtstr: String): String
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toStringFormat[OptimizingMatchTranslator] performed by method StringFormat in scala.Predef.
- Definition Classes
- StringFormat
- Annotations
- @deprecated @inline()
- Deprecated
(Since version 2.12.16) Use
formatString.format(value)
instead ofvalue.formatted(formatString)
, or use thef""
string interpolator. In Java 15 and later,formatted
resolves to the new method in String which has reversed parameters.
- def →[B](y: B): (OptimizingMatchTranslator, B)
- Implicit
- This member is added by an implicit conversion from OptimizingMatchTranslator toArrowAssoc[OptimizingMatchTranslator] performed by method ArrowAssoc in scala.Predef.
- Definition Classes
- ArrowAssoc
- Annotations
- @deprecated
- Deprecated
(Since version 2.13.0) Use
->
instead. If you still wish to display it as one character, consider using a font with programming ligatures such as Fira Code.
The Scala compiler and reflection APIs.