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- #
- #
- # The Nim Compiler
- # (c) Copyright 2020 Andreas Rumpf
- #
- # See the file "copying.txt", included in this
- # distribution, for details about the copyright.
- #
- ## New styled concepts for Nim. See https://github.com/nim-lang/RFCs/issues/168
- ## for details. Note this is a first implementation and only the "Concept matching"
- ## section has been implemented.
- import ast, semdata, lookups, lineinfos, idents, msgs, renderer, types, layeredtable
- import std/intsets
- when defined(nimPreviewSlimSystem):
- import std/assertions
- const
- logBindings = false
- ## Code dealing with Concept declarations
- ## --------------------------------------
- proc declareSelf(c: PContext; info: TLineInfo) =
- ## Adds the magical 'Self' symbols to the current scope.
- let ow = getCurrOwner(c)
- let s = newSym(skType, getIdent(c.cache, "Self"), c.idgen, ow, info)
- s.typ = newType(tyTypeDesc, c.idgen, ow)
- s.typ.flags.incl {tfUnresolved, tfPacked}
- s.typ.add newType(tyEmpty, c.idgen, ow)
- addDecl(c, s, info)
- proc semConceptDecl(c: PContext; n: PNode): PNode =
- ## Recursive helper for semantic checking for the concept declaration.
- ## Currently we only support (possibly empty) lists of statements
- ## containing 'proc' declarations and the like.
- case n.kind
- of nkStmtList, nkStmtListExpr:
- result = shallowCopy(n)
- for i in 0..<n.len:
- result[i] = semConceptDecl(c, n[i])
- of nkProcDef..nkIteratorDef, nkFuncDef:
- result = c.semExpr(c, n, {efWantStmt})
- of nkTypeClassTy:
- result = shallowCopy(n)
- for i in 0..<n.len-1:
- result[i] = n[i]
- result[^1] = semConceptDecl(c, n[^1])
- of nkCommentStmt:
- result = n
- else:
- localError(c.config, n.info, "unexpected construct in the new-styled concept: " & renderTree(n))
- result = n
- proc semConceptDeclaration*(c: PContext; n: PNode): PNode =
- ## Semantic checking for the concept declaration. Runs
- ## when we process the concept itself, not its matching process.
- assert n.kind == nkTypeClassTy
- inc c.inConceptDecl
- openScope(c)
- declareSelf(c, n.info)
- result = semConceptDecl(c, n)
- rawCloseScope(c)
- dec c.inConceptDecl
- ## Concept matching
- ## ----------------
- type
- MatchCon = object ## Context we pass around during concept matching.
- inferred: seq[(PType, PType)] ## we need a seq here so that we can easily undo inferences \
- ## that turned out to be wrong.
- marker: IntSet ## Some protection against wild runaway recursions.
- potentialImplementation: PType ## the concrete type that might match the concept we try to match.
- magic: TMagic ## mArrGet and mArrPut is wrong in system.nim and
- ## cannot be fixed that easily.
- ## Thus we special case it here.
- proc existingBinding(m: MatchCon; key: PType): PType =
- ## checks if we bound the type variable 'key' already to some
- ## concrete type.
- for i in 0..<m.inferred.len:
- if m.inferred[i][0] == key: return m.inferred[i][1]
- return nil
- proc conceptMatchNode(c: PContext; n: PNode; m: var MatchCon): bool
- proc matchType(c: PContext; f, a: PType; m: var MatchCon): bool =
- ## The heart of the concept matching process. 'f' is the formal parameter of some
- ## routine inside the concept that we're looking for. 'a' is the formal parameter
- ## of a routine that might match.
- const
- ignorableForArgType = {tyVar, tySink, tyLent, tyOwned, tyGenericInst, tyAlias, tyInferred}
- case f.kind
- of tyAlias:
- result = matchType(c, f.skipModifier, a, m)
- of tyTypeDesc:
- if isSelf(f):
- #let oldLen = m.inferred.len
- result = matchType(c, a, m.potentialImplementation, m)
- #echo "self is? ", result, " ", a.kind, " ", a, " ", m.potentialImplementation, " ", m.potentialImplementation.kind
- #m.inferred.setLen oldLen
- #echo "A for ", result, " to ", typeToString(a), " to ", typeToString(m.potentialImplementation)
- else:
- if a.kind == tyTypeDesc and f.hasElementType == a.hasElementType:
- if f.hasElementType:
- result = matchType(c, f.elementType, a.elementType, m)
- else:
- result = true # both lack it
- else:
- result = false
- of tyGenericInvocation:
- result = false
- if a.kind == tyGenericInst and a.genericHead.kind == tyGenericBody:
- if sameType(f.genericHead, a.genericHead) and f.kidsLen == a.kidsLen-1:
- for i in FirstGenericParamAt ..< f.kidsLen:
- if not matchType(c, f[i], a[i], m): return false
- return true
- of tyGenericParam:
- let ak = a.skipTypes({tyVar, tySink, tyLent, tyOwned})
- if ak.kind in {tyTypeDesc, tyStatic} and not isSelf(ak):
- result = false
- else:
- let old = existingBinding(m, f)
- if old == nil:
- if f.hasElementType and f.elementType.kind != tyNone:
- # also check the generic's constraints:
- let oldLen = m.inferred.len
- result = matchType(c, f.elementType, a, m)
- m.inferred.setLen oldLen
- if result:
- when logBindings: echo "A adding ", f, " ", ak
- m.inferred.add((f, ak))
- elif m.magic == mArrGet and ak.kind in {tyArray, tyOpenArray, tySequence, tyVarargs, tyCstring, tyString}:
- when logBindings: echo "B adding ", f, " ", lastSon ak
- m.inferred.add((f, last ak))
- result = true
- else:
- when logBindings: echo "C adding ", f, " ", ak
- m.inferred.add((f, ak))
- #echo "binding ", typeToString(ak), " to ", typeToString(f)
- result = true
- elif not m.marker.containsOrIncl(old.id):
- result = matchType(c, old, ak, m)
- if m.magic == mArrPut and ak.kind == tyGenericParam:
- result = true
- else:
- result = false
- #echo "B for ", result, " to ", typeToString(a), " to ", typeToString(m.potentialImplementation)
- of tyVar, tySink, tyLent, tyOwned:
- # modifiers in the concept must be there in the actual implementation
- # too but not vice versa.
- if a.kind == f.kind:
- result = matchType(c, f.elementType, a.elementType, m)
- elif m.magic == mArrPut:
- result = matchType(c, f.elementType, a, m)
- else:
- result = false
- of tyEnum, tyObject, tyDistinct:
- result = sameType(f, a)
- of tyEmpty, tyString, tyCstring, tyPointer, tyNil, tyUntyped, tyTyped, tyVoid:
- result = a.skipTypes(ignorableForArgType).kind == f.kind
- of tyBool, tyChar, tyInt..tyUInt64:
- let ak = a.skipTypes(ignorableForArgType)
- result = ak.kind == f.kind or ak.kind == tyOrdinal or
- (ak.kind == tyGenericParam and ak.hasElementType and ak.elementType.kind == tyOrdinal)
- of tyConcept:
- let oldLen = m.inferred.len
- let oldPotentialImplementation = m.potentialImplementation
- m.potentialImplementation = a
- result = conceptMatchNode(c, f.n.lastSon, m)
- m.potentialImplementation = oldPotentialImplementation
- if not result:
- m.inferred.setLen oldLen
- of tyArray, tyTuple, tyVarargs, tyOpenArray, tyRange, tySequence, tyRef, tyPtr,
- tyGenericInst:
- # ^ XXX Rewrite this logic, it's more complex than it needs to be.
- result = false
- let ak = a.skipTypes(ignorableForArgType - {f.kind})
- if ak.kind == f.kind and f.kidsLen == ak.kidsLen:
- for i in 0..<ak.kidsLen:
- if not matchType(c, f[i], ak[i], m): return false
- return true
- of tyOr:
- let oldLen = m.inferred.len
- if a.kind == tyOr:
- # say the concept requires 'int|float|string' if the potentialImplementation
- # says 'int|string' that is good enough.
- var covered = 0
- for ff in f.kids:
- for aa in a.kids:
- let oldLenB = m.inferred.len
- let r = matchType(c, ff, aa, m)
- if r:
- inc covered
- break
- m.inferred.setLen oldLenB
- result = covered >= a.kidsLen
- if not result:
- m.inferred.setLen oldLen
- else:
- result = false
- for ff in f.kids:
- result = matchType(c, ff, a, m)
- if result: break # and remember the binding!
- m.inferred.setLen oldLen
- of tyNot:
- if a.kind == tyNot:
- result = matchType(c, f.elementType, a.elementType, m)
- else:
- let oldLen = m.inferred.len
- result = not matchType(c, f.elementType, a, m)
- m.inferred.setLen oldLen
- of tyAnything:
- result = true
- of tyOrdinal:
- result = isOrdinalType(a, allowEnumWithHoles = false) or a.kind == tyGenericParam
- else:
- result = false
- proc matchReturnType(c: PContext; f, a: PType; m: var MatchCon): bool =
- ## Like 'matchType' but with extra logic dealing with proc return types
- ## which can be nil or the 'void' type.
- if f.isEmptyType:
- result = a.isEmptyType
- elif a == nil:
- result = false
- else:
- result = matchType(c, f, a, m)
- proc matchSym(c: PContext; candidate: PSym, n: PNode; m: var MatchCon): bool =
- ## Checks if 'candidate' matches 'n' from the concept body. 'n' is a nkProcDef
- ## or similar.
- # watch out: only add bindings after a completely successful match.
- let oldLen = m.inferred.len
- let can = candidate.typ.n
- let con = n[0].sym.typ.n
- if can.len < con.len:
- # too few arguments, cannot be a match:
- return false
- let common = min(can.len, con.len)
- for i in 1 ..< common:
- if not matchType(c, con[i].typ, can[i].typ, m):
- m.inferred.setLen oldLen
- return false
- if not matchReturnType(c, n[0].sym.typ.returnType, candidate.typ.returnType, m):
- m.inferred.setLen oldLen
- return false
- # all other parameters have to be optional parameters:
- for i in common ..< can.len:
- assert can[i].kind == nkSym
- if can[i].sym.ast == nil:
- # has too many arguments one of which is not optional:
- m.inferred.setLen oldLen
- return false
- return true
- proc matchSyms(c: PContext, n: PNode; kinds: set[TSymKind]; m: var MatchCon): bool =
- ## Walk the current scope, extract candidates which the same name as 'n[namePos]',
- ## 'n' is the nkProcDef or similar from the concept that we try to match.
- let candidates = searchInScopesAllCandidatesFilterBy(c, n[namePos].sym.name, kinds)
- for candidate in candidates:
- #echo "considering ", typeToString(candidate.typ), " ", candidate.magic
- m.magic = candidate.magic
- if matchSym(c, candidate, n, m): return true
- result = false
- proc conceptMatchNode(c: PContext; n: PNode; m: var MatchCon): bool =
- ## Traverse the concept's AST ('n') and see if every declaration inside 'n'
- ## can be matched with the current scope.
- case n.kind
- of nkStmtList, nkStmtListExpr:
- for i in 0..<n.len:
- if not conceptMatchNode(c, n[i], m):
- return false
- return true
- of nkProcDef, nkFuncDef:
- # procs match any of: proc, template, macro, func, method, converter.
- # The others are more specific.
- # XXX: Enforce .noSideEffect for 'nkFuncDef'? But then what are the use cases...
- const filter = {skProc, skTemplate, skMacro, skFunc, skMethod, skConverter}
- result = matchSyms(c, n, filter, m)
- of nkTemplateDef:
- result = matchSyms(c, n, {skTemplate}, m)
- of nkMacroDef:
- result = matchSyms(c, n, {skMacro}, m)
- of nkConverterDef:
- result = matchSyms(c, n, {skConverter}, m)
- of nkMethodDef:
- result = matchSyms(c, n, {skMethod}, m)
- of nkIteratorDef:
- result = matchSyms(c, n, {skIterator}, m)
- of nkCommentStmt:
- result = true
- else:
- # error was reported earlier.
- result = false
- proc conceptMatch*(c: PContext; concpt, arg: PType; bindings: var LayeredIdTable; invocation: PType): bool =
- ## Entry point from sigmatch. 'concpt' is the concept we try to match (here still a PType but
- ## we extract its AST via 'concpt.n.lastSon'). 'arg' is the type that might fulfill the
- ## concept's requirements. If so, we return true and fill the 'bindings' with pairs of
- ## (typeVar, instance) pairs. ('typeVar' is usually simply written as a generic 'T'.)
- ## 'invocation' can be nil for atomic concepts. For non-atomic concepts, it contains the
- ## `C[S, T]` parent type that we look for. We need this because we need to store bindings
- ## for 'S' and 'T' inside 'bindings' on a successful match. It is very important that
- ## we do not add any bindings at all on an unsuccessful match!
- var m = MatchCon(inferred: @[], potentialImplementation: arg)
- result = conceptMatchNode(c, concpt.n.lastSon, m)
- if result:
- for (a, b) in m.inferred:
- if b.kind == tyGenericParam:
- var dest = b
- while true:
- dest = existingBinding(m, dest)
- if dest == nil or dest.kind != tyGenericParam: break
- if dest != nil:
- bindings.put(a, dest)
- when logBindings: echo "A bind ", a, " ", dest
- else:
- bindings.put(a, b)
- when logBindings: echo "B bind ", a, " ", b
- # we have a match, so bind 'arg' itself to 'concpt':
- bindings.put(concpt, arg)
- # invocation != nil means we have a non-atomic concept:
- if invocation != nil and arg.kind == tyGenericInst and invocation.kidsLen == arg.kidsLen-1:
- # bind even more generic parameters
- assert invocation.kind == tyGenericInvocation
- for i in FirstGenericParamAt ..< invocation.kidsLen:
- bindings.put(invocation[i], arg[i])
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