# # # The Nimrod Compiler # (c) Copyright 2012 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # ## This module implements semantic checking for calls. # included from sem.nim proc sameMethodDispatcher(a, b: PSym): bool = result = false if a.kind == skMethod and b.kind == skMethod: var aa = lastSon(a.ast) var bb = lastSon(b.ast) if aa.kind == nkSym and bb.kind == nkSym and aa.sym == bb.sym: result = true proc resolveOverloads(c: PContext, n, orig: PNode, filter: TSymKinds): TCandidate = var initialBinding: PNode var f = n.sons[0] if f.kind == nkBracketExpr: # fill in the bindings: initialBinding = f f = f.sons[0] else: initialBinding = nil var o: TOverloadIter alt, z: TCandidate template best: expr = result #Message(n.info, warnUser, renderTree(n)) var sym = initOverloadIter(o, c, f) var symScope = o.lastOverloadScope if sym == nil: return initCandidate(best, sym, initialBinding, symScope) initCandidate(alt, sym, initialBinding, symScope) while sym != nil: if sym.kind in filter: initCandidate(z, sym, initialBinding, o.lastOverloadScope) z.calleeSym = sym matches(c, n, orig, z) if z.state == csMatch: # little hack so that iterators are preferred over everything else: if sym.kind == skIterator: inc(z.exactMatches, 200) case best.state of csEmpty, csNoMatch: best = z of csMatch: var cmp = cmpCandidates(best, z) if cmp < 0: best = z # x is better than the best so far elif cmp == 0: alt = z # x is as good as the best so far else: nil sym = nextOverloadIter(o, c, f) if best.state == csEmpty: # no overloaded proc found # do not generate an error yet; the semantic checking will check for # an overloaded () operator elif alt.state == csMatch and cmpCandidates(best, alt) == 0 and not sameMethodDispatcher(best.calleeSym, alt.calleeSym): if best.state != csMatch: InternalError(n.info, "x.state is not csMatch") #writeMatches(best) #writeMatches(alt) if c.inCompilesContext > 0: # quick error message for performance of 'compiles' built-in: GlobalError(n.Info, errAmbiguousCallXYZ, "") elif gErrorCounter == 0: # don't cascade errors var args = "(" for i in countup(1, sonsLen(n) - 1): if i > 1: add(args, ", ") add(args, typeToString(n.sons[i].typ)) add(args, ")") LocalError(n.Info, errGenerated, msgKindToString(errAmbiguousCallXYZ) % [ getProcHeader(best.calleeSym), getProcHeader(alt.calleeSym), args]) proc semResolvedCall(c: PContext, n: PNode, x: TCandidate): PNode = assert x.state == csMatch var finalCallee = x.calleeSym markUsed(n.sons[0], finalCallee) if finalCallee.ast == nil: internalError(n.info, "calleeSym.ast is nil") # XXX: remove this check! if finalCallee.ast.sons[genericParamsPos].kind != nkEmpty: # a generic proc! if not x.proxyMatch: finalCallee = generateInstance(c, x.calleeSym, x.bindings, n.info) else: result = x.call result.sons[0] = newSymNode(finalCallee, result.sons[0].info) result.typ = finalCallee.typ.sons[0] if ContainsGenericType(result.typ): result.typ = errorType(c) return result = x.call result.sons[0] = newSymNode(finalCallee, result.sons[0].info) result.typ = finalCallee.typ.sons[0] proc semOverloadedCall(c: PContext, n, nOrig: PNode, filter: TSymKinds): PNode = var r = resolveOverloads(c, n, nOrig, filter) if r.state == csMatch: result = semResolvedCall(c, n, r) proc explicitGenericInstError(n: PNode): PNode = LocalError(n.info, errCannotInstantiateX, renderTree(n)) result = n proc explicitGenericSym(c: PContext, n: PNode, s: PSym): PNode = var x: TCandidate initCandidate(x, s, n) var newInst = generateInstance(c, s, x.bindings, n.info) markUsed(n, s) result = newSymNode(newInst, n.info) proc explicitGenericInstantiation(c: PContext, n: PNode, s: PSym): PNode = assert n.kind == nkBracketExpr for i in 1..sonsLen(n)-1: n.sons[i].typ = semTypeNode(c, n.sons[i], nil) var s = s var a = n.sons[0] if a.kind == nkSym: # common case; check the only candidate has the right # number of generic type parameters: if safeLen(s.ast.sons[genericParamsPos]) != n.len-1: return explicitGenericInstError(n) result = explicitGenericSym(c, n, s) elif a.kind in {nkClosedSymChoice, nkOpenSymChoice}: # choose the generic proc with the proper number of type parameters. # XXX I think this could be improved by reusing sigmatch.ParamTypesMatch. # It's good enough for now. result = newNodeI(a.kind, n.info) for i in countup(0, len(a)-1): var candidate = a.sons[i].sym if candidate.kind in {skProc, skMethod, skConverter, skIterator}: # if suffices that the candidate has the proper number of generic # type parameters: if safeLen(candidate.ast.sons[genericParamsPos]) == n.len-1: result.add(explicitGenericSym(c, n, candidate)) # get rid of nkClosedSymChoice if not ambiguous: if result.len == 1 and a.kind == nkClosedSymChoice: result = result[0] # candidateCount != 1: return explicitGenericInstError(n) else: result = explicitGenericInstError(n) proc SearchForBorrowProc(c: PContext, fn: PSym, tos: int): PSym = # Searchs for the fn in the symbol table. If the parameter lists are suitable # for borrowing the sym in the symbol table is returned, else nil. # New approach: generate fn(x, y, z) where x, y, z have the proper types # and use the overloading resolution mechanism: var call = newNode(nkCall) call.add(newIdentNode(fn.name, fn.info)) for i in 1..