# # # The Nim Compiler # (c) Copyright 2013 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # # this module does the semantic checking for expressions # included from sem.nim proc semTemplateExpr(c: PContext, n: PNode, s: PSym, flags: TExprFlags = {}): PNode = markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) pushInfoContext(n.info) result = evalTemplate(n, s, getCurrOwner(c), efFromHlo in flags) if efNoSemCheck notin flags: result = semAfterMacroCall(c, n, result, s, flags) popInfoContext() proc semFieldAccess(c: PContext, n: PNode, flags: TExprFlags = {}): PNode proc semOperand(c: PContext, n: PNode, flags: TExprFlags = {}): PNode = # same as 'semExprWithType' but doesn't check for proc vars result = semExpr(c, n, flags + {efOperand}) #if result.kind == nkEmpty and result.typ.isNil: # do not produce another redundant error message: #raiseRecoverableError("") # result = errorNode(c, n) if result.typ != nil: # XXX tyGenericInst here? if result.typ.kind == tyProc and tfUnresolved in result.typ.flags: localError(n.info, errProcHasNoConcreteType, n.renderTree) if result.typ.kind in {tyVar, tyLent}: result = newDeref(result) elif {efWantStmt, efAllowStmt} * flags != {}: result.typ = newTypeS(tyVoid, c) else: localError(n.info, errExprXHasNoType, renderTree(result, {renderNoComments})) result.typ = errorType(c) proc semExprWithType(c: PContext, n: PNode, flags: TExprFlags = {}): PNode = result = semExpr(c, n, flags+{efWantValue}) if result.isNil or result.kind == nkEmpty: # do not produce another redundant error message: #raiseRecoverableError("") result = errorNode(c, n) if result.typ == nil or result.typ == enforceVoidContext: localError(n.info, errExprXHasNoType, renderTree(result, {renderNoComments})) result.typ = errorType(c) else: if efNoProcvarCheck notin flags: semProcvarCheck(c, result) if result.typ.kind in {tyVar, tyLent}: result = newDeref(result) proc semExprNoDeref(c: PContext, n: PNode, flags: TExprFlags = {}): PNode = result = semExpr(c, n, flags) if result.kind == nkEmpty: # do not produce another redundant error message: result = errorNode(c, n) if result.typ == nil: localError(n.info, errExprXHasNoType, renderTree(result, {renderNoComments})) result.typ = errorType(c) else: semProcvarCheck(c, result) proc semSymGenericInstantiation(c: PContext, n: PNode, s: PSym): PNode = result = symChoice(c, n, s, scClosed) proc inlineConst(n: PNode, s: PSym): PNode {.inline.} = result = copyTree(s.ast) if result.isNil: localError(n.info, "constant of type '" & typeToString(s.typ) & "' has no value") result = newSymNode(s) else: result.typ = s.typ result.info = n.info type TConvStatus = enum convOK, convNotNeedeed, convNotLegal proc checkConversionBetweenObjects(castDest, src: PType; pointers: int): TConvStatus = let diff = inheritanceDiff(castDest, src) return if diff == high(int) or (pointers > 1 and diff != 0): convNotLegal else: convOK const IntegralTypes = {tyBool, tyEnum, tyChar, tyInt..tyUInt64} proc checkConvertible(c: PContext, castDest, src: PType): TConvStatus = result = convOK if sameType(castDest, src) and castDest.sym == src.sym: # don't annoy conversions that may be needed on another processor: if castDest.kind notin IntegralTypes+{tyRange}: result = convNotNeedeed return var d = skipTypes(castDest, abstractVar) var s = src if s.kind in tyUserTypeClasses and s.isResolvedUserTypeClass: s = s.lastSon s = skipTypes(s, abstractVar-{tyTypeDesc}) var pointers = 0 while (d != nil) and (d.kind in {tyPtr, tyRef}) and (d.kind == s.kind): d = d.lastSon s = s.lastSon inc pointers if d == nil: result = convNotLegal elif d.kind == tyObject and s.kind == tyObject: result = checkConversionBetweenObjects(d, s, pointers) elif (skipTypes(castDest, abstractVarRange).kind in IntegralTypes) and (skipTypes(src, abstractVarRange-{tyTypeDesc}).kind in IntegralTypes): # accept conversion between integral types discard else: # we use d, s here to speed up that operation a bit: case cmpTypes(c, d, s) of isNone, isGeneric: if not compareTypes(castDest, src, dcEqIgnoreDistinct): result = convNotLegal else: discard proc isCastable(dst, src: PType): bool = ## Checks whether the source type can be cast to the destination type. ## Casting is very unrestrictive; casts are allowed as long as ## castDest.size >= src.size, and typeAllowed(dst, skParam) #const # castableTypeKinds = {tyInt, tyPtr, tyRef, tyCstring, tyString, # tySequence, tyPointer, tyNil, tyOpenArray, # tyProc, tySet, tyEnum, tyBool, tyChar} let src = src.skipTypes(tyUserTypeClasses) if skipTypes(dst, abstractInst-{tyOpenArray}).kind == tyOpenArray: return false if skipTypes(src, abstractInst-{tyTypeDesc}).kind == tyTypeDesc: return false var dstSize, srcSize: BiggestInt dstSize = computeSize(dst) srcSize = computeSize(src) if dstSize < 0: result = false elif srcSize < 0: result = false elif typeAllowed(dst, skParam) != nil: result = false elif dst.kind == tyProc and dst.callConv == ccClosure: result = src.kind == tyProc and src.callConv == ccClosure else: result = (dstSize >= srcSize) or (skipTypes(dst, abstractInst).kind in IntegralTypes) or (skipTypes(src, abstractInst-{tyTypeDesc}).kind in IntegralTypes) if result and src.kind == tyNil: result = dst.size <= platform.ptrSize proc isSymChoice(n: PNode): bool {.inline.} = result = n.kind in nkSymChoices proc maybeLiftType(t: var PType, c: PContext, info: TLineInfo) = # XXX: liftParamType started to perform addDecl # we could do that instead in semTypeNode by snooping for added # gnrc. params, then it won't be necessary to open a new scope here openScope(c) var lifted = liftParamType(c, skType, newNodeI(nkArgList, info), t, ":anon", info) closeScope(c) if lifted != nil: t = lifted proc semConv(c: PContext, n: PNode): PNode = if sonsLen(n) != 2: localError(n.info, errConvNeedsOneArg) return n result = newNodeI(nkConv, n.info) var targetType = semTypeNode(c, n.sons[0], nil).skipTypes({tyTypeDesc}) maybeLiftType(targetType, c, n[0].info) if targetType.kind in {tySink, tyLent}: let baseType = semTypeNode(c, n.sons[1], nil).skipTypes({tyTypeDesc}) let t = newTypeS(targetType.kind, c) t.rawAddSonNoPropagationOfTypeFlags baseType result = newNodeI(nkType, n.info) result.typ = makeTypeDesc(c, t) return result.addSon copyTree(n.sons[0]) var op = semExprWithType(c, n.sons[1]) if targetType.isMetaType: let final = inferWithMetatype(c, targetType, op, true) result.addSon final result.typ = final.typ return result.typ = targetType # XXX op is overwritten later on, this is likely added too early # here or needs to be overwritten too then. addSon(result, op) if not isSymChoice(op): let status = checkConvertible(c, result.typ, op.typ) case status of convOK: # handle SomeProcType(SomeGenericProc) if op.kind == nkSym and op.sym.isGenericRoutine: result.sons[1] = fitNode(c, result.typ, result.sons[1], result.info) elif op.kind == nkPar and targetType.kind == tyTuple: op = fitNode(c, targetType, op, result.info) of convNotNeedeed: message(n.info, hintConvFromXtoItselfNotNeeded, result.typ.typeToString) of convNotLegal: result = fitNode(c, result.typ, result.sons[1], result.info) if result == nil: localError(n.info, errGenerated, msgKindToString(errIllegalConvFromXtoY)% [op.typ.typeToString, result.typ.typeToString]) else: for i in countup(0, sonsLen(op) - 1): let it = op.sons[i] let status = checkConvertible(c, result.typ, it.typ) if status in {convOK, convNotNeedeed}: markUsed(n.info, it.sym, c.graph.usageSym) styleCheckUse(n.info, it.sym) markIndirect(c, it.sym) return it errorUseQualifier(c, n.info, op.sons[0].sym) proc semCast(c: PContext, n: PNode): PNode = ## Semantically analyze a casting ("cast[type](param)") checkSonsLen(n, 2) let targetType = semTypeNode(c, n.sons[0], nil) let castedExpr = semExprWithType(c, n.sons[1]) if tfHasMeta in targetType.flags: localError(n.sons[0].info, errCastToANonConcreteType, $targetType) if not isCastable(targetType, castedExpr.typ): let tar = $targetType let alt = typeToString(targetType, preferDesc) let msg = if tar != alt: tar & "=" & alt else: tar localError(n.info, errExprCannotBeCastToX, msg) result = newNodeI(nkCast, n.info) result.typ = targetType addSon(result, copyTree(n.sons[0])) addSon(result, castedExpr) proc semLowHigh(c: PContext, n: PNode, m: TMagic): PNode = const opToStr: array[mLow..mHigh, string] = ["low", "high"] if sonsLen(n) != 2: localError(n.info, errXExpectsTypeOrValue, opToStr[m]) else: n.sons[1] = semExprWithType(c, n.sons[1], {efDetermineType}) var typ = skipTypes(n.sons[1].typ, abstractVarRange + {tyTypeDesc}) case typ.kind of tySequence, tyString, tyCString, tyOpenArray, tyVarargs: n.typ = getSysType(tyInt) of tyArray: n.typ = typ.sons[0] # indextype of tyInt..tyInt64, tyChar, tyBool, tyEnum, tyUInt8, tyUInt16, tyUInt32: # do not skip the range! n.typ = n.sons[1].typ.skipTypes(abstractVar) of tyGenericParam: # prepare this for resolving in semtypinst: # we must use copyTree here in order to avoid creating a cycle # that could easily turn into an infinite recursion in semtypinst n.typ = makeTypeFromExpr(c, n.copyTree) else: localError(n.info, errInvalidArgForX, opToStr[m]) result = n proc semSizeof(c: PContext, n: PNode): PNode = if sonsLen(n) != 2: localError(n.info, errXExpectsTypeOrValue, "sizeof") else: n.sons[1] = semExprWithType(c, n.sons[1], {efDetermineType}) #restoreOldStyleType(n.sons[1]) n.typ = getSysType(tyInt) result = n proc isOpImpl(c: PContext, n: PNode, flags: TExprFlags): PNode = internalAssert n.sonsLen == 3 and n[1].typ != nil and n[1].typ.kind == tyTypeDesc and n[2].kind in {nkStrLit..nkTripleStrLit, nkType} let t1 = n[1].typ.skipTypes({tyTypeDesc}) if n[2].kind in {nkStrLit..nkTripleStrLit}: case n[2].strVal.normalize of "closure": let t = skipTypes(t1, abstractRange) result = newIntNode(nkIntLit, ord(t.kind == tyProc and t.callConv == ccClosure and tfIterator notin t.flags)) else: result = newIntNode(nkIntLit, 0) else: var rhsOrigType = n[2].typ var t2 = rhsOrigType.skipTypes({tyTypeDesc}) maybeLiftType(t2, c, n.info) var m: TCandidate initCandidate(c, m, t2) if efExplain in flags: m.diagnostics = @[] let match = typeRel(m, t2, t1) >= isSubtype # isNone result = newIntNode(nkIntLit, ord(match)) result.typ = n.typ proc semIs(c: PContext, n: PNode, flags: TExprFlags): PNode = if sonsLen(n) != 3: localError(n.info, errXExpectsTwoArguments, "is") result = n n.typ = getSysType(tyBool) n.sons[1] = semExprWithType(c, n[1], {efDetermineType, efWantIterator}) if n[2].kind notin {nkStrLit..nkTripleStrLit}: let t2 = semTypeNode(c, n[2], nil) n.sons[2] = newNodeIT(nkType, n[2].info, t2) let lhsType = n[1].typ if lhsType.kind != tyTypeDesc: n.sons[1] = makeTypeSymNode(c, lhsType, n[1].info) elif lhsType.base.kind == tyNone: # this is a typedesc variable, leave for evals return # BUGFIX: don't evaluate this too early: ``T is void`` if not n[1].typ.base.containsGenericType: result = isOpImpl(c, n, flags) proc semOpAux(c: PContext, n: PNode) = const flags = {efDetermineType} for i in countup(1, n.sonsLen-1): var a = n.sons[i] if a.kind == nkExprEqExpr and sonsLen(a) == 2: var info = a.sons[0].info a.sons[0] = newIdentNode(considerQuotedIdent(a.sons[0], a), info) a.sons[1] = semExprWithType(c, a.sons[1], flags) a.typ = a.sons[1].typ else: n.sons[i] = semExprWithType(c, a, flags) proc overloadedCallOpr(c: PContext, n: PNode): PNode = # quick check if there is *any* () operator overloaded: var par = getIdent("()") if searchInScopes(c, par) == nil: result = nil else: result = newNodeI(nkCall, n.info) addSon(result, newIdentNode(par, n.info)) for i in countup(0, sonsLen(n) - 1): addSon(result, n.sons[i]) result = semExpr(c, result) proc changeType(n: PNode, newType: PType, check: bool) = case n.kind of nkCurly, nkBracket: for i in countup(0, sonsLen(n) - 1): changeType(n.sons[i], elemType(newType), check) of nkPar: let tup = newType.skipTypes({tyGenericInst, tyAlias, tySink}) if tup.kind != tyTuple: if tup.kind == tyObject: return globalError(n.info, "no tuple type for constructor") elif sonsLen(n) > 0 and n.sons[0].kind == nkExprColonExpr: # named tuple? for i in countup(0, sonsLen(n) - 1): var m = n.sons[i].sons[0] if m.kind != nkSym: globalError(m.info, "invalid tuple constructor") return if tup.n != nil: var f = getSymFromList(tup.n, m.sym.name) if f == nil: globalError(m.info, "unknown identifier: " & m.sym.name.s) return changeType(n.sons[i].sons[1], f.typ, check) else: changeType(n.sons[i].sons[1], tup.sons[i], check) else: for i in countup(0, sonsLen(n) - 1): changeType(n.sons[i], tup.sons[i], check) when false: var m = n.sons[i] var a = newNodeIT(nkExprColonExpr, m.info, newType.sons[i]) addSon(a, newSymNode(newType.n.sons[i].sym)) addSon(a, m) changeType(m, tup.sons[i], check) of nkCharLit..nkUInt64Lit: if check and n.kind != nkUInt64Lit: let value = n.intVal if value < firstOrd(newType) or value > lastOrd(newType): localError(n.info, errGenerated, "cannot convert " & $value & " to " & typeToString(newType)) else: discard n.typ = newType proc arrayConstrType(c: PContext, n: PNode): PType = var typ = newTypeS(tyArray, c) rawAddSon(typ, nil) # index type if sonsLen(n) == 0: rawAddSon(typ, newTypeS(tyEmpty, c)) # needs an empty basetype! else: var t = skipTypes(n.sons[0].typ, {tyGenericInst, tyVar, tyLent, tyOrdinal, tyAlias, tySink}) addSonSkipIntLit(typ, t) typ.sons[0] = makeRangeType(c, 0, sonsLen(n) - 1, n.info) result = typ proc semArrayConstr(c: PContext, n: PNode, flags: TExprFlags): PNode = result = newNodeI(nkBracket, n.info) result.typ = newTypeS(tyArray, c) rawAddSon(result.typ, nil) # index type if sonsLen(n) == 0: rawAddSon(result.typ, newTypeS(tyEmpty, c)) # needs an empty basetype! else: var x = n.sons[0] var lastIndex: BiggestInt = 0 var indexType = getSysType(tyInt) if x.kind == nkExprColonExpr and sonsLen(x) == 2: var idx = semConstExpr(c, x.sons[0]) lastIndex = getOrdValue(idx) indexType = idx.typ x = x.sons[1] let yy = semExprWithType(c, x) var typ = yy.typ addSon(result, yy) #var typ = skipTypes(result.sons[0].typ, {tyGenericInst, tyVar, tyLent, tyOrdinal}) for i in countup(1, sonsLen(n) - 1): x = n.sons[i] if x.kind == nkExprColonExpr and sonsLen(x) == 2: var idx = semConstExpr(c, x.sons[0]) idx = fitNode(c, indexType, idx, x.info) if lastIndex+1 != getOrdValue(idx): localError(x.info, errInvalidOrderInArrayConstructor) x = x.sons[1] let xx = semExprWithType(c, x, flags*{efAllowDestructor}) result.add xx typ = commonType(typ, xx.typ) #n.sons[i] = semExprWithType(c, x, flags*{efAllowDestructor}) #addSon(result, fitNode(c, typ, n.sons[i])) inc(lastIndex) addSonSkipIntLit(result.typ, typ) for i in 0 ..< result.len: result.sons[i] = fitNode(c, typ, result.sons[i], result.sons[i].info) result.typ.sons[0] = makeRangeType(c, 0, sonsLen(result) - 1, n.info) proc fixAbstractType(c: PContext, n: PNode) = for i in 1 ..< n.len: let it = n.sons[i] # do not get rid of nkHiddenSubConv for OpenArrays, the codegen needs it: if it.kind == nkHiddenSubConv and skipTypes(it.typ, abstractVar).kind notin {tyOpenArray, tyVarargs}: if skipTypes(it.sons[1].typ, abstractVar).kind in {tyNil, tyTuple, tySet} or it[1].isArrayConstr: var s = skipTypes(it.typ, abstractVar) if s.kind != tyExpr: changeType(it.sons[1], s, check=true) n.sons[i] = it.sons[1] proc isAssignable(c: PContext, n: PNode; isUnsafeAddr=false): TAssignableResult = result = parampatterns.isAssignable(c.p.owner, n, isUnsafeAddr) proc newHiddenAddrTaken(c: PContext, n: PNode): PNode = if n.kind == nkHiddenDeref and not (gCmd == cmdCompileToCpp or sfCompileToCpp in c.module.flags): checkSonsLen(n, 1) result = n.sons[0] else: result = newNodeIT(nkHiddenAddr, n.info, makeVarType(c, n.typ)) addSon(result, n) if isAssignable(c, n) notin {arLValue, arLocalLValue}: localError(n.info, errVarForOutParamNeededX, $n) proc analyseIfAddressTaken(c: PContext, n: PNode): PNode = result = n case n.kind of nkSym: # n.sym.typ can be nil in 'check' mode ... if n.sym.typ != nil and skipTypes(n.sym.typ, abstractInst-{tyTypeDesc}).kind notin {tyVar, tyLent}: incl(n.sym.flags, sfAddrTaken) result = newHiddenAddrTaken(c, n) of nkDotExpr: checkSonsLen(n, 2) if n.sons[1].kind != nkSym: internalError(n.info, "analyseIfAddressTaken") return if skipTypes(n.sons[1].sym.typ, abstractInst-{tyTypeDesc}).kind notin {tyVar, tyLent}: incl(n.sons[1].sym.flags, sfAddrTaken) result = newHiddenAddrTaken(c, n) of nkBracketExpr: checkMinSonsLen(n, 1) if skipTypes(n.sons[0].typ, abstractInst-{tyTypeDesc}).kind notin {tyVar, tyLent}: if n.sons[0].kind == nkSym: incl(n.sons[0].sym.flags, sfAddrTaken) result = newHiddenAddrTaken(c, n) else: result = newHiddenAddrTaken(c, n) proc analyseIfAddressTakenInCall(c: PContext, n: PNode) = checkMinSonsLen(n, 1) const FakeVarParams = {mNew, mNewFinalize, mInc, ast.mDec, mIncl, mExcl, mSetLengthStr, mSetLengthSeq, mAppendStrCh, mAppendStrStr, mSwap, mAppendSeqElem, mNewSeq, mReset, mShallowCopy, mDeepCopy} # get the real type of the callee # it may be a proc var with a generic alias type, so we skip over them var t = n.sons[0].typ.skipTypes({tyGenericInst, tyAlias, tySink}) if n.sons[0].kind == nkSym and n.sons[0].sym.magic in FakeVarParams: # BUGFIX: check for L-Value still needs to be done for the arguments! # note sometimes this is eval'ed twice so we check for nkHiddenAddr here: for i in countup(1, sonsLen(n) - 1): if i < sonsLen(t) and t.sons[i] != nil and skipTypes(t.sons[i], abstractInst-{tyTypeDesc}).kind == tyVar: let it = n[i] if isAssignable(c, it) notin {arLValue, arLocalLValue}: if it.kind != nkHiddenAddr: localError(it.info, errVarForOutParamNeededX, $it) return for i in countup(1, sonsLen(n) - 1): if n.sons[i].kind == nkHiddenCallConv: # we need to recurse explicitly here as converters can create nested # calls and then they wouldn't be analysed otherwise analyseIfAddressTakenInCall(c, n.sons[i]) semProcvarCheck(c, n.sons[i]) if i < sonsLen(t) and skipTypes(t.sons[i], abstractInst-{tyTypeDesc}).kind == tyVar: if n.sons[i].kind != nkHiddenAddr: n.sons[i] = analyseIfAddressTaken(c, n.sons[i]) include semmagic proc evalAtCompileTime(c: PContext, n: PNode): PNode = result = n if n.kind notin nkCallKinds or n.sons[0].kind != nkSym: return var callee = n.sons[0].sym # workaround for bug #537 (overly aggressive inlining leading to # wrong NimNode semantics): if n.typ != nil and tfTriggersCompileTime in n.typ.flags: return # constant folding that is necessary for correctness of semantic pass: if callee.magic != mNone and callee.magic in ctfeWhitelist and n.typ != nil: var call = newNodeIT(nkCall, n.info, n.typ) call.add(n.sons[0]) var allConst = true for i in 1 ..< n.len: var a = getConstExpr(c.module, n.sons[i]) if a == nil: allConst = false a = n.sons[i] if a.kind == nkHiddenStdConv: a = a.sons[1] call.add(a) if allConst: result = semfold.getConstExpr(c.module, call) if result.isNil: result = n else: return result block maybeLabelAsStatic: # XXX: temporary work-around needed for tlateboundstatic. # This is certainly not correct, but it will get the job # done until we have a more robust infrastructure for # implicit statics. if n.len > 1: for i in 1 ..< n.len: # see bug #2113, it's possible that n[i].typ for errornous code: if n[i].typ.isNil or n[i].typ.kind != tyStatic or tfUnresolved notin n[i].typ.flags: break maybeLabelAsStatic n.typ = newTypeWithSons(c, tyStatic, @[n.typ]) n.typ.flags.incl tfUnresolved # optimization pass: not necessary for correctness of the semantic pass if {sfNoSideEffect, sfCompileTime} * callee.flags != {} and {sfForward, sfImportc} * callee.flags == {} and n.typ != nil: if sfCompileTime notin callee.flags and optImplicitStatic notin gOptions: return if callee.magic notin ctfeWhitelist: return if callee.kind notin {skProc, skFunc, skConverter} or callee.isGenericRoutine: return if n.typ != nil and typeAllowed(n.typ, skConst) != nil: return var call = newNodeIT(nkCall, n.info, n.typ) call.add(n.sons[0]) for i in 1 ..< n.len: let a = getConstExpr(c.module, n.sons[i]) if a == nil: return n call.add(a) #echo "NOW evaluating at compile time: ", call.renderTree if sfCompileTime in callee.flags: result = evalStaticExpr(c.module, c.cache, call, c.p.owner) if result.isNil: localError(n.info, errCannotInterpretNodeX, renderTree(call)) else: result = fixupTypeAfterEval(c, result, n) else: result = evalConstExpr(c.module, c.cache, call) if result.isNil: result = n else: result = fixupTypeAfterEval(c, result, n) #if result != n: # echo "SUCCESS evaluated at compile time: ", call.renderTree proc semStaticExpr(c: PContext, n: PNode): PNode = let a = semExpr(c, n.sons[0]) if a.findUnresolvedStatic != nil: return a result = evalStaticExpr(c.module, c.cache, a, c.p.owner) if result.isNil: localError(n.info, errCannotInterpretNodeX, renderTree(n)) result = emptyNode else: result = fixupTypeAfterEval(c, result, a) proc semOverloadedCallAnalyseEffects(c: PContext, n: PNode, nOrig: PNode, flags: TExprFlags): PNode = if flags*{efInTypeof, efWantIterator} != {}: # consider: 'for x in pReturningArray()' --> we don't want the restriction # to 'skIterator' anymore; skIterator is preferred in sigmatch already # for typeof support. # for ``type(countup(1,3))``, see ``tests/ttoseq``. result = semOverloadedCall(c, n, nOrig, {skProc, skFunc, skMethod, skConverter, skMacro, skTemplate, skIterator}, flags) else: result = semOverloadedCall(c, n, nOrig, {skProc, skFunc, skMethod, skConverter, skMacro, skTemplate}, flags) if result != nil: if result.sons[0].kind != nkSym: internalError("semOverloadedCallAnalyseEffects") return let callee = result.sons[0].sym case callee.kind of skMacro, skTemplate: discard else: if callee.kind == skIterator and callee.id == c.p.owner.id: localError(n.info, errRecursiveDependencyX, callee.name.s) # error correction, prevents endless for loop elimination in transf. # See bug #2051: result.sons[0] = newSymNode(errorSym(c, n)) proc semObjConstr(c: PContext, n: PNode, flags: TExprFlags): PNode proc resolveIndirectCall(c: PContext; n, nOrig: PNode; t: PType): TCandidate = initCandidate(c, result, t) matches(c, n, nOrig, result) if result.state != csMatch: # try to deref the first argument: if experimentalMode(c) and canDeref(n): n.sons[1] = n.sons[1].tryDeref initCandidate(c, result, t) matches(c, n, nOrig, result) proc bracketedMacro(n: PNode): PSym = if n.len >= 1 and n[0].kind == nkSym: result = n[0].sym if result.kind notin {skMacro, skTemplate}: result = nil proc setGenericParams(c: PContext, n: PNode) = for i in 1 ..< n.len: n[i].typ = semTypeNode(c, n[i], nil) proc afterCallActions(c: PContext; n, orig: PNode, flags: TExprFlags): PNode = result = n let callee = result.sons[0].sym case callee.kind of skMacro: result = semMacroExpr(c, result, orig, callee, flags) of skTemplate: result = semTemplateExpr(c, result, callee, flags) else: semFinishOperands(c, result) activate(c, result) fixAbstractType(c, result) analyseIfAddressTakenInCall(c, result) if callee.magic != mNone: result = magicsAfterOverloadResolution(c, result, flags) if result.typ != nil: liftTypeBoundOps(c, result.typ, n.info) #result = patchResolvedTypeBoundOp(c, result) if c.matchedConcept == nil: result = evalAtCompileTime(c, result) proc semIndirectOp(c: PContext, n: PNode, flags: TExprFlags): PNode = result = nil checkMinSonsLen(n, 1) var prc = n.sons[0] if n.sons[0].kind == nkDotExpr: checkSonsLen(n.sons[0], 2) let n0 = semFieldAccess(c, n.sons[0]) if n0.kind == nkDotCall: # it is a static call! result = n0 result.kind = nkCall result.flags.incl nfExplicitCall for i in countup(1, sonsLen(n) - 1): addSon(result, n.sons[i]) return semExpr(c, result, flags) else: n.sons[0] = n0 else: n.sons[0] = semExpr(c, n.sons[0], {efInCall}) let t = n.sons[0].typ if t != nil and t.kind in {tyVar, tyLent}: n.sons[0] = newDeref(n.sons[0]) elif n.sons[0].kind == nkBracketExpr: let s = bracketedMacro(n.sons[0]) if s != nil: setGenericParams(c, n[0]) return semDirectOp(c, n, flags) let nOrig = n.copyTree semOpAux(c, n) var t: PType = nil if n.sons[0].typ != nil: t = skipTypes(n.sons[0].typ, abstractInst-{tyTypeDesc}) if t != nil and t.kind == tyProc: # This is a proc variable, apply normal overload resolution let m = resolveIndirectCall(c, n, nOrig, t) if m.state != csMatch: if errorOutputs == {}: # speed up error generation: globalError(n.info, errTypeMismatch, "") return emptyNode else: var hasErrorType = false var msg = msgKindToString(errTypeMismatch) for i in countup(1, sonsLen(n) - 1): if i > 1: add(msg, ", ") let nt = n.sons[i].typ add(msg, typeToString(nt)) if nt.kind == tyError: hasErrorType = true break if not hasErrorType: add(msg, ")\n" & msgKindToString(errButExpected) & "\n" & typeToString(n.sons[0].typ)) localError(n.info, errGenerated, msg) return errorNode(c, n) result = nil else: result = m.call instGenericConvertersSons(c, result, m) elif t != nil and t.kind == tyTypeDesc: if n.len == 1: return semObjConstr(c, n, flags) return semConv(c, n) else: result = overloadedCallOpr(c, n) # Now that nkSym does not imply an iteration over the proc/iterator space, # the old ``prc`` (which is likely an nkIdent) has to be restored: if result == nil: # XXX: hmm, what kind of symbols will end up here? # do we really need to try the overload resolution? n.sons[0] = prc nOrig.sons[0] = prc n.flags.incl nfExprCall result = semOverloadedCallAnalyseEffects(c, n, nOrig, flags) if result == nil: return errorNode(c, n) elif result.kind notin nkCallKinds: # the semExpr() in overloadedCallOpr can even break this condition! # See bug #904 of how to trigger it: return result #result = afterCallActions(c, result, nOrig, flags) if result.sons[0].kind == nkSym: result = afterCallActions(c, result, nOrig, flags) else: fixAbstractType(c, result) analyseIfAddressTakenInCall(c, result) proc semDirectOp(c: PContext, n: PNode, flags: TExprFlags): PNode = # this seems to be a hotspot in the compiler! let nOrig = n.copyTree #semLazyOpAux(c, n) result = semOverloadedCallAnalyseEffects(c, n, nOrig, flags) if result != nil: result = afterCallActions(c, result, nOrig, flags) else: result = errorNode(c, n) proc buildEchoStmt(c: PContext, n: PNode): PNode = # we MUST not check 'n' for semantics again here! But for now we give up: result = newNodeI(nkCall, n.info) var e = strTableGet(magicsys.systemModule.tab, getIdent"echo") if e != nil: add(result, newSymNode(e)) else: localError(n.info, errSystemNeeds, "echo") add(result, errorNode(c, n)) add(result, n) result = semExpr(c, result) proc semExprNoType(c: PContext, n: PNode): PNode = result = semExpr(c, n, {efWantStmt}) # make an 'if' expression an 'if' statement again for backwards # compatibility (.discardable was a bad idea!); bug #6980 var isStmt = false if result.kind == nkIfExpr: isStmt = true for condActionPair in result: let action = condActionPair.lastSon if not implicitlyDiscardable(action) and not endsInNoReturn(action): isStmt = false if isStmt: result.kind = nkIfStmt result.typ = nil discardCheck(c, result) proc isTypeExpr(n: PNode): bool = case n.kind of nkType, nkTypeOfExpr: result = true of nkSym: result = n.sym.kind == skType else: result = false proc createSetType(c: PContext; baseType: PType): PType = assert baseType != nil result = newTypeS(tySet, c) rawAddSon(result, baseType) proc lookupInRecordAndBuildCheck(c: PContext, n, r: PNode, field: PIdent, check: var PNode): PSym = # transform in a node that contains the runtime check for the # field, if it is in a case-part... result = nil case r.kind of nkRecList: for i in countup(0, sonsLen(r) - 1): result = lookupInRecordAndBuildCheck(c, n, r.sons[i], field, check) if result != nil: return of nkRecCase: checkMinSonsLen(r, 2) if (r.sons[0].kind != nkSym): illFormedAst(r) result = lookupInRecordAndBuildCheck(c, n, r.sons[0], field, check) if result != nil: return let setType = createSetType(c, r.sons[0].typ) var s = newNodeIT(nkCurly, r.info, setType) for i in countup(1, sonsLen(r) - 1): var it = r.sons[i] case it.kind of nkOfBranch: result = lookupInRecordAndBuildCheck(c, n, lastSon(it), field, check) if result == nil: for j in 0..sonsLen(it)-2: addSon(s, copyTree(it.sons[j])) else: if check == nil: check = newNodeI(nkCheckedFieldExpr, n.info) addSon(check, ast.emptyNode) # make space for access node s = newNodeIT(nkCurly, n.info, setType) for j in countup(0, sonsLen(it) - 2): addSon(s, copyTree(it.sons[j])) var inExpr = newNodeIT(nkCall, n.info, getSysType(tyBool)) addSon(inExpr, newSymNode(opContains, n.info)) addSon(inExpr, s) addSon(inExpr, copyTree(r.sons[0])) addSon(check, inExpr) #addSon(check, semExpr(c, inExpr)) return of nkElse: result = lookupInRecordAndBuildCheck(c, n, lastSon(it), field, check) if result != nil: if check == nil: check = newNodeI(nkCheckedFieldExpr, n.info) addSon(check, ast.emptyNode) # make space for access node var inExpr = newNodeIT(nkCall, n.info, getSysType(tyBool)) addSon(inExpr, newSymNode(opContains, n.info)) addSon(inExpr, s) addSon(inExpr, copyTree(r.sons[0])) var notExpr = newNodeIT(nkCall, n.info, getSysType(tyBool)) addSon(notExpr, newSymNode(opNot, n.info)) addSon(notExpr, inExpr) addSon(check, notExpr) return else: illFormedAst(it) of nkSym: if r.sym.name.id == field.id: result = r.sym else: illFormedAst(n) const tyTypeParamsHolders = {tyGenericInst, tyCompositeTypeClass} tyDotOpTransparent = {tyVar, tyLent, tyPtr, tyRef, tyAlias, tySink} proc readTypeParameter(c: PContext, typ: PType, paramName: PIdent, info: TLineInfo): PNode = if typ.kind in {tyUserTypeClass, tyUserTypeClassInst}: for statement in typ.n: case statement.kind of nkTypeSection: for def in statement: if def[0].sym.name.id == paramName.id: # XXX: Instead of lifting the section type to a typedesc # here, we could try doing it earlier in semTypeSection. # This seems semantically correct and then we'll be able # to return the section symbol directly here let foundType = makeTypeDesc(c, def[2].typ) return newSymNode(copySym(def[0].sym).linkTo(foundType), info) of nkConstSection: for def in statement: if def[0].sym.name.id == paramName.id: return def[2] else: discard if typ.kind != tyUserTypeClass: let ty = if typ.kind == tyCompositeTypeClass: typ.sons[1].skipGenericAlias else: typ.skipGenericAlias let tbody = ty.sons[0] for s in countup(0, tbody.len-2): let tParam = tbody.sons[s] if tParam.sym.name.id == paramName.id: let rawTyp = ty.sons[s + 1] if rawTyp.kind == tyStatic: return rawTyp.n else: let foundTyp = makeTypeDesc(c, rawTyp) return newSymNode(copySym(tParam.sym).linkTo(foundTyp), info) return nil proc semSym(c: PContext, n: PNode, sym: PSym, flags: TExprFlags): PNode = let s = getGenSym(c, sym) case s.kind of skConst: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) case skipTypes(s.typ, abstractInst-{tyTypeDesc}).kind of tyNil, tyChar, tyInt..tyInt64, tyFloat..tyFloat128, tyTuple, tySet, tyUInt..tyUInt64: if s.magic == mNone: result = inlineConst(n, s) else: result = newSymNode(s, n.info) of tyArray, tySequence: # Consider:: # const x = [] # proc p(a: openarray[int]) # proc q(a: openarray[char]) # p(x) # q(x) # # It is clear that ``[]`` means two totally different things. Thus, we # copy `x`'s AST into each context, so that the type fixup phase can # deal with two different ``[]``. if s.ast.len == 0: result = inlineConst(n, s) else: result = newSymNode(s, n.info) else: result = newSymNode(s, n.info) of skMacro: if efNoEvaluateGeneric in flags and s.ast[genericParamsPos].len > 0: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) result = newSymNode(s, n.info) else: result = semMacroExpr(c, n, n, s, flags) of skTemplate: if efNoEvaluateGeneric in flags and s.ast[genericParamsPos].len > 0 or sfCustomPragma in sym.flags: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) result = newSymNode(s, n.info) else: result = semTemplateExpr(c, n, s, flags) of skParam: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) if s.typ != nil and s.typ.kind == tyStatic and s.typ.n != nil: # XXX see the hack in sigmatch.nim ... return s.typ.n elif sfGenSym in s.flags: if c.p.wasForwarded: # gensym'ed parameters that nevertheless have been forward declared # need a special fixup: let realParam = c.p.owner.typ.n[s.position+1] internalAssert realParam.kind == nkSym and realParam.sym.kind == skParam return newSymNode(c.p.owner.typ.n[s.position+1].sym, n.info) elif c.p.owner.kind == skMacro: # gensym'ed macro parameters need a similar hack (see bug #1944): var u = searchInScopes(c, s.name) internalAssert u != nil and u.kind == skParam and u.owner == s.owner return newSymNode(u, n.info) result = newSymNode(s, n.info) of skVar, skLet, skResult, skForVar: if s.magic == mNimvm: localError(n.info, "illegal context for 'nimvm' magic") markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) result = newSymNode(s, n.info) # We cannot check for access to outer vars for example because it's still # not sure the symbol really ends up being used: # var len = 0 # but won't be called # genericThatUsesLen(x) # marked as taking a closure? of skGenericParam: styleCheckUse(n.info, s) if s.typ.kind == tyStatic: result = newSymNode(s, n.info) result.typ = s.typ elif s.ast != nil: result = semExpr(c, s.ast) else: n.typ = s.typ return n of skType: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) if s.typ.kind == tyStatic and s.typ.n != nil: return s.typ.n result = newSymNode(s, n.info) result.typ = makeTypeDesc(c, s.typ) of skField: var p = c.p while p != nil and p.selfSym == nil: p = p.next if p != nil and p.selfSym != nil: var ty = skipTypes(p.selfSym.typ, {tyGenericInst, tyVar, tyLent, tyPtr, tyRef, tyAlias, tySink}) while tfBorrowDot in ty.flags: ty = ty.skipTypes({tyDistinct}) var check: PNode = nil if ty.kind == tyObject: while true: check = nil let f = lookupInRecordAndBuildCheck(c, n, ty.n, s.name, check) if f != nil and fieldVisible(c, f): # is the access to a public field or in the same module or in a friend? doAssert f == s markUsed(n.info, f, c.graph.usageSym) styleCheckUse(n.info, f) result = newNodeIT(nkDotExpr, n.info, f.typ) result.add makeDeref(newSymNode(p.selfSym)) result.add newSymNode(f) # we now have the correct field if check != nil: check.sons[0] = result check.typ = result.typ result = check return result if ty.sons[0] == nil: break ty = skipTypes(ty.sons[0], skipPtrs) # old code, not sure if it's live code: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) result = newSymNode(s, n.info) else: markUsed(n.info, s, c.graph.usageSym) styleCheckUse(n.info, s) result = newSymNode(s, n.info) proc builtinFieldAccess(c: PContext, n: PNode, flags: TExprFlags): PNode = ## returns nil if it's not a built-in field access checkSonsLen(n, 2) # tests/bind/tbindoverload.nim wants an early exit here, but seems to # work without now. template/tsymchoicefield doesn't like an early exit # here at all! #if isSymChoice(n.sons[1]): return when defined(nimsuggest): if gCmd == cmdIdeTools: suggestExpr(c, n) if exactEquals(gTrackPos, n[1].info): suggestExprNoCheck(c, n) var s = qualifiedLookUp(c, n, {checkAmbiguity, checkUndeclared, checkModule}) if s != nil: if s.kind in OverloadableSyms: result = symChoice(c, n, s, scClosed) if result.kind == nkSym: result = semSym(c, n, s, flags) else: markUsed(n.sons[1].info, s, c.graph.usageSym) result = semSym(c, n, s, flags) styleCheckUse(n.sons[1].info, s) return n.sons[0] = semExprWithType(c, n.sons[0], flags+{efDetermineType}) #restoreOldStyleType(n.sons[0]) var i = considerQuotedIdent(n.sons[1], n) var ty = n.sons[0].typ var f: PSym = nil result = nil template tryReadingGenericParam(t: PType) = case t.kind of tyTypeParamsHolders: return readTypeParameter(c, t, i, n.info) of tyUserTypeClasses: if t.isResolvedUserTypeClass: return readTypeParameter(c, t, i, n.info) else: n.typ = makeTypeFromExpr(c, copyTree(n)) return n of tyGenericParam: n.typ = makeTypeFromExpr(c, copyTree(n)) return n else: discard if isTypeExpr(n.sons[0]) or (ty.kind == tyTypeDesc and ty.base.kind != tyNone): if ty.kind == tyTypeDesc: ty = ty.base ty = ty.skipTypes(tyDotOpTransparent) case ty.kind of tyEnum: # look up if the identifier belongs to the enum: while ty != nil: f = getSymFromList(ty.n, i) if f != nil: break ty = ty.sons[0] # enum inheritance if f != nil: result = newSymNode(f) result.info = n.info result.typ = ty markUsed(n.info, f, c.graph.usageSym) styleCheckUse(n.info, f) return of tyObject, tyTuple: if ty.n != nil and ty.n.kind == nkRecList: let field = lookupInRecord(ty.n, i) if field != nil: n.typ = makeTypeDesc(c, field.typ) return n else: tryReadingGenericParam(ty) return # XXX: This is probably not relevant any more # reset to prevent 'nil' bug: see "tests/reject/tenumitems.nim": ty = n.sons[0].typ return nil if ty.kind in tyUserTypeClasses and ty.isResolvedUserTypeClass: ty = ty.lastSon ty = skipTypes(ty, {tyGenericInst, tyVar, tyLent, tyPtr, tyRef, tyAlias, tySink}) while tfBorrowDot in ty.flags: ty = ty.skipTypes({tyDistinct}) var check: PNode = nil if ty.kind == tyObject: while true: check = nil f = lookupInRecordAndBuildCheck(c, n, ty.n, i, check) if f != nil: break if ty.sons[0] == nil: break ty = skipTypes(ty.sons[0], skipPtrs) if f != nil: if fieldVisible(c, f): # is the access to a public field or in the same module or in a friend? markUsed(n.sons[1].info, f, c.graph.usageSym) styleCheckUse(n.sons[1].info, f) n.sons[0] = makeDeref(n.sons[0]) n.sons[1] = newSymNode(f) # we now have the correct field n.typ = f.typ if check == nil: result = n else: check.sons[0] = n check.typ = n.typ result = check elif ty.kind == tyTuple and ty.n != nil: f = getSymFromList(ty.n, i) if f != nil: markUsed(n.sons[1].info, f, c.graph.usageSym) styleCheckUse(n.sons[1].info, f) n.sons[0] = makeDeref(n.sons[0]) n.sons[1] = newSymNode(f) n.typ = f.typ result = n # we didn't find any field, let's look for a generic param if result == nil: let t = n.sons[0].typ.skipTypes(tyDotOpTransparent) tryReadingGenericParam(t) proc dotTransformation(c: PContext, n: PNode): PNode = if isSymChoice(n.sons[1]): result = newNodeI(nkDotCall, n.info) addSon(result, n.sons[1]) addSon(result, copyTree(n[0])) else: var i = considerQuotedIdent(n.sons[1], n) result = newNodeI(nkDotCall, n.info) result.flags.incl nfDotField addSon(result, newIdentNode(i, n[1].info)) addSon(result, copyTree(n[0])) proc semFieldAccess(c: PContext, n: PNode, flags: TExprFlags): PNode = # this is difficult, because the '.' is used in many different contexts # in Nim. We first allow types in the semantic checking. result = builtinFieldAccess(c, n, flags) if result == nil: result = dotTransformation(c, n) proc buildOverloadedSubscripts(n: PNode, ident: PIdent): PNode = result = newNodeI(nkCall, n.info) result.add(newIdentNode(ident, n.info)) for i in 0 .. n.len-1: result.add(n[i]) proc semDeref(c: PContext, n: PNode): PNode = checkSonsLen(n, 1) n.sons[0] = semExprWithType(c, n.sons[0]) result = n var t = skipTypes(n.sons[0].typ, {tyGenericInst, tyVar, tyLent, tyAlias, tySink}) case t.kind of tyRef, tyPtr: n.typ = t.lastSon else: result = nil #GlobalError(n.sons[0].info, errCircumNeedsPointer) proc semSubscript(c: PContext, n: PNode, flags: TExprFlags): PNode = ## returns nil if not a built-in subscript operator; also called for the ## checking of assignments if sonsLen(n) == 1: let x = semDeref(c, n) if x == nil: return nil result = newNodeIT(nkDerefExpr, x.info, x.typ) result.add(x[0]) return checkMinSonsLen(n, 2) # make sure we don't evaluate generic macros/templates n.sons[0] = semExprWithType(c, n.sons[0], {efNoProcvarCheck, efNoEvaluateGeneric}) let arr = skipTypes(n.sons[0].typ, {tyGenericInst, tyVar, tyLent, tyPtr, tyRef, tyAlias, tySink}) case arr.kind of tyArray, tyOpenArray, tyVarargs, tySequence, tyString, tyCString: if n.len != 2: return nil n.sons[0] = makeDeref(n.sons[0]) for i in countup(1, sonsLen(n) - 1): n.sons[i] = semExprWithType(c, n.sons[i], flags*{efInTypeof, efDetermineType}) var indexType = if arr.kind == tyArray: arr.sons[0] else: getSysType(tyInt) var arg = indexTypesMatch(c, indexType, n.sons[1].typ, n.sons[1]) if arg != nil: n.sons[1] = arg result = n result.typ = elemType(arr) #GlobalError(n.info, errIndexTypesDoNotMatch) of tyTypeDesc: # The result so far is a tyTypeDesc bound # a tyGenericBody. The line below will substitute # it with the instantiated type. result = n result.typ = makeTypeDesc(c, semTypeNode(c, n, nil)) #result = symNodeFromType(c, semTypeNode(c, n, nil), n.info) of tyTuple: if n.len != 2: return nil n.sons[0] = makeDeref(n.sons[0]) # [] operator for tuples requires constant expression: n.sons[1] = semConstExpr(c, n.sons[1]) if skipTypes(n.sons[1].typ, {tyGenericInst, tyRange, tyOrdinal, tyAlias, tySink}).kind in {tyInt..tyInt64}: var idx = getOrdValue(n.sons[1]) if idx >= 0 and idx < sonsLen(arr): n.typ = arr.sons[int(idx)] else: localError(n.info, errInvalidIndexValueForTuple) result = n else: result = nil else: let s = if n.sons[0].kind == nkSym: n.sons[0].sym elif n[0].kind in nkSymChoices: n.sons[0][0].sym else: nil if s != nil: case s.kind of skProc, skFunc, skMethod, skConverter, skIterator: # type parameters: partial generic specialization n.sons[0] = semSymGenericInstantiation(c, n.sons[0], s) result = explicitGenericInstantiation(c, n, s) of skMacro, skTemplate: if efInCall in flags: # We are processing macroOrTmpl[] in macroOrTmpl[](...) call. # Return as is, so it can be transformed into complete macro or # template call in semIndirectOp caller. result = n else: # We are processing macroOrTmpl[] not in call. Transform it to the # macro or template call with generic arguments here. n.kind = nkCall case s.kind of skMacro: result = semMacroExpr(c, n, n, s, flags) of skTemplate: result = semTemplateExpr(c, n, s, flags) else: discard of skType: result = symNodeFromType(c, semTypeNode(c, n, nil), n.info) else: discard proc semArrayAccess(c: PContext, n: PNode, flags: TExprFlags): PNode = result = semSubscript(c, n, flags) if result == nil: # overloaded [] operator: result = semExpr(c, buildOverloadedSubscripts(n, getIdent"[]")) proc propertyWriteAccess(c: PContext, n, nOrig, a: PNode): PNode = var id = considerQuotedIdent(a[1], a) var setterId = newIdentNode(getIdent(id.s & '='), n.info) # a[0] is already checked for semantics, that does ``builtinFieldAccess`` # this is ugly. XXX Semantic checking should use the ``nfSem`` flag for # nodes? let aOrig = nOrig[0] result = newNode(nkCall, n.info, sons = @[setterId, a[0], semExprWithType(c, n[1])]) result.flags.incl nfDotSetter let orig = newNode(nkCall, n.info, sons = @[setterId, aOrig[0], nOrig[1]]) result = semOverloadedCallAnalyseEffects(c, result, orig, {}) if result != nil: result = afterCallActions(c, result, nOrig, {}) #fixAbstractType(c, result) #analyseIfAddressTakenInCall(c, result) proc takeImplicitAddr(c: PContext, n: PNode; isLent: bool): PNode = case n.kind of nkHiddenAddr, nkAddr: return n of nkHiddenDeref, nkDerefExpr: return n.sons[0] of nkBracketExpr: if len(n) == 1: return n.sons[0] else: discard var valid = isAssignable(c, n) if valid != arLValue: if valid == arLocalLValue: localError(n.info, errXStackEscape, renderTree(n, {renderNoComments})) elif not isLent: localError(n.info, errExprHasNoAddress) result = newNodeIT(nkHiddenAddr, n.info, makePtrType(c, n.typ)) result.add(n) proc asgnToResultVar(c: PContext, n, le, ri: PNode) {.inline.} = if le.kind == nkHiddenDeref: var x = le.sons[0] if x.typ.kind in {tyVar, tyLent} and x.kind == nkSym and x.sym.kind == skResult: n.sons[0] = x # 'result[]' --> 'result' n.sons[1] = takeImplicitAddr(c, ri, x.typ.kind == tyLent) x.typ.flags.incl tfVarIsPtr #echo x.info, " setting it for this type ", typeToString(x.typ), " ", n.info template resultTypeIsInferrable(typ: PType): untyped = typ.isMetaType and typ.kind != tyTypeDesc proc semAsgn(c: PContext, n: PNode; mode=asgnNormal): PNode = checkSonsLen(n, 2) var a = n.sons[0] case a.kind of nkDotExpr: # r.f = x # --> `f=` (r, x) let nOrig = n.copyTree a = builtinFieldAccess(c, a, {efLValue}) if a == nil: a = propertyWriteAccess(c, n, nOrig, n[0]) if a != nil: return a # we try without the '='; proc that return 'var' or macros are still # possible: a = dotTransformation(c, n[0]) if a.kind == nkDotCall: a.kind = nkCall a = semExprWithType(c, a, {efLValue}) of nkBracketExpr: # a[i] = x # --> `[]=`(a, i, x) a = semSubscript(c, a, {efLValue}) if a == nil: result = buildOverloadedSubscripts(n.sons[0], getIdent"[]=") add(result, n[1]) if mode == noOverloadedSubscript: bracketNotFoundError(c, result) return n else: result = semExprNoType(c, result) return result of nkCurlyExpr: # a{i} = x --> `{}=`(a, i, x) result = buildOverloadedSubscripts(n.sons[0], getIdent"{}=") add(result, n[1]) return semExprNoType(c, result) of nkPar: if a.len >= 2: # unfortunately we need to rewrite ``(x, y) = foo()`` already here so # that overloading of the assignment operator still works. Usually we # prefer to do these rewritings in transf.nim: return semStmt(c, lowerTupleUnpackingForAsgn(n, c.p.owner)) else: a = semExprWithType(c, a, {efLValue}) else: a = semExprWithType(c, a, {efLValue}) n.sons[0] = a # a = b # both are vars, means: a[] = b[] # a = b # b no 'var T' means: a = addr(b) var le = a.typ if (skipTypes(le, {tyGenericInst, tyAlias, tySink}).kind != tyVar and isAssignable(c, a) == arNone) or skipTypes(le, abstractVar).kind in {tyOpenArray, tyVarargs}: # Direct assignment to a discriminant is allowed! localError(a.info, errXCannotBeAssignedTo, renderTree(a, {renderNoComments})) else: let lhs = n.sons[0] lhsIsResult = lhs.kind == nkSym and lhs.sym.kind == skResult var rhs = semExprWithType(c, n.sons[1], if lhsIsResult: {efAllowDestructor} else: {}) if lhsIsResult: n.typ = enforceVoidContext if c.p.owner.kind != skMacro and resultTypeIsInferrable(lhs.sym.typ): var rhsTyp = rhs.typ if rhsTyp.kind in tyUserTypeClasses and rhsTyp.isResolvedUserTypeClass: rhsTyp = rhsTyp.lastSon if cmpTypes(c, lhs.typ, rhsTyp) in {isGeneric, isEqual}: internalAssert c.p.resultSym != nil lhs.typ = rhsTyp c.p.resultSym.typ = rhsTyp c.p.owner.typ.sons[0] = rhsTyp else: typeMismatch(n.info, lhs.typ, rhsTyp) n.sons[1] = fitNode(c, le, rhs, n.info) if not newDestructors: if tfHasAsgn in lhs.typ.flags and not lhsIsResult and mode != noOverloadedAsgn: return overloadedAsgn(c, lhs, n.sons[1]) else: liftTypeBoundOps(c, lhs.typ, lhs.info) fixAbstractType(c, n) asgnToResultVar(c, n, n.sons[0], n.sons[1]) result = n proc semReturn(c: PContext, n: PNode): PNode = result = n checkSonsLen(n, 1) if c.p.owner.kind in {skConverter, skMethod, skProc, skFunc, skMacro} or ( c.p.owner.kind == skIterator and c.p.owner.typ.callConv == ccClosure): if n.sons[0].kind != nkEmpty: # transform ``return expr`` to ``result = expr; return`` if c.p.resultSym != nil: var a = newNodeI(nkAsgn, n.sons[0].info) addSon(a, newSymNode(c.p.resultSym)) addSon(a, n.sons[0]) n.sons[0] = semAsgn(c, a) # optimize away ``result = result``: if n[0][1].kind == nkSym and n[0][1].sym == c.p.resultSym: n.sons[0] = ast.emptyNode else: localError(n.info, errNoReturnTypeDeclared) else: localError(n.info, errXNotAllowedHere, "\'return\'") proc semProcBody(c: PContext, n: PNode): PNode = openScope(c) result = semExpr(c, n) if c.p.resultSym != nil and not isEmptyType(result.typ): if result.kind == nkNilLit: # or ImplicitlyDiscardable(result): # new semantic: 'result = x' triggers the void context result.typ = nil elif result.kind == nkStmtListExpr and result.typ.kind == tyNil: # to keep backwards compatibility bodies like: # nil # # comment # are not expressions: fixNilType(result) else: var a = newNodeI(nkAsgn, n.info, 2) a.sons[0] = newSymNode(c.p.resultSym) a.sons[1] = result result = semAsgn(c, a) else: discardCheck(c, result) if c.p.owner.kind notin {skMacro, skTemplate} and c.p.resultSym != nil and c.p.resultSym.typ.isMetaType: if isEmptyType(result.typ): # we inferred a 'void' return type: c.p.resultSym.typ = errorType(c) c.p.owner.typ.sons[0] = nil else: localError(c.p.resultSym.info, errCannotInferReturnType) closeScope(c) proc semYieldVarResult(c: PContext, n: PNode, restype: PType) = var t = skipTypes(restype, {tyGenericInst, tyAlias, tySink}) case t.kind of tyVar, tyLent: if t.kind == tyVar: t.flags.incl tfVarIsPtr # bugfix for #4048, #4910, #6892 if n.sons[0].kind in {nkHiddenStdConv, nkHiddenSubConv}: n.sons[0] = n.sons[0].sons[1] n.sons[0] = takeImplicitAddr(c, n.sons[0], t.kind == tyLent) of tyTuple: for i in 0.. 0 and c.p.owner.typ.callConv != ccInline: localError(n.info, errYieldNotAllowedInTryStmt) elif n.sons[0].kind != nkEmpty: n.sons[0] = semExprWithType(c, n.sons[0]) # check for type compatibility: var iterType = c.p.owner.typ let restype = iterType.sons[0] if restype != nil: if restype.kind != tyExpr: n.sons[0] = fitNode(c, restype, n.sons[0], n.info) if n.sons[0].typ == nil: internalError(n.info, "semYield") if resultTypeIsInferrable(restype): let inferred = n.sons[0].typ iterType.sons[0] = inferred semYieldVarResult(c, n, restype) else: localError(n.info, errCannotReturnExpr) elif c.p.owner.typ.sons[0] != nil: localError(n.info, errGenerated, "yield statement must yield a value") proc lookUpForDefined(c: PContext, i: PIdent, onlyCurrentScope: bool): PSym = if onlyCurrentScope: result = localSearchInScope(c, i) else: result = searchInScopes(c, i) # no need for stub loading proc lookUpForDefined(c: PContext, n: PNode, onlyCurrentScope: bool): PSym = case n.kind of nkIdent: result = lookUpForDefined(c, n.ident, onlyCurrentScope) of nkDotExpr: result = nil if onlyCurrentScope: return checkSonsLen(n, 2) var m = lookUpForDefined(c, n.sons[0], onlyCurrentScope) if m != nil and m.kind == skModule: let ident = considerQuotedIdent(n[1], n) if m == c.module: result = strTableGet(c.topLevelScope.symbols, ident) else: result = strTableGet(m.tab, ident) of nkAccQuoted: result = lookUpForDefined(c, considerQuotedIdent(n), onlyCurrentScope) of nkSym: result = n.sym of nkOpenSymChoice, nkClosedSymChoice: result = n.sons[0].sym else: localError(n.info, errIdentifierExpected, renderTree(n)) result = nil proc semDefined(c: PContext, n: PNode, onlyCurrentScope: bool): PNode = checkSonsLen(n, 2) # we replace this node by a 'true' or 'false' node: result = newIntNode(nkIntLit, 0) if not onlyCurrentScope and considerQuotedIdent(n[0], n).s == "defined": if n.sons[1].kind != nkIdent: localError(n.info, "obsolete usage of 'defined', use 'declared' instead") elif condsyms.isDefined(n.sons[1].ident): result.intVal = 1 elif lookUpForDefined(c, n.sons[1], onlyCurrentScope) != nil: result.intVal = 1 result.info = n.info result.typ = getSysType(tyBool) proc expectMacroOrTemplateCall(c: PContext, n: PNode): PSym = ## The argument to the proc should be nkCall(...) or similar ## Returns the macro/template symbol if isCallExpr(n): var expandedSym = qualifiedLookUp(c, n[0], {checkUndeclared}) if expandedSym == nil: errorUndeclaredIdentifier(c, n.info, n[0].renderTree) return errorSym(c, n[0]) if expandedSym.kind notin {skMacro, skTemplate}: localError(n.info, errXisNoMacroOrTemplate, expandedSym.name.s) return errorSym(c, n[0]) result = expandedSym else: localError(n.info, errXisNoMacroOrTemplate, n.renderTree) result = errorSym(c, n) proc expectString(c: PContext, n: PNode): string = var n = semConstExpr(c, n) if n.kind in nkStrKinds: return n.strVal else: localError(n.info, errStringLiteralExpected) proc getMagicSym(magic: TMagic): PSym = result = newSym(skProc, getIdent($magic), systemModule, gCodegenLineInfo) result.magic = magic proc newAnonSym(c: PContext; kind: TSymKind, info: TLineInfo): PSym = result = newSym(kind, c.cache.idAnon, getCurrOwner(c), info) result.flags = {sfGenSym} proc semExpandToAst(c: PContext, n: PNode): PNode = let macroCall = n[1] when false: let expandedSym = expectMacroOrTemplateCall(c, macroCall) if expandedSym.kind == skError: return n macroCall.sons[0] = newSymNode(expandedSym, macroCall.info) markUsed(n.info, expandedSym, c.graph.usageSym) styleCheckUse(n.info, expandedSym) if isCallExpr(macroCall): for i in countup(1, macroCall.len-1): #if macroCall.sons[0].typ.sons[i].kind != tyExpr: macroCall.sons[i] = semExprWithType(c, macroCall[i], {}) # performing overloading resolution here produces too serious regressions: let headSymbol = macroCall[0] var cands = 0 var cand: PSym = nil var o: TOverloadIter var symx = initOverloadIter(o, c, headSymbol) while symx != nil: if symx.kind in {skTemplate, skMacro} and symx.typ.len == macroCall.len: cand = symx inc cands symx = nextOverloadIter(o, c, headSymbol) if cands == 0: localError(n.info, "expected a template that takes " & $(macroCall.len-1) & " arguments") elif cands >= 2: localError(n.info, "ambiguous symbol in 'getAst' context: " & $macroCall) else: let info = macroCall.sons[0].info macroCall.sons[0] = newSymNode(cand, info) markUsed(info, cand, c.graph.usageSym) styleCheckUse(info, cand) # we just perform overloading resolution here: #n.sons[1] = semOverloadedCall(c, macroCall, macroCall, {skTemplate, skMacro}) else: localError(n.info, "getAst takes a call, but got " & n.renderTree) # Preserve the magic symbol in order to be handled in evals.nim internalAssert n.sons[0].sym.magic == mExpandToAst #n.typ = getSysSym("NimNode").typ # expandedSym.getReturnType if n.kind == nkStmtList and n.len == 1: result = n[0] else: result = n result.typ = if getCompilerProc("NimNode") != nil: sysTypeFromName"NimNode" else: sysTypeFromName"PNimrodNode" proc semExpandToAst(c: PContext, n: PNode, magicSym: PSym, flags: TExprFlags = {}): PNode = if sonsLen(n) == 2: n.sons[0] = newSymNode(magicSym, n.info) result = semExpandToAst(c, n) else: result = semDirectOp(c, n, flags) proc processQuotations(n: var PNode, op: string, quotes: var seq[PNode], ids: var seq[PNode]) = template returnQuote(q) = quotes.add q n = newIdentNode(getIdent($quotes.len), n.info) ids.add n return if n.kind == nkPrefix: checkSonsLen(n, 2) if n[0].kind == nkIdent: var examinedOp = n[0].ident.s if examinedOp == op: returnQuote n[1] elif examinedOp.startsWith(op): n.sons[0] = newIdentNode(getIdent(examinedOp.substr(op.len)), n.info) elif n.kind == nkAccQuoted and op == "``": returnQuote n[0] for i in 0 ..< n.safeLen: processQuotations(n.sons[i], op, quotes, ids) proc semQuoteAst(c: PContext, n: PNode): PNode = internalAssert n.len == 2 or n.len == 3 # We transform the do block into a template with a param for # each interpolation. We'll pass this template to getAst. var quotedBlock = n[^1] op = if n.len == 3: expectString(c, n[1]) else: "``" quotes = newSeq[PNode](1) # the quotes will be added to a nkCall statement # leave some room for the callee symbol ids = newSeq[PNode]() # this will store the generated param names if quotedBlock.kind != nkStmtList: localError(n.info, errXExpected, "block") processQuotations(quotedBlock, op, quotes, ids) var dummyTemplate = newProcNode( nkTemplateDef, quotedBlock.info, quotedBlock, name = newAnonSym(c, skTemplate, n.info).newSymNode) if ids.len > 0: dummyTemplate.sons[paramsPos] = newNodeI(nkFormalParams, n.info) dummyTemplate[paramsPos].add getSysSym("typed").newSymNode # return type ids.add getSysSym("untyped").newSymNode # params type ids.add emptyNode # no default value dummyTemplate[paramsPos].add newNode(nkIdentDefs, n.info, ids) var tmpl = semTemplateDef(c, dummyTemplate) quotes[0] = tmpl[namePos] result = newNode(nkCall, n.info, @[ getMagicSym(mExpandToAst).newSymNode, newNode(nkCall, n.info, quotes)]) result = semExpandToAst(c, result) proc tryExpr(c: PContext, n: PNode, flags: TExprFlags = {}): PNode = # watch out, hacks ahead: let oldErrorCount = msgs.gErrorCounter let oldErrorMax = msgs.gErrorMax let oldCompilesId = c.compilesContextId inc c.compilesContextIdGenerator c.compilesContextId = c.compilesContextIdGenerator # do not halt after first error: msgs.gErrorMax = high(int) # open a scope for temporary symbol inclusions: let oldScope = c.currentScope openScope(c) let oldOwnerLen = len(c.graph.owners) let oldGenerics = c.generics let oldErrorOutputs = errorOutputs if efExplain notin flags: errorOutputs = {} let oldContextLen = msgs.getInfoContextLen() let oldInGenericContext = c.inGenericContext let oldInUnrolledContext = c.inUnrolledContext let oldInGenericInst = c.inGenericInst let oldProcCon = c.p c.generics = @[] var err: string try: result = semExpr(c, n, flags) if msgs.gErrorCounter != oldErrorCount: result = nil except ERecoverableError: discard # undo symbol table changes (as far as it's possible): c.compilesContextId = oldCompilesId c.generics = oldGenerics c.inGenericContext = oldInGenericContext c.inUnrolledContext = oldInUnrolledContext c.inGenericInst = oldInGenericInst c.p = oldProcCon msgs.setInfoContextLen(oldContextLen) setLen(c.graph.owners, oldOwnerLen) c.currentScope = oldScope errorOutputs = oldErrorOutputs msgs.gErrorCounter = oldErrorCount msgs.gErrorMax = oldErrorMax proc semCompiles(c: PContext, n: PNode, flags: TExprFlags): PNode = # we replace this node by a 'true' or 'false' node: if sonsLen(n) != 2: return semDirectOp(c, n, flags) result = newIntNode(nkIntLit, ord(tryExpr(c, n[1], flags) != nil)) result.info = n.info result.typ = getSysType(tyBool) proc semShallowCopy(c: PContext, n: PNode, flags: TExprFlags): PNode = if sonsLen(n) == 3: # XXX ugh this is really a hack: shallowCopy() can be overloaded only # with procs that take not 2 parameters: result = newNodeI(nkFastAsgn, n.info) result.add(n[1]) result.add(n[2]) result = semAsgn(c, result) else: result = semDirectOp(c, n, flags) proc createFlowVar(c: PContext; t: PType; info: TLineInfo): PType = result = newType(tyGenericInvocation, c.module) addSonSkipIntLit(result, magicsys.getCompilerProc("FlowVar").typ) addSonSkipIntLit(result, t) result = instGenericContainer(c, info, result, allowMetaTypes = false) proc instantiateCreateFlowVarCall(c: PContext; t: PType; info: TLineInfo): PSym = let sym = magicsys.getCompilerProc("nimCreateFlowVar") if sym == nil: localError(info, errSystemNeeds, "nimCreateFlowVar") var bindings: TIdTable initIdTable(bindings) bindings.idTablePut(sym.ast[genericParamsPos].sons[0].typ, t) result = c.semGenerateInstance(c, sym, bindings, info) # since it's an instantiation, we unmark it as a compilerproc. Otherwise # codegen would fail: if sfCompilerProc in result.flags: result.flags = result.flags - {sfCompilerProc, sfExportC, sfImportC} result.loc.r = nil proc setMs(n: PNode, s: PSym): PNode = result = n n.sons[0] = newSymNode(s) n.sons[0].info = n.info proc extractImports(n: PNode; result: PNode) = if n.kind in {nkImportStmt, nkImportExceptStmt, nkFromStmt}: result.add copyTree(n) n.kind = nkEmpty return for i in 0.. 0) == srFlowVar: result.typ = createFlowVar(c, typ, n.info) else: result.typ = typ result.add instantiateCreateFlowVarCall(c, typ, n.info).newSymNode else: result.add emptyNode of mProcCall: result = setMs(n, s) result.sons[1] = semExpr(c, n.sons[1]) result.typ = n[1].typ of mPlugin: # semDirectOp with conditional 'afterCallActions': let nOrig = n.copyTree #semLazyOpAux(c, n) result = semOverloadedCallAnalyseEffects(c, n, nOrig, flags) if result == nil: result = errorNode(c, n) else: let callee = result.sons[0].sym if callee.magic == mNone: semFinishOperands(c, result) activate(c, result) fixAbstractType(c, result) analyseIfAddressTakenInCall(c, result) if callee.magic != mNone: result = magicsAfterOverloadResolution(c, result, flags) of mRunnableExamples: if gCmd == cmdDoc and n.len >= 2 and n.lastSon.kind == nkStmtList: if sfMainModule in c.module.flags: let inp = toFullPath(c.module.info) if c.runnableExamples == nil: c.runnableExamples = newTree(nkStmtList, newTree(nkImportStmt, newStrNode(nkStrLit, expandFilename(inp)))) let imports = newTree(nkStmtList) extractImports(n.lastSon, imports) for imp in imports: c.runnableExamples.add imp c.runnableExamples.add newTree(nkBlockStmt, emptyNode, copyTree n.lastSon) result = setMs(n, s) else: result = emptyNode else: result = semDirectOp(c, n, flags) proc semWhen(c: PContext, n: PNode, semCheck = true): PNode = # If semCheck is set to false, ``when`` will return the verbatim AST of # the correct branch. Otherwise the AST will be passed through semStmt. result = nil template setResult(e: untyped) = if semCheck: result = semExpr(c, e) # do not open a new scope! else: result = e # Check if the node is "when nimvm" # when nimvm: # ... # else: # ... var whenNimvm = false var typ = commonTypeBegin if n.sons.len == 2 and n.sons[0].kind == nkElifBranch and n.sons[1].kind == nkElse: let exprNode = n.sons[0].sons[0] if exprNode.kind == nkIdent: whenNimvm = lookUp(c, exprNode).magic == mNimvm elif exprNode.kind == nkSym: whenNimvm = exprNode.sym.magic == mNimvm if whenNimvm: n.flags.incl nfLL for i in countup(0, sonsLen(n) - 1): var it = n.sons[i] case it.kind of nkElifBranch, nkElifExpr: checkSonsLen(it, 2) if whenNimvm: if semCheck: it.sons[1] = semExpr(c, it.sons[1]) typ = commonType(typ, it.sons[1].typ) result = n # when nimvm is not elimited until codegen else: var e = semConstExpr(c, it.sons[0]) if e.kind != nkIntLit: # can happen for cascading errors, assume false # InternalError(n.info, "semWhen") discard elif e.intVal != 0 and result == nil: setResult(it.sons[1]) of nkElse, nkElseExpr: checkSonsLen(it, 1) if result == nil or whenNimvm: if semCheck: it.sons[0] = semExpr(c, it.sons[0]) typ = commonType(typ, it.sons[0].typ) if result == nil: result = it.sons[0] else: illFormedAst(n) if result == nil: result = newNodeI(nkEmpty, n.info) if whenNimvm: result.typ = typ # The ``when`` statement implements the mechanism for platform dependent # code. Thus we try to ensure here consistent ID allocation after the # ``when`` statement. idSynchronizationPoint(200) proc semSetConstr(c: PContext, n: PNode): PNode = result = newNodeI(nkCurly, n.info) result.typ = newTypeS(tySet, c) if sonsLen(n) == 0: rawAddSon(result.typ, newTypeS(tyEmpty, c)) else: # only semantic checking for all elements, later type checking: var typ: PType = nil for i in countup(0, sonsLen(n) - 1): if isRange(n.sons[i]): checkSonsLen(n.sons[i], 3) n.sons[i].sons[1] = semExprWithType(c, n.sons[i].sons[1]) n.sons[i].sons[2] = semExprWithType(c, n.sons[i].sons[2]) if typ == nil: typ = skipTypes(n.sons[i].sons[1].typ, {tyGenericInst, tyVar, tyLent, tyOrdinal, tyAlias, tySink}) n.sons[i].typ = n.sons[i].sons[2].typ # range node needs type too elif n.sons[i].kind == nkRange: # already semchecked if typ == nil: typ = skipTypes(n.sons[i].sons[0].typ, {tyGenericInst, tyVar, tyLent, tyOrdinal, tyAlias, tySink}) else: n.sons[i] = semExprWithType(c, n.sons[i]) if typ == nil: typ = skipTypes(n.sons[i].typ, {tyGenericInst, tyVar, tyLent, tyOrdinal, tyAlias, tySink}) if not isOrdinalType(typ): localError(n.info, errOrdinalTypeExpected) typ = makeRangeType(c, 0, MaxSetElements-1, n.info) elif lengthOrd(typ) > MaxSetElements: typ = makeRangeType(c, 0, MaxSetElements-1, n.info) addSonSkipIntLit(result.typ, typ) for i in countup(0, sonsLen(n) - 1): var m: PNode let info = n.sons[i].info if isRange(n.sons[i]): m = newNodeI(nkRange, info) addSon(m, fitNode(c, typ, n.sons[i].sons[1], info)) addSon(m, fitNode(c, typ, n.sons[i].sons[2], info)) elif n.sons[i].kind == nkRange: m = n.sons[i] # already semchecked else: m = fitNode(c, typ, n.sons[i], info) addSon(result, m) proc semTableConstr(c: PContext, n: PNode): PNode = # we simply transform ``{key: value, key2, key3: value}`` to # ``[(key, value), (key2, value2), (key3, value2)]`` result = newNodeI(nkBracket, n.info) var lastKey = 0 for i in 0..n.len-1: var x = n.sons[i] if x.kind == nkExprColonExpr and sonsLen(x) == 2: for j in countup(lastKey, i-1): var pair = newNodeI(nkPar, x.info) pair.add(n.sons[j]) pair.add(x[1]) result.add(pair) var pair = newNodeI(nkPar, x.info) pair.add(x[0]) pair.add(x[1]) result.add(pair) lastKey = i+1 if lastKey != n.len: illFormedAst(n) result = semExpr(c, result) type TParKind = enum paNone, paSingle, paTupleFields, paTuplePositions proc checkPar(n: PNode): TParKind = var length = sonsLen(n) if length == 0: result = paTuplePositions # () elif length == 1: if n.sons[0].kind == nkExprColonExpr: result = paTupleFields else: result = paSingle # (expr) else: if n.sons[0].kind == nkExprColonExpr: result = paTupleFields else: result = paTuplePositions for i in countup(0, length - 1): if result == paTupleFields: if (n.sons[i].kind != nkExprColonExpr) or not (n.sons[i].sons[0].kind in {nkSym, nkIdent}): localError(n.sons[i].info, errNamedExprExpected) return paNone else: if n.sons[i].kind == nkExprColonExpr: localError(n.sons[i].info, errNamedExprNotAllowed) return paNone proc semTupleFieldsConstr(c: PContext, n: PNode, flags: TExprFlags): PNode = result = newNodeI(nkPar, n.info) var typ = newTypeS(tyTuple, c) typ.n = newNodeI(nkRecList, n.info) # nkIdentDefs var ids = initIntSet() for i in countup(0, sonsLen(n) - 1): if n[i].kind != nkExprColonExpr or n[i][0].kind notin {nkSym, nkIdent}: illFormedAst(n.sons[i]) var id: PIdent if n.sons[i].sons[0].kind == nkIdent: id = n.sons[i].sons[0].ident else: id = n.sons[i].sons[0].sym.name if containsOrIncl(ids, id.id): localError(n.sons[i].info, errFieldInitTwice, id.s) n.sons[i].sons[1] = semExprWithType(c, n.sons[i].sons[1], flags*{efAllowDestructor}) var f = newSymS(skField, n.sons[i].sons[0], c) f.typ = skipIntLit(n.sons[i].sons[1].typ) f.position = i rawAddSon(typ, f.typ) addSon(typ.n, newSymNode(f)) n.sons[i].sons[0] = newSymNode(f) addSon(result, n.sons[i]) result.typ = typ proc semTuplePositionsConstr(c: PContext, n: PNode, flags: TExprFlags): PNode = result = n # we don't modify n, but compute the type: var typ = newTypeS(tyTuple, c) # leave typ.n nil! for i in countup(0, sonsLen(n) - 1): n.sons[i] = semExprWithType(c, n.sons[i], flags*{efAllowDestructor}) addSonSkipIntLit(typ, n.sons[i].typ) result.typ = typ proc isTupleType(n: PNode): bool = if n.len == 0: return false # don't interpret () as type for i in countup(0, n.len - 1): if n[i].typ == nil or n[i].typ.kind != tyTypeDesc: return false return true include semobjconstr proc semBlock(c: PContext, n: PNode): PNode = result = n inc(c.p.nestedBlockCounter) checkSonsLen(n, 2) openScope(c) # BUGFIX: label is in the scope of block! if n.sons[0].kind != nkEmpty: var labl = newSymG(skLabel, n.sons[0], c) if sfGenSym notin labl.flags: addDecl(c, labl) n.sons[0] = newSymNode(labl, n.sons[0].info) suggestSym(n.sons[0].info, labl, c.graph.usageSym) styleCheckDef(labl) n.sons[1] = semExpr(c, n.sons[1]) n.typ = n.sons[1].typ if isEmptyType(n.typ): n.kind = nkBlockStmt else: n.kind = nkBlockExpr closeScope(c) dec(c.p.nestedBlockCounter) proc semExport(c: PContext, n: PNode): PNode = var x = newNodeI(n.kind, n.info) #let L = if n.kind == nkExportExceptStmt: L = 1 else: n.len for i in 0..