#
#
# 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 of statements
# included from sem.nim
var enforceVoidContext = PType(kind: tyStmt)
proc semDiscard(c: PContext, n: PNode): PNode =
result = n
checkSonsLen(n, 1)
if n.sons[0].kind != nkEmpty:
n.sons[0] = semExprWithType(c, n.sons[0])
if isEmptyType(n.sons[0].typ): localError(n.info, errInvalidDiscard)
proc semBreakOrContinue(c: PContext, n: PNode): PNode =
result = n
checkSonsLen(n, 1)
if n.sons[0].kind != nkEmpty:
if n.kind != nkContinueStmt:
var s: PSym
case n.sons[0].kind
of nkIdent: s = lookUp(c, n.sons[0])
of nkSym: s = n.sons[0].sym
else: illFormedAst(n)
if s.kind == skLabel and s.owner.id == c.p.owner.id:
var x = newSymNode(s)
x.info = n.info
incl(s.flags, sfUsed)
n.sons[0] = x
suggestSym(x.info, s)
styleCheckUse(x.info, s)
else:
localError(n.info, errInvalidControlFlowX, s.name.s)
else:
localError(n.info, errGenerated, "'continue' cannot have a label")
elif (c.p.nestedLoopCounter <= 0) and (c.p.nestedBlockCounter <= 0):
localError(n.info, errInvalidControlFlowX,
renderTree(n, {renderNoComments}))
proc semAsm(con: PContext, n: PNode): PNode =
checkSonsLen(n, 2)
var marker = pragmaAsm(con, n.sons[0])
if marker == '\0': marker = '`' # default marker
result = semAsmOrEmit(con, n, marker)
proc semWhile(c: PContext, n: PNode): PNode =
result = n
checkSonsLen(n, 2)
openScope(c)
n.sons[0] = forceBool(c, semExprWithType(c, n.sons[0]))
inc(c.p.nestedLoopCounter)
n.sons[1] = semStmt(c, n.sons[1])
dec(c.p.nestedLoopCounter)
closeScope(c)
if n.sons[1].typ == enforceVoidContext:
result.typ = enforceVoidContext
proc toCover(t: PType): BiggestInt =
var t2 = skipTypes(t, abstractVarRange-{tyTypeDesc})
if t2.kind == tyEnum and enumHasHoles(t2):
result = sonsLen(t2.n)
else:
result = lengthOrd(skipTypes(t, abstractVar-{tyTypeDesc}))
proc performProcvarCheck(c: PContext, n: PNode, s: PSym) =
## Checks that the given symbol is a proper procedure variable, meaning
## that it
var smoduleId = getModule(s).id
if sfProcvar notin s.flags and s.typ.callConv == ccDefault and
smoduleId != c.module.id:
block outer:
for module in c.friendModules:
if smoduleId == module.id:
break outer
localError(n.info, errXCannotBePassedToProcVar, s.name.s)
proc semProcvarCheck(c: PContext, n: PNode) =
let n = n.skipConv
if n.kind == nkSym and n.sym.kind in {skProc, skMethod, skConverter,
skIterator, skClosureIterator}:
performProcvarCheck(c, n, n.sym)
proc semProc(c: PContext, n: PNode): PNode
include semdestruct
proc semDestructorCheck(c: PContext, n: PNode, flags: TExprFlags) {.inline.} =
if efAllowDestructor notin flags and
n.kind in nkCallKinds+{nkObjConstr,nkBracket}:
if instantiateDestructor(c, n.typ) != nil:
localError(n.info, warnDestructor)
# This still breaks too many things:
when false:
if efDetermineType notin flags and n.typ.kind == tyTypeDesc and
c.p.owner.kind notin {skTemplate, skMacro}:
localError(n.info, errGenerated, "value expected, but got a type")
proc newDeref(n: PNode): PNode {.inline.} =
result = newNodeIT(nkHiddenDeref, n.info, n.typ.sons[0])
addSon(result, n)
proc semExprBranch(c: PContext, n: PNode): PNode =
result = semExpr(c, n)
if result.typ != nil:
# XXX tyGenericInst here?
semProcvarCheck(c, result)
if result.typ.kind == tyVar: result = newDeref(result)
semDestructorCheck(c, result, {})
proc semExprBranchScope(c: PContext, n: PNode): PNode =
openScope(c)
result = semExprBranch(c, n)
closeScope(c)
const
skipForDiscardable = {nkIfStmt, nkIfExpr, nkCaseStmt, nkOfBranch,
nkElse, nkStmtListExpr, nkTryStmt, nkFinally, nkExceptBranch,
nkElifBranch, nkElifExpr, nkElseExpr, nkBlockStmt, nkBlockExpr}
proc implicitlyDiscardable(n: PNode): bool =
var n = n
while n.kind in skipForDiscardable: n = n.lastSon
result = isCallExpr(n) and n.sons[0].kind == nkSym and
sfDiscardable in n.sons[0].sym.flags
proc fixNilType(n: PNode) =
if isAtom(n):
if n.kind != nkNilLit and n.typ != nil:
localError(n.info, errDiscardValueX, n.typ.typeToString)
elif n.kind in {nkStmtList, nkStmtListExpr}:
n.kind = nkStmtList
for it in n: fixNilType(it)
n.typ = nil
proc discardCheck(c: PContext, result: PNode) =
if c.inTypeClass > 0: return
if result.typ != nil and result.typ.kind notin {tyStmt, tyEmpty}:
if result.kind == nkNilLit:
result.typ = nil
message(result.info, warnNilStatement)
elif implicitlyDiscardable(result):
var n = result
result.typ = nil
while n.kind in skipForDiscardable:
n = n.lastSon
n.typ = nil
elif result.typ.kind != tyError and gCmd != cmdInteractive:
if result.typ.kind == tyNil:
fixNilType(result)
message(result.info, warnNilStatement)
else:
var n = result
while n.kind in skipForDiscardable: n = n.lastSon
localError(n.info, errDiscardValueX, result.typ.typeToString)
proc semIf(c: PContext, n: PNode): PNode =
result = n
var typ = commonTypeBegin
var hasElse = false
for i in countup(0, sonsLen(n) - 1):
var it = n.sons[i]
if it.len == 2:
when newScopeForIf: openScope(c)
it.sons[0] = forceBool(c, semExprWithType(c, it.sons[0]))
when not newScopeForIf: openScope(c)
it.sons[1] = semExprBranch(c, it.sons[1])
typ = commonType(typ, it.sons[1].typ)
closeScope(c)
elif it.len == 1:
hasElse = true
it.sons[0] = semExprBranchScope(c, it.sons[0])
typ = commonType(typ, it.sons[0].typ)
else: illFormedAst(it)
if isEmptyType(typ) or typ.kind == tyNil or not hasElse:
for it in n: discardCheck(c, it.lastSon)
result.kind = nkIfStmt
# propagate any enforced VoidContext:
if typ == enforceVoidContext: result.typ = enforceVoidContext
else:
for it in n:
let j = it.len-1
it.sons[j] = fitNode(c, typ, it.sons[j])
result.kind = nkIfExpr
result.typ = typ
proc semCase(c: PContext, n: PNode): PNode =
result = n
checkMinSonsLen(n, 2)
openScope(c)
n.sons[0] = semExprWithType(c, n.sons[0])
var chckCovered = false
var covered: BiggestInt = 0
var typ = commonTypeBegin
var hasElse = false
var notOrdinal = false
case skipTypes(n.sons[0].typ, abstractVarRange-{tyTypeDesc}).kind
of tyInt..tyInt64, tyChar, tyEnum, tyUInt..tyUInt32, tyBool:
chckCovered = true
of tyFloat..tyFloat128, tyString, tyError:
notOrdinal = true
else:
localError(n.info, errSelectorMustBeOfCertainTypes)
return
for i in countup(1, sonsLen(n) - 1):
var x = n.sons[i]
case x.kind
of nkOfBranch:
checkMinSonsLen(x, 2)
semCaseBranch(c, n, x, i, covered)
var last = sonsLen(x)-1
x.sons[last] = semExprBranchScope(c, x.sons[last])
typ = commonType(typ, x.sons[last].typ)
of nkElifBranch:
chckCovered = false
checkSonsLen(x, 2)
when newScopeForIf: openScope(c)
x.sons[0] = forceBool(c, semExprWithType(c, x.sons[0]))
when not newScopeForIf: openScope(c)
x.sons[1] = semExprBranch(c, x.sons[1])
typ = commonType(typ, x.sons[1].typ)
closeScope(c)
of nkElse:
chckCovered = false
checkSonsLen(x, 1)
x.sons[0] = semExprBranchScope(c, x.sons[0])
typ = commonType(typ, x.sons[0].typ)
hasElse = true
else:
illFormedAst(x)
if notOrdinal and not hasElse:
message(n.info, warnDeprecated,
"use 'else: discard'; non-ordinal case without 'else'")
if chckCovered:
if covered == toCover(n.sons[0].typ):
hasElse = true
else:
localError(n.info, errNotAllCasesCovered)
closeScope(c)
if isEmptyType(typ) or typ.kind == tyNil or not hasElse:
for i in 1..n.len-1: discardCheck(c, n.sons[i].lastSon)
# propagate any enforced VoidContext:
if typ == enforceVoidContext:
result.typ = enforceVoidContext
else:
for i in 1..n.len-1:
var it = n.sons[i]
let j = it.len-1
it.sons[j] = fitNode(c, typ, it.sons[j])
result.typ = typ
proc semTry(c: PContext, n: PNode): PNode =
result = n
inc c.p.inTryStmt
checkMinSonsLen(n, 2)
var typ = commonTypeBegin
n.sons[0] = semExprBranchScope(c, n.sons[0])
typ = commonType(typ, n.sons[0].typ)
var check = initIntSet()
var last = sonsLen(n) - 1
for i in countup(1, last):
var a = n.sons[i]
checkMinSonsLen(a, 1)
var length = sonsLen(a)
if a.kind == nkExceptBranch:
# so that ``except [a, b, c]`` is supported:
if length == 2 and a.sons[0].kind == nkBracket:
a.sons[0..0] = a.sons[0].sons
length = a.sonsLen
for j in countup(0, length-2):
var typ = semTypeNode(c, a.sons[j], nil)
if typ.kind == tyRef: typ = typ.sons[0]
if typ.kind != tyObject:
localError(a.sons[j].info, errExprCannotBeRaised)
a.sons[j] = newNodeI(nkType, a.sons[j].info)
a.sons[j].typ = typ
if containsOrIncl(check, typ.id):
localError(a.sons[j].info, errExceptionAlreadyHandled)
elif a.kind != nkFinally:
illFormedAst(n)
# last child of an nkExcept/nkFinally branch is a statement:
a.sons[length-1] = semExprBranchScope(c, a.sons[length-1])
if a.kind != nkFinally: typ = commonType(typ, a.sons[length-1].typ)
else: dec last
dec c.p.inTryStmt
if isEmptyType(typ) or typ.kind == tyNil:
discardCheck(c, n.sons[0])
for i in 1..n.len-1: discardCheck(c, n.sons[i].lastSon)
if typ == enforceVoidContext:
result.typ = enforceVoidContext
else:
if n.lastSon.kind == nkFinally: discardCheck(c, n.lastSon.lastSon)
n.sons[0] = fitNode(c, typ, n.sons[0])
for i in 1..last:
var it = n.sons[i]
let j = it.len-1
it.sons[j] = fitNode(c, typ, it.sons[j])
result.typ = typ
proc fitRemoveHiddenConv(c: PContext, typ: PType, n: PNode): PNode =
result = fitNode(c, typ, n)
if result.kind in {nkHiddenStdConv, nkHiddenSubConv}:
changeType(result.sons[1], typ, check=true)
result = result.sons[1]
elif not sameType(result.typ, typ):
changeType(result, typ, check=false)
proc findShadowedVar(c: PContext, v: PSym): PSym =
for scope in walkScopes(c.currentScope.parent):
if scope == c.topLevelScope: break
let shadowed = strTableGet(scope.symbols, v.name)
if shadowed != nil and shadowed.kind in skLocalVars:
return shadowed
proc identWithin(n: PNode, s: PIdent): bool =
for i in 0 .. n.safeLen-1:
if identWithin(n.sons[i], s): return true
result = n.kind == nkSym and n.sym.name.id == s.id
proc semIdentDef(c: PContext, n: PNode, kind: TSymKind): PSym =
if isTopLevel(c):
result = semIdentWithPragma(c, kind, n, {sfExported})
incl(result.flags, sfGlobal)
else:
result = semIdentWithPragma(c, kind, n, {})
suggestSym(n.info, result)
styleCheckDef(result)
proc checkNilable(v: PSym) =
if sfGlobal in v.flags and {tfNotNil, tfNeedsInit} * v.typ.flags != {}:
if v.ast.isNil:
message(v.info, warnProveInit, v.name.s)
elif tfNotNil in v.typ.flags and tfNotNil notin v.ast.typ.flags:
message(v.info, warnProveInit, v.name.s)
proc semVarOrLet(c: PContext, n: PNode, symkind: TSymKind): PNode =
var b: PNode
result = copyNode(n)
var hasCompileTime = false
for i in countup(0, sonsLen(n)-1):
var a = n.sons[i]
if gCmd == cmdIdeTools: suggestStmt(c, a)
if a.kind == nkCommentStmt: continue
if a.kind notin {nkIdentDefs, nkVarTuple, nkConstDef}: illFormedAst(a)
checkMinSonsLen(a, 3)
var length = sonsLen(a)
var typ: PType
if a.sons[length-2].kind != nkEmpty:
typ = semTypeNode(c, a.sons[length-2], nil)
else:
typ = nil
var def: PNode
if a.sons[length-1].kind != nkEmpty:
def = semExprWithType(c, a.sons[length-1], {efAllowDestructor})
if def.typ.kind == tyTypeDesc and c.p.owner.kind != skMacro:
# prevent the all too common 'var x = int' bug:
localError(def.info, "'typedesc' metatype is not valid here; typed '=' instead of ':'?")
def.typ = errorType(c)
if typ != nil:
if typ.isMetaType:
def = inferWithMetatype(c, typ, def)
typ = def.typ
else:
# BUGFIX: ``fitNode`` is needed here!
# check type compatibility between def.typ and typ
def = fitNode(c, typ, def)
#changeType(def.skipConv, typ, check=true)
else:
typ = skipIntLit(def.typ)
if typ.kind in {tySequence, tyArray, tySet} and
typ.lastSon.kind == tyEmpty:
localError(def.info, errCannotInferTypeOfTheLiteral,
($typ.kind).substr(2).toLower)
else:
def = ast.emptyNode
if symkind == skLet: localError(a.info, errLetNeedsInit)
# this can only happen for errornous var statements:
if typ == nil: continue
typeAllowedCheck(a.info, typ, symkind)
var tup = skipTypes(typ, {tyGenericInst})
if a.kind == nkVarTuple:
if tup.kind != tyTuple:
localError(a.info, errXExpected, "tuple")
elif length-2 != sonsLen(tup):
localError(a.info, errWrongNumberOfVariables)
else:
b = newNodeI(nkVarTuple, a.info)
newSons(b, length)
b.sons[length-2] = a.sons[length-2] # keep type desc for doc generator
b.sons[length-1] = def
addSon(result, b)
elif tup.kind == tyTuple and def.kind == nkPar and
a.kind == nkIdentDefs and a.len > 3:
message(a.info, warnEachIdentIsTuple)
for j in countup(0, length-3):
var v = semIdentDef(c, a.sons[j], symkind)
if sfGenSym notin v.flags: addInterfaceDecl(c, v)
when oKeepVariableNames:
if c.inUnrolledContext > 0: v.flags.incl(sfShadowed)
else:
let shadowed = findShadowedVar(c, v)
if shadowed != nil:
shadowed.flags.incl(sfShadowed)
if shadowed.kind == skResult and sfGenSym notin v.flags:
message(a.info, warnResultShadowed)
# a shadowed variable is an error unless it appears on the right
# side of the '=':
if warnShadowIdent in gNotes and not identWithin(def, v.name):
message(a.info, warnShadowIdent, v.name.s)
if a.kind != nkVarTuple:
if def != nil and def.kind != nkEmpty:
# this is needed for the evaluation pass and for the guard checking:
v.ast = def
if sfThread in v.flags: localError(def.info, errThreadvarCannotInit)
v.typ = typ
b = newNodeI(nkIdentDefs, a.info)
if importantComments():
# keep documentation information:
b.comment = a.comment
addSon(b, newSymNode(v))
addSon(b, a.sons[length-2]) # keep type desc for doc generator
addSon(b, copyTree(def))
addSon(result, b)
else:
if def.kind == nkPar: v.ast = def[j]
v.typ = tup.sons[j]
b.sons[j] = newSymNode(v)
checkNilable(v)
if sfCompileTime in v.flags: hasCompileTime = true
if hasCompileTime: vm.setupCompileTimeVar(c.module, result)
proc semConst(c: PContext, n: PNode): PNode =
result = copyNode(n)
for i in countup(0, sonsLen(n) - 1):
var a = n.sons[i]
if gCmd == cmdIdeTools: suggestStmt(c, a)
if a.kind == nkCommentStmt: continue
if (a.kind != nkConstDef): illFormedAst(a)
checkSonsLen(a, 3)
var v = semIdentDef(c, a.sons[0], skConst)
var typ: PType = nil
if a.sons[1].kind != nkEmpty: typ = semTypeNode(c, a.sons[1], nil)
var def = semConstExpr(c, a.sons[2])
if def == nil:
localError(a.sons[2].info, errConstExprExpected)
continue
# check type compatibility between def.typ and typ:
if typ != nil:
def = fitRemoveHiddenConv(c, typ, def)
else:
typ = def.typ
if typ == nil:
localError(a.sons[2].info, errConstExprExpected)
continue
if typeAllowed(typ, skConst) != nil and def.kind != nkNilLit:
localError(a.info, errXisNoType, typeToString(typ))
continue
v.typ = typ
v.ast = def # no need to copy
if sfGenSym notin v.flags: addInterfaceDecl(c, v)
var b = newNodeI(nkConstDef, a.info)
if importantComments(): b.comment = a.comment
addSon(b, newSymNode(v))
addSon(b, a.sons[1])
addSon(b, copyTree(def))
addSon(result, b)
include semfields
proc addForVarDecl(c: PContext, v: PSym) =
if warnShadowIdent in gNotes:
let shadowed = findShadowedVar(c, v)
if shadowed != nil:
# XXX should we do this here?
#shadowed.flags.incl(sfShadowed)
message(v.info, warnShadowIdent, v.name.s)
addDecl(c, v)
proc symForVar(c: PContext, n: PNode): PSym =
let m = if n.kind == nkPragmaExpr: n.sons[0] else: n
result = newSymG(skForVar, m, c)
styleCheckDef(result)
proc semForVars(c: PContext, n: PNode): PNode =
result = n
var length = sonsLen(n)
let iterBase = n.sons[length-2].typ.skipTypes({tyIter})
var iter = skipTypes(iterBase, {tyGenericInst})
# length == 3 means that there is one for loop variable
# and thus no tuple unpacking:
if iter.kind != tyTuple or length == 3:
if length == 3:
var v = symForVar(c, n.sons[0])
if getCurrOwner().kind == skModule: incl(v.flags, sfGlobal)
# BUGFIX: don't use `iter` here as that would strip away
# the ``tyGenericInst``! See ``tests/compile/tgeneric.nim``
# for an example:
v.typ = iterBase
n.sons[0] = newSymNode(v)
if sfGenSym notin v.flags: addForVarDecl(c, v)
else:
localError(n.info, errWrongNumberOfVariables)
elif length-2 != sonsLen(iter):
localError(n.info, errWrongNumberOfVariables)
else:
for i in countup(0, length - 3):
var v = symForVar(c, n.sons[i])
if getCurrOwner().kind == skModule: incl(v.flags, sfGlobal)
v.typ = iter.sons[i]
n.sons[i] = newSymNode(v)
if sfGenSym notin v.flags: addForVarDecl(c, v)
inc(c.p.nestedLoopCounter)
n.sons[length-1] = semStmt(c, n.sons[length-1])
dec(c.p.nestedLoopCounter)
proc implicitIterator(c: PContext, it: string, arg: PNode): PNode =
result = newNodeI(nkCall, arg.info)
result.add(newIdentNode(it.getIdent, arg.info))
if arg.typ != nil and arg.typ.kind == tyVar:
result.add newDeref(arg)
else:
result.add arg
result = semExprNoDeref(c, result, {efWantIterator})
proc semFor(c: PContext, n: PNode): PNode =
result = n
checkMinSonsLen(n, 3)
var length = sonsLen(n)
openScope(c)
n.sons[length-2] = semExprNoDeref(c, n.sons[length-2], {efWantIterator})
var call = n.sons[length-2]
let isCallExpr = call.kind in nkCallKinds
if isCallExpr and call[0].kind == nkSym and
call[0].sym.magic in {mFields, mFieldPairs, mOmpParFor}:
if call.sons[0].sym.magic == mOmpParFor:
result = semForVars(c, n)
result.kind = nkParForStmt
else:
result = semForFields(c, n, call.sons[0].sym.magic)
elif (isCallExpr and call.sons[0].typ.callConv == ccClosure) or
call.typ.kind == tyIter:
# first class iterator:
result = semForVars(c, n)
elif not isCallExpr or call.sons[0].kind != nkSym or
call.sons[0].sym.kind notin skIterators:
if length == 3:
n.sons[length-2] = implicitIterator(c, "items", n.sons[length-2])
elif length == 4:
n.sons[length-2] = implicitIterator(c, "pairs", n.sons[length-2])
else:
localError(n.sons[length-2].info, errIteratorExpected)
result = semForVars(c, n)
else:
result = semForVars(c, n)
# propagate any enforced VoidContext:
if n.sons[length-1].typ == enforceVoidContext:
result.typ = enforceVoidContext
closeScope(c)
proc semRaise(c: PContext, n: PNode): PNode =
result = n
checkSonsLen(n, 1)
if n.sons[0].kind != nkEmpty:
n.sons[0] = semExprWithType(c, n.sons[0])
var typ = n.sons[0].typ
if typ.kind != tyRef or typ.sons[0].kind != tyObject:
localError(n.info, errExprCannotBeRaised)
proc addGenericParamListToScope(c: PContext, n: PNode) =
if n.kind != nkGenericParams: illFormedAst(n)
for i in countup(0, sonsLen(n)-1):
var a = n.sons[i]
if a.kind == nkSym: addDecl(c, a.sym)
else: illFormedAst(a)
proc typeSectionLeftSidePass(c: PContext, n: PNode) =
# process the symbols on the left side for the whole type section, before
# we even look at the type definitions on the right
for i in countup(0, sonsLen(n) - 1):
var a = n.sons[i]
if gCmd == cmdIdeTools: suggestStmt(c, a)
if a.kind == nkCommentStmt: continue
if a.kind != nkTypeDef: illFormedAst(a)
checkSonsLen(a, 3)
var s = semIdentDef(c, a.sons[0], skType)
s.typ = newTypeS(tyForward, c)
s.typ.sym = s # process pragmas:
if a.sons[0].kind == nkPragmaExpr:
pragma(c, s, a.sons[0].sons[1], typePragmas)
# add it here, so that recursive types are possible:
if sfGenSym notin s.flags: addInterfaceDecl(c, s)
a.sons[0] = newSymNode(s)
proc typeSectionRightSidePass(c: PContext, n: PNode) =
for i in countup(0, sonsLen(n) - 1):
var a = n.sons[i]
if a.kind == nkCommentStmt: continue
if (a.kind != nkTypeDef): illFormedAst(a)
checkSonsLen(a, 3)
if (a.sons[0].kind != nkSym): illFormedAst(a)
var s = a.sons[0].sym
if s.magic == mNone and a.sons[2].kind == nkEmpty:
localError(a.info, errImplOfXexpected, s.name.s)
if s.magic != mNone: processMagicType(c, s)
if a.sons[1].kind != nkEmpty:
# We have a generic type declaration here. In generic types,
# symbol lookup needs to be done here.
openScope(c)
pushOwner(s)
if s.magic == mNone: s.typ.kind = tyGenericBody
# XXX for generic type aliases this is not correct! We need the
# underlying Id really:
#
# type
# TGObj[T] = object
# TAlias[T] = TGObj[T]
#
s.typ.n = semGenericParamList(c, a.sons[1], s.typ)
a.sons[1] = s.typ.n
s.typ.size = -1 # could not be computed properly
# we fill it out later. For magic generics like 'seq', it won't be filled
# so we use tyEmpty instead of nil to not crash for strange conversions
# like: mydata.seq
rawAddSon(s.typ, newTypeS(tyNone, c))
s.ast = a
inc c.inGenericContext
var body = semTypeNode(c, a.sons[2], nil)
dec c.inGenericContext
if body != nil:
body.sym = s
body.size = -1 # could not be computed properly
s.typ.sons[sonsLen(s.typ) - 1] = body
popOwner()
closeScope(c)
elif a.sons[2].kind != nkEmpty:
# process the type's body:
pushOwner(s)
var t = semTypeNode(c, a.sons[2], s.typ)
if s.typ == nil:
s.typ = t
elif t != s.typ:
# this can happen for e.g. tcan_alias_specialised_generic:
assignType(s.typ, t)
#debug s.typ
s.ast = a
popOwner()
proc checkForMetaFields(n: PNode) =
template checkMeta(t) =
if t != nil and t.isMetaType and tfGenericTypeParam notin t.flags:
localError(n.info, errTIsNotAConcreteType, t.typeToString)
if n.isNil: return
case n.kind
of nkRecList, nkRecCase:
for s in n: checkForMetaFields(s)
of nkOfBranch, nkElse:
checkForMetaFields(n.lastSon)
of nkSym:
let t = n.sym.typ
case t.kind
of tySequence, tySet, tyArray, tyOpenArray, tyVar, tyPtr, tyRef,
tyProc, tyGenericInvocation, tyGenericInst:
let start = ord(t.kind in {tyGenericInvocation, tyGenericInst})
for i in start .. <t.sons.len:
checkMeta(t.sons[i])
else:
checkMeta(t)
else:
internalAssert false
proc typeSectionFinalPass(c: PContext, n: PNode) =
for i in countup(0, sonsLen(n) - 1):
var a = n.sons[i]
if a.kind == nkCommentStmt: continue
if a.sons[0].kind != nkSym: illFormedAst(a)
var s = a.sons[0].sym
# compute the type's size and check for illegal recursions:
if a.sons[1].kind == nkEmpty:
if a.sons[2].kind in {nkSym, nkIdent, nkAccQuoted}:
# type aliases are hard:
#MessageOut('for type ' + typeToString(s.typ));
var t = semTypeNode(c, a.sons[2], nil)
if t.kind in {tyObject, tyEnum}:
assignType(s.typ, t)
s.typ.id = t.id # same id
checkConstructedType(s.info, s.typ)
if s.typ.kind in {tyObject, tyTuple} and not s.typ.n.isNil:
checkForMetaFields(s.typ.n)
let aa = a.sons[2]
if aa.kind in {nkRefTy, nkPtrTy} and aa.len == 1 and
aa.sons[0].kind == nkObjectTy:
# give anonymous object a dummy symbol:
var st = s.typ
if st.kind == tyGenericBody: st = st.lastSon
internalAssert st.kind in {tyPtr, tyRef}
internalAssert st.lastSon.sym == nil
st.lastSon.sym = newSym(skType, getIdent(s.name.s & ":ObjectType"),
getCurrOwner(), s.info)
proc semTypeSection(c: PContext, n: PNode): PNode =
## Processes a type section. This must be done in separate passes, in order
## to allow the type definitions in the section to reference each other
## without regard for the order of their definitions.
typeSectionLeftSidePass(c, n)
typeSectionRightSidePass(c, n)
typeSectionFinalPass(c, n)
result = n
proc semParamList(c: PContext, n, genericParams: PNode, s: PSym) =
s.typ = semProcTypeNode(c, n, genericParams, nil, s.kind)
if s.kind notin {skMacro, skTemplate}:
if s.typ.sons[0] != nil and s.typ.sons[0].kind == tyStmt:
localError(n.info, errGenerated, "invalid return type: 'stmt'")
proc addParams(c: PContext, n: PNode, kind: TSymKind) =
for i in countup(1, sonsLen(n)-1):
if n.sons[i].kind == nkSym: addParamOrResult(c, n.sons[i].sym, kind)
else: illFormedAst(n)
proc semBorrow(c: PContext, n: PNode, s: PSym) =
# search for the correct alias:
var b = searchForBorrowProc(c, c.currentScope.parent, s)
if b != nil:
# store the alias:
n.sons[bodyPos] = newSymNode(b)
else:
localError(n.info, errNoSymbolToBorrowFromFound)
proc addResult(c: PContext, t: PType, info: TLineInfo, owner: TSymKind) =
if t != nil:
var s = newSym(skResult, getIdent"result", getCurrOwner(), info)
s.typ = t
incl(s.flags, sfUsed)
addParamOrResult(c, s, owner)
c.p.resultSym = s
proc addResultNode(c: PContext, n: PNode) =
if c.p.resultSym != nil: addSon(n, newSymNode(c.p.resultSym))
proc copyExcept(n: PNode, i: int): PNode =
result = copyNode(n)
for j in 0.. <n.len:
if j != i: result.add(n.sons[j])
proc lookupMacro(c: PContext, n: PNode): PSym =
if n.kind == nkSym:
result = n.sym
if result.kind notin {skMacro, skTemplate}: result = nil
else:
result = searchInScopes(c, considerQuotedIdent(n), {skMacro, skTemplate})
proc semProcAnnotation(c: PContext, prc: PNode;
validPragmas: TSpecialWords): PNode =
var n = prc.sons[pragmasPos]
if n == nil or n.kind == nkEmpty: return
for i in countup(0, <n.len):
var it = n.sons[i]
var key = if it.kind == nkExprColonExpr: it.sons[0] else: it
let m = lookupMacro(c, key)
if m == nil:
if key.kind == nkIdent and key.ident.id == ord(wDelegator):
if considerQuotedIdent(prc.sons[namePos]).s == "()":
prc.sons[namePos] = newIdentNode(idDelegator, prc.info)
prc.sons[pragmasPos] = copyExcept(n, i)
else:
localError(prc.info, errOnlyACallOpCanBeDelegator)
continue
# we transform ``proc p {.m, rest.}`` into ``m(do: proc p {.rest.})`` and
# let the semantic checker deal with it:
var x = newNodeI(nkCall, n.info)
x.add(newSymNode(m))
prc.sons[pragmasPos] = copyExcept(n, i)
if it.kind == nkExprColonExpr:
# pass pragma argument to the macro too:
x.add(it.sons[1])
x.add(prc)
# recursion assures that this works for multiple macro annotations too:
result = semStmt(c, x)
# since a proc annotation can set pragmas, we process these here again.
# This is required for SqueakNim-like export pragmas.
if result.kind in procDefs and result[namePos].kind == nkSym and
result[pragmasPos].kind != nkEmpty:
pragma(c, result[namePos].sym, result[pragmasPos], validPragmas)
return
proc semLambda(c: PContext, n: PNode, flags: TExprFlags): PNode =
# XXX semProcAux should be good enough for this now, we will eventually
# remove semLambda
result = semProcAnnotation(c, n, lambdaPragmas)
if result != nil: return result
result = n
checkSonsLen(n, bodyPos + 1)
var s: PSym
if n[namePos].kind != nkSym:
s = newSym(skProc, idAnon, getCurrOwner(), n.info)
s.ast = n
n.sons[namePos] = newSymNode(s)
else:
s = n[namePos].sym
pushOwner(s)
openScope(c)
var gp: PNode
if n.sons[genericParamsPos].kind != nkEmpty:
n.sons[genericParamsPos] = semGenericParamList(c, n.sons[genericParamsPos])
gp = n.sons[genericParamsPos]
else:
gp = newNodeI(nkGenericParams, n.info)
if n.sons[paramsPos].kind != nkEmpty:
#if n.kind == nkDo and not experimentalMode(c):
# localError(n.sons[paramsPos].info,
# "use the {.experimental.} pragma to enable 'do' with parameters")
semParamList(c, n.sons[paramsPos], gp, s)
# paramsTypeCheck(c, s.typ)
if sonsLen(gp) > 0 and n.sons[genericParamsPos].kind == nkEmpty:
# we have a list of implicit type parameters:
n.sons[genericParamsPos] = gp
else:
s.typ = newProcType(c, n.info)
if n.sons[pragmasPos].kind != nkEmpty:
pragma(c, s, n.sons[pragmasPos], lambdaPragmas)
s.options = gOptions
if n.sons[bodyPos].kind != nkEmpty:
if sfImportc in s.flags:
localError(n.sons[bodyPos].info, errImplOfXNotAllowed, s.name.s)
#if efDetermineType notin flags:
# XXX not good enough; see tnamedparamanonproc.nim
if gp.len == 0 or (gp.len == 1 and tfRetType in gp[0].typ.flags):
pushProcCon(c, s)
addResult(c, s.typ.sons[0], n.info, skProc)
addResultNode(c, n)
let semBody = hloBody(c, semProcBody(c, n.sons[bodyPos]))
n.sons[bodyPos] = transformBody(c.module, semBody, s)
popProcCon(c)
elif efOperand notin flags:
localError(n.info, errGenericLambdaNotAllowed)
sideEffectsCheck(c, s)
else:
localError(n.info, errImplOfXexpected, s.name.s)
closeScope(c) # close scope for parameters
popOwner()
result.typ = s.typ
proc semDo(c: PContext, n: PNode, flags: TExprFlags): PNode =
# 'do' without params produces a stmt:
if n[genericParamsPos].kind == nkEmpty and n[paramsPos].kind == nkEmpty:
result = semStmt(c, n[bodyPos])
else:
result = semLambda(c, n, flags)
proc semInferredLambda(c: PContext, pt: TIdTable, n: PNode): PNode =
var n = n
n = replaceTypesInBody(c, pt, n)
result = n
n.sons[genericParamsPos] = emptyNode
n.sons[paramsPos] = n.typ.n
openScope(c)
var s = n.sons[namePos].sym
pushOwner(s)
addParams(c, n.typ.n, skProc)
pushProcCon(c, s)
addResult(c, n.typ.sons[0], n.info, skProc)
addResultNode(c, n)
let semBody = hloBody(c, semProcBody(c, n.sons[bodyPos]))
n.sons[bodyPos] = transformBody(c.module, semBody, n.sons[namePos].sym)
popProcCon(c)
popOwner()
closeScope(c)
s.ast = result
# alternative variant (not quite working):
# var prc = arg[0].sym
# let inferred = c.semGenerateInstance(c, prc, m.bindings, arg.info)
# result = inferred.ast
# result.kind = arg.kind
proc activate(c: PContext, n: PNode) =
# XXX: This proc is part of my plan for getting rid of
# forward declarations. stay tuned.
when false:
# well for now it breaks code ...
case n.kind
of nkLambdaKinds:
discard semLambda(c, n, {})
of nkCallKinds:
for i in 1 .. <n.len: activate(c, n[i])
else:
discard
proc maybeAddResult(c: PContext, s: PSym, n: PNode) =
if s.typ.sons[0] != nil and s.kind != skIterator:
addResult(c, s.typ.sons[0], n.info, s.kind)
addResultNode(c, n)
proc semOverride(c: PContext, s: PSym, n: PNode) =
case s.name.s.normalize
of "destroy":
doDestructorStuff(c, s, n)
if not experimentalMode(c):
localError n.info, "use the {.experimental.} pragma to enable destructors"
of "deepcopy":
if s.typ.len == 2 and
s.typ.sons[1].skipTypes(abstractInst).kind in {tyRef, tyPtr} and
sameType(s.typ.sons[1], s.typ.sons[0]):
# Note: we store the deepCopy in the base of the pointer to mitigate
# the problem that pointers are structural types:
var t = s.typ.sons[1].skipTypes(abstractInst).lastSon.skipTypes(abstractInst)
while true:
if t.kind == tyGenericBody: t = t.lastSon
elif t.kind == tyGenericInvocation: t = t.sons[0]
else: break
if t.kind in {tyObject, tyDistinct, tyEnum}:
if t.deepCopy.isNil: t.deepCopy = s
else:
localError(n.info, errGenerated,
"cannot bind another 'deepCopy' to: " & typeToString(t))
else:
localError(n.info, errGenerated,
"cannot bind 'deepCopy' to: " & typeToString(t))
else:
localError(n.info, errGenerated,
"signature for 'deepCopy' must be proc[T: ptr|ref](x: T): T")
of "=": discard
else: localError(n.info, errGenerated,
"'destroy' or 'deepCopy' expected for 'override'")
incl(s.flags, sfUsed)
type
TProcCompilationSteps = enum
stepRegisterSymbol,
stepDetermineType,
stepCompileBody
proc isForwardDecl(s: PSym): bool =
internalAssert s.kind == skProc
result = s.ast[bodyPos].kind != nkEmpty
proc semProcAux(c: PContext, n: PNode, kind: TSymKind,
validPragmas: TSpecialWords,
phase = stepRegisterSymbol): PNode =
result = semProcAnnotation(c, n, validPragmas)
if result != nil: return result
result = n
checkSonsLen(n, bodyPos + 1)
var s: PSym
var typeIsDetermined = false
var isAnon = false
if n[namePos].kind != nkSym:
assert phase == stepRegisterSymbol
if n[namePos].kind == nkEmpty:
s = newSym(kind, idAnon, getCurrOwner(), n.info)
isAnon = true
else:
s = semIdentDef(c, n.sons[0], kind)
n.sons[namePos] = newSymNode(s)
s.ast = n
s.scope = c.currentScope
if sfNoForward in c.module.flags and
sfSystemModule notin c.module.flags:
addInterfaceOverloadableSymAt(c, c.currentScope, s)
s.flags.incl sfForward
return
else:
s = n[namePos].sym
s.owner = getCurrOwner()
typeIsDetermined = s.typ == nil
s.ast = n
s.scope = c.currentScope
# if typeIsDetermined: assert phase == stepCompileBody
# else: assert phase == stepDetermineType
# before compiling the proc body, set as current the scope
# where the proc was declared
let oldScope = c.currentScope
c.currentScope = s.scope
pushOwner(s)
openScope(c)
var gp: PNode
if n.sons[genericParamsPos].kind != nkEmpty:
n.sons[genericParamsPos] = semGenericParamList(c, n.sons[genericParamsPos])
gp = n.sons[genericParamsPos]
else:
gp = newNodeI(nkGenericParams, n.info)
# process parameters:
if n.sons[paramsPos].kind != nkEmpty:
semParamList(c, n.sons[paramsPos], gp, s)
if sonsLen(gp) > 0:
if n.sons[genericParamsPos].kind == nkEmpty:
# we have a list of implicit type parameters:
n.sons[genericParamsPos] = gp
# check for semantics again:
# semParamList(c, n.sons[ParamsPos], nil, s)
else:
s.typ = newProcType(c, n.info)
if n.sons[patternPos].kind != nkEmpty:
n.sons[patternPos] = semPattern(c, n.sons[patternPos])
if s.kind in skIterators:
s.typ.flags.incl(tfIterator)
var proto = searchForProc(c, s.scope, s)
if proto == nil:
if s.kind == skClosureIterator: s.typ.callConv = ccClosure
else: s.typ.callConv = lastOptionEntry(c).defaultCC
# add it here, so that recursive procs are possible:
if sfGenSym in s.flags: discard
elif kind in OverloadableSyms:
if not typeIsDetermined:
addInterfaceOverloadableSymAt(c, s.scope, s)
else:
if not typeIsDetermined:
addInterfaceDeclAt(c, s.scope, s)
if n.sons[pragmasPos].kind != nkEmpty:
pragma(c, s, n.sons[pragmasPos], validPragmas)
else:
implicitPragmas(c, s, n, validPragmas)
else:
if n.sons[pragmasPos].kind != nkEmpty:
localError(n.sons[pragmasPos].info, errPragmaOnlyInHeaderOfProc)
if sfForward notin proto.flags:
wrongRedefinition(n.info, proto.name.s)
excl(proto.flags, sfForward)
closeScope(c) # close scope with wrong parameter symbols
openScope(c) # open scope for old (correct) parameter symbols
if proto.ast.sons[genericParamsPos].kind != nkEmpty:
addGenericParamListToScope(c, proto.ast.sons[genericParamsPos])
addParams(c, proto.typ.n, proto.kind)
proto.info = s.info # more accurate line information
s.typ = proto.typ
s = proto
n.sons[genericParamsPos] = proto.ast.sons[genericParamsPos]
n.sons[paramsPos] = proto.ast.sons[paramsPos]
n.sons[pragmasPos] = proto.ast.sons[pragmasPos]
if n.sons[namePos].kind != nkSym: internalError(n.info, "semProcAux")
n.sons[namePos].sym = proto
if importantComments() and not isNil(proto.ast.comment):
n.comment = proto.ast.comment
proto.ast = n # needed for code generation
popOwner()
pushOwner(s)
s.options = gOptions
if sfOverriden in s.flags: semOverride(c, s, n)
if n.sons[bodyPos].kind != nkEmpty:
# for DLL generation it is annoying to check for sfImportc!
if sfBorrow in s.flags:
localError(n.sons[bodyPos].info, errImplOfXNotAllowed, s.name.s)
let usePseudoGenerics = kind in {skMacro, skTemplate}
# Macros and Templates can have generic parameters, but they are
# only used for overload resolution (there is no instantiation of
# the symbol, so we must process the body now)
if n.sons[genericParamsPos].kind == nkEmpty or usePseudoGenerics:
if not usePseudoGenerics: paramsTypeCheck(c, s.typ)
pushProcCon(c, s)
c.p.wasForwarded = proto != nil
maybeAddResult(c, s, n)
if sfImportc notin s.flags:
# no semantic checking for importc:
let semBody = hloBody(c, semProcBody(c, n.sons[bodyPos]))
# unfortunately we cannot skip this step when in 'system.compiles'
# context as it may even be evaluated in 'system.compiles':
n.sons[bodyPos] = transformBody(c.module, semBody, s)
popProcCon(c)
else:
if s.typ.sons[0] != nil and kind notin skIterators:
addDecl(c, newSym(skUnknown, getIdent"result", nil, n.info))
openScope(c)
n.sons[bodyPos] = semGenericStmt(c, n.sons[bodyPos])
closeScope(c)
fixupInstantiatedSymbols(c, s)
if sfImportc in s.flags:
# so we just ignore the body after semantic checking for importc:
n.sons[bodyPos] = ast.emptyNode
else:
if proto != nil: localError(n.info, errImplOfXexpected, proto.name.s)
if {sfImportc, sfBorrow} * s.flags == {} and s.magic == mNone:
incl(s.flags, sfForward)
elif sfBorrow in s.flags: semBorrow(c, n, s)
sideEffectsCheck(c, s)
closeScope(c) # close scope for parameters
c.currentScope = oldScope
popOwner()
if n.sons[patternPos].kind != nkEmpty:
c.patterns.add(s)
if isAnon: result.typ = s.typ
proc determineType(c: PContext, s: PSym) =
if s.typ != nil: return
#if s.magic != mNone: return
discard semProcAux(c, s.ast, s.kind, {}, stepDetermineType)
proc semIterator(c: PContext, n: PNode): PNode =
let kind = if hasPragma(n[pragmasPos], wClosure) or
n[namePos].kind == nkEmpty: skClosureIterator
else: skIterator
# gensym'ed iterator?
if n[namePos].kind == nkSym:
# gensym'ed iterators might need to become closure iterators:
n[namePos].sym.owner = getCurrOwner()
n[namePos].sym.kind = kind
result = semProcAux(c, n, kind, iteratorPragmas)
var s = result.sons[namePos].sym
var t = s.typ
if t.sons[0] == nil and s.typ.callConv != ccClosure:
localError(n.info, errXNeedsReturnType, "iterator")
# iterators are either 'inline' or 'closure'; for backwards compatibility,
# we require first class iterators to be marked with 'closure' explicitly
# -- at least for 0.9.2.
if s.typ.callConv == ccClosure:
incl(s.typ.flags, tfCapturesEnv)
else:
s.typ.callConv = ccInline
when false:
if s.typ.callConv != ccInline:
s.typ.callConv = ccClosure
# and they always at least use the 'env' for the state field:
incl(s.typ.flags, tfCapturesEnv)
if n.sons[bodyPos].kind == nkEmpty and s.magic == mNone:
localError(n.info, errImplOfXexpected, s.name.s)
proc semProc(c: PContext, n: PNode): PNode =
result = semProcAux(c, n, skProc, procPragmas)
proc hasObjParam(s: PSym): bool =
var t = s.typ
for col in countup(1, sonsLen(t)-1):
if skipTypes(t.sons[col], skipPtrs).kind == tyObject:
return true
proc finishMethod(c: PContext, s: PSym) =
if hasObjParam(s):
methodDef(s, false)
proc semMethod(c: PContext, n: PNode): PNode =
if not isTopLevel(c): localError(n.info, errXOnlyAtModuleScope, "method")
result = semProcAux(c, n, skMethod, methodPragmas)
var s = result.sons[namePos].sym
if not isGenericRoutine(s):
# why check for the body? bug #2400 has none. Checking for sfForward makes
# no sense either.
# and result.sons[bodyPos].kind != nkEmpty:
if hasObjParam(s):
methodDef(s, fromCache=false)
else:
localError(n.info, errXNeedsParamObjectType, "method")
proc semConverterDef(c: PContext, n: PNode): PNode =
if not isTopLevel(c): localError(n.info, errXOnlyAtModuleScope, "converter")
checkSonsLen(n, bodyPos + 1)
result = semProcAux(c, n, skConverter, converterPragmas)
var s = result.sons[namePos].sym
var t = s.typ
if t.sons[0] == nil: localError(n.info, errXNeedsReturnType, "converter")
if sonsLen(t) != 2: localError(n.info, errXRequiresOneArgument, "converter")
addConverter(c, s)
proc semMacroDef(c: PContext, n: PNode): PNode =
checkSonsLen(n, bodyPos + 1)
result = semProcAux(c, n, skMacro, macroPragmas)
var s = result.sons[namePos].sym
var t = s.typ
if t.sons[0] == nil: localError(n.info, errXNeedsReturnType, "macro")
if n.sons[bodyPos].kind == nkEmpty:
localError(n.info, errImplOfXexpected, s.name.s)
proc evalInclude(c: PContext, n: PNode): PNode =
result = newNodeI(nkStmtList, n.info)
addSon(result, n)
for i in countup(0, sonsLen(n) - 1):
var f = checkModuleName(n.sons[i])
if f != InvalidFileIDX:
if containsOrIncl(c.includedFiles, f):
localError(n.info, errRecursiveDependencyX, f.toFilename)
else:
addSon(result, semStmt(c, gIncludeFile(c.module, f)))
excl(c.includedFiles, f)
proc setLine(n: PNode, info: TLineInfo) =
for i in 0 .. <safeLen(n): setLine(n.sons[i], info)
n.info = info
proc semPragmaBlock(c: PContext, n: PNode): PNode =
let pragmaList = n.sons[0]
pragma(c, nil, pragmaList, exprPragmas)
result = semExpr(c, n.sons[1])
n.sons[1] = result
for i in 0 .. <pragmaList.len:
case whichPragma(pragmaList.sons[i])
of wLine: setLine(result, pragmaList.sons[i].info)
of wLocks:
result = n
result.typ = n.sons[1].typ
else: discard
proc semStaticStmt(c: PContext, n: PNode): PNode =
#echo "semStaticStmt"
#writeStackTrace()
let a = semStmt(c, n.sons[0])
n.sons[0] = a
evalStaticStmt(c.module, a, c.p.owner)
result = newNodeI(nkDiscardStmt, n.info, 1)
result.sons[0] = emptyNode
when false:
result = evalStaticStmt(c.module, a, c.p.owner)
if result.isNil:
LocalError(n.info, errCannotInterpretNodeX, renderTree(n))
result = emptyNode
elif result.kind == nkEmpty:
result = newNodeI(nkDiscardStmt, n.info, 1)
result.sons[0] = emptyNode
proc usesResult(n: PNode): bool =
# nkStmtList(expr) properly propagates the void context,
# so we don't need to process that all over again:
if n.kind notin {nkStmtList, nkStmtListExpr,
nkMacroDef, nkTemplateDef} + procDefs:
if isAtom(n):
result = n.kind == nkSym and n.sym.kind == skResult
elif n.kind == nkReturnStmt:
result = true
else:
for c in n:
if usesResult(c): return true
proc semStmtList(c: PContext, n: PNode, flags: TExprFlags): PNode =
# these must be last statements in a block:
const
LastBlockStmts = {nkRaiseStmt, nkReturnStmt, nkBreakStmt, nkContinueStmt}
result = n
result.kind = nkStmtList
var length = sonsLen(n)
var voidContext = false
var last = length-1
# by not allowing for nkCommentStmt etc. we ensure nkStmtListExpr actually
# really *ends* in the expression that produces the type: The compiler now
# relies on this fact and it's too much effort to change that. And arguably
# 'R(); #comment' shouldn't produce R's type anyway.
#while last > 0 and n.sons[last].kind in {nkPragma, nkCommentStmt,
# nkNilLit, nkEmpty}:
# dec last
for i in countup(0, length - 1):
let k = n.sons[i].kind
case k
of nkFinally, nkExceptBranch, nkDefer:
# stand-alone finally and except blocks are
# transformed into regular try blocks:
#
# var f = fopen("somefile") | var f = fopen("somefile")
# finally: fclose(f) | try:
# ... | ...
# | finally:
# | fclose(f)
var deferPart: PNode
if k == nkDefer:
deferPart = newNodeI(nkFinally, n.sons[i].info)
deferPart.add n.sons[i].sons[0]
elif k == nkFinally:
message(n.info, warnDeprecated,
"use 'defer'; standalone 'finally'")
deferPart = n.sons[i]
else:
message(n.info, warnDeprecated,
"use an explicit 'try'; standalone 'except'")
deferPart = n.sons[i]
var tryStmt = newNodeI(nkTryStmt, n.sons[i].info)
var body = newNodeI(nkStmtList, n.sons[i].info)
if i < n.sonsLen - 1:
body.sons = n.sons[(i+1)..(-1)]
tryStmt.addSon(body)
tryStmt.addSon(deferPart)
n.sons[i] = semTry(c, tryStmt)
n.sons.setLen(i+1)
n.typ = n.sons[i].typ
return
else:
n.sons[i] = semExpr(c, n.sons[i])
if c.inTypeClass > 0 and n[i].typ != nil:
case n[i].typ.kind
of tyBool:
let verdict = semConstExpr(c, n[i])
if verdict.intVal == 0:
localError(result.info, "type class predicate failed")
of tyUnknown: continue
else: discard
if n.sons[i].typ == enforceVoidContext or usesResult(n.sons[i]):
voidContext = true
n.typ = enforceVoidContext
if i == last and (length == 1 or efWantValue in flags):
n.typ = n.sons[i].typ
if not isEmptyType(n.typ): n.kind = nkStmtListExpr
elif i != last or voidContext:
discardCheck(c, n.sons[i])
else:
n.typ = n.sons[i].typ
if not isEmptyType(n.typ): n.kind = nkStmtListExpr
case n.sons[i].kind
of nkVarSection, nkLetSection:
let (outer, inner) = insertDestructors(c, n.sons[i])
if outer != nil:
n.sons[i] = outer
var rest = newNode(nkStmtList, n.info, n.sons[i+1 .. length-1])
inner.addSon(semStmtList(c, rest, flags))
n.sons.setLen(i+1)
return
of LastBlockStmts:
for j in countup(i + 1, length - 1):
case n.sons[j].kind
of nkPragma, nkCommentStmt, nkNilLit, nkEmpty: discard
else: localError(n.sons[j].info, errStmtInvalidAfterReturn)
else: discard
if result.len == 1:
result = result.sons[0]
when defined(nimfix):
if result.kind == nkCommentStmt and not result.comment.isNil and
not (result.comment[0] == '#' and result.comment[1] == '#'):
# it is an old-style comment statement: we replace it with 'discard ""':
prettybase.replaceComment(result.info)
when false:
# a statement list (s; e) has the type 'e':
if result.kind == nkStmtList and result.len > 0:
var lastStmt = lastSon(result)
if lastStmt.kind != nkNilLit and not implicitlyDiscardable(lastStmt):
result.typ = lastStmt.typ
#localError(lastStmt.info, errGenerated,
# "Last expression must be explicitly returned if it " &
# "is discardable or discarded")
proc semStmt(c: PContext, n: PNode): PNode =
# now: simply an alias:
result = semExprNoType(c, n)
proc semStmtScope(c: PContext, n: PNode): PNode =
openScope(c)
result = semStmt(c, n)
closeScope(c)