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- #
- #
- # 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
- const
- errNoSymbolToBorrowFromFound = "no symbol to borrow from found"
- errDiscardValueX = "value of type '$1' has to be used (or discarded)"
- errInvalidDiscard = "statement returns no value that can be discarded"
- errInvalidControlFlowX = "invalid control flow: $1"
- errSelectorMustBeOfCertainTypes = "selector must be of an ordinal type, float or string"
- errExprCannotBeRaised = "only a 'ref object' can be raised"
- errBreakOnlyInLoop = "'break' only allowed in loop construct"
- errExceptionAlreadyHandled = "exception already handled"
- errYieldNotAllowedHere = "'yield' only allowed in an iterator"
- errYieldNotAllowedInTryStmt = "'yield' cannot be used within 'try' in a non-inlined iterator"
- errInvalidNumberOfYieldExpr = "invalid number of 'yield' expressions"
- errCannotReturnExpr = "current routine cannot return an expression"
- errGenericLambdaNotAllowed = "A nested proc can have generic parameters only when " &
- "it is used as an operand to another routine and the types " &
- "of the generic paramers can be inferred from the expected signature."
- errCannotInferTypeOfTheLiteral = "cannot infer the type of the $1"
- errCannotInferReturnType = "cannot infer the return type of '$1'"
- errCannotInferStaticParam = "cannot infer the value of the static param '$1'"
- errProcHasNoConcreteType = "'$1' doesn't have a concrete type, due to unspecified generic parameters."
- errLetNeedsInit = "'let' symbol requires an initialization"
- errThreadvarCannotInit = "a thread var cannot be initialized explicitly; this would only run for the main thread"
- errImplOfXexpected = "implementation of '$1' expected"
- errRecursiveDependencyX = "recursive dependency: '$1'"
- errRecursiveDependencyIteratorX = "recursion is not supported in iterators: '$1'"
- errPragmaOnlyInHeaderOfProcX = "pragmas are only allowed in the header of a proc; redefinition of $1"
- errCannotAssignToGlobal = "cannot assign local to global variable"
- proc implicitlyDiscardable(n: PNode): bool
- proc hasEmpty(typ: PType): bool =
- if typ.kind in {tySequence, tyArray, tySet}:
- result = typ.lastSon.kind == tyEmpty
- elif typ.kind == tyTuple:
- for s in typ.sons:
- result = result or hasEmpty(s)
- proc semDiscard(c: PContext, n: PNode): PNode =
- result = n
- checkSonsLen(n, 1, c.config)
- if n[0].kind != nkEmpty:
- n[0] = semExprWithType(c, n[0])
- let sonType = n[0].typ
- let sonKind = n[0].kind
- if isEmptyType(sonType) or hasEmpty(sonType) or
- sonType.kind in {tyNone, tyTypeDesc} or
- sonKind == nkTypeOfExpr:
- localError(c.config, n.info, errInvalidDiscard)
- if sonType.kind == tyProc and sonKind notin nkCallKinds:
- # tyProc is disallowed to prevent ``discard foo`` to be valid, when ``discard foo()`` is meant.
- localError(c.config, n.info, "illegal discard proc, did you mean: " & $n[0] & "()")
- proc semBreakOrContinue(c: PContext, n: PNode): PNode =
- result = n
- checkSonsLen(n, 1, c.config)
- if n[0].kind != nkEmpty:
- if n.kind != nkContinueStmt:
- var s: PSym
- case n[0].kind
- of nkIdent: s = lookUp(c, n[0])
- of nkSym: s = n[0].sym
- else: illFormedAst(n, c.config)
- s = getGenSym(c, s)
- 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[0] = x
- suggestSym(c.graph, x.info, s, c.graph.usageSym)
- onUse(x.info, s)
- else:
- localError(c.config, n.info, errInvalidControlFlowX % s.name.s)
- else:
- localError(c.config, n.info, errGenerated, "'continue' cannot have a label")
- elif c.p.nestedBlockCounter > 0 and n.kind == nkBreakStmt and not c.p.breakInLoop:
- localError(c.config, n.info, warnUnnamedBreak)
- elif (c.p.nestedLoopCounter <= 0) and ((c.p.nestedBlockCounter <= 0) or n.kind == nkContinueStmt):
- localError(c.config, n.info, errInvalidControlFlowX %
- renderTree(n, {renderNoComments}))
- proc semAsm(c: PContext, n: PNode): PNode =
- checkSonsLen(n, 2, c.config)
- var marker = pragmaAsm(c, n[0])
- if marker == '\0': marker = '`' # default marker
- result = semAsmOrEmit(c, n, marker)
- proc semWhile(c: PContext, n: PNode; flags: TExprFlags): PNode =
- result = n
- checkSonsLen(n, 2, c.config)
- openScope(c)
- n[0] = forceBool(c, semExprWithType(c, n[0], expectedType = getSysType(c.graph, n.info, tyBool)))
- inc(c.p.nestedLoopCounter)
- let oldBreakInLoop = c.p.breakInLoop
- c.p.breakInLoop = true
- n[1] = semStmt(c, n[1], flags)
- c.p.breakInLoop = oldBreakInLoop
- dec(c.p.nestedLoopCounter)
- closeScope(c)
- if n[1].typ == c.enforceVoidContext:
- result.typ = c.enforceVoidContext
- elif efInTypeof in flags:
- result.typ = n[1].typ
- elif implicitlyDiscardable(n[1]):
- result[1].typ = c.enforceVoidContext
- proc semProc(c: PContext, n: PNode): PNode
- proc semExprBranch(c: PContext, n: PNode; flags: TExprFlags = {}; expectedType: PType = nil): PNode =
- result = semExpr(c, n, flags, expectedType)
- if result.typ != nil:
- # XXX tyGenericInst here?
- if result.typ.kind in {tyVar, tyLent}: result = newDeref(result)
- proc semExprBranchScope(c: PContext, n: PNode; expectedType: PType = nil): PNode =
- openScope(c)
- result = semExprBranch(c, n, expectedType = expectedType)
- closeScope(c)
- const
- skipForDiscardable = {nkIfStmt, nkIfExpr, nkCaseStmt, nkOfBranch,
- nkElse, nkStmtListExpr, nkTryStmt, nkFinally, nkExceptBranch,
- nkElifBranch, nkElifExpr, nkElseExpr, nkBlockStmt, nkBlockExpr,
- nkHiddenStdConv, nkHiddenDeref}
- proc implicitlyDiscardable(n: PNode): bool =
- var n = n
- while n.kind in skipForDiscardable: n = n.lastSon
- result = n.kind in nkLastBlockStmts or
- (isCallExpr(n) and n[0].kind == nkSym and
- sfDiscardable in n[0].sym.flags)
- proc fixNilType(c: PContext; n: PNode) =
- if isAtom(n):
- if n.kind != nkNilLit and n.typ != nil:
- localError(c.config, n.info, errDiscardValueX % n.typ.typeToString)
- elif n.kind in {nkStmtList, nkStmtListExpr}:
- n.transitionSonsKind(nkStmtList)
- for it in n: fixNilType(c, it)
- n.typ = nil
- proc discardCheck(c: PContext, result: PNode, flags: TExprFlags) =
- if c.matchedConcept != nil or efInTypeof in flags: return
- if result.typ != nil and result.typ.kind notin {tyTyped, tyVoid}:
- if implicitlyDiscardable(result):
- var n = newNodeI(nkDiscardStmt, result.info, 1)
- n[0] = result
- elif result.typ.kind != tyError and c.config.cmd != cmdInteractive:
- if result.typ.kind == tyNone:
- localError(c.config, result.info, "expression has no type: " &
- renderTree(result, {renderNoComments}))
- else:
- var n = result
- while n.kind in skipForDiscardable:
- if n.kind == nkTryStmt: n = n[0]
- else: n = n.lastSon
- var s = "expression '" & $n & "' is of type '" &
- result.typ.typeToString & "' and has to be used (or discarded)"
- if result.info.line != n.info.line or
- result.info.fileIndex != n.info.fileIndex:
- s.add "; start of expression here: " & c.config$result.info
- if result.typ.kind == tyProc:
- s.add "; for a function call use ()"
- localError(c.config, n.info, s)
- proc semIf(c: PContext, n: PNode; flags: TExprFlags; expectedType: PType = nil): PNode =
- result = n
- var typ = commonTypeBegin
- var expectedType = expectedType
- var hasElse = false
- for i in 0..<n.len:
- var it = n[i]
- if it.len == 2:
- openScope(c)
- it[0] = forceBool(c, semExprWithType(c, it[0], expectedType = getSysType(c.graph, n.info, tyBool)))
- it[1] = semExprBranch(c, it[1], flags, expectedType)
- typ = commonType(c, typ, it[1])
- expectedType = typ
- closeScope(c)
- elif it.len == 1:
- hasElse = true
- it[0] = semExprBranchScope(c, it[0], expectedType)
- typ = commonType(c, typ, it[0])
- expectedType = typ
- else: illFormedAst(it, c.config)
- if isEmptyType(typ) or typ.kind in {tyNil, tyUntyped} or
- (not hasElse and efInTypeof notin flags):
- for it in n: discardCheck(c, it.lastSon, flags)
- result.transitionSonsKind(nkIfStmt)
- # propagate any enforced VoidContext:
- if typ == c.enforceVoidContext: result.typ = c.enforceVoidContext
- else:
- for it in n:
- let j = it.len-1
- if not endsInNoReturn(it[j]):
- it[j] = fitNode(c, typ, it[j], it[j].info)
- result.transitionSonsKind(nkIfExpr)
- result.typ = typ
- proc semTry(c: PContext, n: PNode; flags: TExprFlags; expectedType: PType = nil): PNode =
- var check = initIntSet()
- template semExceptBranchType(typeNode: PNode): bool =
- # returns true if exception type is imported type
- let typ = semTypeNode(c, typeNode, nil).toObject()
- var isImported = false
- if isImportedException(typ, c.config):
- isImported = true
- elif not isException(typ):
- localError(c.config, typeNode.info, errExprCannotBeRaised)
- elif not isDefectOrCatchableError(typ):
- message(c.config, a.info, warnBareExcept, "catch a more precise Exception deriving from CatchableError or Defect.")
- if containsOrIncl(check, typ.id):
- localError(c.config, typeNode.info, errExceptionAlreadyHandled)
- typeNode = newNodeIT(nkType, typeNode.info, typ)
- isImported
- result = n
- checkMinSonsLen(n, 2, c.config)
- var typ = commonTypeBegin
- var expectedType = expectedType
- n[0] = semExprBranchScope(c, n[0], expectedType)
- typ = commonType(c, typ, n[0].typ)
- expectedType = typ
- var last = n.len - 1
- var catchAllExcepts = 0
- for i in 1..last:
- let a = n[i]
- checkMinSonsLen(a, 1, c.config)
- openScope(c)
- if a.kind == nkExceptBranch:
- if a.len == 2 and a[0].kind == nkBracket:
- # rewrite ``except [a, b, c]: body`` -> ```except a, b, c: body```
- a.sons[0..0] = move a[0].sons
- if a.len == 2 and a[0].isInfixAs():
- # support ``except Exception as ex: body``
- let isImported = semExceptBranchType(a[0][1])
- let symbol = newSymG(skLet, a[0][2], c)
- symbol.typ = if isImported: a[0][1].typ
- else: a[0][1].typ.toRef(c.idgen)
- addDecl(c, symbol)
- # Overwrite symbol in AST with the symbol in the symbol table.
- a[0][2] = newSymNode(symbol, a[0][2].info)
- elif a.len == 1:
- # count number of ``except: body`` blocks
- inc catchAllExcepts
- message(c.config, a.info, warnBareExcept,
- "The bare except clause is deprecated; use `except CatchableError:` instead")
- else:
- # support ``except KeyError, ValueError, ... : body``
- if catchAllExcepts > 0:
- # if ``except: body`` already encountered,
- # cannot be followed by a ``except KeyError, ... : body`` block
- inc catchAllExcepts
- var isNative, isImported: bool
- for j in 0..<a.len-1:
- let tmp = semExceptBranchType(a[j])
- if tmp: isImported = true
- else: isNative = true
- if isNative and isImported:
- localError(c.config, a[0].info, "Mix of imported and native exception types is not allowed in one except branch")
- elif a.kind == nkFinally:
- if i != n.len-1:
- localError(c.config, a.info, "Only one finally is allowed after all other branches")
- else:
- illFormedAst(n, c.config)
- if catchAllExcepts > 1:
- # if number of ``except: body`` blocks is greater than 1
- # or more specific exception follows a general except block, it is invalid
- localError(c.config, a.info, "Only one general except clause is allowed after more specific exceptions")
- # last child of an nkExcept/nkFinally branch is a statement:
- if a.kind != nkFinally:
- a[^1] = semExprBranchScope(c, a[^1], expectedType)
- typ = commonType(c, typ, a[^1])
- expectedType = typ
- else:
- a[^1] = semExprBranchScope(c, a[^1])
- dec last
- closeScope(c)
- if isEmptyType(typ) or typ.kind in {tyNil, tyUntyped}:
- discardCheck(c, n[0], flags)
- for i in 1..<n.len: discardCheck(c, n[i].lastSon, flags)
- if typ == c.enforceVoidContext:
- result.typ = c.enforceVoidContext
- else:
- if n.lastSon.kind == nkFinally: discardCheck(c, n.lastSon.lastSon, flags)
- n[0] = fitNode(c, typ, n[0], n[0].info)
- for i in 1..last:
- var it = n[i]
- let j = it.len-1
- if not endsInNoReturn(it[j]):
- it[j] = fitNode(c, typ, it[j], it[j].info)
- result.typ = typ
- proc fitRemoveHiddenConv(c: PContext, typ: PType, n: PNode): PNode =
- result = fitNode(c, typ, n, n.info)
- if result.kind in {nkHiddenStdConv, nkHiddenSubConv}:
- let r1 = result[1]
- if r1.kind in {nkCharLit..nkUInt64Lit} and typ.skipTypes(abstractRange).kind in {tyFloat..tyFloat128}:
- result = newFloatNode(nkFloatLit, BiggestFloat r1.intVal)
- result.info = n.info
- result.typ = typ
- if not floatRangeCheck(result.floatVal, typ):
- localError(c.config, n.info, errFloatToString % [$result.floatVal, typeToString(typ)])
- else:
- changeType(c, r1, typ, check=true)
- result = r1
- elif not sameType(result.typ, typ):
- changeType(c, result, typ, check=false)
- proc findShadowedVar(c: PContext, v: PSym): PSym =
- for scope in localScopesFrom(c, c.currentScope.parent):
- 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[i], s): return true
- result = n.kind == nkSym and n.sym.name.id == s.id
- proc semIdentDef(c: PContext, n: PNode, kind: TSymKind, reportToNimsuggest = true): PSym =
- if isTopLevel(c):
- result = semIdentWithPragma(c, kind, n, {sfExported})
- incl(result.flags, sfGlobal)
- #if kind in {skVar, skLet}:
- # echo "global variable here ", n.info, " ", result.name.s
- else:
- result = semIdentWithPragma(c, kind, n, {})
- if result.owner.kind == skModule:
- incl(result.flags, sfGlobal)
- result.options = c.config.options
- proc getLineInfo(n: PNode): TLineInfo =
- case n.kind
- of nkPostfix:
- if len(n) > 1:
- return getLineInfo(n[1])
- of nkAccQuoted, nkPragmaExpr:
- if len(n) > 0:
- return getLineInfo(n[0])
- else:
- discard
- result = n.info
- let info = getLineInfo(n)
- if reportToNimsuggest:
- suggestSym(c.graph, info, result, c.graph.usageSym)
- proc checkNilable(c: PContext; v: PSym) =
- if {sfGlobal, sfImportc} * v.flags == {sfGlobal} and v.typ.requiresInit:
- if v.astdef.isNil:
- message(c.config, v.info, warnProveInit, v.name.s)
- elif tfNotNil in v.typ.flags and not v.astdef.typ.isNil and tfNotNil notin v.astdef.typ.flags:
- message(c.config, v.info, warnProveInit, v.name.s)
- #include liftdestructors
- proc addToVarSection(c: PContext; result: var PNode; n: PNode) =
- if result.kind != nkStmtList:
- result = makeStmtList(result)
- result.add n
- proc addToVarSection(c: PContext; result: var PNode; orig, identDefs: PNode) =
- if result.kind == nkStmtList:
- let o = copyNode(orig)
- o.add identDefs
- result.add o
- else:
- result.add identDefs
- proc isDiscardUnderscore(v: PSym): bool =
- if v.name.s == "_":
- v.flags.incl(sfGenSym)
- result = true
- proc semUsing(c: PContext; n: PNode): PNode =
- result = c.graph.emptyNode
- if not isTopLevel(c): localError(c.config, n.info, errXOnlyAtModuleScope % "using")
- for i in 0..<n.len:
- var a = n[i]
- if c.config.cmd == cmdIdeTools: suggestStmt(c, a)
- if a.kind == nkCommentStmt: continue
- if a.kind notin {nkIdentDefs, nkVarTuple, nkConstDef}: illFormedAst(a, c.config)
- checkMinSonsLen(a, 3, c.config)
- if a[^2].kind != nkEmpty:
- let typ = semTypeNode(c, a[^2], nil)
- for j in 0..<a.len-2:
- let v = semIdentDef(c, a[j], skParam)
- styleCheckDef(c, v)
- onDef(a[j].info, v)
- v.typ = typ
- strTableIncl(c.signatures, v)
- else:
- localError(c.config, a.info, "'using' section must have a type")
- var def: PNode
- if a[^1].kind != nkEmpty:
- localError(c.config, a.info, "'using' sections cannot contain assignments")
- proc hasUnresolvedParams(n: PNode; flags: TExprFlags): bool =
- result = tfUnresolved in n.typ.flags
- when false:
- case n.kind
- of nkSym:
- result = isGenericRoutineStrict(n.sym)
- of nkSymChoices:
- for ch in n:
- if hasUnresolvedParams(ch, flags):
- return true
- result = false
- else:
- result = false
- if efOperand in flags:
- if tfUnresolved notin n.typ.flags:
- result = false
- proc makeDeref(n: PNode): PNode =
- var t = n.typ
- if t.kind in tyUserTypeClasses and t.isResolvedUserTypeClass:
- t = t.lastSon
- t = skipTypes(t, {tyGenericInst, tyAlias, tySink, tyOwned})
- result = n
- if t.kind in {tyVar, tyLent}:
- result = newNodeIT(nkHiddenDeref, n.info, t[0])
- result.add n
- t = skipTypes(t[0], {tyGenericInst, tyAlias, tySink, tyOwned})
- while t.kind in {tyPtr, tyRef}:
- var a = result
- let baseTyp = t.lastSon
- result = newNodeIT(nkHiddenDeref, n.info, baseTyp)
- result.add a
- t = skipTypes(baseTyp, {tyGenericInst, tyAlias, tySink, tyOwned})
- proc fillPartialObject(c: PContext; n: PNode; typ: PType) =
- if n.len == 2:
- let x = semExprWithType(c, n[0])
- let y = considerQuotedIdent(c, n[1])
- let obj = x.typ.skipTypes(abstractPtrs)
- if obj.kind == tyObject and tfPartial in obj.flags:
- let field = newSym(skField, getIdent(c.cache, y.s), nextSymId c.idgen, obj.sym, n[1].info)
- field.typ = skipIntLit(typ, c.idgen)
- field.position = obj.n.len
- obj.n.add newSymNode(field)
- n[0] = makeDeref x
- n[1] = newSymNode(field)
- n.typ = field.typ
- else:
- localError(c.config, n.info, "implicit object field construction " &
- "requires a .partial object, but got " & typeToString(obj))
- else:
- localError(c.config, n.info, "nkDotNode requires 2 children")
- proc setVarType(c: PContext; v: PSym, typ: PType) =
- if v.typ != nil and not sameTypeOrNil(v.typ, typ):
- localError(c.config, v.info, "inconsistent typing for reintroduced symbol '" &
- v.name.s & "': previous type was: " & typeToString(v.typ, preferDesc) &
- "; new type is: " & typeToString(typ, preferDesc))
- v.typ = typ
- proc isPossibleMacroPragma(c: PContext, it: PNode, key: PNode): bool =
- # make sure it's not a normal pragma, and calls an identifier
- # considerQuotedIdent below will fail on non-identifiers
- result = whichPragma(it) == wInvalid and key.kind in nkIdentKinds
- if result:
- # make sure it's not a user pragma
- let ident = considerQuotedIdent(c, key)
- result = strTableGet(c.userPragmas, ident) == nil
- if result:
- # make sure it's not a custom pragma
- var amb = false
- let sym = searchInScopes(c, ident, amb)
- result = sym == nil or sfCustomPragma notin sym.flags
- proc copyExcept(n: PNode, i: int): PNode =
- result = copyNode(n)
- for j in 0..<n.len:
- if j != i: result.add(n[j])
- proc semVarMacroPragma(c: PContext, a: PNode, n: PNode): PNode =
- # Mirrored with semProcAnnotation
- result = nil
- # a, b {.prag.}: int = 3 not allowed
- const lhsPos = 0
- if a.len == 3 and a[lhsPos].kind == nkPragmaExpr:
- var b = a[lhsPos]
- const
- namePos = 0
- pragmaPos = 1
- let pragmas = b[pragmaPos]
- for i in 0 ..< pragmas.len:
- let it = pragmas[i]
- let key = if it.kind in nkPragmaCallKinds and it.len >= 1: it[0] else: it
- if isPossibleMacroPragma(c, it, key):
- # we transform ``var p {.m, rest.}`` into ``m(do: var p {.rest.})`` and
- # let the semantic checker deal with it:
- var x = newNodeI(nkCall, key.info)
- x.add(key)
- if it.kind in nkPragmaCallKinds and it.len > 1:
- # pass pragma arguments to the macro too:
- for i in 1..<it.len:
- x.add(it[i])
- # Drop the pragma from the list, this prevents getting caught in endless
- # recursion when the nkCall is semanticized
- let oldExpr = a[lhsPos]
- let newPragmas = copyExcept(pragmas, i)
- if newPragmas.kind != nkEmpty and newPragmas.len == 0:
- a[lhsPos] = oldExpr[namePos]
- else:
- a[lhsPos] = copyNode(oldExpr)
- a[lhsPos].add(oldExpr[namePos])
- a[lhsPos].add(newPragmas)
- var unarySection = newNodeI(n.kind, a.info)
- unarySection.add(a)
- x.add(unarySection)
- # recursion assures that this works for multiple macro annotations too:
- var r = semOverloadedCall(c, x, x, {skMacro, skTemplate}, {efNoUndeclared})
- if r == nil:
- # Restore the old list of pragmas since we couldn't process this
- a[lhsPos] = oldExpr
- # No matching macro was found but there's always the possibility this may
- # be a .pragma. template instead
- continue
- doAssert r[0].kind == nkSym
- let m = r[0].sym
- case m.kind
- of skMacro: result = semMacroExpr(c, r, r, m, {})
- of skTemplate: result = semTemplateExpr(c, r, m, {})
- else:
- a[lhsPos] = oldExpr
- continue
- doAssert result != nil
- return result
- template isLocalSym(sym: PSym): bool =
- sym.kind in {skVar, skLet} and not
- ({sfGlobal, sfPure} * sym.flags != {} or
- sfCompileTime in sym.flags) or
- sym.kind in {skProc, skFunc, skIterator} and
- sfGlobal notin sym.flags
- template isLocalVarSym(n: PNode): bool =
- n.kind == nkSym and isLocalSym(n.sym)
- proc usesLocalVar(n: PNode): bool =
- for z in 1 ..< n.len:
- if n[z].isLocalVarSym:
- return true
- elif n[z].kind in nkCallKinds:
- if usesLocalVar(n[z]):
- return true
- proc globalVarInitCheck(c: PContext, n: PNode) =
- if n.isLocalVarSym or n.kind in nkCallKinds and usesLocalVar(n):
- localError(c.config, n.info, errCannotAssignToGlobal)
- proc makeVarTupleSection(c: PContext, n, a, def: PNode, typ: PType, symkind: TSymKind, origResult: var PNode): PNode =
- ## expand tuple unpacking assignments into new var/let/const section
- if typ.kind != tyTuple:
- localError(c.config, a.info, errXExpected, "tuple")
- elif a.len-2 != typ.len:
- localError(c.config, a.info, errWrongNumberOfVariables)
- var
- tmpTuple: PSym
- lastDef: PNode
- let defkind = if symkind == skConst: nkConstDef else: nkIdentDefs
- # temporary not needed if not const and RHS is tuple literal
- # const breaks with seqs without temporary
- let useTemp = def.kind notin {nkPar, nkTupleConstr} or symkind == skConst
- if useTemp:
- # use same symkind for compatibility with original section
- tmpTuple = newSym(symkind, getIdent(c.cache, "tmpTuple"), nextSymId c.idgen, getCurrOwner(c), n.info)
- tmpTuple.typ = typ
- tmpTuple.flags.incl(sfGenSym)
- lastDef = newNodeI(defkind, a.info)
- newSons(lastDef, 3)
- lastDef[0] = newSymNode(tmpTuple)
- # NOTE: at the moment this is always ast.emptyNode, see parser.nim
- lastDef[1] = a[^2]
- lastDef[2] = def
- tmpTuple.ast = lastDef
- addToVarSection(c, origResult, n, lastDef)
- result = newNodeI(n.kind, a.info)
- for j in 0..<a.len-2:
- let name = a[j]
- if useTemp and name.kind == nkIdent and name.ident.s == "_":
- # skip _ assignments if we are using a temp as they are already evaluated
- continue
- if name.kind == nkVarTuple:
- # nested tuple
- lastDef = newNodeI(nkVarTuple, name.info)
- newSons(lastDef, name.len)
- for k in 0..<name.len-2:
- lastDef[k] = name[k]
- else:
- lastDef = newNodeI(defkind, name.info)
- newSons(lastDef, 3)
- lastDef[0] = name
- lastDef[^2] = c.graph.emptyNode
- if useTemp:
- lastDef[^1] = newTreeIT(nkBracketExpr, name.info, typ[j], newSymNode(tmpTuple), newIntNode(nkIntLit, j))
- else:
- var val = def[j]
- if val.kind == nkExprColonExpr: val = val[1]
- lastDef[^1] = val
- result.add(lastDef)
- proc semVarOrLet(c: PContext, n: PNode, symkind: TSymKind): PNode =
- var b: PNode
- result = copyNode(n)
- for i in 0..<n.len:
- var a = n[i]
- if c.config.cmd == cmdIdeTools: suggestStmt(c, a)
- if a.kind == nkCommentStmt: continue
- if a.kind notin {nkIdentDefs, nkVarTuple}: illFormedAst(a, c.config)
- checkMinSonsLen(a, 3, c.config)
- b = semVarMacroPragma(c, a, n)
- if b != nil:
- addToVarSection(c, result, b)
- continue
- var typ: PType = nil
- if a[^2].kind != nkEmpty:
- typ = semTypeNode(c, a[^2], nil)
- var typFlags: TTypeAllowedFlags
- var def: PNode = c.graph.emptyNode
- if a[^1].kind != nkEmpty:
- def = semExprWithType(c, a[^1], {efTypeAllowed}, typ)
- if def.kind == nkSym and def.sym.kind in {skTemplate, skMacro}:
- typFlags.incl taIsTemplateOrMacro
- elif def.typ.kind == tyTypeDesc and c.p.owner.kind != skMacro:
- typFlags.incl taProcContextIsNotMacro
- 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 = fitNodeConsiderViewType(c, typ, def, def.info)
- #changeType(def.skipConv, typ, check=true)
- else:
- typ = def.typ.skipTypes({tyStatic, tySink}).skipIntLit(c.idgen)
- if typ.kind in tyUserTypeClasses and typ.isResolvedUserTypeClass:
- typ = typ.lastSon
- if hasEmpty(typ):
- localError(c.config, def.info, errCannotInferTypeOfTheLiteral % typ.kind.toHumanStr)
- elif typ.kind == tyProc and def.kind == nkSym and isGenericRoutine(def.sym.ast):
- # tfUnresolved in typ.flags:
- localError(c.config, def.info, errProcHasNoConcreteType % def.renderTree)
- when false:
- # XXX This typing rule is neither documented nor complete enough to
- # justify it. Instead use the newer 'unowned x' until we figured out
- # a more general solution.
- if symkind == skVar and typ.kind == tyOwned and def.kind notin nkCallKinds:
- # special type inference rule: 'var it = ownedPointer' is turned
- # into an unowned pointer.
- typ = typ.lastSon
- # this can only happen for errornous var statements:
- if typ == nil: continue
- if c.matchedConcept != nil:
- typFlags.incl taConcept
- typeAllowedCheck(c, a.info, typ, symkind, typFlags)
- var tup = skipTypes(typ, {tyGenericInst, tyAlias, tySink})
- if a.kind == nkVarTuple:
- # generate new section from tuple unpacking and embed it into this one
- let assignments = makeVarTupleSection(c, n, a, def, tup, symkind, result)
- let resSection = semVarOrLet(c, assignments, symkind)
- for resDef in resSection:
- addToVarSection(c, result, n, resDef)
- else:
- if tup.kind == tyTuple and def.kind in {nkPar, nkTupleConstr} and
- a.len > 3:
- # var a, b = (1, 2)
- message(c.config, a.info, warnEachIdentIsTuple)
- for j in 0..<a.len-2:
- if a[j].kind == nkDotExpr:
- fillPartialObject(c, a[j], typ)
- addToVarSection(c, result, n, a)
- continue
- var v = semIdentDef(c, a[j], symkind, false)
- styleCheckDef(c, v)
- onDef(a[j].info, v)
- if sfGenSym notin v.flags:
- if not isDiscardUnderscore(v): addInterfaceDecl(c, v)
- else:
- if v.owner == nil: v.owner = c.p.owner
- 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(c.config, a.info, warnResultShadowed)
- if def.kind != nkEmpty:
- if sfThread in v.flags: localError(c.config, def.info, errThreadvarCannotInit)
- setVarType(c, v, typ)
- # this is needed for the evaluation pass, guard checking
- # and custom pragmas:
- b = newNodeI(nkIdentDefs, a.info)
- if importantComments(c.config):
- # keep documentation information:
- b.comment = a.comment
- # postfix not generated here (to generate, get rid of it in transf)
- if a[j].kind == nkPragmaExpr:
- var p = newNodeI(nkPragmaExpr, a.info)
- p.add newSymNode(v)
- p.add a[j][1]
- b.add p
- else:
- b.add newSymNode(v)
- # keep type desc for doc generator
- b.add a[^2]
- b.add copyTree(def)
- addToVarSection(c, result, n, b)
- v.ast = b
- if def.kind == nkEmpty:
- let actualType = v.typ.skipTypes({tyGenericInst, tyAlias,
- tyUserTypeClassInst})
- if actualType.kind in {tyObject, tyDistinct} and
- actualType.requiresInit:
- defaultConstructionError(c, v.typ, v.info)
- else:
- checkNilable(c, v)
- # allow let to not be initialised if imported from C:
- if v.kind == skLet and sfImportc notin v.flags and (strictDefs notin c.features or not isLocalSym(v)):
- localError(c.config, a.info, errLetNeedsInit)
- if sfCompileTime in v.flags:
- var x = newNodeI(result.kind, v.info)
- x.add result[i]
- vm.setupCompileTimeVar(c.module, c.idgen, c.graph, x)
- if v.flags * {sfGlobal, sfThread} == {sfGlobal}:
- message(c.config, v.info, hintGlobalVar)
- if {sfGlobal, sfPure} <= v.flags:
- globalVarInitCheck(c, def)
- suggestSym(c.graph, v.info, v, c.graph.usageSym)
- proc semConst(c: PContext, n: PNode): PNode =
- result = copyNode(n)
- inc c.inStaticContext
- var b: PNode
- for i in 0..<n.len:
- var a = n[i]
- if c.config.cmd == cmdIdeTools: suggestStmt(c, a)
- if a.kind == nkCommentStmt: continue
- if a.kind notin {nkConstDef, nkVarTuple}: illFormedAst(a, c.config)
- checkMinSonsLen(a, 3, c.config)
- b = semVarMacroPragma(c, a, n)
- if b != nil:
- addToVarSection(c, result, b)
- continue
- var typ: PType = nil
- if a[^2].kind != nkEmpty:
- typ = semTypeNode(c, a[^2], nil)
- var typFlags: TTypeAllowedFlags
- # don't evaluate here since the type compatibility check below may add a converter
- var def = semExprWithType(c, a[^1], {efTypeAllowed}, typ)
- if def.kind == nkSym and def.sym.kind in {skTemplate, skMacro}:
- typFlags.incl taIsTemplateOrMacro
- elif def.typ.kind == tyTypeDesc and c.p.owner.kind != skMacro:
- typFlags.incl taProcContextIsNotMacro
- # check type compatibility between def.typ and typ:
- if typ != nil:
- if typ.isMetaType:
- def = inferWithMetatype(c, typ, def)
- typ = def.typ
- else:
- def = fitRemoveHiddenConv(c, typ, def)
- else:
- typ = def.typ
- # evaluate the node
- def = semConstExpr(c, def)
- if def == nil:
- localError(c.config, a[^1].info, errConstExprExpected)
- continue
- if def.kind != nkNilLit:
- if c.matchedConcept != nil:
- typFlags.incl taConcept
- typeAllowedCheck(c, a.info, typ, skConst, typFlags)
- if a.kind == nkVarTuple:
- # generate new section from tuple unpacking and embed it into this one
- let assignments = makeVarTupleSection(c, n, a, def, typ, skConst, result)
- let resSection = semConst(c, assignments)
- for resDef in resSection:
- addToVarSection(c, result, n, resDef)
- else:
- for j in 0..<a.len-2:
- var v = semIdentDef(c, a[j], skConst)
- if sfGenSym notin v.flags: addInterfaceDecl(c, v)
- elif v.owner == nil: v.owner = getCurrOwner(c)
- styleCheckDef(c, v)
- onDef(a[j].info, v)
- setVarType(c, v, typ)
- when false:
- v.ast = def # no need to copy
- b = newNodeI(nkConstDef, a.info)
- if importantComments(c.config): b.comment = a.comment
- # postfix not generated here (to generate, get rid of it in transf)
- if a[j].kind == nkPragmaExpr:
- var p = newNodeI(nkPragmaExpr, a.info)
- p.add newSymNode(v)
- p.add a[j][1].copyTree
- b.add p
- else:
- b.add newSymNode(v)
- b.add a[1]
- b.add copyTree(def)
- v.ast = b
- addToVarSection(c, result, n, b)
- dec c.inStaticContext
- include semfields
- proc symForVar(c: PContext, n: PNode): PSym =
- let m = if n.kind == nkPragmaExpr: n[0] else: n
- result = newSymG(skForVar, m, c)
- styleCheckDef(c, result)
- onDef(n.info, result)
- if n.kind == nkPragmaExpr:
- pragma(c, result, n[1], forVarPragmas)
- proc semForVars(c: PContext, n: PNode; flags: TExprFlags): PNode =
- result = n
- let iterBase = n[^2].typ
- var iter = skipTypes(iterBase, {tyGenericInst, tyAlias, tySink, tyOwned})
- var iterAfterVarLent = iter.skipTypes({tyGenericInst, tyAlias, tyLent, tyVar})
- # n.len == 3 means that there is one for loop variable
- # and thus no tuple unpacking:
- if iterAfterVarLent.kind == tyEmpty:
- localError(c.config, n[^2].info, "cannot infer element type of $1" %
- renderTree(n[^2], {renderNoComments}))
- if iterAfterVarLent.kind != tyTuple or n.len == 3:
- if n.len == 3:
- if n[0].kind == nkVarTuple:
- if n[0].len-1 != iterAfterVarLent.len:
- return localErrorNode(c, n, n[0].info, errWrongNumberOfVariables)
- for i in 0..<n[0].len-1:
- var v = symForVar(c, n[0][i])
- if getCurrOwner(c).kind == skModule: incl(v.flags, sfGlobal)
- case iter.kind
- of tyVar, tyLent:
- v.typ = newTypeS(iter.kind, c)
- v.typ.add iterAfterVarLent[i]
- if tfVarIsPtr in iter.flags:
- v.typ.flags.incl tfVarIsPtr
- else:
- v.typ = iter[i]
- n[0][i] = newSymNode(v)
- if sfGenSym notin v.flags and not isDiscardUnderscore(v): addDecl(c, v)
- elif v.owner == nil: v.owner = getCurrOwner(c)
- else:
- var v = symForVar(c, n[0])
- if getCurrOwner(c).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[0] = newSymNode(v)
- if sfGenSym notin v.flags and not isDiscardUnderscore(v): addDecl(c, v)
- elif v.owner == nil: v.owner = getCurrOwner(c)
- else:
- localError(c.config, n.info, errWrongNumberOfVariables)
- elif n.len-2 != iterAfterVarLent.len:
- localError(c.config, n.info, errWrongNumberOfVariables)
- else:
- for i in 0..<n.len - 2:
- if n[i].kind == nkVarTuple:
- var mutable = false
- var isLent = false
- case iter[i].kind
- of tyVar:
- mutable = true
- iter[i] = iter[i].skipTypes({tyVar})
- of tyLent:
- isLent = true
- iter[i] = iter[i].skipTypes({tyLent})
- else: discard
- if n[i].len-1 != iter[i].len:
- localError(c.config, n[i].info, errWrongNumberOfVariables)
- for j in 0..<n[i].len-1:
- var v = symForVar(c, n[i][j])
- if getCurrOwner(c).kind == skModule: incl(v.flags, sfGlobal)
- if mutable:
- v.typ = newTypeS(tyVar, c)
- v.typ.add iter[i][j]
- elif isLent:
- v.typ = newTypeS(tyLent, c)
- v.typ.add iter[i][j]
- else:
- v.typ = iter[i][j]
- n[i][j] = newSymNode(v)
- if not isDiscardUnderscore(v): addDecl(c, v)
- elif v.owner == nil: v.owner = getCurrOwner(c)
- else:
- var v = symForVar(c, n[i])
- if getCurrOwner(c).kind == skModule: incl(v.flags, sfGlobal)
- case iter.kind
- of tyVar, tyLent:
- v.typ = newTypeS(iter.kind, c)
- v.typ.add iterAfterVarLent[i]
- if tfVarIsPtr in iter.flags:
- v.typ.flags.incl tfVarIsPtr
- else:
- v.typ = iter[i]
- n[i] = newSymNode(v)
- if sfGenSym notin v.flags:
- if not isDiscardUnderscore(v): addDecl(c, v)
- elif v.owner == nil: v.owner = getCurrOwner(c)
- inc(c.p.nestedLoopCounter)
- let oldBreakInLoop = c.p.breakInLoop
- c.p.breakInLoop = true
- openScope(c)
- n[^1] = semExprBranch(c, n[^1], flags)
- if efInTypeof notin flags:
- discardCheck(c, n[^1], flags)
- closeScope(c)
- c.p.breakInLoop = oldBreakInLoop
- dec(c.p.nestedLoopCounter)
- proc implicitIterator(c: PContext, it: string, arg: PNode): PNode =
- result = newNodeI(nkCall, arg.info)
- result.add(newIdentNode(getIdent(c.cache, it), arg.info))
- if arg.typ != nil and arg.typ.kind in {tyVar, tyLent}:
- result.add newDeref(arg)
- else:
- result.add arg
- result = semExprNoDeref(c, result, {efWantIterator})
- proc isTrivalStmtExpr(n: PNode): bool =
- for i in 0..<n.len-1:
- if n[i].kind notin {nkEmpty, nkCommentStmt}:
- return false
- result = true
- proc handleStmtMacro(c: PContext; n, selector: PNode; magicType: string;
- flags: TExprFlags): PNode =
- if selector.kind in nkCallKinds:
- # we transform
- # n := for a, b, c in m(x, y, z): Y
- # to
- # m(n)
- let maType = magicsys.getCompilerProc(c.graph, magicType)
- if maType == nil: return
- let headSymbol = selector[0]
- var o: TOverloadIter
- var match: PSym = nil
- var symx = initOverloadIter(o, c, headSymbol)
- while symx != nil:
- if symx.kind in {skTemplate, skMacro}:
- if symx.typ.len == 2 and symx.typ[1] == maType.typ:
- if match == nil:
- match = symx
- else:
- localError(c.config, n.info, errAmbiguousCallXYZ % [
- getProcHeader(c.config, match),
- getProcHeader(c.config, symx), $selector])
- symx = nextOverloadIter(o, c, headSymbol)
- if match == nil: return
- var callExpr = newNodeI(nkCall, n.info)
- callExpr.add newSymNode(match)
- callExpr.add n
- case match.kind
- of skMacro: result = semMacroExpr(c, callExpr, callExpr, match, flags)
- of skTemplate: result = semTemplateExpr(c, callExpr, match, flags)
- else: result = nil
- proc handleForLoopMacro(c: PContext; n: PNode; flags: TExprFlags): PNode =
- result = handleStmtMacro(c, n, n[^2], "ForLoopStmt", flags)
- proc handleCaseStmtMacro(c: PContext; n: PNode; flags: TExprFlags): PNode =
- # n[0] has been sem'checked and has a type. We use this to resolve
- # '`case`(n[0])' but then we pass 'n' to the `case` macro. This seems to
- # be the best solution.
- var toResolve = newNodeI(nkCall, n.info)
- toResolve.add newIdentNode(getIdent(c.cache, "case"), n.info)
- toResolve.add n[0]
- var errors: CandidateErrors
- var r = resolveOverloads(c, toResolve, toResolve, {skTemplate, skMacro}, {efNoDiagnostics},
- errors, false)
- if r.state == csMatch:
- var match = r.calleeSym
- markUsed(c, n[0].info, match)
- onUse(n[0].info, match)
- # but pass 'n' to the `case` macro, not 'n[0]':
- r.call[1] = n
- let toExpand = semResolvedCall(c, r, r.call, {})
- case match.kind
- of skMacro: result = semMacroExpr(c, toExpand, toExpand, match, flags)
- of skTemplate: result = semTemplateExpr(c, toExpand, match, flags)
- else: result = errorNode(c, n[0])
- elif r.state == csNoMatch:
- result = errorNode(c, n[0])
- if result.kind == nkEmpty:
- localError(c.config, n[0].info, errSelectorMustBeOfCertainTypes)
- # this would be the perfectly consistent solution with 'for loop macros',
- # but it kinda sucks for pattern matching as the matcher is not attached to
- # a type then:
- when false:
- result = handleStmtMacro(c, n, n[0], "CaseStmt")
- proc semFor(c: PContext, n: PNode; flags: TExprFlags): PNode =
- checkMinSonsLen(n, 3, c.config)
- result = handleForLoopMacro(c, n, flags)
- if result != nil: return result
- openScope(c)
- result = n
- n[^2] = semExprNoDeref(c, n[^2], {efWantIterator})
- var call = n[^2]
- if call.kind == nkStmtListExpr and (isTrivalStmtExpr(call) or (call.lastSon.kind in nkCallKinds and call.lastSon[0].sym.kind == skIterator)):
- call = call.lastSon
- n[^2] = call
- let isCallExpr = call.kind in nkCallKinds
- if isCallExpr and call[0].kind == nkSym and
- call[0].sym.magic in {mFields, mFieldPairs, mOmpParFor}:
- if call[0].sym.magic == mOmpParFor:
- result = semForVars(c, n, flags)
- result.transitionSonsKind(nkParForStmt)
- else:
- result = semForFields(c, n, call[0].sym.magic)
- elif isCallExpr and isClosureIterator(call[0].typ.skipTypes(abstractInst)):
- # first class iterator:
- result = semForVars(c, n, flags)
- elif not isCallExpr or call[0].kind != nkSym or
- call[0].sym.kind != skIterator:
- if n.len == 3:
- n[^2] = implicitIterator(c, "items", n[^2])
- elif n.len == 4:
- n[^2] = implicitIterator(c, "pairs", n[^2])
- else:
- localError(c.config, n[^2].info, "iterator within for loop context expected")
- result = semForVars(c, n, flags)
- else:
- result = semForVars(c, n, flags)
- # propagate any enforced VoidContext:
- if n[^1].typ == c.enforceVoidContext:
- result.typ = c.enforceVoidContext
- elif efInTypeof in flags:
- result.typ = result.lastSon.typ
- closeScope(c)
- proc semCase(c: PContext, n: PNode; flags: TExprFlags; expectedType: PType = nil): PNode =
- result = n
- checkMinSonsLen(n, 2, c.config)
- openScope(c)
- pushCaseContext(c, n)
- n[0] = semExprWithType(c, n[0])
- var chckCovered = false
- var covered: Int128 = toInt128(0)
- var typ = commonTypeBegin
- var expectedType = expectedType
- var hasElse = false
- let caseTyp = skipTypes(n[0].typ, abstractVar-{tyTypeDesc})
- const shouldChckCovered = {tyInt..tyInt64, tyChar, tyEnum, tyUInt..tyUInt64, tyBool}
- case caseTyp.kind
- of shouldChckCovered:
- chckCovered = true
- of tyRange:
- if skipTypes(caseTyp[0], abstractInst).kind in shouldChckCovered:
- chckCovered = true
- of tyFloat..tyFloat128, tyString, tyCstring, tyError:
- discard
- else:
- popCaseContext(c)
- closeScope(c)
- return handleCaseStmtMacro(c, n, flags)
- template invalidOrderOfBranches(n: PNode) =
- localError(c.config, n.info, "invalid order of case branches")
- break
-
- for i in 1..<n.len:
- setCaseContextIdx(c, i)
- var x = n[i]
- when defined(nimsuggest):
- if c.config.ideCmd == ideSug and exactEquals(c.config.m.trackPos, x.info) and caseTyp.kind == tyEnum:
- suggestEnum(c, x, caseTyp)
- case x.kind
- of nkOfBranch:
- if hasElse: invalidOrderOfBranches(x)
- checkMinSonsLen(x, 2, c.config)
- semCaseBranch(c, n, x, i, covered)
- var last = x.len-1
- x[last] = semExprBranchScope(c, x[last], expectedType)
- typ = commonType(c, typ, x[last])
- expectedType = typ
- of nkElifBranch:
- if hasElse: invalidOrderOfBranches(x)
- chckCovered = false
- checkSonsLen(x, 2, c.config)
- openScope(c)
- x[0] = forceBool(c, semExprWithType(c, x[0], expectedType = getSysType(c.graph, n.info, tyBool)))
- x[1] = semExprBranch(c, x[1], expectedType = expectedType)
- typ = commonType(c, typ, x[1])
- expectedType = typ
- closeScope(c)
- of nkElse:
- checkSonsLen(x, 1, c.config)
- x[0] = semExprBranchScope(c, x[0], expectedType)
- typ = commonType(c, typ, x[0])
- expectedType = typ
- if (chckCovered and covered == toCover(c, n[0].typ)) or hasElse:
- message(c.config, x.info, warnUnreachableElse)
- hasElse = true
- chckCovered = false
- else:
- illFormedAst(x, c.config)
- if chckCovered:
- if covered == toCover(c, n[0].typ):
- hasElse = true
- elif n[0].typ.skipTypes(abstractRange).kind in {tyEnum, tyChar}:
- localError(c.config, n.info, "not all cases are covered; missing: $1" %
- formatMissingEnums(c, n))
- else:
- localError(c.config, n.info, "not all cases are covered")
- popCaseContext(c)
- closeScope(c)
- if isEmptyType(typ) or typ.kind in {tyNil, tyUntyped} or
- (not hasElse and efInTypeof notin flags):
- for i in 1..<n.len: discardCheck(c, n[i].lastSon, flags)
- # propagate any enforced VoidContext:
- if typ == c.enforceVoidContext:
- result.typ = c.enforceVoidContext
- else:
- for i in 1..<n.len:
- var it = n[i]
- let j = it.len-1
- if not endsInNoReturn(it[j]):
- it[j] = fitNode(c, typ, it[j], it[j].info)
- result.typ = typ
- proc semRaise(c: PContext, n: PNode): PNode =
- result = n
- checkSonsLen(n, 1, c.config)
- if n[0].kind != nkEmpty:
- n[0] = semExprWithType(c, n[0])
- var typ = n[0].typ
- if not isImportedException(typ, c.config):
- typ = typ.skipTypes({tyAlias, tyGenericInst, tyOwned})
- if typ.kind != tyRef:
- localError(c.config, n.info, errExprCannotBeRaised)
- if typ.len > 0 and not isException(typ.lastSon):
- localError(c.config, n.info, "raised object of type $1 does not inherit from Exception" % typeToString(typ))
- proc addGenericParamListToScope(c: PContext, n: PNode) =
- if n.kind != nkGenericParams: illFormedAst(n, c.config)
- for i in 0..<n.len:
- var a = n[i]
- if a.kind == nkSym: addDecl(c, a.sym)
- else: illFormedAst(a, c.config)
- proc typeSectionTypeName(c: PContext; n: PNode): PNode =
- if n.kind == nkPragmaExpr:
- if n.len == 0: illFormedAst(n, c.config)
- result = n[0]
- else:
- result = n
- if result.kind != nkSym: illFormedAst(n, c.config)
- proc typeDefLeftSidePass(c: PContext, typeSection: PNode, i: int) =
- let typeDef = typeSection[i]
- checkSonsLen(typeDef, 3, c.config)
- var name = typeDef[0]
- var s: PSym
- if name.kind == nkDotExpr and typeDef[2].kind == nkObjectTy:
- let pkgName = considerQuotedIdent(c, name[0])
- let typName = considerQuotedIdent(c, name[1])
- let pkg = c.graph.packageSyms.strTableGet(pkgName)
- if pkg.isNil or pkg.kind != skPackage:
- localError(c.config, name.info, "unknown package name: " & pkgName.s)
- else:
- let typsym = c.graph.packageTypes.strTableGet(typName)
- if typsym.isNil:
- s = semIdentDef(c, name[1], skType)
- onDef(name[1].info, s)
- s.typ = newTypeS(tyObject, c)
- s.typ.sym = s
- s.flags.incl sfForward
- c.graph.packageTypes.strTableAdd s
- addInterfaceDecl(c, s)
- elif typsym.kind == skType and sfForward in typsym.flags:
- s = typsym
- addInterfaceDecl(c, s)
- # PRTEMP no onDef here?
- else:
- localError(c.config, name.info, typsym.name.s & " is not a type that can be forwarded")
- s = typsym
- else:
- s = semIdentDef(c, name, skType)
- onDef(name.info, s)
- s.typ = newTypeS(tyForward, c)
- s.typ.sym = s # process pragmas:
- if name.kind == nkPragmaExpr:
- let rewritten = applyTypeSectionPragmas(c, name[1], typeDef)
- if rewritten != nil:
- case rewritten.kind
- of nkTypeDef:
- typeSection[i] = rewritten
- of nkTypeSection:
- typeSection.sons[i .. i] = rewritten.sons
- else: illFormedAst(rewritten, c.config)
- typeDefLeftSidePass(c, typeSection, i)
- return
- pragma(c, s, name[1], typePragmas)
- if sfForward in s.flags:
- # check if the symbol already exists:
- let pkg = c.module.owner
- if not isTopLevel(c) or pkg.isNil:
- localError(c.config, name.info, "only top level types in a package can be 'package'")
- else:
- let typsym = c.graph.packageTypes.strTableGet(s.name)
- if typsym != nil:
- if sfForward notin typsym.flags or sfNoForward notin typsym.flags:
- typeCompleted(typsym)
- typsym.info = s.info
- else:
- localError(c.config, name.info, "cannot complete type '" & s.name.s & "' twice; " &
- "previous type completion was here: " & c.config$typsym.info)
- s = typsym
- # add it here, so that recursive types are possible:
- if sfGenSym notin s.flags: addInterfaceDecl(c, s)
- elif s.owner == nil: s.owner = getCurrOwner(c)
- if name.kind == nkPragmaExpr:
- typeDef[0][0] = newSymNode(s)
- else:
- typeDef[0] = newSymNode(s)
- 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
- var i = 0
- while i < n.len: # n may grow due to type pragma macros
- var a = n[i]
- when defined(nimsuggest):
- if c.config.cmd == cmdIdeTools:
- inc c.inTypeContext
- suggestStmt(c, a)
- dec c.inTypeContext
- case a.kind
- of nkCommentStmt: discard
- of nkTypeDef: typeDefLeftSidePass(c, n, i)
- else: illFormedAst(a, c.config)
- inc i
- proc checkCovariantParamsUsages(c: PContext; genericType: PType) =
- var body = genericType[^1]
- proc traverseSubTypes(c: PContext; t: PType): bool =
- template error(msg) = localError(c.config, genericType.sym.info, msg)
- result = false
- template subresult(r) =
- let sub = r
- result = result or sub
- case t.kind
- of tyGenericParam:
- t.flags.incl tfWeakCovariant
- return true
- of tyObject:
- for field in t.n:
- subresult traverseSubTypes(c, field.typ)
- of tyArray:
- return traverseSubTypes(c, t[1])
- of tyProc:
- for subType in t.sons:
- if subType != nil:
- subresult traverseSubTypes(c, subType)
- if result:
- error("non-invariant type param used in a proc type: " & $t)
- of tySequence:
- return traverseSubTypes(c, t[0])
- of tyGenericInvocation:
- let targetBody = t[0]
- for i in 1..<t.len:
- let param = t[i]
- if param.kind == tyGenericParam:
- if tfCovariant in param.flags:
- let formalFlags = targetBody[i-1].flags
- if tfCovariant notin formalFlags:
- error("covariant param '" & param.sym.name.s &
- "' used in a non-covariant position")
- elif tfWeakCovariant in formalFlags:
- param.flags.incl tfWeakCovariant
- result = true
- elif tfContravariant in param.flags:
- let formalParam = targetBody[i-1].sym
- if tfContravariant notin formalParam.typ.flags:
- error("contravariant param '" & param.sym.name.s &
- "' used in a non-contravariant position")
- result = true
- else:
- subresult traverseSubTypes(c, param)
- of tyAnd, tyOr, tyNot, tyStatic, tyBuiltInTypeClass, tyCompositeTypeClass:
- error("non-invariant type parameters cannot be used with types such '" & $t & "'")
- of tyUserTypeClass, tyUserTypeClassInst:
- error("non-invariant type parameters are not supported in concepts")
- of tyTuple:
- for fieldType in t.sons:
- subresult traverseSubTypes(c, fieldType)
- of tyPtr, tyRef, tyVar, tyLent:
- if t.base.kind == tyGenericParam: return true
- return traverseSubTypes(c, t.base)
- of tyDistinct, tyAlias, tySink, tyOwned:
- return traverseSubTypes(c, t.lastSon)
- of tyGenericInst:
- internalAssert c.config, false
- else:
- discard
- discard traverseSubTypes(c, body)
- proc typeSectionRightSidePass(c: PContext, n: PNode) =
- for i in 0..<n.len:
- var a = n[i]
- if a.kind == nkCommentStmt: continue
- if a.kind != nkTypeDef: illFormedAst(a, c.config)
- checkSonsLen(a, 3, c.config)
- let name = typeSectionTypeName(c, a[0])
- var s = name.sym
- if s.magic == mNone and a[2].kind == nkEmpty:
- localError(c.config, a.info, errImplOfXexpected % s.name.s)
- if s.magic != mNone: processMagicType(c, s)
- let oldFlags = s.typ.flags
- if a[1].kind != nkEmpty:
- # We have a generic type declaration here. In generic types,
- # symbol lookup needs to be done here.
- openScope(c)
- pushOwner(c, 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[1], s.typ)
- a[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 tyNone 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[2], s.typ)
- dec c.inGenericContext
- if body != nil:
- body.sym = s
- body.size = -1 # could not be computed properly
- if body.kind == tyObject:
- # add flags applied to generic type to object (nominal) type
- incl(body.flags, oldFlags)
- # {.inheritable, final.} is already disallowed, but
- # object might have been assumed to be final
- if tfInheritable in oldFlags and tfFinal in body.flags:
- excl(body.flags, tfFinal)
- s.typ[^1] = body
- if tfCovariant in s.typ.flags:
- checkCovariantParamsUsages(c, s.typ)
- # XXX: This is a temporary limitation:
- # The codegen currently produces various failures with
- # generic imported types that have fields, but we need
- # the fields specified in order to detect weak covariance.
- # The proper solution is to teach the codegen how to handle
- # such types, because this would offer various interesting
- # possibilities such as instantiating C++ generic types with
- # garbage collected Nim types.
- if sfImportc in s.flags:
- var body = s.typ.lastSon
- if body.kind == tyObject:
- # erases all declared fields
- body.n.sons = @[]
- popOwner(c)
- closeScope(c)
- elif a[2].kind != nkEmpty:
- # process the type's body:
- pushOwner(c, s)
- var t = semTypeNode(c, a[2], s.typ)
- if s.typ == nil:
- s.typ = t
- elif t != s.typ and (s.typ == nil or s.typ.kind != tyAlias):
- # this can happen for e.g. tcan_alias_specialised_generic:
- assignType(s.typ, t)
- #debug s.typ
- s.ast = a
- popOwner(c)
- # If the right hand side expression was a macro call we replace it with
- # its evaluated result here so that we don't execute it once again in the
- # final pass
- if a[2].kind in nkCallKinds:
- incl a[2].flags, nfSem # bug #10548
- if sfExportc in s.flags and s.typ.kind == tyAlias:
- localError(c.config, name.info, "{.exportc.} not allowed for type aliases")
- if tfBorrowDot in s.typ.flags and s.typ.skipTypes({tyGenericBody}).kind != tyDistinct:
- excl s.typ.flags, tfBorrowDot
- localError(c.config, name.info, "only a 'distinct' type can borrow `.`")
- let aa = a[2]
- if aa.kind in {nkRefTy, nkPtrTy} and aa.len == 1 and
- aa[0].kind == nkObjectTy:
- # give anonymous object a dummy symbol:
- var st = s.typ
- if st.kind == tyGenericBody: st = st.lastSon
- internalAssert c.config, st.kind in {tyPtr, tyRef}
- internalAssert c.config, st.lastSon.sym == nil
- incl st.flags, tfRefsAnonObj
- let objTy = st.lastSon
- # add flags for `ref object` etc to underlying `object`
- incl(objTy.flags, oldFlags)
- # {.inheritable, final.} is already disallowed, but
- # object might have been assumed to be final
- if tfInheritable in oldFlags and tfFinal in objTy.flags:
- excl(objTy.flags, tfFinal)
- let obj = newSym(skType, getIdent(c.cache, s.name.s & ":ObjectType"),
- nextSymId c.idgen, getCurrOwner(c), s.info)
- obj.flags.incl sfGeneratedType
- let symNode = newSymNode(obj)
- obj.ast = a.shallowCopy
- case a[0].kind
- of nkSym: obj.ast[0] = symNode
- of nkPragmaExpr:
- obj.ast[0] = a[0].shallowCopy
- obj.ast[0][0] = symNode
- obj.ast[0][1] = a[0][1]
- else: assert(false)
- obj.ast[1] = a[1]
- obj.ast[2] = a[2][0]
- if sfPure in s.flags:
- obj.flags.incl sfPure
- obj.typ = objTy
- objTy.sym = obj
- proc checkForMetaFields(c: PContext; n: PNode) =
- proc checkMeta(c: PContext; n: PNode; t: PType) =
- if t != nil and t.isMetaType and tfGenericTypeParam notin t.flags:
- if t.kind == tyBuiltInTypeClass and t.len == 1 and t[0].kind == tyProc:
- localError(c.config, n.info, ("'$1' is not a concrete type; " &
- "for a callback without parameters use 'proc()'") % t.typeToString)
- else:
- localError(c.config, n.info, errTIsNotAConcreteType % t.typeToString)
- if n.isNil: return
- case n.kind
- of nkRecList, nkRecCase:
- for s in n: checkForMetaFields(c, s)
- of nkOfBranch, nkElse:
- checkForMetaFields(c, n.lastSon)
- of nkSym:
- let t = n.sym.typ
- case t.kind
- of tySequence, tySet, tyArray, tyOpenArray, tyVar, tyLent, tyPtr, tyRef,
- tyProc, tyGenericInvocation, tyGenericInst, tyAlias, tySink, tyOwned:
- let start = ord(t.kind in {tyGenericInvocation, tyGenericInst})
- for i in start..<t.len:
- checkMeta(c, n, t[i])
- else:
- checkMeta(c, n, t)
- else:
- internalAssert c.config, false
- proc typeSectionFinalPass(c: PContext, n: PNode) =
- for i in 0..<n.len:
- var a = n[i]
- if a.kind == nkCommentStmt: continue
- let name = typeSectionTypeName(c, a[0])
- var s = name.sym
- # check the style here after the pragmas have been processed:
- styleCheckDef(c, s)
- # compute the type's size and check for illegal recursions:
- if a[1].kind == nkEmpty:
- var x = a[2]
- if x.kind in nkCallKinds and nfSem in x.flags:
- discard "already semchecked, see line marked with bug #10548"
- else:
- while x.kind in {nkStmtList, nkStmtListExpr} and x.len > 0:
- x = x.lastSon
- # we need the 'safeSkipTypes' here because illegally recursive types
- # can enter at this point, see bug #13763
- if x.kind notin {nkObjectTy, nkDistinctTy, nkEnumTy, nkEmpty} and
- s.typ.safeSkipTypes(abstractPtrs).kind notin {tyObject, tyEnum}:
- # type aliases are hard:
- var t = semTypeNode(c, x, nil)
- assert t != nil
- if s.typ != nil and s.typ.kind notin {tyAlias, tySink}:
- if t.kind in {tyProc, tyGenericInst} and not t.isMetaType:
- assignType(s.typ, t)
- s.typ.itemId = t.itemId
- elif t.kind in {tyObject, tyEnum, tyDistinct}:
- assert s.typ != nil
- assignType(s.typ, t)
- s.typ.itemId = t.itemId # same id
- checkConstructedType(c.config, s.info, s.typ)
- if s.typ.kind in {tyObject, tyTuple} and not s.typ.n.isNil:
- checkForMetaFields(c, s.typ.n)
- # fix bug #5170, bug #17162, bug #15526: ensure locally scoped types get a unique name:
- if s.typ.kind in {tyEnum, tyRef, tyObject} and not isTopLevel(c):
- incl(s.flags, sfGenSym)
- #instAllTypeBoundOp(c, n.info)
- proc semAllTypeSections(c: PContext; n: PNode): PNode =
- proc gatherStmts(c: PContext; n: PNode; result: PNode) {.nimcall.} =
- case n.kind
- of nkIncludeStmt:
- for i in 0..<n.len:
- var f = checkModuleName(c.config, n[i])
- if f != InvalidFileIdx:
- if containsOrIncl(c.includedFiles, f.int):
- localError(c.config, n.info, errRecursiveDependencyX % toMsgFilename(c.config, f))
- else:
- let code = c.graph.includeFileCallback(c.graph, c.module, f)
- gatherStmts c, code, result
- excl(c.includedFiles, f.int)
- of nkStmtList:
- for i in 0..<n.len:
- gatherStmts(c, n[i], result)
- of nkTypeSection:
- incl n.flags, nfSem
- typeSectionLeftSidePass(c, n)
- result.add n
- else:
- result.add n
- result = newNodeI(nkStmtList, n.info)
- gatherStmts(c, n, result)
- template rec(name) =
- for i in 0..<result.len:
- if result[i].kind == nkTypeSection:
- name(c, result[i])
- rec typeSectionRightSidePass
- rec typeSectionFinalPass
- when false:
- # too beautiful to delete:
- template rec(name; setbit=false) =
- proc `name rec`(c: PContext; n: PNode) {.nimcall.} =
- if n.kind == nkTypeSection:
- when setbit: incl n.flags, nfSem
- name(c, n)
- elif n.kind == nkStmtList:
- for i in 0..<n.len:
- `name rec`(c, n[i])
- `name rec`(c, n)
- rec typeSectionLeftSidePass, true
- rec typeSectionRightSidePass
- rec typeSectionFinalPass
- 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.
- if sfNoForward notin c.module.flags or nfSem notin n.flags:
- inc c.inTypeContext
- typeSectionLeftSidePass(c, n)
- typeSectionRightSidePass(c, n)
- typeSectionFinalPass(c, n)
- dec c.inTypeContext
- result = n
- proc semParamList(c: PContext, n, genericParams: PNode, s: PSym) =
- s.typ = semProcTypeNode(c, n, genericParams, nil, s.kind)
- proc addParams(c: PContext, n: PNode, kind: TSymKind) =
- for i in 1..<n.len:
- if n[i].kind == nkSym: addParamOrResult(c, n[i].sym, kind)
- else: illFormedAst(n, c.config)
- 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[bodyPos] = newSymNode(b)
- # Carry over the original symbol magic, this is necessary in order to ensure
- # the semantic pass is correct
- s.magic = b.magic
- if b.typ != nil and b.typ.len > 0:
- s.typ.n[0] = b.typ.n[0]
- s.typ.flags = b.typ.flags
- else:
- localError(c.config, n.info, errNoSymbolToBorrowFromFound)
- proc swapResult(n: PNode, sRes: PSym, dNode: PNode) =
- ## Swap nodes that are (skResult) symbols to d(estination)Node.
- for i in 0..<n.safeLen:
- if n[i].kind == nkSym and n[i].sym == sRes:
- n[i] = dNode
- swapResult(n[i], sRes, dNode)
- proc addResult(c: PContext, n: PNode, t: PType, owner: TSymKind) =
- template genResSym(s) =
- var s = newSym(skResult, getIdent(c.cache, "result"), nextSymId c.idgen,
- getCurrOwner(c), n.info)
- s.typ = t
- incl(s.flags, sfUsed)
- if owner == skMacro or t != nil:
- if n.len > resultPos and n[resultPos] != nil:
- if n[resultPos].sym.kind != skResult:
- localError(c.config, n.info, "incorrect result proc symbol")
- if n[resultPos].sym.owner != getCurrOwner(c):
- # re-write result with new ownership, and re-write the proc accordingly
- let sResSym = n[resultPos].sym
- genResSym(s)
- n[resultPos] = newSymNode(s)
- swapResult(n, sResSym, n[resultPos])
- c.p.resultSym = n[resultPos].sym
- else:
- genResSym(s)
- c.p.resultSym = s
- n.add newSymNode(c.p.resultSym)
- addParamOrResult(c, c.p.resultSym, owner)
- proc semProcAnnotation(c: PContext, prc: PNode;
- validPragmas: TSpecialWords): PNode =
- # Mirrored with semVarMacroPragma
- var n = prc[pragmasPos]
- if n == nil or n.kind == nkEmpty: return
- for i in 0..<n.len:
- let it = n[i]
- let key = if it.kind in nkPragmaCallKinds and it.len >= 1: it[0] else: it
- if isPossibleMacroPragma(c, it, key):
- # we transform ``proc p {.m, rest.}`` into ``m(do: proc p {.rest.})`` and
- # let the semantic checker deal with it:
- var x = newNodeI(nkCall, key.info)
- x.add(key)
- if it.kind in nkPragmaCallKinds and it.len > 1:
- # pass pragma arguments to the macro too:
- for i in 1..<it.len:
- x.add(it[i])
- # Drop the pragma from the list, this prevents getting caught in endless
- # recursion when the nkCall is semanticized
- prc[pragmasPos] = copyExcept(n, i)
- if prc[pragmasPos].kind != nkEmpty and prc[pragmasPos].len == 0:
- prc[pragmasPos] = c.graph.emptyNode
- x.add(prc)
- # recursion assures that this works for multiple macro annotations too:
- var r = semOverloadedCall(c, x, x, {skMacro, skTemplate}, {efNoUndeclared})
- if r == nil:
- # Restore the old list of pragmas since we couldn't process this
- prc[pragmasPos] = n
- # No matching macro was found but there's always the possibility this may
- # be a .pragma. template instead
- continue
- doAssert r[0].kind == nkSym
- let m = r[0].sym
- case m.kind
- of skMacro: result = semMacroExpr(c, r, r, m, {})
- of skTemplate: result = semTemplateExpr(c, r, m, {})
- else:
- prc[pragmasPos] = n
- continue
- doAssert result != nil
- return result
- proc semInferredLambda(c: PContext, pt: TIdTable, n: PNode): PNode =
- ## used for resolving 'auto' in lambdas based on their callsite
- var n = n
- let original = n[namePos].sym
- let s = original #copySym(original, false)
- #incl(s.flags, sfFromGeneric)
- #s.owner = original
- n = replaceTypesInBody(c, pt, n, original)
- result = n
- s.ast = result
- n[namePos].sym = s
- n[genericParamsPos] = c.graph.emptyNode
- # for LL we need to avoid wrong aliasing
- let params = copyTree n.typ.n
- n[paramsPos] = params
- s.typ = n.typ
- for i in 1..<params.len:
- if params[i].typ.kind in {tyTypeDesc, tyGenericParam,
- tyFromExpr}+tyTypeClasses:
- localError(c.config, params[i].info, "cannot infer type of parameter: " &
- params[i].sym.name.s)
- #params[i].sym.owner = s
- openScope(c)
- pushOwner(c, s)
- addParams(c, params, skProc)
- pushProcCon(c, s)
- addResult(c, n, n.typ[0], skProc)
- s.ast[bodyPos] = hloBody(c, semProcBody(c, n[bodyPos], n.typ[0]))
- trackProc(c, s, s.ast[bodyPos])
- popProcCon(c)
- popOwner(c)
- closeScope(c)
- if optOwnedRefs in c.config.globalOptions and result.typ != nil:
- result.typ = makeVarType(c, result.typ, tyOwned)
- # 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.kind == skMacro:
- let resultType = sysTypeFromName(c.graph, n.info, "NimNode")
- addResult(c, n, resultType, s.kind)
- elif s.typ[0] != nil and not isInlineIterator(s.typ):
- addResult(c, n, s.typ[0], s.kind)
- proc canonType(c: PContext, t: PType): PType =
- if t.kind == tySequence:
- result = c.graph.sysTypes[tySequence]
- else:
- result = t
- proc prevDestructor(c: PContext; prevOp: PSym; obj: PType; info: TLineInfo) =
- var msg = "cannot bind another '" & prevOp.name.s & "' to: " & typeToString(obj)
- if sfOverriden notin prevOp.flags:
- msg.add "; previous declaration was constructed here implicitly: " & (c.config $ prevOp.info)
- else:
- msg.add "; previous declaration was here: " & (c.config $ prevOp.info)
- localError(c.config, info, errGenerated, msg)
- proc whereToBindTypeHook(c: PContext; t: PType): PType =
- result = t
- while true:
- if result.kind in {tyGenericBody, tyGenericInst}: result = result.lastSon
- elif result.kind == tyGenericInvocation: result = result[0]
- else: break
- if result.kind in {tyObject, tyDistinct, tySequence, tyString}:
- result = canonType(c, result)
- proc bindTypeHook(c: PContext; s: PSym; n: PNode; op: TTypeAttachedOp) =
- let t = s.typ
- var noError = false
- let cond = if op in {attachedDestructor, attachedWasMoved}:
- t.len == 2 and t[0] == nil and t[1].kind == tyVar
- elif op == attachedTrace:
- t.len == 3 and t[0] == nil and t[1].kind == tyVar and t[2].kind == tyPointer
- else:
- t.len >= 2 and t[0] == nil
- if cond:
- var obj = t[1].skipTypes({tyVar})
- while true:
- incl(obj.flags, tfHasAsgn)
- if obj.kind in {tyGenericBody, tyGenericInst}: obj = obj.lastSon
- elif obj.kind == tyGenericInvocation: obj = obj[0]
- else: break
- if obj.kind in {tyObject, tyDistinct, tySequence, tyString}:
- obj = canonType(c, obj)
- let ao = getAttachedOp(c.graph, obj, op)
- if ao == s:
- discard "forward declared destructor"
- elif ao.isNil and tfCheckedForDestructor notin obj.flags:
- setAttachedOp(c.graph, c.module.position, obj, op, s)
- else:
- prevDestructor(c, ao, obj, n.info)
- noError = true
- if obj.owner.getModule != s.getModule:
- localError(c.config, n.info, errGenerated,
- "type bound operation `" & s.name.s & "` can be defined only in the same module with its type (" & obj.typeToString() & ")")
- if not noError and sfSystemModule notin s.owner.flags:
- if op == attachedTrace:
- localError(c.config, n.info, errGenerated,
- "signature for '=trace' must be proc[T: object](x: var T; env: pointer)")
- else:
- localError(c.config, n.info, errGenerated,
- "signature for '" & s.name.s & "' must be proc[T: object](x: var T)")
- incl(s.flags, sfUsed)
- incl(s.flags, sfOverriden)
- proc semOverride(c: PContext, s: PSym, n: PNode) =
- let name = s.name.s.normalize
- case name
- of "=destroy":
- bindTypeHook(c, s, n, attachedDestructor)
- of "deepcopy", "=deepcopy":
- if s.typ.len == 2 and
- s.typ[1].skipTypes(abstractInst).kind in {tyRef, tyPtr} and
- sameType(s.typ[1], s.typ[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[1].skipTypes(abstractInst).lastSon.skipTypes(abstractInst)
- while true:
- if t.kind == tyGenericBody: t = t.lastSon
- elif t.kind == tyGenericInvocation: t = t[0]
- else: break
- if t.kind in {tyObject, tyDistinct, tyEnum, tySequence, tyString}:
- if getAttachedOp(c.graph, t, attachedDeepCopy).isNil:
- setAttachedOp(c.graph, c.module.position, t, attachedDeepCopy, s)
- else:
- localError(c.config, n.info, errGenerated,
- "cannot bind another 'deepCopy' to: " & typeToString(t))
- else:
- localError(c.config, n.info, errGenerated,
- "cannot bind 'deepCopy' to: " & typeToString(t))
- if t.owner.getModule != s.getModule:
- localError(c.config, n.info, errGenerated,
- "type bound operation `" & name & "` can be defined only in the same module with its type (" & t.typeToString() & ")")
- else:
- localError(c.config, n.info, errGenerated,
- "signature for 'deepCopy' must be proc[T: ptr|ref](x: T): T")
- incl(s.flags, sfUsed)
- incl(s.flags, sfOverriden)
- of "=", "=copy", "=sink":
- if s.magic == mAsgn: return
- incl(s.flags, sfUsed)
- incl(s.flags, sfOverriden)
- if name == "=":
- message(c.config, n.info, warnDeprecated, "Overriding `=` hook is deprecated; Override `=copy` hook instead")
- let t = s.typ
- if t.len == 3 and t[0] == nil and t[1].kind == tyVar:
- var obj = t[1][0]
- while true:
- incl(obj.flags, tfHasAsgn)
- if obj.kind == tyGenericBody: obj = obj.lastSon
- elif obj.kind == tyGenericInvocation: obj = obj[0]
- else: break
- var objB = t[2]
- while true:
- if objB.kind == tyGenericBody: objB = objB.lastSon
- elif objB.kind in {tyGenericInvocation, tyGenericInst}:
- objB = objB[0]
- else: break
- if obj.kind in {tyObject, tyDistinct, tySequence, tyString} and sameType(obj, objB):
- # attach these ops to the canonical tySequence
- obj = canonType(c, obj)
- #echo "ATTACHING TO ", obj.id, " ", s.name.s, " ", cast[int](obj)
- let k = if name == "=" or name == "=copy": attachedAsgn else: attachedSink
- let ao = getAttachedOp(c.graph, obj, k)
- if ao == s:
- discard "forward declared op"
- elif ao.isNil and tfCheckedForDestructor notin obj.flags:
- setAttachedOp(c.graph, c.module.position, obj, k, s)
- else:
- prevDestructor(c, ao, obj, n.info)
- if obj.owner.getModule != s.getModule:
- localError(c.config, n.info, errGenerated,
- "type bound operation `" & name & "` can be defined only in the same module with its type (" & obj.typeToString() & ")")
- return
- if sfSystemModule notin s.owner.flags:
- localError(c.config, n.info, errGenerated,
- "signature for '" & s.name.s & "' must be proc[T: object](x: var T; y: T)")
- of "=trace":
- if s.magic != mTrace:
- bindTypeHook(c, s, n, attachedTrace)
- of "=wasmoved":
- if s.magic != mWasMoved:
- bindTypeHook(c, s, n, attachedWasMoved)
- else:
- if sfOverriden in s.flags:
- localError(c.config, n.info, errGenerated,
- "'destroy' or 'deepCopy' expected for 'override'")
- proc cursorInProcAux(conf: ConfigRef; n: PNode): bool =
- if inCheckpoint(n.info, conf.m.trackPos) != cpNone: return true
- for i in 0..<n.safeLen:
- if cursorInProcAux(conf, n[i]): return true
- proc cursorInProc(conf: ConfigRef; n: PNode): bool =
- if n.info.fileIndex == conf.m.trackPos.fileIndex:
- result = cursorInProcAux(conf, n)
- proc hasObjParam(s: PSym): bool =
- var t = s.typ
- for col in 1..<t.len:
- if skipTypes(t[col], skipPtrs).kind == tyObject:
- return true
- proc finishMethod(c: PContext, s: PSym) =
- if hasObjParam(s):
- methodDef(c.graph, c.idgen, s)
- proc semMethodPrototype(c: PContext; s: PSym; n: PNode) =
- if s.isGenericRoutine:
- let tt = s.typ
- var foundObj = false
- # we start at 1 for now so that tparsecombnum continues to compile.
- # XXX Revisit this problem later.
- for col in 1..<tt.len:
- let t = tt[col]
- if t != nil and t.kind == tyGenericInvocation:
- var x = skipTypes(t[0], {tyVar, tyLent, tyPtr, tyRef, tyGenericInst,
- tyGenericInvocation, tyGenericBody,
- tyAlias, tySink, tyOwned})
- if x.kind == tyObject and t.len-1 == n[genericParamsPos].len:
- foundObj = true
- addMethodToGeneric(c.graph, c.module.position, x, col, s)
- message(c.config, n.info, warnDeprecated, "generic methods are deprecated")
- #if not foundObj:
- # message(c.config, n.info, warnDeprecated, "generic method not attachable to object type is deprecated")
- else:
- # why check for the body? bug #2400 has none. Checking for sfForward makes
- # no sense either.
- # and result[bodyPos].kind != nkEmpty:
- if hasObjParam(s):
- methodDef(c.graph, c.idgen, s)
- else:
- localError(c.config, n.info, "'method' needs a parameter that has an object type")
- proc semProcAux(c: PContext, n: PNode, kind: TSymKind,
- validPragmas: TSpecialWords, flags: TExprFlags = {}): PNode =
- result = semProcAnnotation(c, n, validPragmas)
- if result != nil: return result
- result = n
- checkMinSonsLen(n, bodyPos + 1, c.config)
- let isAnon = n[namePos].kind == nkEmpty
- var s: PSym
- case n[namePos].kind
- of nkEmpty:
- s = newSym(kind, c.cache.idAnon, nextSymId c.idgen, c.getCurrOwner, n.info)
- s.flags.incl sfUsed
- n[namePos] = newSymNode(s)
- of nkSym:
- s = n[namePos].sym
- s.owner = c.getCurrOwner
- else:
- s = semIdentDef(c, n[namePos], kind)
- n[namePos] = newSymNode(s)
- when false:
- # disable for now
- if sfNoForward in c.module.flags and
- sfSystemModule notin c.module.flags:
- addInterfaceOverloadableSymAt(c, c.currentScope, s)
- s.flags.incl sfForward
- return
- assert s.kind in skProcKinds
- s.ast = n
- s.options = c.config.options
- #s.scope = c.currentScope
- # before compiling the proc params & body, set as current the scope
- # where the proc was declared
- let declarationScope = c.currentScope
- pushOwner(c, s)
- openScope(c)
- # process parameters:
- # generic parameters, parameters, and also the implicit generic parameters
- # within are analysed. This is often the entirety of their semantic analysis
- # but later we will have to do a check for forward declarations, which can by
- # way of pragmas, default params, and so on invalidate this parsing.
- # Nonetheless, we need to carry out this analysis to perform the search for a
- # potential forward declaration.
- setGenericParamsMisc(c, n)
- if n[paramsPos].kind != nkEmpty:
- semParamList(c, n[paramsPos], n[genericParamsPos], s)
- else:
- s.typ = newProcType(c, n.info)
- if n[genericParamsPos].safeLen == 0:
- # if there exist no explicit or implicit generic parameters, then this is
- # at most a nullary generic (generic with no type params). Regardless of
- # whether it's a nullary generic or non-generic, we restore the original.
- # In the case of `nkEmpty` it's non-generic and an empty `nkGeneircParams`
- # is a nullary generic.
- #
- # Remarks about nullary generics vs non-generics:
- # The difference between a non-generic and nullary generic is minor in
- # most cases but there are subtle and significant differences as well.
- # Due to instantiation that generic procs go through, a static echo in the
- # body of a nullary generic will not be executed immediately, as it's
- # instantiated and not immediately evaluated.
- n[genericParamsPos] = n[miscPos][1]
- n[miscPos] = c.graph.emptyNode
- if tfTriggersCompileTime in s.typ.flags: incl(s.flags, sfCompileTime)
- if n[patternPos].kind != nkEmpty:
- n[patternPos] = semPattern(c, n[patternPos], s)
- if s.kind == skIterator:
- s.typ.flags.incl(tfIterator)
- elif s.kind == skFunc:
- incl(s.flags, sfNoSideEffect)
- incl(s.typ.flags, tfNoSideEffect)
- var (proto, comesFromShadowScope) =
- if isAnon: (nil, false)
- else: searchForProc(c, declarationScope, s)
- if proto == nil and sfForward in s.flags and n[bodyPos].kind != nkEmpty:
- ## In cases such as a macro generating a proc with a gensymmed name we
- ## know `searchForProc` will not find it and sfForward will be set. In
- ## such scenarios the sym is shared between forward declaration and we
- ## can treat the `s` as the proto.
- ## To differentiate between that happening and a macro just returning a
- ## forward declaration that has been typed before we check if the body
- ## is not empty. This has the sideeffect of allowing multiple forward
- ## declarations if they share the same sym.
- ## See the "doubly-typed forward decls" case in tmacros_issues.nim
- proto = s
- let hasProto = proto != nil
- # set the default calling conventions
- case s.kind
- of skIterator:
- if s.typ.callConv != ccClosure:
- s.typ.callConv = if isAnon: ccClosure else: ccInline
- of skMacro, skTemplate:
- # we don't bother setting calling conventions for macros and templates
- discard
- else:
- # NB: procs with a forward decl have theirs determined by the forward decl
- if not hasProto:
- # in this case we're either a forward declaration or we're an impl without
- # a forward decl. We set the calling convention or will be set during
- # pragma analysis further down.
- s.typ.callConv = lastOptionEntry(c).defaultCC
- if not hasProto and sfGenSym notin s.flags: #and not isAnon:
- if s.kind in OverloadableSyms:
- addInterfaceOverloadableSymAt(c, declarationScope, s)
- else:
- addInterfaceDeclAt(c, declarationScope, s)
- pragmaCallable(c, s, n, validPragmas)
- if not hasProto:
- implicitPragmas(c, s, n.info, validPragmas)
- if n[pragmasPos].kind != nkEmpty and sfBorrow notin s.flags:
- setEffectsForProcType(c.graph, s.typ, n[pragmasPos], s)
- s.typ.flags.incl tfEffectSystemWorkaround
- # To ease macro generation that produce forwarded .async procs we now
- # allow a bit redundancy in the pragma declarations. The rule is
- # a prototype's pragma list must be a superset of the current pragma
- # list.
- # XXX This needs more checks eventually, for example that external
- # linking names do agree:
- if hasProto and (
- # calling convention mismatch
- tfExplicitCallConv in s.typ.flags and proto.typ.callConv != s.typ.callConv or
- # implementation has additional pragmas
- proto.typ.flags < s.typ.flags):
- localError(c.config, n[pragmasPos].info, errPragmaOnlyInHeaderOfProcX %
- ("'" & proto.name.s & "' from " & c.config$proto.info &
- " '" & s.name.s & "' from " & c.config$s.info))
- styleCheckDef(c, s)
- if hasProto:
- onDefResolveForward(n[namePos].info, proto)
- else:
- onDef(n[namePos].info, s)
- if hasProto:
- if sfForward notin proto.flags and proto.magic == mNone:
- wrongRedefinition(c, n.info, proto.name.s, proto.info)
- if not comesFromShadowScope:
- excl(proto.flags, sfForward)
- incl(proto.flags, sfWasForwarded)
- suggestSym(c.graph, s.info, proto, c.graph.usageSym)
- closeScope(c) # close scope with wrong parameter symbols
- openScope(c) # open scope for old (correct) parameter symbols
- if proto.ast[genericParamsPos].isGenericParams:
- addGenericParamListToScope(c, proto.ast[genericParamsPos])
- addParams(c, proto.typ.n, proto.kind)
- proto.info = s.info # more accurate line information
- proto.options = s.options
- s = proto
- n[genericParamsPos] = proto.ast[genericParamsPos]
- n[paramsPos] = proto.ast[paramsPos]
- n[pragmasPos] = proto.ast[pragmasPos]
- if n[namePos].kind != nkSym: internalError(c.config, n.info, "semProcAux")
- n[namePos].sym = proto
- if importantComments(c.config) and proto.ast.comment.len > 0:
- n.comment = proto.ast.comment
- proto.ast = n # needed for code generation
- popOwner(c)
- pushOwner(c, s)
- if not isAnon:
- if sfOverriden in s.flags or s.name.s[0] == '=': semOverride(c, s, n)
- elif s.name.s[0] in {'.', '('}:
- if s.name.s in [".", ".()", ".="] and {Feature.destructor, dotOperators} * c.features == {}:
- localError(c.config, n.info, "the overloaded " & s.name.s &
- " operator has to be enabled with {.experimental: \"dotOperators\".}")
- elif s.name.s == "()" and callOperator notin c.features:
- localError(c.config, n.info, "the overloaded " & s.name.s &
- " operator has to be enabled with {.experimental: \"callOperator\".}")
- if sfBorrow in s.flags and c.config.cmd notin cmdDocLike:
- result[bodyPos] = c.graph.emptyNode
- if n[bodyPos].kind != nkEmpty and sfError notin s.flags:
- # for DLL generation we allow sfImportc to have a body, for use in VM
- if c.config.ideCmd in {ideSug, ideCon} and s.kind notin {skMacro, skTemplate} and not
- cursorInProc(c.config, n[bodyPos]):
- # speed up nimsuggest
- if s.kind == skMethod: semMethodPrototype(c, s, n)
- elif isAnon:
- let gp = n[genericParamsPos]
- if gp.kind == nkEmpty or (gp.len == 1 and tfRetType in gp[0].typ.flags):
- # absolutely no generics (empty) or a single generic return type are
- # allowed, everything else, including a nullary generic is an error.
- pushProcCon(c, s)
- addResult(c, n, s.typ[0], skProc)
- s.ast[bodyPos] = hloBody(c, semProcBody(c, n[bodyPos], s.typ[0]))
- trackProc(c, s, s.ast[bodyPos])
- popProcCon(c)
- elif efOperand notin flags:
- localError(c.config, n.info, errGenericLambdaNotAllowed)
- else:
- pushProcCon(c, s)
- if n[genericParamsPos].kind == nkEmpty or s.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)
- if s.kind notin {skMacro, skTemplate} and s.magic == mNone: paramsTypeCheck(c, s.typ)
- maybeAddResult(c, s, n)
- let resultType =
- if s.kind == skMacro:
- sysTypeFromName(c.graph, n.info, "NimNode")
- elif not isInlineIterator(s.typ):
- s.typ[0]
- else:
- nil
- # semantic checking also needed with importc in case used in VM
- s.ast[bodyPos] = hloBody(c, semProcBody(c, n[bodyPos], resultType))
- # unfortunately we cannot skip this step when in 'system.compiles'
- # context as it may even be evaluated in 'system.compiles':
- trackProc(c, s, s.ast[bodyPos])
- else:
- if (s.typ[0] != nil and s.kind != skIterator):
- addDecl(c, newSym(skUnknown, getIdent(c.cache, "result"), nextSymId c.idgen, s, n.info))
- openScope(c)
- n[bodyPos] = semGenericStmt(c, n[bodyPos])
- closeScope(c)
- if s.magic == mNone:
- fixupInstantiatedSymbols(c, s)
- if s.kind == skMethod: semMethodPrototype(c, s, n)
- popProcCon(c)
- else:
- if s.kind == skMethod: semMethodPrototype(c, s, n)
- if hasProto: localError(c.config, n.info, errImplOfXexpected % proto.name.s)
- if {sfImportc, sfBorrow, sfError} * s.flags == {} and s.magic == mNone:
- # this is a forward declaration and we're building the prototype
- if s.kind in {skProc, skFunc} and s.typ[0] != nil and s.typ[0].kind == tyAnything:
- localError(c.config, n[paramsPos][0].info, "return type 'auto' cannot be used in forward declarations")
- incl(s.flags, sfForward)
- incl(s.flags, sfWasForwarded)
- elif sfBorrow in s.flags: semBorrow(c, n, s)
- sideEffectsCheck(c, s)
- closeScope(c) # close scope for parameters
- # c.currentScope = oldScope
- popOwner(c)
- if n[patternPos].kind != nkEmpty:
- c.patterns.add(s)
- if isAnon:
- n.transitionSonsKind(nkLambda)
- result.typ = s.typ
- if optOwnedRefs in c.config.globalOptions:
- result.typ = makeVarType(c, result.typ, tyOwned)
- elif isTopLevel(c) and s.kind != skIterator and s.typ.callConv == ccClosure:
- localError(c.config, s.info, "'.closure' calling convention for top level routines is invalid")
- proc determineType(c: PContext, s: PSym) =
- if s.typ != nil: return
- #if s.magic != mNone: return
- #if s.ast.isNil: return
- discard semProcAux(c, s.ast, s.kind, {})
- proc semIterator(c: PContext, n: PNode): PNode =
- # gensym'ed iterator?
- if n[namePos].kind == nkSym:
- # gensym'ed iterators might need to become closure iterators:
- n[namePos].sym.owner = getCurrOwner(c)
- n[namePos].sym.transitionRoutineSymKind(skIterator)
- result = semProcAux(c, n, skIterator, iteratorPragmas)
- # bug #7093: if after a macro transformation we don't have an
- # nkIteratorDef aynmore, return. The iterator then might have been
- # sem'checked already. (Or not, if the macro skips it.)
- if result.kind != n.kind: return
- var s = result[namePos].sym
- var t = s.typ
- if t[0] == nil and s.typ.callConv != ccClosure:
- localError(c.config, n.info, "iterator needs a return type")
- # 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
- if n[bodyPos].kind == nkEmpty and s.magic == mNone and c.inConceptDecl == 0:
- localError(c.config, n.info, errImplOfXexpected % s.name.s)
- if optOwnedRefs in c.config.globalOptions and result.typ != nil:
- result.typ = makeVarType(c, result.typ, tyOwned)
- result.typ.callConv = ccClosure
- proc semProc(c: PContext, n: PNode): PNode =
- result = semProcAux(c, n, skProc, procPragmas)
- proc semFunc(c: PContext, n: PNode): PNode =
- let validPragmas = if n[namePos].kind != nkEmpty: procPragmas
- else: lambdaPragmas
- result = semProcAux(c, n, skFunc, validPragmas)
- proc semMethod(c: PContext, n: PNode): PNode =
- if not isTopLevel(c): localError(c.config, n.info, errXOnlyAtModuleScope % "method")
- result = semProcAux(c, n, skMethod, methodPragmas)
- # macros can transform converters to nothing:
- if namePos >= result.safeLen: return result
- # bug #7093: if after a macro transformation we don't have an
- # nkIteratorDef aynmore, return. The iterator then might have been
- # sem'checked already. (Or not, if the macro skips it.)
- if result.kind != nkMethodDef: return
- var s = result[namePos].sym
- # we need to fix the 'auto' return type for the dispatcher here (see tautonotgeneric
- # test case):
- let disp = getDispatcher(s)
- # auto return type?
- if disp != nil and disp.typ[0] != nil and disp.typ[0].kind == tyUntyped:
- let ret = s.typ[0]
- disp.typ[0] = ret
- if disp.ast[resultPos].kind == nkSym:
- if isEmptyType(ret): disp.ast[resultPos] = c.graph.emptyNode
- else: disp.ast[resultPos].sym.typ = ret
- proc semConverterDef(c: PContext, n: PNode): PNode =
- if not isTopLevel(c): localError(c.config, n.info, errXOnlyAtModuleScope % "converter")
- result = semProcAux(c, n, skConverter, converterPragmas)
- # macros can transform converters to nothing:
- if namePos >= result.safeLen: return result
- # bug #7093: if after a macro transformation we don't have an
- # nkIteratorDef aynmore, return. The iterator then might have been
- # sem'checked already. (Or not, if the macro skips it.)
- if result.kind != nkConverterDef: return
- var s = result[namePos].sym
- var t = s.typ
- if t[0] == nil: localError(c.config, n.info, errXNeedsReturnType % "converter")
- if t.len != 2: localError(c.config, n.info, "a converter takes exactly one argument")
- addConverterDef(c, LazySym(sym: s))
- proc semMacroDef(c: PContext, n: PNode): PNode =
- result = semProcAux(c, n, skMacro, macroPragmas)
- # macros can transform macros to nothing:
- if namePos >= result.safeLen: return result
- # bug #7093: if after a macro transformation we don't have an
- # nkIteratorDef aynmore, return. The iterator then might have been
- # sem'checked already. (Or not, if the macro skips it.)
- if result.kind != nkMacroDef: return
- var s = result[namePos].sym
- var t = s.typ
- var allUntyped = true
- for i in 1..<t.n.len:
- let param = t.n[i].sym
- if param.typ.kind != tyUntyped: allUntyped = false
- if allUntyped: incl(s.flags, sfAllUntyped)
- if n[bodyPos].kind == nkEmpty:
- localError(c.config, n.info, errImplOfXexpected % s.name.s)
- proc incMod(c: PContext, n: PNode, it: PNode, includeStmtResult: PNode) =
- var f = checkModuleName(c.config, it)
- if f != InvalidFileIdx:
- addIncludeFileDep(c, f)
- onProcessing(c.graph, f, "include", c.module)
- if containsOrIncl(c.includedFiles, f.int):
- localError(c.config, n.info, errRecursiveDependencyX % toMsgFilename(c.config, f))
- else:
- includeStmtResult.add semStmt(c, c.graph.includeFileCallback(c.graph, c.module, f), {})
- excl(c.includedFiles, f.int)
- proc evalInclude(c: PContext, n: PNode): PNode =
- result = newNodeI(nkStmtList, n.info)
- result.add n
- for i in 0..<n.len:
- var imp: PNode
- let it = n[i]
- if it.kind == nkInfix and it.len == 3 and it[0].ident.s != "/":
- localError(c.config, it.info, "Cannot use '" & it[0].ident.s & "' in 'include'.")
- if it.kind == nkInfix and it.len == 3 and it[2].kind == nkBracket:
- let sep = it[0]
- let dir = it[1]
- imp = newNodeI(nkInfix, it.info)
- imp.add sep
- imp.add dir
- imp.add sep # dummy entry, replaced in the loop
- for x in it[2]:
- imp[2] = x
- incMod(c, n, imp, result)
- else:
- incMod(c, n, it, result)
- proc recursiveSetFlag(n: PNode, flag: TNodeFlag) =
- if n != nil:
- for i in 0..<n.safeLen: recursiveSetFlag(n[i], flag)
- incl(n.flags, flag)
- proc semPragmaBlock(c: PContext, n: PNode; expectedType: PType = nil): PNode =
- checkSonsLen(n, 2, c.config)
- let pragmaList = n[0]
- pragma(c, nil, pragmaList, exprPragmas, isStatement = true)
- var inUncheckedAssignSection = 0
- for p in pragmaList:
- if whichPragma(p) == wCast:
- case whichPragma(p[1])
- of wGcSafe, wNoSideEffect, wTags, wForbids, wRaises:
- discard "handled in sempass2"
- of wUncheckedAssign:
- inUncheckedAssignSection = 1
- else:
- localError(c.config, p.info, "invalid pragma block: " & $p)
- inc c.inUncheckedAssignSection, inUncheckedAssignSection
- n[1] = semExpr(c, n[1], expectedType = expectedType)
- dec c.inUncheckedAssignSection, inUncheckedAssignSection
- result = n
- result.typ = n[1].typ
- for i in 0..<pragmaList.len:
- case whichPragma(pragmaList[i])
- of wLine: setInfoRecursive(result, pragmaList[i].info)
- of wNoRewrite: recursiveSetFlag(result, nfNoRewrite)
- else: discard
- proc semStaticStmt(c: PContext, n: PNode): PNode =
- #echo "semStaticStmt"
- #writeStackTrace()
- inc c.inStaticContext
- openScope(c)
- let a = semStmt(c, n[0], {})
- closeScope(c)
- dec c.inStaticContext
- n[0] = a
- evalStaticStmt(c.module, c.idgen, c.graph, a, c.p.owner)
- when false:
- # for incremental replays, keep the AST as required for replays:
- result = n
- else:
- result = newNodeI(nkDiscardStmt, n.info, 1)
- result[0] = c.graph.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 inferConceptStaticParam(c: PContext, inferred, n: PNode) =
- var typ = inferred.typ
- let res = semConstExpr(c, n)
- if not sameType(res.typ, typ.base):
- localError(c.config, n.info,
- "cannot infer the concept parameter '%s', due to a type mismatch. " &
- "attempt to equate '%s' and '%s'." % [inferred.renderTree, $res.typ, $typ.base])
- typ.n = res
- proc semStmtList(c: PContext, n: PNode, flags: TExprFlags, expectedType: PType = nil): PNode =
- result = n
- result.transitionSonsKind(nkStmtList)
- var voidContext = false
- var last = n.len-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[last].kind in {nkPragma, nkCommentStmt,
- # nkNilLit, nkEmpty}:
- # dec last
- for i in 0..<n.len:
- var x = semExpr(c, n[i], flags, if i == n.len - 1: expectedType else: nil)
- n[i] = x
- if c.matchedConcept != nil and x.typ != nil and
- (nfFromTemplate notin n.flags or i != last):
- case x.typ.kind
- of tyBool:
- if x.kind == nkInfix and
- x[0].kind == nkSym and
- x[0].sym.name.s == "==":
- if x[1].typ.isUnresolvedStatic:
- inferConceptStaticParam(c, x[1], x[2])
- continue
- elif x[2].typ.isUnresolvedStatic:
- inferConceptStaticParam(c, x[2], x[1])
- continue
- let verdict = semConstExpr(c, n[i])
- if verdict == nil or verdict.kind != nkIntLit or verdict.intVal == 0:
- localError(c.config, result.info, "concept predicate failed")
- of tyUnknown: continue
- else: discard
- if n[i].typ == c.enforceVoidContext: #or usesResult(n[i]):
- voidContext = true
- n.typ = c.enforceVoidContext
- if i == last and (n.len == 1 or ({efWantValue, efInTypeof} * flags != {})):
- n.typ = n[i].typ
- if not isEmptyType(n.typ): n.transitionSonsKind(nkStmtListExpr)
- elif i != last or voidContext:
- discardCheck(c, n[i], flags)
- else:
- n.typ = n[i].typ
- if not isEmptyType(n.typ): n.transitionSonsKind(nkStmtListExpr)
- var m = n[i]
- while m.kind in {nkStmtListExpr, nkStmtList} and m.len > 0: # from templates
- m = m.lastSon
- if m.kind in nkLastBlockStmts or
- m.kind in nkCallKinds and m[0].kind == nkSym and
- sfNoReturn in m[0].sym.flags:
- for j in i + 1..<n.len:
- case n[j].kind
- of nkPragma, nkCommentStmt, nkNilLit, nkEmpty, nkState: discard
- else: message(c.config, n[j].info, warnUnreachableCode)
- else: discard
- if result.len == 1 and
- # concept bodies should be preserved as a stmt list:
- c.matchedConcept == nil and
- # also, don't make life complicated for macros.
- # they will always expect a proper stmtlist:
- nfBlockArg notin n.flags and
- result[0].kind != nkDefer:
- result = result[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)
- proc semStmt(c: PContext, n: PNode; flags: TExprFlags): PNode =
- if efInTypeof notin flags:
- result = semExprNoType(c, n)
- else:
- result = semExpr(c, n, flags)
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