#
#
# The Nim Compiler
# (c) Copyright 2017 Andreas Rumpf
#
# See the file "copying.txt", included in this
# distribution, for details about the copyright.
#
## This module contains the data structures for the semantic checking phase.
import
strutils, intsets, options, lexer, ast, astalgo, trees, treetab,
wordrecg,
ropes, msgs, platform, os, condsyms, idents, renderer, types, extccomp, math,
magicsys, nversion, nimsets, parser, times, passes, vmdef,
modulegraphs, lineinfos
type
TOptionEntry* = object # entries to put on a stack for pragma parsing
options*: TOptions
defaultCC*: TCallingConvention
dynlib*: PLib
notes*: TNoteKinds
features*: set[Feature]
otherPragmas*: PNode # every pragma can be pushed
POptionEntry* = ref TOptionEntry
PProcCon* = ref TProcCon
TProcCon* = object # procedure context; also used for top-level
# statements
owner*: PSym # the symbol this context belongs to
resultSym*: PSym # the result symbol (if we are in a proc)
selfSym*: PSym # the 'self' symbol (if available)
nestedLoopCounter*: int # whether we are in a loop or not
nestedBlockCounter*: int # whether we are in a block or not
inTryStmt*: int # whether we are in a try statement; works also
# in standalone ``except`` and ``finally``
next*: PProcCon # used for stacking procedure contexts
wasForwarded*: bool # whether the current proc has a separate header
mappingExists*: bool
mapping*: TIdTable
caseContext*: seq[tuple[n: PNode, idx: int]]
TMatchedConcept* = object
candidateType*: PType
prev*: ptr TMatchedConcept
depth*: int
TInstantiationPair* = object
genericSym*: PSym
inst*: PInstantiation
TExprFlag* = enum
efLValue, efWantIterator, efInTypeof,
efNeedStatic,
# Use this in contexts where a static value is mandatory
efPreferStatic,
# Use this in contexts where a static value could bring more
# information, but it's not strictly mandatory. This may become
# the default with implicit statics in the future.
efPreferNilResult,
# Use this if you want a certain result (e.g. static value),
# but you don't want to trigger a hard error. For example,
# you may be in position to supply a better error message
# to the user.
efWantStmt, efAllowStmt, efDetermineType, efExplain,
efAllowDestructor, efWantValue, efOperand, efNoSemCheck,
efNoEvaluateGeneric, efInCall, efFromHlo,
efNoUndeclared
# Use this if undeclared identifiers should not raise an error during
# overload resolution.
TExprFlags* = set[TExprFlag]
PContext* = ref TContext
TContext* = object of TPassContext # a context represents a module
enforceVoidContext*: PType
module*: PSym # the module sym belonging to the context
currentScope*: PScope # current scope
importTable*: PScope # scope for all imported symbols
topLevelScope*: PScope # scope for all top-level symbols
p*: PProcCon # procedure context
matchedConcept*: ptr TMatchedConcept # the current concept being matched
friendModules*: seq[PSym] # friend modules; may access private data;
# this is used so that generic instantiations
# can access private object fields
instCounter*: int # to prevent endless instantiations
ambiguousSymbols*: IntSet # ids of all ambiguous symbols (cannot
# store this info in the syms themselves!)
inGenericContext*: int # > 0 if we are in a generic type
inStaticContext*: int # > 0 if we are inside a static: block
inUnrolledContext*: int # > 0 if we are unrolling a loop
compilesContextId*: int # > 0 if we are in a ``compiles`` magic
compilesContextIdGenerator*: int
inGenericInst*: int # > 0 if we are instantiating a generic
converters*: seq[PSym]
patterns*: seq[PSym] # sequence of pattern matchers
optionStack*: seq[POptionEntry]
symMapping*: TIdTable # every gensym'ed symbol needs to be mapped
# to some new symbol in a generic instantiation
libs*: seq[PLib] # all libs used by this module
semConstExpr*: proc (c: PContext, n: PNode): PNode {.nimcall.} # for the pragmas
semExpr*: proc (c: PContext, n: PNode, flags: TExprFlags = {}): PNode {.nimcall.}
semTryExpr*: proc (c: PContext, n: PNode, flags: TExprFlags = {}): PNode {.nimcall.}
semTryConstExpr*: proc (c: PContext, n: PNode): PNode {.nimcall.}
semOperand*: proc (c: PContext, n: PNode, flags: TExprFlags = {}): PNode {.nimcall.}
semConstBoolExpr*: proc (c: PContext, n: PNode): PNode {.nimcall.} # XXX bite the bullet
semOverloadedCall*: proc (c: PContext, n, nOrig: PNode,
filter: TSymKinds, flags: TExprFlags): PNode {.nimcall.}
semTypeNode*: proc(c: PContext, n: PNode, prev: PType): PType {.nimcall.}
semInferredLambda*: proc(c: PContext, pt: TIdTable, n: PNode): PNode
semGenerateInstance*: proc (c: PContext, fn: PSym, pt: TIdTable,
info: TLineInfo): PSym
includedFiles*: IntSet # used to detect recursive include files
pureEnumFields*: TStrTable # pure enum fields that can be used unambiguously
userPragmas*: TStrTable
evalContext*: PEvalContext
unknownIdents*: IntSet # ids of all unknown identifiers to prevent
# naming it multiple times
generics*: seq[TInstantiationPair] # pending list of instantiated generics to compile
topStmts*: int # counts the number of encountered top level statements
lastGenericIdx*: int # used for the generics stack
hloLoopDetector*: int # used to prevent endless loops in the HLO
inParallelStmt*: int
instTypeBoundOp*: proc (c: PContext; dc: PSym; t: PType; info: TLineInfo;
op: TTypeAttachedOp; col: int): PSym {.nimcall.}
selfName*: PIdent
cache*: IdentCache
graph*: ModuleGraph
signatures*: TStrTable
recursiveDep*: string
suggestionsMade*: bool
features*: set[Feature]
inTypeContext*: int
typesWithOps*: seq[(PType, PType)] #\
# We need to instantiate the type bound ops lazily after
# the generic type has been constructed completely. See
# tests/destructor/topttree.nim for an example that
# would otherwise fail.
template config*(c: PContext): ConfigRef = c.graph.config
proc makeInstPair*(s: PSym, inst: PInstantiation): TInstantiationPair =
result.genericSym = s
result.inst = inst
proc filename*(c: PContext): string =
# the module's filename
return toFilename(c.config, FileIndex c.module.position)
proc scopeDepth*(c: PContext): int {.inline.} =
result = if c.currentScope != nil: c.currentScope.depthLevel
else: 0
proc getCurrOwner*(c: PContext): PSym =
# owner stack (used for initializing the
# owner field of syms)
# the documentation comment always gets
# assigned to the current owner
result = c.graph.owners[^1]
proc pushOwner*(c: PContext; owner: PSym) =
add(c.graph.owners, owner)
proc popOwner*(c: PContext) =
var length = len(c.graph.owners)
if length > 0: setLen(c.graph.owners, length - 1)
else: internalError(c.config, "popOwner")
proc lastOptionEntry*(c: PContext): POptionEntry =
result = c.optionStack[^1]
proc popProcCon*(c: PContext) {.inline.} = c.p = c.p.next
proc put*(p: PProcCon; key, val: PSym) =
if not p.mappingExists:
initIdTable(p.mapping)
p.mappingExists = true
#echo "put into table ", key.info
p.mapping.idTablePut(key, val)
proc get*(p: PProcCon; key: PSym): PSym =
if not p.mappingExists: return nil
result = PSym(p.mapping.idTableGet(key))
proc getGenSym*(c: PContext; s: PSym): PSym =
if sfGenSym notin s.flags: return s
var it = c.p
while it != nil:
result = get(it, s)
if result != nil:
#echo "got from table ", result.name.s, " ", result.info
return result
it = it.next
result = s
proc considerGenSyms*(c: PContext; n: PNode) =
if n.kind == nkSym:
let s = getGenSym(c, n.sym)
if n.sym != s:
n.sym = s
else:
for i in 0..<n.safeLen:
considerGenSyms(c, n.sons[i])
proc newOptionEntry*(conf: ConfigRef): POptionEntry =
new(result)
result.options = conf.options
result.defaultCC = ccDefault
result.dynlib = nil
result.notes = conf.notes
proc newContext*(graph: ModuleGraph; module: PSym): PContext =
new(result)
result.enforceVoidContext = PType(kind: tyTyped)
result.ambiguousSymbols = initIntSet()
result.optionStack = @[]
result.libs = @[]
result.optionStack.add(newOptionEntry(graph.config))
result.module = module
result.friendModules = @[module]
result.converters = @[]
result.patterns = @[]
result.includedFiles = initIntSet()
initStrTable(result.pureEnumFields)
initStrTable(result.userPragmas)
result.generics = @[]
result.unknownIdents = initIntSet()
result.cache = graph.cache
result.graph = graph
initStrTable(result.signatures)
result.typesWithOps = @[]
result.features = graph.config.features
proc inclSym(sq: var seq[PSym], s: PSym) =
var L = len(sq)
for i in 0 ..< L:
if sq[i].id == s.id: return
setLen(sq, L + 1)
sq[L] = s
proc addConverter*(c: PContext, conv: PSym) =
inclSym(c.converters, conv)
proc addPattern*(c: PContext, p: PSym) =
inclSym(c.patterns, p)
proc newLib*(kind: TLibKind): PLib =
new(result)
result.kind = kind #initObjectSet(result.syms)
proc addToLib*(lib: PLib, sym: PSym) =
#if sym.annex != nil and not isGenericRoutine(sym):
# LocalError(sym.info, errInvalidPragma)
sym.annex = lib
proc newTypeS*(kind: TTypeKind, c: PContext): PType =
result = newType(kind, getCurrOwner(c))
proc makePtrType*(c: PContext, baseType: PType): PType =
result = newTypeS(tyPtr, c)
addSonSkipIntLit(result, baseType)
proc makeTypeWithModifier*(c: PContext,
modifier: TTypeKind,
baseType: PType): PType =
assert modifier in {tyVar, tyLent, tyPtr, tyRef, tyStatic, tyTypeDesc}
if modifier in {tyVar, tyLent, tyTypeDesc} and baseType.kind == modifier:
result = baseType
else:
result = newTypeS(modifier, c)
addSonSkipIntLit(result, baseType)
proc makeVarType*(c: PContext, baseType: PType; kind = tyVar): PType =
if baseType.kind == kind:
result = baseType
else:
result = newTypeS(kind, c)
addSonSkipIntLit(result, baseType)
proc makeVarType*(owner: PSym, baseType: PType; kind = tyVar): PType =
if baseType.kind == kind:
result = baseType
else:
result = newType(kind, owner)
addSonSkipIntLit(result, baseType)
proc makeTypeDesc*(c: PContext, typ: PType): PType =
if typ.kind == tyTypeDesc:
result = typ
else:
result = newTypeS(tyTypeDesc, c)
incl result.flags, tfCheckedForDestructor
result.addSonSkipIntLit(typ)
proc makeTypeSymNode*(c: PContext, typ: PType, info: TLineInfo): PNode =
let typedesc = newTypeS(tyTypeDesc, c)
incl typedesc.flags, tfCheckedForDestructor
typedesc.addSonSkipIntLit(assertNotNil(c.config, typ))
let sym = newSym(skType, c.cache.idAnon, getCurrOwner(c), info,
c.config.options).linkTo(typedesc)
return newSymNode(sym, info)
proc makeTypeFromExpr*(c: PContext, n: PNode): PType =
result = newTypeS(tyFromExpr, c)
assert n != nil
result.n = n
proc newTypeWithSons*(owner: PSym, kind: TTypeKind, sons: seq[PType]): PType =
result = newType(kind, owner)
result.sons = sons
proc newTypeWithSons*(c: PContext, kind: TTypeKind,
sons: seq[PType]): PType =
result = newType(kind, getCurrOwner(c))
result.sons = sons
proc makeStaticExpr*(c: PContext, n: PNode): PNode =
result = newNodeI(nkStaticExpr, n.info)
result.sons = @[n]
result.typ = if n.typ != nil and n.typ.kind == tyStatic: n.typ
else: newTypeWithSons(c, tyStatic, @[n.typ])
proc makeAndType*(c: PContext, t1, t2: PType): PType =
result = newTypeS(tyAnd, c)
result.sons = @[t1, t2]
propagateToOwner(result, t1)
propagateToOwner(result, t2)
result.flags.incl((t1.flags + t2.flags) * {tfHasStatic})
result.flags.incl tfHasMeta
proc makeOrType*(c: PContext, t1, t2: PType): PType =
result = newTypeS(tyOr, c)
if t1.kind != tyOr and t2.kind != tyOr:
result.sons = @[t1, t2]
else:
template addOr(t1) =
if t1.kind == tyOr:
for x in t1.sons: result.rawAddSon x
else:
result.rawAddSon t1
addOr(t1)
addOr(t2)
propagateToOwner(result, t1)
propagateToOwner(result, t2)
result.flags.incl((t1.flags + t2.flags) * {tfHasStatic})
result.flags.incl tfHasMeta
proc makeNotType*(c: PContext, t1: PType): PType =
result = newTypeS(tyNot, c)
result.sons = @[t1]
propagateToOwner(result, t1)
result.flags.incl(t1.flags * {tfHasStatic})
result.flags.incl tfHasMeta
proc nMinusOne(c: PContext; n: PNode): PNode =
result = newNode(nkCall, n.info, @[
newSymNode(getSysMagic(c.graph, n.info, "pred", mPred)), n])
# Remember to fix the procs below this one when you make changes!
proc makeRangeWithStaticExpr*(c: PContext, n: PNode): PType =
let intType = getSysType(c.graph, n.info, tyInt)
result = newTypeS(tyRange, c)
result.sons = @[intType]
if n.typ != nil and n.typ.n == nil:
result.flags.incl tfUnresolved
result.n = newNode(nkRange, n.info, @[
newIntTypeNode(nkIntLit, 0, intType),
makeStaticExpr(c, nMinusOne(c, n))])
template rangeHasUnresolvedStatic*(t: PType): bool =
tfUnresolved in t.flags
proc errorType*(c: PContext): PType =
## creates a type representing an error state
result = newTypeS(tyError, c)
result.flags.incl tfCheckedForDestructor
proc errorNode*(c: PContext, n: PNode): PNode =
result = newNodeI(nkEmpty, n.info)
result.typ = errorType(c)
proc fillTypeS*(dest: PType, kind: TTypeKind, c: PContext) =
dest.kind = kind
dest.owner = getCurrOwner(c)
dest.size = - 1
proc makeRangeType*(c: PContext; first, last: BiggestInt;
info: TLineInfo; intType: PType = nil): PType =
let intType = if intType != nil: intType else: getSysType(c.graph, info, tyInt)
var n = newNodeI(nkRange, info)
addSon(n, newIntTypeNode(nkIntLit, first, intType))
addSon(n, newIntTypeNode(nkIntLit, last, intType))
result = newTypeS(tyRange, c)
result.n = n
addSonSkipIntLit(result, intType) # basetype of range
proc markIndirect*(c: PContext, s: PSym) {.inline.} =
if s.kind in {skProc, skFunc, skConverter, skMethod, skIterator}:
incl(s.flags, sfAddrTaken)
# XXX add to 'c' for global analysis
proc illFormedAst*(n: PNode; conf: ConfigRef) =
globalError(conf, n.info, errIllFormedAstX, renderTree(n, {renderNoComments}))
proc illFormedAstLocal*(n: PNode; conf: ConfigRef) =
localError(conf, n.info, errIllFormedAstX, renderTree(n, {renderNoComments}))
proc checkSonsLen*(n: PNode, length: int; conf: ConfigRef) =
if sonsLen(n) != length: illFormedAst(n, conf)
proc checkMinSonsLen*(n: PNode, length: int; conf: ConfigRef) =
if sonsLen(n) < length: illFormedAst(n, conf)
proc isTopLevel*(c: PContext): bool {.inline.} =
result = c.currentScope.depthLevel <= 2
proc pushCaseContext*(c: PContext, caseNode: PNode) =
add(c.p.caseContext, (caseNode, 0))
proc popCaseContext*(c: PContext) =
discard pop(c.p.caseContext)
proc setCaseContextIdx*(c: PContext, idx: int) =
c.p.caseContext[^1].idx = idx