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- #
- #
- # The Nim Compiler
- # (c) Copyright 2017 Andreas Rumpf
- #
- # See the file "copying.txt", included in this
- # distribution, for details about the copyright.
- #
- ## This module implements the module graph data structure. The module graph
- ## represents a complete Nim project. Single modules can either be kept in RAM
- ## or stored in a rod-file.
- import intsets, tables, hashes, md5_old
- import ast, astalgo, options, lineinfos,idents, btrees, ropes, msgs, pathutils, packages
- import ic / [packed_ast, ic]
- when defined(nimPreviewSlimSystem):
- import std/assertions
- type
- SigHash* = distinct MD5Digest
- LazySym* = object
- id*: FullId
- sym*: PSym
- Iface* = object ## data we don't want to store directly in the
- ## ast.PSym type for s.kind == skModule
- module*: PSym ## module this "Iface" belongs to
- converters*: seq[LazySym]
- patterns*: seq[LazySym]
- pureEnums*: seq[LazySym]
- interf: TStrTable
- interfHidden: TStrTable
- uniqueName*: Rope
- Operators* = object
- opNot*, opContains*, opLe*, opLt*, opAnd*, opOr*, opIsNil*, opEq*: PSym
- opAdd*, opSub*, opMul*, opDiv*, opLen*: PSym
- FullId* = object
- module*: int
- packed*: PackedItemId
- LazyType* = object
- id*: FullId
- typ*: PType
- LazyInstantiation* = object
- module*: int
- sym*: FullId
- concreteTypes*: seq[FullId]
- inst*: PInstantiation
- SymInfoPair* = object
- sym*: PSym
- info*: TLineInfo
- ModuleGraph* {.acyclic.} = ref object
- ifaces*: seq[Iface] ## indexed by int32 fileIdx
- packed*: PackedModuleGraph
- encoders*: seq[PackedEncoder]
- typeInstCache*: Table[ItemId, seq[LazyType]] # A symbol's ItemId.
- procInstCache*: Table[ItemId, seq[LazyInstantiation]] # A symbol's ItemId.
- attachedOps*: array[TTypeAttachedOp, Table[ItemId, LazySym]] # Type ID, destructors, etc.
- methodsPerType*: Table[ItemId, seq[(int, LazySym)]] # Type ID, attached methods
- enumToStringProcs*: Table[ItemId, LazySym]
- emittedTypeInfo*: Table[string, FileIndex]
- startupPackedConfig*: PackedConfig
- packageSyms*: TStrTable
- deps*: IntSet # the dependency graph or potentially its transitive closure.
- importDeps*: Table[FileIndex, seq[FileIndex]] # explicit import module dependencies
- suggestMode*: bool # whether we are in nimsuggest mode or not.
- invalidTransitiveClosure: bool
- inclToMod*: Table[FileIndex, FileIndex] # mapping of include file to the
- # first module that included it
- importStack*: seq[FileIndex] # The current import stack. Used for detecting recursive
- # module dependencies.
- backend*: RootRef # minor hack so that a backend can extend this easily
- config*: ConfigRef
- cache*: IdentCache
- vm*: RootRef # unfortunately the 'vm' state is shared project-wise, this will
- # be clarified in later compiler implementations.
- doStopCompile*: proc(): bool {.closure.}
- usageSym*: PSym # for nimsuggest
- owners*: seq[PSym]
- suggestSymbols*: Table[FileIndex, seq[SymInfoPair]]
- suggestErrors*: Table[FileIndex, seq[Suggest]]
- methods*: seq[tuple[methods: seq[PSym], dispatcher: PSym]] # needs serialization!
- systemModule*: PSym
- sysTypes*: array[TTypeKind, PType]
- compilerprocs*: TStrTable
- exposed*: TStrTable
- packageTypes*: TStrTable
- emptyNode*: PNode
- canonTypes*: Table[SigHash, PType]
- symBodyHashes*: Table[int, SigHash] # symId to digest mapping
- importModuleCallback*: proc (graph: ModuleGraph; m: PSym, fileIdx: FileIndex): PSym {.nimcall.}
- includeFileCallback*: proc (graph: ModuleGraph; m: PSym, fileIdx: FileIndex): PNode {.nimcall.}
- cacheSeqs*: Table[string, PNode] # state that is shared to support the 'macrocache' API; IC: implemented
- cacheCounters*: Table[string, BiggestInt] # IC: implemented
- cacheTables*: Table[string, BTree[string, PNode]] # IC: implemented
- passes*: seq[TPass]
- onDefinition*: proc (graph: ModuleGraph; s: PSym; info: TLineInfo) {.nimcall.}
- onDefinitionResolveForward*: proc (graph: ModuleGraph; s: PSym; info: TLineInfo) {.nimcall.}
- onUsage*: proc (graph: ModuleGraph; s: PSym; info: TLineInfo) {.nimcall.}
- globalDestructors*: seq[PNode]
- strongSemCheck*: proc (graph: ModuleGraph; owner: PSym; body: PNode) {.nimcall.}
- compatibleProps*: proc (graph: ModuleGraph; formal, actual: PType): bool {.nimcall.}
- idgen*: IdGenerator
- operators*: Operators
- TPassContext* = object of RootObj # the pass's context
- idgen*: IdGenerator
- PPassContext* = ref TPassContext
- TPassOpen* = proc (graph: ModuleGraph; module: PSym; idgen: IdGenerator): PPassContext {.nimcall.}
- TPassClose* = proc (graph: ModuleGraph; p: PPassContext, n: PNode): PNode {.nimcall.}
- TPassProcess* = proc (p: PPassContext, topLevelStmt: PNode): PNode {.nimcall.}
- TPass* = tuple[open: TPassOpen,
- process: TPassProcess,
- close: TPassClose,
- isFrontend: bool]
- proc resetForBackend*(g: ModuleGraph) =
- initStrTable(g.compilerprocs)
- g.typeInstCache.clear()
- g.procInstCache.clear()
- for a in mitems(g.attachedOps):
- a.clear()
- g.methodsPerType.clear()
- g.enumToStringProcs.clear()
- const
- cb64 = [
- "A", "B", "C", "D", "E", "F", "G", "H", "I", "J", "K", "L", "M", "N",
- "O", "P", "Q", "R", "S", "T", "U", "V", "W", "X", "Y", "Z",
- "a", "b", "c", "d", "e", "f", "g", "h", "i", "j", "k", "l", "m", "n",
- "o", "p", "q", "r", "s", "t", "u", "v", "w", "x", "y", "z",
- "0", "1", "2", "3", "4", "5", "6", "7", "8", "9a",
- "9b", "9c"]
- proc toBase64a(s: cstring, len: int): string =
- ## encodes `s` into base64 representation.
- result = newStringOfCap(((len + 2) div 3) * 4)
- result.add "__"
- var i = 0
- while i < len - 2:
- let a = ord(s[i])
- let b = ord(s[i+1])
- let c = ord(s[i+2])
- result.add cb64[a shr 2]
- result.add cb64[((a and 3) shl 4) or ((b and 0xF0) shr 4)]
- result.add cb64[((b and 0x0F) shl 2) or ((c and 0xC0) shr 6)]
- result.add cb64[c and 0x3F]
- inc(i, 3)
- if i < len-1:
- let a = ord(s[i])
- let b = ord(s[i+1])
- result.add cb64[a shr 2]
- result.add cb64[((a and 3) shl 4) or ((b and 0xF0) shr 4)]
- result.add cb64[((b and 0x0F) shl 2)]
- elif i < len:
- let a = ord(s[i])
- result.add cb64[a shr 2]
- result.add cb64[(a and 3) shl 4]
- template interfSelect(iface: Iface, importHidden: bool): TStrTable =
- var ret = iface.interf.addr # without intermediate ptr, it creates a copy and compiler becomes 15x slower!
- if importHidden: ret = iface.interfHidden.addr
- ret[]
- template semtab(g: ModuleGraph, m: PSym): TStrTable =
- g.ifaces[m.position].interf
- template semtabAll*(g: ModuleGraph, m: PSym): TStrTable =
- g.ifaces[m.position].interfHidden
- proc initStrTables*(g: ModuleGraph, m: PSym) =
- initStrTable(semtab(g, m))
- initStrTable(semtabAll(g, m))
- proc strTableAdds*(g: ModuleGraph, m: PSym, s: PSym) =
- strTableAdd(semtab(g, m), s)
- strTableAdd(semtabAll(g, m), s)
- proc isCachedModule(g: ModuleGraph; module: int): bool {.inline.} =
- result = module < g.packed.len and g.packed[module].status == loaded
- proc isCachedModule(g: ModuleGraph; m: PSym): bool {.inline.} =
- isCachedModule(g, m.position)
- proc simulateCachedModule*(g: ModuleGraph; moduleSym: PSym; m: PackedModule) =
- when false:
- echo "simulating ", moduleSym.name.s, " ", moduleSym.position
- simulateLoadedModule(g.packed, g.config, g.cache, moduleSym, m)
- proc initEncoder*(g: ModuleGraph; module: PSym) =
- let id = module.position
- if id >= g.encoders.len:
- setLen g.encoders, id+1
- ic.initEncoder(g.encoders[id],
- g.packed[id].fromDisk, module, g.config, g.startupPackedConfig)
- type
- ModuleIter* = object
- fromRod: bool
- modIndex: int
- ti: TIdentIter
- rodIt: RodIter
- importHidden: bool
- proc initModuleIter*(mi: var ModuleIter; g: ModuleGraph; m: PSym; name: PIdent): PSym =
- assert m.kind == skModule
- mi.modIndex = m.position
- mi.fromRod = isCachedModule(g, mi.modIndex)
- mi.importHidden = optImportHidden in m.options
- if mi.fromRod:
- result = initRodIter(mi.rodIt, g.config, g.cache, g.packed, FileIndex mi.modIndex, name, mi.importHidden)
- else:
- result = initIdentIter(mi.ti, g.ifaces[mi.modIndex].interfSelect(mi.importHidden), name)
- proc nextModuleIter*(mi: var ModuleIter; g: ModuleGraph): PSym =
- if mi.fromRod:
- result = nextRodIter(mi.rodIt, g.packed)
- else:
- result = nextIdentIter(mi.ti, g.ifaces[mi.modIndex].interfSelect(mi.importHidden))
- iterator allSyms*(g: ModuleGraph; m: PSym): PSym =
- let importHidden = optImportHidden in m.options
- if isCachedModule(g, m):
- var rodIt: RodIter
- var r = initRodIterAllSyms(rodIt, g.config, g.cache, g.packed, FileIndex m.position, importHidden)
- while r != nil:
- yield r
- r = nextRodIter(rodIt, g.packed)
- else:
- for s in g.ifaces[m.position].interfSelect(importHidden).data:
- if s != nil:
- yield s
- proc someSym*(g: ModuleGraph; m: PSym; name: PIdent): PSym =
- let importHidden = optImportHidden in m.options
- if isCachedModule(g, m):
- result = interfaceSymbol(g.config, g.cache, g.packed, FileIndex(m.position), name, importHidden)
- else:
- result = strTableGet(g.ifaces[m.position].interfSelect(importHidden), name)
- proc systemModuleSym*(g: ModuleGraph; name: PIdent): PSym =
- result = someSym(g, g.systemModule, name)
- iterator systemModuleSyms*(g: ModuleGraph; name: PIdent): PSym =
- var mi: ModuleIter
- var r = initModuleIter(mi, g, g.systemModule, name)
- while r != nil:
- yield r
- r = nextModuleIter(mi, g)
- proc resolveType(g: ModuleGraph; t: var LazyType): PType =
- result = t.typ
- if result == nil and isCachedModule(g, t.id.module):
- result = loadTypeFromId(g.config, g.cache, g.packed, t.id.module, t.id.packed)
- t.typ = result
- assert result != nil
- proc resolveSym(g: ModuleGraph; t: var LazySym): PSym =
- result = t.sym
- if result == nil and isCachedModule(g, t.id.module):
- result = loadSymFromId(g.config, g.cache, g.packed, t.id.module, t.id.packed)
- t.sym = result
- assert result != nil
- proc resolveInst(g: ModuleGraph; t: var LazyInstantiation): PInstantiation =
- result = t.inst
- if result == nil and isCachedModule(g, t.module):
- result = PInstantiation(sym: loadSymFromId(g.config, g.cache, g.packed, t.sym.module, t.sym.packed))
- result.concreteTypes = newSeq[PType](t.concreteTypes.len)
- for i in 0..high(result.concreteTypes):
- result.concreteTypes[i] = loadTypeFromId(g.config, g.cache, g.packed,
- t.concreteTypes[i].module, t.concreteTypes[i].packed)
- t.inst = result
- assert result != nil
- proc resolveAttachedOp(g: ModuleGraph; t: var LazySym): PSym =
- result = t.sym
- if result == nil:
- result = loadSymFromId(g.config, g.cache, g.packed, t.id.module, t.id.packed)
- t.sym = result
- assert result != nil
- iterator typeInstCacheItems*(g: ModuleGraph; s: PSym): PType =
- if g.typeInstCache.contains(s.itemId):
- let x = addr(g.typeInstCache[s.itemId])
- for t in mitems(x[]):
- yield resolveType(g, t)
- iterator procInstCacheItems*(g: ModuleGraph; s: PSym): PInstantiation =
- if g.procInstCache.contains(s.itemId):
- let x = addr(g.procInstCache[s.itemId])
- for t in mitems(x[]):
- yield resolveInst(g, t)
- proc getAttachedOp*(g: ModuleGraph; t: PType; op: TTypeAttachedOp): PSym =
- ## returns the requested attached operation for type `t`. Can return nil
- ## if no such operation exists.
- if g.attachedOps[op].contains(t.itemId):
- result = resolveAttachedOp(g, g.attachedOps[op][t.itemId])
- else:
- result = nil
- proc setAttachedOp*(g: ModuleGraph; module: int; t: PType; op: TTypeAttachedOp; value: PSym) =
- ## we also need to record this to the packed module.
- g.attachedOps[op][t.itemId] = LazySym(sym: value)
- proc setAttachedOpPartial*(g: ModuleGraph; module: int; t: PType; op: TTypeAttachedOp; value: PSym) =
- ## we also need to record this to the packed module.
- g.attachedOps[op][t.itemId] = LazySym(sym: value)
- proc completePartialOp*(g: ModuleGraph; module: int; t: PType; op: TTypeAttachedOp; value: PSym) =
- if g.config.symbolFiles != disabledSf:
- assert module < g.encoders.len
- assert isActive(g.encoders[module])
- toPackedGeneratedProcDef(value, g.encoders[module], g.packed[module].fromDisk)
- #storeAttachedProcDef(t, op, value, g.encoders[module], g.packed[module].fromDisk)
- proc getToStringProc*(g: ModuleGraph; t: PType): PSym =
- result = resolveSym(g, g.enumToStringProcs[t.itemId])
- assert result != nil
- proc setToStringProc*(g: ModuleGraph; t: PType; value: PSym) =
- g.enumToStringProcs[t.itemId] = LazySym(sym: value)
- iterator methodsForGeneric*(g: ModuleGraph; t: PType): (int, PSym) =
- if g.methodsPerType.contains(t.itemId):
- for it in mitems g.methodsPerType[t.itemId]:
- yield (it[0], resolveSym(g, it[1]))
- proc addMethodToGeneric*(g: ModuleGraph; module: int; t: PType; col: int; m: PSym) =
- g.methodsPerType.mgetOrPut(t.itemId, @[]).add (col, LazySym(sym: m))
- proc hasDisabledAsgn*(g: ModuleGraph; t: PType): bool =
- let op = getAttachedOp(g, t, attachedAsgn)
- result = op != nil and sfError in op.flags
- proc copyTypeProps*(g: ModuleGraph; module: int; dest, src: PType) =
- for k in low(TTypeAttachedOp)..high(TTypeAttachedOp):
- let op = getAttachedOp(g, src, k)
- if op != nil:
- setAttachedOp(g, module, dest, k, op)
- proc loadCompilerProc*(g: ModuleGraph; name: string): PSym =
- if g.config.symbolFiles == disabledSf: return nil
- # slow, linear search, but the results are cached:
- for module in 0..high(g.packed):
- #if isCachedModule(g, module):
- let x = searchForCompilerproc(g.packed[module], name)
- if x >= 0:
- result = loadSymFromId(g.config, g.cache, g.packed, module, toPackedItemId(x))
- if result != nil:
- strTableAdd(g.compilerprocs, result)
- return result
- proc loadPackedSym*(g: ModuleGraph; s: var LazySym) =
- if s.sym == nil:
- s.sym = loadSymFromId(g.config, g.cache, g.packed, s.id.module, s.id.packed)
- proc `$`*(u: SigHash): string =
- toBase64a(cast[cstring](unsafeAddr u), sizeof(u))
- proc `==`*(a, b: SigHash): bool =
- result = equalMem(unsafeAddr a, unsafeAddr b, sizeof(a))
- proc hash*(u: SigHash): Hash =
- result = 0
- for x in 0..3:
- result = (result shl 8) or u.MD5Digest[x].int
- proc hash*(x: FileIndex): Hash {.borrow.}
- template getPContext(): untyped =
- when c is PContext: c
- else: c.c
- when defined(nimsuggest):
- template onUse*(info: TLineInfo; s: PSym) = discard
- template onDefResolveForward*(info: TLineInfo; s: PSym) = discard
- else:
- template onUse*(info: TLineInfo; s: PSym) = discard
- template onDef*(info: TLineInfo; s: PSym) = discard
- template onDefResolveForward*(info: TLineInfo; s: PSym) = discard
- proc stopCompile*(g: ModuleGraph): bool {.inline.} =
- result = g.doStopCompile != nil and g.doStopCompile()
- proc createMagic*(g: ModuleGraph; idgen: IdGenerator; name: string, m: TMagic): PSym =
- result = newSym(skProc, getIdent(g.cache, name), nextSymId(idgen), nil, unknownLineInfo, {})
- result.magic = m
- result.flags = {sfNeverRaises}
- proc createMagic(g: ModuleGraph; name: string, m: TMagic): PSym =
- result = createMagic(g, g.idgen, name, m)
- proc registerModule*(g: ModuleGraph; m: PSym) =
- assert m != nil
- assert m.kind == skModule
- if m.position >= g.ifaces.len:
- setLen(g.ifaces, m.position + 1)
- if m.position >= g.packed.len:
- setLen(g.packed, m.position + 1)
- g.ifaces[m.position] = Iface(module: m, converters: @[], patterns: @[],
- uniqueName: rope(uniqueModuleName(g.config, FileIndex(m.position))))
- initStrTables(g, m)
- proc registerModuleById*(g: ModuleGraph; m: FileIndex) =
- registerModule(g, g.packed[int m].module)
- proc initOperators*(g: ModuleGraph): Operators =
- # These are safe for IC.
- # Public because it's used by DrNim.
- result.opLe = createMagic(g, "<=", mLeI)
- result.opLt = createMagic(g, "<", mLtI)
- result.opAnd = createMagic(g, "and", mAnd)
- result.opOr = createMagic(g, "or", mOr)
- result.opIsNil = createMagic(g, "isnil", mIsNil)
- result.opEq = createMagic(g, "==", mEqI)
- result.opAdd = createMagic(g, "+", mAddI)
- result.opSub = createMagic(g, "-", mSubI)
- result.opMul = createMagic(g, "*", mMulI)
- result.opDiv = createMagic(g, "div", mDivI)
- result.opLen = createMagic(g, "len", mLengthSeq)
- result.opNot = createMagic(g, "not", mNot)
- result.opContains = createMagic(g, "contains", mInSet)
- proc initModuleGraphFields(result: ModuleGraph) =
- # A module ID of -1 means that the symbol is not attached to a module at all,
- # but to the module graph:
- result.idgen = IdGenerator(module: -1'i32, symId: 0'i32, typeId: 0'i32)
- initStrTable(result.packageSyms)
- result.deps = initIntSet()
- result.importDeps = initTable[FileIndex, seq[FileIndex]]()
- result.ifaces = @[]
- result.importStack = @[]
- result.inclToMod = initTable[FileIndex, FileIndex]()
- result.owners = @[]
- result.suggestSymbols = initTable[FileIndex, seq[SymInfoPair]]()
- result.suggestErrors = initTable[FileIndex, seq[Suggest]]()
- result.methods = @[]
- initStrTable(result.compilerprocs)
- initStrTable(result.exposed)
- initStrTable(result.packageTypes)
- result.emptyNode = newNode(nkEmpty)
- result.cacheSeqs = initTable[string, PNode]()
- result.cacheCounters = initTable[string, BiggestInt]()
- result.cacheTables = initTable[string, BTree[string, PNode]]()
- result.canonTypes = initTable[SigHash, PType]()
- result.symBodyHashes = initTable[int, SigHash]()
- result.operators = initOperators(result)
- result.emittedTypeInfo = initTable[string, FileIndex]()
- proc newModuleGraph*(cache: IdentCache; config: ConfigRef): ModuleGraph =
- result = ModuleGraph()
- result.config = config
- result.cache = cache
- initModuleGraphFields(result)
- proc resetAllModules*(g: ModuleGraph) =
- initStrTable(g.packageSyms)
- g.deps = initIntSet()
- g.ifaces = @[]
- g.importStack = @[]
- g.inclToMod = initTable[FileIndex, FileIndex]()
- g.usageSym = nil
- g.owners = @[]
- g.methods = @[]
- initStrTable(g.compilerprocs)
- initStrTable(g.exposed)
- initModuleGraphFields(g)
- proc getModule*(g: ModuleGraph; fileIdx: FileIndex): PSym =
- if fileIdx.int32 >= 0:
- if isCachedModule(g, fileIdx.int32):
- result = g.packed[fileIdx.int32].module
- elif fileIdx.int32 < g.ifaces.len:
- result = g.ifaces[fileIdx.int32].module
- proc moduleOpenForCodegen*(g: ModuleGraph; m: FileIndex): bool {.inline.} =
- if g.config.symbolFiles == disabledSf:
- result = true
- else:
- result = g.packed[m.int32].status notin {undefined, stored, loaded}
- proc rememberEmittedTypeInfo*(g: ModuleGraph; m: FileIndex; ti: string) =
- #assert(not isCachedModule(g, m.int32))
- if g.config.symbolFiles != disabledSf:
- #assert g.encoders[m.int32].isActive
- assert g.packed[m.int32].status != stored
- g.packed[m.int32].fromDisk.emittedTypeInfo.add ti
- #echo "added typeinfo ", m.int32, " ", ti, " suspicious ", not g.encoders[m.int32].isActive
- proc rememberFlag*(g: ModuleGraph; m: PSym; flag: ModuleBackendFlag) =
- if g.config.symbolFiles != disabledSf:
- #assert g.encoders[m.int32].isActive
- assert g.packed[m.position].status != stored
- g.packed[m.position].fromDisk.backendFlags.incl flag
- proc closeRodFile*(g: ModuleGraph; m: PSym) =
- if g.config.symbolFiles in {readOnlySf, v2Sf}:
- # For stress testing we seek to reload the symbols from memory. This
- # way much of the logic is tested but the test is reproducible as it does
- # not depend on the hard disk contents!
- let mint = m.position
- saveRodFile(toRodFile(g.config, AbsoluteFile toFullPath(g.config, FileIndex(mint))),
- g.encoders[mint], g.packed[mint].fromDisk)
- g.packed[mint].status = stored
- elif g.config.symbolFiles == stressTest:
- # debug code, but maybe a good idea for production? Could reduce the compiler's
- # memory consumption considerably at the cost of more loads from disk.
- let mint = m.position
- simulateCachedModule(g, m, g.packed[mint].fromDisk)
- g.packed[mint].status = loaded
- proc dependsOn(a, b: int): int {.inline.} = (a shl 15) + b
- proc addDep*(g: ModuleGraph; m: PSym, dep: FileIndex) =
- assert m.position == m.info.fileIndex.int32
- if g.suggestMode:
- g.deps.incl m.position.dependsOn(dep.int)
- # we compute the transitive closure later when querying the graph lazily.
- # this improves efficiency quite a lot:
- #invalidTransitiveClosure = true
- proc addIncludeDep*(g: ModuleGraph; module, includeFile: FileIndex) =
- discard hasKeyOrPut(g.inclToMod, includeFile, module)
- proc parentModule*(g: ModuleGraph; fileIdx: FileIndex): FileIndex =
- ## returns 'fileIdx' if the file belonging to this index is
- ## directly used as a module or else the module that first
- ## references this include file.
- if fileIdx.int32 >= 0 and fileIdx.int32 < g.ifaces.len and g.ifaces[fileIdx.int32].module != nil:
- result = fileIdx
- else:
- result = g.inclToMod.getOrDefault(fileIdx)
- proc transitiveClosure(g: var IntSet; n: int) =
- # warshall's algorithm
- for k in 0..<n:
- for i in 0..<n:
- for j in 0..<n:
- if i != j and not g.contains(i.dependsOn(j)):
- if g.contains(i.dependsOn(k)) and g.contains(k.dependsOn(j)):
- g.incl i.dependsOn(j)
- proc markDirty*(g: ModuleGraph; fileIdx: FileIndex) =
- let m = g.getModule fileIdx
- if m != nil:
- g.suggestSymbols.del(fileIdx)
- g.suggestErrors.del(fileIdx)
- incl m.flags, sfDirty
- proc unmarkAllDirty*(g: ModuleGraph) =
- for i in 0i32..<g.ifaces.len.int32:
- let m = g.ifaces[i].module
- if m != nil:
- m.flags.excl sfDirty
- proc isDirty*(g: ModuleGraph; m: PSym): bool =
- result = g.suggestMode and sfDirty in m.flags
- proc markClientsDirty*(g: ModuleGraph; fileIdx: FileIndex) =
- # we need to mark its dependent modules D as dirty right away because after
- # nimsuggest is done with this module, the module's dirty flag will be
- # cleared but D still needs to be remembered as 'dirty'.
- if g.invalidTransitiveClosure:
- g.invalidTransitiveClosure = false
- transitiveClosure(g.deps, g.ifaces.len)
- # every module that *depends* on this file is also dirty:
- for i in 0i32..<g.ifaces.len.int32:
- if g.deps.contains(i.dependsOn(fileIdx.int)):
- g.markDirty(FileIndex(i))
- proc needsCompilation*(g: ModuleGraph): bool =
- # every module that *depends* on this file is also dirty:
- for i in 0i32..<g.ifaces.len.int32:
- let m = g.ifaces[i].module
- if m != nil:
- if sfDirty in m.flags:
- return true
- proc needsCompilation*(g: ModuleGraph, fileIdx: FileIndex): bool =
- let module = g.getModule(fileIdx)
- if module != nil and g.isDirty(module):
- return true
- for i in 0i32..<g.ifaces.len.int32:
- let m = g.ifaces[i].module
- if m != nil and g.isDirty(m) and g.deps.contains(fileIdx.int32.dependsOn(i)):
- return true
- proc getBody*(g: ModuleGraph; s: PSym): PNode {.inline.} =
- result = s.ast[bodyPos]
- if result == nil and g.config.symbolFiles in {readOnlySf, v2Sf, stressTest}:
- result = loadProcBody(g.config, g.cache, g.packed, s)
- s.ast[bodyPos] = result
- assert result != nil
- proc moduleFromRodFile*(g: ModuleGraph; fileIdx: FileIndex;
- cachedModules: var seq[FileIndex]): PSym =
- ## Returns 'nil' if the module needs to be recompiled.
- if g.config.symbolFiles in {readOnlySf, v2Sf, stressTest}:
- result = moduleFromRodFile(g.packed, g.config, g.cache, fileIdx, cachedModules)
- proc configComplete*(g: ModuleGraph) =
- rememberStartupConfig(g.startupPackedConfig, g.config)
- from std/strutils import repeat, `%`
- proc onProcessing*(graph: ModuleGraph, fileIdx: FileIndex, moduleStatus: string, fromModule: PSym, ) =
- let conf = graph.config
- let isNimscript = conf.isDefined("nimscript")
- if (not isNimscript) or hintProcessing in conf.cmdlineNotes:
- let path = toFilenameOption(conf, fileIdx, conf.filenameOption)
- let indent = ">".repeat(graph.importStack.len)
- let fromModule2 = if fromModule != nil: $fromModule.name.s else: "(toplevel)"
- let mode = if isNimscript: "(nims) " else: ""
- rawMessage(conf, hintProcessing, "$#$# $#: $#: $#" % [mode, indent, fromModule2, moduleStatus, path])
- proc getPackage*(graph: ModuleGraph; fileIdx: FileIndex): PSym =
- ## Returns a package symbol for yet to be defined module for fileIdx.
- ## The package symbol is added to the graph if it doesn't exist.
- let pkgSym = getPackage(graph.config, graph.cache, fileIdx)
- # check if the package is already in the graph
- result = graph.packageSyms.strTableGet(pkgSym.name)
- if result == nil:
- # the package isn't in the graph, so create and add it
- result = pkgSym
- graph.packageSyms.strTableAdd(pkgSym)
- func belongsToStdlib*(graph: ModuleGraph, sym: PSym): bool =
- ## Check if symbol belongs to the 'stdlib' package.
- sym.getPackageSymbol.getPackageId == graph.systemModule.getPackageId
- proc `==`*(a, b: SymInfoPair): bool =
- result = a.sym == b.sym and a.info.exactEquals(b.info)
- proc fileSymbols*(graph: ModuleGraph, fileIdx: FileIndex): seq[SymInfoPair] =
- result = graph.suggestSymbols.getOrDefault(fileIdx, @[])
- iterator suggestSymbolsIter*(g: ModuleGraph): SymInfoPair =
- for xs in g.suggestSymbols.values:
- for x in xs:
- yield x
- iterator suggestErrorsIter*(g: ModuleGraph): Suggest =
- for xs in g.suggestErrors.values:
- for x in xs:
- yield x
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