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- #
- #
- # The Nim Compiler
- # (c) Copyright 2015 Andreas Rumpf
- #
- # See the file "copying.txt", included in this
- # distribution, for details about the copyright.
- #
- import ast, types, msgs, os, options, idents, lineinfos
- from pathutils import AbsoluteFile
- when defined(nimPreviewSlimSystem):
- import std/syncio
- proc opSlurp*(file: string, info: TLineInfo, module: PSym; conf: ConfigRef): string =
- try:
- var filename = parentDir(toFullPath(conf, info)) / file
- if not fileExists(filename):
- filename = findFile(conf, file).string
- result = readFile(filename)
- # we produce a fake include statement for every slurped filename, so that
- # the module dependencies are accurate:
- discard conf.fileInfoIdx(AbsoluteFile filename)
- appendToModule(module, newTreeI(nkIncludeStmt, info, newStrNode(nkStrLit, filename)))
- except IOError:
- localError(conf, info, "cannot open file: " & file)
- result = ""
- proc atomicTypeX(cache: IdentCache; name: string; m: TMagic; t: PType; info: TLineInfo;
- idgen: IdGenerator): PNode =
- let sym = newSym(skType, getIdent(cache, name), idgen, t.owner, info)
- sym.magic = m
- sym.typ = t
- result = newSymNode(sym)
- result.typ = t
- proc atomicTypeX(s: PSym; info: TLineInfo): PNode =
- result = newSymNode(s)
- result.info = info
- proc mapTypeToAstX(cache: IdentCache; t: PType; info: TLineInfo; idgen: IdGenerator;
- inst=false; allowRecursionX=false): PNode
- proc mapTypeToBracketX(cache: IdentCache; name: string; m: TMagic; t: PType; info: TLineInfo;
- idgen: IdGenerator;
- inst=false): PNode =
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicTypeX(cache, name, m, t, info, idgen)
- for i in 0..<t.len:
- if t[i] == nil:
- let void = atomicTypeX(cache, "void", mVoid, t, info, idgen)
- void.typ = newType(tyVoid, nextTypeId(idgen), t.owner)
- result.add void
- else:
- result.add mapTypeToAstX(cache, t[i], info, idgen, inst)
- proc objectNode(cache: IdentCache; n: PNode; idgen: IdGenerator): PNode =
- if n.kind == nkSym:
- result = newNodeI(nkIdentDefs, n.info)
- result.add n # name
- result.add mapTypeToAstX(cache, n.sym.typ, n.info, idgen, true, false) # type
- result.add newNodeI(nkEmpty, n.info) # no assigned value
- else:
- result = copyNode(n)
- for i in 0..<n.safeLen:
- result.add objectNode(cache, n[i], idgen)
- proc mapTypeToAstX(cache: IdentCache; t: PType; info: TLineInfo;
- idgen: IdGenerator;
- inst=false; allowRecursionX=false): PNode =
- var allowRecursion = allowRecursionX
- template atomicType(name, m): untyped = atomicTypeX(cache, name, m, t, info, idgen)
- template atomicType(s): untyped = atomicTypeX(s, info)
- template mapTypeToAst(t,info): untyped = mapTypeToAstX(cache, t, info, idgen, inst)
- template mapTypeToAstR(t,info): untyped = mapTypeToAstX(cache, t, info, idgen, inst, true)
- template mapTypeToAst(t,i,info): untyped =
- if i<t.len and t[i]!=nil: mapTypeToAstX(cache, t[i], info, idgen, inst)
- else: newNodeI(nkEmpty, info)
- template mapTypeToBracket(name, m, t, info): untyped =
- mapTypeToBracketX(cache, name, m, t, info, idgen, inst)
- template newNodeX(kind): untyped =
- newNodeIT(kind, if t.n.isNil: info else: t.n.info, t)
- template newIdentDefs(n,t): untyped =
- var id = newNodeX(nkIdentDefs)
- id.add n # name
- id.add mapTypeToAst(t, info) # type
- id.add newNodeI(nkEmpty, info) # no assigned value
- id
- template newIdentDefs(s): untyped = newIdentDefs(s, s.typ)
- if inst and not allowRecursion and t.sym != nil:
- # getTypeInst behavior: return symbol
- return atomicType(t.sym)
- case t.kind
- of tyNone: result = atomicType("none", mNone)
- of tyBool: result = atomicType("bool", mBool)
- of tyChar: result = atomicType("char", mChar)
- of tyNil: result = atomicType("nil", mNil)
- of tyUntyped: result = atomicType("untyped", mExpr)
- of tyTyped: result = atomicType("typed", mStmt)
- of tyVoid: result = atomicType("void", mVoid)
- of tyEmpty: result = atomicType("empty", mNone)
- of tyUncheckedArray:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicType("UncheckedArray", mUncheckedArray)
- result.add mapTypeToAst(t[0], info)
- of tyArray:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicType("array", mArray)
- if inst and t[0].kind == tyRange:
- var rng = newNodeX(nkInfix)
- rng.add newIdentNode(getIdent(cache, ".."), info)
- rng.add t[0].n[0].copyTree
- rng.add t[0].n[1].copyTree
- result.add rng
- else:
- result.add mapTypeToAst(t[0], info)
- result.add mapTypeToAst(t[1], info)
- of tyTypeDesc:
- if t.base != nil:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicType("typeDesc", mTypeDesc)
- result.add mapTypeToAst(t.base, info)
- else:
- result = atomicType("typeDesc", mTypeDesc)
- of tyGenericInvocation:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- for i in 0..<t.len:
- result.add mapTypeToAst(t[i], info)
- of tyGenericInst:
- if inst:
- if allowRecursion:
- result = mapTypeToAstR(t.lastSon, info)
- # keep original type info for getType calls on the output node:
- result.typ = t
- else:
- result = newNodeX(nkBracketExpr)
- #result.add mapTypeToAst(t.lastSon, info)
- result.add mapTypeToAst(t[0], info)
- for i in 1..<t.len-1:
- result.add mapTypeToAst(t[i], info)
- else:
- result = mapTypeToAstX(cache, t.lastSon, info, idgen, inst, allowRecursion)
- # keep original type info for getType calls on the output node:
- result.typ = t
- of tyGenericBody:
- if inst:
- result = mapTypeToAstR(t.lastSon, info)
- else:
- result = mapTypeToAst(t.lastSon, info)
- of tyAlias:
- result = mapTypeToAstX(cache, t.lastSon, info, idgen, inst, allowRecursion)
- of tyOrdinal:
- result = mapTypeToAst(t.lastSon, info)
- of tyDistinct:
- if inst:
- result = newNodeX(nkDistinctTy)
- result.add mapTypeToAst(t[0], info)
- else:
- if allowRecursion or t.sym == nil:
- result = mapTypeToBracket("distinct", mDistinct, t, info)
- else:
- result = atomicType(t.sym)
- of tyGenericParam, tyForward:
- result = atomicType(t.sym)
- of tyObject:
- if inst:
- result = newNodeX(nkObjectTy)
- var objectDef = t.sym.ast[2]
- if objectDef.kind == nkRefTy:
- objectDef = objectDef[0]
- result.add objectDef[0].copyTree # copy object pragmas
- if t[0] == nil:
- result.add newNodeI(nkEmpty, info)
- else: # handle parent object
- var nn = newNodeX(nkOfInherit)
- nn.add mapTypeToAst(t[0], info)
- result.add nn
- if t.n.len > 0:
- result.add objectNode(cache, t.n, idgen)
- else:
- result.add newNodeI(nkEmpty, info)
- else:
- if allowRecursion or t.sym == nil:
- result = newNodeIT(nkObjectTy, if t.n.isNil: info else: t.n.info, t)
- result.add newNodeI(nkEmpty, info)
- if t[0] == nil:
- result.add newNodeI(nkEmpty, info)
- else:
- result.add mapTypeToAst(t[0], info)
- result.add copyTree(t.n)
- else:
- result = atomicType(t.sym)
- of tyEnum:
- result = newNodeIT(nkEnumTy, if t.n.isNil: info else: t.n.info, t)
- result.add newNodeI(nkEmpty, info) # pragma node, currently always empty for enum
- for c in t.n.sons:
- result.add copyTree(c)
- of tyTuple:
- if inst:
- # only named tuples have a node, unnamed tuples don't
- if t.n.isNil:
- result = newNodeX(nkTupleConstr)
- for subType in t:
- result.add mapTypeToAst(subType, info)
- else:
- result = newNodeX(nkTupleTy)
- for s in t.n.sons:
- result.add newIdentDefs(s)
- else:
- result = mapTypeToBracket("tuple", mTuple, t, info)
- of tySet: result = mapTypeToBracket("set", mSet, t, info)
- of tyPtr:
- if inst:
- result = newNodeX(nkPtrTy)
- result.add mapTypeToAst(t[0], info)
- else:
- result = mapTypeToBracket("ptr", mPtr, t, info)
- of tyRef:
- if inst:
- result = newNodeX(nkRefTy)
- result.add mapTypeToAst(t[0], info)
- else:
- result = mapTypeToBracket("ref", mRef, t, info)
- of tyVar:
- if inst:
- result = newNodeX(nkVarTy)
- result.add mapTypeToAst(t[0], info)
- else:
- result = mapTypeToBracket("var", mVar, t, info)
- of tyLent: result = mapTypeToBracket("lent", mBuiltinType, t, info)
- of tySink: result = mapTypeToBracket("sink", mBuiltinType, t, info)
- of tySequence: result = mapTypeToBracket("seq", mSeq, t, info)
- of tyProc:
- if inst:
- result = newNodeX(nkProcTy)
- var fp = newNodeX(nkFormalParams)
- if t[0] == nil:
- fp.add newNodeI(nkEmpty, info)
- else:
- fp.add mapTypeToAst(t[0], t.n[0].info)
- for i in 1..<t.len:
- fp.add newIdentDefs(t.n[i], t[i])
- result.add fp
- result.add if t.n[0].len > 0: t.n[0][pragmasEffects].copyTree
- else: newNodeI(nkEmpty, info)
- else:
- result = mapTypeToBracket("proc", mNone, t, info)
- of tyOpenArray: result = mapTypeToBracket("openArray", mOpenArray, t, info)
- of tyRange:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicType("range", mRange)
- if inst and t.n.len == 2:
- let rng = newNodeX(nkInfix)
- rng.add newIdentNode(getIdent(cache, ".."), info)
- rng.add t.n[0].copyTree
- rng.add t.n[1].copyTree
- result.add rng
- else:
- result.add t.n[0].copyTree
- if t.n.len > 1:
- result.add t.n[1].copyTree
- of tyPointer: result = atomicType("pointer", mPointer)
- of tyString: result = atomicType("string", mString)
- of tyCstring: result = atomicType("cstring", mCstring)
- of tyInt: result = atomicType("int", mInt)
- of tyInt8: result = atomicType("int8", mInt8)
- of tyInt16: result = atomicType("int16", mInt16)
- of tyInt32: result = atomicType("int32", mInt32)
- of tyInt64: result = atomicType("int64", mInt64)
- of tyFloat: result = atomicType("float", mFloat)
- of tyFloat32: result = atomicType("float32", mFloat32)
- of tyFloat64: result = atomicType("float64", mFloat64)
- of tyFloat128: result = atomicType("float128", mFloat128)
- of tyUInt: result = atomicType("uint", mUInt)
- of tyUInt8: result = atomicType("uint8", mUInt8)
- of tyUInt16: result = atomicType("uint16", mUInt16)
- of tyUInt32: result = atomicType("uint32", mUInt32)
- of tyUInt64: result = atomicType("uint64", mUInt64)
- of tyVarargs: result = mapTypeToBracket("varargs", mVarargs, t, info)
- of tyProxy: result = atomicType("error", mNone)
- of tyBuiltInTypeClass:
- result = mapTypeToBracket("builtinTypeClass", mNone, t, info)
- of tyUserTypeClass, tyUserTypeClassInst:
- if t.isResolvedUserTypeClass:
- result = mapTypeToAst(t.lastSon, info)
- else:
- result = mapTypeToBracket("concept", mNone, t, info)
- result.add t.n.copyTree
- of tyCompositeTypeClass:
- result = mapTypeToBracket("compositeTypeClass", mNone, t, info)
- of tyAnd: result = mapTypeToBracket("and", mAnd, t, info)
- of tyOr: result = mapTypeToBracket("or", mOr, t, info)
- of tyNot: result = mapTypeToBracket("not", mNot, t, info)
- of tyIterable: result = mapTypeToBracket("iterable", mIterableType, t, info)
- of tyAnything: result = atomicType("anything", mNone)
- of tyInferred: result = mapTypeToAstX(cache, t.lastSon, info, idgen, inst, allowRecursion)
- of tyStatic, tyFromExpr:
- if inst:
- if t.n != nil: result = t.n.copyTree
- else: result = atomicType("void", mVoid)
- else:
- result = newNodeIT(nkBracketExpr, if t.n.isNil: info else: t.n.info, t)
- result.add atomicType("static", mNone)
- if t.n != nil:
- result.add t.n.copyTree
- of tyOwned: result = mapTypeToBracket("owned", mBuiltinType, t, info)
- of tyConcept:
- result = mapTypeToBracket("concept", mNone, t, info)
- result.add t.n.copyTree
- proc opMapTypeToAst*(cache: IdentCache; t: PType; info: TLineInfo; idgen: IdGenerator): PNode =
- result = mapTypeToAstX(cache, t, info, idgen, inst=false, allowRecursionX=true)
- # the "Inst" version includes generic parameters in the resulting type tree
- # and also tries to look like the corresponding Nim type declaration
- proc opMapTypeInstToAst*(cache: IdentCache; t: PType; info: TLineInfo; idgen: IdGenerator): PNode =
- result = mapTypeToAstX(cache, t, info, idgen, inst=true, allowRecursionX=false)
- # the "Impl" version includes generic parameters in the resulting type tree
- # and also tries to look like the corresponding Nim type implementation
- proc opMapTypeImplToAst*(cache: IdentCache; t: PType; info: TLineInfo; idgen: IdGenerator): PNode =
- result = mapTypeToAstX(cache, t, info, idgen, inst=true, allowRecursionX=true)
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