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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.
- #
- # this module folds constants; used by semantic checking phase
- # and evaluation phase
- import
- strutils, options, ast, trees, nimsets,
- platform, math, msgs, idents, renderer, types,
- commands, magicsys, modulegraphs, strtabs, lineinfos, wordrecg
- from system/memory import nimCStrLen
- when defined(nimPreviewSlimSystem):
- import std/[assertions, formatfloat]
- proc errorType*(g: ModuleGraph): PType =
- ## creates a type representing an error state
- result = newType(tyError, nextTypeId(g.idgen), g.owners[^1])
- result.flags.incl tfCheckedForDestructor
- proc getIntLitTypeG(g: ModuleGraph; literal: PNode; idgen: IdGenerator): PType =
- # we cache some common integer literal types for performance:
- let ti = getSysType(g, literal.info, tyInt)
- result = copyType(ti, nextTypeId(idgen), ti.owner)
- result.n = literal
- proc newIntNodeT*(intVal: Int128, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- result = newIntTypeNode(intVal, n.typ)
- # See bug #6989. 'pred' et al only produce an int literal type if the
- # original type was 'int', not a distinct int etc.
- if n.typ.kind == tyInt:
- # access cache for the int lit type
- result.typ = getIntLitTypeG(g, result, idgen)
- result.info = n.info
- proc newFloatNodeT*(floatVal: BiggestFloat, n: PNode; g: ModuleGraph): PNode =
- if n.typ.skipTypes(abstractInst).kind == tyFloat32:
- result = newFloatNode(nkFloat32Lit, floatVal)
- else:
- result = newFloatNode(nkFloatLit, floatVal)
- result.typ = n.typ
- result.info = n.info
- proc newStrNodeT*(strVal: string, n: PNode; g: ModuleGraph): PNode =
- result = newStrNode(nkStrLit, strVal)
- result.typ = n.typ
- result.info = n.info
- proc getConstExpr*(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode
- # evaluates the constant expression or returns nil if it is no constant
- # expression
- proc evalOp*(m: TMagic, n, a, b, c: PNode; idgen: IdGenerator; g: ModuleGraph): PNode
- proc checkInRange(conf: ConfigRef; n: PNode, res: Int128): bool =
- res in firstOrd(conf, n.typ)..lastOrd(conf, n.typ)
- proc foldAdd(a, b: Int128, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- let res = a + b
- if checkInRange(g.config, n, res):
- result = newIntNodeT(res, n, idgen, g)
- else:
- result = nil
- proc foldSub(a, b: Int128, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- let res = a - b
- if checkInRange(g.config, n, res):
- result = newIntNodeT(res, n, idgen, g)
- else:
- result = nil
- proc foldUnarySub(a: Int128, n: PNode; idgen: IdGenerator, g: ModuleGraph): PNode =
- if a != firstOrd(g.config, n.typ):
- result = newIntNodeT(-a, n, idgen, g)
- else:
- result = nil
- proc foldAbs(a: Int128, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- if a != firstOrd(g.config, n.typ):
- result = newIntNodeT(abs(a), n, idgen, g)
- else:
- result = nil
- proc foldMul(a, b: Int128, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- let res = a * b
- if checkInRange(g.config, n, res):
- return newIntNodeT(res, n, idgen, g)
- else:
- result = nil
- proc ordinalValToString*(a: PNode; g: ModuleGraph): string =
- # because $ has the param ordinal[T], `a` is not necessarily an enum, but an
- # ordinal
- var x = getInt(a)
- var t = skipTypes(a.typ, abstractRange)
- case t.kind
- of tyChar:
- result = $chr(toInt64(x) and 0xff)
- of tyEnum:
- result = ""
- var n = t.n
- for i in 0..<n.len:
- if n[i].kind != nkSym: internalError(g.config, a.info, "ordinalValToString")
- var field = n[i].sym
- if field.position == x:
- if field.ast == nil:
- return field.name.s
- else:
- return field.ast.strVal
- localError(g.config, a.info,
- "Cannot convert int literal to $1. The value is invalid." %
- [typeToString(t)])
- else:
- result = $x
- proc isFloatRange(t: PType): bool {.inline.} =
- result = t.kind == tyRange and t[0].kind in {tyFloat..tyFloat128}
- proc isIntRange(t: PType): bool {.inline.} =
- result = t.kind == tyRange and t[0].kind in {
- tyInt..tyInt64, tyUInt8..tyUInt32}
- proc pickIntRange(a, b: PType): PType =
- if isIntRange(a): result = a
- elif isIntRange(b): result = b
- else: result = a
- proc isIntRangeOrLit(t: PType): bool =
- result = isIntRange(t) or isIntLit(t)
- proc evalOp(m: TMagic, n, a, b, c: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- # b and c may be nil
- result = nil
- case m
- of mOrd: result = newIntNodeT(getOrdValue(a), n, idgen, g)
- of mChr: result = newIntNodeT(getInt(a), n, idgen, g)
- of mUnaryMinusI, mUnaryMinusI64: result = foldUnarySub(getInt(a), n, idgen, g)
- of mUnaryMinusF64: result = newFloatNodeT(-getFloat(a), n, g)
- of mNot: result = newIntNodeT(One - getInt(a), n, idgen, g)
- of mCard: result = newIntNodeT(toInt128(nimsets.cardSet(g.config, a)), n, idgen, g)
- of mBitnotI:
- if n.typ.isUnsigned:
- result = newIntNodeT(bitnot(getInt(a)).maskBytes(int(getSize(g.config, n.typ))), n, idgen, g)
- else:
- result = newIntNodeT(bitnot(getInt(a)), n, idgen, g)
- of mLengthArray: result = newIntNodeT(lengthOrd(g.config, a.typ), n, idgen, g)
- of mLengthSeq, mLengthOpenArray, mLengthStr:
- if a.kind == nkNilLit:
- result = newIntNodeT(Zero, n, idgen, g)
- elif a.kind in {nkStrLit..nkTripleStrLit}:
- if a.typ.kind == tyString:
- result = newIntNodeT(toInt128(a.strVal.len), n, idgen, g)
- elif a.typ.kind == tyCstring:
- result = newIntNodeT(toInt128(nimCStrLen(a.strVal.cstring)), n, idgen, g)
- else:
- result = newIntNodeT(toInt128(a.len), n, idgen, g)
- of mUnaryPlusI, mUnaryPlusF64: result = a # throw `+` away
- # XXX: Hides overflow/underflow
- of mAbsI: result = foldAbs(getInt(a), n, idgen, g)
- of mSucc: result = foldAdd(getOrdValue(a), getInt(b), n, idgen, g)
- of mPred: result = foldSub(getOrdValue(a), getInt(b), n, idgen, g)
- of mAddI: result = foldAdd(getInt(a), getInt(b), n, idgen, g)
- of mSubI: result = foldSub(getInt(a), getInt(b), n, idgen, g)
- of mMulI: result = foldMul(getInt(a), getInt(b), n, idgen, g)
- of mMinI:
- let argA = getInt(a)
- let argB = getInt(b)
- result = newIntNodeT(if argA < argB: argA else: argB, n, idgen, g)
- of mMaxI:
- let argA = getInt(a)
- let argB = getInt(b)
- result = newIntNodeT(if argA > argB: argA else: argB, n, idgen, g)
- of mShlI:
- case skipTypes(n.typ, abstractRange).kind
- of tyInt8: result = newIntNodeT(toInt128(toInt8(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyInt16: result = newIntNodeT(toInt128(toInt16(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyInt32: result = newIntNodeT(toInt128(toInt32(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyInt64: result = newIntNodeT(toInt128(toInt64(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyInt:
- if g.config.target.intSize == 4:
- result = newIntNodeT(toInt128(toInt32(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- else:
- result = newIntNodeT(toInt128(toInt64(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyUInt8: result = newIntNodeT(toInt128(toUInt8(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyUInt16: result = newIntNodeT(toInt128(toUInt16(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyUInt32: result = newIntNodeT(toInt128(toUInt32(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyUInt64: result = newIntNodeT(toInt128(toUInt64(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- of tyUInt:
- if g.config.target.intSize == 4:
- result = newIntNodeT(toInt128(toUInt32(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- else:
- result = newIntNodeT(toInt128(toUInt64(getInt(a)) shl toInt64(getInt(b))), n, idgen, g)
- else: internalError(g.config, n.info, "constant folding for shl")
- of mShrI:
- var a = cast[uint64](getInt(a))
- let b = cast[uint64](getInt(b))
- # To support the ``-d:nimOldShiftRight`` flag, we need to mask the
- # signed integers to cut off the extended sign bit in the internal
- # representation.
- if 0'u64 < b: # do not cut off the sign extension, when there is
- # no bit shifting happening.
- case skipTypes(n.typ, abstractRange).kind
- of tyInt8: a = a and 0xff'u64
- of tyInt16: a = a and 0xffff'u64
- of tyInt32: a = a and 0xffffffff'u64
- of tyInt:
- if g.config.target.intSize == 4:
- a = a and 0xffffffff'u64
- else:
- # unsigned and 64 bit integers don't need masking
- discard
- let c = cast[BiggestInt](a shr b)
- result = newIntNodeT(toInt128(c), n, idgen, g)
- of mAshrI:
- case skipTypes(n.typ, abstractRange).kind
- of tyInt8: result = newIntNodeT(toInt128(ashr(toInt8(getInt(a)), toInt8(getInt(b)))), n, idgen, g)
- of tyInt16: result = newIntNodeT(toInt128(ashr(toInt16(getInt(a)), toInt16(getInt(b)))), n, idgen, g)
- of tyInt32: result = newIntNodeT(toInt128(ashr(toInt32(getInt(a)), toInt32(getInt(b)))), n, idgen, g)
- of tyInt64, tyInt:
- result = newIntNodeT(toInt128(ashr(toInt64(getInt(a)), toInt64(getInt(b)))), n, idgen, g)
- else: internalError(g.config, n.info, "constant folding for ashr")
- of mDivI:
- let argA = getInt(a)
- let argB = getInt(b)
- if argB != Zero and (argA != firstOrd(g.config, n.typ) or argB != NegOne):
- result = newIntNodeT(argA div argB, n, idgen, g)
- of mModI:
- let argA = getInt(a)
- let argB = getInt(b)
- if argB != Zero and (argA != firstOrd(g.config, n.typ) or argB != NegOne):
- result = newIntNodeT(argA mod argB, n, idgen, g)
- of mAddF64: result = newFloatNodeT(getFloat(a) + getFloat(b), n, g)
- of mSubF64: result = newFloatNodeT(getFloat(a) - getFloat(b), n, g)
- of mMulF64: result = newFloatNodeT(getFloat(a) * getFloat(b), n, g)
- of mDivF64:
- result = newFloatNodeT(getFloat(a) / getFloat(b), n, g)
- of mIsNil:
- let val = a.kind == nkNilLit or
- # nil closures have the value (nil, nil)
- (a.typ != nil and skipTypes(a.typ, abstractRange).kind == tyProc and
- a.kind == nkTupleConstr and a.len == 2 and
- a[0].kind == nkNilLit and a[1].kind == nkNilLit)
- result = newIntNodeT(toInt128(ord(val)), n, idgen, g)
- of mLtI, mLtB, mLtEnum, mLtCh:
- result = newIntNodeT(toInt128(ord(getOrdValue(a) < getOrdValue(b))), n, idgen, g)
- of mLeI, mLeB, mLeEnum, mLeCh:
- result = newIntNodeT(toInt128(ord(getOrdValue(a) <= getOrdValue(b))), n, idgen, g)
- of mEqI, mEqB, mEqEnum, mEqCh:
- result = newIntNodeT(toInt128(ord(getOrdValue(a) == getOrdValue(b))), n, idgen, g)
- of mLtF64: result = newIntNodeT(toInt128(ord(getFloat(a) < getFloat(b))), n, idgen, g)
- of mLeF64: result = newIntNodeT(toInt128(ord(getFloat(a) <= getFloat(b))), n, idgen, g)
- of mEqF64: result = newIntNodeT(toInt128(ord(getFloat(a) == getFloat(b))), n, idgen, g)
- of mLtStr: result = newIntNodeT(toInt128(ord(getStr(a) < getStr(b))), n, idgen, g)
- of mLeStr: result = newIntNodeT(toInt128(ord(getStr(a) <= getStr(b))), n, idgen, g)
- of mEqStr: result = newIntNodeT(toInt128(ord(getStr(a) == getStr(b))), n, idgen, g)
- of mLtU:
- result = newIntNodeT(toInt128(ord(`<%`(toInt64(getOrdValue(a)), toInt64(getOrdValue(b))))), n, idgen, g)
- of mLeU:
- result = newIntNodeT(toInt128(ord(`<=%`(toInt64(getOrdValue(a)), toInt64(getOrdValue(b))))), n, idgen, g)
- of mBitandI, mAnd: result = newIntNodeT(bitand(a.getInt, b.getInt), n, idgen, g)
- of mBitorI, mOr: result = newIntNodeT(bitor(getInt(a), getInt(b)), n, idgen, g)
- of mBitxorI, mXor: result = newIntNodeT(bitxor(getInt(a), getInt(b)), n, idgen, g)
- of mAddU:
- let val = maskBytes(getInt(a) + getInt(b), int(getSize(g.config, n.typ)))
- result = newIntNodeT(val, n, idgen, g)
- of mSubU:
- let val = maskBytes(getInt(a) - getInt(b), int(getSize(g.config, n.typ)))
- result = newIntNodeT(val, n, idgen, g)
- # echo "subU: ", val, " n: ", n, " result: ", val
- of mMulU:
- let val = maskBytes(getInt(a) * getInt(b), int(getSize(g.config, n.typ)))
- result = newIntNodeT(val, n, idgen, g)
- of mModU:
- let argA = maskBytes(getInt(a), int(getSize(g.config, a.typ)))
- let argB = maskBytes(getInt(b), int(getSize(g.config, a.typ)))
- if argB != Zero:
- result = newIntNodeT(argA mod argB, n, idgen, g)
- of mDivU:
- let argA = maskBytes(getInt(a), int(getSize(g.config, a.typ)))
- let argB = maskBytes(getInt(b), int(getSize(g.config, a.typ)))
- if argB != Zero:
- result = newIntNodeT(argA div argB, n, idgen, g)
- of mLeSet: result = newIntNodeT(toInt128(ord(containsSets(g.config, a, b))), n, idgen, g)
- of mEqSet: result = newIntNodeT(toInt128(ord(equalSets(g.config, a, b))), n, idgen, g)
- of mLtSet:
- result = newIntNodeT(toInt128(ord(
- containsSets(g.config, a, b) and not equalSets(g.config, a, b))), n, idgen, g)
- of mMulSet:
- result = nimsets.intersectSets(g.config, a, b)
- result.info = n.info
- of mPlusSet:
- result = nimsets.unionSets(g.config, a, b)
- result.info = n.info
- of mMinusSet:
- result = nimsets.diffSets(g.config, a, b)
- result.info = n.info
- of mConStrStr: result = newStrNodeT(getStrOrChar(a) & getStrOrChar(b), n, g)
- of mInSet: result = newIntNodeT(toInt128(ord(inSet(a, b))), n, idgen, g)
- of mRepr:
- # BUGFIX: we cannot eval mRepr here for reasons that I forgot.
- discard
- of mIntToStr, mInt64ToStr: result = newStrNodeT($(getOrdValue(a)), n, g)
- of mBoolToStr:
- if getOrdValue(a) == 0: result = newStrNodeT("false", n, g)
- else: result = newStrNodeT("true", n, g)
- of mFloatToStr: result = newStrNodeT($getFloat(a), n, g)
- of mCStrToStr, mCharToStr:
- result = newStrNodeT(getStrOrChar(a), n, g)
- of mStrToStr: result = newStrNodeT(getStrOrChar(a), n, g)
- of mEnumToStr: result = newStrNodeT(ordinalValToString(a, g), n, g)
- of mArrToSeq:
- result = copyTree(a)
- result.typ = n.typ
- of mCompileOption:
- result = newIntNodeT(toInt128(ord(commands.testCompileOption(g.config, a.getStr, n.info))), n, idgen, g)
- of mCompileOptionArg:
- result = newIntNodeT(toInt128(ord(
- testCompileOptionArg(g.config, getStr(a), getStr(b), n.info))), n, idgen, g)
- of mEqProc:
- result = newIntNodeT(toInt128(ord(
- exprStructuralEquivalent(a, b, strictSymEquality=true))), n, idgen, g)
- else: discard
- proc getConstIfExpr(c: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- result = nil
- for i in 0..<n.len:
- var it = n[i]
- if it.len == 2:
- var e = getConstExpr(c, it[0], idgen, g)
- if e == nil: return nil
- if getOrdValue(e) != 0:
- if result == nil:
- result = getConstExpr(c, it[1], idgen, g)
- if result == nil: return
- elif it.len == 1:
- if result == nil: result = getConstExpr(c, it[0], idgen, g)
- else: internalError(g.config, it.info, "getConstIfExpr()")
- proc leValueConv*(a, b: PNode): bool =
- result = false
- case a.kind
- of nkCharLit..nkUInt64Lit:
- case b.kind
- of nkCharLit..nkUInt64Lit: result = a.getInt <= b.getInt
- of nkFloatLit..nkFloat128Lit: result = a.intVal <= round(b.floatVal).int
- else: result = false #internalError(a.info, "leValueConv")
- of nkFloatLit..nkFloat128Lit:
- case b.kind
- of nkFloatLit..nkFloat128Lit: result = a.floatVal <= b.floatVal
- of nkCharLit..nkUInt64Lit: result = a.floatVal <= toFloat64(b.getInt)
- else: result = false # internalError(a.info, "leValueConv")
- else: result = false # internalError(a.info, "leValueConv")
- proc magicCall(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- if n.len <= 1: return
- var s = n[0].sym
- var a = getConstExpr(m, n[1], idgen, g)
- var b, c: PNode = nil
- if a == nil: return
- if n.len > 2:
- b = getConstExpr(m, n[2], idgen, g)
- if b == nil: return
- if n.len > 3:
- c = getConstExpr(m, n[3], idgen, g)
- if c == nil: return
- result = evalOp(s.magic, n, a, b, c, idgen, g)
- proc getAppType(n: PNode; g: ModuleGraph): PNode =
- if g.config.globalOptions.contains(optGenDynLib):
- result = newStrNodeT("lib", n, g)
- elif g.config.globalOptions.contains(optGenStaticLib):
- result = newStrNodeT("staticlib", n, g)
- elif g.config.globalOptions.contains(optGenGuiApp):
- result = newStrNodeT("gui", n, g)
- else:
- result = newStrNodeT("console", n, g)
- proc rangeCheck(n: PNode, value: Int128; g: ModuleGraph) =
- if value < firstOrd(g.config, n.typ) or value > lastOrd(g.config, n.typ):
- localError(g.config, n.info, "cannot convert " & $value &
- " to " & typeToString(n.typ))
- proc floatRangeCheck(n: PNode, value: BiggestFloat; g: ModuleGraph) =
- if value < firstFloat(n.typ) or value > lastFloat(n.typ):
- localError(g.config, n.info, "cannot convert " & $value &
- " to " & typeToString(n.typ))
- proc foldConv(n, a: PNode; idgen: IdGenerator; g: ModuleGraph; check = false): PNode =
- let dstTyp = skipTypes(n.typ, abstractRange - {tyTypeDesc})
- let srcTyp = skipTypes(a.typ, abstractRange - {tyTypeDesc})
- # if srcTyp.kind == tyUInt64 and "FFFFFF" in $n:
- # echo "n: ", n, " a: ", a
- # echo "from: ", srcTyp, " to: ", dstTyp, " check: ", check
- # echo getInt(a)
- # echo high(int64)
- # writeStackTrace()
- case dstTyp.kind
- of tyBool:
- case srcTyp.kind
- of tyFloat..tyFloat64:
- result = newIntNodeT(toInt128(getFloat(a) != 0.0), n, idgen, g)
- of tyChar, tyUInt..tyUInt64, tyInt..tyInt64:
- result = newIntNodeT(toInt128(a.getOrdValue != 0), n, idgen, g)
- of tyBool, tyEnum: # xxx shouldn't we disallow `tyEnum`?
- result = a
- result.typ = n.typ
- else:
- raiseAssert $srcTyp.kind
- of tyInt..tyInt64, tyUInt..tyUInt64:
- case srcTyp.kind
- of tyFloat..tyFloat64:
- result = newIntNodeT(toInt128(getFloat(a)), n, idgen, g)
- of tyChar, tyUInt..tyUInt64, tyInt..tyInt64:
- var val = a.getOrdValue
- if check: rangeCheck(n, val, g)
- result = newIntNodeT(val, n, idgen, g)
- if dstTyp.kind in {tyUInt..tyUInt64}:
- result.transitionIntKind(nkUIntLit)
- else:
- result = a
- result.typ = n.typ
- if check and result.kind in {nkCharLit..nkUInt64Lit}:
- rangeCheck(n, getInt(result), g)
- of tyFloat..tyFloat64:
- case srcTyp.kind
- of tyInt..tyInt64, tyUInt..tyUInt64, tyEnum, tyBool, tyChar:
- result = newFloatNodeT(toFloat64(getOrdValue(a)), n, g)
- else:
- result = a
- result.typ = n.typ
- of tyOpenArray, tyVarargs, tyProc, tyPointer:
- result = nil
- else:
- result = a
- result.typ = n.typ
- proc getArrayConstr(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- if n.kind == nkBracket:
- result = n
- else:
- result = getConstExpr(m, n, idgen, g)
- if result == nil: result = n
- proc foldArrayAccess(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- var x = getConstExpr(m, n[0], idgen, g)
- if x == nil or x.typ.skipTypes({tyGenericInst, tyAlias, tySink}).kind == tyTypeDesc:
- return
- var y = getConstExpr(m, n[1], idgen, g)
- if y == nil: return
- var idx = toInt64(getOrdValue(y))
- case x.kind
- of nkPar, nkTupleConstr:
- if idx >= 0 and idx < x.len:
- result = x.sons[idx]
- if result.kind == nkExprColonExpr: result = result[1]
- else:
- result = nil
- localError(g.config, n.info, formatErrorIndexBound(idx, x.len-1) & $n)
- of nkBracket:
- idx -= toInt64(firstOrd(g.config, x.typ))
- if idx >= 0 and idx < x.len: result = x[int(idx)]
- else:
- result = nil
- localError(g.config, n.info, formatErrorIndexBound(idx, x.len-1) & $n)
- of nkStrLit..nkTripleStrLit:
- result = newNodeIT(nkCharLit, x.info, n.typ)
- if idx >= 0 and idx < x.strVal.len:
- result.intVal = ord(x.strVal[int(idx)])
- else:
- localError(g.config, n.info, formatErrorIndexBound(idx, x.strVal.len-1) & $n)
- else: result = nil
- proc foldFieldAccess(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- # a real field access; proc calls have already been transformed
- result = nil
- if n[1].kind != nkSym: return nil
- var x = getConstExpr(m, n[0], idgen, g)
- if x == nil or x.kind notin {nkObjConstr, nkPar, nkTupleConstr}: return
- var field = n[1].sym
- for i in ord(x.kind == nkObjConstr)..<x.len:
- var it = x[i]
- if it.kind != nkExprColonExpr:
- # lookup per index:
- result = x[field.position]
- if result.kind == nkExprColonExpr: result = result[1]
- return
- if it[0].sym.name.id == field.name.id:
- result = x[i][1]
- return
- localError(g.config, n.info, "field not found: " & field.name.s)
- proc foldConStrStr(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- result = newNodeIT(nkStrLit, n.info, n.typ)
- result.strVal = ""
- for i in 1..<n.len:
- let a = getConstExpr(m, n[i], idgen, g)
- if a == nil: return nil
- result.strVal.add(getStrOrChar(a))
- proc newSymNodeTypeDesc*(s: PSym; idgen: IdGenerator; info: TLineInfo): PNode =
- result = newSymNode(s, info)
- if s.typ.kind != tyTypeDesc:
- result.typ = newType(tyTypeDesc, idgen.nextTypeId, s.owner)
- result.typ.addSonSkipIntLit(s.typ, idgen)
- else:
- result.typ = s.typ
- proc foldDefine(m, s: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- result = nil
- var name = s.name.s
- let prag = extractPragma(s)
- if prag != nil:
- for it in prag:
- if it.kind in nkPragmaCallKinds and it.len == 2 and it[0].kind == nkIdent:
- let word = whichKeyword(it[0].ident)
- if word in {wStrDefine, wIntDefine, wBoolDefine, wDefine}:
- # should be processed in pragmas.nim already
- if it[1].kind in {nkStrLit, nkRStrLit, nkTripleStrLit}:
- name = it[1].strVal
- if isDefined(g.config, name):
- let str = g.config.symbols[name]
- case s.magic
- of mIntDefine:
- try:
- result = newIntNodeT(toInt128(str.parseInt), n, idgen, g)
- except ValueError:
- localError(g.config, s.info,
- "{.intdefine.} const was set to an invalid integer: '" &
- str & "'")
- of mStrDefine:
- result = newStrNodeT(str, n, g)
- of mBoolDefine:
- try:
- result = newIntNodeT(toInt128(str.parseBool.int), n, idgen, g)
- except ValueError:
- localError(g.config, s.info,
- "{.booldefine.} const was set to an invalid bool: '" &
- str & "'")
- of mGenericDefine:
- let rawTyp = s.typ
- # pretend we don't support distinct types
- let typ = rawTyp.skipTypes(abstractVarRange-{tyDistinct})
- try:
- template intNode(value): PNode =
- let val = toInt128(value)
- rangeCheck(n, val, g)
- newIntNodeT(val, n, idgen, g)
- case typ.kind
- of tyString, tyCstring:
- result = newStrNodeT(str, n, g)
- of tyInt..tyInt64:
- result = intNode(str.parseBiggestInt)
- of tyUInt..tyUInt64:
- result = intNode(str.parseBiggestUInt)
- of tyBool:
- result = intNode(str.parseBool.int)
- of tyEnum:
- # compile time parseEnum
- let ident = getIdent(g.cache, str)
- for e in typ.n:
- if e.kind != nkSym: internalError(g.config, "foldDefine for enum")
- let es = e.sym
- let match =
- if es.ast.isNil:
- es.name.id == ident.id
- else:
- es.ast.strVal == str
- if match:
- result = intNode(es.position)
- break
- if result.isNil:
- raise newException(ValueError, "invalid enum value: " & str)
- else:
- localError(g.config, s.info, "unsupported type $1 for define '$2'" %
- [name, typeToString(rawTyp)])
- except ValueError as e:
- localError(g.config, s.info,
- "could not process define '$1' of type $2; $3" %
- [name, typeToString(rawTyp), e.msg])
- else: result = copyTree(s.astdef) # unreachable
- else:
- result = copyTree(s.astdef)
- if result != nil:
- result.info = n.info
- proc getConstExpr(m: PSym, n: PNode; idgen: IdGenerator; g: ModuleGraph): PNode =
- result = nil
- case n.kind
- of nkSym:
- var s = n.sym
- case s.kind
- of skEnumField:
- result = newIntNodeT(toInt128(s.position), n, idgen, g)
- of skConst:
- case s.magic
- of mIsMainModule: result = newIntNodeT(toInt128(ord(sfMainModule in m.flags)), n, idgen, g)
- of mCompileDate: result = newStrNodeT(getDateStr(), n, g)
- of mCompileTime: result = newStrNodeT(getClockStr(), n, g)
- of mCpuEndian: result = newIntNodeT(toInt128(ord(CPU[g.config.target.targetCPU].endian)), n, idgen, g)
- of mHostOS: result = newStrNodeT(toLowerAscii(platform.OS[g.config.target.targetOS].name), n, g)
- of mHostCPU: result = newStrNodeT(platform.CPU[g.config.target.targetCPU].name.toLowerAscii, n, g)
- of mBuildOS: result = newStrNodeT(toLowerAscii(platform.OS[g.config.target.hostOS].name), n, g)
- of mBuildCPU: result = newStrNodeT(platform.CPU[g.config.target.hostCPU].name.toLowerAscii, n, g)
- of mAppType: result = getAppType(n, g)
- of mIntDefine, mStrDefine, mBoolDefine, mGenericDefine:
- result = foldDefine(m, s, n, idgen, g)
- else:
- result = copyTree(s.astdef)
- if result != nil:
- result.info = n.info
- of skProc, skFunc, skMethod:
- result = n
- of skParam:
- if s.typ != nil and s.typ.kind == tyTypeDesc:
- result = newSymNodeTypeDesc(s, idgen, n.info)
- of skType:
- # XXX gensym'ed symbols can come here and cannot be resolved. This is
- # dirty, but correct.
- if s.typ != nil:
- result = newSymNodeTypeDesc(s, idgen, n.info)
- of skGenericParam:
- if s.typ.kind == tyStatic:
- if s.typ.n != nil and tfUnresolved notin s.typ.flags:
- result = s.typ.n
- result.typ = s.typ.base
- elif s.typ.isIntLit:
- result = s.typ.n
- else:
- result = newSymNodeTypeDesc(s, idgen, n.info)
- else: discard
- of nkCharLit..nkNilLit:
- result = copyNode(n)
- of nkIfExpr:
- result = getConstIfExpr(m, n, idgen, g)
- of nkCallKinds:
- if n[0].kind != nkSym: return
- var s = n[0].sym
- if s.kind != skProc and s.kind != skFunc: return
- try:
- case s.magic
- of mNone:
- # If it has no sideEffect, it should be evaluated. But not here.
- return
- of mLow:
- if skipTypes(n[1].typ, abstractVarRange).kind in tyFloat..tyFloat64:
- result = newFloatNodeT(firstFloat(n[1].typ), n, g)
- else:
- result = newIntNodeT(firstOrd(g.config, n[1].typ), n, idgen, g)
- of mHigh:
- if skipTypes(n[1].typ, abstractVar+{tyUserTypeClassInst}).kind notin
- {tySequence, tyString, tyCstring, tyOpenArray, tyVarargs}:
- if skipTypes(n[1].typ, abstractVarRange).kind in tyFloat..tyFloat64:
- result = newFloatNodeT(lastFloat(n[1].typ), n, g)
- else:
- result = newIntNodeT(lastOrd(g.config, skipTypes(n[1].typ, abstractVar)), n, idgen, g)
- else:
- var a = getArrayConstr(m, n[1], idgen, g)
- if a.kind == nkBracket:
- # we can optimize it away:
- result = newIntNodeT(toInt128(a.len-1), n, idgen, g)
- of mLengthOpenArray:
- var a = getArrayConstr(m, n[1], idgen, g)
- if a.kind == nkBracket:
- # we can optimize it away! This fixes the bug ``len(134)``.
- result = newIntNodeT(toInt128(a.len), n, idgen, g)
- else:
- result = magicCall(m, n, idgen, g)
- of mLengthArray:
- # It doesn't matter if the argument is const or not for mLengthArray.
- # This fixes bug #544.
- result = newIntNodeT(lengthOrd(g.config, n[1].typ), n, idgen, g)
- of mSizeOf:
- result = foldSizeOf(g.config, n, nil)
- of mAlignOf:
- result = foldAlignOf(g.config, n, nil)
- of mOffsetOf:
- result = foldOffsetOf(g.config, n, nil)
- of mAstToStr:
- result = newStrNodeT(renderTree(n[1], {renderNoComments}), n, g)
- of mConStrStr:
- result = foldConStrStr(m, n, idgen, g)
- of mIs:
- # The only kind of mIs node that comes here is one depending on some
- # generic parameter and that's (hopefully) handled at instantiation time
- discard
- else:
- result = magicCall(m, n, idgen, g)
- except OverflowDefect:
- localError(g.config, n.info, "over- or underflow")
- except DivByZeroDefect:
- localError(g.config, n.info, "division by zero")
- of nkAddr:
- var a = getConstExpr(m, n[0], idgen, g)
- if a != nil:
- result = n
- n[0] = a
- of nkBracket, nkCurly:
- result = copyNode(n)
- for son in n.items:
- var a = getConstExpr(m, son, idgen, g)
- if a == nil: return nil
- result.add a
- incl(result.flags, nfAllConst)
- of nkRange:
- var a = getConstExpr(m, n[0], idgen, g)
- if a == nil: return
- var b = getConstExpr(m, n[1], idgen, g)
- if b == nil: return
- result = copyNode(n)
- result.add a
- result.add b
- #of nkObjConstr:
- # result = copyTree(n)
- # for i in 1..<n.len:
- # var a = getConstExpr(m, n[i][1])
- # if a == nil: return nil
- # result[i][1] = a
- # incl(result.flags, nfAllConst)
- of nkPar, nkTupleConstr:
- # tuple constructor
- result = copyNode(n)
- if (n.len > 0) and (n[0].kind == nkExprColonExpr):
- for expr in n.items:
- let exprNew = copyNode(expr) # nkExprColonExpr
- exprNew.add expr[0]
- let a = getConstExpr(m, expr[1], idgen, g)
- if a == nil: return nil
- exprNew.add a
- result.add exprNew
- else:
- for expr in n.items:
- let a = getConstExpr(m, expr, idgen, g)
- if a == nil: return nil
- result.add a
- incl(result.flags, nfAllConst)
- of nkChckRangeF, nkChckRange64, nkChckRange:
- var a = getConstExpr(m, n[0], idgen, g)
- if a == nil: return
- if leValueConv(n[1], a) and leValueConv(a, n[2]):
- result = a # a <= x and x <= b
- result.typ = n.typ
- else:
- localError(g.config, n.info,
- "conversion from $1 to $2 is invalid" %
- [typeToString(n[0].typ), typeToString(n.typ)])
- of nkStringToCString, nkCStringToString:
- var a = getConstExpr(m, n[0], idgen, g)
- if a == nil: return
- result = a
- result.typ = n.typ
- of nkHiddenStdConv, nkHiddenSubConv, nkConv:
- var a = getConstExpr(m, n[1], idgen, g)
- if a == nil: return
- result = foldConv(n, a, idgen, g, check=true)
- of nkDerefExpr, nkHiddenDeref:
- let a = getConstExpr(m, n[0], idgen, g)
- if a != nil and a.kind == nkNilLit:
- result = nil
- #localError(g.config, n.info, "nil dereference is not allowed")
- of nkCast:
- var a = getConstExpr(m, n[1], idgen, g)
- if a == nil: return
- if n.typ != nil and n.typ.kind in NilableTypes:
- # we allow compile-time 'cast' for pointer types:
- result = a
- result.typ = n.typ
- of nkBracketExpr: result = foldArrayAccess(m, n, idgen, g)
- of nkDotExpr: result = foldFieldAccess(m, n, idgen, g)
- of nkCheckedFieldExpr:
- assert n[0].kind == nkDotExpr
- result = foldFieldAccess(m, n[0], idgen, g)
- of nkStmtListExpr:
- var i = 0
- while i <= n.len - 2:
- if n[i].kind in {nkComesFrom, nkCommentStmt, nkEmpty}: i.inc
- else: break
- if i == n.len - 1:
- result = getConstExpr(m, n[i], idgen, g)
- else:
- discard
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