# # # 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, astalgo, trees, treetab, nimsets, times, nversion, platform, math, msgs, os, condsyms, idents, renderer, types, commands, magicsys, modulegraphs, strtabs proc newIntNodeT*(intVal: BiggestInt, n: PNode; g: ModuleGraph): PNode = case skipTypes(n.typ, abstractVarRange).kind of tyInt: result = newIntNode(nkIntLit, intVal) # 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: result.typ = getIntLitType(g, result) else: result.typ = n.typ # hrm, this is not correct: 1 + high(int) shouldn't produce tyInt64 ... #setIntLitType(result) of tyChar: result = newIntNode(nkCharLit, intVal) result.typ = n.typ else: result = newIntNode(nkIntLit, intVal) result.typ = n.typ result.info = n.info proc newFloatNodeT*(floatVal: BiggestFloat, n: PNode; g: ModuleGraph): PNode = result = newFloatNode(nkFloatLit, floatVal) if skipTypes(n.typ, abstractVarRange).kind == tyFloat: result.typ = getFloatLitType(g, result) else: 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; 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; g: ModuleGraph): PNode proc checkInRange(n: PNode, res: BiggestInt): bool = if res in firstOrd(n.typ)..lastOrd(n.typ): result = true proc foldAdd(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = let res = a +% b if ((res xor a) >= 0'i64 or (res xor b) >= 0'i64) and checkInRange(n, res): result = newIntNodeT(res, n, g) proc foldSub*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = let res = a -% b if ((res xor a) >= 0'i64 or (res xor not b) >= 0'i64) and checkInRange(n, res): result = newIntNodeT(res, n, g) proc foldAbs*(a: BiggestInt, n: PNode; g: ModuleGraph): PNode = if a != firstOrd(n.typ): result = newIntNodeT(a, n, g) proc foldMod*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = if b != 0'i64: result = newIntNodeT(a mod b, n, g) proc foldModU*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = if b != 0'i64: result = newIntNodeT(a %% b, n, g) proc foldDiv*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = if b != 0'i64 and (a != firstOrd(n.typ) or b != -1'i64): result = newIntNodeT(a div b, n, g) proc foldDivU*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = if b != 0'i64: result = newIntNodeT(a /% b, n, g) proc foldMul*(a, b: BiggestInt, n: PNode; g: ModuleGraph): PNode = let res = a *% b let floatProd = toBiggestFloat(a) * toBiggestFloat(b) let resAsFloat = toBiggestFloat(res) # Fast path for normal case: small multiplicands, and no info # is lost in either method. if resAsFloat == floatProd and checkInRange(n, res): return newIntNodeT(res, n, g) # Somebody somewhere lost info. Close enough, or way off? Note # that a != 0 and b != 0 (else resAsFloat == floatProd == 0). # The difference either is or isn't significant compared to the # true value (of which floatProd is a good approximation). # abs(diff)/abs(prod) <= 1/32 iff # 32 * abs(diff) <= abs(prod) -- 5 good bits is "close enough" if 32.0 * abs(resAsFloat - floatProd) <= abs(floatProd) and checkInRange(n, res): return newIntNodeT(res, n, g) 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(int(x) and 0xff) of tyEnum: var n = t.n for i in countup(0, sonsLen(n) - 1): if n.sons[i].kind != nkSym: internalError(g.config, a.info, "ordinalValToString") var field = n.sons[i].sym if field.position == x: if field.ast == nil: return field.name.s else: return field.ast.strVal internalError(g.config, a.info, "no symbol for ordinal value: " & $x) else: result = $x proc isFloatRange(t: PType): bool {.inline.} = result = t.kind == tyRange and t.sons[0].kind in {tyFloat..tyFloat128} proc isIntRange(t: PType): bool {.inline.} = result = t.kind == tyRange and t.sons[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 makeRange(typ: PType, first, last: BiggestInt; g: ModuleGraph): PType = let minA = min(first, last) let maxA = max(first, last) let lowerNode = newIntNode(nkIntLit, minA) if typ.kind == tyInt and minA == maxA: result = getIntLitType(g, lowerNode) elif typ.kind in {tyUint, tyUInt64}: # these are not ordinal types, so you get no subrange type for these: result = typ else: var n = newNode(nkRange) addSon(n, lowerNode) addSon(n, newIntNode(nkIntLit, maxA)) result = newType(tyRange, typ.owner) result.n = n addSonSkipIntLit(result, skipTypes(typ, {tyRange})) proc makeRangeF(typ: PType, first, last: BiggestFloat; g: ModuleGraph): PType = var n = newNode(nkRange) addSon(n, newFloatNode(nkFloatLit, min(first.float, last.float))) addSon(n, newFloatNode(nkFloatLit, max(first.float, last.float))) result = newType(tyRange, typ.owner) result.n = n addSonSkipIntLit(result, skipTypes(typ, {tyRange})) proc evalIs(n, a: PNode): PNode = # XXX: This should use the standard isOpImpl #internalAssert a.kind == nkSym and a.sym.kind == skType #internalAssert n.sonsLen == 3 and # n[2].kind in {nkStrLit..nkTripleStrLit, nkType} let t1 = a.sym.typ if n[2].kind in {nkStrLit..nkTripleStrLit}: case n[2].strVal.normalize of "closure": let t = skipTypes(t1, abstractRange) result = newIntNode(nkIntLit, ord(t.kind == tyProc and t.callConv == ccClosure and tfIterator notin t.flags)) of "iterator": let t = skipTypes(t1, abstractRange) result = newIntNode(nkIntLit, ord(t.kind == tyProc and t.callConv == ccClosure and tfIterator in t.flags)) else: discard else: # XXX semexprs.isOpImpl is slightly different and requires a context. yay. let t2 = n[2].typ var match = sameType(t1, t2) result = newIntNode(nkIntLit, ord(match)) result.typ = n.typ proc evalOp(m: TMagic, n, a, b, c: PNode; g: ModuleGraph): PNode = # b and c may be nil result = nil case m of mOrd: result = newIntNodeT(getOrdValue(a), n, g) of mChr: result = newIntNodeT(getInt(a), n, g) of mUnaryMinusI, mUnaryMinusI64: result = newIntNodeT(- getInt(a), n, g) of mUnaryMinusF64: result = newFloatNodeT(- getFloat(a), n, g) of mNot: result = newIntNodeT(1 - getInt(a), n, g) of mCard: result = newIntNodeT(nimsets.cardSet(a), n, g) of mBitnotI: result = newIntNodeT(not getInt(a), n, g) of mLengthArray: result = newIntNodeT(lengthOrd(a.typ), n, g) of mLengthSeq, mLengthOpenArray, mXLenSeq, mLengthStr, mXLenStr: if a.kind == nkNilLit: result = newIntNodeT(0, n, g) elif a.kind in {nkStrLit..nkTripleStrLit}: result = newIntNodeT(len a.strVal, n, g) else: result = newIntNodeT(sonsLen(a), n, g) of mUnaryPlusI, mUnaryPlusF64: result = a # throw `+` away of mToFloat, mToBiggestFloat: result = newFloatNodeT(toFloat(int(getInt(a))), n, g) # XXX: Hides overflow/underflow of mToInt, mToBiggestInt: result = newIntNodeT(system.toInt(getFloat(a)), n, g) of mAbsF64: result = newFloatNodeT(abs(getFloat(a)), n, g) of mAbsI: result = foldAbs(getInt(a), n, g) of mZe8ToI, mZe8ToI64, mZe16ToI, mZe16ToI64, mZe32ToI64, mZeIToI64: # byte(-128) = 1...1..1000_0000'64 --> 0...0..1000_0000'64 result = newIntNodeT(getInt(a) and (`shl`(1, getSize(a.typ) * 8) - 1), n, g) of mToU8: result = newIntNodeT(getInt(a) and 0x000000FF, n, g) of mToU16: result = newIntNodeT(getInt(a) and 0x0000FFFF, n, g) of mToU32: result = newIntNodeT(getInt(a) and 0x00000000FFFFFFFF'i64, n, g) of mUnaryLt: result = foldSub(getOrdValue(a), 1, n, g) of mSucc: result = foldAdd(getOrdValue(a), getInt(b), n, g) of mPred: result = foldSub(getOrdValue(a), getInt(b), n, g) of mAddI: result = foldAdd(getInt(a), getInt(b), n, g) of mSubI: result = foldSub(getInt(a), getInt(b), n, g) of mMulI: result = foldMul(getInt(a), getInt(b), n, g) of mMinI: if getInt(a) > getInt(b): result = newIntNodeT(getInt(b), n, g) else: result = newIntNodeT(getInt(a), n, g) of mMaxI: if getInt(a) > getInt(b): result = newIntNodeT(getInt(a), n, g) else: result = newIntNodeT(getInt(b), n, g) of mShlI: case skipTypes(n.typ, abstractRange).kind of tyInt8: result = newIntNodeT(int8(getInt(a)) shl int8(getInt(b)), n, g) of tyInt16: result = newIntNodeT(int16(getInt(a)) shl int16(getInt(b)), n, g) of tyInt32: result = newIntNodeT(int32(getInt(a)) shl int32(getInt(b)), n, g) of tyInt64, tyInt, tyUInt..tyUInt64: result = newIntNodeT(`shl`(getInt(a), getInt(b)), n, g) else: internalError(g.config, n.info, "constant folding for shl") of mShrI: case skipTypes(n.typ, abstractRange).kind of tyInt8: result = newIntNodeT(int8(getInt(a)) shr int8(getInt(b)), n, g) of tyInt16: result = newIntNodeT(int16(getInt(a)) shr int16(getInt(b)), n, g) of tyInt32: result = newIntNodeT(int32(getInt(a)) shr int32(getInt(b)), n, g) of tyInt64, tyInt, tyUInt..tyUInt64: result = newIntNodeT(`shr`(getInt(a), getInt(b)), n, g) else: internalError(g.config, n.info, "constant folding for shr") of mDivI: result = foldDiv(getInt(a), getInt(b), n, g) of mModI: result = foldMod(getInt(a), getInt(b), n, 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: if getFloat(b) == 0.0: if getFloat(a) == 0.0: result = newFloatNodeT(NaN, n, g) elif getFloat(b).classify == fcNegZero: result = newFloatNodeT(-Inf, n, g) else: result = newFloatNodeT(Inf, n, g) else: result = newFloatNodeT(getFloat(a) / getFloat(b), n, g) of mMaxF64: if getFloat(a) > getFloat(b): result = newFloatNodeT(getFloat(a), n, g) else: result = newFloatNodeT(getFloat(b), n, g) of mMinF64: if getFloat(a) > getFloat(b): result = newFloatNodeT(getFloat(b), n, g) else: result = newFloatNodeT(getFloat(a), n, g) of mIsNil: result = newIntNodeT(ord(a.kind == nkNilLit), n, g) of mLtI, mLtB, mLtEnum, mLtCh: result = newIntNodeT(ord(getOrdValue(a) < getOrdValue(b)), n, g) of mLeI, mLeB, mLeEnum, mLeCh: result = newIntNodeT(ord(getOrdValue(a) <= getOrdValue(b)), n, g) of mEqI, mEqB, mEqEnum, mEqCh: result = newIntNodeT(ord(getOrdValue(a) == getOrdValue(b)), n, g) of mLtF64: result = newIntNodeT(ord(getFloat(a) < getFloat(b)), n, g) of mLeF64: result = newIntNodeT(ord(getFloat(a) <= getFloat(b)), n, g) of mEqF64: result = newIntNodeT(ord(getFloat(a) == getFloat(b)), n, g) of mLtStr: result = newIntNodeT(ord(getStr(a) < getStr(b)), n, g) of mLeStr: result = newIntNodeT(ord(getStr(a) <= getStr(b)), n, g) of mEqStr: result = newIntNodeT(ord(getStr(a) == getStr(b)), n, g) of mLtU, mLtU64: result = newIntNodeT(ord(`<%`(getOrdValue(a), getOrdValue(b))), n, g) of mLeU, mLeU64: result = newIntNodeT(ord(`<=%`(getOrdValue(a), getOrdValue(b))), n, g) of mBitandI, mAnd: result = newIntNodeT(a.getInt and b.getInt, n, g) of mBitorI, mOr: result = newIntNodeT(getInt(a) or getInt(b), n, g) of mBitxorI, mXor: result = newIntNodeT(a.getInt xor b.getInt, n, g) of mAddU: result = newIntNodeT(`+%`(getInt(a), getInt(b)), n, g) of mSubU: result = newIntNodeT(`-%`(getInt(a), getInt(b)), n, g) of mMulU: result = newIntNodeT(`*%`(getInt(a), getInt(b)), n, g) of mModU: result = foldModU(getInt(a), getInt(b), n, g) of mDivU: result = foldDivU(getInt(a), getInt(b), n, g) of mLeSet: result = newIntNodeT(ord(containsSets(a, b)), n, g) of mEqSet: result = newIntNodeT(ord(equalSets(a, b)), n, g) of mLtSet: result = newIntNodeT(ord(containsSets(a, b) and not equalSets(a, b)), n, g) of mMulSet: result = nimsets.intersectSets(a, b) result.info = n.info of mPlusSet: result = nimsets.unionSets(a, b) result.info = n.info of mMinusSet: result = nimsets.diffSets(a, b) result.info = n.info of mSymDiffSet: result = nimsets.symdiffSets(a, b) result.info = n.info of mConStrStr: result = newStrNodeT(getStrOrChar(a) & getStrOrChar(b), n, g) of mInSet: result = newIntNodeT(ord(inSet(a, b)), n, 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 mCopyStr: result = newStrNodeT(substr(getStr(a), int(getOrdValue(b))), n, g) of mCopyStrLast: result = newStrNodeT(substr(getStr(a), int(getOrdValue(b)), int(getOrdValue(c))), n, g) of mFloatToStr: result = newStrNodeT($getFloat(a), n, g) of mCStrToStr, mCharToStr: if a.kind == nkBracket: var s = "" for b in a.sons: s.add b.getStrOrChar result = newStrNodeT(s, n, g) else: result = newStrNodeT(getStrOrChar(a), n, g) of mStrToStr: result = a of mEnumToStr: result = newStrNodeT(ordinalValToString(a, g), n, g) of mArrToSeq: result = copyTree(a) result.typ = n.typ of mCompileOption: result = newIntNodeT(ord(commands.testCompileOption(g.config, a.getStr, n.info)), n, g) of mCompileOptionArg: result = newIntNodeT(ord( testCompileOptionArg(g.config, getStr(a), getStr(b), n.info)), n, g) of mEqProc: result = newIntNodeT(ord( exprStructuralEquivalent(a, b, strictSymEquality=true)), n, g) else: discard proc getConstIfExpr(c: PSym, n: PNode; g: ModuleGraph): PNode = result = nil for i in countup(0, sonsLen(n) - 1): var it = n.sons[i] if it.len == 2: var e = getConstExpr(c, it.sons[0], g) if e == nil: return nil if getOrdValue(e) != 0: if result == nil: result = getConstExpr(c, it.sons[1], g) if result == nil: return elif it.len == 1: if result == nil: result = getConstExpr(c, it.sons[0], 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.intVal <= b.intVal 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 <= toFloat(int(b.intVal)) else: result = false # internalError(a.info, "leValueConv") else: result = false # internalError(a.info, "leValueConv") proc magicCall(m: PSym, n: PNode; g: ModuleGraph): PNode = if sonsLen(n) <= 1: return var s = n.sons[0].sym var a = getConstExpr(m, n.sons[1], g) var b, c: PNode if a == nil: return if sonsLen(n) > 2: b = getConstExpr(m, n.sons[2], g) if b == nil: return if sonsLen(n) > 3: c = getConstExpr(m, n.sons[3], g) if c == nil: return result = evalOp(s.magic, n, a, b, c, g) proc getAppType(n: PNode; g: ModuleGraph): PNode = if gGlobalOptions.contains(optGenDynLib): result = newStrNodeT("lib", n, g) elif gGlobalOptions.contains(optGenStaticLib): result = newStrNodeT("staticlib", n, g) elif gGlobalOptions.contains(optGenGuiApp): result = newStrNodeT("gui", n, g) else: result = newStrNodeT("console", n, g) proc rangeCheck(n: PNode, value: BiggestInt; g: ModuleGraph) = var err = false if n.typ.skipTypes({tyRange}).kind in {tyUInt..tyUInt64}: err = value <% firstOrd(n.typ) or value >% lastOrd(n.typ, fixedUnsigned=true) else: err = value < firstOrd(n.typ) or value > lastOrd(n.typ) if err: localError(g.config, n.info, "cannot convert " & $value & " to " & typeToString(n.typ)) proc foldConv*(n, a: PNode; g: ModuleGraph; check = false): PNode = # XXX range checks? case skipTypes(n.typ, abstractRange).kind of tyInt..tyInt64, tyUInt..tyUInt64: case skipTypes(a.typ, abstractRange).kind of tyFloat..tyFloat64: result = newIntNodeT(int(getFloat(a)), n, g) of tyChar: result = newIntNodeT(getOrdValue(a), n, g) else: result = a result.typ = n.typ if check and result.kind in {nkCharLit..nkUInt64Lit}: rangeCheck(n, result.intVal, g) of tyFloat..tyFloat64: case skipTypes(a.typ, abstractRange).kind of tyInt..tyInt64, tyEnum, tyBool, tyChar: result = newFloatNodeT(toBiggestFloat(getOrdValue(a)), n, g) else: result = a result.typ = n.typ of tyOpenArray, tyVarargs, tyProc: discard else: result = a result.typ = n.typ proc getArrayConstr(m: PSym, n: PNode; g: ModuleGraph): PNode = if n.kind == nkBracket: result = n else: result = getConstExpr(m, n, g) if result == nil: result = n proc foldArrayAccess(m: PSym, n: PNode; g: ModuleGraph): PNode = var x = getConstExpr(m, n.sons[0], g) if x == nil or x.typ.skipTypes({tyGenericInst, tyAlias, tySink}).kind == tyTypeDesc: return var y = getConstExpr(m, n.sons[1], g) if y == nil: return var idx = getOrdValue(y) case x.kind of nkPar, nkTupleConstr: if idx >= 0 and idx < sonsLen(x): result = x.sons[int(idx)] if result.kind == nkExprColonExpr: result = result.sons[1] else: localError(g.config, n.info, "index out of bounds: " & $n) of nkBracket: idx = idx - x.typ.firstOrd if idx >= 0 and idx < x.len: result = x.sons[int(idx)] else: localError(g.config, n.info, "index out of bounds: " & $n) of nkStrLit..nkTripleStrLit: result = newNodeIT(nkCharLit, x.info, n.typ) if idx >= 0 and idx < len(x.strVal): result.intVal = ord(x.strVal[int(idx)]) elif idx == len(x.strVal) and optLaxStrings in gOptions: discard else: localError(g.config, n.info, "index out of bounds: " & $n) else: discard proc foldFieldAccess(m: PSym, n: PNode; g: ModuleGraph): PNode = # a real field access; proc calls have already been transformed var x = getConstExpr(m, n.sons[0], g) if x == nil or x.kind notin {nkObjConstr, nkPar, nkTupleConstr}: return var field = n.sons[1].sym for i in countup(ord(x.kind == nkObjConstr), sonsLen(x) - 1): var it = x.sons[i] if it.kind != nkExprColonExpr: # lookup per index: result = x.sons[field.position] if result.kind == nkExprColonExpr: result = result.sons[1] return if it.sons[0].sym.name.id == field.name.id: result = x.sons[i].sons[1] return localError(g.config, n.info, "field not found: " & field.name.s) proc foldConStrStr(m: PSym, n: PNode; g: ModuleGraph): PNode = result = newNodeIT(nkStrLit, n.info, n.typ) result.strVal = "" for i in countup(1, sonsLen(n) - 1): let a = getConstExpr(m, n.sons[i], g) if a == nil: return nil result.strVal.add(getStrOrChar(a)) proc newSymNodeTypeDesc*(s: PSym; info: TLineInfo): PNode = result = newSymNode(s, info) if s.typ.kind != tyTypeDesc: result.typ = newType(tyTypeDesc, s.owner) result.typ.addSonSkipIntLit(s.typ) else: result.typ = s.typ proc getConstExpr(m: PSym, n: PNode; g: ModuleGraph): PNode = result = nil proc getSrcTimestamp(): DateTime = try: result = utc(fromUnix(parseInt(getEnv("SOURCE_DATE_EPOCH", "not a number")))) except ValueError: # Environment variable malformed. # https://reproducible-builds.org/specs/source-date-epoch/: "If the # value is malformed, the build process SHOULD exit with a non-zero # error code", which this doesn't do. This uses local time, because # that maintains compatibility with existing usage. result = local(getTime()) case n.kind of nkSym: var s = n.sym case s.kind of skEnumField: result = newIntNodeT(s.position, n, g) of skConst: case s.magic of mIsMainModule: result = newIntNodeT(ord(sfMainModule in m.flags), n, g) of mCompileDate: result = newStrNodeT(format(getSrcTimestamp(), "yyyy-MM-dd"), n, g) of mCompileTime: result = newStrNodeT(format(getSrcTimestamp(), "HH:mm:ss"), n, g) of mCpuEndian: result = newIntNodeT(ord(CPU[targetCPU].endian), n, g) of mHostOS: result = newStrNodeT(toLowerAscii(platform.OS[targetOS].name), n, g) of mHostCPU: result = newStrNodeT(platform.CPU[targetCPU].name.toLowerAscii, n, g) of mBuildOS: result = newStrNodeT(toLowerAscii(platform.OS[platform.hostOS].name), n, g) of mBuildCPU: result = newStrNodeT(platform.CPU[platform.hostCPU].name.toLowerAscii, n, g) of mAppType: result = getAppType(n, g) of mNaN: result = newFloatNodeT(NaN, n, g) of mInf: result = newFloatNodeT(Inf, n, g) of mNegInf: result = newFloatNodeT(NegInf, n, g) of mIntDefine: if isDefined(g.config, s.name.s): try: result = newIntNodeT(g.config.symbols[s.name.s].parseInt, n, g) except ValueError: localError(g.config, n.info, "expression is not an integer literal") of mStrDefine: if isDefined(g.config, s.name.s): result = newStrNodeT(g.config.symbols[s.name.s], n, g) else: result = copyTree(s.ast) of skProc, skFunc, skMethod: result = n 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, 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, n.info) else: discard of nkCharLit..nkNilLit: result = copyNode(n) of nkIfExpr: result = getConstIfExpr(m, n, g) of nkCallKinds: if n.sons[0].kind != nkSym: return var s = n.sons[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 mSizeOf: var a = n.sons[1] if computeSize(a.typ) < 0: localError(g.config, a.info, "cannot evaluate 'sizeof' because its type is not defined completely") result = nil elif skipTypes(a.typ, typedescInst+{tyRange}).kind in IntegralTypes+NilableTypes+{tySet}: #{tyArray,tyObject,tyTuple}: result = newIntNodeT(getSize(a.typ), n, g) else: result = nil # XXX: size computation for complex types is still wrong of mLow: result = newIntNodeT(firstOrd(n.sons[1].typ), n, g) of mHigh: if skipTypes(n.sons[1].typ, abstractVar).kind notin {tySequence, tyString, tyCString, tyOpenArray, tyVarargs}: result = newIntNodeT(lastOrd(skipTypes(n[1].typ, abstractVar)), n, g) else: var a = getArrayConstr(m, n.sons[1], g) if a.kind == nkBracket: # we can optimize it away: result = newIntNodeT(sonsLen(a)-1, n, g) of mLengthOpenArray: var a = getArrayConstr(m, n.sons[1], g) if a.kind == nkBracket: # we can optimize it away! This fixes the bug ``len(134)``. result = newIntNodeT(sonsLen(a), n, g) else: result = magicCall(m, n, g) of mLengthArray: # It doesn't matter if the argument is const or not for mLengthArray. # This fixes bug #544. result = newIntNodeT(lengthOrd(n.sons[1].typ), n, g) of mAstToStr: result = newStrNodeT(renderTree(n[1], {renderNoComments}), n, g) of mConStrStr: result = foldConStrStr(m, n, g) of mIs: let a = getConstExpr(m, n[1], g) if a != nil and a.kind == nkSym and a.sym.kind == skType: result = evalIs(n, a) else: result = magicCall(m, n, g) except OverflowError: localError(g.config, n.info, "over- or underflow") except DivByZeroError: localError(g.config, n.info, "division by zero") of nkAddr: var a = getConstExpr(m, n.sons[0], g) if a != nil: result = n n.sons[0] = a of nkBracket: result = copyTree(n) for i in countup(0, sonsLen(n) - 1): var a = getConstExpr(m, n.sons[i], g) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) of nkRange: var a = getConstExpr(m, n.sons[0], g) if a == nil: return var b = getConstExpr(m, n.sons[1], g) if b == nil: return result = copyNode(n) addSon(result, a) addSon(result, b) of nkCurly: result = copyTree(n) for i in countup(0, sonsLen(n) - 1): var a = getConstExpr(m, n.sons[i], g) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) #of nkObjConstr: # result = copyTree(n) # for i in countup(1, sonsLen(n) - 1): # var a = getConstExpr(m, n.sons[i].sons[1]) # if a == nil: return nil # result.sons[i].sons[1] = a # incl(result.flags, nfAllConst) of nkPar, nkTupleConstr: # tuple constructor result = copyTree(n) if (sonsLen(n) > 0) and (n.sons[0].kind == nkExprColonExpr): for i in countup(0, sonsLen(n) - 1): var a = getConstExpr(m, n.sons[i].sons[1], g) if a == nil: return nil result.sons[i].sons[1] = a else: for i in countup(0, sonsLen(n) - 1): var a = getConstExpr(m, n.sons[i], g) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) of nkChckRangeF, nkChckRange64, nkChckRange: var a = getConstExpr(m, n.sons[0], g) if a == nil: return if leValueConv(n.sons[1], a) and leValueConv(a, n.sons[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.sons[0].typ), typeToString(n.typ)]) of nkStringToCString, nkCStringToString: var a = getConstExpr(m, n.sons[0], g) if a == nil: return result = a result.typ = n.typ of nkHiddenStdConv, nkHiddenSubConv, nkConv: var a = getConstExpr(m, n.sons[1], g) if a == nil: return result = foldConv(n, a, g, check=n.kind == nkHiddenStdConv) of nkCast: var a = getConstExpr(m, n.sons[1], 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, g) of nkDotExpr: result = foldFieldAccess(m, n, g) of nkStmtListExpr: if n.len == 2 and n[0].kind == nkComesFrom: result = getConstExpr(m, n[1], g) else: discard