# # # The Nimrod Compiler # (c) Copyright 2012 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, lists, options, ast, astalgo, trees, treetab, nimsets, times, nversion, platform, math, msgs, os, condsyms, idents, renderer, types, commands, magicsys, saturate proc getConstExpr*(m: PSym, n: PNode): PNode # evaluates the constant expression or returns nil if it is no constant # expression proc evalOp*(m: TMagic, n, a, b, c: PNode): PNode proc leValueConv*(a, b: PNode): bool proc newIntNodeT*(intVal: BiggestInt, n: PNode): PNode proc newFloatNodeT*(floatVal: BiggestFloat, n: PNode): PNode proc newStrNodeT*(strVal: string, n: PNode): PNode # implementation proc newIntNodeT(intVal: BiggestInt, n: PNode): PNode = case skipTypes(n.typ, abstractVarRange).kind of tyInt: result = newIntNode(nkIntLit, intVal) result.typ = getIntLitType(result) # 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): PNode = result = newFloatNode(nkFloatLit, floatVal) result.typ = n.typ result.info = n.info proc newStrNodeT(strVal: string, n: PNode): PNode = result = newStrNode(nkStrLit, strVal) result.typ = n.typ result.info = n.info proc ordinalValToString(a: PNode): 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(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(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 pickMinInt(n: PNode): biggestInt = if n.kind in {nkIntLit..nkUInt64Lit}: result = n.intVal elif isIntLit(n.typ): result = n.typ.n.intVal elif isIntRange(n.typ): result = firstOrd(n.typ) else: InternalError(n.info, "pickMinInt") proc pickMaxInt(n: PNode): biggestInt = if n.kind in {nkIntLit..nkUInt64Lit}: result = n.intVal elif isIntLit(n.typ): result = n.typ.n.intVal elif isIntRange(n.typ): result = lastOrd(n.typ) else: InternalError(n.info, "pickMaxInt") proc makeRange(typ: PType, first, last: biggestInt): PType = var n = newNode(nkRange) addSon(n, newIntNode(nkIntLit, min(first, last))) addSon(n, newIntNode(nkIntLit, max(first, last))) result = newType(tyRange, typ.owner) result.n = n addSonSkipIntLit(result, skipTypes(typ, {tyRange})) proc makeRangeF(typ: PType, first, last: biggestFloat): 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 getIntervalType*(m: TMagic, n: PNode): PType = # Nimrod requires interval arithmetic for ``range`` types. Lots of tedious # work but the feature is very nice for reducing explicit conversions. result = n.typ template commutativeOp(opr: expr) {.immediate.} = let a = n.sons[1] let b = n.sons[2] if isIntRangeOrLit(a.typ) and isIntRangeOrLit(b.typ): result = makeRange(pickIntRange(a.typ, b.typ), opr(pickMinInt(a), pickMinInt(b)), opr(pickMaxInt(a), pickMaxInt(b))) template binaryOp(opr: expr) {.immediate.} = let a = n.sons[1] let b = n.sons[2] if isIntRange(a.typ) and b.kind in {nkIntLit..nkUInt64Lit}: result = makeRange(a.typ, opr(pickMinInt(a), pickMinInt(b)), opr(pickMaxInt(a), pickMaxInt(b))) case m of mUnaryMinusI, mUnaryMinusI64: let a = n.sons[1].typ if isIntRange(a): # (1..3) * (-1) == (-3.. -1) result = makeRange(a, 0|-|lastOrd(a), 0|-|firstOrd(a)) of mUnaryMinusF64: let a = n.sons[1].typ if isFloatRange(a): result = makeRangeF(a, -getFloat(a.n.sons[1]), -getFloat(a.n.sons[0])) of mAbsF64: let a = n.sons[1].typ if isFloatRange(a): # abs(-5.. 1) == (1..5) result = makeRangeF(a, abs(getFloat(a.n.sons[1])), abs(getFloat(a.n.sons[0]))) of mAbsI, mAbsI64: let a = n.sons[1].typ if isIntRange(a): result = makeRange(a, `|abs|`(getInt(a.n.sons[1])), `|abs|`(getInt(a.n.sons[0]))) of mSucc: let a = n.sons[1].typ let b = n.sons[2].typ if isIntRange(a) and isIntLit(b): # (-5.. 1) + 6 == (-5 + 6)..(-1 + 6) result = makeRange(a, pickMinInt(n.sons[1]) |+| pickMinInt(n.sons[2]), pickMaxInt(n.sons[1]) |+| pickMaxInt(n.sons[2])) of mPred: let a = n.sons[1].typ let b = n.sons[2].typ if isIntRange(a) and isIntLit(b): result = makeRange(a, pickMinInt(n.sons[1]) |-| pickMinInt(n.sons[2]), pickMaxInt(n.sons[1]) |-| pickMaxInt(n.sons[2])) of mAddI, mAddI64, mAddU: commutativeOp(`|+|`) of mMulI, mMulI64, mMulU: commutativeOp(`|*|`) of mSubI, mSubI64, mSubU: binaryOp(`|-|`) of mBitandI, mBitandI64: var a = n.sons[1] var b = n.sons[2] # symmetrical: if b.kind notin {nkIntLit..nkUInt64Lit}: swap(a, b) if b.kind in {nkIntLit..nkUInt64Lit}: let x = b.intVal|+|1 if (x and -x) == x and x >= 0: result = makeRange(a.typ, 0, b.intVal) of mModU: let a = n.sons[1] let b = n.sons[2] if b.kind in {nkIntLit..nkUInt64Lit}: if b.intVal >= 0: result = makeRange(a.typ, 0, b.intVal-1) else: result = makeRange(a.typ, b.intVal+1, 0) of mModI, mModI64: # so ... if you ever wondered about modulo's signedness; this defines it: let a = n.sons[1] let b = n.sons[2] if b.kind in {nkIntLit..nkUInt64Lit}: if b.intVal >= 0: result = makeRange(a.typ, -(b.intVal-1), b.intVal-1) else: result = makeRange(a.typ, b.intVal+1, -(b.intVal+1)) of mDivI, mDivI64, mDivU: binaryOp(`|div|`) of mMinI, mMinI64: commutativeOp(min) of mMaxI, mMaxI64: commutativeOp(max) else: nil discard """ mShlI, mShlI64, mShrI, mShrI64, mAddF64, mSubF64, mMulF64, mDivF64, mMaxF64, mMinF64 """ proc evalOp(m: TMagic, n, a, b, c: PNode): PNode = # b and c may be nil result = nil case m of mOrd: result = newIntNodeT(getOrdValue(a), n) of mChr: result = newIntNodeT(getInt(a), n) of mUnaryMinusI, mUnaryMinusI64: result = newIntNodeT(- getInt(a), n) of mUnaryMinusF64: result = newFloatNodeT(- getFloat(a), n) of mNot: result = newIntNodeT(1 - getInt(a), n) of mCard: result = newIntNodeT(nimsets.cardSet(a), n) of mBitnotI, mBitnotI64: result = newIntNodeT(not getInt(a), n) of mLengthStr: result = newIntNodeT(len(getStr(a)), n) of mLengthArray: result = newIntNodeT(lengthOrd(a.typ), n) of mLengthSeq, mLengthOpenArray: result = newIntNodeT(sonsLen(a), n) # BUGFIX of mUnaryPlusI, mUnaryPlusI64, mUnaryPlusF64: result = a # throw `+` away of mToFloat, mToBiggestFloat: result = newFloatNodeT(toFloat(int(getInt(a))), n) of mToInt, mToBiggestInt: result = newIntNodeT(system.toInt(getFloat(a)), n) of mAbsF64: result = newFloatNodeT(abs(getFloat(a)), n) of mAbsI, mAbsI64: if getInt(a) >= 0: result = a else: result = newIntNodeT(- getInt(a), n) 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) of mToU8: result = newIntNodeT(getInt(a) and 0x000000FF, n) of mToU16: result = newIntNodeT(getInt(a) and 0x0000FFFF, n) of mToU32: result = newIntNodeT(getInt(a) and 0x00000000FFFFFFFF'i64, n) of mUnaryLt: result = newIntNodeT(getOrdValue(a) - 1, n) of mSucc: result = newIntNodeT(getOrdValue(a) + getInt(b), n) of mPred: result = newIntNodeT(getOrdValue(a) - getInt(b), n) of mAddI, mAddI64: result = newIntNodeT(getInt(a) + getInt(b), n) of mSubI, mSubI64: result = newIntNodeT(getInt(a) - getInt(b), n) of mMulI, mMulI64: result = newIntNodeT(getInt(a) * getInt(b), n) of mMinI, mMinI64: if getInt(a) > getInt(b): result = newIntNodeT(getInt(b), n) else: result = newIntNodeT(getInt(a), n) of mMaxI, mMaxI64: if getInt(a) > getInt(b): result = newIntNodeT(getInt(a), n) else: result = newIntNodeT(getInt(b), n) of mShlI, mShlI64: case skipTypes(n.typ, abstractRange).kind of tyInt8: result = newIntNodeT(int8(getInt(a)) shl int8(getInt(b)), n) of tyInt16: result = newIntNodeT(int16(getInt(a)) shl int16(getInt(b)), n) of tyInt32: result = newIntNodeT(int32(getInt(a)) shl int32(getInt(b)), n) of tyInt64, tyInt, tyUInt..tyUInt64: result = newIntNodeT(`shl`(getInt(a), getInt(b)), n) else: InternalError(n.info, "constant folding for shl") of mShrI, mShrI64: case skipTypes(n.typ, abstractRange).kind of tyInt8: result = newIntNodeT(int8(getInt(a)) shr int8(getInt(b)), n) of tyInt16: result = newIntNodeT(int16(getInt(a)) shr int16(getInt(b)), n) of tyInt32: result = newIntNodeT(int32(getInt(a)) shr int32(getInt(b)), n) of tyInt64, tyInt, tyUInt..tyUInt64: result = newIntNodeT(`shr`(getInt(a), getInt(b)), n) else: InternalError(n.info, "constant folding for shr") of mDivI, mDivI64: result = newIntNodeT(getInt(a) div getInt(b), n) of mModI, mModI64: result = newIntNodeT(getInt(a) mod getInt(b), n) of mAddF64: result = newFloatNodeT(getFloat(a) + getFloat(b), n) of mSubF64: result = newFloatNodeT(getFloat(a) - getFloat(b), n) of mMulF64: result = newFloatNodeT(getFloat(a) * getFloat(b), n) of mDivF64: if getFloat(b) == 0.0: if getFloat(a) == 0.0: result = newFloatNodeT(NaN, n) else: result = newFloatNodeT(Inf, n) else: result = newFloatNodeT(getFloat(a) / getFloat(b), n) of mMaxF64: if getFloat(a) > getFloat(b): result = newFloatNodeT(getFloat(a), n) else: result = newFloatNodeT(getFloat(b), n) of mMinF64: if getFloat(a) > getFloat(b): result = newFloatNodeT(getFloat(b), n) else: result = newFloatNodeT(getFloat(a), n) of mIsNil: result = newIntNodeT(ord(a.kind == nkNilLit), n) of mLtI, mLtI64, mLtB, mLtEnum, mLtCh: result = newIntNodeT(ord(getOrdValue(a) < getOrdValue(b)), n) of mLeI, mLeI64, mLeB, mLeEnum, mLeCh: result = newIntNodeT(ord(getOrdValue(a) <= getOrdValue(b)), n) of mEqI, mEqI64, mEqB, mEqEnum, mEqCh: result = newIntNodeT(ord(getOrdValue(a) == getOrdValue(b)), n) of mLtF64: result = newIntNodeT(ord(getFloat(a) < getFloat(b)), n) of mLeF64: result = newIntNodeT(ord(getFloat(a) <= getFloat(b)), n) of mEqF64: result = newIntNodeT(ord(getFloat(a) == getFloat(b)), n) of mLtStr: result = newIntNodeT(ord(getStr(a) < getStr(b)), n) of mLeStr: result = newIntNodeT(ord(getStr(a) <= getStr(b)), n) of mEqStr: result = newIntNodeT(ord(getStr(a) == getStr(b)), n) of mLtU, mLtU64: result = newIntNodeT(ord(`<%`(getOrdValue(a), getOrdValue(b))), n) of mLeU, mLeU64: result = newIntNodeT(ord(`<=%`(getOrdValue(a), getOrdValue(b))), n) of mBitandI, mBitandI64, mAnd: result = newIntNodeT(a.getInt and b.getInt, n) of mBitorI, mBitorI64, mOr: result = newIntNodeT(getInt(a) or getInt(b), n) of mBitxorI, mBitxorI64, mXor: result = newIntNodeT(a.getInt xor b.getInt, n) of mAddU: result = newIntNodeT(`+%`(getInt(a), getInt(b)), n) of mSubU: result = newIntNodeT(`-%`(getInt(a), getInt(b)), n) of mMulU: result = newIntNodeT(`*%`(getInt(a), getInt(b)), n) of mModU: result = newIntNodeT(`%%`(getInt(a), getInt(b)), n) of mDivU: result = newIntNodeT(`/%`(getInt(a), getInt(b)), n) of mLeSet: result = newIntNodeT(Ord(containsSets(a, b)), n) of mEqSet: result = newIntNodeT(Ord(equalSets(a, b)), n) of mLtSet: result = newIntNodeT(Ord(containsSets(a, b) and not equalSets(a, b)), n) 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) of mInSet: result = newIntNodeT(Ord(inSet(a, b)), n) of mRepr: # BUGFIX: we cannot eval mRepr here for reasons that I forgot. of mIntToStr, mInt64ToStr: result = newStrNodeT($(getOrdValue(a)), n) of mBoolToStr: if getOrdValue(a) == 0: result = newStrNodeT("false", n) else: result = newStrNodeT("true", n) of mCopyStr: result = newStrNodeT(substr(getStr(a), int(getOrdValue(b))), n) of mCopyStrLast: result = newStrNodeT(substr(getStr(a), int(getOrdValue(b)), int(getOrdValue(c))), n) of mFloatToStr: result = newStrNodeT($getFloat(a), n) of mCStrToStr, mCharToStr: result = newStrNodeT(getStrOrChar(a), n) of mStrToStr: result = a of mEnumToStr: result = newStrNodeT(ordinalValToString(a), n) of mArrToSeq: result = copyTree(a) result.typ = n.typ of mCompileOption: result = newIntNodeT(Ord(commands.testCompileOption(a.getStr, n.info)), n) of mCompileOptionArg: result = newIntNodeT(Ord( testCompileOptionArg(getStr(a), getStr(b), n.info)), n) of mNewString, mNewStringOfCap, mExit, mInc, ast.mDec, mEcho, mSwap, mAppendStrCh, mAppendStrStr, mAppendSeqElem, mSetLengthStr, mSetLengthSeq, mParseExprToAst, mParseStmtToAst, mExpandToAst, mTypeTrait, mNLen..mNError, mEqRef, mSlurp, mStaticExec: nil of mRand: result = newIntNodeT(math.random(a.getInt.int), n) else: InternalError(a.info, "evalOp(" & $m & ')') proc getConstIfExpr(c: PSym, n: PNode): PNode = result = nil for i in countup(0, sonsLen(n) - 1): var it = n.sons[i] case it.kind of nkElifExpr: var e = getConstExpr(c, it.sons[0]) if e == nil: return nil if getOrdValue(e) != 0: if result == nil: result = getConstExpr(c, it.sons[1]) if result == nil: return of nkElseExpr: if result == nil: result = getConstExpr(c, it.sons[0]) else: internalError(it.info, "getConstIfExpr()") proc partialAndExpr(c: PSym, n: PNode): PNode = # partial evaluation result = n var a = getConstExpr(c, n.sons[1]) var b = getConstExpr(c, n.sons[2]) if a != nil: if getInt(a) == 0: result = a elif b != nil: result = b else: result = n.sons[2] elif b != nil: if getInt(b) == 0: result = b else: result = n.sons[1] proc partialOrExpr(c: PSym, n: PNode): PNode = # partial evaluation result = n var a = getConstExpr(c, n.sons[1]) var b = getConstExpr(c, n.sons[2]) if a != nil: if getInt(a) != 0: result = a elif b != nil: result = b else: result = n.sons[2] elif b != nil: if getInt(b) != 0: result = b else: result = n.sons[1] 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) else: 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: InternalError(a.info, "leValueConv") else: InternalError(a.info, "leValueConv") proc magicCall(m: PSym, n: PNode): PNode = if sonsLen(n) <= 1: return var s = n.sons[0].sym var a = getConstExpr(m, n.sons[1]) var b, c: PNode if a == nil: return if sonsLen(n) > 2: b = getConstExpr(m, n.sons[2]) if b == nil: return if sonsLen(n) > 3: c = getConstExpr(m, n.sons[3]) if c == nil: return else: b = nil result = evalOp(s.magic, n, a, b, c) proc getAppType(n: PNode): PNode = if gGlobalOptions.contains(optGenDynLib): result = newStrNodeT("lib", n) elif gGlobalOptions.contains(optGenStaticLib): result = newStrNodeT("staticlib", n) elif gGlobalOptions.contains(optGenGuiApp): result = newStrNodeT("gui", n) else: result = newStrNodeT("console", n) proc foldConv*(n, a: PNode): PNode = # XXX range checks? case skipTypes(n.typ, abstractRange).kind of tyInt..tyInt64: case skipTypes(a.typ, abstractRange).kind of tyFloat..tyFloat64: result = newIntNodeT(system.toInt(getFloat(a)), n) of tyChar: result = newIntNodeT(getOrdValue(a), n) else: result = a result.typ = n.typ of tyFloat..tyFloat64: case skipTypes(a.typ, abstractRange).kind of tyInt..tyInt64, tyEnum, tyBool, tyChar: result = newFloatNodeT(toFloat(int(getOrdValue(a))), n) else: result = a result.typ = n.typ of tyOpenArray, tyVarargs, tyProc: nil else: result = a result.typ = n.typ proc getArrayConstr(m: PSym, n: PNode): PNode = if n.kind == nkBracket: result = n else: result = getConstExpr(m, n) if result == nil: result = n proc foldArrayAccess(m: PSym, n: PNode): PNode = var x = getConstExpr(m, n.sons[0]) if x == nil: return var y = getConstExpr(m, n.sons[1]) if y == nil: return var idx = getOrdValue(y) case x.kind of nkPar: if (idx >= 0) and (idx < sonsLen(x)): result = x.sons[int(idx)] if result.kind == nkExprColonExpr: result = result.sons[1] else: LocalError(n.info, errIndexOutOfBounds) of nkBracket, nkMetaNode: if (idx >= 0) and (idx < sonsLen(x)): result = x.sons[int(idx)] else: LocalError(n.info, errIndexOutOfBounds) 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): nil else: LocalError(n.info, errIndexOutOfBounds) else: nil proc foldFieldAccess(m: PSym, n: PNode): PNode = # a real field access; proc calls have already been transformed var x = getConstExpr(m, n.sons[0]) if x == nil or x.kind != nkPar: return var field = n.sons[1].sym for i in countup(0, 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(n.info, errFieldXNotFound, field.name.s) proc foldConStrStr(m: PSym, n: PNode): 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]) if a == nil: return nil result.strVal.add(getStrOrChar(a)) proc getConstExpr(m: PSym, n: PNode): PNode = result = nil case n.kind of nkSym: var s = n.sym if s.kind == skEnumField: result = newIntNodeT(s.position, n) elif s.kind == skConst: case s.magic of mIsMainModule: result = newIntNodeT(ord(sfMainModule in m.flags), n) of mCompileDate: result = newStrNodeT(times.getDateStr(), n) of mCompileTime: result = newStrNodeT(times.getClockStr(), n) of mNimrodVersion: result = newStrNodeT(VersionAsString, n) of mNimrodMajor: result = newIntNodeT(VersionMajor, n) of mNimrodMinor: result = newIntNodeT(VersionMinor, n) of mNimrodPatch: result = newIntNodeT(VersionPatch, n) of mCpuEndian: result = newIntNodeT(ord(CPU[targetCPU].endian), n) of mHostOS: result = newStrNodeT(toLower(platform.OS[targetOS].name), n) of mHostCPU: result = newStrNodeT(platform.CPU[targetCPU].name.toLower, n) of mAppType: result = getAppType(n) of mNaN: result = newFloatNodeT(NaN, n) of mInf: result = newFloatNodeT(Inf, n) of mNegInf: result = newFloatNodeT(NegInf, n) else: if sfFakeConst notin s.flags: result = copyTree(s.ast) elif s.kind in {skProc, skMethod}: # BUGFIX result = n of nkCharLit..nkNilLit: result = copyNode(n) of nkIfExpr: result = getConstIfExpr(m, n) of nkCall, nkCommand, nkCallStrLit, nkPrefix, nkInfix: if n.sons[0].kind != nkSym: return var s = n.sons[0].sym if s.kind != skProc: return try: case s.magic of mNone: return # XXX: if it has no sideEffect, it should be evaluated of mSizeOf: var a = n.sons[1] if computeSize(a.typ) < 0: LocalError(a.info, errCannotEvalXBecauseIncompletelyDefined, "sizeof") result = nil elif skipTypes(a.typ, abstractInst).kind in {tyArray,tyObject,tyTuple}: result = nil # XXX: size computation for complex types is still wrong else: result = newIntNodeT(getSize(a.typ), n) of mLow: result = newIntNodeT(firstOrd(n.sons[1].typ), n) of mHigh: if skipTypes(n.sons[1].typ, abstractVar).kind notin {tyOpenArray, tyVarargs, tySequence, tyString}: result = newIntNodeT(lastOrd(skipTypes(n[1].typ, abstractVar)), n) else: var a = getArrayConstr(m, n.sons[1]) if a.kind == nkBracket: # we can optimize it away: result = newIntNodeT(sonsLen(a)-1, n) of mLengthOpenArray: var a = getArrayConstr(m, n.sons[1]) if a.kind == nkBracket: # we can optimize it away! This fixes the bug ``len(134)``. result = newIntNodeT(sonsLen(a), n) else: result = magicCall(m, n) of mAstToStr: result = newStrNodeT(renderTree(n[1], {renderNoComments}), n) of mConStrStr: result = foldConStrStr(m, n) else: result = magicCall(m, n) except EOverflow: LocalError(n.info, errOverOrUnderflow) except EDivByZero: LocalError(n.info, errConstantDivisionByZero) of nkAddr: var a = getConstExpr(m, n.sons[0]) 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]) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) of nkRange: var a = getConstExpr(m, n.sons[0]) if a == nil: return var b = getConstExpr(m, n.sons[1]) 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]) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) of nkPar: # 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]) 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]) if a == nil: return nil result.sons[i] = a incl(result.flags, nfAllConst) of nkChckRangeF, nkChckRange64, nkChckRange: var a = getConstExpr(m, n.sons[0]) 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(n.info, errGenerated, `%`( msgKindToString(errIllegalConvFromXtoY), [typeToString(n.sons[0].typ), typeToString(n.typ)])) of nkStringToCString, nkCStringToString: var a = getConstExpr(m, n.sons[0]) if a == nil: return result = a result.typ = n.typ of nkHiddenStdConv, nkHiddenSubConv, nkConv, nkCast: var a = getConstExpr(m, n.sons[1]) if a == nil: return result = foldConv(n, a) of nkBracketExpr: result = foldArrayAccess(m, n) of nkDotExpr: result = foldFieldAccess(m, n) else: nil