# # # The Nim Compiler # (c) Copyright 2015 Andreas Rumpf # # See the file "copying.txt", included in this # distribution, for details about the copyright. # # # included from cgen.nim proc leftAppearsOnRightSide(le, ri: PNode): bool = if le != nil: for i in 1 ..< ri.len: let r = ri[i] if isPartOf(le, r) != arNo: return true proc hasNoInit(call: PNode): bool {.inline.} = result = call.sons[0].kind == nkSym and sfNoInit in call.sons[0].sym.flags proc fixupCall(p: BProc, le, ri: PNode, d: var TLoc, callee, params: Rope) = var pl = callee & ~"(" & params # getUniqueType() is too expensive here: var typ = skipTypes(ri.sons[0].typ, abstractInst) if typ.sons[0] != nil: if isInvalidReturnType(p.config, typ.sons[0]): if params != nil: pl.add(~", ") # beware of 'result = p(result)'. We may need to allocate a temporary: if d.k in {locTemp, locNone} or not leftAppearsOnRightSide(le, ri): # Great, we can use 'd': if d.k == locNone: getTemp(p, typ.sons[0], d, needsInit=true) elif d.k notin {locTemp} and not hasNoInit(ri): # reset before pass as 'result' var: discard "resetLoc(p, d)" add(pl, addrLoc(p.config, d)) add(pl, ~");$n") line(p, cpsStmts, pl) else: var tmp: TLoc getTemp(p, typ.sons[0], tmp, needsInit=true) add(pl, addrLoc(p.config, tmp)) add(pl, ~");$n") line(p, cpsStmts, pl) genAssignment(p, d, tmp, {}) # no need for deep copying else: add(pl, ~")") if p.module.compileToCpp and lfSingleUse in d.flags: # do not generate spurious temporaries for C++! For C we're better off # with them to prevent undefined behaviour and because the codegen # is free to emit expressions multiple times! d.k = locCall d.r = pl excl d.flags, lfSingleUse else: if d.k == locNone: getTemp(p, typ.sons[0], d) assert(d.t != nil) # generate an assignment to d: var list: TLoc initLoc(list, locCall, d.lode, OnUnknown) list.r = pl genAssignment(p, d, list, {}) # no need for deep copying else: add(pl, ~");$n") line(p, cpsStmts, pl) proc isInCurrentFrame(p: BProc, n: PNode): bool = # checks if `n` is an expression that refers to the current frame; # this does not work reliably because of forwarding + inlining can break it case n.kind of nkSym: if n.sym.kind in {skVar, skResult, skTemp, skLet} and p.prc != nil: result = p.prc.id == n.sym.owner.id of nkDotExpr, nkBracketExpr: if skipTypes(n.sons[0].typ, abstractInst).kind notin {tyVar,tyLent,tyPtr,tyRef}: result = isInCurrentFrame(p, n.sons[0]) of nkHiddenStdConv, nkHiddenSubConv, nkConv: result = isInCurrentFrame(p, n.sons[1]) of nkHiddenDeref, nkDerefExpr: # what about: var x = addr(y); callAsOpenArray(x[])? # *shrug* ``addr`` is unsafe anyway. result = false of nkObjUpConv, nkObjDownConv, nkCheckedFieldExpr: result = isInCurrentFrame(p, n.sons[0]) else: discard proc genBoundsCheck(p: BProc; arr, a, b: TLoc) proc openArrayLoc(p: BProc, n: PNode): Rope = var a: TLoc let q = skipConv(n) if getMagic(q) == mSlice: # magic: pass slice to openArray: var b, c: TLoc initLocExpr(p, q[1], a) initLocExpr(p, q[2], b) initLocExpr(p, q[3], c) # but first produce the required index checks: if optBoundsCheck in p.options: genBoundsCheck(p, a, b, c) let ty = skipTypes(a.t, abstractVar+{tyPtr}) case ty.kind of tyArray: let first = firstOrd(p.config, ty) if first == 0: result = "($1)+($2), ($3)-($2)+1" % [rdLoc(a), rdLoc(b), rdLoc(c)] else: result = "($1)+(($2)-($4)), ($3)-($2)+1" % [rdLoc(a), rdLoc(b), rdLoc(c), intLiteral(first)] of tyOpenArray, tyVarargs: result = "($1)+($2), ($3)-($2)+1" % [rdLoc(a), rdLoc(b), rdLoc(c)] of tyString, tySequence: if skipTypes(n.typ, abstractInst).kind == tyVar and not compileToCpp(p.module): result = "(*$1)$4+($2), ($3)-($2)+1" % [rdLoc(a), rdLoc(b), rdLoc(c), dataField(p)] else: result = "$1$4+($2), ($3)-($2)+1" % [rdLoc(a), rdLoc(b), rdLoc(c), dataField(p)] else: internalError(p.config, "openArrayLoc: " & typeToString(a.t)) else: initLocExpr(p, n, a) case skipTypes(a.t, abstractVar).kind of tyOpenArray, tyVarargs: result = "$1, $1Len_0" % [rdLoc(a)] of tyString, tySequence: if skipTypes(n.typ, abstractInst).kind == tyVar and not compileToCpp(p.module): result = "(*$1)$3, (*$1 ? (*$1)->$2 : 0)" % [a.rdLoc, lenField(p), dataField(p)] else: result = "$1$3, ($1 ? $1->$2 : 0)" % [a.rdLoc, lenField(p), dataField(p)] of tyArray: result = "$1, $2" % [rdLoc(a), rope(lengthOrd(p.config, a.t))] of tyPtr, tyRef: case lastSon(a.t).kind of tyString, tySequence: result = "(*$1)$3, (*$1 ? (*$1)->$2 : 0)" % [a.rdLoc, lenField(p), dataField(p)] of tyArray: result = "$1, $2" % [rdLoc(a), rope(lengthOrd(p.config, lastSon(a.t)))] else: internalError(p.config, "openArrayLoc: " & typeToString(a.t)) else: internalError(p.config, "openArrayLoc: " & typeToString(a.t)) proc genArgStringToCString(p: BProc, n: PNode): Rope {.inline.} = var a: TLoc initLocExpr(p, n.sons[0], a) result = ropecg(p.module, "#nimToCStringConv($1)", [a.rdLoc]) proc genArg(p: BProc, n: PNode, param: PSym; call: PNode): Rope = var a: TLoc if n.kind == nkStringToCString: result = genArgStringToCString(p, n) elif skipTypes(param.typ, abstractVar).kind in {tyOpenArray, tyVarargs}: var n = if n.kind != nkHiddenAddr: n else: n.sons[0] result = openArrayLoc(p, n) elif ccgIntroducedPtr(p.config, param): initLocExpr(p, n, a) result = addrLoc(p.config, a) elif p.module.compileToCpp and param.typ.kind == tyVar and n.kind == nkHiddenAddr: initLocExprSingleUse(p, n.sons[0], a) # if the proc is 'importc'ed but not 'importcpp'ed then 'var T' still # means '*T'. See posix.nim for lots of examples that do that in the wild. let callee = call.sons[0] if callee.kind == nkSym and {sfImportC, sfInfixCall, sfCompilerProc} * callee.sym.flags == {sfImportC} and {lfHeader, lfNoDecl} * callee.sym.loc.flags != {}: result = addrLoc(p.config, a) else: result = rdLoc(a) else: initLocExprSingleUse(p, n, a) result = rdLoc(a) proc genArgNoParam(p: BProc, n: PNode): Rope = var a: TLoc if n.kind == nkStringToCString: result = genArgStringToCString(p, n) else: initLocExprSingleUse(p, n, a) result = rdLoc(a) template genParamLoop(params) {.dirty.} = if i < sonsLen(typ): assert(typ.n.sons[i].kind == nkSym) let paramType = typ.n.sons[i] if not paramType.typ.isCompileTimeOnly: if params != nil: add(params, ~", ") add(params, genArg(p, ri.sons[i], paramType.sym, ri)) else: if params != nil: add(params, ~", ") add(params, genArgNoParam(p, ri.sons[i])) proc genPrefixCall(p: BProc, le, ri: PNode, d: var TLoc) = var op: TLoc # this is a hotspot in the compiler initLocExpr(p, ri.sons[0], op) var params: Rope # getUniqueType() is too expensive here: var typ = skipTypes(ri.sons[0].typ, abstractInst) assert(typ.kind == tyProc) assert(sonsLen(typ) == sonsLen(typ.n)) var length = sonsLen(ri) for i in countup(1, length - 1): genParamLoop(params) fixupCall(p, le, ri, d, op.r, params) proc genClosureCall(p: BProc, le, ri: PNode, d: var TLoc) = proc getRawProcType(p: BProc, t: PType): Rope = result = getClosureType(p.module, t, clHalf) proc addComma(r: Rope): Rope = result = if r == nil: r else: r & ~", " const PatProc = "$1.ClE_0? $1.ClP_0($3$1.ClE_0):(($4)($1.ClP_0))($2)" const PatIter = "$1.ClP_0($3$1.ClE_0)" # we know the env exists var op: TLoc initLocExpr(p, ri.sons[0], op) var pl: Rope var typ = skipTypes(ri.sons[0].typ, abstractInst) assert(typ.kind == tyProc) var length = sonsLen(ri) for i in countup(1, length - 1): assert(sonsLen(typ) == sonsLen(typ.n)) genParamLoop(pl) template genCallPattern {.dirty.} = lineF(p, cpsStmts, callPattern & ";$n", [op.r, pl, pl.addComma, rawProc]) let rawProc = getRawProcType(p, typ) let callPattern = if tfIterator in typ.flags: PatIter else: PatProc if typ.sons[0] != nil: if isInvalidReturnType(p.config, typ.sons[0]): if sonsLen(ri) > 1: add(pl, ~", ") # beware of 'result = p(result)'. We may need to allocate a temporary: if d.k in {locTemp, locNone} or not leftAppearsOnRightSide(le, ri): # Great, we can use 'd': if d.k == locNone: getTemp(p, typ.sons[0], d, needsInit=true) elif d.k notin {locTemp} and not hasNoInit(ri): # reset before pass as 'result' var: discard "resetLoc(p, d)" add(pl, addrLoc(p.config, d)) genCallPattern() else: var tmp: TLoc getTemp(p, typ.sons[0], tmp, needsInit=true) add(pl, addrLoc(p.config, tmp)) genCallPattern() genAssignment(p, d, tmp, {}) # no need for deep copying else: if d.k == locNone: getTemp(p, typ.sons[0], d) assert(d.t != nil) # generate an assignment to d: var list: TLoc initLoc(list, locCall, d.lode, OnUnknown) list.r = callPattern % [op.r, pl, pl.addComma, rawProc] genAssignment(p, d, list, {}) # no need for deep copying else: genCallPattern() proc genOtherArg(p: BProc; ri: PNode; i: int; typ: PType): Rope = if i < sonsLen(typ): # 'var T' is 'T&' in C++. This means we ignore the request of # any nkHiddenAddr when it's a 'var T'. let paramType = typ.n.sons[i] assert(paramType.kind == nkSym) if paramType.typ.isCompileTimeOnly: result = nil elif typ.sons[i].kind == tyVar and ri.sons[i].kind == nkHiddenAddr: result = genArgNoParam(p, ri.sons[i][0]) else: result = genArgNoParam(p, ri.sons[i]) #, typ.n.sons[i].sym) else: if tfVarargs notin typ.flags: localError(p.config, ri.info, "wrong argument count") result = nil else: result = genArgNoParam(p, ri.sons[i]) discard """ Dot call syntax in C++ ====================== so c2nim translates 'this' sometimes to 'T' and sometimes to 'var T' both of which are wrong, but often more convenient to use. For manual wrappers it can also be 'ptr T' Fortunately we know which parameter is the 'this' parameter and so can fix this mess in the codegen. now ... if the *argument* is a 'ptr' the codegen shall emit -> and otherwise . but this only depends on the argument and not on how the 'this' was declared however how the 'this' was declared affects whether we end up with wrong 'addr' and '[]' ops... Since I'm tired I'll enumerate all the cases here: var x: ptr T y: T proc t(x: T) x[].t() --> (*x).t() is correct. y.t() --> y.t() is correct proc u(x: ptr T) x.u() --> needs to become x->u() (addr y).u() --> needs to become y.u() proc v(x: var T) --> first skip the implicit 'nkAddr' node x[].v() --> (*x).v() is correct, but might have been eliminated due to the nkAddr node! So for this case we need to generate '->' y.v() --> y.v() is correct """ proc skipAddrDeref(node: PNode): PNode = var n = node var isAddr = false case n.kind of nkAddr, nkHiddenAddr: n = n.sons[0] isAddr = true of nkDerefExpr, nkHiddenDeref: n = n.sons[0] else: return n if n.kind == nkObjDownConv: n = n.sons[0] if isAddr and n.kind in {nkDerefExpr, nkHiddenDeref}: result = n.sons[0] elif n.kind in {nkAddr, nkHiddenAddr}: result = n.sons[0] else: result = node proc genThisArg(p: BProc; ri: PNode; i: int; typ: PType): Rope = # for better or worse c2nim translates the 'this' argument to a 'var T'. # However manual wrappers may also use 'ptr T'. In any case we support both # for convenience. internalAssert p.config, i < sonsLen(typ) assert(typ.n.sons[i].kind == nkSym) # if the parameter is lying (tyVar) and thus we required an additional deref, # skip the deref: var ri = ri[i] while ri.kind == nkObjDownConv: ri = ri[0] let t = typ.sons[i].skipTypes({tyGenericInst, tyAlias, tySink}) if t.kind == tyVar: let x = if ri.kind == nkHiddenAddr: ri[0] else: ri if x.typ.kind == tyPtr: result = genArgNoParam(p, x) result.add("->") elif x.kind in {nkHiddenDeref, nkDerefExpr} and x[0].typ.kind == tyPtr: result = genArgNoParam(p, x[0]) result.add("->") else: result = genArgNoParam(p, x) result.add(".") elif t.kind == tyPtr: if ri.kind in {nkAddr, nkHiddenAddr}: result = genArgNoParam(p, ri[0]) result.add(".") else: result = genArgNoParam(p, ri) result.add("->") else: ri = skipAddrDeref(ri) if ri.kind in {nkAddr, nkHiddenAddr}: ri = ri[0] result = genArgNoParam(p, ri) #, typ.n.sons[i].sym) result.add(".") proc genPatternCall(p: BProc; ri: PNode; pat: string; typ: PType): Rope = var i = 0 var j = 1 while i < pat.len: case pat[i] of '@': if j < ri.len: result.add genOtherArg(p, ri, j, typ) for k in j+1 ..< ri.len: result.add(~", ") result.add genOtherArg(p, ri, k, typ) inc i of '#': if pat[i+1] in {'+', '@'}: let ri = ri[j] if ri.kind in nkCallKinds: let typ = skipTypes(ri.sons[0].typ, abstractInst) if pat[i+1] == '+': result.add genArgNoParam(p, ri.sons[0]) result.add(~"(") if 1 < ri.len: result.add genOtherArg(p, ri, 1, typ) for k in j+1 ..< ri.len: result.add(~", ") result.add genOtherArg(p, ri, k, typ) result.add(~")") else: localError(p.config, ri.info, "call expression expected for C++ pattern") inc i elif pat[i+1] == '.': result.add genThisArg(p, ri, j, typ) inc i elif pat[i+1] == '[': var arg = ri.sons[j].skipAddrDeref while arg.kind in {nkAddr, nkHiddenAddr, nkObjDownConv}: arg = arg[0] result.add genArgNoParam(p, arg) #result.add debugTree(arg, 0, 10) else: result.add genOtherArg(p, ri, j, typ) inc j inc i of '\'': var idx, stars: int if scanCppGenericSlot(pat, i, idx, stars): var t = resolveStarsInCppType(typ, idx, stars) if t == nil: result.add(~"void") else: result.add(getTypeDesc(p.module, t)) else: let start = i while i < pat.len: if pat[i] notin {'@', '#', '\''}: inc(i) else: break if i - 1 >= start: add(result, substr(pat, start, i - 1)) proc genInfixCall(p: BProc, le, ri: PNode, d: var TLoc) = var op: TLoc initLocExpr(p, ri.sons[0], op) # getUniqueType() is too expensive here: var typ = skipTypes(ri.sons[0].typ, abstractInst) assert(typ.kind == tyProc) var length = sonsLen(ri) assert(sonsLen(typ) == sonsLen(typ.n)) # don't call '$' here for efficiency: let pat = ri.sons[0].sym.loc.r.data internalAssert p.config, pat != nil if pat.contains({'#', '(', '@', '\''}): var pl = genPatternCall(p, ri, pat, typ) # simpler version of 'fixupCall' that works with the pl+params combination: var typ = skipTypes(ri.sons[0].typ, abstractInst) if typ.sons[0] != nil: if p.module.compileToCpp and lfSingleUse in d.flags: # do not generate spurious temporaries for C++! For C we're better off # with them to prevent undefined behaviour and because the codegen # is free to emit expressions multiple times! d.k = locCall d.r = pl excl d.flags, lfSingleUse else: if d.k == locNone: getTemp(p, typ.sons[0], d) assert(d.t != nil) # generate an assignment to d: var list: TLoc initLoc(list, locCall, d.lode, OnUnknown) list.r = pl genAssignment(p, d, list, {}) # no need for deep copying else: add(pl, ~";$n") line(p, cpsStmts, pl) else: var pl: Rope = nil #var param = typ.n.sons[1].sym if 1 < ri.len: add(pl, genThisArg(p, ri, 1, typ)) add(pl, op.r) var params: Rope for i in countup(2, length - 1): if params != nil: params.add(~", ") assert(sonsLen(typ) == sonsLen(typ.n)) add(params, genOtherArg(p, ri, i, typ)) fixupCall(p, le, ri, d, pl, params) proc genNamedParamCall(p: BProc, ri: PNode, d: var TLoc) = # generates a crappy ObjC call var op: TLoc initLocExpr(p, ri.sons[0], op) var pl = ~"[" # getUniqueType() is too expensive here: var typ = skipTypes(ri.sons[0].typ, abstractInst) assert(typ.kind == tyProc) var length = sonsLen(ri) assert(sonsLen(typ) == sonsLen(typ.n)) # don't call '$' here for efficiency: let pat = ri.sons[0].sym.loc.r.data internalAssert p.config, pat != nil var start = 3 if ' ' in pat: start = 1 add(pl, op.r) if length > 1: add(pl, ~": ") add(pl, genArg(p, ri.sons[1], typ.n.sons[1].sym, ri)) start = 2 else: if length > 1: add(pl, genArg(p, ri.sons[1], typ.n.sons[1].sym, ri)) add(pl, ~" ") add(pl, op.r) if length > 2: add(pl, ~": ") add(pl, genArg(p, ri.sons[2], typ.n.sons[2].sym, ri)) for i in countup(start, length-1): assert(sonsLen(typ) == sonsLen(typ.n)) if i >= sonsLen(typ): internalError(p.config, ri.info, "varargs for objective C method?") assert(typ.n.sons[i].kind == nkSym) var param = typ.n.sons[i].sym add(pl, ~" ") add(pl, param.name.s) add(pl, ~": ") add(pl, genArg(p, ri.sons[i], param, ri)) if typ.sons[0] != nil: if isInvalidReturnType(p.config, typ.sons[0]): if sonsLen(ri) > 1: add(pl, ~" ") # beware of 'result = p(result)'. We always allocate a temporary: if d.k in {locTemp, locNone}: # We already got a temp. Great, special case it: if d.k == locNone: getTemp(p, typ.sons[0], d, needsInit=true) add(pl, ~"Result: ") add(pl, addrLoc(p.config, d)) add(pl, ~"];$n") line(p, cpsStmts, pl) else: var tmp: TLoc getTemp(p, typ.sons[0], tmp, needsInit=true) add(pl, addrLoc(p.config, tmp)) add(pl, ~"];$n") line(p, cpsStmts, pl) genAssignment(p, d, tmp, {}) # no need for deep copying else: add(pl, ~"]") if d.k == locNone: getTemp(p, typ.sons[0], d) assert(d.t != nil) # generate an assignment to d: var list: TLoc initLoc(list, locCall, ri, OnUnknown) list.r = pl genAssignment(p, d, list, {}) # no need for deep copying else: add(pl, ~"];$n") line(p, cpsStmts, pl) proc genCall(p: BProc, e: PNode, d: var TLoc) = if e.sons[0].typ.skipTypes({tyGenericInst, tyAlias, tySink}).callConv == ccClosure: genClosureCall(p, nil, e, d) elif e.sons[0].kind == nkSym and sfInfixCall in e.sons[0].sym.flags: genInfixCall(p, nil, e, d) elif e.sons[0].kind == nkSym and sfNamedParamCall in e.sons[0].sym.flags: genNamedParamCall(p, e, d) else: genPrefixCall(p, nil, e, d) postStmtActions(p) proc genAsgnCall(p: BProc, le, ri: PNode, d: var TLoc) = if ri.sons[0].typ.skipTypes({tyGenericInst, tyAlias, tySink}).callConv == ccClosure: genClosureCall(p, le, ri, d) elif ri.sons[0].kind == nkSym and sfInfixCall in ri.sons[0].sym.flags: genInfixCall(p, le, ri, d) elif ri.sons[0].kind == nkSym and sfNamedParamCall in ri.sons[0].sym.flags: genNamedParamCall(p, ri, d) else: genPrefixCall(p, le, ri, d) postStmtActions(p)