/** * Handle introspection functionality of the `__traits()` construct. * * Specification: $(LINK2 https://dlang.org/spec/traits.html, Traits) * * Copyright: Copyright (C) 1999-2022 by The D Language Foundation, All Rights Reserved * Authors: $(LINK2 https://www.digitalmars.com, Walter Bright) * License: $(LINK2 https://www.boost.org/LICENSE_1_0.txt, Boost License 1.0) * Source: $(LINK2 https://github.com/dlang/dmd/blob/master/src/dmd/traits.d, _traits.d) * Documentation: https://dlang.org/phobos/dmd_traits.html * Coverage: https://codecov.io/gh/dlang/dmd/src/master/src/dmd/traits.d */ module dmd.traits; import core.stdc.stdio; import dmd.aggregate; import dmd.arraytypes; import dmd.astcodegen; import dmd.astenums; import dmd.attrib; import dmd.canthrow; import dmd.dclass; import dmd.declaration; import dmd.dimport; import dmd.dmangle; import dmd.dmodule; import dmd.dscope; import dmd.dsymbol; import dmd.dsymbolsem; import dmd.dtemplate; import dmd.errors; import dmd.expression; import dmd.expressionsem; import dmd.func; import dmd.globals; import dmd.hdrgen; import dmd.id; import dmd.identifier; import dmd.mtype; import dmd.nogc; import dmd.parse; import dmd.root.array; import dmd.root.speller; import dmd.root.stringtable; import dmd.target; import dmd.tokens; import dmd.typesem; import dmd.visitor; import dmd.root.rootobject; import dmd.common.outbuffer; import dmd.root.string; enum LOGSEMANTIC = false; /************************ TraitsExp ************************************/ /************************************** * Convert `Expression` or `Type` to corresponding `Dsymbol`, additionally * stripping off expression contexts. * * Some symbol related `__traits` ignore arguments expression contexts. * For example: * ---- * struct S { void f() {} } * S s; * pragma(msg, __traits(isNested, s.f)); * // s.f is `DotVarExp`, but `__traits(isNested)`` needs a `FuncDeclaration`. * ---- * * This is used for that common `__traits` behavior. * * Input: * oarg object to get the symbol for * Returns: * Dsymbol the corresponding symbol for oarg */ private Dsymbol getDsymbolWithoutExpCtx(RootObject oarg) { if (auto e = isExpression(oarg)) { if (auto dve = e.isDotVarExp()) return dve.var; if (auto dte = e.isDotTemplateExp()) return dte.td; } return getDsymbol(oarg); } private const StringTable!bool traitsStringTable; shared static this() { static immutable string[] names = [ "isAbstractClass", "isArithmetic", "isAssociativeArray", "isDisabled", "isDeprecated", "isFuture", "isFinalClass", "isPOD", "isNested", "isFloating", "isIntegral", "isScalar", "isStaticArray", "isUnsigned", "isVirtualFunction", "isVirtualMethod", "isAbstractFunction", "isFinalFunction", "isOverrideFunction", "isStaticFunction", "isModule", "isPackage", "isRef", "isOut", "isLazy", "isReturnOnStack", "hasMember", "identifier", "getProtection", "getVisibility", "parent", "child", "getLinkage", "getMember", "getOverloads", "getVirtualFunctions", "getVirtualMethods", "classInstanceSize", "classInstanceAlignment", "allMembers", "derivedMembers", "isSame", "compiles", "getAliasThis", "getAttributes", "getFunctionAttributes", "getFunctionVariadicStyle", "getParameterStorageClasses", "getUnitTests", "getVirtualIndex", "getPointerBitmap", "isZeroInit", "getTargetInfo", "getLocation", "hasPostblit", "hasCopyConstructor", "isCopyable", "parameters" ]; StringTable!(bool)* stringTable = cast(StringTable!(bool)*) &traitsStringTable; stringTable._init(names.length); foreach (s; names) { auto sv = stringTable.insert(s, true); assert(sv); } } /** * get an array of size_t values that indicate possible pointer words in memory * if interpreted as the type given as argument * Returns: the size of the type in bytes, ulong.max on error */ ulong getTypePointerBitmap(Loc loc, Type t, Array!(ulong)* data) { ulong sz; if (t.ty == Tclass && !(cast(TypeClass)t).sym.isInterfaceDeclaration()) sz = (cast(TypeClass)t).sym.AggregateDeclaration.size(loc); else sz = t.size(loc); if (sz == SIZE_INVALID) return ulong.max; const sz_size_t = Type.tsize_t.size(loc); if (sz > sz.max - sz_size_t) { error(loc, "size overflow for type `%s`", t.toChars()); return ulong.max; } ulong bitsPerWord = sz_size_t * 8; ulong cntptr = (sz + sz_size_t - 1) / sz_size_t; ulong cntdata = (cntptr + bitsPerWord - 1) / bitsPerWord; data.setDim(cast(size_t)cntdata); data.zero(); extern (C++) final class PointerBitmapVisitor : Visitor { alias visit = Visitor.visit; public: extern (D) this(Array!(ulong)* _data, ulong _sz_size_t) { this.data = _data; this.sz_size_t = _sz_size_t; } void setpointer(ulong off) { ulong ptroff = off / sz_size_t; (*data)[cast(size_t)(ptroff / (8 * sz_size_t))] |= 1L << (ptroff % (8 * sz_size_t)); } override void visit(Type t) { Type tb = t.toBasetype(); if (tb != t) tb.accept(this); } override void visit(TypeError t) { visit(cast(Type)t); } override void visit(TypeNext t) { assert(0); } override void visit(TypeBasic t) { if (t.ty == Tvoid) setpointer(offset); } override void visit(TypeVector t) { } override void visit(TypeArray t) { assert(0); } override void visit(TypeSArray t) { ulong arrayoff = offset; ulong nextsize = t.next.size(); if (nextsize == SIZE_INVALID) error = true; ulong dim = t.dim.toInteger(); for (ulong i = 0; i < dim; i++) { offset = arrayoff + i * nextsize; t.next.accept(this); } offset = arrayoff; } override void visit(TypeDArray t) { setpointer(offset + sz_size_t); } // dynamic array is {length,ptr} override void visit(TypeAArray t) { setpointer(offset); } override void visit(TypePointer t) { if (t.nextOf().ty != Tfunction) // don't mark function pointers setpointer(offset); } override void visit(TypeReference t) { setpointer(offset); } override void visit(TypeClass t) { setpointer(offset); } override void visit(TypeFunction t) { } override void visit(TypeDelegate t) { setpointer(offset); } // delegate is {context, function} override void visit(TypeQualified t) { assert(0); } // assume resolved override void visit(TypeIdentifier t) { assert(0); } override void visit(TypeInstance t) { assert(0); } override void visit(TypeTypeof t) { assert(0); } override void visit(TypeReturn t) { assert(0); } override void visit(TypeEnum t) { visit(cast(Type)t); } override void visit(TypeTuple t) { visit(cast(Type)t); } override void visit(TypeSlice t) { assert(0); } override void visit(TypeNull t) { // always a null pointer } override void visit(TypeStruct t) { ulong structoff = offset; foreach (v; t.sym.fields) { offset = structoff + v.offset; if (v.type.ty == Tclass) setpointer(offset); else v.type.accept(this); } offset = structoff; } // a "toplevel" class is treated as an instance, while TypeClass fields are treated as references void visitClass(TypeClass t) { ulong classoff = offset; // skip vtable-ptr and monitor if (t.sym.baseClass) visitClass(cast(TypeClass)t.sym.baseClass.type); foreach (v; t.sym.fields) { offset = classoff + v.offset; v.type.accept(this); } offset = classoff; } Array!(ulong)* data; ulong offset; ulong sz_size_t; bool error; } scope PointerBitmapVisitor pbv = new PointerBitmapVisitor(data, sz_size_t); if (t.ty == Tclass) pbv.visitClass(cast(TypeClass)t); else t.accept(pbv); return pbv.error ? ulong.max : sz; } /** * get an array of size_t values that indicate possible pointer words in memory * if interpreted as the type given as argument * the first array element is the size of the type for independent interpretation * of the array * following elements bits represent one word (4/8 bytes depending on the target * architecture). If set the corresponding memory might contain a pointer/reference. * * Returns: [T.sizeof, pointerbit0-31/63, pointerbit32/64-63/128, ...] */ private Expression pointerBitmap(TraitsExp e) { if (!e.args || e.args.dim != 1) { error(e.loc, "a single type expected for trait pointerBitmap"); return ErrorExp.get(); } Type t = getType((*e.args)[0]); if (!t) { error(e.loc, "`%s` is not a type", (*e.args)[0].toChars()); return ErrorExp.get(); } Array!(ulong) data; ulong sz = getTypePointerBitmap(e.loc, t, &data); if (sz == ulong.max) return ErrorExp.get(); auto exps = new Expressions(data.dim + 1); (*exps)[0] = new IntegerExp(e.loc, sz, Type.tsize_t); foreach (size_t i; 1 .. exps.dim) (*exps)[i] = new IntegerExp(e.loc, data[cast(size_t) (i - 1)], Type.tsize_t); auto ale = new ArrayLiteralExp(e.loc, Type.tsize_t.sarrayOf(data.dim + 1), exps); return ale; } Expression semanticTraits(TraitsExp e, Scope* sc) { static if (LOGSEMANTIC) { printf("TraitsExp::semantic() %s\n", e.toChars()); } if (e.ident != Id.compiles && e.ident != Id.isSame && e.ident != Id.identifier && e.ident != Id.getProtection && e.ident != Id.getVisibility && e.ident != Id.getAttributes) { // Pretend we're in a deprecated scope so that deprecation messages // aren't triggered when checking if a symbol is deprecated const save = sc.stc; if (e.ident == Id.isDeprecated) sc.stc |= STC.deprecated_; if (!TemplateInstance.semanticTiargs(e.loc, sc, e.args, 1)) { sc.stc = save; return ErrorExp.get(); } sc.stc = save; } size_t dim = e.args ? e.args.dim : 0; Expression dimError(int expected) { e.error("expected %d arguments for `%s` but had %d", expected, e.ident.toChars(), cast(int)dim); return ErrorExp.get(); } static IntegerExp True() { return IntegerExp.createBool(true); } static IntegerExp False() { return IntegerExp.createBool(false); } /******** * Gets the function type from a given AST node * if the node is a function of some sort. * Params: * o = an AST node to check for a `TypeFunction` * fdp = if `o` is a FuncDeclaration then fdp is set to that, otherwise `null` * Returns: * a type node if `o` is a declaration of * a delegate, function, function-pointer or a variable of the former. * Otherwise, `null`. */ static TypeFunction toTypeFunction(RootObject o, out FuncDeclaration fdp) { Type t; if (auto s = getDsymbolWithoutExpCtx(o)) { if (auto fd = s.isFuncDeclaration()) { t = fd.type; fdp = fd; } else if (auto vd = s.isVarDeclaration()) t = vd.type; else t = isType(o); } else t = isType(o); if (t) { if (auto tf = t.isFunction_Delegate_PtrToFunction()) return tf; } return null; } IntegerExp isX(T)(bool delegate(T) fp) { if (!dim) return False(); foreach (o; *e.args) { static if (is(T == Type)) auto y = getType(o); static if (is(T : Dsymbol)) { auto s = getDsymbolWithoutExpCtx(o); if (!s) return False(); } static if (is(T == Dsymbol)) alias y = s; static if (is(T == Declaration)) auto y = s.isDeclaration(); static if (is(T == FuncDeclaration)) auto y = s.isFuncDeclaration(); if (!y || !fp(y)) return False(); } return True(); } alias isTypeX = isX!Type; alias isDsymX = isX!Dsymbol; alias isDeclX = isX!Declaration; alias isFuncX = isX!FuncDeclaration; Expression isPkgX(bool function(Package) fp) { return isDsymX((Dsymbol sym) { Package p = resolveIsPackage(sym); return (p !is null) && fp(p); }); } if (e.ident == Id.isArithmetic) { return isTypeX(t => t.isintegral() || t.isfloating()); } if (e.ident == Id.isFloating) { return isTypeX(t => t.isfloating()); } if (e.ident == Id.isIntegral) { return isTypeX(t => t.isintegral()); } if (e.ident == Id.isScalar) { return isTypeX(t => t.isscalar()); } if (e.ident == Id.isUnsigned) { return isTypeX(t => t.isunsigned()); } if (e.ident == Id.isAssociativeArray) { return isTypeX(t => t.toBasetype().ty == Taarray); } if (e.ident == Id.isDeprecated) { if (isTypeX(t => t.iscomplex() || t.isimaginary()).toBool().hasValue(true)) return True(); return isDsymX(t => t.isDeprecated()); } if (e.ident == Id.isFuture) { return isDeclX(t => t.isFuture()); } if (e.ident == Id.isStaticArray) { return isTypeX(t => t.toBasetype().ty == Tsarray); } if (e.ident == Id.isAbstractClass) { return isTypeX(t => t.toBasetype().ty == Tclass && (cast(TypeClass)t.toBasetype()).sym.isAbstract()); } if (e.ident == Id.isFinalClass) { return isTypeX(t => t.toBasetype().ty == Tclass && ((cast(TypeClass)t.toBasetype()).sym.storage_class & STC.final_) != 0); } if (e.ident == Id.isTemplate) { if (dim != 1) return dimError(1); return isDsymX((s) { if (!s.toAlias().isOverloadable()) return false; return overloadApply(s, sm => sm.isTemplateDeclaration() !is null) != 0; }); } if (e.ident == Id.isPOD) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto t = isType(o); if (!t) { e.error("type expected as second argument of __traits `%s` instead of `%s`", e.ident.toChars(), o.toChars()); return ErrorExp.get(); } Type tb = t.baseElemOf(); if (auto sd = tb.ty == Tstruct ? (cast(TypeStruct)tb).sym : null) { return sd.isPOD() ? True() : False(); } return True(); } if (e.ident == Id.hasCopyConstructor || e.ident == Id.hasPostblit) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto t = isType(o); if (!t) { e.error("type expected as second argument of __traits `%s` instead of `%s`", e.ident.toChars(), o.toChars()); return ErrorExp.get(); } Type tb = t.baseElemOf(); if (auto sd = tb.ty == Tstruct ? (cast(TypeStruct)tb).sym : null) { return (e.ident == Id.hasPostblit) ? (sd.postblit ? True() : False()) : (sd.hasCopyCtor ? True() : False()); } return False(); } if (e.ident == Id.isCopyable) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto t = isType(o); if (!t) { e.error("type expected as second argument of __traits `%s` instead of `%s`", e.ident.toChars(), o.toChars()); return ErrorExp.get(); } t = t.toBasetype(); // get the base in case `t` is an `enum` if (auto ts = t.isTypeStruct()) { ts.sym.dsymbolSemantic(sc); } return isCopyable(t) ? True() : False(); } if (e.ident == Id.isNested) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); if (!s) { } else if (auto ad = s.isAggregateDeclaration()) { return ad.isNested() ? True() : False(); } else if (auto fd = s.isFuncDeclaration()) { return fd.isNested() ? True() : False(); } e.error("aggregate or function expected instead of `%s`", o.toChars()); return ErrorExp.get(); } if (e.ident == Id.isDisabled) { if (dim != 1) return dimError(1); return isDeclX(f => f.isDisabled()); } if (e.ident == Id.isAbstractFunction) { if (dim != 1) return dimError(1); return isFuncX(f => f.isAbstract()); } if (e.ident == Id.isVirtualFunction) { if (dim != 1) return dimError(1); return isFuncX(f => f.isVirtual()); } if (e.ident == Id.isVirtualMethod) { if (dim != 1) return dimError(1); return isFuncX(f => f.isVirtualMethod()); } if (e.ident == Id.isFinalFunction) { if (dim != 1) return dimError(1); return isFuncX(f => f.isFinalFunc()); } if (e.ident == Id.isOverrideFunction) { if (dim != 1) return dimError(1); return isFuncX(f => f.isOverride()); } if (e.ident == Id.isStaticFunction) { if (dim != 1) return dimError(1); return isFuncX(f => !f.needThis() && !f.isNested()); } if (e.ident == Id.isModule) { if (dim != 1) return dimError(1); return isPkgX(p => p.isModule() || p.isPackageMod()); } if (e.ident == Id.isPackage) { if (dim != 1) return dimError(1); return isPkgX(p => p.isModule() is null); } if (e.ident == Id.isRef) { if (dim != 1) return dimError(1); return isDeclX(d => d.isRef()); } if (e.ident == Id.isOut) { if (dim != 1) return dimError(1); return isDeclX(d => d.isOut()); } if (e.ident == Id.isLazy) { if (dim != 1) return dimError(1); return isDeclX(d => (d.storage_class & STC.lazy_) != 0); } if (e.ident == Id.identifier) { // Get identifier for symbol as a string literal /* Specify 0 for bit 0 of the flags argument to semanticTiargs() so that * a symbol should not be folded to a constant. * Bit 1 means don't convert Parameter to Type if Parameter has an identifier */ if (!TemplateInstance.semanticTiargs(e.loc, sc, e.args, 2)) return ErrorExp.get(); if (dim != 1) return dimError(1); auto o = (*e.args)[0]; Identifier id; if (auto po = isParameter(o)) { if (!po.ident) { e.error("argument `%s` has no identifier", po.type.toChars()); return ErrorExp.get(); } id = po.ident; } else { Dsymbol s = getDsymbolWithoutExpCtx(o); if (!s || !s.ident) { e.error("argument `%s` has no identifier", o.toChars()); return ErrorExp.get(); } id = s.ident; } auto se = new StringExp(e.loc, id.toString()); return se.expressionSemantic(sc); } if (e.ident == Id.getProtection || e.ident == Id.getVisibility) { if (dim != 1) return dimError(1); Scope* sc2 = sc.push(); sc2.flags = sc.flags | SCOPE.noaccesscheck | SCOPE.ignoresymbolvisibility; bool ok = TemplateInstance.semanticTiargs(e.loc, sc2, e.args, 1); sc2.pop(); if (!ok) return ErrorExp.get(); auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); if (!s) { if (!isError(o)) e.error("argument `%s` has no visibility", o.toChars()); return ErrorExp.get(); } if (s.semanticRun == PASS.initial) s.dsymbolSemantic(null); auto protName = visibilityToString(s.visible().kind); // TODO: How about package(names) assert(protName); auto se = new StringExp(e.loc, protName); return se.expressionSemantic(sc); } if (e.ident == Id.parent) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); if (s) { // https://issues.dlang.org/show_bug.cgi?id=12496 // Consider: // class T1 // { // class C(uint value) { } // } // __traits(parent, T1.C!2) if (auto ad = s.isAggregateDeclaration()) // `s` is `C` { if (ad.isNested()) // `C` is nested { if (auto p = s.toParent()) // `C`'s parent is `C!2`, believe it or not { if (p.isTemplateInstance()) // `C!2` is a template instance { s = p; // `C!2`'s parent is `T1` auto td = (cast(TemplateInstance)p).tempdecl; if (td) s = td; // get the declaration context just in case there's two contexts } } } } if (auto fd = s.isFuncDeclaration()) // https://issues.dlang.org/show_bug.cgi?id=8943 s = fd.toAliasFunc(); if (!s.isImport()) // https://issues.dlang.org/show_bug.cgi?id=8922 s = s.toParent(); } if (!s || s.isImport()) { e.error("argument `%s` has no parent", o.toChars()); return ErrorExp.get(); } if (auto f = s.isFuncDeclaration()) { if (auto td = getFuncTemplateDecl(f)) { if (td.overroot) // if not start of overloaded list of TemplateDeclaration's td = td.overroot; // then get the start Expression ex = new TemplateExp(e.loc, td, f); ex = ex.expressionSemantic(sc); return ex; } if (auto fld = f.isFuncLiteralDeclaration()) { // Directly translate to VarExp instead of FuncExp Expression ex = new VarExp(e.loc, fld, true); return ex.expressionSemantic(sc); } } return symbolToExp(s, e.loc, sc, false); } if (e.ident == Id.child) { if (dim != 2) return dimError(2); Expression ex; auto op = (*e.args)[0]; if (auto symp = getDsymbol(op)) ex = new DsymbolExp(e.loc, symp); else if (auto exp = op.isExpression()) ex = exp; else { e.error("symbol or expression expected as first argument of __traits `child` instead of `%s`", op.toChars()); return ErrorExp.get(); } ex = ex.expressionSemantic(sc); auto oc = (*e.args)[1]; auto symc = getDsymbol(oc); if (!symc) { e.error("symbol expected as second argument of __traits `child` instead of `%s`", oc.toChars()); return ErrorExp.get(); } if (auto d = symc.isDeclaration()) ex = new DotVarExp(e.loc, ex, d); else if (auto td = symc.isTemplateDeclaration()) ex = new DotExp(e.loc, ex, new TemplateExp(e.loc, td)); else if (auto ti = symc.isScopeDsymbol()) ex = new DotExp(e.loc, ex, new ScopeExp(e.loc, ti)); else assert(0); ex = ex.expressionSemantic(sc); return ex; } if (e.ident == Id.toType) { if (dim != 1) return dimError(1); auto ex = isExpression((*e.args)[0]); if (!ex) { e.error("expression expected as second argument of __traits `%s`", e.ident.toChars()); return ErrorExp.get(); } ex = ex.ctfeInterpret(); StringExp se = semanticString(sc, ex, "__traits(toType, string)"); if (!se) { return ErrorExp.get(); } Type t = decoToType(se.toUTF8(sc).peekString()); if (!t) { e.error("cannot determine `%s`", e.toChars()); return ErrorExp.get(); } return (new TypeExp(e.loc, t)).expressionSemantic(sc); } if (e.ident == Id.hasMember || e.ident == Id.getMember || e.ident == Id.getOverloads || e.ident == Id.getVirtualMethods || e.ident == Id.getVirtualFunctions) { if (dim != 2 && !(dim == 3 && e.ident == Id.getOverloads)) return dimError(2); auto o = (*e.args)[0]; auto ex = isExpression((*e.args)[1]); if (!ex) { e.error("expression expected as second argument of __traits `%s`", e.ident.toChars()); return ErrorExp.get(); } ex = ex.ctfeInterpret(); bool includeTemplates = false; if (dim == 3 && e.ident == Id.getOverloads) { auto b = isExpression((*e.args)[2]); b = b.ctfeInterpret(); if (!b.type.equals(Type.tbool)) { e.error("`bool` expected as third argument of `__traits(getOverloads)`, not `%s` of type `%s`", b.toChars(), b.type.toChars()); return ErrorExp.get(); } includeTemplates = b.toBool().get(); } StringExp se = ex.toStringExp(); if (!se || se.len == 0) { e.error("string expected as second argument of __traits `%s` instead of `%s`", e.ident.toChars(), ex.toChars()); return ErrorExp.get(); } se = se.toUTF8(sc); if (se.sz != 1) { e.error("string must be chars"); return ErrorExp.get(); } auto id = Identifier.idPool(se.peekString()); /* Prefer a Type, because getDsymbol(Type) can lose type modifiers. Then a Dsymbol, because it might need some runtime contexts. */ Dsymbol sym = getDsymbol(o); if (auto t = isType(o)) ex = typeDotIdExp(e.loc, t, id); else if (sym) { if (e.ident == Id.hasMember) { if (auto sm = sym.search(e.loc, id)) return True(); } ex = new DsymbolExp(e.loc, sym); ex = new DotIdExp(e.loc, ex, id); } else if (auto ex2 = isExpression(o)) ex = new DotIdExp(e.loc, ex2, id); else { e.error("invalid first argument"); return ErrorExp.get(); } // ignore symbol visibility and disable access checks for these traits Scope* scx = sc.push(); scx.flags |= SCOPE.ignoresymbolvisibility | SCOPE.noaccesscheck; scope (exit) scx.pop(); if (e.ident == Id.hasMember) { /* Take any errors as meaning it wasn't found */ ex = ex.trySemantic(scx); return ex ? True() : False(); } else if (e.ident == Id.getMember) { if (auto die = ex.isDotIdExp()) // Prevent semantic() from replacing Symbol with its initializer die.wantsym = true; ex = ex.expressionSemantic(scx); return ex; } else if (e.ident == Id.getVirtualFunctions || e.ident == Id.getVirtualMethods || e.ident == Id.getOverloads) { uint errors = global.errors; Expression eorig = ex; ex = ex.expressionSemantic(scx); if (errors < global.errors) e.error("`%s` cannot be resolved", eorig.toChars()); /* Create tuple of functions of ex */ auto exps = new Expressions(); Dsymbol f; if (auto ve = ex.isVarExp) { if (ve.var.isFuncDeclaration() || ve.var.isOverDeclaration()) f = ve.var; ex = null; } else if (auto dve = ex.isDotVarExp) { if (dve.var.isFuncDeclaration() || dve.var.isOverDeclaration()) f = dve.var; if (dve.e1.op == EXP.dotType || dve.e1.op == EXP.this_) ex = null; else ex = dve.e1; } else if (auto te = ex.isTemplateExp) { auto td = te.td; f = td; if (td && td.funcroot) f = td.funcroot; ex = null; } else if (auto dte = ex.isDotTemplateExp) { auto td = dte.td; f = td; if (td && td.funcroot) f = td.funcroot; ex = null; if (dte.e1.op != EXP.dotType && dte.e1.op != EXP.this_) ex = dte.e1; } bool[string] funcTypeHash; /* Compute the function signature and insert it in the * hashtable, if not present. This is needed so that * traits(getOverlods, F3, "visit") does not count `int visit(int)` * twice in the following example: * * ============================================= * interface F1 { int visit(int);} * interface F2 { int visit(int); void visit(); } * interface F3 : F2, F1 {} *============================================== */ void insertInterfaceInheritedFunction(FuncDeclaration fd, Expression e) { auto signature = fd.type.toString(); //printf("%s - %s\n", fd.toChars, signature); if (signature !in funcTypeHash) { funcTypeHash[signature] = true; exps.push(e); } } int dg(Dsymbol s) { auto fd = s.isFuncDeclaration(); if (!fd) { if (includeTemplates) { if (auto td = s.isTemplateDeclaration()) { // if td is part of an overload set we must take a copy // which shares the same `instances` cache but without // `overroot` and `overnext` set to avoid overload // behaviour in the result. if (td.overnext !is null) { if (td.instances is null) { // create an empty AA just to copy it scope ti = new TemplateInstance(Loc.initial, Id.empty, null); auto tib = TemplateInstanceBox(ti); td.instances[tib] = null; td.instances.clear(); } td = td.syntaxCopy(null); import core.stdc.string : memcpy; memcpy(cast(void*) td, cast(void*) s, __traits(classInstanceSize, TemplateDeclaration)); td.overroot = null; td.overnext = null; } auto e = ex ? new DotTemplateExp(Loc.initial, ex, td) : new DsymbolExp(Loc.initial, td); exps.push(e); } } return 0; } if (e.ident == Id.getVirtualFunctions && !fd.isVirtual()) return 0; if (e.ident == Id.getVirtualMethods && !fd.isVirtualMethod()) return 0; auto fa = new FuncAliasDeclaration(fd.ident, fd, false); fa.visibility = fd.visibility; auto e = ex ? new DotVarExp(Loc.initial, ex, fa, false) : new DsymbolExp(Loc.initial, fa, false); // if the parent is an interface declaration // we must check for functions with the same signature // in different inherited interfaces if (sym && sym.isInterfaceDeclaration()) insertInterfaceInheritedFunction(fd, e); else exps.push(e); return 0; } InterfaceDeclaration ifd = null; if (sym) ifd = sym.isInterfaceDeclaration(); // If the symbol passed as a parameter is an // interface that inherits other interfaces overloadApply(f, &dg); if (ifd && ifd.interfaces && f) { // check the overloads of each inherited interface individually foreach (bc; ifd.interfaces) { if (auto fd = bc.sym.search(e.loc, f.ident)) overloadApply(fd, &dg); } } auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(scx); } else assert(0); } if (e.ident == Id.classInstanceSize || e.ident == Id.classInstanceAlignment) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbol(o); auto cd = s ? s.isClassDeclaration() : null; if (!cd) { e.error("first argument is not a class"); return ErrorExp.get(); } if (cd.sizeok != Sizeok.done) { cd.size(e.loc); } if (cd.sizeok != Sizeok.done) { e.error("%s `%s` is forward referenced", cd.kind(), cd.toChars()); return ErrorExp.get(); } return new IntegerExp(e.loc, e.ident == Id.classInstanceSize ? cd.structsize : cd.alignsize, Type.tsize_t); } if (e.ident == Id.getAliasThis) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbol(o); auto ad = s ? s.isAggregateDeclaration() : null; auto exps = new Expressions(); if (ad && ad.aliasthis) exps.push(new StringExp(e.loc, ad.aliasthis.ident.toString())); Expression ex = new TupleExp(e.loc, exps); ex = ex.expressionSemantic(sc); return ex; } if (e.ident == Id.getAttributes) { /* Specify 0 for bit 0 of the flags argument to semanticTiargs() so that * a symbol should not be folded to a constant. * Bit 1 means don't convert Parameter to Type if Parameter has an identifier */ if (!TemplateInstance.semanticTiargs(e.loc, sc, e.args, 3)) return ErrorExp.get(); if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto po = isParameter(o); auto s = getDsymbolWithoutExpCtx(o); auto typeOfArg = isType(o); UserAttributeDeclaration udad = null; if (po) { udad = po.userAttribDecl; } else if (s) { if (s.isImport()) { s = s.isImport().mod; } //printf("getAttributes %s, attrs = %p, scope = %p\n", s.toChars(), s.userAttribDecl, s._scope); udad = s.userAttribDecl; } else if (typeOfArg) { // If there is a type but no symbol, do nothing rather than erroring. } else { version (none) { Expression x = isExpression(o); Type t = isType(o); if (x) printf("e = %s %s\n", EXPtoString(x.op).ptr, x.toChars()); if (t) printf("t = %d %s\n", t.ty, t.toChars()); } e.error("first argument is not a symbol"); return ErrorExp.get(); } auto exps = udad ? udad.getAttributes() : new Expressions(); auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(sc); } if (e.ident == Id.getFunctionAttributes) { /* Extract all function attributes as a tuple (const/shared/inout/pure/nothrow/etc) except UDAs. * https://dlang.org/spec/traits.html#getFunctionAttributes */ if (dim != 1) return dimError(1); FuncDeclaration fd; TypeFunction tf = toTypeFunction((*e.args)[0], fd); if (!tf) { e.error("first argument is not a function"); return ErrorExp.get(); } auto mods = new Expressions(); void addToMods(string str) { mods.push(new StringExp(Loc.initial, str)); } tf.modifiersApply(&addToMods); tf.attributesApply(&addToMods, TRUSTformatSystem); auto tup = new TupleExp(e.loc, mods); return tup.expressionSemantic(sc); } if (e.ident == Id.isReturnOnStack) { /* Extract as a boolean if function return value is on the stack * https://dlang.org/spec/traits.html#isReturnOnStack */ if (dim != 1) return dimError(1); RootObject o = (*e.args)[0]; FuncDeclaration fd; TypeFunction tf = toTypeFunction(o, fd); if (!tf) { e.error("argument to `__traits(isReturnOnStack, %s)` is not a function", o.toChars()); return ErrorExp.get(); } bool value = target.isReturnOnStack(tf, fd && fd.needThis()); return IntegerExp.createBool(value); } if (e.ident == Id.getFunctionVariadicStyle) { /* Accept a symbol or a type. Returns one of the following: * "none" not a variadic function * "argptr" extern(D) void dstyle(...), use `__argptr` and `__arguments` * "stdarg" extern(C) void cstyle(int, ...), use core.stdc.stdarg * "typesafe" void typesafe(T[] ...) */ // get symbol linkage as a string if (dim != 1) return dimError(1); LINK link; VarArg varargs; auto o = (*e.args)[0]; FuncDeclaration fd; TypeFunction tf = toTypeFunction(o, fd); if (tf) { link = tf.linkage; varargs = tf.parameterList.varargs; } else { if (!fd) { e.error("argument to `__traits(getFunctionVariadicStyle, %s)` is not a function", o.toChars()); return ErrorExp.get(); } link = fd._linkage; varargs = fd.getParameterList().varargs; } string style; final switch (varargs) { case VarArg.none: style = "none"; break; case VarArg.variadic: style = (link == LINK.d) ? "argptr" : "stdarg"; break; case VarArg.typesafe: style = "typesafe"; break; } auto se = new StringExp(e.loc, style); return se.expressionSemantic(sc); } if (e.ident == Id.getParameterStorageClasses) { /* Accept a function symbol or a type, followed by a parameter index. * Returns a tuple of strings of the parameter's storage classes. */ // get symbol linkage as a string if (dim != 2) return dimError(2); auto o = (*e.args)[0]; auto o1 = (*e.args)[1]; ParameterList fparams; CallExp ce; if (auto exp = isExpression(o)) ce = exp.isCallExp(); if (ce) { fparams = ce.f.getParameterList(); } else { FuncDeclaration fd; auto tf = toTypeFunction(o, fd); if (tf) fparams = tf.parameterList; else if (fd) fparams = fd.getParameterList(); else { e.error("first argument to `__traits(getParameterStorageClasses, %s, %s)` is not a function or a function call", o.toChars(), o1.toChars()); return ErrorExp.get(); } } // Avoid further analysis for invalid functions leading to misleading error messages if (!fparams.parameters) return ErrorExp.get(); StorageClass stc; // Set stc to storage class of the ith parameter auto ex = isExpression((*e.args)[1]); if (!ex) { e.error("expression expected as second argument of `__traits(getParameterStorageClasses, %s, %s)`", o.toChars(), o1.toChars()); return ErrorExp.get(); } ex = ex.ctfeInterpret(); auto ii = ex.toUInteger(); if (ii >= fparams.length) { e.error("parameter index must be in range 0..%u not %s", cast(uint)fparams.length, ex.toChars()); return ErrorExp.get(); } uint n = cast(uint)ii; Parameter p = fparams[n]; stc = p.storageClass; // This mirrors hdrgen.visit(Parameter p) if (p.type && p.type.mod & MODFlags.shared_) stc &= ~STC.shared_; auto exps = new Expressions; void push(string s) { exps.push(new StringExp(e.loc, s)); } if (stc & STC.auto_) push("auto"); if (stc & STC.return_) push("return"); if (stc & STC.out_) push("out"); else if (stc & STC.in_) push("in"); else if (stc & STC.ref_) push("ref"); else if (stc & STC.lazy_) push("lazy"); else if (stc & STC.alias_) push("alias"); if (stc & STC.const_) push("const"); if (stc & STC.immutable_) push("immutable"); if (stc & STC.wild) push("inout"); if (stc & STC.shared_) push("shared"); if (stc & STC.scope_ && !(stc & STC.scopeinferred)) push("scope"); auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(sc); } if (e.ident == Id.getLinkage) { // get symbol linkage as a string if (dim != 1) return dimError(1); LINK link; auto o = (*e.args)[0]; FuncDeclaration fd; TypeFunction tf = toTypeFunction(o, fd); if (tf) { link = fd ? fd.toAliasFunc()._linkage : tf.linkage; } else { auto s = getDsymbol(o); Declaration d; AggregateDeclaration agg; if (!s || ((d = s.isDeclaration()) is null && (agg = s.isAggregateDeclaration()) is null)) { e.error("argument to `__traits(getLinkage, %s)` is not a declaration", o.toChars()); return ErrorExp.get(); } if (d !is null) link = d._linkage; else { // Resolves forward references if (agg.sizeok != Sizeok.done) { agg.size(e.loc); if (agg.sizeok != Sizeok.done) { e.error("%s `%s` is forward referenced", agg.kind(), agg.toChars()); return ErrorExp.get(); } } final switch (agg.classKind) { case ClassKind.d: link = LINK.d; break; case ClassKind.cpp: link = LINK.cpp; break; case ClassKind.objc: link = LINK.objc; break; case ClassKind.c: link = LINK.c; break; } } } auto linkage = linkageToChars(link); auto se = new StringExp(e.loc, linkage.toDString()); return se.expressionSemantic(sc); } if (e.ident == Id.allMembers || e.ident == Id.derivedMembers) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbol(o); if (!s) { e.error("in expression `%s` `%s` can't have members", e.toChars(), o.toChars()); e.errorSupplemental("`%s` must evaluate to either a module, a struct, an union, a class, an interface or a template instantiation", o.toChars()); return ErrorExp.get(); } if (auto imp = s.isImport()) { // https://issues.dlang.org/show_bug.cgi?id=9692 s = imp.mod; } // https://issues.dlang.org/show_bug.cgi?id=16044 if (auto p = s.isPackage()) { if (auto pm = p.isPackageMod()) s = pm; } auto sds = s.isScopeDsymbol(); if (!sds || sds.isTemplateDeclaration()) { e.error("in expression `%s` %s `%s` has no members", e.toChars(), s.kind(), s.toChars()); e.errorSupplemental("`%s` must evaluate to either a module, a struct, an union, a class, an interface or a template instantiation", s.toChars()); return ErrorExp.get(); } auto idents = new Identifiers(); int pushIdentsDg(size_t n, Dsymbol sm) { if (!sm) return 1; // skip local symbols, such as static foreach loop variables if (auto decl = sm.isDeclaration()) { if (decl.storage_class & STC.local) { return 0; } // skip 'this' context pointers else if (decl.isThisDeclaration()) return 0; } // https://issues.dlang.org/show_bug.cgi?id=20915 // skip version and debug identifiers if (sm.isVersionSymbol() || sm.isDebugSymbol()) return 0; //printf("\t[%i] %s %s\n", i, sm.kind(), sm.toChars()); if (sm.ident) { // https://issues.dlang.org/show_bug.cgi?id=10096 // https://issues.dlang.org/show_bug.cgi?id=10100 // Skip over internal members in __traits(allMembers) if ((sm.isCtorDeclaration() && sm.ident != Id.ctor) || (sm.isDtorDeclaration() && sm.ident != Id.dtor) || (sm.isPostBlitDeclaration() && sm.ident != Id.postblit) || sm.isInvariantDeclaration() || sm.isUnitTestDeclaration()) { return 0; } if (sm.ident == Id.empty) { return 0; } if (sm.isTypeInfoDeclaration()) // https://issues.dlang.org/show_bug.cgi?id=15177 return 0; if ((!sds.isModule() && !sds.isPackage()) && sm.isImport()) // https://issues.dlang.org/show_bug.cgi?id=17057 return 0; //printf("\t%s\n", sm.ident.toChars()); /* Skip if already present in idents[] */ foreach (id; *idents) { if (id == sm.ident) return 0; // Avoid using strcmp in the first place due to the performance impact in an O(N^2) loop. debug { import core.stdc.string : strcmp; assert(strcmp(id.toChars(), sm.ident.toChars()) != 0); } } idents.push(sm.ident); } else if (auto ed = sm.isEnumDeclaration()) { ScopeDsymbol._foreach(null, ed.members, &pushIdentsDg); } return 0; } ScopeDsymbol._foreach(sc, sds.members, &pushIdentsDg); auto cd = sds.isClassDeclaration(); if (cd && e.ident == Id.allMembers) { if (cd.semanticRun < PASS.semanticdone) cd.dsymbolSemantic(null); // https://issues.dlang.org/show_bug.cgi?id=13668 // Try to resolve forward reference void pushBaseMembersDg(ClassDeclaration cd) { for (size_t i = 0; i < cd.baseclasses.dim; i++) { auto cb = (*cd.baseclasses)[i].sym; assert(cb); ScopeDsymbol._foreach(null, cb.members, &pushIdentsDg); if (cb.baseclasses.dim) pushBaseMembersDg(cb); } } pushBaseMembersDg(cd); } // Turn Identifiers into StringExps reusing the allocated array assert(Expressions.sizeof == Identifiers.sizeof); auto exps = cast(Expressions*)idents; foreach (i, id; *idents) { auto se = new StringExp(e.loc, id.toString()); (*exps)[i] = se; } /* Making this a tuple is more flexible, as it can be statically unrolled. * To make an array literal, enclose __traits in [ ]: * [ __traits(allMembers, ...) ] */ Expression ex = new TupleExp(e.loc, exps); ex = ex.expressionSemantic(sc); return ex; } if (e.ident == Id.compiles) { /* Determine if all the objects - types, expressions, or symbols - * compile without error */ if (!dim) return False(); foreach (o; *e.args) { uint errors = global.startGagging(); Scope* sc2 = sc.push(); sc2.tinst = null; sc2.minst = null; sc2.flags = (sc.flags & ~(SCOPE.ctfe | SCOPE.condition)) | SCOPE.compile | SCOPE.fullinst; bool err = false; auto t = isType(o); auto ex = isExpression(o); if (t) { Dsymbol s; t.resolve(e.loc, sc2, ex, t, s); if (t) { t.typeSemantic(e.loc, sc2); if (t.ty == Terror) err = true; } else if (s && s.errors) err = true; } if (ex) { ex = ex.expressionSemantic(sc2); ex = resolvePropertiesOnly(sc2, ex); ex = ex.optimize(WANTvalue); if (sc2.func && sc2.func.type.ty == Tfunction) { const tf = cast(TypeFunction)sc2.func.type; err |= tf.isnothrow && canThrow(ex, sc2.func, false); } ex = checkGC(sc2, ex); if (ex.op == EXP.error) err = true; } // Carefully detach the scope from the parent and throw it away as // we only need it to evaluate the expression // https://issues.dlang.org/show_bug.cgi?id=15428 sc2.detach(); if (global.endGagging(errors) || err) { return False(); } } return True(); } if (e.ident == Id.isSame) { /* Determine if two symbols are the same */ if (dim != 2) return dimError(2); // https://issues.dlang.org/show_bug.cgi?id=20761 // tiarg semantic may expand in place the list of arguments, for example: // // before tiarg sema: __traits(isSame, seq!(0,0), seq!(1,1)) // after : __traits(isSame, 0, 0, 1, 1) // // so we split in two lists Objects ob1; ob1.push((*e.args)[0]); Objects ob2; ob2.push((*e.args)[1]); if (!TemplateInstance.semanticTiargs(e.loc, sc, &ob1, 0)) return ErrorExp.get(); if (!TemplateInstance.semanticTiargs(e.loc, sc, &ob2, 0)) return ErrorExp.get(); if (ob1.dim != ob2.dim) return False(); foreach (immutable i; 0 .. ob1.dim) if (!ob1[i].isSame(ob2[i], sc)) return False(); return True(); } if (e.ident == Id.getUnitTests) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); if (!s) { e.error("argument `%s` to __traits(getUnitTests) must be a module or aggregate", o.toChars()); return ErrorExp.get(); } if (auto imp = s.isImport()) // https://issues.dlang.org/show_bug.cgi?id=10990 s = imp.mod; auto sds = s.isScopeDsymbol(); if (!sds || sds.isTemplateDeclaration()) { e.error("argument `%s` to __traits(getUnitTests) must be a module or aggregate, not a %s", s.toChars(), s.kind()); return ErrorExp.get(); } auto exps = new Expressions(); if (global.params.useUnitTests) { bool[void*] uniqueUnitTests; void symbolDg(Dsymbol s) { if (auto ad = s.isAttribDeclaration()) { ad.include(null).foreachDsymbol(&symbolDg); } else if (auto tm = s.isTemplateMixin()) { tm.members.foreachDsymbol(&symbolDg); } else if (auto ud = s.isUnitTestDeclaration()) { if (cast(void*)ud in uniqueUnitTests) return; uniqueUnitTests[cast(void*)ud] = true; auto ad = new FuncAliasDeclaration(ud.ident, ud, false); ad.visibility = ud.visibility; auto e = new DsymbolExp(Loc.initial, ad, false); exps.push(e); } } sds.members.foreachDsymbol(&symbolDg); } auto te = new TupleExp(e.loc, exps); return te.expressionSemantic(sc); } if (e.ident == Id.getVirtualIndex) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); auto fd = s ? s.isFuncDeclaration() : null; if (!fd) { e.error("first argument to __traits(getVirtualIndex) must be a function"); return ErrorExp.get(); } fd = fd.toAliasFunc(); // Necessary to support multiple overloads. return new IntegerExp(e.loc, fd.vtblIndex, Type.tptrdiff_t); } if (e.ident == Id.getPointerBitmap) { return pointerBitmap(e); } if (e.ident == Id.initSymbol) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; Type t = isType(o); AggregateDeclaration ad = t ? isAggregate(t) : null; // Interfaces don't have an init symbol and hence cause linker errors if (!ad || ad.isInterfaceDeclaration()) { e.error("struct / class type expected as argument to __traits(initSymbol) instead of `%s`", o.toChars()); return ErrorExp.get(); } Declaration d = new SymbolDeclaration(ad.loc, ad); d.type = Type.tvoid.arrayOf().constOf(); d.storage_class |= STC.rvalue; return new VarExp(e.loc, d); } if (e.ident == Id.isZeroInit) { if (dim != 1) return dimError(1); auto o = (*e.args)[0]; Type t = isType(o); if (!t) { e.error("type expected as second argument of __traits `%s` instead of `%s`", e.ident.toChars(), o.toChars()); return ErrorExp.get(); } Type tb = t.baseElemOf(); return tb.isZeroInit(e.loc) ? True() : False(); } if (e.ident == Id.getTargetInfo) { if (dim != 1) return dimError(1); auto ex = isExpression((*e.args)[0]); StringExp se = ex ? ex.ctfeInterpret().toStringExp() : null; if (!ex || !se || se.len == 0) { e.error("string expected as argument of __traits `%s` instead of `%s`", e.ident.toChars(), ex.toChars()); return ErrorExp.get(); } se = se.toUTF8(sc); const slice = se.peekString(); Expression r = target.getTargetInfo(slice.ptr, e.loc); // BUG: reliance on terminating 0 if (!r) { e.error("`getTargetInfo` key `\"%.*s\"` not supported by this implementation", cast(int)slice.length, slice.ptr); return ErrorExp.get(); } return r.expressionSemantic(sc); } if (e.ident == Id.getLocation) { if (dim != 1) return dimError(1); auto arg0 = (*e.args)[0]; Dsymbol s = getDsymbolWithoutExpCtx(arg0); if (!s || !s.loc.isValid()) { e.error("can only get the location of a symbol, not `%s`", arg0.toChars()); return ErrorExp.get(); } const fd = s.isFuncDeclaration(); // FIXME:td.overnext is always set, even when using an index on it //const td = s.isTemplateDeclaration(); if ((fd && fd.overnext) /*|| (td && td.overnext)*/) { e.error("cannot get location of an overload set, " ~ "use `__traits(getOverloads, ..., \"%s\"%s)[N]` " ~ "to get the Nth overload", arg0.toChars(), /*td ? ", true".ptr :*/ "".ptr); return ErrorExp.get(); } auto exps = new Expressions(3); (*exps)[0] = new StringExp(e.loc, s.loc.filename.toDString()); (*exps)[1] = new IntegerExp(e.loc, s.loc.linnum,Type.tint32); (*exps)[2] = new IntegerExp(e.loc, s.loc.charnum,Type.tint32); auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(sc); } if (e.ident == Id.getCppNamespaces) { auto o = (*e.args)[0]; auto s = getDsymbolWithoutExpCtx(o); auto exps = new Expressions(0); if (auto d = s.isDeclaration()) { if (d.inuse) { d.error("circular reference in `__traits(GetCppNamespaces,...)`"); return ErrorExp.get(); } d.inuse = 1; } /** Prepend the namespaces in the linked list `ns` to `es`. Returns: true if `ns` contains an `ErrorExp`. */ bool prependNamespaces(Expressions* es, CPPNamespaceDeclaration ns) { // Semantic processing will convert `extern(C++, "a", "b", "c")` // into `extern(C++, "a") extern(C++, "b") extern(C++, "c")`, // creating a linked list what `a`'s `cppnamespace` points to `b`, // and `b`'s points to `c`. Our entry point is `a`. for (; ns !is null; ns = ns.cppnamespace) { ns.dsymbolSemantic(sc); if (ns.exp.isErrorExp()) return true; auto se = ns.exp.toStringExp(); // extern(C++, (emptyTuple)) // struct D {} // will produce a blank ident if (!se.len) continue; es.insert(0, se); } return false; } for (auto p = s; !p.isModule(); p = p.toParent()) { p.dsymbolSemantic(sc); auto pp = p.toParent(); if (pp.isTemplateInstance()) { if (!p.cppnamespace) continue; //if (!p.toParent().cppnamespace) // continue; auto inner = new Expressions(0); auto outer = new Expressions(0); if (prependNamespaces(inner, p.cppnamespace)) return ErrorExp.get(); if (prependNamespaces(outer, pp.cppnamespace)) return ErrorExp.get(); size_t i = 0; while(i < outer.dim && ((*inner)[i]) == (*outer)[i]) i++; foreach_reverse (ns; (*inner)[][i .. $]) exps.insert(0, ns); continue; } if (p.isNspace()) exps.insert(0, new StringExp(p.loc, p.ident.toString())); if (prependNamespaces(exps, p.cppnamespace)) return ErrorExp.get(); } if (auto d = s.isDeclaration()) d.inuse = 0; auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(sc); } //https://issues.dlang.org/show_bug.cgi?id=22291 if (e.ident == Id.parameters) { //No args are valid if (e.args) { char[] contents = cast(char[]) e.args.toString(); contents = contents[1..$]; contents[$-1] = '\0'; e.error("`__traits(parameters)` cannot have arguments, but `%s` was supplied", contents.ptr); return ErrorExp.get(); } auto fd = sc.getEnclosingFunction(); if (!fd) { e.error("`__traits(parameters)` may only be used inside a function"); return ErrorExp.get(); } auto tf = fd.type.isTypeFunction(); assert(tf); auto exps = new Expressions(0); int addParameterDG(size_t idx, Parameter x) { assert(x.ident); exps.push(new IdentifierExp(e.loc, x.ident)); return 0; } /* This is required since not all "parameters" actually have a name until they (tuples) are expanded e.g. an anonymous tuple parameter's contents get given names but not the tuple itself. */ Parameter._foreach(tf.parameterList.parameters, &addParameterDG); auto tup = new TupleExp(e.loc, exps); return tup.expressionSemantic(sc); } static const(char)[] trait_search_fp(const(char)[] seed, out int cost) { //printf("trait_search_fp('%s')\n", seed); if (!seed.length) return null; cost = 0; // all the same cost const sv = traitsStringTable.lookup(seed); return sv ? sv.toString() : null; } if (auto sub = speller!trait_search_fp(e.ident.toString())) e.error("unrecognized trait `%s`, did you mean `%.*s`?", e.ident.toChars(), cast(int) sub.length, sub.ptr); else e.error("unrecognized trait `%s`", e.ident.toChars()); return ErrorExp.get(); } /// compare arguments of __traits(isSame) private bool isSame(RootObject o1, RootObject o2, Scope* sc) { static FuncLiteralDeclaration isLambda(RootObject oarg) { if (auto t = isDsymbol(oarg)) { if (auto td = t.isTemplateDeclaration()) { if (td.members && td.members.dim == 1) { if (auto fd = (*td.members)[0].isFuncLiteralDeclaration()) return fd; } } } else if (auto ea = isExpression(oarg)) { if (ea.op == EXP.function_) { if (auto fe = ea.isFuncExp()) return fe.fd; } } return null; } auto l1 = isLambda(o1); auto l2 = isLambda(o2); if (l1 && l2) { import dmd.lambdacomp : isSameFuncLiteral; if (isSameFuncLiteral(l1, l2, sc)) return true; } // issue 12001, allow isSame, , Type t1 = isType(o1); Type t2 = isType(o2); if (t1 && t2 && t1.equals(t2)) return true; auto s1 = getDsymbol(o1); auto s2 = getDsymbol(o2); //printf("isSame: %s, %s\n", o1.toChars(), o2.toChars()); version (none) { printf("o1: %p\n", o1); printf("o2: %p\n", o2); if (!s1) { if (auto ea = isExpression(o1)) printf("%s\n", ea.toChars()); if (auto ta = isType(o1)) printf("%s\n", ta.toChars()); return false; } else printf("%s %s\n", s1.kind(), s1.toChars()); } if (!s1 && !s2) { auto ea1 = isExpression(o1); auto ea2 = isExpression(o2); if (ea1 && ea2) { if (ea1.equals(ea2)) return true; } } if (!s1 || !s2) return false; s1 = s1.toAlias(); s2 = s2.toAlias(); if (auto fa1 = s1.isFuncAliasDeclaration()) s1 = fa1.toAliasFunc(); if (auto fa2 = s2.isFuncAliasDeclaration()) s2 = fa2.toAliasFunc(); // https://issues.dlang.org/show_bug.cgi?id=11259 // compare import symbol to a package symbol static bool cmp(Dsymbol s1, Dsymbol s2) { auto imp = s1.isImport(); return imp && imp.pkg && imp.pkg == s2.isPackage(); } if (cmp(s1,s2) || cmp(s2,s1)) return true; if (s1 == s2) return true; // https://issues.dlang.org/show_bug.cgi?id=18771 // OverloadSets are equal if they contain the same functions auto overSet1 = s1.isOverloadSet(); if (!overSet1) return false; auto overSet2 = s2.isOverloadSet(); if (!overSet2) return false; if (overSet1.a.dim != overSet2.a.dim) return false; // OverloadSets contain array of Dsymbols => O(n*n) // to compare for equality as the order of overloads // might not be the same Lnext: foreach(overload1; overSet1.a) { foreach(overload2; overSet2.a) { if (overload1 == overload2) continue Lnext; } return false; } return true; }