Mercurial > hg > CbC > CbC_gcc
view gcc/d/dmd/clone.c @ 145:1830386684a0
gcc-9.2.0
| author | anatofuz |
|---|---|
| date | Thu, 13 Feb 2020 11:34:05 +0900 |
| parents | |
| children |
line wrap: on
line source
/* Compiler implementation of the D programming language * Copyright (C) 1999-2019 by The D Language Foundation, All Rights Reserved * written by Walter Bright * http://www.digitalmars.com * Distributed under the Boost Software License, Version 1.0. * http://www.boost.org/LICENSE_1_0.txt * https://github.com/D-Programming-Language/dmd/blob/master/src/clone.c */ #include "root/dsystem.h" #include "root/root.h" #include "aggregate.h" #include "scope.h" #include "mtype.h" #include "declaration.h" #include "module.h" #include "id.h" #include "expression.h" #include "statement.h" #include "init.h" #include "template.h" #include "tokens.h" Expression *semantic(Expression *e, Scope *sc); /******************************************* * Merge function attributes pure, nothrow, @safe, @nogc, and @disable */ StorageClass mergeFuncAttrs(StorageClass s1, FuncDeclaration *f) { if (!f) return s1; StorageClass s2 = (f->storage_class & STCdisable); TypeFunction *tf = (TypeFunction *)f->type; if (tf->trust == TRUSTsafe) s2 |= STCsafe; else if (tf->trust == TRUSTsystem) s2 |= STCsystem; else if (tf->trust == TRUSTtrusted) s2 |= STCtrusted; if (tf->purity != PUREimpure) s2 |= STCpure; if (tf->isnothrow) s2 |= STCnothrow; if (tf->isnogc) s2 |= STCnogc; StorageClass stc = 0; StorageClass sa = s1 & s2; StorageClass so = s1 | s2; if (so & STCsystem) stc |= STCsystem; else if (sa & STCtrusted) stc |= STCtrusted; else if ((so & (STCtrusted | STCsafe)) == (STCtrusted | STCsafe)) stc |= STCtrusted; else if (sa & STCsafe) stc |= STCsafe; if (sa & STCpure) stc |= STCpure; if (sa & STCnothrow) stc |= STCnothrow; if (sa & STCnogc) stc |= STCnogc; if (so & STCdisable) stc |= STCdisable; return stc; } /******************************************* * Check given aggregate actually has an identity opAssign or not. * Params: * ad = struct or class * sc = current scope * Returns: * if found, returns FuncDeclaration of opAssign, otherwise null */ FuncDeclaration *hasIdentityOpAssign(AggregateDeclaration *ad, Scope *sc) { Dsymbol *assign = search_function(ad, Id::assign); if (assign) { /* check identity opAssign exists */ UnionExp er; new(&er) NullExp(ad->loc, ad->type); // dummy rvalue UnionExp el; new(&el) IdentifierExp(ad->loc, Id::p); // dummy lvalue el.exp()->type = ad->type; Expressions a; a.setDim(1); unsigned errors = global.startGagging(); // Do not report errors, even if the template opAssign fbody makes it. sc = sc->push(); sc->tinst = NULL; sc->minst = NULL; a[0] = er.exp(); FuncDeclaration *f = resolveFuncCall(ad->loc, sc, assign, NULL, ad->type, &a, 1); if (!f) { a[0] = el.exp(); f = resolveFuncCall(ad->loc, sc, assign, NULL, ad->type, &a, 1); } sc = sc->pop(); global.endGagging(errors); if (f) { if (f->errors) return NULL; int varargs; Parameters *fparams = f->getParameters(&varargs); if (fparams->dim >= 1) { Parameter *fparam0 = Parameter::getNth(fparams, 0); if (fparam0->type->toDsymbol(NULL) != ad) f = NULL; } } // BUGS: This detection mechanism cannot find some opAssign-s like follows: // struct S { void opAssign(ref immutable S) const; } return f; } return NULL; } /******************************************* * We need an opAssign for the struct if * it has a destructor or a postblit. * We need to generate one if a user-specified one does not exist. */ bool needOpAssign(StructDeclaration *sd) { //printf("StructDeclaration::needOpAssign() %s\n", sd->toChars()); if (sd->isUnionDeclaration()) return false; if (sd->hasIdentityAssign) goto Lneed; // because has identity==elaborate opAssign if (sd->dtor || sd->postblit) goto Lneed; /* If any of the fields need an opAssign, then we * need it too. */ for (size_t i = 0; i < sd->fields.dim; i++) { VarDeclaration *v = sd->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) // if field of a union continue; // user must handle it themselves Type *tv = v->type->baseElemOf(); if (tv->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)tv; if (ts->sym->isUnionDeclaration()) continue; if (needOpAssign(ts->sym)) goto Lneed; } } //printf("\tdontneed\n"); return false; Lneed: //printf("\tneed\n"); return true; } /****************************************** * Build opAssign for struct. * ref S opAssign(S s) { ... } * * Note that s will be constructed onto the stack, and probably * copy-constructed in caller site. * * If S has copy copy construction and/or destructor, * the body will make bit-wise object swap: * S __swap = this; // bit copy * this = s; // bit copy * __swap.dtor(); * Instead of running the destructor on s, run it on tmp instead. * * Otherwise, the body will make member-wise assignments: * Then, the body is: * this.field1 = s.field1; * this.field2 = s.field2; * ...; */ FuncDeclaration *buildOpAssign(StructDeclaration *sd, Scope *sc) { if (FuncDeclaration *f = hasIdentityOpAssign(sd, sc)) { sd->hasIdentityAssign = true; return f; } // Even if non-identity opAssign is defined, built-in identity opAssign // will be defined. if (!needOpAssign(sd)) return NULL; //printf("StructDeclaration::buildOpAssign() %s\n", sd->toChars()); StorageClass stc = STCsafe | STCnothrow | STCpure | STCnogc; Loc declLoc = sd->loc; Loc loc = Loc(); // internal code should have no loc to prevent coverage // One of our sub-field might have `@disable opAssign` so we need to // check for it. // In this event, it will be reflected by having `stc` (opAssign's // storage class) include `STCdisabled`. for (size_t i = 0; i < sd->fields.dim; i++) { VarDeclaration *v = sd->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) continue; Type *tv = v->type->baseElemOf(); if (tv->ty != Tstruct) continue; StructDeclaration *sdv = ((TypeStruct *)tv)->sym; stc = mergeFuncAttrs(stc, hasIdentityOpAssign(sdv, sc)); } if (sd->dtor || sd->postblit) { if (!sd->type->isAssignable()) // Bugzilla 13044 return NULL; stc = mergeFuncAttrs(stc, sd->dtor); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; } Parameters *fparams = new Parameters; fparams->push(new Parameter(STCnodtor, sd->type, Id::p, NULL)); TypeFunction *tf = new TypeFunction(fparams, sd->handleType(), 0, LINKd, stc | STCref); FuncDeclaration *fop = new FuncDeclaration(declLoc, Loc(), Id::assign, stc, tf); fop->storage_class |= STCinference; fop->generated = true; Expression *e = NULL; if (stc & STCdisable) { } else if (sd->dtor || sd->postblit) { /* Do swap this and rhs. * __swap = this; this = s; __swap.dtor(); */ //printf("\tswap copy\n"); Identifier *idtmp = Identifier::generateId("__swap"); VarDeclaration *tmp = NULL; AssignExp *ec = NULL; if (sd->dtor) { tmp = new VarDeclaration(loc, sd->type, idtmp, new VoidInitializer(loc)); tmp->storage_class |= STCnodtor | STCtemp | STCctfe; e = new DeclarationExp(loc, tmp); ec = new BlitExp(loc, new VarExp(loc, tmp), new ThisExp(loc)); e = Expression::combine(e, ec); } ec = new BlitExp(loc, new ThisExp(loc), new IdentifierExp(loc, Id::p)); e = Expression::combine(e, ec); if (sd->dtor) { /* Instead of running the destructor on s, run it * on tmp. This avoids needing to copy tmp back in to s. */ Expression *ec2 = new DotVarExp(loc, new VarExp(loc, tmp), sd->dtor, false); ec2 = new CallExp(loc, ec2); e = Expression::combine(e, ec2); } } else { /* Do memberwise copy. * * If sd is a nested struct, its vthis field assignment is: * 1. If it's nested in a class, it's a rebind of class reference. * 2. If it's nested in a function or struct, it's an update of void*. * In both cases, it will change the parent context. */ //printf("\tmemberwise copy\n"); for (size_t i = 0; i < sd->fields.dim; i++) { VarDeclaration *v = sd->fields[i]; // this.v = s.v; AssignExp *ec = new AssignExp(loc, new DotVarExp(loc, new ThisExp(loc), v), new DotVarExp(loc, new IdentifierExp(loc, Id::p), v)); e = Expression::combine(e, ec); } } if (e) { Statement *s1 = new ExpStatement(loc, e); /* Add: * return this; */ e = new ThisExp(loc); Statement *s2 = new ReturnStatement(loc, e); fop->fbody = new CompoundStatement(loc, s1, s2); tf->isreturn = true; } sd->members->push(fop); fop->addMember(sc, sd); sd->hasIdentityAssign = true; // temporary mark identity assignable unsigned errors = global.startGagging(); // Do not report errors, even if the template opAssign fbody makes it. Scope *sc2 = sc->push(); sc2->stc = 0; sc2->linkage = LINKd; fop->semantic(sc2); fop->semantic2(sc2); // Bugzilla 15044: fop->semantic3 isn't run here for lazy forward reference resolution. sc2->pop(); if (global.endGagging(errors)) // if errors happened { // Disable generated opAssign, because some members forbid identity assignment. fop->storage_class |= STCdisable; fop->fbody = NULL; // remove fbody which contains the error } //printf("-StructDeclaration::buildOpAssign() %s, errors = %d\n", sd->toChars(), (fop->storage_class & STCdisable) != 0); return fop; } /******************************************* * We need an opEquals for the struct if * any fields has an opEquals. * Generate one if a user-specified one does not exist. */ bool needOpEquals(StructDeclaration *sd) { //printf("StructDeclaration::needOpEquals() %s\n", sd->toChars()); if (sd->isUnionDeclaration()) goto Ldontneed; if (sd->hasIdentityEquals) goto Lneed; /* If any of the fields has an opEquals, then we * need it too. */ for (size_t i = 0; i < sd->fields.dim; i++) { VarDeclaration *v = sd->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) continue; Type *tv = v->type->toBasetype(); Type *tvbase = tv->baseElemOf(); if (tvbase->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)tvbase; if (ts->sym->isUnionDeclaration()) continue; if (needOpEquals(ts->sym)) goto Lneed; if (ts->sym->aliasthis) // Bugzilla 14806 goto Lneed; } if (tv->isfloating()) { // This is necessray for: // 1. comparison of +0.0 and -0.0 should be true. // 2. comparison of NANs should be false always. goto Lneed; } if (tv->ty == Tarray) goto Lneed; if (tv->ty == Taarray) goto Lneed; if (tv->ty == Tclass) goto Lneed; } Ldontneed: //printf("\tdontneed\n"); return false; Lneed: //printf("\tneed\n"); return true; } /******************************************* * Check given aggregate actually has an identity opEquals or not. */ FuncDeclaration *hasIdentityOpEquals(AggregateDeclaration *ad, Scope *sc) { Dsymbol *eq = search_function(ad, Id::eq); if (eq) { /* check identity opEquals exists */ UnionExp er; new(&er) NullExp(ad->loc, NULL); // dummy rvalue UnionExp el; new(&el) IdentifierExp(ad->loc, Id::p); // dummy lvalue Expressions a; a.setDim(1); for (size_t i = 0; i < 5; i++) { Type *tthis = NULL; // dead-store to prevent spurious warning switch (i) { case 0: tthis = ad->type; break; case 1: tthis = ad->type->constOf(); break; case 2: tthis = ad->type->immutableOf(); break; case 3: tthis = ad->type->sharedOf(); break; case 4: tthis = ad->type->sharedConstOf(); break; default: assert(0); } FuncDeclaration *f = NULL; unsigned errors = global.startGagging(); // Do not report errors, even if the template opAssign fbody makes it. sc = sc->push(); sc->tinst = NULL; sc->minst = NULL; for (size_t j = 0; j < 2; j++) { a[0] = (j == 0 ? er.exp() : el.exp()); a[0]->type = tthis; f = resolveFuncCall(ad->loc, sc, eq, NULL, tthis, &a, 1); if (f) break; } sc = sc->pop(); global.endGagging(errors); if (f) { if (f->errors) return NULL; return f; } } } return NULL; } /****************************************** * Build opEquals for struct. * const bool opEquals(const S s) { ... } * * By fixing bugzilla 3789, opEquals is changed to be never implicitly generated. * Now, struct objects comparison s1 == s2 is translated to: * s1.tupleof == s2.tupleof * to calculate structural equality. See EqualExp::op_overload. */ FuncDeclaration *buildOpEquals(StructDeclaration *sd, Scope *sc) { if (hasIdentityOpEquals(sd, sc)) { sd->hasIdentityEquals = true; } return NULL; } /****************************************** * Build __xopEquals for TypeInfo_Struct * static bool __xopEquals(ref const S p, ref const S q) * { * return p == q; * } * * This is called by TypeInfo.equals(p1, p2). If the struct does not support * const objects comparison, it will throw "not implemented" Error in runtime. */ FuncDeclaration *buildXopEquals(StructDeclaration *sd, Scope *sc) { if (!needOpEquals(sd)) return NULL; // bitwise comparison would work //printf("StructDeclaration::buildXopEquals() %s\n", sd->toChars()); if (Dsymbol *eq = search_function(sd, Id::eq)) { if (FuncDeclaration *fd = eq->isFuncDeclaration()) { TypeFunction *tfeqptr; { Scope scx; /* const bool opEquals(ref const S s); */ Parameters *parameters = new Parameters; parameters->push(new Parameter(STCref | STCconst, sd->type, NULL, NULL)); tfeqptr = new TypeFunction(parameters, Type::tbool, 0, LINKd); tfeqptr->mod = MODconst; tfeqptr = (TypeFunction *)tfeqptr->semantic(Loc(), &scx); } fd = fd->overloadExactMatch(tfeqptr); if (fd) return fd; } } if (!sd->xerreq) { // object._xopEquals Identifier *id = Identifier::idPool("_xopEquals"); Expression *e = new IdentifierExp(sd->loc, Id::empty); e = new DotIdExp(sd->loc, e, Id::object); e = new DotIdExp(sd->loc, e, id); e = semantic(e, sc); Dsymbol *s = getDsymbol(e); assert(s); sd->xerreq = s->isFuncDeclaration(); } Loc declLoc = Loc(); // loc is unnecessary so __xopEquals is never called directly Loc loc = Loc(); // loc is unnecessary so errors are gagged Parameters *parameters = new Parameters; parameters->push(new Parameter(STCref | STCconst, sd->type, Id::p, NULL)); parameters->push(new Parameter(STCref | STCconst, sd->type, Id::q, NULL)); TypeFunction *tf = new TypeFunction(parameters, Type::tbool, 0, LINKd); Identifier *id = Id::xopEquals; FuncDeclaration *fop = new FuncDeclaration(declLoc, Loc(), id, STCstatic, tf); fop->generated = true; Expression *e1 = new IdentifierExp(loc, Id::p); Expression *e2 = new IdentifierExp(loc, Id::q); Expression *e = new EqualExp(TOKequal, loc, e1, e2); fop->fbody = new ReturnStatement(loc, e); unsigned errors = global.startGagging(); // Do not report errors Scope *sc2 = sc->push(); sc2->stc = 0; sc2->linkage = LINKd; fop->semantic(sc2); fop->semantic2(sc2); sc2->pop(); if (global.endGagging(errors)) // if errors happened fop = sd->xerreq; return fop; } /****************************************** * Build __xopCmp for TypeInfo_Struct * static bool __xopCmp(ref const S p, ref const S q) * { * return p.opCmp(q); * } * * This is called by TypeInfo.compare(p1, p2). If the struct does not support * const objects comparison, it will throw "not implemented" Error in runtime. */ FuncDeclaration *buildXopCmp(StructDeclaration *sd, Scope *sc) { //printf("StructDeclaration::buildXopCmp() %s\n", toChars()); if (Dsymbol *cmp = search_function(sd, Id::cmp)) { if (FuncDeclaration *fd = cmp->isFuncDeclaration()) { TypeFunction *tfcmpptr; { Scope scx; /* const int opCmp(ref const S s); */ Parameters *parameters = new Parameters; parameters->push(new Parameter(STCref | STCconst, sd->type, NULL, NULL)); tfcmpptr = new TypeFunction(parameters, Type::tint32, 0, LINKd); tfcmpptr->mod = MODconst; tfcmpptr = (TypeFunction *)tfcmpptr->semantic(Loc(), &scx); } fd = fd->overloadExactMatch(tfcmpptr); if (fd) return fd; } } else { // FIXME: doesn't work for recursive alias this return NULL; } if (!sd->xerrcmp) { // object._xopCmp Identifier *id = Identifier::idPool("_xopCmp"); Expression *e = new IdentifierExp(sd->loc, Id::empty); e = new DotIdExp(sd->loc, e, Id::object); e = new DotIdExp(sd->loc, e, id); e = semantic(e, sc); Dsymbol *s = getDsymbol(e); assert(s); sd->xerrcmp = s->isFuncDeclaration(); } Loc declLoc = Loc(); // loc is unnecessary so __xopCmp is never called directly Loc loc = Loc(); // loc is unnecessary so errors are gagged Parameters *parameters = new Parameters; parameters->push(new Parameter(STCref | STCconst, sd->type, Id::p, NULL)); parameters->push(new Parameter(STCref | STCconst, sd->type, Id::q, NULL)); TypeFunction *tf = new TypeFunction(parameters, Type::tint32, 0, LINKd); Identifier *id = Id::xopCmp; FuncDeclaration *fop = new FuncDeclaration(declLoc, Loc(), id, STCstatic, tf); fop->generated = true; Expression *e1 = new IdentifierExp(loc, Id::p); Expression *e2 = new IdentifierExp(loc, Id::q); #ifdef IN_GCC Expression *e = new CallExp(loc, new DotIdExp(loc, e1, Id::cmp), e2); #else Expression *e = new CallExp(loc, new DotIdExp(loc, e2, Id::cmp), e1); #endif fop->fbody = new ReturnStatement(loc, e); unsigned errors = global.startGagging(); // Do not report errors Scope *sc2 = sc->push(); sc2->stc = 0; sc2->linkage = LINKd; fop->semantic(sc2); fop->semantic2(sc2); sc2->pop(); if (global.endGagging(errors)) // if errors happened fop = sd->xerrcmp; return fop; } /******************************************* * We need a toHash for the struct if * any fields has a toHash. * Generate one if a user-specified one does not exist. */ bool needToHash(StructDeclaration *sd) { //printf("StructDeclaration::needToHash() %s\n", sd->toChars()); if (sd->isUnionDeclaration()) goto Ldontneed; if (sd->xhash) goto Lneed; /* If any of the fields has an opEquals, then we * need it too. */ for (size_t i = 0; i < sd->fields.dim; i++) { VarDeclaration *v = sd->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) continue; Type *tv = v->type->toBasetype(); Type *tvbase = tv->baseElemOf(); if (tvbase->ty == Tstruct) { TypeStruct *ts = (TypeStruct *)tvbase; if (ts->sym->isUnionDeclaration()) continue; if (needToHash(ts->sym)) goto Lneed; if (ts->sym->aliasthis) // Bugzilla 14948 goto Lneed; } if (tv->isfloating()) { // This is necessray for: // 1. comparison of +0.0 and -0.0 should be true. goto Lneed; } if (tv->ty == Tarray) goto Lneed; if (tv->ty == Taarray) goto Lneed; if (tv->ty == Tclass) goto Lneed; } Ldontneed: //printf("\tdontneed\n"); return false; Lneed: //printf("\tneed\n"); return true; } /****************************************** * Build __xtoHash for non-bitwise hashing * static hash_t xtoHash(ref const S p) nothrow @trusted; */ FuncDeclaration *buildXtoHash(StructDeclaration *sd, Scope *sc) { if (Dsymbol *s = search_function(sd, Id::tohash)) { static TypeFunction *tftohash; if (!tftohash) { tftohash = new TypeFunction(NULL, Type::thash_t, 0, LINKd); tftohash->mod = MODconst; tftohash = (TypeFunction *)tftohash->merge(); } if (FuncDeclaration *fd = s->isFuncDeclaration()) { fd = fd->overloadExactMatch(tftohash); if (fd) return fd; } } if (!needToHash(sd)) return NULL; //printf("StructDeclaration::buildXtoHash() %s\n", sd->toPrettyChars()); Loc declLoc = Loc(); // loc is unnecessary so __xtoHash is never called directly Loc loc = Loc(); // internal code should have no loc to prevent coverage Parameters *parameters = new Parameters(); parameters->push(new Parameter(STCref | STCconst, sd->type, Id::p, NULL)); TypeFunction *tf = new TypeFunction(parameters, Type::thash_t, 0, LINKd, STCnothrow | STCtrusted); Identifier *id = Id::xtoHash; FuncDeclaration *fop = new FuncDeclaration(declLoc, Loc(), id, STCstatic, tf); fop->generated = true; /* Do memberwise hashing. * * If sd is a nested struct, and if it's nested in a class, the calculated * hash value will also contain the result of parent class's toHash(). */ const char *code = "size_t h = 0;" "foreach (i, T; typeof(p.tupleof))" " h += typeid(T).getHash(cast(const void*)&p.tupleof[i]);" "return h;"; fop->fbody = new CompileStatement(loc, new StringExp(loc, const_cast<char *>(code))); Scope *sc2 = sc->push(); sc2->stc = 0; sc2->linkage = LINKd; fop->semantic(sc2); fop->semantic2(sc2); sc2->pop(); //printf("%s fop = %s %s\n", sd->toChars(), fop->toChars(), fop->type->toChars()); return fop; } /***************************************** * Create inclusive postblit for struct by aggregating * all the postblits in postblits[] with the postblits for * all the members. * Note the close similarity with AggregateDeclaration::buildDtor(), * and the ordering changes (runs forward instead of backwards). */ FuncDeclaration *buildPostBlit(StructDeclaration *sd, Scope *sc) { //printf("StructDeclaration::buildPostBlit() %s\n", sd->toChars()); if (sd->isUnionDeclaration()) return NULL; StorageClass stc = STCsafe | STCnothrow | STCpure | STCnogc; Loc declLoc = sd->postblits.dim ? sd->postblits[0]->loc : sd->loc; Loc loc = Loc(); // internal code should have no loc to prevent coverage for (size_t i = 0; i < sd->postblits.dim; i++) { stc |= sd->postblits[i]->storage_class & STCdisable; } Statements *a = new Statements(); for (size_t i = 0; i < sd->fields.dim && !(stc & STCdisable); i++) { VarDeclaration *v = sd->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) continue; Type *tv = v->type->baseElemOf(); if (tv->ty != Tstruct) continue; StructDeclaration *sdv = ((TypeStruct *)tv)->sym; if (!sdv->postblit) continue; assert(!sdv->isUnionDeclaration()); sdv->postblit->functionSemantic(); stc = mergeFuncAttrs(stc, sdv->postblit); stc = mergeFuncAttrs(stc, sdv->dtor); if (stc & STCdisable) { a->setDim(0); break; } Expression *ex = NULL; tv = v->type->toBasetype(); if (tv->ty == Tstruct) { // this.v.__xpostblit() ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call postblits on const/immutable objects. ex = new AddrExp(loc, ex); ex = new CastExp(loc, ex, v->type->mutableOf()->pointerTo()); ex = new PtrExp(loc, ex); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new DotVarExp(loc, ex, sdv->postblit, false); ex = new CallExp(loc, ex); } else { // __ArrayPostblit((cast(S*)this.v.ptr)[0 .. n]) uinteger_t n = tv->numberOfElems(loc); if (n == 0) continue; ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call postblits on const/immutable objects. ex = new DotIdExp(loc, ex, Id::ptr); ex = new CastExp(loc, ex, sdv->type->pointerTo()); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new SliceExp(loc, ex, new IntegerExp(loc, 0, Type::tsize_t), new IntegerExp(loc, n, Type::tsize_t)); // Prevent redundant bounds check ((SliceExp *)ex)->upperIsInBounds = true; ((SliceExp *)ex)->lowerIsLessThanUpper = true; ex = new CallExp(loc, new IdentifierExp(loc, Id::__ArrayPostblit), ex); } a->push(new ExpStatement(loc, ex)); // combine in forward order /* Bugzilla 10972: When the following field postblit calls fail, * this field should be destructed for Exception Safety. */ if (!sdv->dtor) continue; sdv->dtor->functionSemantic(); tv = v->type->toBasetype(); if (v->type->toBasetype()->ty == Tstruct) { // this.v.__xdtor() ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call destructors on const/immutable objects. ex = new AddrExp(loc, ex); ex = new CastExp(loc, ex, v->type->mutableOf()->pointerTo()); ex = new PtrExp(loc, ex); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new DotVarExp(loc, ex, sdv->dtor, false); ex = new CallExp(loc, ex); } else { // __ArrayDtor((cast(S*)this.v.ptr)[0 .. n]) uinteger_t n = tv->numberOfElems(loc); //if (n == 0) // continue; ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call destructors on const/immutable objects. ex = new DotIdExp(loc, ex, Id::ptr); ex = new CastExp(loc, ex, sdv->type->pointerTo()); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new SliceExp(loc, ex, new IntegerExp(loc, 0, Type::tsize_t), new IntegerExp(loc, n, Type::tsize_t)); // Prevent redundant bounds check ((SliceExp *)ex)->upperIsInBounds = true; ((SliceExp *)ex)->lowerIsLessThanUpper = true; ex = new CallExp(loc, new IdentifierExp(loc, Id::__ArrayDtor), ex); } a->push(new OnScopeStatement(loc, TOKon_scope_failure, new ExpStatement(loc, ex))); } // Build our own "postblit" which executes a, but only if needed. if (a->dim || (stc & STCdisable)) { //printf("Building __fieldPostBlit()\n"); PostBlitDeclaration *dd = new PostBlitDeclaration(declLoc, Loc(), stc, Id::__fieldPostblit); dd->generated = true; dd->storage_class |= STCinference; dd->fbody = (stc & STCdisable) ? NULL : new CompoundStatement(loc, a); sd->postblits.shift(dd); sd->members->push(dd); dd->semantic(sc); } FuncDeclaration *xpostblit = NULL; switch (sd->postblits.dim) { case 0: break; case 1: xpostblit = sd->postblits[0]; break; default: Expression *e = NULL; stc = STCsafe | STCnothrow | STCpure | STCnogc; for (size_t i = 0; i < sd->postblits.dim; i++) { FuncDeclaration *fd = sd->postblits[i]; stc = mergeFuncAttrs(stc, fd); if (stc & STCdisable) { e = NULL; break; } Expression *ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, fd, false); ex = new CallExp(loc, ex); e = Expression::combine(e, ex); } PostBlitDeclaration *dd = new PostBlitDeclaration(declLoc, Loc(), stc, Id::__aggrPostblit); dd->storage_class |= STCinference; dd->fbody = new ExpStatement(loc, e); sd->members->push(dd); dd->semantic(sc); xpostblit = dd; break; } // Add an __xpostblit alias to make the inclusive postblit accessible if (xpostblit) { AliasDeclaration *alias = new AliasDeclaration(Loc(), Id::__xpostblit, xpostblit); alias->semantic(sc); sd->members->push(alias); alias->addMember(sc, sd); // add to symbol table } return xpostblit; } /***************************************** * Create inclusive destructor for struct/class by aggregating * all the destructors in dtors[] with the destructors for * all the members. * Note the close similarity with StructDeclaration::buildPostBlit(), * and the ordering changes (runs backward instead of forwards). */ FuncDeclaration *buildDtor(AggregateDeclaration *ad, Scope *sc) { //printf("AggregateDeclaration::buildDtor() %s\n", ad->toChars()); if (ad->isUnionDeclaration()) return NULL; StorageClass stc = STCsafe | STCnothrow | STCpure | STCnogc; Loc declLoc = ad->dtors.dim ? ad->dtors[0]->loc : ad->loc; Loc loc = Loc(); // internal code should have no loc to prevent coverage Expression *e = NULL; for (size_t i = 0; i < ad->fields.dim; i++) { VarDeclaration *v = ad->fields[i]; if (v->storage_class & STCref) continue; if (v->overlapped) continue; Type *tv = v->type->baseElemOf(); if (tv->ty != Tstruct) continue; StructDeclaration *sdv = ((TypeStruct *)tv)->sym; if (!sdv->dtor) continue; sdv->dtor->functionSemantic(); stc = mergeFuncAttrs(stc, sdv->dtor); if (stc & STCdisable) { e = NULL; break; } Expression *ex = NULL; tv = v->type->toBasetype(); if (tv->ty == Tstruct) { // this.v.__xdtor() ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call destructors on const/immutable objects. ex = new AddrExp(loc, ex); ex = new CastExp(loc, ex, v->type->mutableOf()->pointerTo()); ex = new PtrExp(loc, ex); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new DotVarExp(loc, ex, sdv->dtor, false); ex = new CallExp(loc, ex); } else { // __ArrayDtor((cast(S*)this.v.ptr)[0 .. n]) uinteger_t n = tv->numberOfElems(loc); if (n == 0) continue; ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, v); // This is a hack so we can call destructors on const/immutable objects. ex = new DotIdExp(loc, ex, Id::ptr); ex = new CastExp(loc, ex, sdv->type->pointerTo()); if (stc & STCsafe) stc = (stc & ~STCsafe) | STCtrusted; ex = new SliceExp(loc, ex, new IntegerExp(loc, 0, Type::tsize_t), new IntegerExp(loc, n, Type::tsize_t)); // Prevent redundant bounds check ((SliceExp *)ex)->upperIsInBounds = true; ((SliceExp *)ex)->lowerIsLessThanUpper = true; ex = new CallExp(loc, new IdentifierExp(loc, Id::__ArrayDtor), ex); } e = Expression::combine(ex, e); // combine in reverse order } /* Build our own "destructor" which executes e */ if (e || (stc & STCdisable)) { //printf("Building __fieldDtor()\n"); DtorDeclaration *dd = new DtorDeclaration(declLoc, Loc(), stc, Id::__fieldDtor); dd->generated = true; dd->storage_class |= STCinference; dd->fbody = new ExpStatement(loc, e); ad->dtors.shift(dd); ad->members->push(dd); dd->semantic(sc); } FuncDeclaration *xdtor = NULL; switch (ad->dtors.dim) { case 0: break; case 1: xdtor = ad->dtors[0]; break; default: e = NULL; stc = STCsafe | STCnothrow | STCpure | STCnogc; for (size_t i = 0; i < ad->dtors.dim; i++) { FuncDeclaration *fd = ad->dtors[i]; stc = mergeFuncAttrs(stc, fd); if (stc & STCdisable) { e = NULL; break; } Expression *ex = new ThisExp(loc); ex = new DotVarExp(loc, ex, fd, false); ex = new CallExp(loc, ex); e = Expression::combine(ex, e); } DtorDeclaration *dd = new DtorDeclaration(declLoc, Loc(), stc, Id::__aggrDtor); dd->generated = true; dd->storage_class |= STCinference; dd->fbody = new ExpStatement(loc, e); ad->members->push(dd); dd->semantic(sc); xdtor = dd; break; } // Add an __xdtor alias to make the inclusive dtor accessible if (xdtor) { AliasDeclaration *alias = new AliasDeclaration(Loc(), Id::__xdtor, xdtor); alias->semantic(sc); ad->members->push(alias); alias->addMember(sc, ad); // add to symbol table } return xdtor; } /****************************************** * Create inclusive invariant for struct/class by aggregating * all the invariants in invs[]. * void __invariant() const [pure nothrow @trusted] * { * invs[0](), invs[1](), ...; * } */ FuncDeclaration *buildInv(AggregateDeclaration *ad, Scope *sc) { StorageClass stc = STCsafe | STCnothrow | STCpure | STCnogc; Loc declLoc = ad->loc; Loc loc = Loc(); // internal code should have no loc to prevent coverage switch (ad->invs.dim) { case 0: return NULL; case 1: // Don't return invs[0] so it has uniquely generated name. /* fall through */ default: Expression *e = NULL; StorageClass stcx = 0; for (size_t i = 0; i < ad->invs.dim; i++) { stc = mergeFuncAttrs(stc, ad->invs[i]); if (stc & STCdisable) { // What should do? } StorageClass stcy = (ad->invs[i]->storage_class & STCsynchronized) | (ad->invs[i]->type->mod & MODshared ? STCshared : 0); if (i == 0) stcx = stcy; else if (stcx ^ stcy) { #if 1 // currently rejects ad->error(ad->invs[i]->loc, "mixing invariants with shared/synchronized differene is not supported"); e = NULL; break; #endif } e = Expression::combine(e, new CallExp(loc, new VarExp(loc, ad->invs[i], false))); } InvariantDeclaration *inv; inv = new InvariantDeclaration(declLoc, Loc(), stc | stcx, Id::classInvariant); inv->fbody = new ExpStatement(loc, e); ad->members->push(inv); inv->semantic(sc); return inv; } }