int BaseClass::fillVtbl(ClassDeclaration *cd, FuncDeclarations *vtbl, int newinstance)
{
ClassDeclaration *id = base;
int result = 0;
//printf("BaseClass::fillVtbl(this='%s', cd='%s')\n", base->toChars(), cd->toChars());
if (vtbl)
vtbl->setDim(base->vtbl.dim);
// first entry is ClassInfo reference
for (size_t j = base->vtblOffset(); j < base->vtbl.dim; j++)
{
FuncDeclaration *ifd = base->vtbl[j]->isFuncDeclaration();
FuncDeclaration *fd;
TypeFunction *tf;
//printf(" vtbl[%d] is '%s'\n", j, ifd ? ifd->toChars() : "null");
assert(ifd);
// Find corresponding function in this class
tf = (ifd->type->ty == Tfunction) ? (TypeFunction *)(ifd->type) : NULL;
assert(tf); // should always be non-null
fd = cd->findFunc(ifd->ident, tf);
if (fd && !fd->isAbstract())
{
//printf(" found\n");
// Check that calling conventions match
if (fd->linkage != ifd->linkage)
fd->error("linkage doesn't match interface function");
// Check that it is current
if (newinstance &&
fd->toParent() != cd &&
ifd->toParent() == base)
cd->error("interface function %s.%s is not implemented",
id->toChars(), ifd->ident->toChars());
if (fd->toParent() == cd)
result = 1;
}
else
{
//printf(" not found\n");
// BUG: should mark this class as abstract?
if (!cd->isAbstract())
cd->error("interface function %s.%s%s isn't implemented",
id->toChars(), ifd->ident->toChars(),
Parameter::argsTypesToChars(tf->parameters, tf->varargs));
fd = NULL;
}
if (vtbl)
(*vtbl)[j] = fd;
}
return result;
}
bool ClassDeclaration::isAbstract()
{
if (isabstract)
return true;
for (size_t i = 1; i < vtbl.dim; i++)
{
FuncDeclaration *fd = vtbl[i]->isFuncDeclaration();
//printf("\tvtbl[%d] = %p\n", i, fd);
if (!fd || fd->isAbstract())
{
isabstract |= 1;
return true;
}
}
return false;
}
int ClassDeclaration::isAbstract()
{
if (isabstract)
return TRUE;
for (size_t i = 1; i < vtbl.dim; i++)
{
FuncDeclaration *fd = vtbl.tdata()[i]->isFuncDeclaration();
//printf("\tvtbl[%d] = %p\n", i, fd);
if (!fd || fd->isAbstract())
{
isabstract |= 1;
return TRUE;
}
}
return FALSE;
}
int ClassDeclaration::isAbstract()
{
if (isabstract)
return TRUE;
for (int i = 1; i < vtbl.dim; i++)
{
FuncDeclaration *fd = ((Dsymbol *)vtbl.data[i])->isFuncDeclaration();
//printf("\tvtbl[%d] = %p\n", i, fd);
if (!fd || fd->isAbstract())
{
isabstract |= 1;
return TRUE;
}
}
return FALSE;
}
Expression *TraitsExp::semantic(Scope *sc)
{
#if LOGSEMANTIC
printf("TraitsExp::semantic() %s\n", toChars());
#endif
if (ident != Id::compiles && ident != Id::isSame &&
ident != Id::identifier)
{
TemplateInstance::semanticTiargs(loc, sc, args, 1);
}
size_t dim = args ? args->dim : 0;
Declaration *d;
#define ISTYPE(cond) \
for (size_t i = 0; i < dim; i++) \
{ Type *t = getType((*args)[i]); \
if (!t) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
#define ISDSYMBOL(cond) \
for (size_t i = 0; i < dim; i++) \
{ Dsymbol *s = getDsymbol((*args)[i]); \
if (!s) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
if (ident == Id::isArithmetic)
{
ISTYPE(t->isintegral() || t->isfloating())
}
else if (ident == Id::isFloating)
{
ISTYPE(t->isfloating())
}
else if (ident == Id::isIntegral)
{
ISTYPE(t->isintegral())
}
else if (ident == Id::isScalar)
{
ISTYPE(t->isscalar())
}
else if (ident == Id::isUnsigned)
{
ISTYPE(t->isunsigned())
}
else if (ident == Id::isAssociativeArray)
{
ISTYPE(t->toBasetype()->ty == Taarray)
}
else if (ident == Id::isStaticArray)
{
ISTYPE(t->toBasetype()->ty == Tsarray)
}
else if (ident == Id::isAbstractClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->isAbstract())
}
else if (ident == Id::isFinalClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->storage_class & STCfinal)
}
else if (ident == Id::isAbstractFunction)
{
FuncDeclaration *f;
ISDSYMBOL((f = s->isFuncDeclaration()) != NULL && f->isAbstract())
}
Expression *TraitsExp::semantic(Scope *sc)
{
#if LOGSEMANTIC
printf("TraitsExp::semantic() %s\n", toChars());
#endif
if (ident != Id::compiles && ident != Id::isSame &&
ident != Id::identifier)
{
TemplateInstance::semanticTiargs(loc, sc, args, 1);
}
size_t dim = args ? args->dim : 0;
Declaration *d;
#define ISTYPE(cond) \
for (size_t i = 0; i < dim; i++) \
{ Type *t = getType((*args)[i]); \
if (!t) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
#define ISDSYMBOL(cond) \
for (size_t i = 0; i < dim; i++) \
{ Dsymbol *s = getDsymbol((*args)[i]); \
if (!s) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
if (ident == Id::isArithmetic)
{
ISTYPE(t->isintegral() || t->isfloating())
}
else if (ident == Id::isFloating)
{
ISTYPE(t->isfloating())
}
else if (ident == Id::isIntegral)
{
ISTYPE(t->isintegral())
}
else if (ident == Id::isScalar)
{
ISTYPE(t->isscalar())
}
else if (ident == Id::isUnsigned)
{
ISTYPE(t->isunsigned())
}
else if (ident == Id::isAssociativeArray)
{
ISTYPE(t->toBasetype()->ty == Taarray)
}
else if (ident == Id::isStaticArray)
{
ISTYPE(t->toBasetype()->ty == Tsarray)
}
else if (ident == Id::isAbstractClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->isAbstract())
}
else if (ident == Id::isFinalClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->storage_class & STCfinal)
}
else if (ident == Id::isPOD)
{
if (dim != 1)
goto Ldimerror;
Object *o = (*args)[0];
Type *t = isType(o);
StructDeclaration *sd;
if (!t)
{
error("type expected as second argument of __traits %s instead of %s", ident->toChars(), o->toChars());
goto Lfalse;
}
if (t->toBasetype()->ty == Tstruct
&& ((sd = (StructDeclaration *)(((TypeStruct *)t->toBasetype())->sym)) != NULL))
{
if (sd->isPOD())
goto Ltrue;
else
goto Lfalse;
}
goto Ltrue;
}
else if (ident == Id::isNested)
{
if (dim != 1)
goto Ldimerror;
Object *o = (*args)[0];
Dsymbol *s = getDsymbol(o);
AggregateDeclaration *a;
FuncDeclaration *f;
if (!s) { }
else if ((a = s->isAggregateDeclaration()) != NULL)
{
if (a->isNested())
goto Ltrue;
else
goto Lfalse;
}
else if ((f = s->isFuncDeclaration()) != NULL)
{
if (f->isNested())
goto Ltrue;
else
goto Lfalse;
}
error("aggregate or function expected instead of '%s'", o->toChars());
goto Lfalse;
}
else if (ident == Id::isAbstractFunction)
{
FuncDeclaration *f;
ISDSYMBOL((f = s->isFuncDeclaration()) != NULL && f->isAbstract())
}
llvm::GlobalVariable * IrStruct::getInterfaceVtbl(BaseClass * b, bool new_instance, size_t interfaces_index)
{
ClassGlobalMap::iterator it = interfaceVtblMap.find(b->base);
if (it != interfaceVtblMap.end())
return it->second;
IF_LOG Logger::println("Building vtbl for implementation of interface %s in class %s",
b->base->toPrettyChars(), aggrdecl->toPrettyChars());
LOG_SCOPE;
ClassDeclaration* cd = aggrdecl->isClassDeclaration();
assert(cd && "not a class aggregate");
FuncDeclarations vtbl_array;
b->fillVtbl(cd, &vtbl_array, new_instance);
std::vector<llvm::Constant*> constants;
constants.reserve(vtbl_array.dim);
// start with the interface info
VarDeclarationIter interfaces_idx(ClassDeclaration::classinfo->fields, 3);
// index into the interfaces array
llvm::Constant* idxs[2] = {
DtoConstSize_t(0),
DtoConstSize_t(interfaces_index)
};
llvm::Constant* c = llvm::ConstantExpr::getGetElementPtr(
getInterfaceArraySymbol(), idxs, true);
constants.push_back(c);
// add virtual function pointers
size_t n = vtbl_array.dim;
for (size_t i = 1; i < n; i++)
{
Dsymbol* dsym = static_cast<Dsymbol*>(vtbl_array.data[i]);
if (dsym == NULL)
{
// FIXME
// why is this null?
// happens for mini/s.d
constants.push_back(getNullValue(getVoidPtrType()));
continue;
}
FuncDeclaration* fd = dsym->isFuncDeclaration();
assert(fd && "vtbl entry not a function");
assert((!fd->isAbstract() || fd->fbody) &&
"null symbol in interface implementation vtable");
fd->codegen(Type::sir);
assert(fd->ir.irFunc && "invalid vtbl function");
constants.push_back(fd->ir.irFunc->func);
}
// build the vtbl constant
llvm::Constant* vtbl_constant = LLConstantStruct::getAnon(gIR->context(), constants, false);
// create the global variable to hold it
llvm::GlobalValue::LinkageTypes _linkage = DtoExternalLinkage(aggrdecl);
std::string mangle("_D");
mangle.append(cd->mangle());
mangle.append("11__interface");
mangle.append(b->base->mangle());
mangle.append("6__vtblZ");
llvm::GlobalVariable* GV = new llvm::GlobalVariable(
*gIR->module,
vtbl_constant->getType(),
true,
_linkage,
vtbl_constant,
mangle
);
// insert into the vtbl map
interfaceVtblMap.insert(std::make_pair(b->base, GV));
return GV;
}
LLConstant * IrStruct::getVtblInit()
{
if (constVtbl)
return constVtbl;
IF_LOG Logger::println("Building vtbl initializer");
LOG_SCOPE;
ClassDeclaration* cd = aggrdecl->isClassDeclaration();
assert(cd && "not class");
std::vector<llvm::Constant*> constants;
constants.reserve(cd->vtbl.dim);
// start with the classinfo
llvm::Constant* c = getClassInfoSymbol();
c = DtoBitCast(c, DtoType(ClassDeclaration::classinfo->type));
constants.push_back(c);
// add virtual function pointers
size_t n = cd->vtbl.dim;
for (size_t i = 1; i < n; i++)
{
Dsymbol* dsym = static_cast<Dsymbol*>(cd->vtbl.data[i]);
assert(dsym && "null vtbl member");
FuncDeclaration* fd = dsym->isFuncDeclaration();
assert(fd && "vtbl entry not a function");
if (cd->isAbstract() || (fd->isAbstract() && !fd->fbody))
{
c = getNullValue(DtoType(fd->type->pointerTo()));
}
else
{
fd->codegen(Type::sir);
assert(fd->ir.irFunc && "invalid vtbl function");
c = fd->ir.irFunc->func;
#if DMDV2
if (cd->isFuncHidden(fd))
{ /* fd is hidden from the view of this class.
* If fd overlaps with any function in the vtbl[], then
* issue 'hidden' error.
*/
for (size_t j = 1; j < n; j++)
{ if (j == i)
continue;
FuncDeclaration *fd2 = static_cast<Dsymbol *>(cd->vtbl.data[j])->isFuncDeclaration();
if (!fd2->ident->equals(fd->ident))
continue;
if (fd->leastAsSpecialized(fd2) || fd2->leastAsSpecialized(fd))
{
if (global.params.warnings)
{
TypeFunction *tf = static_cast<TypeFunction *>(fd->type);
if (tf->ty == Tfunction)
error("%s%s is hidden by %s\n", fd->toPrettyChars(), Parameter::argsTypesToChars(tf->parameters, tf->varargs), toChars());
else
error("%s is hidden by %s\n", fd->toPrettyChars(), toChars());
}
c = DtoBitCast(LLVM_D_GetRuntimeFunction(gIR->module, "_d_hidden_func"), c->getType());
break;
}
}
}
#endif
}
constants.push_back(c);
}
// build the constant struct
LLType* vtblTy = stripModifiers(type)->irtype->isClass()->getVtbl();
constVtbl = LLConstantStruct::get(isaStruct(vtblTy), constants);
#if 0
IF_LOG Logger::cout() << "constVtbl type: " << *constVtbl->getType() << std::endl;
IF_LOG Logger::cout() << "vtbl type: " << *stripModifiers(type)->irtype->isClass()->getVtbl() << std::endl;
#endif
#if 0
size_t nc = constants.size();
for (size_t i = 0; i < nc; ++i)
{
if (constVtbl->getOperand(i)->getType() != vtblTy->getContainedType(i))
{
Logger::cout() << "type mismatch for entry # " << i << " in vtbl initializer" << std::endl;
constVtbl->getOperand(i)->dump();
vtblTy->getContainedType(i)->dump();
}
}
#endif
assert(constVtbl->getType() == stripModifiers(type)->irtype->isClass()->getVtbl() &&
"vtbl initializer type mismatch");
return constVtbl;
}
Expression *TraitsExp::semantic(Scope *sc)
{
#if LOGSEMANTIC
printf("TraitsExp::semantic() %s\n", toChars());
#endif
if (ident != Id::compiles && ident != Id::isSame)
TemplateInstance::semanticTiargs(loc, sc, args, 1);
size_t dim = args ? args->dim : 0;
Object *o;
FuncDeclaration *f;
#define ISTYPE(cond) \
for (size_t i = 0; i < dim; i++) \
{ Type *t = getType((Object *)args->data[i]); \
if (!t) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
#define ISDSYMBOL(cond) \
for (size_t i = 0; i < dim; i++) \
{ Dsymbol *s = getDsymbol((Object *)args->data[i]); \
if (!s) \
goto Lfalse; \
if (!(cond)) \
goto Lfalse; \
} \
if (!dim) \
goto Lfalse; \
goto Ltrue;
if (ident == Id::isArithmetic)
{
ISTYPE(t->isintegral() || t->isfloating())
}
else if (ident == Id::isFloating)
{
ISTYPE(t->isfloating())
}
else if (ident == Id::isIntegral)
{
ISTYPE(t->isintegral())
}
else if (ident == Id::isScalar)
{
ISTYPE(t->isscalar())
}
else if (ident == Id::isUnsigned)
{
ISTYPE(t->isunsigned())
}
else if (ident == Id::isAssociativeArray)
{
ISTYPE(t->toBasetype()->ty == Taarray)
}
else if (ident == Id::isStaticArray)
{
ISTYPE(t->toBasetype()->ty == Tsarray)
}
else if (ident == Id::isAbstractClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->isAbstract())
}
else if (ident == Id::isFinalClass)
{
ISTYPE(t->toBasetype()->ty == Tclass && ((TypeClass *)t->toBasetype())->sym->storage_class & STCfinal)
}
else if (ident == Id::isAbstractFunction)
{
ISDSYMBOL((f = s->isFuncDeclaration()) != NULL && f->isAbstract())
}
else if (ident == Id::isVirtualFunction)
{
ISDSYMBOL((f = s->isFuncDeclaration()) != NULL && f->isVirtual())
}
else if (ident == Id::isFinalFunction)
{
ISDSYMBOL((f = s->isFuncDeclaration()) != NULL && f->isFinal())
}
else if (ident == Id::hasMember ||
ident == Id::getMember ||
ident == Id::getVirtualFunctions)
{
if (dim != 2)
goto Ldimerror;
Object *o = (Object *)args->data[0];
Expression *e = isExpression((Object *)args->data[1]);
if (!e)
{ // error("expression expected as second argument of __traits %s", ident->toChars());
goto Lfalse;
}
e = e->optimize(WANTvalue | WANTinterpret);
if (e->op != TOKstring)
{ // error("string expected as second argument of __traits %s instead of %s", ident->toChars(), e->toChars());
goto Lfalse;
}
StringExp *se = (StringExp *)e;
se = se->toUTF8(sc);
if (se->sz != 1)
{ // error("string must be chars");
goto Lfalse;
}
Identifier *id = Lexer::idPool((char *)se->string);
Type *t = isType(o);
e = isExpression(o);
Dsymbol *s = isDsymbol(o);
if (t)
e = new TypeDotIdExp(loc, t, id);
else if (e)
e = new DotIdExp(loc, e, id);
else if (s)
{ e = new DsymbolExp(loc, s);
e = new DotIdExp(loc, e, id);
}
else
{ // error("invalid first argument");
goto Lfalse;
}
if (ident == Id::hasMember)
{ /* Take any errors as meaning it wasn't found
*/
unsigned errors = global.errors;
global.gag++;
e = e->semantic(sc);
global.gag--;
if (errors != global.errors)
{ if (global.gag == 0)
global.errors = errors;
goto Lfalse;
}
else
goto Ltrue;
}
else if (ident == Id::getMember)
{
e = e->semantic(sc);
return e;
}
else if (ident == Id::getVirtualFunctions)
{
unsigned errors = global.errors;
Expression *ex = e;
e = e->semantic(sc);
/* if (errors < global.errors)
error("%s cannot be resolved", ex->toChars()); */
/* Create tuple of virtual function overloads of e
*/
//e->dump(0);
Expressions *exps = new Expressions();
FuncDeclaration *f;
if (e->op == TOKvar)
{ VarExp *ve = (VarExp *)e;
f = ve->var->isFuncDeclaration();
}
else if (e->op == TOKdotvar)
{ DotVarExp *dve = (DotVarExp *)e;
f = dve->var->isFuncDeclaration();
}
else
f = NULL;
Pvirtuals p;
p.exps = exps;
p.e1 = e;
overloadApply(f, fpvirtuals, &p);
TupleExp *tup = new TupleExp(loc, exps);
return tup->semantic(sc);
}
else
assert(0);
}
else if (ident == Id::classInstanceSize)
{
if (dim != 1)
goto Ldimerror;
Object *o = (Object *)args->data[0];
Dsymbol *s = getDsymbol(o);
ClassDeclaration *cd;
if (!s || (cd = s->isClassDeclaration()) == NULL)
{
// error("first argument is not a class");
goto Lfalse;
}
return new IntegerExp(loc, cd->structsize, Type::tsize_t);
}
else if (ident == Id::allMembers || ident == Id::derivedMembers)
{
if (dim != 1)
goto Ldimerror;
Object *o = (Object *)args->data[0];
Dsymbol *s = getDsymbol(o);
ScopeDsymbol *sd;
if (!s)
{
// error("argument has no members");
goto Lfalse;
}
if ((sd = s->isScopeDsymbol()) == NULL)
{
// error("%s %s has no members", s->kind(), s->toChars());
goto Lfalse;
}
Expressions *exps = new Expressions;
while (1)
{ size_t dim = ScopeDsymbol::dim(sd->members);
for (size_t i = 0; i < dim; i++)
{
Dsymbol *sm = ScopeDsymbol::getNth(sd->members, i);
//printf("\t[%i] %s %s\n", i, sm->kind(), sm->toChars());
if (sm->ident)
{
//printf("\t%s\n", sm->ident->toChars());
char *str = sm->ident->toChars();
/* Skip if already present in exps[]
*/
for (size_t j = 0; j < exps->dim; j++)
{ StringExp *se2 = (StringExp *)exps->data[j];
if (strcmp(str, (char *)se2->string) == 0)
goto Lnext;
}
StringExp *se = new StringExp(loc, str);
exps->push(se);
}
Lnext:
;
}
ClassDeclaration *cd = sd->isClassDeclaration();
if (cd && cd->baseClass && ident == Id::allMembers)
sd = cd->baseClass; // do again with base class
else
break;
}
Expression *e = new ArrayLiteralExp(loc, exps);
e = e->semantic(sc);
return e;
}
else if (ident == Id::compiles)
{
/* Determine if all the objects - types, expressions, or symbols -
* compile without error
*/
if (!dim)
goto Lfalse;
for (size_t i = 0; i < dim; i++)
{ Object *o = (Object *)args->data[i];
Type *t;
Expression *e;
Dsymbol *s;
unsigned errors = global.errors;
global.gag++;
t = isType(o);
if (t)
{ t->resolve(loc, sc, &e, &t, &s);
if (t)
t->semantic(loc, sc);
else if (e)
e->semantic(sc);
}
else
{ e = isExpression(o);
if (e)
e->semantic(sc);
}
global.gag--;
if (errors != global.errors)
{ if (global.gag == 0)
global.errors = errors;
goto Lfalse;
}
}
goto Ltrue;
}
else if (ident == Id::isSame)
{ /* Determine if two symbols are the same
*/
if (dim != 2)
goto Ldimerror;
TemplateInstance::semanticTiargs(loc, sc, args, 0);
Object *o1 = (Object *)args->data[0];
Object *o2 = (Object *)args->data[1];
Dsymbol *s1 = getDsymbol(o1);
Dsymbol *s2 = getDsymbol(o2);
#if 0
printf("o1: %p\n", o1);
printf("o2: %p\n", o2);
if (!s1)
{ Expression *ea = isExpression(o1);
if (ea)
printf("%s\n", ea->toChars());
Type *ta = isType(o1);
if (ta)
printf("%s\n", ta->toChars());
goto Lfalse;
}
else
printf("%s %s\n", s1->kind(), s1->toChars());
#endif
if (!s1 && !s2)
{ Expression *ea1 = isExpression(o1);
Expression *ea2 = isExpression(o2);
if (ea1 && ea2 && ea1->equals(ea2))
goto Ltrue;
}
if (!s1 || !s2)
goto Lfalse;
s1 = s1->toAlias();
s2 = s2->toAlias();
if (s1 == s2)
goto Ltrue;
else
goto Lfalse;
}
else
{ // error("unrecognized trait %s", ident->toChars());
goto Lfalse;
}
return NULL;
Lnottype:
// error("%s is not a type", o->toChars());
goto Lfalse;
Ldimerror:
// error("wrong number of arguments %d", dim);
goto Lfalse;
Lfalse:
return new IntegerExp(loc, 0, Type::tbool);
Ltrue:
return new IntegerExp(loc, 1, Type::tbool);
}
llvm::GlobalVariable * IrAggr::getInterfaceVtbl(BaseClass * b, bool new_instance, size_t interfaces_index)
{
ClassGlobalMap::iterator it = interfaceVtblMap.find(b->base);
if (it != interfaceVtblMap.end())
return it->second;
IF_LOG Logger::println("Building vtbl for implementation of interface %s in class %s",
b->base->toPrettyChars(), aggrdecl->toPrettyChars());
LOG_SCOPE;
ClassDeclaration* cd = aggrdecl->isClassDeclaration();
assert(cd && "not a class aggregate");
FuncDeclarations vtbl_array;
b->fillVtbl(cd, &vtbl_array, new_instance);
std::vector<llvm::Constant*> constants;
constants.reserve(vtbl_array.dim);
if (!b->base->isCPPinterface()) { // skip interface info for CPP interfaces
// start with the interface info
VarDeclarationIter interfaces_idx(ClassDeclaration::classinfo->fields, 3);
// index into the interfaces array
llvm::Constant* idxs[2] = {
DtoConstSize_t(0),
DtoConstSize_t(interfaces_index)
};
llvm::Constant* c = llvm::ConstantExpr::getGetElementPtr(
getInterfaceArraySymbol(), idxs, true);
constants.push_back(c);
}
// add virtual function pointers
size_t n = vtbl_array.dim;
for (size_t i = b->base->vtblOffset(); i < n; i++)
{
Dsymbol* dsym = static_cast<Dsymbol*>(vtbl_array.data[i]);
if (dsym == NULL)
{
// FIXME
// why is this null?
// happens for mini/s.d
constants.push_back(getNullValue(getVoidPtrType()));
continue;
}
FuncDeclaration* fd = dsym->isFuncDeclaration();
assert(fd && "vtbl entry not a function");
assert((!fd->isAbstract() || fd->fbody) &&
"null symbol in interface implementation vtable");
fd->codegen(Type::sir);
assert(fd->ir.irFunc && "invalid vtbl function");
LLFunction *fn = fd->ir.irFunc->func;
// If the base is a cpp interface, 'this' parameter is a pointer to
// the interface not the underlying object as expected. Instead of
// the function, we place into the vtable a small wrapper, called thunk,
// that casts 'this' to the object and then pass it to the real function.
if (b->base->isCPPinterface()) {
TypeFunction *f = (TypeFunction*)fd->type->toBasetype();
assert(f->fty.arg_this);
// create the thunk function
OutBuffer name;
name.writestring("Th");
name.printf("%i", b->offset);
name.writestring(fd->mangle());
LLFunction *thunk = LLFunction::Create(isaFunction(fn->getType()->getContainedType(0)),
DtoLinkage(fd), name.toChars(), gIR->module);
// create entry and end blocks
llvm::BasicBlock* beginbb = llvm::BasicBlock::Create(gIR->context(), "entry", thunk);
llvm::BasicBlock* endbb = llvm::BasicBlock::Create(gIR->context(), "endentry", thunk);
gIR->scopes.push_back(IRScope(beginbb, endbb));
// copy the function parameters, so later we can pass them to the real function
std::vector<LLValue*> args;
llvm::Function::arg_iterator iarg = thunk->arg_begin();
for (; iarg != thunk->arg_end(); ++iarg)
args.push_back(iarg);
// cast 'this' to Object
LLValue* &thisArg = args[(f->fty.arg_sret == 0) ? 0 : 1];
LLType* thisType = thisArg->getType();
thisArg = DtoBitCast(thisArg, getVoidPtrType());
thisArg = DtoGEP1(thisArg, DtoConstInt(-b->offset));
thisArg = DtoBitCast(thisArg, thisType);
// call the real vtbl function.
LLValue *retVal = gIR->ir->CreateCall(fn, args);
// return from the thunk
if (thunk->getReturnType() == LLType::getVoidTy(gIR->context()))
llvm::ReturnInst::Create(gIR->context(), beginbb);
else
llvm::ReturnInst::Create(gIR->context(), retVal, beginbb);
// clean up
gIR->scopes.pop_back();
thunk->getBasicBlockList().pop_back();
fn = thunk;
}
constants.push_back(fn);
}
// build the vtbl constant
llvm::Constant* vtbl_constant = LLConstantStruct::getAnon(gIR->context(), constants, false);
// create the global variable to hold it
llvm::GlobalValue::LinkageTypes _linkage = DtoExternalLinkage(aggrdecl);
std::string mangle("_D");
mangle.append(cd->mangle());
mangle.append("11__interface");
mangle.append(b->base->mangle());
mangle.append("6__vtblZ");
llvm::GlobalVariable* GV = getOrCreateGlobal(cd->loc,
*gIR->module,
vtbl_constant->getType(),
true,
_linkage,
vtbl_constant,
mangle
);
// insert into the vtbl map
interfaceVtblMap.insert(std::make_pair(b->base, GV));
return GV;
}
