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bf89205f7d36a2d12412f5fa1d3fffac144e2daf
ldc/gen/toir.cpp
Frits van Bommel 1958e17734 Rewrite StructLiteralExp::toElem to store individual fields instead of 
generating a constant to fill the entire struct with a single `store`.
This is much more efficient at compile time (fixing #320) and vastly reduces
the size of the emitted code. Since LLVM no longer needs to keep the data for
all fields in "registers" until the store happens, it should also be more
efficient at run time in cases where the fields aren't assigned with constants.

There's also some code clean-up by removing duplicated logic.
2009-06-06 20:16:13 +02:00

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// Backend stubs
/* DMDFE backend stubs
* This file contains the implementations of the backend routines.
* For dmdfe these do nothing but print a message saying the module
* has been parsed. Substitute your own behaviors for these routimes.
*/
#include <stdio.h>
#include <math.h>
#include <fstream>
#include "gen/llvm.h"
#include "attrib.h"
#include "init.h"
#include "mtype.h"
#include "template.h"
#include "hdrgen.h"
#include "port.h"
#include "rmem.h"
#include "id.h"
#include "enum.h"
#include "gen/irstate.h"
#include "gen/logger.h"
#include "gen/tollvm.h"
#include "gen/llvmhelpers.h"
#include "gen/runtime.h"
#include "gen/arrays.h"
#include "gen/structs.h"
#include "gen/classes.h"
#include "gen/typeinf.h"
#include "gen/complex.h"
#include "gen/dvalue.h"
#include "gen/aa.h"
#include "gen/functions.h"
#include "gen/todebug.h"
#include "gen/nested.h"
#include "gen/utils.h"
#include "llvm/Support/ManagedStatic.h"
//////////////////////////////////////////////////////////////////////////////////////////
void Expression::cacheLvalue(IRState* irs)
{
error("expression %s does not mask any l-value", toChars());
fatal();
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* DeclarationExp::toElem(IRState* p)
{
Logger::print("DeclarationExp::toElem: %s | T=%s\n", toChars(), type->toChars());
LOG_SCOPE;
return DtoDeclarationExp(declaration);
}
//////////////////////////////////////////////////////////////////////////////////////////
void VarExp::cacheLvalue(IRState* p)
{
Logger::println("Caching l-value of %s", toChars());
LOG_SCOPE;
cachedLvalue = toElem(p)->getLVal();
}
DValue* VarExp::toElem(IRState* p)
{
Logger::print("VarExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(var);
if (cachedLvalue)
{
LLValue* V = cachedLvalue;
cachedLvalue = NULL;
return new DVarValue(type, V);
}
if (VarDeclaration* vd = var->isVarDeclaration())
{
Logger::println("VarDeclaration ' %s ' of type ' %s '", vd->toChars(), vd->type->toChars());
// this is an error! must be accessed with DotVarExp
if (var->needThis())
{
error("need 'this' to access member %s", toChars());
fatal();
}
// _arguments
if (vd->ident == Id::_arguments && p->func()->_arguments)
{
Logger::println("Id::_arguments");
LLValue* v = p->func()->_arguments;
return new DVarValue(type, vd, v);
}
// _argptr
else if (vd->ident == Id::_argptr && p->func()->_argptr)
{
Logger::println("Id::_argptr");
LLValue* v = p->func()->_argptr;
return new DVarValue(type, vd, v);
}
// _dollar
else if (vd->ident == Id::dollar)
{
Logger::println("Id::dollar");
assert(!p->arrays.empty());
LLValue* tmp = DtoArrayLen(p->arrays.back());
return new DImValue(type, tmp);
}
// typeinfo
else if (TypeInfoDeclaration* tid = vd->isTypeInfoDeclaration())
{
Logger::println("TypeInfoDeclaration");
tid->codegen(Type::sir);
assert(tid->ir.getIrValue());
const LLType* vartype = DtoType(type);
LLValue* m = tid->ir.getIrValue();
if (m->getType() != getPtrToType(vartype))
m = p->ir->CreateBitCast(m, vartype, "tmp");
return new DImValue(type, m);
}
// classinfo
else if (ClassInfoDeclaration* cid = vd->isClassInfoDeclaration())
{
Logger::println("ClassInfoDeclaration: %s", cid->cd->toChars());
cid->cd->codegen(Type::sir);;
return new DVarValue(type, vd, cid->cd->ir.irStruct->getClassInfoSymbol());
}
// nested variable
#if DMDV2
else if (vd->nestedrefs.dim) {
#else
else if (vd->nestedref) {
#endif
Logger::println("nested variable");
return DtoNestedVariable(loc, type, vd);
}
// function parameter
else if (vd->isParameter()) {
Logger::println("function param");
Logger::println("type: %s", vd->type->toChars());
FuncDeclaration* fd = vd->toParent2()->isFuncDeclaration();
if (fd && fd != p->func()->decl) {
Logger::println("nested parameter");
return DtoNestedVariable(loc, type, vd);
}
else if (vd->storage_class & STClazy) {
Logger::println("lazy parameter");
assert(type->ty == Tdelegate);
return new DVarValue(type, vd->ir.getIrValue());
}
else if (vd->isRef() || vd->isOut() || DtoIsPassedByRef(vd->type) || llvm::isa<llvm::AllocaInst>(vd->ir.getIrValue())) {
return new DVarValue(type, vd, vd->ir.getIrValue());
}
else if (llvm::isa<llvm::Argument>(vd->ir.getIrValue())) {
return new DImValue(type, vd->ir.getIrValue());
}
else assert(0);
}
else {
Logger::println("a normal variable");
// take care of forward references of global variables
if (vd->isDataseg() || (vd->storage_class & STCextern)) {
vd->codegen(Type::sir);
}
LLValue* val;
if (!vd->ir.isSet() || !(val = vd->ir.getIrValue())) {
// FIXME: this error is bad!
// We should be VERY careful about adding errors in general, as they have
// a tendency to "mask" out the underlying problems ...
error("variable %s not resolved", vd->toChars());
if (Logger::enabled())
Logger::cout() << "unresolved variable had type: " << *DtoType(vd->type) << '\n';
fatal();
}
if (vd->isDataseg() || (vd->storage_class & STCextern)) {
DtoConstInitGlobal(vd);
val = DtoBitCast(val, DtoType(type->pointerTo()));
}
return new DVarValue(type, vd, val);
}
}
else if (FuncDeclaration* fdecl = var->isFuncDeclaration())
{
Logger::println("FuncDeclaration");
LLValue* func = 0;
if (fdecl->llvmInternal == LLVMinline_asm) {
error("special ldc inline asm is not a normal function");
fatal();
}
else if (fdecl->llvmInternal != LLVMva_arg) {
fdecl->codegen(Type::sir);
func = fdecl->ir.irFunc->func;
}
return new DFuncValue(fdecl, func);
}
else if (StaticStructInitDeclaration* sdecl = var->isStaticStructInitDeclaration())
{
// this seems to be the static initialiser for structs
Type* sdecltype = sdecl->type->toBasetype();
Logger::print("Sym: type=%s\n", sdecltype->toChars());
assert(sdecltype->ty == Tstruct);
TypeStruct* ts = (TypeStruct*)sdecltype;
assert(ts->sym);
ts->sym->codegen(Type::sir);
LLValue* initsym = ts->sym->ir.irStruct->getInitSymbol();
initsym = DtoBitCast(initsym, DtoType(ts->pointerTo()));
return new DVarValue(type, initsym);
}
else
{
assert(0 && "Unimplemented VarExp type");
}
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* VarExp::toConstElem(IRState* p)
{
Logger::print("VarExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
if (StaticStructInitDeclaration* sdecl = var->isStaticStructInitDeclaration())
{
// this seems to be the static initialiser for structs
Type* sdecltype = sdecl->type->toBasetype();
Logger::print("Sym: type=%s\n", sdecltype->toChars());
assert(sdecltype->ty == Tstruct);
TypeStruct* ts = (TypeStruct*)sdecltype;
ts->sym->codegen(Type::sir);
return ts->sym->ir.irStruct->getDefaultInit();
}
if (TypeInfoDeclaration* ti = var->isTypeInfoDeclaration())
{
const LLType* vartype = DtoType(type);
LLConstant* m = DtoTypeInfoOf(ti->tinfo, false);
if (m->getType() != getPtrToType(vartype))
m = llvm::ConstantExpr::getBitCast(m, vartype);
return m;
}
VarDeclaration* vd = var->isVarDeclaration();
if (vd && vd->isConst() && vd->init)
{
// return the initializer
return DtoConstInitializer(loc, type, vd->init);
}
// fail
error("non-constant expression %s", toChars());
return llvm::UndefValue::get(DtoType(type));
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* IntegerExp::toElem(IRState* p)
{
Logger::print("IntegerExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
LLConstant* c = toConstElem(p);
return new DConstValue(type, c);
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* IntegerExp::toConstElem(IRState* p)
{
Logger::print("IntegerExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
const LLType* t = DtoType(type);
if (isaPointer(t)) {
Logger::println("pointer");
LLConstant* i = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)value,false);
return llvm::ConstantExpr::getIntToPtr(i, t);
}
assert(llvm::isa<LLIntegerType>(t));
LLConstant* c = llvm::ConstantInt::get(t,(uint64_t)value,!type->isunsigned());
assert(c);
if (Logger::enabled())
Logger::cout() << "value = " << *c << '\n';
return c;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* RealExp::toElem(IRState* p)
{
Logger::print("RealExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
LLConstant* c = toConstElem(p);
return new DConstValue(type, c);
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* RealExp::toConstElem(IRState* p)
{
Logger::print("RealExp::toConstElem: %s @ %s | %La\n", toChars(), type->toChars(), value);
LOG_SCOPE;
Type* t = type->toBasetype();
return DtoConstFP(t, value);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* NullExp::toElem(IRState* p)
{
Logger::print("NullExp::toElem(type=%s): %s\n", type->toChars(),toChars());
LOG_SCOPE;
LLConstant* c = toConstElem(p);
return new DNullValue(type, c);
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* NullExp::toConstElem(IRState* p)
{
Logger::print("NullExp::toConstElem(type=%s): %s\n", type->toChars(),toChars());
LOG_SCOPE;
const LLType* t = DtoType(type);
if (type->ty == Tarray) {
assert(isaStruct(t));
return llvm::ConstantAggregateZero::get(t);
}
else {
return llvm::Constant::getNullValue(t);
}
assert(0);
return NULL;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ComplexExp::toElem(IRState* p)
{
Logger::print("ComplexExp::toElem(): %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
LLConstant* c = toConstElem(p);
LLValue* res;
if (c->isNullValue()) {
Type* t = type->toBasetype();
if (t->ty == Tcomplex32)
c = DtoConstFP(Type::tfloat32, 0);
else if (t->ty == Tcomplex64)
c = DtoConstFP(Type::tfloat64, 0);
else if (t->ty == Tcomplex80)
c = DtoConstFP(Type::tfloat80, 0);
else
assert(0);
res = DtoAggrPair(DtoType(type), c, c);
}
else {
res = DtoAggrPair(DtoType(type), c->getOperand(0), c->getOperand(1));
}
return new DImValue(type, res);
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* ComplexExp::toConstElem(IRState* p)
{
Logger::print("ComplexExp::toConstElem(): %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
return DtoConstComplex(type, value.re, value.im);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* StringExp::toElem(IRState* p)
{
Logger::print("StringExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
Type* dtype = type->toBasetype();
Type* cty = dtype->nextOf()->toBasetype();
const LLType* ct = DtoTypeNotVoid(cty);
//printf("ct = %s\n", type->nextOf()->toChars());
const LLArrayType* at = LLArrayType::get(ct,len+1);
LLConstant* _init;
if (cty->size() == 1) {
uint8_t* str = (uint8_t*)string;
std::string cont((char*)str, len);
_init = llvm::ConstantArray::get(cont,true);
}
else if (cty->size() == 2) {
uint16_t* str = (uint16_t*)string;
std::vector<LLConstant*> vals;
vals.reserve(len+1);
for(size_t i=0; i<len; ++i) {
vals.push_back(llvm::ConstantInt::get(ct, str[i], false));;
}
vals.push_back(llvm::ConstantInt::get(ct, 0, false));
_init = llvm::ConstantArray::get(at,vals);
}
else if (cty->size() == 4) {
uint32_t* str = (uint32_t*)string;
std::vector<LLConstant*> vals;
vals.reserve(len+1);
for(size_t i=0; i<len; ++i) {
vals.push_back(llvm::ConstantInt::get(ct, str[i], false));;
}
vals.push_back(llvm::ConstantInt::get(ct, 0, false));
_init = llvm::ConstantArray::get(at,vals);
}
else
assert(0);
llvm::GlobalValue::LinkageTypes _linkage = llvm::GlobalValue::InternalLinkage;
if (Logger::enabled())
Logger::cout() << "type: " << *at << "\ninit: " << *_init << '\n';
llvm::GlobalVariable* gvar = new llvm::GlobalVariable(at,true,_linkage,_init,".str",gIR->module);
llvm::ConstantInt* zero = llvm::ConstantInt::get(LLType::Int32Ty, 0, false);
LLConstant* idxs[2] = { zero, zero };
LLConstant* arrptr = llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2);
if (dtype->ty == Tarray) {
LLConstant* clen = llvm::ConstantInt::get(DtoSize_t(),len,false);
return new DImValue(type, DtoConstSlice(clen, arrptr));
}
else if (dtype->ty == Tsarray) {
const LLType* dstType = getPtrToType(LLArrayType::get(ct, len));
LLValue* emem = (gvar->getType() == dstType) ? gvar : DtoBitCast(gvar, dstType);
return new DVarValue(type, emem);
}
else if (dtype->ty == Tpointer) {
return new DImValue(type, arrptr);
}
assert(0);
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* StringExp::toConstElem(IRState* p)
{
Logger::print("StringExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
Type* t = type->toBasetype();
Type* cty = t->nextOf()->toBasetype();
bool nullterm = (t->ty != Tsarray);
size_t endlen = nullterm ? len+1 : len;
const LLType* ct = DtoType(cty);
const LLArrayType* at = LLArrayType::get(ct,endlen);
LLConstant* _init;
if (cty->size() == 1) {
uint8_t* str = (uint8_t*)string;
std::string cont((char*)str, len);
_init = llvm::ConstantArray::get(cont, nullterm);
}
else if (cty->size() == 2) {
uint16_t* str = (uint16_t*)string;
std::vector<LLConstant*> vals;
vals.reserve(len+1);
for(size_t i=0; i<len; ++i) {
vals.push_back(llvm::ConstantInt::get(ct, str[i], false));;
}
if (nullterm)
vals.push_back(llvm::ConstantInt::get(ct, 0, false));
_init = llvm::ConstantArray::get(at,vals);
}
else if (cty->size() == 4) {
uint32_t* str = (uint32_t*)string;
std::vector<LLConstant*> vals;
vals.reserve(len+1);
for(size_t i=0; i<len; ++i) {
vals.push_back(llvm::ConstantInt::get(ct, str[i], false));;
}
if (nullterm)
vals.push_back(llvm::ConstantInt::get(ct, 0, false));
_init = llvm::ConstantArray::get(at,vals);
}
else
assert(0);
if (t->ty == Tsarray)
{
return _init;
}
llvm::GlobalValue::LinkageTypes _linkage = llvm::GlobalValue::InternalLinkage;
llvm::GlobalVariable* gvar = new llvm::GlobalVariable(_init->getType(),true,_linkage,_init,".str",gIR->module);
llvm::ConstantInt* zero = llvm::ConstantInt::get(LLType::Int32Ty, 0, false);
LLConstant* idxs[2] = { zero, zero };
LLConstant* arrptr = llvm::ConstantExpr::getGetElementPtr(gvar,idxs,2);
if (t->ty == Tpointer) {
return arrptr;
}
else if (t->ty == Tarray) {
LLConstant* clen = llvm::ConstantInt::get(DtoSize_t(),len,false);
return DtoConstSlice(clen, arrptr);
}
assert(0);
return NULL;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AssignExp::toElem(IRState* p)
{
Logger::print("AssignExp::toElem: %s | (%s)(%s = %s)\n", toChars(), type->toChars(), e1->type->toChars(), e2->type ? e2->type->toChars() : 0);
LOG_SCOPE;
if (e1->op == TOKarraylength)
{
Logger::println("performing array.length assignment");
ArrayLengthExp *ale = (ArrayLengthExp *)e1;
DValue* arr = ale->e1->toElem(p);
DVarValue arrval(ale->e1->type, arr->getLVal());
DValue* newlen = e2->toElem(p);
DSliceValue* slice = DtoResizeDynArray(arrval.getType(), &arrval, newlen);
DtoAssign(loc, &arrval, slice);
return newlen;
}
Logger::println("performing normal assignment");
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
DtoAssign(loc, l, r);
if (l->isSlice())
return l;
return r;
}
//////////////////////////////////////////////////////////////////////////////////////////
/// Finds the proper lvalue for a binassign expressions.
/// Makes sure the given LHS expression is only evaluated once.
static Expression* findLvalue(IRState* irs, Expression* exp)
{
Expression* e = exp;
// skip past any casts
while(e->op == TOKcast)
e = ((CastExp*)e)->e1;
// cache lvalue and return
e->cacheLvalue(irs);
return e;
}
#define BIN_ASSIGN(X) \
DValue* X##AssignExp::toElem(IRState* p) \
{ \
Logger::print(#X"AssignExp::toElem: %s @ %s\n", toChars(), type->toChars()); \
LOG_SCOPE; \
X##Exp e3(loc, e1, e2); \
e3.type = e1->type; \
DValue* dst = findLvalue(p, e1)->toElem(p); \
DValue* res = e3.toElem(p); \
DValue* stval = DtoCast(loc, res, dst->getType()); \
DtoAssign(loc, dst, stval); \
return DtoCast(loc, res, type); \
}
BIN_ASSIGN(Add)
BIN_ASSIGN(Min)
BIN_ASSIGN(Mul)
BIN_ASSIGN(Div)
BIN_ASSIGN(Mod)
BIN_ASSIGN(And)
BIN_ASSIGN(Or)
BIN_ASSIGN(Xor)
BIN_ASSIGN(Shl)
BIN_ASSIGN(Shr)
BIN_ASSIGN(Ushr)
#undef BIN_ASSIGN
//////////////////////////////////////////////////////////////////////////////////////////
static void errorOnIllegalArrayOp(Expression* base, Expression* e1, Expression* e2)
{
Type* t1 = e1->type->toBasetype();
Type* t2 = e2->type->toBasetype();
// valid array ops would have been transformed by optimize
if ((t1->ty == Tarray || t1->ty == Tsarray) &&
(t2->ty == Tarray || t2->ty == Tsarray)
)
{
error("Array operation %s not recognized", base->toChars());
fatal();
}
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AddExp::toElem(IRState* p)
{
Logger::print("AddExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
Type* t = type->toBasetype();
Type* e1type = e1->type->toBasetype();
Type* e1next = e1type->nextOf() ? e1type->nextOf()->toBasetype() : NULL;
Type* e2type = e2->type->toBasetype();
errorOnIllegalArrayOp(this, e1, e2);
if (e1type != e2type) {
if (e1type->ty == Tpointer) {
Logger::println("add to pointer");
if (DConstValue* cv = r->isConst()) {
if (cv->c->isNullValue()) {
Logger::println("is zero");
return new DImValue(type, l->getRVal());
}
}
LLValue* v = llvm::GetElementPtrInst::Create(l->getRVal(), r->getRVal(), "tmp", p->scopebb());
return new DImValue(type, v);
}
else if (t->iscomplex()) {
return DtoComplexAdd(loc, type, l, r);
}
assert(0);
}
else if (t->iscomplex()) {
return DtoComplexAdd(loc, type, l, r);
}
else {
return DtoBinAdd(l,r);
}
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* MinExp::toElem(IRState* p)
{
Logger::print("MinExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
Type* t = type->toBasetype();
Type* t1 = e1->type->toBasetype();
Type* t2 = e2->type->toBasetype();
errorOnIllegalArrayOp(this, e1, e2);
if (t1->ty == Tpointer && t2->ty == Tpointer) {
LLValue* lv = l->getRVal();
LLValue* rv = r->getRVal();
if (Logger::enabled())
Logger::cout() << "lv: " << *lv << " rv: " << *rv << '\n';
lv = p->ir->CreatePtrToInt(lv, DtoSize_t(), "tmp");
rv = p->ir->CreatePtrToInt(rv, DtoSize_t(), "tmp");
LLValue* diff = p->ir->CreateSub(lv,rv,"tmp");
if (diff->getType() != DtoType(type))
diff = p->ir->CreateIntToPtr(diff, DtoType(type), "tmp");
return new DImValue(type, diff);
}
else if (t1->ty == Tpointer) {
LLValue* idx = p->ir->CreateNeg(r->getRVal(), "tmp");
LLValue* v = llvm::GetElementPtrInst::Create(l->getRVal(), idx, "tmp", p->scopebb());
return new DImValue(type, v);
}
else if (t->iscomplex()) {
return DtoComplexSub(loc, type, l, r);
}
else {
return DtoBinSub(l,r);
}
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* MulExp::toElem(IRState* p)
{
Logger::print("MulExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
errorOnIllegalArrayOp(this, e1, e2);
if (type->iscomplex()) {
return DtoComplexMul(loc, type, l, r);
}
return DtoBinMul(type, l, r);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* DivExp::toElem(IRState* p)
{
Logger::print("DivExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
errorOnIllegalArrayOp(this, e1, e2);
if (type->iscomplex()) {
return DtoComplexDiv(loc, type, l, r);
}
return DtoBinDiv(type, l, r);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ModExp::toElem(IRState* p)
{
Logger::print("ModExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
errorOnIllegalArrayOp(this, e1, e2);
return DtoBinRem(type, l, r);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CallExp::toElem(IRState* p)
{
Logger::print("CallExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// handle magic inline asm
if (e1->op == TOKvar)
{
VarExp* ve = (VarExp*)e1;
if (FuncDeclaration* fd = ve->var->isFuncDeclaration())
{
if (fd->llvmInternal == LLVMinline_asm)
{
return DtoInlineAsmExpr(loc, fd, arguments);
}
}
}
// get the callee value
DValue* fnval = e1->toElem(p);
// get func value if any
DFuncValue* dfnval = fnval->isFunc();
// handle magic intrinsics (mapping to instructions)
bool va_intrinsic = false;
if (dfnval && dfnval->func)
{
FuncDeclaration* fndecl = dfnval->func;
// va_start instruction
if (fndecl->llvmInternal == LLVMva_start) {
// llvm doesn't need the second param hence the override
Expression* exp = (Expression*)arguments->data[0];
DValue* expv = exp->toElem(p);
LLValue* arg = DtoBitCast(expv->getLVal(), getVoidPtrType());
return new DImValue(type, gIR->ir->CreateCall(GET_INTRINSIC_DECL(vastart), arg, ""));
}
// va_arg instruction
else if (fndecl->llvmInternal == LLVMva_arg) {
return DtoVaArg(loc, type, (Expression*)arguments->data[0]);
}
// C alloca
else if (fndecl->llvmInternal == LLVMalloca) {
Expression* exp = (Expression*)arguments->data[0];
DValue* expv = exp->toElem(p);
if (expv->getType()->toBasetype()->ty != Tint32)
expv = DtoCast(loc, expv, Type::tint32);
return new DImValue(type, p->ir->CreateAlloca(LLType::Int8Ty, expv->getRVal(), ".alloca"));
}
}
return DtoCallFunction(loc, type, fnval, arguments);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CastExp::toElem(IRState* p)
{
Logger::print("CastExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// get the value to cast
DValue* u = e1->toElem(p);
// cast it to the 'to' type, if necessary
DValue* v = u;
if (!to->equals(e1->type))
v = DtoCast(loc, u, to);
// paint the type, if necessary
if (!type->equals(to))
v = DtoPaintType(loc, v, type);
// return the new rvalue
return v;
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* CastExp::toConstElem(IRState* p)
{
Logger::print("CastExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
LLConstant* res;
const LLType* lltype = DtoType(type);
Type* tb = to->toBasetype();
// string literal to dyn array:
// reinterpret the string data as an array, calculate the length
if (e1->op == TOKstring && tb->ty == Tarray) {
/* StringExp *strexp = (StringExp*)e1;
size_t datalen = strexp->sz * strexp->len;
Type* eltype = tb->nextOf()->toBasetype();
if (datalen % eltype->size() != 0) {
error("the sizes don't line up");
return e1->toConstElem(p);
}
size_t arrlen = datalen / eltype->size();*/
error("ct cast of string to dynamic array not fully implemented");
return e1->toConstElem(p);
}
// pointer to pointer
else if (tb->ty == Tpointer && e1->type->toBasetype()->ty == Tpointer) {
res = llvm::ConstantExpr::getBitCast(e1->toConstElem(p), lltype);
}
else {
error("can not cast %s to %s at compile time", e1->type->toChars(), type->toChars());
return e1->toConstElem(p);
}
return res;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* SymOffExp::toElem(IRState* p)
{
Logger::print("SymOffExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(0 && "SymOffExp::toElem should no longer be called :/");
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AddrExp::toElem(IRState* p)
{
Logger::println("AddrExp::toElem: %s @ %s", toChars(), type->toChars());
LOG_SCOPE;
DValue* v = e1->toElem(p);
if (v->isField()) {
Logger::println("is field");
return v;
}
else if (DFuncValue* fv = v->isFunc()) {
Logger::println("is func");
//Logger::println("FuncDeclaration");
FuncDeclaration* fd = fv->func;
assert(fd);
fd->codegen(Type::sir);
return new DFuncValue(fd, fd->ir.irFunc->func);
}
else if (DImValue* im = v->isIm()) {
Logger::println("is immediate");
return v;
}
Logger::println("is nothing special");
// we special case here, since apparently taking the address of a slice is ok
LLValue* lval;
if (v->isLVal())
lval = v->getLVal();
else
{
assert(v->isSlice());
LLValue* rval = v->getRVal();
lval = DtoRawAlloca(rval->getType(), 0, ".tmp_slice_storage");
DtoStore(rval, lval);
}
if (Logger::enabled())
Logger::cout() << "lval: " << *lval << '\n';
return new DImValue(type, DtoBitCast(lval, DtoType(type)));
}
LLConstant* AddrExp::toConstElem(IRState* p)
{
// FIXME: this should probably be generalized more so we don't
// need to have a case for each thing we can take the address of
// address of global variable
if (e1->op == TOKvar)
{
VarExp* vexp = (VarExp*)e1;
// make sure 'this' isn't needed
if (vexp->var->needThis())
{
error("need 'this' to access %s", vexp->var->toChars());
fatal();
}
// global variable
if (VarDeclaration* vd = vexp->var->isVarDeclaration())
{
vd->codegen(Type::sir);
LLConstant* llc = llvm::dyn_cast<LLConstant>(vd->ir.getIrValue());
assert(llc);
return llc;
}
// static function
else if (FuncDeclaration* fd = vexp->var->isFuncDeclaration())
{
fd->codegen(Type::sir);
IrFunction* irfunc = fd->ir.irFunc;
return irfunc->func;
}
// something else
else
{
// fail
goto Lerr;
}
}
// address of indexExp
else if (e1->op == TOKindex)
{
IndexExp* iexp = (IndexExp*)e1;
// indexee must be global static array var
assert(iexp->e1->op == TOKvar);
VarExp* vexp = (VarExp*)iexp->e1;
VarDeclaration* vd = vexp->var->isVarDeclaration();
assert(vd);
assert(vd->type->toBasetype()->ty == Tsarray);
assert(vd->ir.irGlobal);
// get index
LLConstant* index = iexp->e2->toConstElem(p);
assert(index->getType() == DtoSize_t());
// gep
LLConstant* idxs[2] = { DtoConstSize_t(0), index };
LLConstant* gep = llvm::ConstantExpr::getGetElementPtr(isaConstant(vd->ir.irGlobal->value), idxs, 2);
// bitcast to requested type
assert(type->toBasetype()->ty == Tpointer);
return DtoBitCast(gep, DtoType(type));
}
else if (e1->op == TOKstructliteral)
{
// FIXME: is this right?
StructLiteralExp* slexp = (StructLiteralExp*)e1;
LLConstant* lit = slexp->toConstElem(p);
return lit;
}
// not yet supported
else
{
Lerr:
error("constant expression '%s' not yet implemented", toChars());
fatal();
}
}
//////////////////////////////////////////////////////////////////////////////////////////
void PtrExp::cacheLvalue(IRState* p)
{
Logger::println("Caching l-value of %s", toChars());
LOG_SCOPE;
cachedLvalue = e1->toElem(p)->getRVal();
}
DValue* PtrExp::toElem(IRState* p)
{
Logger::println("PtrExp::toElem: %s @ %s", toChars(), type->toChars());
LOG_SCOPE;
// function pointers are special
if (type->toBasetype()->ty == Tfunction)
{
assert(!cachedLvalue);
return new DImValue(type, e1->toElem(p)->getRVal());
}
// get the rvalue and return it as an lvalue
LLValue* V;
if (cachedLvalue)
{
V = cachedLvalue;
cachedLvalue = NULL;
}
else
{
V = e1->toElem(p)->getRVal();
}
return new DVarValue(type, V);
}
//////////////////////////////////////////////////////////////////////////////////////////
void DotVarExp::cacheLvalue(IRState* p)
{
Logger::println("Caching l-value of %s", toChars());
LOG_SCOPE;
cachedLvalue = toElem(p)->getLVal();
}
DValue* DotVarExp::toElem(IRState* p)
{
Logger::print("DotVarExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
if (cachedLvalue)
{
Logger::println("using cached lvalue");
LLValue *V = cachedLvalue;
cachedLvalue = NULL;
VarDeclaration* vd = var->isVarDeclaration();
assert(vd);
return new DVarValue(type, vd, V);
}
DValue* l = e1->toElem(p);
Type* t = type->toBasetype();
Type* e1type = e1->type->toBasetype();
//Logger::println("e1type=%s", e1type->toChars());
//Logger::cout() << *DtoType(e1type) << '\n';
if (VarDeclaration* vd = var->isVarDeclaration()) {
LLValue* arrptr;
// indexing struct pointer
if (e1type->ty == Tpointer) {
assert(e1type->nextOf()->ty == Tstruct);
TypeStruct* ts = (TypeStruct*)e1type->nextOf();
arrptr = DtoIndexStruct(l->getRVal(), ts->sym, vd);
}
// indexing normal struct
else if (e1type->ty == Tstruct) {
TypeStruct* ts = (TypeStruct*)e1type;
arrptr = DtoIndexStruct(l->getRVal(), ts->sym, vd);
}
// indexing class
else if (e1type->ty == Tclass) {
TypeClass* tc = (TypeClass*)e1type;
arrptr = DtoIndexClass(l->getRVal(), tc->sym, vd);
}
else
assert(0);
//Logger::cout() << "mem: " << *arrptr << '\n';
return new DVarValue(type, vd, arrptr);
}
else if (FuncDeclaration* fdecl = var->isFuncDeclaration())
{
DtoResolveDsymbol(fdecl);
LLValue* funcval;
LLValue* vthis2 = 0;
if (e1type->ty == Tclass) {
TypeClass* tc = (TypeClass*)e1type;
if (tc->sym->isInterfaceDeclaration()) {
vthis2 = DtoCastInterfaceToObject(l, NULL)->getRVal();
}
}
LLValue* vthis = l->getRVal();
if (!vthis2) vthis2 = vthis;
//
// decide whether this function needs to be looked up in the vtable
//
bool vtbllookup = fdecl->isAbstract() || (!fdecl->isFinal() && fdecl->isVirtual());
// even virtual functions are looked up directly if super or DotTypeExp
// are used, thus we need to walk through the this expression and check
Expression* e = e1;
while (e && vtbllookup) {
if (e->op == TOKsuper || e->op == TOKdottype)
vtbllookup = false;
else if (e->op == TOKcast)
e = ((CastExp*)e)->e1;
else
break;
}
//
// look up function
//
if (!vtbllookup) {
fdecl->codegen(Type::sir);
funcval = fdecl->ir.irFunc->func;
assert(funcval);
}
else {
DImValue vthis3(e1type, vthis);
funcval = DtoVirtualFunctionPointer(&vthis3, fdecl, toChars());
}
return new DFuncValue(fdecl, funcval, vthis2);
}
else {
printf("unsupported dotvarexp: %s\n", var->toChars());
}
assert(0);
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ThisExp::toElem(IRState* p)
{
Logger::print("ThisExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// regular this expr
if (VarDeclaration* vd = var->isVarDeclaration()) {
LLValue* v;
if (vd->toParent2() != p->func()->decl) {
Logger::println("nested this exp");
return DtoNestedVariable(loc, type, vd);
}
else {
Logger::println("normal this exp");
v = p->func()->thisArg;
}
return new DVarValue(type, vd, v);
}
// anything we're not yet handling ?
assert(0 && "no var in ThisExp");
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
void IndexExp::cacheLvalue(IRState* p)
{
Logger::println("Caching l-value of %s", toChars());
LOG_SCOPE;
cachedLvalue = toElem(p)->getLVal();
}
DValue* IndexExp::toElem(IRState* p)
{
Logger::print("IndexExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
if (cachedLvalue)
{
LLValue* V = cachedLvalue;
cachedLvalue = NULL;
return new DVarValue(type, V);
}
DValue* l = e1->toElem(p);
Type* e1type = e1->type->toBasetype();
p->arrays.push_back(l); // if $ is used it must be an array so this is fine.
DValue* r = e2->toElem(p);
p->arrays.pop_back();
LLValue* zero = DtoConstUint(0);
LLValue* one = DtoConstUint(1);
LLValue* arrptr = 0;
if (e1type->ty == Tpointer) {
arrptr = DtoGEP1(l->getRVal(),r->getRVal());
}
else if (e1type->ty == Tsarray) {
if(global.params.useArrayBounds)
DtoArrayBoundsCheck(loc, l, r, false);
arrptr = DtoGEP(l->getRVal(), zero, r->getRVal());
}
else if (e1type->ty == Tarray) {
if(global.params.useArrayBounds)
DtoArrayBoundsCheck(loc, l, r, false);
arrptr = DtoArrayPtr(l);
arrptr = DtoGEP1(arrptr,r->getRVal());
}
else if (e1type->ty == Taarray) {
return DtoAAIndex(loc, type, l, r, modifiable);
}
else {
Logger::println("invalid index exp! e1type: %s", e1type->toChars());
assert(0);
}
return new DVarValue(type, arrptr);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* SliceExp::toElem(IRState* p)
{
Logger::print("SliceExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// this is the new slicing code, it's different in that a full slice will no longer retain the original pointer.
// but this was broken if there *was* no original pointer, ie. a slice of a slice...
// now all slices have *both* the 'len' and 'ptr' fields set to != null.
// value being sliced
LLValue* elen;
LLValue* eptr;
DValue* e = e1->toElem(p);
// handle pointer slicing
Type* etype = e1->type->toBasetype();
if (etype->ty == Tpointer)
{
assert(lwr);
eptr = e->getRVal();
}
// array slice
else
{
eptr = DtoArrayPtr(e);
}
// has lower bound, pointer needs adjustment
if (lwr)
{
// must have upper bound too then
assert(upr);
// get bounds (make sure $ works)
p->arrays.push_back(e);
DValue* lo = lwr->toElem(p);
DValue* up = upr->toElem(p);
p->arrays.pop_back();
LLValue* vlo = lo->getRVal();
LLValue* vup = up->getRVal();
if(global.params.useArrayBounds && (etype->ty == Tsarray || etype->ty == Tarray))
DtoArrayBoundsCheck(loc, e, up, true);
// offset by lower
eptr = DtoGEP1(eptr, vlo);
// adjust length
elen = p->ir->CreateSub(vup, vlo, "tmp");
}
// no bounds or full slice -> just convert to slice
else
{
assert(e1->type->toBasetype()->ty != Tpointer);
// if the sliceee is a static array, we use the length of that as DMD seems
// to give contrary inconsistent sizesin some multidimensional static array cases.
// (namely default initialization, int[16][16] arr; -> int[256] arr = 0;)
if (etype->ty == Tsarray)
{
TypeSArray* tsa = (TypeSArray*)etype;
elen = DtoConstSize_t(tsa->dim->toUInteger());
// in this case, we also need to make sure the pointer is cast to the innermost element type
eptr = DtoBitCast(eptr, DtoType(tsa->nextOf()->pointerTo()));
}
// for normal code the actual array length is what we want!
else
{
elen = DtoArrayLen(e);
}
}
return new DSliceValue(type, elen, eptr);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CmpExp::toElem(IRState* p)
{
Logger::print("CmpExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
Type* t = e1->type->toBasetype();
Type* e2t = e2->type->toBasetype();
LLValue* eval = 0;
if (t->isintegral() || t->ty == Tpointer)
{
llvm::ICmpInst::Predicate cmpop;
bool skip = false;
// pointers don't report as being unsigned
bool uns = (t->isunsigned() || t->ty == Tpointer);
switch(op)
{
case TOKlt:
case TOKul:
cmpop = uns ? llvm::ICmpInst::ICMP_ULT : llvm::ICmpInst::ICMP_SLT;
break;
case TOKle:
case TOKule:
cmpop = uns ? llvm::ICmpInst::ICMP_ULE : llvm::ICmpInst::ICMP_SLE;
break;
case TOKgt:
case TOKug:
cmpop = uns ? llvm::ICmpInst::ICMP_UGT : llvm::ICmpInst::ICMP_SGT;
break;
case TOKge:
case TOKuge:
cmpop = uns ? llvm::ICmpInst::ICMP_UGE : llvm::ICmpInst::ICMP_SGE;
break;
case TOKue:
cmpop = llvm::ICmpInst::ICMP_EQ;
break;
case TOKlg:
cmpop = llvm::ICmpInst::ICMP_NE;
break;
case TOKleg:
skip = true;
eval = llvm::ConstantInt::getTrue();
break;
case TOKunord:
skip = true;
eval = llvm::ConstantInt::getFalse();
break;
default:
assert(0);
}
if (!skip)
{
LLValue* a = l->getRVal();
LLValue* b = r->getRVal();
if (Logger::enabled())
{
Logger::cout() << "type 1: " << *a << '\n';
Logger::cout() << "type 2: " << *b << '\n';
}
if (a->getType() != b->getType())
b = DtoBitCast(b, a->getType());
eval = p->ir->CreateICmp(cmpop, a, b, "tmp");
}
}
else if (t->isfloating())
{
llvm::FCmpInst::Predicate cmpop;
switch(op)
{
case TOKlt:
cmpop = llvm::FCmpInst::FCMP_OLT;break;
case TOKle:
cmpop = llvm::FCmpInst::FCMP_OLE;break;
case TOKgt:
cmpop = llvm::FCmpInst::FCMP_OGT;break;
case TOKge:
cmpop = llvm::FCmpInst::FCMP_OGE;break;
case TOKunord:
cmpop = llvm::FCmpInst::FCMP_UNO;break;
case TOKule:
cmpop = llvm::FCmpInst::FCMP_ULE;break;
case TOKul:
cmpop = llvm::FCmpInst::FCMP_ULT;break;
case TOKuge:
cmpop = llvm::FCmpInst::FCMP_UGE;break;
case TOKug:
cmpop = llvm::FCmpInst::FCMP_UGT;break;
case TOKue:
cmpop = llvm::FCmpInst::FCMP_UEQ;break;
case TOKlg:
cmpop = llvm::FCmpInst::FCMP_ONE;break;
case TOKleg:
cmpop = llvm::FCmpInst::FCMP_ORD;break;
default:
assert(0);
}
eval = p->ir->CreateFCmp(cmpop, l->getRVal(), r->getRVal(), "tmp");
}
else if (t->ty == Tsarray || t->ty == Tarray)
{
Logger::println("static or dynamic array");
eval = DtoArrayCompare(loc,op,l,r);
}
else
{
assert(0 && "Unsupported CmpExp type");
}
return new DImValue(type, eval);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* EqualExp::toElem(IRState* p)
{
Logger::print("EqualExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
Type* t = e1->type->toBasetype();
Type* e2t = e2->type->toBasetype();
//assert(t == e2t);
LLValue* eval = 0;
// the Tclass catches interface comparisons, regular
// class equality should be rewritten as a.opEquals(b) by this time
if (t->isintegral() || t->ty == Tpointer || t->ty == Tclass)
{
Logger::println("integral or pointer or interface");
llvm::ICmpInst::Predicate cmpop;
switch(op)
{
case TOKequal:
cmpop = llvm::ICmpInst::ICMP_EQ;
break;
case TOKnotequal:
cmpop = llvm::ICmpInst::ICMP_NE;
break;
default:
assert(0);
}
LLValue* lv = l->getRVal();
LLValue* rv = r->getRVal();
if (rv->getType() != lv->getType()) {
rv = DtoBitCast(rv, lv->getType());
}
if (Logger::enabled())
{
Logger::cout() << "lv: " << *lv << '\n';
Logger::cout() << "rv: " << *rv << '\n';
}
eval = p->ir->CreateICmp(cmpop, lv, rv, "tmp");
}
else if (t->iscomplex())
{
Logger::println("complex");
eval = DtoComplexEquals(loc, op, l, r);
}
else if (t->isfloating())
{
Logger::println("floating");
llvm::FCmpInst::Predicate cmpop;
switch(op)
{
case TOKequal:
cmpop = llvm::FCmpInst::FCMP_OEQ;
break;
case TOKnotequal:
cmpop = llvm::FCmpInst::FCMP_UNE;
break;
default:
assert(0);
}
eval = p->ir->CreateFCmp(cmpop, l->getRVal(), r->getRVal(), "tmp");
}
else if (t->ty == Tsarray || t->ty == Tarray)
{
Logger::println("static or dynamic array");
eval = DtoArrayEquals(loc,op,l,r);
}
else if (t->ty == Tdelegate)
{
Logger::println("delegate");
eval = DtoDelegateEquals(op,l->getRVal(),r->getRVal());
}
else if (t->ty == Tstruct)
{
Logger::println("struct");
// when this is reached it means there is no opEquals overload.
eval = DtoStructEquals(op,l,r);
}
else
{
assert(0 && "Unsupported EqualExp type");
}
return new DImValue(type, eval);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* PostExp::toElem(IRState* p)
{
Logger::print("PostExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
DValue* r = e2->toElem(p);
LLValue* val = l->getRVal();
LLValue* post = 0;
Type* e1type = e1->type->toBasetype();
Type* e2type = e2->type->toBasetype();
if (e1type->isintegral())
{
assert(e2type->isintegral());
LLValue* one = llvm::ConstantInt::get(val->getType(), 1, !e2type->isunsigned());
if (op == TOKplusplus) {
post = llvm::BinaryOperator::CreateAdd(val,one,"tmp",p->scopebb());
}
else if (op == TOKminusminus) {
post = llvm::BinaryOperator::CreateSub(val,one,"tmp",p->scopebb());
}
}
else if (e1type->ty == Tpointer)
{
assert(e2type->isintegral());
LLConstant* minusone = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)-1,true);
LLConstant* plusone = llvm::ConstantInt::get(DtoSize_t(),(uint64_t)1,false);
LLConstant* whichone = (op == TOKplusplus) ? plusone : minusone;
post = llvm::GetElementPtrInst::Create(val, whichone, "tmp", p->scopebb());
}
else if (e1type->isfloating())
{
assert(e2type->isfloating());
LLValue* one = DtoConstFP(e1type, 1.0);
if (op == TOKplusplus) {
post = llvm::BinaryOperator::CreateAdd(val,one,"tmp",p->scopebb());
}
else if (op == TOKminusminus) {
post = llvm::BinaryOperator::CreateSub(val,one,"tmp",p->scopebb());
}
}
else
assert(post);
DtoStore(post,l->getLVal());
return new DImValue(type,val);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* NewExp::toElem(IRState* p)
{
Logger::print("NewExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(newtype);
Type* ntype = newtype->toBasetype();
// new class
if (ntype->ty == Tclass) {
Logger::println("new class");
return DtoNewClass(loc, (TypeClass*)ntype, this);
}
// new dynamic array
else if (ntype->ty == Tarray)
{
Logger::println("new dynamic array: %s", newtype->toChars());
// get dim
assert(arguments);
assert(arguments->dim >= 1);
if (arguments->dim == 1)
{
DValue* sz = ((Expression*)arguments->data[0])->toElem(p);
// allocate & init
return DtoNewDynArray(loc, newtype, sz, true);
}
else
{
size_t ndims = arguments->dim;
std::vector<DValue*> dims(ndims);
for (size_t i=0; i<ndims; ++i)
dims[i] = ((Expression*)arguments->data[i])->toElem(p);
return DtoNewMulDimDynArray(loc, newtype, &dims[0], ndims, true);
}
}
// new static array
else if (ntype->ty == Tsarray)
{
assert(0);
}
// new struct
else if (ntype->ty == Tstruct)
{
Logger::println("new struct on heap: %s\n", newtype->toChars());
// allocate
LLValue* mem = DtoNew(newtype);
// init
TypeStruct* ts = (TypeStruct*)ntype;
if (ts->isZeroInit(ts->sym->loc)) {
DtoAggrZeroInit(mem);
}
else {
assert(ts->sym);
ts->sym->codegen(Type::sir);
DtoAggrCopy(mem, ts->sym->ir.irStruct->getInitSymbol());
}
return new DImValue(type, mem);
}
// new basic type
else
{
// allocate
LLValue* mem = DtoNew(newtype);
DVarValue tmpvar(newtype, mem);
// default initialize
// static arrays never appear here, so using the defaultInit is ok!
Expression* exp = newtype->defaultInit(loc);
DValue* iv = exp->toElem(gIR);
DtoAssign(loc, &tmpvar, iv);
// return as pointer-to
return new DImValue(type, mem);
}
assert(0);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* DeleteExp::toElem(IRState* p)
{
Logger::print("DeleteExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* dval = e1->toElem(p);
Type* et = e1->type->toBasetype();
// simple pointer
if (et->ty == Tpointer)
{
LLValue* rval = dval->getRVal();
DtoDeleteMemory(rval);
if (dval->isVar())
DtoStore(llvm::Constant::getNullValue(rval->getType()), dval->getLVal());
}
// class
else if (et->ty == Tclass)
{
bool onstack = false;
TypeClass* tc = (TypeClass*)et;
if (tc->sym->isInterfaceDeclaration())
{
DtoDeleteInterface(dval->getRVal());
onstack = true;
}
else if (DVarValue* vv = dval->isVar()) {
if (vv->var && vv->var->onstack) {
DtoFinalizeClass(dval->getRVal());
onstack = true;
}
}
if (!onstack) {
LLValue* rval = dval->getRVal();
DtoDeleteClass(rval);
}
if (dval->isVar()) {
LLValue* lval = dval->getLVal();
DtoStore(llvm::Constant::getNullValue(lval->getType()->getContainedType(0)), lval);
}
}
// dyn array
else if (et->ty == Tarray)
{
DtoDeleteArray(dval);
if (dval->isLVal())
DtoSetArrayToNull(dval->getLVal());
}
// unknown/invalid
else
{
assert(0 && "invalid delete");
}
// no value to return
return NULL;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ArrayLengthExp::toElem(IRState* p)
{
Logger::print("ArrayLengthExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
return new DImValue(type, DtoArrayLen(u));
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AssertExp::toElem(IRState* p)
{
Logger::print("AssertExp::toElem: %s\n", toChars());
LOG_SCOPE;
if(!global.params.useAssert)
return NULL;
// condition
DValue* cond;
Type* condty;
// special case for dmd generated assert(this); when not in -release mode
if (e1->op == TOKthis && ((ThisExp*)e1)->var == NULL)
{
LLValue* thisarg = p->func()->thisArg;
assert(thisarg && "null thisarg, but we're in assert(this) exp;");
LLValue* thisptr = DtoLoad(p->func()->thisArg);
condty = e1->type->toBasetype();
cond = new DImValue(condty, thisptr);
}
else
{
cond = e1->toElem(p);
condty = e1->type->toBasetype();
}
InvariantDeclaration* invdecl;
// class invariants
if(
global.params.useInvariants &&
condty->ty == Tclass &&
!((TypeClass*)condty)->sym->isInterfaceDeclaration())
{
Logger::println("calling class invariant");
llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_invariant");
LLValue* arg = DtoBitCast(cond->getRVal(), fn->getFunctionType()->getParamType(0));
gIR->CreateCallOrInvoke(fn, arg);
}
// struct invariants
else if(
global.params.useInvariants &&
condty->ty == Tpointer && condty->nextOf()->ty == Tstruct &&
(invdecl = ((TypeStruct*)condty->nextOf())->sym->inv) != NULL)
{
Logger::print("calling struct invariant");
DFuncValue invfunc(invdecl, invdecl->ir.irFunc->func, cond->getRVal());
DtoCallFunction(loc, NULL, &invfunc, NULL);
}
else
{
// create basic blocks
llvm::BasicBlock* oldend = p->scopeend();
llvm::BasicBlock* assertbb = llvm::BasicBlock::Create("assert", p->topfunc(), oldend);
llvm::BasicBlock* endbb = llvm::BasicBlock::Create("noassert", p->topfunc(), oldend);
// test condition
LLValue* condval = DtoCast(loc, cond, Type::tbool)->getRVal();
// branch
llvm::BranchInst::Create(endbb, assertbb, condval, p->scopebb());
// call assert runtime functions
p->scope() = IRScope(assertbb,endbb);
DtoAssert(p->func()->decl->getModule(), loc, msg ? msg->toElem(p) : NULL);
// rewrite the scope
p->scope() = IRScope(endbb,oldend);
}
// no meaningful return value
return NULL;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* NotExp::toElem(IRState* p)
{
Logger::print("NotExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
LLValue* b = DtoCast(loc, u, Type::tbool)->getRVal();
LLConstant* zero = DtoConstBool(false);
b = p->ir->CreateICmpEQ(b,zero);
return new DImValue(type, b);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AndAndExp::toElem(IRState* p)
{
Logger::print("AndAndExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
llvm::BasicBlock* oldend = p->scopeend();
llvm::BasicBlock* andand = llvm::BasicBlock::Create("andand", gIR->topfunc(), oldend);
llvm::BasicBlock* andandend = llvm::BasicBlock::Create("andandend", gIR->topfunc(), oldend);
LLValue* ubool = DtoCast(loc, u, Type::tbool)->getRVal();
llvm::BasicBlock* oldblock = p->scopebb();
llvm::BranchInst::Create(andand,andandend,ubool,p->scopebb());
p->scope() = IRScope(andand, andandend);
DValue* v = e2->toElem(p);
LLValue* vbool = 0;
if (!v->isFunc() && v->getType() != Type::tvoid)
{
vbool = DtoCast(loc, v, Type::tbool)->getRVal();
}
llvm::BasicBlock* newblock = p->scopebb();
llvm::BranchInst::Create(andandend,p->scopebb());
p->scope() = IRScope(andandend, oldend);
LLValue* resval = 0;
if (ubool == vbool || !vbool) {
// No need to create a PHI node.
resval = ubool;
} else {
llvm::PHINode* phi = p->ir->CreatePHI(LLType::Int1Ty, "andandval");
// If we jumped over evaluation of the right-hand side,
// the result is false. Otherwise it's the value of the right-hand side.
phi->addIncoming(LLConstantInt::getFalse(), oldblock);
phi->addIncoming(vbool, newblock);
resval = phi;
}
return new DImValue(type, resval);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* OrOrExp::toElem(IRState* p)
{
Logger::print("OrOrExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
llvm::BasicBlock* oldend = p->scopeend();
llvm::BasicBlock* oror = llvm::BasicBlock::Create("oror", gIR->topfunc(), oldend);
llvm::BasicBlock* ororend = llvm::BasicBlock::Create("ororend", gIR->topfunc(), oldend);
LLValue* ubool = DtoCast(loc, u, Type::tbool)->getRVal();
llvm::BasicBlock* oldblock = p->scopebb();
llvm::BranchInst::Create(ororend,oror,ubool,p->scopebb());
p->scope() = IRScope(oror, ororend);
DValue* v = e2->toElem(p);
LLValue* vbool = 0;
if (!v->isFunc() && v->getType() != Type::tvoid)
{
vbool = DtoCast(loc, v, Type::tbool)->getRVal();
}
llvm::BasicBlock* newblock = p->scopebb();
llvm::BranchInst::Create(ororend,p->scopebb());
p->scope() = IRScope(ororend, oldend);
LLValue* resval = 0;
if (ubool == vbool || !vbool) {
// No need to create a PHI node.
resval = ubool;
} else {
llvm::PHINode* phi = p->ir->CreatePHI(LLType::Int1Ty, "ororval");
// If we jumped over evaluation of the right-hand side,
// the result is true. Otherwise, it's the value of the right-hand side.
phi->addIncoming(LLConstantInt::getTrue(), oldblock);
phi->addIncoming(vbool, newblock);
resval = phi;
}
return new DImValue(type, resval);
}
//////////////////////////////////////////////////////////////////////////////////////////
#define BinBitExp(X,Y) \
DValue* X##Exp::toElem(IRState* p) \
{ \
Logger::print("%sExp::toElem: %s @ %s\n", #X, toChars(), type->toChars()); \
LOG_SCOPE; \
DValue* u = e1->toElem(p); \
DValue* v = e2->toElem(p); \
errorOnIllegalArrayOp(this, e1, e2); \
LLValue* x = llvm::BinaryOperator::Create(llvm::Instruction::Y, u->getRVal(), v->getRVal(), "tmp", p->scopebb()); \
return new DImValue(type, x); \
}
BinBitExp(And,And);
BinBitExp(Or,Or);
BinBitExp(Xor,Xor);
BinBitExp(Shl,Shl);
BinBitExp(Ushr,LShr);
DValue* ShrExp::toElem(IRState* p)
{
Logger::print("ShrExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
DValue* v = e2->toElem(p);
LLValue* x;
if (e1->type->isunsigned())
x = p->ir->CreateLShr(u->getRVal(), v->getRVal(), "tmp");
else
x = p->ir->CreateAShr(u->getRVal(), v->getRVal(), "tmp");
return new DImValue(type, x);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* HaltExp::toElem(IRState* p)
{
Logger::print("HaltExp::toElem: %s\n", toChars());
LOG_SCOPE;
// FIXME: DMD inserts a trap here... we probably should as well !?!
#if 1
DtoAssert(p->func()->decl->getModule(), loc, NULL);
#else
// call the new (?) trap intrinsic
p->ir->CreateCall(GET_INTRINSIC_DECL(trap),"");
new llvm::UnreachableInst(p->scopebb());
#endif
// this terminated the basicblock, start a new one
// this is sensible, since someone might goto behind the assert
// and prevents compiler errors if a terminator follows the assert
llvm::BasicBlock* oldend = gIR->scopeend();
llvm::BasicBlock* bb = llvm::BasicBlock::Create("afterhalt", p->topfunc(), oldend);
p->scope() = IRScope(bb,oldend);
return 0;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* DelegateExp::toElem(IRState* p)
{
Logger::print("DelegateExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
if(func->isStatic())
error("can't take delegate of static function %s, it does not require a context ptr", func->toChars());
const LLPointerType* int8ptrty = getPtrToType(LLType::Int8Ty);
assert(type->toBasetype()->ty == Tdelegate);
const LLType* dgty = DtoType(type);
DValue* u = e1->toElem(p);
LLValue* uval;
if (DFuncValue* f = u->isFunc()) {
assert(f->func);
LLValue* contextptr = DtoNestedContext(loc, f->func);
uval = DtoBitCast(contextptr, getVoidPtrType());
}
else {
DValue* src = u;
if (ClassDeclaration* cd = u->getType()->isClassHandle())
{
Logger::println("context type is class handle");
if (cd->isInterfaceDeclaration())
{
Logger::println("context type is interface");
src = DtoCastInterfaceToObject(u, ClassDeclaration::object->type);
}
}
uval = src->getRVal();
}
if (Logger::enabled())
Logger::cout() << "context = " << *uval << '\n';
LLValue* castcontext = DtoBitCast(uval, int8ptrty);
Logger::println("func: '%s'", func->toPrettyChars());
LLValue* castfptr;
if (func->isVirtual() && !func->isFinal())
castfptr = DtoVirtualFunctionPointer(u, func, toChars());
else if (func->isAbstract())
assert(0 && "TODO delegate to abstract method");
else if (func->toParent()->isInterfaceDeclaration())
assert(0 && "TODO delegate to interface method");
else
{
func->codegen(Type::sir);
castfptr = func->ir.irFunc->func;
}
castfptr = DtoBitCast(castfptr, dgty->getContainedType(1));
return new DImValue(type, DtoAggrPair(castcontext, castfptr, ".dg"));
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* IdentityExp::toElem(IRState* p)
{
Logger::print("IdentityExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
DValue* v = e2->toElem(p);
Type* t1 = e1->type->toBasetype();
// handle dynarray specially
if (t1->ty == Tarray)
return new DImValue(type, DtoDynArrayIs(op,u,v));
// also structs
else if (t1->ty == Tstruct)
return new DImValue(type, DtoStructEquals(op,u,v));
// FIXME this stuff isn't pretty
LLValue* l = u->getRVal();
LLValue* r = v->getRVal();
LLValue* eval = 0;
if (t1->ty == Tdelegate) {
if (v->isNull()) {
r = NULL;
}
else {
assert(l->getType() == r->getType());
}
eval = DtoDelegateEquals(op,l,r);
}
else if (t1->isfloating())
{
eval = (op == TOKidentity)
? p->ir->CreateFCmpOEQ(l,r,"tmp")
: p->ir->CreateFCmpONE(l,r,"tmp");
}
else if (t1->ty == Tpointer || t1->ty == Tclass)
{
if (l->getType() != r->getType()) {
if (v->isNull())
r = llvm::ConstantPointerNull::get(isaPointer(l->getType()));
else
r = DtoBitCast(r, l->getType());
}
eval = (op == TOKidentity)
? p->ir->CreateICmpEQ(l,r,"tmp")
: p->ir->CreateICmpNE(l,r,"tmp");
}
else {
assert(l->getType() == r->getType());
eval = (op == TOKidentity)
? p->ir->CreateICmpEQ(l,r,"tmp")
: p->ir->CreateICmpNE(l,r,"tmp");
}
return new DImValue(type, eval);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CommaExp::toElem(IRState* p)
{
Logger::print("CommaExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
DValue* v = e2->toElem(p);
assert(e2->type == type);
return v;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CondExp::toElem(IRState* p)
{
Logger::print("CondExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
Type* dtype = type->toBasetype();
DValue* dvv;
// voids returns will need no storage
if (dtype->ty != Tvoid) {
// allocate a temporary for the final result. failed to come up with a better way :/
LLValue* resval = DtoAlloca(dtype,"condtmp");
dvv = new DVarValue(type, resval);
} else {
dvv = new DConstValue(type, getNullValue(DtoTypeNotVoid(dtype)));
}
llvm::BasicBlock* oldend = p->scopeend();
llvm::BasicBlock* condtrue = llvm::BasicBlock::Create("condtrue", gIR->topfunc(), oldend);
llvm::BasicBlock* condfalse = llvm::BasicBlock::Create("condfalse", gIR->topfunc(), oldend);
llvm::BasicBlock* condend = llvm::BasicBlock::Create("condend", gIR->topfunc(), oldend);
DValue* c = econd->toElem(p);
LLValue* cond_val = DtoCast(loc, c, Type::tbool)->getRVal();
llvm::BranchInst::Create(condtrue,condfalse,cond_val,p->scopebb());
p->scope() = IRScope(condtrue, condfalse);
DValue* u = e1->toElem(p);
if (dtype->ty != Tvoid)
DtoAssign(loc, dvv, u);
llvm::BranchInst::Create(condend,p->scopebb());
p->scope() = IRScope(condfalse, condend);
DValue* v = e2->toElem(p);
if (dtype->ty != Tvoid)
DtoAssign(loc, dvv, v);
llvm::BranchInst::Create(condend,p->scopebb());
p->scope() = IRScope(condend, oldend);
return dvv;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ComExp::toElem(IRState* p)
{
Logger::print("ComExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* u = e1->toElem(p);
LLValue* value = u->getRVal();
LLValue* minusone = llvm::ConstantInt::get(value->getType(), (uint64_t)-1, true);
value = llvm::BinaryOperator::Create(llvm::Instruction::Xor, value, minusone, "tmp", p->scopebb());
return new DImValue(type, value);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* NegExp::toElem(IRState* p)
{
Logger::print("NegExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
if (type->iscomplex()) {
return DtoComplexNeg(loc, type, l);
}
LLValue* val = l->getRVal();
val = gIR->ir->CreateNeg(val,"negval");
return new DImValue(type, val);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CatExp::toElem(IRState* p)
{
Logger::print("CatExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
Type* t = type->toBasetype();
bool arrNarr = e1->type->toBasetype() == e2->type->toBasetype();
// array ~ array
if (arrNarr)
{
return DtoCatArrays(type, e1, e2);
}
// array ~ element
// element ~ array
else
{
return DtoCatArrayElement(type, e1, e2);
}
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* CatAssignExp::toElem(IRState* p)
{
Logger::print("CatAssignExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* l = e1->toElem(p);
Type* e1type = e1->type->toBasetype();
Type* elemtype = e1type->nextOf()->toBasetype();
Type* e2type = e2->type->toBasetype();
if (e2type == elemtype) {
DSliceValue* slice = DtoCatAssignElement(l,e2);
DtoAssign(loc, l, slice);
}
else if (e1type == e2type) {
DSliceValue* slice = DtoCatAssignArray(l,e2);
DtoAssign(loc, l, slice);
}
else
assert(0 && "only one element at a time right now");
return l;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* FuncExp::toElem(IRState* p)
{
Logger::print("FuncExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(fd);
if (fd->isNested()) Logger::println("nested");
Logger::println("kind = %s\n", fd->kind());
fd->codegen(Type::sir);
assert(fd->ir.irFunc->func);
if(fd->tok == TOKdelegate) {
const LLType* dgty = DtoType(type);
LLValue* cval;
IrFunction* irfn = p->func();
if (irfn->nestedVar)
cval = irfn->nestedVar;
else if (irfn->nestArg)
cval = irfn->nestArg;
else
cval = getNullPtr(getVoidPtrType());
cval = DtoBitCast(cval, dgty->getContainedType(0));
LLValue* castfptr = DtoBitCast(fd->ir.irFunc->func, dgty->getContainedType(1));
return new DImValue(type, DtoAggrPair(cval, castfptr, ".func"));
} else if(fd->tok == TOKfunction) {
return new DImValue(type, fd->ir.irFunc->func);
}
assert(0 && "fd->tok must be TOKfunction or TOKdelegate");
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* FuncExp::toConstElem(IRState* p)
{
Logger::print("FuncExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(fd);
if (fd->tok != TOKfunction)
{
assert(fd->tok == TOKdelegate);
error("delegate literals as constant expressions are not yet allowed");
}
fd->codegen(Type::sir);
assert(fd->ir.irFunc->func);
return fd->ir.irFunc->func;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* ArrayLiteralExp::toElem(IRState* p)
{
Logger::print("ArrayLiteralExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// D types
Type* arrayType = type->toBasetype();
Type* elemType = arrayType->nextOf()->toBasetype();
// is dynamic ?
bool dyn = (arrayType->ty == Tarray);
// length
size_t len = elements->dim;
// llvm target type
const LLType* llType = DtoType(arrayType);
if (Logger::enabled())
Logger::cout() << (dyn?"dynamic":"static") << " array literal with length " << len << " of D type: '" << arrayType->toChars() << "' has llvm type: '" << *llType << "'\n";
// llvm storage type
const LLType* llElemType = DtoTypeNotVoid(elemType);
const LLType* llStoType = LLArrayType::get(llElemType, len);
if (Logger::enabled())
Logger::cout() << "llvm storage type: '" << *llStoType << "'\n";
// don't allocate storage for zero length dynamic array literals
if (dyn && len == 0)
{
// dmd seems to just make them null...
return new DSliceValue(type, DtoConstSize_t(0), getNullPtr(getPtrToType(llElemType)));
}
// dst pointer
LLValue* dstMem;
DSliceValue* dynSlice = NULL;
if(dyn)
{
dynSlice = DtoNewDynArray(loc, arrayType, new DConstValue(Type::tsize_t, DtoConstSize_t(len)), false);
dstMem = dynSlice->ptr;
}
else
dstMem = DtoRawAlloca(llStoType, 0, "arrayliteral");
// store elements
for (size_t i=0; i<len; ++i)
{
Expression* expr = (Expression*)elements->data[i];
LLValue* elemAddr;
if(dyn)
elemAddr = DtoGEPi1(dstMem, i, "tmp", p->scopebb());
else
elemAddr = DtoGEPi(dstMem,0,i,"tmp",p->scopebb());
// emulate assignment
DVarValue* vv = new DVarValue(expr->type, elemAddr);
DValue* e = expr->toElem(p);
DtoAssign(loc, vv, e);
}
// return storage directly ?
if (!dyn)
return new DImValue(type, dstMem);
// return slice
return dynSlice;
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* ArrayLiteralExp::toConstElem(IRState* p)
{
Logger::print("ArrayLiteralExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// extract D types
Type* bt = type->toBasetype();
Type* elemt = bt->nextOf();
// build llvm array type
const LLArrayType* arrtype = LLArrayType::get(DtoType(elemt), elements->dim);
// dynamic arrays can occur here as well ...
bool dyn = (bt->ty == Tarray);
// build the initializer
std::vector<LLConstant*> vals(elements->dim, NULL);
for (unsigned i=0; i<elements->dim; ++i)
{
Expression* expr = (Expression*)elements->data[i];
vals[i] = expr->toConstElem(p);
}
// build the constant array initializer
LLConstant* initval = llvm::ConstantArray::get(arrtype, vals);
// if static array, we're done
if (!dyn)
return initval;
// for dynamic arrays we need to put the initializer in a global, and build a constant dynamic array reference with the .ptr field pointing into this global
// Important: don't make the global constant, since this const initializer might
// be used as an initializer for a static T[] - where modifying contents is allowed.
LLConstant* globalstore = new LLGlobalVariable(arrtype, false, LLGlobalValue::InternalLinkage, initval, ".dynarrayStorage", p->module);
LLConstant* idxs[2] = { DtoConstUint(0), DtoConstUint(0) };
LLConstant* globalstorePtr = llvm::ConstantExpr::getGetElementPtr(globalstore, idxs, 2);
return DtoConstSlice(DtoConstSize_t(elements->dim), globalstorePtr);
}
//////////////////////////////////////////////////////////////////////////////////////////
extern LLConstant* get_default_initializer(VarDeclaration* vd, Initializer* init);
static LLValue* write_zeroes(LLValue* mem, unsigned start, unsigned end) {
mem = DtoBitCast(mem, getVoidPtrType());
LLValue* gep = DtoGEPi1(mem, start, ".padding");
DtoMemSetZero(gep, DtoConstSize_t(end - start));
return mem;
}
DValue* StructLiteralExp::toElem(IRState* p)
{
Logger::print("StructLiteralExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// make sure the struct is fully resolved
sd->codegen(Type::sir);
// alloca a stack slot
LLValue* mem = DtoRawAlloca(DtoType(type), 0, ".structliteral");
// ready elements data
assert(elements && "struct literal has null elements");
size_t nexprs = elements->dim;
Expression** exprs = (Expression**)elements->data;
LLValue* voidptr = mem;
unsigned offset = 0;
// go through fields
ArrayIter<VarDeclaration> it(sd->fields);
for (; !it.done(); it.next())
{
VarDeclaration* vd = it.get();
// don't re-initialize unions
if (vd->offset < offset)
{
IF_LOG Logger::println("skipping field: %s %s (+%u)", vd->type->toChars(), vd->toChars(), vd->offset);
continue;
}
// initialize any padding so struct comparisons work
if (vd->offset != offset)
voidptr = write_zeroes(voidptr, offset, vd->offset);
offset = vd->offset + vd->type->size();
IF_LOG Logger::println("initializing field: %s %s (+%u)", vd->type->toChars(), vd->toChars(), vd->offset);
// get initializer
Expression* expr = (it.index < nexprs) ? exprs[it.index] : NULL;
IF_LOG Logger::println("expr: %p", expr);
DValue* val;
DConstValue cv(vd->type, NULL); // Only used in one branch; value is set beforehand
if (expr)
{
IF_LOG Logger::println("expr %zu = %s", it.index, expr->toChars());
val = expr->toElem(gIR);
}
else
{
IF_LOG Logger::println("using default initializer");
cv.c = get_default_initializer(vd, NULL);
val = &cv;
}
// get a pointer to this field
DVarValue field(vd->type, vd, DtoIndexStruct(mem, sd, vd));
// store the initializer there
DtoAssign(loc, &field, val);
}
// initialize trailing padding
if (sd->structsize != offset)
write_zeroes(voidptr, offset, sd->structsize);
// return as a var
return new DVarValue(type, mem);
}
//////////////////////////////////////////////////////////////////////////////////////////
LLConstant* StructLiteralExp::toConstElem(IRState* p)
{
Logger::print("StructLiteralExp::toConstElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
// make sure the struct is resolved
sd->codegen(Type::sir);
// get inits
std::vector<LLValue*> inits(sd->fields.dim, NULL);
size_t nexprs = elements->dim;;
Expression** exprs = (Expression**)elements->data;
for (size_t i = 0; i < nexprs; i++)
if (exprs[i])
inits[i] = exprs[i]->toConstElem(p);
// vector of values to build aggregate from
std::vector<LLValue*> values = DtoStructLiteralValues(sd, inits);
// we know those values are constants.. cast them
std::vector<LLConstant*> constvals(values.size(), NULL);
for (size_t i = 0; i < values.size(); ++i)
constvals[i] = llvm::cast<LLConstant>(values[i]);
// return constant struct
return LLConstantStruct::get(constvals, sd->ir.irStruct->packed);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* InExp::toElem(IRState* p)
{
Logger::print("InExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
DValue* key = e1->toElem(p);
DValue* aa = e2->toElem(p);
return DtoAAIn(loc, type, aa, key);
}
DValue* RemoveExp::toElem(IRState* p)
{
Logger::print("RemoveExp::toElem: %s\n", toChars());
LOG_SCOPE;
DValue* aa = e1->toElem(p);
DValue* key = e2->toElem(p);
DtoAARemove(loc, aa, key);
return NULL; // does not produce anything useful
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* AssocArrayLiteralExp::toElem(IRState* p)
{
Logger::print("AssocArrayLiteralExp::toElem: %s @ %s\n", toChars(), type->toChars());
LOG_SCOPE;
assert(keys);
assert(values);
assert(keys->dim == values->dim);
Type* aatype = type->toBasetype();
Type* vtype = aatype->nextOf();
// it should be possible to avoid the temporary in some cases
LLValue* tmp = DtoAlloca(type,"aaliteral");
DValue* aa = new DVarValue(type, tmp);
DtoStore(LLConstant::getNullValue(DtoType(type)), tmp);
const size_t n = keys->dim;
for (size_t i=0; i<n; ++i)
{
Expression* ekey = (Expression*)keys->data[i];
Expression* eval = (Expression*)values->data[i];
Logger::println("(%zu) aa[%s] = %s", i, ekey->toChars(), eval->toChars());
// index
DValue* key = ekey->toElem(p);
DValue* mem = DtoAAIndex(loc, vtype, aa, key, true);
// store
DValue* val = eval->toElem(p);
DtoAssign(loc, mem, val);
}
return aa;
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* GEPExp::toElem(IRState* p)
{
// this should be good enough for now!
DValue* val = e1->toElem(p);
assert(val->isLVal());
LLValue* v = DtoGEPi(val->getLVal(), 0, index);
return new DVarValue(type, DtoBitCast(v, getPtrToType(DtoType(type))));
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* BoolExp::toElem(IRState* p)
{
return new DImValue(type, DtoCast(loc, e1->toElem(p), Type::tbool)->getRVal());
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* DotTypeExp::toElem(IRState* p)
{
Type* t = sym->getType();
assert(t);
return e1->toElem(p);
}
//////////////////////////////////////////////////////////////////////////////////////////
DValue* TypeExp::toElem(IRState *p)
{
error("type %s is not an expression", toChars());
//TODO: Improve error handling. DMD just returns some value here and hopes
// some more sensible error messages will be triggered.
fatal();
return NULL;
}
//////////////////////////////////////////////////////////////////////////////////////////
#define STUB(x) DValue *x::toElem(IRState * p) {error("Exp type "#x" not implemented: %s", toChars()); fatal(); return 0; }
STUB(Expression);
STUB(ScopeExp);
STUB(TupleExp);
#if DMDV2
STUB(SymbolExp);
#endif
#define CONSTSTUB(x) LLConstant* x::toConstElem(IRState * p) { \
error("expression '%s' is not a constant", toChars()); \
fatal(); \
return NULL; \
}
CONSTSTUB(Expression);
CONSTSTUB(GEPExp);
CONSTSTUB(SliceExp);
CONSTSTUB(IndexExp);
CONSTSTUB(AssocArrayLiteralExp);
//////////////////////////////////////////////////////////////////////////////////////////
void obj_includelib(const char* lib)
{
size_t n = strlen(lib)+3;
char *arg = (char *)mem.malloc(n);
strcpy(arg, "-l");
strncat(arg, lib, n);
global.params.linkswitches->push(arg);
}
void backend_init()
{
// LLVM_D_InitRuntime is done in Module::genLLVMModule
// since it requires the semantic pass to be done
}
void backend_term()
{
LLVM_D_FreeRuntime();
llvm::llvm_shutdown();
}
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