Mercurial > projects > ldc
view gen/llvmhelpers.cpp @ 803:c62c6936635b
Removed DtoConstFieldInitializer, it's no longer needed and was buggy.
| author | Tomas Lindquist Olsen <tomas.l.olsen@gmail.com> |
|---|---|
| date | Sat, 29 Nov 2008 21:26:50 +0100 |
| parents | 92ea3015ace6 |
| children | 6c2ff06c4201 |
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#include "gen/llvm.h" #include "llvm/Target/TargetMachineRegistry.h" #include "mars.h" #include "init.h" #include "id.h" #include "expression.h" #include "template.h" #include "module.h" #include "gen/tollvm.h" #include "gen/llvmhelpers.h" #include "gen/irstate.h" #include "gen/runtime.h" #include "gen/logger.h" #include "gen/arrays.h" #include "gen/dvalue.h" #include "gen/complex.h" #include "gen/classes.h" #include "gen/functions.h" #include "gen/typeinf.h" #include "gen/todebug.h" #include "ir/irmodule.h" #include <stack> /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // DYNAMIC MEMORY HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ LLValue* DtoNew(Type* newtype) { // get runtime function llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_allocmemoryT"); // get type info LLConstant* ti = DtoTypeInfoOf(newtype); assert(isaPointer(ti)); // call runtime allocator LLValue* mem = gIR->CreateCallOrInvoke(fn, ti, ".gc_mem")->get(); // cast return DtoBitCast(mem, getPtrToType(DtoType(newtype)), ".gc_mem"); } void DtoDeleteMemory(LLValue* ptr) { // get runtime function llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_delmemory"); // build args LLSmallVector<LLValue*,1> arg; arg.push_back(DtoBitCast(ptr, getVoidPtrType(), ".tmp")); // call gIR->CreateCallOrInvoke(fn, arg.begin(), arg.end()); } void DtoDeleteClass(LLValue* inst) { // get runtime function llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_delclass"); // build args LLSmallVector<LLValue*,1> arg; arg.push_back(DtoBitCast(inst, fn->getFunctionType()->getParamType(0), ".tmp")); // call gIR->CreateCallOrInvoke(fn, arg.begin(), arg.end()); } void DtoDeleteInterface(LLValue* inst) { // get runtime function llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_delinterface"); // build args LLSmallVector<LLValue*,1> arg; arg.push_back(DtoBitCast(inst, fn->getFunctionType()->getParamType(0), ".tmp")); // call gIR->CreateCallOrInvoke(fn, arg.begin(), arg.end()); } void DtoDeleteArray(DValue* arr) { // get runtime function llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_delarray"); // build args LLSmallVector<LLValue*,2> arg; arg.push_back(DtoArrayLen(arr)); arg.push_back(DtoBitCast(DtoArrayPtr(arr), getVoidPtrType(), ".tmp")); // call gIR->CreateCallOrInvoke(fn, arg.begin(), arg.end()); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // ALLOCA HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ llvm::AllocaInst* DtoAlloca(const LLType* lltype, const std::string& name) { return new llvm::AllocaInst(lltype, name, gIR->topallocapoint()); } llvm::AllocaInst* DtoAlloca(const LLType* lltype, LLValue* arraysize, const std::string& name) { return new llvm::AllocaInst(lltype, arraysize, name, gIR->topallocapoint()); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // ASSERT HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoAssert(Loc* loc, DValue* msg) { std::vector<LLValue*> args; // func const char* fname = msg ? "_d_assert_msg" : "_d_assert"; llvm::Function* fn = LLVM_D_GetRuntimeFunction(gIR->module, fname); // msg param if (msg) { args.push_back(msg->getRVal()); } // file param args.push_back(DtoLoad(gIR->dmodule->ir.irModule->fileName)); // line param LLConstant* c = DtoConstUint(loc->linnum); args.push_back(c); // call CallOrInvoke* call = gIR->CreateCallOrInvoke(fn, args.begin(), args.end()); // end debug info if (global.params.symdebug) DtoDwarfFuncEnd(gIR->func()->decl); // after assert is always unreachable gIR->ir->CreateUnreachable(); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // LABEL HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ LabelStatement* DtoLabelStatement(Identifier* ident) { FuncDeclaration* fd = gIR->func()->decl; FuncDeclaration::LabelMap::iterator iter = fd->labmap.find(ident->toChars()); if (iter == fd->labmap.end()) { if (fd->returnLabel && fd->returnLabel->ident->equals(ident)) { assert(fd->returnLabel->statement); return fd->returnLabel->statement; } return NULL; } return iter->second; } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // GOTO HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoGoto(Loc* loc, Identifier* target, EnclosingHandler* enclosinghandler, TryFinallyStatement* sourcetf) { assert(!gIR->scopereturned()); LabelStatement* lblstmt = DtoLabelStatement(target); if(!lblstmt) { error(*loc, "the label %s does not exist", target->toChars()); fatal(); } // if the target label is inside inline asm, error if(lblstmt->asmLabel) { error(*loc, "cannot goto to label %s inside an inline asm block", target->toChars()); fatal(); } // find target basic block std::string labelname = gIR->func()->getScopedLabelName(target->toChars()); llvm::BasicBlock*& targetBB = gIR->func()->labelToBB[labelname]; if (targetBB == NULL) targetBB = llvm::BasicBlock::Create("label", gIR->topfunc()); // find finallys between goto and label EnclosingHandler* endfinally = enclosinghandler; while(endfinally != NULL && endfinally != lblstmt->enclosinghandler) { endfinally = endfinally->getEnclosing(); } // error if didn't find tf statement of label if(endfinally != lblstmt->enclosinghandler) error(*loc, "cannot goto into try block"); // goto into finally blocks is forbidden by the spec // though it should not be problematic to implement if(lblstmt->tf != sourcetf) { error(*loc, "spec disallows goto into finally block"); fatal(); } // emit code for finallys between goto and label DtoEnclosingHandlers(enclosinghandler, endfinally); llvm::BranchInst::Create(targetBB, gIR->scopebb()); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // TRY-FINALLY, VOLATILE AND SYNCHRONIZED HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ void EnclosingSynchro::emitCode(IRState * p) { if (s->exp) DtoLeaveMonitor(s->llsync); else DtoLeaveCritical(s->llsync); } EnclosingHandler* EnclosingSynchro::getEnclosing() { return s->enclosinghandler; } //////////////////////////////////////////////////////////////////////////////////////// void EnclosingVolatile::emitCode(IRState * p) { // store-load barrier DtoMemoryBarrier(false, false, true, false); } EnclosingHandler* EnclosingVolatile::getEnclosing() { return v->enclosinghandler; } //////////////////////////////////////////////////////////////////////////////////////// void EnclosingTryFinally::emitCode(IRState * p) { assert(tf->finalbody); tf->finalbody->toIR(p); } EnclosingHandler* EnclosingTryFinally::getEnclosing() { return tf->enclosinghandler; } //////////////////////////////////////////////////////////////////////////////////////// void DtoEnclosingHandlers(EnclosingHandler* start, EnclosingHandler* end) { // verify that end encloses start EnclosingHandler* endfinally = start; while(endfinally != NULL && endfinally != end) { endfinally = endfinally->getEnclosing(); } assert(endfinally == end); // // emit code for finallys between start and end // // since the labelstatements possibly inside are private // and might already exist push a label scope gIR->func()->pushUniqueLabelScope("enclosing"); EnclosingHandler* tf = start; while(tf != end) { tf->emitCode(gIR); tf = tf->getEnclosing(); } gIR->func()->popLabelScope(); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // SYNCHRONIZED SECTION HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoEnterCritical(LLValue* g) { LLFunction* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_criticalenter"); gIR->CreateCallOrInvoke(fn, g); } void DtoLeaveCritical(LLValue* g) { LLFunction* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_criticalexit"); gIR->CreateCallOrInvoke(fn, g); } void DtoEnterMonitor(LLValue* v) { LLFunction* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_monitorenter"); v = DtoBitCast(v, fn->getFunctionType()->getParamType(0)); gIR->CreateCallOrInvoke(fn, v); } void DtoLeaveMonitor(LLValue* v) { LLFunction* fn = LLVM_D_GetRuntimeFunction(gIR->module, "_d_monitorexit"); v = DtoBitCast(v, fn->getFunctionType()->getParamType(0)); gIR->CreateCallOrInvoke(fn, v); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // NESTED VARIABLE HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ DValue* DtoNestedVariable(Loc loc, Type* astype, VarDeclaration* vd) { Dsymbol* vdparent = vd->toParent2(); assert(vdparent); IrFunction* irfunc = gIR->func(); // is the nested variable in this scope? if (vdparent == irfunc->decl) { LLValue* val = vd->ir.getIrValue(); return new DVarValue(astype, vd, val); } // get it from the nested context LLValue* ctx = 0; if (irfunc->decl->isMember2()) { ClassDeclaration* cd = irfunc->decl->isMember2()->isClassDeclaration(); LLValue* val = DtoLoad(irfunc->thisArg); ctx = DtoLoad(DtoGEPi(val, 0,cd->vthis->ir.irField->index, ".vthis")); } else ctx = irfunc->nestArg; assert(ctx); assert(vd->ir.irLocal); LLValue* val = DtoBitCast(ctx, getPtrToType(getVoidPtrType())); val = DtoGEPi1(val, vd->ir.irLocal->nestedIndex); val = DtoLoad(val); assert(vd->ir.irLocal->value); val = DtoBitCast(val, vd->ir.irLocal->value->getType(), vd->toChars()); return new DVarValue(astype, vd, val); } LLValue* DtoNestedContext(Loc loc, Dsymbol* sym) { Logger::println("DtoNestedContext for %s", sym->toPrettyChars()); LOG_SCOPE; IrFunction* irfunc = gIR->func(); // if this func has its own vars that are accessed by nested funcs // use its own context if (irfunc->nestedVar) return irfunc->nestedVar; // otherwise, it may have gotten a context from the caller else if (irfunc->nestArg) return irfunc->nestArg; // or just have a this argument else if (irfunc->thisArg) { ClassDeclaration* cd = irfunc->decl->isMember2()->isClassDeclaration(); if (!cd || !cd->vthis) return getNullPtr(getVoidPtrType()); LLValue* val = DtoLoad(irfunc->thisArg); return DtoLoad(DtoGEPi(val, 0,cd->vthis->ir.irField->index, ".vthis")); } else { return getNullPtr(getVoidPtrType()); } } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // ASSIGNMENT HELPER (store this in that) ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoAssign(Loc& loc, DValue* lhs, DValue* rhs) { Logger::println("DtoAssign(...);\n"); LOG_SCOPE; Type* t = lhs->getType()->toBasetype(); Type* t2 = rhs->getType()->toBasetype(); if (t->ty == Tstruct) { if (!t->equals(t2)) { // TODO: fix this, use 'rhs' for something DtoAggrZeroInit(lhs->getLVal()); } else { DtoAggrCopy(lhs->getLVal(), rhs->getRVal()); } } else if (t->ty == Tarray) { // lhs is slice if (DSliceValue* s = lhs->isSlice()) { if (DSliceValue* s2 = rhs->isSlice()) { DtoArrayCopySlices(s, s2); } else if (t->nextOf()->toBasetype()->equals(t2)) { DtoArrayInit(loc, s, rhs); } else { DtoArrayCopyToSlice(s, rhs); } } // rhs is slice else if (DSliceValue* s = rhs->isSlice()) { assert(s->getType()->toBasetype() == lhs->getType()->toBasetype()); DtoSetArray(lhs->getLVal(),DtoArrayLen(s),DtoArrayPtr(s)); } // null else if (rhs->isNull()) { DtoSetArrayToNull(lhs->getLVal()); } // reference assignment else if (t2->ty == Tarray) { DtoStore(rhs->getRVal(), lhs->getLVal()); } // some implicitly converting ref assignment else { DtoSetArray(lhs->getLVal(), DtoArrayLen(rhs), DtoArrayPtr(rhs)); } } else if (t->ty == Tsarray) { // T[n] = T[n] if (DtoType(lhs->getType()) == DtoType(rhs->getType())) { DtoStaticArrayCopy(lhs->getLVal(), rhs->getRVal()); } // T[n] = T else if (t->nextOf()->toBasetype()->equals(t2)) { DtoArrayInit(loc, lhs, rhs); } // T[n] = T[] - generally only generated by frontend in rare cases else if (t2->ty == Tarray && t->nextOf()->toBasetype()->equals(t2->nextOf()->toBasetype())) { DtoMemCpy(lhs->getLVal(), DtoArrayPtr(rhs), DtoArrayLen(rhs)); } else { assert(0 && "Unimplemented static array assign!"); } } else if (t->ty == Tdelegate) { LLValue* l = lhs->getLVal(); LLValue* r = rhs->getRVal(); if (Logger::enabled()) Logger::cout() << "assign\nlhs: " << *l << "rhs: " << *r << '\n'; DtoStore(r, l); } else if (t->ty == Tclass) { assert(t2->ty == Tclass); LLValue* l = lhs->getLVal(); LLValue* r = rhs->getRVal(); if (Logger::enabled()) { Logger::cout() << "l : " << *l << '\n'; Logger::cout() << "r : " << *r << '\n'; } r = DtoBitCast(r, l->getType()->getContainedType(0)); DtoStore(r, l); } else if (t->iscomplex()) { LLValue* dst; if (DLRValue* lr = lhs->isLRValue()) { dst = lr->getLVal(); rhs = DtoCastComplex(loc, rhs, lr->getLType()); } else { dst = lhs->getLVal(); } DtoStore(rhs->getRVal(), dst); } else { LLValue* l = lhs->getLVal(); LLValue* r = rhs->getRVal(); if (Logger::enabled()) Logger::cout() << "assign\nlhs: " << *l << "rhs: " << *r << '\n'; const LLType* lit = l->getType()->getContainedType(0); if (r->getType() != lit) { // handle lvalue cast assignments if (DLRValue* lr = lhs->isLRValue()) { Logger::println("lvalue cast!"); r = DtoCast(loc, rhs, lr->getLType())->getRVal(); } else { r = DtoCast(loc, rhs, lhs->getType())->getRVal(); } if (Logger::enabled()) Logger::cout() << "really assign\nlhs: " << *l << "rhs: " << *r << '\n'; assert(r->getType() == l->getType()->getContainedType(0)); } gIR->ir->CreateStore(r, l); } } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // NULL VALUE HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ DValue* DtoNullValue(Type* type) { Type* basetype = type->toBasetype(); TY basety = basetype->ty; const LLType* lltype = DtoType(basetype); // complex, needs to be first since complex are also floating if (basetype->iscomplex()) { const LLType* basefp = DtoComplexBaseType(basetype); LLValue* res = DtoAggrPair(DtoType(type), LLConstant::getNullValue(basefp), LLConstant::getNullValue(basefp)); return new DImValue(type, res); } // integer, floating, pointer and class have no special representation else if (basetype->isintegral() || basetype->isfloating() || basety == Tpointer || basety == Tclass) { return new DConstValue(type, LLConstant::getNullValue(lltype)); } // dynamic array else if (basety == Tarray) { LLValue* len = DtoConstSize_t(0); LLValue* ptr = getNullPtr(getPtrToType(DtoType(basetype->nextOf()))); return new DSliceValue(type, len, ptr); } // delegate else if (basety == Tdelegate) { return new DNullValue(type, LLConstant::getNullValue(lltype)); } // unknown std::cout << "unsupported: null value for " << type->toChars() << '\n'; assert(0); return 0; } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // CASTING HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ DValue* DtoCastInt(Loc& loc, DValue* val, Type* _to) { const LLType* tolltype = DtoType(_to); Type* to = _to->toBasetype(); Type* from = val->getType()->toBasetype(); assert(from->isintegral()); size_t fromsz = from->size(); size_t tosz = to->size(); LLValue* rval = val->getRVal(); if (rval->getType() == tolltype) { return new DImValue(_to, rval); } if (to->ty == Tbool) { LLValue* zero = LLConstantInt::get(rval->getType(), 0, false); rval = gIR->ir->CreateICmpNE(rval, zero, "tmp"); } else if (to->isintegral()) { if (fromsz < tosz || from->ty == Tbool) { if (Logger::enabled()) Logger::cout() << "cast to: " << *tolltype << '\n'; if (from->isunsigned() || from->ty == Tbool) { rval = new llvm::ZExtInst(rval, tolltype, "tmp", gIR->scopebb()); } else { rval = new llvm::SExtInst(rval, tolltype, "tmp", gIR->scopebb()); } } else if (fromsz > tosz) { rval = new llvm::TruncInst(rval, tolltype, "tmp", gIR->scopebb()); } else { rval = DtoBitCast(rval, tolltype); } } else if (to->iscomplex()) { return DtoComplex(loc, to, val); } else if (to->isfloating()) { if (from->isunsigned()) { rval = new llvm::UIToFPInst(rval, tolltype, "tmp", gIR->scopebb()); } else { rval = new llvm::SIToFPInst(rval, tolltype, "tmp", gIR->scopebb()); } } else if (to->ty == Tpointer) { if (Logger::enabled()) Logger::cout() << "cast pointer: " << *tolltype << '\n'; rval = gIR->ir->CreateIntToPtr(rval, tolltype, "tmp"); } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), _to->toChars()); fatal(); } return new DImValue(_to, rval); } DValue* DtoCastPtr(Loc& loc, DValue* val, Type* to) { const LLType* tolltype = DtoType(to); Type* totype = to->toBasetype(); Type* fromtype = val->getType()->toBasetype(); assert(fromtype->ty == Tpointer || fromtype->ty == Tfunction); LLValue* rval; if (totype->ty == Tpointer || totype->ty == Tclass) { LLValue* src = val->getRVal(); if (Logger::enabled()) Logger::cout() << "src: " << *src << "to type: " << *tolltype << '\n'; rval = DtoBitCast(src, tolltype); } else if (totype->ty == Tbool) { LLValue* src = val->getRVal(); LLValue* zero = LLConstant::getNullValue(src->getType()); rval = gIR->ir->CreateICmpNE(src, zero, "tmp"); } else if (totype->isintegral()) { rval = new llvm::PtrToIntInst(val->getRVal(), tolltype, "tmp", gIR->scopebb()); } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), to->toChars()); fatal(); } return new DImValue(to, rval); } DValue* DtoCastFloat(Loc& loc, DValue* val, Type* to) { if (val->getType() == to) return val; const LLType* tolltype = DtoType(to); Type* totype = to->toBasetype(); Type* fromtype = val->getType()->toBasetype(); assert(fromtype->isfloating()); size_t fromsz = fromtype->size(); size_t tosz = totype->size(); LLValue* rval; if (totype->ty == Tbool) { rval = val->getRVal(); LLValue* zero = LLConstant::getNullValue(rval->getType()); rval = gIR->ir->CreateFCmpUNE(rval, zero, "tmp"); } else if (totype->iscomplex()) { return DtoComplex(loc, to, val); } else if (totype->isfloating()) { if (fromsz == tosz) { rval = val->getRVal(); assert(rval->getType() == tolltype); } else if (fromsz < tosz) { rval = new llvm::FPExtInst(val->getRVal(), tolltype, "tmp", gIR->scopebb()); } else if (fromsz > tosz) { rval = new llvm::FPTruncInst(val->getRVal(), tolltype, "tmp", gIR->scopebb()); } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), to->toChars()); fatal(); } } else if (totype->isintegral()) { if (totype->isunsigned()) { rval = new llvm::FPToUIInst(val->getRVal(), tolltype, "tmp", gIR->scopebb()); } else { rval = new llvm::FPToSIInst(val->getRVal(), tolltype, "tmp", gIR->scopebb()); } } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), to->toChars()); fatal(); } return new DImValue(to, rval); } DValue* DtoCastDelegate(Loc& loc, DValue* val, Type* to) { if (to->toBasetype()->ty == Tdelegate) { return DtoPaintType(loc, val, to); } else if (to->toBasetype()->ty == Tbool) { return new DImValue(to, DtoDelegateEquals(TOKnotequal, val->getRVal(), NULL)); } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), to->toChars()); fatal(); } } DValue* DtoCast(Loc& loc, DValue* val, Type* to) { Type* fromtype = val->getType()->toBasetype(); Logger::println("Casting from '%s' to '%s'", fromtype->toChars(), to->toChars()); if (fromtype->isintegral()) { return DtoCastInt(loc, val, to); } else if (fromtype->iscomplex()) { return DtoCastComplex(loc, val, to); } else if (fromtype->isfloating()) { return DtoCastFloat(loc, val, to); } else if (fromtype->ty == Tclass) { return DtoCastClass(val, to); } else if (fromtype->ty == Tarray || fromtype->ty == Tsarray) { return DtoCastArray(loc, val, to); } else if (fromtype->ty == Tpointer || fromtype->ty == Tfunction) { return DtoCastPtr(loc, val, to); } else if (fromtype->ty == Tdelegate) { return DtoCastDelegate(loc, val, to); } else { error(loc, "invalid cast from '%s' to '%s'", val->getType()->toChars(), to->toChars()); fatal(); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoPaintType(Loc& loc, DValue* val, Type* to) { Type* from = val->getType()->toBasetype(); Logger::println("repainting from '%s' to '%s'", from->toChars(), to->toChars()); if (from->ty == Tarray) { Type* at = to->toBasetype(); assert(at->ty == Tarray); Type* elem = at->nextOf()->pointerTo(); if (DSliceValue* slice = val->isSlice()) { return new DSliceValue(to, slice->len, DtoBitCast(slice->ptr, DtoType(elem))); } else if (val->isLVal()) { LLValue* ptr = val->getLVal(); ptr = DtoBitCast(ptr, DtoType(at->pointerTo())); return new DVarValue(to, ptr); } else { LLValue *len, *ptr; len = DtoArrayLen(val); ptr = DtoArrayPtr(val); ptr = DtoBitCast(ptr, DtoType(elem)); return new DImValue(to, DtoAggrPair(len, ptr, "tmp")); } } else if (from->ty == Tdelegate) { Type* dgty = to->toBasetype(); assert(dgty->ty == Tdelegate); if (val->isLVal()) { LLValue* ptr = val->getLVal(); assert(isaPointer(ptr)); ptr = DtoBitCast(ptr, getPtrToType(DtoType(dgty))); if (Logger::enabled()) Logger::cout() << "dg ptr: " << *ptr << '\n'; return new DVarValue(to, ptr); } else { LLValue* dg = val->getRVal(); LLValue* context = gIR->ir->CreateExtractValue(dg, 0, ".context"); LLValue* funcptr = gIR->ir->CreateExtractValue(dg, 1, ".funcptr"); funcptr = DtoBitCast(funcptr, DtoType(dgty)->getContainedType(1)); LLValue* aggr = DtoAggrPair(context, funcptr, "tmp"); if (Logger::enabled()) Logger::cout() << "dg: " << *aggr << '\n'; return new DImValue(to, aggr); } } else if (from->ty == Tpointer || from->ty == Tclass || from->ty == Taarray) { Type* b = to->toBasetype(); assert(b->ty == Tpointer || b->ty == Tclass || b->ty == Taarray); LLValue* ptr = DtoBitCast(val->getRVal(), DtoType(b)); return new DImValue(to, ptr); } else { assert(!val->isLVal()); assert(DtoType(to) == DtoType(to)); return new DImValue(to, val->getRVal()); } } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // TEMPLATE HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ bool DtoIsTemplateInstance(Dsymbol* s) { if (!s) return false; if (s->isTemplateInstance() && !s->isTemplateMixin()) return true; else if (s->parent) return DtoIsTemplateInstance(s->parent); return false; } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // LAZY STATIC INIT HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoLazyStaticInit(bool istempl, LLValue* gvar, Initializer* init, Type* t) { // create a flag to make sure initialization only happens once llvm::GlobalValue::LinkageTypes gflaglink = istempl ? llvm::GlobalValue::WeakLinkage : llvm::GlobalValue::InternalLinkage; std::string gflagname(gvar->getName()); gflagname.append("__initflag"); llvm::GlobalVariable* gflag = new llvm::GlobalVariable(LLType::Int1Ty,false,gflaglink,DtoConstBool(false),gflagname,gIR->module); // check flag and do init if not already done llvm::BasicBlock* oldend = gIR->scopeend(); llvm::BasicBlock* initbb = llvm::BasicBlock::Create("ifnotinit",gIR->topfunc(),oldend); llvm::BasicBlock* endinitbb = llvm::BasicBlock::Create("ifnotinitend",gIR->topfunc(),oldend); LLValue* cond = gIR->ir->CreateICmpEQ(gIR->ir->CreateLoad(gflag,"tmp"),DtoConstBool(false)); gIR->ir->CreateCondBr(cond, initbb, endinitbb); gIR->scope() = IRScope(initbb,endinitbb); DValue* ie = DtoInitializer(gvar, init); DVarValue dst(t, gvar); DtoAssign(init->loc, &dst, ie); gIR->ir->CreateStore(DtoConstBool(true), gflag); gIR->ir->CreateBr(endinitbb); gIR->scope() = IRScope(endinitbb,oldend); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // PROCESSING QUEUE HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ void DtoResolveDsymbol(Dsymbol* dsym) { if (StructDeclaration* sd = dsym->isStructDeclaration()) { DtoResolveStruct(sd); } else if (ClassDeclaration* cd = dsym->isClassDeclaration()) { DtoResolveClass(cd); } else if (FuncDeclaration* fd = dsym->isFuncDeclaration()) { DtoResolveFunction(fd); } else if (TypeInfoDeclaration* fd = dsym->isTypeInfoDeclaration()) { DtoResolveTypeInfo(fd); } else { error(dsym->loc, "unsupported dsymbol: %s", dsym->toChars()); assert(0 && "unsupported dsymbol for DtoResolveDsymbol"); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoDeclareDsymbol(Dsymbol* dsym) { if (StructDeclaration* sd = dsym->isStructDeclaration()) { DtoDeclareStruct(sd); } else if (ClassDeclaration* cd = dsym->isClassDeclaration()) { DtoDeclareClass(cd); } else if (FuncDeclaration* fd = dsym->isFuncDeclaration()) { DtoDeclareFunction(fd); } else if (TypeInfoDeclaration* fd = dsym->isTypeInfoDeclaration()) { DtoDeclareTypeInfo(fd); } else { error(dsym->loc, "unsupported dsymbol: %s", dsym->toChars()); assert(0 && "unsupported dsymbol for DtoDeclareDsymbol"); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoConstInitDsymbol(Dsymbol* dsym) { if (StructDeclaration* sd = dsym->isStructDeclaration()) { DtoConstInitStruct(sd); } else if (ClassDeclaration* cd = dsym->isClassDeclaration()) { DtoConstInitClass(cd); } else if (TypeInfoDeclaration* fd = dsym->isTypeInfoDeclaration()) { DtoConstInitTypeInfo(fd); } else if (VarDeclaration* vd = dsym->isVarDeclaration()) { DtoConstInitGlobal(vd); } else { error(dsym->loc, "unsupported dsymbol: %s", dsym->toChars()); assert(0 && "unsupported dsymbol for DtoConstInitDsymbol"); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoDefineDsymbol(Dsymbol* dsym) { if (StructDeclaration* sd = dsym->isStructDeclaration()) { DtoDefineStruct(sd); } else if (ClassDeclaration* cd = dsym->isClassDeclaration()) { DtoDefineClass(cd); } else if (FuncDeclaration* fd = dsym->isFuncDeclaration()) { DtoDefineFunc(fd); } else if (TypeInfoDeclaration* fd = dsym->isTypeInfoDeclaration()) { DtoDefineTypeInfo(fd); } else { error(dsym->loc, "unsupported dsymbol: %s", dsym->toChars()); assert(0 && "unsupported dsymbol for DtoDefineDsymbol"); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoConstInitGlobal(VarDeclaration* vd) { if (vd->ir.initialized) return; vd->ir.initialized = gIR->dmodule; Logger::println("DtoConstInitGlobal(%s) @ %s", vd->toChars(), vd->locToChars()); LOG_SCOPE; // if the variable is a function local static variable with a runtime initializer // we must do lazy initialization, which involves a boolean flag to make sure it happens only once // FIXME: I don't think it's thread safe ... bool doLazyInit = false; Dsymbol* par = vd->toParent(); if (par && par->isFuncDeclaration() && vd->init) { if (ExpInitializer* einit = vd->init->isExpInitializer()) { if (!einit->exp->isConst()) { // mark as needing lazy now doLazyInit = true; } } } // if we do lazy init, we start out with an undefined initializer LLConstant* initVal; if (doLazyInit) { initVal = llvm::UndefValue::get(DtoType(vd->type)); } // otherwise we build it else { initVal = DtoConstInitializer(vd->loc, vd->type, vd->init); } // set the initializer if appropriate IrGlobal* glob = vd->ir.irGlobal; llvm::GlobalVariable* gvar = llvm::cast<llvm::GlobalVariable>(glob->value); // refine the global's opaque type to the type of the initializer llvm::cast<LLOpaqueType>(glob->type.get())->refineAbstractTypeTo(initVal->getType()); glob->constInit = initVal; bool istempl = false; if ((vd->storage_class & STCcomdat) || (vd->parent && DtoIsTemplateInstance(vd->parent))) { istempl = true; } // assign the initializer llvm::GlobalVariable* globalvar = llvm::cast<llvm::GlobalVariable>(glob->value); if (!(vd->storage_class & STCextern) && (vd->getModule() == gIR->dmodule || istempl)) { if (Logger::enabled()) { Logger::println("setting initializer"); Logger::cout() << "global: " << *gvar << '\n'; Logger::cout() << "init: " << *initVal << '\n'; } gvar->setInitializer(initVal); // do debug info if (global.params.symdebug) { LLGlobalVariable* gv = DtoDwarfGlobalVariable(gvar, vd); // keep a reference so GDCE doesn't delete it ! gIR->usedArray.push_back(llvm::ConstantExpr::getBitCast(gv, getVoidPtrType())); } } if (doLazyInit) DtoLazyStaticInit(istempl, gvar, vd->init, vd->type); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoEmptyResolveList() { //Logger::println("DtoEmptyResolveList()"); Dsymbol* dsym; while (!gIR->resolveList.empty()) { dsym = gIR->resolveList.front(); gIR->resolveList.pop_front(); DtoResolveDsymbol(dsym); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoEmptyDeclareList() { //Logger::println("DtoEmptyDeclareList()"); Dsymbol* dsym; while (!gIR->declareList.empty()) { dsym = gIR->declareList.front(); gIR->declareList.pop_front(); DtoDeclareDsymbol(dsym); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoEmptyConstInitList() { //Logger::println("DtoEmptyConstInitList()"); Dsymbol* dsym; while (!gIR->constInitList.empty()) { dsym = gIR->constInitList.front(); gIR->constInitList.pop_front(); DtoConstInitDsymbol(dsym); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoEmptyDefineList() { //Logger::println("DtoEmptyDefineList()"); Dsymbol* dsym; while (!gIR->defineList.empty()) { dsym = gIR->defineList.front(); gIR->defineList.pop_front(); DtoDefineDsymbol(dsym); } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoEmptyAllLists() { for(;;) { Dsymbol* dsym; if (!gIR->resolveList.empty()) { dsym = gIR->resolveList.front(); gIR->resolveList.pop_front(); DtoResolveDsymbol(dsym); } else if (!gIR->declareList.empty()) { dsym = gIR->declareList.front(); gIR->declareList.pop_front(); DtoDeclareDsymbol(dsym); } else if (!gIR->constInitList.empty()) { dsym = gIR->constInitList.front(); gIR->constInitList.pop_front(); DtoConstInitDsymbol(dsym); } else if (!gIR->defineList.empty()) { dsym = gIR->defineList.front(); gIR->defineList.pop_front(); DtoDefineDsymbol(dsym); } else { break; } } } ////////////////////////////////////////////////////////////////////////////////////////// void DtoForceDeclareDsymbol(Dsymbol* dsym) { if (dsym->ir.declared) return; Logger::println("DtoForceDeclareDsymbol(%s)", dsym->toPrettyChars()); LOG_SCOPE; DtoResolveDsymbol(dsym); DtoEmptyResolveList(); DtoDeclareDsymbol(dsym); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoForceConstInitDsymbol(Dsymbol* dsym) { if (dsym->ir.initialized) return; Logger::println("DtoForceConstInitDsymbol(%s)", dsym->toPrettyChars()); LOG_SCOPE; DtoResolveDsymbol(dsym); DtoEmptyResolveList(); DtoEmptyDeclareList(); DtoConstInitDsymbol(dsym); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoForceDefineDsymbol(Dsymbol* dsym) { if (dsym->ir.defined) return; Logger::println("DtoForceDefineDsymbol(%s)", dsym->toPrettyChars()); LOG_SCOPE; DtoResolveDsymbol(dsym); DtoEmptyResolveList(); DtoEmptyDeclareList(); DtoEmptyConstInitList(); DtoDefineDsymbol(dsym); } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // DECLARATION EXP HELPER ////////////////////////////////////////////////////////////////////////////////////////*/ DValue* DtoDeclarationExp(Dsymbol* declaration) { Logger::print("DtoDeclarationExp: %s\n", declaration->toChars()); LOG_SCOPE; // variable declaration if (VarDeclaration* vd = declaration->isVarDeclaration()) { Logger::println("VarDeclaration"); // if aliassym is set, this VarDecl is redone as an alias to another symbol // this seems to be done to rewrite Tuple!(...) v; // as a TupleDecl that contains a bunch of individual VarDecls if (vd->aliassym) return DtoDeclarationExp(vd->aliassym); // static if (vd->isDataseg()) { vd->toObjFile(0); // TODO: multiobj } else { if (global.params.llvmAnnotate) DtoAnnotation(declaration->toChars()); Logger::println("vdtype = %s", vd->type->toChars()); // referenced by nested delegate? #if DMDV2 if (vd->nestedrefs.dim) { #else if (vd->nestedref) { #endif Logger::println("has nestedref set"); assert(vd->ir.irLocal); // alloca as usual if no value already if (!vd->ir.irLocal->value) { vd->ir.irLocal->value = DtoAlloca(DtoType(vd->type), vd->toChars()); } // store the address into the nested vars array assert(vd->ir.irLocal->nestedIndex >= 0); LLValue* gep = DtoGEPi(gIR->func()->decl->ir.irFunc->nestedVar, 0, vd->ir.irLocal->nestedIndex); assert(isaPointer(vd->ir.irLocal->value)); LLValue* val = DtoBitCast(vd->ir.irLocal->value, getVoidPtrType()); DtoStore(val, gep); } // normal stack variable, allocate storage on the stack if it has not already been done else if(!vd->ir.irLocal) { const LLType* lltype = DtoType(vd->type); llvm::Value* allocainst; if(gTargetData->getTypeSizeInBits(lltype) == 0) allocainst = llvm::ConstantPointerNull::get(getPtrToType(lltype)); else allocainst = DtoAlloca(lltype, vd->toChars()); //allocainst->setAlignment(vd->type->alignsize()); // TODO vd->ir.irLocal = new IrLocal(vd); vd->ir.irLocal->value = allocainst; if (global.params.symdebug) { DtoDwarfLocalVariable(allocainst, vd); } } else { assert(vd->ir.irLocal->value); } if (Logger::enabled()) Logger::cout() << "llvm value for decl: " << *vd->ir.irLocal->value << '\n'; DValue* ie = DtoInitializer(vd->ir.irLocal->value, vd->init); } return new DVarValue(vd->type, vd, vd->ir.getIrValue()); } // struct declaration else if (StructDeclaration* s = declaration->isStructDeclaration()) { Logger::println("StructDeclaration"); DtoForceConstInitDsymbol(s); } // function declaration else if (FuncDeclaration* f = declaration->isFuncDeclaration()) { Logger::println("FuncDeclaration"); DtoForceDeclareDsymbol(f); } // alias declaration else if (AliasDeclaration* a = declaration->isAliasDeclaration()) { Logger::println("AliasDeclaration - no work"); // do nothing } // enum else if (EnumDeclaration* e = declaration->isEnumDeclaration()) { Logger::println("EnumDeclaration - no work"); // do nothing } // class else if (ClassDeclaration* e = declaration->isClassDeclaration()) { Logger::println("ClassDeclaration"); DtoForceConstInitDsymbol(e); } // typedef else if (TypedefDeclaration* tdef = declaration->isTypedefDeclaration()) { Logger::println("TypedefDeclaration"); DtoTypeInfoOf(tdef->type, false); } // attribute declaration else if (AttribDeclaration* a = declaration->isAttribDeclaration()) { Logger::println("AttribDeclaration"); for (int i=0; i < a->decl->dim; ++i) { DtoDeclarationExp((Dsymbol*)a->decl->data[i]); } } // mixin declaration else if (TemplateMixin* m = declaration->isTemplateMixin()) { Logger::println("TemplateMixin"); for (int i=0; i < m->members->dim; ++i) { Dsymbol* mdsym = (Dsymbol*)m->members->data[i]; DtoDeclarationExp(mdsym); } } // tuple declaration else if (TupleDeclaration* tupled = declaration->isTupleDeclaration()) { Logger::println("TupleDeclaration"); if(!tupled->isexp) { error(declaration->loc, "don't know how to handle non-expression tuple decls yet"); assert(0); } assert(tupled->objects); for (int i=0; i < tupled->objects->dim; ++i) { DsymbolExp* exp = (DsymbolExp*)tupled->objects->data[i]; DtoDeclarationExp(exp->s); } } // unsupported declaration else { error(declaration->loc, "Unimplemented Declaration type for DeclarationExp. kind: %s", declaration->kind()); assert(0); } return NULL; } // does pretty much the same as DtoDeclarationExp, except it doesn't initialize, and only handles var declarations LLValue* DtoRawVarDeclaration(VarDeclaration* var) { // we don't handle globals with this one assert(!var->isDataseg()); // we don't handle aliases either assert(!var->aliassym); // if this already has storage, it must've been handled already if (var->ir.irLocal && var->ir.irLocal->value) return var->ir.irLocal->value; // referenced by nested function? #if DMDV2 if (var->nestedrefs.dim) #else if (var->nestedref) #endif { assert(var->ir.irLocal); assert(!var->ir.irLocal->value); // alloca var->ir.irLocal->value = DtoAlloca(DtoType(var->type), var->toChars()); // store the address into the nested vars array assert(var->ir.irLocal->nestedIndex >= 0); LLValue* gep = DtoGEPi(gIR->func()->decl->ir.irFunc->nestedVar, 0, var->ir.irLocal->nestedIndex); assert(isaPointer(var->ir.irLocal->value)); LLValue* val = DtoBitCast(var->ir.irLocal->value, getVoidPtrType()); DtoStore(val, gep); } // normal local variable else { assert(!var->ir.isSet()); var->ir.irLocal = new IrLocal(var); var->ir.irLocal->value = DtoAlloca(DtoType(var->type), var->toChars()); } // add debug info if (global.params.symdebug) DtoDwarfLocalVariable(var->ir.irLocal->value, var); // return the alloca return var->ir.irLocal->value; } /****************************************************************************************/ /*//////////////////////////////////////////////////////////////////////////////////////// // INITIALIZER HELPERS ////////////////////////////////////////////////////////////////////////////////////////*/ LLConstant* DtoConstInitializer(Loc loc, Type* type, Initializer* init) { LLConstant* _init = 0; // may return zero if (!init) { Logger::println("const default initializer for %s", type->toChars()); _init = DtoConstExpInit(loc, type, type->defaultInit()); } else if (ExpInitializer* ex = init->isExpInitializer()) { Logger::println("const expression initializer"); _init = DtoConstExpInit(loc, type, ex->exp);; } else if (StructInitializer* si = init->isStructInitializer()) { Logger::println("const struct initializer"); _init = DtoConstStructInitializer(si); } else if (ArrayInitializer* ai = init->isArrayInitializer()) { Logger::println("const array initializer"); _init = DtoConstArrayInitializer(ai); } else if (init->isVoidInitializer()) { Logger::println("const void initializer"); const LLType* ty = DtoType(type); _init = llvm::Constant::getNullValue(ty); } else { Logger::println("unsupported const initializer: %s", init->toChars()); } return _init; } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoInitializer(LLValue* target, Initializer* init) { if (!init) return 0; else if (ExpInitializer* ex = init->isExpInitializer()) { Logger::println("expression initializer"); assert(ex->exp); DValue* res = ex->exp->toElem(gIR); assert(llvm::isa<llvm::PointerType>(target->getType()) && "init target must be ptr"); const LLType* targetty = target->getType()->getContainedType(0); if(targetty == LLType::X86_FP80Ty) { Logger::println("setting fp80 padding to zero"); LLValue* castv = DtoBitCast(target, getPtrToType(LLType::Int16Ty)); LLValue* padding = DtoGEPi1(castv, 5); DtoStore(llvm::Constant::getNullValue(LLType::Int16Ty), padding); } else if(targetty == DtoComplexType(Type::tcomplex80)) { Logger::println("setting complex fp80 padding to zero"); LLValue* castv = DtoBitCast(target, getPtrToType(LLType::Int16Ty)); LLValue* padding = DtoGEPi1(castv, 5); DtoStore(llvm::Constant::getNullValue(LLType::Int16Ty), padding); padding = DtoGEPi1(castv, 11); DtoStore(llvm::Constant::getNullValue(LLType::Int16Ty), padding); } return res; } else if (init->isVoidInitializer()) { // do nothing } else { Logger::println("unsupported initializer: %s", init->toChars()); assert(0); } return 0; } ////////////////////////////////////////////////////////////////////////////////////////// static LLConstant* expand_to_sarray(Type *base, Expression* exp) { Logger::println("building type %s from expression (%s) of type %s", base->toChars(), exp->toChars(), exp->type->toChars()); const LLType* dstTy = DtoType(base); if (Logger::enabled()) Logger::cout() << "final llvm type requested: " << *dstTy << '\n'; LLConstant* val = exp->toConstElem(gIR); Type* expbase = exp->type->toBasetype(); Logger::println("expbase: %s", expbase->toChars()); Type* t = base->toBasetype(); LLSmallVector<size_t, 4> dims; while(1) { Logger::println("t: %s", t->toChars()); if (t->equals(expbase)) break; assert(t->ty == Tsarray); TypeSArray* tsa = (TypeSArray*)t; dims.push_back(tsa->dim->toInteger()); assert(t->nextOf()); t = t->nextOf()->toBasetype(); } size_t i = dims.size(); assert(i); std::vector<LLConstant*> inits; while (i--) { const LLArrayType* arrty = LLArrayType::get(val->getType(), dims[i]); inits.clear(); inits.insert(inits.end(), dims[i], val); val = LLConstantArray::get(arrty, inits); } return val; } LLConstant* DtoConstExpInit(Loc loc, Type* type, Expression* exp) { Type* expbase = exp->type->toBasetype(); Type* base = type->toBasetype(); // if not the same basetypes, we won't get the same llvm types either if (!expbase->equals(base)) { if (base->ty == Tsarray) { if (base->nextOf()->toBasetype()->ty == Tvoid) { error(loc, "static arrays of voids have no default initializer"); fatal(); } Logger::println("type is a static array, building constant array initializer to single value"); return expand_to_sarray(base, exp); } else { error("cannot yet convert default initializer %s to type %s to %s", exp->toChars(), exp->type->toChars(), type->toChars()); fatal(); } assert(0); } return exp->toConstElem(gIR); } ////////////////////////////////////////////////////////////////////////////////////////// void DtoAnnotation(const char* str) { std::string s("CODE: "); s.append(str); char* p = &s[0]; while (*p) { if (*p == '"') *p = '\''; ++p; } // create a noop with the code as the result name! // FIXME: this is const folded and eliminated immediately ... :/ gIR->ir->CreateAnd(DtoConstSize_t(0),DtoConstSize_t(0),s.c_str()); } ////////////////////////////////////////////////////////////////////////////////////////// LLConstant* DtoTypeInfoOf(Type* type, bool base) { type = type->merge(); // needed.. getTypeInfo does the same type->getTypeInfo(NULL); TypeInfoDeclaration* tidecl = type->vtinfo; assert(tidecl); DtoForceDeclareDsymbol(tidecl); assert(tidecl->ir.irGlobal != NULL); LLConstant* c = isaConstant(tidecl->ir.irGlobal->value); assert(c != NULL); if (base) return llvm::ConstantExpr::getBitCast(c, DtoType(Type::typeinfo->type)); return c; } ////////////////////////////////////////////////////////////////////////////////////////// void DtoOverloadedIntrinsicName(TemplateInstance* ti, TemplateDeclaration* td, std::string& name) { Logger::println("DtoOverloadedIntrinsicName"); LOG_SCOPE; Logger::println("template instance: %s", ti->toChars()); Logger::println("template declaration: %s", td->toChars()); Logger::println("intrinsic name: %s", td->intrinsicName.c_str()); // for now use the size in bits of the first template param in the instance assert(ti->tdtypes.dim == 1); Type* T = (Type*)ti->tdtypes.data[0]; char tmp[10]; if (T->toBasetype()->ty == Tbool) // otherwise we'd get a mismatch sprintf(tmp, "1"); else sprintf(tmp, "%lu", T->size()*8); // replace # in name with bitsize name = td->intrinsicName; std::string needle("#"); size_t pos; while(std::string::npos != (pos = name.find(needle))) name.replace(pos, 1, tmp); Logger::println("final intrinsic name: %s", name.c_str()); }