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view gen/tocall.cpp @ 1117:4c20fcc4252b
Fun with parameter attributes: For several of the "synthetic" parameters added
to D functions, we can apply noalias and nocapture. They are sret parameters,
'nest' pointers passed to nested functions, and _argptr:
Nocapture:
- Sret and nest are nocapture because they don't represent D-level variables,
and thus the callee can't (validly) obtain a pointer to them, let alone keep
it around after it returns.
- _argptr is nocapture because although the callee has access to it as a
pointer, that pointer is invalidated when it returns.
All three are noalias because they're function-local variables
- Sret and _argptr are noalias because they're freshly alloca'd memory only
used for a single function call that's not allowed to keep an aliasing
pointer to it around (since the parameter is nocapture).
- 'Nest' is noalias because the callee only ever has access to one such pointer
per parent function, and every parent function has a different one.
This commit also ensures attributes set on sret, _arguments and _argptr are
propagated to calls to such functions.
It also adds one exception to the general rule that attributes on function types
should propagate to calls: the type of a delegate's function pointer has a
'nest' parameter, but this can either be a true 'nest' (for delegates to nested
functions) or a 'this' (for delegates to member functions). Since 'this' is
neither noalias nor nocapture, and there's generally no way to tell which one it
is, we remove these attributes at the call site if the callee is a delegate.
| author | Frits van Bommel <fvbommel wxs.nl> |
|---|---|
| date | Sat, 14 Mar 2009 22:15:31 +0100 |
| parents | dc608dc33081 |
| children | 5ebe8224988b |
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#include "gen/llvm.h" #include "mtype.h" #include "declaration.h" #include "gen/tollvm.h" #include "gen/llvmhelpers.h" #include "gen/irstate.h" #include "gen/dvalue.h" #include "gen/functions.h" #include "gen/abi.h" #include "gen/logger.h" ////////////////////////////////////////////////////////////////////////////////////////// TypeFunction* DtoTypeFunction(DValue* fnval) { Type* type = fnval->getType()->toBasetype(); if (type->ty == Tfunction) { return (TypeFunction*)type; } else if (type->ty == Tdelegate) { Type* next = type->nextOf(); assert(next->ty == Tfunction); return (TypeFunction*)next; } assert(0 && "cant get TypeFunction* from non lazy/function/delegate"); return 0; } ////////////////////////////////////////////////////////////////////////////////////////// unsigned DtoCallingConv(Loc loc, LINK l) { if (l == LINKc || l == LINKcpp || l == LINKintrinsic) return llvm::CallingConv::C; else if (l == LINKd || l == LINKdefault) { //TODO: StdCall is not a good base on Windows due to extra name mangling // applied there if (global.params.cpu == ARCHx86) return (global.params.os != OSWindows) ? llvm::CallingConv::X86_StdCall : llvm::CallingConv::C; else return llvm::CallingConv::Fast; } // on the other hand, here, it's exactly what we want!!! TODO: right? else if (l == LINKwindows) return llvm::CallingConv::X86_StdCall; else { error(loc, "unsupported calling convention"); fatal(); } } ////////////////////////////////////////////////////////////////////////////////////////// DValue* DtoVaArg(Loc& loc, Type* type, Expression* valistArg) { DValue* expelem = valistArg->toElem(gIR); const LLType* llt = DtoType(type); if (DtoIsPassedByRef(type)) llt = getPtrToType(llt); // issue a warning for broken va_arg instruction. if (global.params.cpu != ARCHx86) warning("%s: va_arg for C variadic functions is probably broken for anything but x86", loc.toChars()); // done return new DImValue(type, gIR->ir->CreateVAArg(expelem->getLVal(), llt, "tmp")); } ////////////////////////////////////////////////////////////////////////////////////////// LLValue* DtoCallableValue(DValue* fn) { Type* type = fn->getType()->toBasetype(); if (type->ty == Tfunction) { return fn->getRVal(); } else if (type->ty == Tdelegate) { if (fn->isLVal()) { LLValue* dg = fn->getLVal(); LLValue* funcptr = DtoGEPi(dg, 0, 1); return DtoLoad(funcptr); } else { LLValue* dg = fn->getRVal(); assert(isaStruct(dg)); return gIR->ir->CreateExtractValue(dg, 1, ".funcptr"); } } else { assert(0 && "not a callable type"); return NULL; } } ////////////////////////////////////////////////////////////////////////////////////////// const LLFunctionType* DtoExtractFunctionType(const LLType* type) { if (const LLFunctionType* fty = isaFunction(type)) return fty; else if (const LLPointerType* pty = isaPointer(type)) { if (const LLFunctionType* fty = isaFunction(pty->getElementType())) return fty; } return NULL; } ////////////////////////////////////////////////////////////////////////////////////////// void DtoBuildDVarArgList(std::vector<LLValue*>& args, std::vector<llvm::AttributeWithIndex>& attrs, TypeFunction* tf, Expressions* arguments, size_t argidx) { Logger::println("doing d-style variadic arguments"); std::vector<const LLType*> vtypes; // number of non variadic args int begin = tf->parameters->dim; Logger::println("num non vararg params = %d", begin); // get n args in arguments list size_t n_arguments = arguments ? arguments->dim : 0; // build struct with argument types (non variadic args) for (int i=begin; i<n_arguments; i++) { Expression* argexp = (Expression*)arguments->data[i]; vtypes.push_back(DtoType(argexp->type)); size_t sz = getTypePaddedSize(vtypes.back()); if (sz < PTRSIZE) vtypes.back() = DtoSize_t(); } const LLStructType* vtype = LLStructType::get(vtypes); if (Logger::enabled()) Logger::cout() << "d-variadic argument struct type:\n" << *vtype << '\n'; LLValue* mem = DtoAlloca(vtype,"_argptr_storage"); // store arguments in the struct for (int i=begin,k=0; i<n_arguments; i++,k++) { Expression* argexp = (Expression*)arguments->data[i]; if (global.params.llvmAnnotate) DtoAnnotation(argexp->toChars()); LLValue* argdst = DtoGEPi(mem,0,k); argdst = DtoBitCast(argdst, getPtrToType(DtoType(argexp->type))); DtoVariadicArgument(argexp, argdst); } // build type info array const LLType* typeinfotype = DtoType(Type::typeinfo->type); const LLArrayType* typeinfoarraytype = LLArrayType::get(typeinfotype,vtype->getNumElements()); llvm::GlobalVariable* typeinfomem = new llvm::GlobalVariable(typeinfoarraytype, true, llvm::GlobalValue::InternalLinkage, NULL, "._arguments.storage", gIR->module); if (Logger::enabled()) Logger::cout() << "_arguments storage: " << *typeinfomem << '\n'; std::vector<LLConstant*> vtypeinfos; for (int i=begin,k=0; i<n_arguments; i++,k++) { Expression* argexp = (Expression*)arguments->data[i]; vtypeinfos.push_back(DtoTypeInfoOf(argexp->type)); } // apply initializer LLConstant* tiinits = llvm::ConstantArray::get(typeinfoarraytype, vtypeinfos); typeinfomem->setInitializer(tiinits); // put data in d-array std::vector<LLConstant*> pinits; pinits.push_back(DtoConstSize_t(vtype->getNumElements())); pinits.push_back(llvm::ConstantExpr::getBitCast(typeinfomem, getPtrToType(typeinfotype))); const LLType* tiarrty = DtoType(Type::typeinfo->type->arrayOf()); tiinits = llvm::ConstantStruct::get(pinits); LLValue* typeinfoarrayparam = new llvm::GlobalVariable(tiarrty, true, llvm::GlobalValue::InternalLinkage, tiinits, "._arguments.array", gIR->module); llvm::AttributeWithIndex Attr; // specify arguments args.push_back(DtoLoad(typeinfoarrayparam)); if (unsigned atts = tf->fty.arg_arguments->attrs) { Attr.Index = argidx; Attr.Attrs = atts; attrs.push_back(Attr); } ++argidx; args.push_back(gIR->ir->CreateBitCast(mem, getPtrToType(LLType::Int8Ty), "tmp")); if (unsigned atts = tf->fty.arg_argptr->attrs) { Attr.Index = argidx; Attr.Attrs = atts; attrs.push_back(Attr); } ++argidx; // pass non variadic args for (int i=0; i<begin; i++) { Argument* fnarg = Argument::getNth(tf->parameters, i); DValue* argval = DtoArgument(fnarg, (Expression*)arguments->data[i]); args.push_back(argval->getRVal()); if (tf->fty.args[i]->attrs) { llvm::AttributeWithIndex Attr; Attr.Index = argidx; Attr.Attrs = tf->fty.args[i]->attrs; attrs.push_back(Attr); } ++argidx; } } // FIXME: this function is a mess ! DValue* DtoCallFunction(Loc& loc, Type* resulttype, DValue* fnval, Expressions* arguments) { if (Logger::enabled()) { Logger::println("DtoCallFunction()"); } LOG_SCOPE // the callee D type Type* calleeType = fnval->getType(); // if the type has not yet been processed, do so now if (calleeType->ir.type == NULL) DtoType(calleeType); // get func value if any DFuncValue* dfnval = fnval->isFunc(); // handle special vararg intrinsics bool va_intrinsic = (dfnval && dfnval->func && dfnval->func->isVaIntrinsic()); // get function type info TypeFunction* tf = DtoTypeFunction(fnval); // misc bool retinptr = tf->fty.arg_sret; bool thiscall = tf->fty.arg_this; bool delegatecall = (calleeType->toBasetype()->ty == Tdelegate); bool nestedcall = tf->fty.arg_nest; bool dvarargs = (tf->linkage == LINKd && tf->varargs == 1); unsigned callconv = DtoCallingConv(loc, tf->linkage); // get callee llvm value LLValue* callable = DtoCallableValue(fnval); const LLFunctionType* callableTy = DtoExtractFunctionType(callable->getType()); assert(callableTy); // if (Logger::enabled()) // Logger::cout() << "callable: " << *callable << '\n'; // get n arguments size_t n_arguments = arguments ? arguments->dim : 0; // get llvm argument iterator, for types LLFunctionType::param_iterator argbegin = callableTy->param_begin(); LLFunctionType::param_iterator argiter = argbegin; // parameter attributes std::vector<llvm::AttributeWithIndex> attrs; llvm::AttributeWithIndex Attr; // return attrs if (tf->fty.ret->attrs) { Attr.Index = 0; Attr.Attrs = tf->fty.ret->attrs; attrs.push_back(Attr); } // handle implicit arguments std::vector<LLValue*> args; args.reserve(tf->fty.args.size()); // return in hidden ptr is first if (retinptr) { LLValue* retvar = DtoAlloca(argiter->get()->getContainedType(0), ".rettmp"); ++argiter; args.push_back(retvar); // add attrs for hidden ptr Attr.Index = 1; Attr.Attrs = tf->fty.arg_sret->attrs; assert((Attr.Attrs & llvm::Attribute::StructRet) && "Sret arg not sret?"); attrs.push_back(Attr); } // then comes a context argument... if(thiscall || delegatecall || nestedcall) { // ... which can be a 'this' argument if (thiscall && dfnval && dfnval->vthis) { LLValue* thisarg = DtoBitCast(dfnval->vthis, argiter->get()); ++argiter; args.push_back(thisarg); } // ... or a delegate context arg else if (delegatecall) { LLValue* ctxarg; if (fnval->isLVal()) { ctxarg = DtoLoad(DtoGEPi(fnval->getLVal(), 0,0)); } else { ctxarg = gIR->ir->CreateExtractValue(fnval->getRVal(), 0, ".ptr"); } assert(ctxarg->getType() == argiter->get()); ++argiter; args.push_back(ctxarg); } // ... or a nested function context arg else if (nestedcall) { LLValue* contextptr = DtoNestedContext(loc, dfnval->func); contextptr = DtoBitCast(contextptr, getVoidPtrType()); ++argiter; args.push_back(contextptr); } else { error(loc, "Context argument required but none given"); fatal(); } // add attributes for context argument if (tf->fty.arg_this && tf->fty.arg_this->attrs) { Attr.Index = retinptr ? 2 : 1; Attr.Attrs = tf->fty.arg_this->attrs; attrs.push_back(Attr); } else if (tf->fty.arg_nest && tf->fty.arg_nest->attrs) { Attr.Index = retinptr ? 2 : 1; Attr.Attrs = tf->fty.arg_nest->attrs; // For delegates, we can't assume 'nest' is noalias and nocapture // (like we can with nested functions) since it might actually be // a 'this', and thus neither attribute generally applies to it. // TODO: don't remove nocapture if it's a "pure" delegate? if (delegatecall) { Attr.Attrs &= ~(llvm::Attribute::NoAlias | llvm::Attribute::NoCapture); } // LLVM doesn't like it when no bits are set... if (Attr.Attrs) attrs.push_back(Attr); } } // handle the rest of the arguments based on param passing style // variadic instrinsics need some custom casts if (va_intrinsic) { for (int i=0; i<n_arguments; i++) { Expression* exp = (Expression*)arguments->data[i]; DValue* expelem = exp->toElem(gIR); // cast to va_list* LLValue* val = DtoBitCast(expelem->getLVal(), getVoidPtrType()); ++argiter; args.push_back(val); } } // d style varargs needs a few more hidden arguments as well as special passing else if (dvarargs) { DtoBuildDVarArgList(args, attrs, tf, arguments, argiter-argbegin+1); } // otherwise we're looking at a normal function call // or a C style vararg call else { Logger::println("doing normal arguments"); if (Logger::enabled()) { Logger::println("Arguments so far: (%d)", (int)args.size()); Logger::indent(); for (size_t i = 0; i < args.size(); i++) { Logger::cout() << *args[i] << '\n'; } Logger::undent(); Logger::cout() << "Function type: " << tf->toChars() << '\n'; Logger::cout() << "LLVM functype: " << *callable->getType() << '\n'; } size_t n = Argument::dim(tf->parameters); LLSmallVector<unsigned, 10> attrptr(n, 0); // do formal params int beg = argiter-argbegin; for (int i=0; i<n; i++) { Argument* fnarg = Argument::getNth(tf->parameters, i); assert(fnarg); DValue* argval = DtoArgument(fnarg, (Expression*)arguments->data[i]); if (Logger::enabled()) { Logger::cout() << "Argument before ABI: " << *argval->getRVal() << '\n'; Logger::cout() << "Argument type before ABI: " << *DtoType(argval->getType()) << '\n'; } // give the ABI a say LLValue* arg = tf->fty.putParam(argval->getType(), i, argval); if (Logger::enabled()) { Logger::cout() << "Argument after ABI: " << *arg << '\n'; Logger::cout() << "Argument type after ABI: " << *arg->getType() << '\n'; } int j = tf->fty.reverseParams ? beg + n - i - 1 : beg + i; // Hack around LDC assuming structs are in memory: // If the function wants a struct, and the argument value is a // pointer to a struct, load from it before passing it in. if (argval->getType()->ty == Tstruct && isaPointer(arg) && !isaPointer(callableTy->getParamType(j))) { Logger::println("Loading struct type for function argument"); arg = DtoLoad(arg); } // parameter type mismatch, this is hard to get rid of if (arg->getType() != callableTy->getParamType(j)) { #if 1 if (Logger::enabled()) { Logger::cout() << "arg: " << *arg << '\n'; Logger::cout() << "expects: " << *callableTy->getParamType(j) << '\n'; } #endif arg = DtoBitCast(arg, callableTy->getParamType(j)); } // param attrs attrptr[i] = tf->fty.args[i]->attrs; ++argiter; args.push_back(arg); } // reverse the relevant params as well as the param attrs if (tf->fty.reverseParams) { std::reverse(args.begin() + beg, args.end()); std::reverse(attrptr.begin(), attrptr.end()); } // add attributes for (int i = 0; i < n; i++) { if (attrptr[i]) { Attr.Index = beg + i + 1; Attr.Attrs = attrptr[i]; attrs.push_back(Attr); } } // do C varargs if (n_arguments > n) { for (int i=n; i<n_arguments; i++) { Argument* fnarg = Argument::getNth(tf->parameters, i); DValue* argval = DtoArgument(fnarg, (Expression*)arguments->data[i]); LLValue* arg = argval->getRVal(); // FIXME: do we need any param attrs here ? ++argiter; args.push_back(arg); } } } #if 0 if (Logger::enabled()) { Logger::println("%lu params passed", args.size()); for (int i=0; i<args.size(); ++i) { assert(args[i]); Logger::cout() << "arg["<<i<<"] = " << *args[i] << '\n'; } } #endif // void returns cannot not be named const char* varname = ""; if (callableTy->getReturnType() != LLType::VoidTy) varname = "tmp"; #if 0 if (Logger::enabled()) Logger::cout() << "Calling: " << *callable << '\n'; #endif // call the function LLCallSite call = gIR->CreateCallOrInvoke(callable, args.begin(), args.end(), varname); // get return value LLValue* retllval = (retinptr) ? args[0] : call.getInstruction(); // Ignore ABI for intrinsics if (tf->linkage != LINKintrinsic && !retinptr) { // do abi specific return value fixups DImValue dretval(tf->next, retllval); retllval = tf->fty.getRet(tf->next, &dretval); } // Hack around LDC assuming structs are in memory: // If the function returns a struct, and the return value is not a // pointer to a struct, store it to a stack slot before continuing. if (tf->next->ty == Tstruct && !isaPointer(retllval)) { Logger::println("Storing return value to stack slot"); LLValue* mem = DtoAlloca(retllval->getType()); DtoStore(retllval, mem); retllval = mem; } // repaint the type if necessary if (resulttype) { Type* rbase = resulttype->toBasetype(); Type* nextbase = tf->nextOf()->toBasetype(); #if DMDV2 rbase = rbase->mutableOf(); nextbase = nextbase->mutableOf(); #endif if (!rbase->equals(nextbase)) { Logger::println("repainting return value from '%s' to '%s'", tf->nextOf()->toChars(), rbase->toChars()); switch(rbase->ty) { case Tarray: retllval = DtoAggrPaint(retllval, DtoType(rbase)); break; case Tclass: case Taarray: case Tpointer: retllval = DtoBitCast(retllval, DtoType(rbase)); break; default: assert(0 && "unhandled repainting of return value"); } if (Logger::enabled()) Logger::cout() << "final return value: " << *retllval << '\n'; } } // set calling convention and parameter attributes llvm::AttrListPtr attrlist = llvm::AttrListPtr::get(attrs.begin(), attrs.end()); if (dfnval && dfnval->func) { LLFunction* llfunc = llvm::dyn_cast<LLFunction>(dfnval->val); if (llfunc && llfunc->isIntrinsic()) // override intrinsic attrs attrlist = llvm::Intrinsic::getAttributes((llvm::Intrinsic::ID)llfunc->getIntrinsicID()); else call.setCallingConv(callconv); } else call.setCallingConv(callconv); call.setAttributes(attrlist); // if we are returning through a pointer arg // make sure we provide a lvalue back! if (retinptr) return new DVarValue(resulttype, retllval); return new DImValue(resulttype, retllval); }