elem *setEthis(Loc loc, IRState *irs, elem *ey, AggregateDeclaration *ad) { elem *ethis; FuncDeclaration *thisfd = irs->getFunc(); int offset = 0; Dsymbol *cdp = ad->toParent2(); // class/func we're nested in //printf("setEthis(ad = %s, cdp = %s, thisfd = %s)\n", ad->toChars(), cdp->toChars(), thisfd->toChars()); if (cdp == thisfd) { /* Class we're new'ing is a local class in this function: * void thisfd() { class ad { } } */ if (irs->sclosure) ethis = el_var(irs->sclosure); else if (irs->sthis) { if (thisfd->hasNestedFrameRefs()) { ethis = el_ptr(irs->sthis); } else ethis = el_var(irs->sthis); } else { ethis = el_long(TYnptr, 0); if (thisfd->hasNestedFrameRefs()) { ethis->Eoper = OPframeptr; } } } else if (thisfd->vthis && (cdp == thisfd->toParent2() || (cdp->isClassDeclaration() && cdp->isClassDeclaration()->isBaseOf(thisfd->toParent2()->isClassDeclaration(), &offset) ) ) ) { /* Class we're new'ing is at the same level as thisfd */ assert(offset == 0); // BUG: should handle this case ethis = el_var(irs->sthis); } else { ethis = getEthis(loc, irs, ad->toParent2()); ethis = el_una(OPaddr, TYnptr, ethis); } ey = el_bin(OPadd, TYnptr, ey, el_long(TYsize_t, ad->vthis->offset)); ey = el_una(OPind, TYnptr, ey); ey = el_bin(OPeq, TYnptr, ey, ethis); return ey; }
/************************* * Initialize the hidden aggregate member, vthis, with * the context pointer. * Returns: * *(ey + ad.vthis.offset) = this; */ elem *setEthis(Loc loc, IRState *irs, elem *ey, AggregateDeclaration *ad) { elem *ethis; FuncDeclaration *thisfd = irs->getFunc(); int offset = 0; Dsymbol *adp = ad->toParent2(); // class/func we're nested in //printf("[%s] setEthis(ad = %s, adp = %s, thisfd = %s)\n", loc.toChars(), ad->toChars(), adp->toChars(), thisfd->toChars()); if (adp == thisfd) { ethis = getEthis(loc, irs, ad); } else if (thisfd->vthis && (adp == thisfd->toParent2() || (adp->isClassDeclaration() && adp->isClassDeclaration()->isBaseOf(thisfd->toParent2()->isClassDeclaration(), &offset) ) ) ) { /* Class we're new'ing is at the same level as thisfd */ assert(offset == 0); // BUG: should handle this case ethis = el_var(irs->sthis); } else { ethis = getEthis(loc, irs, adp); FuncDeclaration *fdp = adp->isFuncDeclaration(); if (fdp && fdp->hasNestedFrameRefs()) ethis = el_una(OPaddr, TYnptr, ethis); } ey = el_bin(OPadd, TYnptr, ey, el_long(TYsize_t, ad->vthis->offset)); ey = el_una(OPind, TYnptr, ey); ey = el_bin(OPeq, TYnptr, ey, ethis); return ey; }
bool alreadyOrWillBeDefined(FuncDeclaration &fdecl) { for (FuncDeclaration *f = &fdecl; f;) { if (!f->isInstantiated() && f->inNonRoot()) { return false; } if (f->isNested()) { f = f->toParent2()->isFuncDeclaration(); } else { break; } } return true; }
void FuncDeclaration::toObjFile(bool multiobj) { FuncDeclaration *func = this; ClassDeclaration *cd = func->parent->isClassDeclaration(); int reverse; //printf("FuncDeclaration::toObjFile(%p, %s.%s)\n", func, parent->toChars(), func->toChars()); //if (type) printf("type = %s\n", func->type->toChars()); #if 0 //printf("line = %d\n",func->getWhere() / LINEINC); EEcontext *ee = env->getEEcontext(); if (ee->EEcompile == 2) { if (ee->EElinnum < (func->getWhere() / LINEINC) || ee->EElinnum > (func->endwhere / LINEINC) ) return; // don't compile this function ee->EEfunc = toSymbol(func); } #endif if (semanticRun >= PASSobj) // if toObjFile() already run return; if (type && type->ty == Tfunction && ((TypeFunction *)type)->next == NULL) return; // If errors occurred compiling it, such as bugzilla 6118 if (type && type->ty == Tfunction && ((TypeFunction *)type)->next->ty == Terror) return; if (global.errors) return; if (!func->fbody) return; UnitTestDeclaration *ud = func->isUnitTestDeclaration(); if (ud && !global.params.useUnitTests) return; if (multiobj && !isStaticDtorDeclaration() && !isStaticCtorDeclaration()) { obj_append(this); return; } if (semanticRun == PASSsemanticdone) { /* What happened is this function failed semantic3() with errors, * but the errors were gagged. * Try to reproduce those errors, and then fail. */ error("errors compiling the function"); return; } assert(semanticRun == PASSsemantic3done); assert(ident != Id::empty); if (!needsCodegen()) return; FuncDeclaration *fdp = func->toParent2()->isFuncDeclaration(); if (isNested()) { if (fdp && fdp->semanticRun < PASSobj) { if (fdp->semantic3Errors) return; /* Can't do unittest's out of order, they are order dependent in that their * execution is done in lexical order. */ if (UnitTestDeclaration *udp = fdp->isUnitTestDeclaration()) { udp->deferredNested.push(func); return; } } } if (isArrayOp && isDruntimeArrayOp(ident)) { // Implementation is in druntime return; } // start code generation semanticRun = PASSobj; if (global.params.verbose) fprintf(global.stdmsg, "function %s\n",func->toPrettyChars()); Symbol *s = toSymbol(func); func_t *f = s->Sfunc; // tunnel type of "this" to debug info generation if (AggregateDeclaration* ad = func->parent->isAggregateDeclaration()) { ::type* t = Type_toCtype(ad->getType()); if(cd) t = t->Tnext; // skip reference f->Fclass = (Classsym *)t; } #if TARGET_WINDOS /* This is done so that the 'this' pointer on the stack is the same * distance away from the function parameters, so that an overriding * function can call the nested fdensure or fdrequire of its overridden function * and the stack offsets are the same. */ if (isVirtual() && (fensure || frequire)) f->Fflags3 |= Ffakeeh; #endif #if TARGET_OSX s->Sclass = SCcomdat; #else s->Sclass = SCglobal; #endif for (Dsymbol *p = parent; p; p = p->parent) { if (p->isTemplateInstance()) { s->Sclass = SCcomdat; break; } } /* Vector operations should be comdat's */ if (isArrayOp) s->Sclass = SCcomdat; if (isNested()) { //if (!(config.flags3 & CFG3pic)) // s->Sclass = SCstatic; f->Fflags3 |= Fnested; /* The enclosing function must have its code generated first, * in order to calculate correct frame pointer offset. */ if (fdp && fdp->semanticRun < PASSobj) { fdp->toObjFile(multiobj); } } else { const char *libname = (global.params.symdebug) ? global.params.debuglibname : global.params.defaultlibname; // Pull in RTL startup code (but only once) if (func->isMain() && onlyOneMain(loc)) { #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS objmod->external_def("_main"); objmod->ehsections(); // initialize exception handling sections #endif #if TARGET_WINDOS if (I64) { objmod->external_def("main"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("_main"); objmod->external_def("__acrtused_con"); } #endif objmod->includelib(libname); s->Sclass = SCglobal; } else if (strcmp(s->Sident, "main") == 0 && linkage == LINKc) { #if TARGET_WINDOS if (I64) { objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); } else { objmod->external_def("__acrtused_con"); // bring in C startup code objmod->includelib("snn.lib"); // bring in C runtime library } #endif s->Sclass = SCglobal; } #if TARGET_WINDOS else if (func->isWinMain() && onlyOneMain(loc)) { if (I64) { objmod->includelib("uuid"); objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("__acrtused"); } objmod->includelib(libname); s->Sclass = SCglobal; } // Pull in RTL startup code else if (func->isDllMain() && onlyOneMain(loc)) { if (I64) { objmod->includelib("uuid"); objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("__acrtused_dll"); } objmod->includelib(libname); s->Sclass = SCglobal; } #endif } symtab_t *symtabsave = cstate.CSpsymtab; cstate.CSpsymtab = &f->Flocsym; // Find module m for this function Module *m = NULL; for (Dsymbol *p = parent; p; p = p->parent) { m = p->isModule(); if (m) break; } IRState irs(m, func); Dsymbols deferToObj; // write these to OBJ file later irs.deferToObj = &deferToObj; TypeFunction *tf; RET retmethod; symbol *shidden = NULL; Symbol *sthis = NULL; tym_t tyf; tyf = tybasic(s->Stype->Tty); //printf("linkage = %d, tyf = x%x\n", linkage, tyf); reverse = tyrevfunc(s->Stype->Tty); assert(func->type->ty == Tfunction); tf = (TypeFunction *)(func->type); retmethod = retStyle(tf); if (retmethod == RETstack) { // If function returns a struct, put a pointer to that // as the first argument ::type *thidden = Type_toCtype(tf->next->pointerTo()); char hiddenparam[5+4+1]; static int hiddenparami; // how many we've generated so far sprintf(hiddenparam,"__HID%d",++hiddenparami); shidden = symbol_name(hiddenparam,SCparameter,thidden); shidden->Sflags |= SFLtrue | SFLfree; if (func->nrvo_can && func->nrvo_var && func->nrvo_var->nestedrefs.dim) type_setcv(&shidden->Stype, shidden->Stype->Tty | mTYvolatile); irs.shidden = shidden; this->shidden = shidden; } else { // Register return style cannot make nrvo. // Auto functions keep the nrvo_can flag up to here, // so we should eliminate it before entering backend. nrvo_can = 0; } if (vthis) { assert(!vthis->csym); sthis = toSymbol(vthis); irs.sthis = sthis; if (!(f->Fflags3 & Fnested)) f->Fflags3 |= Fmember; } // Estimate number of parameters, pi size_t pi = (v_arguments != NULL); if (parameters) pi += parameters->dim; // Create a temporary buffer, params[], to hold function parameters Symbol *paramsbuf[10]; Symbol **params = paramsbuf; // allocate on stack if possible if (pi + 2 > 10) // allow extra 2 for sthis and shidden { params = (Symbol **)malloc((pi + 2) * sizeof(Symbol *)); assert(params); } // Get the actual number of parameters, pi, and fill in the params[] pi = 0; if (v_arguments) { params[pi] = toSymbol(v_arguments); pi += 1; } if (parameters) { for (size_t i = 0; i < parameters->dim; i++) { VarDeclaration *v = (*parameters)[i]; //printf("param[%d] = %p, %s\n", i, v, v->toChars()); assert(!v->csym); params[pi + i] = toSymbol(v); } pi += parameters->dim; } if (reverse) { // Reverse params[] entries for (size_t i = 0; i < pi/2; i++) { Symbol *sptmp = params[i]; params[i] = params[pi - 1 - i]; params[pi - 1 - i] = sptmp; } } if (shidden) { #if 0 // shidden becomes last parameter params[pi] = shidden; #else // shidden becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = shidden; #endif pi++; } if (sthis) { #if 0 // sthis becomes last parameter params[pi] = sthis; #else // sthis becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = sthis; #endif pi++; } if ((global.params.isLinux || global.params.isOSX || global.params.isFreeBSD || global.params.isSolaris) && linkage != LINKd && shidden && sthis) { /* swap shidden and sthis */ Symbol *sp = params[0]; params[0] = params[1]; params[1] = sp; } for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; sp->Sclass = SCparameter; sp->Sflags &= ~SFLspill; sp->Sfl = FLpara; symbol_add(sp); } // Determine register assignments if (pi) { FuncParamRegs fpr(tyf); for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; if (fpr.alloc(sp->Stype, sp->Stype->Tty, &sp->Spreg, &sp->Spreg2)) { sp->Sclass = (config.exe == EX_WIN64) ? SCshadowreg : SCfastpar; sp->Sfl = (sp->Sclass == SCshadowreg) ? FLpara : FLfast; } } } // Done with params if (params != paramsbuf) free(params); params = NULL; if (func->fbody) { localgot = NULL; Statement *sbody = func->fbody; Blockx bx; memset(&bx,0,sizeof(bx)); bx.startblock = block_calloc(); bx.curblock = bx.startblock; bx.funcsym = s; bx.scope_index = -1; bx.classdec = cd; bx.member = func; bx.module = getModule(); irs.blx = &bx; /* Doing this in semantic3() caused all kinds of problems: * 1. couldn't reliably get the final mangling of the function name due to fwd refs * 2. impact on function inlining * 3. what to do when writing out .di files, or other pretty printing */ if (global.params.trace) { /* Wrap the entire function body in: * trace_pro("funcname"); * try * body; * finally * _c_trace_epi(); */ StringExp *se = StringExp::create(Loc(), s->Sident); se->type = Type::tstring; se->type = se->type->semantic(Loc(), NULL); Expressions *exps = Expressions_create(); exps->push(se); FuncDeclaration *fdpro = FuncDeclaration::genCfunc(NULL, Type::tvoid, "trace_pro"); Expression *ec = VarExp::create(Loc(), fdpro); Expression *e = CallExp::create(Loc(), ec, exps); e->type = Type::tvoid; Statement *sp = ExpStatement::create(loc, e); FuncDeclaration *fdepi = FuncDeclaration::genCfunc(NULL, Type::tvoid, "_c_trace_epi"); ec = VarExp::create(Loc(), fdepi); e = CallExp::create(Loc(), ec); e->type = Type::tvoid; Statement *sf = ExpStatement::create(loc, e); Statement *stf; if (sbody->blockExit(this, tf->isnothrow) == BEfallthru) stf = CompoundStatement::create(Loc(), sbody, sf); else stf = TryFinallyStatement::create(Loc(), sbody, sf); sbody = CompoundStatement::create(Loc(), sp, stf); } buildClosure(this, &irs); #if TARGET_WINDOS if (func->isSynchronized() && cd && config.flags2 & CFG2seh && !func->isStatic() && !sbody->usesEH() && !global.params.trace) { /* The "jmonitor" hack uses an optimized exception handling frame * which is a little shorter than the more general EH frame. */ s->Sfunc->Fflags3 |= Fjmonitor; } #endif Statement_toIR(sbody, &irs); bx.curblock->BC = BCret; f->Fstartblock = bx.startblock; // einit = el_combine(einit,bx.init); if (isCtorDeclaration()) { assert(sthis); for (block *b = f->Fstartblock; b; b = b->Bnext) { if (b->BC == BCret) { b->BC = BCretexp; b->Belem = el_combine(b->Belem, el_var(sthis)); } } } } // If static constructor if (isSharedStaticCtorDeclaration()) // must come first because it derives from StaticCtorDeclaration { ssharedctors.push(s); } else if (isStaticCtorDeclaration()) { sctors.push(s); } // If static destructor if (isSharedStaticDtorDeclaration()) // must come first because it derives from StaticDtorDeclaration { SharedStaticDtorDeclaration *f = isSharedStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ esharedctorgates.push(f); } sshareddtors.shift(s); } else if (isStaticDtorDeclaration()) { StaticDtorDeclaration *f = isStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ ectorgates.push(f); } sdtors.shift(s); } // If unit test if (ud) { stests.push(s); } if (global.errors) { // Restore symbol table cstate.CSpsymtab = symtabsave; return; } writefunc(s); // Restore symbol table cstate.CSpsymtab = symtabsave; if (isExport()) objmod->export_symbol(s, Para.offset); for (size_t i = 0; i < irs.deferToObj->dim; i++) { Dsymbol *s = (*irs.deferToObj)[i]; s->toObjFile(0); } if (ud) { for (size_t i = 0; i < ud->deferredNested.dim; i++) { FuncDeclaration *fd = ud->deferredNested[i]; fd->toObjFile(0); } } #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS // A hack to get a pointer to this function put in the .dtors segment if (ident && memcmp(ident->toChars(), "_STD", 4) == 0) objmod->staticdtor(s); #endif if (irs.startaddress) { //printf("Setting start address\n"); objmod->startaddress(irs.startaddress); } }
void FuncDeclaration::toObjFile(int multiobj) { FuncDeclaration *func = this; ClassDeclaration *cd = func->parent->isClassDeclaration(); int reverse; int has_arguments; //printf("FuncDeclaration::toObjFile(%p, %s.%s)\n", func, parent->toChars(), func->toChars()); //if (type) printf("type = %s\n", func->type->toChars()); #if 0 //printf("line = %d\n",func->getWhere() / LINEINC); EEcontext *ee = env->getEEcontext(); if (ee->EEcompile == 2) { if (ee->EElinnum < (func->getWhere() / LINEINC) || ee->EElinnum > (func->endwhere / LINEINC) ) return; // don't compile this function ee->EEfunc = func->toSymbol(); } #endif if (semanticRun >= PASSobj) // if toObjFile() already run return; // If errors occurred compiling it, such as bugzilla 6118 if (type && type->ty == Tfunction && ((TypeFunction *)type)->next->ty == Terror) return; if (!func->fbody) { return; } if (func->isUnitTestDeclaration() && !global.params.useUnitTests) return; if (multiobj && !isStaticDtorDeclaration() && !isStaticCtorDeclaration()) { obj_append(this); return; } assert(semanticRun == PASSsemantic3done); semanticRun = PASSobj; if (global.params.verbose) printf("function %s\n",func->toChars()); Symbol *s = func->toSymbol(); func_t *f = s->Sfunc; #if TARGET_WINDOS /* This is done so that the 'this' pointer on the stack is the same * distance away from the function parameters, so that an overriding * function can call the nested fdensure or fdrequire of its overridden function * and the stack offsets are the same. */ if (isVirtual() && (fensure || frequire)) f->Fflags3 |= Ffakeeh; #endif #if TARGET_OSX s->Sclass = SCcomdat; #else s->Sclass = SCglobal; #endif for (Dsymbol *p = parent; p; p = p->parent) { if (p->isTemplateInstance()) { s->Sclass = SCcomdat; break; } } /* Vector operations should be comdat's */ if (isArrayOp) s->Sclass = SCcomdat; if (isNested()) { // if (!(config.flags3 & CFG3pic)) // s->Sclass = SCstatic; f->Fflags3 |= Fnested; } else { const char *libname = (global.params.symdebug) ? global.params.debuglibname : global.params.defaultlibname; // Pull in RTL startup code if (func->isMain()) { objextdef("_main"); #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS obj_ehsections(); // initialize exception handling sections #endif #if TARGET_WINDOS objextdef("__acrtused_con"); #endif obj_includelib(libname); s->Sclass = SCglobal; } else if (strcmp(s->Sident, "main") == 0 && linkage == LINKc) { #if TARGET_WINDOS objextdef("__acrtused_con"); // bring in C startup code obj_includelib("snn.lib"); // bring in C runtime library #endif s->Sclass = SCglobal; } else if (func->isWinMain()) { objextdef("__acrtused"); obj_includelib(libname); s->Sclass = SCglobal; } // Pull in RTL startup code else if (func->isDllMain()) { objextdef("__acrtused_dll"); obj_includelib(libname); s->Sclass = SCglobal; } } cstate.CSpsymtab = &f->Flocsym; // Find module m for this function Module *m = NULL; for (Dsymbol *p = parent; p; p = p->parent) { m = p->isModule(); if (m) break; } IRState irs(m, func); Dsymbols deferToObj; // write these to OBJ file later irs.deferToObj = &deferToObj; TypeFunction *tf; enum RET retmethod; symbol *shidden = NULL; Symbol *sthis = NULL; tym_t tyf; tyf = tybasic(s->Stype->Tty); //printf("linkage = %d, tyf = x%x\n", linkage, tyf); reverse = tyrevfunc(s->Stype->Tty); assert(func->type->ty == Tfunction); tf = (TypeFunction *)(func->type); has_arguments = (tf->linkage == LINKd) && (tf->varargs == 1); retmethod = tf->retStyle(); if (retmethod == RETstack) { // If function returns a struct, put a pointer to that // as the first argument ::type *thidden = tf->next->pointerTo()->toCtype(); char hiddenparam[5+4+1]; static int hiddenparami; // how many we've generated so far sprintf(hiddenparam,"__HID%d",++hiddenparami); shidden = symbol_name(hiddenparam,SCparameter,thidden); shidden->Sflags |= SFLtrue | SFLfree; #if DMDV1 if (func->nrvo_can && func->nrvo_var && func->nrvo_var->nestedref) #else if (func->nrvo_can && func->nrvo_var && func->nrvo_var->nestedrefs.dim) #endif type_setcv(&shidden->Stype, shidden->Stype->Tty | mTYvolatile); irs.shidden = shidden; this->shidden = shidden; } else { // Register return style cannot make nrvo. // Auto functions keep the nrvo_can flag up to here, // so we should eliminate it before entering backend. nrvo_can = 0; } if (vthis) { assert(!vthis->csym); sthis = vthis->toSymbol(); irs.sthis = sthis; if (!(f->Fflags3 & Fnested)) f->Fflags3 |= Fmember; } Symbol **params; unsigned pi; // Estimate number of parameters, pi pi = (v_arguments != NULL); if (parameters) pi += parameters->dim; // Allow extra 2 for sthis and shidden params = (Symbol **)alloca((pi + 2) * sizeof(Symbol *)); // Get the actual number of parameters, pi, and fill in the params[] pi = 0; if (v_arguments) { params[pi] = v_arguments->toSymbol(); pi += 1; } if (parameters) { for (size_t i = 0; i < parameters->dim; i++) { VarDeclaration *v = (*parameters)[i]; if (v->csym) { error("compiler error, parameter '%s', bugzilla 2962?", v->toChars()); assert(0); } params[pi + i] = v->toSymbol(); } pi += parameters->dim; } if (reverse) { // Reverse params[] entries for (size_t i = 0; i < pi/2; i++) { Symbol *sptmp = params[i]; params[i] = params[pi - 1 - i]; params[pi - 1 - i] = sptmp; } } if (shidden) { #if 0 // shidden becomes last parameter params[pi] = shidden; #else // shidden becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = shidden; #endif pi++; } if (sthis) { #if 0 // sthis becomes last parameter params[pi] = sthis; #else // sthis becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = sthis; #endif pi++; } if ((global.params.isLinux || global.params.isOSX || global.params.isFreeBSD || global.params.isSolaris) && linkage != LINKd && shidden && sthis) { /* swap shidden and sthis */ Symbol *sp = params[0]; params[0] = params[1]; params[1] = sp; } for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; sp->Sclass = SCparameter; sp->Sflags &= ~SFLspill; sp->Sfl = FLpara; symbol_add(sp); } // Determine register assignments if (pi) { size_t numintegerregs = 0, numfloatregs = 0; const unsigned char* argregs = getintegerparamsreglist(tyf, &numintegerregs); const unsigned char* floatregs = getfloatparamsreglist(tyf, &numfloatregs); // Order of assignment of pointer or integer parameters int r = 0; int xmmcnt = 0; for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; tym_t ty = tybasic(sp->Stype->Tty); // BUG: doesn't work for structs if (r < numintegerregs) { if ((I64 || (i == 0 && (tyf == TYjfunc || tyf == TYmfunc))) && type_jparam(sp->Stype)) { sp->Sclass = SCfastpar; sp->Spreg = argregs[r]; sp->Sfl = FLauto; ++r; } } if (xmmcnt < numfloatregs) { if (tyxmmreg(ty)) { sp->Sclass = SCfastpar; sp->Spreg = floatregs[xmmcnt]; sp->Sfl = FLauto; ++xmmcnt; } } } } if (func->fbody) { block *b; Blockx bx; Statement *sbody; localgot = NULL; sbody = func->fbody; memset(&bx,0,sizeof(bx)); bx.startblock = block_calloc(); bx.curblock = bx.startblock; bx.funcsym = s; bx.scope_index = -1; bx.classdec = cd; bx.member = func; bx.module = getModule(); irs.blx = &bx; #if DMDV2 buildClosure(&irs); #endif #if 0 if (func->isSynchronized()) { if (cd) { elem *esync; if (func->isStatic()) { // monitor is in ClassInfo esync = el_ptr(cd->toSymbol()); } else { // 'this' is the monitor esync = el_var(sthis); } if (func->isStatic() || sbody->usesEH() || !(config.flags2 & CFG2seh)) { // BUG: what if frequire or fensure uses EH? sbody = new SynchronizedStatement(func->loc, esync, sbody); } else { #if TARGET_WINDOS if (config.flags2 & CFG2seh) { /* The "jmonitor" uses an optimized exception handling frame * which is a little shorter than the more general EH frame. * It isn't strictly necessary. */ s->Sfunc->Fflags3 |= Fjmonitor; } #endif el_free(esync); } } else { error("synchronized function %s must be a member of a class", func->toChars()); } } #elif TARGET_WINDOS if (func->isSynchronized() && cd && config.flags2 & CFG2seh && !func->isStatic() && !sbody->usesEH()) { /* The "jmonitor" hack uses an optimized exception handling frame * which is a little shorter than the more general EH frame. */ s->Sfunc->Fflags3 |= Fjmonitor; } #endif sbody->toIR(&irs); bx.curblock->BC = BCret; f->Fstartblock = bx.startblock; // einit = el_combine(einit,bx.init); if (isCtorDeclaration()) { assert(sthis); for (b = f->Fstartblock; b; b = b->Bnext) { if (b->BC == BCret) { b->BC = BCretexp; b->Belem = el_combine(b->Belem, el_var(sthis)); } } } } // If static constructor #if DMDV2 if (isSharedStaticCtorDeclaration()) // must come first because it derives from StaticCtorDeclaration { ssharedctors.push(s); } else #endif if (isStaticCtorDeclaration()) { sctors.push(s); } // If static destructor #if DMDV2 if (isSharedStaticDtorDeclaration()) // must come first because it derives from StaticDtorDeclaration { SharedStaticDtorDeclaration *f = isSharedStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ esharedctorgates.push(f); } sshareddtors.shift(s); } else #endif if (isStaticDtorDeclaration()) { StaticDtorDeclaration *f = isStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ ectorgates.push(f); } sdtors.shift(s); } // If unit test if (isUnitTestDeclaration()) { stests.push(s); } if (global.errors) return; writefunc(s); if (isExport()) obj_export(s, Poffset); for (size_t i = 0; i < irs.deferToObj->dim; i++) { Dsymbol *s = (*irs.deferToObj)[i]; FuncDeclaration *fd = s->isFuncDeclaration(); if (fd) { FuncDeclaration *fdp = fd->toParent2()->isFuncDeclaration(); if (fdp && fdp->semanticRun < PASSobj) { /* Bugzilla 7595 * FuncDeclaration::buildClosure() relies on nested functions * being toObjFile'd after the outer function. Otherwise, the * v->offset's for the closure variables are wrong. * So, defer fd until after fdp is done. */ fdp->deferred.push(fd); continue; } } s->toObjFile(0); } for (size_t i = 0; i < deferred.dim; i++) { FuncDeclaration *fd = deferred[i]; fd->toObjFile(0); } #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS // A hack to get a pointer to this function put in the .dtors segment if (ident && memcmp(ident->toChars(), "_STD", 4) == 0) obj_staticdtor(s); #endif #if DMDV2 if (irs.startaddress) { printf("Setting start address\n"); obj_startaddress(irs.startaddress); } #endif }
Expression *VarExp::doInline(InlineDoState *ids) { //printf("VarExp::doInline(%s)\n", toChars()); for (size_t i = 0; i < ids->from.dim; i++) { if (var == ids->from[i]) { VarExp *ve = (VarExp *)copy(); ve->var = (Declaration *)ids->to[i]; return ve; } } if (ids->fd && var == ids->fd->vthis) { VarExp *ve = new VarExp(loc, ids->vthis); ve->type = type; return ve; } /* Inlining context pointer access for nested referenced variables. * For example: * auto fun() { * int i = 40; * auto foo() { * int g = 2; * struct Result { * auto bar() { return i + g; } * } * return Result(); * } * return foo(); * } * auto t = fun(); * 'i' and 'g' are nested referenced variables in Result.bar(), so: * auto x = t.bar(); * should be inlined to: * auto x = *(t.vthis.vthis + i->voffset) + *(t.vthis + g->voffset) */ VarDeclaration *v = var->isVarDeclaration(); if (v && v->nestedrefs.dim && ids->vthis) { Dsymbol *s = ids->fd; FuncDeclaration *fdv = v->toParent()->isFuncDeclaration(); assert(fdv); Expression *ve = new VarExp(loc, ids->vthis); ve->type = ids->vthis->type; while (s != fdv) { FuncDeclaration *f = s->isFuncDeclaration(); if (AggregateDeclaration *ad = s->isThis()) { assert(ad->vthis); ve = new DotVarExp(loc, ve, ad->vthis); ve->type = ad->vthis->type; s = ad->toParent2(); } else if (f && f->isNested()) { assert(f->vthis); if (f->hasNestedFrameRefs()) { ve = new DotVarExp(loc, ve, f->vthis); ve->type = f->vthis->type; } s = f->toParent2(); } else assert(0); assert(s); } ve = new DotVarExp(loc, ve, v); ve->type = v->type; //printf("\t==> ve = %s, type = %s\n", ve->toChars(), ve->type->toChars()); return ve; } return this; }
void FuncDeclaration::toObjFile(int multiobj) { FuncDeclaration *func = this; ClassDeclaration *cd = func->parent->isClassDeclaration(); int reverse; int has_arguments; //printf("FuncDeclaration::toObjFile(%p, %s.%s)\n", func, parent->toChars(), func->toChars()); //if (type) printf("type = %s\n", func->type->toChars()); #if 0 //printf("line = %d\n",func->getWhere() / LINEINC); EEcontext *ee = env->getEEcontext(); if (ee->EEcompile == 2) { if (ee->EElinnum < (func->getWhere() / LINEINC) || ee->EElinnum > (func->endwhere / LINEINC) ) return; // don't compile this function ee->EEfunc = func->toSymbol(); } #endif if (semanticRun >= PASSobj) // if toObjFile() already run return; // If errors occurred compiling it, such as bugzilla 6118 if (type && type->ty == Tfunction && ((TypeFunction *)type)->next->ty == Terror) return; if (!func->fbody) { return; } if (func->isUnitTestDeclaration() && !global.params.useUnitTests) return; if (multiobj && !isStaticDtorDeclaration() && !isStaticCtorDeclaration()) { obj_append(this); return; } if (semanticRun == PASSsemanticdone) { /* What happened is this function failed semantic3() with errors, * but the errors were gagged. * Try to reproduce those errors, and then fail. */ error("errors compiling the function"); return; } assert(semanticRun == PASSsemantic3done); semanticRun = PASSobj; if (global.params.verbose) printf("function %s\n",func->toPrettyChars()); Symbol *s = func->toSymbol(); func_t *f = s->Sfunc; // tunnel type of "this" to debug info generation if (AggregateDeclaration* ad = func->parent->isAggregateDeclaration()) { ::type* t = ad->getType()->toCtype(); if(cd) t = t->Tnext; // skip reference f->Fclass = (Classsym *)t; } #if TARGET_WINDOS /* This is done so that the 'this' pointer on the stack is the same * distance away from the function parameters, so that an overriding * function can call the nested fdensure or fdrequire of its overridden function * and the stack offsets are the same. */ if (isVirtual() && (fensure || frequire)) f->Fflags3 |= Ffakeeh; #endif #if TARGET_OSX s->Sclass = SCcomdat; #else s->Sclass = SCglobal; #endif for (Dsymbol *p = parent; p; p = p->parent) { if (p->isTemplateInstance()) { s->Sclass = SCcomdat; break; } } /* Vector operations should be comdat's */ if (isArrayOp) s->Sclass = SCcomdat; if (isNested()) { // if (!(config.flags3 & CFG3pic)) // s->Sclass = SCstatic; f->Fflags3 |= Fnested; /* The enclosing function must have its code generated first, * so we know things like where its local symbols are stored. */ FuncDeclaration *fdp = toAliasFunc()->toParent2()->isFuncDeclaration(); // Bug 8016 - only include the function if it is a template instance Dsymbol * owner = NULL; if (fdp) { owner = fdp->toParent(); while (owner && !owner->isTemplateInstance()) owner = owner->toParent(); } if (owner && fdp && fdp->semanticRun == PASSsemantic3done && !fdp->isUnitTestDeclaration()) { /* Can't do unittest's out of order, they are order dependent in that their * execution is done in lexical order, and some modules (std.datetime *cough* * *cough*) rely on this. */ fdp->toObjFile(multiobj); } } else { const char *libname = (global.params.symdebug) ? global.params.debuglibname : global.params.defaultlibname; // Pull in RTL startup code (but only once) if (func->isMain() && onlyOneMain(loc)) { #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS objmod->external_def("_main"); objmod->ehsections(); // initialize exception handling sections #endif #if TARGET_WINDOS if (I64) { objmod->external_def("main"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("_main"); objmod->external_def("__acrtused_con"); } #endif objmod->includelib(libname); s->Sclass = SCglobal; } else if (strcmp(s->Sident, "main") == 0 && linkage == LINKc) { #if TARGET_WINDOS if (I64) { objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); } else { objmod->external_def("__acrtused_con"); // bring in C startup code objmod->includelib("snn.lib"); // bring in C runtime library } #endif s->Sclass = SCglobal; } #if TARGET_WINDOS else if (func->isWinMain() && onlyOneMain(loc)) { if (I64) { objmod->includelib("uuid"); objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("__acrtused"); } objmod->includelib(libname); s->Sclass = SCglobal; } // Pull in RTL startup code else if (func->isDllMain() && onlyOneMain(loc)) { if (I64) { objmod->includelib("uuid"); objmod->includelib("LIBCMT"); objmod->includelib("OLDNAMES"); objmod->ehsections(); // initialize exception handling sections } else { objmod->external_def("__acrtused_dll"); } objmod->includelib(libname); s->Sclass = SCglobal; } #endif } cstate.CSpsymtab = &f->Flocsym; // Find module m for this function Module *m = NULL; for (Dsymbol *p = parent; p; p = p->parent) { m = p->isModule(); if (m) break; } IRState irs(m, func); Dsymbols deferToObj; // write these to OBJ file later irs.deferToObj = &deferToObj; TypeFunction *tf; enum RET retmethod; symbol *shidden = NULL; Symbol *sthis = NULL; tym_t tyf; tyf = tybasic(s->Stype->Tty); //printf("linkage = %d, tyf = x%x\n", linkage, tyf); reverse = tyrevfunc(s->Stype->Tty); assert(func->type->ty == Tfunction); tf = (TypeFunction *)(func->type); has_arguments = (tf->linkage == LINKd) && (tf->varargs == 1); retmethod = tf->retStyle(); if (retmethod == RETstack) { // If function returns a struct, put a pointer to that // as the first argument ::type *thidden = tf->next->pointerTo()->toCtype(); char hiddenparam[5+4+1]; static int hiddenparami; // how many we've generated so far sprintf(hiddenparam,"__HID%d",++hiddenparami); shidden = symbol_name(hiddenparam,SCparameter,thidden); shidden->Sflags |= SFLtrue | SFLfree; #if DMDV1 if (func->nrvo_can && func->nrvo_var && func->nrvo_var->nestedref) #else if (func->nrvo_can && func->nrvo_var && func->nrvo_var->nestedrefs.dim) #endif type_setcv(&shidden->Stype, shidden->Stype->Tty | mTYvolatile); irs.shidden = shidden; this->shidden = shidden; } else { // Register return style cannot make nrvo. // Auto functions keep the nrvo_can flag up to here, // so we should eliminate it before entering backend. nrvo_can = 0; } if (vthis) { assert(!vthis->csym); sthis = vthis->toSymbol(); irs.sthis = sthis; if (!(f->Fflags3 & Fnested)) f->Fflags3 |= Fmember; } // Estimate number of parameters, pi size_t pi = (v_arguments != NULL); if (parameters) pi += parameters->dim; // Create a temporary buffer, params[], to hold function parameters Symbol *paramsbuf[10]; Symbol **params = paramsbuf; // allocate on stack if possible if (pi + 2 > 10) // allow extra 2 for sthis and shidden { params = (Symbol **)malloc((pi + 2) * sizeof(Symbol *)); assert(params); } // Get the actual number of parameters, pi, and fill in the params[] pi = 0; if (v_arguments) { params[pi] = v_arguments->toSymbol(); pi += 1; } if (parameters) { for (size_t i = 0; i < parameters->dim; i++) { VarDeclaration *v = (*parameters)[i]; if (v->csym) { error("compiler error, parameter '%s', bugzilla 2962?", v->toChars()); assert(0); } params[pi + i] = v->toSymbol(); } pi += parameters->dim; } if (reverse) { // Reverse params[] entries for (size_t i = 0; i < pi/2; i++) { Symbol *sptmp = params[i]; params[i] = params[pi - 1 - i]; params[pi - 1 - i] = sptmp; } } if (shidden) { #if 0 // shidden becomes last parameter params[pi] = shidden; #else // shidden becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = shidden; #endif pi++; } if (sthis) { #if 0 // sthis becomes last parameter params[pi] = sthis; #else // sthis becomes first parameter memmove(params + 1, params, pi * sizeof(params[0])); params[0] = sthis; #endif pi++; } if ((global.params.isLinux || global.params.isOSX || global.params.isFreeBSD || global.params.isSolaris) && linkage != LINKd && shidden && sthis) { /* swap shidden and sthis */ Symbol *sp = params[0]; params[0] = params[1]; params[1] = sp; } for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; sp->Sclass = SCparameter; sp->Sflags &= ~SFLspill; sp->Sfl = FLpara; symbol_add(sp); } // Determine register assignments if (pi) { FuncParamRegs fpr(tyf); for (size_t i = 0; i < pi; i++) { Symbol *sp = params[i]; if (fpr.alloc(sp->Stype, sp->Stype->Tty, &sp->Spreg, &sp->Spreg2)) { sp->Sclass = (config.exe == EX_WIN64) ? SCshadowreg : SCfastpar; sp->Sfl = (sp->Sclass == SCshadowreg) ? FLpara : FLfast; } } } // Done with params if (params != paramsbuf) free(params); params = NULL; if (func->fbody) { localgot = NULL; Statement *sbody = func->fbody; Blockx bx; memset(&bx,0,sizeof(bx)); bx.startblock = block_calloc(); bx.curblock = bx.startblock; bx.funcsym = s; bx.scope_index = -1; bx.classdec = cd; bx.member = func; bx.module = getModule(); irs.blx = &bx; /* If profiling, insert call to the profiler here. * _c_trace_pro(char* funcname); */ if (global.params.trace) { dt_t *dt = NULL; char *id = s->Sident; size_t len = strlen(id); dtnbytes(&dt, len + 1, id); Symbol *sfuncname = symbol_generate(SCstatic,type_fake(TYchar)); sfuncname->Sdt = dt; sfuncname->Sfl = FLdata; out_readonly(sfuncname); outdata(sfuncname); elem *efuncname = el_ptr(sfuncname); elem *eparam = el_params(efuncname, el_long(TYsize_t, len), NULL); elem *e = el_bin(OPcall, TYvoid, el_var(rtlsym[RTLSYM_TRACE_CPRO]), eparam); block_appendexp(bx.curblock, e); } #if DMDV2 buildClosure(&irs); #endif #if TARGET_WINDOS if (func->isSynchronized() && cd && config.flags2 & CFG2seh && !func->isStatic() && !sbody->usesEH()) { /* The "jmonitor" hack uses an optimized exception handling frame * which is a little shorter than the more general EH frame. */ s->Sfunc->Fflags3 |= Fjmonitor; } #endif sbody->toIR(&irs); bx.curblock->BC = BCret; f->Fstartblock = bx.startblock; // einit = el_combine(einit,bx.init); if (isCtorDeclaration()) { assert(sthis); for (block *b = f->Fstartblock; b; b = b->Bnext) { if (b->BC == BCret) { b->BC = BCretexp; b->Belem = el_combine(b->Belem, el_var(sthis)); } } } } // If static constructor #if DMDV2 if (isSharedStaticCtorDeclaration()) // must come first because it derives from StaticCtorDeclaration { ssharedctors.push(s); } else #endif if (isStaticCtorDeclaration()) { sctors.push(s); } // If static destructor #if DMDV2 if (isSharedStaticDtorDeclaration()) // must come first because it derives from StaticDtorDeclaration { SharedStaticDtorDeclaration *f = isSharedStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ esharedctorgates.push(f); } sshareddtors.shift(s); } else #endif if (isStaticDtorDeclaration()) { StaticDtorDeclaration *f = isStaticDtorDeclaration(); assert(f); if (f->vgate) { /* Increment destructor's vgate at construction time */ ectorgates.push(f); } sdtors.shift(s); } // If unit test if (isUnitTestDeclaration()) { stests.push(s); } if (global.errors) return; writefunc(s); if (isExport()) objmod->export_symbol(s, Para.offset); for (size_t i = 0; i < irs.deferToObj->dim; i++) { Dsymbol *s = (*irs.deferToObj)[i]; FuncDeclaration *fd = s->isFuncDeclaration(); if (fd) { FuncDeclaration *fdp = fd->toParent2()->isFuncDeclaration(); if (fdp && fdp->semanticRun < PASSobj) { /* Bugzilla 7595 * FuncDeclaration::buildClosure() relies on nested functions * being toObjFile'd after the outer function. Otherwise, the * v->offset's for the closure variables are wrong. * So, defer fd until after fdp is done. */ fdp->deferred.push(fd); continue; } } s->toObjFile(0); } for (size_t i = 0; i < deferred.dim; i++) { FuncDeclaration *fd = deferred[i]; fd->toObjFile(0); } #if TARGET_LINUX || TARGET_OSX || TARGET_FREEBSD || TARGET_OPENBSD || TARGET_SOLARIS // A hack to get a pointer to this function put in the .dtors segment if (ident && memcmp(ident->toChars(), "_STD", 4) == 0) objmod->staticdtor(s); #endif #if DMDV2 if (irs.startaddress) { //printf("Setting start address\n"); objmod->startaddress(irs.startaddress); } #endif }
void Declaration::checkModify(Loc loc, Scope *sc, Type *t) { if (sc->incontract && isParameter()) error(loc, "cannot modify parameter '%s' in contract", toChars()); if (sc->incontract && isResult()) error(loc, "cannot modify result '%s' in contract", toChars()); if (isCtorinit() && !t->isMutable()) { // It's only modifiable if inside the right constructor Dsymbol *s = sc->func; while (1) { FuncDeclaration *fd = NULL; if (s) fd = s->isFuncDeclaration(); if (fd && ((fd->isCtorDeclaration() && storage_class & STCfield) || (fd->isStaticCtorDeclaration() && !(storage_class & STCfield))) && fd->toParent2() == toParent() ) { VarDeclaration *v = isVarDeclaration(); assert(v); v->ctorinit = 1; //printf("setting ctorinit\n"); } else { if (s) { s = s->toParent2(); continue; } else { const char *p = isStatic() ? "static " : ""; error(loc, "can only initialize %sconst %s inside %sconstructor", p, toChars(), p); } } break; } } else { VarDeclaration *v = isVarDeclaration(); if (v && v->canassign == 0) { const char *p = NULL; if (isConst()) p = "const"; else if (isImmutable()) p = "immutable"; else if (storage_class & STCmanifest) p = "enum"; else if (!t->isAssignable()) p = "struct with immutable members"; if (p) { error(loc, "cannot modify %s", p); } } } }
void DtoDefineFunction(FuncDeclaration* fd) { IF_LOG Logger::println("DtoDefineFunction(%s): %s", fd->toPrettyChars(), fd->loc.toChars()); LOG_SCOPE; if (fd->ir.isDefined()) return; if ((fd->type && fd->type->ty == Terror) || (fd->type && fd->type->ty == Tfunction && static_cast<TypeFunction *>(fd->type)->next == NULL) || (fd->type && fd->type->ty == Tfunction && static_cast<TypeFunction *>(fd->type)->next->ty == Terror)) { IF_LOG Logger::println("Ignoring; has error type, no return type or returns error type"); fd->ir.setDefined(); return; } if (fd->semanticRun == PASSsemanticdone) { /* What happened is this function failed semantic3() with errors, * but the errors were gagged. * Try to reproduce those errors, and then fail. */ error(fd->loc, "errors compiling function %s", fd->toPrettyChars()); fd->ir.setDefined(); return; } DtoResolveFunction(fd); if (fd->isUnitTestDeclaration() && !global.params.useUnitTests) { IF_LOG Logger::println("No code generation for unit test declaration %s", fd->toChars()); fd->ir.setDefined(); return; } // Skip array ops implemented in druntime if (fd->isArrayOp && isDruntimeArrayOp(fd)) { IF_LOG Logger::println("No code generation for array op %s implemented in druntime", fd->toChars()); fd->ir.setDefined(); return; } // Check whether the frontend knows that the function is already defined // in some other module (see DMD's FuncDeclaration::toObjFile). for (FuncDeclaration *f = fd; f; ) { if (!f->isInstantiated() && f->inNonRoot()) { IF_LOG Logger::println("Skipping '%s'.", fd->toPrettyChars()); // TODO: Emit as available_externally for inlining purposes instead // (see #673). fd->ir.setDefined(); return; } if (f->isNested()) f = f->toParent2()->isFuncDeclaration(); else break; } DtoDeclareFunction(fd); assert(fd->ir.isDeclared()); // DtoResolveFunction might also set the defined flag for functions we // should not touch. if (fd->ir.isDefined()) return; fd->ir.setDefined(); // We cannot emit nested functions with parents that have not gone through // semantic analysis. This can happen as DMD leaks some template instances // from constraints into the module member list. DMD gets away with being // sloppy as functions in template contraints obviously never need to access // data from the template function itself, but it would still mess up our // nested context creation code. FuncDeclaration* parent = fd; while ((parent = getParentFunc(parent, true))) { if (parent->semanticRun != PASSsemantic3done || parent->semantic3Errors) { IF_LOG Logger::println("Ignoring nested function with unanalyzed parent."); return; } } assert(fd->semanticRun == PASSsemantic3done); assert(fd->ident != Id::empty); if (fd->isUnitTestDeclaration()) { gIR->unitTests.push_back(fd); } else if (fd->isSharedStaticCtorDeclaration()) { gIR->sharedCtors.push_back(fd); } else if (StaticDtorDeclaration *dtorDecl = fd->isSharedStaticDtorDeclaration()) { gIR->sharedDtors.push_front(fd); if (dtorDecl->vgate) gIR->sharedGates.push_front(dtorDecl->vgate); } else if (fd->isStaticCtorDeclaration()) { gIR->ctors.push_back(fd); } else if (StaticDtorDeclaration *dtorDecl = fd->isStaticDtorDeclaration()) { gIR->dtors.push_front(fd); if (dtorDecl->vgate) gIR->gates.push_front(dtorDecl->vgate); } // if this function is naked, we take over right away! no standard processing! if (fd->naked) { DtoDefineNakedFunction(fd); return; } IrFunction *irFunc = getIrFunc(fd); IrFuncTy &irFty = irFunc->irFty; // debug info irFunc->diSubprogram = gIR->DBuilder.EmitSubProgram(fd); Type* t = fd->type->toBasetype(); TypeFunction* f = static_cast<TypeFunction*>(t); // assert(f->ctype); llvm::Function* func = irFunc->func; // is there a body? if (fd->fbody == NULL) return; IF_LOG Logger::println("Doing function body for: %s", fd->toChars()); gIR->functions.push_back(irFunc); if (fd->isMain()) gIR->emitMain = true; func->setLinkage(lowerFuncLinkage(fd)); // On x86_64, always set 'uwtable' for System V ABI compatibility. // TODO: Find a better place for this. // TODO: Is this required for Win64 as well? if (global.params.targetTriple.getArch() == llvm::Triple::x86_64) { func->addFnAttr(LDC_ATTRIBUTE(UWTable)); } #if LDC_LLVM_VER >= 303 if (opts::sanitize != opts::None) { // Set the required sanitizer attribute. if (opts::sanitize == opts::AddressSanitizer) { func->addFnAttr(LDC_ATTRIBUTE(SanitizeAddress)); } if (opts::sanitize == opts::MemorySanitizer) { func->addFnAttr(LDC_ATTRIBUTE(SanitizeMemory)); } if (opts::sanitize == opts::ThreadSanitizer) { func->addFnAttr(LDC_ATTRIBUTE(SanitizeThread)); } } #endif llvm::BasicBlock* beginbb = llvm::BasicBlock::Create(gIR->context(), "", func); llvm::BasicBlock* endbb = llvm::BasicBlock::Create(gIR->context(), "endentry", func); //assert(gIR->scopes.empty()); gIR->scopes.push_back(IRScope(beginbb, endbb)); // create alloca point // this gets erased when the function is complete, so alignment etc does not matter at all llvm::Instruction* allocaPoint = new llvm::AllocaInst(LLType::getInt32Ty(gIR->context()), "alloca point", beginbb); irFunc->allocapoint = allocaPoint; // debug info - after all allocas, but before any llvm.dbg.declare etc gIR->DBuilder.EmitFuncStart(fd); // this hack makes sure the frame pointer elimination optimization is disabled. // this this eliminates a bunch of inline asm related issues. if (fd->hasReturnExp & 8) // has inline asm { // emit a call to llvm_eh_unwind_init LLFunction* hack = GET_INTRINSIC_DECL(eh_unwind_init); gIR->ir->CreateCall(hack, ""); } // give the 'this' argument storage and debug info if (irFty.arg_this) { LLValue* thisvar = irFunc->thisArg; assert(thisvar); LLValue* thismem = thisvar; if (!irFty.arg_this->byref) { thismem = DtoRawAlloca(thisvar->getType(), 0, "this"); // FIXME: align? DtoStore(thisvar, thismem); irFunc->thisArg = thismem; } assert(getIrParameter(fd->vthis)->value == thisvar); getIrParameter(fd->vthis)->value = thismem; gIR->DBuilder.EmitLocalVariable(thismem, fd->vthis); } // give the 'nestArg' storage if (irFty.arg_nest) { LLValue *nestArg = irFunc->nestArg; LLValue *val = DtoRawAlloca(nestArg->getType(), 0, "nestedFrame"); DtoStore(nestArg, val); irFunc->nestArg = val; } // give arguments storage // and debug info if (fd->parameters) { size_t n = irFty.args.size(); assert(n == fd->parameters->dim); for (size_t i=0; i < n; ++i) { Dsymbol* argsym = static_cast<Dsymbol*>(fd->parameters->data[i]); VarDeclaration* vd = argsym->isVarDeclaration(); assert(vd); IrParameter* irparam = getIrParameter(vd); assert(irparam); bool refout = vd->storage_class & (STCref | STCout); bool lazy = vd->storage_class & STClazy; if (!refout && (!irparam->arg->byref || lazy)) { // alloca a stack slot for this first class value arg LLValue* mem = DtoAlloca(irparam->arg->type, vd->ident->toChars()); // let the abi transform the argument back first DImValue arg_dval(vd->type, irparam->value); irFty.getParam(vd->type, i, &arg_dval, mem); // set the arg var value to the alloca irparam->value = mem; } if (global.params.symdebug && !(isaArgument(irparam->value) && isaArgument(irparam->value)->hasByValAttr()) && !refout) gIR->DBuilder.EmitLocalVariable(irparam->value, vd); } } FuncGen fg; irFunc->gen = &fg; DtoCreateNestedContext(fd); if (fd->vresult && ! fd->vresult->nestedrefs.dim // FIXME: not sure here :/ ) { DtoVarDeclaration(fd->vresult); } // D varargs: prepare _argptr and _arguments if (f->linkage == LINKd && f->varargs == 1) { // allocate _argptr (of type core.stdc.stdarg.va_list) LLValue* argptrmem = DtoAlloca(Type::tvalist, "_argptr_mem"); irFunc->_argptr = argptrmem; // initialize _argptr with a call to the va_start intrinsic LLValue* vaStartArg = gABI->prepareVaStart(argptrmem); llvm::CallInst::Create(GET_INTRINSIC_DECL(vastart), vaStartArg, "", gIR->scopebb()); // copy _arguments to a memory location LLType* argumentsType = irFunc->_arguments->getType(); LLValue* argumentsmem = DtoRawAlloca(argumentsType, 0, "_arguments_mem"); new llvm::StoreInst(irFunc->_arguments, argumentsmem, gIR->scopebb()); irFunc->_arguments = argumentsmem; } // output function body codegenFunction(fd->fbody, gIR); irFunc->gen = 0; llvm::BasicBlock* bb = gIR->scopebb(); if (pred_begin(bb) == pred_end(bb) && bb != &bb->getParent()->getEntryBlock()) { // This block is trivially unreachable, so just delete it. // (This is a common case because it happens when 'return' // is the last statement in a function) bb->eraseFromParent(); } else if (!gIR->scopereturned()) { // llvm requires all basic blocks to end with a TerminatorInst but DMD does not put a return statement // in automatically, so we do it here. // pass the previous block into this block gIR->DBuilder.EmitFuncEnd(fd); if (func->getReturnType() == LLType::getVoidTy(gIR->context())) { llvm::ReturnInst::Create(gIR->context(), gIR->scopebb()); } else if (!fd->isMain()) { AsmBlockStatement* asmb = fd->fbody->endsWithAsm(); if (asmb) { assert(asmb->abiret); llvm::ReturnInst::Create(gIR->context(), asmb->abiret, bb); } else { llvm::ReturnInst::Create(gIR->context(), llvm::UndefValue::get(func->getReturnType()), bb); } } else llvm::ReturnInst::Create(gIR->context(), LLConstant::getNullValue(func->getReturnType()), bb); } // erase alloca point if (allocaPoint->getParent()) allocaPoint->eraseFromParent(); allocaPoint = 0; gIR->func()->allocapoint = 0; gIR->scopes.pop_back(); // get rid of the endentry block, it's never used assert(!func->getBasicBlockList().empty()); func->getBasicBlockList().pop_back(); gIR->functions.pop_back(); }