/* * (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands. * See the copyright notice in the ACK home directory, in the file "Copyright". * * Author: Ceriel J.H. Jacobs */ /* P A R S E T R E E W A L K E R */ /* $Header$ */ /* Routines to walk through parts of the parse tree, and generate code for these parts. */ #include "debug.h" #include #include #include #include #include #include #include #include "strict3rd.h" #include "LLlex.h" #include "def.h" #include "type.h" #include "scope.h" #include "main.h" #include "node.h" #include "Lpars.h" #include "desig.h" #include "f_info.h" #include "idf.h" #include "chk_expr.h" #include "walk.h" #include "misc.h" #include "warning.h" extern arith NewPtr(); extern arith NewInt(); extern int proclevel; label text_label; label data_label = 1; struct withdesig *WithDesigs; t_node *Modules; static t_type *func_type; static t_node *priority; static int oldlineno; static int RegisterMessage(); static int WalkDef(); static int MkCalls(); static int UseWarnings(); #define NO_EXIT_LABEL ((label) 0) #define RETURN_LABEL ((label) 1) LblWalkNode(lbl, nd, exit) label lbl, exit; register t_node *nd; { /* Generate code for node "nd", after generating instruction label "lbl". "exit" is the exit label for the closest enclosing LOOP. */ def_ilb(lbl); WalkNode(nd, exit); } STATIC DoPriority() { /* For the time being (???), handle priorities by calls to the runtime system */ register t_node *pri = priority; if (pri) { C_loc(pri->nd_INT); C_cal("_stackprio"); C_asp(word_size); } } STATIC EndPriority() { if (priority) { C_cal("_unstackprio"); } } def_ilb(l) label l; { C_df_ilb(l); oldlineno = 0; } DoLineno(nd) register t_node *nd; { if (! options['L'] && nd->nd_lineno && nd->nd_lineno != oldlineno) { oldlineno = nd->nd_lineno; C_lin((arith) nd->nd_lineno); } } DoFilename(nd) t_node *nd; { static label filename_label = 0; oldlineno = 0; if (! options['L']) { if (! filename_label) { filename_label = 1; C_df_dlb((label) 1); C_rom_scon(FileName, (arith) (strlen(FileName) + 1)); } C_fil_dlb((label) 1, (arith) 0); if (nd) DoLineno(nd); } } WalkModule(module) register t_def *module; { /* Walk through a module, and all its local definitions. Also generate code for its body. This code is collected in an initialization routine. */ register t_scope *sc; t_scopelist *savevis = CurrVis; CurrVis = module->mod_vis; priority = module->mod_priority; sc = CurrentScope; /* Walk through it's local definitions */ WalkDefList(sc->sc_def, WalkDef); /* Now, generate initialization code for this module. First call initialization routines for modules defined within this module. */ sc->sc_off = 0; /* no locals (yet) */ text_label = 1; /* label at end of initialization routine */ TmpOpen(sc); /* Initialize for temporaries */ C_pro_narg(sc->sc_name); DoPriority(); DoFilename(module->mod_body); if (module == Defined) { /* Body of implementation or program module. Call initialization routines of imported modules. Also prevent recursive calls of this one. */ register t_node *nd = Modules; if (state == IMPLEMENTATION) { /* We don't actually prevent recursive calls, but do nothing if called recursively */ C_df_dlb(++data_label); C_con_cst((arith) 0); /* if this one is set to non-zero, the initialization was already done. */ C_loe_dlb(data_label, (arith) 0); C_zne(RETURN_LABEL); C_ine_dlb(data_label, (arith) 0); } for (; nd; nd = nd->nd_left) { C_cal(nd->nd_IDF->id_text); } } WalkDefList(sc->sc_def, MkCalls); proclevel++; WalkNode(module->mod_body, NO_EXIT_LABEL); DO_DEBUG(options['X'], PrNode(module->mod_body, 0)); def_ilb(RETURN_LABEL); EndPriority(); C_ret((arith) 0); C_end(-sc->sc_off); proclevel--; TmpClose(); CurrVis = savevis; WalkDefList(sc->sc_def, UseWarnings); } WalkProcedure(procedure) register t_def *procedure; { /* Walk through the definition of a procedure and all its local definitions, checking and generating code. */ t_scopelist *savevis = CurrVis; register t_scope *procscope = procedure->prc_vis->sc_scope; register t_type *tp; register t_param *param; label func_res_label = 0; arith StackAdjustment = 0; arith retsav = 0; arith func_res_size = 0; proclevel++; CurrVis = procedure->prc_vis; /* Generate code for all local modules and procedures */ WalkDefList(procscope->sc_def, WalkDef); /* Generate code for this procedure */ C_pro_narg(procscope->sc_name); DoPriority(); DoFilename(procedure->prc_body); TmpOpen(procscope); func_type = tp = RemoveEqual(ResultType(procedure->df_type)); if (tp) { func_res_size = WA(tp->tp_size); if (IsConstructed(tp)) { /* The result type of this procedure is constructed. The actual procedure will return a pointer to a global data area in which the function result is stored. Notice that this does make the code non-reentrant. Here, we create the data area for the function result. */ func_res_label = ++data_label; C_df_dlb(func_res_label); C_bss_cst(func_res_size, (arith) 0, 0); } } /* Generate calls to initialization routines of modules defined within this procedure */ WalkDefList(procscope->sc_def, MkCalls); /* Make sure that arguments of size < word_size are on a fixed place. Also make copies of conformant arrays when neccessary. */ for (param = ParamList(procedure->df_type); param; param = param->par_next) { if (! IsVarParam(param)) { tp = TypeOfParam(param); if (! IsConformantArray(tp)) { if (tp->tp_size < word_size && (int) word_size % (int) tp->tp_size == 0) { C_lol(param->par_def->var_off); C_lal(param->par_def->var_off); C_sti(tp->tp_size); } } else { /* Here, we have to make a copy of the array. We must also remember how much room is reserved for copies, because we have to adjust the stack pointer before a RET is done. This is even more complicated when the procedure returns a value. Then, the value must be saved (in retval), the stack adjusted, the return value pushed again, and then RET */ if (! StackAdjustment) { /* First time we get here */ if (func_type && !func_res_label) { /* Some local space, only needed if the value itself is returned */ procscope->sc_off -= func_res_size; retsav = procscope->sc_off; } StackAdjustment = NewPtr(); C_lor((arith) 1); C_stl(StackAdjustment); } /* First compute new stackpointer */ C_lal(param->par_def->var_off); C_cal("_new_stackptr"); C_asp(pointer_size); C_lfr(pointer_size); C_str((arith) 1); /* adjusted stack pointer */ C_lol(param->par_def->var_off); /* push source address */ C_cal("_copy_array"); /* copy */ C_asp(word_size); } } } text_label = 1; /* label at end of procedure */ WalkNode(procedure->prc_body, NO_EXIT_LABEL); DO_DEBUG(options['X'], PrNode(procedure->prc_body, 0)); if (func_res_size) { c_loc(M2_NORESULT); C_trp(); C_asp(-func_res_size); } def_ilb(RETURN_LABEL); /* label at end */ if (func_res_label) { /* Fill the data area reserved for the function result with the result */ c_lae_dlb(func_res_label); C_sti(func_res_size); if (StackAdjustment) { /* Remove copies of conformant arrays */ C_lol(StackAdjustment); C_str((arith) 1); } c_lae_dlb(func_res_label); func_res_size = pointer_size; } else if (StackAdjustment) { /* First save the function result in a safe place. Then remove copies of conformant arrays, and put function result back on the stack */ if (func_type) { C_lal(retsav); C_sti(func_res_size); } C_lol(StackAdjustment); C_str((arith) 1); if (func_type) { C_lal(retsav); C_loi(func_res_size); } FreePtr(StackAdjustment); } EndPriority(); C_ret(func_res_size); if (! options['n']) WalkDefList(procscope->sc_def, RegisterMessage); C_end(-procscope->sc_off); if (! fit(procscope->sc_off, (int) word_size)) { node_error(procedure->prc_body, "maximum local byte count exceeded"); } TmpClose(); CurrVis = savevis; proclevel--; WalkDefList(procscope->sc_def, UseWarnings); } static int WalkDef(df) register t_def *df; { /* Walk through a list of definitions */ switch(df->df_kind) { case D_MODULE: WalkModule(df); break; case D_PROCEDURE: WalkProcedure(df); break; case D_VARIABLE: if (!proclevel && !(df->df_flags & D_ADDRGIVEN)) { C_df_dnam(df->var_name); C_bss_cst( WA(df->df_type->tp_size), (arith) 0, 0); } break; default: /* nothing */ ; } } static int MkCalls(df) register t_def *df; { /* Generate calls to initialization routines of modules */ if (df->df_kind == D_MODULE) { C_lxl((arith) 0); C_cal(df->mod_vis->sc_scope->sc_name); C_asp(pointer_size); } } WalkLink(nd, exit_label) register t_node *nd; label exit_label; { /* Walk node "nd", which is a link. */ while (nd && nd->nd_class == Link) { /* statement list */ WalkNode(nd->nd_left, exit_label); nd = nd->nd_right; } WalkNode(nd, exit_label); } STATIC ForLoopVarExpr(nd) register t_node *nd; { register t_type *tp = nd->nd_type; CodePExpr(nd); CodeCoercion(tp, BaseType(tp)); } WalkStat(nd, exit_label) register t_node *nd; label exit_label; { /* Walk through a statement, generating code for it. */ register t_node *left = nd->nd_left; register t_node *right = nd->nd_right; assert(nd->nd_class == Stat); DoLineno(nd); switch(nd->nd_symb) { case '(': if (ChkCall(nd)) { if (nd->nd_type != 0) { node_error(nd, "illegal function call"); break; } CodeCall(nd); } break; case ';': break; case BECOMES: DoAssign(left, right); break; case IF: { label l1 = ++text_label, l3 = ++text_label; ExpectBool(left, l3, l1); assert(right->nd_symb == THEN); LblWalkNode(l3, right->nd_left, exit_label); if (right->nd_right) { /* ELSE part */ label l2 = ++text_label; C_bra(l2); LblWalkNode(l1, right->nd_right, exit_label); l1 = l2; } def_ilb(l1); break; } case CASE: CaseCode(nd, exit_label); break; case WHILE: { label loop = ++text_label, exit = ++text_label, dummy = ++text_label; def_ilb(loop); ExpectBool(left, dummy, exit); LblWalkNode(dummy, right, exit_label); C_bra(loop); def_ilb(exit); break; } case REPEAT: { label loop = ++text_label, exit = ++text_label; LblWalkNode(loop, left, exit_label); ExpectBool(right, exit, loop); def_ilb(exit); break; } case LOOP: { label loop = ++text_label, exit = ++text_label; LblWalkNode(loop, right, exit); C_bra(loop); def_ilb(exit); break; } case FOR: { arith tmp = NewInt(); arith tmp2; register t_node *fnd; int good_forvar; label l1 = ++text_label; label l2 = ++text_label; int uns = 0; arith stepsize; t_type *bstp; good_forvar = DoForInit(nd); if ((stepsize = left->nd_INT) == 0) { node_warning(left, W_ORDINARY, "zero stepsize in FOR loop"); } fnd = left->nd_right; if (good_forvar) { bstp = BaseType(nd->nd_type); uns = bstp->tp_fund != T_INTEGER; C_dup(int_size); CodeDStore(nd); CodePExpr(fnd); C_stl(tmp); C_lol(tmp); if (uns) C_cmu(int_size); else C_cmi(int_size); if (left->nd_INT >= 0) { C_zgt(l2); C_lol(tmp); ForLoopVarExpr(nd); } else { stepsize = -stepsize; C_zlt(l2); ForLoopVarExpr(nd); C_lol(tmp); } C_sbu(int_size); if (stepsize) { C_loc(stepsize); C_dvu(int_size); } C_stl(tmp); nd->nd_def->df_flags |= D_FORLOOP; def_ilb(l1); if (! options['R']) { tmp2 = NewInt(); ForLoopVarExpr(nd); C_stl(tmp2); } } WalkNode(right, exit_label); nd->nd_def->df_flags &= ~D_FORLOOP; if (good_forvar) { if (! options['R']) { label x = ++text_label; C_lol(tmp2); ForLoopVarExpr(nd); C_beq(x); c_loc(M2_FORCH); C_trp(); def_ilb(x); FreeInt(tmp2); } if (stepsize) { C_lol(tmp); C_zeq(l2); C_lol(tmp); c_loc(1); C_sbu(int_size); C_stl(tmp); C_loc(left->nd_INT); ForLoopVarExpr(nd); C_adu(int_size); RangeCheck(nd->nd_type, bstp); CodeDStore(nd); } } C_bra(l1); def_ilb(l2); FreeInt(tmp); #ifdef DEBUG nd->nd_left = left; nd->nd_right = right; #endif } break; case WITH: { t_scopelist link; struct withdesig wds; t_desig ds; if (! WalkDesignator(left, &ds, D_USED|D_DEFINED)) break; if (left->nd_type->tp_fund != T_RECORD) { node_error(left, "record variable expected"); break; } wds.w_next = WithDesigs; WithDesigs = &wds; wds.w_scope = left->nd_type->rec_scope; CodeAddress(&ds); ds.dsg_kind = DSG_FIXED; /* Create a designator structure for the temporary. */ ds.dsg_offset = NewPtr(); ds.dsg_name = 0; CodeStore(&ds, address_type); ds.dsg_kind = DSG_PFIXED; /* the record is indirectly available */ wds.w_desig = ds; link.sc_scope = wds.w_scope; link.sc_next = CurrVis; CurrVis = &link; WalkNode(right, exit_label); CurrVis = link.sc_next; WithDesigs = wds.w_next; FreePtr(ds.dsg_offset); break; } case EXIT: assert(exit_label != 0); C_bra(exit_label); break; case RETURN: if (right) { if (! ChkExpression(right)) break; /* The type of the return-expression must be assignment compatible with the result type of the function procedure (See Rep. 9.11). */ if (!ChkAssCompat(&(nd->nd_right), func_type, "RETURN")) { break; } right = nd->nd_right; if (right->nd_type->tp_fund == T_STRING) { CodePString(right, func_type); } else CodePExpr(right); } C_bra(RETURN_LABEL); break; default: crash("(WalkStat)"); } } extern int NodeCrash(); STATIC WalkOption(nd) t_node *nd; { /* Set option indicated by node "nd" */ options[nd->nd_symb] = nd->nd_INT; } int (*WalkTable[])() = { NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, NodeCrash, WalkStat, WalkLink, WalkOption }; ExpectBool(nd, true_label, false_label) register t_node *nd; label true_label, false_label; { /* "nd" must indicate a boolean expression. Check this and generate code to evaluate the expression. */ register t_desig *ds = new_desig(); if (ChkExpression(nd)) { if (nd->nd_type != bool_type && nd->nd_type != error_type) { node_error(nd, "boolean expression expected"); } CodeExpr(nd, ds, true_label, false_label); } free_desig(ds); } int WalkDesignator(nd, ds, flags) t_node *nd; t_desig *ds; { /* Check designator and generate code for it */ if (! ChkVariable(nd, flags)) return 0; clear((char *) ds, sizeof(t_desig)); CodeDesig(nd, ds); return 1; } DoForInit(nd) register t_node *nd; { register t_node *left = nd->nd_left; register t_def *df; t_type *tpl, *tpr; nd->nd_left = nd->nd_right = 0; nd->nd_class = Name; nd->nd_symb = IDENT; if (!( ChkVariable(nd, D_USED|D_DEFINED) & ChkExpression(left->nd_left) & ChkExpression(left->nd_right))) return 0; df = nd->nd_def; if (df->df_kind == D_FIELD) { node_error(nd, "FOR-loop variable may not be a field of a record"); return 1; } if (!df->var_name && df->var_off >= 0) { node_error(nd, "FOR-loop variable may not be a parameter"); return 1; } if (df->df_scope != CurrentScope) { register t_scopelist *sc = CurrVis; for (;;) { if (!sc) { node_error(nd, "FOR-loop variable may not be imported"); return 1; } if (sc->sc_scope == df->df_scope) break; sc = nextvisible(sc); } } if (df->df_type->tp_size > word_size || !(df->df_type->tp_fund & T_DISCRETE)) { node_error(nd, "illegal type of FOR loop variable"); return 1; } tpl = left->nd_left->nd_type; tpr = left->nd_right->nd_type; #ifndef STRICT_3RD_ED if (! options['3']) { if (!ChkAssCompat(&(left->nd_left), df->df_type, "FOR statement") || !ChkAssCompat(&(left->nd_right), BaseType(df->df_type), "FOR statement")) { return 1; } if (!TstCompat(df->df_type, tpl) || !TstCompat(df->df_type, tpr)) { node_warning(nd, W_OLDFASHIONED, "compatibility required in FOR statement"); } } else #endif if (!ChkCompat(&(left->nd_left), df->df_type, "FOR statement") || !ChkCompat(&(left->nd_right), BaseType(df->df_type), "FOR statement")) { return 1; } CodePExpr(left->nd_left); return 1; } DoAssign(left, right) register t_node *left; t_node *right; { /* May we do it in this order (expression first) ??? The reference manual sais nothing about it, but the book does: it sais that the left hand side is evaluated first. DAMN THE BOOK! */ register t_desig *dsr; register t_type *tp; if (! (ChkExpression(right) & ChkVariable(left, D_DEFINED))) return; tp = left->nd_type; if (right->nd_symb == STRING) TryToString(right, tp); if (! ChkAssCompat(&right, tp, "assignment")) { return; } dsr = new_desig(); #define StackNeededFor(ds) ((ds)->dsg_kind == DSG_PLOADED \ || (ds)->dsg_kind == DSG_INDEXED) CodeExpr(right, dsr, NO_LABEL, NO_LABEL); tp = right->nd_type; if (complex(tp)) { if (StackNeededFor(dsr)) CodeAddress(dsr); } else { CodeValue(dsr, tp); } CodeMove(dsr, left, tp); free_desig(dsr); } static int RegisterMessage(df) register t_def *df; { register t_type *tp; arith sz; int regtype; if (df->df_kind == D_VARIABLE) { if ( !(df->df_flags & D_NOREG)) { /* Examine type and size */ regtype = -1; tp = BaseType(df->df_type); if ((df->df_flags & D_VARPAR) || (tp->tp_fund&(T_POINTER|T_HIDDEN|T_EQUAL))) { sz = pointer_size; regtype = reg_pointer; } else if (tp->tp_fund & T_NUMERIC) { sz = tp->tp_size; regtype = tp->tp_fund == T_REAL ? reg_float : reg_any; } if (regtype >= 0) { C_ms_reg(df->var_off, sz, regtype, 0); } } } } static int UseWarnings(df) register t_def *df; { if (is_anon_idf(df->df_idf)) return; if (df->df_kind & (D_IMPORTED | D_VARIABLE | D_PROCEDURE | D_CONST | D_TYPE)) { struct node *nd; if (df->df_flags & (D_EXPORTED | D_QEXPORTED)) return; if (df->df_kind & D_IMPORTED) { register t_def *df1 = df->imp_def; df1->df_flags |= df->df_flags & (D_USED|D_DEFINED); if (df->df_kind == D_INUSE) return; if ( !(df->df_flags & D_IMP_BY_EXP)) { if (! (df->df_flags & (D_USED | D_DEFINED))) { node_warning( df->df_scope->sc_end, W_ORDINARY, "identifier \"%s\" imported but not %s", df->df_idf->id_text, df1->df_kind == D_VARIABLE ? "used/assigned" : "used"); } return; } df = df1; } if (! (df->df_kind & (D_VARIABLE|D_PROCEDURE|D_TYPE|D_CONST))) return; nd = df->df_scope->sc_end; if (! (df->df_flags & D_DEFINED)) { node_warning(nd, W_ORDINARY, "identifier \"%s\" never assigned", df->df_idf->id_text); } if (! (df->df_flags & D_USED)) { node_warning(nd, W_ORDINARY, "identifier \"%s\" never used", df->df_idf->id_text); } } } WalkDefList(df, proc) register t_def *df; int (*proc)(); { for (; df; df = df->df_nextinscope) { (*proc)(df); } }