/* * (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands. * See the copyright notice in the ACK home directory, in the file "Copyright". */ /* $Header$ */ /* S W I T C H - S T A T E M E N T A D M I N I S T R A T I O N */ #include "lint.h" #ifndef LINT #include #else #include "l_em.h" #endif LINT #include "debug.h" #include "botch_free.h" #include #include "density.h" #include "Lpars.h" #include "idf.h" #include "label.h" #include #include "arith.h" #include "switch.h" #include "code.h" #include "assert.h" #include "expr.h" #include "type.h" #include "sizes.h" extern char options[]; int density = DENSITY; compact(nr, low, up) arith low, up; { /* Careful! up - low might not fit in an arith. And then, the test "up-low < 0" might also not work to detect this situation! Or is this just a bug in the M68020/M68000? */ arith diff = up - low; return (nr == 0 || (diff >= 0 && diff / nr <= (density - 1))); } static struct switch_hdr *switch_stack = 0; /* (EB 86.05.20) The following rules hold for switch statements: - the expression E in "switch(E)" shall have integral type (3.6.4.2) - the expression E in "case E:" is converted to the promoted type of the controlling expression For simplicity, we suppose int_size == word_size. */ code_startswitch(expp) struct expr **expp; { /* Check the expression, stack a new case header and fill in the necessary fields. */ register label l_table = text_label(); register label l_break = text_label(); register struct switch_hdr *sh = new_switch_hdr(); int fund = any2arith(expp, SWITCH); /* INT, LONG, FLOAT, DOUBLE or LNGDBL */ switch (fund) { case FLOAT: case DOUBLE: case LNGDBL: error("floating point type in switch"); erroneous2int(expp); break; } stack_stmt(l_break, NO_LABEL); sh->sh_break = l_break; /* sh->sh_default = 0; */ sh->sh_table = l_table; /* sh->sh_nrofentries = 0; */ sh->sh_type = (*expp)->ex_type; /* the expression switched */ /* sh->sh_entries = (struct case_entry *) 0; /* case-entry list */ sh->sh_expr = *expp; #ifdef LINT code_expr(sh->sh_expr, RVAL, TRUE, NO_LABEL, NO_LABEL); #endif sh->next = switch_stack; /* push onto switch-stack */ switch_stack = sh; C_bra(l_table); /* goto start of switch_table */ } extern char *long2str(); code_endswitch() { register struct switch_hdr *sh = switch_stack; register label tablabel; register struct case_entry *ce; arith size = sh->sh_type->tp_size; if (sh->sh_default == 0) /* no default occurred yet */ sh->sh_default = sh->sh_break; #ifndef LINT C_bra(sh->sh_break); /* skip the switch table now */ C_df_ilb(sh->sh_table); /* switch table entry */ /* evaluate the switch expr. */ code_expr(sh->sh_expr, RVAL, TRUE, NO_LABEL, NO_LABEL); if (sh->sh_nrofentries <= 1) { if (sh->sh_nrofentries) { load_cst(sh->sh_lowerbd, size); C_cms(size); C_zeq(sh->sh_entries->ce_label); } else C_asp(size); C_bra(sh->sh_default); } else { tablabel = data_label(); /* the rom must have a label */ C_df_dlb(tablabel); C_rom_ilb(sh->sh_default); if (compact(sh->sh_nrofentries, sh->sh_lowerbd, sh->sh_upperbd)) { /* CSA */ register arith val; C_rom_icon(long2str((long)sh->sh_lowerbd,10), size); C_rom_icon(long2str((long)(sh->sh_upperbd - sh->sh_lowerbd),10), size); ce = sh->sh_entries; for (val = sh->sh_lowerbd; val <= sh->sh_upperbd; val++) { ASSERT(ce); if (val == ce->ce_value) { C_rom_ilb(ce->ce_label); ce = ce->next; } else C_rom_ilb(sh->sh_default); } C_lae_dlb(tablabel, (arith)0); /* perform the switch */ C_csa(size); } else { /* CSB */ C_rom_icon(long2str((long)sh->sh_nrofentries,10),size); for (ce = sh->sh_entries; ce; ce = ce->next) { /* generate the entries: value + prog.label */ C_rom_icon(long2str((long)ce->ce_value,10),size); C_rom_ilb(ce->ce_label); } C_lae_dlb(tablabel, (arith)0); /* perform the switch */ C_csb(size); } } C_df_ilb(sh->sh_break); #endif switch_stack = sh->next; /* unstack the switch descriptor */ for (ce = sh->sh_entries; ce;) { /* free allocated switch structure */ register struct case_entry *tmp = ce->next; free_case_entry(ce); ce = tmp; } free_switch_hdr(sh); unstack_stmt(); } code_case(expr) struct expr *expr; { register arith val; register struct case_entry *ce; register struct switch_hdr *sh = switch_stack; ASSERT(is_cp_cst(expr)); if (sh == 0) { error("case statement not in switch"); return; } if (expr->ex_flags & EX_ERROR) /* is probably 0 anyway */ return; ch3cast(&expr, CASE, sh->sh_type); ce = new_case_entry(); C_df_ilb(ce->ce_label = text_label()); ce->ce_value = val = expr->VL_VALUE; if (sh->sh_entries == 0) { /* first case entry */ /* ce->next = (struct case_entry *) 0; */ sh->sh_entries = ce; sh->sh_lowerbd = sh->sh_upperbd = val; sh->sh_nrofentries = 1; } else { /* second etc. case entry; put ce into proper place */ register struct case_entry *c1 = sh->sh_entries, *c2 = 0; if (val < sh->sh_lowerbd) sh->sh_lowerbd = val; else if (val > sh->sh_upperbd) sh->sh_upperbd = val; while (c1 && c1->ce_value < ce->ce_value) { c2 = c1; c1 = c1->next; } /* At this point three cases are possible: 1: c1 != 0 && c2 != 0: insert ce somewhere in the middle 2: c1 != 0 && c2 == 0: insert ce right after the head 3: c1 == 0 && c2 != 0: append ce to last element The case c1 == 0 && c2 == 0 cannot occur, since the list is guaranteed to be non-empty. */ if (c1) { if (c1->ce_value == ce->ce_value) { error("multiple case entry for value %ld", ce->ce_value); free_case_entry(ce); return; } if (c2) { ce->next = c2->next; c2->next = ce; } else { ce->next = sh->sh_entries; sh->sh_entries = ce; } } else { ASSERT(c2); ce->next = (struct case_entry *) 0; c2->next = ce; } (sh->sh_nrofentries)++; } } code_default() { register struct switch_hdr *sh = switch_stack; if (sh == 0) { error("default statement not in switch"); return; } if (sh->sh_default != 0) { error("multiple entry for default in switch"); return; } C_df_ilb(sh->sh_default = text_label()); }