472 lines
9.7 KiB
C
472 lines
9.7 KiB
C
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#include "symtab.h"
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#include "sizes.h"
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#include "expr.h"
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#include "Lpars.h"
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static void rvalue(), assignable(), inputable(), outputable(), subscriptable();
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static void assigned();
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/* The new_* functions make use of the used() and assinged() functions to
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* make known what is done to a variable.
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*/
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struct expr *new_node(op, left, right, byte)
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int op;
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register struct expr *left, *right;
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int byte;
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/* Makes a new node with given operator, left and right operand.
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* Constant folding is done if possible.
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*/
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{
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if (op!=FOR && constant(left) && (right==nil || constant(right))) {
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register long lc, rc;
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lc=left->u.const;
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rc=right->u.const;
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switch (op) {
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case '+': lc+=rc; break;
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case '-': lc-=rc; break;
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case '*': lc*=rc; break;
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case '/': if (rc==0L)
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report("division by zero");
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else
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lc/=rc;
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break;
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case BS: lc%=rc; break;
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case '<': lc= lc<rc ? -1L : 0L; break;
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case '>': lc= lc>rc ? -1L : 0L; break;
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case LE: lc= lc<=rc ? -1L : 0L; break;
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case GE: lc= lc>=rc ? -1L : 0L; break;
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case NE: lc= lc!=rc ? -1L : 0L; break;
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case '=': lc= lc==rc ? -1L : 0L; break;
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case AFTER: lc= (lc-rc)>0 ? -1L : 0L; break;
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case BA: lc&=rc; break;
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case BO: lc|=rc; break;
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case BX: lc^=rc; break;
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case AND: lc= lc&&rc ? -1L : 0L; break;
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case OR: lc= lc||rc ? -1L : 0L; break;
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case LS: lc<<=rc; break;
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case RS: lc>>=rc; break;
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case '~': lc= -lc; break;
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case NOT: lc= ~lc; break;
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default:
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report("illegal operator on constants");
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}
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destroy(right);
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left->u.const=lc;
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return left;
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} else {
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register struct expr *pe;
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int type=0, arr_siz=1;
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switch (op) {
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case '+': case '-': case '*': case '/':
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case BS: case '<': case '>': case LE:
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case GE: case NE: case '=': case AFTER:
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case BA: case BO: case BX: case AND:
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case OR: case LS: case RS:
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rvalue(left);
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rvalue(right);
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type=T_VALUE;
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break;
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case '~':
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case NOT:
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rvalue(left);
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type=T_VALUE;
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break;
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case AS:
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assignable(left, right);
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type=T_VOID;
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break;
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case '[':
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subscriptable(left, right, byte, &type, &arr_siz);
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break;
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}
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=E_NODE;
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pe->type=type;
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pe->arr_siz=arr_siz;
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pe->u.node.op=op;
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pe->u.node.left=left;
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pe->u.node.right=right;
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return pe;
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}
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}
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struct expr *new_var(var)
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register struct symbol *var;
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/* Given a variable an expression node is constructed. Note the changes in
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* type! T_VAR becomes T_VALUE with flag T_LVALUE.
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*/
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{
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register struct expr *pe;
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=E_VAR;
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if ((var->type&T_TYPE)==T_VAR || var->type&T_NOTDECL) {
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pe->type=(var->type&(~T_TYPE));
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pe->type|=T_VALUE|T_LVALUE;
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} else
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pe->type=var->type;
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pe->arr_siz=var->arr_siz;
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pe->u.var=var;
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return pe;
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}
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struct expr *new_const(const)
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long const;
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/* Make a constant, which is a VALUE, of course. */
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{
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register struct expr *pe;
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=E_CONST;
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pe->type=T_VALUE;
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pe->u.const=const;
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return pe;
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}
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struct expr *new_table(kind, tab)
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register kind;
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register struct table *tab;
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/* One table is being made, it is no doubt a VALUEd ARRay, but maybe even a
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* BYTE array. A label is reserved for it and the individual elements are
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* rommified.
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*/
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{
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register struct expr *pe;
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=kind;
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pe->type=T_VALUE|T_ARR;
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if (kind==E_BTAB) pe->type|=T_BYTE;
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dot_label(new_dot_label(&pe->u.tab));
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pe->arr_siz=0;
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while (tab!=nil) {
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register struct table *junk=tab;
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rom(kind==E_BTAB ? 1 : vz, tab->val);
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tab=tab->next;
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pe->arr_siz++;
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free(junk);
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}
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return pe;
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}
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struct expr *copy_const(e) struct expr *e;
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/* If you double it up, you've got one you can throw away. (Or do something
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* useful with).
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*/
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{
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register struct expr *c;
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c= (struct expr *) malloc(sizeof *c);
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*c= *e;
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return c;
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}
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struct expr *new_now()
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/* Now is the time to make a VALUE cell for the clock. */
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{
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register struct expr *pe;
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=E_NOW;
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pe->type=T_VALUE;
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return pe;
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}
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struct expr *new_io(out, chan, args)
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int out;
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register struct expr *chan;
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struct expr_list *args;
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/* Either c ? v0; v1; v2; ... (out=0) or c ! e0; e1; e2; ... (out=1). */
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{
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register struct expr *pe;
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if ( ( (chan->type&T_TYPE) != T_CHAN || (chan->type&T_ARR) )
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&& ! (chan->type&T_NOTDECL)
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)
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report("channel variable expected");
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used(chan);
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pe= (struct expr *) malloc(sizeof *pe);
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pe->kind=E_IO;
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pe->type=T_VOID;
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pe->u.io.out=out;
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pe->u.io.chan=chan;
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pe->u.io.args=args;
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return pe;
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}
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struct expr *new_call(proc, args)
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struct expr *proc;
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struct expr_list *args;
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/* Dial proc(arg1, arg2, ...) and you'll hear the tone of this function.
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* Dialing yourself is not allowed, but it will work if you ignore the
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* compiler generated noise.
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*/
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{
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register struct expr *pe;
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pe= (struct expr *) malloc(sizeof *pe);
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used(proc);
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check_recursion(proc);
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pe->kind=E_CALL;
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pe->type=T_VOID;
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pe->u.call.proc=proc;
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pe->u.call.args=args;
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return pe;
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}
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void table_add(aapt, val) register struct table ***aapt; long val;
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/* Adds a value to a table using a hook to a hook. */
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{
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register struct table *pt;
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pt= (struct table *) malloc(sizeof *pt);
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pt->val=val;
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pt->next= **aapt;
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**aapt=pt;
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*aapt= &pt->next;
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}
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void expr_list_add(aaelp, arg)
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register struct expr_list ***aaelp;
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struct expr *arg;
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/* Another add, this time for actual arguments and the like. */
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{
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register struct expr_list *elp;
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elp= (struct expr_list *) malloc(sizeof *elp);
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elp->arg=arg;
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elp->next= **aaelp;
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**aaelp=elp;
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*aaelp= &elp->next;
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}
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void check_io(out, arg) int out; struct expr *arg;
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{
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if (out)
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outputable(arg);
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else
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inputable(arg);
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}
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void check_wait(e) struct expr *e;
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{
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if ((e->type&T_TYPE)!=T_VALUE)
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report("WAIT process needs valued operand");
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}
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static void assigned(e) register struct expr *e;
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/* Tries to tell e that it is assigned to. */
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{
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if (e->kind==E_VAR || (e->kind==E_NODE && e->u.node.op=='['
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&& (e=e->u.node.left)->kind==E_VAR)
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) {
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register struct symbol *var;
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if ((var=e->u.var)->type&T_REP) {
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warning("replicator index %s may not be assigned",
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var->name);
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var->type&= ~T_REP;
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}
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var->type|=T_ASSIGNED;
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}
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}
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void used(e) register struct expr *e;
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{
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if (e->kind==E_VAR || (e->kind==E_NODE && e->u.node.op=='['
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&& (e=e->u.node.left)->kind==E_VAR)
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) {
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register struct symbol *var;
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if ( ! ( (var=e->u.var)->type&(T_ASSIGNED|T_BUILTIN))
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&& (var->type&T_TYPE)==T_VAR
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&& var->info.vc.st.level==curr_level)
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warning("%s used before assigned", var->name);
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var->type|=(T_USED|T_ASSIGNED);
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}
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}
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static void rvalue(e) register struct expr *e;
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{
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if ((e->type&T_TYPE)!=T_VALUE || e->type&T_ARR)
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report("illegal operand of arithmetic operator");
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used(e);
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}
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static void assignable(l, r) register struct expr *l, *r;
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/* See if l can be assigned r. */
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{
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if ( ! ( (l->type&T_LVALUE && (r->type&T_TYPE)==T_VALUE
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&& (l->type&T_ARR)==(r->type&T_ARR))
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|| (l->type|r->type)&T_NOTDECL
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))
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report("operands of assignment are not conformable");
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else
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if (l->type&T_ARR && ! ( (l->type|r->type)&T_NOTDECL ) ) {
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register lsiz=l->arr_siz, rsiz=r->arr_siz;
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if (lsiz!=0 && rsiz!=0 && lsiz!=rsiz)
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report("arrays have incompatible sizes");
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}
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used(r);
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assigned(l);
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}
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static void inputable(e) struct expr *e;
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{
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if ( ! (e->type&T_LVALUE) )
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report("operand of input process can't be assigned");
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assigned(e);
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}
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static void outputable(e) struct expr *e;
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{
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if ( ! ( (e->type&T_TYPE)==T_VALUE ) )
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report("operand of output process has no value");
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used(e);
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}
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static void subscriptable(l, r, byte, atype, arr_siz)
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register struct expr *l, *r;
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register byte;
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int *atype, *arr_siz;
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/* Tries to subscript l by r, returning type and array size for slices. */
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{
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register type= (l->type&T_TYPE)|byte;
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if ( !(l->type&(T_ARR|T_NOTDECL) ) )
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report("indexing on a non-array");
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else
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if ( ! ( (r->type&T_TYPE)==T_VALUE
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|| (r->kind==E_NODE && r->u.node.op==FOR)
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) )
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report("index is not computable");
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type|=(l->type&T_LVALUE);
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if (r->kind==E_NODE && r->u.node.op==FOR) {
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type|=T_ARR;
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if (r->u.node.right->kind!=E_CONST)
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report("slice must be of constant size");
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else
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*arr_siz=r->u.node.right->u.const;
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used(r->u.node.left);
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} else
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used(r);
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*atype=type;
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}
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void check_param(aform, act, err)
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struct par_list **aform;
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register struct expr *act;
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int *err;
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/* Test if formal parameter *aform corresponds with actual act. Err returns
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* error status. The aform hook is set to the next formal after the check.
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*/
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{
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register struct par_list *form= *aform;
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register struct expr *left;
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register struct symbol *var;
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static char NONCORR[]="actual and formal parameter don't correspond";
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if (form==nil) {
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if (! *err) {
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report("too many actual parameters");
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*err=1;
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}
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return;
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}
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if ((form->type&T_ARR)!=(act->type&T_ARR) && !(act->type&T_NOTDECL) ) {
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report(NONCORR);
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} else {
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switch (form->type&T_TYPE) {
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case T_VAR:
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if ( ! (
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(act->type&T_TYPE)==T_VALUE
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&& act->type&T_LVALUE
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&& !(act->type&T_BYTE)
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))
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report(NONCORR);
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assigned(act);
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used(act);
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break;
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case T_CHAN:
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if((act->type&T_TYPE)!=T_CHAN && !(act->type&T_NOTDECL))
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report(NONCORR);
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used(act);
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break;
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case T_VALUE:
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if ((act->type&T_TYPE)!=T_VALUE)
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report(NONCORR);
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used(act);
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break;
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}
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}
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*aform= form->next;
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}
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void destroy(e) register struct expr *e;
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/* Opposite of making. */
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{
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if (e!=nil) {
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switch (e->kind) {
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case E_NODE:
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destroy(e->u.node.left);
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destroy(e->u.node.right);
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break;
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case E_IO:
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case E_CALL:
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destroy(e->kind==E_IO ? e->u.io.chan : e->u.call.proc);
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{
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register struct expr_list *elp, *junk;
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elp= e->kind==E_IO ? e->u.io.args : e->u.call.args;
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||
|
|
||
|
while (elp!=nil) {
|
||
|
destroy(elp->arg);
|
||
|
junk=elp;
|
||
|
elp=elp->next;
|
||
|
free(junk);
|
||
|
}
|
||
|
}
|
||
|
break;
|
||
|
}
|
||
|
free(e);
|
||
|
}
|
||
|
}
|