Example #1
0
static void emit_stmt_stask(ivl_scope_t scope, ivl_statement_t stmt)
{
      unsigned count = ivl_stmt_parm_count(stmt);
      fprintf(vlog_out, "%*c%s", get_indent(), ' ', ivl_stmt_name(stmt));
      if (count != 0) {
	    unsigned idx;
	    fprintf(vlog_out, "(");
	    count -= 1;
	    for (idx = 0; idx < count; idx += 1) {
		  ivl_expr_t expr = ivl_stmt_parm(stmt, idx);
		  if (expr) emit_expr(scope, expr, 0);
		  fprintf(vlog_out, ", ");
	    }
	    emit_expr(scope, ivl_stmt_parm(stmt, count), 0);
	    fprintf(vlog_out, ")");
      }
      fprintf(vlog_out, ";");
      emit_stmt_file_line(stmt);
      fprintf(vlog_out, "\n");
}
Example #2
0
static void draw_vpi_taskfunc_args(const char*call_string,
				   ivl_statement_t tnet,
				   ivl_expr_t fnet)
{
      unsigned idx;
      unsigned parm_count = tnet
	    ? ivl_stmt_parm_count(tnet)
	    : ivl_expr_parms(fnet);

      struct args_info *args = calloc(parm_count, sizeof(struct args_info));

      char buffer[4096];

      ivl_parameter_t par;

	/* Figure out how many expressions are going to be evaluated
	   for this task call. I won't need to evaluate expressions
	   for items that are VPI objects directly. */
      for (idx = 0 ;  idx < parm_count ;  idx += 1) {
	    ivl_expr_t expr = tnet
		  ? ivl_stmt_parm(tnet, idx)
		  : ivl_expr_parm(fnet, idx);

	    switch (ivl_expr_type(expr)) {

		    /* These expression types can be handled directly,
		       with VPI handles of their own. Therefore, skip
		       them in the process of evaluating expressions. */
		case IVL_EX_NONE:
		  args[idx].text = strdup("\" \"");
		  continue;

		case IVL_EX_ARRAY:
		  snprintf(buffer, sizeof buffer,
			   "v%p", ivl_expr_signal(expr));
		  args[idx].text = strdup(buffer);
		  continue;

		case IVL_EX_NUMBER: {
		  if (( par = ivl_expr_parameter(expr) )) {
			snprintf(buffer, sizeof buffer, "P_%p", par);
		  } else {
			unsigned bit, wid = ivl_expr_width(expr);
			const char*bits = ivl_expr_bits(expr);
			char*dp;

			snprintf(buffer, sizeof buffer, "%u'%sb",
			         wid, ivl_expr_signed(expr)? "s" : "");
			dp = buffer + strlen(buffer);
			for (bit = wid ;  bit > 0 ;  bit -= 1)
			      *dp++ = bits[bit-1];
			*dp++ = 0;
			assert(dp >= buffer);
			assert((unsigned)(dp - buffer) <= sizeof buffer);
		  }
		  args[idx].text = strdup(buffer);
		  continue;
		}

		case IVL_EX_STRING:
		  if (( par = ivl_expr_parameter(expr) )) {
			snprintf(buffer, sizeof buffer, "P_%p", par);

		  } else {
			snprintf(buffer, sizeof buffer, "\"%s\"", ivl_expr_string(expr));
		  }
		  args[idx].text = strdup(buffer);
		  continue;

		case IVL_EX_REALNUM:
		  if (( par = ivl_expr_parameter(expr) )) {
			snprintf(buffer, sizeof buffer, "P_%p", par);
			args[idx].text = strdup(buffer);
			continue;
		  }
		  break;

		case IVL_EX_ENUMTYPE:
		  snprintf(buffer, sizeof buffer, "enum%p", ivl_expr_enumtype(expr));
		  args[idx].text = strdup(buffer);
		  continue;
		case IVL_EX_EVENT:
		  snprintf(buffer, sizeof buffer, "E_%p", ivl_expr_event(expr));
		  args[idx].text = strdup(buffer);
		  continue;
		case IVL_EX_SCOPE:
		  snprintf(buffer, sizeof buffer, "S_%p", ivl_expr_scope(expr));
		  args[idx].text = strdup(buffer);
		  continue;

		case IVL_EX_SFUNC:
		  if (is_magic_sfunc(ivl_expr_name(expr))) {
			snprintf(buffer, sizeof buffer, "%s", ivl_expr_name(expr));
			args[idx].text = strdup(buffer);
			continue;
		  }
		  break;

		case IVL_EX_SIGNAL:
		case IVL_EX_SELECT:
		  if (get_vpi_taskfunc_signal_arg(&args[idx], expr)) continue;
		  else break;

		    /* Everything else will need to be evaluated and
		       passed as a constant to the vpi task. */
		default:
		  break;
	    }

	    switch (ivl_expr_value(expr)) {
		case IVL_VT_LOGIC:
		case IVL_VT_BOOL:
		  args[idx].vec_flag = 1;
		  args[idx].vec = draw_eval_expr(expr, 0);
		  snprintf(buffer, sizeof buffer,
			   "T<%u,%u,%s>", args[idx].vec.base, args[idx].vec.wid,
			   ivl_expr_signed(expr)? "s" : "u");
		  break;
		case IVL_VT_REAL:
		  args[idx].vec_flag = 1;
		  args[idx].vec.base = draw_eval_real(expr);
		  args[idx].vec.wid  = 0;
		  snprintf(buffer, sizeof buffer,
		           "W<%u,r>", args[idx].vec.base);
		  break;
		case IVL_VT_STRING:
		    /* STRING expressions not supported yet. */
		default:
		  assert(0);
	    }
	    args[idx].text = strdup(buffer);
      }

      fprintf(vvp_out, "%s", call_string);

      for (idx = 0 ;  idx < parm_count ;  idx += 1) {
	    struct args_info*ptr;

	    fprintf(vvp_out, ", %s", args[idx].text);
	    free(args[idx].text);
	      /* Clear the nested children vectors. */
	    for (ptr = &args[idx]; ptr != NULL; ptr = ptr->child) {
		  if (ptr->vec_flag) {
			if (ptr->vec.wid > 0) clr_vector(ptr->vec);
			else clr_word(ptr->vec.base);
		  }
	    }
	      /* Free the nested children. */
	    ptr = args[idx].child;
	    while (ptr != NULL) {
		struct args_info*tptr = ptr;
		ptr = ptr->child;
		free(tptr);
	    }
      }

      free(args);

      fprintf(vvp_out, ";\n");
}
static void draw_vpi_taskfunc_args(const char*call_string,
				   ivl_statement_t tnet,
				   ivl_expr_t fnet)
{
      unsigned idx;
      unsigned parm_count = tnet
	    ? ivl_stmt_parm_count(tnet)
	    : ivl_expr_parms(fnet);
      struct vector_info *vec = 0x0;
      unsigned int vecs= 0;
      unsigned int veci= 0;

      ivl_parameter_t par;

	/* Figure out how many expressions are going to be evaluated
	   for this task call. I won't need to evaluate expressions
	   for items that are VPI objects directly. */
      for (idx = 0 ;  idx < parm_count ;  idx += 1) {
	    ivl_expr_t expr = tnet
		  ? ivl_stmt_parm(tnet, idx)
		  : ivl_expr_parm(fnet, idx);
	    
	    switch (ivl_expr_type(expr)) {

		    /* These expression types can be handled directly,
		       with VPI handles of their own. Therefore, skip
		       them in the process of evaluating expressions. */
		case IVL_EX_NONE:
		case IVL_EX_NUMBER:
		case IVL_EX_STRING:
		case IVL_EX_EVENT:
		case IVL_EX_SCOPE:
		case IVL_EX_VARIABLE:
		  continue;

		case IVL_EX_SFUNC:
		  if (is_magic_sfunc(ivl_expr_name(expr)))
			continue;

		  break;

		case IVL_EX_SIGNAL:
		    /* If the signal node is narrower then the signal
		       itself, then this is a part select so I'm going
		       to need to evaluate the expression.

		       Also, if the signedness of the expression is
		       different from the signedness of the
		       signal. This could be caused by a $signed or
		       $unsigned system function.

		       If I don't need to do any evaluating, then skip
		       it as I'll be passing the handle to the signal
		       itself. */
		  if (ivl_expr_width(expr) !=
		      ivl_signal_pins(ivl_expr_signal(expr))) {
			break;

		  } else if (ivl_expr_signed(expr) !=
			     ivl_signal_signed(ivl_expr_signal(expr))) {
			break;

		  } else {
			continue;
		  }


		case IVL_EX_MEMORY:
		  if (!ivl_expr_oper1(expr)) {
			continue;
		  }

		    /* Everything else will need to be evaluated and
		       passed as a constant to the vpi task. */
		default:
		  break;
	    }

	    vec = (struct vector_info *)
		  realloc(vec, (vecs+1)*sizeof(struct vector_info));

	    switch (ivl_expr_value(expr)) {
		case IVL_VT_VECTOR:
		  vec[vecs] = draw_eval_expr(expr, 0);
		  break;
		case IVL_VT_REAL:
		  vec[vecs].base = draw_eval_real(expr);
		  vec[vecs].wid = 0;
		  break;
		default:
		  assert(0);
	    }
	    vecs++;
      }

      fprintf(vvp_out, "%s", call_string);

      for (idx = 0 ;  idx < parm_count ;  idx += 1) {
	    ivl_expr_t expr = tnet
		  ? ivl_stmt_parm(tnet, idx)
		  : ivl_expr_parm(fnet, idx);
	    
	    switch (ivl_expr_type(expr)) {
		case IVL_EX_NONE:
		  fprintf(vvp_out, ", \" \"");
		  continue;

		case IVL_EX_NUMBER: {
		      unsigned bit, wid = ivl_expr_width(expr);
		      const char*bits = ivl_expr_bits(expr);

		      fprintf(vvp_out, ", %u'%sb", wid,
			      ivl_expr_signed(expr)? "s" : "");
		      for (bit = wid ;  bit > 0 ;  bit -= 1)
			    fputc(bits[bit-1], vvp_out);
		      continue;
		}

		case IVL_EX_SIGNAL:
		    /* If this is a part select, then the value was
		       calculated above. Otherwise, just pass the
		       signal. */
		  if (ivl_expr_width(expr) !=
		      ivl_signal_pins(ivl_expr_signal(expr))) {
			break;

		  } else if (ivl_expr_signed(expr) !=
			     ivl_signal_signed(ivl_expr_signal(expr))) {
			break;

		  } else {
			fprintf(vvp_out, ", V_%s", 
				vvp_signal_label(ivl_expr_signal(expr)));
			continue;
		  }

		case IVL_EX_VARIABLE: {
		      ivl_variable_t var = ivl_expr_variable(expr);
		      fprintf(vvp_out, ", W_%s", vvp_word_label(var));
		      continue;
		}

		case IVL_EX_STRING:
		  if (( par = ivl_expr_parameter(expr) )) {
			fprintf(vvp_out, ", P_%p", par);

		  } else {
			fprintf(vvp_out, ", \"%s\"", 
				ivl_expr_string(expr));
		  }
		  continue;

		case IVL_EX_EVENT:
		  fprintf(vvp_out, ", E_%p", ivl_expr_event(expr));
		  continue;

		case IVL_EX_SCOPE:
		  fprintf(vvp_out, ", S_%p", ivl_expr_scope(expr));
		  continue;

		case IVL_EX_SFUNC:
		  if (is_magic_sfunc(ivl_expr_name(expr))) {
			fprintf(vvp_out, ", %s", ivl_expr_name(expr));
			continue;
		  }
		  break;
		  
		case IVL_EX_MEMORY:
		  if (!ivl_expr_oper1(expr)) {
			fprintf(vvp_out, ", M_%s", 
				vvp_memory_label(ivl_expr_memory(expr)));
			continue;
		  }
		  break;

		default:
		  break;
	    }
	    assert(veci < vecs);

	    switch (ivl_expr_value(expr)) {

		case IVL_VT_VECTOR:
		  fprintf(vvp_out, ", T<%u,%u,%s>", vec[veci].base,
			  vec[veci].wid, ivl_expr_signed(expr)? "s" : "u");
		  break;

		case IVL_VT_REAL:
		  fprintf(vvp_out, ", W<%u,r>", vec[veci].base);
		  break;

		default:
		  assert(0);
	    }
	    veci++;
      }
      
      assert(veci == vecs);

      if (vecs) {
	    for (idx = 0; idx < vecs; idx++) {
		  if (vec[idx].wid > 0)
			clr_vector(vec[idx]);
		  else if (vec[idx].wid == 0)
			clr_word(vec[idx].base);
	    }
	    free(vec);
      }

      fprintf(vvp_out, ";\n");
}
Example #4
0
static void show_statement(ivl_statement_t net, unsigned ind)
{
      const ivl_statement_type_t code = ivl_statement_type(net);

      switch (code) {
	  case IVL_ST_ASSIGN:
	    fprintf(out, "%*s", ind, "");
	    show_assign_lvals(net);
	    fprintf(out, " = ");
	    show_expression(ivl_stmt_rval(net));
	    fprintf(out, ";\n");
	    break;

	  case IVL_ST_BLOCK: {
		unsigned cnt = ivl_stmt_block_count(net);
		unsigned idx;
		fprintf(out, "%*sbegin\n", ind, "");
		for (idx = 0 ;  idx < cnt ;  idx += 1) {
		      ivl_statement_t cur = ivl_stmt_block_stmt(net, idx);
		      show_statement(cur, ind+4);
		}
		fprintf(out, "%*send\n", ind, "");
		break;
	  }

	  case IVL_ST_CONDIT: {
		ivl_statement_t t = ivl_stmt_cond_true(net);
		ivl_statement_t f = ivl_stmt_cond_false(net);

		fprintf(out, "%*sif (", ind, "");
		show_expression(ivl_stmt_cond_expr(net));
		fprintf(out, ")\n");

		if (t)
		      show_statement(t, ind+4);
		else
		      fprintf(out, "%*s;\n", ind+4, "");

		if (f) {
		      fprintf(out, "%*selse\n", ind, "");
		      show_statement(f, ind+4);
		}

		break;
	  }

	  case IVL_ST_DELAY:
	    fprintf(out, "%*s#%lu\n", ind, "", ivl_stmt_delay_val(net));
	    show_statement(ivl_stmt_sub_stmt(net), ind+2);
	    break;

	  case IVL_ST_NOOP:
	    fprintf(out, "%*s/* noop */;\n", ind, "");
	    break;

	  case IVL_ST_STASK:
	    if (ivl_stmt_parm_count(net) == 0) {
		  fprintf(out, "%*s%s;\n", ind, "", ivl_stmt_name(net));

	    } else {
		  unsigned idx;
		  fprintf(out, "%*s%s(", ind, "", ivl_stmt_name(net));
		  show_expression(ivl_stmt_parm(net, 0));
		  for (idx = 1 ;  idx < ivl_stmt_parm_count(net) ; idx += 1) {
			fprintf(out, ", ");
			show_expression(ivl_stmt_parm(net, idx));
		  }
		  fprintf(out, ");\n");
	    }
	    break;

	  case IVL_ST_WAIT:
	    fprintf(out, "%*s@(...)\n", ind, "");
	    show_statement(ivl_stmt_sub_stmt(net), ind+2);
	    break;

	  case IVL_ST_WHILE:
	    fprintf(out, "%*swhile (<?>)\n", ind, "");
	    show_statement(ivl_stmt_sub_stmt(net), ind+2);
	    break;

	  default:
	    fprintf(out, "%*sunknown statement type (%d)\n", ind, "", code);
      }
}