Beispiel #1
0
static void string_ex_concat(ivl_expr_t expr)
{
      unsigned repeat;

      assert(ivl_expr_parms(expr) != 0);
      assert(ivl_expr_repeat(expr) != 0);

	/* Push the first string onto the stack, no matter what. */
      draw_eval_string(ivl_expr_parm(expr,0));

      for (repeat = 0 ; repeat < ivl_expr_repeat(expr) ; repeat += 1) {
	    unsigned idx;
	    for (idx = (repeat==0)? 1 : 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
		  ivl_expr_t sub = ivl_expr_parm(expr,idx);

		    /* Special case: If operand is a string literal,
		       then concat it using the %concati/str
		       instruction. */
		  if (ivl_expr_type(sub) == IVL_EX_STRING) {
			fprintf(vvp_out, "    %%concati/str \"%s\";\n",
				ivl_expr_string(sub));
			continue;
		  }

		  draw_eval_string(sub);
		  fprintf(vvp_out, "    %%concat/str;\n");
	    }
      }
}
Beispiel #2
0
static int show_stmt_assign_sig_darray(ivl_statement_t net)
{
      int errors = 0;
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);
      ivl_expr_t part = ivl_lval_part_off(lval);
      ivl_signal_t var= ivl_lval_sig(lval);
      ivl_type_t var_type= ivl_signal_net_type(var);
      assert(ivl_type_base(var_type) == IVL_VT_DARRAY);
      ivl_type_t element_type = ivl_type_element(var_type);

      ivl_expr_t mux  = ivl_lval_idx(lval);

      assert(ivl_stmt_lvals(net) == 1);
      assert(ivl_stmt_opcode(net) == 0);
      assert(ivl_lval_mux(lval) == 0);
      assert(part == 0);

      if (mux && (ivl_type_base(element_type)==IVL_VT_REAL)) {
	    draw_eval_real(rval);

	      /* The %set/dar expects the array index to be in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%store/dar/r v%p_0;\n", var);

      } else if (mux && ivl_type_base(element_type)==IVL_VT_STRING) {

	      /* Evaluate the rval into the top of the string stack. */
	    draw_eval_string(rval);

	      /* The %store/dar/s expects the array index to me in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%store/dar/str v%p_0;\n", var);

      } else if (mux) {
	    struct vector_info rvec = draw_eval_expr_wid(rval, ivl_lval_width(lval),
							 STUFF_OK_XZ);
	      /* The %set/dar expects the array index to be in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%set/dar v%p_0, %u, %u;\n",
		    var, rvec.base, rvec.wid);

	    if (rvec.base >= 4) clr_vector(rvec);

      } else {
	      /* There is no l-value mux, so this must be an
		 assignment to the array as a whole. Evaluate the
		 "object", and store the evaluated result. */
	    errors += draw_eval_object(rval);
	    fprintf(vvp_out, "    %%store/obj v%p_0;\n", var);
      }

      return errors;
}
Beispiel #3
0
static void draw_eval_function_argument(ivl_signal_t port, ivl_expr_t expr)
{
    ivl_variable_type_t dtype = ivl_signal_data_type(port);
    switch (dtype) {
    case IVL_VT_BOOL:
    /* For now, treat bit2 variables as bit4 variables. */
    case IVL_VT_LOGIC:
        function_argument_logic(port, expr);
        break;
    case IVL_VT_REAL:
        function_argument_real(port, expr);
        break;
    case IVL_VT_CLASS:
        vvp_errors += draw_eval_object(expr);
        break;
    case IVL_VT_STRING:
        draw_eval_string(expr);
        break;
    case IVL_VT_DARRAY:
        vvp_errors += draw_eval_object(expr);
        break;
    default:
        fprintf(stderr, "XXXX function argument %s type=%d?!\n",
                ivl_signal_basename(port), dtype);
        assert(0);
    }
}
Beispiel #4
0
static int show_stmt_assign_sig_string(ivl_statement_t net)
{
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);
      ivl_expr_t part = ivl_lval_part_off(lval);
      ivl_expr_t aidx = ivl_lval_idx(lval);
      ivl_signal_t var= ivl_lval_sig(lval);

      assert(ivl_stmt_lvals(net) == 1);
      assert(ivl_stmt_opcode(net) == 0);
      assert(ivl_lval_mux(lval) == 0);

	/* Simplest case: no mux. Evaluate the r-value as a string and
	   store the result into the variable. Note that the
	   %store/str opcode pops the string result. */
      if (part == 0 && aidx == 0) {
	    draw_eval_string(rval);
	    fprintf(vvp_out, "    %%store/str v%p_0;\n", var);
	    return 0;
      }

	/* Assign to array. The l-value has an index expression
	   expression so we are assigning to an array word. */
      if (aidx != 0) {
	    unsigned ix;
	    assert(part == 0);
	    draw_eval_string(rval);
	    draw_eval_expr_into_integer(aidx, (ix = allocate_word()));
	    fprintf(vvp_out, "    %%store/stra v%p, %u;\n", var, ix);
	    clr_word(ix);
	    return 0;
      }

	/* Calculate the character select for the word. */
      int mux_word = allocate_word();
      draw_eval_expr_into_integer(part, mux_word);

	/* Evaluate the r-value as a vector. */
      struct vector_info rvec = draw_eval_expr_wid(rval, 8, STUFF_OK_XZ);

      assert(rvec.wid == 8);
      fprintf(vvp_out, "    %%putc/str/v v%p_0, %d, %u;\n", var, mux_word, rvec.base);

      clr_vector(rvec);
      clr_word(mux_word);
      return 0;
}
Beispiel #5
0
static void draw_binary_vec4_compare_string(ivl_expr_t expr)
{
      draw_eval_string(ivl_expr_oper1(expr));
      draw_eval_string(ivl_expr_oper2(expr));

      switch (ivl_expr_opcode(expr)) {
	  case 'e': /* == */
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 4;\n");
	    break;
	  case 'n': /* != */
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_inv 4;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 4;\n");
	    break;
	  default:
	    assert(0);
      }
}
Beispiel #6
0
static void draw_select_vec4(ivl_expr_t expr)
{
	// This is the sub-expression to part-select.
      ivl_expr_t subexpr = ivl_expr_oper1(expr);
	// This is the base of the part select
      ivl_expr_t base = ivl_expr_oper2(expr);
	// This is the part select width
      unsigned wid = ivl_expr_width(expr);
	// Is the select base expression signed or unsigned?
      char sign_suff = ivl_expr_signed(base)? 's' : 'u';

	// Special Case: If the sub-expression is a STRING, then this
	// is a select from that string.
      if (ivl_expr_value(subexpr)==IVL_VT_STRING) {
	    assert(base);
	    assert(wid==8);
	    draw_eval_string(subexpr);
	    int base_idx = allocate_word();
	    draw_eval_expr_into_integer(base, base_idx);
	    fprintf(vvp_out, "    %%substr/vec4 %d, %u;\n", base_idx, wid);
	    fprintf(vvp_out, "    %%pop/str 1;\n");
	    clr_word(base_idx);
	    return;
      }

      if (ivl_expr_value(subexpr)==IVL_VT_DARRAY) {
	    ivl_signal_t sig = ivl_expr_signal(subexpr);
	    assert(sig);
	    assert( (ivl_signal_data_type(sig)==IVL_VT_DARRAY)
		    || (ivl_signal_data_type(sig)==IVL_VT_QUEUE) );

	    assert(base);
	    draw_eval_expr_into_integer(base, 3);
	    fprintf(vvp_out, "    %%load/dar/vec4 v%p_0;\n", sig);

	    return;
      }

      if (test_immediate_vec4_ok(base)) {
	    unsigned long val0, valx;
	    unsigned base_wid;
	    make_immediate_vec4_words(base, &val0, &valx, &base_wid);
	    assert(valx == 0);

	    draw_eval_vec4(subexpr);
	    fprintf(vvp_out, "    %%parti/%c %u, %lu, %u;\n",
		    sign_suff, wid, val0, base_wid);

      } else {
	    draw_eval_vec4(subexpr);
	    draw_eval_vec4(base);
	    fprintf(vvp_out, "    %%part/%c %u;\n", sign_suff, wid);
      }
}
Beispiel #7
0
/*
 * This function handles the special case that we assign an array
 * pattern to a dynamic array. Handle this by assigning each
 * element. The array pattern will have a fixed size.
 */
static int show_stmt_assign_darray_pattern(ivl_statement_t net)
{
      int errors = 0;
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);

      ivl_signal_t var= ivl_lval_sig(lval);
      ivl_type_t var_type= ivl_signal_net_type(var);
      assert(ivl_type_base(var_type) == IVL_VT_DARRAY);

      ivl_type_t element_type = ivl_type_element(var_type);
      unsigned idx;
#if 0
      unsigned element_width = 1;
      if (ivl_type_base(element_type) == IVL_VT_BOOL)
	    element_width = width_of_packed_type(element_type);
      else if (ivl_type_base(element_type) == IVL_VT_LOGIC)
	    element_width = width_of_packed_type(element_type);
#endif
      assert(ivl_expr_type(rval) == IVL_EX_ARRAY_PATTERN);
      for (idx = 0 ; idx < ivl_expr_parms(rval) ; idx += 1) {
	    switch (ivl_type_base(element_type)) {
		case IVL_VT_BOOL:
		case IVL_VT_LOGIC:
		  draw_eval_vec4(ivl_expr_parm(rval,idx));
		  fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
		  fprintf(vvp_out, "    %%store/dar/vec4 v%p_0;\n", var);
		  break;

		case IVL_VT_REAL:
		  draw_eval_real(ivl_expr_parm(rval,idx));
		  fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
		  fprintf(vvp_out, "    %%store/dar/r v%p_0;\n", var);
		  break;

		case IVL_VT_STRING:
		  draw_eval_string(ivl_expr_parm(rval,idx));
		  fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
		  fprintf(vvp_out, "    %%store/dar/str v%p_0;\n", var);
		  break;

		default:
		  fprintf(vvp_out, "; ERROR: show_stmt_assign_darray_pattern: type_base=%d not implemented\n", ivl_type_base(element_type));
		  errors += 1;
		  break;
	    }
      }

      return errors;
}
Beispiel #8
0
static void draw_binary_vec4_le_string(ivl_expr_t expr)
{
      ivl_expr_t le = ivl_expr_oper1(expr);
      ivl_expr_t re = ivl_expr_oper2(expr);

      switch (ivl_expr_opcode(expr)) {
	  case '<':
	    draw_eval_string(le);
	    draw_eval_string(re);
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 5;\n");
	    break;

	  case 'L': /* <= */
	    draw_eval_string(le);
	    draw_eval_string(re);
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 4;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 5;\n");
	    fprintf(vvp_out, "    %%or;\n");
	    break;

	  case '>':
	    draw_eval_string(re);
	    draw_eval_string(le);
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 5;\n");
	    break;

	  case 'G': /* >= */
	    draw_eval_string(re);
	    draw_eval_string(le);
	    fprintf(vvp_out, "    %%cmp/str;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 4;\n");
	    fprintf(vvp_out, "    %%flag_get/vec4 5;\n");
	    fprintf(vvp_out, "    %%or;\n");
	    break;

	  default:
	    assert(0);
	    break;
      }
}
Beispiel #9
0
static void string_ex_substr(ivl_expr_t expr)
{
      ivl_expr_t arg;
      unsigned arg1;
      unsigned arg2;
      assert(ivl_expr_parms(expr) == 3);

      arg = ivl_expr_parm(expr,0);
      draw_eval_string(arg);

	/* Evaluate the arguments... */
      arg = ivl_expr_parm(expr, 1);
      arg1 = allocate_word();
      draw_eval_expr_into_integer(arg, arg1);

      arg = ivl_expr_parm(expr, 2);
      arg2 = allocate_word();
      draw_eval_expr_into_integer(arg, arg2);

      fprintf(vvp_out, "    %%substr %u, %u;\n", arg1, arg2);
      clr_word(arg1);
      clr_word(arg2);
}
Beispiel #10
0
static int show_stmt_assign_sig_cobject(ivl_statement_t net)
{
      int errors = 0;
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);
      ivl_signal_t sig= ivl_lval_sig(lval);

      int prop_idx = ivl_lval_property_idx(lval);

      if (prop_idx >= 0) {
	    ivl_type_t sig_type = ivl_signal_net_type(sig);
	    ivl_type_t prop_type = ivl_type_prop_type(sig_type, prop_idx);

	    if (ivl_type_base(prop_type) == IVL_VT_BOOL) {
		  assert(ivl_type_packed_dimensions(prop_type) == 1);
		  assert(ivl_type_packed_msb(prop_type,0) >= ivl_type_packed_lsb(prop_type, 0));
		  int wid = ivl_type_packed_msb(prop_type,0) - ivl_type_packed_lsb(prop_type,0) + 1;

		  struct vector_info val = draw_eval_expr_wid(rval, wid, STUFF_OK_XZ);

		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/v %d, %u, %u; Store in bool property %s\n",
			  prop_idx, val.base, val.wid,
			  ivl_type_prop_name(sig_type, prop_idx));
		  fprintf(vvp_out, "    %%pop/obj 1;\n");
		  clr_vector(val);

	    } else if (ivl_type_base(prop_type) == IVL_VT_LOGIC) {
		  assert(ivl_type_packed_dimensions(prop_type) == 1);
		  assert(ivl_type_packed_msb(prop_type,0) >= ivl_type_packed_lsb(prop_type, 0));
		  int wid = ivl_type_packed_msb(prop_type,0) - ivl_type_packed_lsb(prop_type,0) + 1;

		  struct vector_info val = draw_eval_expr_wid(rval, wid, STUFF_OK_XZ);

		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/v %d, %u, %u; Store in logic property %s\n",
			  prop_idx, val.base, val.wid,
			  ivl_type_prop_name(sig_type, prop_idx));
		  fprintf(vvp_out, "    %%pop/obj 1;\n");
		  clr_vector(val);

	    } else if (ivl_type_base(prop_type) == IVL_VT_REAL) {

		    /* Calculate the real value into the real value
		       stack. The %store/prop/r will pop the stack
		       value. */
		  draw_eval_real(rval);
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/r %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_STRING) {

		    /* Calculate the string value into the string value
		       stack. The %store/prop/r will pop the stack
		       value. */
		  draw_eval_string(rval);
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/str %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_DARRAY) {

		    /* The property is a darray, and there is no mux
		       expression to the assignment is of an entire
		       array object. */
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  draw_eval_object(rval);
		  fprintf(vvp_out, "    %%store/prop/obj %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_CLASS) {

		    /* The property is a class object. */
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  draw_eval_object(rval);
		  fprintf(vvp_out, "    %%store/prop/obj %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1;\n");

	    } else {
		  fprintf(vvp_out, " ; ERROR: ivl_type_base(prop_type) = %d\n",
			  ivl_type_base(prop_type));
		  assert(0);
	    }

      } else {
	      /* There is no property select, so evaluate the r-value
		 as an object and assign the entire object to the
		 variable. */
	    errors += draw_eval_object(rval);
	    fprintf(vvp_out, "    %%store/obj v%p_0;\n", sig);
      }

      return errors;
}
Beispiel #11
0
static int eval_darray_new(ivl_expr_t ex)
{
      int errors = 0;
      unsigned size_reg = allocate_word();
      ivl_expr_t size_expr = ivl_expr_oper1(ex);
      ivl_expr_t init_expr = ivl_expr_oper2(ex);
      draw_eval_expr_into_integer(size_expr, size_reg);

	// The new function has a net_type that contains the details
	// of the type.
      ivl_type_t net_type = ivl_expr_net_type(ex);
      assert(net_type);

      ivl_type_t element_type = ivl_type_element(net_type);
      assert(element_type);

      switch (ivl_type_base(element_type)) {
	    int msb, lsb, wid;
	  case IVL_VT_REAL:
	      // REAL objects are not packable.
	    assert(ivl_type_packed_dimensions(element_type) == 0);
	    fprintf(vvp_out, "    %%new/darray %u, \"r\";\n", size_reg);
	    break;
	  case IVL_VT_STRING:
	      // STRING objects are not packable.
	    assert(ivl_type_packed_dimensions(element_type) == 0);
	    fprintf(vvp_out, "    %%new/darray %u, \"S\";\n", size_reg);
	    break;
	  case IVL_VT_BOOL:
	      // bool objects are vectorable, but for now only support
	      // a single dimensions.
	    assert(ivl_type_packed_dimensions(element_type) == 1);
	    msb = ivl_type_packed_msb(element_type, 0);
	    lsb = ivl_type_packed_lsb(element_type, 0);
	    wid = msb>=lsb? msb - lsb : lsb - msb;
	    wid += 1;
	    fprintf(vvp_out, "    %%new/darray %u, \"%sb%d\";\n", size_reg,
	                     ivl_type_signed(element_type) ? "s" : "", wid);
	    break;
	  case IVL_VT_LOGIC:
	      // logic objects are vectorable, but for now only support
	      // a single dimensions.
	    assert(ivl_type_packed_dimensions(element_type) == 1);
	    msb = ivl_type_packed_msb(element_type, 0);
	    lsb = ivl_type_packed_lsb(element_type, 0);
	    wid = msb>=lsb? msb - lsb : lsb - msb;
	    wid += 1;
	    fprintf(vvp_out, "    %%new/darray %u, \"%sv%d\";\n", size_reg,
	                     ivl_type_signed(element_type) ? "s" : "", wid);
	    break;

	  default:
	    assert(0);
	    break;
      }
      clr_word(size_reg);

      if (init_expr && ivl_expr_type(init_expr)==IVL_EX_ARRAY_PATTERN) {
	    unsigned idx;
	    switch (ivl_type_base(element_type)) {
		case IVL_VT_BOOL:
		case IVL_VT_LOGIC:
		  for (idx = 0 ; idx < ivl_expr_parms(init_expr) ; idx += 1) {
			draw_eval_vec4(ivl_expr_parm(init_expr,idx));
			fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
			fprintf(vvp_out, "    %%set/dar/obj/vec4 3;\n");
			fprintf(vvp_out, "    %%pop/vec4 1;\n");
		  }
		  break;
		case IVL_VT_REAL:
		  for (idx = 0 ; idx < ivl_expr_parms(init_expr) ; idx += 1) {
			draw_eval_real(ivl_expr_parm(init_expr,idx));
			fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
			fprintf(vvp_out, "    %%set/dar/obj/real 3;\n");
			fprintf(vvp_out, "    %%pop/real 1;\n");
		  }
		  break;
		case IVL_VT_STRING:
		  for (idx = 0 ; idx < ivl_expr_parms(init_expr) ; idx += 1) {
			draw_eval_string(ivl_expr_parm(init_expr,idx));
			fprintf(vvp_out, "    %%ix/load 3, %u, 0;\n", idx);
			fprintf(vvp_out, "    %%set/dar/obj/str 3;\n");
			fprintf(vvp_out, "    %%pop/str 1;\n");
		  }
		  break;
		default:
		  fprintf(vvp_out, "; ERROR: Sorry, this type not supported here.\n");
		  errors += 1;
		  break;
	    }
      } else if (init_expr && (ivl_expr_value(init_expr) == IVL_VT_DARRAY)) {
		  ivl_signal_t sig = ivl_expr_signal(init_expr);
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%scopy;\n");

      } else if (init_expr && number_is_immediate(size_expr,32,0)) {
	      /* In this case, there is an init expression, the
		 expression is NOT an array_pattern, and the size
		 expression used to calculate the size of the array is
		 a constant. Generate an unrolled set of assignments. */
	    long idx;
	    long cnt = get_number_immediate(size_expr);
	    unsigned wid;
	    switch (ivl_type_base(element_type)) {
		case IVL_VT_BOOL:
		case IVL_VT_LOGIC:
		  wid = width_of_packed_type(element_type);
		  for (idx = 0 ; idx < cnt ; idx += 1) {
			draw_eval_vec4(init_expr);
			fprintf(vvp_out, "    %%parti/%c %u, %ld, 6;\n",
                                ivl_expr_signed(init_expr) ? 's' : 'u', wid, idx * wid);
			fprintf(vvp_out, "    %%ix/load 3, %ld, 0;\n", cnt - idx - 1);
			fprintf(vvp_out, "    %%set/dar/obj/vec4 3;\n");
			fprintf(vvp_out, "    %%pop/vec4 1;\n");
		  }
		  break;
		case IVL_VT_REAL:
		  draw_eval_real(init_expr);
		  for (idx = 0 ; idx < cnt ; idx += 1) {
			fprintf(vvp_out, "    %%ix/load 3, %ld, 0;\n", idx);
			fprintf(vvp_out, "    %%set/dar/obj/real 3;\n");
		  }
		  fprintf(vvp_out, "    %%pop/real 1;\n");
		  break;
		case IVL_VT_STRING:
		  draw_eval_string(init_expr);
		  for (idx = 0 ; idx < cnt ; idx += 1) {
			fprintf(vvp_out, "    %%ix/load 3, %ld, 0;\n", idx);
			fprintf(vvp_out, "    %%set/dar/obj/str 3;\n");
		  }
		  fprintf(vvp_out, "    %%pop/str 1;\n");
		  break;
		default:
		  fprintf(vvp_out, "; ERROR: Sorry, this type not supported here.\n");
		  errors += 1;
		  break;
	    }

      } else if (init_expr) {
	    fprintf(vvp_out, "; ERROR: Sorry, I don't know how to work with this size expr.\n");
	    errors += 1;
      }

      return errors;
}
Beispiel #12
0
static int show_stmt_assign_sig_cobject(ivl_statement_t net)
{
      int errors = 0;
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);
      ivl_signal_t sig= ivl_lval_sig(lval);
      unsigned lwid = ivl_lval_width(lval);

      int prop_idx = ivl_lval_property_idx(lval);

      if (prop_idx >= 0) {
	    ivl_type_t sig_type = ivl_signal_net_type(sig);
	    ivl_type_t prop_type = ivl_type_prop_type(sig_type, prop_idx);

	    if (ivl_type_base(prop_type) == IVL_VT_BOOL) {
		  assert(ivl_type_packed_dimensions(prop_type) == 1);
		  assert(ivl_type_packed_msb(prop_type,0) >= ivl_type_packed_lsb(prop_type, 0));

		  draw_eval_vec4(rval);
		  if (ivl_expr_value(rval)!=IVL_VT_BOOL)
			fprintf(vvp_out, "    %%cast2;\n");

		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/v %d, %u; Store in bool property %s\n",
			  prop_idx, lwid, ivl_type_prop_name(sig_type, prop_idx));
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_LOGIC) {
		  assert(ivl_type_packed_dimensions(prop_type) == 1);
		  assert(ivl_type_packed_msb(prop_type,0) >= ivl_type_packed_lsb(prop_type, 0));

		  draw_eval_vec4(rval);

		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/v %d, %u; Store in logic property %s\n",
			  prop_idx, lwid, ivl_type_prop_name(sig_type, prop_idx));
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_REAL) {

		    /* Calculate the real value into the real value
		       stack. The %store/prop/r will pop the stack
		       value. */
		  draw_eval_real(rval);
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/r %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_STRING) {

		    /* Calculate the string value into the string value
		       stack. The %store/prop/r will pop the stack
		       value. */
		  draw_eval_string(rval);
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  fprintf(vvp_out, "    %%store/prop/str %d;\n", prop_idx);
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_DARRAY) {

		  int idx = 0;

		    /* The property is a darray, and there is no mux
		       expression to the assignment is of an entire
		       array object. */
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  draw_eval_object(rval);
		  fprintf(vvp_out, "    %%store/prop/obj %d, %d; IVL_VT_DARRAY\n", prop_idx, idx);
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

	    } else if (ivl_type_base(prop_type) == IVL_VT_CLASS) {

		  int idx = 0;
		  ivl_expr_t idx_expr;
		  if ( (idx_expr = ivl_lval_idx(lval)) ) {
			idx = allocate_word();
		  }

		    /* The property is a class object. */
		  fprintf(vvp_out, "    %%load/obj v%p_0;\n", sig);
		  draw_eval_object(rval);
		  if (idx_expr) draw_eval_expr_into_integer(idx_expr, idx);
		  fprintf(vvp_out, "    %%store/prop/obj %d, %d; IVL_VT_CLASS\n", prop_idx, idx);
		  fprintf(vvp_out, "    %%pop/obj 1, 0;\n");

		  if (idx_expr) clr_word(idx);

	    } else {
		  fprintf(vvp_out, " ; ERROR: ivl_type_base(prop_type) = %d\n",
			  ivl_type_base(prop_type));
		  assert(0);
	    }

      } else {
	      /* There is no property select, so evaluate the r-value
		 as an object and assign the entire object to the
		 variable. */
	    errors += draw_eval_object(rval);

	    if (ivl_signal_array_count(sig) > 1) {
		  unsigned ix;
		  ivl_expr_t aidx = ivl_lval_idx(lval);

		  draw_eval_expr_into_integer(aidx, (ix = allocate_word()));
		  fprintf(vvp_out, "    %%store/obja v%p, %u;\n", sig, ix);
		  clr_word(ix);

	    } else {
		    /* Not an array, so no index expression */
		  fprintf(vvp_out, "    %%store/obj v%p_0;\n", sig);
	    }
      }

      return errors;
}
Beispiel #13
0
static int show_stmt_assign_sig_darray(ivl_statement_t net)
{
      int errors = 0;
      ivl_lval_t lval = ivl_stmt_lval(net, 0);
      ivl_expr_t rval = ivl_stmt_rval(net);
      ivl_expr_t part = ivl_lval_part_off(lval);
      ivl_signal_t var= ivl_lval_sig(lval);
      ivl_type_t var_type= ivl_signal_net_type(var);
      assert(ivl_type_base(var_type) == IVL_VT_DARRAY);
      ivl_type_t element_type = ivl_type_element(var_type);

      ivl_expr_t mux  = ivl_lval_idx(lval);

      assert(ivl_stmt_lvals(net) == 1);
      assert(ivl_stmt_opcode(net) == 0);
      assert(part == 0);

      if (mux && (ivl_type_base(element_type)==IVL_VT_REAL)) {
	    draw_eval_real(rval);

	      /* The %set/dar expects the array index to be in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%store/dar/r v%p_0;\n", var);

      } else if (mux && ivl_type_base(element_type)==IVL_VT_STRING) {

	      /* Evaluate the rval into the top of the string stack. */
	    draw_eval_string(rval);

	      /* The %store/dar/s expects the array index to me in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%store/dar/str v%p_0;\n", var);

      } else if (mux) {
	    draw_eval_vec4(rval);

	      /* The %store/dar/vec4 expects the array index to be in index
		 register 3. Calculate the index in place. */
	    draw_eval_expr_into_integer(mux, 3);

	    fprintf(vvp_out, "    %%store/dar/vec4 v%p_0;\n", var);

      } else if (ivl_expr_type(rval) == IVL_EX_ARRAY_PATTERN) {
	      /* There is no l-value mux, but the r-value is an array
		 pattern. This is a special case of an assignment to
		 elements of the l-value. */
	    errors += show_stmt_assign_darray_pattern(net);

      } else {
	      /* There is no l-value mux, so this must be an
		 assignment to the array as a whole. Evaluate the
		 "object", and store the evaluated result. */
	    errors += draw_eval_object(rval);
	    fprintf(vvp_out, "    %%store/obj v%p_0;\n", var);
      }

      return errors;
}