static void draw_ufunc_preamble(ivl_expr_t expr)
{
ivl_scope_t def = ivl_expr_def(expr);
unsigned idx;
/* If this is an automatic function, allocate the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%alloc S_%p;\n", def);
}
/* evaluate the expressions and send the results to the
function ports. */
assert(ivl_expr_parms(expr) == (ivl_scope_ports(def)-1));
for (idx = 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
ivl_signal_t port = ivl_scope_port(def, idx+1);
draw_function_argument(port, ivl_expr_parm(expr, idx));
}
/* Call the function */
fprintf(vvp_out, " %%fork TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
fprintf(vvp_out, " %%join;\n");
}
void draw_ufunc_real(ivl_expr_t expr)
{
ivl_scope_t def = ivl_expr_def(expr);
ivl_signal_t retval = ivl_scope_port(def, 0);
unsigned idx;
/* If this is an automatic function, allocate the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%alloc S_%p;\n", def);
}
assert(ivl_expr_parms(expr) == (ivl_scope_ports(def)-1));
for (idx = 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
ivl_signal_t port = ivl_scope_port(def, idx+1);
draw_function_argument(port, ivl_expr_parm(expr, idx));
}
/* Call the function */
fprintf(vvp_out, " %%fork TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
fprintf(vvp_out, " %%join;\n");
/* Return value signal cannot be an array. */
assert(ivl_signal_dimensions(retval) == 0);
/* Load the result into a word. */
fprintf(vvp_out, " %%load/real v%p_0;\n", retval);
/* If this is an automatic function, free the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%free S_%p;\n", def);
}
}
static void draw_ufunc_preamble(ivl_expr_t expr)
{
ivl_scope_t def = ivl_expr_def(expr);
unsigned idx;
/* If this is an automatic function, allocate the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%alloc S_%p;\n", def);
}
/* Evaluate the expressions and send the results to the
function ports. Do this in two passes - evaluate,
then send - this avoids the function input variables
being overwritten if the same (non-automatic) function
is called in one of the exressions. */
assert(ivl_expr_parms(expr) == (ivl_scope_ports(def)-1));
for (idx = 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
ivl_signal_t port = ivl_scope_port(def, idx+1);
draw_eval_function_argument(port, ivl_expr_parm(expr, idx));
}
for (idx = ivl_expr_parms(expr) ; idx > 0 ; idx -= 1) {
ivl_signal_t port = ivl_scope_port(def, idx);
draw_send_function_argument(port);
}
/* Call the function */
fprintf(vvp_out, " %%fork TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
fprintf(vvp_out, " %%join;\n");
}
static int show_stmt_utask(ivl_statement_t net)
{
ivl_scope_t task = ivl_stmt_call(net);
fprintf(vvp_out, " %%fork TD_%s",
vvp_mangle_id(ivl_scope_name(task)));
fprintf(vvp_out, ", S_%p;\n", task);
fprintf(vvp_out, " %%join;\n");
clear_expression_lookaside();
return 0;
}
static void draw_ufunc_preamble(ivl_expr_t expr)
{
ivl_scope_t def = ivl_expr_def(expr);
unsigned idx;
/* If this is an automatic function, allocate the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%alloc S_%p;\n", def);
}
/* Evaluate the expressions and send the results to the
function ports. Do this in two passes - evaluate,
then send - this avoids the function input variables
being overwritten if the same (non-automatic) function
is called in one of the expressions. */
assert(ivl_expr_parms(expr) == (ivl_scope_ports(def)-1));
for (idx = 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
ivl_signal_t port = ivl_scope_port(def, idx+1);
draw_eval_function_argument(port, ivl_expr_parm(expr, idx));
}
for (idx = ivl_expr_parms(expr) ; idx > 0 ; idx -= 1) {
ivl_signal_t port = ivl_scope_port(def, idx);
draw_send_function_argument(port);
}
/* Call the function */
switch (ivl_expr_value(expr)) {
case IVL_VT_VOID:
fprintf(vvp_out, " %%callf/void TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
break;
case IVL_VT_REAL:
fprintf(vvp_out, " %%callf/real TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
break;
case IVL_VT_BOOL:
case IVL_VT_LOGIC:
fprintf(vvp_out, " %%callf/vec4 TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
break;
case IVL_VT_STRING:
fprintf(vvp_out, " %%callf/str TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
break;
case IVL_VT_CLASS:
case IVL_VT_DARRAY:
case IVL_VT_QUEUE:
fprintf(vvp_out, " %%callf/obj TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
break;
default:
fprintf(vvp_out, " %%fork TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
fprintf(vvp_out, " %%join;\n");
break;
}
}
static void draw_udp_def(ivl_udp_t udp)
{
unsigned init;
unsigned i;
switch (ivl_udp_init(udp))
{
case '0':
init = 0;
break;
case '1':
init = 1;
break;
default:
init = 2;
break;
}
if (ivl_udp_sequ(udp))
fprintf(vvp_out,
"UDP_%s .udp/sequ \"%s\", %d, %d",
vvp_mangle_id(ivl_udp_name(udp)),
vvp_mangle_name(ivl_udp_name(udp)),
ivl_udp_nin(udp),
init );
else
fprintf(vvp_out,
"UDP_%s .udp/comb \"%s\", %d",
vvp_mangle_id(ivl_udp_name(udp)),
vvp_mangle_name(ivl_udp_name(udp)),
ivl_udp_nin(udp));
for (i=0; i<ivl_udp_rows(udp); i++)
fprintf(vvp_out, "\n ,\"%s\"", ivl_udp_row(udp, i) );
fprintf(vvp_out, ";\n");
}
static void draw_lpm_ufunc(ivl_lpm_t net)
{
unsigned idx;
ivl_scope_t def = ivl_lpm_define(net);
const char*dly = draw_lpm_output_delay(net);
fprintf(vvp_out, "L_%p%s .ufunc TD_%s, %u", net, dly,
vvp_mangle_id(ivl_scope_name(def)),
ivl_lpm_width(net));
/* Print all the net signals that connect to the input of the
function. */
for (idx = 0 ; idx < ivl_lpm_size(net) ; idx += 1) {
fprintf(vvp_out, ", %s", draw_net_input(ivl_lpm_data(net, idx)));
}
assert((ivl_lpm_size(net)+1) == ivl_scope_ports(def));
/* Now print all the variables in the function scope that
receive the input values given in the previous list. */
for (idx = 0 ; idx < ivl_lpm_size(net) ; idx += 1) {
ivl_signal_t psig = ivl_scope_port(def, idx+1);
if (idx == 0)
fprintf(vvp_out, " (");
else
fprintf(vvp_out, ", ");
assert(ivl_signal_dimensions(psig) == 0);
fprintf(vvp_out, "v%p_0", psig);
}
fprintf(vvp_out, ")");
/* Now print the reference to the signal from which the
result is collected. */
{ ivl_signal_t psig = ivl_scope_port(def, 0);
assert(ivl_lpm_width(net) == ivl_signal_width(psig));
assert(ivl_signal_dimensions(psig) == 0);
fprintf(vvp_out, " v%p_0", psig);
}
/* Finally, print the scope identifier. */
fprintf(vvp_out, " S_%p;\n", def);
}
int draw_func_definition(ivl_scope_t scope)
{
int rc = 0;
ivl_statement_t def = ivl_scope_def(scope);
fprintf(vvp_out, "TD_%s ;\n", vvp_mangle_id(ivl_scope_name(scope)));
clear_expression_lookaside();
assert(def);
rc += show_statement(def, scope);
fprintf(vvp_out, " %%end;\n");
thread_count += 1;
return rc;
}
static void draw_udp_in_scope(ivl_net_logic_t lptr)
{
unsigned pdx;
ivl_udp_t udp = ivl_logic_udp(lptr);
static ivl_udp_t *udps = 0x0;
static int nudps = 0;
int i;
for (i=0; i<nudps; i++)
if (udps[i] == udp)
break;
if (i >= nudps)
{
udps = realloc(udps, (nudps+1)*sizeof(ivl_udp_t));
assert(udps);
udps[nudps++] = udp;
draw_udp_def(udp);
}
fprintf(vvp_out, "L_%p .udp", lptr);
fprintf(vvp_out, " UDP_%s",
vvp_mangle_id(ivl_udp_name(udp)));
draw_delay(lptr);
for (pdx = 1 ; pdx < ivl_logic_pins(lptr) ; pdx += 1) {
ivl_nexus_t nex = ivl_logic_pin(lptr, pdx);
/* Unlike other logic gates, primitives may have unconnected
inputs. The proper behavior is to attach a HiZ to the
port. */
if (nex == 0) {
assert(ivl_logic_width(lptr) == 1);
fprintf(vvp_out, ", C4<z>");
} else {
fprintf(vvp_out, ", %s", draw_net_input(nex));
}
}
fprintf(vvp_out, ";\n");
}
struct vector_info draw_ufunc_expr(ivl_expr_t expr, unsigned wid)
{
unsigned idx;
unsigned swid = ivl_expr_width(expr);
ivl_scope_t def = ivl_expr_def(expr);
ivl_signal_t retval = ivl_scope_port(def, 0);
struct vector_info res;
unsigned load_wid;
/* If this is an automatic function, allocate the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%alloc S_%p;\n", def);
}
/* evaluate the expressions and send the results to the
function ports. */
assert(ivl_expr_parms(expr) == (ivl_scope_ports(def)-1));
for (idx = 0 ; idx < ivl_expr_parms(expr) ; idx += 1) {
ivl_signal_t port = ivl_scope_port(def, idx+1);
draw_function_argument(port, ivl_expr_parm(expr, idx));
}
/* Call the function */
fprintf(vvp_out, " %%fork TD_%s", vvp_mangle_id(ivl_scope_name(def)));
fprintf(vvp_out, ", S_%p;\n", def);
fprintf(vvp_out, " %%join;\n");
/* Fresh basic block starts after the join. */
clear_expression_lookaside();
/* The return value is in a signal that has the name of the
expression. Load that into the thread and return the
vector result. */
res.base = allocate_vector(wid);
res.wid = wid;
if (res.base == 0) {
fprintf(stderr, "%s:%u: vvp.tgt error: "
"Unable to allocate %u thread bits for function result.\n",
ivl_expr_file(expr), ivl_expr_lineno(expr), wid);
vvp_errors += 1;
return res;
}
assert(res.base != 0);
load_wid = swid;
if (load_wid > ivl_signal_width(retval))
load_wid = ivl_signal_width(retval);
assert(ivl_signal_dimensions(retval) == 0);
fprintf(vvp_out, " %%load/v %u, v%p_0, %u;\n",
res.base, retval, load_wid);
/* Pad the signal value with zeros. */
if (load_wid < wid)
pad_expr_in_place(expr, res, swid);
/* If this is an automatic function, free the local storage. */
if (ivl_scope_is_auto(def)) {
fprintf(vvp_out, " %%free S_%p;\n", def);
}
return res;
}
