static int show_stmt_assign_vector(ivl_statement_t net)
{
ivl_expr_t rval = ivl_stmt_rval(net);
struct vector_info res;
struct vector_info lres = {0, 0};
struct vec_slice_info*slices = 0;
/* If this is a compressed assignment, then get the contents
of the l-value. We need these values as part of the r-value
calculation. */
if (ivl_stmt_opcode(net) != 0) {
slices = calloc(ivl_stmt_lvals(net), sizeof(struct vec_slice_info));
lres = get_vec_from_lval(net, slices);
}
/* Handle the special case that the expression is a real
value. Evaluate the real expression, then convert the
result to a vector. Then store that vector into the
l-value. */
if (ivl_expr_value(rval) == IVL_VT_REAL) {
draw_eval_real(rval);
/* This is the accumulated with of the l-value of the
assignment. */
unsigned wid = ivl_stmt_lwidth(net);
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 "
"r-value expression.\n", ivl_expr_file(rval),
ivl_expr_lineno(rval), wid);
vvp_errors += 1;
}
fprintf(vvp_out, " %%cvt/vr %u, %u;\n", res.base, res.wid);
} else {
res = draw_eval_expr(rval, 0);
}
switch (ivl_stmt_opcode(net)) {
case 0:
set_vec_to_lval(net, res);
break;
case '+':
if (res.base > 3) {
fprintf(vvp_out, " %%add %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
} else {
fprintf(vvp_out, " %%add %u, %u, %u;\n",
lres.base, res.base, res.wid);
res.base = lres.base;
}
put_vec_to_lval(net, slices, res);
break;
case '-':
fprintf(vvp_out, " %%sub %u, %u, %u;\n",
lres.base, res.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
put_vec_to_lval(net, slices, res);
break;
case '*':
if (res.base > 3) {
fprintf(vvp_out, " %%mul %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
} else {
fprintf(vvp_out, " %%mul %u, %u, %u;\n",
lres.base, res.base, res.wid);
res.base = lres.base;
}
put_vec_to_lval(net, slices, res);
break;
case '/':
fprintf(vvp_out, " %%div%s %u, %u, %u;\n",
ivl_expr_signed(rval)? "/s" : "",
lres.base, res.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
put_vec_to_lval(net, slices, res);
break;
case '%':
fprintf(vvp_out, " %%mod%s %u, %u, %u;\n",
ivl_expr_signed(rval)? "/s" : "",
lres.base, res.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
put_vec_to_lval(net, slices, res);
break;
case '&':
if (res.base > 3) {
fprintf(vvp_out, " %%and %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
} else {
fprintf(vvp_out, " %%and %u, %u, %u;\n",
lres.base, res.base, res.wid);
res.base = lres.base;
}
put_vec_to_lval(net, slices, res);
break;
case '|':
if (res.base > 3) {
fprintf(vvp_out, " %%or %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
} else {
fprintf(vvp_out, " %%or %u, %u, %u;\n",
lres.base, res.base, res.wid);
res.base = lres.base;
}
put_vec_to_lval(net, slices, res);
break;
case '^':
if (res.base > 3) {
fprintf(vvp_out, " %%xor %u, %u, %u;\n",
res.base, lres.base, res.wid);
clr_vector(lres);
} else {
fprintf(vvp_out, " %%xor %u, %u, %u;\n",
lres.base, res.base, res.wid);
res.base = lres.base;
}
put_vec_to_lval(net, slices, res);
break;
case 'l': /* lres <<= res */
fprintf(vvp_out, " %%ix/get 0, %u, %u;\n", res.base, res.wid);
fprintf(vvp_out, " %%shiftl/i0 %u, %u;\n", lres.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
break;
case 'r': /* lres >>= res */
fprintf(vvp_out, " %%ix/get 0, %u, %u;\n", res.base, res.wid);
fprintf(vvp_out, " %%shiftr/i0 %u, %u;\n", lres.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
break;
case 'R': /* lres >>>= res */
fprintf(vvp_out, " %%ix/get 0, %u, %u;\n", res.base, res.wid);
fprintf(vvp_out, " %%shiftr/s/i0 %u, %u;\n", lres.base, res.wid);
fprintf(vvp_out, " %%mov %u, %u, %u;\n",
res.base, lres.base, res.wid);
break;
default:
fprintf(vvp_out, "; UNSUPPORTED ASSIGNMENT OPCODE: %c\n", ivl_stmt_opcode(net));
assert(0);
break;
}
if (slices)
free(slices);
if (res.base > 3)
clr_vector(res);
return 0;
}
static int show_stmt_assign_vector(ivl_statement_t net)
{
ivl_lval_t lval;
ivl_expr_t rval = ivl_stmt_rval(net);
ivl_memory_t mem;
/* Handle the special case that the expression is a real
value. Evaluate the real expression, then convert the
result to a vector. Then store that vector into the
l-value. */
if (ivl_expr_value(rval) == IVL_VT_REAL) {
int word = draw_eval_real(rval);
/* This is the accumulated with of the l-value of the
assignment. */
unsigned wid = ivl_stmt_lwidth(net);
struct vector_info vec;
vec.base = allocate_vector(wid);
vec.wid = wid;
fprintf(vvp_out, " %%cvt/vr %u, %d, %u;\n",
vec.base, word, vec.wid);
clr_word(word);
set_vec_to_lval(net, vec);
clr_vector(vec);
return 0;
}
/* Handle the special case that the r-value is a constant. We
can generate the %set statement directly, without any worry
about generating code to evaluate the r-value expressions. */
if (ivl_expr_type(rval) == IVL_EX_NUMBER) {
unsigned lidx;
const char*bits = ivl_expr_bits(rval);
unsigned wid = ivl_expr_width(rval);
unsigned cur_rbit = 0;
for (lidx = 0 ; lidx < ivl_stmt_lvals(net) ; lidx += 1) {
unsigned skip_set = transient_id++;
unsigned skip_set_flag = 0;
unsigned idx;
unsigned bit_limit = wid - cur_rbit;
lval = ivl_stmt_lval(net, lidx);
/* If there is a mux for the lval, calculate the
value and write it into index0. */
if (ivl_lval_mux(lval)) {
calculate_into_x0(ivl_lval_mux(lval));
/* Generate code to skip around the set
if the index has X values. */
fprintf(vvp_out, " %%jmp/1 t_%u, 4;\n", skip_set);
skip_set_flag = 1;
}
mem = ivl_lval_mem(lval);
if (mem) {
draw_memory_index_expr(mem, ivl_lval_idx(lval));
/* Generate code to skip around the set
if the index has X values. */
fprintf(vvp_out, " %%jmp/1 t_%u, 4;\n", skip_set);
skip_set_flag = 1;
}
if (bit_limit > ivl_lval_pins(lval))
bit_limit = ivl_lval_pins(lval);
if (mem) {
for (idx = 0 ; idx < bit_limit ; idx += 1) {
set_to_memory(mem, idx,
bitchar_to_idx(bits[cur_rbit]));
cur_rbit += 1;
}
for (idx = bit_limit
; idx < ivl_lval_pins(lval) ; idx += 1)
set_to_memory(mem, idx, 0);
} else {
idx = 0;
while (idx < bit_limit) {
unsigned cnt = 1;
while (((idx + cnt) < bit_limit)
&& (bits[cur_rbit] == bits[cur_rbit+cnt]))
cnt += 1;
set_to_lvariable(lval, idx,
bitchar_to_idx(bits[cur_rbit]),
cnt);
cur_rbit += cnt;
idx += cnt;
}
if (bit_limit < ivl_lval_pins(lval)) {
unsigned cnt = ivl_lval_pins(lval) - bit_limit;
set_to_lvariable(lval, bit_limit, 0, cnt);
}
}
if (skip_set_flag) {
fprintf(vvp_out, "t_%u ;\n", skip_set);
clear_expression_lookaside();
}
}
return 0;
}
{ struct vector_info res = draw_eval_expr(rval, 0);
set_vec_to_lval(net, res);
if (res.base > 3)
clr_vector(res);
}
return 0;
}
