std::vector<SigSpec> new_wr_en(GetSize(old_wr_en));
std::vector<SigSpec> new_wr_data(GetSize(old_wr_data));
std::vector<SigSpec> new_rd_data(GetSize(old_rd_data));
+ std::vector<std::vector<State>> new_initdata;
std::vector<int> shuffle_map;
+ if (cell_init)
+ new_initdata.resize(mem_size);
+
for (auto &it : en_order)
{
auto &bits = bits_wr_en.at(it);
}
for (int j = 0; j < rd_ports; j++)
new_rd_data[j].append(old_rd_data[j][bits[i]]);
+ if (cell_init) {
+ for (int j = 0; j < mem_size; j++)
+ new_initdata[j].push_back(initdata[j][bits[i]]);
+ }
shuffle_map.push_back(bits[i]);
}
}
for (int j = 0; j < rd_ports; j++)
new_rd_data[j].append(State::Sx);
+ if (cell_init) {
+ for (int j = 0; j < mem_size; j++)
+ new_initdata[j].push_back(State::Sx);
+ }
shuffle_map.push_back(-1);
}
}
for (int i = 0; i < rd_ports; i++)
rd_data.replace(i*mem_width, new_rd_data[i]);
+
+ if (cell_init) {
+ for (int i = 0; i < mem_size; i++)
+ initdata[i] = Const(new_initdata[i]);
+ }
}
// assign write ports
-
+ pair<SigBit, bool> wr_clkdom;
for (int cell_port_i = 0, bram_port_i = 0; cell_port_i < wr_ports; cell_port_i++)
{
bool clken = wr_clken[cell_port_i] == State::S1;
pair<SigBit, bool> clkdom(clksig, clkpol);
if (!clken)
clkdom = pair<SigBit, bool>(State::S1, false);
-
+ wr_clkdom = clkdom;
log(" Write port #%d is in clock domain %s%s.\n",
cell_port_i, clkdom.second ? "" : "!",
clken ? log_signal(clkdom.first) : "~async~");
pi.sig_addr = SigSpec();
pi.sig_data = SigSpec();
pi.sig_en = SigSpec();
+ pi.make_outreg = false;
+ pi.make_transp = false;
}
new_portinfos.push_back(pi);
if (pi.dupidx == dup_count-1) {
bool transp = rd_transp[cell_port_i] == State::S1;
SigBit clksig = rd_clk[cell_port_i];
+ if (wr_ports == 0)
+ transp = false;
+
pair<SigBit, bool> clkdom(clksig, clkpol);
if (!clken)
clkdom = pair<SigBit, bool>(State::S1, false);
if (read_transp.count(pi.transp) && read_transp.at(pi.transp) != transp) {
if (match.make_transp && wr_ports <= 1) {
pi.make_transp = true;
- enable_make_transp = true;
+ if (pi.clocks != 0) {
+ if (wr_ports == 1 && wr_clkdom != clkdom) {
+ log(" Bram port %c%d.%d cannot have soft transparency logic added as read and write clock domains differ.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
+ goto skip_bram_rport;
+ }
+ enable_make_transp = true;
+ }
} else {
log(" Bram port %c%d.%d has incompatible read transparency.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
goto skip_bram_rport;
if (clken) {
clock_domains[pi.clocks] = clkdom;
clock_polarities[pi.clkpol] = clkdom.second;
- read_transp[pi.transp] = transp;
+ if (!pi.make_transp)
+ read_transp[pi.transp] = transp;
pi.sig_clock = clkdom.first;
pi.sig_en = rd_en[cell_port_i];
pi.effective_clkpol = clkdom.second;
State padding = State::Sx;
for (int j = 0; j < bram.dbits; j++)
if (init_offset+i < GetSize(initdata) && init_shift+j < GetSize(initdata[init_offset+i]))
- padding = initparam[i*bram.dbits+j] = initdata[init_offset+i][init_shift+j];
+ initparam[i*bram.dbits+j] = initdata[init_offset+i][init_shift+j];
else
initparam[i*bram.dbits+j] = padding;
}
} else {
SigSpec bram_dout = module->addWire(NEW_ID, bram.dbits);
c->setPort(stringf("\\%sDATA", pf), bram_dout);
-
- if (pi.make_outreg) {
+ if (pi.make_outreg && pi.make_transp) {
+ log(" Moving output register to address for transparent port %c%d.%d.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
+ SigSpec sig_addr_q = module->addWire(NEW_ID, bram.abits);
+ module->addDff(NEW_ID, pi.sig_clock, sig_addr, sig_addr_q, pi.effective_clkpol);
+ c->setPort(stringf("\\%sADDR", pf), sig_addr_q);
+ } else if (pi.make_outreg) {
SigSpec bram_dout_q = module->addWire(NEW_ID, bram.dbits);
if (!pi.sig_en.empty())
bram_dout = module->Mux(NEW_ID, bram_dout_q, bram_dout, pi.sig_en);
module->addDff(NEW_ID, pi.sig_clock, bram_dout, bram_dout_q, pi.effective_clkpol);
bram_dout = bram_dout_q;
- }
-
- if (pi.make_transp)
- {
+ } else if (pi.make_transp) {
log(" Adding extra logic for transparent port %c%d.%d.\n", pi.group + 'A', pi.index + 1, pi.dupidx + 1);
SigSpec transp_en_d = module->Mux(NEW_ID, SigSpec(0, make_transp_enbits),
SigSpec addr_ok_q = addr_ok;
if ((pi.clocks || pi.make_outreg) && !addr_ok.empty()) {
addr_ok_q = module->addWire(NEW_ID);
+ if (!pi.sig_en.empty())
+ addr_ok = module->Mux(NEW_ID, addr_ok_q, addr_ok, pi.sig_en);
module->addDff(NEW_ID, pi.sig_clock, addr_ok, addr_ok_q, pi.effective_clkpol);
}
struct MemoryBramPass : public Pass {
MemoryBramPass() : Pass("memory_bram", "map memories to block rams") { }
- virtual void help()
+ void help() YS_OVERRIDE
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log("the data bits to accommodate the enable pattern of port A.\n");
log("\n");
}
- virtual void execute(vector<string> args, Design *design)
+ void execute(vector<string> args, Design *design) YS_OVERRIDE
{
rules_t rules;