Merge remote-tracking branch 'upstream/master'

This commit is contained in:
Jim Lawson 2019-04-03 09:45:02 -07:00
commit efc3c13ec3
3 changed files with 203 additions and 30 deletions

View File

@ -106,6 +106,95 @@ struct FirrtlWorker
RTLIL::Design *design; RTLIL::Design *design;
std::string indent; std::string indent;
// Define read/write ports and memories.
// We'll collect their definitions and emit the corresponding FIRRTL definitions at the appropriate point in module construction.
// For the moment, we don't handle $readmemh or $readmemb.
// These will be part of a subsequent PR.
struct read_port {
string name;
bool clk_enable;
bool clk_parity;
bool transparent;
RTLIL::SigSpec clk;
RTLIL::SigSpec ena;
RTLIL::SigSpec addr;
read_port(string name, bool clk_enable, bool clk_parity, bool transparent, RTLIL::SigSpec clk, RTLIL::SigSpec ena, RTLIL::SigSpec addr) : name(name), clk_enable(clk_enable), clk_parity(clk_parity), transparent(transparent), clk(clk), ena(ena), addr(addr) {
// Current (3/13/2019) conventions:
// generate a constant 0 for clock and a constant 1 for enable if they are undefined.
if (!clk.is_fully_def())
this->clk = SigSpec(RTLIL::Const(0, 1));
if (!ena.is_fully_def())
this->ena = SigSpec(RTLIL::Const(1, 1));
}
string gen_read(const char * indent) {
string addr_expr = make_expr(addr);
string ena_expr = make_expr(ena);
string clk_expr = make_expr(clk);
string addr_str = stringf("%s%s.addr <= %s\n", indent, name.c_str(), addr_expr.c_str());
string ena_str = stringf("%s%s.en <= %s\n", indent, name.c_str(), ena_expr.c_str());
string clk_str = stringf("%s%s.clk <= asClock(%s)\n", indent, name.c_str(), clk_expr.c_str());
return addr_str + ena_str + clk_str;
}
};
struct write_port : read_port {
RTLIL::SigSpec mask;
write_port(string name, bool clk_enable, bool clk_parity, bool transparent, RTLIL::SigSpec clk, RTLIL::SigSpec ena, RTLIL::SigSpec addr, RTLIL::SigSpec mask) : read_port(name, clk_enable, clk_parity, transparent, clk, ena, addr), mask(mask) {
if (!clk.is_fully_def())
this->clk = SigSpec(RTLIL::Const(0));
if (!ena.is_fully_def())
this->ena = SigSpec(RTLIL::Const(0));
if (!mask.is_fully_def())
this->ena = SigSpec(RTLIL::Const(1));
}
string gen_read(const char * /* indent */) {
log_error("gen_read called on write_port: %s\n", name.c_str());
return stringf("gen_read called on write_port: %s\n", name.c_str());
}
string gen_write(const char * indent) {
string addr_expr = make_expr(addr);
string ena_expr = make_expr(ena);
string clk_expr = make_expr(clk);
string mask_expr = make_expr(mask);
string mask_str = stringf("%s%s.mask <= %s\n", indent, name.c_str(), mask_expr.c_str());
string addr_str = stringf("%s%s.addr <= %s\n", indent, name.c_str(), addr_expr.c_str());
string ena_str = stringf("%s%s.en <= %s\n", indent, name.c_str(), ena_expr.c_str());
string clk_str = stringf("%s%s.clk <= asClock(%s)\n", indent, name.c_str(), clk_expr.c_str());
return addr_str + ena_str + clk_str + mask_str;
}
};
/* Memories defined within this module. */
struct memory {
string name; // memory name
int abits; // number of address bits
int size; // size (in units) of the memory
int width; // size (in bits) of each element
int read_latency;
int write_latency;
vector<read_port> read_ports;
vector<write_port> write_ports;
std::string init_file;
std::string init_file_srcFileSpec;
memory(string name, int abits, int size, int width) : name(name), abits(abits), size(size), width(width), read_latency(0), write_latency(1), init_file(""), init_file_srcFileSpec("") {}
memory() : read_latency(0), write_latency(1), init_file(""), init_file_srcFileSpec(""){}
void add_memory_read_port(read_port &rp) {
read_ports.push_back(rp);
}
void add_memory_write_port(write_port &wp) {
write_ports.push_back(wp);
}
void add_memory_file(std::string init_file, std::string init_file_srcFileSpec) {
this->init_file = init_file;
this->init_file_srcFileSpec = init_file_srcFileSpec;
}
};
dict<string, memory> memories;
void register_memory(memory &m)
{
memories[m.name] = m;
}
void register_reverse_wire_map(string id, SigSpec sig) void register_reverse_wire_map(string id, SigSpec sig)
{ {
for (int i = 0; i < GetSize(sig); i++) for (int i = 0; i < GetSize(sig); i++)
@ -116,7 +205,7 @@ struct FirrtlWorker
{ {
} }
string make_expr(const SigSpec &sig) static string make_expr(const SigSpec &sig)
{ {
string expr; string expr;
@ -515,6 +604,7 @@ struct FirrtlWorker
int abits = cell->parameters.at("\\ABITS").as_int(); int abits = cell->parameters.at("\\ABITS").as_int();
int width = cell->parameters.at("\\WIDTH").as_int(); int width = cell->parameters.at("\\WIDTH").as_int();
int size = cell->parameters.at("\\SIZE").as_int(); int size = cell->parameters.at("\\SIZE").as_int();
memory m(mem_id, abits, size, width);
int rd_ports = cell->parameters.at("\\RD_PORTS").as_int(); int rd_ports = cell->parameters.at("\\RD_PORTS").as_int();
int wr_ports = cell->parameters.at("\\WR_PORTS").as_int(); int wr_ports = cell->parameters.at("\\WR_PORTS").as_int();
@ -531,33 +621,24 @@ struct FirrtlWorker
if (offset != 0) if (offset != 0)
log_error("Memory with nonzero offset: %s.%s\n", log_id(module), log_id(cell)); log_error("Memory with nonzero offset: %s.%s\n", log_id(module), log_id(cell));
cell_exprs.push_back(stringf(" mem %s:\n", mem_id.c_str()));
cell_exprs.push_back(stringf(" data-type => UInt<%d>\n", width));
cell_exprs.push_back(stringf(" depth => %d\n", size));
for (int i = 0; i < rd_ports; i++)
cell_exprs.push_back(stringf(" reader => r%d\n", i));
for (int i = 0; i < wr_ports; i++)
cell_exprs.push_back(stringf(" writer => w%d\n", i));
cell_exprs.push_back(stringf(" read-latency => 0\n"));
cell_exprs.push_back(stringf(" write-latency => 1\n"));
cell_exprs.push_back(stringf(" read-under-write => undefined\n"));
for (int i = 0; i < rd_ports; i++) for (int i = 0; i < rd_ports; i++)
{ {
if (rd_clk_enable[i] != State::S0) if (rd_clk_enable[i] != State::S0)
log_error("Clocked read port %d on memory %s.%s.\n", i, log_id(module), log_id(cell)); log_error("Clocked read port %d on memory %s.%s.\n", i, log_id(module), log_id(cell));
SigSpec addr_sig = cell->getPort("\\RD_ADDR").extract(i*abits, abits);
SigSpec data_sig = cell->getPort("\\RD_DATA").extract(i*width, width); SigSpec data_sig = cell->getPort("\\RD_DATA").extract(i*width, width);
string addr_expr = make_expr(cell->getPort("\\RD_ADDR").extract(i*abits, abits)); string addr_expr = make_expr(addr_sig);
string name(stringf("%s.r%d", m.name.c_str(), i));
cell_exprs.push_back(stringf(" %s.r%d.addr <= %s\n", mem_id.c_str(), i, addr_expr.c_str())); bool clk_enable = false;
cell_exprs.push_back(stringf(" %s.r%d.en <= UInt<1>(1)\n", mem_id.c_str(), i)); bool clk_parity = true;
cell_exprs.push_back(stringf(" %s.r%d.clk <= asClock(UInt<1>(0))\n", mem_id.c_str(), i)); bool transparency = false;
SigSpec ena_sig = RTLIL::SigSpec(RTLIL::State::S1, 1);
register_reverse_wire_map(stringf("%s.r%d.data", mem_id.c_str(), i), data_sig); SigSpec clk_sig = RTLIL::SigSpec(RTLIL::State::S0, 1);
read_port rp(name, clk_enable, clk_parity, transparency, clk_sig, ena_sig, addr_sig);
m.add_memory_read_port(rp);
cell_exprs.push_back(rp.gen_read(indent.c_str()));
register_reverse_wire_map(stringf("%s.data", name.c_str()), data_sig);
} }
for (int i = 0; i < wr_ports; i++) for (int i = 0; i < wr_ports; i++)
@ -568,9 +649,16 @@ struct FirrtlWorker
if (wr_clk_polarity[i] != State::S1) if (wr_clk_polarity[i] != State::S1)
log_error("Negedge write port %d on memory %s.%s.\n", i, log_id(module), log_id(cell)); log_error("Negedge write port %d on memory %s.%s.\n", i, log_id(module), log_id(cell));
string addr_expr = make_expr(cell->getPort("\\WR_ADDR").extract(i*abits, abits)); string name(stringf("%s.w%d", m.name.c_str(), i));
string data_expr = make_expr(cell->getPort("\\WR_DATA").extract(i*width, width)); bool clk_enable = true;
string clk_expr = make_expr(cell->getPort("\\WR_CLK").extract(i)); bool clk_parity = true;
bool transparency = false;
SigSpec addr_sig =cell->getPort("\\WR_ADDR").extract(i*abits, abits);
string addr_expr = make_expr(addr_sig);
SigSpec data_sig =cell->getPort("\\WR_DATA").extract(i*width, width);
string data_expr = make_expr(data_sig);
SigSpec clk_sig = cell->getPort("\\WR_CLK").extract(i);
string clk_expr = make_expr(clk_sig);
SigSpec wen_sig = cell->getPort("\\WR_EN").extract(i*width, width); SigSpec wen_sig = cell->getPort("\\WR_EN").extract(i*width, width);
string wen_expr = make_expr(wen_sig[0]); string wen_expr = make_expr(wen_sig[0]);
@ -579,13 +667,50 @@ struct FirrtlWorker
if (wen_sig[0] != wen_sig[i]) if (wen_sig[0] != wen_sig[i])
log_error("Complex write enable on port %d on memory %s.%s.\n", i, log_id(module), log_id(cell)); log_error("Complex write enable on port %d on memory %s.%s.\n", i, log_id(module), log_id(cell));
cell_exprs.push_back(stringf(" %s.w%d.addr <= %s\n", mem_id.c_str(), i, addr_expr.c_str())); SigSpec mask_sig = RTLIL::SigSpec(RTLIL::State::S1, 1);
cell_exprs.push_back(stringf(" %s.w%d.data <= %s\n", mem_id.c_str(), i, data_expr.c_str())); write_port wp(name, clk_enable, clk_parity, transparency, clk_sig, wen_sig[0], addr_sig, mask_sig);
cell_exprs.push_back(stringf(" %s.w%d.en <= %s\n", mem_id.c_str(), i, wen_expr.c_str())); m.add_memory_write_port(wp);
cell_exprs.push_back(stringf(" %s.w%d.mask <= UInt<1>(1)\n", mem_id.c_str(), i)); cell_exprs.push_back(stringf("%s%s.data <= %s\n", indent.c_str(), name.c_str(), data_expr.c_str()));
cell_exprs.push_back(stringf(" %s.w%d.clk <= asClock(%s)\n", mem_id.c_str(), i, clk_expr.c_str())); cell_exprs.push_back(wp.gen_write(indent.c_str()));
} }
register_memory(m);
continue;
}
if (cell->type.in("$memwr", "$memrd", "$meminit"))
{
std::string cell_type = fid(cell->type);
std::string mem_id = make_id(cell->parameters["\\MEMID"].decode_string());
memory *mp = nullptr;
if (cell->type == "$meminit" ) {
log_error("$meminit (%s.%s.%s) currently unsupported\n", log_id(module), log_id(cell), mem_id.c_str());
} else {
// It's a $memwr or $memrd. Remember the read/write port parameters for the eventual FIRRTL memory definition.
auto addrSig = cell->getPort("\\ADDR");
auto dataSig = cell->getPort("\\DATA");
auto enableSig = cell->getPort("\\EN");
auto clockSig = cell->getPort("\\CLK");
Const clk_enable = cell->parameters.at("\\CLK_ENABLE");
Const clk_polarity = cell->parameters.at("\\CLK_POLARITY");
mp = &memories.at(mem_id);
int portNum = 0;
bool transparency = false;
string data_expr = make_expr(dataSig);
if (cell->type.in("$memwr")) {
portNum = (int) mp->write_ports.size();
write_port wp(stringf("%s.w%d", mem_id.c_str(), portNum), clk_enable.as_bool(), clk_polarity.as_bool(), transparency, clockSig, enableSig, addrSig, dataSig);
mp->add_memory_write_port(wp);
cell_exprs.push_back(stringf("%s%s.data <= %s\n", indent.c_str(), wp.name.c_str(), data_expr.c_str()));
cell_exprs.push_back(wp.gen_write(indent.c_str()));
} else if (cell->type.in("$memrd")) {
portNum = (int) mp->read_ports.size();
read_port rp(stringf("%s.r%d", mem_id.c_str(), portNum), clk_enable.as_bool(), clk_polarity.as_bool(), transparency, clockSig, enableSig, addrSig);
mp->add_memory_read_port(rp);
cell_exprs.push_back(rp.gen_read(indent.c_str()));
register_reverse_wire_map(stringf("%s.data", rp.name.c_str()), dataSig);
}
}
continue; continue;
} }
@ -763,6 +888,24 @@ struct FirrtlWorker
f << stringf("\n"); f << stringf("\n");
// If we have any memory definitions, output them.
for (auto kv : memories) {
memory m = kv.second;
f << stringf(" mem %s:\n", m.name.c_str());
f << stringf(" data-type => UInt<%d>\n", m.width);
f << stringf(" depth => %d\n", m.size);
for (int i = 0; i < (int) m.read_ports.size(); i += 1) {
f << stringf(" reader => r%d\n", i);
}
for (int i = 0; i < (int) m.write_ports.size(); i += 1) {
f << stringf(" writer => w%d\n", i);
}
f << stringf(" read-latency => %d\n", m.read_latency);
f << stringf(" write-latency => %d\n", m.write_latency);
f << stringf(" read-under-write => undefined\n");
}
f << stringf("\n");
for (auto str : cell_exprs) for (auto str : cell_exprs)
f << str; f << str;

View File

@ -957,6 +957,8 @@ grow_read_ports:;
SigSpec addr_ok_q = addr_ok; SigSpec addr_ok_q = addr_ok;
if ((pi.clocks || pi.make_outreg) && !addr_ok.empty()) { if ((pi.clocks || pi.make_outreg) && !addr_ok.empty()) {
addr_ok_q = module->addWire(NEW_ID); 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); module->addDff(NEW_ID, pi.sig_clock, addr_ok, addr_ok_q, pi.effective_clkpol);
} }

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@ -340,6 +340,7 @@ RTLIL::SigSpec signal_to_mux_tree(RTLIL::Module *mod, SnippetSwCache &swcache, d
// evaluate in reverse order to give the first entry the top priority // evaluate in reverse order to give the first entry the top priority
RTLIL::SigSpec initial_val = result; RTLIL::SigSpec initial_val = result;
RTLIL::Cell *last_mux_cell = NULL; RTLIL::Cell *last_mux_cell = NULL;
bool shiftx = initial_val.is_fully_undef();
for (size_t i = 0; i < sw->cases.size(); i++) { for (size_t i = 0; i < sw->cases.size(); i++) {
int case_idx = sw->cases.size() - i - 1; int case_idx = sw->cases.size() - i - 1;
RTLIL::CaseRule *cs2 = sw->cases[case_idx]; RTLIL::CaseRule *cs2 = sw->cases[case_idx];
@ -348,6 +349,33 @@ RTLIL::SigSpec signal_to_mux_tree(RTLIL::Module *mod, SnippetSwCache &swcache, d
append_pmux(mod, sw->signal, cs2->compare, value, last_mux_cell, sw, ifxmode); append_pmux(mod, sw->signal, cs2->compare, value, last_mux_cell, sw, ifxmode);
else else
result = gen_mux(mod, sw->signal, cs2->compare, value, result, last_mux_cell, sw, ifxmode); result = gen_mux(mod, sw->signal, cs2->compare, value, result, last_mux_cell, sw, ifxmode);
// Ignore output values which are entirely don't care
if (shiftx && !value.is_fully_undef()) {
// Keep checking if case condition is the same as the current case index
if (cs2->compare.size() == 1 && cs2->compare.front().is_fully_const())
shiftx = (cs2->compare.front().as_int() == case_idx);
else
shiftx = false;
}
}
// Transform into a $shiftx where possible
if (shiftx && last_mux_cell && last_mux_cell->type == "$pmux") {
// Create bit-blasted $shiftx-es that shifts by the address line used in the case statement
auto pmux_b_port = last_mux_cell->getPort("\\B");
auto pmux_y_port = last_mux_cell->getPort("\\Y");
int width = last_mux_cell->getParam("\\WIDTH").as_int();
for (int i = 0; i < width; ++i) {
RTLIL::SigSpec a_port;
// Because we went in reverse order above, un-reverse $pmux's B port here
for (int j = pmux_b_port.size()/width-1; j >= 0; --j)
a_port.append(pmux_b_port.extract(j*width+i, 1));
// Create a $shiftx that shifts by the address line used in the case statement
mod->addShiftx(NEW_ID, a_port, sw->signal, pmux_y_port.extract(i, 1));
}
// Disconnect $pmux by replacing its output port with a floating wire
last_mux_cell->setPort("\\Y", mod->addWire(NEW_ID, width));
} }
} }