litex/misoclib/mem/sdram/core/lasmicon/multiplexer.py

224 lines
8.7 KiB
Python

from migen.fhdl.std import *
from migen.genlib.roundrobin import *
from migen.genlib.misc import optree
from migen.genlib.fsm import FSM, NextState
from migen.bank.description import AutoCSR
from misoclib.mem.sdram.core.lasmicon.perf import Bandwidth
class CommandRequest:
def __init__(self, a, ba):
self.a = Signal(a)
self.ba = Signal(ba)
self.cas_n = Signal(reset=1)
self.ras_n = Signal(reset=1)
self.we_n = Signal(reset=1)
class CommandRequestRW(CommandRequest):
def __init__(self, a, ba):
CommandRequest.__init__(self, a, ba)
self.stb = Signal()
self.ack = Signal()
self.is_cmd = Signal()
self.is_read = Signal()
self.is_write = Signal()
class _CommandChooser(Module):
def __init__(self, requests):
self.want_reads = Signal()
self.want_writes = Signal()
self.want_cmds = Signal()
# NB: cas_n/ras_n/we_n are 1 when stb is inactive
self.cmd = CommandRequestRW(flen(requests[0].a), flen(requests[0].ba))
###
rr = RoundRobin(len(requests), SP_CE)
self.submodules += rr
self.comb += [rr.request[i].eq(req.stb & ((req.is_cmd & self.want_cmds) | ((req.is_read == self.want_reads) | (req.is_write == self.want_writes))))
for i, req in enumerate(requests)]
stb = Signal()
self.comb += stb.eq(Array(req.stb for req in requests)[rr.grant])
for name in ["a", "ba", "is_read", "is_write", "is_cmd"]:
choices = Array(getattr(req, name) for req in requests)
self.comb += getattr(self.cmd, name).eq(choices[rr.grant])
for name in ["cas_n", "ras_n", "we_n"]:
# we should only assert those signals when stb is 1
choices = Array(getattr(req, name) for req in requests)
self.comb += If(self.cmd.stb, getattr(self.cmd, name).eq(choices[rr.grant]))
self.comb += self.cmd.stb.eq(stb \
& ((self.cmd.is_cmd & self.want_cmds) | ((self.cmd.is_read == self.want_reads) \
& (self.cmd.is_write == self.want_writes))))
self.comb += [If(self.cmd.stb & self.cmd.ack & (rr.grant == i), req.ack.eq(1))
for i, req in enumerate(requests)]
self.comb += rr.ce.eq(self.cmd.ack)
class _Steerer(Module):
def __init__(self, commands, dfi):
ncmd = len(commands)
nph = len(dfi.phases)
self.sel = [Signal(max=ncmd) for i in range(nph)]
###
def stb_and(cmd, attr):
if not hasattr(cmd, "stb"):
return 0
else:
return cmd.stb & getattr(cmd, attr)
for phase, sel in zip(dfi.phases, self.sel):
self.comb += [
phase.cke.eq(1),
phase.cs_n.eq(0)
]
if hasattr(phase, "odt"):
self.comb += phase.odt.eq(1)
if hasattr(phase, "reset_n"):
self.comb += phase.reset_n.eq(1)
self.sync += [
phase.address.eq(Array(cmd.a for cmd in commands)[sel]),
phase.bank.eq(Array(cmd.ba for cmd in commands)[sel]),
phase.cas_n.eq(Array(cmd.cas_n for cmd in commands)[sel]),
phase.ras_n.eq(Array(cmd.ras_n for cmd in commands)[sel]),
phase.we_n.eq(Array(cmd.we_n for cmd in commands)[sel]),
phase.rddata_en.eq(Array(stb_and(cmd, "is_read") for cmd in commands)[sel]),
phase.wrdata_en.eq(Array(stb_and(cmd, "is_write") for cmd in commands)[sel])
]
class Multiplexer(Module, AutoCSR):
def __init__(self, phy_settings, geom_settings, timing_settings, controller_settings, bank_machines, refresher, dfi, lasmic,
with_bandwidth=False):
assert(phy_settings.nphases == len(dfi.phases))
self.phy_settings = phy_settings
# Command choosing
requests = [bm.cmd for bm in bank_machines]
self.submodules.choose_cmd = choose_cmd = _CommandChooser(requests)
self.submodules.choose_req = choose_req = _CommandChooser(requests)
self.comb += [
choose_cmd.want_reads.eq(0),
choose_cmd.want_writes.eq(0)
]
if phy_settings.nphases == 1:
self.comb += [
choose_cmd.want_cmds.eq(1),
choose_req.want_cmds.eq(1)
]
# Command steering
nop = CommandRequest(geom_settings.addressbits, geom_settings.bankbits)
commands = [nop, choose_cmd.cmd, choose_req.cmd, refresher.cmd] # nop must be 1st
(STEER_NOP, STEER_CMD, STEER_REQ, STEER_REFRESH) = range(4)
steerer = _Steerer(commands, dfi)
self.submodules += steerer
# Read/write turnaround
read_available = Signal()
write_available = Signal()
self.comb += [
read_available.eq(optree("|", [req.stb & req.is_read for req in requests])),
write_available.eq(optree("|", [req.stb & req.is_write for req in requests]))
]
def anti_starvation(timeout):
en = Signal()
max_time = Signal()
if timeout:
t = timeout - 1
time = Signal(max=t+1)
self.comb += max_time.eq(time == 0)
self.sync += If(~en,
time.eq(t)
).Elif(~max_time,
time.eq(time - 1)
)
else:
self.comb += max_time.eq(0)
return en, max_time
read_time_en, max_read_time = anti_starvation(controller_settings.read_time)
write_time_en, max_write_time = anti_starvation(controller_settings.write_time)
# Refresh
self.comb += [bm.refresh_req.eq(refresher.req) for bm in bank_machines]
go_to_refresh = Signal()
self.comb += go_to_refresh.eq(optree("&", [bm.refresh_gnt for bm in bank_machines]))
# Datapath
all_rddata = [p.rddata for p in dfi.phases]
all_wrdata = [p.wrdata for p in dfi.phases]
all_wrdata_mask = [p.wrdata_mask for p in dfi.phases]
self.comb += [
lasmic.dat_r.eq(Cat(*all_rddata)),
Cat(*all_wrdata).eq(lasmic.dat_w),
Cat(*all_wrdata_mask).eq(~lasmic.dat_we)
]
# Control FSM
fsm = FSM()
self.submodules += fsm
def steerer_sel(steerer, phy_settings, r_w_n):
r = []
for i in range(phy_settings.nphases):
s = steerer.sel[i].eq(STEER_NOP)
if r_w_n == "read":
if i == phy_settings.rdphase:
s = steerer.sel[i].eq(STEER_REQ)
elif i == phy_settings.rdcmdphase:
s = steerer.sel[i].eq(STEER_CMD)
elif r_w_n == "write":
if i == phy_settings.wrphase:
s = steerer.sel[i].eq(STEER_REQ)
elif i == phy_settings.wrcmdphase:
s = steerer.sel[i].eq(STEER_CMD)
else:
raise ValueError
r.append(s)
return r
fsm.act("READ",
read_time_en.eq(1),
choose_req.want_reads.eq(1),
choose_cmd.cmd.ack.eq(1),
choose_req.cmd.ack.eq(1),
steerer_sel(steerer, phy_settings, "read"),
If(write_available,
# TODO: switch only after several cycles of ~read_available?
If(~read_available | max_read_time, NextState("RTW"))
),
If(go_to_refresh, NextState("REFRESH"))
)
fsm.act("WRITE",
write_time_en.eq(1),
choose_req.want_writes.eq(1),
choose_cmd.cmd.ack.eq(1),
choose_req.cmd.ack.eq(1),
steerer_sel(steerer, phy_settings, "write"),
If(read_available,
If(~write_available | max_write_time, NextState("WTR"))
),
If(go_to_refresh, NextState("REFRESH"))
)
fsm.act("REFRESH",
steerer.sel[0].eq(STEER_REFRESH),
If(~refresher.req, NextState("READ"))
)
fsm.delayed_enter("RTW", "WRITE", phy_settings.read_latency-1) # FIXME: reduce this, actual limit is around (cl+1)/nphases
fsm.delayed_enter("WTR", "READ", timing_settings.tWTR-1)
# FIXME: workaround for zero-delay loop simulation problem with Icarus Verilog
fsm.finalize()
self.comb += refresher.ack.eq(fsm.state == fsm.encoding["REFRESH"])
self.with_bandwidth = with_bandwidth
def add_bandwidth(self):
self.with_bandwidth = True
def do_finalize(self):
if self.with_bandwidth:
data_width = self.phy_settings.dfi_databits*self.phy_settings.nphases
self.submodules.bandwidth = Bandwidth(self.choose_req.cmd, data_width)