litex/liteusb/phy/ft2232h.py

308 lines
6.4 KiB
Python

from migen.fhdl.std import *
from migen.flow.actor import *
from migen.actorlib.fifo import AsyncFIFO
from migen.fhdl.specials import *
from liteusb.ftdi.std import *
class FtdiPHY(Module):
def __init__(self, pads, fifo_depth=32, read_time=16, write_time=16):
dw = flen(pads.data)
#
# Read / Write Fifos
#
# Read Fifo (Ftdi --> SoC)
read_fifo = RenameClockDomains(AsyncFIFO(phy_layout, fifo_depth),
{"write":"ftdi", "read":"sys"})
read_buffer = RenameClockDomains(SyncFIFO(phy_layout, 4),
{"sys":"ftdi"})
self.comb += read_buffer.source.connect(read_fifo.sink)
# Write Fifo (SoC --> Ftdi)
write_fifo = RenameClockDomains(AsyncFIFO(phy_layout, fifo_depth),
{"write":"sys", "read":"ftdi"})
self.submodules += read_fifo, read_buffer, write_fifo
#
# Sink / Source interfaces
#
self.sink = write_fifo.sink
self.source = read_fifo.source
#
# Read / Write Arbitration
#
wants_write = Signal()
wants_read = Signal()
txe_n = Signal()
rxf_n = Signal()
self.comb += [
txe_n.eq(pads.txe_n),
rxf_n.eq(pads.rxf_n),
wants_write.eq(~txe_n & write_fifo.source.stb),
wants_read.eq(~rxf_n & read_fifo.sink.ack),
]
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(read_time)
write_time_en, max_write_time = anti_starvation(write_time)
data_w_accepted = Signal(reset=1)
fsm = FSM()
self.submodules += RenameClockDomains(fsm, {"sys": "ftdi"})
fsm.act("READ",
read_time_en.eq(1),
If(wants_write,
If(~wants_read | max_read_time, NextState("RTW"))
)
)
fsm.act("RTW",
NextState("WRITE")
)
fsm.act("WRITE",
write_time_en.eq(1),
If(wants_read,
If(~wants_write | max_write_time, NextState("WTR"))
),
write_fifo.source.ack.eq(wants_write & data_w_accepted)
)
fsm.act("WTR",
NextState("READ")
)
#
# Read / Write Actions
#
data_w = Signal(dw)
data_r = Signal(dw)
data_oe = Signal()
pads.oe_n.reset = 1
pads.rd_n.reset = 1
pads.wr_n.reset = 1
self.sync.ftdi += [
If(fsm.ongoing("READ"),
data_oe.eq(0),
pads.oe_n.eq(0),
pads.rd_n.eq(~wants_read),
pads.wr_n.eq(1)
).Elif(fsm.ongoing("WRITE"),
data_oe.eq(1),
pads.oe_n.eq(1),
pads.rd_n.eq(1),
pads.wr_n.eq(~wants_write),
data_w_accepted.eq(~txe_n)
).Else(
data_oe.eq(1),
pads.oe_n.eq(~fsm.ongoing("WTR")),
pads.rd_n.eq(1),
pads.wr_n.eq(1)
),
read_buffer.sink.stb.eq(~pads.rd_n & ~rxf_n),
read_buffer.sink.d.eq(data_r),
If(~txe_n & data_w_accepted,
data_w.eq(write_fifo.source.d)
)
]
#
# Databus Tristate
#
self.specials += Tristate(pads.data, data_w, data_oe, data_r)
self.debug = Signal(8)
self.comb += self.debug.eq(data_r)
#
# TB
#
class FtdiModel(Module, RandRun):
def __init__(self, rd_data):
RandRun.__init__(self, 50)
self.rd_data = [0] + rd_data
self.rd_idx = 0
# pads
self.data = Signal(8)
self.rxf_n = Signal(reset=1)
self.txe_n = Signal(reset=1)
self.rd_n = Signal(reset=1)
self.wr_n = Signal(reset=1)
self.oe_n = Signal(reset=1)
self.siwua = Signal()
self.pwren_n = Signal(reset=1)
self.init = True
self.wr_data = []
self.wait_wr_n = False
self.rd_done = 0
def wr_sim(self, selfp):
if not selfp.wr_n and not selfp.txe_n:
self.wr_data.append(selfp.data)
self.wait_wr_n = False
if not self.wait_wr_n:
if self.run:
selfp.txe_n = 1
else:
if selfp.txe_n:
self.wait_wr_n = True
selfp.txe_n = 0
def rd_sim(self, selfp):
rxf_n = selfp.rxf_n
if self.run:
if self.rd_idx < len(self.rd_data)-1:
self.rd_done = selfp.rxf_n
selfp.rxf_n = 0
else:
selfp.rxf_n = self.rd_done
else:
selfp.rxf_n = self.rd_done
if not selfp.rd_n and not selfp.oe_n:
if self.rd_idx < len(self.rd_data)-1:
self.rd_idx += not rxf_n
selfp.data = self.rd_data[self.rd_idx]
self.rd_done = 1
def do_simulation(self, selfp):
RandRun.do_simulation(self, selfp)
if self.init:
selfp.rxf_n = 0
self.wr_data = []
self.init = False
self.wr_sim(selfp)
self.rd_sim(selfp)
class UserModel(Module, RandRun):
def __init__(self, wr_data):
RandRun.__init__(self, 50)
self.wr_data = wr_data
self.wr_data_idx = 0
self.sink = Sink(phy_layout)
self.source = Source(phy_layout)
self.rd_data = []
def wr_sim(self, selfp):
auth = True
if selfp.source.stb and not selfp.source.ack:
auth = False
if auth:
if self.wr_data_idx < len(self.wr_data):
if self.run:
selfp.source.d = self.wr_data[self.wr_data_idx]
selfp.source.stb = 1
self.wr_data_idx += 1
else:
selfp.source.stb = 0
else:
self.source.stb = 0
def rd_sim(self, selfp):
if self.run:
selfp.sink.ack = 1
else:
selfp.sink.ack = 0
if selfp.sink.stb & selfp.sink.ack:
self.rd_data.append(selfp.sink.d)
def do_simulation(self, selfp):
RandRun.do_simulation(self, selfp)
self.wr_sim(selfp)
self.rd_sim(selfp)
LENGTH = 512
model_rd_data = [i%256 for i in range(LENGTH)][::-1]
user_wr_data = [i%256 for i in range(LENGTH)]
class TB(Module):
def __init__(self):
self.submodules.model = FtdiModel(model_rd_data)
self.submodules.phy = FtdiPHY(self.model)
self.submodules.user = UserModel(user_wr_data)
self.comb += [
self.user.source.connect(self.phy.sink),
self.phy.source.connect(self.user.sink)
]
# Use sys_clk as ftdi_clk in simulation
self.comb += [
ClockSignal("ftdi").eq(ClockSignal()),
ResetSignal("ftdi").eq(ResetSignal())
]
def print_results(s, l1, l2):
def comp(l1, l2):
r = True
try:
for i, val in enumerate(l1):
if val != l2[i]:
print(s + " : val : %02X, exp : %02X" %(val, l2[i]))
r = False
except:
return r
return r
c = comp(l1, l2)
r = s + " "
if c:
r += "[OK]"
else:
r += "[KO]"
print(r)
def main():
from migen.sim.generic import run_simulation
tb = TB()
run_simulation(tb, ncycles=8000, vcd_name="tb_phy.vcd")
###
#print(tb.user.rd_data)
#print(tb.model.wr_data)
#print(len(tb.user.rd_data))
#print(len(tb.model.wr_data))
print_results("FtdiModel --> UserModel", model_rd_data, tb.user.rd_data)
print_results("UserModel --> FtdiModel", user_wr_data, tb.model.wr_data)
if __name__ == "__main__":
main()