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serwb: move common datapath code to datapath.py, simplify flow control

This commit is contained in:
Florent Kermarrec 2018-06-08 12:15:00 +02:00
parent 89797d08ed
commit 7296a76f18
5 changed files with 297 additions and 323 deletions

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@ -0,0 +1,198 @@
from migen import *
from migen.genlib.io import *
from migen.genlib.misc import BitSlip, WaitTimer
from misoc.interconnect import stream
from misoc.cores.code_8b10b import Encoder, Decoder
from artiq.gateware.serwb.scrambler import Scrambler, Descrambler
def K(x, y):
return (y << 5) | x
class _8b10bEncoder(Module):
def __init__(self):
self.sink = sink = stream.Endpoint([("d", 32), ("k", 4)])
self.source = source = stream.Endpoint([("data", 40)])
# # #
encoder = CEInserter()(Encoder(4, True))
self.submodules += encoder
# control
self.comb += [
source.stb.eq(sink.stb),
sink.ack.eq(source.ack),
encoder.ce.eq(source.stb & source.ack)
]
# datapath
for i in range(4):
self.comb += [
encoder.k[i].eq(sink.k[i]),
encoder.d[i].eq(sink.d[8*i:8*(i+1)]),
source.data[10*i:10*(i+1)].eq(encoder.output[i])
]
class _8b10bDecoder(Module):
def __init__(self):
self.sink = sink = stream.Endpoint([("data", 40)])
self.source = source = stream.Endpoint([("d", 32), ("k", 4)])
# # #
decoders = [CEInserter()(Decoder(True)) for _ in range(4)]
self.submodules += decoders
# control
self.comb += [
source.stb.eq(sink.stb),
sink.ack.eq(source.ack)
]
self.comb += [decoders[i].ce.eq(source.stb & source.ack) for i in range(4)]
# datapath
for i in range(4):
self.comb += [
decoders[i].input.eq(sink.data[10*i:10*(i+1)]),
source.k[i].eq(decoders[i].k),
source.d[8*i:8*(i+1)].eq(decoders[i].d)
]
class _Bitslip(Module):
def __init__(self):
self.value = value = Signal(6)
self.sink = sink = stream.Endpoint([("data", 40)])
self.source = source = stream.Endpoint([("data", 40)])
# # #
bitslip = CEInserter()(BitSlip(40))
self.submodules += bitslip
# control
self.comb += [
source.stb.eq(sink.stb),
sink.ack.eq(source.ack),
bitslip.value.eq(value),
bitslip.ce.eq(source.stb & source.ack)
]
# datapath
self.comb += [
bitslip.i.eq(sink.data),
source.data.eq(bitslip.o)
]
class TXDatapath(Module):
def __init__(self, phy_dw, with_scrambling=True):
self.idle = idle = Signal()
self.comma = comma = Signal()
self.sink = sink = stream.Endpoint([("data", 32)])
self.source = source = stream.Endpoint([("data", phy_dw)])
# # #
# scrambler
if with_scrambling:
self.submodules.scrambler = scrambler = Scrambler()
# line coding
self.submodules.encoder = encoder = _8b10bEncoder()
# converter
self.submodules.converter = converter = stream.Converter(40, phy_dw)
# dataflow
if with_scrambling:
self.comb += [
sink.connect(scrambler.sink),
If(comma,
encoder.sink.stb.eq(1),
encoder.sink.k.eq(1),
encoder.sink.d.eq(K(28,5))
).Else(
scrambler.source.connect(encoder.sink)
)
]
else:
self.comb += [
If(comma,
encoder.sink.stb.eq(1),
encoder.sink.k.eq(1),
encoder.sink.d.eq(K(28,5))
).Else(
sink.connect(encoder.sink, omit={"data"}),
encoder.sink.d.eq(sink.data)
),
]
self.comb += [
If(idle,
converter.sink.stb.eq(1),
converter.sink.data.eq(0)
).Else(
encoder.source.connect(converter.sink),
),
converter.source.connect(source)
]
class RXDatapath(Module):
def __init__(self, phy_dw, with_scrambling=True):
self.bitslip_value = bitslip_value = Signal(6)
self.sink = sink = stream.Endpoint([("data", phy_dw)])
self.source = source = stream.Endpoint([("data", 32)])
self.idle = idle = Signal()
self.comma = comma = Signal()
# # #
# converter
self.submodules.converter = converter = stream.Converter(phy_dw, 40)
# bitslip
self.submodules.bitslip = bitslip = _Bitslip()
self.comb += bitslip.value.eq(bitslip_value)
# line coding
self.submodules.decoder = decoder = _8b10bDecoder()
# descrambler
if with_scrambling:
self.submodules.descrambler = descrambler = Descrambler()
# dataflow
self.comb += [
sink.connect(converter.sink),
converter.source.connect(bitslip.sink),
bitslip.source.connect(decoder.sink)
]
if with_scrambling:
self.comb += [
decoder.source.connect(descrambler.sink),
descrambler.source.connect(source)
]
else:
self.comb += [
decoder.source.connect(source, omit={"d", "k"}),
source.data.eq(decoder.source.d)
]
# idle decoding
idle_timer = WaitTimer(256)
self.submodules += idle_timer
self.comb += [
idle_timer.wait.eq(1),
idle.eq(idle_timer.done & ((converter.source.data == 0) | (converter.source.data == (2**40-1))))
]
# comma decoding
self.sync += \
If(decoder.source.stb,
comma.eq((decoder.source.k == 1) & (decoder.source.d == K(28, 5)))
)

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@ -4,13 +4,8 @@ from migen.genlib.misc import BitSlip, WaitTimer
from misoc.interconnect import stream from misoc.interconnect import stream
from misoc.interconnect.csr import * from misoc.interconnect.csr import *
from misoc.cores.code_8b10b import Encoder, Decoder
from artiq.gateware.serwb.scrambler import Scrambler, Descrambler from artiq.gateware.serwb.datapath import TXDatapath, RXDatapath
def K(x, y):
return (y << 5) | x
class _SerdesClocking(Module): class _SerdesClocking(Module):
@ -30,59 +25,33 @@ class _SerdesClocking(Module):
class _SerdesTX(Module): class _SerdesTX(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads):
# Control # Control
self.idle = idle = Signal() self.idle = idle = Signal()
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.sink = sink = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
# 8b10b encoder # Datapath
self.submodules.encoder = encoder = CEInserter()(Encoder(4, True)) self.submodules.datapath = datapath = TXDatapath(1)
self.comb += encoder.ce.eq(ce)
# 40 --> 1 converter
converter = stream.Converter(40, 1)
self.submodules += converter
self.comb += [ self.comb += [
converter.sink.stb.eq(1), sink.connect(datapath.sink),
converter.source.ack.eq(1), datapath.source.ack.eq(1),
# Enable pipeline when converter accepts the 40 bits datapath.idle.eq(idle),
ce.eq(converter.sink.ack), datapath.comma.eq(comma)
# If not idle, connect encoder to converter
If(~idle,
converter.sink.data.eq(Cat(*[encoder.output[i] for i in range(4)]))
),
# If comma, send K28.5
If(comma,
encoder.k[0].eq(1),
encoder.d[0].eq(K(28,5)),
# Else connect TX to encoder
).Else(
encoder.k[0].eq(k[0]),
encoder.k[1].eq(k[1]),
encoder.k[2].eq(k[2]),
encoder.k[3].eq(k[3]),
encoder.d[0].eq(d[0:8]),
encoder.d[1].eq(d[8:16]),
encoder.d[2].eq(d[16:24]),
encoder.d[3].eq(d[24:32])
)
] ]
# Data output (on rising edge of sys_clk) # Output data (on rising edge of sys_clk)
data = Signal() data = Signal()
self.sync += data.eq(converter.source.data) self.sync += data.eq(datapath.source.data)
self.specials += DifferentialOutput(data, pads.tx_p, pads.tx_n) self.specials += DifferentialOutput(data, pads.tx_p, pads.tx_n)
class _SerdesRX(Module): class _SerdesRX(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads):
# Control # Control
self.bitslip_value = bitslip_value = Signal(6) self.bitslip_value = bitslip_value = Signal(6)
@ -91,9 +60,7 @@ class _SerdesRX(Module):
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.source = source = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
@ -103,50 +70,15 @@ class _SerdesRX(Module):
self.specials += DifferentialInput(pads.rx_p, pads.rx_n, data) self.specials += DifferentialInput(pads.rx_p, pads.rx_n, data)
self.sync += data_d.eq(data) self.sync += data_d.eq(data)
# 1 --> 40 converter and bitslip # Datapath
converter = stream.Converter(1, 40) self.submodules.datapath = datapath = RXDatapath(1)
self.submodules += converter
bitslip = CEInserter()(BitSlip(40))
self.submodules += bitslip
self.comb += [ self.comb += [
converter.sink.stb.eq(1), datapath.sink.stb.eq(1),
converter.source.ack.eq(1), datapath.sink.data.eq(data_d),
# Enable pipeline when converter outputs the 40 bits datapath.bitslip_value.eq(bitslip_value),
ce.eq(converter.source.stb), datapath.source.connect(source),
# Connect input data to converter idle.eq(datapath.idle),
converter.sink.data.eq(data), comma.eq(datapath.comma)
# Connect converter to bitslip
bitslip.ce.eq(ce),
bitslip.value.eq(bitslip_value),
bitslip.i.eq(converter.source.data)
]
# 8b10b decoder
self.submodules.decoders = decoders = [CEInserter()(Decoder(True)) for _ in range(4)]
self.comb += [decoders[i].ce.eq(ce) for i in range(4)]
self.comb += [
# Connect bitslip to decoder
decoders[0].input.eq(bitslip.o[0:10]),
decoders[1].input.eq(bitslip.o[10:20]),
decoders[2].input.eq(bitslip.o[20:30]),
decoders[3].input.eq(bitslip.o[30:40]),
# Connect decoder to output
self.k.eq(Cat(*[decoders[i].k for i in range(4)])),
self.d.eq(Cat(*[decoders[i].d for i in range(4)])),
]
# Status
idle_timer = WaitTimer(256)
self.submodules += idle_timer
self.comb += [
idle_timer.wait.eq(1),
self.idle.eq(idle_timer.done &
((bitslip.o == 0) | (bitslip.o == (2**40-1)))),
self.comma.eq(
(decoders[0].k == 1) & (decoders[0].d == K(28,5)) &
(decoders[1].k == 0) & (decoders[1].d == 0) &
(decoders[2].k == 0) & (decoders[2].d == 0) &
(decoders[3].k == 0) & (decoders[3].d == 0))
] ]
@ -154,8 +86,8 @@ class _SerdesRX(Module):
class _Serdes(Module): class _Serdes(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads, mode="master"):
self.submodules.clocking = _SerdesClocking(pads, mode) self.submodules.clocking = _SerdesClocking(pads, mode)
self.submodules.tx = _SerdesTX(pads, mode) self.submodules.tx = _SerdesTX(pads)
self.submodules.rx = _SerdesRX(pads, mode) self.submodules.rx = _SerdesRX(pads)
# SERWB Master <--> Slave physical synchronization process: # SERWB Master <--> Slave physical synchronization process:
@ -378,34 +310,21 @@ class SERWBPHY(Module, AutoCSR):
self.submodules.init = _SerdesSlaveInit(self.serdes, init_timeout) self.submodules.init = _SerdesSlaveInit(self.serdes, init_timeout)
self.submodules.control = _SerdesControl(self.serdes, self.init, mode) self.submodules.control = _SerdesControl(self.serdes, self.init, mode)
# scrambling # tx/rx dataflow
self.submodules.scrambler = scrambler = Scrambler()
self.submodules.descrambler = descrambler = Descrambler()
# tx dataflow
self.comb += \
If(self.init.ready,
sink.connect(scrambler.sink),
scrambler.source.ack.eq(self.serdes.tx.ce),
If(scrambler.source.stb,
self.serdes.tx.d.eq(scrambler.source.d),
self.serdes.tx.k.eq(scrambler.source.k)
)
)
# rx dataflow
self.comb += [ self.comb += [
If(self.init.ready, If(self.init.ready,
descrambler.sink.stb.eq(self.serdes.rx.ce), sink.connect(self.serdes.tx.sink),
descrambler.sink.d.eq(self.serdes.rx.d), self.serdes.rx.source.connect(source)
descrambler.sink.k.eq(self.serdes.rx.k), ).Else(
descrambler.source.connect(source) self.serdes.rx.source.ack.eq(1)
), ),
# For PRBS test we are using the scrambler/descrambler as PRBS, self.serdes.tx.sink.stb.eq(1) # always transmitting
# sending 0 to the scrambler and checking that descrambler
# output is always 0.
self.control.prbs_error.eq(
descrambler.source.stb &
descrambler.source.ack &
(descrambler.source.data != 0))
] ]
# For PRBS test we are using the scrambler/descrambler as PRBS,
# sending 0 to the scrambler and checking that descrambler
# output is always 0.
self.comb += self.control.prbs_error.eq(
source.stb &
source.ack &
(source.data != 0))

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@ -5,9 +5,7 @@ from migen.genlib.misc import BitSlip, WaitTimer
from misoc.interconnect import stream from misoc.interconnect import stream
from misoc.cores.code_8b10b import Encoder, Decoder from misoc.cores.code_8b10b import Encoder, Decoder
from artiq.gateware.serwb.datapath import TXDatapath, RXDatapath
def K(x, y):
return (y << 5) | x
class _KUSerdesClocking(Module): class _KUSerdesClocking(Module):
@ -45,52 +43,27 @@ class _KUSerdesClocking(Module):
class _KUSerdesTX(Module): class _KUSerdesTX(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads):
# Control # Control
self.idle = idle = Signal() self.idle = idle = Signal()
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.sink = sink = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
# 8b10b encoder
self.submodules.encoder = encoder = CEInserter()(Encoder(4, True))
self.comb += encoder.ce.eq(ce)
# 40 --> 8 converter # Datapath
converter = stream.Converter(40, 8) self.submodules.datapath = datapath = TXDatapath(8)
self.submodules += converter
self.comb += [ self.comb += [
converter.sink.stb.eq(1), sink.connect(datapath.sink),
converter.source.ack.eq(1), datapath.source.ack.eq(1),
# Enable pipeline when converter accepts the 40 bits datapath.idle.eq(idle),
ce.eq(converter.sink.ack), datapath.comma.eq(comma)
# If not idle, connect encoder to converter
If(~idle,
converter.sink.data.eq(Cat(*[encoder.output[i] for i in range(4)]))
),
# If comma, send K28.5
If(comma,
encoder.k[0].eq(1),
encoder.d[0].eq(K(28,5)),
# Else connect TX to encoder
).Else(
encoder.k[0].eq(k[0]),
encoder.k[1].eq(k[1]),
encoder.k[2].eq(k[2]),
encoder.k[3].eq(k[3]),
encoder.d[0].eq(d[0:8]),
encoder.d[1].eq(d[8:16]),
encoder.d[2].eq(d[16:24]),
encoder.d[3].eq(d[24:32])
)
] ]
# Data output (DDR with sys4x) # Output Data(DDR with sys4x)
data = Signal() data = Signal()
self.specials += [ self.specials += [
Instance("OSERDESE3", Instance("OSERDESE3",
@ -100,14 +73,14 @@ class _KUSerdesTX(Module):
o_OQ=data, o_OQ=data,
i_RST=ResetSignal("sys"), i_RST=ResetSignal("sys"),
i_CLK=ClockSignal("sys4x"), i_CLKDIV=ClockSignal("sys"), i_CLK=ClockSignal("sys4x"), i_CLKDIV=ClockSignal("sys"),
i_D=converter.source.data i_D=datapath.source.data
), ),
DifferentialOutput(data, pads.tx_p, pads.tx_n) DifferentialOutput(data, pads.tx_p, pads.tx_n)
] ]
class _KUSerdesRX(Module): class _KUSerdesRX(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads):
# Control # Control
self.delay_rst = Signal() self.delay_rst = Signal()
self.delay_inc = Signal() self.delay_inc = Signal()
@ -118,9 +91,7 @@ class _KUSerdesRX(Module):
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.source = source = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
@ -158,50 +129,15 @@ class _KUSerdesRX(Module):
) )
] ]
# 8 --> 40 converter and bitslip # Datapath
converter = stream.Converter(8, 40) self.submodules.datapath = datapath = RXDatapath(8)
self.submodules += converter
bitslip = CEInserter()(BitSlip(40))
self.submodules += bitslip
self.comb += [ self.comb += [
converter.sink.stb.eq(1), datapath.sink.stb.eq(1),
converter.source.ack.eq(1), datapath.sink.data.eq(data_deserialized),
# Enable pipeline when converter outputs the 40 bits datapath.bitslip_value.eq(bitslip_value),
ce.eq(converter.source.stb), datapath.source.connect(source),
# Connect input data to converter idle.eq(datapath.idle),
converter.sink.data.eq(data_deserialized), comma.eq(datapath.comma)
# Connect converter to bitslip
bitslip.ce.eq(ce),
bitslip.value.eq(bitslip_value),
bitslip.i.eq(converter.source.data)
]
# 8b10b decoder
self.submodules.decoders = decoders = [CEInserter()(Decoder(True)) for _ in range(4)]
self.comb += [decoders[i].ce.eq(ce) for i in range(4)]
self.comb += [
# Connect bitslip to decoder
decoders[0].input.eq(bitslip.o[0:10]),
decoders[1].input.eq(bitslip.o[10:20]),
decoders[2].input.eq(bitslip.o[20:30]),
decoders[3].input.eq(bitslip.o[30:40]),
# Connect decoder to output
self.k.eq(Cat(*[decoders[i].k for i in range(4)])),
self.d.eq(Cat(*[decoders[i].d for i in range(4)])),
]
# Status
idle_timer = WaitTimer(256)
self.submodules += idle_timer
self.comb += [
idle_timer.wait.eq(1),
self.idle.eq(idle_timer.done &
((bitslip.o == 0) | (bitslip.o == (2**40-1)))),
self.comma.eq(
(decoders[0].k == 1) & (decoders[0].d == K(28,5)) &
(decoders[1].k == 0) & (decoders[1].d == 0) &
(decoders[2].k == 0) & (decoders[2].d == 0) &
(decoders[3].k == 0) & (decoders[3].d == 0))
] ]
@ -209,5 +145,5 @@ class _KUSerdesRX(Module):
class KUSerdes(Module): class KUSerdes(Module):
def __init__(self, pads, mode="master"): def __init__(self, pads, mode="master"):
self.submodules.clocking = _KUSerdesClocking(pads, mode) self.submodules.clocking = _KUSerdesClocking(pads, mode)
self.submodules.tx = _KUSerdesTX(pads, mode) self.submodules.tx = _KUSerdesTX(pads)
self.submodules.rx = _KUSerdesRX(pads, mode) self.submodules.rx = _KUSerdesRX(pads)

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@ -4,14 +4,13 @@ from migen.genlib.misc import WaitTimer
from misoc.interconnect import stream from misoc.interconnect import stream
from misoc.interconnect.csr import * from misoc.interconnect.csr import *
from artiq.gateware.serwb.scrambler import Scrambler, Descrambler
from artiq.gateware.serwb.kuserdes import KUSerdes from artiq.gateware.serwb.kuserdes import KUSerdes
from artiq.gateware.serwb.s7serdes import S7Serdes from artiq.gateware.serwb.s7serdes import S7Serdes
# Master <--> Slave synchronization: # SERWB Master <--> Slave physical synchronization process:
# 1) Master sends idle pattern (zeroes) to reset Slave. # 1) Master sends idle patterns (zeroes) to Slave to reset it.
# 2) Master sends K28.5 commas to allow Slave to calibrate, Slave sends idle pattern. # 2) Master sends K28.5 commas to allow Slave to calibrate, Slave sends idle patterns.
# 3) Slave sends K28.5 commas to allow Master to calibrate, Master sends K28.5 commas. # 3) Slave sends K28.5 commas to allow Master to calibrate, Master sends K28.5 commas.
# 4) Master stops sending K28.5 commas. # 4) Master stops sending K28.5 commas.
# 5) Slave stops sending K28.5 commas. # 5) Slave stops sending K28.5 commas.
@ -360,34 +359,21 @@ class SERWBPHY(Module, AutoCSR):
self.submodules.init = _SerdesSlaveInit(self.serdes, taps, init_timeout) self.submodules.init = _SerdesSlaveInit(self.serdes, taps, init_timeout)
self.submodules.control = _SerdesControl(self.serdes, self.init, mode) self.submodules.control = _SerdesControl(self.serdes, self.init, mode)
# scrambling # tx/rx dataflow
self.submodules.scrambler = scrambler = Scrambler()
self.submodules.descrambler = descrambler = Descrambler()
# tx dataflow
self.comb += \
If(self.init.ready,
sink.connect(scrambler.sink),
scrambler.source.ack.eq(self.serdes.tx.ce),
If(scrambler.source.stb,
self.serdes.tx.d.eq(scrambler.source.d),
self.serdes.tx.k.eq(scrambler.source.k)
)
)
# rx dataflow
self.comb += [ self.comb += [
If(self.init.ready, If(self.init.ready,
descrambler.sink.stb.eq(self.serdes.rx.ce), sink.connect(self.serdes.tx.sink),
descrambler.sink.d.eq(self.serdes.rx.d), self.serdes.rx.source.connect(source)
descrambler.sink.k.eq(self.serdes.rx.k), ).Else(
descrambler.source.connect(source) self.serdes.rx.source.ack.eq(1)
), ),
# For PRBS test we are using the scrambler/descrambler as PRBS, self.serdes.tx.sink.stb.eq(1) # always transmitting
# sending 0 to the scrambler and checking that descrambler
# output is always 0.
self.control.prbs_error.eq(
descrambler.source.stb &
descrambler.source.ack &
(descrambler.source.data != 0))
] ]
# For PRBS test we are using the scrambler/descrambler as PRBS,
# sending 0 to the scrambler and checking that descrambler
# output is always 0.
self.comb += self.control.prbs_error.eq(
source.stb &
source.ack &
(source.data != 0))

View File

@ -5,9 +5,7 @@ from migen.genlib.misc import BitSlip, WaitTimer
from misoc.interconnect import stream from misoc.interconnect import stream
from misoc.cores.code_8b10b import Encoder, Decoder from misoc.cores.code_8b10b import Encoder, Decoder
from artiq.gateware.serwb.datapath import TXDatapath, RXDatapath
def K(x, y):
return (y << 5) | x
class _S7SerdesClocking(Module): class _S7SerdesClocking(Module):
@ -55,46 +53,20 @@ class _S7SerdesTX(Module):
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.sink = sink = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
# 8b10b encoder # Datapath
self.submodules.encoder = encoder = CEInserter()(Encoder(4, True)) self.submodules.datapath = datapath = TXDatapath(8)
self.comb += encoder.ce.eq(ce)
# 40 --> 8 converter
converter = stream.Converter(40, 8)
self.submodules += converter
self.comb += [ self.comb += [
converter.sink.stb.eq(1), sink.connect(datapath.sink),
converter.source.ack.eq(1), datapath.source.ack.eq(1),
# Enable pipeline when converter accepts the 40 bits datapath.idle.eq(idle),
ce.eq(converter.sink.ack), datapath.comma.eq(comma)
# If not idle, connect encoder to converter
If(~idle,
converter.sink.data.eq(Cat(*[encoder.output[i] for i in range(4)]))
),
# If comma, send K28.5
If(comma,
encoder.k[0].eq(1),
encoder.d[0].eq(K(28,5)),
# Else connect TX to encoder
).Else(
encoder.k[0].eq(k[0]),
encoder.k[1].eq(k[1]),
encoder.k[2].eq(k[2]),
encoder.k[3].eq(k[3]),
encoder.d[0].eq(d[0:8]),
encoder.d[1].eq(d[8:16]),
encoder.d[2].eq(d[16:24]),
encoder.d[3].eq(d[24:32])
)
] ]
# Data output (DDR with sys4x) # Output Data(DDR with sys4x)
data = Signal() data = Signal()
self.specials += [ self.specials += [
Instance("OSERDESE2", Instance("OSERDESE2",
@ -106,10 +78,10 @@ class _S7SerdesTX(Module):
i_OCE=1, i_OCE=1,
i_RST=ResetSignal("sys"), i_RST=ResetSignal("sys"),
i_CLK=ClockSignal("sys4x"), i_CLKDIV=ClockSignal("sys"), i_CLK=ClockSignal("sys4x"), i_CLKDIV=ClockSignal("sys"),
i_D1=converter.source.data[0], i_D2=converter.source.data[1], i_D1=datapath.source.data[0], i_D2=datapath.source.data[1],
i_D3=converter.source.data[2], i_D4=converter.source.data[3], i_D3=datapath.source.data[2], i_D4=datapath.source.data[3],
i_D5=converter.source.data[4], i_D6=converter.source.data[5], i_D5=datapath.source.data[4], i_D6=datapath.source.data[5],
i_D7=converter.source.data[6], i_D8=converter.source.data[7] i_D7=datapath.source.data[6], i_D8=datapath.source.data[7]
), ),
DifferentialOutput(data, pads.tx_p, pads.tx_n) DifferentialOutput(data, pads.tx_p, pads.tx_n)
] ]
@ -127,9 +99,7 @@ class _S7SerdesRX(Module):
self.comma = comma = Signal() self.comma = comma = Signal()
# Datapath # Datapath
self.ce = ce = Signal() self.source = source = stream.Endpoint([("data", 32)])
self.k = k = Signal(4)
self.d = d = Signal(32)
# # # # # #
@ -170,50 +140,15 @@ class _S7SerdesRX(Module):
) )
] ]
# 8 --> 40 converter and bitslip # Datapath
converter = stream.Converter(8, 40) self.submodules.datapath = datapath = RXDatapath(8)
self.submodules += converter
bitslip = CEInserter()(BitSlip(40))
self.submodules += bitslip
self.comb += [ self.comb += [
converter.sink.stb.eq(1), datapath.sink.stb.eq(1),
converter.source.ack.eq(1), datapath.sink.data.eq(data_deserialized),
# Enable pipeline when converter outputs the 40 bits datapath.bitslip_value.eq(bitslip_value),
ce.eq(converter.source.stb), datapath.source.connect(source),
# Connect input data to converter idle.eq(datapath.idle),
converter.sink.data.eq(data_deserialized), comma.eq(datapath.comma)
# Connect converter to bitslip
bitslip.ce.eq(ce),
bitslip.value.eq(bitslip_value),
bitslip.i.eq(converter.source.data)
]
# 8b10b decoder
self.submodules.decoders = decoders = [CEInserter()(Decoder(True)) for _ in range(4)]
self.comb += [decoders[i].ce.eq(ce) for i in range(4)]
self.comb += [
# Connect bitslip to decoder
decoders[0].input.eq(bitslip.o[0:10]),
decoders[1].input.eq(bitslip.o[10:20]),
decoders[2].input.eq(bitslip.o[20:30]),
decoders[3].input.eq(bitslip.o[30:40]),
# Connect decoder to output
self.k.eq(Cat(*[decoders[i].k for i in range(4)])),
self.d.eq(Cat(*[decoders[i].d for i in range(4)])),
]
# Status
idle_timer = WaitTimer(256)
self.submodules += idle_timer
self.comb += [
idle_timer.wait.eq(1),
self.idle.eq(idle_timer.done &
((bitslip.o == 0) | (bitslip.o == (2**40-1)))),
self.comma.eq(
(decoders[0].k == 1) & (decoders[0].d == K(28,5)) &
(decoders[1].k == 0) & (decoders[1].d == 0) &
(decoders[2].k == 0) & (decoders[2].d == 0) &
(decoders[3].k == 0) & (decoders[3].d == 0))
] ]