phy/ecp5rgmii.py: Add support for dynamic link speeds

This commit is contained in:
rowanG077 2023-07-14 17:00:45 +02:00
parent 64cceb24b1
commit 82d5f641e5
3 changed files with 278 additions and 28 deletions

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@ -8,6 +8,8 @@
# Copyright (c) 2023 LumiGuide Fietsdetectie B.V. <goemansrowan@gmail.com> # Copyright (c) 2023 LumiGuide Fietsdetectie B.V. <goemansrowan@gmail.com>
# SPDX-License-Identifier: BSD-2-Clause # SPDX-License-Identifier: BSD-2-Clause
import math
from liteeth.common import * from liteeth.common import *
from liteeth.mac import gap, preamble, crc, padding, last_be from liteeth.mac import gap, preamble, crc, padding, last_be
from liteeth.phy.model import LiteEthPHYModel from liteeth.phy.model import LiteEthPHYModel
@ -103,7 +105,14 @@ class LiteEthMACCore(Module, AutoCSR):
self.pipeline.append(tx_preamble) self.pipeline.append(tx_preamble)
def add_gap(self): def add_gap(self):
tx_gap = gap.LiteEthMACGap(phy_dw) # Some phys, ECP5 for example, have a byte time enable to support
# dynamic link speeds.
# In the gap inserter we need to ensure this is enable holds for
# the gap counter. If not we would insert a gap that might be too
# short.
default_gap = Constant(math.ceil(eth_interpacket_gap/(phy_dw//8)))
gap_len = getattr(phy, "gap", default_gap)
tx_gap = gap.LiteEthMACGap(phy_dw, gap_len)
tx_gap = ClockDomainsRenamer("eth_tx")(tx_gap) tx_gap = ClockDomainsRenamer("eth_tx")(tx_gap)
self.submodules += tx_gap self.submodules += tx_gap
self.pipeline.append(tx_gap) self.pipeline.append(tx_gap)

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@ -4,35 +4,33 @@
# Copyright (c) 2015-2021 Florent Kermarrec <florent@enjoy-digital.fr> # Copyright (c) 2015-2021 Florent Kermarrec <florent@enjoy-digital.fr>
# Copyright (c) 2015-2017 Sebastien Bourdeauducq <sb@m-labs.hk> # Copyright (c) 2015-2017 Sebastien Bourdeauducq <sb@m-labs.hk>
# Copyright (c) 2018 whitequark <whitequark@whitequark.org> # Copyright (c) 2018 whitequark <whitequark@whitequark.org>
# Copyright (c) 2023 LumiGuide Fietsdetectie B.V. <goemansrowan@gmail.com>
# SPDX-License-Identifier: BSD-2-Clause # SPDX-License-Identifier: BSD-2-Clause
import math
from liteeth.common import * from liteeth.common import *
# MAC Gap ------------------------------------------------------------------------------------------ # MAC Gap ------------------------------------------------------------------------------------------
class LiteEthMACGap(Module): class LiteEthMACGap(Module):
def __init__(self, dw): def __init__(self, dw, gap=None):
self.sink = sink = stream.Endpoint(eth_phy_description(dw)) self.sink = sink = stream.Endpoint(eth_phy_description(dw))
self.source = source = stream.Endpoint(eth_phy_description(dw)) self.source = source = stream.Endpoint(eth_phy_description(dw))
# # # # # #
counter_bits, _ = value_bits_sign(gap)
gap = math.ceil(eth_interpacket_gap/(dw//8)) counter = Signal(max=2**counter_bits, reset_less=True)
counter = Signal(max=gap, reset_less=True)
self.submodules.fsm = fsm = FSM(reset_state="COPY") self.submodules.fsm = fsm = FSM(reset_state="COPY")
fsm.act("COPY", fsm.act("COPY",
NextValue(counter, 0), NextValue(counter, gap),
sink.connect(source), sink.connect(source),
If(sink.valid & sink.last & sink.ready, If(sink.valid & sink.last & sink.ready,
NextState("GAP") NextState("GAP")
) )
) )
fsm.act("GAP", fsm.act("GAP",
NextValue(counter, counter + 1), NextValue(counter, counter - 1),
If(counter == (gap-1), If(counter == 1,
NextState("COPY") NextState("COPY")
) )
) )

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@ -9,6 +9,7 @@
from migen import * from migen import *
from migen.genlib.resetsync import AsyncResetSynchronizer from migen.genlib.resetsync import AsyncResetSynchronizer
from migen.genlib.cdc import MultiReg
from litex.gen import * from litex.gen import *
@ -17,10 +18,44 @@ from litex.build.io import DDROutput, DDRInput
from liteeth.common import * from liteeth.common import *
from liteeth.phy.common import * from liteeth.phy.common import *
# LiteEth PHY RGMII LINK Status --------------------------------------------------------------------
class LiteEthOneHotLinkState(LiteXModule):
def __init__(self):
# Encode link status as one hot so we can easily use a DFF synchronizer
self.link_up = Signal(reset_less=True)
self.link_10M = Signal(reset_less=True)
self.link_100M = Signal(reset_less=True)
self.link_1G = Signal(reset_less=True)
def synchronize(self, to, cd):
return [
MultiReg(
self.link_up,
to.link_up,
cd
),
MultiReg(
self.link_1G,
to.link_1G,
cd
),
MultiReg(
self.link_100M,
to.link_100M,
cd
),
MultiReg(
self.link_10M,
to.link_10M,
cd
)
]
# LiteEth PHY RGMII TX ----------------------------------------------------------------------------- # LiteEth PHY RGMII TX -----------------------------------------------------------------------------
class LiteEthPHYRGMIITX(LiteXModule): class LiteEthPHYRGMIITX(LiteXModule):
def __init__(self, pads): def __init__(self, pads, linkstate=None, clk_en=None):
self.sink = sink = stream.Endpoint(eth_phy_description(8)) self.sink = sink = stream.Endpoint(eth_phy_description(8))
# # # # # #
@ -28,11 +63,61 @@ class LiteEthPHYRGMIITX(LiteXModule):
tx_ctl_oddrx1f = Signal() tx_ctl_oddrx1f = Signal()
tx_data_oddrx1f = Signal(4) tx_data_oddrx1f = Signal(4)
valid = Signal()
data = Signal(8)
ready = Signal()
if linkstate is not None:
ready_next = Signal()
nibble_select = Signal()
# If link speed is not 1G we need to take care
# that the DDR lines only transfer 4-bit of data at a time
# This means we need to provide back pressure on non-1G link speeds
self.sync += If(clk_en,
ready_next.eq(~ready_next & sink.valid)
)
self.sync += If(linkstate.link_1G,
data.eq(sink.data)
).Elif(clk_en & nibble_select,
data.eq(Cat(sink.data[4:8], sink.data[4:8]))
).Elif(clk_en,
data.eq(Cat(sink.data[0:4], sink.data[0:4]))
)
self.sync += If(clk_en,
valid.eq(sink.valid)
)
self.sync += If(linkstate.link_1G,
ready.eq(1),
).Elif(clk_en,
ready.eq(ready_next)
).Else(
ready.eq(0)
)
self.sync += If(linkstate.link_1G,
nibble_select.eq(0)
).Elif(clk_en & sink.valid,
nibble_select.eq(~nibble_select)
).Else(
nibble_select.eq(nibble_select)
)
else:
self.comb += [
ready.eq(1),
valid.eq(sink.valid),
data.eq(sink.data)
]
self.specials += [ self.specials += [
DDROutput( DDROutput(
clk = ClockSignal("eth_tx"), clk = ClockSignal("eth_tx"),
i1 = sink.valid, i1 = valid,
i2 = sink.valid, i2 = valid,
o = tx_ctl_oddrx1f, o = tx_ctl_oddrx1f,
), ),
Instance("DELAYG", Instance("DELAYG",
@ -46,8 +131,8 @@ class LiteEthPHYRGMIITX(LiteXModule):
self.specials += [ self.specials += [
DDROutput( DDROutput(
clk = ClockSignal("eth_tx"), clk = ClockSignal("eth_tx"),
i1 = sink.data[i], i1 = data[i],
i2 = sink.data[4+i], i2 = data[4+i],
o = tx_data_oddrx1f[i], o = tx_data_oddrx1f[i],
), ),
Instance("DELAYG", Instance("DELAYG",
@ -57,12 +142,12 @@ class LiteEthPHYRGMIITX(LiteXModule):
o_Z = pads.tx_data[i], o_Z = pads.tx_data[i],
) )
] ]
self.comb += sink.ready.eq(1) self.comb += sink.ready.eq(ready)
# LiteEth PHY RGMII RX ----------------------------------------------------------------------------- # LiteEth PHY RGMII RX -----------------------------------------------------------------------------
class LiteEthPHYRGMIIRX(LiteXModule): class LiteEthPHYRGMIIRX(LiteXModule):
def __init__(self, pads, rx_delay=2e-9, with_inband_status=True): def __init__(self, pads, rx_delay=2e-9, with_inband_status=True, linkstate=None):
self.source = source = stream.Endpoint(eth_phy_description(8)) self.source = source = stream.Endpoint(eth_phy_description(8))
if with_inband_status: if with_inband_status:
@ -123,15 +208,46 @@ class LiteEthPHYRGMIIRX(LiteXModule):
o2 = rx_data[i+4], o2 = rx_data[i+4],
) )
] ]
self.sync += rx_data_reg.eq(rx_data)
rx_ctl_reg_d = Signal(2) # 1G has DDR, 100m and 10m are SDR on Rising edge only
self.sync += rx_ctl_reg_d.eq(rx_ctl_reg) valid_reg = Signal()
valid_last0 = Signal()
valid_last1 = Signal()
if linkstate is not None:
valid_sdr = Signal()
self.sync += If(linkstate.link_1G,
rx_data_reg.eq(rx_data),
).Else(
rx_data_reg.eq(Cat(rx_data_reg[4:8], rx_data[0:4])),
)
self.sync += If(linkstate.link_1G,
valid_sdr.eq(0),
valid_reg.eq(rx_ctl[0])
).Elif(rx_ctl[0],
valid_sdr.eq(~valid_sdr),
valid_reg.eq(valid_sdr)
).Else(
valid_reg.eq(valid_sdr)
)
self.sync += valid_last0.eq(rx_ctl[0])
else:
self.sync += [
rx_data_reg.eq(rx_data),
valid_reg.eq(rx_ctl[0])
]
self.comb += valid_last0.eq(valid_reg)
self.sync += valid_last1.eq(valid_last0)
last = Signal() last = Signal()
self.comb += last.eq(~rx_ctl_reg[0] & rx_ctl_reg_d[0]) self.comb += last.eq(~valid_last0 & valid_last1)
self.sync += [ self.sync += [
source.valid.eq(rx_ctl_reg[0]), source.valid.eq(valid_reg),
source.data.eq(rx_data_reg) source.data.eq(rx_data_reg)
] ]
self.comb += source.last.eq(last) self.comb += source.last.eq(last)
@ -142,13 +258,17 @@ class LiteEthPHYRGMIIRX(LiteXModule):
self.inband_status.fields.link_status.eq( rx_data[0]), self.inband_status.fields.link_status.eq( rx_data[0]),
self.inband_status.fields.clock_speed.eq( rx_data[1:3]), self.inband_status.fields.clock_speed.eq( rx_data[1:3]),
self.inband_status.fields.duplex_status.eq(rx_data[3]), self.inband_status.fields.duplex_status.eq(rx_data[3]),
linkstate.link_up.eq(rx_data[0]),
linkstate.link_10M.eq(rx_data[1:3] == 0b00),
linkstate.link_100M.eq(rx_data[1:3] == 0b01),
linkstate.link_1G.eq(rx_data[1:3] == 0b10),
) )
] ]
# LiteEth PHY RGMII CRG ---------------------------------------------------------------------------- # LiteEth PHY RGMII CRG ----------------------------------------------------------------------------
class LiteEthPHYRGMIICRG(LiteXModule): class LiteEthPHYRGMIICRG(LiteXModule):
def __init__(self, clock_pads, pads, with_hw_init_reset, tx_delay=2e-9, tx_clk=None): def __init__(self, clock_pads, pads, with_hw_init_reset, tx_delay=2e-9, tx_clk=None, linkstate_rx=None, linkstate_tx=None):
self._reset = CSRStorage() self._reset = CSRStorage()
# # # # # #
@ -167,12 +287,76 @@ class LiteEthPHYRGMIICRG(LiteXModule):
tx_delay_taps = int(tx_delay/25e-12) # 25ps per tap tx_delay_taps = int(tx_delay/25e-12) # 25ps per tap
assert tx_delay_taps < 128 assert tx_delay_taps < 128
self.tx_clk_en = Signal(reset_less=True)
rising_edge = Signal()
falling_edge = Signal()
# Without loop-clocking we need to divide the 125Mhz clock
# into either 25Mhz or 2.5Mhz. Some Phys require the clock to
# be glitchless
if linkstate_rx is not None and tx_clk is not None:
with_switch = Signal()
counter_switch = Signal(5)
counter = Signal(6)
counter_rst = Signal(1)
self.comb += counter_rst.eq(counter == 0)
# clock divider for 100M and 10M
self.sync.eth_tx += If(counter_rst,
If(linkstate_tx.link_10M,
with_switch.eq(0),
counter_switch.eq(24),
counter.eq(49)
).Elif(linkstate_tx.link_100M,
with_switch.eq(1),
counter_switch.eq(2),
counter.eq(4)
).Else(
with_switch.eq(1),
counter_switch.eq(0),
counter.eq(0)
)
).Else(
counter.eq(counter - 1)
)
at_switch = Signal()
self.comb += at_switch.eq(counter == counter_switch)
self.sync.eth_tx += If(with_switch & at_switch,
rising_edge.eq(1),
falling_edge.eq(0),
).Elif(counter > counter_switch,
rising_edge.eq(1),
falling_edge.eq(1),
).Else(
rising_edge.eq(0),
falling_edge.eq(0)
)
self.sync.eth_tx += self.tx_clk_en.eq(counter == 0)
# When loop clocking we don't need to divide the tx clock since it will
# allready be at the correct speed.
elif linkstate_rx is not None:
self.comb += [
self.tx_clk_en.eq(1),
rising_edge.eq(1),
falling_edge.eq(0)
]
else:
self.comb += [
rising_edge.eq(1),
falling_edge.eq(0)
]
eth_tx_clk_o = Signal() eth_tx_clk_o = Signal()
self.specials += [ self.specials += [
DDROutput( DDROutput(
clk = ClockSignal("eth_tx"), clk = ClockSignal("eth_tx"),
i1 = 1, i1 = rising_edge,
i2 = 0, i2 = falling_edge,
o = eth_tx_clk_o, o = eth_tx_clk_o,
), ),
Instance("DELAYG", Instance("DELAYG",
@ -207,11 +391,70 @@ class LiteEthPHYRGMII(LiteXModule):
rx_delay = 2e-9, rx_delay = 2e-9,
with_inband_status = True, with_inband_status = True,
tx_clk = None, tx_clk = None,
linkstate = None
): ):
self.crg = LiteEthPHYRGMIICRG(clock_pads, pads, with_hw_init_reset, tx_delay, tx_clk)
self.tx = ClockDomainsRenamer("eth_tx")(LiteEthPHYRGMIITX(pads)) # We cannot have two sources of linkstate
self.rx = ClockDomainsRenamer("eth_rx")(LiteEthPHYRGMIIRX(pads, rx_delay, with_inband_status)) assert not (linkstate is not None and with_inband_status)
linkstate_rx = None
linkstate_tx = None
if linkstate or with_inband_status:
linkstate_rx = LiteEthOneHotLinkState()
# If we have a source of link state from sys we need to sync it to rx clk
if linkstate:
self.specials += linkstate.synchronize(linkstate_rx, "eth_rx")
self.rx = ClockDomainsRenamer("eth_rx")(LiteEthPHYRGMIIRX(
pads, rx_delay, with_inband_status,
linkstate=linkstate_rx
))
if linkstate_rx is not None:
linkstate_tx = linkstate_rx
# If we aren't loop clocking the tx is clock is different from the rx
# clock and we need to synchronize
if tx_clk is not None:
linkstate_src = linkstate if linkstate is not None else linkstate_rx
linkstate_tx = LiteEthOneHotLinkState()
self.specials += linkstate_src.synchronize(linkstate_tx, "eth_tx")
if linkstate is None:
linkstate = LiteEthOneHotLinkState()
self.specials += linkstate_rx.synchronize(linkstate, "sys")
self.crg = LiteEthPHYRGMIICRG(
clock_pads, pads, with_hw_init_reset, tx_delay, tx_clk,
linkstate_rx, linkstate_tx
)
self.tx = ClockDomainsRenamer("eth_tx")(LiteEthPHYRGMIITX(
pads, linkstate=linkstate_rx, clk_en = self.crg.tx_clk_en
))
self.sink, self.source = self.tx.sink, self.rx.source self.sink, self.source = self.tx.sink, self.rx.source
# Create a custom gap length to paper over transmit clock and Phy
# internal clock periods beeing different
if linkstate is not None and tx_clk is not None:
self.gap = Signal(max=eth_interpacket_gap*100, reset_less = True)
self.sync += If(linkstate.link_1G,
self.gap.eq(eth_interpacket_gap)
).Elif(linkstate.link_100M,
self.gap.eq(eth_interpacket_gap*10)
).Else(
self.gap.eq(eth_interpacket_gap*100)
)
elif linkstate is not None:
self.gap = Signal(max=eth_interpacket_gap*2, reset_less = True)
self.sync += If(linkstate.link_1G,
self.gap.eq(eth_interpacket_gap)
).Else(
self.gap.eq(eth_interpacket_gap*2)
)
if hasattr(pads, "mdc"): if hasattr(pads, "mdc"):
self.mdio = LiteEthPHYMDIO(pads) self.mdio = LiteEthPHYMDIO(pads)