Merge branch 'drtio'

This commit is contained in:
Sebastien Bourdeauducq 2016-12-03 23:25:17 +08:00
commit 88ad054ab6
35 changed files with 4112 additions and 242 deletions

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# This is an example device database that needs to be adapted to your setup.
# The RTIO channel numbers here are for NIST CLOCK on KC705.
# The list of devices here is not exhaustive.
{
"comm": {
"type": "local",
"module": "artiq.coredevice.comm_tcp",
"class": "Comm",
"arguments": {"host": "kc705.lab.m-labs.hk"}
},
"core": {
"type": "local",
"module": "artiq.coredevice.core",
"class": "Core",
"arguments": {"ref_period": 2e-9}
},
"core_cache": {
"type": "local",
"module": "artiq.coredevice.cache",
"class": "CoreCache"
},
"rled0": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0},
},
"rled1": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 1},
},
"rled2": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 2},
},
"rled3": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 3},
},
"rled4": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 4},
},
"rled5": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 5},
},
"rled6": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 6},
},
"rled7": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 7},
},
"rsmap": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 8}
},
"rsman": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 9}
},
"led0": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010000},
},
"led1": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010001},
},
"led2": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010002},
},
"led3": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010003},
},
"led4": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010004},
},
"led5": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010005},
},
"led6": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010006},
},
"led7": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010007},
},
"smap": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010008}
},
"sman": {
"type": "local",
"module": "artiq.coredevice.ttl",
"class": "TTLOut",
"arguments": {"channel": 0x010009}
},
}

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from artiq.experiment import *
class BlinkForever(EnvExperiment):
def build(self):
self.setattr_device("core")
self.rleds = [self.get_device("rled" + str(i)) for i in range(8)]
self.leds = [self.get_device("led" + str(i)) for i in range(8)]
@kernel
def run(self):
self.core.reset()
while True:
with parallel:
for led in self.leds:
led.pulse(250*ms)
for led in self.rleds:
led.pulse(250*ms)
t = now_mu()
for led in self.leds:
at_mu(t)
led.pulse(500*ms)
for led in self.rleds:
at_mu(t)
led.pulse(500*ms)
delay(250*ms)

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from artiq.experiment import *
class PulseRate(EnvExperiment):
def build(self):
self.setattr_device("core")
self.setattr_device("rsmap")
@kernel
def run(self):
self.core.reset()
dt = self.core.seconds_to_mu(300*ns)
while True:
for i in range(10000):
try:
self.rsmap.pulse_mu(dt)
delay_mu(dt)
except RTIOUnderflow:
dt += 1
self.core.break_realtime()
break
else:
print(self.core.mu_to_seconds(dt))
return

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from artiq.gateware.drtio.core import DRTIOSatellite, DRTIOMaster

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from migen import *
from migen.fhdl.simplify import FullMemoryWE
from migen.genlib.cdc import MultiReg, PulseSynchronizer
from misoc.interconnect.csr import *
from misoc.interconnect import stream
from misoc.interconnect import wishbone
max_packet = 1024
class Transmitter(Module, AutoCSR):
def __init__(self, link_layer, min_mem_dw):
ll_dw = len(link_layer.tx_aux_data)
mem_dw = max(min_mem_dw, ll_dw)
self.aux_tx_length = CSRStorage(bits_for(max_packet),
alignment_bits=log2_int(mem_dw//8))
self.aux_tx = CSR()
self.specials.mem = Memory(mem_dw, max_packet//(mem_dw//8))
converter = stream.Converter(mem_dw, ll_dw)
self.submodules += converter
# when continuously fed, the Converter outputs data continuously
self.comb += [
converter.source.ack.eq(link_layer.tx_aux_ack),
link_layer.tx_aux_frame.eq(converter.source.stb),
link_layer.tx_aux_data.eq(converter.source.data)
]
seen_eop_rst = Signal()
frame_r = Signal()
seen_eop = Signal()
self.sync.rtio += [
If(link_layer.tx_aux_ack,
frame_r.eq(link_layer.tx_aux_frame),
If(frame_r & ~link_layer.tx_aux_frame, seen_eop.eq(1))
),
If(seen_eop_rst, seen_eop.eq(0))
]
mem_port = self.mem.get_port(clock_domain="rtio")
self.specials += mem_port
self.aux_tx_length.storage.attr.add("no_retiming")
tx_length = Signal(bits_for(max_packet))
self.specials += MultiReg(self.aux_tx_length.storage, tx_length, "rtio")
frame_counter_nbits = bits_for(max_packet) - log2_int(mem_dw//8)
frame_counter = Signal(frame_counter_nbits)
frame_counter_next = Signal(frame_counter_nbits)
frame_counter_ce = Signal()
frame_counter_rst = Signal()
self.comb += [
frame_counter_next.eq(frame_counter),
If(frame_counter_rst,
frame_counter_next.eq(0)
).Elif(frame_counter_ce,
frame_counter_next.eq(frame_counter + 1)
),
mem_port.adr.eq(frame_counter_next),
converter.sink.data.eq(mem_port.dat_r)
]
self.sync.rtio += frame_counter.eq(frame_counter_next)
start_tx = PulseSynchronizer("sys", "rtio")
tx_done = PulseSynchronizer("rtio", "sys")
self.submodules += start_tx, tx_done
self.comb += start_tx.i.eq(self.aux_tx.re)
self.sync += [
If(tx_done.o, self.aux_tx.w.eq(0)),
If(self.aux_tx.re, self.aux_tx.w.eq(1))
]
fsm = ClockDomainsRenamer("rtio")(FSM(reset_state="IDLE"))
self.submodules += fsm
fsm.act("IDLE",
frame_counter_rst.eq(1),
seen_eop_rst.eq(1),
If(start_tx.o, NextState("TRANSMIT"))
)
fsm.act("TRANSMIT",
converter.sink.stb.eq(1),
If(converter.sink.ack,
frame_counter_ce.eq(1)
),
If(frame_counter_next == tx_length, NextState("WAIT_INTERFRAME"))
)
fsm.act("WAIT_INTERFRAME",
If(seen_eop,
tx_done.i.eq(1),
NextState("IDLE")
)
)
class Receiver(Module, AutoCSR):
def __init__(self, link_layer, min_mem_dw):
self.aux_rx_length = CSRStatus(bits_for(max_packet))
self.aux_rx_present = CSR()
self.aux_rx_error = CSR()
ll_dw = len(link_layer.rx_aux_data)
mem_dw = max(min_mem_dw, ll_dw)
self.specials.mem = Memory(mem_dw, max_packet//(mem_dw//8))
converter = stream.Converter(ll_dw, mem_dw)
self.submodules += converter
# when continuously drained, the Converter accepts data continuously
frame_r = Signal()
self.sync.rtio_rx += [
If(link_layer.rx_aux_stb,
frame_r.eq(link_layer.rx_aux_frame),
converter.sink.data.eq(link_layer.rx_aux_data)
)
]
self.comb += [
converter.sink.stb.eq(link_layer.rx_aux_stb & frame_r),
converter.sink.eop.eq(converter.sink.stb & ~link_layer.rx_aux_frame)
]
mem_port = self.mem.get_port(write_capable=True, clock_domain="rtio_rx")
self.specials += mem_port
frame_counter_nbits = bits_for(max_packet) - log2_int(mem_dw//8)
frame_counter = Signal(frame_counter_nbits)
self.comb += [
mem_port.adr.eq(frame_counter),
mem_port.dat_w.eq(converter.source.data),
converter.source.ack.eq(1)
]
frame_counter.attr.add("no_retiming")
frame_counter_sys = Signal(frame_counter_nbits)
self.specials += MultiReg(frame_counter, frame_counter_sys)
self.comb += self.aux_rx_length.status.eq(frame_counter_sys << log2_int(mem_dw//8))
signal_frame = PulseSynchronizer("rtio_rx", "sys")
frame_ack = PulseSynchronizer("sys", "rtio_rx")
signal_error = PulseSynchronizer("rtio_rx", "sys")
self.submodules += signal_frame, frame_ack, signal_error
self.sync += [
If(self.aux_rx_present.re, self.aux_rx_present.w.eq(0)),
If(signal_frame.o, self.aux_rx_present.w.eq(1)),
If(self.aux_rx_error.re, self.aux_rx_error.w.eq(0)),
If(signal_error.o, self.aux_rx_error.w.eq(1))
]
self.comb += frame_ack.i.eq(self.aux_rx_present.re)
fsm = ClockDomainsRenamer("rtio_rx")(FSM(reset_state="IDLE"))
self.submodules += fsm
sop = Signal(reset=1)
self.sync.rtio_rx += \
If(converter.source.stb,
If(converter.source.eop,
sop.eq(1)
).Else(
sop.eq(0)
)
)
fsm.act("IDLE",
If(converter.source.stb & sop,
NextValue(frame_counter, frame_counter + 1),
mem_port.we.eq(1),
If(converter.source.eop,
NextState("SIGNAL_FRAME")
).Else(
NextState("FRAME")
)
).Else(
NextValue(frame_counter, 0)
)
)
fsm.act("FRAME",
If(converter.source.stb,
NextValue(frame_counter, frame_counter + 1),
mem_port.we.eq(1),
If(frame_counter == max_packet,
mem_port.we.eq(0),
signal_error.i.eq(1),
NextState("IDLE") # discard the rest of the frame
),
If(converter.source.eop,
NextState("SIGNAL_FRAME")
)
)
)
fsm.act("SIGNAL_FRAME",
signal_frame.i.eq(1),
NextState("WAIT_ACK"),
If(converter.source.stb, signal_error.i.eq(1))
)
fsm.act("WAIT_ACK",
If(frame_ack.o,
NextValue(frame_counter, 0),
NextState("IDLE")
),
If(converter.source.stb, signal_error.i.eq(1))
)
# TODO: FullMemoryWE should be applied by migen.build
@FullMemoryWE()
class AuxController(Module):
def __init__(self, link_layer):
self.bus = wishbone.Interface()
self.submodules.transmitter = Transmitter(link_layer, len(self.bus.dat_w))
self.submodules.receiver = Receiver(link_layer, len(self.bus.dat_w))
tx_sdram_if = wishbone.SRAM(self.transmitter.mem, read_only=False)
rx_sdram_if = wishbone.SRAM(self.receiver.mem, read_only=True)
wsb = log2_int(len(self.bus.dat_w)//8)
decoder = wishbone.Decoder(self.bus,
[(lambda a: a[log2_int(max_packet)-wsb] == 0, tx_sdram_if.bus),
(lambda a: a[log2_int(max_packet)-wsb] == 1, rx_sdram_if.bus)],
register=True)
self.submodules += tx_sdram_if, rx_sdram_if, decoder
def get_csrs(self):
return self.transmitter.get_csrs() + self.receiver.get_csrs()

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from types import SimpleNamespace
from migen import *
from artiq.gateware.drtio import link_layer, rt_packets, iot, rt_controller, aux_controller
class DRTIOSatellite(Module):
def __init__(self, transceiver, rx_synchronizer, channels, fine_ts_width=3, full_ts_width=63):
self.submodules.link_layer = link_layer.LinkLayer(
transceiver.encoder, transceiver.decoders)
self.comb += self.link_layer.rx_ready.eq(transceiver.rx_ready)
link_layer_sync = SimpleNamespace(
tx_aux_frame=self.link_layer.tx_aux_frame,
tx_aux_data=self.link_layer.tx_aux_data,
tx_aux_ack=self.link_layer.tx_aux_ack,
tx_rt_frame=self.link_layer.tx_rt_frame,
tx_rt_data=self.link_layer.tx_rt_data,
rx_aux_stb=rx_synchronizer.resync(self.link_layer.rx_aux_stb),
rx_aux_frame=rx_synchronizer.resync(self.link_layer.rx_aux_frame),
rx_aux_data=rx_synchronizer.resync(self.link_layer.rx_aux_data),
rx_rt_frame=rx_synchronizer.resync(self.link_layer.rx_rt_frame),
rx_rt_data=rx_synchronizer.resync(self.link_layer.rx_rt_data)
)
self.submodules.rt_packets = ClockDomainsRenamer("rtio")(
rt_packets.RTPacketSatellite(link_layer_sync))
self.submodules.iot = iot.IOT(
self.rt_packets, channels, fine_ts_width, full_ts_width)
self.clock_domains.cd_rio = ClockDomain()
self.clock_domains.cd_rio_phy = ClockDomain()
self.comb += [
self.cd_rio.clk.eq(ClockSignal("rtio")),
self.cd_rio.rst.eq(self.rt_packets.reset),
self.cd_rio_phy.clk.eq(ClockSignal("rtio")),
self.cd_rio_phy.rst.eq(self.rt_packets.reset_phy),
]
self.submodules.aux_controller = aux_controller.AuxController(
self.link_layer)
def get_csrs(self):
return self.aux_controller.get_csrs()
class DRTIOMaster(Module):
def __init__(self, transceiver, channel_count=1024, fine_ts_width=3):
self.submodules.link_layer = link_layer.LinkLayer(
transceiver.encoder, transceiver.decoders)
self.comb += self.link_layer.rx_ready.eq(transceiver.rx_ready)
self.submodules.rt_packets = rt_packets.RTPacketMaster(self.link_layer)
self.submodules.rt_controller = rt_controller.RTController(
self.rt_packets, channel_count, fine_ts_width)
self.submodules.rt_manager = rt_controller.RTManager(self.rt_packets)
self.cri = self.rt_controller.cri
self.submodules.aux_controller = aux_controller.AuxController(
self.link_layer)
def get_csrs(self):
return (self.link_layer.get_csrs() +
self.rt_controller.get_csrs() +
self.rt_manager.get_csrs() +
self.aux_controller.get_csrs())

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from migen import *
from migen.genlib.fifo import SyncFIFOBuffered
from migen.genlib.record import *
from artiq.gateware.rtio import rtlink
class IOT(Module):
def __init__(self, rt_packets, channels, max_fine_ts_width, full_ts_width):
tsc = Signal(full_ts_width - max_fine_ts_width)
self.sync.rtio += \
If(rt_packets.tsc_load,
tsc.eq(rt_packets.tsc_value)
).Else(
tsc.eq(tsc + 1)
)
for n, channel in enumerate(channels):
interface = channel.interface.o
data_width = rtlink.get_data_width(interface)
address_width = rtlink.get_address_width(interface)
fine_ts_width = rtlink.get_fine_ts_width(interface)
assert fine_ts_width <= max_fine_ts_width
# FIFO
ev_layout = []
if data_width:
ev_layout.append(("data", data_width))
if address_width:
ev_layout.append(("address", address_width))
ev_layout.append(("timestamp", len(tsc) + fine_ts_width))
fifo = ClockDomainsRenamer("rio")(
SyncFIFOBuffered(layout_len(ev_layout), channel.ofifo_depth))
self.submodules += fifo
fifo_in = Record(ev_layout)
fifo_out = Record(ev_layout)
self.comb += [
fifo.din.eq(fifo_in.raw_bits()),
fifo_out.raw_bits().eq(fifo.dout)
]
# FIFO level
self.sync.rio += \
If(rt_packets.fifo_space_update &
(rt_packets.fifo_space_channel == n),
rt_packets.fifo_space.eq(channel.ofifo_depth - fifo.level))
# FIFO write
self.comb += fifo.we.eq(rt_packets.write_stb
& (rt_packets.write_channel == n))
self.sync.rio += [
If(rt_packets.write_overflow_ack,
rt_packets.write_overflow.eq(0)),
If(rt_packets.write_underflow_ack,
rt_packets.write_underflow.eq(0)),
If(fifo.we,
If(~fifo.writable, rt_packets.write_overflow.eq(1)),
If(rt_packets.write_timestamp[max_fine_ts_width:] < (tsc + 4),
rt_packets.write_underflow.eq(1)
)
)
]
if data_width:
self.comb += fifo_in.data.eq(rt_packets.write_data)
if address_width:
self.comb += fifo_in.address.eq(rt_packets.write_address)
self.comb += fifo_in.timestamp.eq(
rt_packets.write_timestamp[max_fine_ts_width-fine_ts_width:])
# FIFO read
self.sync.rio += [
fifo.re.eq(0),
interface.stb.eq(0),
If(fifo.readable &
(fifo_out.timestamp[fine_ts_width:] == tsc),
fifo.re.eq(1),
interface.stb.eq(1)
)
]
if data_width:
self.sync.rio += interface.data.eq(fifo_out.data)
if address_width:
self.sync.rio += interface.address.eq(fifo_out.address)
if fine_ts_width:
self.sync.rio += interface.fine_ts.eq(fifo_out.timestamp[:fine_ts_width])

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from functools import reduce
from operator import xor, or_
from migen import *
from migen.genlib.fsm import *
from migen.genlib.cdc import MultiReg
from migen.genlib.misc import WaitTimer
from misoc.interconnect.csr import *
class Scrambler(Module):
def __init__(self, n_io1, n_io2, n_state=23, taps=[17, 22]):
self.i1 = Signal(n_io1)
self.o1 = Signal(n_io1)
self.i2 = Signal(n_io2)
self.o2 = Signal(n_io2)
self.sel = Signal()
# # #
state = Signal(n_state, reset=1)
stmts1 = []
stmts2 = []
for stmts, si, so in ((stmts1, self.i1, self.o1),
(stmts2, self.i2, self.o2)):
curval = [state[i] for i in range(n_state)]
for i in reversed(range(len(si))):
out = si[i] ^ reduce(xor, [curval[tap] for tap in taps])
stmts += [so[i].eq(out)]
curval.insert(0, out)
curval.pop()
stmts += [state.eq(Cat(*curval[:n_state]))]
self.sync += If(self.sel, stmts2).Else(stmts1)
class Descrambler(Module):
def __init__(self, n_io1, n_io2, n_state=23, taps=[17, 22]):
self.i1 = Signal(n_io1)
self.o1 = Signal(n_io1)
self.i2 = Signal(n_io2)
self.o2 = Signal(n_io2)
self.sel = Signal()
# # #
state = Signal(n_state, reset=1)
stmts1 = []
stmts2 = []
for stmts, si, so in ((stmts1, self.i1, self.o1),
(stmts2, self.i2, self.o2)):
curval = [state[i] for i in range(n_state)]
for i in reversed(range(len(si))):
flip = reduce(xor, [curval[tap] for tap in taps])
stmts += [so[i].eq(si[i] ^ flip)]
curval.insert(0, si[i])
curval.pop()
stmts += [state.eq(Cat(*curval[:n_state]))]
self.sync += If(self.sel, stmts2).Else(stmts1)
def K(x, y):
return (y << 5) | x
aux_coding_comma = [
K(28, 5),
K(28, 0),
K(28, 1),
K(28, 2),
K(23, 7),
K(27, 7),
K(29, 7),
K(30, 7),
]
aux_coding_nocomma = [
K(28, 0),
K(28, 2),
K(28, 3),
K(28, 4),
K(23, 7),
K(27, 7),
K(29, 7),
K(30, 7),
]
class LinkLayerTX(Module):
def __init__(self, encoder):
nwords = len(encoder.k)
# nwords must be a power of 2
assert nwords & (nwords - 1) == 0
self.aux_frame = Signal()
self.aux_data = Signal(2*nwords)
self.aux_ack = Signal()
self.rt_frame = Signal()
self.rt_data = Signal(8*nwords)
# # #
# Idle and auxiliary traffic use special characters defined in the
# aux_coding_* tables.
# The first (or only) character uses aux_coding_comma which guarantees
# that commas appear regularly in the absence of traffic.
# The subsequent characters, if any (depending on the transceiver
# serialization ratio) use aux_coding_nocomma which does not contain
# commas. This permits aligning the comma to the first character at
# the receiver.
#
# A set of 8 special characters is chosen using a 3-bit control word.
# This control word is scrambled to reduce EMI. The control words have
# the following meanings:
# 100 idle/auxiliary framing
# 0AB 2 bits of auxiliary data
#
# RT traffic uses D characters and is also scrambled. The aux and RT
# scramblers are multiplicative and share the same state so that idle
# or aux traffic can synchronize the RT descrambler.
scrambler = Scrambler(3*nwords, 8*nwords)
self.submodules += scrambler
# scrambler input
aux_data_ctl = []
for i in range(nwords):
aux_data_ctl.append(self.aux_data[i*2:i*2+2])
aux_data_ctl.append(0)
self.comb += [
If(self.aux_frame,
scrambler.i1.eq(Cat(*aux_data_ctl))
).Else(
scrambler.i1.eq(Replicate(0b100, nwords))
),
scrambler.i2.eq(self.rt_data),
scrambler.sel.eq(self.rt_frame),
self.aux_ack.eq(~self.rt_frame)
]
# compensate for scrambler latency
rt_frame_r = Signal()
self.sync += rt_frame_r.eq(self.rt_frame)
# scrambler output
for i in range(nwords):
scrambled_ctl = scrambler.o1[i*3:i*3+3]
if i:
aux_coding = aux_coding_nocomma
else:
aux_coding = aux_coding_comma
self.sync += [
encoder.k[i].eq(1),
encoder.d[i].eq(Array(aux_coding)[scrambled_ctl])
]
self.sync += \
If(rt_frame_r,
[k.eq(0) for k in encoder.k],
[d.eq(scrambler.o2[i*8:i*8+8]) for i, d in enumerate(encoder.d)]
)
class LinkLayerRX(Module):
def __init__(self, decoders):
nwords = len(decoders)
# nwords must be a power of 2
assert nwords & (nwords - 1) == 0
self.aux_stb = Signal()
self.aux_frame = Signal()
self.aux_data = Signal(2*nwords)
self.rt_frame = Signal()
self.rt_data = Signal(8*nwords)
# # #
descrambler = Descrambler(3*nwords, 8*nwords)
self.submodules += descrambler
# scrambler input
all_decoded_aux = []
for i, d in enumerate(decoders):
decoded_aux = Signal(3)
all_decoded_aux.append(decoded_aux)
if i:
aux_coding = aux_coding_nocomma
else:
aux_coding = aux_coding_comma
cases = {code: decoded_aux.eq(i) for i, code in enumerate(aux_coding)}
self.comb += Case(d.d, cases).makedefault()
self.comb += [
descrambler.i1.eq(Cat(*all_decoded_aux)),
descrambler.i2.eq(Cat(*[d.d for d in decoders])),
descrambler.sel.eq(~decoders[0].k)
]
# scrambler output
self.comb += [
self.aux_frame.eq(~descrambler.o1[2]),
self.aux_data.eq(
Cat(*[descrambler.o1[3*i:3*i+2] for i in range(nwords)])),
self.rt_data.eq(descrambler.o2)
]
self.sync += [
self.aux_stb.eq(decoders[0].k),
self.rt_frame.eq(~decoders[0].k)
]
class LinkLayer(Module, AutoCSR):
def __init__(self, encoder, decoders):
self.link_status = CSRStatus()
# receiver locked, comma aligned, receiving valid 8b10b symbols
self.rx_ready = Signal()
tx = ClockDomainsRenamer("rtio")(LinkLayerTX(encoder))
rx = ClockDomainsRenamer("rtio_rx")(LinkLayerRX(decoders))
self.submodules += tx, rx
# in rtio clock domain
self.tx_aux_frame = tx.aux_frame
self.tx_aux_data = tx.aux_data
self.tx_aux_ack = tx.aux_ack
self.tx_rt_frame = tx.rt_frame
self.tx_rt_data = tx.rt_data
# in rtio_rx clock domain
self.rx_aux_stb = rx.aux_stb
self.rx_aux_frame = Signal()
self.rx_aux_data = rx.aux_data
self.rx_rt_frame = Signal()
self.rx_rt_data = rx.rt_data
# # #
ready = Signal()
ready_r = Signal()
self.sync.rtio += ready_r.eq(ready)
ready_rx = Signal()
ready_r.attr.add("no_retiming")
self.specials += MultiReg(ready_r, ready_rx, "rtio_rx")
self.comb += [
self.rx_aux_frame.eq(rx.aux_frame & ready_rx),
self.rx_rt_frame.eq(rx.rt_frame & ready_rx),
]
self.specials += MultiReg(ready_r, self.link_status.status)
wait_scrambler = ClockDomainsRenamer("rtio")(WaitTimer(15))
self.submodules += wait_scrambler
fsm = ClockDomainsRenamer("rtio")(FSM(reset_state="WAIT_RX_READY"))
self.submodules += fsm
fsm.act("WAIT_RX_READY",
If(self.rx_ready, NextState("WAIT_SCRAMBLER_SYNC"))
)
fsm.act("WAIT_SCRAMBLER_SYNC",
wait_scrambler.wait.eq(1),
If(wait_scrambler.done, NextState("READY"))
)
fsm.act("READY",
ready.eq(1),
If(~self.rx_ready, NextState("WAIT_RX_READY"))
)

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from migen import *
from migen.genlib.cdc import MultiReg
from migen.genlib.misc import WaitTimer
from misoc.interconnect.csr import *
from artiq.gateware.rtio.cdc import RTIOCounter
from artiq.gateware.rtio import cri
class _CSRs(AutoCSR):
def __init__(self):
self.chan_sel_override = CSRStorage(16)
self.chan_sel_override_en = CSRStorage()
self.tsc_correction = CSRStorage(64)
self.set_time = CSR()
self.underflow_margin = CSRStorage(16, reset=200)
self.o_get_fifo_space = CSR()
self.o_dbg_fifo_space = CSRStatus(16)
self.o_dbg_last_timestamp = CSRStatus(64)
self.o_reset_channel_status = CSR()
self.o_wait = CSRStatus()
self.o_fifo_space_timeout = CSR()
class RTController(Module):
def __init__(self, rt_packets, channel_count, fine_ts_width):
self.csrs = _CSRs()
self.cri = cri.Interface()
self.comb += self.cri.arb_gnt.eq(1)
# channel selection
chan_sel = Signal(16)
self.comb += chan_sel.eq(
Mux(self.csrs.chan_sel_override_en.storage,
self.csrs.chan_sel_override.storage,
self.cri.chan_sel[:16]))
# master RTIO counter and counter synchronization
self.submodules.counter = RTIOCounter(64-fine_ts_width)
self.comb += self.cri.counter.eq(self.counter.value_sys << fine_ts_width)
tsc_correction = Signal(64)
self.csrs.tsc_correction.storage.attr.add("no_retiming")
self.specials += MultiReg(self.csrs.tsc_correction.storage, tsc_correction)
self.comb += [
rt_packets.tsc_value.eq(
self.counter.value_rtio + tsc_correction),
self.csrs.set_time.w.eq(rt_packets.set_time_stb)
]
self.sync += [
If(rt_packets.set_time_ack, rt_packets.set_time_stb.eq(0)),
If(self.csrs.set_time.re, rt_packets.set_time_stb.eq(1))
]
# reset
self.sync += [
If(rt_packets.reset_ack, rt_packets.reset_stb.eq(0)),
If(self.cri.cmd == cri.commands["reset"],
rt_packets.reset_stb.eq(1),
rt_packets.reset_phy.eq(0)
),
If(self.cri.cmd == cri.commands["reset_phy"],
rt_packets.reset_stb.eq(1),
rt_packets.reset_phy.eq(1)
),
]
# remote channel status cache
fifo_spaces_mem = Memory(16, channel_count)
fifo_spaces = fifo_spaces_mem.get_port(write_capable=True)
self.specials += fifo_spaces_mem, fifo_spaces
last_timestamps_mem = Memory(64, channel_count)
last_timestamps = last_timestamps_mem.get_port(write_capable=True)
self.specials += last_timestamps_mem, last_timestamps
# common packet fields
rt_packets_fifo_request = Signal()
self.comb += [
fifo_spaces.adr.eq(chan_sel),
last_timestamps.adr.eq(chan_sel),
last_timestamps.dat_w.eq(self.cri.o_timestamp),
rt_packets.write_channel.eq(chan_sel),
rt_packets.write_address.eq(self.cri.o_address),
rt_packets.write_data.eq(self.cri.o_data),
If(rt_packets_fifo_request,
rt_packets.write_timestamp.eq(0xffff000000000000)
).Else(
rt_packets.write_timestamp.eq(self.cri.o_timestamp)
)
]
fsm = FSM()
self.submodules += fsm
status_wait = Signal()
status_underflow = Signal()
status_sequence_error = Signal()
self.comb += [
self.cri.o_status.eq(Cat(
status_wait, status_underflow, status_sequence_error)),
self.csrs.o_wait.status.eq(status_wait)
]
sequence_error_set = Signal()
underflow_set = Signal()
self.sync += [
If(self.cri.cmd == cri.commands["o_underflow_reset"], status_underflow.eq(0)),
If(self.cri.cmd == cri.commands["o_sequence_error_reset"], status_sequence_error.eq(0)),
If(underflow_set, status_underflow.eq(1)),
If(sequence_error_set, status_sequence_error.eq(1)),
]
signal_fifo_space_timeout = Signal()
self.sync += [
If(self.csrs.o_fifo_space_timeout.re, self.csrs.o_fifo_space_timeout.w.eq(0)),
If(signal_fifo_space_timeout, self.csrs.o_fifo_space_timeout.w.eq(1))
]
timeout_counter = WaitTimer(8191)
self.submodules += timeout_counter
# TODO: collision, replace, busy
cond_sequence_error = self.cri.o_timestamp < last_timestamps.dat_r
cond_underflow = ((self.cri.o_timestamp[fine_ts_width:]
- self.csrs.underflow_margin.storage[fine_ts_width:]) < self.counter.value_sys)
cond_fifo_emptied = ((last_timestamps.dat_r[fine_ts_width:] < self.counter.value_sys)
& (last_timestamps.dat_r != 0))
fsm.act("IDLE",
If(self.cri.cmd == cri.commands["write"],
If(cond_sequence_error,
sequence_error_set.eq(1)
).Elif(cond_underflow,
underflow_set.eq(1)
).Else(
NextState("WRITE")
)
),
If(self.csrs.o_get_fifo_space.re,
NextState("GET_FIFO_SPACE")
)
)
fsm.act("WRITE",
status_wait.eq(1),
rt_packets.write_stb.eq(1),
If(rt_packets.write_ack,
fifo_spaces.we.eq(1),
If(cond_fifo_emptied,
fifo_spaces.dat_w.eq(1),
).Else(
fifo_spaces.dat_w.eq(fifo_spaces.dat_r - 1)
),
last_timestamps.we.eq(1),
If(~cond_fifo_emptied & (fifo_spaces.dat_r <= 1),
NextState("GET_FIFO_SPACE")
).Else(
NextState("IDLE")
)
)
)
fsm.act("GET_FIFO_SPACE",
status_wait.eq(1),
rt_packets_fifo_request.eq(1),
rt_packets.write_stb.eq(1),
If(rt_packets.write_ack,
NextState("GET_FIFO_SPACE_REPLY")
)
)
fsm.act("GET_FIFO_SPACE_REPLY",
status_wait.eq(1),
fifo_spaces.dat_w.eq(rt_packets.fifo_space),
fifo_spaces.we.eq(1),
rt_packets.fifo_space_not_ack.eq(1),
If(rt_packets.fifo_space_not,
If(rt_packets.fifo_space > 0,
NextState("IDLE")
).Else(
NextState("GET_FIFO_SPACE")
)
),
timeout_counter.wait.eq(1),
If(timeout_counter.done,
signal_fifo_space_timeout.eq(1),
NextState("IDLE")
)
)
# channel state access
self.comb += [
self.csrs.o_dbg_fifo_space.status.eq(fifo_spaces.dat_r),
self.csrs.o_dbg_last_timestamp.status.eq(last_timestamps.dat_r),
If(self.csrs.o_reset_channel_status.re,
fifo_spaces.dat_w.eq(0),
fifo_spaces.we.eq(1),
last_timestamps.dat_w.eq(0),
last_timestamps.we.eq(1)
)
]
def get_csrs(self):
return self.csrs.get_csrs()
class RTManager(Module, AutoCSR):
def __init__(self, rt_packets):
self.request_echo = CSR()
self.packet_err_present = CSR()
self.packet_err_code = CSRStatus(8)
self.update_packet_cnt = CSR()
self.packet_cnt_tx = CSRStatus(32)
self.packet_cnt_rx = CSRStatus(32)
# # #
self.comb += self.request_echo.w.eq(rt_packets.echo_stb)
self.sync += [
If(rt_packets.echo_ack, rt_packets.echo_stb.eq(0)),
If(self.request_echo.re, rt_packets.echo_stb.eq(1))
]
self.comb += [
self.packet_err_present.w.eq(rt_packets.error_not),
rt_packets.error_not_ack.eq(self.packet_err_present.re),
self.packet_err_code.status.eq(rt_packets.error_code)
]
self.sync += \
If(self.update_packet_cnt.re,
self.packet_cnt_tx.status.eq(rt_packets.packet_cnt_tx),
self.packet_cnt_rx.status.eq(rt_packets.packet_cnt_rx)
)

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from types import SimpleNamespace
from migen import *
from migen.genlib.fsm import *
from migen.genlib.fifo import AsyncFIFO
from migen.genlib.cdc import PulseSynchronizer
from artiq.gateware.rtio.cdc import GrayCodeTransfer
def layout_len(l):
return sum(e[1] for e in l)
class PacketLayoutManager:
def __init__(self, alignment):
self.alignment = alignment
self.layouts = dict()
self.types = dict()
self.type_names = dict()
def add_type(self, name, *fields, pad=True):
type_n = len(self.types)
self.types[name] = type_n
self.type_names[type_n] = name
layout = [("ty", 8)] + list(fields)
misalignment = layout_len(layout) % self.alignment
if misalignment:
layout.append(("packet_pad", self.alignment - misalignment))
self.layouts[name] = layout
def field_length(self, type_name, field_name):
layout = self.layouts[type_name]
for name, length in layout:
if name == field_name:
return length
raise KeyError
def get_m2s_layouts(alignment):
if alignment > 128:
short_data_len = alignment - 128 + 16
else:
short_data_len = 16
plm = PacketLayoutManager(alignment)
plm.add_type("echo_request")
plm.add_type("set_time", ("timestamp", 64))
plm.add_type("reset", ("phy", 1))
plm.add_type("write", ("timestamp", 64),
("channel", 16),
("address", 16),
("extra_data_cnt", 8),
("short_data", short_data_len))
plm.add_type("fifo_space_request", ("channel", 16))
return plm
def get_s2m_layouts(alignment):
plm = PacketLayoutManager(alignment)
plm.add_type("error", ("code", 8))
plm.add_type("echo_reply")
plm.add_type("fifo_space_reply", ("space", 16))
return plm
error_codes = {
"unknown_type_local": 0,
"unknown_type_remote": 1,
# The transmitter is normally responsible for avoiding
# overflows and underflows. Those error reports are only
# for diagnosing internal ARTIQ bugs.
"write_overflow": 2,
"write_underflow": 3
}
class ReceiveDatapath(Module):
def __init__(self, frame, data, plm):
ws = len(data)
# control
self.packet_buffer_load = Signal()
# outputs
self.frame_r = Signal()
self.data_r = Signal(ws)
self.packet_type = Signal(8)
self.packet_last = Signal()
self.packet_as = dict()
# # #
# input pipeline stage - determine packet length based on type
lastword_per_type = [layout_len(plm.layouts[plm.type_names[i]])//ws - 1
for i in range(len(plm.layouts))]
packet_last_n = Signal(max=max(lastword_per_type)+1)
self.sync += [
self.frame_r.eq(frame),
self.data_r.eq(data),
If(frame & ~self.frame_r,
self.packet_type.eq(data[:8]),
packet_last_n.eq(Array(lastword_per_type)[data[:8]])
)
]
# bufferize packet
packet_buffer = Signal(max(layout_len(l)
for l in plm.layouts.values()))
w_in_packet = len(packet_buffer)//ws
packet_buffer_count = Signal(max=w_in_packet+1)
self.sync += \
If(self.packet_buffer_load,
Case(packet_buffer_count,
{i: packet_buffer[i*ws:(i+1)*ws].eq(self.data_r)
for i in range(w_in_packet)}),
packet_buffer_count.eq(packet_buffer_count + 1)
).Else(
packet_buffer_count.eq(0)
)
self.comb += self.packet_last.eq(packet_buffer_count == packet_last_n)
# dissect packet
for name, layout in plm.layouts.items():
fields = SimpleNamespace()
idx = 0
for field_name, field_size in layout:
setattr(fields, field_name, packet_buffer[idx:idx+field_size])
idx += field_size
self.packet_as[name] = fields
class TransmitDatapath(Module):
def __init__(self, frame, data, plm):
ws = len(data)
assert ws % 8 == 0
self.ws = ws
self.plm = plm
self.packet_buffer = Signal(max(layout_len(l)
for l in plm.layouts.values()))
w_in_packet = len(self.packet_buffer)//ws
self.packet_last_n = Signal(max=max(w_in_packet, 2))
self.packet_stb = Signal()
self.packet_last = Signal()
self.raw_stb = Signal()
self.raw_data = Signal(ws)
# # #
self.sync += frame.eq(0)
if w_in_packet > 1:
packet_buffer_count = Signal(max=w_in_packet)
self.comb += self.packet_last.eq(packet_buffer_count == self.packet_last_n)
self.sync += [
packet_buffer_count.eq(0),
If(self.packet_stb,
frame.eq(1),
Case(packet_buffer_count,
{i: data.eq(self.packet_buffer[i*ws:(i+1)*ws])
for i in range(w_in_packet)}),
packet_buffer_count.eq(packet_buffer_count + 1)
)
]
else:
self.comb += self.packet_last.eq(1)
self.sync += \
If(self.packet_stb,
frame.eq(1),
data.eq(self.packet_buffer)
)
self.sync += [
If(self.raw_stb,
frame.eq(1),
data.eq(self.raw_data)
)
]
def send(self, ty, **kwargs):
idx = 8
value = self.plm.types[ty]
for field_name, field_size in self.plm.layouts[ty][1:]:
try:
fvalue = kwargs[field_name]
del kwargs[field_name]
except KeyError:
fvalue = 0
value = value | (fvalue << idx)
idx += field_size
if kwargs:
raise ValueError
return [
self.packet_stb.eq(1),
self.packet_buffer.eq(value),
self.packet_last_n.eq(idx//self.ws-1)
]
class RTPacketSatellite(Module):
def __init__(self, link_layer):
self.tsc_load = Signal()
self.tsc_value = Signal(64)
self.reset = Signal(reset=1)
self.reset_phy = Signal(reset=1)
self.fifo_space_channel = Signal(16)
self.fifo_space_update = Signal()
self.fifo_space = Signal(16)
self.write_stb = Signal()
self.write_timestamp = Signal(64)
self.write_channel = Signal(16)
self.write_address = Signal(16)
self.write_data = Signal(512)
self.write_overflow = Signal()
self.write_overflow_ack = Signal()
self.write_underflow = Signal()
self.write_underflow_ack = Signal()
# # #
# RX/TX datapath
assert len(link_layer.tx_rt_data) == len(link_layer.rx_rt_data)
assert len(link_layer.tx_rt_data) % 8 == 0
ws = len(link_layer.tx_rt_data)
rx_plm = get_m2s_layouts(ws)
rx_dp = ReceiveDatapath(
link_layer.rx_rt_frame, link_layer.rx_rt_data, rx_plm)
self.submodules += rx_dp
tx_plm = get_s2m_layouts(ws)
tx_dp = TransmitDatapath(
link_layer.tx_rt_frame, link_layer.tx_rt_data, tx_plm)
self.submodules += tx_dp
# RX write data buffer
write_data_buffer_load = Signal()
write_data_buffer_cnt = Signal(max=512//ws+1)
write_data_buffer = Signal(512)
self.sync += \
If(write_data_buffer_load,
Case(write_data_buffer_cnt,
{i: write_data_buffer[i*ws:(i+1)*ws].eq(rx_dp.data_r)
for i in range(512//ws)}),
write_data_buffer_cnt.eq(write_data_buffer_cnt + 1)
).Else(
write_data_buffer_cnt.eq(0)
)
# RX->TX
echo_req = Signal()
err_set = Signal()
err_req = Signal()
err_ack = Signal()
fifo_space_set = Signal()
fifo_space_req = Signal()
fifo_space_ack = Signal()
self.sync += [
If(err_ack, err_req.eq(0)),
If(err_set, err_req.eq(1)),
If(fifo_space_ack, fifo_space_req.eq(0)),
If(fifo_space_set, fifo_space_req.eq(1)),
]
err_code = Signal(max=len(error_codes)+1)
# RX FSM
self.comb += [
self.tsc_value.eq(
rx_dp.packet_as["set_time"].timestamp),
self.fifo_space_channel.eq(
rx_dp.packet_as["fifo_space_request"].channel),
self.write_timestamp.eq(
rx_dp.packet_as["write"].timestamp),
self.write_channel.eq(
rx_dp.packet_as["write"].channel),
self.write_address.eq(
rx_dp.packet_as["write"].address),
self.write_data.eq(
Cat(rx_dp.packet_as["write"].short_data, write_data_buffer))
]
reset = Signal()
reset_phy = Signal()
self.sync += [
self.reset.eq(reset),
self.reset_phy.eq(reset_phy)
]
rx_fsm = FSM(reset_state="INPUT")
self.submodules += rx_fsm
rx_fsm.act("INPUT",
If(rx_dp.frame_r,
rx_dp.packet_buffer_load.eq(1),
If(rx_dp.packet_last,
Case(rx_dp.packet_type, {
# echo must have fixed latency, so there is no memory
# mechanism
rx_plm.types["echo_request"]: echo_req.eq(1),
rx_plm.types["set_time"]: NextState("SET_TIME"),
rx_plm.types["reset"]: NextState("RESET"),
rx_plm.types["write"]: NextState("WRITE"),
rx_plm.types["fifo_space_request"]:
NextState("FIFO_SPACE"),
"default": [
err_set.eq(1),
NextValue(err_code, error_codes["unknown_type_remote"])]
})
)
)
)
rx_fsm.act("SET_TIME",
self.tsc_load.eq(1),
NextState("INPUT")
)
rx_fsm.act("RESET",
If(rx_dp.packet_as["reset"].phy,
reset_phy.eq(1)
).Else(
reset.eq(1)
),
NextState("INPUT")
)
rx_fsm.act("WRITE",
write_data_buffer_load.eq(1),
If(write_data_buffer_cnt == rx_dp.packet_as["write"].extra_data_cnt,
self.write_stb.eq(1),
NextState("INPUT")
)
)
rx_fsm.act("FIFO_SPACE",
fifo_space_set.eq(1),
self.fifo_space_update.eq(1),
NextState("INPUT")
)
# TX FSM
tx_fsm = FSM(reset_state="IDLE")
self.submodules += tx_fsm
tx_fsm.act("IDLE",
If(echo_req, NextState("ECHO")),
If(fifo_space_req, NextState("FIFO_SPACE")),
If(self.write_overflow, NextState("ERROR_WRITE_OVERFLOW")),
If(self.write_underflow, NextState("ERROR_WRITE_UNDERFLOW")),
If(err_req, NextState("ERROR"))
)
tx_fsm.act("ECHO",
tx_dp.send("echo_reply"),
If(tx_dp.packet_last, NextState("IDLE"))
)
tx_fsm.act("FIFO_SPACE",
fifo_space_ack.eq(1),
tx_dp.send("fifo_space_reply", space=self.fifo_space),
If(tx_dp.packet_last, NextState("IDLE"))
)
tx_fsm.act("ERROR_WRITE_OVERFLOW",
self.write_overflow_ack.eq(1),
tx_dp.send("error", code=error_codes["write_overflow"]),
If(tx_dp.packet_last, NextState("IDLE"))
)
tx_fsm.act("ERROR_WRITE_UNDERFLOW",
self.write_underflow_ack.eq(1),
tx_dp.send("error", code=error_codes["write_underflow"]),
If(tx_dp.packet_last, NextState("IDLE"))
)
tx_fsm.act("ERROR",
err_ack.eq(1),
tx_dp.send("error", code=err_code),
If(tx_dp.packet_last, NextState("IDLE"))
)
class _CrossDomainRequest(Module):
def __init__(self, domain,
req_stb, req_ack, req_data,
srv_stb, srv_ack, srv_data):
dsync = getattr(self.sync, domain)
request = PulseSynchronizer("sys", domain)
reply = PulseSynchronizer(domain, "sys")
self.submodules += request, reply
ongoing = Signal()
self.comb += request.i.eq(~ongoing & req_stb)
self.sync += [
req_ack.eq(reply.o),
If(req_stb, ongoing.eq(1)),
If(req_ack, ongoing.eq(0))
]
if req_data is not None:
req_data_r = Signal.like(req_data)
req_data_r.attr.add("no_retiming")
self.sync += If(req_stb, req_data_r.eq(req_data))
dsync += [
If(request.o, srv_stb.eq(1)),
If(srv_ack, srv_stb.eq(0))
]
if req_data is not None:
dsync += If(request.o, srv_data.eq(req_data_r))
self.comb += reply.i.eq(srv_stb & srv_ack)
class _CrossDomainNotification(Module):
def __init__(self, domain,
emi_stb, emi_data,
rec_stb, rec_ack, rec_data):
emi_data_r = Signal.like(emi_data)
emi_data_r.attr.add("no_retiming")
dsync = getattr(self.sync, domain)
dsync += If(emi_stb, emi_data_r.eq(emi_data))
ps = PulseSynchronizer(domain, "sys")
self.submodules += ps
self.comb += ps.i.eq(emi_stb)
self.sync += [
If(rec_ack, rec_stb.eq(0)),
If(ps.o,
rec_data.eq(emi_data_r),
rec_stb.eq(1)
)
]
class RTPacketMaster(Module):
def __init__(self, link_layer, write_fifo_depth=4):
# all interface signals in sys domain unless otherwise specified
# write interface, optimized for throughput
self.write_stb = Signal()
self.write_ack = Signal()
self.write_timestamp = Signal(64)
self.write_channel = Signal(16)
self.write_address = Signal(16)
self.write_data = Signal(512)
# fifo space interface
# write with timestamp[48:] == 0xffff to make a fifo space request
# (space requests have to be ordered wrt writes)
self.fifo_space_not = Signal()
self.fifo_space_not_ack = Signal()
self.fifo_space = Signal(16)
# echo interface
self.echo_stb = Signal()
self.echo_ack = Signal()
self.echo_sent_now = Signal() # in rtio domain
self.echo_received_now = Signal() # in rtio_rx domain
# set_time interface
self.set_time_stb = Signal()
self.set_time_ack = Signal()
# in rtio domain, must be valid all time while there is
# a set_time request pending
self.tsc_value = Signal(64)
# reset interface
self.reset_stb = Signal()
self.reset_ack = Signal()
self.reset_phy = Signal()
# errors
self.error_not = Signal()
self.error_not_ack = Signal()
self.error_code = Signal(8)
# packet counters
self.packet_cnt_tx = Signal(32)
self.packet_cnt_rx = Signal(32)
# # #
# RX/TX datapath
assert len(link_layer.tx_rt_data) == len(link_layer.rx_rt_data)
assert len(link_layer.tx_rt_data) % 8 == 0
ws = len(link_layer.tx_rt_data)
tx_plm = get_m2s_layouts(ws)
tx_dp = ClockDomainsRenamer("rtio")(TransmitDatapath(
link_layer.tx_rt_frame, link_layer.tx_rt_data, tx_plm))
self.submodules += tx_dp
rx_plm = get_s2m_layouts(ws)
rx_dp = ClockDomainsRenamer("rtio_rx")(ReceiveDatapath(
link_layer.rx_rt_frame, link_layer.rx_rt_data, rx_plm))
self.submodules += rx_dp
# Write FIFO and extra data count
wfifo = ClockDomainsRenamer({"write": "sys", "read": "rtio"})(
AsyncFIFO(64+16+16+512, write_fifo_depth))
self.submodules += wfifo
write_timestamp_d = Signal(64)
write_channel_d = Signal(16)
write_address_d = Signal(16)
write_data_d = Signal(512)
self.comb += [
wfifo.we.eq(self.write_stb),
self.write_ack.eq(wfifo.writable),
wfifo.din.eq(Cat(self.write_timestamp, self.write_channel,
self.write_address, self.write_data)),
Cat(write_timestamp_d, write_channel_d,
write_address_d, write_data_d).eq(wfifo.dout)
]
wfb_readable = Signal()
wfb_re = Signal()
self.comb += wfifo.re.eq(wfifo.readable & (~wfb_readable | wfb_re))
self.sync.rtio += \
If(wfifo.re,
wfb_readable.eq(1),
).Elif(wfb_re,
wfb_readable.eq(0),
)
write_timestamp = Signal(64)
write_channel = Signal(16)
write_address = Signal(16)
write_extra_data_cnt = Signal(8)
write_data = Signal(512)
self.sync.rtio += If(wfifo.re,
write_timestamp.eq(write_timestamp_d),
write_channel.eq(write_channel_d),
write_address.eq(write_address_d),
write_data.eq(write_data_d))
short_data_len = tx_plm.field_length("write", "short_data")
write_extra_data_d = Signal(512)
self.comb += write_extra_data_d.eq(write_data_d[short_data_len:])
for i in range(512//ws):
self.sync.rtio += If(wfifo.re,
If(write_extra_data_d[ws*i:ws*(i+1)] != 0, write_extra_data_cnt.eq(i+1)))
write_extra_data = Signal(512)
self.sync.rtio += If(wfifo.re, write_extra_data.eq(write_extra_data_d))
extra_data_ce = Signal()
extra_data_last = Signal()
extra_data_counter = Signal(max=512//ws+1)
self.comb += [
Case(extra_data_counter,
{i+1: tx_dp.raw_data.eq(write_extra_data[i*ws:(i+1)*ws])
for i in range(512//ws)}),
extra_data_last.eq(extra_data_counter == write_extra_data_cnt)
]
self.sync.rtio += \
If(extra_data_ce,
extra_data_counter.eq(extra_data_counter + 1),
).Else(
extra_data_counter.eq(1)
)
# CDC
fifo_space_not = Signal()
fifo_space = Signal(16)
self.submodules += _CrossDomainNotification("rtio_rx",
fifo_space_not, fifo_space,
self.fifo_space_not, self.fifo_space_not_ack, self.fifo_space)
set_time_stb = Signal()
set_time_ack = Signal()
self.submodules += _CrossDomainRequest("rtio",
self.set_time_stb, self.set_time_ack, None,
set_time_stb, set_time_ack, None)
reset_stb = Signal()
reset_ack = Signal()
reset_phy = Signal()
self.submodules += _CrossDomainRequest("rtio",
self.reset_stb, self.reset_ack, self.reset_phy,
reset_stb, reset_ack, reset_phy)
echo_stb = Signal()
echo_ack = Signal()
self.submodules += _CrossDomainRequest("rtio",
self.echo_stb, self.echo_ack, None,
echo_stb, echo_ack, None)
error_not = Signal()
error_code = Signal(8)
self.submodules += _CrossDomainNotification("rtio_rx",
error_not, error_code,
self.error_not, self.error_not_ack, self.error_code)
# TX FSM
tx_fsm = ClockDomainsRenamer("rtio")(FSM(reset_state="IDLE"))
self.submodules += tx_fsm
echo_sent_now = Signal()
self.sync.rtio += self.echo_sent_now.eq(echo_sent_now)
tsc_value = Signal(64)
tsc_value_load = Signal()
self.sync.rtio += If(tsc_value_load, tsc_value.eq(self.tsc_value))
tx_fsm.act("IDLE",
If(wfb_readable,
If(write_timestamp[48:] == 0xffff,
NextState("FIFO_SPACE")
).Else(
NextState("WRITE")
)
).Else(
If(echo_stb,
echo_sent_now.eq(1),
NextState("ECHO")
).Elif(set_time_stb,
tsc_value_load.eq(1),
NextState("SET_TIME")
).Elif(reset_stb,
NextState("RESET")
)
)
)
tx_fsm.act("WRITE",
tx_dp.send("write",
timestamp=write_timestamp,
channel=write_channel,
address=write_address,
extra_data_cnt=write_extra_data_cnt,
short_data=write_data[:short_data_len]),
If(tx_dp.packet_last,
If(write_extra_data_cnt == 0,
wfb_re.eq(1),
NextState("IDLE")
).Else(
NextState("WRITE_EXTRA")
)
)
)
tx_fsm.act("WRITE_EXTRA",
tx_dp.raw_stb.eq(1),
extra_data_ce.eq(1),
If(extra_data_last,
wfb_re.eq(1),
NextState("IDLE")
)
)
tx_fsm.act("FIFO_SPACE",
tx_dp.send("fifo_space_request", channel=write_channel),
If(tx_dp.packet_last,
wfb_re.eq(1),
NextState("IDLE")
)
)
tx_fsm.act("ECHO",
tx_dp.send("echo_request"),
If(tx_dp.packet_last,
echo_ack.eq(1),
NextState("IDLE")
)
)
tx_fsm.act("SET_TIME",
tx_dp.send("set_time", timestamp=tsc_value),
If(tx_dp.packet_last,
set_time_ack.eq(1),
NextState("IDLE")
)
)
tx_fsm.act("RESET",
tx_dp.send("reset", phy=reset_phy),
If(tx_dp.packet_last,
reset_ack.eq(1),
NextState("IDLE")
)
)
# RX FSM
rx_fsm = ClockDomainsRenamer("rtio_rx")(FSM(reset_state="INPUT"))
self.submodules += rx_fsm
echo_received_now = Signal()
self.sync.rtio_rx += self.echo_received_now.eq(echo_received_now)
rx_fsm.act("INPUT",
If(rx_dp.frame_r,
rx_dp.packet_buffer_load.eq(1),
If(rx_dp.packet_last,
Case(rx_dp.packet_type, {
rx_plm.types["error"]: NextState("ERROR"),
rx_plm.types["echo_reply"]: echo_received_now.eq(1),
rx_plm.types["fifo_space_reply"]: NextState("FIFO_SPACE"),
"default": [
error_not.eq(1),
error_code.eq(error_codes["unknown_type_local"])
]
})
)
)
)
rx_fsm.act("ERROR",
error_not.eq(1),
error_code.eq(rx_dp.packet_as["error"].code),
NextState("INPUT")
)
rx_fsm.act("FIFO_SPACE",
fifo_space_not.eq(1),
fifo_space.eq(rx_dp.packet_as["fifo_space_reply"].space),
NextState("INPUT")
)
# packet counters
tx_frame_r = Signal()
packet_cnt_tx = Signal(32)
self.sync.rtio += [
tx_frame_r.eq(link_layer.tx_rt_frame),
If(link_layer.tx_rt_frame & ~tx_frame_r,
packet_cnt_tx.eq(packet_cnt_tx + 1))
]
cdc_packet_cnt_tx = GrayCodeTransfer(32)
self.submodules += cdc_packet_cnt_tx
self.comb += [
cdc_packet_cnt_tx.i.eq(packet_cnt_tx),
self.packet_cnt_tx.eq(cdc_packet_cnt_tx.o)
]
rx_frame_r = Signal()
packet_cnt_rx = Signal(32)
self.sync.rtio_rx += [
rx_frame_r.eq(link_layer.rx_rt_frame),
If(link_layer.rx_rt_frame & ~rx_frame_r,
packet_cnt_rx.eq(packet_cnt_rx + 1))
]
cdc_packet_cnt_rx = ClockDomainsRenamer({"rtio": "rtio_rx"})(
GrayCodeTransfer(32))
self.submodules += cdc_packet_cnt_rx
self.comb += [
cdc_packet_cnt_rx.i.eq(packet_cnt_rx),
self.packet_cnt_rx.eq(cdc_packet_cnt_rx.o)
]

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from migen import *
from migen.genlib.resetsync import AsyncResetSynchronizer
from misoc.cores.code_8b10b import Encoder, Decoder
from misoc.interconnect.csr import *
from artiq.gateware.drtio.transceiver.gtx_7series_init import *
class GTX_20X(Module):
# The transceiver clock on clock_pads must be at the RTIO clock
# frequency when clock_div2=False, and 2x that frequency when
# clock_div2=True.
def __init__(self, clock_pads, tx_pads, rx_pads, sys_clk_freq,
clock_div2=False):
self.submodules.encoder = ClockDomainsRenamer("rtio")(
Encoder(2, True))
self.decoders = [ClockDomainsRenamer("rtio_rx")(
Decoder(True)) for _ in range(2)]
self.submodules += self.decoders
self.rx_ready = Signal()
# transceiver direct clock outputs
# useful to specify clock constraints in a way palatable to Vivado
self.txoutclk = Signal()
self.rxoutclk = Signal()
# # #
refclk = Signal()
if clock_div2:
self.specials += Instance("IBUFDS_GTE2",
i_CEB=0,
i_I=clock_pads.p,
i_IB=clock_pads.n,
o_ODIV2=refclk
)
else:
self.specials += Instance("IBUFDS_GTE2",
i_CEB=0,
i_I=clock_pads.p,
i_IB=clock_pads.n,
o_O=refclk
)
cplllock = Signal()
# TX generates RTIO clock, init must be in system domain
tx_init = GTXInit(sys_clk_freq, False)
# RX receives restart commands from RTIO domain
rx_init = ClockDomainsRenamer("rtio")(
GTXInit(self.rtio_clk_freq, True))
self.submodules += tx_init, rx_init
self.comb += tx_init.cplllock.eq(cplllock), \
rx_init.cplllock.eq(cplllock)
txdata = Signal(20)
rxdata = Signal(20)
self.specials += \
Instance("GTXE2_CHANNEL",
# PMA Attributes
p_PMA_RSV=0x00018480,
p_PMA_RSV2=0x2050,
p_PMA_RSV3=0,
p_PMA_RSV4=0,
p_RX_BIAS_CFG=0b100,
p_RX_CM_TRIM=0b010,
p_RX_OS_CFG=0b10000000,
p_RX_CLK25_DIV=5,
p_TX_CLK25_DIV=5,
# Power-Down Attributes
p_PD_TRANS_TIME_FROM_P2=0x3c,
p_PD_TRANS_TIME_NONE_P2=0x3c,
p_PD_TRANS_TIME_TO_P2=0x64,
# CPLL
p_CPLL_CFG=0xBC07DC,
p_CPLL_FBDIV=4,
p_CPLL_FBDIV_45=5,
p_CPLL_REFCLK_DIV=1,
p_RXOUT_DIV=2,
p_TXOUT_DIV=2,
o_CPLLLOCK=cplllock,
i_CPLLLOCKEN=1,
i_CPLLREFCLKSEL=0b001,
i_TSTIN=2**20-1,
i_GTREFCLK0=refclk,
# TX clock
p_TXBUF_EN="FALSE",
p_TX_XCLK_SEL="TXUSR",
o_TXOUTCLK=self.txoutclk,
i_TXSYSCLKSEL=0b00,
i_TXOUTCLKSEL=0b11,
# TX Startup/Reset
i_GTTXRESET=tx_init.gtXxreset,
o_TXRESETDONE=tx_init.Xxresetdone,
i_TXDLYSRESET=tx_init.Xxdlysreset,
o_TXDLYSRESETDONE=tx_init.Xxdlysresetdone,
o_TXPHALIGNDONE=tx_init.Xxphaligndone,
i_TXUSERRDY=tx_init.Xxuserrdy,
# TX data
p_TX_DATA_WIDTH=20,
p_TX_INT_DATAWIDTH=0,
i_TXCHARDISPMODE=Cat(txdata[9], txdata[19]),
i_TXCHARDISPVAL=Cat(txdata[8], txdata[18]),
i_TXDATA=Cat(txdata[:8], txdata[10:18]),
i_TXUSRCLK=ClockSignal("rtio"),
i_TXUSRCLK2=ClockSignal("rtio"),
# TX electrical
i_TXBUFDIFFCTRL=0b100,
i_TXDIFFCTRL=0b1000,
# RX Startup/Reset
i_GTRXRESET=rx_init.gtXxreset,
o_RXRESETDONE=rx_init.Xxresetdone,
i_RXDLYSRESET=rx_init.Xxdlysreset,
o_RXDLYSRESETDONE=rx_init.Xxdlysresetdone,
o_RXPHALIGNDONE=rx_init.Xxphaligndone,
i_RXUSERRDY=rx_init.Xxuserrdy,
# RX AFE
p_RX_DFE_XYD_CFG=0,
i_RXDFEXYDEN=1,
i_RXDFEXYDHOLD=0,
i_RXDFEXYDOVRDEN=0,
i_RXLPMEN=0,
# RX clock
p_RXBUF_EN="FALSE",
p_RX_XCLK_SEL="RXUSR",
i_RXDDIEN=1,
i_RXSYSCLKSEL=0b00,
i_RXOUTCLKSEL=0b010,
o_RXOUTCLK=self.rxoutclk,
i_RXUSRCLK=ClockSignal("rtio_rx"),
i_RXUSRCLK2=ClockSignal("rtio_rx"),
p_RXCDR_CFG=0x03000023FF10100020,
# RX Clock Correction Attributes
p_CLK_CORRECT_USE="FALSE",
p_CLK_COR_SEQ_1_1=0b0100000000,
p_CLK_COR_SEQ_2_1=0b0100000000,
p_CLK_COR_SEQ_1_ENABLE=0b1111,
p_CLK_COR_SEQ_2_ENABLE=0b1111,
# RX data
p_RX_DATA_WIDTH=20,
p_RX_INT_DATAWIDTH=0,
o_RXDISPERR=Cat(rxdata[9], rxdata[19]),
o_RXCHARISK=Cat(rxdata[8], rxdata[18]),
o_RXDATA=Cat(rxdata[:8], rxdata[10:18]),
# Pads
i_GTXRXP=rx_pads.p,
i_GTXRXN=rx_pads.n,
o_GTXTXP=tx_pads.p,
o_GTXTXN=tx_pads.n,
)
tx_reset_deglitched = Signal()
tx_reset_deglitched.attr.add("no_retiming")
self.sync += tx_reset_deglitched.eq(~tx_init.done)
self.clock_domains.cd_rtio = ClockDomain()
self.specials += [
Instance("BUFG", i_I=self.txoutclk, o_O=self.cd_rtio.clk),
AsyncResetSynchronizer(self.cd_rtio, tx_reset_deglitched)
]
rx_reset_deglitched = Signal()
rx_reset_deglitched.attr.add("no_retiming")
self.sync.rtio += rx_reset_deglitched.eq(~rx_init.done)
self.clock_domains.cd_rtio_rx = ClockDomain()
self.specials += [
Instance("BUFG", i_I=self.rxoutclk, o_O=self.cd_rtio_rx.clk),
AsyncResetSynchronizer(self.cd_rtio_rx, rx_reset_deglitched)
]
self.comb += [
txdata.eq(Cat(self.encoder.output[0], self.encoder.output[1])),
self.decoders[0].input.eq(rxdata[:10]),
self.decoders[1].input.eq(rxdata[10:])
]
clock_aligner = BruteforceClockAligner(0b0101111100, self.rtio_clk_freq)
self.submodules += clock_aligner
self.comb += [
clock_aligner.rxdata.eq(rxdata),
rx_init.restart.eq(clock_aligner.restart),
self.rx_ready.eq(clock_aligner.ready)
]
class GTX_1000BASE_BX10(GTX_20X):
rtio_clk_freq = 62.5e6
class GTX_3G(GTX_20X):
rtio_clk_freq = 150e6
class RXSynchronizer(Module, AutoCSR):
"""Delays the data received in the rtio_rx by a configurable amount
so that it meets s/h in the rtio domain, and recapture it in the rtio
domain. This has fixed latency.
Since Xilinx doesn't provide decent on-chip delay lines, we implement the
delay with MMCM that provides a clock and a finely configurable phase, used
to resample the data.
The phase has to be determined either empirically or by making sense of the
Xilinx scriptures (when existent) and should be constant for a given design
placement.
"""
def __init__(self, rtio_clk_freq, initial_phase=0.0):
self.phase_shift = CSR()
self.phase_shift_done = CSRStatus()
self.clock_domains.cd_rtio_delayed = ClockDomain()
mmcm_output = Signal()
mmcm_fb = Signal()
mmcm_locked = Signal()
# maximize VCO frequency to maximize phase shift resolution
mmcm_mult = 1200e6//rtio_clk_freq
self.specials += [
Instance("MMCME2_ADV",
p_CLKIN1_PERIOD=1e9/rtio_clk_freq,
i_CLKIN1=ClockSignal("rtio_rx"),
i_RST=ResetSignal("rtio_rx"),
i_CLKINSEL=1, # yes, 1=CLKIN1 0=CLKIN2
p_CLKFBOUT_MULT_F=mmcm_mult,
p_CLKOUT0_DIVIDE_F=mmcm_mult,
p_CLKOUT0_PHASE=initial_phase,
p_DIVCLK_DIVIDE=1,
# According to Xilinx, there is no guarantee of input/output
# phase relationship when using internal feedback. We assume
# here that the input/ouput skew is constant to save BUFGs.
o_CLKFBOUT=mmcm_fb,
i_CLKFBIN=mmcm_fb,
p_CLKOUT0_USE_FINE_PS="TRUE",
o_CLKOUT0=mmcm_output,
o_LOCKED=mmcm_locked,
i_PSCLK=ClockSignal(),
i_PSEN=self.phase_shift.re,
i_PSINCDEC=self.phase_shift.r,
o_PSDONE=self.phase_shift_done.status,
),
Instance("BUFR", i_I=mmcm_output, o_O=self.cd_rtio_delayed.clk),
AsyncResetSynchronizer(self.cd_rtio_delayed, ~mmcm_locked)
]
def resync(self, signal):
delayed = Signal.like(signal, related=signal)
synchronized = Signal.like(signal, related=signal)
self.sync.rtio_delayed += delayed.eq(signal)
self.sync.rtio += synchronized.eq(delayed)
return synchronized

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from math import ceil
from functools import reduce
from operator import add
from migen import *
from migen.genlib.cdc import MultiReg, PulseSynchronizer
from migen.genlib.misc import WaitTimer
from migen.genlib.fsm import FSM
class GTXInit(Module):
# Based on LiteSATA by Enjoy-Digital
def __init__(self, sys_clk_freq, rx):
self.done = Signal()
self.restart = Signal()
# GTX signals
self.cplllock = Signal()
self.gtXxreset = Signal()
self.Xxresetdone = Signal()
self.Xxdlysreset = Signal()
self.Xxdlysresetdone = Signal()
self.Xxphaligndone = Signal()
self.Xxuserrdy = Signal()
# # #
# Double-latch transceiver asynch outputs
cplllock = Signal()
Xxresetdone = Signal()
Xxdlysresetdone = Signal()
Xxphaligndone = Signal()
self.specials += [
MultiReg(self.cplllock, cplllock),
MultiReg(self.Xxresetdone, Xxresetdone),
MultiReg(self.Xxdlysresetdone, Xxdlysresetdone),
MultiReg(self.Xxphaligndone, Xxphaligndone),
]
# Deglitch FSM outputs driving transceiver asynch inputs
gtXxreset = Signal()
Xxdlysreset = Signal()
Xxuserrdy = Signal()
self.sync += [
self.gtXxreset.eq(gtXxreset),
self.Xxdlysreset.eq(Xxdlysreset),
self.Xxuserrdy.eq(Xxuserrdy)
]
# After configuration, transceiver resets have to stay low for
# at least 500ns (see AR43482)
startup_cycles = ceil(500*sys_clk_freq/1000000000)
startup_timer = WaitTimer(startup_cycles)
self.submodules += startup_timer
startup_fsm = FSM(reset_state="INITIAL")
self.submodules += startup_fsm
if rx:
cdr_stable_timer = WaitTimer(1024)
self.submodules += cdr_stable_timer
Xxphaligndone_r = Signal(reset=1)
Xxphaligndone_rising = Signal()
self.sync += Xxphaligndone_r.eq(Xxphaligndone)
self.comb += Xxphaligndone_rising.eq(Xxphaligndone & ~Xxphaligndone_r)
startup_fsm.act("INITIAL",
startup_timer.wait.eq(1),
If(startup_timer.done, NextState("RESET_GTX"))
)
startup_fsm.act("RESET_GTX",
gtXxreset.eq(1),
NextState("WAIT_CPLL")
)
startup_fsm.act("WAIT_CPLL",
gtXxreset.eq(1),
If(cplllock, NextState("RELEASE_RESET"))
)
# Release GTX reset and wait for GTX resetdone
# (from UG476, GTX is reset on falling edge
# of gttxreset)
if rx:
startup_fsm.act("RELEASE_RESET",
Xxuserrdy.eq(1),
cdr_stable_timer.wait.eq(1),
If(Xxresetdone & cdr_stable_timer.done, NextState("ALIGN"))
)
else:
startup_fsm.act("RELEASE_RESET",
Xxuserrdy.eq(1),
If(Xxresetdone, NextState("ALIGN"))
)
# Start delay alignment (pulse)
startup_fsm.act("ALIGN",
Xxuserrdy.eq(1),
Xxdlysreset.eq(1),
NextState("WAIT_ALIGN")
)
# Wait for delay alignment
startup_fsm.act("WAIT_ALIGN",
Xxuserrdy.eq(1),
If(Xxdlysresetdone, NextState("WAIT_FIRST_ALIGN_DONE"))
)
# Wait 2 rising edges of rxphaligndone
# (from UG476 in buffer bypass config)
startup_fsm.act("WAIT_FIRST_ALIGN_DONE",
Xxuserrdy.eq(1),
If(Xxphaligndone_rising, NextState("WAIT_SECOND_ALIGN_DONE"))
)
startup_fsm.act("WAIT_SECOND_ALIGN_DONE",
Xxuserrdy.eq(1),
If(Xxphaligndone_rising, NextState("READY"))
)
startup_fsm.act("READY",
Xxuserrdy.eq(1),
self.done.eq(1),
If(self.restart, NextState("RESET_GTX"))
)
# Changes the phase of the transceiver RX clock to align the comma to
# the LSBs of RXDATA, fixing the latency.
#
# This is implemented by repeatedly resetting the transceiver until it
# gives out the correct phase. Each reset gives a random phase.
#
# If Xilinx had designed the GTX transceiver correctly, RXSLIDE_MODE=PMA
# would achieve this faster and in a cleaner way. But:
# * the phase jumps are of 2 UI at every second RXSLIDE pulse, instead
# of 1 UI at every pulse. It is unclear what the latency becomes.
# * RXSLIDE_MODE=PMA cannot be used with the RX buffer bypassed.
# Those design flaws make RXSLIDE_MODE=PMA yet another broken and useless
# transceiver "feature".
#
# Warning: Xilinx transceivers are LSB first, and comma needs to be flipped
# compared to the usual 8b10b binary representation.
class BruteforceClockAligner(Module):
def __init__(self, comma, rtio_clk_freq, check_period=6e-3):
self.rxdata = Signal(20)
self.restart = Signal()
self.ready = Signal()
check_max_val = ceil(check_period*rtio_clk_freq)
check_counter = Signal(max=check_max_val+1)
check = Signal()
reset_check_counter = Signal()
self.sync.rtio += [
check.eq(0),
If(reset_check_counter,
check_counter.eq(check_max_val)
).Else(
If(check_counter == 0,
check.eq(1),
check_counter.eq(check_max_val)
).Else(
check_counter.eq(check_counter-1)
)
)
]
checks_reset = PulseSynchronizer("rtio", "rtio_rx")
self.submodules += checks_reset
comma_n = ~comma & 0b1111111111
comma_seen_rxclk = Signal()
comma_seen = Signal()
comma_seen_rxclk.attr.add("no_retiming")
self.specials += MultiReg(comma_seen_rxclk, comma_seen)
self.sync.rtio_rx += \
If(checks_reset.o,
comma_seen_rxclk.eq(0)
).Elif((self.rxdata[:10] == comma) | (self.rxdata[:10] == comma_n),
comma_seen_rxclk.eq(1)
)
error_seen_rxclk = Signal()
error_seen = Signal()
error_seen_rxclk.attr.add("no_retiming")
self.specials += MultiReg(error_seen_rxclk, error_seen)
rx1cnt = Signal(max=11)
self.sync.rtio_rx += [
rx1cnt.eq(reduce(add, [self.rxdata[i] for i in range(10)])),
If(checks_reset.o,
error_seen_rxclk.eq(0)
).Elif((rx1cnt != 4) & (rx1cnt != 5) & (rx1cnt != 6),
error_seen_rxclk.eq(1)
)
]
fsm = ClockDomainsRenamer("rtio")(FSM(reset_state="WAIT_COMMA"))
self.submodules += fsm
fsm.act("WAIT_COMMA",
If(check,
# Errors are still OK at this stage, as the transceiver
# has just been reset and may output garbage data.
If(comma_seen,
NextState("WAIT_NOERROR")
).Else(
self.restart.eq(1)
),
checks_reset.i.eq(1)
)
)
fsm.act("WAIT_NOERROR",
If(check,
If(comma_seen & ~error_seen,
NextState("READY")
).Else(
self.restart.eq(1),
NextState("WAIT_COMMA")
),
checks_reset.i.eq(1)
)
)
fsm.act("READY",
reset_check_counter.eq(1),
self.ready.eq(1),
If(error_seen,
checks_reset.i.eq(1),
self.restart.eq(1),
NextState("WAIT_COMMA")
)
)

View File

@ -1,3 +1,5 @@
from artiq.gateware.rtio.core import Channel, LogChannel, RTIO from artiq.gateware.rtio.cri import KernelInitiator, CRIInterconnectShared
from artiq.gateware.rtio.core import Channel, LogChannel, Core
from artiq.gateware.rtio.analyzer import Analyzer from artiq.gateware.rtio.analyzer import Analyzer
from artiq.gateware.rtio.moninj import MonInj from artiq.gateware.rtio.moninj import MonInj
from artiq.gateware.rtio.dma import DMA

View File

@ -42,7 +42,7 @@ assert layout_len(stopped_layout) == message_len
class MessageEncoder(Module, AutoCSR): class MessageEncoder(Module, AutoCSR):
def __init__(self, rtio_core, enable): def __init__(self, kcsrs, rtio_counter, enable):
self.source = stream.Endpoint([("data", message_len)]) self.source = stream.Endpoint([("data", message_len)])
self.overflow = CSRStatus() self.overflow = CSRStatus()
@ -50,27 +50,15 @@ class MessageEncoder(Module, AutoCSR):
# # # # # #
kcsrs = rtio_core.kcsrs
input_output_stb = Signal() input_output_stb = Signal()
input_output = Record(input_output_layout) input_output = Record(input_output_layout)
if hasattr(kcsrs, "o_data"):
o_data = kcsrs.o_data.storage o_data = kcsrs.o_data.storage
else:
o_data = 0
if hasattr(kcsrs, "o_address"):
o_address = kcsrs.o_address.storage o_address = kcsrs.o_address.storage
else:
o_address = 0
if hasattr(kcsrs, "i_data"):
i_data = kcsrs.i_data.status i_data = kcsrs.i_data.status
else:
i_data = 0
self.comb += [ self.comb += [
input_output.channel.eq(kcsrs.chan_sel.storage), input_output.channel.eq(kcsrs.chan_sel.storage),
input_output.address_padding.eq(o_address), input_output.address_padding.eq(o_address),
input_output.rtio_counter.eq( input_output.rtio_counter.eq(rtio_counter),
rtio_core.counter.value_sys << rtio_core.fine_ts_width),
If(kcsrs.o_we.re, If(kcsrs.o_we.re,
input_output.message_type.eq(MessageType.output.value), input_output.message_type.eq(MessageType.output.value),
input_output.timestamp.eq(kcsrs.o_timestamp.storage), input_output.timestamp.eq(kcsrs.o_timestamp.storage),
@ -88,10 +76,10 @@ class MessageEncoder(Module, AutoCSR):
self.comb += [ self.comb += [
exception.message_type.eq(MessageType.exception.value), exception.message_type.eq(MessageType.exception.value),
exception.channel.eq(kcsrs.chan_sel.storage), exception.channel.eq(kcsrs.chan_sel.storage),
exception.rtio_counter.eq( exception.rtio_counter.eq(rtio_counter),
rtio_core.counter.value_sys << rtio_core.fine_ts_width),
] ]
for ename in ("o_underflow_reset", "o_sequence_error_reset", for ename in ("reset", "reset_phy",
"o_underflow_reset", "o_sequence_error_reset",
"o_collision_reset", "i_overflow_reset"): "o_collision_reset", "i_overflow_reset"):
self.comb += \ self.comb += \
If(getattr(kcsrs, ename).re, If(getattr(kcsrs, ename).re,
@ -99,28 +87,11 @@ class MessageEncoder(Module, AutoCSR):
exception.exception_type.eq( exception.exception_type.eq(
getattr(ExceptionType, ename).value) getattr(ExceptionType, ename).value)
) )
for rname in "reset", "reset_phy":
r_d = Signal(reset=1)
r = getattr(kcsrs, rname).storage
self.sync += r_d.eq(r)
self.comb += [
If(r & ~r_d,
exception_stb.eq(1),
exception.exception_type.eq(
getattr(ExceptionType, rname+"_rising").value)
),
If(~r & r_d,
exception_stb.eq(1),
exception.exception_type.eq(
getattr(ExceptionType, rname+"_falling").value)
)
]
stopped = Record(stopped_layout) stopped = Record(stopped_layout)
self.comb += [ self.comb += [
stopped.message_type.eq(MessageType.stopped.value), stopped.message_type.eq(MessageType.stopped.value),
stopped.rtio_counter.eq( stopped.rtio_counter.eq(rtio_counter),
rtio_core.counter.value_sys << rtio_core.fine_ts_width),
] ]
enable_r = Signal() enable_r = Signal()
@ -210,13 +181,13 @@ class DMAWriter(Module, AutoCSR):
class Analyzer(Module, AutoCSR): class Analyzer(Module, AutoCSR):
def __init__(self, rtio_core, membus, fifo_depth=128): def __init__(self, kcsrs, rtio_counter, membus, fifo_depth=128):
# shutdown procedure: set enable to 0, wait until busy=0 # shutdown procedure: set enable to 0, wait until busy=0
self.enable = CSRStorage() self.enable = CSRStorage()
self.busy = CSRStatus() self.busy = CSRStatus()
self.submodules.message_encoder = MessageEncoder( self.submodules.message_encoder = MessageEncoder(
rtio_core, self.enable.storage) kcsrs, rtio_counter, self.enable.storage)
self.submodules.fifo = stream.SyncFIFO( self.submodules.fifo = stream.SyncFIFO(
[("data", message_len)], fifo_depth, True) [("data", message_len)], fifo_depth, True)
self.submodules.converter = stream.Converter( self.submodules.converter = stream.Converter(

View File

@ -0,0 +1,66 @@
from migen import *
from migen.genlib.cdc import *
__all__ = ["GrayCodeTransfer", "RTIOCounter", "BlindTransfer"]
# note: transfer is in rtio/sys domains and not affected by the reset CSRs
class GrayCodeTransfer(Module):
def __init__(self, width):
self.i = Signal(width) # in rtio domain
self.o = Signal(width) # in sys domain
# # #
# convert to Gray code
value_gray_rtio = Signal(width)
self.sync.rtio += value_gray_rtio.eq(self.i ^ self.i[1:])
# transfer to system clock domain
value_gray_sys = Signal(width)
value_gray_rtio.attr.add("no_retiming")
self.specials += MultiReg(value_gray_rtio, value_gray_sys)
# convert back to binary
value_sys = Signal(width)
self.comb += value_sys[-1].eq(value_gray_sys[-1])
for i in reversed(range(width-1)):
self.comb += value_sys[i].eq(value_sys[i+1] ^ value_gray_sys[i])
self.sync += self.o.eq(value_sys)
class RTIOCounter(Module):
def __init__(self, width):
self.width = width
# Timestamp counter in RTIO domain
self.value_rtio = Signal(width)
# Timestamp counter resynchronized to sys domain
# Lags behind value_rtio, monotonic and glitch-free
self.value_sys = Signal(width)
# # #
# note: counter is in rtio domain and never affected by the reset CSRs
self.sync.rtio += self.value_rtio.eq(self.value_rtio + 1)
gt = GrayCodeTransfer(width)
self.submodules += gt
self.comb += gt.i.eq(self.value_rtio), self.value_sys.eq(gt.o)
class BlindTransfer(Module):
def __init__(self):
self.i = Signal()
self.o = Signal()
ps = PulseSynchronizer("rio", "rsys")
ps_ack = PulseSynchronizer("rsys", "rio")
self.submodules += ps, ps_ack
blind = Signal()
self.sync.rio += [
If(self.i, blind.eq(1)),
If(ps_ack.o, blind.eq(0))
]
self.comb += [
ps.i.eq(self.i & ~blind),
ps_ack.i.eq(ps.o),
self.o.eq(ps.o)
]

View File

@ -3,73 +3,11 @@ from operator import and_
from migen import * from migen import *
from migen.genlib.record import Record from migen.genlib.record import Record
from migen.genlib.cdc import *
from migen.genlib.fifo import AsyncFIFO from migen.genlib.fifo import AsyncFIFO
from migen.genlib.resetsync import AsyncResetSynchronizer from migen.genlib.resetsync import AsyncResetSynchronizer
from misoc.interconnect.csr import *
from artiq.gateware.rtio import rtlink from artiq.gateware.rtio import cri, rtlink
from artiq.gateware.rtio.cdc import *
# note: transfer is in rtio/sys domains and not affected by the reset CSRs
class _GrayCodeTransfer(Module):
def __init__(self, width):
self.i = Signal(width) # in rtio domain
self.o = Signal(width) # in sys domain
# # #
# convert to Gray code
value_gray_rtio = Signal(width)
self.sync.rtio += value_gray_rtio.eq(self.i ^ self.i[1:])
# transfer to system clock domain
value_gray_sys = Signal(width)
value_gray_rtio.attr.add("no_retiming")
self.specials += MultiReg(value_gray_rtio, value_gray_sys)
# convert back to binary
value_sys = Signal(width)
self.comb += value_sys[-1].eq(value_gray_sys[-1])
for i in reversed(range(width-1)):
self.comb += value_sys[i].eq(value_sys[i+1] ^ value_gray_sys[i])
self.sync += self.o.eq(value_sys)
class _RTIOCounter(Module):
def __init__(self, width):
self.width = width
# Timestamp counter in RTIO domain
self.value_rtio = Signal(width)
# Timestamp counter resynchronized to sys domain
# Lags behind value_rtio, monotonic and glitch-free
self.value_sys = Signal(width)
# # #
# note: counter is in rtio domain and never affected by the reset CSRs
self.sync.rtio += self.value_rtio.eq(self.value_rtio + 1)
gt = _GrayCodeTransfer(width)
self.submodules += gt
self.comb += gt.i.eq(self.value_rtio), self.value_sys.eq(gt.o)
class _BlindTransfer(Module):
def __init__(self):
self.i = Signal()
self.o = Signal()
ps = PulseSynchronizer("rio", "rsys")
ps_ack = PulseSynchronizer("rsys", "rio")
self.submodules += ps, ps_ack
blind = Signal()
self.sync.rio += [
If(self.i, blind.eq(1)),
If(ps_ack.o, blind.eq(0))
]
self.comb += [
ps.i.eq(self.i & ~blind),
ps_ack.i.eq(ps.o),
self.o.eq(ps.o)
]
# CHOOSING A GUARD TIME # CHOOSING A GUARD TIME
@ -227,7 +165,7 @@ class _OutputManager(Module):
interface.stb.eq(dout_stb & dout_ack) interface.stb.eq(dout_stb & dout_ack)
] ]
busy_transfer = _BlindTransfer() busy_transfer = BlindTransfer()
self.submodules += busy_transfer self.submodules += busy_transfer
self.comb += [ self.comb += [
busy_transfer.i.eq(interface.stb & interface.busy), busy_transfer.i.eq(interface.stb & interface.busy),
@ -289,7 +227,7 @@ class _InputManager(Module):
fifo.re.eq(self.re) fifo.re.eq(self.re)
] ]
overflow_transfer = _BlindTransfer() overflow_transfer = BlindTransfer()
self.submodules += overflow_transfer self.submodules += overflow_transfer
self.comb += [ self.comb += [
overflow_transfer.i.eq(fifo.we & ~fifo.writable), overflow_transfer.i.eq(fifo.we & ~fifo.writable),
@ -326,81 +264,47 @@ class LogChannel:
self.overrides = [] self.overrides = []
class _KernelCSRs(AutoCSR): class Core(Module):
def __init__(self, chan_sel_width, def __init__(self, channels, fine_ts_width=None, guard_io_cycles=20):
data_width, address_width, full_ts_width): if fine_ts_width is None:
self.reset = CSRStorage(reset=1)
self.reset_phy = CSRStorage(reset=1)
self.chan_sel = CSRStorage(chan_sel_width)
if data_width:
self.o_data = CSRStorage(data_width, write_from_dev=True)
if address_width:
self.o_address = CSRStorage(address_width, write_from_dev=True)
self.o_timestamp = CSRStorage(full_ts_width)
self.o_we = CSR()
self.o_status = CSRStatus(5)
self.o_underflow_reset = CSR()
self.o_sequence_error_reset = CSR()
self.o_collision_reset = CSR()
self.o_busy_reset = CSR()
if data_width:
self.i_data = CSRStatus(data_width)
self.i_timestamp = CSRStatus(full_ts_width)
self.i_re = CSR()
self.i_status = CSRStatus(2)
self.i_overflow_reset = CSR()
self.counter = CSRStatus(full_ts_width)
self.counter_update = CSR()
class RTIO(Module):
def __init__(self, channels, full_ts_width=63, guard_io_cycles=20):
data_width = max(rtlink.get_data_width(c.interface)
for c in channels)
address_width = max(rtlink.get_address_width(c.interface)
for c in channels)
fine_ts_width = max(rtlink.get_fine_ts_width(c.interface) fine_ts_width = max(rtlink.get_fine_ts_width(c.interface)
for c in channels) for c in channels)
self.data_width = data_width self.cri = cri.Interface()
self.address_width = address_width self.comb += self.cri.arb_gnt.eq(1)
self.fine_ts_width = fine_ts_width
# CSRs
self.kcsrs = _KernelCSRs(bits_for(len(channels)-1),
data_width, address_width,
full_ts_width)
# Clocking/Reset # Clocking/Reset
# Create rsys, rio and rio_phy domains based on sys and rtio # Create rsys, rio and rio_phy domains based on sys and rtio
# with reset controlled by CSR. # with reset controlled by CRI.
cmd_reset = Signal(reset=1)
cmd_reset_phy = Signal(reset=1)
self.sync += [
cmd_reset.eq(self.cri.cmd == cri.commands["reset"]),
cmd_reset_phy.eq(self.cri.cmd == cri.commands["reset_phy"])
]
cmd_reset.attr.add("no_retiming")
cmd_reset_phy.attr.add("no_retiming")
self.clock_domains.cd_rsys = ClockDomain() self.clock_domains.cd_rsys = ClockDomain()
self.clock_domains.cd_rio = ClockDomain() self.clock_domains.cd_rio = ClockDomain()
self.clock_domains.cd_rio_phy = ClockDomain() self.clock_domains.cd_rio_phy = ClockDomain()
self.comb += [ self.comb += [
self.cd_rsys.clk.eq(ClockSignal()), self.cd_rsys.clk.eq(ClockSignal()),
self.cd_rsys.rst.eq(self.kcsrs.reset.storage) self.cd_rsys.rst.eq(cmd_reset)
] ]
self.comb += self.cd_rio.clk.eq(ClockSignal("rtio")) self.comb += self.cd_rio.clk.eq(ClockSignal("rtio"))
self.specials += AsyncResetSynchronizer( self.specials += AsyncResetSynchronizer(
self.cd_rio, self.cd_rio, cmd_reset)
self.kcsrs.reset.storage | ResetSignal("rtio",
allow_reset_less=True))
self.comb += self.cd_rio_phy.clk.eq(ClockSignal("rtio")) self.comb += self.cd_rio_phy.clk.eq(ClockSignal("rtio"))
self.specials += AsyncResetSynchronizer( self.specials += AsyncResetSynchronizer(
self.cd_rio_phy, self.cd_rio_phy, cmd_reset_phy)
self.kcsrs.reset_phy.storage | ResetSignal("rtio",
allow_reset_less=True))
# Managers # Managers
self.submodules.counter = _RTIOCounter(full_ts_width - fine_ts_width) self.submodules.counter = RTIOCounter(len(self.cri.o_timestamp) - fine_ts_width)
i_datas, i_timestamps = [], [] i_datas, i_timestamps = [], []
o_statuses, i_statuses = [], [] o_statuses, i_statuses = [], []
sel = self.kcsrs.chan_sel.storage sel = self.cri.chan_sel[:16]
for n, channel in enumerate(channels): for n, channel in enumerate(channels):
if isinstance(channel, LogChannel): if isinstance(channel, LogChannel):
i_datas.append(0) i_datas.append(0)
@ -416,30 +320,26 @@ class RTIO(Module):
self.submodules += o_manager self.submodules += o_manager
if hasattr(o_manager.ev, "data"): if hasattr(o_manager.ev, "data"):
self.comb += o_manager.ev.data.eq( self.comb += o_manager.ev.data.eq(self.cri.o_data)
self.kcsrs.o_data.storage)
if hasattr(o_manager.ev, "address"): if hasattr(o_manager.ev, "address"):
self.comb += o_manager.ev.address.eq( self.comb += o_manager.ev.address.eq(self.cri.o_address)
self.kcsrs.o_address.storage) ts_shift = len(self.cri.o_timestamp) - len(o_manager.ev.timestamp)
ts_shift = (len(self.kcsrs.o_timestamp.storage) self.comb += o_manager.ev.timestamp.eq(self.cri.o_timestamp[ts_shift:])
- len(o_manager.ev.timestamp))
self.comb += o_manager.ev.timestamp.eq(
self.kcsrs.o_timestamp.storage[ts_shift:])
self.comb += o_manager.we.eq(selected & self.kcsrs.o_we.re) self.comb += o_manager.we.eq(selected & (self.cri.cmd == cri.commands["write"]))
underflow = Signal() underflow = Signal()
sequence_error = Signal() sequence_error = Signal()
collision = Signal() collision = Signal()
busy = Signal() busy = Signal()
self.sync.rsys += [ self.sync.rsys += [
If(selected & self.kcsrs.o_underflow_reset.re, If(selected & (self.cri.cmd == cri.commands["o_underflow_reset"]),
underflow.eq(0)), underflow.eq(0)),
If(selected & self.kcsrs.o_sequence_error_reset.re, If(selected & (self.cri.cmd == cri.commands["o_sequence_error_reset"]),
sequence_error.eq(0)), sequence_error.eq(0)),
If(selected & self.kcsrs.o_collision_reset.re, If(selected & (self.cri.cmd == cri.commands["o_collision_reset"]),
collision.eq(0)), collision.eq(0)),
If(selected & self.kcsrs.o_busy_reset.re, If(selected & (self.cri.cmd == cri.commands["o_busy_reset"]),
busy.eq(0)), busy.eq(0)),
If(o_manager.underflow, underflow.eq(1)), If(o_manager.underflow, underflow.eq(1)),
If(o_manager.sequence_error, sequence_error.eq(1)), If(o_manager.sequence_error, sequence_error.eq(1)),
@ -462,17 +362,16 @@ class RTIO(Module):
else: else:
i_datas.append(0) i_datas.append(0)
if channel.interface.i.timestamped: if channel.interface.i.timestamped:
ts_shift = (len(self.kcsrs.i_timestamp.status) ts_shift = (len(self.cri.i_timestamp) - len(i_manager.ev.timestamp))
- len(i_manager.ev.timestamp))
i_timestamps.append(i_manager.ev.timestamp << ts_shift) i_timestamps.append(i_manager.ev.timestamp << ts_shift)
else: else:
i_timestamps.append(0) i_timestamps.append(0)
self.comb += i_manager.re.eq(selected & self.kcsrs.i_re.re) self.comb += i_manager.re.eq(selected & (self.cri.cmd == cri.commands["read"]))
overflow = Signal() overflow = Signal()
self.sync.rsys += [ self.sync.rsys += [
If(selected & self.kcsrs.i_overflow_reset.re, If(selected & (self.cri.cmd == cri.commands["i_overflow_reset"]),
overflow.eq(0)), overflow.eq(0)),
If(i_manager.overflow, If(i_manager.overflow,
overflow.eq(1)) overflow.eq(1))
@ -483,28 +382,11 @@ class RTIO(Module):
i_datas.append(0) i_datas.append(0)
i_timestamps.append(0) i_timestamps.append(0)
i_statuses.append(0) i_statuses.append(0)
if data_width:
self.comb += self.kcsrs.i_data.status.eq(Array(i_datas)[sel])
self.comb += [ self.comb += [
self.kcsrs.i_timestamp.status.eq(Array(i_timestamps)[sel]), self.cri.i_data.eq(Array(i_datas)[sel]),
self.kcsrs.o_status.status.eq(Array(o_statuses)[sel]), self.cri.i_timestamp.eq(Array(i_timestamps)[sel]),
self.kcsrs.i_status.status.eq(Array(i_statuses)[sel]) self.cri.o_status.eq(Array(o_statuses)[sel]),
self.cri.i_status.eq(Array(i_statuses)[sel])
] ]
# Counter access self.comb += self.cri.counter.eq(self.counter.value_sys << fine_ts_width)
self.sync += \
If(self.kcsrs.counter_update.re,
self.kcsrs.counter.status.eq(self.counter.value_sys
<< fine_ts_width)
)
# Auto clear/zero pad event data
self.comb += [
self.kcsrs.o_data.dat_w.eq(0),
self.kcsrs.o_data.we.eq(self.kcsrs.o_timestamp.re),
self.kcsrs.o_address.dat_w.eq(0),
self.kcsrs.o_address.we.eq(self.kcsrs.o_timestamp.re),
]
def get_csrs(self):
return self.kcsrs.get_csrs()

196
artiq/gateware/rtio/cri.py Normal file
View File

@ -0,0 +1,196 @@
"""Common RTIO Interface"""
from migen import *
from migen.genlib.record import *
from misoc.interconnect.csr import *
commands = {
"nop": 0,
"reset": 1,
"reset_phy": 2,
"write": 3,
"read": 4,
"o_underflow_reset": 5,
"o_sequence_error_reset": 6,
"o_collision_reset": 7,
"o_busy_reset": 8,
"i_overflow_reset": 9
}
layout = [
("arb_req", 1, DIR_M_TO_S),
("arb_gnt", 1, DIR_S_TO_M),
("cmd", 4, DIR_M_TO_S),
# 8 MSBs of chan_sel are used to select core
("chan_sel", 24, DIR_M_TO_S),
("o_data", 512, DIR_M_TO_S),
("o_address", 16, DIR_M_TO_S),
("o_timestamp", 64, DIR_M_TO_S),
# o_status bits:
# <0:wait> <1:underflow> <2:sequence_error> <3:collision> <4:busy>
("o_status", 5, DIR_S_TO_M),
("i_data", 32, DIR_S_TO_M),
("i_timestamp", 64, DIR_S_TO_M),
# i_status bits:
# <0:wait> <1:overflow>
("i_status", 2, DIR_S_TO_M),
("counter", 64, DIR_S_TO_M)
]
class Interface(Record):
def __init__(self):
Record.__init__(self, layout)
class KernelInitiator(Module, AutoCSR):
def __init__(self, cri=None):
self.arb_req = CSRStorage()
self.arb_gnt = CSRStatus()
self.reset = CSR()
self.reset_phy = CSR()
self.chan_sel = CSRStorage(24)
self.o_data = CSRStorage(512, write_from_dev=True)
self.o_address = CSRStorage(16)
self.o_timestamp = CSRStorage(64)
self.o_we = CSR()
self.o_status = CSRStatus(5)
self.o_underflow_reset = CSR()
self.o_sequence_error_reset = CSR()
self.o_collision_reset = CSR()
self.o_busy_reset = CSR()
self.i_data = CSRStatus(32)
self.i_timestamp = CSRStatus(64)
self.i_re = CSR()
self.i_status = CSRStatus(2)
self.i_overflow_reset = CSR()
self.counter = CSRStatus(64)
self.counter_update = CSR()
if cri is None:
cri = Interface()
self.cri = cri
# # #
self.comb += [
self.cri.arb_req.eq(self.arb_req.storage),
self.arb_gnt.status.eq(self.cri.arb_gnt),
self.cri.cmd.eq(commands["nop"]),
If(self.reset.re, self.cri.cmd.eq(commands["reset"])),
If(self.reset_phy.re, self.cri.cmd.eq(commands["reset_phy"])),
If(self.o_we.re, self.cri.cmd.eq(commands["write"])),
If(self.i_re.re, self.cri.cmd.eq(commands["read"])),
If(self.o_underflow_reset.re, self.cri.cmd.eq(commands["o_underflow_reset"])),
If(self.o_sequence_error_reset.re, self.cri.cmd.eq(commands["o_sequence_error_reset"])),
If(self.o_collision_reset.re, self.cri.cmd.eq(commands["o_collision_reset"])),
If(self.o_busy_reset.re, self.cri.cmd.eq(commands["o_busy_reset"])),
If(self.i_overflow_reset.re, self.cri.cmd.eq(commands["i_overflow_reset"])),
self.cri.chan_sel.eq(self.chan_sel.storage),
self.cri.o_data.eq(self.o_data.storage),
self.cri.o_address.eq(self.o_address.storage),
self.cri.o_timestamp.eq(self.o_timestamp.storage),
self.o_status.status.eq(self.cri.o_status),
self.i_data.status.eq(self.cri.i_data),
self.i_timestamp.status.eq(self.cri.i_timestamp),
self.i_status.status.eq(self.cri.i_status),
self.o_data.dat_w.eq(0),
self.o_data.we.eq(self.o_timestamp.re),
]
self.sync += If(self.counter_update.re, self.counter.status.eq(self.cri.counter))
class CRIDecoder(Module):
def __init__(self, slaves=2, master=None):
if isinstance(slaves, int):
slaves = [Interface() for _ in range(slaves)]
if master is None:
master = Interface()
self.slaves = slaves
self.master = master
# # #
selected = Signal(8)
self.sync += selected.eq(self.master.chan_sel[16:])
# master -> slave
for n, slave in enumerate(slaves):
for name, size, direction in layout:
if direction == DIR_M_TO_S and name != "cmd":
self.comb += getattr(slave, name).eq(getattr(master, name))
self.comb += If(selected == n, slave.cmd.eq(master.cmd))
# slave -> master
cases = dict()
for n, slave in enumerate(slaves):
cases[n] = []
for name, size, direction in layout:
if direction == DIR_S_TO_M:
cases[n].append(getattr(master, name).eq(getattr(slave, name)))
self.comb += Case(selected, cases)
class CRIArbiter(Module):
def __init__(self, masters=2, slave=None):
if isinstance(masters, int):
masters = [Interface() for _ in range(masters)]
if slave is None:
slave = Interface()
self.masters = masters
self.slave = slave
# # #
if len(masters) == 1:
self.comb += masters[0].connect(slave)
else:
selected = Signal(max=len(masters))
# mux master->slave signals
for name, size, direction in layout:
if direction == DIR_M_TO_S:
choices = Array(getattr(m, name) for m in masters)
self.comb += getattr(slave, name).eq(choices[selected])
# connect slave->master signals
for name, size, direction in layout:
if direction == DIR_S_TO_M:
source = getattr(slave, name)
for i, m in enumerate(masters):
dest = getattr(m, name)
if name == "arb_gnt":
self.comb += dest.eq(source & (selected == i))
else:
self.comb += dest.eq(source)
# select master
self.sync += \
If(~slave.arb_req,
[If(m.arb_req, selected.eq(i)) for i, m in enumerate(masters)]
)
class CRIInterconnectShared(Module):
def __init__(self, masters=2, slaves=2):
shared = Interface()
self.submodules.arbiter = CRIArbiter(masters, shared)
self.submodules.decoder = CRIDecoder(slaves, shared)

332
artiq/gateware/rtio/dma.py Normal file
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@ -0,0 +1,332 @@
from migen import *
from migen.genlib.record import Record, layout_len
from migen.genlib.fsm import FSM
from misoc.interconnect.csr import *
from misoc.interconnect import stream, wishbone
from artiq.gateware.rtio import cri
class WishboneReader(Module):
def __init__(self, bus=None):
if bus is None:
bus = wishbone.Interface
self.bus = bus
aw = len(bus.adr)
dw = len(bus.dat_w)
self.sink = stream.Endpoint([("address", aw)])
self.source = stream.Endpoint([("data", dw)])
# # #
bus_stb = Signal()
data_reg_loaded = Signal()
self.comb += [
bus_stb.eq(self.sink.stb & (~data_reg_loaded | self.source.ack)),
bus.cyc.eq(bus_stb),
bus.stb.eq(bus_stb),
bus.adr.eq(self.sink.address),
self.sink.ack.eq(bus.ack),
self.source.stb.eq(data_reg_loaded),
]
self.sync += [
If(self.source.ack, data_reg_loaded.eq(0)),
If(bus.ack,
data_reg_loaded.eq(1),
self.source.data.eq(bus.dat_r),
self.source.eop.eq(self.sink.eop)
)
]
class DMAReader(Module, AutoCSR):
def __init__(self, membus, enable):
aw = len(membus.adr)
data_alignment = log2_int(len(membus.dat_w)//8)
self.submodules.wb_reader = WishboneReader(membus)
self.source = self.wb_reader.source
# All numbers in bytes
self.base_address = CSRStorage(aw + data_alignment,
alignment_bits=data_alignment)
self.last_address = CSRStorage(aw + data_alignment,
alignment_bits=data_alignment)
# # #
enable_r = Signal()
address = self.wb_reader.sink
self.sync += [
enable_r.eq(enable),
If(enable & ~enable_r,
address.address.eq(self.base_address.storage),
address.eop.eq(0),
address.stb.eq(1)
),
If(address.stb & address.ack,
If(address.eop,
address.stb.eq(0)
).Else(
address.address.eq(address.address + 1),
If(~enable | (address.address == self.last_address.storage),
address.eop.eq(1)
)
)
)
]
class RawSlicer(Module):
def __init__(self, in_size, out_size, granularity):
g = granularity
self.sink = stream.Endpoint([("data", in_size*g)])
self.source = Signal(out_size*g)
self.source_stb = Signal()
self.source_consume = Signal(max=out_size+1)
# # #
# worst-case buffer space required (when loading):
# <data being shifted out> <new incoming word> <EOP marker>
buf_size = out_size - 1 + in_size + 1
buf = Signal(buf_size*g)
self.comb += self.source.eq(buf[:out_size])
level = Signal(max=buf_size+1)
next_level = Signal(max=buf_size+1)
self.sync += level.eq(next_level)
self.comb += next_level.eq(level)
load_buf = Signal()
shift_buf = Signal()
self.sync += [
If(load_buf, Case(level,
# note how the MSBs of the buffer are set to 0
# (including the EOP marker position)
{i: buf[i*g:].eq(self.sink.data)
for i in range(out_size)})),
If(shift_buf, buf.eq(buf >> self.source_consume*g))
]
fsm = FSM(reset_state="FETCH")
self.submodules += fsm
fsm.act("FETCH",
self.sink.ack.eq(1),
load_buf.eq(1),
If(self.sink.stb,
If(self.sink.eop,
# insert <granularity> bits of 0 to mark EOP
next_level.eq(level + in_size + 1)
).Else(
next_level.eq(level + in_size)
)
),
If(next_level >= out_size, NextState("OUTPUT"))
)
fsm.act("OUTPUT",
self.source_stb.eq(1),
shift_buf.eq(1),
next_level.eq(level - self.source_consume),
If(next_level < out_size, NextState("FETCH"))
)
record_layout = [
("length", 8), # of whole record (header+data)
("channel", 24),
("timestamp", 64),
("address", 16),
("data", 512) # variable length
]
class RecordConverter(Module):
def __init__(self, stream_slicer):
self.source = stream.Endpoint(record_layout)
hdrlen = layout_len(record_layout) - 512
record_raw = Record(record_layout)
self.comb += [
record_raw.raw_bits().eq(stream_slicer.source),
self.source.channel.eq(record_raw.channel),
self.source.timestamp.eq(record_raw.timestamp),
self.source.address.eq(record_raw.address),
Case(record_raw.length,
{hdrlen+i*8: self.source.data.eq(record_raw.data[:])
for i in range(512//8)}),
self.source.stb.eq(stream_slicer.source_stb),
self.source.eop.eq(record_raw.length == 0),
If(self.source.ack,
If(record_raw.length == 0,
stream_slicer.source_consume.eq(1)
).Else(
stream_slicer.source_consume.eq(record_raw.length)
)
)
]
class RecordSlicer(Module):
def __init__(self, in_size):
self.submodules.raw_slicer = RawSlicer(
in_size, layout_len(record_layout)//8, 8)
self.submodules.record_converter = RecordConverter(self.raw_slicer)
self.sink = self.raw_slicer.sink
self.source = self.record_converter.source
class TimeOffset(Module, AutoCSR):
def __init__(self):
self.time_offset = CSRStorage(64)
self.source = stream.Endpoint(record_layout)
self.sink = stream.Endpoint(record_layout)
# # #
pipe_ce = Signal()
self.sync += \
If(pipe_ce,
self.sink.payload.connect(self.source.payload,
leave_out={"timestamp"}),
self.source.payload.timestamp.eq(self.sink.payload.timestamp
+ self.time_offset.storage),
self.source.stb.eq(self.sink.stb)
)
self.comb += [
pipe_ce.eq(self.source.ack | ~self.source.stb),
self.sink.ack.eq(pipe_ce)
]
class CRIMaster(Module, AutoCSR):
def __init__(self):
self.arb_req = CSRStorage()
self.arb_gnt = CSRStatus()
self.error_status = CSRStatus(5) # same encoding as RTIO status
self.error_underflow_reset = CSR()
self.error_sequence_error_reset = CSR()
self.error_collision_reset = CSR()
self.error_busy_reset = CSR()
self.error_channel = CSRStatus(24)
self.error_timestamp = CSRStatus(64)
self.error_address = CSRStatus(16)
self.sink = stream.Endpoint(record_layout)
self.cri = cri.Interface()
self.busy = Signal()
# # #
self.comb += [
self.cri.arb_req.eq(self.arb_req.storage),
self.arb_gnt.status.eq(self.cri.arb_gnt)
]
error_set = Signal(4)
for i, rcsr in enumerate([self.error_underflow_reset, self.error_sequence_error_reset,
self.error_collision_reset, self.error_busy_reset]):
# bit 0 is RTIO wait and always 0 here
bit = i + 1
self.sync += [
If(error_set[i],
self.error_status.status[bit].eq(1),
self.error_channel.status.eq(self.sink.channel),
self.error_timestamp.status.eq(self.sink.timestamp),
self.error_address.status.eq(self.sink.address)
),
If(rcsr.re, self.error_status.status[bit].eq(0))
]
self.comb += [
self.cri.chan_sel.eq(self.sink.channel),
self.cri.o_timestamp.eq(self.sink.timestamp),
self.cri.o_address.eq(self.sink.address),
]
fsm = FSM(reset_state="IDLE")
self.submodules += fsm
fsm.act("IDLE",
If(self.error_status.status == 0,
If(self.sink.stb, NextState("WRITE"))
).Else(
# discard all data until errors are acked
self.sink.ack.eq(1)
)
)
fsm.act("WRITE",
self.busy.eq(1),
self.cri.cmd.eq(cri.commands["write"]),
NextState("CHECK_STATE")
)
fsm.act("CHECK_STATE",
self.busy.eq(1),
If(~self.cri.o_status,
self.sink.ack.eq(1),
NextState("IDLE")
),
If(self.cri.o_status[1], NextState("UNDERFLOW")),
If(self.cri.o_status[2], NextState("SEQUENCE_ERROR")),
If(self.cri.o_status[3], NextState("COLLISION")),
If(self.cri.o_status[4], NextState("BUSY"))
)
for n, name in enumerate(["UNDERFLOW", "SEQUENCE_ERROR",
"COLLISION", "BUSY"]):
fsm.act(name,
self.busy.eq(1),
error_set.eq(1 << n),
self.cri.cmd.eq(cri.commands["o_" + name.lower() + "_reset"]),
self.sink.ack.eq(1),
NextState("IDLE")
)
class DMA(Module):
def __init__(self, membus):
# shutdown procedure: set enable to 0, wait until busy=0
self.enable = CSRStorage()
self.busy = CSRStatus()
self.submodules.dma = DMAReader(membus, self.enable.storage)
self.submodules.slicer = RecordSlicer(len(membus.dat_w))
self.submodules.time_offset = TimeOffset()
self.submodules.cri_master = CRIMaster()
self.cri = self.cri_master.cri
self.comb += [
self.dma.source.connect(self.slicer.sink),
self.slicer.source.connect(self.time_offset.sink),
self.time_offset.source.connect(self.cri_master.sink)
]
fsm = FSM(reset_state="IDLE")
self.submodules += fsm
fsm.act("IDLE",
If(self.enable.storage, NextState("FLOWING"))
)
fsm.act("FLOWING",
self.busy.status.eq(1),
If(self.cri_master.sink.stb & self.cri_master.sink.ack & self.cri_master.sink.eop,
NextState("WAIT_CRI_MASTER")
)
)
fsm.act("WAIT_CRI_MASTER",
self.busy.status.eq(1),
If(~self.cri_master.busy, NextState("IDLE"))
)
def get_csrs(self):
return ([self.enable, self.busy] +
self.dma.get_csrs() + self.time_offset.get_csrs() +
self.cri_master.get_csrs())

View File

@ -39,7 +39,8 @@ class AMPSoC:
self.submodules.timer_kernel = timer.Timer() self.submodules.timer_kernel = timer.Timer()
self.register_kernel_cpu_csrdevice("timer_kernel") self.register_kernel_cpu_csrdevice("timer_kernel")
def register_kernel_cpu_csrdevice(self, name): def register_kernel_cpu_csrdevice(self, name, csrs=None):
if csrs is None:
csrs = getattr(self, name).get_csrs() csrs = getattr(self, name).get_csrs()
bank = wishbone.CSRBank(csrs) bank = wishbone.CSRBank(csrs)
self.submodules += bank self.submodules += bank

View File

@ -101,10 +101,11 @@ _ams101_dac = [
class _NIST_Ions(MiniSoC, AMPSoC): class _NIST_Ions(MiniSoC, AMPSoC):
mem_map = { mem_map = {
"timer_kernel": 0x10000000, # (shadow @0x90000000) "timer_kernel": 0x10000000,
"rtio": 0x20000000, # (shadow @0xa0000000) "rtio": 0x20000000,
"i2c": 0x30000000, # (shadow @0xb0000000) "rtio_dma": 0x30000000,
"mailbox": 0x70000000 # (shadow @0xf0000000) "i2c": 0x50000000,
"mailbox": 0x70000000
} }
mem_map.update(MiniSoC.mem_map) mem_map.update(MiniSoC.mem_map)
@ -142,8 +143,14 @@ class _NIST_Ions(MiniSoC, AMPSoC):
def add_rtio(self, rtio_channels): def add_rtio(self, rtio_channels):
self.submodules.rtio_crg = _RTIOCRG(self.platform, self.crg.cd_sys.clk) self.submodules.rtio_crg = _RTIOCRG(self.platform, self.crg.cd_sys.clk)
self.csr_devices.append("rtio_crg") self.csr_devices.append("rtio_crg")
self.submodules.rtio = rtio.RTIO(rtio_channels) self.submodules.rtio_core = rtio.Core(rtio_channels)
self.submodules.rtio = rtio.KernelInitiator()
self.submodules.rtio_dma = rtio.DMA(self.get_native_sdram_if())
self.register_kernel_cpu_csrdevice("rtio") self.register_kernel_cpu_csrdevice("rtio")
self.register_kernel_cpu_csrdevice("rtio_dma")
self.submodules.cri_con = rtio.CRIInterconnectShared(
[self.rtio.cri, self.rtio_dma.cri],
[self.rtio_core.cri])
self.submodules.rtio_moninj = rtio.MonInj(rtio_channels) self.submodules.rtio_moninj = rtio.MonInj(rtio_channels)
self.csr_devices.append("rtio_moninj") self.csr_devices.append("rtio_moninj")
@ -153,8 +160,8 @@ class _NIST_Ions(MiniSoC, AMPSoC):
self.crg.cd_sys.clk, self.crg.cd_sys.clk,
self.rtio_crg.cd_rtio.clk) self.rtio_crg.cd_rtio.clk)
self.submodules.rtio_analyzer = rtio.Analyzer(self.rtio, self.submodules.rtio_analyzer = rtio.Analyzer(
self.get_native_sdram_if()) self.rtio, self.rtio_core.cri.counter, self.get_native_sdram_if())
self.csr_devices.append("rtio_analyzer") self.csr_devices.append("rtio_analyzer")

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@ -0,0 +1,126 @@
#!/usr/bin/env python3.5
import argparse
from migen import *
from migen.build.generic_platform import *
from misoc.targets.kc705 import MiniSoC, soc_kc705_args, soc_kc705_argdict
from misoc.integration.builder import builder_args, builder_argdict
from artiq.gateware.soc import AMPSoC, build_artiq_soc
from artiq.gateware import rtio
from artiq.gateware.rtio.phy import ttl_simple
from artiq.gateware.drtio.transceiver import gtx_7series
from artiq.gateware.drtio import DRTIOMaster
from artiq import __version__ as artiq_version
fmc_clock_io = [
("ad9154_refclk", 0,
Subsignal("p", Pins("HPC:GBTCLK0_M2C_P")),
Subsignal("n", Pins("HPC:GBTCLK0_M2C_N")),
)
]
class Master(MiniSoC, AMPSoC):
mem_map = {
"timer_kernel": 0x10000000,
"rtio": 0x20000000,
"rtio_dma": 0x30000000,
"mailbox": 0x70000000
}
mem_map.update(MiniSoC.mem_map)
def __init__(self, cfg, medium, **kwargs):
MiniSoC.__init__(self,
cpu_type="or1k",
sdram_controller_type="minicon",
l2_size=128*1024,
with_timer=False,
ident=artiq_version,
**kwargs)
AMPSoC.__init__(self)
platform = self.platform
if medium == "sfp":
self.comb += platform.request("sfp_tx_disable_n").eq(1)
tx_pads = platform.request("sfp_tx")
rx_pads = platform.request("sfp_rx")
elif medium == "sma":
tx_pads = platform.request("user_sma_mgt_tx")
rx_pads = platform.request("user_sma_mgt_rx")
else:
raise ValueError
if cfg == "simple_gbe":
# GTX_1000BASE_BX10 Ethernet compatible, 62.5MHz RTIO clock
# simple TTLs
self.submodules.transceiver = gtx_7series.GTX_1000BASE_BX10(
clock_pads=platform.request("sgmii_clock"),
tx_pads=tx_pads,
rx_pads=rx_pads,
sys_clk_freq=self.clk_freq,
clock_div2=True)
elif cfg == "sawg_3g":
# 3Gb link, 150MHz RTIO clock
# with SAWG on local RTIO and AD9154-FMC-EBZ
platform.register_extension(fmc_clock_io)
self.submodules.transceiver = gtx_7series.GTX_3G(
clock_pads=platform.request("ad9154_refclk"),
tx_pads=tx_pads,
rx_pads=rx_pads,
sys_clk_freq=self.clk_freq)
else:
raise ValueError
self.submodules.drtio = DRTIOMaster(self.transceiver)
self.csr_devices.append("drtio")
rtio_clk_period = 1e9/self.transceiver.rtio_clk_freq
platform.add_period_constraint(self.transceiver.txoutclk, rtio_clk_period)
platform.add_period_constraint(self.transceiver.rxoutclk, rtio_clk_period)
platform.add_false_path_constraints(
self.crg.cd_sys.clk,
self.transceiver.txoutclk, self.transceiver.rxoutclk)
rtio_channels = []
for i in range(8):
phy = ttl_simple.Output(platform.request("user_led", i))
self.submodules += phy
rtio_channels.append(rtio.Channel.from_phy(phy))
for sma in "user_sma_gpio_p", "user_sma_gpio_n":
phy = ttl_simple.Inout(platform.request(sma))
self.submodules += phy
rtio_channels.append(rtio.Channel.from_phy(phy))
self.submodules.rtio_core = rtio.Core(rtio_channels, 3)
self.submodules.rtio = rtio.KernelInitiator()
self.submodules.rtio_dma = rtio.DMA(self.get_native_sdram_if())
self.register_kernel_cpu_csrdevice("rtio")
self.register_kernel_cpu_csrdevice("rtio_dma")
self.submodules.cri_con = rtio.CRIInterconnectShared(
[self.rtio.cri, self.rtio_dma.cri],
[self.drtio.cri, self.rtio_core.cri])
def main():
parser = argparse.ArgumentParser(
description="ARTIQ with DRTIO on KC705 - Master")
builder_args(parser)
soc_kc705_args(parser)
parser.add_argument("-c", "--config", default="simple_gbe",
help="configuration: simple_gbe/sawg_3g "
"(default: %(default)s)")
parser.add_argument("--medium", default="sfp",
help="medium to use for transceiver link: sfp/sma "
"(default: %(default)s)")
args = parser.parse_args()
soc = Master(args.config, args.medium, **soc_kc705_argdict(args))
build_artiq_soc(soc, builder_argdict(args))
if __name__ == "__main__":
main()

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@ -0,0 +1,220 @@
import argparse
from migen import *
from migen.build.generic_platform import *
from migen.build.platforms import kc705
from misoc.cores.i2c import *
from misoc.cores.sequencer import *
from artiq.gateware import rtio
from artiq.gateware.rtio.phy import ttl_simple
from artiq.gateware.drtio.transceiver import gtx_7series
from artiq.gateware.drtio import DRTIOSatellite
# TODO: parameters for sawg_3g
def get_i2c_program(sys_clk_freq):
# NOTE: the logical parameters DO NOT MAP to physical values written
# into registers. They have to be mapped; see the datasheet.
# DSPLLsim reports the logical parameters in the design summary, not
# the physical register values (but those are present separately).
N1_HS = 6 # 10
NC1_LS = 7 # 8
N2_HS = 6 # 10
N2_LS = 20111 # 20112
N31 = 2513 # 2514
N32 = 4596 # 4597
i2c_sequence = [
# PCA9548: select channel 7
[(0x74 << 1), 1 << 7],
# Si5324: configure
[(0x68 << 1), 0, 0b01010000], # FREE_RUN=1
[(0x68 << 1), 1, 0b11100100], # CK_PRIOR2=1 CK_PRIOR1=0
[(0x68 << 1), 2, 0b0010 | (4 << 4)], # BWSEL=4
[(0x68 << 1), 3, 0b0101 | 0x10], # SQ_ICAL=1
[(0x68 << 1), 4, 0b10010010], # AUTOSEL_REG=b10
[(0x68 << 1), 6, 0x07], # SFOUT1_REG=b111
[(0x68 << 1), 25, (N1_HS << 5 ) & 0xff],
[(0x68 << 1), 31, (NC1_LS >> 16) & 0xff],
[(0x68 << 1), 32, (NC1_LS >> 8 ) & 0xff],
[(0x68 << 1), 33, (NC1_LS) & 0xff],
[(0x68 << 1), 40, (N2_HS << 5 ) & 0xff |
(N2_LS >> 16) & 0xff],
[(0x68 << 1), 41, (N2_LS >> 8 ) & 0xff],
[(0x68 << 1), 42, (N2_LS) & 0xff],
[(0x68 << 1), 43, (N31 >> 16) & 0xff],
[(0x68 << 1), 44, (N31 >> 8) & 0xff],
[(0x68 << 1), 45, (N31) & 0xff],
[(0x68 << 1), 46, (N32 >> 16) & 0xff],
[(0x68 << 1), 47, (N32 >> 8) & 0xff],
[(0x68 << 1), 48, (N32) & 0xff],
[(0x68 << 1), 137, 0x01], # FASTLOCK=1
[(0x68 << 1), 136, 0x40], # ICAL=1
]
program = [
InstWrite(I2C_CONFIG_ADDR, int(sys_clk_freq/1e3)),
]
for subseq in i2c_sequence:
program += [
InstWrite(I2C_XFER_ADDR, I2C_START),
InstWait(I2C_XFER_ADDR, I2C_IDLE),
]
for octet in subseq:
program += [
InstWrite(I2C_XFER_ADDR, I2C_WRITE | octet),
InstWait(I2C_XFER_ADDR, I2C_IDLE),
]
program += [
InstWrite(I2C_XFER_ADDR, I2C_STOP),
InstWait(I2C_XFER_ADDR, I2C_IDLE),
]
program += [
InstEnd(),
]
return program
class Si5324ResetClock(Module):
def __init__(self, platform, sys_clk_freq):
self.si5324_not_ready = Signal(reset=1)
# minimum reset pulse 1us
reset_done = Signal()
si5324_rst_n = platform.request("si5324").rst_n
reset_val = int(sys_clk_freq*1.1e-6)
reset_ctr = Signal(max=reset_val+1, reset=reset_val)
self.sync += \
If(reset_ctr != 0,
reset_ctr.eq(reset_ctr - 1)
).Else(
si5324_rst_n.eq(1),
reset_done.eq(1)
)
# 10ms after reset to microprocessor access ready
ready_val = int(sys_clk_freq*11e-3)
ready_ctr = Signal(max=ready_val+1, reset=ready_val)
self.sync += \
If(reset_done,
If(ready_ctr != 0,
ready_ctr.eq(ready_ctr - 1)
).Else(
self.si5324_not_ready.eq(0)
)
)
si5324_clkin = platform.request("si5324_clkin")
self.specials += \
Instance("OBUFDS",
i_I=ClockSignal("rtio_rx"),
o_O=si5324_clkin.p, o_OB=si5324_clkin.n
)
fmc_clock_io = [
("ad9154_refclk", 0,
Subsignal("p", Pins("HPC:GBTCLK0_M2C_P")),
Subsignal("n", Pins("HPC:GBTCLK0_M2C_N")),
)
]
class Satellite(Module):
def __init__(self, cfg, medium, toolchain):
self.platform = platform = kc705.Platform(toolchain=toolchain)
rtio_channels = []
for i in range(8):
phy = ttl_simple.Output(platform.request("user_led", i))
self.submodules += phy
rtio_channels.append(rtio.Channel.from_phy(phy))
for sma in "user_sma_gpio_p", "user_sma_gpio_n":
phy = ttl_simple.Inout(platform.request(sma))
self.submodules += phy
rtio_channels.append(rtio.Channel.from_phy(phy))
sys_clock_pads = platform.request("clk156")
self.clock_domains.cd_sys = ClockDomain(reset_less=True)
self.specials += Instance("IBUFGDS",
i_I=sys_clock_pads.p, i_IB=sys_clock_pads.n,
o_O=self.cd_sys.clk)
sys_clk_freq = 156000000
i2c_master = I2CMaster(platform.request("i2c"))
sequencer = ResetInserter()(Sequencer(get_i2c_program(sys_clk_freq)))
si5324_reset_clock = Si5324ResetClock(platform, sys_clk_freq)
self.submodules += i2c_master, sequencer, si5324_reset_clock
self.comb += [
sequencer.bus.connect(i2c_master.bus),
sequencer.reset.eq(si5324_reset_clock.si5324_not_ready)
]
if medium == "sfp":
self.comb += platform.request("sfp_tx_disable_n").eq(1)
tx_pads = platform.request("sfp_tx")
rx_pads = platform.request("sfp_rx")
elif medium == "sma":
tx_pads = platform.request("user_sma_mgt_tx")
rx_pads = platform.request("user_sma_mgt_rx")
else:
raise ValueError
if cfg == "simple_gbe":
# GTX_1000BASE_BX10 Ethernet compatible, 62.5MHz RTIO clock
# simple TTLs
self.submodules.transceiver = gtx_7series.GTX_1000BASE_BX10(
clock_pads=platform.request("sgmii_clock"),
tx_pads=tx_pads,
rx_pads=rx_pads,
sys_clk_freq=sys_clk_freq,
clock_div2=True)
elif cfg == "sawg_3g":
# 3Gb link, 150MHz RTIO clock
# with SAWG on local RTIO and AD9154-FMC-EBZ
platform.register_extension(fmc_clock_io)
self.submodules.transceiver = gtx_7series.GTX_3G(
clock_pads=platform.request("ad9154_refclk"),
tx_pads=tx_pads,
rx_pads=rx_pads,
sys_clk_freq=sys_clk_freq)
else:
raise ValueError
self.submodules.rx_synchronizer = gtx_7series.RXSynchronizer(
self.transceiver.rtio_clk_freq)
self.submodules.drtio = DRTIOSatellite(
self.transceiver, self.rx_synchronizer, rtio_channels)
rtio_clk_period = 1e9/self.transceiver.rtio_clk_freq
platform.add_period_constraint(self.transceiver.txoutclk, rtio_clk_period)
platform.add_period_constraint(self.transceiver.rxoutclk, rtio_clk_period)
platform.add_false_path_constraints(
sys_clock_pads,
self.transceiver.txoutclk, self.transceiver.rxoutclk)
def build(self, *args, **kwargs):
self.platform.build(self, *args, **kwargs)
def main():
parser = argparse.ArgumentParser(description="KC705 DRTIO satellite")
parser.add_argument("--toolchain", default="vivado",
help="FPGA toolchain to use: ise, vivado")
parser.add_argument("--output-dir", default="drtiosat_kc705",
help="output directory for generated "
"source files and binaries")
parser.add_argument("-c", "--config", default="simple_gbe",
help="configuration: simple_gbe/sawg_3g "
"(default: %(default)s)")
parser.add_argument("--medium", default="sfp",
help="medium to use for transceiver link: sfp/sma "
"(default: %(default)s)")
args = parser.parse_args()
top = Satellite(args.config, args.medium, args.toolchain)
top.build(build_dir=args.output_dir)
if __name__ == "__main__":
main()

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@ -217,12 +217,13 @@ trce -v 12 -fastpaths -tsi {build_name}.tsi -o {build_name}.twr {build_name}.ncd
rtio_channels.append(rtio.LogChannel()) rtio_channels.append(rtio.LogChannel())
# RTIO logic # RTIO logic
self.submodules.rtio = rtio.RTIO(rtio_channels) self.submodules.rtio_core = rtio.Core(rtio_channels)
self.submodules.rtio = rtio.KernelInitiator(self.rtio_core.cri)
self.register_kernel_cpu_csrdevice("rtio") self.register_kernel_cpu_csrdevice("rtio")
self.submodules.rtio_moninj = rtio.MonInj(rtio_channels) self.submodules.rtio_moninj = rtio.MonInj(rtio_channels)
self.csr_devices.append("rtio_moninj") self.csr_devices.append("rtio_moninj")
self.submodules.rtio_analyzer = rtio.Analyzer( self.submodules.rtio_analyzer = rtio.Analyzer(
self.rtio, self.get_native_sdram_if()) self.rtio, self.rtio_core.cri.counter, self.get_native_sdram_if())
self.csr_devices.append("rtio_analyzer") self.csr_devices.append("rtio_analyzer")

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@ -9,10 +9,10 @@ class MessageType(Enum):
class ExceptionType(Enum): class ExceptionType(Enum):
reset_rising = 0b000000 reset = 0b000000
reset_falling = 0b000001 legacy_reset_falling = 0b000001
reset_phy_rising = 0b000010 reset_phy = 0b000010
reset_phy_falling = 0b000011 legacy_reset_phy_falling = 0b000011
o_underflow_reset = 0b010000 o_underflow_reset = 0b010000
o_sequence_error_reset = 0b010001 o_sequence_error_reset = 0b010001

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@ -322,10 +322,7 @@ pub unsafe fn main() {
(mem::transmute::<usize, fn()>(library.lookup("__modinit__")))(); (mem::transmute::<usize, fn()>(library.lookup("__modinit__")))();
send(&NowSave(NOW)); send(&NowSave(NOW));
let typeinfo = library.lookup("typeinfo"); attribute_writeback(library.lookup("typeinfo") as *const ());
if typeinfo != 0 {
attribute_writeback(typeinfo as *const ())
}
send(&RunFinished); send(&RunFinished);

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@ -13,8 +13,6 @@ const RTIO_I_STATUS_OVERFLOW: u32 = 2;
pub extern fn init() { pub extern fn init() {
unsafe { unsafe {
csr::rtio::reset_write(1); csr::rtio::reset_write(1);
csr::rtio::reset_write(0);
csr::rtio::reset_phy_write(0);
} }
} }

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@ -0,0 +1,70 @@
use board::csr;
use sched::{Waiter, Spawner};
fn drtio_link_is_up() -> bool {
unsafe {
csr::drtio::link_status_read() == 1
}
}
fn drtio_sync_tsc() {
unsafe {
csr::drtio::set_time_write(1);
while csr::drtio::set_time_read() == 1 {}
}
}
fn drtio_init_channel(channel: u16) {
unsafe {
csr::drtio::chan_sel_override_write(channel);
csr::drtio::chan_sel_override_en_write(1);
csr::drtio::o_reset_channel_status_write(1);
csr::drtio::o_get_fifo_space_write(1);
while csr::drtio::o_wait_read() == 1 {}
info!("FIFO space on channel {} is {}", channel, csr::drtio::o_dbg_fifo_space_read());
csr::drtio::chan_sel_override_en_write(0);
}
}
pub fn link_thread(waiter: Waiter, _spawner: Spawner) {
loop {
waiter.until(drtio_link_is_up).unwrap();
info!("link RX is up");
waiter.sleep(600).unwrap();
info!("wait for remote side done");
drtio_sync_tsc();
info!("TSC synced");
for channel in 0..16 {
drtio_init_channel(channel);
}
info!("link initialization completed");
waiter.until(|| !drtio_link_is_up()).unwrap();
info!("link is down");
}
}
fn drtio_packet_error_present() -> bool {
unsafe {
csr::drtio::packet_err_present_read() != 0
}
}
fn drtio_get_packet_error() -> u8 {
unsafe {
let err = csr::drtio::packet_err_code_read();
csr::drtio::packet_err_present_write(1);
err
}
}
pub fn error_thread(waiter: Waiter, _spawner: Spawner) {
loop {
waiter.until(drtio_packet_error_present).unwrap();
error!("DRTIO packet error {}", drtio_get_packet_error());
}
}

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@ -80,6 +80,8 @@ mod session;
mod moninj; mod moninj;
#[cfg(has_rtio_analyzer)] #[cfg(has_rtio_analyzer)]
mod analyzer; mod analyzer;
#[cfg(has_drtio)]
mod drtio;
extern { extern {
fn network_init(); fn network_init();
@ -127,6 +129,11 @@ pub unsafe extern fn rust_main() {
scheduler.spawner().spawn(4096, moninj::thread); scheduler.spawner().spawn(4096, moninj::thread);
#[cfg(has_rtio_analyzer)] #[cfg(has_rtio_analyzer)]
scheduler.spawner().spawn(4096, analyzer::thread); scheduler.spawner().spawn(4096, analyzer::thread);
#[cfg(has_drtio)]
{
scheduler.spawner().spawn(4096, drtio::link_thread);
scheduler.spawner().spawn(4096, drtio::error_thread);
}
loop { loop {
scheduler.run(); scheduler.run();

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@ -1,12 +1,11 @@
use core::{mem, ptr}; use core::{mem, ptr};
use core::cell::{Cell, RefCell}; use core::cell::RefCell;
use log::{self, Log, LogLevel, LogMetadata, LogRecord, LogLevelFilter}; use log::{self, Log, LogLevel, LogMetadata, LogRecord, LogLevelFilter};
use log_buffer::LogBuffer; use log_buffer::LogBuffer;
use clock; use clock;
pub struct BufferLogger { pub struct BufferLogger {
buffer: RefCell<LogBuffer<&'static mut [u8]>>, buffer: RefCell<LogBuffer<&'static mut [u8]>>
trace_to_uart: Cell<bool>
} }
unsafe impl Sync for BufferLogger {} unsafe impl Sync for BufferLogger {}
@ -16,8 +15,7 @@ static mut LOGGER: *const BufferLogger = ptr::null();
impl BufferLogger { impl BufferLogger {
pub fn new(buffer: &'static mut [u8]) -> BufferLogger { pub fn new(buffer: &'static mut [u8]) -> BufferLogger {
BufferLogger { BufferLogger {
buffer: RefCell::new(LogBuffer::new(buffer)), buffer: RefCell::new(LogBuffer::new(buffer))
trace_to_uart: Cell::new(true)
} }
} }
@ -50,14 +48,6 @@ impl BufferLogger {
pub fn extract<R, F: FnOnce(&str) -> R>(&self, f: F) -> R { pub fn extract<R, F: FnOnce(&str) -> R>(&self, f: F) -> R {
f(self.buffer.borrow_mut().extract()) f(self.buffer.borrow_mut().extract())
} }
pub fn disable_trace_to_uart(&self) {
if self.trace_to_uart.get() {
trace!("disabling tracing to UART; all further trace messages \
are sent to core log only");
self.trace_to_uart.set(false)
}
}
} }
impl Log for BufferLogger { impl Log for BufferLogger {
@ -71,10 +61,7 @@ impl Log for BufferLogger {
writeln!(self.buffer.borrow_mut(), writeln!(self.buffer.borrow_mut(),
"[{:12}us] {:>5}({}): {}", "[{:12}us] {:>5}({}): {}",
clock::get_us(), record.level(), record.target(), record.args()).unwrap(); clock::get_us(), record.level(), record.target(), record.args()).unwrap();
if record.level() <= LogLevel::Info {
// Printing to UART is really slow, so avoid doing that when we have an alternative
// route to retrieve the debug messages.
if self.trace_to_uart.get() || record.level() <= LogLevel::Info {
println!("[{:12}us] {:>5}({}): {}", println!("[{:12}us] {:>5}({}): {}",
clock::get_us(), record.level(), record.target(), record.args()); clock::get_us(), record.level(), record.target(), record.args());
} }

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@ -583,8 +583,6 @@ pub fn thread(waiter: Waiter, spawner: Spawner) {
} }
} }
BufferLogger::with_instance(|logger| logger.disable_trace_to_uart());
let addr = SocketAddr::new(IP_ANY, 1381); let addr = SocketAddr::new(IP_ANY, 1381);
let listener = TcpListener::bind(waiter, addr).expect("cannot bind socket"); let listener = TcpListener::bind(waiter, addr).expect("cannot bind socket");
listener.set_keepalive(true); listener.set_keepalive(true);

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@ -0,0 +1,95 @@
import unittest
import random
from types import SimpleNamespace
from migen import *
from artiq.gateware.drtio.link_layer import *
from artiq.gateware.drtio.aux_controller import *
class Loopback(Module):
def __init__(self, nwords):
ks = [Signal() for k in range(nwords)]
ds = [Signal(8) for d in range(nwords)]
encoder = SimpleNamespace(k=ks, d=ds)
decoders = [SimpleNamespace(k=k, d=d) for k, d in zip(ks, ds)]
self.submodules.tx = LinkLayerTX(encoder)
self.submodules.rx = LinkLayerRX(decoders)
self.ready = Signal()
self.tx_aux_frame = self.tx.aux_frame
self.tx_aux_data = self.tx.aux_data
self.tx_aux_ack = self.tx.aux_ack
self.tx_rt_frame = self.tx.rt_frame
self.tx_rt_data = self.tx.rt_data
self.rx_aux_stb = self.rx.aux_stb
self.rx_aux_frame = self.rx.aux_frame & self.ready
self.rx_aux_data = self.rx.aux_data
self.rx_rt_frame = self.rx.rt_frame & self.ready
self.rx_rt_data = self.rx.rt_data
class TB(Module):
def __init__(self, nwords):
self.submodules.link_layer = Loopback(nwords)
self.submodules.aux_controller = ClockDomainsRenamer(
{"rtio": "sys", "rtio_rx": "sys"})(AuxController(self.link_layer))
class TestAuxController(unittest.TestCase):
def test_aux_controller(self):
dut = TB(4)
def link_init():
for i in range(8):
yield
yield dut.link_layer.ready.eq(1)
def send_packet(packet):
for i, d in enumerate(packet):
yield from dut.aux_controller.bus.write(i, d)
yield from dut.aux_controller.transmitter.aux_tx_length.write(len(packet)*4)
yield from dut.aux_controller.transmitter.aux_tx.write(1)
yield
while (yield from dut.aux_controller.transmitter.aux_tx.read()):
yield
def receive_packet():
while not (yield from dut.aux_controller.receiver.aux_rx_present.read()):
yield
length = yield from dut.aux_controller.receiver.aux_rx_length.read()
r = []
for i in range(length//4):
r.append((yield from dut.aux_controller.bus.read(256+i)))
yield from dut.aux_controller.receiver.aux_rx_present.write(1)
return r
prng = random.Random(0)
def send_and_check_packet():
data = [prng.randrange(2**32-1) for _ in range(prng.randrange(1, 16))]
yield from send_packet(data)
received = yield from receive_packet()
self.assertEqual(data, received)
def sim():
yield from link_init()
for i in range(8):
yield from send_and_check_packet()
@passive
def rt_traffic():
while True:
while prng.randrange(4):
yield
yield dut.link_layer.tx_rt_frame.eq(1)
yield
while prng.randrange(4):
yield
yield dut.link_layer.tx_rt_frame.eq(0)
yield
run_simulation(dut, [sim(), rt_traffic()])

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@ -0,0 +1,258 @@
import unittest
from types import SimpleNamespace
import random
from migen import *
from artiq.gateware.drtio import *
from artiq.gateware import rtio
from artiq.gateware.rtio import rtlink
from artiq.gateware.rtio.phy import ttl_simple
from artiq.coredevice.exceptions import *
class DummyTransceiverPair:
def __init__(self, nwords):
a2b_k = [Signal() for _ in range(nwords)]
a2b_d = [Signal(8) for _ in range(nwords)]
b2a_k = [Signal() for _ in range(nwords)]
b2a_d = [Signal(8) for _ in range(nwords)]
self.alice = SimpleNamespace(
encoder=SimpleNamespace(k=a2b_k, d=a2b_d),
decoders=[SimpleNamespace(k=k, d=d) for k, d in zip(b2a_k, b2a_d)],
rx_ready=1
)
self.bob = SimpleNamespace(
encoder=SimpleNamespace(k=b2a_k, d=b2a_d),
decoders=[SimpleNamespace(k=k, d=d) for k, d in zip(a2b_k, a2b_d)],
rx_ready=1
)
class DummyRXSynchronizer:
def resync(self, signal):
return signal
class LargeDataReceiver(Module):
def __init__(self, width):
self.rtlink = rtlink.Interface(rtlink.OInterface(width))
self.received_data = Signal(width)
self.sync.rio_phy += If(self.rtlink.o.stb,
self.received_data.eq(self.rtlink.o.data))
class DUT(Module):
def __init__(self, nwords):
self.ttl0 = Signal()
self.ttl1 = Signal()
self.transceivers = DummyTransceiverPair(nwords)
self.submodules.master = DRTIOMaster(self.transceivers.alice)
self.submodules.master_ki = rtio.KernelInitiator(self.master.cri)
rx_synchronizer = DummyRXSynchronizer()
self.submodules.phy0 = ttl_simple.Output(self.ttl0)
self.submodules.phy1 = ttl_simple.Output(self.ttl1)
self.submodules.phy2 = LargeDataReceiver(512)
rtio_channels = [
rtio.Channel.from_phy(self.phy0, ofifo_depth=4),
rtio.Channel.from_phy(self.phy1, ofifo_depth=4),
rtio.Channel.from_phy(self.phy2, ofifo_depth=4),
]
self.submodules.satellite = DRTIOSatellite(
self.transceivers.bob, rx_synchronizer, rtio_channels)
class TestFullStack(unittest.TestCase):
clocks = {"sys": 8, "rtio": 5, "rtio_rx": 5, "rio": 5, "rio_phy": 5}
def test_controller(self):
dut = DUT(2)
kcsrs = dut.master_ki
csrs = dut.master.rt_controller.csrs
mgr = dut.master.rt_manager
ttl_changes = []
correct_ttl_changes = [
# from test_pulses
(203, 0),
(208, 0),
(208, 1),
(214, 1),
# from test_fifo_space
(414, 0),
(454, 0),
(494, 0),
(534, 0),
(574, 0),
(614, 0)
]
now = 0
def delay(dt):
nonlocal now
now += dt
def get_fifo_space(channel):
yield from csrs.chan_sel_override_en.write(1)
yield from csrs.chan_sel_override.write(channel)
yield from csrs.o_get_fifo_space.write(1)
yield
while (yield from csrs.o_wait.read()):
yield
r = (yield from csrs.o_dbg_fifo_space.read())
yield from csrs.chan_sel_override_en.write(0)
return r
def write(channel, data):
yield from kcsrs.chan_sel.write(channel)
yield from kcsrs.o_timestamp.write(now)
yield from kcsrs.o_data.write(data)
yield from kcsrs.o_we.write(1)
yield
status = 1
wlen = 0
while status:
status = yield from kcsrs.o_status.read()
if status & 2:
yield from kcsrs.o_underflow_reset.write(1)
raise RTIOUnderflow
if status & 4:
yield from kcsrs.o_sequence_error_reset.write(1)
raise RTIOSequenceError
yield
wlen += 1
return wlen
def test_init():
yield from get_fifo_space(0)
yield from get_fifo_space(1)
def test_underflow():
with self.assertRaises(RTIOUnderflow):
yield from write(0, 0)
def test_pulses():
delay(200*8)
yield from write(0, 1)
delay(5*8)
yield from write(0, 0)
yield from write(1, 1)
delay(6*8)
yield from write(1, 0)
def test_sequence_error():
delay(-200*8)
with self.assertRaises(RTIOSequenceError):
yield from write(0, 1)
delay(200*8)
def test_large_data():
correct_large_data = random.Random(0).randrange(2**512-1)
self.assertNotEqual((yield dut.phy2.received_data), correct_large_data)
delay(10*8)
yield from write(2, correct_large_data)
for i in range(40):
yield
self.assertEqual((yield dut.phy2.received_data), correct_large_data)
def test_fifo_space():
delay(200*8)
max_wlen = 0
for _ in range(3):
wlen = yield from write(0, 1)
max_wlen = max(max_wlen, wlen)
delay(40*8)
wlen = yield from write(0, 0)
max_wlen = max(max_wlen, wlen)
delay(40*8)
# check that some writes caused FIFO space requests
self.assertGreater(max_wlen, 5)
def test_fifo_emptied():
# wait for all TTL events to execute
while len(ttl_changes) < len(correct_ttl_changes):
yield
# check "last timestamp passed" FIFO empty condition
delay(1000*8)
wlen = yield from write(0, 1)
self.assertEqual(wlen, 2)
def test_tsc_error():
err_present = yield from mgr.packet_err_present.read()
self.assertEqual(err_present, 0)
yield from csrs.tsc_correction.write(100000000)
yield from csrs.set_time.write(1)
for i in range(15):
yield
delay(10000*8)
yield from write(0, 1)
for i in range(10):
yield
err_present = yield from mgr.packet_err_present.read()
err_code = yield from mgr.packet_err_code.read()
self.assertEqual(err_present, 1)
self.assertEqual(err_code, 3)
yield from mgr.packet_err_present.write(1)
yield
err_present = yield from mgr.packet_err_present.read()
self.assertEqual(err_present, 0)
def test():
while not (yield from dut.master.link_layer.link_status.read()):
yield
yield from test_init()
yield from test_underflow()
yield from test_pulses()
yield from test_sequence_error()
yield from test_fifo_space()
yield from test_large_data()
yield from test_fifo_emptied()
yield from test_tsc_error()
@passive
def check_ttls():
cycle = 0
old_ttls = [0, 0]
while True:
ttls = [(yield dut.ttl0), (yield dut.ttl1)]
for n, (old_ttl, ttl) in enumerate(zip(old_ttls, ttls)):
if ttl != old_ttl:
ttl_changes.append((cycle, n))
old_ttls = ttls
yield
cycle += 1
run_simulation(dut,
{"sys": test(), "rtio": check_ttls()}, self.clocks)
self.assertEqual(ttl_changes, correct_ttl_changes)
def test_echo(self):
dut = DUT(2)
csrs = dut.master.rt_controller.csrs
mgr = dut.master.rt_manager
def test():
while not (yield from dut.master.link_layer.link_status.read()):
yield
yield from mgr.update_packet_cnt.write(1)
yield
self.assertEqual((yield from mgr.packet_cnt_tx.read()), 0)
self.assertEqual((yield from mgr.packet_cnt_rx.read()), 0)
yield from mgr.request_echo.write(1)
for i in range(15):
yield
yield from mgr.update_packet_cnt.write(1)
yield
self.assertEqual((yield from mgr.packet_cnt_tx.read()), 1)
self.assertEqual((yield from mgr.packet_cnt_rx.read()), 1)
run_simulation(dut, test(), self.clocks)

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import unittest
from types import SimpleNamespace
from migen import *
from artiq.gateware.drtio.link_layer import *
def process(seq):
dut = Scrambler(8)
rseq = []
def pump():
yield dut.i.eq(seq[0])
yield
for w in seq[1:]:
yield dut.i.eq(w)
yield
rseq.append((yield dut.o))
yield
rseq.append((yield dut.o))
run_simulation(dut, pump())
return rseq
class Loopback(Module):
def __init__(self, nwords):
ks = [Signal() for k in range(nwords)]
ds = [Signal(8) for d in range(nwords)]
encoder = SimpleNamespace(k=ks, d=ds)
decoders = [SimpleNamespace(k=k, d=d) for k, d in zip(ks, ds)]
self.submodules.tx = LinkLayerTX(encoder)
self.submodules.rx = LinkLayerRX(decoders)
class TestLinkLayer(unittest.TestCase):
def test_packets(self):
dut = Loopback(4)
def scrambler_sync():
for i in range(8):
yield
rt_packets = [
[0x12459970, 0x9938cdef, 0x12340000],
[0xabcdef00, 0x12345678],
[0xeeeeeeee, 0xffffffff, 0x01020304, 0x11223344],
[0x88277475, 0x19883332, 0x19837662, 0x81726668, 0x81876261]
]
def transmit_rt_packets():
yield from scrambler_sync()
for packet in rt_packets:
yield dut.tx.rt_frame.eq(1)
for data in packet:
yield dut.tx.rt_data.eq(data)
yield
yield dut.tx.rt_frame.eq(0)
yield
# flush
for i in range(20):
yield
rx_rt_packets = []
@passive
def receive_rt_packets():
yield from scrambler_sync()
previous_frame = 0
while True:
frame = yield dut.rx.rt_frame
if frame and not previous_frame:
packet = []
rx_rt_packets.append(packet)
previous_frame = frame
if frame:
packet.append((yield dut.rx.rt_data))
yield
aux_packets = [
[0x12, 0x34],
[0x44, 0x11, 0x98, 0x78],
[0xbb, 0xaa, 0xdd, 0xcc, 0x00, 0xff, 0xee]
]
def transmit_aux_packets():
yield from scrambler_sync()
for packet in aux_packets:
yield dut.tx.aux_frame.eq(1)
for data in packet:
yield dut.tx.aux_data.eq(data)
yield
while not (yield dut.tx.aux_ack):
yield
yield dut.tx.aux_frame.eq(0)
yield
while not (yield dut.tx.aux_ack):
yield
# flush
for i in range(20):
yield
rx_aux_packets = []
@passive
def receive_aux_packets():
yield from scrambler_sync()
previous_frame = 0
while True:
if (yield dut.rx.aux_stb):
frame = yield dut.rx.aux_frame
if frame and not previous_frame:
packet = []
rx_aux_packets.append(packet)
previous_frame = frame
if frame:
packet.append((yield dut.rx.aux_data))
yield
run_simulation(dut, [transmit_rt_packets(), receive_rt_packets(),
transmit_aux_packets(), receive_aux_packets()])
# print("RT:")
# for packet in rx_rt_packets:
# print(" ".join("{:08x}".format(x) for x in packet))
# print("AUX:")
# for packet in rx_aux_packets:
# print(" ".join("{:02x}".format(x) for x in packet))
self.assertEqual(rt_packets, rx_rt_packets)
self.assertEqual(aux_packets, rx_aux_packets)

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import unittest
from types import SimpleNamespace
import random
from migen import *
from artiq.gateware.drtio.rt_packets import *
from artiq.gateware.drtio.rt_packets import (_CrossDomainRequest,
_CrossDomainNotification)
class PacketInterface:
def __init__(self, direction, ws):
if direction == "m2s":
self.plm = get_m2s_layouts(ws)
elif direction == "s2m":
self.plm = get_s2m_layouts(ws)
else:
raise ValueError
self.frame = Signal()
self.data = Signal(ws)
def send(self, ty, **kwargs):
idx = 8
value = self.plm.types[ty]
for field_name, field_size in self.plm.layouts[ty][1:]:
try:
fvalue = kwargs[field_name]
del kwargs[field_name]
except KeyError:
fvalue = 0
value = value | (fvalue << idx)
idx += field_size
if kwargs:
raise ValueError
ws = len(self.data)
yield self.frame.eq(1)
for i in range(idx//ws):
yield self.data.eq(value)
value >>= ws
yield
yield self.frame.eq(0)
yield
@passive
def receive(self, callback):
previous_frame = 0
frame_words = []
while True:
frame = yield self.frame
if frame:
frame_words.append((yield self.data))
if previous_frame and not frame:
packet_type = self.plm.type_names[frame_words[0] & 0xff]
packet_nwords = layout_len(self.plm.layouts[packet_type]) \
//len(self.data)
packet, trailer = frame_words[:packet_nwords], \
frame_words[packet_nwords:]
n = 0
packet_int = 0
for w in packet:
packet_int |= (w << n)
n += len(self.data)
field_dict = dict()
idx = 0
for field_name, field_size in self.plm.layouts[packet_type]:
v = (packet_int >> idx) & (2**field_size - 1)
field_dict[field_name] = v
idx += field_size
callback(packet_type, field_dict, trailer)
frame_words = []
previous_frame = frame
yield
class TestSatellite(unittest.TestCase):
def create_dut(self, nwords):
pt = PacketInterface("m2s", nwords*8)
pr = PacketInterface("s2m", nwords*8)
dut = RTPacketSatellite(SimpleNamespace(
rx_rt_frame=pt.frame, rx_rt_data=pt.data,
tx_rt_frame=pr.frame, tx_rt_data=pr.data))
return pt, pr, dut
def test_echo(self):
for nwords in range(1, 8):
pt, pr, dut = self.create_dut(nwords)
completed = False
def send():
yield from pt.send("echo_request")
while not completed:
yield
def receive(packet_type, field_dict, trailer):
nonlocal completed
self.assertEqual(packet_type, "echo_reply")
self.assertEqual(trailer, [])
completed = True
run_simulation(dut, [send(), pr.receive(receive)])
def test_set_time(self):
for nwords in range(1, 8):
pt, _, dut = self.create_dut(nwords)
tx_times = [0x12345678aabbccdd, 0x0102030405060708,
0xaabbccddeeff1122]
def send():
for t in tx_times:
yield from pt.send("set_time", timestamp=t)
# flush
for i in range(10):
yield
rx_times = []
@passive
def receive():
while True:
if (yield dut.tsc_load):
rx_times.append((yield dut.tsc_value))
yield
run_simulation(dut, [send(), receive()])
self.assertEqual(tx_times, rx_times)
class TestCDC(unittest.TestCase):
def test_cross_domain_request(self):
prng = random.Random(1)
for sys_freq in 3, 6, 11:
for srv_freq in 3, 6, 11:
req_stb = Signal()
req_ack = Signal()
req_data = Signal(8)
srv_stb = Signal()
srv_ack = Signal()
srv_data = Signal(8)
test_seq = [93, 92, 19, 39, 91, 30, 12, 91, 38, 42]
received_seq = []
def requester():
for data in test_seq:
yield req_data.eq(data)
yield req_stb.eq(1)
yield
while not (yield req_ack):
yield
yield req_stb.eq(0)
for j in range(prng.randrange(0, 10)):
yield
def server():
for i in range(len(test_seq)):
while not (yield srv_stb):
yield
received_seq.append((yield srv_data))
for j in range(prng.randrange(0, 10)):
yield
yield srv_ack.eq(1)
yield
yield srv_ack.eq(0)
yield
dut = _CrossDomainRequest("srv",
req_stb, req_ack, req_data,
srv_stb, srv_ack, srv_data)
run_simulation(dut,
{"sys": requester(), "srv": server()},
{"sys": sys_freq, "srv": srv_freq})
self.assertEqual(test_seq, received_seq)
def test_cross_domain_notification(self):
prng = random.Random(1)
emi_stb = Signal()
emi_data = Signal(8)
rec_stb = Signal()
rec_ack = Signal()
rec_data = Signal(8)
test_seq = [23, 12, 8, 3, 28]
received_seq = []
def emitter():
for data in test_seq:
yield emi_stb.eq(1)
yield emi_data.eq(data)
yield
yield emi_stb.eq(0)
yield
for j in range(prng.randrange(0, 3)):
yield
def receiver():
for i in range(len(test_seq)):
while not (yield rec_stb):
yield
received_seq.append((yield rec_data))
yield rec_ack.eq(1)
yield
yield rec_ack.eq(0)
yield
for j in range(prng.randrange(0, 3)):
yield
dut = _CrossDomainNotification("emi",
emi_stb, emi_data,
rec_stb, rec_ack, rec_data)
run_simulation(dut,
{"emi": emitter(), "sys": receiver()},
{"emi": 13, "sys": 3})
self.assertEqual(test_seq, received_seq)