usb-tools/amaranth
1
0
Fork 0
Code Issues Pull requests Actions Packages Projects Releases Wiki Activity

lib.fifo: adjust properties to have consistent naming.

Browse source
This commit is contained in:
whitequark 2019-09-12 19:51:01 +00:00
parent 9ea3ff7ae2
commit da4b810fe1
3 changed files with 189 additions and 150 deletions
Show stats Download patch file Download diff file Expand all files Collapse all files

202
nmigen/lib/fifo.py
View file

@ -2,7 +2,7 @@
from .. import *
from ..asserts import *
from ..tools import log2_int
from ..tools import log2_int, deprecated
from .coding import GrayEncoder
from .cdc import MultiReg
@ -25,35 +25,37 @@ class FIFOInterface:
Attributes
----------
{attributes}
din : in, width
w_data : in, width
Input data.
writable : out
Asserted if there is space in the queue, i.e. ``we`` can be asserted to write a new entry.
we : in
Write strobe. Latches ``din`` into the queue. Does nothing if ``writable`` is not asserted.
w_rdy : out
Asserted if there is space in the queue, i.e. ``w_en`` can be asserted to write
a new entry.
w_en : in
Write strobe. Latches ``w_data`` into the queue. Does nothing if ``w_rdy`` is not asserted.
{w_attributes}
dout : out, width
Output data. {dout_valid}
readable : out
Asserted if there is an entry in the queue, i.e. ``re`` can be asserted to read this entry.
re : in
Read strobe. Makes the next entry (if any) available on ``dout`` at the next cycle.
Does nothing if ``readable`` is not asserted.
r_data : out, width
Output data. {r_data_valid}
r_rdy : out
Asserted if there is an entry in the queue, i.e. ``r_en`` can be asserted to read
an existing entry.
r_en : in
Read strobe. Makes the next entry (if any) available on ``r_data`` at the next cycle.
Does nothing if ``r_rdy`` is not asserted.
{r_attributes}
"""
__doc__ = _doc_template.format(description="""
Data written to the input interface (``din``, ``we``, ``writable``) is buffered and can be
read at the output interface (``dout``, ``re``, ``readable`). The data entry written first
Data written to the input interface (``w_data``, ``w_rdy``, ``w_en``) is buffered and can be
read at the output interface (``r_data``, ``r_rdy``, ``r_en`). The data entry written first
to the input also appears first on the output.
""",
parameters="",
dout_valid="The conditions in which ``dout`` is valid depends on the type of the queue.",
r_data_valid="The conditions in which ``r_data`` is valid depends on the type of the queue.",
attributes="""
fwft : bool
First-word fallthrough. If set, when ``readable`` rises, the first entry is already
available, i.e. ``dout`` is valid. Otherwise, after ``readable`` rises, it is necessary
to strobe ``re`` for ``dout`` to become valid.
First-word fallthrough. If set, when ``r_rdy`` rises, the first entry is already
available, i.e. ``r_data`` is valid. Otherwise, after ``r_rdy`` rises, it is necessary
to strobe ``r_en`` for ``r_data`` to become valid.
""".strip(),
w_attributes="",
r_attributes="")
@ -63,30 +65,66 @@ class FIFOInterface:
self.depth = depth
self.fwft = fwft
self.din = Signal(width, reset_less=True)
self.writable = Signal() # not full
self.we = Signal()
self.w_data = Signal(width, reset_less=True)
self.w_rdy = Signal() # not full
self.w_en = Signal()
self.dout = Signal(width, reset_less=True)
self.readable = Signal() # not empty
self.re = Signal()
self.r_data = Signal(width, reset_less=True)
self.r_rdy = Signal() # not empty
self.r_en = Signal()
def read(self):
"""Read method for simulation."""
assert (yield self.readable)
yield self.re.eq(1)
assert (yield self.r_rdy)
yield self.r_en.eq(1)
yield
value = (yield self.dout)
yield self.re.eq(0)
value = (yield self.r_data)
yield self.r_en.eq(0)
return value
def write(self, data):
"""Write method for simulation."""
assert (yield self.writable)
yield self.din.eq(data)
yield self.we.eq(1)
assert (yield self.w_rdy)
yield self.w_data.eq(data)
yield self.w_en.eq(1)
yield
yield self.we.eq(0)
yield self.w_en.eq(0)
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.din`, use `fifo.w_data`")
def din(self):
return self.w_data
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.writable`, use `fifo.w_rdy`")
def writable(self):
return self.w_rdy
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.we`, use `fifo.w_en`")
def we(self):
return self.w_en
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.dout`, use `fifo.r_data`")
def dout(self):
return self.r_data
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.readable`, use `fifo.r_rdy`")
def readable(self):
return self.r_rdy
# TODO(nmigen-0.2): move this to nmigen.compat and make it a deprecated extension
@property
@deprecated("instead of `fifo.re`, use `fifo.r_en`")
def re(self):
return self.r_en
def _incr(signal, modulo):
@ -108,11 +146,11 @@ class SyncFIFO(Elaboratable, FIFOInterface):
fwft : bool
First-word fallthrough. If set, when the queue is empty and an entry is written into it,
that entry becomes available on the output on the same clock cycle. Otherwise, it is
necessary to assert ``re`` for ``dout`` to become valid.
necessary to assert ``r_en`` for ``r_data`` to become valid.
""".strip(),
dout_valid="""
For FWFT queues, valid if ``readable`` is asserted. For non-FWFT queues, valid on the next
cycle after ``readable`` and ``re`` have been asserted.
r_data_valid="""
For FWFT queues, valid if ``r_rdy`` is asserted. For non-FWFT queues, valid on the next
cycle after ``r_rdy`` and ``r_en`` have been asserted.
""".strip(),
attributes="",
r_attributes="""
@ -129,34 +167,34 @@ class SyncFIFO(Elaboratable, FIFOInterface):
def elaborate(self, platform):
m = Module()
m.d.comb += [
self.writable.eq(self.level != self.depth),
self.readable.eq(self.level != 0)
self.w_rdy.eq(self.level != self.depth),
self.r_rdy.eq(self.level != 0)
]
do_read = self.readable & self.re
do_write = self.writable & self.we
do_read = self.r_rdy & self.r_en
do_write = self.w_rdy & self.w_en
storage = Memory(self.width, self.depth)
wrport = m.submodules.wrport = storage.write_port()
rdport = m.submodules.rdport = storage.read_port(
w_port = m.submodules.w_port = storage.write_port()
r_port = m.submodules.r_port = storage.read_port(
domain="comb" if self.fwft else "sync", transparent=self.fwft)
produce = Signal.range(self.depth)
consume = Signal.range(self.depth)
m.d.comb += [
wrport.addr.eq(produce),
wrport.data.eq(self.din),
wrport.en.eq(self.we & self.writable)
w_port.addr.eq(produce),
w_port.data.eq(self.w_data),
w_port.en.eq(self.w_en & self.w_rdy)
]
with m.If(do_write):
m.d.sync += produce.eq(_incr(produce, self.depth))
m.d.comb += [
rdport.addr.eq(consume),
self.dout.eq(rdport.data),
r_port.addr.eq(consume),
self.r_data.eq(r_port.data),
]
if not self.fwft:
m.d.comb += rdport.en.eq(self.re)
m.d.comb += r_port.en.eq(self.r_en)
with m.If(do_read):
m.d.sync += consume.eq(_incr(consume, self.depth))
@ -201,7 +239,7 @@ class SyncFIFOBuffered(Elaboratable, FIFOInterface):
This queue's interface is identical to :class:`SyncFIFO` configured as ``fwft=True``, but it
does not use asynchronous memory reads, which are incompatible with FPGA block RAMs.
In exchange, the latency between an entry being written to an empty queue and that entry
In exchange, the latency betw_enen an entry being written to an empty queue and that entry
becoming available on the output is increased to one cycle.
""".strip(),
parameters="""
@ -209,7 +247,7 @@ class SyncFIFOBuffered(Elaboratable, FIFOInterface):
Always set.
""".strip(),
attributes="",
dout_valid="Valid if ``readable`` is asserted.",
r_data_valid="Valid if ``r_rdy`` is asserted.",
r_attributes="""
level : out
Number of unread entries.
@ -229,21 +267,21 @@ class SyncFIFOBuffered(Elaboratable, FIFOInterface):
m.submodules.unbuffered = fifo = SyncFIFO(self.width, self.depth - 1, fwft=False)
m.d.comb += [
fifo.din.eq(self.din),
fifo.we.eq(self.we),
self.writable.eq(fifo.writable),
fifo.w_data.eq(self.w_data),
fifo.w_en.eq(self.w_en),
self.w_rdy.eq(fifo.w_rdy),
]
m.d.comb += [
self.dout.eq(fifo.dout),
fifo.re.eq(fifo.readable & (~self.readable | self.re)),
self.r_data.eq(fifo.r_data),
fifo.r_en.eq(fifo.r_rdy & (~self.r_rdy | self.r_en)),
]
with m.If(fifo.re):
m.d.sync += self.readable.eq(1)
with m.Elif(self.re):
m.d.sync += self.readable.eq(0)
with m.If(fifo.r_en):
m.d.sync += self.r_rdy.eq(1)
with m.Elif(self.r_en):
m.d.sync += self.r_rdy.eq(0)
m.d.comb += self.level.eq(fifo.level + self.readable)
m.d.comb += self.level.eq(fifo.level + self.r_rdy)
return m
@ -261,7 +299,7 @@ class AsyncFIFO(Elaboratable, FIFOInterface):
Always set.
""".strip(),
attributes="",
dout_valid="Valid if ``readable`` is asserted.",
r_data_valid="Valid if ``r_rdy`` is asserted.",
r_attributes="",
w_attributes="")
@ -280,8 +318,8 @@ class AsyncFIFO(Elaboratable, FIFOInterface):
m = Module()
do_write = self.writable & self.we
do_read = self.readable & self.re
do_write = self.w_rdy & self.w_en
do_read = self.r_rdy & self.r_en
# TODO: extract this pattern into lib.cdc.GrayCounter
produce_w_bin = Signal(self._ctr_bits)
@ -313,24 +351,24 @@ class AsyncFIFO(Elaboratable, FIFOInterface):
m.d.read += consume_r_gry.eq(consume_enc.o)
m.d.comb += [
self.writable.eq(
self.w_rdy.eq(
(produce_w_gry[-1] == consume_w_gry[-1]) |
(produce_w_gry[-2] == consume_w_gry[-2]) |
(produce_w_gry[:-2] != consume_w_gry[:-2])),
self.readable.eq(consume_r_gry != produce_r_gry)
self.r_rdy.eq(consume_r_gry != produce_r_gry)
]
storage = Memory(self.width, self.depth)
wrport = m.submodules.wrport = storage.write_port(domain="write")
rdport = m.submodules.rdport = storage.read_port (domain="read")
w_port = m.submodules.w_port = storage.write_port(domain="write")
r_port = m.submodules.r_port = storage.read_port (domain="read")
m.d.comb += [
wrport.addr.eq(produce_w_bin[:-1]),
wrport.data.eq(self.din),
wrport.en.eq(do_write)
w_port.addr.eq(produce_w_bin[:-1]),
w_port.data.eq(self.w_data),
w_port.en.eq(do_write)
]
m.d.comb += [
rdport.addr.eq((consume_r_bin + do_read)[:-1]),
self.dout.eq(rdport.data),
r_port.addr.eq((consume_r_bin + do_read)[:-1]),
self.r_data.eq(r_port.data),
]
if platform == "formal":
@ -349,7 +387,7 @@ class AsyncFIFOBuffered(Elaboratable, FIFOInterface):
This queue's interface is identical to :class:`AsyncFIFO`, but it has an additional register
on the output, improving timing in case of block RAM that has large clock-to-output delay.
In exchange, the latency between an entry being written to an empty queue and that entry
In exchange, the latency betw_enen an entry being written to an empty queue and that entry
becoming available on the output is increased to one cycle.
""".strip(),
parameters="""
@ -357,7 +395,7 @@ class AsyncFIFOBuffered(Elaboratable, FIFOInterface):
Always set.
""".strip(),
attributes="",
dout_valid="Valid if ``readable`` is asserted.",
r_data_valid="Valid if ``r_rdy`` is asserted.",
r_attributes="",
w_attributes="")
@ -369,17 +407,17 @@ class AsyncFIFOBuffered(Elaboratable, FIFOInterface):
m.submodules.unbuffered = fifo = AsyncFIFO(self.width, self.depth - 1)
m.d.comb += [
fifo.din.eq(self.din),
self.writable.eq(fifo.writable),
fifo.we.eq(self.we),
fifo.w_data.eq(self.w_data),
self.w_rdy.eq(fifo.w_rdy),
fifo.w_en.eq(self.w_en),
]
with m.If(self.re | ~self.readable):
with m.If(self.r_en | ~self.r_rdy):
m.d.read += [
self.dout.eq(fifo.dout),
self.readable.eq(fifo.readable)
self.r_data.eq(fifo.r_data),
self.r_rdy.eq(fifo.r_rdy)
]
m.d.comb += \
fifo.re.eq(1)
fifo.r_en.eq(1)
return m

1
nmigen/test/compat/support.py
View file

@ -12,4 +12,5 @@ class SimCase:
verilog.convert(self.tb)
def run_with(self, generator):
with _ignore_deprecated():
run_simulation(self.tb, generator)

134
nmigen/test/test_lib_fifo.py
View file

@ -12,10 +12,10 @@ class FIFOSmokeTestCase(FHDLTestCase):
def process():
yield from fifo.write(1)
yield from fifo.write(2)
while not (yield fifo.readable):
while not (yield fifo.r_rdy):
yield
if not fifo.fwft:
yield fifo.re.eq(1)
yield fifo.r_en.eq(1)
yield
self.assertEqual((yield from fifo.read()), 1)
self.assertEqual((yield from fifo.read()), 2)
@ -45,11 +45,11 @@ class FIFOModel(Elaboratable, FIFOInterface):
"""
Non-synthesizable first-in first-out queue, implemented naively as a chain of registers.
"""
def __init__(self, width, depth, fwft, rdomain, wdomain):
def __init__(self, width, depth, *, fwft, r_domain, w_domain):
super().__init__(width, depth, fwft=fwft)
self.rdomain = rdomain
self.wdomain = wdomain
self.r_domain = r_domain
self.w_domain = w_domain
self.level = Signal.range(self.depth + 1)
@ -57,36 +57,36 @@ class FIFOModel(Elaboratable, FIFOInterface):
m = Module()
storage = Memory(self.width, self.depth)
wrport = m.submodules.wrport = storage.write_port(domain=self.wdomain)
rdport = m.submodules.rdport = storage.read_port (domain="comb")
w_port = m.submodules.w_port = storage.write_port(domain=self.w_domain)
r_port = m.submodules.r_port = storage.read_port (domain="comb")
produce = Signal.range(self.depth)
consume = Signal.range(self.depth)
m.d.comb += self.readable.eq(self.level > 0)
m.d.comb += rdport.addr.eq((consume + 1) % self.depth)
m.d.comb += self.r_rdy.eq(self.level > 0)
m.d.comb += r_port.addr.eq((consume + 1) % self.depth)
if self.fwft:
m.d.comb += self.dout.eq(rdport.data)
with m.If(self.re & self.readable):
m.d.comb += self.r_data.eq(r_port.data)
with m.If(self.r_en & self.r_rdy):
if not self.fwft:
m.d[self.rdomain] += self.dout.eq(rdport.data)
m.d[self.rdomain] += consume.eq(rdport.addr)
m.d[self.r_domain] += self.r_data.eq(r_port.data)
m.d[self.r_domain] += consume.eq(r_port.addr)
m.d.comb += self.writable.eq(self.level < self.depth)
m.d.comb += wrport.data.eq(self.din)
with m.If(self.we & self.writable):
m.d.comb += wrport.addr.eq((produce + 1) % self.depth)
m.d.comb += wrport.en.eq(1)
m.d[self.wdomain] += produce.eq(wrport.addr)
m.d.comb += self.w_rdy.eq(self.level < self.depth)
m.d.comb += w_port.data.eq(self.w_data)
with m.If(self.w_en & self.w_rdy):
m.d.comb += w_port.addr.eq((produce + 1) % self.depth)
m.d.comb += w_port.en.eq(1)
m.d[self.w_domain] += produce.eq(w_port.addr)
with m.If(ResetSignal(self.rdomain) | ResetSignal(self.wdomain)):
with m.If(ResetSignal(self.r_domain) | ResetSignal(self.w_domain)):
m.d.sync += self.level.eq(0)
with m.Else():
m.d.sync += self.level.eq(self.level
+ (self.writable & self.we)
- (self.readable & self.re))
+ (self.w_rdy & self.w_en)
- (self.r_rdy & self.r_en))
m.d.comb += Assert(ResetSignal(self.rdomain) == ResetSignal(self.wdomain))
m.d.comb += Assert(ResetSignal(self.r_domain) == ResetSignal(self.w_domain))
return m
@ -97,36 +97,36 @@ class FIFOModelEquivalenceSpec(Elaboratable):
signals, the behavior of the implementation under test exactly matches the ideal model,
except for behavior not defined by the model.
"""
def __init__(self, fifo, rdomain, wdomain):
def __init__(self, fifo, r_domain, w_domain):
self.fifo = fifo
self.rdomain = rdomain
self.wdomain = wdomain
self.r_domain = r_domain
self.w_domain = w_domain
def elaborate(self, platform):
m = Module()
m.submodules.dut = dut = self.fifo
m.submodules.gold = gold = FIFOModel(dut.width, dut.depth, dut.fwft,
self.rdomain, self.wdomain)
m.submodules.gold = gold = FIFOModel(dut.width, dut.depth, fwft=dut.fwft,
r_domain=self.r_domain, w_domain=self.w_domain)
m.d.comb += [
gold.re.eq(dut.readable & dut.re),
gold.we.eq(dut.we),
gold.din.eq(dut.din),
gold.r_en.eq(dut.r_rdy & dut.r_en),
gold.w_en.eq(dut.w_en),
gold.w_data.eq(dut.w_data),
]
m.d.comb += Assert(dut.readable.implies(gold.readable))
m.d.comb += Assert(dut.writable.implies(gold.writable))
m.d.comb += Assert(dut.r_rdy.implies(gold.r_rdy))
m.d.comb += Assert(dut.w_rdy.implies(gold.w_rdy))
if hasattr(dut, "level"):
m.d.comb += Assert(dut.level == gold.level)
if dut.fwft:
m.d.comb += Assert(dut.readable
.implies(dut.dout == gold.dout))
m.d.comb += Assert(dut.r_rdy
.implies(dut.r_data == gold.r_data))
else:
m.d.comb += Assert((Past(dut.readable, domain=self.rdomain) &
Past(dut.re, domain=self.rdomain))
.implies(dut.dout == gold.dout))
m.d.comb += Assert((Past(dut.r_rdy, domain=self.r_domain) &
Past(dut.r_en, domain=self.r_domain))
.implies(dut.r_data == gold.r_data))
return m
@ -137,10 +137,10 @@ class FIFOContractSpec(Elaboratable):
consecutively, they must be read out consecutively at some later point, no matter all other
circumstances, with the exception of reset.
"""
def __init__(self, fifo, rdomain, wdomain, bound):
def __init__(self, fifo, r_domain, w_domain, bound):
self.fifo = fifo
self.rdomain = rdomain
self.wdomain = wdomain
self.r_domain = r_domain
self.w_domain = w_domain
self.bound = bound
def elaborate(self, platform):
@ -149,45 +149,45 @@ class FIFOContractSpec(Elaboratable):
m.domains += ClockDomain("sync")
m.d.comb += ResetSignal().eq(0)
if self.wdomain != "sync":
m.domains += ClockDomain(self.wdomain)
m.d.comb += ResetSignal(self.wdomain).eq(0)
if self.rdomain != "sync":
m.domains += ClockDomain(self.rdomain)
m.d.comb += ResetSignal(self.rdomain).eq(0)
if self.w_domain != "sync":
m.domains += ClockDomain(self.w_domain)
m.d.comb += ResetSignal(self.w_domain).eq(0)
if self.r_domain != "sync":
m.domains += ClockDomain(self.r_domain)
m.d.comb += ResetSignal(self.r_domain).eq(0)
entry_1 = AnyConst(fifo.width)
entry_2 = AnyConst(fifo.width)
with m.FSM(domain=self.wdomain) as write_fsm:
with m.FSM(domain=self.w_domain) as write_fsm:
with m.State("WRITE-1"):
with m.If(fifo.writable):
with m.If(fifo.w_rdy):
m.d.comb += [
fifo.din.eq(entry_1),
fifo.we.eq(1)
fifo.w_data.eq(entry_1),
fifo.w_en.eq(1)
]
m.next = "WRITE-2"
with m.State("WRITE-2"):
with m.If(fifo.writable):
with m.If(fifo.w_rdy):
m.d.comb += [
fifo.din.eq(entry_2),
fifo.we.eq(1)
fifo.w_data.eq(entry_2),
fifo.w_en.eq(1)
]
m.next = "DONE"
with m.FSM(domain=self.rdomain) as read_fsm:
with m.FSM(domain=self.r_domain) as read_fsm:
read_1 = Signal(fifo.width)
read_2 = Signal(fifo.width)
with m.State("READ"):
m.d.comb += fifo.re.eq(1)
m.d.comb += fifo.r_en.eq(1)
if fifo.fwft:
readable = fifo.readable
r_rdy = fifo.r_rdy
else:
readable = Past(fifo.readable, domain=self.rdomain)
with m.If(readable):
r_rdy = Past(fifo.r_rdy, domain=self.r_domain)
with m.If(r_rdy):
m.d.sync += [
read_1.eq(read_2),
read_2.eq(fifo.dout),
read_2.eq(fifo.r_data),
]
with m.If((read_1 == entry_1) & (read_2 == entry_2)):
m.next = "DONE"
@ -198,18 +198,18 @@ class FIFOContractSpec(Elaboratable):
with m.If(Past(Initial(), self.bound - 1)):
m.d.comb += Assert(read_fsm.ongoing("DONE"))
if self.wdomain != "sync" or self.rdomain != "sync":
m.d.comb += Assume(Rose(ClockSignal(self.wdomain)) |
Rose(ClockSignal(self.rdomain)))
if self.w_domain != "sync" or self.r_domain != "sync":
m.d.comb += Assume(Rose(ClockSignal(self.w_domain)) |
Rose(ClockSignal(self.r_domain)))
return m
class FIFOFormalCase(FHDLTestCase):
def check_sync_fifo(self, fifo):
self.assertFormal(FIFOModelEquivalenceSpec(fifo, rdomain="sync", wdomain="sync"),
self.assertFormal(FIFOModelEquivalenceSpec(fifo, r_domain="sync", w_domain="sync"),
mode="bmc", depth=fifo.depth + 1)
self.assertFormal(FIFOContractSpec(fifo, rdomain="sync", wdomain="sync",
self.assertFormal(FIFOContractSpec(fifo, r_domain="sync", w_domain="sync",
bound=fifo.depth * 2 + 1),
mode="hybrid", depth=fifo.depth * 2 + 1)
@ -237,9 +237,9 @@ class FIFOFormalCase(FHDLTestCase):
def check_async_fifo(self, fifo):
# TODO: properly doing model equivalence checking on this likely requires multiclock,
# which is not really documented nor is it clear how to use it.
# self.assertFormal(FIFOModelEquivalenceSpec(fifo, rdomain="read", wdomain="write"),
# self.assertFormal(FIFOModelEquivalenceSpec(fifo, r_domain="read", w_domain="write"),
# mode="bmc", depth=fifo.depth * 3 + 1)
self.assertFormal(FIFOContractSpec(fifo, rdomain="read", wdomain="write",
self.assertFormal(FIFOContractSpec(fifo, r_domain="read", w_domain="write",
bound=fifo.depth * 4 + 1),
mode="hybrid", depth=fifo.depth * 4 + 1)