artiq-zynq/src/gateware/test_dma.py
mwojcik 46b2687d70 RTIO/SYS Clock merge
Co-authored-by: mwojcik <mw@m-labs.hk>
Co-committed-by: mwojcik <mw@m-labs.hk>
2023-02-17 15:52:43 +08:00

237 lines
6.6 KiB
Python

import unittest
import random
import itertools
from migen import *
from migen_axi.interconnect import axi
from artiq.coredevice.exceptions import RTIOUnderflow, RTIODestinationUnreachable
from artiq.gateware import rtio
from artiq.gateware.rtio import cri
from artiq.gateware.rtio.phy import ttl_simple
import endianness
import dma
class AXIMemorySim:
def __init__(self, bus, data, max_queue=12):
self.bus = bus
self.data = data
self.max_queue = max_queue
self.align = len(bus.r.data)//8
self.queue = []
@passive
def ar(self):
while True:
if len(self.queue) < self.max_queue:
request = yield from self.bus.read_ar()
self.queue.append(request)
else:
yield
@passive
def r(self):
while True:
if self.queue:
request = self.queue.pop()
if request.burst:
request_len = request.len + 1
else:
request_len = 1
for i in range(request_len):
if request.addr % self.align:
raise ValueError
addr = request.addr//self.align + i
if addr < len(self.data):
data = self.data[addr]
else:
data = 0
data = endianness.convert_value(data, len(self.bus.r.data))
yield from self.bus.write_r(request.id, data, last=i == request_len-1)
else:
yield
def encode_n(n, min_length, max_length):
r = []
while n:
r.append(n & 0xff)
n >>= 8
r += [0]*(min_length - len(r))
if len(r) > max_length:
raise ValueError
return r
def encode_record(channel, timestamp, address, data):
r = []
r += encode_n(channel, 3, 3)
r += encode_n(timestamp, 8, 8)
r += encode_n(address, 1, 1)
r += encode_n(data, 1, 64)
return encode_n(len(r)+1, 1, 1) + r
def pack(x, size):
r = []
for i in range((len(x)+size-1)//size):
n = 0
for j in range(i*size, (i+1)*size):
n <<= 8
try:
n |= x[j]
except IndexError:
pass
r.append(n)
return r
def encode_sequence(writes, ws):
sequence = [b for write in writes for b in encode_record(*write)]
sequence.append(0)
return pack(sequence, ws)
def do_dma(dut, address):
yield from dut.dma.base_address.write(address)
yield from dut.enable.write(1)
yield
while ((yield from dut.enable.read())):
yield
error = yield from dut.cri_master.error.read()
if error & 1:
raise RTIOUnderflow
if error & 2:
raise RTIODestinationUnreachable
test_writes1 = [
(0x01, 0x23, 0x12, 0x33),
(0x901, 0x902, 0x11, 0xeeeeeeeeeeeeeefffffffffffffffffffffffffffffff28888177772736646717738388488),
(0x81, 0x288, 0x88, 0x8888)
]
test_writes2 = [
(0x10, 0x10000, 0x20, 0x77),
(0x11, 0x10001, 0x22, 0x7777),
(0x12, 0x10002, 0x30, 0x777777),
(0x13, 0x10003, 0x40, 0x77777788),
(0x14, 0x10004, 0x50, 0x7777778899),
]
prng = random.Random(0)
class TB(Module):
def __init__(self, ws):
sequence1 = encode_sequence(test_writes1, ws)
sequence2 = encode_sequence(test_writes2, ws)
offset = 512//ws
assert len(sequence1) < offset
sequence = (
sequence1 +
[prng.randrange(2**(ws*8)) for _ in range(offset-len(sequence1))] +
sequence2)
bus = axi.Interface(ws*8)
self.memory = AXIMemorySim(bus, sequence)
self.submodules.dut = dma.DMA(bus)
test_writes_full_stack = [
(0, 32, 0, 1),
(1, 40, 0, 1),
(0, 48, 0, 0),
(1, 50, 0, 0),
]
class FullStackTB(Module):
def __init__(self, ws):
self.ttl0 = Signal()
self.ttl1 = Signal()
self.submodules.phy0 = ttl_simple.Output(self.ttl0)
self.submodules.phy1 = ttl_simple.Output(self.ttl1)
rtio_channels = [
rtio.Channel.from_phy(self.phy0),
rtio.Channel.from_phy(self.phy1)
]
sequence = encode_sequence(test_writes_full_stack, ws)
bus = axi.Interface(ws*8)
self.memory = AXIMemorySim(bus, sequence)
self.submodules.dut = dma.DMA(bus)
self.submodules.tsc = rtio.TSC()
self.submodules.rtio = rtio.Core(self.tsc, rtio_channels)
self.comb += self.dut.cri.connect(self.rtio.cri)
class TestDMA(unittest.TestCase):
def test_dma_noerror(self):
tb = TB(8)
def do_writes():
yield from do_dma(tb.dut, 0)
yield from do_dma(tb.dut, 512)
received = []
@passive
def rtio_sim():
dut_cri = tb.dut.cri
while True:
cmd = yield dut_cri.cmd
if cmd == cri.commands["nop"]:
pass
elif cmd == cri.commands["write"]:
channel = yield dut_cri.chan_sel
timestamp = yield dut_cri.o_timestamp
address = yield dut_cri.o_address
data = yield dut_cri.o_data
received.append((channel, timestamp, address, data))
yield dut_cri.o_status.eq(1)
for i in range(prng.randrange(10)):
yield
yield dut_cri.o_status.eq(0)
else:
self.fail("unexpected RTIO command")
yield
run_simulation(tb, [do_writes(), rtio_sim(), tb.memory.ar(), tb.memory.r()])
self.assertEqual(received, test_writes1 + test_writes2)
def test_full_stack(self):
tb = FullStackTB(8)
ttl_changes = []
@passive
def monitor():
old_ttl_states = [0, 0]
for time in itertools.count():
ttl_states = [
(yield tb.ttl0),
(yield tb.ttl1)
]
for i, (old, new) in enumerate(zip(old_ttl_states, ttl_states)):
if new != old:
ttl_changes.append((time, i))
old_ttl_states = ttl_states
yield
run_simulation(tb, {"sys": [
do_dma(tb.dut, 0), monitor(),
(None for _ in range(70)),
tb.memory.ar(), tb.memory.r()
]}, {"sys": 8, "rsys": 8, "rio": 8, "rio_phy": 8})
correct_changes = [(timestamp + 11, channel)
for channel, timestamp, _, _ in test_writes_full_stack]
self.assertEqual(ttl_changes, correct_changes)