#!/usr/bin/env python3
+"""
+pinmux documented here https://libre-soc.org/docs/pinmux/
+"""
from nmigen.build.dsl import Resource, Subsignal, Pins
from nmigen.build.plat import TemplatedPlatform
from nmigen.build.res import ResourceManager, ResourceError
+from nmigen.hdl.rec import Layout
from nmigen import Elaboratable, Signal, Module, Instance
from collections import OrderedDict
from jtag import JTAG, resiotypes
from copy import deepcopy
+from nmigen.cli import rtlil
+import sys
+
+# extra dependencies for jtag testing (?)
+#from soc.bus.sram import SRAM
+
+#from nmigen import Memory
+from nmigen.sim import Simulator, Delay, Settle, Tick, Passive
+
+from nmutil.util import wrap
+
+#from soc.debug.jtagutils import (jtag_read_write_reg,
+# jtag_srv, jtag_set_reset,
+# jtag_set_ir, jtag_set_get_dr)
+
+from c4m.nmigen.jtag.tap import TAP, IOType
+from c4m.nmigen.jtag.bus import Interface as JTAGInterface
+#from soc.debug.dmi import DMIInterface, DBGCore
+#from soc.debug.test.dmi_sim import dmi_sim
+#from soc.debug.test.jtagremote import JTAGServer, JTAGClient
+from nmigen.build.res import ResourceError
# Was thinking of using these functions, but skipped for simplicity for now
# XXX nope. the output from JSON file.
gpios.append("%d*" % i)
return {'uart': ['tx+', 'rx-'],
'gpio': gpios,
+ #'jtag': ['tms-', 'tdi-', 'tdo+', 'tck+'],
'i2c': ['sda*', 'scl+']}
"""
ios = []
for pin in pins:
pname = "gpio"+pin[:-1] # strip "*" on end
- pads = []
# urrrr... tristsate and io assume a single pin which is
# of course exactly what we don't want in an ASIC: we want
# *all three* pins but the damn port is not outputted
# as a triplet, it's a single Record named "io". sigh.
# therefore the only way to get a triplet of i/o/oe
# is to *actually* create explicit triple pins
+ # XXX ARRRGH, doesn't work
+ #pad = Subsignal("io",
+ # Pins("%s_i %s_o %s_oe" % (pname, pname, pname),
+ # dir="io", assert_width=3))
+ #ios.append(Resource(pname, 0, pad))
+ pads = []
pads.append(Subsignal("i",
Pins(pname+"_i", dir="i", assert_width=1)))
pads.append(Subsignal("o",
Pins(pname+"_o", dir="o", assert_width=1)))
pads.append(Subsignal("oe",
- Pins(pname+"_oe", dir="oe", assert_width=1)))
+ Pins(pname+"_oe", dir="o", assert_width=1)))
ios.append(Resource.family(pname, 0, default_name=pname,
ios=pads))
resources.append(Resource.family(periph, 0, default_name="gpio",
return resources
+def JTAGResource(*args):
+ io = []
+ io.append(Subsignal("tms", Pins("tms", dir="i", assert_width=1)))
+ io.append(Subsignal("tdi", Pins("tdi", dir="i", assert_width=1)))
+ io.append(Subsignal("tck", Pins("tck", dir="i", assert_width=1)))
+ io.append(Subsignal("tdo", Pins("tdo", dir="o", assert_width=1)))
+ return Resource.family(*args, default_name="jtag", ios=io)
+
def UARTResource(*args, rx, tx):
io = []
io.append(Subsignal("rx", Pins(rx, dir="i", assert_width=1)))
def I2CResource(*args, scl, sda):
- io = []
- io.append(Subsignal("scl", Pins(scl, dir="io", assert_width=1)))
- io.append(Subsignal("sda", Pins(sda, dir="io", assert_width=1)))
- return Resource.family(*args, default_name="i2c", ios=io)
-
-
-# ridiculously-simple top-level module. doesn't even have a sync domain
-# and can't have one until a clock has been established by ASICPlatform.
+ ios = []
+ pads = []
+ pads.append(Subsignal("i", Pins(sda+"_i", dir="i", assert_width=1)))
+ pads.append(Subsignal("o", Pins(sda+"_o", dir="o", assert_width=1)))
+ pads.append(Subsignal("oe", Pins(sda+"_oe", dir="o", assert_width=1)))
+ ios.append(Resource.family(sda, 0, default_name=sda, ios=pads))
+ pads = []
+ pads.append(Subsignal("i", Pins(scl+"_i", dir="i", assert_width=1)))
+ pads.append(Subsignal("o", Pins(scl+"_o", dir="o", assert_width=1)))
+ pads.append(Subsignal("oe", Pins(scl+"_oe", dir="o", assert_width=1)))
+ ios.append(Resource.family(scl, 0, default_name=scl, ios=pads))
+ return Resource.family(*args, default_name="i2c", ios=ios)
+
+
+# top-level demo module.
class Blinker(Elaboratable):
- def __init__(self, pinset):
- self.jtag = JTAG({}, "sync")
+ def __init__(self, pinset, resources, no_jtag_connect=False):
+ self.no_jtag_connect = no_jtag_connect
+ self.jtag = JTAG({}, "sync", resources=resources)
+ #memory = Memory(width=32, depth=16)
+ #self.sram = SRAM(memory=memory, bus=self.jtag.wb)
def elaborate(self, platform):
+ jtag_resources = self.jtag.pad_mgr.resources
m = Module()
m.submodules.jtag = self.jtag
+ #m.submodules.sram = self.sram
+
count = Signal(5)
- m.d.sync += count.eq(5)
- print ("resources", platform.resources.items())
- gpio = platform.request('gpio')
+ m.d.sync += count.eq(count+1)
+ print ("resources", platform, jtag_resources.items())
+ gpio = self.jtag.request('gpio')
print (gpio, gpio.layout, gpio.fields)
# get the GPIO bank, mess about with some of the pins
m.d.comb += gpio.gpio0.o.eq(1)
m.d.comb += gpio.gpio1.oe.eq(count[4])
m.d.sync += count[0].eq(gpio.gpio1.i)
# get the UART resource, mess with the output tx
- uart = platform.request('uart')
- print (uart, uart.fields)
- m.d.comb += uart.tx.eq(1)
- return m
+ uart = self.jtag.request('uart')
+ print ("uart fields", uart, uart.fields)
+ self.intermediary = Signal()
+ m.d.comb += uart.tx.eq(self.intermediary)
+ m.d.comb += self.intermediary.eq(uart.rx)
+
+ # to even be able to get at objects, you first have to make them
+ # available - i.e. not as local variables
+ self.gpio = gpio
+ self.uart = uart
+
+ # sigh these wire up to the pads so you cannot set Signals
+ # that are already wired
+ if self.no_jtag_connect: # bypass jtag pad connect for testing purposes
+ return m
+ return self.jtag.boundary_elaborate(m, platform)
+
+ def ports(self):
+ return list(self)
+ def __iter__(self):
+ yield from self.jtag.iter_ports()
'''
_trellis_command_templates = [
connectors = []
resources = OrderedDict()
required_tools = []
- command_templates = ['/bin/true']
+ command_templates = ['/bin/true'] # no command needed: stops barfing
file_templates = {
**TemplatedPlatform.build_script_templates,
"{{name}}.il": r"""
default_rst = "rst" # should be picked up / overridden by platform sys.rst
def __init__(self, resources, jtag):
- self.pad_mgr = ResourceManager([], [])
self.jtag = jtag
super().__init__()
+
# create set of pin resources based on the pinset, this is for the core
+ #jtag_resources = self.jtag.pad_mgr.resources
self.add_resources(resources)
- # record resource lookup between core IO names and pads
- self.padlookup = {}
-
- def request(self, name, number=0, *, dir=None, xdr=None):
- """request a Resource (e.g. name="uart", number=0) which will
- return a data structure containing Records of all the pins.
- this override will also - automatically - create a JTAG Boundary Scan
- connection *without* any change to the actual Platform.request() API
- """
- # okaaaay, bit of shenanigens going on: the important data structure
- # here is Resourcemanager._ports. requests add to _ports, which is
- # what needs redirecting. therefore what has to happen is to
- # capture the number of ports *before* the request. sigh.
- start_ports = len(self._ports)
- value = super().request(name, number, dir=dir, xdr=xdr)
- end_ports = len(self._ports)
-
- # now make a corresponding (duplicate) request to the pad manager
- # BUT, if it doesn't exist, don't sweat it: all it means is, the
- # application did not request Boundary Scan for that resource.
- pad_start_ports = len(self.pad_mgr._ports)
- try:
- pvalue = self.pad_mgr.request(name, number, dir=dir, xdr=xdr)
- except AssertionError:
- return value
- pad_end_ports = len(self.pad_mgr._ports)
-
- # ok now we have the lengths: now create a lookup between the pad
- # and the core, so that JTAG boundary scan can be inserted in between
- core = self._ports[start_ports:end_ports]
- pads = self.pad_mgr._ports[pad_start_ports:pad_end_ports]
- # oops if not the same numbers added. it's a duplicate. shouldn't happen
- assert len(core) == len(pads), "argh, resource manager error"
- print ("core", core)
- print ("pads", pads)
-
- # pad/core each return a list of tuples of (res, pin, port, attrs)
- for pad, core in zip(pads, core):
- # create a lookup on pin name to get at the hidden pad instance
- # this pin name will be handed to get_input, get_output etc.
- # and without the padlookup you can't find the (duplicate) pad.
- # note that self.padlookup and self.jtag.ios use the *exact* same
- # pin.name per pin
- pin = pad[1]
- corepin = core[1]
- if pin is None: continue # skip when pin is None
- assert corepin is not None # if pad was None, core should be too
- print ("iter", pad, pin.name)
- assert pin.name not in self.padlookup # no overwrites allowed!
- assert pin.name == corepin.name # has to be the same!
- self.padlookup[pin.name] = pad # store pad by pin name
-
- # now add the IO Shift Register. first identify the type
- # then request a JTAG IOConn. we can't wire it up (yet) because
- # we don't have a Module() instance. doh. that comes in get_input
- # and get_output etc. etc.
- iotype = resiotypes[pin.dir] # look up the C4M-JTAG IOType
- io = self.jtag.add_io(iotype=iotype, name=pin.name) # create IOConn
- self.jtag.ios[pin.name] = io # store IOConn Record by pin name
-
- # finally return the value just like ResourceManager.request()
- return value
+ # add JTAG without scan
+ self.add_resources([JTAGResource('jtag', 0)], no_boundary_scan=True)
def add_resources(self, resources, no_boundary_scan=False):
- super().add_resources(resources)
- if no_boundary_scan:
- return
- # make a *second* - identical - set of pin resources for the IO ring
- padres = deepcopy(resources)
- self.pad_mgr.add_resources(padres)
+ print ("ASICPlatform add_resources", resources)
+ return super().add_resources(resources)
+
+ #def iter_ports(self):
+ # yield from super().iter_ports()
+ # for io in self.jtag.ios.values():
+ # print ("iter ports", io.layout, io)
+ # for field in io.core.fields:
+ # yield getattr(io.core, field)
+ # for field in io.pad.fields:
+ # yield getattr(io.pad, field)
# XXX these aren't strictly necessary right now but the next
# phase is to add JTAG Boundary Scan so it maaay be worth adding?
def get_input(self, pin, port, attrs, invert):
self._check_feature("single-ended input", pin, attrs,
valid_xdrs=(0,), valid_attrs=None)
- # Create a module first
+
m = Module()
print (" get_input", pin, "port", port, port.layout)
- if pin.name in ['clk_0', 'rst_0']: # sigh
- # simple pass-through from port to pin
- print("No JTAG chain in-between")
- m.d.comb += pin.i.eq(self._invert_if(invert, port))
- return m
- (res, pin, port, attrs) = self.padlookup[pin.name]
- io = self.jtag.ios[pin.name]
- print (" pad", res, pin, port, attrs)
- print (" pin", pin.layout)
- print (" jtag", io.core.layout, io.pad.layout)
- m.d.comb += io.pad.i.eq(self._invert_if(invert, port))
- m.d.comb += pin.i.eq(io.core.i)
+ m.d.comb += pin.i.eq(self._invert_if(invert, port))
return m
def get_output(self, pin, port, attrs, invert):
self._check_feature("single-ended output", pin, attrs,
valid_xdrs=(0,), valid_attrs=None)
- print (" get_output", pin, "port", port, port.layout)
m = Module()
+ print (" get_output", pin, "port", port, port.layout)
m.d.comb += port.eq(self._invert_if(invert, pin.o))
return m
self._check_feature("single-ended tristate", pin, attrs,
valid_xdrs=(0,), valid_attrs=None)
+ print (" get_tristate", pin, "port", port, port.layout)
m = Module()
- m.submodules += Instance("$tribuf",
- p_WIDTH=pin.width,
- i_EN=pin.oe,
- i_A=self._invert_if(invert, pin.o),
- o_Y=port,
- )
+ print (" pad", pin, port, attrs)
+ print (" pin", pin.layout)
+ return m
+ # m.submodules += Instance("$tribuf",
+ # p_WIDTH=pin.width,
+ # i_EN=pin.oe,
+ # i_A=self._invert_if(invert, pin.o),
+ # o_Y=port,
+ # )
+ m.d.comb += io.core.o.eq(pin.o)
+ m.d.comb += io.core.oe.eq(pin.oe)
+ m.d.comb += pin.i.eq(io.core.i)
+ m.d.comb += io.pad.i.eq(port.i)
+ m.d.comb += port.o.eq(io.pad.o)
+ m.d.comb += port.oe.eq(io.pad.oe)
return m
def get_input_output(self, pin, port, attrs, invert):
self._check_feature("single-ended input/output", pin, attrs,
valid_xdrs=(0,), valid_attrs=None)
+
print (" get_input_output", pin, "port", port, port.layout)
m = Module()
- m.submodules += Instance("$tribuf",
- p_WIDTH=pin.width,
- i_EN=pin.oe,
- i_A=self._invert_if(invert, pin.o),
- o_Y=port,
- )
- m.d.comb += pin.i.eq(self._invert_if(invert, port))
+ print (" port layout", port.layout)
+ print (" pin", pin)
+ print (" layout", pin.layout)
+ #m.submodules += Instance("$tribuf",
+ # p_WIDTH=pin.width,
+ # i_EN=io.pad.oe,
+ # i_A=self._invert_if(invert, io.pad.o),
+ # o_Y=port,
+ #)
+ # Create aliases for the port sub-signals
+ port_i = port.io[0]
+ port_o = port.io[1]
+ port_oe = port.io[2]
+
+ m.d.comb += pin.i.eq(self._invert_if(invert, port_i))
+ m.d.comb += port_o.eq(self._invert_if(invert, pin.o))
+ m.d.comb += port_oe.eq(pin.oe)
+
return m
+ def toolchain_prepare(self, fragment, name, **kwargs):
+ """override toolchain_prepare in order to grab the fragment
+ """
+ self.fragment = fragment
+ return super().toolchain_prepare(fragment, name, **kwargs)
"""
and to create a Platform instance with that list, and build
p.build(Blinker())
"""
pinset = dummy_pinset()
-top = Blinker(pinset)
print(pinset)
resources = create_resources(pinset)
-p = ASICPlatform (resources, top.jtag)
-p.build(top)
-
+top = Blinker(pinset, resources)
+
+vl = rtlil.convert(top, ports=top.ports())
+with open("test_jtag_blinker.il", "w") as f:
+ f.write(vl)
+
+if False:
+ # XXX these modules are all being added *AFTER* the build process links
+ # everything together. the expectation that this would work is...
+ # unrealistic. ordering, clearly, is important.
+
+ # dut = JTAG(test_pinset(), wb_data_wid=64, domain="sync")
+ top.jtag.stop = False
+ # rather than the client access the JTAG bus directly
+ # create an alternative that the client sets
+ class Dummy: pass
+ cdut = Dummy()
+ cdut.cbus = JTAGInterface()
+
+ # set up client-server on port 44843-something
+ top.jtag.s = JTAGServer()
+ cdut.c = JTAGClient()
+ top.jtag.s.get_connection()
+ #else:
+ # print ("running server only as requested, use openocd remote to test")
+ # sys.stdout.flush()
+ # top.jtag.s.get_connection(None) # block waiting for connection
+
+ # take copy of ir_width and scan_len
+ cdut._ir_width = top.jtag._ir_width
+ cdut.scan_len = top.jtag.scan_len
+
+ p = ASICPlatform (resources, top.jtag)
+ p.build(top)
+ # this is what needs to gets treated as "top", after "main module" top
+ # is augmented with IO pads with JTAG tacked on. the expectation that
+ # the get_input() etc functions will be called magically by some other
+ # function is unrealistic.
+ top_fragment = p.fragment
+
+# XXX simulating top (the module that does not itself contain IO pads
+# because that's covered by build) cannot possibly be expected to work
+# particularly when modules have been added *after* the platform build()
+# function has been called.
+
+def test_case0():
+ print("Starting sanity test case!")
+ print("printing out list of stuff in top")
+ print ("JTAG IOs", top.jtag.ios)
+ # ok top now has a variable named "gpio", let's enumerate that too
+ print("printing out list of stuff in top.gpio and its type")
+ print(top.gpio.__class__.__name__, dir(top.gpio))
+ # ok, it's a nmigen Record, therefore it has a layout. let's print
+ # that too
+ print("top.gpio is a Record therefore has fields and a layout")
+ print(" layout:", top.gpio.layout)
+ print(" fields:", top.gpio.fields)
+ print("Fun never ends...")
+ print(" layout, gpio2:", top.gpio.layout['gpio2'])
+ print(" fields, gpio2:", top.gpio.fields['gpio2'])
+ print(top.jtag.__class__.__name__, dir(top.jtag))
+
+ # etc etc. you get the general idea
+ delayVal = 0.2e-6
+ yield top.uart.rx.eq(0)
+ yield Delay(delayVal)
+ yield Settle()
+ yield top.gpio.gpio2.o.eq(0)
+ yield top.gpio.gpio3.o.eq(1)
+ yield Delay(delayVal)
+ yield Settle()
+ yield top.gpio.gpio2.oe.eq(1)
+ yield top.gpio.gpio3.oe.eq(1)
+ #yield top.jtag.gpio.gpio2.i.eq(1)
+ yield Delay(delayVal)
+ yield Settle()
+ gpio_o2 = 0
+ for _ in range(20):
+ # get a value first (as an integer). you were trying to set
+ # it to the actual Signal. this is not going to work. or if
+ # it does, it's very scary.
+ gpio_o2 = not gpio_o2
+ yield top.gpio.gpio2.o.eq(gpio_o2)
+
+ # ditto: here you are trying to set to an AST expression
+ # which is inadviseable (likely to fail)
+ yield top.gpio.gpio3.o.eq(~top.gpio.gpio3.o)
+ yield Delay(delayVal)
+ yield Settle()
+ # grab the JTAG resource pad
+ uart_pad = top.jtag.resource_table_pads[('uart', 0)]
+ yield uart_pad.rx.i.eq(gpio_o2)
+ yield Delay(delayVal)
+ yield Settle()
+ yield # one clock cycle
+ tx_val = yield uart_pad.tx.o
+ print ("xmit uart", tx_val, gpio_o2)
+
+ print ("jtag pad table keys")
+ print (top.jtag.resource_table_pads.keys())
+ uart_pad = top.jtag.resource_table_pads[('uart', 0)]
+ print ("uart pad", uart_pad)
+ print ("uart pad", uart_pad.layout)
+
+ yield top.gpio.gpio2.oe.eq(0)
+ yield top.gpio.gpio3.oe.eq(0)
+ #yield top.jtag.gpio.gpio2.i.eq(0)
+ yield Delay(delayVal)
+ yield Settle()
+
+# Code borrowed from cesar, runs, but shouldn't actually work because of
+# self. statements and non-existent signal names.
+def test_case1():
+ print("Example test case")
+ yield Passive()
+ while True:
+ # Settle() is needed to give a quick response to
+ # the zero delay case
+ yield Settle()
+ # wait for rel_o to become active
+ while not (yield self.rel_o):
+ yield
+ yield Settle()
+ # read the transaction parameters
+ assert self.expecting, "an unexpected result was produced"
+ delay = (yield self.delay)
+ expected = (yield self.expected)
+ # wait for `delay` cycles
+ for _ in range(delay):
+ yield
+ # activate go_i for one cycle
+ yield self.go_i.eq(1)
+ yield self.count.eq(self.count + 1)
+ yield
+ # check received data against the expected value
+ result = (yield self.port)
+ assert result == expected,\
+ f"expected {expected}, received {result}"
+ yield self.go_i.eq(0)
+ yield self.port.eq(0)
+
+sim = Simulator(top)
+sim.add_clock(1e-6, domain="sync") # standard clock
+
+#sim.add_sync_process(wrap(jtag_srv(top))) #? jtag server
+#if len(sys.argv) != 2 or sys.argv[1] != 'server':
+#sim.add_sync_process(wrap(jtag_sim(cdut, top.jtag))) # actual jtag tester
+#sim.add_sync_process(wrap(dmi_sim(top.jtag))) # handles (pretends to be) DMI
+
+#sim.add_sync_process(wrap(test_case1()))
+sim.add_sync_process(wrap(test_case0()))
+
+with sim.write_vcd("blinker_test.vcd"):
+ sim.run()