-#!/usr/bin/env python
-#from pinfunctions import i2s, lpc, emmc, sdmmc, mspi, mquadspi, spi, quadspi, i2c, mi2c, jtag, uart, uartfull, rgbttl, ulpi, rgmii, flexbus1, flexbus2, sdram1, sdram2, sdram3, vss, vdd, sys, eint, pwm, gpio
+#!/usr/bin/env python3
+from nmigen.build.dsl import Resource, Subsignal, Pins
+from nmigen.build.plat import TemplatedPlatform
+from nmigen.build.res import ResourceManager, ResourceError
+from nmigen import Elaboratable, Signal, Module, Instance
+from collections import OrderedDict
+from jtag import JTAG, resiotypes
+from copy import deepcopy
+
+# Was thinking of using these functions, but skipped for simplicity for now
+# XXX nope. the output from JSON file.
+#from pinfunctions import (i2s, lpc, emmc, sdmmc, mspi, mquadspi, spi,
+# quadspi, i2c, mi2c, jtag, uart, uartfull, rgbttl, ulpi, rgmii, flexbus1,
+# flexbus2, sdram1, sdram2, sdram3, vss, vdd, sys, eint, pwm, gpio)
+
+# File for stage 1 pinmux tested proposed by Luke,
+# https://bugs.libre-soc.org/show_bug.cgi?id=50#c10
-# File for stage 1 pinmux tested proposed by Luke, https://bugs.libre-soc.org/show_bug.cgi?id=50#c10
def dummy_pinset():
# sigh this needs to come from pinmux.
- num_gpios = 16
- num_eint = 3
- num_pow3v3 = 10
- num_pow1v8 = 13
-
gpios = []
- for i in range(num_gpios):
+ for i in range(4):
gpios.append("%d*" % i)
-
- eint = []
- for i in range(num_eint):
- eint.append("%d-" % i)
-
- vdd3v3 = []
- vss3v3 = []
- vdd1v8 = []
- vss1v8 = []
- for i in range(num_pow3v3):
- vdd3v3.append("%d-" % i)
- vss3v3.append("%d-" % i)
- for i in range(num_pow1v8):
- vdd1v8.append("%d-" % i)
- vss1v8.append("%d-" % i)
-
- rgmii = ['erxd0-', 'erxd1-', 'erxd2-', 'erxd3-', 'etxd0+', 'etxd1+', 'etxd2+', 'etxd3+', 'erxck-', 'erxerr-', 'erxdv-', 'emdc+', 'emdio*', 'etxen+', 'etxck+', 'ecrs-', 'ecol+', 'etxerr+']
- ulpi = ['CK+', 'DIR+', 'STP+', 'NXT+', 'D0*', 'D1*', 'D2*', 'D3*', 'D4*', 'D5*', 'D6*', 'D7*']
-
- sdr = ['DQM0+', 'D0*', 'D1*', 'D2*', 'D3*', 'D4*', 'D5*', 'D6*', 'D7*', 'BA0+', 'BA1+', 'AD0+', 'AD1+', 'AD2+', 'AD3+', 'AD4+', 'AD5+', 'AD6+', 'AD7+', 'AD8+', 'AD9+', 'CLK+', 'CKE+', 'RASn+', 'CASn+', 'WEn+', 'CSn0+']
return {'uart': ['tx+', 'rx-'],
'gpio': gpios,
- 'i2c': ['sda*', 'scl+'],
- 'rg0': rgmii,
- 'rg1': rgmii,
- 'rg2': rgmii,
- 'rg3': rgmii,
- 'rg4': rgmii,
- 'ulpi0': ulpi,
- 'ulpi1': ulpi,
- 'sdr': sdr,
- 'jtag': ['TMS-', 'TDI-', 'TDO+', 'TCK+'],
- 'vdd3v3': vdd3v3,
- 'vss3v3': vss3v3,
- 'vdd1v8': vdd1v8,
- 'vss1v8': vss1v8,
- 'sys': ['RST-', 'PLLCLK-', 'PLLSELA0-', 'PLLSELA1-', 'PLLTESTOUT+', 'PLLVCOUT+'],
- 'mspi0': ['CK+', 'NSS+', 'MOSI+', 'MISO-'],
- 'eint': eint,
- 'qspi': ['CK+', 'NSS+', 'IO0*', 'IO1*', 'IO2*', 'IO3*'],
- 'sd0': ['CMD*', 'CLK+', 'D0*', 'D1*', 'D2*', 'D3*'],
- }
-
-# testing .....
-resources = dummy_pinset()
-print(resources)
\ No newline at end of file
+ 'i2c': ['sda*', 'scl+']}
+
+"""
+a function is needed which turns the results of dummy_pinset()
+into:
+
+[UARTResource("uart", 0, tx=..., rx=..),
+ I2CResource("i2c", 0, scl=..., sda=...),
+ Resource("gpio", 0, Subsignal("i"...), Subsignal("o"...)
+ Resource("gpio", 1, Subsignal("i"...), Subsignal("o"...)
+ ...
+]
+"""
+
+
+def create_resources(pinset):
+ resources = []
+ for periph, pins in pinset.items():
+ print(periph, pins)
+ if periph == 'i2c':
+ #print("I2C required!")
+ resources.append(I2CResource('i2c', 0, sda='sda', scl='scl'))
+ elif periph == 'uart':
+ #print("UART required!")
+ resources.append(UARTResource('uart', 0, tx='tx', rx='rx'))
+ elif periph == 'gpio':
+ #print("GPIO required!")
+ print ("GPIO is defined as '*' type, meaning i, o and oe needed")
+ ios = []
+ for pin in pins:
+ pname = "gpio"+pin[:-1] # strip "*" on end
+ # 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
+ pad = Subsignal("io",
+ Pins("%s_i %s_o %s_oe" % (pname, pname, pname),
+ dir="io", assert_width=3))
+ ios.append(Resource(pname, 0, pad))
+ resources.append(Resource.family(periph, 0, default_name="gpio",
+ ios=ios))
+
+ # add clock and reset
+ clk = Resource("clk", 0, Pins("sys_clk", dir="i"))
+ rst = Resource("rst", 0, Pins("sys_rst", dir="i"))
+ resources.append(clk)
+ resources.append(rst)
+ return resources
+
+
+def UARTResource(*args, rx, tx):
+ io = []
+ io.append(Subsignal("rx", Pins(rx, dir="i", assert_width=1)))
+ io.append(Subsignal("tx", Pins(tx, dir="o", assert_width=1)))
+ return Resource.family(*args, default_name="uart", ios=io)
+
+
+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.
+class Blinker(Elaboratable):
+ def __init__(self, pinset):
+ self.jtag = JTAG({}, "sync")
+
+ def elaborate(self, platform):
+ m = Module()
+ m.submodules.jtag = self.jtag
+ count = Signal(5)
+ m.d.sync += count.eq(5)
+ print ("resources", platform.resources.items())
+ gpio = platform.request('gpio')
+ print (gpio, gpio.layout, gpio.fields)
+ # get the GPIO bank, mess about with some of the pins
+ m.d.comb += gpio.gpio0.io.o.eq(1)
+ m.d.comb += gpio.gpio1.io.o.eq(gpio.gpio2.io.i)
+ m.d.comb += gpio.gpio1.io.oe.eq(count[4])
+ m.d.sync += count[0].eq(gpio.gpio1.io.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
+
+
+'''
+ _trellis_command_templates = [
+ r"""
+ {{invoke_tool("yosys")}}
+ {{quiet("-q")}}
+ {{get_override("yosys_opts")|options}}
+ -l {{name}}.rpt
+ {{name}}.ys
+ """,
+ ]
+'''
+
+# sigh, have to create a dummy platform for now.
+# TODO: investigate how the heck to get it to output ilang. or verilog.
+# or, anything, really. but at least it doesn't barf
+class ASICPlatform(TemplatedPlatform):
+ connectors = []
+ resources = OrderedDict()
+ required_tools = []
+ command_templates = ['/bin/true']
+ file_templates = {
+ **TemplatedPlatform.build_script_templates,
+ "{{name}}.il": r"""
+ # {{autogenerated}}
+ {{emit_rtlil()}}
+ """,
+ "{{name}}.debug.v": r"""
+ /* {{autogenerated}} */
+ {{emit_debug_verilog()}}
+ """,
+ }
+ toolchain = None
+ default_clk = "clk" # should be picked up / overridden by platform sys.clk
+ 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
+ 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)
+ print ("existing pads", self.padlookup.keys())
+ 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
+
+ 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)
+
+ # XXX these aren't strictly necessary right now but the next
+ # phase is to add JTAG Boundary Scan so it maaay be worth adding?
+ # at least for the print statements
+ def get_input(self, pin, port, attrs, invert):
+ self._check_feature("single-ended input", pin, attrs,
+ valid_xdrs=(0,), valid_attrs=None)
+
+ 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)
+ return m
+
+ def get_output(self, pin, port, attrs, invert):
+ self._check_feature("single-ended output", pin, attrs,
+ valid_xdrs=(0,), valid_attrs=None)
+
+ m = Module()
+ print (" get_output", pin, "port", port, port.layout)
+ if pin.name in ['clk_0', 'rst_0']: # sigh
+ # simple pass-through from pin to port
+ print("No JTAG chain in-between")
+ m.d.comb += port.eq(self._invert_if(invert, pin.o))
+ 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 += port.eq(self._invert_if(invert, io.pad.o))
+ m.d.comb += pin.o.eq(io.core.o)
+ return m
+
+ def get_tristate(self, pin, port, attrs, invert):
+ self._check_feature("single-ended tristate", pin, attrs,
+ valid_xdrs=(0,), valid_attrs=None)
+
+ print (" get_tristate", pin, "port", port, port.layout)
+ m = Module()
+ if pin.name in ['clk_0', 'rst_0']: # sigh
+ print("No JTAG chain in-between")
+ # Can port's i/o/oe be accessed like this?
+ m.d.comb += port.o.eq(pin.o)
+ m.d.comb += port.oe.eq(pin.oe)
+ m.d.comb += pin.i.eq(port.i)
+ 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.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()
+ if pin.name in ['clk_0', 'rst_0']: # sigh
+ print("No JTAG chain in-between")
+ m.submodules += Instance("$tribuf",
+ p_WIDTH=pin.width,
+ i_EN=pin.oe,
+ i_A=self._invert_if(invert, pin.o),
+ o_Y=port,
+ )
+ m.d.comb += pin.i.eq(self._invert_if(invert, port))
+ return m
+ (res, pin, port, attrs) = self.padlookup[pin.name]
+ io = self.jtag.ios[pin.name]
+ print (" pad", res, pin, port, attrs)
+ print (" pin", pin.layout)
+ print (" jtag", io.core.layout, io.pad.layout)
+ m.submodules += Instance("$tribuf",
+ p_WIDTH=pin.width,
+ i_EN=io.pad.oe,
+ i_A=self._invert_if(invert, io.pad.o),
+ o_Y=port,
+ )
+ m.d.comb += io.pad.i.eq(self._invert_if(invert, port))
+ m.d.comb += pin.i.eq(io.core.i)
+ m.d.comb += io.core.o.eq(pin.o)
+ m.d.comb += io.core.oe.eq(pin.oe)
+ return m
+
+
+"""
+and to create a Platform instance with that list, and build
+something random
+
+ p=Platform()
+ p.resources=listofstuff
+ p.build(Blinker())
+"""
+pinset = dummy_pinset()
+top = Blinker(pinset)
+print(pinset)
+resources = create_resources(pinset)
+p = ASICPlatform (resources, top.jtag)
+p.build(top)
+