Modified for use with pinmux, will probably change the class name later.
"""
from random import randint
-from nmigen import Elaboratable, Module, Signal, Record, Array
+from math import ceil, floor
+from nmigen import Elaboratable, Module, Signal, Record, Array, Cat, Const
+from nmigen.hdl.rec import Layout
from nmigen.utils import log2_int
from nmigen.cli import rtlil
from soc.minerva.wishbone import make_wb_layout
from nmutil.util import wrap
from soc.bus.test.wb_rw import wb_read, wb_write
+from nmutil.gtkw import write_gtkw
+
cxxsim = False
if cxxsim:
from nmigen.sim.cxxsim import Simulator, Settle
from nmigen.sim import Simulator, Settle
# Layout of 8-bit configuration word:
-# bank_select[2:0] i/o | pden puen ien oe
-OESHIFT = 0
-IESHIFT = 1
-PUSHIFT = 2
-PDSHIFT = 3
-IOSHIFT = 4
-BANKSHIFT = 5
-NUMBANKBITS = 3 # only supporting 8 banks (0-7)
-
-# For future testing:
-WORDSIZE = 8 # in bytes
+# bank[2:0] i/o | pden puen ien oe
+NUMBANKBITS = 3 # max 3 bits, only supporting 4 banks (0-3)
+csrbus_layout = (("oe", 1),
+ ("ie", 1),
+ ("puen", 1),
+ ("pden", 1),
+ ("io", 1),
+ ("bank", NUMBANKBITS)
+ )
+
+gpio_layout = (("i", 1),
+ ("oe", 1),
+ ("o", 1),
+ ("puen", 1),
+ ("pden", 1),
+ ("bank", NUMBANKBITS)
+ )
class SimpleGPIO(Elaboratable):
- def __init__(self, n_gpio=16):
+ def __init__(self, wordsize=4, n_gpio=16):
+ self.wordsize = wordsize
self.n_gpio = n_gpio
+ self.n_rows = ceil(self.n_gpio / self.wordsize)
+ print("SimpleGPIO: WB Data # of bytes: {0}, #GPIOs: {1}, Rows: {2}"
+ .format(self.wordsize, self.n_gpio, self.n_rows))
class Spec: pass
spec = Spec()
spec.addr_wid = 30
spec.mask_wid = 4
- spec.reg_wid = 32
+ spec.reg_wid = wordsize*8 # 32
self.bus = Record(make_wb_layout(spec), name="gpio_wb")
- self.bank_sel = Array([Signal(NUMBANKBITS) for _ in range(n_gpio)])
- self.gpio_o = Signal(n_gpio)
- self.gpio_oe = Signal(n_gpio)
- self.gpio_i = Signal(n_gpio)
- self.gpio_ie = Signal(n_gpio)
- self.pden = Signal(n_gpio)
- self.puen = Signal(n_gpio)
+
+ temp = []
+ for i in range(self.n_gpio):
+ name = "gpio{}".format(i)
+ temp.append(Record(name=name, layout=gpio_layout))
+ self.gpio_ports = Array(temp)
def elaborate(self, platform):
m = Module()
wb_wr_data = bus.dat_w
wb_ack = bus.ack
- bank_sel = self.bank_sel
- gpio_o = self.gpio_o
- gpio_oe = self.gpio_oe
- gpio_i = self.gpio_i
- gpio_ie = self.gpio_ie
- pden = self.pden
- puen = self.puen
-
- comb += wb_ack.eq(0)
-
- gpio_addr = Signal(log2_int(self.n_gpio))
- gpio_o_list = Array(list(gpio_o))
- print(bank_sel)
- print(gpio_o_list)
- gpio_oe_list = Array(list(gpio_oe))
- gpio_i_list = Array(list(gpio_i))
- gpio_ie_list = Array(list(gpio_ie))
- pden_list = Array(list(pden))
- puen_list = Array(list(puen))
-
- #print("Types:")
- #print("gpio_addr: ", type(gpio_addr))
- #print("gpio_o_list: ", type(gpio_o_list))
- #print("bank_sel: ", type(bank_sel))
+ gpio_ports = self.gpio_ports
+
+ # MultiCSR read and write buses
+ rd_multi = []
+ for i in range(self.wordsize):
+ name = "rd_word%d" % i
+ rd_multi.append(Record(name=name, layout=csrbus_layout))
+
+ wr_multi = []
+ for i in range(self.wordsize):
+ name = "wr_word%d" % i
+ wr_multi.append(Record(name=name, layout=csrbus_layout))
+
+ # Connecting intermediate signals to the WB data buses
+ # allows the use of Records/Layouts
+ # Split the WB data into bytes for use with individual GPIOs
+ comb += Cat(*wr_multi).eq(wb_wr_data)
+ # Connect GPIO config bytes to form a single word
+ comb += wb_rd_data.eq(Cat(*rd_multi))
+ for i in range(len(bus.sel)):
+ sync += rd_multi[i].eq(0)
# One address used to configure CSR, set output, read input
with m.If(bus.cyc & bus.stb):
- comb += wb_ack.eq(1) # always ack
- comb += gpio_addr.eq(bus.adr)
with m.If(bus.we): # write
- # Write/set output
- sync += gpio_oe_list[gpio_addr].eq(wb_wr_data[OESHIFT])
- sync += gpio_ie_list[gpio_addr].eq(wb_wr_data[IESHIFT])
- # check GPIO is in output mode and NOT input (oe high, ie low)
- with m.If(wb_wr_data[OESHIFT] & (~wb_wr_data[IESHIFT])):
- sync += gpio_o_list[gpio_addr].eq(wb_wr_data[IOSHIFT])
- sync += puen_list[gpio_addr].eq(wb_wr_data[PUSHIFT])
- sync += pden_list[gpio_addr].eq(wb_wr_data[PDSHIFT])
- # TODO: clean up name
- sync += bank_sel[gpio_addr].eq(
- wb_wr_data[BANKSHIFT:BANKSHIFT+NUMBANKBITS])
+ # Update the GPIO configs with sent parameters
+ for i in range(len(bus.sel)):
+ GPIO_num = Signal(16) # fixed for now
+ comb += GPIO_num.eq(bus.adr*len(bus.sel)+i)
+ with m.If(bus.sel[i]):
+ sync += gpio_ports[GPIO_num].oe.eq(wr_multi[i].oe)
+ sync += gpio_ports[GPIO_num].puen.eq(wr_multi[i].puen)
+ sync += gpio_ports[GPIO_num].pden.eq(wr_multi[i].pden)
+ with m.If (wr_multi[i].oe):
+ sync += gpio_ports[GPIO_num].o.eq(wr_multi[i].io)
+ with m.Else():
+ sync += gpio_ports[GPIO_num].o.eq(0)
+ sync += gpio_ports[GPIO_num].bank.eq(wr_multi[i].bank)
with m.Else(): # read
- # Read the state of CSR bits
- # Return state of input if ie
- with m.If(gpio_ie_list[gpio_addr] == 1):
- comb += wb_rd_data.eq((gpio_oe_list[gpio_addr] << OESHIFT)
- + (gpio_ie_list[gpio_addr] << IESHIFT)
- + (puen_list[gpio_addr] << PUSHIFT)
- + (pden_list[gpio_addr] << PDSHIFT)
- + (gpio_i_list[gpio_addr] << IOSHIFT)
- + (bank_sel[gpio_addr] << BANKSHIFT))
- # Return state of out if oe
- with m.Else():
- comb += wb_rd_data.eq((gpio_oe_list[gpio_addr] << OESHIFT)
- + (gpio_ie_list[gpio_addr] << IESHIFT)
- + (puen_list[gpio_addr] << PUSHIFT)
- + (pden_list[gpio_addr] << PDSHIFT)
- + (gpio_o_list[gpio_addr] << IOSHIFT)
- + (bank_sel[gpio_addr] << BANKSHIFT))
+ # Update the read multi bus with current GPIO configs
+ # not ack'ing as we need to wait 1 clk cycle before data ready
+ for i in range(len(bus.sel)):
+ GPIO_num = Signal(16) # fixed for now
+ comb += GPIO_num.eq(bus.adr*len(bus.sel)+i)
+ with m.If(bus.sel[i]):
+ sync += rd_multi[i].oe.eq(gpio_ports[GPIO_num].oe)
+ sync += rd_multi[i].ie.eq(~gpio_ports[GPIO_num].oe)
+ sync += rd_multi[i].puen.eq(gpio_ports[GPIO_num].puen)
+ sync += rd_multi[i].pden.eq(gpio_ports[GPIO_num].pden)
+ with m.If (gpio_ports[GPIO_num].oe):
+ sync += rd_multi[i].io.eq(gpio_ports[GPIO_num].o)
+ with m.Else():
+ sync += rd_multi[i].io.eq(gpio_ports[GPIO_num].i)
+ sync += rd_multi[i].bank.eq(gpio_ports[GPIO_num].bank)
+ sync += wb_ack.eq(1) # ack after latching data
+ with m.Else():
+ sync += wb_ack.eq(0)
return m
def __iter__(self):
for field in self.bus.fields.values():
yield field
- yield self.gpio_o
+ for gpio in range(len(self.gpio_ports)):
+ for field in self.gpio_ports[gpio].fields.values():
+ yield field
def ports(self):
return list(self)
-# TODO: probably make into class (or return state in a variable)
-def gpio_configure(dut, gpio, oe, ie, puen, pden, outval, bank_sel):
- csr_val = ( (oe << OESHIFT)
- | (ie << IESHIFT)
- | (puen << PUSHIFT)
- | (pden << PDSHIFT)
- | (bank_sel << BANKSHIFT) )
- print("Configuring CSR to {0:x}".format(csr_val))
- yield from wb_write(dut.bus, gpio, csr_val)
- return csr_val # return the config state
-
-# TODO: Return the configuration states
-def gpio_rd_csr(dut, gpio):
- csr_val = yield from wb_read(dut.bus, gpio)
- print("GPIO{0} | CSR: {1:x}".format(gpio, csr_val))
- print("Output Enable: {0:b}".format((csr_val >> OESHIFT) & 1))
- print("Input Enable: {0:b}".format((csr_val >> IESHIFT) & 1))
- print("Pull-Up Enable: {0:b}".format((csr_val >> PUSHIFT) & 1))
- print("Pull-Down Enable: {0:b}".format((csr_val >> PDSHIFT) & 1))
- if ((csr_val >> IESHIFT) & 1):
- print("Input: {0:b}".format((csr_val >> IOSHIFT) & 1))
- else:
- print("Output: {0:b}".format((csr_val >> IOSHIFT) & 1))
- print("Bank Select: {0:b}".format((csr_val >> BANKSHIFT) & 1))
- # gpio_parse_csr(csr_val)
- return csr_val
-
-# TODO
-def gpio_rd_input(dut, gpio):
- in_val = yield from wb_read(dut.bus, gpio)
- in_val = (in_val >> IOSHIFT) & 1
- print("GPIO{0} | Input: {1:b}".format(gpio, in_val))
- return in_val
-
-def gpio_set_out(dut, gpio, csr_val, output):
- print("Setting GPIO{0} output to {1}".format(gpio, output))
- yield from wb_write(dut.bus, gpio, csr_val | (output<<IOSHIFT))
-
-# TODO: There's probably a cleaner way to clear the bit...
-def gpio_set_in_pad(dut, gpio, in_val):
- old_in_val = yield dut.gpio_i
- if in_val:
- new_in_val = old_in_val | (in_val << gpio)
- else:
- temp = (old_in_val >> gpio) & 1
- if temp:
- mask = ~(1 << gpio)
- new_in_val = old_in_val & mask
- else:
- new_in_val = old_in_val
- print("Previous GPIO i: {0:b} | New GPIO i: {1:b}"
- .format(old_in_val, new_in_val))
- yield dut.gpio_i.eq(new_in_val)
-
+"""
def gpio_test_in_pattern(dut, pattern):
- num_gpios = len(dut.gpio_o)
+ num_gpios = len(dut.gpio_ports)
print("Test pattern:")
print(pattern)
for pat in range(0, len(pattern)):
for gpio in range(0, num_gpios):
- yield from gpio_set_in_pad(dut, gpio, pattern[pat])
+ yield gpio_set_in_pad(dut, gpio, pattern[pat])
yield
temp = yield from gpio_rd_input(dut, gpio)
print("Pattern: {0}, Reading {1}".format(pattern[pat], temp))
pat += 1
if pat == len(pattern):
break
+"""
-
-def sim_gpio(dut, use_random=True):
- print(dir(dut))
- print(dut)
- num_gpios = len(dut.gpio_o)
- if use_random:
- bank_sel = randint(0, num_gpios)
- else:
- bank_sel = 3 # not special, chose for testing
+def test_gpio_single(dut, gpio, use_random=True):
oe = 1
ie = 0
output = 0
- puen = 1
+ puen = 0
pden = 0
- gpio_csr = [0] * num_gpios
- # Configure GPIOs for
- for gpio in range(0, num_gpios):
- gpio_csr[gpio] = yield from gpio_configure(dut, gpio, oe, ie, puen,
- pden, output, bank_sel)
- # Set outputs
- for gpio in range(0, num_gpios):
- yield from gpio_set_out(dut, gpio, gpio_csr[gpio], 1)
-
- # Read CSR
- for gpio in range(0, num_gpios):
- yield from gpio_rd_csr(dut, gpio)
+ if use_random:
+ bank = randint(0, (2**NUMBANKBITS)-1)
+ print("Random bank select: {0:b}".format(bank))
+ else:
+ bank = 3 # not special, chose for testing
+
+ gpio_csr = yield from gpio_config(dut, gpio, oe, ie, puen, pden, output,
+ bank, check=True)
+ # Enable output
+ output = 1
+ gpio_csr = yield from gpio_config(dut, gpio, oe, ie, puen, pden, output,
+ bank, check=True)
+
+# Shadow reg container class
+class GPIOConfigReg():
+ def __init__(self, shift_dict):
+ self.shift_dict = shift_dict
+ self.oe=0
+ self.ie=1 # By default gpio set as input
+ self.puen=0
+ self.pden=0
+ self.io=0
+ self.bank=0
+ self.packed=0
+
+ def set(self, oe=0, ie=0, puen=0, pden=0, io=0, bank=0):
+ self.oe=oe
+ self.ie=ie
+ self.puen=puen
+ self.pden=pden
+ self.io=io
+ self.bank=bank
+ self.pack() # Produce packed byte for sending
+
+ def set_out(self, outval):
+ self.io=outval
+ self.pack() # Produce packed byte for sending
+
+ # Take config parameters of specified GPIOs, and combine them to produce
+ # bytes for sending via WB bus
+ def pack(self):
+ self.packed = ((self.oe << self.shift_dict['oe'])
+ | (self.ie << self.shift_dict['ie'])
+ | (self.puen << self.shift_dict['puen'])
+ | (self.pden << self.shift_dict['pden'])
+ | (self.io << self.shift_dict['io'])
+ | (self.bank << self.shift_dict['bank']))
+
+ #print("GPIO Packed CSR: {0:x}".format(self.packed))
+
+# Object for storing each gpio's config state
+
+class GPIOManager():
+ def __init__(self, dut, layout, wb_bus):
+ self.dut = dut
+ self.wb_bus = wb_bus
+ # arrangement of config bits making up csr word
+ self.csr_layout = layout
+ self.shift_dict = self._create_shift_dict()
+ self.n_gpios = len(self.dut.gpio_ports)
+ print(dir(self.dut))
+ # Get the number of bits of the WB sel signal
+ # indicates the number of gpios per address
+ self.n_gp_per_adr = len(self.dut.bus.sel)
+ # Shows if data is byte/half-word/word/qword addressable?
+ self.granuality = len(self.dut.bus.dat_w) // self.n_gp_per_adr
+ self.n_rows = ceil(self.n_gpios / self.n_gp_per_adr)
+ self.shadow_csr = []
+ for i in range(self.n_gpios):
+ self.shadow_csr.append(GPIOConfigReg(self.shift_dict))
+
+ def print_info(self):
+ print("----------")
+ print("GPIO Block Info:")
+ print("Number of GPIOs: %d" % self.n_gpios)
+ print("GPIOs per WB data word: %d" % self.n_gp_per_adr)
+ print("WB data granuality: %d" % self.granuality)
+ print("Number of address rows: %d" % self.n_rows)
+ print("----------")
+
+ # The shifting of control bits in the configuration word is dependent on the
+ # defined layout. To prevent maintaining the shift constants in a separate
+ # location, the same layout is used to generate a dictionary of bit shifts
+ # with which the configuration word can be produced!
+ def _create_shift_dict(self):
+ shift = 0
+ shift_dict = {}
+ for i in range(0, len(self.csr_layout)):
+ shift_dict[self.csr_layout[i][0]] = shift
+ shift += self.csr_layout[i][1]
+ print(shift_dict)
+ return shift_dict
+
+ def _parse_gpio_arg(self, gpio_str):
+ # TODO: No input checking!
+ print("Given GPIO/range string: {}".format(gpio_str))
+ if gpio_str == "all":
+ start = 0
+ end = self.n_gpios
+ elif '-' in gpio_str:
+ start, end = gpio_str.split('-')
+ start = int(start)
+ end = int(end) + 1
+ if (end < start) or (end > self.n_gpios):
+ raise Exception("Second GPIO must be higher than first and"
+ + " must be lower or equal to last available GPIO.")
+ else:
+ start = int(gpio_str)
+ if start >= self.n_gpios:
+ raise Exception("GPIO must be less/equal to last GPIO.")
+ end = start + 1
+ print("Parsed GPIOs {0} until {1}".format(start, end))
+ return start, end
+
+ # Take a combined word and update shadow reg's
+ # TODO: convert hard-coded sizes to use the csrbus_layout (or dict?)
+ def update_single_shadow(self, csr_byte, gpio):
+ oe = (csr_byte >> self.shift_dict['oe']) & 0x1
+ ie = (csr_byte >> self.shift_dict['ie']) & 0x1
+ puen = (csr_byte >> self.shift_dict['puen']) & 0x1
+ pden = (csr_byte >> self.shift_dict['pden']) & 0x1
+ io = (csr_byte >> self.shift_dict['io']) & 0x1
+ bank = (csr_byte >> self.shift_dict['bank']) & 0x3
+
+ print("csr={0:x} | oe={1}, ie={2}, puen={3}, pden={4}, io={5}, bank={6}"
+ .format(csr_byte, oe, ie, puen, pden, io, bank))
+
+ self.shadow_csr[gpio].set(oe, ie, puen, pden, io, bank)
+ return oe, ie, puen, pden, io, bank
+
+ # Update multiple configuration registers
+ def wr(self, gp_start, gp_end, check=False):
+ # Some maths to determine how many transactions, and at which
+ # address to start transmitting
+ n_gp_config = gp_end - gp_start
+ adr_start = gp_start // self.n_gp_per_adr
+ n_adr = ceil(n_gp_config / self.n_gp_per_adr)
+
+ curr_gpio = gp_start
+ # cycle through addresses, each iteration is a WB tx
+ for adr in range(adr_start, adr_start + n_adr):
+ tx_sel = 0
+ tx_word = 0
+ # cycle through every WB sel bit, and add configs of
+ # corresponding gpios
+ for i in range(0, self.n_gp_per_adr):
+ # if current gpio's location in the WB data word matches sel bit
+ if (curr_gpio % self.n_gp_per_adr) == i:
+ print("gpio%d" % curr_gpio)
+ tx_sel += 1 << i
+ tx_word += (self.shadow_csr[curr_gpio].packed
+ << (self.granuality * i))
+ curr_gpio += 1
+ # stop if we processed all required gpios
+ if curr_gpio >= gp_end:
+ break
+ print("Adr: %x | Sel: %x | TX Word: %x" % (adr, tx_sel, tx_word))
+ yield from wb_write(self.wb_bus, adr, tx_word, tx_sel)
+ yield # Allow one clk cycle to propagate
+
+ if(check):
+ row_word = yield from wb_read(self.wb_bus, adr, tx_sel)
+ assert config_word == read_word
+
+ def rd(self, gp_start, gp_end):
+ # Some maths to determine how many transactions, and at which
+ # address to start transmitting
+ n_gp_config = gp_end - gp_start
+ adr_start = gp_start // self.n_gp_per_adr
+ n_adr = ceil(n_gp_config / self.n_gp_per_adr)
+
+ curr_gpio = gp_start
+ # cycle through addresses, each iteration is a WB tx
+ for adr in range(adr_start, adr_start + n_adr):
+ tx_sel = 0
+ # cycle through every WB sel bit, and add configs of
+ # corresponding gpios
+ for i in range(0, self.n_gp_per_adr):
+ # if current gpio's location in the WB data word matches sel bit
+ if (curr_gpio % self.n_gp_per_adr) == i:
+ print("gpio%d" % curr_gpio)
+ tx_sel += 1 << i
+ curr_gpio += 1
+ # stop if we processed all required gpios
+ if curr_gpio >= gp_end:
+ break
+ print("Adr: %x | Sel: %x " % (adr, tx_sel))
+ row_word = yield from wb_read(self.wb_bus, adr, tx_sel)
+
+ mask = (2**self.granuality) - 1
+ for i in range(self.n_gp_per_adr):
+ if ((tx_sel >> i) & 1) == 1:
+ single_csr = (row_word >> (i*self.granuality)) & mask
+ curr_gpio = adr*self.n_gp_per_adr + i
+ #print("rd gpio%d" % curr_gpio)
+ self.update_single_shadow(single_csr, curr_gpio)
+
+ # Write all shadow registers to GPIO block
+ def wr_all(self, check=False):
+ for row in range(0, self.n_rows):
+ yield from self.wr(0, self.n_gpios, check)
+
+ # Read all GPIO block row addresses and update shadow reg's
+ def rd_all(self, check=False):
+ for row in range(0, self.n_rows):
+ yield from self.rd(0, self.n_gpios)
+
+ def config(self, gpio_str, oe, ie, puen, pden, outval, bank, check=False):
+ start, end = self._parse_gpio_arg(gpio_str)
+ # Update the shadow configuration
+ for gpio in range(start, end):
+ # print(oe, ie, puen, pden, outval, bank)
+ self.shadow_csr[gpio].set(oe, ie, puen, pden, outval, bank)
+ # TODO: only update the required rows?
+ #yield from self.wr_all()
+ yield from self.wr(start, end)
+
+ # Set/Clear the output bit for single or group of GPIOs
+ def set_out(self, gpio_str, outval):
+ start, end = self._parse_gpio_arg(gpio_str)
+ for gpio in range(start, end):
+ self.shadow_csr[gpio].set_out(outval)
+
+ if start == end:
+ print("Setting GPIO{0} output to {1}".format(start, outval))
+ else:
+ print("Setting GPIOs {0}-{1} output to {2}"
+ .format(start, end-1, outval))
+
+ yield from self.wr(start, end)
+
+ def rd_input(self, gpio_str):
+ start, end = self._parse_gpio_arg(gpio_str)
+ #read_data = [0] * self.n_rows
+ #for row in range(0, self.n_rows):
+ # read_data[row] = yield from self.rd_row(row)
+ yield from self.rd(start, end)
+
+ num_to_read = (end - start)
+ read_in = [0] * num_to_read
+ curr_gpio = 0
+ for i in range(0, num_to_read):
+ read_in[i] = self.shadow_csr[curr_gpio].io
+ curr_gpio += 1
+
+ print("GPIOs %d until %d, i=%s".format(start, end, read_in))
+ return read_in
+
+ # TODO: There's probably a cleaner way to clear the bit...
+ def sim_set_in_pad(self, gpio_str, in_val):
+ start, end = self._parse_gpio_arg(gpio_str)
+ for gpio in range(start, end):
+ old_in_val = yield self.dut.gpio_ports[gpio].i
+ print(old_in_val)
+ print("GPIO{0} Previous i: {1:b} | New i: {2:b}"
+ .format(gpio, old_in_val, in_val))
+ yield self.dut.gpio_ports[gpio].i.eq(in_val)
+ yield # Allow one clk cycle to propagate
+
+ def rd_shadow(self):
+ shadow_csr = [0] * self.n_gpios
+ for gpio in range(0, self.n_gpios):
+ shadow_csr[gpio] = self.shadow_csr[gpio].packed
+
+ hex_str = ""
+ for reg in shadow_csr:
+ hex_str += " "+hex(reg)
+ print("Shadow reg's: ", hex_str)
+
+ return shadow_csr
+
+
+def sim_gpio(dut, use_random=True):
+ #print(dut)
+ #print(dir(dut.gpio_ports))
+ #print(len(dut.gpio_ports))
+ gpios = GPIOManager(dut, csrbus_layout)
+ gpios.print_info()
# TODO: not working yet
#test_pattern = []
#for i in range(0, (num_gpios * 2)):
# test_pattern.append(randint(0,1))
#yield from gpio_test_in_pattern(dut, test_pattern)
+ #yield from gpio_config(dut, start_gpio, oe, ie, puen, pden, outval, bank, end_gpio, check=False, wordsize=4)
+ #reg_val = 0xC56271A2
+ #reg_val = 0xFFFFFFFF
+ #yield from reg_write(dut, 0, reg_val)
+ #yield from reg_write(dut, 0, reg_val)
+ #yield
+
+ #csr_val = yield from wb_read(dut.bus, 0)
+ #print("CSR Val: {0:x}".format(csr_val))
print("Finished the simple GPIO block test!")
+def gen_gtkw_doc(n_gpios, wordsize, filename):
+ # GTKWave doc generation
+ wb_data_width = wordsize*8
+ n_rows = ceil(n_gpios/wordsize)
+ style = {
+ '': {'base': 'hex'},
+ 'in': {'color': 'orange'},
+ 'out': {'color': 'yellow'},
+ 'debug': {'module': 'top', 'color': 'red'}
+ }
+
+ # Create a trace list, each block expected to be a tuple()
+ traces = []
+ wb_traces = ('Wishbone Bus', [
+ ('gpio_wb__cyc', 'in'),
+ ('gpio_wb__stb', 'in'),
+ ('gpio_wb__we', 'in'),
+ ('gpio_wb__adr[27:0]', 'in'),
+ ('gpio_wb__sel[3:0]', 'in'),
+ ('gpio_wb__dat_w[{}:0]'.format(wb_data_width-1), 'in'),
+ ('gpio_wb__dat_r[{}:0]'.format(wb_data_width-1), 'out'),
+ ('gpio_wb__ack', 'out'),
+ ])
+ traces.append(wb_traces)
+
+ gpio_internal_traces = ('Internal', [
+ ('clk', 'in'),
+ ('new_transaction'),
+ ('rst', 'in')
+ ])
+ traces.append(gpio_internal_traces)
+
+ traces.append({'comment': 'Multi-byte GPIO config read bus'})
+ for word in range(0, wordsize):
+ prefix = "rd_word{}__".format(word)
+ single_word = []
+ word_signals = []
+ single_word.append('Word{}'.format(word))
+ word_signals.append((prefix+'bank[{}:0]'.format(NUMBANKBITS-1)))
+ word_signals.append((prefix+'ie'))
+ word_signals.append((prefix+'io'))
+ word_signals.append((prefix+'oe'))
+ word_signals.append((prefix+'pden'))
+ word_signals.append((prefix+'puen'))
+ single_word.append(word_signals)
+ traces.append(tuple(single_word))
+
+ traces.append({'comment': 'Multi-byte GPIO config write bus'})
+ for word in range(0, wordsize):
+ prefix = "wr_word{}__".format(word)
+ single_word = []
+ word_signals = []
+ single_word.append('Word{}'.format(word))
+ word_signals.append((prefix+'bank[{}:0]'.format(NUMBANKBITS-1)))
+ word_signals.append((prefix+'ie'))
+ word_signals.append((prefix+'io'))
+ word_signals.append((prefix+'oe'))
+ word_signals.append((prefix+'pden'))
+ word_signals.append((prefix+'puen'))
+ single_word.append(word_signals)
+ traces.append(tuple(single_word))
+
+ for gpio in range(0, n_gpios):
+ prefix = "gpio{}__".format(gpio)
+ single_gpio = []
+ gpio_signals = []
+ single_gpio.append('GPIO{} Port'.format(gpio))
+ gpio_signals.append((prefix+'bank[{}:0]'.format(NUMBANKBITS-1), 'out'))
+ gpio_signals.append( (prefix+'i', 'in') )
+ gpio_signals.append( (prefix+'o', 'out') )
+ gpio_signals.append( (prefix+'oe', 'out') )
+ gpio_signals.append( (prefix+'pden', 'out') )
+ gpio_signals.append( (prefix+'puen', 'out') )
+ single_gpio.append(gpio_signals)
+ traces.append(tuple(single_gpio))
+
+ #print(traces)
+
+ #module = "top.xics_icp"
+ module = "bench.top.xics_icp"
+ write_gtkw(filename+".gtkw", filename+".vcd", traces, style,
+ module=module)
+
def test_gpio():
- dut = SimpleGPIO()
+ filename = "test_gpio" # Doesn't include extension
+ n_gpios = 8
+ wordsize = 4 # Number of bytes in the WB data word
+ dut = SimpleGPIO(wordsize, n_gpios)
vl = rtlil.convert(dut, ports=dut.ports())
- with open("test_gpio.il", "w") as f:
+ with open(filename+".il", "w") as f:
f.write(vl)
m = Module()
sim = Simulator(m)
sim.add_clock(1e-6)
- sim.add_sync_process(wrap(sim_gpio(dut)))
- sim_writer = sim.write_vcd('test_gpio.vcd')
+ #sim.add_sync_process(wrap(sim_gpio(dut, use_random=False)))
+ sim.add_sync_process(wrap(test_gpioman(dut)))
+ sim_writer = sim.write_vcd(filename+".vcd")
with sim_writer:
sim.run()
+ gen_gtkw_doc(n_gpios, wordsize, filename)
+
+def test_gpioman(dut):
+ print("------START----------------------")
+ gpios = GPIOManager(dut, csrbus_layout, dut.bus)
+ gpios.print_info()
+ #gpios._parse_gpio_arg("all")
+ #gpios._parse_gpio_arg("0")
+ #gpios._parse_gpio_arg("1-3")
+ #gpios._parse_gpio_arg("20")
+
+ oe = 1
+ ie = 0
+ puen = 0
+ pden = 1
+ outval = 0
+ bank = 3
+ yield from gpios.config("0-1", oe=1, ie=0, puen=0, pden=1, outval=0, bank=2)
+ ie = 1
+ yield from gpios.config("5-7", oe=0, ie=1, puen=0, pden=1, outval=0, bank=6)
+ yield from gpios.set_out("0-1", outval=1)
+
+ #yield from gpios.rd_all()
+ yield from gpios.sim_set_in_pad("6-7", 1)
+ print("----------------------------")
+ yield from gpios.rd_input("4-7")
+
+ gpios.rd_shadow()
if __name__ == '__main__':
test_gpio()