+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))
+ print("Pads:")
+ print(top.jtag.resource_table_pads[('gpio', 0)])
+
+ # 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
+ yield top.gpio.gpio3.oe.eq(1)
+ yield
+ yield top.gpio.gpio3.oe.eq(0)
+ # grab the JTAG resource pad
+ gpios_pad = top.jtag.resource_table_pads[('gpio', 0)]
+ yield gpios_pad.gpio3.i.eq(1)
+ yield Delay(delayVal)
+ yield Settle()
+ yield top.gpio.gpio2.oe.eq(1)
+ yield top.gpio.gpio3.oe.eq(1)
+ yield gpios_pad.gpio3.i.eq(0)
+ 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)
+ gpio_o3 = not gpio_o2
+ yield top.gpio.gpio3.o.eq(gpio_o3)
+ 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()
+
+
+def test_gpios(dut):
+ print("Starting GPIO test case!")
+ # TODO: make pad access parametrisable to cope with more than 4 GPIOs
+ num_gpios = dut.gpio_o_test.width
+ # Grab GPIO outpud pad resource from JTAG BS - end of chain
+ print(dut.jtag.boundary_scan_pads.keys())
+ gpio0_o = dut.jtag.boundary_scan_pads['gpio_0__gpio0__o']['o']
+ gpio1_o = dut.jtag.boundary_scan_pads['gpio_0__gpio1__o']['o']
+ gpio2_o = dut.jtag.boundary_scan_pads['gpio_0__gpio2__o']['o']
+ gpio3_o = dut.jtag.boundary_scan_pads['gpio_0__gpio3__o']['o']
+ gpio_pad_out = [gpio0_o, gpio1_o, gpio2_o, gpio3_o]
+
+ # Grab GPIO output enable pad resource from JTAG BS - end of chain
+ gpio0_oe = dut.jtag.boundary_scan_pads['gpio_0__gpio0__oe']['o']
+ gpio1_oe = dut.jtag.boundary_scan_pads['gpio_0__gpio1__oe']['o']
+ gpio2_oe = dut.jtag.boundary_scan_pads['gpio_0__gpio2__oe']['o']
+ gpio3_oe = dut.jtag.boundary_scan_pads['gpio_0__gpio3__oe']['o']
+ gpio_pad_oe = [gpio0_oe, gpio1_oe, gpio2_oe, gpio3_oe]
+
+ # Grab GPIO input pad resource from JTAG BS - start of chain
+ gpio0_pad_in = dut.jtag.boundary_scan_pads['gpio_0__gpio0__i']['i']
+ gpio1_pad_in = dut.jtag.boundary_scan_pads['gpio_0__gpio1__i']['i']
+ gpio2_pad_in = dut.jtag.boundary_scan_pads['gpio_0__gpio2__i']['i']
+ gpio3_pad_in = dut.jtag.boundary_scan_pads['gpio_0__gpio3__i']['i']
+ gpio_pad_in = [gpio0_pad_in, gpio1_pad_in, gpio2_pad_in, gpio3_pad_in]
+
+ # Have the sim run through a for-loop where the gpio_o_test is
+ # incremented like a counter (0000, 0001...)
+ # At each iteration of the for-loop, assert:
+ # + output set at core matches output seen at pad
+ # TODO + input set at pad matches input seen at core
+ # TODO + if gpio_o_test bit is cleared, output seen at pad matches
+ # input seen at pad
+ num_gpio_o_states = num_gpios**2
+ pad_out = [0] * num_gpios
+ pad_oe = [0] * num_gpios
+ #print("Num of permutations of gpio_o_test record: ", num_gpio_o_states)
+ for gpio_o_val in range(0, num_gpio_o_states):
+ yield dut.gpio_o_test.eq(gpio_o_val)
+ # yield Settle()
+ yield # Move to the next clk cycle
+
+ # Cycle through all input combinations
+ for gpio_i_val in range(0, num_gpio_o_states):
+ # Set each gpio input at pad to test value
+ for gpio_bit in range(0, num_gpios):
+ yield gpio_pad_in[gpio_bit].eq((gpio_i_val >> gpio_bit) & 0x1)
+ yield
+ # After changing the gpio0/1/2/3 inputs,
+ # the output is also going to change.
+ # *therefore it must be read again* to get the
+ # snapshot (as a python value)
+ for gpio_bit in range(0, num_gpios):
+ pad_out[gpio_bit] = yield gpio_pad_out[gpio_bit]
+ yield
+ for gpio_bit in range(0, num_gpios):
+ # check core and pad in
+ gpio_i_ro = yield dut.gpio_i_ro[gpio_bit]
+ out_test_bit = ((gpio_o_val & (1 << gpio_bit)) != 0)
+ in_bit = ((gpio_i_val & (1 << gpio_bit)) != 0)
+ # Check that the core end input matches pad
+ assert in_bit == gpio_i_ro
+ # Test that the output at pad matches:
+ # Pad output == given test output XOR test input
+ assert (out_test_bit ^ in_bit) == pad_out[gpio_bit]
+
+ # For debugging - VERY verbose
+ # print("---------------------")
+ #print("Test Out: ", bin(gpio_o_val))
+ #print("Test Input: ", bin(gpio_i_val))
+ # Print MSB first
+ #print("Pad Output: ", list(reversed(pad_out)))
+ # print("---------------------")
+
+ # For-loop for testing output enable signals
+ for gpio_o_val in range(0, num_gpio_o_states):
+ yield dut.gpio_oe_test.eq(gpio_o_val)
+ yield # Move to the next clk cycle
+
+ for gpio_bit in range(0, num_gpios):
+ pad_oe[gpio_bit] = yield gpio_pad_oe[gpio_bit]
+ yield
+
+ for gpio_bit in range(0, num_gpios):
+ oe_test_bit = ((gpio_o_val & (1 << gpio_bit)) != 0)
+ # oe set at core matches oe seen at pad:
+ assert oe_test_bit == pad_oe[gpio_bit]
+ # For debugging - VERY verbose
+ # print("---------------------")
+ #print("Test Output Enable: ", bin(gpio_o_val))
+ # Print MSB first
+ #print("Pad Output Enable: ", list(reversed(pad_oe)))
+ # print("---------------------")
+
+ # Reset test ouput register
+ yield dut.gpio_o_test.eq(0)
+ print("GPIO Test PASSED!")
+
+
+def test_uart(dut):
+ # grab the JTAG resource pad
+ print()
+ print("bs pad keys", dut.jtag.boundary_scan_pads.keys())
+ print()
+ uart_rx_pad = dut.jtag.boundary_scan_pads['uart_0__rx']['i']
+ uart_tx_pad = dut.jtag.boundary_scan_pads['uart_0__tx']['o']
+
+ print("uart rx pad", uart_rx_pad)
+ print("uart tx pad", uart_tx_pad)
+
+ # Test UART by writing 0 and 1 to RX
+ # Internally TX connected to RX,
+ # so match pad TX with RX
+ for i in range(0, 2):
+ yield uart_rx_pad.eq(i)
+ # yield uart_rx_pad.eq(i)
+ yield Settle()
+ yield # one clock cycle
+ tx_val = yield uart_tx_pad
+ print("xmit uart", tx_val, 1)
+ assert tx_val == i
+
+ print("UART Test PASSED!")
+
+
+def test_i2c(dut):
+ i2c_sda_i_pad = dut.jtag.boundary_scan_pads['i2c_0__sda__i']['i']
+ i2c_sda_o_pad = dut.jtag.boundary_scan_pads['i2c_0__sda__o']['o']
+ i2c_sda_oe_pad = dut.jtag.boundary_scan_pads['i2c_0__sda__oe']['o']
+
+ i2c_scl_i_pad = dut.jtag.boundary_scan_pads['i2c_0__scl__i']['i']
+ i2c_scl_o_pad = dut.jtag.boundary_scan_pads['i2c_0__scl__o']['o']
+ i2c_scl_oe_pad = dut.jtag.boundary_scan_pads['i2c_0__scl__oe']['o']
+
+ #i2c_pad = dut.jtag.resource_table_pads[('i2c', 0)]
+ #print ("i2c pad", i2c_pad)
+ #print ("i2c pad", i2c_pad.layout)
+
+ for i in range(0, 2):
+ yield i2c_sda_i_pad.eq(i) # i2c_pad.sda.i.eq(i)
+ yield i2c_scl_i_pad.eq(i) # i2c_pad.scl.i.eq(i)
+ yield dut.i2c_sda_oe_test.eq(i)
+ yield dut.i2c_scl_oe_test.eq(i)
+ yield Settle()
+ yield # one clock cycle
+ sda_o_val = yield i2c_sda_o_pad
+ scl_o_val = yield i2c_scl_o_pad
+ sda_oe_val = yield i2c_sda_oe_pad
+ scl_oe_val = yield i2c_scl_oe_pad
+ print("Test input: ", i, " SDA/SCL out: ", sda_o_val, scl_o_val,
+ " SDA/SCL oe: ", sda_oe_val, scl_oe_val)
+ assert sda_o_val == i
+ assert scl_o_val == i
+ assert sda_oe_val == i
+ assert scl_oe_val == i
+
+ print("I2C Test PASSED!")
+
+# JTAG boundary scan reg addresses - See c4m/nmigen/jtag/tap.py line #357
+BS_EXTEST = 0
+BS_INTEST = 0
+BS_SAMPLE = 2
+BS_PRELOAD = 2
+
+def test_jtag_bs_chain(dut):
+ # print(dir(dut.jtag))
+ # print(dir(dut))
+ # print(dut.jtag._ir_width)
+ # print("JTAG I/O dictionary of core/pad signals:")
+ # print(dut.jtag.ios.keys())
+
+ print("JTAG BS Reset")
+ yield from jtag_set_reset(dut.jtag)
+
+ # TODO: cleanup!
+ # Based on number of ios entries, produce a test shift reg pattern
+ bslen = len(dut.jtag.ios)
+ bsdata = 2**bslen - 1 # Fill with all 1s for now
+ fulldata = bsdata # for testing
+ emptydata = 0 # for testing
+
+ mask_i = produce_ios_mask(dut, is_i=True, is_o=False, is_oe=False)
+ mask_i_oe = produce_ios_mask(dut, is_i=True, is_o=False, is_oe=True)
+ mask_o = produce_ios_mask(dut, is_i=False, is_o=True, is_oe=False)
+ mask_oe = produce_ios_mask(dut, is_i=False, is_o=False, is_oe=True)
+ mask_o_oe = produce_ios_mask(dut, is_i=False, is_o=True, is_oe=True)
+ mask_low = 0
+ mask_all = 2**bslen - 1
+
+ num_bit_format = "{:0" + str(bslen) + "b}"
+ print("Masks (LSB corresponds to bit0 of the BS chain register!)")
+ print("Input only :", num_bit_format.format(mask_i))
+ print("Input and oe:", num_bit_format.format(mask_o_oe))
+ print("Output only :", num_bit_format.format(mask_o))
+ print("Out en only :", num_bit_format.format(mask_oe))
+ print("Output and oe:", num_bit_format.format(mask_o_oe))
+
+ yield from jtag_unit_test(dut, BS_EXTEST, False, bsdata, mask_o_oe, mask_o)
+ yield from jtag_unit_test(dut, BS_SAMPLE, False, bsdata, mask_low, mask_low)
+
+ # Run through GPIO, UART, and I2C tests so that all signals are asserted
+ yield from test_gpios(dut)
+ yield from test_uart(dut)
+ yield from test_i2c(dut)
+
+ bsdata = emptydata
+ yield from jtag_unit_test(dut, BS_EXTEST, True, bsdata, mask_i, mask_i_oe)
+ yield from jtag_unit_test(dut, BS_SAMPLE, True, bsdata, mask_all, mask_all)
+
+ print("JTAG Boundary Scan Chain Test PASSED!")
+
+# ONLY NEEDED FOR DEBUG - MAKE SURE TAP DRIVER FUNCTIONS CORRECT FIRST!
+def swap_bit_order(word, wordlen):
+ rev_word = 0
+ for i in range(wordlen):
+ rev_word += ((word >> i) & 0x1) << (wordlen-1-i)
+
+ num_bit_format = "{:0" + str(wordlen) + "b}"
+ print_str = "Orig:" + num_bit_format + " | Bit Swapped:" + num_bit_format
+ print(print_str.format(word, rev_word))
+
+ return rev_word
+
+def jtag_unit_test(dut, bs_type, is_io_set, bsdata, exp_pads, exp_tdo):
+ bslen = len(dut.jtag.ios) #* 2
+ print("Chain len based on jtag.ios: {}".format(bslen))
+ if bs_type == BS_EXTEST:
+ print("Sending TDI data with core/pads disconnected")
+ elif bs_type == BS_SAMPLE:
+ print("Sending TDI data with core/pads connected")
+ else:
+ raise Exception("Unsupported BS chain mode!")
+
+ if is_io_set:
+ print("All pad inputs/core outputs set, bs data: {0:b}"
+ .format(bsdata))
+ else:
+ print("All pad inputs/core outputs reset, bs data: {0:b}"
+ .format(bsdata))
+
+ result = yield from jtag_read_write_reg(dut.jtag, bs_type, bslen, bsdata,
+ reverse=True)
+ if bs_type == BS_EXTEST:
+ # TDO is only outputting previous BS chain data, must configure to
+ # output BS chain to the main shift register
+ yield from jtag_set_shift_dr(dut.jtag)
+ result = yield from tms_data_getset(dut.jtag, bs_type, bslen, bsdata,
+ reverse=True)
+ yield from jtag_set_idle(dut.jtag)
+
+ # TODO: make format based on bslen, not a magic number 20-bits wide
+ print("TDI BS Data: {0:020b}, Data Length (bits): {1}"
+ .format(bsdata, bslen))
+ print("TDO BS Data: {0:020b}".format(result))
+ yield from check_ios_keys(dut, result, exp_pads, exp_tdo)
+
+ #yield # testing extra clock
+ # Reset shift register between tests
+ yield from jtag_set_reset(dut.jtag)
+
+def check_ios_keys(dut, tdo_data, test_vector, exp_tdo):
+ print("Checking ios signals with TDO and given test vectors")
+ bslen = len(dut.jtag.ios)
+ ios_keys = list(dut.jtag.ios.keys())
+ print(" ios Signals | From TDO | --- | ----")
+ print("Side|Exp|Seen | Side|Exp|Seen | I/O | Name")
+ for i in range(0, bslen):
+ signal = ios_keys[i]
+ exp_pad_val = (test_vector >> i) & 0b1
+ exp_tdo_val = (exp_tdo >> i) & 0b1
+ tdo_value = (tdo_data >> i) & 0b1
+ # Only observed signals so far are outputs...
+ # TODO: Cleanup!
+ if check_if_signal_output(ios_keys[i]):
+ temp_result = yield dut.jtag.boundary_scan_pads[signal]['o']
+ print("Pad |{0:3b}|{1:4b} | Core|{2:3b}|{3:4b} | o | {4}"
+ .format(exp_pad_val, temp_result, exp_tdo_val, tdo_value, signal))
+ # ...or inputs
+ elif check_if_signal_input(ios_keys[i]):
+ temp_result = yield dut.jtag.boundary_scan_pads[signal]['i']
+ print("Pad |{0:3b}|{1:4b} | Pad |{2:3b}|{3:4b} | i | {4}"
+ .format(exp_pad_val, temp_result, exp_tdo_val, tdo_value, signal))
+ else:
+ raise Exception("Signal in JTAG ios dict: " + signal
+ + " cannot be determined as input or output!")
+ assert temp_result == exp_pad_val
+ assert tdo_value == exp_tdo_val
+
+# TODO: may need to expand to support further signals contained in the
+# JTAG module ios dictionary!
+
+
+def check_if_signal_output(signal_str):
+ if ('__o' in signal_str) or ('__tx' in signal_str):
+ return True
+ else:
+ return False
+
+
+def check_if_signal_input(signal_str):
+ if ('__i' in signal_str) or ('__rx' in signal_str):
+ return True
+ else:
+ return False
+
+
+def produce_ios_mask(dut, is_i=False, is_o=True, is_oe=False):
+ if is_i and not(is_o) and not(is_oe):
+ mask_type = "input"
+ elif not(is_i) and is_o:
+ mask_type = "output"
+ else:
+ mask_type = "i={:b} | o={:b} | oe={:b} ".format(is_i, is_o, is_oe)
+ print("Determine the", mask_type, "mask")
+ bslen = len(dut.jtag.ios)
+ ios_keys = list(dut.jtag.ios.keys())
+ mask = 0
+ for i in range(0, bslen):
+ signal = ios_keys[i]
+ if (('__o' in ios_keys[i]) or ('__tx' in ios_keys[i])):
+ if ('__oe' in ios_keys[i]):
+ if is_oe:
+ mask += (1 << i)
+ else:
+ if is_o:
+ mask += (1 << i)
+ else:
+ if is_i:
+ mask += (1 << i)
+ return mask
+
+
+def print_all_ios_keys(dut):
+ print("Print all ios keys")
+ bslen = len(dut.jtag.ios)
+ ios_keys = list(dut.jtag.ios.keys())
+ for i in range(0, bslen):
+ signal = ios_keys[i]
+ # Check if outputs are asserted
+ if ('__o' in ios_keys[i]) or ('__tx' in ios_keys[i]):
+ print("Pad Output | Name: ", signal)
+ else:
+ print("Pad Input | Name: ", signal)
+
+
+# Copied from test_jtag_tap.py
+# JTAG-ircodes for accessing DMI
+DMI_ADDR = 5
+DMI_READ = 6
+DMI_WRRD = 7
+
+# JTAG-ircodes for accessing Wishbone
+WB_ADDR = 8
+WB_READ = 9
+WB_WRRD = 10
+
+
+def test_jtag_dmi_wb():
+ print(dir(top.jtag))
+ print(dir(top))
+ print("JTAG BS Reset")
+ yield from jtag_set_reset(top.jtag)
+
+ print("JTAG I/O dictionary of core/pad signals:")
+ print(top.jtag.ios.keys())
+
+ # Copied from test_jtag_tap
+ # Don't know if the ID is the same for all JTAG instances
+ ####### JTAGy stuff (IDCODE) ######
+
+ # read idcode
+ idcode = yield from jtag_read_write_reg(top.jtag, 0b1, 32)
+ print("idcode", hex(idcode))
+ assert idcode == 0x18ff
+
+ ####### JTAG to DMI ######
+
+ # write DMI address
+ yield from jtag_read_write_reg(top.jtag, DMI_ADDR, 8, DBGCore.CTRL)
+
+ # read DMI CTRL register
+ status = yield from jtag_read_write_reg(top.jtag, DMI_READ, 64)
+ print("dmi ctrl status", hex(status))
+ #assert status == 4
+
+ # write DMI address
+ yield from jtag_read_write_reg(top.jtag, DMI_ADDR, 8, 0)
+
+ # write DMI CTRL register
+ status = yield from jtag_read_write_reg(top.jtag, DMI_WRRD, 64, 0b101)
+ print("dmi ctrl status", hex(status))
+ # assert status == 4 # returned old value (nice! cool feature!)
+
+ # write DMI address
+ yield from jtag_read_write_reg(top.jtag, DMI_ADDR, 8, DBGCore.CTRL)
+
+ # read DMI CTRL register
+ status = yield from jtag_read_write_reg(top.jtag, DMI_READ, 64)
+ print("dmi ctrl status", hex(status))
+ #assert status == 6
+
+ # write DMI MSR address
+ yield from jtag_read_write_reg(top.jtag, DMI_ADDR, 8, DBGCore.MSR)
+
+ # read DMI MSR register
+ msr = yield from jtag_read_write_reg(top.jtag, DMI_READ, 64)
+ print("dmi msr", hex(msr))
+ #assert msr == 0xdeadbeef
+
+ ####### JTAG to Wishbone ######
+
+ # write Wishbone address
+ yield from jtag_read_write_reg(top.jtag, WB_ADDR, 16, 0x18)
+
+ # write/read wishbone data
+ data = yield from jtag_read_write_reg(top.jtag, WB_WRRD, 16, 0xfeef)
+ print("wb write", hex(data))
+
+ # write Wishbone address
+ yield from jtag_read_write_reg(top.jtag, WB_ADDR, 16, 0x18)
+
+ # write/read wishbone data
+ data = yield from jtag_read_write_reg(top.jtag, WB_READ, 16, 0)
+ print("wb read", hex(data))
+
+ ####### done - tell dmi_sim to stop (otherwise it won't) ########
+
+ top.jtag.stop = True
+
+
+def test_debug_print(dut):
+ print("Test used for getting object methods/information")
+ print("Moved here to clear clutter of gpio test")
+
+ print("printing out info about the resource gpio0")
+ print(dut.gpio['gpio0']['i'])
+ print("this is a PIN resource", type(dut.gpio['gpio0']['i']))
+ # yield can only be done on SIGNALS or RECORDS,
+ # NOT Pins/Resources gpio0_core_in = yield top.gpio['gpio0']['i']
+ #print("Test gpio0 core in: ", gpio0_core_in)
+
+ print("JTAG")
+ print(dut.jtag.__class__.__name__, dir(dut.jtag))
+ print("TOP")
+ print(dut.__class__.__name__, dir(dut))
+ print("PORT")
+ print(dut.ports.__class__.__name__, dir(dut.ports))
+ print("GPIO")
+ print(dut.gpio.__class__.__name__, dir(dut.gpio))
+
+ print("UART")
+ print(dir(dut.jtag.boundary_scan_pads['uart_0__rx__pad__i']))
+ print(dut.jtag.boundary_scan_pads['uart_0__rx__pad__i'].keys())
+ print(dut.jtag.boundary_scan_pads['uart_0__tx__pad__o'])
+ # print(type(dut.jtag.boundary_scan_pads['uart_0__rx__pad__i']['rx']))
+ print("jtag pad table keys")
+ print(dut.jtag.resource_table_pads.keys())
+ print(type(dut.jtag.resource_table_pads[('uart', 0)].rx.i))
+ print(dut.jtag.boundary_scan_pads['uart_0__rx__i'])
+
+ print("I2C")
+ print(dut.jtag.boundary_scan_pads['i2c_0__sda__i'])
+ print(type(dut.jtag.boundary_scan_pads['i2c_0__sda__i']['i']))
+
+ print(dut.jtag.resource_table_pads)
+ print(dut.jtag.boundary_scan_pads)
+
+ # Trying to read input from core side, looks like might be a pin...
+ # XXX don't "look like" - don't guess - *print it out*
+ #print ("don't guess, CHECK", type(top.gpio.gpio0.i))
+
+ print() # extra print to divide the output
+ yield
+
+
+def setup_blinker(build_blinker=False):
+ """
+ and to create a Platform instance with that list, and build
+ something random
+
+ p=Platform()
+ p.resources=listofstuff
+ p.build(Blinker())
+ """
+
+ pinset = dummy_pinset()
+ print(pinset)
+ resources = create_resources(pinset)
+ top = Blinker(pinset, resources, no_jtag_connect=False) # True)
+
+ vl = rtlil.convert(top, ports=top.ports())
+ with open("test_jtag_blinker.il", "w") as f:
+ f.write(vl)
+
+ if build_blinker:
+ # 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.
+
+ # This JTAG code copied from test, probably not needed
+ # 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
+
+ return top
+
+
+def test_jtag():
+ dut = setup_blinker(build_blinker=False)
+
+ # 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.
+
+ sim = Simulator(dut)
+ 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':
+ # actual jtag tester
+ #sim.add_sync_process(wrap(jtag_sim(cdut, top.jtag)))
+ # handles (pretends to be) DMI
+ # sim.add_sync_process(wrap(dmi_sim(top.jtag)))
+
+ # sim.add_sync_process(wrap(test_gpios(top)))
+ # sim.add_sync_process(wrap(test_uart(top)))
+ # sim.add_sync_process(wrap(test_i2c(top)))
+ # sim.add_sync_process(wrap(test_debug_print()))
+
+ sim.add_sync_process(wrap(test_jtag_bs_chain(dut)))
+
+ with sim.write_vcd("blinker_test.vcd"):
+ sim.run()
+
+
+if __name__ == '__main__':
+ test_jtag()