logicanalyzer
24 channel, 100Msps logic analyzer hardware and software
##
## This file is part of the libsigrokdecode project.
##
## Copyright (C) 2012-2020 Uwe Hermann <[email protected]>
##
## This program is free software; you can redistribute it and/or modify
## it under the terms of the GNU General Public License as published by
## the Free Software Foundation; either version 2 of the License, or
## (at your option) any later version.
##
## This program is distributed in the hope that it will be useful,
## but WITHOUT ANY WARRANTY; without even the implied warranty of
## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
## GNU General Public License for more details.
##
## You should have received a copy of the GNU General Public License
## along with this program; if not, see <http://www.gnu.org/licenses/>.
##
import sigrokdecode as srd
from common.srdhelper import SrdStrEnum
'''
OUTPUT_PYTHON format:
Packet:
[<ptype>, <pdata>]
<ptype>:
- 'NEW STATE': <pdata> is the new state of the JTAG state machine.
Valid values: 'TEST-LOGIC-RESET', 'RUN-TEST/IDLE', 'SELECT-DR-SCAN',
'CAPTURE-DR', 'SHIFT-DR', 'EXIT1-DR', 'PAUSE-DR', 'EXIT2-DR', 'UPDATE-DR',
'SELECT-IR-SCAN', 'CAPTURE-IR', 'SHIFT-IR', 'EXIT1-IR', 'PAUSE-IR',
'EXIT2-IR', 'UPDATE-IR'.
- 'IR TDI': Bitstring that was clocked into the IR register.
- 'IR TDO': Bitstring that was clocked out of the IR register.
- 'DR TDI': Bitstring that was clocked into the DR register.
- 'DR TDO': Bitstring that was clocked out of the DR register.
All bitstrings are a list consisting of two items. The first is a sequence
of '1' and '0' characters (the right-most character is the LSB. Example:
'01110001', where 1 is the LSB). The second item is a list of ss/es values
for each bit that is in the bitstring.
'''
s = 'TEST-LOGIC-RESET RUN-TEST/IDLE \
SELECT-DR-SCAN CAPTURE-DR UPDATE-DR PAUSE-DR SHIFT-DR EXIT1-DR EXIT2-DR \
SELECT-IR-SCAN CAPTURE-IR UPDATE-IR PAUSE-IR SHIFT-IR EXIT1-IR EXIT2-IR'
St = SrdStrEnum.from_str('St', s)
jtag_states = [s.value for s in St]
class Decoder(srd.Decoder):
api_version = 3
id = 'jtag'
name = 'JTAG'
longname = 'Joint Test Action Group (IEEE 1149.1)'
desc = 'Protocol for testing, debugging, and flashing ICs.'
license = 'gplv2+'
inputs = ['logic']
outputs = ['jtag']
tags = ['Debug/trace']
channels = (
{'id': 'tdi', 'name': 'TDI', 'desc': 'Test data input'},
{'id': 'tdo', 'name': 'TDO', 'desc': 'Test data output'},
{'id': 'tck', 'name': 'TCK', 'desc': 'Test clock'},
{'id': 'tms', 'name': 'TMS', 'desc': 'Test mode select'},
)
optional_channels = (
{'id': 'trst', 'name': 'TRST#', 'desc': 'Test reset'},
{'id': 'srst', 'name': 'SRST#', 'desc': 'System reset'},
{'id': 'rtck', 'name': 'RTCK', 'desc': 'Return clock signal'},
)
annotations = tuple([tuple([s.lower(), s]) for s in jtag_states]) + ( \
('bit-tdi', 'Bit (TDI)'),
('bit-tdo', 'Bit (TDO)'),
('bitstring-tdi', 'Bitstring (TDI)'),
('bitstring-tdo', 'Bitstring (TDO)'),
)
annotation_rows = (
('bits-tdi', 'Bits (TDI)', (16,)),
('bits-tdo', 'Bits (TDO)', (17,)),
('bitstrings-tdi', 'Bitstrings (TDI)', (18,)),
('bitstrings-tdo', 'Bitstrings (TDO)', (19,)),
('states', 'States', tuple(range(15 + 1))),
)
def __init__(self):
self.reset()
def reset(self):
# self.state = St.TEST_LOGIC_RESET
self.state = St.RUN_TEST_IDLE
self.oldstate = None
self.bits_tdi = []
self.bits_tdo = []
self.bits_samplenums_tdi = []
self.bits_samplenums_tdo = []
self.ss_item = self.es_item = None
self.ss_bitstring = self.es_bitstring = None
self.saved_item = None
self.first = True
self.first_bit = True
def start(self):
self.out_python = self.register(srd.OUTPUT_PYTHON)
self.out_ann = self.register(srd.OUTPUT_ANN)
def putx(self, data):
self.put(self.ss_item, self.es_item, self.out_ann, data)
def putp(self, data):
self.put(self.ss_item, self.es_item, self.out_python, data)
def putx_bs(self, data):
self.put(self.ss_bitstring, self.es_bitstring, self.out_ann, data)
def putp_bs(self, data):
self.put(self.ss_bitstring, self.es_bitstring, self.out_python, data)
def advance_state_machine(self, tms):
self.oldstate = self.state
# Intro "tree"
if self.state == St.TEST_LOGIC_RESET:
self.state = St.TEST_LOGIC_RESET if (tms) else St.RUN_TEST_IDLE
elif self.state == St.RUN_TEST_IDLE:
self.state = St.SELECT_DR_SCAN if (tms) else St.RUN_TEST_IDLE
# DR "tree"
elif self.state == St.SELECT_DR_SCAN:
self.state = St.SELECT_IR_SCAN if (tms) else St.CAPTURE_DR
elif self.state == St.CAPTURE_DR:
self.state = St.EXIT1_DR if (tms) else St.SHIFT_DR
elif self.state == St.SHIFT_DR:
self.state = St.EXIT1_DR if (tms) else St.SHIFT_DR
elif self.state == St.EXIT1_DR:
self.state = St.UPDATE_DR if (tms) else St.PAUSE_DR
elif self.state == St.PAUSE_DR:
self.state = St.EXIT2_DR if (tms) else St.PAUSE_DR
elif self.state == St.EXIT2_DR:
self.state = St.UPDATE_DR if (tms) else St.SHIFT_DR
elif self.state == St.UPDATE_DR:
self.state = St.SELECT_DR_SCAN if (tms) else St.RUN_TEST_IDLE
# IR "tree"
elif self.state == St.SELECT_IR_SCAN:
self.state = St.TEST_LOGIC_RESET if (tms) else St.CAPTURE_IR
elif self.state == St.CAPTURE_IR:
self.state = St.EXIT1_IR if (tms) else St.SHIFT_IR
elif self.state == St.SHIFT_IR:
self.state = St.EXIT1_IR if (tms) else St.SHIFT_IR
elif self.state == St.EXIT1_IR:
self.state = St.UPDATE_IR if (tms) else St.PAUSE_IR
elif self.state == St.PAUSE_IR:
self.state = St.EXIT2_IR if (tms) else St.PAUSE_IR
elif self.state == St.EXIT2_IR:
self.state = St.UPDATE_IR if (tms) else St.SHIFT_IR
elif self.state == St.UPDATE_IR:
self.state = St.SELECT_DR_SCAN if (tms) else St.RUN_TEST_IDLE
def handle_rising_tck_edge(self, pins):
(tdi, tdo, tck, tms, trst, srst, rtck) = pins
# Rising TCK edges always advance the state machine.
self.advance_state_machine(tms)
if self.first:
# Save the start sample and item for later (no output yet).
self.ss_item = self.samplenum
self.first = False
else:
# Output the saved item (from the last CLK edge to the current).
self.es_item = self.samplenum
# Output the old state (from last rising TCK edge to current one).
self.putx([jtag_states.index(self.oldstate.value), [self.oldstate.value]])
self.putp(['NEW STATE', self.state.value])
# Upon SHIFT-*/EXIT1-* collect the current TDI/TDO values.
if self.oldstate.value.startswith('SHIFT-') or \
self.oldstate.value.startswith('EXIT1-'):
if self.first_bit:
self.ss_bitstring = self.samplenum
self.first_bit = False
else:
self.putx([16, [str(self.bits_tdi[-1])]])
self.putx([17, [str(self.bits_tdo[-1])]])
# Use self.samplenum as ES of the previous bit.
self.bits_samplenums_tdi[-1][1] = self.samplenum
self.bits_samplenums_tdo[-1][1] = self.samplenum
self.bits_tdi.append(tdi)
self.bits_tdo.append(tdo)
# Use self.samplenum as SS of the current bit.
self.bits_samplenums_tdi.append([self.samplenum, -1])
self.bits_samplenums_tdo.append([self.samplenum, -1])
# Output all TDI/TDO bits if we just switched to UPDATE-*.
if self.state.value.startswith('UPDATE-'):
self.es_bitstring = self.samplenum
t = self.state.value[-2:] + ' TDI'
self.bits_tdi.reverse()
self.bits_samplenums_tdi.reverse()
b = ''.join(map(str, self.bits_tdi[1:]))
h = ' (0x%x' % int('0b0' + b, 2) + ')'
s = t + ': ' + b + h + ', ' + str(len(self.bits_tdi[1:])) + ' bits'
self.putx_bs([18, [s]])
self.putp_bs([t, [b, self.bits_samplenums_tdi[1:]]])
self.bits_tdi = []
self.bits_samplenums_tdi = []
t = self.state.value[-2:] + ' TDO'
self.bits_tdo.reverse()
self.bits_samplenums_tdo.reverse()
b = ''.join(map(str, self.bits_tdo[1:]))
h = ' (0x%x' % int('0b0' + b, 2) + ')'
s = t + ': ' + b + h + ', ' + str(len(self.bits_tdo[1:])) + ' bits'
self.putx_bs([19, [s]])
self.putp_bs([t, [b, self.bits_samplenums_tdo[1:]]])
self.bits_tdo = []
self.bits_samplenums_tdo = []
self.first_bit = True
self.ss_bitstring = self.samplenum
self.ss_item = self.samplenum
def decode(self):
while True:
# Wait for a rising edge on TCK.
self.handle_rising_tck_edge(self.wait({2: 'r'}))