## ## This file is part of the libsigrokdecode project. ## ## Copyright (C) 2012-2013 Uwe Hermann ## ## 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, write to the Free Software ## Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA ## import sigrokdecode as srd ''' OUTPUT_PYTHON format: Packet: [, ] : - 'NEW STATE': 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 sequence of '1' and '0' characters. The right-most character in the bitstring is the LSB. Example: '01110001' (1 is LSB). ''' jtag_states = [ # Intro "tree" 'TEST-LOGIC-RESET', 'RUN-TEST/IDLE', # DR "tree" 'SELECT-DR-SCAN', 'CAPTURE-DR', 'UPDATE-DR', 'PAUSE-DR', 'SHIFT-DR', 'EXIT1-DR', 'EXIT2-DR', # IR "tree" 'SELECT-IR-SCAN', 'CAPTURE-IR', 'UPDATE-IR', 'PAUSE-IR', 'SHIFT-IR', 'EXIT1-IR', 'EXIT2-IR', ] class Decoder(srd.Decoder): api_version = 2 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'] 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]) def __init__(self, **kwargs): # self.state = 'TEST-LOGIC-RESET' self.state = 'RUN-TEST/IDLE' self.oldstate = None self.oldpins = (-1, -1, -1, -1) self.oldtck = -1 self.bits_tdi = [] self.bits_tdo = [] self.samplenum = 0 self.ss_item = self.es_item = None self.saved_item = None self.first = 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 advance_state_machine(self, tms): self.oldstate = self.state # Intro "tree" if self.state == 'TEST-LOGIC-RESET': self.state = 'TEST-LOGIC-RESET' if (tms) else 'RUN-TEST/IDLE' elif self.state == 'RUN-TEST/IDLE': self.state = 'SELECT-DR-SCAN' if (tms) else 'RUN-TEST/IDLE' # DR "tree" elif self.state == 'SELECT-DR-SCAN': self.state = 'SELECT-IR-SCAN' if (tms) else 'CAPTURE-DR' elif self.state == 'CAPTURE-DR': self.state = 'EXIT1-DR' if (tms) else 'SHIFT-DR' elif self.state == 'SHIFT-DR': self.state = 'EXIT1-DR' if (tms) else 'SHIFT-DR' elif self.state == 'EXIT1-DR': self.state = 'UPDATE-DR' if (tms) else 'PAUSE-DR' elif self.state == 'PAUSE-DR': self.state = 'EXIT2-DR' if (tms) else 'PAUSE-DR' elif self.state == 'EXIT2-DR': self.state = 'UPDATE-DR' if (tms) else 'SHIFT-DR' elif self.state == 'UPDATE-DR': self.state = 'SELECT-DR-SCAN' if (tms) else 'RUN-TEST/IDLE' # IR "tree" elif self.state == 'SELECT-IR-SCAN': self.state = 'TEST-LOGIC-RESET' if (tms) else 'CAPTURE-IR' elif self.state == 'CAPTURE-IR': self.state = 'EXIT1-IR' if (tms) else 'SHIFT-IR' elif self.state == 'SHIFT-IR': self.state = 'EXIT1-IR' if (tms) else 'SHIFT-IR' elif self.state == 'EXIT1-IR': self.state = 'UPDATE-IR' if (tms) else 'PAUSE-IR' elif self.state == 'PAUSE-IR': self.state = 'EXIT2-IR' if (tms) else 'PAUSE-IR' elif self.state == 'EXIT2-IR': self.state = 'UPDATE-IR' if (tms) else 'SHIFT-IR' elif self.state == 'UPDATE-IR': self.state = 'SELECT-DR-SCAN' if (tms) else 'RUN-TEST/IDLE' def handle_rising_tck_edge(self, tdi, tdo, tck, tms): # Rising TCK edges always advance the state machine. self.advance_state_machine(tms) if self.first == True: # Save the start sample and item for later (no output yet). self.ss_item = self.samplenum self.first = False self.saved_item = self.state else: # Output the saved item (from the last CLK edge to the current). self.es_item = self.samplenum # Output the state we just switched to. self.putx([jtag_states.index(self.state), [self.state]]) self.putp(['NEW STATE', self.state]) self.ss_item = self.samplenum self.saved_item = self.state # If we went from SHIFT-IR to SHIFT-IR, or SHIFT-DR to SHIFT-DR, # collect the current TDI/TDO values (upon rising TCK edge). if self.state.startswith('SHIFT-') and self.oldstate == self.state: self.bits_tdi.insert(0, tdi) self.bits_tdo.insert(0, tdo) # TODO: ANN/PROTO output. # self.putx([0, ['TDI add: ' + str(tdi)]]) # self.putp([0, ['TDO add: ' + str(tdo)]]) # Output all TDI/TDO bits if we just switched from SHIFT-* to EXIT1-*. if self.oldstate.startswith('SHIFT-') and \ self.state.startswith('EXIT1-'): t = self.state[-2:] + ' TDI' b = ''.join(map(str, self.bits_tdi)) h = ' (0x%x' % int('0b' + b, 2) + ')' s = t + ': ' + b + h + ', ' + str(len(self.bits_tdi)) + ' bits' # self.putx([0, [s]]) # self.putp([t, b]) self.bits_tdi = [] t = self.state[-2:] + ' TDO' b = ''.join(map(str, self.bits_tdo)) h = ' (0x%x' % int('0b' + b, 2) + ')' s = t + ': ' + b + h + ', ' + str(len(self.bits_tdo)) + ' bits' # self.putx([0, [s]]) # self.putp([t, b]) self.bits_tdo = [] def decode(self, ss, es, data): for (self.samplenum, pins) in data: # If none of the pins changed, there's nothing to do. if self.oldpins == pins: continue # Store current pin values for the next round. self.oldpins = pins # Get individual pin values into local variables. # Unused channels will have a value of > 1. (tdi, tdo, tck, tms, trst, srst, rtck) = pins # We only care about TCK edges (either rising or falling). if (self.oldtck == tck): continue # Store start/end sample for later usage. self.ss, self.es = ss, es # self.putx([0, ['tdi:%s, tdo:%s, tck:%s, tms:%s' \ # % (tdi, tdo, tck, tms)]]) if (self.oldtck == 0 and tck == 1): self.handle_rising_tck_edge(tdi, tdo, tck, tms) self.oldtck = tck