## ## This file is part of the libsigrokdecode project. ## ## Copyright (C) 2019 Uli Huber ## Copyright (C) 2020 Soeren Apel ## ## 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 . ## import sigrokdecode as srd ann_bit, ann_stat_bit, ann_type, ann_command, ann_parameter, ann_parity, ann_pos, ann_status, ann_warning = range(9) frame_type_none, frame_type_command, frame_type_16bit_pos, frame_type_18bit_pos = range(4) class Decoder(srd.Decoder): api_version = 3 id = 'xy2-100' name = 'XY2-100' longname = 'XY2-100(E) and XY-200(E) galvanometer protocol' desc = 'Serial protocol for galvanometer positioning in laser systems' license = 'gplv2+' inputs = ['logic'] outputs = [] tags = ['Embedded/industrial'] channels = ( {'id': 'clk', 'name': 'CLK', 'desc': 'Clock'}, {'id': 'sync', 'name': 'SYNC', 'desc': 'Sync'}, {'id': 'data', 'name': 'DATA', 'desc': 'X, Y or Z axis data'}, ) optional_channels = ( {'id': 'status', 'name': 'STAT', 'desc': 'X, Y or Z axis status'}, ) annotations = ( ('bit', 'Data Bit'), ('stat_bit', 'Status Bit'), ('type', 'Frame Type'), ('command', 'Command'), ('parameter', 'Parameter'), ('parity', 'Parity'), ('position', 'Position'), ('status', 'Status'), ('warning', 'Human-readable warnings'), ) annotation_rows = ( ('bits', 'Data Bits', (ann_bit,)), ('stat_bits', 'Status Bits', (ann_stat_bit,)), ('data', 'Data', (ann_type, ann_command, ann_parameter, ann_parity)), ('positions', 'Positions', (ann_pos,)), ('statuses', 'Statuses', (ann_status,)), ('warnings', 'Warnings', (ann_warning,)), ) def __init__(self): self.samplerate = None self.reset() def reset(self): self.bits = [] self.stat_bits = [] self.stat_skip_bit = True def metadata(self, key, value): if key == srd.SRD_CONF_SAMPLERATE: self.samplerate = value def start(self): self.out_ann = self.register(srd.OUTPUT_ANN) def put_ann(self, ss, es, ann_class, value): self.put(ss, es, self.out_ann, [ann_class, value]) def process_bit(self, sync, bit_ss, bit_es, bit_value): self.put_ann(bit_ss, bit_es, ann_bit, ['%d' % bit_value]) self.bits.append((bit_ss, bit_es, bit_value)) if sync == 0: if len(self.bits) < 20: self.put_ann(self.bits[0][0], bit_es, ann_warning, ['Not enough data bits']) self.reset() return # Bit structure: # 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 # T --------------- 18-bit pos ----------------- PARITY or # -TYPE-- ------------ 16-bit pos -------------- PARITY or # -TYPE-- -8-bit command -8-bit parameter value- PARITY # Calculate parity, excluding the parity bit itself parity = 0 for ss, es, value in self.bits[:-1]: parity ^= value par_ss, par_es, par_value = self.bits[19] parity_even = 0 parity_odd = 0 if (par_value == parity): parity_even = 1 else: parity_odd = 1 type_1_value = self.bits[0][2] type_3_value = (self.bits[0][2] << 2) | (self.bits[1][2] << 1) | self.bits[2][2] # Determine frame type type = frame_type_none parity_status = ['X', 'Unknown'] type_ss = self.bits[0][0] type_es = self.bits[2][1] ### 18-bit position if (type_1_value == 1) and (parity_odd == 1): type = frame_type_18bit_pos type_es = self.bits[0][1] self.put_ann(self.bits[0][0], bit_es, ann_warning, ['Careful: 18-bit position frames with wrong parity and command frames with wrong parity cannot be identified']) ### 16-bit position elif (type_3_value == 1): type = frame_type_16bit_pos if (parity_even == 1): parity_status = ['OK'] else: parity_status = ['NOK'] self.put_ann(self.bits[0][0], bit_es, ann_warning, ['Parity error', 'PE']) ### Command elif (type_3_value == 7) and (parity_even == 1): type = frame_type_command self.put_ann(self.bits[0][0], bit_es, ann_warning, ['Careful: 18-bit position frames with wrong parity and command frames with wrong parity cannot be identified']) ### Other else: self.put_ann(self.bits[0][0], bit_es, ann_warning, ['Error', 'Unknown command or parity error']) self.reset() return # Output command and parity annotations if (type == frame_type_16bit_pos): self.put_ann(type_ss, type_es, ann_type, ['16 bit Position Frame', '16 bit Pos', 'Pos', 'P']) if (type == frame_type_18bit_pos): self.put_ann(type_ss, type_es, ann_type, ['18 bit Position Frame', '18 bit Pos', 'Pos', 'P']) if (type == frame_type_command): self.put_ann(type_ss, type_es, ann_type, ['Command Frame', 'Command', 'C']) self.put_ann(par_ss, par_es, ann_parity, parity_status) # Output value if (type == frame_type_16bit_pos) or (type == frame_type_18bit_pos): pos = 0 if (type == frame_type_16bit_pos): count = 15 for ss, es, value in self.bits[3:19]: pos |= value << count count -= 1 pos = pos if pos < 32768 else pos - 65536 else: count = 17 for ss, es, value in self.bits[3:19]: pos |= value << count count -= 1 pos = pos if pos < 131072 else pos - 262144 self.put_ann(type_es, par_ss, ann_pos, ['%d' % pos]) if (type == frame_type_command): count = 7 cmd = 0 cmd_es = 0 for ss, es, value in self.bits[3:11]: cmd |= value << count count -= 1 cmd_es = es self.put_ann(type_es, cmd_es, ann_command, ['Command 0x%X' % cmd, 'Cmd 0x%X' % cmd, '0x%X' % cmd]) count = 7 param = 0 for ss, es, value in self.bits[11:19]: param |= value << count count -= 1 self.put_ann(cmd_es, par_ss, ann_parameter, ['Parameter 0x%X / %d' % (param, param), '0x%X / %d' % (param, param),'0x%X' % param]) self.reset() def process_stat_bit(self, sync, bit_ss, bit_es, bit_value): if self.stat_skip_bit: self.stat_skip_bit = False return self.put_ann(bit_ss, bit_es, ann_stat_bit, ['%d' % bit_value]) self.stat_bits.append((bit_ss, bit_es, bit_value)) if (sync == 0) and (len(self.stat_bits) == 19): stat_ss = self.stat_bits[0][0] stat_es = self.stat_bits[18][1] status = 0 count = 18 for ss, es, value in self.stat_bits: status |= value << count count -= 1 self.put_ann(stat_ss, stat_es, ann_status, ['Status 0x%X' % status, '0x%X' % status]) def decode(self): bit_ss = None bit_es = None bit_value = 0 stat_ss = None stat_es = None stat_value = 0 sync_value = 0 has_stat = self.has_channel(3) while True: # Wait for any edge on clk clk, sync, data, stat = self.wait({0: 'e'}) if clk == 1: stat_value = stat bit_es = self.samplenum if bit_ss: self.process_bit(sync_value, bit_ss, bit_es, bit_value) bit_ss = self.samplenum else: bit_value = data sync_value = sync stat_es = self.samplenum if stat_ss and has_stat: self.process_stat_bit(sync_value, stat_ss, stat_es, stat_value) stat_ss = self.samplenum