From: Bert Vermeulen Date: Sat, 31 Aug 2013 09:18:49 +0000 (+0200) Subject: xfp: Decoder for XFP I2C structures X-Git-Tag: libsigrokdecode-0.3.0~343 X-Git-Url: https://sigrok.org/gitaction?a=commitdiff_plain;h=845f0d4031780220451037e87885e1ff79670976;p=libsigrokdecode.git xfp: Decoder for XFP I2C structures --- diff --git a/configure.ac b/configure.ac index 3ed527f..46f854d 100644 --- a/configure.ac +++ b/configure.ac @@ -182,6 +182,7 @@ AC_CONFIG_FILES([Makefile decoders/uart_dump/Makefile decoders/usb_protocol/Makefile decoders/usb_signalling/Makefile + decoders/xfp/Makefile ]) AC_OUTPUT diff --git a/decoders/Makefile.am b/decoders/Makefile.am index b259d9c..7bc5d26 100644 --- a/decoders/Makefile.am +++ b/decoders/Makefile.am @@ -49,5 +49,6 @@ SUBDIRS = \ uart \ uart_dump \ usb_protocol \ - usb_signalling + usb_signalling \ + xfp diff --git a/decoders/xfp/Makefile.am b/decoders/xfp/Makefile.am new file mode 100644 index 0000000..68d982c --- /dev/null +++ b/decoders/xfp/Makefile.am @@ -0,0 +1,26 @@ +## +## This file is part of the libsigrokdecode project. +## +## Copyright (C) 2013 Bert Vermeulen +## +## 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 +## + +pkgdatadir = $(DECODERS_DIR)/xfp + +dist_pkgdata_DATA = __init__.py pd.py + +CLEANFILES = *.pyc + diff --git a/decoders/xfp/__init__.py b/decoders/xfp/__init__.py new file mode 100644 index 0000000..928fbc7 --- /dev/null +++ b/decoders/xfp/__init__.py @@ -0,0 +1,41 @@ +## +## This file is part of the libsigrokdecode project. +## +## Copyright (C) 2013 Bert Vermeulen +## +## 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 +## + +''' +XFP I2C management interface structure decoder. + +XFP modules include an I2C interface, used to monitor and control various +aspects of the module. The specification defines an I2C slave at address +0x50 (0xa0) which returns 128 bytes of a standard structure ("lower memory"), +and, after setting a table number in lower memory, a set of 256 "higher +memory" tables, which can be mapped to different subdevices on the XFP. + +Only one table is defined in the specification: table 0x01, the default on +module startup. Other table are either reserved for future expansion, or +available for vendor-specific extensions. This decoder supports both lower +memory and table 0x01. + +The XFP specification is available here: + + ftp://ftp.seagate.com/sff/INF-8077.PDF +''' + +from .pd import * + diff --git a/decoders/xfp/pd.py b/decoders/xfp/pd.py new file mode 100644 index 0000000..3d204ad --- /dev/null +++ b/decoders/xfp/pd.py @@ -0,0 +1,653 @@ +## +## This file is part of the libsigrokdecode project. +## +## Copyright (C) 2013 Bert Vermeulen +## +## 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 3 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 . +## + +# XFP protocol decoder + +import sigrokdecode as srd +import os + +MODULE_ID = { + 0x01: 'GBIC', + 0x02: 'Integrated module/connector', + 0x03: 'SFP', + 0x04: '300-pin XBI', + 0x05: 'XENPAK', + 0x06: 'XFP', + 0x07: 'XFF', + 0x08: 'XFP-E', + 0x09: 'XPAK', + 0x0a: 'X2', +} + +ALARM_THRESHOLDS = { + 0: "Temp high alarm", + 2: "Temp low alarm", + 4: "Temp high warning", + 6: "Temp low warning", + 16: "Bias high alarm", + 18: "Bias low alarm", + 20: "Bias high warning", + 22: "Bias low warning", + 24: "TX power high alarm", + 26: "TX power low alarm", + 28: "TX power high warning", + 30: "TX power low warning", + 32: "RX power high alarm", + 34: "RX power low alarm", + 36: "RX power high warning", + 38: "RX power low warning", + 40: "AUX 1 high alarm", + 42: "AUX 1 low alarm", + 44: "AUX 1 high warning", + 46: "AUX 1 low warning", + 48: "AUX 2 high alarm", + 50: "AUX 2 low alarm", + 52: "AUX 2 high warning", + 54: "AUX 2 low warning", +} + +AD_READOUTS = { + 0: "Module temperature", + 4: "TX bias current", + 6: "Measured TX output power", + 8: "Measured RX input power", + 10: "AUX 1 measurement", + 12: "AUX 2 measurement", +} + +GCS_BITS = [ + "TX disable", + "Soft TX disable", + "MOD_NR", + "P_Down", + "Soft P_Down", + "Interrupt", + "RX_LOS", + "Data_Not_Ready", + "TX_NR", + "TX_Fault", + "TX_CDR not locked", + "RX_NR", + "RX_CDR not locked", +] + +CONNECTOR = { + 0x01: "SC", + 0x02: "Fibre Channel style 1 copper", + 0x03: "Fibre Channel style 2 copper", + 0x04: "BNC/TNC", + 0x05: "Fibre Channel coax", + 0x06: "FiberJack", + 0x07: "LC", + 0x08: "MT-RJ", + 0x09: "MU", + 0x0a: "SG", + 0x0b: "Optical pigtail", + 0x20: "HSSDC II", + 0x21: "Copper pigtail", +} + +TRANSCEIVER = [ + # 10GB Ethernet + ["10GBASE-SR", "10GBASE-LR", "10GBASE-ER", "10GBASE-LRM", "10GBASE-SW", + "10GBASE-LW", "10GBASE-EW"], + # 10GB Fibre Channel + ["1200-MX-SN-I", "1200-SM-LL-L", "Extended Reach 1550 nm", + "Intermediate reach 1300 nm FP"], + # 10GB Copper + [], + # 10GB low speed + ["1000BASE-SX / 1xFC MMF", "1000BASE-LX / 1xFC SMF", "2xFC MMF", + "2xFC SMF", "OC48-SR", "OC48-IR", "OC48-LR"], + # 10GB SONET/SDH interconnect + ["I-64.1r", "I-64.1", "I-64.2r", "I-64.2", "I-64.3", "I-64.5"], + # 10GB SONET/SDH short haul + ["S-64.1", "S-64.2a", "S-64.2b", "S-64.3a", "S-64.3b", "S-64.5a", "S-64.5b"], + # 10GB SONET/SDH long haul + ["L-64.1", "L-64.2a", "L-64.2b", "L-64.2c", "L-64.3", "G.959.1 P1L1-2D2"], + # 10GB SONET/SDH very long haul + ["V-64.2a", "V-64.2b", "V-64.3"], +] + +SERIAL_ENCODING = [ + "64B/66B", + "8B/10B", + "SONET scrambled", + "NRZ", + "RZ", +] + +XMIT_TECH = [ + "850 nm VCSEL", + "1310 nm VCSEL", + "1550 nm VCSEL", + "1310 nm FP", + "1310 nm DFB", + "1550 nm DFB", + "1310 nm EML" + "1550 nm EML" + "copper", +] + +CDR = [ + "9.95Gb/s", + "10.3Gb/s", + "10.5Gb/s", + "10.7Gb/s", + "11.1Gb/s", + "(unknown)", + "lineside loopback mode", + "XFI loopback mode", +] + +DEVICE_TECH = [ + ["no wavelength control", "sctive wavelength control"], + ["uncooled transmitter device", "cooled transmitter"], + ["PIN detector", "APD detector"], + ["transmitter not tunable", "transmitter tunable"], +] + +ENHANCED_OPTS = [ + "VPS", + "soft TX_DISABLE", + "soft P_Down", + "VPS LV regulator mode", + "VPS bypassed regulator mode", + "active FEC control", + "wavelength tunability", + "CMU", +] + +AUX_TYPES = [ + "not implemented", + "APD bias voltage", + "(unknown)", + "TEC current", + "laser temperature", + "laser wavelength", + "5V supply voltage", + "3.3V supply voltage", + "1.8V supply voltage", + "-5.2V supply voltage", + "5V supply current", + "(unknown)", + "(unknown)", + "3.3V supply current", + "1.8V supply current", + "-5.2V supply current", +] + +class Decoder(srd.Decoder): + api_version = 1 + id = 'xfp' + name = 'XFP' + longname = '10 Gigabit Small Form Factor Pluggable Module (XFP)' + desc = 'Data structure describing display device capabilities.' + license = 'gplv3+' + inputs = ['i2c'] + outputs = ['xfp'] + probes = [] + optional_probes = [] + options = {} + annotations = [ + ['XFP field names and values', 'XFP structure field names and values'], + ['XFP fields', 'XFP structure fields'], + ] + + def __init__(self, **kwargs): + # Received data items, used as an index into samplenum/data + self.cnt = -1 + # Start/end sample numbers per data item + self.sn = [] + # Multi-byte structure buffer + self.buf = [] + # Filled in by address 0x7f in low memory + self.cur_highmem_page = 0 + # Filled in by extended ID value in table 2 + self.have_clei = False + # Handlers for each field in the structure, keyed by the end + # index of that field. Each handler is fed all unhandled bytes + # up until that point, so mark unused space with the dummy + # handler self.ignore(). + self.MAP_LOWER_MEMORY = { + 0: self.module_id, + 1: self.signal_cc, + 57: self.alarm_warnings, + 59: self.vps, + 69: self.ignore, + 71: self.ber, + 75: self.wavelength_cr, + 79: self.fec_cr, + 95: self.int_ctrl, + 109: self.ad_readout, + 111: self.gcs, + 117: self.ignore, + 118: self.ignore, + 122: self.ignore, + 126: self.ignore, + 127: self.page_select, + } + self.MAP_HIGH_TABLE_1 = { + 128: self.module_id, + 129: self.ext_module_id, + 130: self.connector, + 138: self.transceiver, + 139: self.serial_encoding, + 140: self.br_min, + 141: self.br_max, + 142: self.link_length_smf, + 143: self.link_length_e50, + 144: self.link_length_50um, + 145: self.link_length_625um, + 146: self.link_length_copper, + 147: self.device_tech, + 163: self.vendor, + 164: self.cdr, + 167: self.vendor_oui, + 183: self.vendor_pn, + 185: self.vendor_rev, + 187: self.wavelength, + 189: self.wavelength_tolerance, + 190: self.max_case_temp, + 191: self.ignore, + 195: self.power_supply, + 211: self.vendor_sn, + 219: self.manuf_date, + 220: self.diag_mon, + 221: self.enhanced_opts, + 222: self.aux_mon, + 223: self.ignore, + 255: self.maybe_ascii, + } + + def start(self, metadata): + self.out_ann = self.add(srd.OUTPUT_ANN, 'xfp') + + def decode(self, ss, es, data): + cmd, data = data + + # We only care about actual data bytes that are read (for now). + if cmd != 'DATA READ': + return + + self.cnt += 1 + self.sn.append([ss, es]) + + self.buf.append(data) + if self.cnt < 0x80: + if self.cnt in self.MAP_LOWER_MEMORY: + self.MAP_LOWER_MEMORY[self.cnt](self.buf) + self.buf.clear() + elif self.cnt < 0x0100 and self.cur_highmem_page == 0x01: + # Serial ID memory map + if self.cnt in self.MAP_HIGH_TABLE_1: + self.MAP_HIGH_TABLE_1[self.cnt](self.buf) + self.buf.clear() + + # Annotation helper + def annotate(self, key, value, start_cnt=None, end_cnt=None): + if start_cnt is None: + start_cnt = self.cnt - len(self.buf) + 1 + if end_cnt is None: + end_cnt = self.cnt + self.put(self.sn[start_cnt][0], self.sn[end_cnt][1], + self.out_ann, [0, [key + ": " + value]]) + self.put(self.sn[start_cnt][0], self.sn[end_cnt][1], + self.out_ann, [1, [value]]) + + # Placeholder handler, needed to advance the buffer past unused or + # reserved space in the structures. + def ignore(self, data): + pass + + # Show as ASCII if possible + def maybe_ascii(self, data): + for i in range(len(data)): + if data[i] >= 0x20 and data[i] < 0x7f: + cnt = self.cnt - len(data) + 1 + self.annotate("Vendor ID", chr(data[i]), cnt, cnt) + + # Convert 16-bit two's complement values, with each increment + # representing 1/256C, to degrees Celcius. + def to_temp(self, value): + if value & 0x8000: + value = -((value ^ 0xffff) + 1) + temp = value / 256.0 + return "%.1f C" % temp + + # TX bias current in uA. Each increment represents 0.2uA + def to_current(self, value): + current = value / 500000.0 + return "%.1f mA" % current + + # Power in mW, with each increment representing 0.1uW + def to_power(self, value): + power = value / 10000.0 + return "%.2f mW" % power + + # Wavelength in increments of 0.05nm + def to_wavelength(self, value): + wl = value / 20 + return "%d nm" % wl + + # Wavelength in increments of 0.005nm + def to_wavelength_tolerance(self, value): + wl = value / 200.0 + return "%.1f nm" % wl + + def module_id(self, data): + self.annotate("Module identifier", MODULE_ID.get(data[0], "Unknown")) + + def signal_cc(self, data): + # No good data available. + if (data[0] != 0x00): + self.annotate("Signal Conditioner Control", "%.2x" % data[0]) + + def alarm_warnings(self, data): + cnt_idx = self.cnt - len(data) + idx = 0 + while idx < 56: + if idx == 8: + # Skip over reserved A/D flag thresholds + idx += 8 + value = (data[idx] << 8) | data[idx + 1] + if value != 0: + name = ALARM_THRESHOLDS.get(idx, "...") + if idx in (0, 2, 4, 6): + self.annotate(name, self.to_temp(value), + cnt_idx + idx, cnt_idx + idx + 1) + elif idx in (16, 18, 20, 22): + self.annotate(name, self.to_current(value), + cnt_idx + idx, cnt_idx + idx + 1) + elif idx in (24, 26, 28, 30, 32, 34, 36, 38): + self.annotate(name, self.to_power(value), + cnt_idx + idx, cnt_idx + idx + 1) + else: + self.annotate(name, "%d" % name, value, cnt_idx + idx, + cnt_idx + idx + 1) + idx += 2 + + def vps(self, data): + # No good data available. + if (data != [0, 0]): + self.annotate("VPS", "%.2x%.2x" % (data[0], data[1])) + + def ber(self, data): + # No good data available. + if (data != [0, 0]): + self.annotate("BER", str(data)) + + def wavelength_cr(self, data): + # No good data available. + if (data != [0, 0, 0, 0]): + self.annotate("WCR", str(data)) + + def fec_cr(self, data): + if (data != [0, 0, 0, 0]): + self.annotate("FEC", str(data)) + + def int_ctrl(self, data): + # No good data available. Also boring. + out = [] + for d in data: + out.append("%.2x" % d) + self.annotate("Interrupt bits", ' '.join(out)) + + def ad_readout(self, data): + cnt_idx = self.cnt - len(data) + 1 + idx = 0 + while idx < 14: + if idx == 2: + # Skip over reserved field + idx += 2 + value = (data[idx] << 8) | data[idx + 1] + name = AD_READOUTS.get(idx, "...") + if value != 0: + if idx == 0: + self.annotate(name, self.to_temp(value), + cnt_idx + idx, cnt_idx + idx + 1) + elif idx == 4: + self.annotate(name, self.to_current(value), + cnt_idx + idx, cnt_idx + idx + 1) + elif idx in (6, 8): + self.annotate(name, self.to_power(value), + cnt_idx + idx, cnt_idx + idx + 1) + else: + self.annotate(name, str(value), cnt_idx + idx, + cnt_idx + idx + 1) + idx += 2 + + def gcs(self, data): + allbits = (data[0] << 8) | data[1] + out = [] + for b in range(13): + if allbits & 0x8000: + out.append(GCS_BITS[b]) + allbits <<= 1 + self.annotate("General Control/Status", ', '.join(out)) + + def page_select(self, data): + self.cur_highmem_page = data[0] + + def ext_module_id(self, data): + out = ["Power level %d module" % ((data[0] >> 6) + 1)] + if data[0] & 0x20 == 0: + out.append("CDR") + if data[0] & 0x10 == 0: + out.append("TX ref clock input required") + if data[0] & 0x08 == 0: + self.have_clei = True + self.annotate("Extended id", ', '.join(out)) + + def connector(self, data): + if data[0] in CONNECTOR: + self.annotate("Connector", CONNECTOR[data[0]]) + + def transceiver(self, data): + out = [] + for t in range(8): + if data[t] == 0: + continue + value = data[t] + for b in range(8): + if value & 0x80: + if len(TRANSCEIVER[t]) < b + 1: + out.append("(unknown)") + else: + out.append(TRANSCEIVER[t][b]) + value <<= 1 + self.annotate("Transceiver compliance", ', '.join(out)) + + def serial_encoding(self, data): + out = [] + value = data[0] + for b in range(8): + if value & 0x80: + if len(SERIAL_ENCODING) < b + 1: + out.append("(unknown)") + else: + out.append(SERIAL_ENCODING[b]) + value <<= 1 + self.annotate("Serial encoding support", ', '.join(out)) + + def br_min(self, data): + # Increments represent 100Mb/s + rate = data[0] / 10.0 + self.annotate("Minimum bit rate", "%.3f GB/s" % rate) + + def br_max(self, data): + # Increments represent 100Mb/s + rate = data[0] / 10.0 + self.annotate("Maximum bit rate", "%.3f GB/s" % rate) + + def link_length_smf(self, data): + if data[0] == 0: + length = "(standard)" + elif data[0] == 255: + length = "> 254 km" + else: + length = "%d km" % data[0] + self.annotate("Link length (SMF)", length) + + def link_length_e50(self, data): + if data[0] == 0: + length = "(standard)" + elif data[0] == 255: + length = "> 508 m" + else: + length = "%d m" % (data[0] * 2) + self.annotate("Link length (extended, 50μm MMF)", length) + + def link_length_50um(self, data): + if data[0] == 0: + length = "(standard)" + elif data[0] == 255: + length = "> 254 m" + else: + length = "%d m" % data[0] + self.annotate("Link length (50μm MMF)", length) + + def link_length_625um(self, data): + if data[0] == 0: + length = "(standard)" + elif data[0] == 255: + length = "> 254 m" + else: + length = "%d m" % (data[0]) + self.annotate("Link length (62.5μm MMF)", length) + + def link_length_copper(self, data): + if data[0] == 0: + length = "(unknown)" + elif data[0] == 255: + length = "> 254 m" + else: + length = "%d m" % (data[0] * 2) + self.annotate("Link length (copper)", length) + + def device_tech(self, data): + out = [] + xmit = data[0] >> 4 + if xmit <= len(XMIT_TECH) - 1: + out.append("%s transmitter" % XMIT_TECH[xmit]) + dev = data[0] & 0x0f + for b in range(4): + out.append(DEVICE_TECH[b][(dev >> (3 - b)) & 0x01]) + self.annotate("Device technology", ', '.join(out)) + + def vendor(self, data): + name = bytes(data).strip().decode('ascii').strip('\x00') + if name: + self.annotate("Vendor", name) + + def cdr(self, data): + out = [] + value = data[0] + for b in range(8): + if value & 0x80: + out.append(CDR[b]) + value <<= 1 + self.annotate("CDR support", ', '.join(out)) + + def vendor_oui(self, data): + if data != [0, 0, 0]: + self.annotate("Vendor OUI", "%.2X-%.2X-%.2X" % tuple(data)) + + def vendor_pn(self, data): + name = bytes(data).strip().decode('ascii').strip('\x00') + if name: + self.annotate("Vendor part number", name) + + def vendor_rev(self, data): + name = bytes(data).strip().decode('ascii').strip('\x00') + if name: + self.annotate("Vendor revision", name) + + def wavelength(self, data): + value = (data[0] << 8) | data[1] + self.annotate("Wavelength", self.to_wavelength(value)) + + def wavelength_tolerance(self, data): + value = (data[0] << 8) | data[1] + self.annotate("Wavelength tolerance", self.to_wavelength_tolerance(value)) + + def max_case_temp(self, data): + self.annotate("Maximum case temperature", "%d C" % data[0]) + + def power_supply(self, data): + out = [] + self.annotate("Max power dissipation", + "%.3f W" % (data[0] * 0.02), self.cnt - 3, self.cnt - 3) + self.annotate("Max power dissipation (powered down)", + "%.3f W" % (data[1] * 0.01), self.cnt - 2, self.cnt - 2) + value = (data[2] >> 4) * 0.050 + self.annotate("Max current required (5V supply)", + "%.3f A" % value, self.cnt - 1, self.cnt - 1) + value = (data[2] & 0x0f) * 0.100 + self.annotate("Max current required (3.3V supply)", + "%.3f A" % value, self.cnt - 1, self.cnt - 1) + value = (data[3] >> 4) * 0.100 + self.annotate("Max current required (1.8V supply)", + "%.3f A" % value, self.cnt, self.cnt) + value = (data[3] & 0x0f) * 0.050 + self.annotate("Max current required (-5.2V supply)", + "%.3f A" % value, self.cnt, self.cnt) + + def vendor_sn(self, data): + name = bytes(data).strip().decode('ascii').strip('\x00') + if name: + self.annotate("Vendor serial number", name) + + def manuf_date(self, data): + y = int(bytes(data[0:2])) + 2000 + m = int(bytes(data[2:4])) + d = int(bytes(data[4:6])) + mnf = "%.4d-%.2d-%.2d" % (y, m, d) + lot = bytes(data[6:]).strip().decode('ascii').strip('\x00') + if lot: + mnf += " lot " + lot + self.annotate("Manufacturing date", mnf) + + def diag_mon(self, data): + out = [] + if data[0] & 0x10: + out.append("BER support") + else: + out.append("no BER support") + if data[0] & 0x08: + out.append("average power measurement") + else: + out.append("OMA power measurement") + self.annotate("Diagnostic monitoring", ', '.join(out)) + + def enhanced_opts(self, data): + out = [] + value = data[0] + for b in range(8): + if value & 0x80: + out.append(ENHANCED_OPTS[b]) + value <<= 1 + self.annotate("Enhanced option support", ', '.join(out)) + + def aux_mon(self, data): + aux = AUX_TYPES[data[0] >> 4] + self.annotate("AUX1 monitoring", aux) + aux = AUX_TYPES[data[0] & 0x0f] + self.annotate("AUX2 monitoring", aux) +