/* vwr.c * Copyright (c) 2011 by Tom Alexander * * Wiretap Library * Copyright (c) 1998 by Gilbert Ramirez * * SPDX-License-Identifier: GPL-2.0-or-later * */ #include "config.h" #include #include "wtap-int.h" #include "file_wrappers.h" #include "vwr.h" #include /* platform-specific definitions for portability */ /* unsigned long long constants */ # define NS_IN_US G_GUINT64_CONSTANT(1000) /* nanoseconds-to-microseconds */ # define NS_IN_SEC G_GUINT64_CONSTANT(1000000000) /* nanoseconds-to-seconds */ # define US_IN_SEC G_GUINT64_CONSTANT(1000000) /* microseconds-to-seconds */ # define LL_ZERO G_GUINT64_CONSTANT(0) /* zero in unsigned long long */ /* * Fetch a 64-bit value in "Corey-endian" form. */ #define pcoreytohll(p) ((guint64)*((const guint8 *)(p)+4)<<56| \ (guint64)*((const guint8 *)(p)+5)<<48| \ (guint64)*((const guint8 *)(p)+6)<<40| \ (guint64)*((const guint8 *)(p)+7)<<32| \ (guint64)*((const guint8 *)(p)+0)<<24| \ (guint64)*((const guint8 *)(p)+1)<<16| \ (guint64)*((const guint8 *)(p)+2)<<8| \ (guint64)*((const guint8 *)(p)+3)<<0) /* * Fetch a 48-bit value in "Corey-endian" form; it's stored as * a 64-bit Corey-endian value, with the upper 16 bits ignored. */ #define pcorey48tohll(p) ((guint64)*((const guint8 *)(p)+6)<<40| \ (guint64)*((const guint8 *)(p)+7)<<32| \ (guint64)*((const guint8 *)(p)+0)<<24| \ (guint64)*((const guint8 *)(p)+1)<<16| \ (guint64)*((const guint8 *)(p)+2)<<8| \ (guint64)*((const guint8 *)(p)+3)<<0) /* .vwr log file defines */ #define B_SIZE 32768 /* max var len message = 32 kB */ #define VT_FRAME 0 /* varlen msg is a frame */ #define VT_CPMSG 1 /* varlen msg is a CP<->PP msg */ #define VT_UNKNOWN -1 /* varlen msg is unknown */ #define MAX_TRACKED_CLIENTS 1024 /* track 1024 clients */ #define MAX_TRACKED_FLOWS 65536 /* and 64K flows */ /* * The file consists of a sequence of records. * A record begins with a 16-byte header, the first 8 bytes of which * begin with a byte containing a command plus transmit-receive flags. * * Following that are two big-endian 32-bit quantities; for some records * one or the other of them is the length of the rest of the record. * Other records contain only the header. */ #define VW_RECORD_HEADER_LENGTH 16 /* * Maximum number of bytes to read looking for a valid frame starting * with a command byte to determine if this is our file type. Arbitrary. */ #define VW_BYTES_TO_CHECK 0x3FFFFFFFU /* Command byte values */ #define COMMAND_RX 0x21 #define COMMAND_TX 0x31 #define COMMAND_RFN 0x30 #define COMMAND_RF 0x38 #define COMMAND_RFRX 0x39 /* * The data in packet records begins with a sequence of metadata headers. * * For packet records from FPGA versions < 48: * * The first header is the IxVeriWave common header, and that's * followed either by a WLAN metadata header or an Ethernet * metadata header. The port type field indicates whether it's * a WLAN packet or an Ethernet packet. Following that may, for * WLAN, be 1 octet of information from the FPGA and 16 bytes of * data including the PLCP header. After that comes the WLAN or * Ethernet frame, beginning with the MAC header. * * For packet records from FPGA versions >= 48: * * The first header contains only a 1-octet port type value, which * has a packet type value in the upper 4 bits and zero in the lower * 4 bits. NOTE: this is indistinguishable from an old FPGA header * if the packet type value is 0. * * If the packet type value isn't 3, the port type value is followed * by a 1-octet FPGA version number, which is followed by a timestamp * header. * * If the packet type value is 3 or 4, the next item is an RF metadata * header. For type 3, that immediately follows the port number octet, * otherwise it immediately follows the timestamp header. * * If the packet type isn't 3, the next item is a WLAN metadata header, * in a format different from the WLAN metadata header for FPGA versions * < 48. That is followed by a PLCP header, which is followed by a * header giving additional layer 2 through 4 metadata. * * Following those headers is the WLAN or Ethernet frame, beginning with * the MAC header. */ /* * IxVeriWave common header: * * 1 octet - port type * 1 octet - FPGA version, or 0 * 2 octets - length of the common header * 2 octets - MSDU length * 4 octets - flow ID * 2 octets - VC ID * 2 octets - flow sequence number * 4 octets - latency or 0 * 4 octets - lower 32 bits of signature time stamp * 8 octets - start time * 8 octets - end time * 4 octets - delta(?) time */ /* Size of the IxVeriWave common header */ #define STATS_COMMON_FIELDS_LEN (1+1+2+2+4+2+2+4+4+8+8+4) /* Port type */ #define WLAN_PORT 0 #define ETHERNET_PORT 1 /* For VeriWave WLAN and Ethernet metadata headers vw_flags field */ #define VW_FLAGS_TXF 0x01 /* frame was transmitted */ #define VW_FLAGS_FCSERR 0x02 /* FCS error detected */ /* * VeriWave WLAN metadata header: * * 2 octets - header length * 2 octets - rflags * 2 octets - channel flags * 2 octets - PHY rate * 1 octet - PLCP type * 1 octet - MCS index * 1 octet - number of spatial streams * 1 octet - RSSI * 1 octet - antenna b signal power, or 100 if missing * 1 octet - antenna c signal power, or 100 if missing * 1 octet - antenna d signal power, or 100 if missing * 1 octet - padding * 2 octets - VeriWave flags * 2 octets - HT len * 2 octets - info * 2 octets - errors */ /* Size of the VeriWave WLAN metadata header */ #define EXT_WLAN_FIELDS_LEN (2+2+2+2+1+1+1+1+1+1+1+1+2+2+2+4) /* Flags, for rflags field */ #define FLAGS_SHORTPRE 0x0002 /* sent/received with short preamble */ #define FLAGS_WEP 0x0004 /* sent/received with WEP encryption */ #define FLAGS_CHAN_HT 0x0040 /* In HT mode */ #define FLAGS_CHAN_VHT 0x0080 /* VHT Mode */ #define FLAGS_CHAN_SHORTGI 0x0100 /* Short guard interval */ #define FLAGS_CHAN_40MHZ 0x0200 /* 40 Mhz channel bandwidth */ #define FLAGS_CHAN_80MHZ 0x0400 /* 80 Mhz channel bandwidth */ #define FLAGS_CHAN_160MHZ 0x0800 /* 160 Mhz channel bandwidth */ /* Channel flags, for channel flags field */ #define CHAN_CCK 0x0020 /* CCK channel */ #define CHAN_OFDM 0x0040 /* OFDM channel */ /* For VeriWave WLAN metadata header vw_flags field */ #define VW_FLAGS_RETRERR 0x04 /* excess retry error detected */ #define VW_FLAGS_DCRERR 0x10 /* decrypt error detected (WLAN) */ #define VW_FLAGS_ENCMSK 0x60 /* encryption type mask */ /* 0 = none, 1 = WEP, 2 = TKIP, 3 = CCKM */ #define VW_FLAGS_IS_WEP 0x20 /* WEP */ #define VW_FLAGS_IS_TKIP 0x40 /* TKIP */ #define VW_FLAGS_IS_CCMP 0x60 /* CCMP */ /* * VeriWave Ethernet metadata header: * * 2 octets - header length * 2 octets - VeriWave flags * 2 octets - info * 4 octets - errors * 4 octets - layer 4 ID * 4 octets - pad * * Ethernet frame follows, beginning with the MAC header */ /* Size of the VeriWave Ethernet metadata header */ #define EXT_ETHERNET_FIELDS_LEN (2+2+2+4+4+4) /* * OCTO timestamp header. * * 4 octets - latency or 0 * 4 octets - lower 32 bits of signature time stamp * 8 octets - start time * 8 octets - end time * 4 octets - delta(?) time */ /* Size of Timestamp header */ #define OCTO_TIMESTAMP_FIELDS_LEN (4+4+8+8+4+4) /* * OCTO layer 1-4 header: * * 2 octets - header length * 1 octet - l1p_1 * 1 octet - number of spatial streams * 2 octets - PHY rate * 1 octet - l1p_2 * 1 octet - RSSI * 1 octet - antenna b signal power, or 100 if missing * 1 octet - antenna c signal power, or 100 if missing * 1 octet - antenna d signal power, or 100 if missing * 1 octet - signal bandwidth mask * 1 octet - antenna port energy detect and VU_MASK * 1 octet - L1InfoC or 0 * 2 octets - MSDU length * 16 octets - PLCP? * 4 octets - BM, BV, CV, BSSID and ClientID * 2 octets - FV, QT, HT, L4V, TID and WLAN type * 1 octets - flow sequence number * 3 octets - flow ID * 2 octets - layer 4 ID * 4 octets - payload decode * 3 octets - info * 4 octets - errors */ /* Size of Layer-1, PLCP, and Layer-2/4 header in case of OCTO version FPGA */ #define OCTO_LAYER1TO4_LEN (2+14+16+23) /* * OCTO modified RF layer: * * 1 octet - RF ID * 3 octets - unused (zero) * 8 octets - noise for 4 ports * 8 octets - signal/noise ration for 4 ports * 8 octets - PFE for 4 ports * 8 octets - EVM SIG data for 4 ports * 8 octets - EVM SIG pilot for 4 ports * 8 octets - EVM Data data for 4 ports * 8 octets - EVM Data pilot for 4 ports * 8 octets - EVM worst symbol for 4 ports * 8 octets - CONTEXT_P for 4 ports * * Not supplied: * 24 octets of additional data */ /* Size of RF header, if all fields were supplied */ #define OCTO_RF_MOD_ACTUAL_LEN 100 /* */ /* Size of RF header with the fields we do supply */ #define OCTO_MODIFIED_RF_LEN 76 /* 24 bytes of RF are not displayed*/ /*Offset of different parameters of RF header for port-1*/ #define RF_PORT_1_NOISE_OFF 4 #define RF_PORT_1_SNR_OFF 6 #define RF_PORT_1_PFE_OFF 8 #define RF_PORT_1_CONTEXT_OFF 10 #define RF_PORT_1_EVM_SD_SIG_OFF 12 #define RF_PORT_1_EVM_SP_SIG_OFF 14 #define RF_PORT_1_EVM_SD_DATA_OFF 16 #define RF_PORT_1_EVM_SP_DATA_OFF 18 #define RF_PORT_1_DSYMBOL_IDX_OFF 22 #define RF_INTER_PORT_GAP_OFF 24 /*As size of RF information per port is 24 bytes*/ #define RF_NUMBER_OF_PORTS 4 /* FPGA-generated frame buffer STATS block offsets and definitions */ /* definitions for v2.2 frames, Ethernet format */ #define v22_E_STATS_LEN 44 /* length of stats block trailer */ #define v22_E_VALID_OFF 0 /* bit 6 (0x40) is flow-is-valid flag */ #define v22_E_MTYPE_OFF 1 /* offset of modulation type */ #define v22_E_VCID_OFF 2 /* offset of VC ID */ #define v22_E_FLOWSEQ_OFF 4 /* offset of signature sequence number */ #define v22_E_FLOWID_OFF 5 /* offset of flow ID */ #define v22_E_OCTET_OFF 8 /* offset of octets */ #define v22_E_ERRORS_OFF 10 /* offset of error vector */ #define v22_E_PATN_OFF 12 /* offset of pattern match vector */ #define v22_E_L4ID_OFF 12 #define v22_E_IPLEN_OFF 14 #define v22_E_FRAME_TYPE_OFF 16 /* offset of frame type, 32 bits */ #define v22_E_RSSI_OFF 21 /* RSSI (NOTE: invalid for Ethernet) */ #define v22_E_STARTT_OFF 20 /* offset of start time, 64 bits */ #define v22_E_ENDT_OFF 28 /* offset of end time, 64 bits */ #define v22_E_LATVAL_OFF 36 /* offset of latency, 32 bits */ #define v22_E_INFO_OFF 40 /* NO INFO FIELD IN ETHERNET STATS! */ #define v22_E_DIFFERENTIATOR_OFF 0 /* offset to determine whether */ /* eth/802.11, 8 bits */ /* Media types */ #define v22_E_MT_10_HALF 0 /* 10 Mb/s half-duplex */ #define v22_E_MT_10_FULL 1 /* 10 Mb/s full-duplex */ #define v22_E_MT_100_HALF 2 /* 100 Mb/s half-duplex */ #define v22_E_MT_100_FULL 3 /* 100 Mb/s full-duplex */ #define v22_E_MT_1G_HALF 4 /* 1 Gb/s half-duplex */ #define v22_E_MT_1G_FULL 5 /* 1 Gb/s full-duplex */ /* Error flags */ #define v22_E_FCS_ERROR 0x0002 /* FCS error flag in error vector */ #define v22_E_CRYPTO_ERR 0x1f00 /* RX decrypt error flags (UNUSED) */ #define v22_E_SIG_ERR 0x0004 /* signature magic byte mismatch */ #define v22_E_PAYCHK_ERR 0x0008 /* payload checksum failure */ #define v22_E_RETRY_ERR 0x0400 /* excessive retries on TX fail (UNUSED)*/ /* Masks and defines */ #define v22_E_IS_RX 0x08 /* TX/RX bit in STATS block */ #define v22_E_MT_MASK 0x07 /* modulation type mask (UNUSED) */ #define v22_E_VCID_MASK 0x03ff /* VC ID is only 10 bits */ #define v22_E_FLOW_VALID 0x40 /* flow-is-valid flag (else force to 0) */ #define v22_E_DIFFERENTIATOR_MASK 0x3F /* mask to differentiate ethernet from */ /* Bits in FRAME_TYPE field */ #define v22_E_IS_TCP 0x00000040 /* TCP bit in FRAME_TYPE field */ #define v22_E_IS_UDP 0x00000010 /* UDP bit in FRAME_TYPE field */ #define v22_E_IS_ICMP 0x00000020 /* ICMP bit in FRAME_TYPE field */ #define v22_E_IS_IGMP 0x00000080 /* IGMP bit in FRAME_TYPE field */ /* Bits in MTYPE field (WLAN only) */ #define v22_E_IS_QOS 0x80 /* QoS bit in MTYPE field (WLAN only) */ #define v22_E_IS_VLAN 0x00200000 #define v22_E_RX_DECRYPTS 0x0007 /* RX-frame-was-decrypted (UNUSED) */ #define v22_E_TX_DECRYPTS 0x0007 /* TX-frame-was-decrypted (UNUSED) */ #define v22_E_FC_PROT_BIT 0x40 /* Protected Frame bit in FC1 of frame */ #define v22_E_IS_ETHERNET 0x00700000 /* bits set in frame type if ethernet */ #define v22_E_IS_80211 0x7F000000 /* bits set in frame type if 802.11 */ /* definitions for v2.2 frames, WLAN format for VW510006 FPGA*/ #define v22_W_STATS_LEN 64 /* length of stats block trailer */ #define v22_W_VALID_OFF 0 /* bit 6 (0x40) is flow-is-valid flag */ #define v22_W_MTYPE_OFF 1 /* offset of modulation type */ #define v22_W_VCID_OFF 2 /* offset of VC ID */ #define v22_W_FLOWSEQ_OFF 4 /* offset of signature sequence number */ #define v22_W_FLOWID_OFF 5 /* offset of flow ID */ #define v22_W_OCTET_OFF 8 /* offset of octets */ #define v22_W_ERRORS_OFF 10 /* offset of error vector */ #define v22_W_PATN_OFF 12 #define v22_W_L4ID_OFF 12 #define v22_W_IPLEN_OFF 14 #define v22_W_FRAME_TYPE_OFF 16 /* offset of frame type, 32 bits */ #define v22_W_RSSI_OFF 21 /* RSSI (NOTE: RSSI must be negated!) */ #define v22_W_STARTT_OFF 24 /* offset of start time, 64 bits */ #define v22_W_ENDT_OFF 32 /* offset of end time, 64 bits */ #define v22_W_LATVAL_OFF 40 /* offset of latency, 32 bits */ #define v22_W_INFO_OFF 54 /* offset of INFO field, 16 LSBs */ #define v22_W_DIFFERENTIATOR_OFF 20 /* offset to determine whether */ /* eth/802.11, 32 bits */ #define v22_W_PLCP_LENGTH_OFF 4 /* LENGTH field in the plcp header */ /* Modulation types */ #define v22_W_MT_CCKL 0 /* CCK modulation, long preamble */ #define v22_W_MT_CCKS 1 /* CCK modulation, short preamble */ #define v22_W_MT_OFDM 2 /* OFDM modulation */ /* Bits in FRAME_TYPE field */ #define v22_W_IS_TCP 0x00000040 /* TCP bit in FRAME_TYPE field */ #define v22_W_IS_UDP 0x00000010 /* UDP bit in FRAME_TYPE field */ #define v22_W_IS_ICMP 0x00000020 /* ICMP bit in FRAME_TYPE field */ #define v22_W_IS_IGMP 0x00000080 /* IGMP bit in FRAME_TYPE field */ /* Bits in MTYPE field (WLAN only) */ #define v22_W_IS_QOS 0x80 /* QoS */ /* Error flags */ #define v22_W_FCS_ERROR 0x0002 /* FCS error flag in error vector */ #define v22_W_CRYPTO_ERR 0x1f00 /* RX decrypt error flags */ #define v22_W_SIG_ERR 0x0004 /* signature magic byte mismatch */ #define v22_W_PAYCHK_ERR 0x0008 /* payload checksum failure */ #define v22_W_RETRY_ERR 0x0400 /* excessive retries on TX failure */ /* Masks and defines */ #define v22_W_IS_RX 0x08 /* TX/RX bit in STATS block */ #define v22_W_MT_MASK 0x07 /* modulation type mask */ #define v22_W_VCID_MASK 0x01ff /* VC ID is only 9 bits */ #define v22_W_FLOW_VALID 0x40 /* flow-is-valid flag (else force to 0) */ #define v22_W_DIFFERENTIATOR_MASK 0xf0ff /* mask to differentiate ethernet from */ /* 802.11 capture */ #define v22_W_RX_DECRYPTS 0x0007 /* RX-frame-was-decrypted bits */ #define v22_W_TX_DECRYPTS 0x0007 /* TX-frame-was-decrypted bits */ /* Info bits */ #define v22_W_WEPTYPE 0x0001 /* WEP frame */ #define v22_W_TKIPTYPE 0x0002 /* TKIP frame */ #define v22_W_CCMPTYPE 0x0004 /* CCMP frame */ #define v22_W_MPDU_OF_A_MPDU 0x0400 /* MPDU of A-MPDU */ #define v22_W_FIRST_MPDU_OF_A_MPDU 0x0800 /* first MPDU of A-MPDU */ #define v22_W_LAST_MPDU_OF_A_MPDU 0x1000 /* last MPDU of A-MPDU */ #define v22_W_MSDU_OF_A_MSDU 0x2000 /* MSDU of A-MSDU */ #define v22_W_FIRST_MSDU_OF_A_MSDU 0x4000 /* first MSDU of A-MSDU */ #define v22_W_LAST_MSDU_OF_A_MSDU 0x8000 /* last MSDU of A-MSDU */ /* All aggregation flags */ #define v22_W_AGGREGATE_FLAGS \ (v22_W_MPDU_OF_A_MPDU | \ v22_W_FIRST_MPDU_OF_A_MPDU | \ v22_W_LAST_MPDU_OF_A_MPDU | \ v22_W_MSDU_OF_A_MSDU | \ v22_W_FIRST_MSDU_OF_A_MSDU | \ v22_W_LAST_MSDU_OF_A_MSDU) #define v22_W_FC_PROT_BIT 0x40 /* Protected Frame bit in FC1 of frame */ #define v22_W_IS_ETHERNET 0x00100000 /* bits set in frame type if ethernet */ #define v22_W_IS_80211 0x7F000000 /* bits set in frame type if 802.11 */ /* definitions for VW510021 FPGA, WLAN format */ /* FORMAT: 16 BYTE header 8 bytes of stat block plcp stuff (11 bytes plcp + 1 byte pad) data remaining 48 bytes of stat block */ /* offsets in the stats block */ #define vVW510021_W_STATS_HEADER_LEN 8 /* length of stats block header at beginning of record data */ #define vVW510021_W_STATS_TRAILER_LEN 48 /* length of stats block trailer after the plcp portion*/ #define vVW510021_W_STARTT_OFF 0 /* offset of start time, 64 bits */ #define vVW510021_W_ENDT_OFF 8 /* offset of end time, 64 bits */ #define vVW510021_W_ERRORS_OFF 16 /* offset of error vector */ #define vVW510021_W_VALID_OFF 20 /* 2 Bytes with different validity bits */ #define vVW510021_W_INFO_OFF 22 /* offset of INFO field, 16 LSBs */ #define vVW510021_W_FRAME_TYPE_OFF 24 #define vVW510021_W_L4ID_OFF 28 #define vVW510021_W_IPLEN_OFF 30 /* offset of IP Total Length field */ #define vVW510021_W_FLOWSEQ_OFF 32 /* offset of signature sequence number */ #define vVW510021_W_FLOWID_OFF 33 /* offset of flow ID */ #define vVW510021_W_LATVAL_OFF 36 /* offset of delay/flowtimestamp, 32b */ #define vVW510021_W_DEBUG_OFF 40 /* offset of debug, 16 bits */ #define S2_W_FPGA_VERSION_OFF 44 /* offset of fpga version, 16 bits */ #define vVW510021_W_MATCH_OFF 47 /* offset of pattern match vector */ /* offsets in the header block */ #define vVW510021_W_HEADER_LEN 16 /* length of FRAME header */ #define vVW510021_W_RXTX_OFF 0 /* rxtx offset, cmd byte of header */ #define vVW510021_W_HEADER_VERSION_OFF 9 /* version, 2bytes */ #define vVW510021_MSG_LENGTH_OFF 10 /* MSG LENGTH, 2bytes */ #define vVW510021_W_DEVICE_TYPE_OFF 8 /* version, 2bytes */ /* offsets that occur right after the header */ #define vVW510021_W_AFTERHEADER_LEN 8 /* length of STATs info directly after header */ #define vVW510021_W_L1P_1_OFF 0 /* offset of 1st byte of layer one info */ #define vVW510021_W_L1P_2_OFF 1 /* offset of 2nd byte of layer one info */ #define vVW510021_W_MTYPE_OFF vVW510021_W_L1P_2_OFF #define vVW510021_W_PREAMBLE_OFF vVW510021_W_L1P_1_OFF #define vVW510021_W_RSSI_TXPOWER_OFF 2 /* RSSI (NOTE: RSSI must be negated!) */ #define vVW510021_W_MSDU_LENGTH_OFF 3 /* 7:0 of length, next byte 11:8 in top 4 bits */ #define vVW510021_W_BVCV_VALID_OFF 4 /* BV,CV Determine validaity of bssid and txpower */ #define vVW510021_W_VCID_OFF 6 /* offset of VC (client) ID */ #define vVW510021_W_PLCP_LENGTH_OFF 12 /* LENGTH field in the plcp header */ /* Masks and defines */ #define vVW510021_W_IS_BV 0x04 /* BV bit in STATS block */ #define vVW510021_W_IS_CV 0x02 /* BV bit in STATS block */ #define vVW510021_W_FLOW_VALID 0x8000 /* valid_off flow-is-valid flag (else 0) */ #define vVW510021_W_QOS_VALID 0x4000 #define vVW510021_W_HT_VALID 0x2000 #define vVW510021_W_L4ID_VALID 0x1000 #define vVW510021_W_MCS_MASK 0x3f /* mcs index (a/b) type mask */ #define vVW510021_W_MOD_SCHEME_MASK 0x3f /* modulation type mask */ #define vVW510021_W_PLCPC_MASK 0x03 /* PLPCP type mask */ #define vVW510021_W_SEL_MASK 0x80 #define vVW510021_W_WEP_MASK 0x0001 #define vVW510021_W_CBW_MASK 0xC0 #define vVW510024_W_VCID_MASK 0x03ff /* VC ID is only 10 bits */ #define vVW510021_W_MT_SEL_LEGACY 0x00 #define vVW510021_W_IS_WEP 0x0001 /* L1p byte 1 info */ /* Common to Series II and Series III */ #define vVW510021_W_IS_LONGPREAMBLE 0x40 /* short/long preamble bit */ #define vVW510021_W_IS_LONGGI 0x40 /* short/long guard interval bit */ /* Series II */ /* * Pre-HT - contains rate index. */ #define vVW510021_W_S2_RATE_INDEX(l1p_1) ((l1p_1) & 0x3f) /* rate index for pre-HT */ /* * HT - contains MCS index. * * XXX - MCS indices for HT go up to 76, which doesn't fit in 6 bits; * either the mask is wrong, or the hardware can't receive packets * with an MCS of 64 through 76, or the hardware can but misreports * the MCS. */ #define vVW510021_W_S2_MCS_INDEX_HT(l1p_1) ((l1p_1) & 0x3f) /* * VHT - contains MCS index and number of spatial streams. * The number of spatial streams from the FPGA is zero-based, so we add * 1 to it. */ #define vVW510021_W_S2_MCS_INDEX_VHT(l1p_1) ((l1p_1) & 0x0f) /* MCS index for VHT */ #define vVW510021_W_S2_NSS_VHT(l1p_1) (((l1p_1) >> 4) + 1) /* NSS */ /* Series III */ /* * Pre-HT - contains rate index. */ #define vVW510021_W_S3_RATE_INDEX(l1p_1) ((l1p_1) & 0x3f) /* * HT - contains MCS index. * * XXX - MCS indices for HT go up to 76, which doesn't fit in 6 bits; * either the mask is wrong, or the hardware can't receive packets * with an MCS of 64 through 76, or the hardware can but misreports * the MCS. */ #define vVW510021_W_S3_MCS_INDEX_HT(l1p_1) ((l1p_1) & 0x3f) /* * VHT - contains MCS index and number of spatial streams. * The number of spatial streams from the FPGA is zero-based, so we add * 1 to it. */ #define vVW510021_W_S3_MCS_INDEX_VHT(l1p_1) ((l1p_1) & 0x0f) /* MCS index */ #define vVW510021_W_S3_NSS_VHT(l1p_1) ((((l1p_1) >> 4) & 0x03) + 1) /* NSS */ /* L1p byte 2 info */ /* Common to Series II and Series III */ #define vVW510021_W_BANDWIDTH_VHT(l1p_2) (((l1p_2) >> 4) & 0xf) /* 3 = 40 MHz, 4 = 80 MHz; what about 20 and 160 MHz? */ /* Series II */ #define vVW510021_W_S2_PLCP_TYPE(l1p_2) ((l1p_2) & 0x03) /* PLCP type */ /* Series III */ #define vVW510021_W_S3_PLCP_TYPE(l1p_2) ((l1p_2) & 0x0f) /* PLCP type */ /* PLCP types */ #define vVW510021_W_PLCP_LEGACY 0x00 /* pre-HT (11b/a/g) */ #define vVW510021_W_PLCP_MIXED 0x01 /* HT, mixed (11n) */ #define vVW510021_W_PLCP_GREENFIELD 0x02 /* HT, greenfield (11n) */ #define vVW510021_W_PLCP_VHT_MIXED 0x03 /* VHT (11ac) */ /* Bits in FRAME_TYPE field */ #define vVW510021_W_IS_TCP 0x01000000 /* TCP */ #define vVW510021_W_IS_UDP 0x00100000 /* UDP */ #define vVW510021_W_IS_ICMP 0x00001000 /* ICMP */ #define vVW510021_W_IS_IGMP 0x00010000 /* IGMP */ #define vVW510021_W_HEADER_VERSION 0x00 #define vVW510021_W_DEVICE_TYPE 0x15 #define vVW510021_W_11n_DEVICE_TYPE 0x20 #define S2_W_FPGA_VERSION 0x000C #define vVW510021_W_11n_FPGA_VERSION 0x000D /* Error flags */ #define vVW510021_W_FCS_ERROR 0x01 #define vVW510021_W_CRYPTO_ERROR 0x50000 #define vVW510021_W_WEPTYPE 0x0001 /* WEP frame */ #define vVW510021_W_TKIPTYPE 0x0002 /* TKIP frame */ #define vVW510021_W_CCMPTYPE 0x0004 /* CCMP frame */ /* definitions for VW510024 FPGA, wired ethernet format */ /* FORMAT: 16 BYTE header 52 bytes of stats block trailer */ /* offsets in the stats block */ #define vVW510024_E_STATS_LEN 48 /* length of stats block trailer */ #define vVW510024_E_MSDU_LENGTH_OFF 0 /* MSDU 16 BITS */ #define vVW510024_E_BMCV_VALID_OFF 2 /* BM,CV Determine validITY */ #define vVW510024_E_VCID_OFF 2 /* offset of VC (client) ID 13:8, */ /* 7:0 IN offset 7*/ #define vVW510024_E_STARTT_OFF 4 /* offset of start time, 64 bits */ #define vVW510024_E_ENDT_OFF 12 /* offset of end time, 64 bits */ #define vVW510024_E_ERRORS_OFF 22 /* offset of error vector */ #define vVW510024_E_VALID_OFF 24 /* 2 Bytes with different validity bits */ #define vVW510024_E_INFO_OFF 26 /* offset of INFO field, 16 LSBs */ #define vVW510024_E_FRAME_TYPE_OFF 28 #define vVW510024_E_L4ID_OFF 32 #define vVW510024_E_IPLEN_OFF 34 #define vVW510024_E_FLOWSEQ_OFF 36 /* offset of signature sequence number */ #define vVW510024_E_FLOWID_OFF 37 /* offset of flow ID */ #define vVW510024_E_LATVAL_OFF 40 /* offset of delay/flowtimestamp, 32 bits */ #define vVW510024_E_FPGA_VERSION_OFF 20 /* offset of fpga version, 16 bits */ #define vVW510024_E_MATCH_OFF 51 /* offset of pattern match vector */ /* offsets in the header block */ #define vVW510024_E_HEADER_LEN vVW510021_W_HEADER_LEN /* length of FRAME header */ #define vVW510024_E_RXTX_OFF vVW510021_W_RXTX_OFF /* rxtx offset, cmd byte */ #define vVW510024_E_HEADER_VERSION_OFF 16 /* version, 2bytes */ #define vVW510024_E_MSG_LENGTH_OFF vVW510021_MSG_LENGTH_OFF /* MSG LENGTH, 2bytes */ #define vVW510024_E_DEVICE_TYPE_OFF vVW510021_W_DEVICE_TYPE_OFF /* Device Type, 2bytes */ /* Masks and defines */ #define vVW510024_E_IS_BV 0x80 /* Bm bit in STATS block */ #define vVW510024_E_IS_CV 0x40 /* cV bit in STATS block */ #define vVW510024_E_FLOW_VALID 0x8000 /* valid_off flow-is-valid flag (else force to 0) */ #define vVW510024_E_QOS_VALID 0x0000 /** not valid for ethernet **/ #define vVW510024_E_L4ID_VALID 0x1000 #define vVW510024_E_CBW_MASK 0xC0 #define vVW510024_E_VCID_MASK 0x3FFF /* VCID is only 14 bits */ #define vVW510024_E_IS_TCP 0x01000000 /* TCP bit in FRAME_TYPE field */ #define vVW510024_E_IS_UDP 0x00100000 /* UDP bit in FRAME_TYPE field */ #define vVW510024_E_IS_ICMP 0x00001000 /* ICMP bit in FRAME_TYPE field */ #define vVW510024_E_IS_IGMP 0x00010000 #define vVW510024_E_IS_VLAN 0x00004000 #define vVW510024_E_HEADER_VERSION 0x00 #define vVW510024_E_DEVICE_TYPE 0x18 #define vVW510024_E_FPGA_VERSION 0x0001 #define FPGA_VER_NOT_APPLICABLE 0 #define UNKNOWN_FPGA 0 #define S2_W_FPGA 1 #define S1_W_FPGA 2 #define vVW510012_E_FPGA 3 #define vVW510024_E_FPGA 4 #define S3_W_FPGA 5 /* the flow signature is: Byte Description 0 Magic Number (0xDD) 1 Chassis Number[7:0] 2 Slot Number[7:0] 3 Port Number[7:0] 4 Flow ID[7:0] 5 Flow ID[15:8] 6 Flow ID[23:16] 7 Flow Sequence Number[7:0] 8 Timestamp[7:0] 9 Timestamp[15:8] 10 Timestamp[23:16] 11 Timestamp[31:24] 12 Timestamp[39:32] 13 Timestamp[47:40] 14 CRC16 15 CRC16 */ #define SIG_SIZE 16 /* size of signature field, bytes */ #define SIG_FID_OFF 4 /* offset of flow ID in signature */ #define SIG_FSQ_OFF 7 /* offset of flow seqnum in signature */ #define SIG_TS_OFF 8 /* offset of flow seqnum in signature */ /*--------------------------------------------------------------------------------------*/ /* Per-capture file private data structure */ typedef struct { /* offsets in stats block; these are dependent on the frame type (Ethernet/WLAN) and */ /* version number of .vwr file, and are set up by setup_defaults() */ guint32 STATS_LEN; /* length of stats block trailer */ guint32 STATS_START_OFF; /* STATS OFF AFTER HEADER */ guint32 VALID_OFF; /* bit 6 (0x40) is flow-is-valid flag */ guint32 MTYPE_OFF; /* offset of modulation type */ guint32 VCID_OFF; /* offset of VC ID */ guint32 FLOWSEQ_OFF; /* offset of signature sequence number */ guint32 FLOWID_OFF; /* offset of flow ID */ guint32 OCTET_OFF; /* offset of octets */ guint32 ERRORS_OFF; /* offset of error vector */ guint32 PATN_OFF; /* offset of pattern match vector */ guint32 RSSI_OFF; /* RSSI (NOTE: RSSI must be negated!) */ guint32 STARTT_OFF; /* offset of start time, 64 bits */ guint32 ENDT_OFF; /* offset of end time, 64 bits */ guint32 LATVAL_OFF; /* offset of latency, 32 bits */ guint32 INFO_OFF; /* offset of INFO field, 16 bits */ guint32 L1P_1_OFF; /* offset 1ST Byte of l1params */ guint32 L1P_2_OFF; /* offset 2nd Byte of l1params */ guint32 L4ID_OFF; /* LAYER 4 id offset*/ guint32 IPLEN_OFF; /* */ guint32 PLCP_LENGTH_OFF; /* offset of length field in the PLCP header */ guint32 FPGA_VERSION_OFF; /* offset of fpga version field, 16 bits */ guint32 HEADER_VERSION_OFF; /* offset of header version, 16 bits */ guint32 RXTX_OFF; /* offset of CMD bit, rx or tx */ guint32 FRAME_TYPE_OFF; /* other information about the file in question */ guint32 MT_10_HALF; /* 10 Mb/s half-duplex */ guint32 MT_10_FULL; /* 10 Mb/s full-duplex */ guint32 MT_100_HALF; /* 100 Mb/s half-duplex */ guint32 MT_100_FULL; /* 100 Mb/s full-duplex */ guint32 MT_1G_HALF; /* 1 Gb/s half-duplex */ guint32 MT_1G_FULL; /* 1 Gb/s full-duplex */ guint32 FCS_ERROR; /* FCS error in frame */ guint32 CRYPTO_ERR; /* RX decrypt error flags */ guint32 PAYCHK_ERR; /* payload checksum failure */ guint32 RETRY_ERR; /* excessive retries on TX failure */ guint8 IS_RX; /* TX/RX bit in STATS block */ guint8 MT_MASK; /* modulation type mask */ guint16 VCID_MASK; /* VC ID might not be a full 16 bits */ guint32 FLOW_VALID; /* flow-is-valid flag (else force to 0) */ guint16 QOS_VALID; guint32 RX_DECRYPTS; /* RX-frame-was-decrypted bits */ guint32 TX_DECRYPTS; /* TX-frame-was-decrypted bits */ guint32 FC_PROT_BIT; /* Protected Frame bit in FC1 of frame */ guint32 MT_CCKL; /* CCK modulation, long preamble */ guint32 MT_CCKS; /* CCK modulation, short preamble */ guint32 MT_OFDM; /* OFDM modulation */ guint32 MCS_INDEX_MASK; /* mcs index type mask */ guint32 FPGA_VERSION; guint32 WEPTYPE; /* frame is WEP */ guint32 TKIPTYPE; /* frame is TKIP */ guint32 CCMPTYPE; /* frame is CCMP */ guint32 IS_TCP; guint32 IS_UDP; guint32 IS_ICMP; guint32 IS_IGMP; guint16 IS_QOS; guint32 IS_VLAN; guint32 MPDU_OFF; guint32 OCTO_VERSION; } vwr_t; /* * NSS for various MCS values. */ #define MAX_HT_MCS 76 static guint nss_for_mcs[MAX_HT_MCS+1] = { 1, 1, 1, 1, 1, 1, 1, 1, /* 0-7 */ 2, 2, 2, 2, 2, 2, 2, 2, /* 8-15 */ 3, 3, 3, 3, 3, 3, 3, 3, /* 16-23 */ 4, 4, 4, 4, 4, 4, 4, 4, /* 24-31 */ 1, /* 32 */ 2, 2, 2, 2, 2, 2, /* 33-38 */ 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, /* 39-52 */ 4, 4, 4, 4, 4, 4, /* 53-58 */ 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4 /* 59-76 */ }; /* internal utility functions */ static int decode_msg(vwr_t *vwr, register guint8 *, int *, int *, int *); static guint8 get_ofdm_rate(const guint8 *); static guint8 get_cck_rate(const guint8 *plcp); static void setup_defaults(vwr_t *, guint16); static gboolean vwr_read(wtap *, wtap_rec *, Buffer *, int *, gchar **, gint64 *); static gboolean vwr_seek_read(wtap *, gint64, wtap_rec *, Buffer *, int *, gchar **); static gboolean vwr_read_rec_header(vwr_t *, FILE_T, int *, int *, int *, int *, gchar **); static gboolean vwr_process_rec_data(FILE_T fh, int rec_size, wtap_rec *record, Buffer *buf, vwr_t *vwr, int IS_TX, int log_mode, int *err, gchar **err_info); static int vwr_get_fpga_version(wtap *, int *, gchar **); static gboolean vwr_read_s1_W_rec(vwr_t *, wtap_rec *, Buffer *, const guint8 *, int, int *, gchar **); static gboolean vwr_read_s2_W_rec(vwr_t *, wtap_rec *, Buffer *, const guint8 *, int, int, int *, gchar **); /* For FPGA version >= 48 (OCTO Platform), following function will be used */ static gboolean vwr_read_s3_W_rec(vwr_t *, wtap_rec *, Buffer *, const guint8 *, int, int, int, int *, gchar **); static gboolean vwr_read_rec_data_ethernet(vwr_t *, wtap_rec *, Buffer *, const guint8 *, int, int, int *, gchar **); static int find_signature(const guint8 *, int, int, register guint32, register guint8); static guint64 get_signature_ts(const guint8 *, int, int); static float get_legacy_rate(guint8); static float get_ht_rate(guint8, guint16); static float get_vht_rate(guint8, guint16, guint8); static int vwr_80211_file_type_subtype = -1; static int vwr_eth_file_type_subtype = -1; void register_vwr(void); /* Open a .vwr file for reading */ /* This does very little, except setting the wiretap header for a VWR file type */ /* and setting the timestamp precision to microseconds. */ wtap_open_return_val vwr_open(wtap *wth, int *err, gchar **err_info) { int fpgaVer; vwr_t *vwr; *err = 0; fpgaVer = vwr_get_fpga_version(wth, err, err_info); if (fpgaVer == -1) { return WTAP_OPEN_ERROR; /* I/O error */ } if (fpgaVer == UNKNOWN_FPGA) { return WTAP_OPEN_NOT_MINE; /* not a VWR file */ } /* This is a vwr file */ vwr = g_new0(vwr_t, 1); wth->priv = (void *)vwr; vwr->FPGA_VERSION = fpgaVer; /* set the local module options first */ setup_defaults(vwr, fpgaVer); wth->snapshot_length = 0; wth->subtype_read = vwr_read; wth->subtype_seek_read = vwr_seek_read; wth->file_tsprec = WTAP_TSPREC_USEC; wth->file_encap = WTAP_ENCAP_IXVERIWAVE; if (fpgaVer == S2_W_FPGA || fpgaVer == S1_W_FPGA || fpgaVer == S3_W_FPGA) wth->file_type_subtype = vwr_80211_file_type_subtype; else if (fpgaVer == vVW510012_E_FPGA || fpgaVer == vVW510024_E_FPGA) wth->file_type_subtype = vwr_eth_file_type_subtype; /* * Add an IDB; we don't know how many interfaces were * involved, so we just say one interface, about which * we only know the link-layer type, snapshot length, * and time stamp resolution. */ wtap_add_generated_idb(wth); return WTAP_OPEN_MINE; } /* Read the next packet */ /* Note that the VWR file format consists of a sequence of fixed 16-byte record headers of */ /* different types; some types, including frame record headers, are followed by */ /* variable-length data. */ /* A frame record consists of: the above 16-byte record header, a 1-16384 byte raw PLCP */ /* frame, and a 64-byte statistics block trailer. */ /* The PLCP frame consists of a 4-byte or 6-byte PLCP header, followed by the MAC frame */ static gboolean vwr_read(wtap *wth, wtap_rec *rec, Buffer *buf, int *err, gchar **err_info, gint64 *data_offset) { vwr_t *vwr = (vwr_t *)wth->priv; int rec_size = 0, IS_TX = 0, log_mode = 0; /* read the next frame record header in the capture file; if no more frames, return */ if (!vwr_read_rec_header(vwr, wth->fh, &rec_size, &IS_TX, &log_mode, err, err_info)) return FALSE; /* Read error or EOF */ /* * We're past the header; return the offset of the header, not of * the data past the header. */ *data_offset = (file_tell(wth->fh) - VW_RECORD_HEADER_LENGTH); /* got a frame record; read and process it */ if (!vwr_process_rec_data(wth->fh, rec_size, rec, buf, vwr, IS_TX, log_mode, err, err_info)) return FALSE; return TRUE; } /* read a random record in the middle of a file; the start of the record is @ seek_off */ static gboolean vwr_seek_read(wtap *wth, gint64 seek_off, wtap_rec *record, Buffer *buf, int *err, gchar **err_info) { vwr_t *vwr = (vwr_t *)wth->priv; int rec_size, IS_TX = 0, log_mode = 0; /* first seek to the indicated record header */ if (file_seek(wth->random_fh, seek_off, SEEK_SET, err) == -1) return FALSE; /* read in the record header */ if (!vwr_read_rec_header(vwr, wth->random_fh, &rec_size, &IS_TX, &log_mode, err, err_info)) return FALSE; /* Read error or EOF */ return vwr_process_rec_data(wth->random_fh, rec_size, record, buf, vwr, IS_TX, log_mode, err, err_info); } /* Scan down in the input capture file to find the next frame header. */ /* Decode and skip over all non-frame messages that are in the way. */ /* Return TRUE on success, FALSE on EOF or error. */ /* Also return the frame size in bytes and the "is transmitted frame" flag. */ static gboolean vwr_read_rec_header(vwr_t *vwr, FILE_T fh, int *rec_size, int *IS_TX, int *log_mode, int *err, gchar **err_info) { int f_len, v_type; guint8 header[VW_RECORD_HEADER_LENGTH]; *rec_size = 0; /* Read out the file data in 16-byte messages, stopping either after we find a frame, */ /* or if we run out of data. */ /* Each 16-byte message is decoded; if we run across a non-frame message followed by a */ /* variable-length item, we read the variable length item out and discard it. */ /* If we find a frame, we return (with the header in the passed buffer). */ while (1) { if (!wtap_read_bytes_or_eof(fh, header, VW_RECORD_HEADER_LENGTH, err, err_info)) return FALSE; /* Got a header; invoke decode-message function to parse and process it. */ /* If the function returns a length, then a frame or variable-length message */ /* follows the 16-byte message. */ /* If the variable length message is not a frame, simply skip over it. */ if ((f_len = decode_msg(vwr, header, &v_type, IS_TX, log_mode)) != 0) { if (f_len > B_SIZE) { *err = WTAP_ERR_BAD_FILE; *err_info = ws_strdup_printf("vwr: Invalid message record length %d", f_len); return FALSE; } else if (v_type != VT_FRAME) { if (!wtap_read_bytes(fh, NULL, f_len, err, err_info)) return FALSE; } else { *rec_size = f_len; return TRUE; } } } } /* Figure out the FPGA version (and also see whether this is a VWR file type. */ /* Return FPGA version if it's a known version, UNKNOWN_FPGA if it's not, */ /* and -1 on an I/O error. */ static int vwr_get_fpga_version(wtap *wth, int *err, gchar **err_info) { guint8 *rec; /* local buffer (holds input record) */ guint8 header[VW_RECORD_HEADER_LENGTH]; int rec_size = 0; guint8 i; guint8 *s_510006_ptr = NULL; guint8 *s_510024_ptr = NULL; guint8 *s_510012_ptr = NULL; /* stats pointers */ gint64 filePos = -1; guint64 bytes_read = 0; guint32 frame_type = 0; int f_len, v_type; guint16 data_length = 0; guint16 fpga_version; gboolean valid_but_empty_file = FALSE; filePos = file_tell(wth->fh); if (filePos == -1) { *err = file_error(wth->fh, err_info); return -1; } fpga_version = 1000; rec = (guint8*)g_malloc(B_SIZE); /* Got a frame record; see if it is vwr */ /* If we don't get it all, then declare an error, we can't process the frame. */ /* Read out the file data in 16-byte messages, stopping either after we find a frame, */ /* or if we run out of data. */ /* Each 16-byte message is decoded; if we run across a non-frame message followed by a */ /* variable-length item, we read the variable length item out and discard it. */ /* If we find a frame, we return (with the header in the passed buffer). */ while (wtap_read_bytes(wth->fh, header, VW_RECORD_HEADER_LENGTH, err, err_info)) { /* Got a header; invoke decode-message function to parse and process it. */ /* If the function returns a length, then a frame or variable-length message */ /* follows the 16-byte message. */ /* If the variable length message is not a frame, simply skip over it. */ if ((f_len = decode_msg(NULL, header, &v_type, NULL, NULL)) != 0) { if (f_len > B_SIZE) { g_free(rec); /* Treat this here as an indication that the file probably */ /* isn't a vwr file. */ return UNKNOWN_FPGA; } else if (v_type != VT_FRAME) { if (!wtap_read_bytes(wth->fh, NULL, f_len, err, err_info)) { g_free(rec); if (*err == WTAP_ERR_SHORT_READ) return UNKNOWN_FPGA; /* short read - not a vwr file */ return -1; } else if (v_type == VT_CPMSG) valid_but_empty_file = TRUE; } else { rec_size = f_len; /* Got a frame record; read over entire record (frame + trailer) into a local buffer */ /* If we don't get it all, assume this isn't a vwr file */ if (!wtap_read_bytes(wth->fh, rec, rec_size, err, err_info)) { g_free(rec); if (*err == WTAP_ERR_SHORT_READ) return UNKNOWN_FPGA; /* short read - not a vwr file */ return -1; } /* I'll grab the bytes where the Ethernet "octets" field should be and the bytes where */ /* the 802.11 "octets" field should be. Then if I do rec_size - octets - */ /* size_of_stats_block and it's 0, I can select the correct type. */ /* octets + stats_len = rec_size only when octets have been incremented to nearest */ /* number divisible by 4. */ /* First check for series I WLAN since the check is more rigorous. */ if (rec_size > v22_W_STATS_LEN) { s_510006_ptr = &(rec[rec_size - v22_W_STATS_LEN]); /* point to 510006 WLAN */ /* stats block */ data_length = pntoh16(&s_510006_ptr[v22_W_OCTET_OFF]); i = 0; while (((data_length + i) % 4) != 0) i = i + 1; frame_type = pntoh32(&s_510006_ptr[v22_W_FRAME_TYPE_OFF]); if (rec_size == (data_length + v22_W_STATS_LEN + i) && (frame_type & v22_W_IS_80211) == 0x1000000) { fpga_version = S1_W_FPGA; } } /* Next for the series I Ethernet */ if ((rec_size > v22_E_STATS_LEN) && (fpga_version == 1000)) { s_510012_ptr = &(rec[rec_size - v22_E_STATS_LEN]); /* point to 510012 enet */ /* stats block */ data_length = pntoh16(&s_510012_ptr[v22_E_OCTET_OFF]); i = 0; while (((data_length + i) % 4) != 0) i = i + 1; if (rec_size == (data_length + v22_E_STATS_LEN + i)) fpga_version = vVW510012_E_FPGA; } /* Next the series II WLAN */ if ((rec_size > vVW510021_W_STATS_TRAILER_LEN) && (fpga_version == 1000)) { /* stats block */ if ((header[8] == 48) || (header[8] == 61) || (header[8] == 68)) fpga_version = S3_W_FPGA; else { data_length = (256 * (rec[vVW510021_W_MSDU_LENGTH_OFF + 1] & 0x1f)) + rec[vVW510021_W_MSDU_LENGTH_OFF]; i = 0; while (((data_length + i) % 4) != 0) i = i + 1; /*the 12 is from the 12 bytes of plcp header */ if (rec_size == (data_length + vVW510021_W_STATS_TRAILER_LEN +vVW510021_W_AFTERHEADER_LEN+12+i)) fpga_version = S2_W_FPGA; } } /* Finally the Series II Ethernet */ if ((rec_size > vVW510024_E_STATS_LEN) && (fpga_version == 1000)) { s_510024_ptr = &(rec[rec_size - vVW510024_E_STATS_LEN]); /* point to 510024 ENET */ data_length = pntoh16(&s_510024_ptr[vVW510024_E_MSDU_LENGTH_OFF]); i = 0; while (((data_length + i) % 4) != 0) i = i + 1; if (rec_size == (data_length + vVW510024_E_STATS_LEN + i)) fpga_version = vVW510024_E_FPGA; } if (fpga_version != 1000) { /* reset the file position offset */ if (file_seek (wth->fh, filePos, SEEK_SET, err) == -1) { g_free(rec); return (-1); } /* We found an FPGA that works */ g_free(rec); return fpga_version; } } } bytes_read += VW_RECORD_HEADER_LENGTH; if (bytes_read > VW_BYTES_TO_CHECK) { /* no frame found in VW_BYTES_TO_CHECK - not a vwr file */ g_free(rec); return UNKNOWN_FPGA; } } /* Is this a valid but empty file? If so, claim it's the S3_W_FPGA FPGA. */ if (valid_but_empty_file) { g_free(rec); return(S3_W_FPGA); } if (*err == WTAP_ERR_SHORT_READ) { g_free(rec); return UNKNOWN_FPGA; /* short read - not a vwr file */ } /* * Read error. */ g_free(rec); return -1; } /* Copy the actual packet data from the capture file into the target data block. */ /* The packet is constructed as a 38-byte VeriWave metadata header plus the raw */ /* MAC octets. */ static gboolean vwr_read_s1_W_rec(vwr_t *vwr, wtap_rec *record, Buffer *buf, const guint8 *rec, int rec_size, int *err, gchar **err_info) { guint8 *data_ptr; int bytes_written = 0; /* bytes output to buf so far */ const guint8 *s_ptr, *m_ptr; /* stats pointer */ guint16 msdu_length, actual_octets; /* octets in frame */ guint16 plcp_hdr_len; /* PLCP header length */ guint16 rflags; guint8 m_type; /* mod type (CCK-L/CCK-S/OFDM), seqnum */ guint flow_seq; guint64 s_time = LL_ZERO, e_time = LL_ZERO; /* start/end */ /* times, nsec */ guint32 latency; guint64 start_time, s_sec, s_usec = LL_ZERO; /* start time, sec + usec */ guint64 end_time; /* end time */ guint32 info; /* INFO/ERRORS fields in stats blk */ gint8 rssi; /* RSSI, signed 8-bit number */ int f_tx; /* flag: if set, is a TX frame */ guint8 rate_index; /* pre-HT only */ guint16 vc_id, ht_len=0; /* VC ID, total ip length */ guint flow_id; /* flow ID */ guint32 d_time, errors; /* packet duration & errors */ int sig_off, pay_off; /* MAC+SNAP header len, signature offset */ guint64 sig_ts; /* 32 LSBs of timestamp in signature */ guint16 phyRate; guint16 vw_flags; /* VeriWave-specific packet flags */ /* * The record data must be large enough to hold the statistics trailer. */ if (rec_size < v22_W_STATS_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, v22_W_STATS_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } /* Calculate the start of the statistics block in the buffer */ /* Also get a bunch of fields from the stats block */ s_ptr = &(rec[rec_size - v22_W_STATS_LEN]); /* point to it */ m_type = s_ptr[v22_W_MTYPE_OFF] & v22_E_MT_MASK; f_tx = !(s_ptr[v22_W_MTYPE_OFF] & v22_E_IS_RX); actual_octets = pntoh16(&s_ptr[v22_W_OCTET_OFF]); vc_id = pntoh16(&s_ptr[v22_W_VCID_OFF]) & v22_E_VCID_MASK; flow_seq = s_ptr[v22_W_FLOWSEQ_OFF]; latency = (guint32)pcorey48tohll(&s_ptr[v22_W_LATVAL_OFF]); flow_id = pntoh16(&s_ptr[v22_W_FLOWID_OFF+1]); /* only 16 LSBs kept */ errors = pntoh16(&s_ptr[v22_W_ERRORS_OFF]); info = pntoh16(&s_ptr[v22_W_INFO_OFF]); rssi = (s_ptr[v22_W_RSSI_OFF] & 0x80) ? (-1 * (s_ptr[v22_W_RSSI_OFF] & 0x7f)) : s_ptr[v22_W_RSSI_OFF]; /* * Sanity check the octets field to determine if it's greater than * the packet data available in the record - i.e., the record size * minus the length of the statistics block. * * Report an error if it is. */ if (actual_octets > rec_size - v22_W_STATS_LEN) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (runs past the end of the record)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } /* Decode OFDM or CCK PLCP header and determine rate and short preamble flag. */ /* The SIGNAL byte is always the first byte of the PLCP header in the frame. */ if (m_type == vwr->MT_OFDM) rate_index = get_ofdm_rate(rec); else if ((m_type == vwr->MT_CCKL) || (m_type == vwr->MT_CCKS)) rate_index = get_cck_rate(rec); else rate_index = 1; rflags = (m_type == vwr->MT_CCKS) ? FLAGS_SHORTPRE : 0; /* Calculate the MPDU size/ptr stuff; MPDU starts at 4 or 6 depending on OFDM/CCK. */ /* Note that the number of octets in the frame also varies depending on OFDM/CCK, */ /* because the PLCP header is prepended to the actual MPDU. */ plcp_hdr_len = (m_type == vwr->MT_OFDM) ? 4 : 6; if (actual_octets >= plcp_hdr_len) actual_octets -= plcp_hdr_len; else { *err_info = ws_strdup_printf("vwr: Invalid data length %u (too short to include %u-byte PLCP header)", actual_octets, plcp_hdr_len); *err = WTAP_ERR_BAD_FILE; return FALSE; } m_ptr = &rec[plcp_hdr_len]; msdu_length = actual_octets; /* * The MSDU length includes the FCS. * * The packet data does *not* include the FCS - it's just 4 bytes * of junk - so we have to remove it. * * We'll be stripping off that junk, so make sure we have at least * 4 octets worth of packet data. * * There seems to be a special case of a length of 0. */ if (actual_octets < 4) { if (actual_octets != 0) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (too short to include %u-byte PLCP header and 4 bytes of FCS)", actual_octets, plcp_hdr_len); *err = WTAP_ERR_BAD_FILE; return FALSE; } } else { actual_octets -= 4; } /* Calculate start & end times (in sec/usec), converting 64-bit times to usec. */ /* 64-bit times are "Corey-endian" */ s_time = pcoreytohll(&s_ptr[v22_W_STARTT_OFF]); e_time = pcoreytohll(&s_ptr[v22_W_ENDT_OFF]); /* find the packet duration (difference between start and end times) */ d_time = (guint32)((e_time - s_time) / NS_IN_US); /* find diff, converting to usec */ /* also convert the packet start time to seconds and microseconds */ start_time = s_time / NS_IN_US; /* convert to microseconds first */ s_sec = (start_time / US_IN_SEC); /* get the number of seconds */ s_usec = start_time - (s_sec * US_IN_SEC); /* get the number of microseconds */ /* also convert the packet end time to seconds and microseconds */ end_time = e_time / NS_IN_US; /* convert to microseconds first */ /* extract the 32 LSBs of the signature timestamp field from the data block*/ pay_off = 42; /* 24 (MAC) + 8 (SNAP) + IP */ sig_off = find_signature(m_ptr, rec_size - 6, pay_off, flow_id, flow_seq); if (m_ptr[sig_off] == 0xdd) sig_ts = get_signature_ts(m_ptr, sig_off, rec_size - v22_W_STATS_LEN); else sig_ts = 0; /* * Fill up the per-packet header. * * We include the length of the metadata headers in the packet lengths. * * The maximum value of actual_octets is 8191, which, even after * adding the lengths of the metadata headers, is less than * WTAP_MAX_PACKET_SIZE_STANDARD will ever be, so we don't need to check it. */ record->rec_header.packet_header.len = STATS_COMMON_FIELDS_LEN + EXT_WLAN_FIELDS_LEN + actual_octets; record->rec_header.packet_header.caplen = STATS_COMMON_FIELDS_LEN + EXT_WLAN_FIELDS_LEN + actual_octets; record->ts.secs = (time_t)s_sec; record->ts.nsecs = (int)(s_usec * 1000); record->rec_header.packet_header.pkt_encap = WTAP_ENCAP_IXVERIWAVE; record->rec_type = REC_TYPE_PACKET; record->block = wtap_block_create(WTAP_BLOCK_PACKET); record->presence_flags = WTAP_HAS_TS; ws_buffer_assure_space(buf, record->rec_header.packet_header.caplen); data_ptr = ws_buffer_start_ptr(buf); /* * Generate and copy out the common metadata headers, * set the port type to 0 (WLAN). * * All values are copied out in little-endian byte order. */ /* 1st octet of record for port_type and command (command is 0, hence RX) */ phtole8(&data_ptr[bytes_written], WLAN_PORT); bytes_written += 1; /* 2nd octet of record for fpga version (0, hence pre-OCTO) */ phtole8(&data_ptr[bytes_written], 0); bytes_written += 1; phtoles(&data_ptr[bytes_written], STATS_COMMON_FIELDS_LEN); /* it_len */ bytes_written += 2; phtoles(&data_ptr[bytes_written], msdu_length); bytes_written += 2; phtolel(&data_ptr[bytes_written], flow_id); bytes_written += 4; phtoles(&data_ptr[bytes_written], vc_id); bytes_written += 2; phtoles(&data_ptr[bytes_written], flow_seq); bytes_written += 2; if (!f_tx && sig_ts != 0) { phtolel(&data_ptr[bytes_written], latency); } else { phtolel(&data_ptr[bytes_written], 0); } bytes_written += 4; phtolel(&data_ptr[bytes_written], sig_ts); /* 32 LSBs of signature timestamp (nsec) */ bytes_written += 4; phtolell(&data_ptr[bytes_written], start_time); /* record start & end times of frame */ bytes_written += 8; phtolell(&data_ptr[bytes_written], end_time); bytes_written += 8; phtolel(&data_ptr[bytes_written], d_time); bytes_written += 4; /* * Generate and copy out the WLAN metadata headers. * * All values are copied out in little-endian byte order. */ phtoles(&data_ptr[bytes_written], EXT_WLAN_FIELDS_LEN); bytes_written += 2; phtoles(&data_ptr[bytes_written], rflags); bytes_written += 2; if (m_type == vwr->MT_OFDM) { phtoles(&data_ptr[bytes_written], CHAN_OFDM); } else { phtoles(&data_ptr[bytes_written], CHAN_CCK); } bytes_written += 2; phyRate = (guint16)(get_legacy_rate(rate_index) * 10); phtoles(&data_ptr[bytes_written], phyRate); bytes_written += 2; data_ptr[bytes_written] = vVW510021_W_PLCP_LEGACY; /* pre-HT */ bytes_written += 1; data_ptr[bytes_written] = rate_index; bytes_written += 1; data_ptr[bytes_written] = 1; /* pre-VHT, so NSS = 1 */ bytes_written += 1; data_ptr[bytes_written] = rssi; bytes_written += 1; /* antennae b, c, d signal power */ data_ptr[bytes_written] = 100; bytes_written += 1; data_ptr[bytes_written] = 100; bytes_written += 1; data_ptr[bytes_written] = 100; bytes_written += 1; /* padding */ data_ptr[bytes_written] = 0; bytes_written += 1; /* fill in the VeriWave flags field */ vw_flags = 0; if (f_tx) vw_flags |= VW_FLAGS_TXF; if (errors & vwr->FCS_ERROR) vw_flags |= VW_FLAGS_FCSERR; if (!f_tx && (errors & vwr->CRYPTO_ERR)) vw_flags |= VW_FLAGS_DCRERR; if (!f_tx && (errors & vwr->RETRY_ERR)) vw_flags |= VW_FLAGS_RETRERR; if (info & vwr->WEPTYPE) vw_flags |= VW_FLAGS_IS_WEP; else if (info & vwr->TKIPTYPE) vw_flags |= VW_FLAGS_IS_TKIP; else if (info & vwr->CCMPTYPE) vw_flags |= VW_FLAGS_IS_CCMP; phtoles(&data_ptr[bytes_written], vw_flags); bytes_written += 2; phtoles(&data_ptr[bytes_written], ht_len); bytes_written += 2; phtoles(&data_ptr[bytes_written], info); bytes_written += 2; phtolel(&data_ptr[bytes_written], errors); bytes_written += 4; /* * Finally, copy the whole MAC frame to the packet buffer as-is. * This does not include the PLCP; the MPDU starts at 4 or 6 * depending on OFDM/CCK. * This also does not include the last 4 bytes, as those don't * contain an FCS, they just contain junk. */ memcpy(&data_ptr[bytes_written], &rec[plcp_hdr_len], actual_octets); return TRUE; } static gboolean vwr_read_s2_W_rec(vwr_t *vwr, wtap_rec *record, Buffer *buf, const guint8 *rec, int rec_size, int IS_TX, int *err, gchar **err_info) { guint8 *data_ptr; int bytes_written = 0; /* bytes output to buf so far */ const guint8 *s_start_ptr,*s_trail_ptr, *plcp_ptr, *m_ptr; /* stats & MPDU ptr */ guint32 msdu_length, actual_octets; /* octets in frame */ guint8 l1p_1, l1p_2, plcp_type, rate_mcs_index, nss; /* mod (CCK-L/CCK-S/OFDM) */ guint flow_seq; guint64 s_time = LL_ZERO, e_time = LL_ZERO; /* start/end */ /* times, nsec */ guint64 latency = LL_ZERO; guint64 start_time, s_sec, s_usec = LL_ZERO; /* start time, sec + usec */ guint64 end_time; /* end time */ guint16 info; /* INFO/ERRORS fields in stats blk */ guint32 errors; gint8 rssi[] = {0,0,0,0}; /* RSSI, signed 8-bit number */ int f_tx; /* flag: if set, is a TX frame */ guint16 vc_id, ht_len=0; /* VC ID , total ip length*/ guint32 flow_id, d_time; /* flow ID, packet duration*/ int sig_off, pay_off; /* MAC+SNAP header len, signature offset */ guint64 sig_ts, tsid; /* 32 LSBs of timestamp in signature */ guint16 chanflags = 0; /* channel flags for WLAN metadata header */ guint16 radioflags = 0; /* flags for WLAN metadata header */ guint64 delta_b; /* Used for calculating latency */ float rate; guint16 phyRate; guint16 vw_flags; /* VeriWave-specific packet flags */ /* * The record data must be large enough to hold the statistics header, * the PLCP, and the statistics trailer. */ if ((guint)rec_size < vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } /* Calculate the start of the statistics blocks in the buffer */ /* Also get a bunch of fields from the stats blocks */ s_start_ptr = &(rec[0]); /* point to stats header */ s_trail_ptr = &(rec[rec_size - vVW510021_W_STATS_TRAILER_LEN]); /* point to stats trailer */ l1p_1 = s_start_ptr[vVW510021_W_L1P_1_OFF]; l1p_2 = s_start_ptr[vVW510021_W_L1P_2_OFF]; plcp_type = vVW510021_W_S2_PLCP_TYPE(l1p_2); /* we do the range checks at the end before copying the values into the wtap header */ msdu_length = ((s_start_ptr[vVW510021_W_MSDU_LENGTH_OFF+1] & 0x1f) << 8) + s_start_ptr[vVW510021_W_MSDU_LENGTH_OFF]; vc_id = pntoh16(&s_start_ptr[vVW510021_W_VCID_OFF]); if (IS_TX) { rssi[0] = (s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF] & 0x80) ? -1 * (s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF] & 0x7f) : s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF] & 0x7f; } else { rssi[0] = (s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF] & 0x80) ? (s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF]- 256) : s_start_ptr[vVW510021_W_RSSI_TXPOWER_OFF]; } rssi[1] = 100; rssi[2] = 100; rssi[3] = 100; plcp_ptr = &(rec[8]); actual_octets = msdu_length; /* * Sanity check the octets field to determine if it's greater than * the packet data available in the record - i.e., the record size * minus the sum of (length of statistics header + PLCP) and * (length of statistics trailer). * * Report an error if it is. */ if (actual_octets > rec_size - (vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN)) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (runs past the end of the record)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } f_tx = IS_TX; flow_seq = s_trail_ptr[vVW510021_W_FLOWSEQ_OFF]; latency = 0x00000000; /* clear latency */ flow_id = pntoh24(&s_trail_ptr[vVW510021_W_FLOWID_OFF]); /* all 24 bits valid */ /* For tx latency is duration, for rx latency is timestamp */ /* Get 48-bit latency value */ tsid = pcorey48tohll(&s_trail_ptr[vVW510021_W_LATVAL_OFF]); errors = pntoh32(&s_trail_ptr[vVW510021_W_ERRORS_OFF]); info = pntoh16(&s_trail_ptr[vVW510021_W_INFO_OFF]); if ((info & v22_W_AGGREGATE_FLAGS) != 0) /* this length includes the Start_Spacing + Delimiter + MPDU + Padding for each piece of the aggregate*/ ht_len = pletoh16(&s_start_ptr[vwr->PLCP_LENGTH_OFF]); /* decode OFDM or CCK PLCP header and determine rate and short preamble flag */ /* the SIGNAL byte is always the first byte of the PLCP header in the frame */ switch (plcp_type) { case vVW510021_W_PLCP_LEGACY: /* * From IEEE Std 802.11-2012: * * According to section 17.2.2 "PPDU format", the PLCP header * for the High Rate DSSS PHY (11b) has a SIGNAL field that's * 8 bits, followed by a SERVICE field that's 8 bits, followed * by a LENGTH field that's 16 bits, followed by a CRC field * that's 16 bits. The PSDU follows it. Section 17.2.3 "PPDU * field definitions" describes those fields. * * According to sections 18.3.2 "PLCP frame format" and 18.3.4 * "SIGNAL field", the PLCP for the OFDM PHY (11a) has a SIGNAL * field that's 24 bits, followed by a service field that's * 16 bits, followed by the PSDU. Section 18.3.5.2 "SERVICE * field" describes the SERVICE field. * * According to section 19.3.2 "PPDU format", the frames for the * Extended Rate PHY (11g) either extend the 11b format, using * additional bits in the SERVICE field, or extend the 11a * format. */ rate_mcs_index = vVW510021_W_S2_RATE_INDEX(l1p_1); if (rate_mcs_index < 4) { chanflags |= CHAN_CCK; } else { chanflags |= CHAN_OFDM; } rate = get_legacy_rate(rate_mcs_index); nss = 0; break; case vVW510021_W_PLCP_MIXED: /* * According to section 20.3.2 "PPDU format", the HT-mixed * PLCP header has a "Non-HT SIGNAL field" (L-SIG), which * looks like an 11a SIGNAL field, followed by an HT SIGNAL * field (HT-SIG) described in section 20.3.9.4.3 "HT-SIG * definition". * * This means that the first octet of HT-SIG is at * plcp_ptr[3], skipping the 3 octets of the L-SIG field. * * 0x80 is the CBW 20/40 bit of HT-SIG. */ /* set the appropriate flags to indicate HT mode and CB */ rate_mcs_index = vVW510021_W_S2_MCS_INDEX_HT(l1p_1); radioflags |= FLAGS_CHAN_HT | ((plcp_ptr[3] & 0x80) ? FLAGS_CHAN_40MHZ : 0) | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); chanflags |= CHAN_OFDM; nss = (rate_mcs_index < MAX_HT_MCS) ? nss_for_mcs[rate_mcs_index] : 0; rate = get_ht_rate(rate_mcs_index, radioflags); break; case vVW510021_W_PLCP_GREENFIELD: /* * According to section 20.3.2 "PPDU format", the HT-greenfield * PLCP header just has the HT SIGNAL field (HT-SIG) above, with * no L-SIG field. * * This means that the first octet of HT-SIG is at * plcp_ptr[0], as there's no L-SIG field to skip. * * 0x80 is the CBW 20/40 bit of HT-SIG. */ /* set the appropriate flags to indicate HT mode and CB */ rate_mcs_index = vVW510021_W_S2_MCS_INDEX_HT(l1p_1); radioflags |= FLAGS_CHAN_HT | ((plcp_ptr[0] & 0x80) ? FLAGS_CHAN_40MHZ : 0) | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); chanflags |= CHAN_OFDM; nss = (rate_mcs_index < MAX_HT_MCS) ? nss_for_mcs[rate_mcs_index] : 0; rate = get_ht_rate(rate_mcs_index, radioflags); break; case vVW510021_W_PLCP_VHT_MIXED: /* * According to section 22.3.2 "VHT PPDU format" of IEEE Std * 802.11ac-2013, the VHT PLCP header has a "non-HT SIGNAL field" * (L-SIG), which looks like an 11a SIGNAL field, followed by * a VHT Signal A field (VHT-SIG-A) described in section * 22.3.8.3.3 "VHT-SIG-A definition", with training fields * between it and a VHT Signal B field (VHT-SIG-B) described * in section 22.3.8.3.6 "VHT-SIG-B definition", followed by * the PSDU. */ { guint8 SBW = vVW510021_W_BANDWIDTH_VHT(l1p_2); rate_mcs_index = vVW510021_W_S2_MCS_INDEX_VHT(l1p_1); radioflags |= FLAGS_CHAN_VHT | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); chanflags |= CHAN_OFDM; if (SBW == 3) radioflags |= FLAGS_CHAN_40MHZ; else if (SBW == 4) radioflags |= FLAGS_CHAN_80MHZ; nss = vVW510021_W_S2_NSS_VHT(l1p_1); rate = get_vht_rate(rate_mcs_index, radioflags, nss); } break; default: rate_mcs_index = 0; nss = 0; rate = 0.0f; break; } /* * The MSDU length includes the FCS. * * The packet data does *not* include the FCS - it's just 4 bytes * of junk - so we have to remove it. * * We'll be stripping off that junk, so make sure we have at least * 4 octets worth of packet data. * * There seems to be a special case of a length of 0. */ if (actual_octets < 4) { if (actual_octets != 0) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (too short to include 4 bytes of FCS)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } } else { actual_octets -= 4; } /* Calculate start & end times (in sec/usec), converting 64-bit times to usec. */ /* 64-bit times are "Corey-endian" */ s_time = pcoreytohll(&s_trail_ptr[vVW510021_W_STARTT_OFF]); e_time = pcoreytohll(&s_trail_ptr[vVW510021_W_ENDT_OFF]); /* find the packet duration (difference between start and end times) */ d_time = (guint32)((e_time - s_time) / NS_IN_US); /* find diff, converting to usec */ /* also convert the packet start time to seconds and microseconds */ start_time = s_time / NS_IN_US; /* convert to microseconds first */ s_sec = (start_time / US_IN_SEC); /* get the number of seconds */ s_usec = start_time - (s_sec * US_IN_SEC); /* get the number of microseconds */ /* also convert the packet end time to seconds and microseconds */ end_time = e_time / NS_IN_US; /* convert to microseconds first */ /* extract the 32 LSBs of the signature timestamp field */ m_ptr = &(rec[8+12]); pay_off = 42; /* 24 (MAC) + 8 (SNAP) + IP */ sig_off = find_signature(m_ptr, rec_size - 20, pay_off, flow_id, flow_seq); if (m_ptr[sig_off] == 0xdd) sig_ts = get_signature_ts(m_ptr, sig_off, rec_size - vVW510021_W_STATS_TRAILER_LEN); else sig_ts = 0; /* Set latency based on rx/tx and signature timestamp */ if (!IS_TX) { if (tsid < s_time) { latency = s_time - tsid; } else { /* Account for the rollover case. Since we cannot use 0x100000000 - l_time + s_time */ /* we look for a large difference between l_time and s_time. */ delta_b = tsid - s_time; if (delta_b > 0x10000000) latency = 0; else latency = delta_b; } } /* * Fill up the per-packet header. * * We include the length of the metadata headers in the packet lengths. * * The maximum value of actual_octets is 8191, which, even after * adding the lengths of the metadata headers, is less than * WTAP_MAX_PACKET_SIZE_STANDARD will ever be, so we don't need to check it. */ record->rec_header.packet_header.len = STATS_COMMON_FIELDS_LEN + EXT_WLAN_FIELDS_LEN + actual_octets; record->rec_header.packet_header.caplen = STATS_COMMON_FIELDS_LEN + EXT_WLAN_FIELDS_LEN + actual_octets; record->ts.secs = (time_t)s_sec; record->ts.nsecs = (int)(s_usec * 1000); record->rec_type = REC_TYPE_PACKET; record->block = wtap_block_create(WTAP_BLOCK_PACKET); record->presence_flags = WTAP_HAS_TS; ws_buffer_assure_space(buf, record->rec_header.packet_header.caplen); data_ptr = ws_buffer_start_ptr(buf); /* * Generate and copy out the common metadata headers, * set the port type to 0 (WLAN). * * All values are copied out in little-endian byte order. */ /*** msdu_length = msdu_length + 16; ***/ /* 1st octet of record for port_type and command (command is 0, hence RX) */ phtole8(&data_ptr[bytes_written], WLAN_PORT); bytes_written += 1; /* 2nd octet of record for fpga version (0, hence pre-OCTO) */ phtole8(&data_ptr[bytes_written], 0); bytes_written += 1; phtoles(&data_ptr[bytes_written], STATS_COMMON_FIELDS_LEN); /* it_len */ bytes_written += 2; phtoles(&data_ptr[bytes_written], msdu_length); bytes_written += 2; phtolel(&data_ptr[bytes_written], flow_id); bytes_written += 4; phtoles(&data_ptr[bytes_written], vc_id); bytes_written += 2; phtoles(&data_ptr[bytes_written], flow_seq); bytes_written += 2; if (!f_tx && sig_ts != 0) { phtolel(&data_ptr[bytes_written], latency); } else { phtolel(&data_ptr[bytes_written], 0); } bytes_written += 4; phtolel(&data_ptr[bytes_written], sig_ts); /* 32 LSBs of signature timestamp (nsec) */ bytes_written += 4; phtolell(&data_ptr[bytes_written], start_time); /* record start & end times of frame */ bytes_written += 8; phtolell(&data_ptr[bytes_written], end_time); bytes_written += 8; phtolel(&data_ptr[bytes_written], d_time); bytes_written += 4; /* * Generate and copy out the WLAN metadata headers. * * All values are copied out in little-endian byte order. */ phtoles(&data_ptr[bytes_written], EXT_WLAN_FIELDS_LEN); bytes_written += 2; if (info & vVW510021_W_IS_WEP) radioflags |= FLAGS_WEP; if (!(l1p_1 & vVW510021_W_IS_LONGPREAMBLE) && (plcp_type == vVW510021_W_PLCP_LEGACY)) radioflags |= FLAGS_SHORTPRE; phtoles(&data_ptr[bytes_written], radioflags); bytes_written += 2; phtoles(&data_ptr[bytes_written], chanflags); bytes_written += 2; phyRate = (guint16)(rate * 10); phtoles(&data_ptr[bytes_written], phyRate); bytes_written += 2; data_ptr[bytes_written] = plcp_type; bytes_written += 1; data_ptr[bytes_written] = rate_mcs_index; bytes_written += 1; data_ptr[bytes_written] = nss; bytes_written += 1; data_ptr[bytes_written] = rssi[0]; bytes_written += 1; data_ptr[bytes_written] = rssi[1]; bytes_written += 1; data_ptr[bytes_written] = rssi[2]; bytes_written += 1; data_ptr[bytes_written] = rssi[3]; bytes_written += 1; /* padding */ data_ptr[bytes_written] = 0; bytes_written += 1; /* fill in the VeriWave flags field */ vw_flags = 0; if (f_tx) vw_flags |= VW_FLAGS_TXF; if (errors & 0x1f) /* If any error is flagged, then set the FCS error bit */ vw_flags |= VW_FLAGS_FCSERR; if (!f_tx && (errors & vwr->CRYPTO_ERR)) vw_flags |= VW_FLAGS_DCRERR; if (!f_tx && (errors & vwr->RETRY_ERR)) vw_flags |= VW_FLAGS_RETRERR; if (info & vwr->WEPTYPE) vw_flags |= VW_FLAGS_IS_WEP; else if (info & vwr->TKIPTYPE) vw_flags |= VW_FLAGS_IS_TKIP; else if (info & vwr->CCMPTYPE) vw_flags |= VW_FLAGS_IS_CCMP; phtoles(&data_ptr[bytes_written], vw_flags); bytes_written += 2; phtoles(&data_ptr[bytes_written], ht_len); bytes_written += 2; phtoles(&data_ptr[bytes_written], info); bytes_written += 2; phtolel(&data_ptr[bytes_written], errors); bytes_written += 4; /* Finally, copy the whole MAC frame to the packet buffer as-is. * This does not include the stats header or the PLCP. * This also does not include the last 4 bytes, as those don't * contain an FCS, they just contain junk. */ memcpy(&data_ptr[bytes_written], &rec[vwr->MPDU_OFF], actual_octets); return TRUE; } static gboolean vwr_read_s3_W_rec(vwr_t *vwr, wtap_rec *record, Buffer *buf, const guint8 *rec, int rec_size, int IS_TX, int log_mode, int *err, gchar **err_info) { guint8 *data_ptr; int bytes_written = 0; /* bytes output to buf so far */ int i; int stats_offset = 0; const guint8 *s_start_ptr = NULL,*s_trail_ptr = NULL, *plcp_ptr, *m_ptr; /* stats & MPDU ptr */ guint32 msdu_length = 0, actual_octets = 0; /* octets in frame */ guint8 l1p_1 = 0,l1p_2 = 0, plcp_type, rate_mcs_index, nss; /* mod (CCK-L/CCK-S/OFDM) */ guint64 s_time = LL_ZERO, e_time = LL_ZERO; /* start/end */ /* times, nsec */ guint64 latency = LL_ZERO; guint64 start_time = 0, s_sec = 0, s_usec = LL_ZERO; /* start time, sec + usec */ guint64 end_time = 0; /* end time */ guint16 info = 0; /* INFO/ERRORS fields in stats blk */ guint32 errors = 0; gint8 info_2nd = 0,rssi[] = {0,0,0,0}; /* RSSI, signed 8-bit number */ int frame_size; guint32 d_time = 0, flow_id = 0; /* packet duration, Flow Signature ID*/ int sig_off, pay_off; /* MAC+SNAP header len, signature offset */ guint64 sig_ts = 0, tsid; /* 32 LSBs of timestamp in signature */ guint64 delta_b; /* Used for calculating latency */ guint8 L1InfoC = 0, port_type, ver_fpga = 0; guint8 flow_seq =0,plcp_hdr_flag = 0,rf_id = 0; /* indicates plcp hdr info */ const guint8 *rf_ptr = NULL; float rate; guint16 phyRate; /* * The record data must be large enough to hold the statistics header, * the PLCP, and the statistics trailer. */ if (IS_TX == 3) { /*IS_TX =3, i.e., command type is RF Modified*/ if ((guint)rec_size < OCTO_MODIFIED_RF_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, OCTO_MODIFIED_RF_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } rf_ptr = &(rec[0]); rf_id = rf_ptr[0]; /* * Fill up the per-packet header. * * We include the length of the metadata headers in the packet lengths. * * OCTO_MODIFIED_RF_LEN + 1 is less than WTAP_MAX_PACKET_SIZE_STANDARD will * ever be, so we don't need to check it. */ record->rec_header.packet_header.len = OCTO_MODIFIED_RF_LEN + 1; /* 1st octet is reserved for detecting type of frame while displaying in wireshark */ record->rec_header.packet_header.caplen = OCTO_MODIFIED_RF_LEN + 1; record->ts.secs = (time_t)s_sec; record->ts.nsecs = (int)(s_usec * 1000); record->rec_type = REC_TYPE_PACKET; record->block = wtap_block_create(WTAP_BLOCK_PACKET); record->presence_flags = WTAP_HAS_TS; ws_buffer_assure_space(buf, record->rec_header.packet_header.caplen); data_ptr = ws_buffer_start_ptr(buf); port_type = IS_TX << 4; nss = 0; phyRate = 0; } else { /* Calculate the start of the statistics blocks in the buffer */ /* Also get a bunch of fields from the stats blocks */ /* 'stats_offset' variable is use to locate the exact offset. * When a RX frame contrains RF, * the position of Stats, Layer 1-4, PLCP parameters are shifted to * + OCTO_RF_MOD_ACTUAL_LEN bytes */ if (IS_TX == 4) /*IS_TX =4, i.e., command type is RF-RX Modified*/ { stats_offset = OCTO_RF_MOD_ACTUAL_LEN; if ((guint)rec_size < stats_offset + vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, stats_offset + vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } rf_ptr = &(rec[0]); rf_id = rf_ptr[0]; } else { stats_offset = 0; if ((guint)rec_size < vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } } s_start_ptr = &(rec[stats_offset]); /* point to stats header */ s_trail_ptr = &(rec[rec_size - vVW510021_W_STATS_TRAILER_LEN] ); /* point to stats trailer */ l1p_1 = s_start_ptr[vVW510021_W_L1P_1_OFF]; l1p_2 = s_start_ptr[vVW510021_W_L1P_2_OFF]; plcp_type = vVW510021_W_S3_PLCP_TYPE(l1p_2); switch (plcp_type) { case vVW510021_W_PLCP_LEGACY: /* pre-HT */ rate_mcs_index = vVW510021_W_S3_RATE_INDEX(l1p_1); nss = 0; break; case vVW510021_W_PLCP_MIXED: case vVW510021_W_PLCP_GREENFIELD: rate_mcs_index = vVW510021_W_S3_MCS_INDEX_HT(l1p_1); nss = (rate_mcs_index < MAX_HT_MCS) ? nss_for_mcs[rate_mcs_index] : 0; break; case vVW510021_W_PLCP_VHT_MIXED: rate_mcs_index = vVW510021_W_S3_MCS_INDEX_VHT(l1p_1); nss = vVW510021_W_S3_NSS_VHT(l1p_1); plcp_hdr_flag = 1; break; default: rate_mcs_index = 0; nss = 0; plcp_hdr_flag = 0; break; } for (i = 0; i < 4; i++) { if (IS_TX == 1) { rssi[i] = (s_start_ptr[4+i] & 0x80) ? -1 * (s_start_ptr[4+i] & 0x7f) : s_start_ptr[4+i] & 0x7f; } else { rssi[i] = (s_start_ptr[4+i] >= 128) ? (s_start_ptr[4+i] - 256) : s_start_ptr[4+i]; } } if (IS_TX == 0 || IS_TX == 4){ L1InfoC = s_start_ptr[8]; } msdu_length = pntoh24(&s_start_ptr[9]); /*** 16 bytes of PLCP header + 1 byte of L1P for user position ***/ plcp_ptr = &(rec[stats_offset+16]); /*** Add the PLCP length for S3_W_FPGA version VHT frames for Beamforming decode ***/ if (log_mode == 3) { frame_size = rec_size - (stats_offset + vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN); if (frame_size > ((int) msdu_length)) actual_octets = msdu_length; else { /* * XXX - does this mean "the packet was cut short during * capture" or "this is a malformed record"? */ actual_octets = frame_size; } } else { actual_octets = msdu_length; } /* * Sanity check the octets field to determine if it's greater than * the packet data available in the record - i.e., the record size * minus the sum of (length of statistics header + PLCP) and * (length of statistics trailer). * * Report an error if it is. */ if (actual_octets > rec_size - (stats_offset + vwr->MPDU_OFF + vVW510021_W_STATS_TRAILER_LEN)) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (runs past the end of the record)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } flow_seq = s_trail_ptr[vVW510021_W_FLOWSEQ_OFF]; latency = 0x00000000; /* clear latency */ flow_id = pntoh24(&s_trail_ptr[vVW510021_W_FLOWID_OFF]); /* all 24 bits valid */ /* For tx latency is duration, for rx latency is timestamp */ /* Get 48-bit latency value */ tsid = pcorey48tohll(&s_trail_ptr[vVW510021_W_LATVAL_OFF]); errors = pntoh32(&s_trail_ptr[vVW510021_W_ERRORS_OFF]); info = pntoh16(&s_trail_ptr[vVW510021_W_INFO_OFF]); if (IS_TX == 0 || IS_TX == 4) info_2nd = s_trail_ptr[41]; /*** Calculate Data rate based on * PLCP type, MCS index and number of spatial stream * radioflags is temporarily calculated, which is used in * get_ht_rate() and get_vht_rate(). **/ switch (plcp_type) { case vVW510021_W_PLCP_LEGACY: rate = get_legacy_rate(rate_mcs_index); break; case vVW510021_W_PLCP_MIXED: /* * According to section 20.3.2 "PPDU format", the HT-mixed * PLCP header has a "Non-HT SIGNAL field" (L-SIG), which * looks like an 11a SIGNAL field, followed by an HT SIGNAL * field (HT-SIG) described in section 20.3.9.4.3 "HT-SIG * definition". * * This means that the first octet of HT-SIG is at * plcp_ptr[3], skipping the 3 octets of the L-SIG field. * * 0x80 is the CBW 20/40 bit of HT-SIG. */ { /* set the appropriate flags to indicate HT mode and CB */ guint16 radioflags = FLAGS_CHAN_HT | ((plcp_ptr[3] & 0x80) ? FLAGS_CHAN_40MHZ : 0) | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); rate = get_ht_rate(rate_mcs_index, radioflags); } break; case vVW510021_W_PLCP_GREENFIELD: /* * According to section 20.3.2 "PPDU format", the HT-greenfield * PLCP header just has the HT SIGNAL field (HT-SIG) above, with * no L-SIG field. * * This means that the first octet of HT-SIG is at * plcp_ptr[0], as there's no L-SIG field to skip. * * 0x80 is the CBW 20/40 bit of HT-SIG. */ { /* set the appropriate flags to indicate HT mode and CB */ guint16 radioflags = FLAGS_CHAN_HT | ((plcp_ptr[0] & 0x80) ? FLAGS_CHAN_40MHZ : 0) | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); rate = get_ht_rate(rate_mcs_index, radioflags); } break; case vVW510021_W_PLCP_VHT_MIXED: /* * According to section 22.3.2 "VHT PPDU format" of IEEE Std * 802.11ac-2013, the VHT PLCP header has a "non-HT SIGNAL field" * (L-SIG), which looks like an 11a SIGNAL field, followed by * a VHT Signal A field (VHT-SIG-A) described in section * 22.3.8.3.3 "VHT-SIG-A definition", with training fields * between it and a VHT Signal B field (VHT-SIG-B) described * in section 22.3.8.3.6 "VHT-SIG-B definition", followed by * the PSDU. */ { guint8 SBW = vVW510021_W_BANDWIDTH_VHT(l1p_2); guint16 radioflags = FLAGS_CHAN_VHT | ((l1p_1 & vVW510021_W_IS_LONGGI) ? 0 : FLAGS_CHAN_SHORTGI); if (SBW == 3) radioflags |= FLAGS_CHAN_40MHZ; else if (SBW == 4) radioflags |= FLAGS_CHAN_80MHZ; rate = get_vht_rate(rate_mcs_index, radioflags, nss); } break; default: rate = 0.0f; break; } phyRate = (guint16)(rate * 10); /* Calculation of Data rate ends*/ /* 'ver_fpga' is the 2nd Octet of each frame. * msb/lsb nibble indicates log mode/fpga version respectively. * where log mode = 0 is normal capture and 1 is reduced capture, * lsb nibble is set to 1 always as this function is applicable for only FPGA version >= 48 */ if (log_mode == 3) { if (frame_size >= (int) msdu_length) { /* * The MSDU length includes the FCS. * * The packet data does *not* include the FCS - it's just 4 * bytes of junk - so we have to remove it. * * We'll be stripping off that junk, so make sure we have at * least 4 octets worth of packet data. * * XXX - is the FCS actually present here, as it appears to be * if log_mode isn't 3? * * There seems to be a special case of a length of 0. */ if (actual_octets < 4) { if (actual_octets != 0) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (too short to include 4 bytes of FCS)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } } else { actual_octets -= 4; } } ver_fpga = 0x11; } else { ver_fpga = 0x01; } /* Calculate start & end times (in sec/usec), converting 64-bit times to usec. */ /* 64-bit times are "Corey-endian" */ s_time = pcoreytohll(&s_trail_ptr[vVW510021_W_STARTT_OFF]); e_time = pcoreytohll(&s_trail_ptr[vVW510021_W_ENDT_OFF]); /* find the packet duration (difference between start and end times) */ d_time = (guint32)((e_time - s_time) / NS_IN_US); /* find diff, converting to usec */ /* also convert the packet start time to seconds and microseconds */ start_time = s_time / NS_IN_US; /* convert to microseconds first */ s_sec = (start_time / US_IN_SEC); /* get the number of seconds */ s_usec = start_time - (s_sec * US_IN_SEC); /* get the number of microseconds */ /* also convert the packet end time to seconds and microseconds */ end_time = e_time / NS_IN_US; /* convert to microseconds first */ /* extract the 32 LSBs of the signature timestamp field */ int m_ptr_offset = stats_offset + 8 + 12; m_ptr = rec + m_ptr_offset; pay_off = 42; /* 24 (MAC) + 8 (SNAP) + IP */ sig_off = find_signature(m_ptr, rec_size - m_ptr_offset, pay_off, flow_id, flow_seq); if (m_ptr[sig_off] == 0xdd) sig_ts = get_signature_ts(m_ptr, sig_off, rec_size - vVW510021_W_STATS_TRAILER_LEN); else sig_ts = 0; /* Set latency based on rx/tx and signature timestamp */ if (IS_TX == 0 || IS_TX == 4) { if (tsid < s_time) { latency = s_time - tsid; } else { /* Account for the rollover case. Since we cannot use 0x100000000 - l_time + s_time */ /* we look for a large difference between l_time and s_time. */ delta_b = tsid - s_time; if (delta_b > 0x10000000) latency = 0; else latency = delta_b; } } port_type = IS_TX << 4; /* * Fill up the per-packet header. * * We include the length of the metadata headers in the packet lengths. */ if (IS_TX == 4) { record->rec_header.packet_header.len = OCTO_MODIFIED_RF_LEN + OCTO_TIMESTAMP_FIELDS_LEN + OCTO_LAYER1TO4_LEN + actual_octets; record->rec_header.packet_header.caplen = OCTO_MODIFIED_RF_LEN + OCTO_TIMESTAMP_FIELDS_LEN + OCTO_LAYER1TO4_LEN + actual_octets; } else { record->rec_header.packet_header.len = OCTO_TIMESTAMP_FIELDS_LEN + OCTO_LAYER1TO4_LEN + actual_octets; record->rec_header.packet_header.caplen = OCTO_TIMESTAMP_FIELDS_LEN + OCTO_LAYER1TO4_LEN + actual_octets; } if (record->rec_header.packet_header.caplen > WTAP_MAX_PACKET_SIZE_STANDARD) { /* * Probably a corrupt capture file; return an error, * so that our caller doesn't blow up trying to allocate * space for an immensely-large packet. */ *err_info = ws_strdup_printf("vwr: File has %u-byte packet, bigger than maximum of %u", record->rec_header.packet_header.caplen, WTAP_MAX_PACKET_SIZE_STANDARD); *err = WTAP_ERR_BAD_FILE; return FALSE; } record->ts.secs = (time_t)s_sec; record->ts.nsecs = (int)(s_usec * 1000); record->rec_type = REC_TYPE_PACKET; record->block = wtap_block_create(WTAP_BLOCK_PACKET); record->presence_flags = WTAP_HAS_TS; ws_buffer_assure_space(buf, record->rec_header.packet_header.caplen); data_ptr = ws_buffer_start_ptr(buf); } /* * Generate and copy out the common metadata headers, * set the port type to port_type (XXX). * * All values are copied out in little-endian byte order. */ /*** msdu_length = msdu_length + 16; ***/ /* 1st octet of record for port_type and other crud */ phtole8(&data_ptr[bytes_written], port_type); bytes_written += 1; if (IS_TX != 3) { phtole8(&data_ptr[bytes_written], ver_fpga); /* 2nd octet of record for FPGA version*/ bytes_written += 1; phtoles(&data_ptr[bytes_written], OCTO_TIMESTAMP_FIELDS_LEN); /* it_len */ bytes_written += 2; /*** Time Collapsible header started***/ if (IS_TX == 1 && sig_ts != 0) { phtolel(&data_ptr[bytes_written], latency); } else { phtolel(&data_ptr[bytes_written], 0); } bytes_written += 4; phtolel(&data_ptr[bytes_written], sig_ts); /* 32 LSBs of signature timestamp (nsec) */ bytes_written += 4; phtolell(&data_ptr[bytes_written], start_time); /* record start & end times of frame */ bytes_written += 8; phtolell(&data_ptr[bytes_written], end_time); bytes_written += 8; phtolel(&data_ptr[bytes_written], d_time); bytes_written += 4; /*** Time Collapsible header ends ***/ } /*** RF Collapsible header starts***/ if (IS_TX == 3 || IS_TX == 4) { phtole8(&data_ptr[bytes_written], rf_id); bytes_written += 1; data_ptr[bytes_written] = 0; bytes_written += 1; data_ptr[bytes_written] = 0; bytes_written += 1; data_ptr[bytes_written] = 0; bytes_written += 1; /*** NOISE for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_NOISE_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_NOISE_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_NOISE_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** SNR for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_SNR_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_SNR_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_SNR_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** PFE for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_PFE_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_PFE_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_PFE_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** EVM SIG Data for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_EVM_SD_SIG_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SD_SIG_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SD_SIG_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** EVM SIG PILOT for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_EVM_SP_SIG_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SP_SIG_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SP_SIG_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** EVM Data Data for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_EVM_SD_DATA_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SD_DATA_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SD_DATA_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** EVM Data PILOT for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_EVM_SP_DATA_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SP_DATA_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_EVM_SP_DATA_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** EVM WORST SYMBOL for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_DSYMBOL_IDX_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_DSYMBOL_IDX_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_DSYMBOL_IDX_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** CONTEXT_P for all 4 Ports ***/ for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[RF_PORT_1_CONTEXT_OFF+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[RF_PORT_1_CONTEXT_OFF+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[RF_PORT_1_CONTEXT_OFF+1+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } /*** FOR rest 24 RF data bytes are commented for future use ***/ /*** for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[20+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[20+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[21+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[24+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[24+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[25+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } for (i = 0; i < RF_NUMBER_OF_PORTS; i++) { if (pntoh16(&rf_ptr[26+i*RF_INTER_PORT_GAP_OFF]) == 0) { phtoles(&data_ptr[bytes_written], 0); bytes_written += 2; } else { data_ptr[bytes_written] = rf_ptr[26+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; data_ptr[bytes_written] = rf_ptr[27+i*RF_INTER_PORT_GAP_OFF]; bytes_written += 1; } } ***/ } /*** RF Collapsible header ends***/ if (IS_TX != 3) { /* * Generate and copy out the WLAN metadata headers. * * All values are copied out in little-endian byte order. */ phtoles(&data_ptr[bytes_written], OCTO_LAYER1TO4_LEN); bytes_written += 2; /*** Layer-1 Collapsible header started***/ data_ptr[bytes_written] = l1p_1; bytes_written += 1; data_ptr[bytes_written] = (nss << 4) | IS_TX; bytes_written += 1; phtoles(&data_ptr[bytes_written], phyRate); /* To dosplay Data rate based on the PLCP type & MCS*/ bytes_written += 2; data_ptr[bytes_written] = l1p_2; bytes_written += 1; data_ptr[bytes_written] = rssi[0]; bytes_written += 1; data_ptr[bytes_written] = rssi[1]; bytes_written += 1; data_ptr[bytes_written] = rssi[2]; bytes_written += 1; data_ptr[bytes_written] = rssi[3]; bytes_written += 1; /* padding may not be required for S3_W*/ data_ptr[bytes_written] = s_start_ptr[2]; /*** For Signal Bandwidth Mask ***/ bytes_written += 1; data_ptr[bytes_written] = s_start_ptr[3]; /*** For Antenna Port Energy Detect and MU_MASK ***/ bytes_written += 1; if (plcp_hdr_flag == 1 && (IS_TX == 0 || IS_TX == 4)) { data_ptr[bytes_written] = L1InfoC; /*** For Other plcp type = VHT ***/ } else { data_ptr[bytes_written] = 0; /*** For Other plcp type, this offset is set to 0***/ } bytes_written += 1; phtoles(&data_ptr[bytes_written], msdu_length); bytes_written += 2; /*** Layer-1 Collapsible header Ends ***/ /*** PLCP Collapsible header Starts ***/ memcpy(&data_ptr[bytes_written], &rec[stats_offset+16], 16); bytes_written += 16; /*** PLCP Collapsible header Ends ***/ /*** Layer 2-4 Collapsible header Starts ***/ phtolel(&data_ptr[bytes_written], pntoh32(&s_start_ptr[12])); /*** This 4 bytes includes BM,BV,CV,BSSID and ClientID ***/ bytes_written += 4; phtoles(&data_ptr[bytes_written], pntoh16(&s_trail_ptr[20])); /*** 2 bytes includes FV,QT,HT,L4V,TID and WLAN type ***/ bytes_written += 2; data_ptr[bytes_written] = flow_seq; bytes_written += 1; phtole24(&data_ptr[bytes_written], flow_id); bytes_written += 3; phtoles(&data_ptr[bytes_written], pntoh16(&s_trail_ptr[28])); /*** 2 bytes for Layer 4 ID ***/ bytes_written += 2; phtolel(&data_ptr[bytes_written], pntoh32(&s_trail_ptr[24])); /*** 4 bytes for Payload Decode ***/ bytes_written += 4; /*** In case of RX, Info has 3 bytes of data, whereas for TX, 2 bytes ***/ if (IS_TX == 0 || IS_TX == 4) { phtoles(&data_ptr[bytes_written], info); bytes_written += 2; data_ptr[bytes_written] = info_2nd; bytes_written += 1; } else { phtoles(&data_ptr[bytes_written], info); bytes_written += 2; data_ptr[bytes_written] = 0; bytes_written += 1; } phtolel(&data_ptr[bytes_written], errors); bytes_written += 4; /*** Layer 2-4 Collapsible header Ends ***/ /* Finally, copy the whole MAC frame to the packet buffer as-is. * This does not include the stats header or the PLCP. * This also does not include the last 4 bytes, as those don't * contain an FCS, they just contain junk. */ memcpy(&data_ptr[bytes_written], &rec[stats_offset+(vwr->MPDU_OFF)], actual_octets); } return TRUE; } /* read an Ethernet packet */ /* Copy the actual packet data from the capture file into the target data block. */ /* The packet is constructed as a 38-byte VeriWave-extended Radiotap header plus the raw */ /* MAC octets. */ static gboolean vwr_read_rec_data_ethernet(vwr_t *vwr, wtap_rec *record, Buffer *buf, const guint8 *rec, int rec_size, int IS_TX, int *err, gchar **err_info) { guint8 *data_ptr; int bytes_written = 0; /* bytes output to buf so far */ const guint8 *s_ptr, *m_ptr; /* stats and MPDU pointers */ guint16 msdu_length, actual_octets; /* octets in frame */ guint flow_seq; /* seqnum */ guint64 s_time = LL_ZERO, e_time = LL_ZERO; /* start/end */ /* times, nsec */ guint32 latency = 0; guint64 start_time, s_sec = LL_ZERO, s_usec = LL_ZERO; /* start time, sec + usec */ guint64 end_time; /* end time */ guint l4id; guint16 info, validityBits; /* INFO/ERRORS fields in stats */ guint32 errors; guint16 vc_id; /* VC ID, total (incl of aggregates) */ guint32 flow_id, d_time; /* packet duration */ int f_flow; /* flags: flow valid */ guint32 frame_type; /* frame type field */ int mac_len, sig_off, pay_off; /* MAC header len, signature offset */ /* XXX - the code here fetched tsid, but never used it! */ guint64 sig_ts/*, tsid*/; /* 32 LSBs of timestamp in signature */ guint64 delta_b; /* Used for calculating latency */ guint16 vw_flags; /* VeriWave-specific packet flags */ if ((guint)rec_size < vwr->STATS_LEN) { *err_info = ws_strdup_printf("vwr: Invalid record length %d (must be at least %u)", rec_size, vwr->STATS_LEN); *err = WTAP_ERR_BAD_FILE; return FALSE; } /* Calculate the start of the statistics block in the buffer. */ /* Also get a bunch of fields from the stats block. */ m_ptr = &(rec[0]); /* point to the data block */ s_ptr = &(rec[rec_size - vwr->STATS_LEN]); /* point to the stats block */ msdu_length = pntoh16(&s_ptr[vwr->OCTET_OFF]); actual_octets = msdu_length; /* * Sanity check the octets field to determine if it's greater than * the packet data available in the record - i.e., the record size * minus the length of the statistics block. * * Report an error if it is. */ if (actual_octets > rec_size - vwr->STATS_LEN) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (runs past the end of the record)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } vc_id = pntoh16(&s_ptr[vwr->VCID_OFF]) & vwr->VCID_MASK; flow_seq = s_ptr[vwr->FLOWSEQ_OFF]; frame_type = pntoh32(&s_ptr[vwr->FRAME_TYPE_OFF]); if (vwr->FPGA_VERSION == vVW510024_E_FPGA) { validityBits = pntoh16(&s_ptr[vwr->VALID_OFF]); f_flow = validityBits & vwr->FLOW_VALID; mac_len = (validityBits & vwr->IS_VLAN) ? 16 : 14; /* MAC hdr length based on VLAN tag */ errors = pntoh16(&s_ptr[vwr->ERRORS_OFF]); } else { f_flow = s_ptr[vwr->VALID_OFF] & vwr->FLOW_VALID; mac_len = (frame_type & vwr->IS_VLAN) ? 16 : 14; /* MAC hdr length based on VLAN tag */ /* for older fpga errors is only represented by 16 bits) */ errors = pntoh16(&s_ptr[vwr->ERRORS_OFF]); } info = pntoh16(&s_ptr[vwr->INFO_OFF]); /* 24 LSBs */ flow_id = pntoh24(&s_ptr[vwr->FLOWID_OFF]); #if 0 /* For tx latency is duration, for rx latency is timestamp. */ /* Get 64-bit latency value. */ tsid = pcorey48tohll(&s_ptr[vwr->LATVAL_OFF]); #endif l4id = pntoh16(&s_ptr[vwr->L4ID_OFF]); /* * The MSDU length includes the FCS. * * The packet data does *not* include the FCS - it's just 4 bytes * of junk - so we have to remove it. * * We'll be stripping off that junk, so make sure we have at least * 4 octets worth of packet data. * * There seems to be a special case of a length of 0. */ if (actual_octets < 4) { if (actual_octets != 0) { *err_info = ws_strdup_printf("vwr: Invalid data length %u (too short to include 4 bytes of FCS)", actual_octets); *err = WTAP_ERR_BAD_FILE; return FALSE; } } else { actual_octets -= 4; } /* Calculate start & end times (in sec/usec), converting 64-bit times to usec. */ /* 64-bit times are "Corey-endian" */ s_time = pcoreytohll(&s_ptr[vwr->STARTT_OFF]); e_time = pcoreytohll(&s_ptr[vwr->ENDT_OFF]); /* find the packet duration (difference between start and end times) */ d_time = (guint32)((e_time - s_time)); /* find diff, leaving in nsec for Ethernet */ /* also convert the packet start time to seconds and microseconds */ start_time = s_time / NS_IN_US; /* convert to microseconds first */ s_sec = (start_time / US_IN_SEC); /* get the number of seconds */ s_usec = start_time - (s_sec * US_IN_SEC); /* get the number of microseconds */ /* also convert the packet end time to seconds and microseconds */ end_time = e_time / NS_IN_US; /* convert to microseconds first */ if (frame_type & vwr->IS_TCP) /* signature offset for TCP frame */ { pay_off = mac_len + 40; } else if (frame_type & vwr->IS_UDP) /* signature offset for UDP frame */ { pay_off = mac_len + 28; } else if (frame_type & vwr->IS_ICMP) /* signature offset for ICMP frame */ { pay_off = mac_len + 24; } else if (frame_type & vwr->IS_IGMP) /* signature offset for IGMPv2 frame */ { pay_off = mac_len + 28; } else /* signature offset for raw IP frame */ { pay_off = mac_len + 20; } sig_off = find_signature(m_ptr, rec_size, pay_off, flow_id, flow_seq); if ((m_ptr[sig_off] == 0xdd) && (f_flow != 0)) sig_ts = get_signature_ts(m_ptr, sig_off, msdu_length); else sig_ts = 0; /* Set latency based on rx/tx and signature timestamp */ if (!IS_TX) { if (sig_ts < s_time) { latency = (guint32)(s_time - sig_ts); } else { /* Account for the rollover case. Since we cannot use 0x100000000 - l_time + s_time */ /* we look for a large difference between l_time and s_time. */ delta_b = sig_ts - s_time; if (delta_b > 0x10000000) { latency = 0; } else latency = (guint32)delta_b; } } /* * Fill up the per-packet header. * * We include the length of the metadata headers in the packet lengths. * * The maximum value of actual_octets is 65535, which, even after * adding the lengths of the metadata headers, is less than * WTAP_MAX_PACKET_SIZE_STANDARD will ever be, so we don't need to check it. */ record->rec_header.packet_header.len = STATS_COMMON_FIELDS_LEN + EXT_ETHERNET_FIELDS_LEN + actual_octets; record->rec_header.packet_header.caplen = STATS_COMMON_FIELDS_LEN + EXT_ETHERNET_FIELDS_LEN + actual_octets; record->ts.secs = (time_t)s_sec; record->ts.nsecs = (int)(s_usec * 1000); record->rec_type = REC_TYPE_PACKET; record->block = wtap_block_create(WTAP_BLOCK_PACKET); record->presence_flags = WTAP_HAS_TS; /*etap_hdr.vw_ip_length = (guint16)ip_len;*/ ws_buffer_assure_space(buf, record->rec_header.packet_header.caplen); data_ptr = ws_buffer_start_ptr(buf); /* * Generate and copy out the common metadata headers, * set the port type to 1 (Ethernet). * * All values are copied out in little-endian byte order. */ /* 1st octet of record for port_type and command (command is 0, hence RX) */ phtole8(&data_ptr[bytes_written], ETHERNET_PORT); bytes_written += 1; /* 2nd octet of record for fpga version (Ethernet, hence non-OCTO) */ phtole8(&data_ptr[bytes_written], 0); bytes_written += 1; phtoles(&data_ptr[bytes_written], STATS_COMMON_FIELDS_LEN); bytes_written += 2; phtoles(&data_ptr[bytes_written], msdu_length); bytes_written += 2; phtolel(&data_ptr[bytes_written], flow_id); bytes_written += 4; phtoles(&data_ptr[bytes_written], vc_id); bytes_written += 2; phtoles(&data_ptr[bytes_written], flow_seq); bytes_written += 2; if (!IS_TX && (sig_ts != 0)) { phtolel(&data_ptr[bytes_written], latency); } else { phtolel(&data_ptr[bytes_written], 0); } bytes_written += 4; phtolel(&data_ptr[bytes_written], sig_ts); bytes_written += 4; phtolell(&data_ptr[bytes_written], start_time) /* record start & end times of frame */ bytes_written += 8; phtolell(&data_ptr[bytes_written], end_time); bytes_written += 8; phtolel(&data_ptr[bytes_written], d_time); bytes_written += 4; /* * Generate and copy out the Ethernet metadata headers. * * All values are copied out in little-endian byte order. */ phtoles(&data_ptr[bytes_written], EXT_ETHERNET_FIELDS_LEN); bytes_written += 2; vw_flags = 0; if (IS_TX) vw_flags |= VW_FLAGS_TXF; if (errors & vwr->FCS_ERROR) vw_flags |= VW_FLAGS_FCSERR; phtoles(&data_ptr[bytes_written], vw_flags); bytes_written += 2; phtoles(&data_ptr[bytes_written], info); bytes_written += 2; phtolel(&data_ptr[bytes_written], errors); bytes_written += 4; phtolel(&data_ptr[bytes_written], l4id); bytes_written += 4; /* Add in pad */ phtolel(&data_ptr[bytes_written], 0); bytes_written += 4; /* * Finally, copy the whole MAC frame to the packet buffer as-is. * This also does not include the last 4 bytes, as those don't * contain an FCS, they just contain junk. */ memcpy(&data_ptr[bytes_written], m_ptr, actual_octets); return TRUE; } /*--------------------------------------------------------------------------------------*/ /* utility to split up and decode a 16-byte message record */ static int decode_msg(vwr_t *vwr, guint8 *rec, int *v_type, int *IS_TX, int *log_mode) { guint8 cmd,fpga_log_mode; /* components of message */ guint32 wd2, wd3; int v_size; /* size of var-len message */ /* break up the message record into its pieces */ cmd = rec[0]; fpga_log_mode = rec[1]; fpga_log_mode = ((fpga_log_mode & 0x30) >> 4); wd2 = pntoh32(&rec[8]); wd3 = pntoh32(&rec[12]); if (vwr != NULL) *log_mode = fpga_log_mode; /* Log mode = 3, when MPDU data is reduced */ /* now decode based on the command byte */ switch (cmd) { case COMMAND_RX: if (vwr != NULL) { *IS_TX = 0; } v_size = (int)(wd2 & 0xffff); *v_type = VT_FRAME; break; case COMMAND_TX: if (vwr != NULL) { *IS_TX = 1; } v_size = (int)(wd2 & 0xffff); *v_type = VT_FRAME; break; /* case COMMAND_RFN: if (vwr != NULL) { *IS_TX = 3; } v_size = (int)(wd2 & 0xffff); *v_type = VT_FRAME; break; */ case COMMAND_RF: /* For RF Modified only */ if (vwr != NULL) { *IS_TX = 3; } v_size = (int)(wd2 & 0xffff); *v_type = VT_FRAME; break; case COMMAND_RFRX: /* For RF_RX Modified only */ if (vwr != NULL) { *IS_TX = 4; } v_size = (int)(wd2 & 0xffff); *v_type = VT_FRAME; break; case 0xc1: case 0x8b: case 0xbb: if (vwr != NULL) { *IS_TX = 2; } v_size = (int)(wd2 & 0xffff); *v_type = VT_CPMSG; break; case 0xfe: if (vwr != NULL) { *IS_TX = 2; } v_size = (int)(wd3 & 0xffff); *v_type = VT_CPMSG; break; default: if (vwr != NULL) { *IS_TX = 2; } v_size = 0; *v_type = VT_UNKNOWN; break; } return v_size; } /*---------------------------------------------------------------------------------------*/ /* Utilities to extract and decode the PHY bit rate from 802.11 PLCP headers (OFDM/CCK). */ /* They are passed a pointer to 4 or 6 consecutive bytes of PLCP header. */ /* The integer returned by the get_xxx_rate() functions is in units of 0.5 Mb/s. */ /* The string returned by the decode_xxx_rate() functions is 3 characters wide. */ static guint8 get_ofdm_rate(const guint8 *plcp) { /* extract the RATE field (LS nibble of first byte) then convert it to the MCS index used by the L1p fields */ switch (plcp[0] & 0x0f) { case 0x0b: return 4; case 0x0f: return 5; case 0x0a: return 6; case 0x0e: return 7; case 0x09: return 8; case 0x0d: return 9; case 0x08: return 10; case 0x0c: return 11; default: return 0; } } static guint8 get_cck_rate(const guint8 *plcp) { /* extract rate from the SIGNAL field then convert it to the MCS index used by the L1p fields */ switch (plcp[0]) { case 0x0a: return 0; case 0x14: return 1; case 0x37: return 2; case 0x6e: return 3; default: return 0; } } /*--------------------------------------------------------------------------------------*/ /* utility to set up offsets and bitmasks for decoding the stats blocks */ static void setup_defaults(vwr_t *vwr, guint16 fpga) { switch (fpga) { /* WLAN frames */ case S2_W_FPGA: vwr->STATS_LEN = vVW510021_W_STATS_TRAILER_LEN; vwr->VALID_OFF = vVW510021_W_VALID_OFF; vwr->MTYPE_OFF = vVW510021_W_MTYPE_OFF; vwr->VCID_OFF = vVW510021_W_VCID_OFF; vwr->FLOWSEQ_OFF = vVW510021_W_FLOWSEQ_OFF; vwr->FLOWID_OFF = vVW510021_W_FLOWID_OFF; /*vwr->OCTET_OFF = v22_W_OCTET_OFF;*/ vwr->ERRORS_OFF = vVW510021_W_ERRORS_OFF; vwr->PATN_OFF = vVW510021_W_MATCH_OFF; vwr->RSSI_OFF = vVW510021_W_RSSI_TXPOWER_OFF; vwr->STARTT_OFF = vVW510021_W_STARTT_OFF; vwr->ENDT_OFF = vVW510021_W_ENDT_OFF; vwr->LATVAL_OFF = vVW510021_W_LATVAL_OFF; vwr->INFO_OFF = vVW510021_W_INFO_OFF; vwr->FPGA_VERSION_OFF = S2_W_FPGA_VERSION_OFF; vwr->HEADER_VERSION_OFF = vVW510021_W_HEADER_VERSION_OFF; vwr->OCTET_OFF = vVW510021_W_MSDU_LENGTH_OFF; vwr->L1P_1_OFF = vVW510021_W_L1P_1_OFF; vwr->L1P_2_OFF = vVW510021_W_L1P_2_OFF; vwr->L4ID_OFF = vVW510021_W_L4ID_OFF; vwr->IPLEN_OFF = vVW510021_W_IPLEN_OFF; vwr->PLCP_LENGTH_OFF = vVW510021_W_PLCP_LENGTH_OFF; vwr->MT_MASK = vVW510021_W_SEL_MASK; vwr->MCS_INDEX_MASK = vVW510021_W_MCS_MASK; vwr->VCID_MASK = 0xffff; vwr->FLOW_VALID = vVW510021_W_FLOW_VALID; vwr->STATS_START_OFF = vVW510021_W_HEADER_LEN; vwr->FCS_ERROR = vVW510021_W_FCS_ERROR; vwr->CRYPTO_ERR = v22_W_CRYPTO_ERR; vwr->RETRY_ERR = v22_W_RETRY_ERR; /*vwr->STATS_START_OFF = 0;*/ vwr->RXTX_OFF = vVW510021_W_RXTX_OFF; vwr->MT_10_HALF = 0; vwr->MT_10_FULL = 0; vwr->MT_100_HALF = 0; vwr->MT_100_FULL = 0; vwr->MT_1G_HALF = 0; vwr->MT_1G_FULL = 0; vwr->MT_CCKL = v22_W_MT_CCKL; vwr->MT_CCKS = v22_W_MT_CCKS; /*vwr->MT_OFDM = vVW510021_W_MT_OFDM;*/ vwr->WEPTYPE = vVW510021_W_WEPTYPE; vwr->TKIPTYPE = vVW510021_W_TKIPTYPE; vwr->CCMPTYPE = vVW510021_W_CCMPTYPE; vwr->FRAME_TYPE_OFF = vVW510021_W_FRAME_TYPE_OFF; vwr->IS_TCP = vVW510021_W_IS_TCP; vwr->IS_UDP = vVW510021_W_IS_UDP; vwr->IS_ICMP = vVW510021_W_IS_ICMP; vwr->IS_IGMP = vVW510021_W_IS_IGMP; vwr->IS_QOS = vVW510021_W_QOS_VALID; /* * vVW510021_W_STATS_HEADER_LEN = 8 is: * * 2 bytes of l1p_1/l1p_2; * 1 byte of RSSI; * 2 bytes of MSDU length + other bits * 1 byte of XXX; * 2 bytes of VCID. * * The 12 is for 11 bytes of PLCP and 1 byte of pad * before the data. */ vwr->MPDU_OFF = vVW510021_W_STATS_HEADER_LEN + 12; break; case S3_W_FPGA: vwr->STATS_LEN = vVW510021_W_STATS_TRAILER_LEN; vwr->PLCP_LENGTH_OFF = 16; /* * The 16 + 16 is: * * 2 bytes of l1p_1/l1p_2; * 1 byte of signal bandwidth mask; * 1 byte of antenna port energy; * 4 bytes of per-antenna RSSI; * 1 byte of L1InfoC; * 3 bytes of MSDU length; * 4 bytes of something; * 16 bytes of PLCP. */ vwr->MPDU_OFF = 16 + 16; break; case vVW510012_E_FPGA: vwr->STATS_LEN = v22_E_STATS_LEN; vwr->VALID_OFF = v22_E_VALID_OFF; vwr->MTYPE_OFF = v22_E_MTYPE_OFF; vwr->VCID_OFF = v22_E_VCID_OFF; vwr->FLOWSEQ_OFF = v22_E_FLOWSEQ_OFF; vwr->FLOWID_OFF = v22_E_FLOWID_OFF; vwr->OCTET_OFF = v22_E_OCTET_OFF; vwr->ERRORS_OFF = v22_E_ERRORS_OFF; vwr->PATN_OFF = v22_E_PATN_OFF; vwr->RSSI_OFF = v22_E_RSSI_OFF; vwr->STARTT_OFF = v22_E_STARTT_OFF; vwr->ENDT_OFF = v22_E_ENDT_OFF; vwr->LATVAL_OFF = v22_E_LATVAL_OFF; vwr->INFO_OFF = v22_E_INFO_OFF; vwr->L4ID_OFF = v22_E_L4ID_OFF; vwr->IS_RX = v22_E_IS_RX; vwr->MT_MASK = v22_E_MT_MASK; vwr->VCID_MASK = v22_E_VCID_MASK; vwr->FLOW_VALID = v22_E_FLOW_VALID; vwr->FCS_ERROR = v22_E_FCS_ERROR; vwr->RX_DECRYPTS = v22_E_RX_DECRYPTS; vwr->TX_DECRYPTS = v22_E_TX_DECRYPTS; vwr->FC_PROT_BIT = v22_E_FC_PROT_BIT; vwr->MT_10_HALF = v22_E_MT_10_HALF; vwr->MT_10_FULL = v22_E_MT_10_FULL; vwr->MT_100_HALF = v22_E_MT_100_HALF; vwr->MT_100_FULL = v22_E_MT_100_FULL; vwr->MT_1G_HALF = v22_E_MT_1G_HALF; vwr->MT_1G_FULL = v22_E_MT_1G_FULL; vwr->MT_CCKL = 0; vwr->MT_CCKS = 0; vwr->MT_OFDM = 0; vwr->FRAME_TYPE_OFF = v22_E_FRAME_TYPE_OFF; vwr->IS_TCP = v22_E_IS_TCP; vwr->IS_UDP = v22_E_IS_UDP; vwr->IS_ICMP = v22_E_IS_ICMP; vwr->IS_IGMP = v22_E_IS_IGMP; vwr->IS_QOS = v22_E_IS_QOS; vwr->IS_VLAN = v22_E_IS_VLAN; break; /* WLAN frames */ case S1_W_FPGA: vwr->STATS_LEN = v22_W_STATS_LEN; vwr->MTYPE_OFF = v22_W_MTYPE_OFF; vwr->VALID_OFF = v22_W_VALID_OFF; vwr->VCID_OFF = v22_W_VCID_OFF; vwr->FLOWSEQ_OFF = v22_W_FLOWSEQ_OFF; vwr->FLOWID_OFF = v22_W_FLOWID_OFF; vwr->OCTET_OFF = v22_W_OCTET_OFF; vwr->ERRORS_OFF = v22_W_ERRORS_OFF; vwr->PATN_OFF = v22_W_PATN_OFF; vwr->RSSI_OFF = v22_W_RSSI_OFF; vwr->STARTT_OFF = v22_W_STARTT_OFF; vwr->ENDT_OFF = v22_W_ENDT_OFF; vwr->LATVAL_OFF = v22_W_LATVAL_OFF; vwr->INFO_OFF = v22_W_INFO_OFF; vwr->L4ID_OFF = v22_W_L4ID_OFF; vwr->IPLEN_OFF = v22_W_IPLEN_OFF; vwr->PLCP_LENGTH_OFF = v22_W_PLCP_LENGTH_OFF; vwr->FCS_ERROR = v22_W_FCS_ERROR; vwr->CRYPTO_ERR = v22_W_CRYPTO_ERR; vwr->PAYCHK_ERR = v22_W_PAYCHK_ERR; vwr->RETRY_ERR = v22_W_RETRY_ERR; vwr->IS_RX = v22_W_IS_RX; vwr->MT_MASK = v22_W_MT_MASK; vwr->VCID_MASK = v22_W_VCID_MASK; vwr->FLOW_VALID = v22_W_FLOW_VALID; vwr->RX_DECRYPTS = v22_W_RX_DECRYPTS; vwr->TX_DECRYPTS = v22_W_TX_DECRYPTS; vwr->FC_PROT_BIT = v22_W_FC_PROT_BIT; vwr->MT_10_HALF = 0; vwr->MT_10_FULL = 0; vwr->MT_100_HALF = 0; vwr->MT_100_FULL = 0; vwr->MT_1G_HALF = 0; vwr->MT_1G_FULL = 0; vwr->MT_CCKL = v22_W_MT_CCKL; vwr->MT_CCKS = v22_W_MT_CCKS; vwr->MT_OFDM = v22_W_MT_OFDM; vwr->WEPTYPE = v22_W_WEPTYPE; vwr->TKIPTYPE = v22_W_TKIPTYPE; vwr->CCMPTYPE = v22_W_CCMPTYPE; vwr->FRAME_TYPE_OFF = v22_W_FRAME_TYPE_OFF; vwr->IS_TCP = v22_W_IS_TCP; vwr->IS_UDP = v22_W_IS_UDP; vwr->IS_ICMP = v22_W_IS_ICMP; vwr->IS_IGMP = v22_W_IS_IGMP; vwr->IS_QOS = v22_W_IS_QOS; break; /* Ethernet frames */ case vVW510024_E_FPGA: vwr->STATS_LEN = vVW510024_E_STATS_LEN; vwr->VALID_OFF = vVW510024_E_VALID_OFF; vwr->VCID_OFF = vVW510024_E_VCID_OFF; vwr->FLOWSEQ_OFF = vVW510024_E_FLOWSEQ_OFF; vwr->FLOWID_OFF = vVW510024_E_FLOWID_OFF; vwr->OCTET_OFF = vVW510024_E_MSDU_LENGTH_OFF; vwr->ERRORS_OFF = vVW510024_E_ERRORS_OFF; vwr->PATN_OFF = vVW510024_E_MATCH_OFF; vwr->STARTT_OFF = vVW510024_E_STARTT_OFF; vwr->ENDT_OFF = vVW510024_E_ENDT_OFF; vwr->LATVAL_OFF = vVW510024_E_LATVAL_OFF; vwr->INFO_OFF = vVW510024_E_INFO_OFF; vwr->L4ID_OFF = vVW510024_E_L4ID_OFF; vwr->IPLEN_OFF = vVW510024_E_IPLEN_OFF; vwr->FPGA_VERSION_OFF = vVW510024_E_FPGA_VERSION_OFF; vwr->HEADER_VERSION_OFF = vVW510024_E_HEADER_VERSION_OFF; vwr->VCID_MASK = vVW510024_E_VCID_MASK; vwr->FLOW_VALID = vVW510024_E_FLOW_VALID; vwr->FCS_ERROR = v22_E_FCS_ERROR; vwr->FRAME_TYPE_OFF = vVW510024_E_FRAME_TYPE_OFF; vwr->IS_TCP = vVW510024_E_IS_TCP; vwr->IS_UDP = vVW510024_E_IS_UDP; vwr->IS_ICMP = vVW510024_E_IS_ICMP; vwr->IS_IGMP = vVW510024_E_IS_IGMP; vwr->IS_QOS = vVW510024_E_QOS_VALID; vwr->IS_VLAN = vVW510024_E_IS_VLAN; break; } } #define SIG_SCAN_RANGE 64 /* range of signature scanning region */ /* Utility routine: check that signature is at specified location; scan for it if not. */ /* If we can't find a signature at all, then simply return the originally supplied offset. */ int find_signature(const guint8 *m_ptr, int rec_size, int pay_off, guint32 flow_id, guint8 flow_seq) { int tgt; /* temps */ guint32 fid; /* initial check is very simple: look for a '0xdd' at the target location */ if (m_ptr[pay_off] == 0xdd) /* if magic byte is present */ return pay_off; /* got right offset, return it */ /* Hmmm, signature magic byte is not where it is supposed to be; scan from start of */ /* payload until maximum scan range exhausted to see if we can find it. */ /* The scanning process consists of looking for a '0xdd', then checking for the correct */ /* flow ID and sequence number at the appropriate offsets. */ for (tgt = pay_off; tgt < (rec_size); tgt++) { if (m_ptr[tgt] == 0xdd) { /* found magic byte? check fields */ if ((tgt + 15 < rec_size) && (m_ptr[tgt + 15] == 0xe2)) { if (m_ptr[tgt + 4] != flow_seq) continue; fid = pletoh24(&m_ptr[tgt + 1]); if (fid != flow_id) continue; return (tgt); } else if (tgt + SIG_FSQ_OFF < rec_size) { /* out which one... */ if (m_ptr[tgt + SIG_FSQ_OFF] != flow_seq) /* check sequence number */ continue; /* if failed, keep scanning */ fid = pletoh24(&m_ptr[tgt + SIG_FID_OFF]); /* assemble flow ID from signature */ if (fid != flow_id) /* check flow ID against expected */ continue; /* if failed, keep scanning */ /* matched magic byte, sequence number, flow ID; found the signature */ return (tgt); /* return offset of signature */ } } } /* failed to find the signature, return the original offset as default */ return pay_off; } /* utility routine: harvest the signature time stamp from the data frame */ guint64 get_signature_ts(const guint8 *m_ptr,int sig_off, int sig_max) { int ts_offset; guint64 sig_ts; if (sig_off + 15 >= sig_max) return 0; if (m_ptr[sig_off + 15] == 0xe2) ts_offset = 5; else ts_offset = 8; sig_ts = pletoh32(&m_ptr[sig_off + ts_offset]); return (sig_ts & 0xffffffff); } static float get_legacy_rate(guint8 rate_index) { /* Rate conversion data */ static const float canonical_rate_legacy[] = {1.0f, 2.0f, 5.5f, 11.0f, 6.0f, 9.0f, 12.0f, 18.0f, 24.0f, 36.0f, 48.0f, 54.0f}; float bitrate = 0.0f; if (rate_index < G_N_ELEMENTS(canonical_rate_legacy)) bitrate = canonical_rate_legacy[rate_index]; return bitrate; } static float get_ht_rate(guint8 mcs_index, guint16 rflags) { /* Rate conversion data */ static const int canonical_ndbps_20_ht[8] = {26, 52, 78, 104, 156, 208, 234, 260}; static const int canonical_ndbps_40_ht[8] = {54, 108, 162, 216, 324, 432, 486, 540}; float symbol_tx_time, bitrate; int ndbps; if (rflags & FLAGS_CHAN_SHORTGI) symbol_tx_time = 3.6f; else symbol_tx_time = 4.0f; if (rflags & FLAGS_CHAN_40MHZ) ndbps = canonical_ndbps_40_ht[mcs_index - 8*(int)(mcs_index/8)]; else ndbps = canonical_ndbps_20_ht[mcs_index - 8*(int)(mcs_index/8)]; bitrate = (ndbps * (((int)(mcs_index >> 3) + 1))) / symbol_tx_time; return bitrate; } static float get_vht_rate(guint8 mcs_index, guint16 rflags, guint8 nss) { /* Rate conversion data */ static const int canonical_ndbps_20_vht[9] = {26, 52, 78, 104, 156, 208, 234, 260, 312}; static const int canonical_ndbps_40_vht[10] = {54, 108, 162, 216, 324, 432, 486, 540, 648, 720}; static const int canonical_ndbps_80_vht[10] = {117, 234, 351, 468, 702, 936, 1053, 1170, 1404, 1560}; float symbol_tx_time, bitrate; if (rflags & FLAGS_CHAN_SHORTGI) symbol_tx_time = 3.6f; else symbol_tx_time = 4.0f; /* * Check for the out of range mcs_index. * Should never happen, but if mcs index is greater than 9 just * return 0. */ if (mcs_index > 9) return 0.0f; if (rflags & FLAGS_CHAN_40MHZ) bitrate = (canonical_ndbps_40_vht[mcs_index] * nss) / symbol_tx_time; else if (rflags & FLAGS_CHAN_80MHZ) bitrate = (canonical_ndbps_80_vht[mcs_index] * nss) / symbol_tx_time; else { if (mcs_index == 9) { /* This is a special case for 20 MHz. */ if (nss == 3) bitrate = 1040 / symbol_tx_time; else if (nss == 6) bitrate = 2080 / symbol_tx_time; else bitrate = 0.0f; } else bitrate = (canonical_ndbps_20_vht[mcs_index] * nss) / symbol_tx_time; } return bitrate; } static gboolean vwr_process_rec_data(FILE_T fh, int rec_size, wtap_rec *record, Buffer *buf, vwr_t *vwr, int IS_TX, int log_mode, int *err, gchar **err_info) { guint8* rec; /* local buffer (holds input record) */ gboolean ret = FALSE; rec = (guint8*)g_malloc(B_SIZE); /* Read over the entire record (frame + trailer) into a local buffer. */ /* If we don't get it all, then declare an error, we can't process the frame. */ if (!wtap_read_bytes(fh, rec, rec_size, err, err_info)) { g_free(rec); return FALSE; } /* now format up the frame data */ switch (vwr->FPGA_VERSION) { case S1_W_FPGA: ret = vwr_read_s1_W_rec(vwr, record, buf, rec, rec_size, err, err_info); break; case S2_W_FPGA: ret = vwr_read_s2_W_rec(vwr, record, buf, rec, rec_size, IS_TX, err, err_info); break; case S3_W_FPGA: ret = vwr_read_s3_W_rec(vwr, record, buf, rec, rec_size, IS_TX, log_mode, err, err_info); break; case vVW510012_E_FPGA: case vVW510024_E_FPGA: ret = vwr_read_rec_data_ethernet(vwr, record, buf, rec, rec_size, IS_TX, err, err_info); break; default: g_free(rec); ws_assert_not_reached(); return ret; } g_free(rec); return ret; } static const struct supported_block_type vwr_80211_blocks_supported[] = { /* * We support packet blocks, with no comments or other options. */ { WTAP_BLOCK_PACKET, MULTIPLE_BLOCKS_SUPPORTED, NO_OPTIONS_SUPPORTED } }; static const struct file_type_subtype_info vwr_80211_info = { "Ixia IxVeriWave .vwr Raw 802.11 Capture", "vwr80211", "vwr", NULL, FALSE, BLOCKS_SUPPORTED(vwr_80211_blocks_supported), NULL, NULL, NULL }; static const struct supported_block_type vwr_eth_blocks_supported[] = { /* * We support packet blocks, with no comments or other options. */ { WTAP_BLOCK_PACKET, MULTIPLE_BLOCKS_SUPPORTED, NO_OPTIONS_SUPPORTED } }; static const struct file_type_subtype_info vwr_eth_info = { "Ixia IxVeriWave .vwr Raw Ethernet Capture", "vwreth", "vwr", NULL, FALSE, BLOCKS_SUPPORTED(vwr_eth_blocks_supported), NULL, NULL, NULL }; void register_vwr(void) { vwr_80211_file_type_subtype = wtap_register_file_type_subtype(&vwr_80211_info); vwr_eth_file_type_subtype = wtap_register_file_type_subtype(&vwr_eth_info); /* * Register names for backwards compatibility with the * wtap_filetypes table in Lua. */ wtap_register_backwards_compatibility_lua_name("VWR_80211", vwr_80211_file_type_subtype); wtap_register_backwards_compatibility_lua_name("VWR_ETH", vwr_eth_file_type_subtype); } /* * Editor modelines - https://www.wireshark.org/tools/modelines.html * * Local variables: * c-basic-offset: 4 * tab-width: 8 * indent-tabs-mode: nil * End: * * vi: set shiftwidth=4 tabstop=8 expandtab: * :indentSize=4:tabSize=8:noTabs=true: */