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wireshark/wiretap/k12.c

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/*
* k12.c
*
* routines for importing tektronix k12xx *.rf5 files
*
* Copyright (c) 2005, Luis E. Garia Ontanon <luis@ontanon.org>
*
* Wiretap Library
* Copyright (c) 1998 by Gilbert Ramirez <gram@alumni.rice.edu>
*
* SPDX-License-Identifier: GPL-2.0-or-later
*/
#include "config.h"
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include "wtap-int.h"
#include "file_wrappers.h"
#include "k12.h"
#include <wsutil/str_util.h>
#include <wsutil/glib-compat.h>
/*
* See
*
* https://www.tek.com/manual/record-file-api-programmer-manual
*
* for some information about the file format. You may have to fill in
* a form to download the document ("Record File API Programmer Manual").
*
* Unfortunately, it describes an API that delivers records from an rf5
* file, not the raw format of an rf5 file, so, while it gives the formats
* of the records with various types, it does not indicate how those records
* are stored in the file.
*/
static int k12_file_type_subtype = -1;
void register_k12(void);
/* #define DEBUG_K12 */
#ifdef DEBUG_K12
#include <stdio.h>
#include <stdarg.h>
#include <wsutil/file_util.h>
FILE* dbg_out = NULL;
char* env_file = NULL;
static unsigned int debug_level = 0;
void k12_fprintf(const char* fmt, ...) {
va_list ap;
va_start(ap,fmt);
vfprintf(dbg_out, fmt, ap);
va_end(ap);
}
#define CAT(a,b) a##b
#define K12_DBG(level,args) do { if (level <= debug_level) { \
fprintf(dbg_out,"%s:%d: ",CAT(__FI,LE__),CAT(__LI,NE__)); \
k12_fprintf args ; \
fprintf(dbg_out,"\n"); \
} } while(0)
void k12_hex_ascii_dump(guint level, gint64 offset, const char* label, const unsigned char* b, unsigned int len) {
static const char* c2t[] = {
"00","01","02","03","04","05","06","07","08","09","0a","0b","0c","0d","0e","0f",
"10","11","12","13","14","15","16","17","18","19","1a","1b","1c","1d","1e","1f",
"20","21","22","23","24","25","26","27","28","29","2a","2b","2c","2d","2e","2f",
"30","31","32","33","34","35","36","37","38","39","3a","3b","3c","3d","3e","3f",
"40","41","42","43","44","45","46","47","48","49","4a","4b","4c","4d","4e","4f",
"50","51","52","53","54","55","56","57","58","59","5a","5b","5c","5d","5e","5f",
"60","61","62","63","64","65","66","67","68","69","6a","6b","6c","6d","6e","6f",
"70","71","72","73","74","75","76","77","78","79","7a","7b","7c","7d","7e","7f",
"80","81","82","83","84","85","86","87","88","89","8a","8b","8c","8d","8e","8f",
"90","91","92","93","94","95","96","97","98","99","9a","9b","9c","9d","9e","9f",
"a0","a1","a2","a3","a4","a5","a6","a7","a8","a9","aa","ab","ac","ad","ae","af",
"b0","b1","b2","b3","b4","b5","b6","b7","b8","b9","ba","bb","bc","bd","be","bf",
"c0","c1","c2","c3","c4","c5","c6","c7","c8","c9","ca","cb","cc","cd","ce","cf",
"d0","d1","d2","d3","d4","d5","d6","d7","d8","d9","da","db","dc","dd","de","df",
"e0","e1","e2","e3","e4","e5","e6","e7","e8","e9","ea","eb","ec","ed","ee","ef",
"f0","f1","f2","f3","f4","f5","f6","f7","f8","f9","fa","fb","fc","fd","fe","ff"
};
unsigned int i, j;
if (debug_level < level) return;
fprintf(dbg_out,"%s(%.8" PRIx64 ",%.4x):\n",label,offset,len);
for (i=0 ; i<len ; i += 16) {
for (j=0; j<16; j++) {
if ((j%4)==0)
fprintf(dbg_out," ");
if ((i+j)<len)
fprintf(dbg_out, "%s", c2t[b[i+j]]);
else
fprintf(dbg_out, " ");
}
fprintf(dbg_out, " ");
for (j=0; j<16; j++) {
if ((i+j)<len)
fprintf(dbg_out, "%c", g_ascii_isprint(b[i+j]) ? b[i+j] : '.');
}
fprintf(dbg_out,"\n");
}
}
#define K12_HEX_ASCII_DUMP(x,a,b,c,d) k12_hex_ascii_dump(x,a,b,c,d)
void k12_ascii_dump(guint level, guint8 *buf, guint32 len, guint32 buf_offset) {
guint32 i;
if (debug_level < level) return;
for (i = buf_offset; i < len; i++) {
if (g_ascii_isprint(buf[i]) || buf[i] == '\n' || buf[i] == '\t')
putc(buf[i], dbg_out);
else if (buf[i] == '\0')
fprintf(dbg_out, "(NUL)\n");
}
}
#define K12_ASCII_DUMP(x,a,b,c) k12_ascii_dump(x,a,b,c)
#else
#define K12_DBG(level,args) (void)0
#define K12_HEX_ASCII_DUMP(x,a,b,c,d)
#define K12_ASCII_DUMP(x,a,b,c)
#endif
/*
* A 32-bit .rf5 file begins with a 512-byte file header, containing:
*
* a 32-bit big-endian file header length, in bytes - always 512 in
* the files we've seen;
*
* 4 unknown bytes, always 0x12 0x05 0x00 0x10;
*
* a 32-bit big-endian file length, giving the total length of the file,
* in bytes;
*
* a 32-bit big-endian number giving the "page size" of the file, in
* bytes, which is normally 8192;
*
* 20 unknown bytes;
*
* a 32-bit count of the number of records in the file;
*
* 4 unknown bytes;
*
* a 32-bit count of the number of records in the file;
*
* 464 unknown bytes;
*
* followed by a sequence of records containing:
*
* a 32-bit big-endian record length;
*
* a 32-bit big-endian record type;
*
* a 32-bit big-endian frame length;
*
* a 32-bit big-endian source ID.
*
* Every 8192 bytes, starting immediately after the 512-byte header,
* there's a 16-byte blob; it's not part of the record data.
* There's no obvious pattern to the data; it might be junk left
* in memory as the file was being written.
*
* There's a 16-bit terminator FFFF at the end.
*
* Older versions of the Wireshark .rf5 writing code incorrectly wrote
* the header - they put 512 in the file length field (counting only the
* header), put a count of records into the "page size" field, and wrote
* out zeroes in the rest of the header. We detect those files by
* checking whether the rest of the header is zero.
*/
/*
* We use the first 8 bytes of the file header as a magic number.
*/
static const guint8 k12_file_magic[] = { 0x00, 0x00, 0x02, 0x00 ,0x12, 0x05, 0x00, 0x10 };
#define K12_FILE_HDR_LEN 512
/*
* Offsets in the file header.
*/
#define K12_FILE_HDR_MAGIC_NUMBER 0x00
#define K12_FILE_HDR_FILE_SIZE 0x08
#define K12_FILE_HDR_PAGE_SIZE 0x0C
#define K12_FILE_HDR_RECORD_COUNT_1 0x24
#define K12_FILE_HDR_RECORD_COUNT_2 0x2C
#define K12_FILE_BLOB_LEN 16
typedef struct {
guint32 file_len;
guint32 num_of_records; /* XXX: not sure about this */
GHashTable* src_by_id; /* k12_srcdsc_recs by input */
GHashTable* src_by_name; /* k12_srcdsc_recs by stack_name */
guint8 *seq_read_buff; /* read buffer for sequential reading */
guint seq_read_buff_len; /* length of that buffer */
guint8 *rand_read_buff; /* read buffer for random reading */
guint rand_read_buff_len; /* length of that buffer */
Buffer extra_info; /* Buffer to hold per packet extra information */
} k12_t;
typedef struct _k12_src_desc_t {
guint32 input;
guint32 input_type;
gchar* input_name;
gchar* stack_file;
k12_input_info_t input_info;
} k12_src_desc_t;
/*
* According to the Tektronix documentation, this value is a combination of
* a "group" code and a "type" code, with both being 2-byte values and
* with the "group" code followe by the "type" code. The "group" values
* are:
*
* 0x0001 - "data event"
* 0x0002 - "text or L1 event"
* 0x0007 - "configuration event"
*
* and the "type" values are:
*
* data events:
* 0x0020 - "frame" (i.e., "an actual packet")
* 0x0021 - "transparent frame"
* 0x0022 - "bit data (TRAU frame)"
* 0x0024 - "used to mark the frame which is a fragment"
* 0x0026 - "used to mark the frame which is a fragment"
* 0x0028 - "used to mark the frame which is generated by the LSA"
* 0x002A - "used to mark the frame which is generated by the LSA"
*
* text or L1 events:
* 0x0030 - "text event"
* 0x0031 - "L1 event"
* 0x0032 - "L1 event (BAI)"
* 0x0033 - "L1 event (VX)"
*
* configuration events:
* 0x0040 - Logical Data Source configuration event
* 0x0041 - Logical Link configuration event
*/
/* so far we've seen these types of records */
#define K12_REC_PACKET 0x00010020 /* an actual packet */
#define K12_REC_D0020 0x000d0020 /* an actual packet, seen in a k18 file */
#define K12_REC_SCENARIO 0x00070040 /* what appears as the window's title */
#define K12_REC_SRCDSC 0x00070041 /* port-stack mapping + more, the key of the whole thing */
#define K12_REC_STK_FILE 0x00070042 /* a dump of an stk file */
#define K12_REC_SRCDSC2 0x00070043 /* another port-stack mapping */
#define K12_REC_TEXT 0x00070044 /* a string containing something with a grammar (conditions/responses?) */
#define K12_REC_START 0x00020030 /* a string containing human readable start time */
#define K12_REC_STOP 0x00020031 /* a string containing human readable stop time */
/*
* According to the Tektronix documentation, packets, i.e. "data events",
* have several different group/type values, which differ in the last
* nibble of the type code. For now, we just mask that nibble off; the
* format of the items are different, so we might have to treat different
* data event types differently.
*/
#define K12_MASK_PACKET 0xfffffff0
/* offsets of elements in the records */
#define K12_RECORD_LEN 0x0 /* uint32, in bytes */
#define K12_RECORD_TYPE 0x4 /* uint32, see above */
#define K12_RECORD_FRAME_LEN 0x8 /* uint32, in bytes */
#define K12_RECORD_SRC_ID 0xc /* uint32 */
/*
* Some records from K15 files have a port ID of an undeclared
* interface which happens to be the only one with the first byte changed.
* It is still unknown how to recognize when this happens.
* If the lookup of the interface record fails we'll mask it
* and retry.
*/
#define K12_RECORD_SRC_ID_MASK 0x00ffffff
/* elements of packet records */
#define K12_PACKET_TIMESTAMP 0x18 /* int64 (8b) representing 1/2us since 01-01-1990 Z00:00:00 */
#define K12_PACKET_FRAME 0x20 /* start of the actual frame in the record */
#define K12_PACKET_FRAME_D0020 0x34 /* start of the actual frame in the record */
#define K12_PACKET_OFFSET_VP 0x08 /* 2 bytes, big endian */
#define K12_PACKET_OFFSET_VC 0x0a /* 2 bytes, big endian */
#define K12_PACKET_OFFSET_CID 0x0c /* 1 byte */
/* elements of the source description records */
#define K12_SRCDESC_COLOR_FOREGROUND 0x12 /* 1 byte */
#define K12_SRCDESC_COLOR_BACKGROUND 0x13 /* 1 byte */
#define K12_SRCDESC_PORT_TYPE 0x1a /* 1 byte */
#define K12_SRCDESC_HWPARTLEN 0x1e /* uint16, big endian */
#define K12_SRCDESC_NAMELEN 0x20 /* uint16, big endian */
#define K12_SRCDESC_STACKLEN 0x22 /* uint16, big endian */
/* Hardware part of the record */
#define K12_SRCDESC_HWPART 0x24 /* offset of the hardware part */
/* Offsets relative to the beginning of the hardware part */
#define K12_SRCDESC_HWPARTTYPE 0 /* uint32, big endian */
#define K12_SRCDESC_DS0_MASK 24 /* variable-length */
#define K12_SRCDESC_ATM_VPI 20 /* uint16, big endian */
#define K12_SRCDESC_ATM_VCI 22 /* uint16, big endian */
#define K12_SRCDESC_ATM_AAL 24 /* 1 byte */
/*
* A "stack file", as appears in a K12_REC_STK_FILE record, is a text
* file (with CR-LF line endings) with a sequence of lines, each of
* which begins with a keyword, and has white-space-separated tokens
* after that.
*
* They appear to be:
*
* STKVER, which is followed by a number (presumably a version number
* for the stack file format)
*
* STACK, which is followed by a quoted string ("ProtocolStack" in one
* file) and two numbers
*
* PATH, which is followed by a non-quoted string giving the pathname
* of the directory containing the stack file
*
* HLAYER, which is followed by a quoted string, a path for something
* (protocol module?), a keyword ("LOADED", in one file), and a
* quoted string giving a description - this is probably a protocol
* layer of some sort
*
* LAYER, which has a similar syntax to HLAYER - the first quoted
* string is a protocol name
*
* RELATION, which has a quoted string giving a protocol name,
* another quoted string giving a protocol name, and a condition
* specifier of some sort, which probably says the second protocol
* is layered atop the first protocol if the condition is true.
* The first protocol can also be "BASE", which means that the
* second protocol is the lowest-level protocol.
* The conditions are:
*
* CPLX, which may mean "complex" - it has parenthesized expressions
* including "&", presumably a boolean AND, with the individual
* tests being L:expr, where L is a letter such as "L", "D", or "P",
* and expr is:
*
* 0x........ for L, where each . is a hex digit or a ?, presumably
* meaning "don't care"
*
* 0;0{=,!=}0b........ for D, where . is presumably a bit or a ?
*
* param=value for P, where param is something such as "src_port"
* and value is a value, presumably to test, for example, TCP or
* UDP ports
*
* UNCOND, presumably meaning "always"
*
* PARAM, followed by a parameter name (as with P:) and a value,
* possibly followed by LAYPARAM and a hex value
*
* DECKRNL, followed by a quoted string protocol name, un-quoted
* "LSBF" or "MSBF" (Least/Most Significant Byte First?), and
* an un-quoted string ending with _DK
*
* LAYPARAM, followed by a quoted protocol name and a number (-2147221504
* in one file, which is 0x80040000)
*
* SPC_CONF, folloed by a number, a quoted string with numbers separated
* by hyphens, and another number
*
* CIC_CONF, with a similar syntax to SPC_CONF
*
* LAYPOS, followed by a protocol name or "BASE" and 3 numbers.
*
* Most of this is probably not useful, but the RELATION lines with
* "BASE" could be used to figure out how to start the dissection
* (if we knew what "L" and "D" did), and *some* of the others might
* be useful if they don't match what's already in various dissector
* tables (the ones for IP and a higher-level protocol, for example,
* aren't very useful, as those are standardized, but the ones for
* TCP, UDP, and SCTP ports, and SCTP PPIs, might be useful).
*/
/*
* get_record: Get the next record into a buffer
* Every 8192 bytes 16 bytes are inserted in the file,
* even in the middle of a record.
* This reads the next record without the eventual 16 bytes.
* returns the length of the record + the stuffing (if any)
*
* Returns number of bytes read on success, 0 on EOF, -1 on error;
* if -1 is returned, *err is set to the error indication and, for
* errors where that's appropriate, *err_info is set to an additional
* error string.
*
* XXX: works at most with 8191 bytes per record
*/
static gint get_record(k12_t *file_data, FILE_T fh, gint64 file_offset,
gboolean is_random, int *err, gchar **err_info) {
guint8 *buffer = is_random ? file_data->rand_read_buff : file_data->seq_read_buff;
guint buffer_len = is_random ? file_data->rand_read_buff_len : file_data->seq_read_buff_len;
guint total_read = 0;
guint left;
guint8* writep;
#ifdef DEBUG_K12
guint actual_len;
#endif
/*
* Where the next unknown 16 bytes are stuffed to the file.
* Following the file header, they appear every 8192 bytes,
* starting right after the file header, so if the file offset
* relative to the file header is a multiple of 8192, the
* 16-byte blob is there.
*/
guint junky_offset = 8192 - (gint) ( (file_offset - K12_FILE_HDR_LEN) % 8192 );
K12_DBG(6,("get_record: ENTER: junky_offset=%" PRId64 ", file_offset=%" PRId64,junky_offset,file_offset));
/* no buffer is given, lets create it */
if (buffer == NULL) {
buffer = (guint8*)g_malloc(8192);
buffer_len = 8192;
if (is_random) {
file_data->rand_read_buff = buffer;
file_data->rand_read_buff_len = buffer_len;
} else {
file_data->seq_read_buff = buffer;
file_data->seq_read_buff_len = buffer_len;
}
}
if ( junky_offset == 8192 ) {
/*
* We're at the beginning of one of the 16-byte blobs,
* so we first need to skip the blob.
*
* XXX - what if the blob is in the middle of the record
* length? If the record length is always a multiple of
* 4 bytes, that won't happen.
*/
if ( ! wtap_read_bytes( fh, NULL, K12_FILE_BLOB_LEN, err, err_info ) )
return -1;
total_read += K12_FILE_BLOB_LEN;
}
/*
* Read the record length.
*/
if ( !wtap_read_bytes( fh, buffer, 4, err, err_info ) )
return -1;
total_read += 4;
left = pntoh32(buffer + K12_RECORD_LEN);
#ifdef DEBUG_K12
actual_len = left;
#endif
junky_offset -= 4;
K12_DBG(5,("get_record: GET length=%u",left));
/*
* Record length must be at least large enough for the length
* and type, hence 8 bytes.
*
* XXX - is WTAP_MAX_PACKET_SIZE_STANDARD the right check for a maximum
* record size? Should we report this error differently?
*/
if (left < 8) {
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: Record length %u is less than 8 bytes long",left);
return -1;
}
if (left > WTAP_MAX_PACKET_SIZE_STANDARD) {
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: Record length %u is greater than the maximum %u",left,WTAP_MAX_PACKET_SIZE_STANDARD);
return -1;
}
/*
* XXX - calculate the lowest power of 2 >= left, rather than just
* looping.
*/
while (left > buffer_len) {
buffer = (guint8*)g_realloc(buffer,buffer_len*=2);
if (is_random) {
file_data->rand_read_buff = buffer;
file_data->rand_read_buff_len = buffer_len;
} else {
file_data->seq_read_buff = buffer;
file_data->seq_read_buff_len = buffer_len;
}
}
writep = buffer + 4;
left -= 4;
/* Read the rest of the record. */
do {
K12_DBG(6,("get_record: looping left=%d junky_offset=%" PRId64,left,junky_offset));
if (junky_offset > left) {
/*
* The next 16-byte blob is past the end of this record.
* Just read the rest of the record.
*/
if ( !wtap_read_bytes( fh, writep, left, err, err_info ) )
return -1;
total_read += left;
break;
} else {
/*
* The next 16-byte blob is part of this record.
* Read up to the blob.
*/
if ( !wtap_read_bytes( fh, writep, junky_offset, err, err_info ) )
return -1;
total_read += junky_offset;
writep += junky_offset;
/*
* Skip the blob.
*/
if ( !wtap_read_bytes( fh, NULL, K12_FILE_BLOB_LEN, err, err_info ) )
return -1;
total_read += K12_FILE_BLOB_LEN;
left -= junky_offset;
junky_offset = 8192;
}
} while(left);
K12_HEX_ASCII_DUMP(5,file_offset, "GOT record", buffer, actual_len);
return total_read;
}
static gboolean
memiszero(const void *ptr, size_t count)
{
const guint8 *p = (const guint8 *)ptr;
while (count != 0) {
if (*p != 0)
return FALSE;
p++;
count--;
}
return TRUE;
}
static gboolean
process_packet_data(wtap_rec *rec, Buffer *target, guint8 *buffer,
guint record_len, k12_t *k12, int *err, gchar **err_info)
{
guint32 type;
guint buffer_offset;
guint64 ts;
guint32 length;
guint32 extra_len;
guint32 src_id;
k12_src_desc_t* src_desc;
type = pntoh32(buffer + K12_RECORD_TYPE);
buffer_offset = (type == K12_REC_D0020) ? K12_PACKET_FRAME_D0020 : K12_PACKET_FRAME;
if (buffer_offset > record_len) {
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: Frame data offset %u > record length %u",
buffer_offset, record_len);
return FALSE;
}
length = pntoh32(buffer + K12_RECORD_FRAME_LEN) & 0x00001FFF;
if (length > record_len - buffer_offset) {
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: Frame length %u > record frame data %u",
length, record_len - buffer_offset);
return FALSE;
}
rec->rec_type = REC_TYPE_PACKET;
rec->block = wtap_block_create(WTAP_BLOCK_PACKET);
rec->presence_flags = WTAP_HAS_TS;
ts = pntoh64(buffer + K12_PACKET_TIMESTAMP);
rec->ts.secs = (time_t) ((ts / 2000000) + 631152000);
rec->ts.nsecs = (guint32) ( (ts % 2000000) * 500 );
rec->rec_header.packet_header.len = rec->rec_header.packet_header.caplen = length;
ws_buffer_assure_space(target, length);
memcpy(ws_buffer_start_ptr(target), buffer + buffer_offset, length);
/* extra information need by some protocols */
extra_len = record_len - buffer_offset - length;
ws_buffer_assure_space(&(k12->extra_info), extra_len);
memcpy(ws_buffer_start_ptr(&(k12->extra_info)),
buffer + buffer_offset + length, extra_len);
rec->rec_header.packet_header.pseudo_header.k12.extra_info = (guint8*)ws_buffer_start_ptr(&(k12->extra_info));
rec->rec_header.packet_header.pseudo_header.k12.extra_length = extra_len;
src_id = pntoh32(buffer + K12_RECORD_SRC_ID);
K12_DBG(5,("process_packet_data: src_id=%.8x",src_id));
rec->rec_header.packet_header.pseudo_header.k12.input = src_id;
if ( ! (src_desc = (k12_src_desc_t*)g_hash_table_lookup(k12->src_by_id,GUINT_TO_POINTER(src_id))) ) {
/*
* Some records from K15 files have a port ID of an undeclared
* interface which happens to be the only one with the first byte changed.
* It is still unknown how to recognize when this happens.
* If the lookup of the interface record fails we'll mask it
* and retry.
*/
src_desc = (k12_src_desc_t*)g_hash_table_lookup(k12->src_by_id,GUINT_TO_POINTER(src_id&K12_RECORD_SRC_ID_MASK));
}
if (src_desc) {
K12_DBG(5,("process_packet_data: input_name='%s' stack_file='%s' type=%x",src_desc->input_name,src_desc->stack_file,src_desc->input_type));
rec->rec_header.packet_header.pseudo_header.k12.input_name = src_desc->input_name;
rec->rec_header.packet_header.pseudo_header.k12.stack_file = src_desc->stack_file;
rec->rec_header.packet_header.pseudo_header.k12.input_type = src_desc->input_type;
switch(src_desc->input_type) {
case K12_PORT_ATMPVC:
if (buffer_offset + length + K12_PACKET_OFFSET_CID < record_len) {
rec->rec_header.packet_header.pseudo_header.k12.input_info.atm.vp = pntoh16(buffer + buffer_offset + length + K12_PACKET_OFFSET_VP);
rec->rec_header.packet_header.pseudo_header.k12.input_info.atm.vc = pntoh16(buffer + buffer_offset + length + K12_PACKET_OFFSET_VC);
rec->rec_header.packet_header.pseudo_header.k12.input_info.atm.cid = *((unsigned char*)(buffer + buffer_offset + length + K12_PACKET_OFFSET_CID));
break;
}
/* Fall through */
default:
memcpy(&(rec->rec_header.packet_header.pseudo_header.k12.input_info),&(src_desc->input_info),sizeof(src_desc->input_info));
break;
}
} else {
K12_DBG(5,("process_packet_data: NO SRC_RECORD FOUND"));
memset(&(rec->rec_header.packet_header.pseudo_header.k12),0,sizeof(rec->rec_header.packet_header.pseudo_header.k12));
rec->rec_header.packet_header.pseudo_header.k12.input_name = "unknown port";
rec->rec_header.packet_header.pseudo_header.k12.stack_file = "unknown stack file";
}
rec->rec_header.packet_header.pseudo_header.k12.input = src_id;
rec->rec_header.packet_header.pseudo_header.k12.stuff = k12;
return TRUE;
}
static gboolean k12_read(wtap *wth, wtap_rec *rec, Buffer *buf, int *err, gchar **err_info, gint64 *data_offset) {
k12_t *k12 = (k12_t *)wth->priv;
k12_src_desc_t* src_desc;
guint8* buffer;
gint64 offset;
gint len;
guint32 type;
guint32 src_id;
offset = file_tell(wth->fh);
/* ignore the record if it isn't a packet */
do {
if ( k12->num_of_records == 0 ) {
/* No more records */
*err = 0;
return FALSE;
}
K12_DBG(5,("k12_read: offset=%i",offset));
*data_offset = offset;
len = get_record(k12, wth->fh, offset, FALSE, err, err_info);
if (len < 0) {
/* read error */
return FALSE;
} else if (len == 0) {
/* EOF */
*err = WTAP_ERR_SHORT_READ;
return FALSE;
} else if (len < K12_RECORD_SRC_ID + 4) {
/* Record not large enough to contain a src ID */
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: Data record length %d too short", len);
return FALSE;
}
k12->num_of_records--;
buffer = k12->seq_read_buff;
type = pntoh32(buffer + K12_RECORD_TYPE);
src_id = pntoh32(buffer + K12_RECORD_SRC_ID);
if ( ! (src_desc = (k12_src_desc_t*)g_hash_table_lookup(k12->src_by_id,GUINT_TO_POINTER(src_id))) ) {
/*
* Some records from K15 files have a port ID of an undeclared
* interface which happens to be the only one with the first byte changed.
* It is still unknown how to recognize when this happens.
* If the lookup of the interface record fails we'll mask it
* and retry.
*/
src_desc = (k12_src_desc_t*)g_hash_table_lookup(k12->src_by_id,GUINT_TO_POINTER(src_id&K12_RECORD_SRC_ID_MASK));
}
K12_DBG(5,("k12_read: record type=%x src_id=%x",type,src_id));
offset += len;
} while ( ((type & K12_MASK_PACKET) != K12_REC_PACKET && (type & K12_MASK_PACKET) != K12_REC_D0020) || !src_id || !src_desc );
return process_packet_data(rec, buf, buffer, (guint)len, k12, err, err_info);
}
static gboolean k12_seek_read(wtap *wth, gint64 seek_off, wtap_rec *rec, Buffer *buf, int *err, gchar **err_info) {
k12_t *k12 = (k12_t *)wth->priv;
guint8* buffer;
gint len;
gboolean status;
K12_DBG(5,("k12_seek_read: ENTER"));
if ( file_seek(wth->random_fh, seek_off, SEEK_SET, err) == -1) {
K12_DBG(5,("k12_seek_read: SEEK ERROR"));
return FALSE;
}
len = get_record(k12, wth->random_fh, seek_off, TRUE, err, err_info);
if (len < 0) {
K12_DBG(5,("k12_seek_read: READ ERROR"));
return FALSE;
} else if (len < K12_RECORD_SRC_ID + 4) {
/* Record not large enough to contain a src ID */
K12_DBG(5,("k12_seek_read: SHORT READ"));
*err = WTAP_ERR_SHORT_READ;
return FALSE;
}
buffer = k12->rand_read_buff;
status = process_packet_data(rec, buf, buffer, (guint)len, k12, err, err_info);
K12_DBG(5,("k12_seek_read: DONE OK"));
return status;
}
static k12_t* new_k12_file_data(void) {
k12_t* fd = g_new(k12_t,1);
fd->file_len = 0;
fd->num_of_records = 0;
fd->src_by_name = g_hash_table_new(g_str_hash,g_str_equal);
fd->src_by_id = g_hash_table_new(g_direct_hash,g_direct_equal);
fd->seq_read_buff = NULL;
fd->seq_read_buff_len = 0;
fd->rand_read_buff = NULL;
fd->rand_read_buff_len = 0;
ws_buffer_init(&(fd->extra_info), 100);
return fd;
}
static gboolean destroy_srcdsc(gpointer k _U_, gpointer v, gpointer p _U_) {
k12_src_desc_t* rec = (k12_src_desc_t*)v;
g_free(rec->input_name);
g_free(rec->stack_file);
g_free(rec);
return TRUE;
}
static void destroy_k12_file_data(k12_t* fd) {
g_hash_table_destroy(fd->src_by_id);
g_hash_table_foreach_remove(fd->src_by_name,destroy_srcdsc,NULL);
g_hash_table_destroy(fd->src_by_name);
ws_buffer_free(&(fd->extra_info));
g_free(fd->seq_read_buff);
g_free(fd->rand_read_buff);
g_free(fd);
}
static void k12_close(wtap *wth) {
k12_t *k12 = (k12_t *)wth->priv;
destroy_k12_file_data(k12);
wth->priv = NULL; /* destroy_k12_file_data freed it */
#ifdef DEBUG_K12
K12_DBG(5,("k12_close: CLOSED"));
if (env_file) fclose(dbg_out);
#endif
}
wtap_open_return_val k12_open(wtap *wth, int *err, gchar **err_info) {
k12_src_desc_t* rec;
guint8 header_buffer[K12_FILE_HDR_LEN];
guint8* read_buffer;
guint32 type;
long offset;
long len;
guint port_type;
guint32 rec_len;
guint32 hwpart_len;
guint32 name_len;
guint32 stack_len;
guint i;
k12_t* file_data;
#ifdef DEBUG_K12
gchar* env_level = getenv("K12_DEBUG_LEVEL");
env_file = getenv("K12_DEBUG_FILENAME");
if ( env_file ) {
dbg_out = ws_fopen(env_file,"w");
if (dbg_out == NULL) {
dbg_out = stderr;
K12_DBG(1,("unable to open K12 DEBUG FILENAME for writing! Logging to standard error"));
}
}
else
dbg_out = stderr;
if ( env_level ) debug_level = (unsigned int)strtoul(env_level,NULL,10);
K12_DBG(1,("k12_open: ENTER debug_level=%u",debug_level));
#endif
if ( !wtap_read_bytes(wth->fh,header_buffer,K12_FILE_HDR_LEN,err,err_info) ) {
K12_DBG(1,("k12_open: FILE HEADER TOO SHORT OR READ ERROR"));
if (*err != WTAP_ERR_SHORT_READ) {
return WTAP_OPEN_ERROR;
}
return WTAP_OPEN_NOT_MINE;
}
if ( memcmp(header_buffer,k12_file_magic,8) != 0 ) {
K12_DBG(1,("k12_open: BAD MAGIC"));
return WTAP_OPEN_NOT_MINE;
}
offset = K12_FILE_HDR_LEN;
file_data = new_k12_file_data();
file_data->file_len = pntoh32( header_buffer + 0x8);
if (memiszero(header_buffer + 0x10, K12_FILE_HDR_LEN - 0x10)) {
/*
* The rest of the file header is all zeroes. That means
* this is a file written by the old Wireshark code, and
* a count of records in the file is at an offset of 0x0C.
*/
file_data->num_of_records = pntoh32( header_buffer + 0x0C );
} else {
/*
* There's at least one non-zero byte in the rest of the
* header. The value 8192 is at 0xC (page size?), and
* what appears to be the number of records in the file
* is at an offset of 0x24 and at an offset of 0x2c.
*
* If the two values are not the same, we fail; if that's
* the case, we need to see the file to figure out which
* of those two values, if any, is the count.
*/
file_data->num_of_records = pntoh32( header_buffer + K12_FILE_HDR_RECORD_COUNT_1 );
if ( file_data->num_of_records != pntoh32( header_buffer + K12_FILE_HDR_RECORD_COUNT_2 ) ) {
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: two different record counts, %u at 0x%02x and %u at 0x%02x",
file_data->num_of_records,
K12_FILE_HDR_RECORD_COUNT_1,
pntoh32( header_buffer + K12_FILE_HDR_RECORD_COUNT_2 ),
K12_FILE_HDR_RECORD_COUNT_2 );
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
}
K12_DBG(5,("k12_open: FILE_HEADER OK: offset=%x file_len=%i records=%i",
offset,
file_data->file_len,
file_data->num_of_records ));
do {
if ( file_data->num_of_records == 0 ) {
*err = WTAP_ERR_SHORT_READ;
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
len = get_record(file_data, wth->fh, offset, FALSE, err, err_info);
if ( len < 0 ) {
K12_DBG(1,("k12_open: BAD HEADER RECORD",len));
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
if ( len == 0 ) {
K12_DBG(1,("k12_open: BAD HEADER RECORD",len));
*err = WTAP_ERR_SHORT_READ;
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
read_buffer = file_data->seq_read_buff;
rec_len = pntoh32( read_buffer + K12_RECORD_LEN );
if (rec_len < K12_RECORD_TYPE + 4) {
/* Record isn't long enough to have a type field */
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: record length %u < %u",
rec_len, K12_RECORD_TYPE + 4);
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
type = pntoh32( read_buffer + K12_RECORD_TYPE );
if ( (type & K12_MASK_PACKET) == K12_REC_PACKET ||
(type & K12_MASK_PACKET) == K12_REC_D0020) {
/*
* we are at the first packet record, rewind and leave.
*/
if (file_seek(wth->fh, offset, SEEK_SET, err) == -1) {
destroy_k12_file_data(file_data);
return WTAP_OPEN_ERROR;
}
K12_DBG(5,("k12_open: FIRST PACKET offset=%x",offset));
break;
}
switch (type) {
case K12_REC_SRCDSC:
case K12_REC_SRCDSC2:
rec = g_new0(k12_src_desc_t,1);
if (rec_len < K12_SRCDESC_HWPART) {
/*
* Record isn't long enough to have the fixed-length portion
* of the source descriptor field.
*/
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: source descriptor record length %u < %u",
rec_len, K12_SRCDESC_HWPART);
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
port_type = read_buffer[K12_SRCDESC_PORT_TYPE];
hwpart_len = pntoh16( read_buffer + K12_SRCDESC_HWPARTLEN );
name_len = pntoh16( read_buffer + K12_SRCDESC_NAMELEN );
stack_len = pntoh16( read_buffer + K12_SRCDESC_STACKLEN );
rec->input = pntoh32( read_buffer + K12_RECORD_SRC_ID );
K12_DBG(5,("k12_open: INTERFACE RECORD offset=%x interface=%x",offset,rec->input));
if (name_len == 0) {
K12_DBG(5,("k12_open: failed (name_len == 0 in source description"));
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_NOT_MINE;
}
if (stack_len == 0) {
K12_DBG(5,("k12_open: failed (stack_len == 0 in source description"));
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_NOT_MINE;
}
if (rec_len < K12_SRCDESC_HWPART + hwpart_len + name_len + stack_len) {
/*
* Record isn't long enough to have the full source descriptor
* field, including the variable-length parts.
*/
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: source descriptor record length %u < %u (%u + %u + %u + %u)",
rec_len,
K12_SRCDESC_HWPART + hwpart_len + name_len + stack_len,
K12_SRCDESC_HWPART, hwpart_len, name_len, stack_len);
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
if (hwpart_len) {
if (hwpart_len < 4) {
/* Hardware part isn't long enough to have a type field */
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: source descriptor hardware part length %u < 4",
hwpart_len);
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
switch(( rec->input_type = pntoh32( read_buffer + K12_SRCDESC_HWPART + K12_SRCDESC_HWPARTTYPE ) )) {
case K12_PORT_DS0S:
/* This appears to be variable-length */
rec->input_info.ds0mask = 0x00000000;
if (hwpart_len > K12_SRCDESC_DS0_MASK) {
for (i = 0; i < hwpart_len - K12_SRCDESC_DS0_MASK; i++) {
rec->input_info.ds0mask |= ( *(read_buffer + K12_SRCDESC_HWPART + K12_SRCDESC_DS0_MASK + i) == 0xff ) ? 1U<<(31-i) : 0x0;
}
}
break;
case K12_PORT_ATMPVC:
if (hwpart_len < K12_SRCDESC_ATM_VCI + 2) {
/* Hardware part isn't long enough to have ATM information */
*err = WTAP_ERR_BAD_FILE;
*err_info = ws_strdup_printf("k12: source descriptor hardware part length %u < %u",
hwpart_len,
K12_SRCDESC_ATM_VCI + 2);
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
rec->input_info.atm.vp = pntoh16( read_buffer + K12_SRCDESC_HWPART + K12_SRCDESC_ATM_VPI );
rec->input_info.atm.vc = pntoh16( read_buffer + K12_SRCDESC_HWPART + K12_SRCDESC_ATM_VCI );
break;
default:
break;
}
} else {
/* Record viewer generated files don't have this information */
if (port_type >= 0x14
&& port_type <= 0x17) {
/* For ATM2_E1DS1, ATM2_E3DS3,
ATM2_STM1EL and ATM2_STM1OP */
rec->input_type = K12_PORT_ATMPVC;
rec->input_info.atm.vp = 0;
rec->input_info.atm.vc = 0;
}
}
if (read_buffer[K12_SRCDESC_HWPART + hwpart_len + name_len - 1] != '\0') {
*err = WTAP_ERR_BAD_FILE;
*err_info = g_strdup("k12_open: source descriptor record contains non-null-terminated link-layer name");
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
if (read_buffer[K12_SRCDESC_HWPART + hwpart_len + name_len + stack_len - 1] != '\0') {
*err = WTAP_ERR_BAD_FILE;
*err_info = g_strdup("k12_open: source descriptor record contains non-null-terminated stack path");
destroy_k12_file_data(file_data);
g_free(rec);
return WTAP_OPEN_ERROR;
}
rec->input_name = (gchar *)g_memdup2(read_buffer + K12_SRCDESC_HWPART + hwpart_len, name_len);
rec->stack_file = (gchar *)g_memdup2(read_buffer + K12_SRCDESC_HWPART + hwpart_len + name_len, stack_len);
ascii_strdown_inplace (rec->stack_file);
g_hash_table_insert(file_data->src_by_id,GUINT_TO_POINTER(rec->input),rec);
g_hash_table_insert(file_data->src_by_name,rec->stack_file,rec);
break;
case K12_REC_STK_FILE:
K12_DBG(1,("k12_open: K12_REC_STK_FILE"));
K12_DBG(1,("Field 1: 0x%08x",pntoh32( read_buffer + 0x08 )));
K12_DBG(1,("Field 2: 0x%08x",pntoh32( read_buffer + 0x0c )));
K12_ASCII_DUMP(1, read_buffer, rec_len, 16);
break;
default:
K12_DBG(1,("k12_open: RECORD TYPE 0x%08x",type));
break;
}
offset += len;
file_data->num_of_records--;
} while(1);
wth->file_type_subtype = k12_file_type_subtype;
wth->file_encap = WTAP_ENCAP_K12;
wth->snapshot_length = 0;
wth->subtype_read = k12_read;
wth->subtype_seek_read = k12_seek_read;
wth->subtype_close = k12_close;
wth->priv = (void *)file_data;
wth->file_tsprec = WTAP_TSPREC_NSEC;
/*
* 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;
}
typedef struct {
guint32 file_len;
guint32 num_of_records;
guint32 file_offset;
} k12_dump_t;
static int k12_dump_can_write_encap(int encap) {
if (encap == WTAP_ENCAP_PER_PACKET)
return WTAP_ERR_ENCAP_PER_PACKET_UNSUPPORTED;
if (encap != WTAP_ENCAP_K12)
return WTAP_ERR_UNWRITABLE_ENCAP;
return 0;
}
static const gchar dumpy_junk[] = { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 };
static gboolean k12_dump_record(wtap_dumper *wdh, guint32 len, guint8* buffer, int *err_p) {
k12_dump_t *k12 = (k12_dump_t *)wdh->priv;
guint32 junky_offset = (8192 - ( (k12->file_offset - K12_FILE_HDR_LEN) % 8192 )) % 8192;
if (len > junky_offset) {
if (junky_offset) {
if (! wtap_dump_file_write(wdh, buffer, junky_offset, err_p))
return FALSE;
}
if (! wtap_dump_file_write(wdh, dumpy_junk, K12_FILE_BLOB_LEN, err_p))
return FALSE;
if (! wtap_dump_file_write(wdh, buffer+junky_offset, len - junky_offset, err_p))
return FALSE;
k12->file_offset += len + K12_FILE_BLOB_LEN;
k12->file_len += len + K12_FILE_BLOB_LEN;
} else {
if (! wtap_dump_file_write(wdh, buffer, len, err_p))
return FALSE;
k12->file_offset += len;
k12->file_len += len;
}
k12->num_of_records++;
return TRUE;
}
static void k12_dump_src_setting(gpointer k _U_, gpointer v, gpointer p) {
k12_src_desc_t* src_desc = (k12_src_desc_t*)v;
wtap_dumper *wdh = (wtap_dumper *)p;
guint32 len;
guint offset;
guint i;
int errxxx; /* dummy */
union {
guint8 buffer[8192];
struct {
guint32 len;
guint32 type;
guint32 unk32_1;
guint32 input;
guint16 unk32_2;
guint16 color;
guint32 unk32_3;
guint32 unk32_4;
guint16 unk16_1;
guint16 hwpart_len;
guint16 name_len;
guint16 stack_len;
struct {
guint32 type;
union {
struct {
guint32 unk32;
guint8 mask[32];
} ds0mask;
struct {
guint8 unk_data[16];
guint16 vp;
guint16 vc;
} atm;
guint32 unk;
} desc;
} extra;
} record;
} obj;
obj.record.type = g_htonl(K12_REC_SRCDSC);
obj.record.unk32_1 = g_htonl(0x00000001);
obj.record.input = g_htonl(src_desc->input);
obj.record.unk32_2 = g_htons(0x0000);
obj.record.color = g_htons(0x060f);
obj.record.unk32_3 = g_htonl(0x00000003);
switch (src_desc->input_type) {
case K12_PORT_ATMPVC:
obj.record.unk32_4 = g_htonl(0x01001400);
break;
default:
obj.record.unk32_4 = g_htonl(0x01000100);
}
obj.record.unk16_1 = g_htons(0x0000);
obj.record.name_len = (guint16) strlen(src_desc->input_name) + 1;
obj.record.stack_len = (guint16) strlen(src_desc->stack_file) + 1;
obj.record.extra.type = g_htonl(src_desc->input_type);
switch (src_desc->input_type) {
case K12_PORT_ATMPVC:
obj.record.hwpart_len = g_htons(0x18);
obj.record.extra.desc.atm.vp = g_htons(src_desc->input_info.atm.vp);
obj.record.extra.desc.atm.vc = g_htons(src_desc->input_info.atm.vc);
offset = 0x3c;
break;
case K12_PORT_DS0S:
obj.record.hwpart_len = g_htons(0x18);
for( i=0; i<32; i++ ) {
obj.record.extra.desc.ds0mask.mask[i] =
(src_desc->input_info.ds0mask & (1UL << i)) ? 0xff : 0x00;
}
offset = 0x3c;
break;
default:
obj.record.hwpart_len = g_htons(0x08);
offset = 0x2c;
break;
}
memcpy(obj.buffer + offset,
src_desc->input_name,
obj.record.name_len);
memcpy(obj.buffer + offset + obj.record.name_len,
src_desc->stack_file,
obj.record.stack_len);
len = offset + obj.record.name_len + obj.record.stack_len;
len += (len % 4) ? 4 - (len % 4) : 0;
obj.record.len = g_htonl(len);
obj.record.name_len = g_htons(obj.record.name_len);
obj.record.stack_len = g_htons(obj.record.stack_len);
k12_dump_record(wdh,len,obj.buffer, &errxxx); /* fwrite errs ignored: see k12_dump below */
}
static gboolean k12_dump(wtap_dumper *wdh, const wtap_rec *rec,
const guint8 *pd, int *err, gchar **err_info _U_) {
const union wtap_pseudo_header *pseudo_header = &rec->rec_header.packet_header.pseudo_header;
k12_dump_t *k12 = (k12_dump_t *)wdh->priv;
guint32 len;
union {
guint8 buffer[8192];
struct {
guint32 len;
guint32 type;
guint32 frame_len;
guint32 input;
guint32 datum_1;
guint32 datum_2;
guint64 ts;
guint8 frame[0x1fc0];
} record;
} obj;
/* We can only write packet records. */
if (rec->rec_type != REC_TYPE_PACKET) {
*err = WTAP_ERR_UNWRITABLE_REC_TYPE;
return FALSE;
}
/*
* Make sure this packet doesn't have a link-layer type that
* differs from the one for the file.
*/
if (wdh->encap != rec->rec_header.packet_header.pkt_encap) {
*err = WTAP_ERR_ENCAP_PER_PACKET_UNSUPPORTED;
return FALSE;
}
if (k12->num_of_records == 0) {
k12_t* file_data = (k12_t*)pseudo_header->k12.stuff;
/* XXX: We'll assume that any fwrite errors in k12_dump_src_setting will */
/* repeat during the final k12_dump_record at the end of k12_dump */
/* (and thus cause an error return from k12_dump). */
/* (I don't see a reasonably clean way to handle any fwrite errors */
/* encountered in k12_dump_src_setting). */
g_hash_table_foreach(file_data->src_by_id,k12_dump_src_setting,wdh);
}
obj.record.len = 0x20 + rec->rec_header.packet_header.caplen;
obj.record.len += (obj.record.len % 4) ? 4 - obj.record.len % 4 : 0;
len = obj.record.len;
obj.record.len = g_htonl(obj.record.len);
obj.record.type = g_htonl(K12_REC_PACKET);
obj.record.frame_len = g_htonl(rec->rec_header.packet_header.caplen);
obj.record.input = g_htonl(pseudo_header->k12.input);
obj.record.ts = GUINT64_TO_BE((((guint64)rec->ts.secs - 631152000) * 2000000) + (rec->ts.nsecs / 1000 * 2));
memcpy(obj.record.frame,pd,rec->rec_header.packet_header.caplen);
return k12_dump_record(wdh,len,obj.buffer, err);
}
static const guint8 k12_eof[] = {0xff,0xff};
static gboolean k12_dump_finish(wtap_dumper *wdh, int *err, gchar **err_info _U_) {
k12_dump_t *k12 = (k12_dump_t *)wdh->priv;
union {
guint8 b[sizeof(guint32)];
guint32 u;
} d;
if (! wtap_dump_file_write(wdh, k12_eof, 2, err))
return FALSE;
k12->file_len += 2;
if (wtap_dump_file_seek(wdh, K12_FILE_HDR_FILE_SIZE, SEEK_SET, err) == -1)
return FALSE;
d.u = g_htonl(k12->file_len);
if (! wtap_dump_file_write(wdh, d.b, 4, err))
return FALSE;
if (wtap_dump_file_seek(wdh, K12_FILE_HDR_PAGE_SIZE, SEEK_SET, err) == -1)
return FALSE;
d.u = g_htonl(8192);
if (! wtap_dump_file_write(wdh, d.b, 4, err))
return FALSE;
if (wtap_dump_file_seek(wdh, K12_FILE_HDR_RECORD_COUNT_1, SEEK_SET, err) == -1)
return FALSE;
d.u = g_htonl(k12->num_of_records);
if (! wtap_dump_file_write(wdh, d.b, 4, err))
return FALSE;
if (wtap_dump_file_seek(wdh, K12_FILE_HDR_RECORD_COUNT_2, SEEK_SET, err) == -1)
return FALSE;
d.u = g_htonl(k12->num_of_records);
if (! wtap_dump_file_write(wdh, d.b, 4, err))
return FALSE;
return TRUE;
}
static gboolean k12_dump_open(wtap_dumper *wdh, int *err, gchar **err_info _U_) {
k12_dump_t *k12;
if ( ! wtap_dump_file_write(wdh, k12_file_magic, 8, err)) {
return FALSE;
}
if (wtap_dump_file_seek(wdh, K12_FILE_HDR_LEN, SEEK_SET, err) == -1)
return FALSE;
wdh->subtype_write = k12_dump;
wdh->subtype_finish = k12_dump_finish;
k12 = g_new(k12_dump_t, 1);
wdh->priv = (void *)k12;
k12->file_len = K12_FILE_HDR_LEN;
k12->num_of_records = 0;
k12->file_offset = K12_FILE_HDR_LEN;
return TRUE;
}
static const struct supported_block_type k12_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 k12_info = {
"Tektronix K12xx 32-bit .rf5 format", "rf5", "rf5", NULL,
TRUE, BLOCKS_SUPPORTED(k12_blocks_supported),
k12_dump_can_write_encap, k12_dump_open, NULL
};
void register_k12(void)
{
k12_file_type_subtype = wtap_register_file_type_subtype(&k12_info);
/*
* Register name for backwards compatibility with the
* wtap_filetypes table in Lua.
*/
wtap_register_backwards_compatibility_lua_name("K12",
k12_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:
*/
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