direwolf/src/xid.c

838 lines
25 KiB
C

//
// This file is part of Dire Wolf, an amateur radio packet TNC.
//
// Copyright (C) 2014, 2016, 2017 John Langner, WB2OSZ
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 2 of the License, or
// (at your option) any later version.
//
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
/*------------------------------------------------------------------
*
* Module: xid.c
*
* Purpose: Encode and decode the info field of XID frames.
*
* Description: If we originate the connection, and the other end is
* capable of AX.25 version 2.2,
*
* - We send an XID command frame with our capabilities.
* - the other sends back an XID response, possibly
* reducing some values to be acceptable there.
* - Both ends use the values in that response.
*
* If the other end originates the connection,
*
* - It sends XID command frame with its capabilities.
* - We might decrease some of them to be acceptable.
* - Send XID response.
* - Both ends use values in my response.
*
* References: AX.25 Protocol Spec, sections 4.3.3.7 & 6.3.2.
*
*---------------------------------------------------------------*/
#include "direwolf.h"
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <stdio.h>
#include <unistd.h>
#include "textcolor.h"
#include "xid.h"
#define FI_Format_Indicator 0x82
#define GI_Group_Identifier 0x80
#define PI_Classes_of_Procedures 2
#define PI_HDLC_Optional_Functions 3
#define PI_I_Field_Length_Rx 6
#define PI_Window_Size_Rx 8
#define PI_Ack_Timer 9
#define PI_Retries 10
// Forget about the bit order at the physical layer (e.g. HDLC).
// It doesn't matter at all here. We are dealing with bytes.
// A different encoding could send the bits in the opposite order.
// The bit numbers are confusing because this one table (Fig. 4.5) starts
// with 1 for the LSB when everywhere else refers to the LSB as bit 0.
// The first byte must be of the form 0xx0 0001
// The second byte must be of the form 0000 0000
// If we process the two byte "Classes of Procedures" like
// the other multibyte numeric fields, with the more significant
// byte first, we end up with the bit masks below.
// The bit order would be 8 7 6 5 4 3 2 1 16 15 14 13 12 11 10 9
// (This has nothing to do with the HDLC serializing order.
// I'm talking about the way we would normally write binary numbers.)
#define PV_Classes_Procedures_Balanced_ABM 0x0100
#define PV_Classes_Procedures_Half_Duplex 0x2000
#define PV_Classes_Procedures_Full_Duplex 0x4000
// The first byte must be of the form 1000 0xx0
// The second byte must be of the form 1010 xx00
// The third byte must be of the form 0000 0010
// If we process the three byte "HDLC Optional Parmeters" like
// the other multibyte numeric fields, with the most significant
// byte first, we end up with bit masks like this.
// The bit order would be 8 7 6 5 4 3 2 1 16 15 14 13 12 11 10 9 24 23 22 21 20 19 18 17
#define PV_HDLC_Optional_Functions_REJ_cmd_resp 0x020000
#define PV_HDLC_Optional_Functions_SREJ_cmd_resp 0x040000
#define PV_HDLC_Optional_Functions_Extended_Address 0x800000
#define PV_HDLC_Optional_Functions_Modulo_8 0x000400
#define PV_HDLC_Optional_Functions_Modulo_128 0x000800
#define PV_HDLC_Optional_Functions_TEST_cmd_resp 0x002000
#define PV_HDLC_Optional_Functions_16_bit_FCS 0x008000
#define PV_HDLC_Optional_Functions_Multi_SREJ_cmd_resp 0x000020
#define PV_HDLC_Optional_Functions_Segmenter 0x000040
#define PV_HDLC_Optional_Functions_Synchronous_Tx 0x000002
/*-------------------------------------------------------------------
*
* Name: xid_parse
*
* Purpose: Decode information part of XID frame into individual values.
*
* Inputs: info - pointer to information part of frame.
*
* info_len - Number of bytes in information part of frame.
* Could be 0.
*
* desc_size - Size of desc. 100 is good.
*
* Outputs: result - Structure with extracted values.
*
* desc - Text description for troubleshooting.
*
* Returns: 1 for mostly successful (with possible error messages), 0 for failure.
*
* Description: 6.3.2 "The receipt of an XID response from the other station
* establishes that both stations are using AX.25 version
* 2.2 or higher and enables the use of the segmenter/reassembler
* and selective reject."
*
*--------------------------------------------------------------------*/
int xid_parse (unsigned char *info, int info_len, struct xid_param_s *result, char *desc, int desc_size)
{
unsigned char *p;
int group_len;
char stemp[64];
strlcpy (desc, "", desc_size);
// What should we do when some fields are missing?
// The AX.25 v2.2 protocol spec says, for most of these,
// "If this field is not present, the current values are retained."
// We set the numeric values to our usual G_UNKNOWN to mean undefined and let the caller deal with it.
// rej and modulo are enum so we can't use G_UNKNOWN there.
result->full_duplex = G_UNKNOWN;
result->srej = srej_not_specified;
result->modulo = modulo_unknown;
result->i_field_length_rx = G_UNKNOWN;
result->window_size_rx = G_UNKNOWN;
result->ack_timer = G_UNKNOWN;
result->retries = G_UNKNOWN;
/* Information field is optional but that seems pretty lame. */
if (info_len == 0) {
return (1);
}
p = info;
if (*p != FI_Format_Indicator) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: First byte of info field should be Format Indicator, %02x.\n", FI_Format_Indicator);
dw_printf ("XID info part: %02x %02x %02x %02x %02x ... length=%d\n", info[0], info[1], info[2], info[3], info[4], info_len);
return 0;
}
p++;
if (*p != GI_Group_Identifier) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Second byte of info field should be Group Indicator, %d.\n", GI_Group_Identifier);
return 0;
}
p++;
group_len = *p++;
group_len = (group_len << 8) + *p++;
while (p < info + 4 + group_len) {
int pind, plen, pval, j;
pind = *p++;
plen = *p++; // should have sanity checking
if (plen < 1 || plen > 4) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Length ????? TODO ???? %d.\n", plen);
return (1); // got this far.
}
pval = 0;
for (j=0; j<plen; j++) {
pval = (pval << 8) + *p++;
}
switch (pind) {
case PI_Classes_of_Procedures:
if ( ! (pval & PV_Classes_Procedures_Balanced_ABM)) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected Balanced ABM to be set.\n");
}
if (pval & PV_Classes_Procedures_Half_Duplex && ! (pval & PV_Classes_Procedures_Full_Duplex)) {
result->full_duplex = 0;
strlcat (desc, "Half-Duplex ", desc_size);
}
else if (pval & PV_Classes_Procedures_Full_Duplex && ! (pval & PV_Classes_Procedures_Half_Duplex)) {
result->full_duplex = 1;
strlcat (desc, "Full-Duplex ", desc_size);
}
else {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected one of Half or Full Duplex be set.\n");
result->full_duplex = 0;
}
break;
case PI_HDLC_Optional_Functions:
// Pick highest of those offered.
if (pval & PV_HDLC_Optional_Functions_REJ_cmd_resp) {
strlcat (desc, "REJ ", desc_size);
}
if (pval & PV_HDLC_Optional_Functions_SREJ_cmd_resp) {
strlcat (desc, "SREJ ", desc_size);
}
if (pval & PV_HDLC_Optional_Functions_Multi_SREJ_cmd_resp) {
strlcat (desc, "Multi-SREJ ", desc_size);
}
if (pval & PV_HDLC_Optional_Functions_Multi_SREJ_cmd_resp) {
result->srej = srej_multi;
}
else if (pval & PV_HDLC_Optional_Functions_SREJ_cmd_resp) {
result->srej = srej_single;
}
else if (pval & PV_HDLC_Optional_Functions_REJ_cmd_resp) {
result->srej = srej_none;
}
else {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected at least one of REJ, SREJ, Multi-SREJ to be set.\n");
result->srej = srej_none;
}
if ((pval & PV_HDLC_Optional_Functions_Modulo_8) && ! (pval & PV_HDLC_Optional_Functions_Modulo_128)) {
result->modulo = modulo_8;
strlcat (desc, "modulo-8 ", desc_size);
}
else if ((pval & PV_HDLC_Optional_Functions_Modulo_128) && ! (pval & PV_HDLC_Optional_Functions_Modulo_8)) {
result->modulo = modulo_128;
strlcat (desc, "modulo-128 ", desc_size);
}
else {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected one of Modulo 8 or 128 be set.\n");
}
if ( ! (pval & PV_HDLC_Optional_Functions_Extended_Address)) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected Extended Address to be set.\n");
}
if ( ! (pval & PV_HDLC_Optional_Functions_TEST_cmd_resp)) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected TEST cmd/resp to be set.\n");
}
if ( ! (pval & PV_HDLC_Optional_Functions_16_bit_FCS)) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected 16 bit FCS to be set.\n");
}
if ( ! (pval & PV_HDLC_Optional_Functions_Synchronous_Tx)) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Expected Synchronous Tx to be set.\n");
}
break;
case PI_I_Field_Length_Rx:
result->i_field_length_rx = pval / 8;
snprintf (stemp, sizeof(stemp), "I-Field-Length-Rx=%d ", result->i_field_length_rx);
strlcat (desc, stemp, desc_size);
if (pval & 0x7) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: I Field Length Rx, %d, is not a whole number of bytes.\n", pval);
}
break;
case PI_Window_Size_Rx:
result->window_size_rx = pval;
snprintf (stemp, sizeof(stemp), "Window-Size-Rx=%d ", result->window_size_rx);
strlcat (desc, stemp, desc_size);
if (pval < 1 || pval > 127) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Window Size Rx, %d, is not in range of 1 thru 127.\n", pval);
result->window_size_rx = 127;
// Let the caller deal with modulo 8 consideration.
}
//continue here with more error checking.
break;
case PI_Ack_Timer:
result->ack_timer = pval;
snprintf (stemp, sizeof(stemp), "Ack-Timer=%d ", result->ack_timer);
strlcat (desc, stemp, desc_size);
break;
case PI_Retries: // Is it retrys or retries?
result->retries = pval;
snprintf (stemp, sizeof(stemp), "Retries=%d ", result->retries);
strlcat (desc, stemp, desc_size);
break;
default:
break; // Ignore anything we don't recognize.
}
}
if (p != info + info_len) {
text_color_set (DW_COLOR_ERROR);
dw_printf ("XID error: Frame / Group Length mismatch.\n");
}
return (1);
} /* end xid_parse */
/*-------------------------------------------------------------------
*
* Name: xid_encode
*
* Purpose: Encode the information part of an XID frame.
*
* Inputs: param->
* full_duplex - As command, am I capable of full duplex operation?
* When a response, are we both?
* 0 = half duplex.
* 1 = full duplex.
*
* srej - Level of selective reject.
* srej_none (use REJ), srej_single, srej_multi
* As command, offer a menu of what I can handle. (i.e. perhaps multiple bits set)
* As response, take minimum of what is offered and what I can handle. (one bit set)
*
* modulo - 8 or 128.
*
* i_field_length_rx - Maximum number of bytes I can handle in info part.
* Default is 256.
* Up to 8191 will fit into the field.
* Use G_UNKNOWN to omit this.
*
* window_size_rx - Maximum window size ("k") that I can handle.
* Defaults are are 4 for modulo 8 and 32 for modulo 128.
*
* ack_timer - Acknowledge timer in milliseconds.
* *** describe meaning. ***
* Default is 3000.
* Use G_UNKNOWN to omit this.
*
* retries - Allows negotiation of retries.
* Default is 10.
* Use G_UNKNOWN to omit this.
*
* cr - Is it a command or response?
*
* Outputs: info - Information part of XID frame.
* Does not include the control byte.
* Use buffer of 40 bytes just to be safe.
*
* Returns: Number of bytes in the info part. Should be at most 27.
* Again, provide a larger space just to be safe in case this ever changes.
*
* Description: 6.3.2 "Parameter negotiation occurs at any time. It is accomplished by sending
* the XID command frame and receiving the XID response frame. Implementations of
* AX.25 prior to version 2.2 respond to an XID command frame with a FRMR response
* frame. The TNC receiving the FRMR uses a default set of parameters compatible
* with previous versions of AX.25."
*
* "This version of AX.25 implements the negotiation or notification of six AX.25
* parameters. Notification simply tells the distant TNC some limit that cannot be exceeded.
* The distant TNC can choose to use the limit or some other value that is within the
* limits. Notification is used with the Window Size Receive (k) and Information
* Field Length Receive (N1) parameters. Negotiation involves both TNCs choosing a
* value that is mutually acceptable. The XID command frame contains a set of values
* acceptable to the originating TNC. The distant TNC chooses to accept the values
* offered, or other acceptable values, and places these values in the XID response.
* Both TNCs set themselves up based on the values used in the XID response. Negotiation
* is used by Classes of Procedures, HDLC Optional Functions, Acknowledge Timer and Retries."
*
* Comment: I have a problem with "... occurs at any time." What if we were in the middle
* of transferring a large file with k=32 then along comes XID which says switch to modulo 8?
*
* Insight: Or is it Erratum?
* After reading the base standards documents, it seems that the XID command should offer
* up a menu of all the acceptable choices. e.g. REJ, SREJ, Multi-SREJ. One or more bits
* can be set. The XID response, would set a single bit which is the desired choice from
* among those offered.
* Should go back and review half/full duplex and modulo.
*
*--------------------------------------------------------------------*/
int xid_encode (struct xid_param_s *param, unsigned char *info, cmdres_t cr)
{
unsigned char *p;
int len;
int x;
int m = 0;
p = info;
*p++ = FI_Format_Indicator;
*p++ = GI_Group_Identifier;
*p++ = 0;
m = 4; // classes of procedures
m += 5; // HDLC optional features
if (param->i_field_length_rx != G_UNKNOWN) m += 4;
if (param->window_size_rx != G_UNKNOWN) m += 3;
if (param->ack_timer != G_UNKNOWN) m += 4;
if (param->retries != G_UNKNOWN) m += 3;
*p++ = m; // 0x17 if all present.
// "Classes of Procedures" has half / full duplex.
// We always send this.
*p++ = PI_Classes_of_Procedures;
*p++ = 2;
x = PV_Classes_Procedures_Balanced_ABM;
if (param->full_duplex == 1)
x |= PV_Classes_Procedures_Full_Duplex;
else // includes G_UNKNOWN
x |= PV_Classes_Procedures_Half_Duplex;
*p++ = (x >> 8) & 0xff;
*p++ = x & 0xff;
// "HDLC Optional Functions" contains REJ/SREJ & modulo 8/128.
// We always send this.
// Watch out for unknown values and do something reasonable.
*p++ = PI_HDLC_Optional_Functions;
*p++ = 3;
x = PV_HDLC_Optional_Functions_Extended_Address |
PV_HDLC_Optional_Functions_TEST_cmd_resp |
PV_HDLC_Optional_Functions_16_bit_FCS |
PV_HDLC_Optional_Functions_Synchronous_Tx;
//text_color_set (DW_COLOR_ERROR);
//dw_printf ("****** XID temp hack - test no SREJ ******\n");
// param->srej = srej_none;
if (cr == cr_cmd) {
// offer a "menu" of acceptable choices. i.e. 1, 2 or 3 bits set.
switch (param->srej) {
case srej_none:
default:
x |= PV_HDLC_Optional_Functions_REJ_cmd_resp;
break;
case srej_single:
x |= PV_HDLC_Optional_Functions_REJ_cmd_resp |
PV_HDLC_Optional_Functions_SREJ_cmd_resp;
break;
case srej_multi:
x |= PV_HDLC_Optional_Functions_REJ_cmd_resp |
PV_HDLC_Optional_Functions_SREJ_cmd_resp |
PV_HDLC_Optional_Functions_Multi_SREJ_cmd_resp;
break;
}
}
else {
// for response, set only a single bit.
switch (param->srej) {
case srej_none:
default:
x |= PV_HDLC_Optional_Functions_REJ_cmd_resp;
break;
case srej_single:
x |= PV_HDLC_Optional_Functions_SREJ_cmd_resp;
break;
case srej_multi:
x |= PV_HDLC_Optional_Functions_Multi_SREJ_cmd_resp;
break;
}
}
if (param->modulo == modulo_128)
x |= PV_HDLC_Optional_Functions_Modulo_128;
else // includes modulo_8 and modulo_unknown
x |= PV_HDLC_Optional_Functions_Modulo_8;
*p++ = (x >> 16) & 0xff;
*p++ = (x >> 8) & 0xff;
*p++ = x & 0xff;
// The rest are skipped if undefined values.
// "I Field Length Rx" - max I field length acceptable to me.
// This is in bits. 8191 would be max number of bytes to fit in field.
if (param->i_field_length_rx != G_UNKNOWN) {
*p++ = PI_I_Field_Length_Rx;
*p++ = 2;
x = param->i_field_length_rx * 8;
*p++ = (x >> 8) & 0xff;
*p++ = x & 0xff;
}
// "Window Size Rx"
if (param->window_size_rx != G_UNKNOWN) {
*p++ = PI_Window_Size_Rx;
*p++ = 1;
*p++ = param->window_size_rx;
}
// "Ack Timer" milliseconds. We could handle up to 65535 here.
if (param->ack_timer != G_UNKNOWN) {
*p++ = PI_Ack_Timer;
*p++ = 2;
*p++ = (param->ack_timer >> 8) & 0xff;
*p++ = param->ack_timer & 0xff;
}
// "Retries."
if (param->retries != G_UNKNOWN) {
*p++ = PI_Retries;
*p++ = 1;
*p++ = param->retries;
}
len = p - info;
return (len);
} /* end xid_encode */
/*-------------------------------------------------------------------
*
* Name: main
*
* Purpose: Unit test for other functions here.
*
* Description: Run with:
*
* gcc -DXIDTEST -g xid.c textcolor.o && ./a
*
* Result should be:
*
* XID test: Success.
*
* with no error messages.
*
*--------------------------------------------------------------------*/
#if XIDTEST
/* From Figure 4.6. Typical XID frame, from AX.25 protocol spec, v. 2.2 */
/* This is the info part after a control byte of 0xAF. */
static unsigned char example[27] = {
/* FI */ 0x82, /* Format indicator */
/* GI */ 0x80, /* Group Identifier - parameter negotiation */
/* GL */ 0x00, /* Group length - all of the PI/PL/PV fields */
/* GL */ 0x17, /* (2 bytes) */
/* PI */ 0x02, /* Parameter Indicator - classes of procedures */
/* PL */ 0x02, /* Parameter Length */
#if 0 // Erratum: Example in the protocol spec looks wrong.
/* PV */ 0x00, /* Parameter Variable - Half Duplex, Async, Balanced Mode */
/* PV */ 0x20, /* */
#else // I think it should be like this instead.
/* PV */ 0x21, /* Parameter Variable - Half Duplex, Async, Balanced Mode */
/* PV */ 0x00, /* Reserved */
#endif
/* PI */ 0x03, /* Parameter Indicator - optional functions */
/* PL */ 0x03, /* Parameter Length */
/* PV */ 0x86, /* Parameter Variable - SREJ/REJ, extended addr */
/* PV */ 0xA8, /* 16-bit FCS, TEST cmd/resp, Modulo 128 */
/* PV */ 0x02, /* synchronous transmit */
/* PI */ 0x06, /* Parameter Indicator - Rx I field length (bits) */
/* PL */ 0x02, /* Parameter Length */
// Erratum: The text does not say anything about the byte order for multibyte
// numeric values. In the example, we have two cases where 16 bit numbers are
// sent with the more significant byte first.
/* PV */ 0x04, /* Parameter Variable - 1024 bits (128 octets) */
/* PV */ 0x00, /* */
/* PI */ 0x08, /* Parameter Indicator - Rx window size */
/* PL */ 0x01, /* Parameter length */
/* PV */ 0x02, /* Parameter Variable - 2 frames */
/* PI */ 0x09, /* Parameter Indicator - Timer T1 */
/* PL */ 0x02, /* Parameter Length */
/* PV */ 0x10, /* Parameter Variable - 4096 MSec */
/* PV */ 0x00, /* */
/* PI */ 0x0A, /* Parameter Indicator - Retries (N1) */
/* PL */ 0x01, /* Parameter Length */
/* PV */ 0x03 /* Parameter Variable - 3 retries */
};
int main (int argc, char *argv[]) {
struct xid_param_s param;
struct xid_param_s param2;
int n;
unsigned char info[40]; // Currently max of 27 but things can change.
char desc[150]; // I've seen 109.
/* parse example. */
n = xid_parse (example, sizeof(example), &param, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
#ifdef NDEBUG
#error "This won't work properly if NDEBUG is defined. It should be undefined in direwolf.h"
#endif
assert (n==1);
assert (param.full_duplex == 0);
assert (param.srej == srej_single);
assert (param.modulo == modulo_128);
assert (param.i_field_length_rx == 128);
assert (param.window_size_rx == 2);
assert (param.ack_timer == 4096);
assert (param.retries == 3);
/* encode and verify it comes out the same. */
n = xid_encode (&param, info, cr_cmd);
assert (n == sizeof(example));
n = memcmp(info, example, 27);
//for (n=0; n<27; n++) {
// dw_printf ("%2d %02x %02x\n", n, example[n], info[n]);
//}
assert (n == 0);
/* try a couple different values, no srej. */
param.full_duplex = 1;
param.srej = srej_none;
param.modulo = modulo_8;
param.i_field_length_rx = 2048;
param.window_size_rx = 3;
param.ack_timer = 1234;
param.retries = 12;
n = xid_encode (&param, info, cr_cmd);
n = xid_parse (info, n, &param2, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
assert (param2.full_duplex == 1);
assert (param2.srej == srej_none);
assert (param2.modulo == modulo_8);
assert (param2.i_field_length_rx == 2048);
assert (param2.window_size_rx == 3);
assert (param2.ack_timer == 1234);
assert (param2.retries == 12);
/* Other values, single srej. */
param.full_duplex = 0;
param.srej = srej_single;
param.modulo = modulo_8;
param.i_field_length_rx = 61;
param.window_size_rx = 4;
param.ack_timer = 5555;
param.retries = 9;
n = xid_encode (&param, info, cr_cmd);
n = xid_parse (info, n, &param2, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
assert (param2.full_duplex == 0);
assert (param2.srej == srej_single);
assert (param2.modulo == modulo_8);
assert (param2.i_field_length_rx == 61);
assert (param2.window_size_rx == 4);
assert (param2.ack_timer == 5555);
assert (param2.retries == 9);
/* Other values, multi srej. */
param.full_duplex = 0;
param.srej = srej_multi;
param.modulo = modulo_128;
param.i_field_length_rx = 61;
param.window_size_rx = 4;
param.ack_timer = 5555;
param.retries = 9;
n = xid_encode (&param, info, cr_cmd);
n = xid_parse (info, n, &param2, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
assert (param2.full_duplex == 0);
assert (param2.srej == srej_multi);
assert (param2.modulo == modulo_128);
assert (param2.i_field_length_rx == 61);
assert (param2.window_size_rx == 4);
assert (param2.ack_timer == 5555);
assert (param2.retries == 9);
/* Specify some and not others. */
param.full_duplex = 0;
param.srej = srej_single;
param.modulo = modulo_8;
param.i_field_length_rx = G_UNKNOWN;
param.window_size_rx = G_UNKNOWN;
param.ack_timer = 999;
param.retries = G_UNKNOWN;
n = xid_encode (&param, info, cr_cmd);
n = xid_parse (info, n, &param2, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
assert (param2.full_duplex == 0);
assert (param2.srej == srej_single);
assert (param2.modulo == modulo_8);
assert (param2.i_field_length_rx == G_UNKNOWN);
assert (param2.window_size_rx == G_UNKNOWN);
assert (param2.ack_timer == 999);
assert (param2.retries == G_UNKNOWN);
/* Default values for empty info field. */
n = 0;
n = xid_parse (info, n, &param2, desc, sizeof(desc));
text_color_set (DW_COLOR_DEBUG);
dw_printf ("%d: %s\n", __LINE__, desc);
fflush (stdout);
SLEEP_SEC (1);
text_color_set (DW_COLOR_ERROR);
assert (param2.full_duplex == G_UNKNOWN);
assert (param2.srej == srej_not_specified);
assert (param2.modulo == modulo_unknown);
assert (param2.i_field_length_rx == G_UNKNOWN);
assert (param2.window_size_rx == G_UNKNOWN);
assert (param2.ack_timer == G_UNKNOWN);
assert (param2.retries == G_UNKNOWN);
text_color_set (DW_COLOR_REC);
dw_printf ("XID test: Success.\n");
exit (0);
}
#endif
/* end xid.c */