FreeCalypso > hg > fc-magnetite
view src/g23m-gprs/sm/sm_debug.c @ 323:f08212cf0b04
components/fchg compilation recipe created
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Mon, 04 Dec 2017 06:00:15 +0000 |
parents | 219afcfc6250 |
children |
line wrap: on
line source
/*---------------------------------------------------------------------------- | Project : 3G PS | Module : SM +----------------------------------------------------------------------------- | Copyright 2003 Texas Instruments. | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments . | The receipt of or possession of this file does not convey | any rights to reproduce or disclose its contents or to | manufacture, use, or sell anything it may describe, in | whole, or in part, without the specific written consent of | Texas Instruments. +----------------------------------------------------------------------------- | Purpose: Debug functions implementation in the SM entity. | For design details, see: | 8010.908 SM Detailed Specification +---------------------------------------------------------------------------*/ /*==== DECLARATION CONTROL =================================================*/ /*==== INCLUDES =============================================================*/ #include <stdio.h> #include "sm.h" #include "sm_timer_handler.h" /*==== CONSTS ===============================================================*/ /*==== TYPES ================================================================*/ /*==== LOCALS ===============================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /*==== PUBLIC FUNCTIONS =====================================================*/ #ifdef DEBUG /* * Debug function for dumping the contents of an QoS structure. */ static void sm_qos_dump_r97_qos(T_PS_qos_r97 *qos_r97) { /*@observer@*/const char *indent = " - "; /*@observer@*/const char *peak_text[16] = { /* NAS_PEAK_SUB */ "SUBSCRIBED", /* NAS_PEAK_1K */ "Up to 1000 octet/s", /* NAS_PEAK_2K */ "Up to 2000 octet/s", /* NAS_PEAK_4K */ "Up to 4000 octet/s", /* NAS_PEAK_8K */ "Up to 8000 octet/s", /* NAS_PEAK_16K */ "Up to 16000 octet/s", /* NAS_PEAK_32K */ "Up to 32000 octet/s", /* NAS_PEAK_64K */ "Up to 64000 octet/s", /* NAS_PEAK_128K */ "Up to 128000 octet/s", /* NAS_PEAK_256K */ "Up to 256000 octet/s", /* 10 */ "RESERVED - 1000 octets/s", /* 11 */ "RESERVED - 1000 octets/s", /* 12 */ "RESERVED - 1000 octets/s", /* 13 */ "RESERVED - 1000 octets/s", /* 14 */ "RESERVED - 1000 octets/s", /* 15 */ "RESERVED", }; /*@observer@*/const char *mean_text[32] = { /* NAS_MEAN_SUB */ "SUBSCRIBED", /* NAS_MEAN_100 */ "100 octets/h", /* NAS_MEAN_200 */ "200 octets/h", /* NAS_MEAN_500 */ "500 octets/h", /* NAS_MEAN_1K */ "1000 octets/h", /* NAS_MEAN_2K */ "2000 octets/h", /* NAS_MEAN_5K */ "5000 octets/h", /* NAS_MEAN_10K */ "10000 octets/h", /* NAS_MEAN_20K */ "20000 octets/h", /* NAS_MEAN_50K */ "50000 octets/h", /* NAS_MEAN_100K */ "100000 octets/h", /* NAS_MEAN_200K */ "200000 octets/h", /* NAS_MEAN_500K */ "500000 octets/h", /* NAS_MEAN_1M */ "1000000 octets/h", /* NAS_MEAN_2M */ "2000000 octets/h", /* NAS_MEAN_5M */ "5000000 octets/h", /* NAS_MEAN_10M */ "10000000 octets/h", /* NAS_MEAN_20M */ "20000000 octets/h", /* NAS_MEAN_50M */ "50000000 octets/h", /* 19 */ "RESERVED", /* 20 */ "RESERVED", /* 21 */ "RESERVED", /* 22 */ "RESERVED", /* 23 */ "RESERVED", /* 24 */ "RESERVED", /* 25 */ "RESERVED", /* 26 */ "RESERVED", /* 27 */ "RESERVED", /* 28 */ "RESERVED", /* 29 */ "RESERVED", /* 30 */ "RESERVED", /* NAS_MEAN_BEST */"BEST EFFORT" }; /*@observer@*/const char *rel_text[8] = { /* NAS_RELCLASS_SUB */ "Subscribed reliability class", /* NAS_GTP_LLC_RLC_PROT */ "Ack'ed GTP, LLC, and RLC; Protected data", /* NAS_LLC_RLC_PROT */ "Unack'ed GTP; Ack'ed LLC and RLC, Protected data", /* NAS_RLC_PROT */ "Unack'ed GTP and LLC; Ack'ed RLC, Protected data", /* NAS_PROT */ "Unack'ed GTP, LLC, and RLC, Protected data", /* NAS_NO_PROT */ "Unack'ed GTP, LLC, and RLC, Unprotected data", /* 6 */ "UNKNOWN VALUE", /* 7 */ "RESERVED" }; (void)TRACE_EVENT_P3("%sDelay class: 0x%02x (Class %d)", indent, qos_r97->delay, qos_r97->delay); (void)TRACE_EVENT_P3("%sReliability class: 0x%02x (%s)", indent, qos_r97->relclass, rel_text[(U16)qos_r97->relclass]); (void)TRACE_EVENT_P3("%sPeak bitrate 0x%02x (%s)", indent, qos_r97->peak, peak_text[(U16)qos_r97->peak]); (void)TRACE_EVENT_P2("%sPrecedence class: 0x%02x", indent, qos_r97->preced); (void)TRACE_EVENT_P3("%sMean bitrate 0x%02x (%s)", indent, qos_r97->mean, mean_text[(U16)qos_r97->mean]); } static void sm_qos_dump_r99_qos(T_PS_qos_r99 *qos_r99) { /*@observer@*/const char *indent = " - "; (void)TRACE_EVENT_P3("%sTraffic class: 0x%02x (%s)", indent, qos_r99->tc, (qos_r99->tc == (U8)PS_TC_CONV ? "CONVERSATIONAL" : (qos_r99->tc == (U8)PS_TC_STREAM ? "STREAMING" : (qos_r99->tc == (U8)PS_TC_INTER ? "INTERACTIVE" : (qos_r99->tc == (U8)PS_TC_BG ? "BACKGROUND" : (qos_r99->tc == (U8)PS_TC_SUB ? "SUBSCRIBED" : "UNKNOWN")))))); (void)TRACE_EVENT_P3("%sDelivery order: 0x%02x (%s)", indent, qos_r99->order, (qos_r99->order == (U8)PS_ORDER_YES ? "YES" : (qos_r99->order == (U8)PS_ORDER_NO ? "NO" : (qos_r99->order == (U8)PS_ORDER_SUB ? "SUBSCRIBED" : "UNKNOWN")))); (void)TRACE_EVENT_P3("%sDeliver erroneous SDUs: 0x%02x (%s)", indent, qos_r99->del_err_sdu, (qos_r99->del_err_sdu == (U8)PS_DEL_ERR_YES ? "YES" : (qos_r99->del_err_sdu == (U8)PS_DEL_ERR_NO ? "NO" : (qos_r99->del_err_sdu == (U8)PS_DEL_ERR_NODETECT ? "NODETECT" : (qos_r99->del_err_sdu == (U8)PS_DEL_ERR_SUB ? "SUBSCRIBED" : "UNKNOWN"))))); (void)TRACE_EVENT_P3("%sMax SDU size: 0x%04x (%d octets)", indent, qos_r99->max_sdu, qos_r99->max_sdu); (void)TRACE_EVENT_P3("%sMax bit-rate uplink: 0x%04x (%dkbps)", indent, qos_r99->max_rate_ul, qos_r99->max_rate_ul); (void)TRACE_EVENT_P3("%sMax bit-rate downlink: 0x%04x (%dkbps)", indent, qos_r99->max_rate_dl, qos_r99->max_rate_dl); (void)TRACE_EVENT_P3("%sMax residual BER: %dE-%d", indent, qos_r99->ber.ratio_mant, qos_r99->ber.ratio_exp); (void)TRACE_EVENT_P3("%sMax SDU error ratio: %dE-%d", indent, qos_r99->sdu_err_ratio.ratio_mant, qos_r99->sdu_err_ratio.ratio_exp); (void)TRACE_EVENT_P3("%sTransfer delay: 0x%04x (%dms)", indent, qos_r99->xfer_delay, qos_r99->xfer_delay); (void)TRACE_EVENT_P3("%sTraffic handling prio: 0x%02x (%d)", indent, qos_r99->handling_pri, qos_r99->handling_pri); (void)TRACE_EVENT_P3("%sGuar. bit-rate uplink: 0x%04x (%dkbps)", indent, qos_r99->guar_br_ul, qos_r99->guar_br_ul); (void)TRACE_EVENT_P3("%sGuar. bit-rate downlink: 0x%04x (%dkbps)", indent, qos_r99->guar_br_dl, qos_r99->guar_br_dl); } static void sm_qos_dump_qos(T_SM_qos *qos, const char *type) { if (qos->ctrl_qos == PS_is_R97) { (void)TRACE_EVENT_P1( " R97 %s QoS:", type); sm_qos_dump_r97_qos(&qos->qos.qos_r97); } else if (qos->ctrl_qos == PS_is_R99) { (void)TRACE_EVENT_P1( " R99 %s QoS:", type); sm_qos_dump_r99_qos(&qos->qos.qos_r99); } else { (void)TRACE_EVENT_P2("ERROR! Invalid union controller == %d in %s QoS!", qos->ctrl_qos, type); } } static BOOL sm_debug_is_port_range(U16 low_limit, U16 high_limit) { return (high_limit != 0 && low_limit < high_limit); } static /*@observer@*/char * sm_debug_dump_port_range(U16 low_limit, U16 high_limit) { static char range[sizeof("65535-65535")]; /*@-bufferoverflowhigh@*/ if (sm_debug_is_port_range(low_limit, high_limit)) { sprintf(range, "%5hu-%5hu", low_limit, high_limit); } else { sprintf(range, "%5hu", low_limit); } /*@=bufferoverflowhigh@*/ return range; } static U32 sm_debug_octet_as_bits(U8 octet) /*@*/ { const U32 bit_masks[16] = { 0000UL, 0001UL, 0010UL, 0011UL, 0100UL, 0101UL, 0110UL, 0111UL, 1000UL, 1001UL, 1010UL, 1011UL, 1100UL, 1101UL, 1110UL, 1111UL }; return (bit_masks[(U16)octet >> 4] * 10000UL + bit_masks[(U16)octet & 15]); } static void sm_debug_dump_ipv4_tft(T_NAS_tft_pf_ipv4 *pf, U8 valid_bits) { if ( (valid_bits & NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0) { (void)TRACE_EVENT_P1(" + IPv4 protocol number = %hu", (U16)pf->tft_protocol); } if ( (valid_bits & NAS_TFT_ID_TOS_AND_MASK) != (U8)0) { (void)TRACE_EVENT_P2(" + IPv4 ToS and mask = 0x%02x/0x%02x", pf->tft_tos_and_mask.tos_value, pf->tft_tos_and_mask.tos_mask); } if ( (valid_bits & NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0) { (void)TRACE_EVENT_P1(" + Dest port (range) = %s", sm_debug_dump_port_range(pf->tft_dest_port_range.low_limit, pf->tft_dest_port_range.high_limit)); } if ( (valid_bits & NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0) { (void)TRACE_EVENT_P1(" + Source port (range) = %s", sm_debug_dump_port_range(pf->tft_src_port_range.low_limit, pf->tft_src_port_range.high_limit)); } if ( (valid_bits & NAS_TFT_ID_IPSEC_SPI) != (U8)0) { (void)TRACE_EVENT_P1(" + IPv4 IPSEC SPI = %08x", pf->tft_ipsec_spi); } if ( (valid_bits & NAS_TFT_ID_IPv4_SRC_ADDR_MASK) != (U8)0) { U8 *a4 = pf->tft_ipv4_src_addr_mask.tft_ipv4_addr; (void)TRACE_EVENT_P8(" + IPv4 src address/mask = %hu.%hu.%hu.%hu" "/%hu.%hu.%hu.%hu", (U16)a4[0], (U16)a4[1], (U16)a4[2], (U16)a4[3], (U16)a4[0], (U16)a4[1], (U16)a4[2], (U16)a4[3]); } } static void sm_debug_dump_ipv6_tft(T_NAS_tft_pf_ipv6 *pf, U8 valid_bits) { if ( (valid_bits & NAS_TFT_ID_PROTOCOL_OR_NEXT_HDR) != (U8)0) { (void)TRACE_EVENT_P1(" + IPv6 next header = %hu", (U16)pf->tft_next_hdr); } if ( (valid_bits & NAS_TFT_ID_TOS_AND_MASK) != (U8)0) { (void)TRACE_EVENT_P2(" + IPv6 traffic class/mask= 0x%02x/0x%02x", pf->tft_tos_and_mask.tos_value, pf->tft_tos_and_mask.tos_mask); } if ( (valid_bits & NAS_TFT_ID_DEST_PORT_RANGE) != (U8)0) { (void)TRACE_EVENT_P1(" + Dest port (range) = %s", sm_debug_dump_port_range(pf->tft_dest_port_range.low_limit, pf->tft_dest_port_range.high_limit)); } if ( (valid_bits & NAS_TFT_ID_SRC_PORT_RANGE) != (U8)0) { (void)TRACE_EVENT_P1(" + Source port (range) = %s", sm_debug_dump_port_range(pf->tft_src_port_range.low_limit, pf->tft_src_port_range.high_limit)); } if ( (valid_bits & NAS_TFT_ID_IPSEC_SPI) != (U8)0) { (void)TRACE_EVENT_P1(" + IPv6 IPSEC SPI = %08x", pf->tft_ipsec_spi); } if ( (valid_bits & NAS_TFT_ID_FLOW_LABEL) != (U8)0) { (void)TRACE_EVENT_P1(" + IPv6 flow label = %06x", pf->tft_flow_label); } if ( (valid_bits & NAS_TFT_ID_IPv6_SRC_ADDR_MASK) != (U8)0) { char src_addr [SM_SIZE_FORMATTED_IPv6_ADDR], addr_mask[SM_SIZE_FORMATTED_IPv6_ADDR]; (void)sm_format_ipv6_addr(pf->tft_ipv6_src_addr_mask.tft_ipv6_addr, src_addr); (void)sm_format_ipv6_addr(pf->tft_ipv6_src_addr_mask.tft_ipv6_mask, addr_mask); (void)TRACE_EVENT_P2(" + IPv6 src address/mask = %s/%s", src_addr, addr_mask); } } static void sm_debug_dump_tft_pf(T_NAS_tft_pf *tft_pf, U16 index) { (void)TRACE_EVENT_P3(" #%-2u: ID=%u, precedence=%3u, valid_mask=%08ul", index, tft_pf->tft_pf_precedence, sm_debug_octet_as_bits(tft_pf->tft_pf_valid_bits)); if (tft_pf->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv4) { sm_debug_dump_ipv4_tft(&tft_pf->tft_pf_entry.tft_pf_ipv4, tft_pf->tft_pf_valid_bits); } else if (tft_pf->ctrl_tft_pf_entry == NAS_is_tft_pf_ipv6) { sm_debug_dump_ipv6_tft(&tft_pf->tft_pf_entry.tft_pf_ipv6, tft_pf->tft_pf_valid_bits); } else { (void)TRACE_EVENT_P1(" ERROR! Wrong union controller (%d) " "for tft_pf_entry; discarded...", tft_pf->ctrl_tft_pf_entry); } } static void sm_debug_dump_tft(T_SM_tft *tft) { if (tft->ptr_tft_pf != NULL && tft->c_tft_pf > (U8)0) { U16 index; (void)TRACE_EVENT_P3(" TFT [%08x] with %d filters (mask 0b%08ul)", tft->ptr_tft_pf, tft->c_tft_pf, sm_debug_octet_as_bits(tft->tft_precence_mask)); for (index = 0; index < (U16)NAS_SIZE_TFT_FILTER; index++) { if ( (tft->tft_precence_mask & (1UL << index)) != 0) { sm_debug_dump_tft_pf(&tft->ptr_tft_pf[index], index); } } } else { (void)TRACE_EVENT (" TFT [ NULL ]"); } } /*@observer@*/char * sm_format_ipv6_addr(U8 *addr, /*@out@*/ /*@returned@*/ char *dest) { /*@-bufferoverflowhigh@*/ (void)sprintf(dest, "%04hx:%04hx:%04hx:%04hx:%04hx:%04hx:%04hx:%04hx", ((U16)addr[ 0] << 8) | (U16)addr[ 1], ((U16)addr[ 2] << 8) | (U16)addr[ 3], ((U16)addr[ 4] << 8) | (U16)addr[ 5], ((U16)addr[ 6] << 8) | (U16)addr[ 7], ((U16)addr[ 8] << 8) | (U16)addr[ 9], ((U16)addr[10] << 8) | (U16)addr[11], ((U16)addr[12] << 8) | (U16)addr[13], ((U16)addr[14] << 8) | (U16)addr[15]); /*@=bufferoverflowhigh@*/ return dest; } static void sm_format_ip_address(T_NAS_ip *ip_addr, /*@out@*/char *dest) { if (ip_addr->ctrl_ip_address == NAS_is_ip_not_present) { strcpy(dest, "NOT_PRESENT"); } else if (ip_addr->ctrl_ip_address == NAS_is_ipv4) { U8 *ptr_addr = ip_addr->ip_address.ipv4_addr.a4; /*@-bufferoverflowhigh@*/ (void)sprintf(dest, "%hu.%hu.%hu.%hu", (U16)ptr_addr[0], (U16)ptr_addr[1], (U16)ptr_addr[2], (U16)ptr_addr[3]); /*@=bufferoverflowhigh@*/ } else if (ip_addr->ctrl_ip_address == NAS_is_ipv6) { (void)sm_format_ipv6_addr(ip_addr->ip_address.ipv6_addr.a6, dest); } else { strcpy(dest, "INVALID_CTRL"); } } struct T_SM_FLAG_STRING { U16 flag; /*@null@*/ /*@observer@*/const char *name; }; static const struct T_SM_FLAG_STRING sm_context_flags[7] = { {(U16)SM_CONTEXT_FLAG_COMP_PARAMS, "COMP_PARAMS"}, {(U16)SM_CONTEXT_FLAG_STARTED_DURING_SUSPEND, "STARTED_DURING_SUSPEND"}, {(U16)SM_CONTEXT_FLAG_SECONDARY_CONTEXT, "SECONDARY_CONTEXT"}, {(U16)SM_CONTEXT_FLAG_PENDING_DEALLOCATION, "PENDING_DEALLOCATION"}, {(U16)SM_CONTEXT_FLAG_PENDING_REACTIVATION, "PENDING_REACTIVATION"}, {(U16)SM_CONTEXT_FLAG_PFI_PRESENT, "PFI_PRESENT"}, {(U16)0, NULL} }; static void sm_flags_to_string(const struct T_SM_FLAG_STRING *flag_string, /*@out@*/ char *dest, U16 flags) { U16 index, flag_count; flag_count = 0; for (index = 0; index < (U16)16 && flag_string->flag != 0; index++) { if ((flags & flag_string->flag) != 0 && flag_string->name != NULL) { if (flag_count != 0) { *dest++ = ','; *dest++ = ' '; } else { flag_count++; } strcpy(dest, flag_string->name); dest = &dest[strlen(flag_string->name)]; } /* if */ flag_string++; } /* for */ *dest = '\0'; } /*@observer@*/static const char *sm_pdp_type_name(U8 pdp_type) { switch ((T_SMREG_pdp_type) pdp_type) { case SMREG_PDP_PPP: return "PPP"; case SMREG_PDP_IPV4: return "IPv4"; case SMREG_PDP_IPV6: return "IPv6"; case SMREG_PDP_EMPTY: return "DYNAMIC"; default: return "INVALID!"; } } /*@observer@*/const char *sm_timer_name(U8 timer) { switch ((T_SM_TIMER_TYPE) timer) { case SM_TIMER_NONE: return "NONE"; case SM_TIMER_T3380: return "T3380"; case SM_TIMER_T3381: return "T3381"; case SM_TIMER_T3390: return "T3390"; default: return "UNKNOWN"; } } /*@observer@*/static const char *sm_pfi_name(U8 pfi) { switch ((T_PS_pkt_flow_id) pfi) { case PS_PFI_BEST_EFFORT: return "Best Effort"; case PS_PFI_SIGNALING: return "Signalling"; case PS_PFI_SMS: return "SMS"; case PS_PKT_FLOW_ID_NOT_PRES: return "NONE"; default: return "UNKNOWN"; } } static void sm_format_apn(T_SMREG_apn *apn, /*@out@*/char *dest) { U16 index; assert(apn != NULL && apn->c_apn_buf > (U8)0); /* First, copy (all) APN text skipping first length byte. */ if (apn == NULL) { return; /*Fix for Lint warning*/ } memcpy(dest, &apn->apn_buf[1], (size_t)apn->c_apn_buf - 1); index = (U16)apn->apn_buf[0]; while (index < (U16)apn->c_apn_buf) { dest[index] = '.'; index += (U16)apn->apn_buf[index]; } dest[(U16)apn->c_apn_buf - 1] = '\0'; } /*@observer@*/char *sm_context_bitfield(/*@out@*/ /*@returned@*/char *status, U16 status_bits) { U16 index; for (index = 0; index < (U16)SM_MAX_NSAPI_OFFSET; index++) { U16 nsapi = sm_index_to_nsapi(index); status[index] = (sm_is_nsapi_in_nsapi_set(nsapi, status_bits) ? '1' : '0'); } status[SM_MAX_NSAPI_OFFSET] = '\0'; return status; } void sm_dump_state(void) { int nsapi; char req_addr[SM_SIZE_FORMATTED_IPv6_ADDR], neg_addr[SM_SIZE_FORMATTED_IPv6_ADDR]; char context_status[SM_MAX_NSAPI_OFFSET + 1]; (void)TRACE_FUNCTION("sm_dump_state"); (void)TRACE_EVENT_P3("SM is active in a(n) %s network in %s RAT; SM is%s suspended", (sm_get_current_nw_release() == PS_SGSN_98_OLDER ? "pre-R99" : (sm_get_current_nw_release() == PS_SGSN_99_ONWARDS ? "R99" : "UNKNOWN")), (sm_get_current_rat() == PS_RAT_GSM ? "GSM" : (sm_get_current_rat() == PS_RAT_UMTS_FDD ? "UMTS" : "NONE")), (sm_is_suspended() ? "" : " not")); (void)TRACE_EVENT_P1("Context activation status: %s", sm_context_bitfield(context_status, sm_data.sm_context_activation_status)); for (nsapi = (int)NAS_NSAPI_5; nsapi < NAS_SIZE_NSAPI; nsapi++) { struct T_SM_CONTEXT_DATA *context; context = sm_get_context_data_from_nsapi(nsapi); if (context != NULL) { char flags[256]; (void)TRACE_EVENT_P7("NSAPI%3d: [%08x] nsapi=%d, ti=%d, linked_ti=%d, " "active_timer=%s, timeouts=%d", nsapi, context, context->nsapi, context->ti, context->linked_ti, sm_timer_name(context->active_timer), context->timeouts); (void)TRACE_EVENT_P4(" sapi=%d, radio_prio=%d, pfi=%d (%s)", context->sapi, context->radio_prio, context->pfi, sm_pfi_name(context->pfi)); sm_flags_to_string(sm_context_flags, flags, (U16)context->flags); (void)TRACE_EVENT_P2(" flags=0x%02x (%s)", context->flags, flags); (void)TRACE_EVENT_P1(" Network Control state: %s", sm_network_control_state(context)); (void)TRACE_EVENT_P1(" Context Control state: %s", sm_context_control_state(context)); (void)TRACE_EVENT_P1(" Context Deactivate Control state: %s", sm_context_deactivate_control_state(context)); (void)TRACE_EVENT_P1(" User Plane Control state: %s", sm_user_plane_control_state(context)); if (!sm_is_secondary(context)) { sm_format_ip_address(&context->requested_address, req_addr); sm_format_ip_address(&context->negotiated_address, neg_addr); (void)TRACE_EVENT_P4(" PDP type=0x%02x (%s), " "requested_address=%s, negotiated_address=%s", context->pdp_type, sm_pdp_type_name(context->pdp_type), req_addr, neg_addr); } sm_qos_dump_qos(&context->minimum_qos, "minimum"); sm_qos_dump_qos(&context->requested_qos, "requested"); sm_qos_dump_qos(&context->accepted_qos, "negotiated"); if (!sm_is_secondary(context)) { if (context->apn == NULL) { (void)TRACE_EVENT (" APN [ NULL ]"); } else { char apn[103]; sm_format_apn(context->apn, apn); (void)TRACE_EVENT_P2(" APN [%08x]: %s", context->apn, apn); } } sm_debug_dump_tft(&context->active_tft); } else { (void)TRACE_EVENT_P1("NSAPI%3d: [ NULL ]", nsapi); } } } #endif /* DEBUG */ /*==== END OF FILE ==========================================================*/