FreeCalypso > hg > fc-selenite
view src/g23m-gprs/llc/llc_uirxf.c @ 16:5ba4316fa42c
targets: initial import from Magnetite (pruned)
author | Mychaela Falconia <falcon@freecalypso.org> |
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date | Sun, 15 Jul 2018 21:40:06 +0000 |
parents | d393cd9bb723 |
children |
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/* +----------------------------------------------------------------------------- | Project : | Modul : +----------------------------------------------------------------------------- | Copyright 2002 Texas Instruments Berlin, AG | All rights reserved. | | This file is confidential and a trade secret of Texas | Instruments Berlin, AG | 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 Berlin, AG. +----------------------------------------------------------------------------- | Purpose : This modul is part of the entity LLC and implements all | procedures and functions as described in the | SDL-documentation (UIRX-statemachine) +----------------------------------------------------------------------------- */ #ifndef LLC_UIRXF_C #define LLC_UIRXF_C #endif #define ENTITY_LLC /*==== INCLUDES =============================================================*/ #include "typedefs.h" /* to get Condat data types */ #include "vsi.h" /* to get a lot of macros */ #include "macdef.h" #include "gprs.h" #include "gsm.h" /* to get a lot of macros */ #include "cnf_llc.h" /* to get cnf-definitions */ #include "mon_llc.h" /* to get mon-definitions */ #include "prim.h" /* to get the definitions of used SAP and directions */ #include "llc.h" /* to get the global entity definitions */ #include "llc_uirxf.h" /* to compare own prototyes */ /*==== CONST ================================================================*/ /*==== LOCAL VARS ===========================================================*/ /*==== PRIVATE FUNCTIONS ====================================================*/ /*==== PUBLIC FUNCTIONS =====================================================*/ /* +------------------------------------------------------------------------------ | Function : uirx_queue_clean +------------------------------------------------------------------------------ | Description : This procedure removes all entries from the UIRX queue | | Parameters : | +------------------------------------------------------------------------------ */ GLOBAL void uirx_queue_clean (void) { T_UIRX_QUEUE** entry = &(llc_data->uirx->queue); TRACE_FUNCTION( "uirx_queue_clean" ); while (*entry) { /* * get pointer to next (=first) entry */ T_UIRX_QUEUE* current = *entry; /* * Free frame, if one is attached to the entry */ if (current->frame != NULL) { PFREE (current->frame); } /* * remove next entry from the entry (make second to first) */ *entry = current->next; /* * free the removed entry */ MFREE (current); } } /* uirx_queue_clean() */ /* +------------------------------------------------------------------------------ | Function : uirx_queue_store +------------------------------------------------------------------------------ | Description : This procedure stores the primitive to the end of the queue. | If the queue is full, an the primitive is freed. | | Parameters : | +------------------------------------------------------------------------------ */ GLOBAL void uirx_queue_store (T_LL_UNITDATA_IND *ll_unitdata_ind) { T_UIRX_QUEUE** entry = &(llc_data->uirx->queue); int num_entries = 0; TRACE_FUNCTION( "uirx_queue_store" ); /* * Skip, but count, already for L3 ready waiting entries. * If queue is already full, free this primitive. */ while (*entry) { num_entries++; if (num_entries >= UIRX_QUEUE_SIZE) { PFREE (ll_unitdata_ind); TRACE_EVENT ("LL_UNITDATA_IND ignored -> UIRX queue is full"); return; } entry = &((*entry)->next); } /* * Allocate management memory */ MALLOC( *entry, sizeof(T_UIRX_QUEUE) ); if (*entry) { /* * Queue primitive */ (*entry)->next = NULL; (*entry)->frame = ll_unitdata_ind; } else { /* * Out of memory */ PFREE (ll_unitdata_ind); TRACE_ERROR( "Out of memory in uirx_queue_store()" ); } } /* uirx_queue_store() */ /* +------------------------------------------------------------------------------ | Function : uirx_queue_retrieve +------------------------------------------------------------------------------ | Description : Retrieve the next frame, if any. | | Parameters : | +------------------------------------------------------------------------------ */ GLOBAL BOOL uirx_queue_retrieve (T_LL_UNITDATA_IND **ll_unitdata_ind) { T_UIRX_QUEUE** entry = &(llc_data->uirx->queue); TRACE_FUNCTION( "uirx_queue_retrieve" ); /* * Take the first queue entry, if there is any. */ if (*entry) { /* * Store pointer to the entry */ T_UIRX_QUEUE* current = *entry; /* * Remove entry from the queue (make second to first) */ *entry = current->next; *ll_unitdata_ind = current->frame; /* * Free retrieved management entry */ MFREE (current); return TRUE; } else { /* * Set default return values */ *ll_unitdata_ind = NULL; return FALSE; } } /* uirx_queue_retrieve() */ /* +------------------------------------------------------------------------------ | Function : uirx_init +------------------------------------------------------------------------------ | Description : This procedure initialises all necessary variables of | ui_frames_rx for all SAPIs. | | Parameters : | +------------------------------------------------------------------------------ */ GLOBAL void uirx_init (void) { UBYTE inc; TRACE_FUNCTION( "uirx_init" ); /* * Initialise every incarnation of UIRX with state TLLI_UNASSIGNED_NOT_READY, * except incarnation 0 (= SAPI 1), because we have no flow control for * SAPI 1. */ SWITCH_SERVICE (llc, uirx, 0); INIT_STATE (UIRX_0, UIRX_TLLI_UNASSIGNED_READY); SWITCH_SERVICE (llc, uirx, 1); INIT_STATE (UIRX_1, UIRX_TLLI_UNASSIGNED_NOT_READY); SWITCH_SERVICE (llc, uirx, 2); INIT_STATE (UIRX_2, UIRX_TLLI_UNASSIGNED_NOT_READY); SWITCH_SERVICE (llc, uirx, 3); INIT_STATE (UIRX_3, UIRX_TLLI_UNASSIGNED_NOT_READY); SWITCH_SERVICE (llc, uirx, 4); INIT_STATE (UIRX_4, UIRX_TLLI_UNASSIGNED_NOT_READY); SWITCH_SERVICE (llc, uirx, 5); INIT_STATE (UIRX_5, UIRX_TLLI_UNASSIGNED_NOT_READY); /* * Initialise the UIRX queue structure */ for (inc = 0; inc < UIRX_NUM_INC; inc++) { SWITCH_SERVICE (llc, uirx, inc); /* * Free old used resources (in case of an LLC restart): */ uirx_queue_clean (); llc_data->uirx->queue = NULL; } return; } /* uirx_init() */ /* +------------------------------------------------------------------------------ | Function : uirx_init_sapi +------------------------------------------------------------------------------ | Description : This procedure initialises all necessary variables of | ui_frames_rx for the given SAPI. | | Parameters : | +------------------------------------------------------------------------------ */ GLOBAL void uirx_init_sapi (void) { TRACE_FUNCTION( "uirx_init_sapi" ); /* * <R.LLC.TLLI_ASS.A.007>, <R.LLC.TLLI_ASS.A.009> */ llc_data->sapi->vur = 0; llc_data->uirx->last_32_frames_bitfield = 0L; return; } /* uirx_init_sapi() */ /* +------------------------------------------------------------------------------ | Function : uirx_store_nu +------------------------------------------------------------------------------ | Description : This procedure stores the given n(u) in a list of the last 32 | received n(u)s concerning the given SAPI. Therefore the | variable v(ur) is passed to the procedure, which contains | the current value of the unacknowledged receive sequence | number. | | Parameters : nu - N(U), must be in the range vur-32 <= nu < vur | vur - V(UR) | +------------------------------------------------------------------------------ */ GLOBAL void uirx_store_nu (T_FRAME_NUM nu, T_FRAME_NUM vur) { USHORT diff; TRACE_FUNCTION( "uirx_store_nu" ); /* * Set the bit for the received N(U) in last_32_frames_bitfield. The * relative bit position referring to V(UR) has already been stored * in diff. */ diff = (vur + (MAX_SEQUENCE_NUMBER+1) - nu - 1) % (MAX_SEQUENCE_NUMBER+1); llc_data->uirx->last_32_frames_bitfield |= (0x00000001L) << diff; return; } /* uirx_store_nu() */ /* +------------------------------------------------------------------------------ | Function : uirx_check_nu +------------------------------------------------------------------------------ | Description : This procedure checks if the given n(u) has already been | received for the current SAPI within the last 32 frames (see | procedure store_nu). | | Parameters : nu - N(U), must be in the range vur-32 <= nu < vur | vur - V(UR) | | Returns : TRUE - if frame was already received. | FALSE - else +------------------------------------------------------------------------------ */ GLOBAL BOOL uirx_check_nu (T_FRAME_NUM nu, T_FRAME_NUM vur) { USHORT diff; TRACE_FUNCTION( "uirx_check_nu" ); /* * The difference (modulo counted) between V(UR) and N(U) is * calculated as follows: * - add 512 (maximum sequence number + 1) to V(UR), in case V(UR) * is smaller than N(U) * - subtract N(U) * - subtract 1 because V(UR) is not contained within * last_32_frames_bitfield and thus the bit shift must be one less * - afterwards apply modulo 512 to get back into the range of * sequence numbers, because we added this value initially to * V(UR) */ diff = (vur + (MAX_SEQUENCE_NUMBER+1) - nu - 1) % (MAX_SEQUENCE_NUMBER + 1); /* * Check if the corresponding bit of N(U) in last_32_frames_bitfield is * set. The bit is stored in last_32_frames_bitfield relative to V(UR). */ return ((llc_data->uirx->last_32_frames_bitfield & (0x00000001L << diff)) != 0L); } /* uirx_check_nu() */ /* +------------------------------------------------------------------------------ | Function : uirx_set_new_vur +------------------------------------------------------------------------------ | Description : This procedure handles setting vur to a new value. The modulo | operation and the handling of the last_32_frames_bitfield | is done here. | | Parameters : new_vur - V(UR), must be in range V(UR) < new_vur < V(UR)-32 | +------------------------------------------------------------------------------ */ GLOBAL void uirx_set_new_vur (T_FRAME_NUM new_vur) { USHORT diff; TRACE_FUNCTION( "uirx_set_new_vur" ); new_vur %= (MAX_SEQUENCE_NUMBER+1); /* * The difference (modulo counted) between V(UR) and the new_vur is * calculated as follows: * - add 512 (maximum sequence number + 1) to new_vur * - subtract V(UR) * - afterwards apply modulo 512 to get back into the range of * sequence numbers, because we added this value initially */ diff = (new_vur + (MAX_SEQUENCE_NUMBER+1) - llc_data->sapi->vur) % (MAX_SEQUENCE_NUMBER+1); /* * Now move the bitfield indicating the last 32 frames numbers. If the diff * from current to new_vur is to large, the bitfild is automaticly cleard * by shifting all bits out. */ llc_data->uirx->last_32_frames_bitfield <<= diff; /* * Increase oc if necessary. If new_vur is a higher value, no overflow * encountered. If new_vur is lower, an retransmission could be possible * or we have had an overflow. But this function will not be called in * case of a retransmission! */ if ( new_vur < llc_data->sapi->vur ) { llc_data->sapi->oc_ui_rx += (MAX_SEQUENCE_NUMBER+1); } /* * Set net V(UR) value */ llc_data->sapi->vur = new_vur; } /* uirx_set_new_vur() */