FreeCalypso > hg > fc-magnetite
view src/g23m-fad/l2r/l2r_upf.c @ 433:f6ea8d4a5cd8
components/mfw-tcs3: recipe created, starting to compile
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Mon, 22 Jan 2018 00:43:18 +0000 |
parents | 90eb61ecd093 |
children |
line wrap: on
line source
/* +----------------------------------------------------------------------------- | Project : CSD (8411) | Modul : L2r_upf.c +----------------------------------------------------------------------------- | 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 defines the procedures and functions for | the component L2R of the base station +----------------------------------------------------------------------------- */ #ifndef L2R_UPF_C #define L2R_UPF_C #endif #define ENTITY_L2R /*==== INCLUDES ===================================================*/ #include <string.h> #include "typedefs.h" #include "pconst.cdg" #include "vsi.h" #include "macdef.h" #include "custom.h" #include "gsm.h" #include "cus_l2r.h" #include "cnf_l2r.h" #include "mon_l2r.h" #include "prim.h" #include "pei.h" #include "tok.h" #include "dti.h" /* functionality of the dti library */ #include "cl_ribu.h" #include "l2r.h" /*==== CONST =======================================================*/ /*==== TYPES =======================================================*/ /*==== VAR EXPORT ==================================================*/ /*==== VAR LOCAL ===================================================*/ /*==== FUNCTIONS ===================================================*/ /* +------------------------------------------------------------------------------ | Function : up_init +------------------------------------------------------------------------------ | Description : initialise the l2r data for the uplink process | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_init(T_UP *dup) { register ULONG i; TRACE_FUNCTION ("up_init()"); dup->FlowCtrlUsed = FALSE; dup->DnFlow = FL_INACTIVE; dup->UpFlow = FL_INACTIVE; dup->ULFlow = FL_INACTIVE; dup->LLFlow = FL_INACTIVE; dup->MrgFlow = FL_INACTIVE; dup->FlowThreshLo = MAX_UPRIM_RIBU_SIZE/2; dup->FlowThreshHi = 3*MAX_UPRIM_RIBU_SIZE/4; dup->DataSize = 0; dup->FrameSize = 0; dup->OldFrameSize = 0; dup->FramesPerPrim = L2R_FRAMES_PER_PRIM_MAX; dup->LastRcvdSa = 0; dup->LastRcvdSb = 0; dup->LastSentSa = 0; dup->LastSentSb = 0; dup->LastSentFlow = FL_INACTIVE; dup->StoreDataActive = FALSE; dup->UrgentMsg = FALSE; dup->DiscardRemapData = FALSE; dup->QRemapRead = 0; dup->QRemapWrite = 0; dup->BRemapAdr = NULL; dup->BRemapLen = 0; dup->BRemapSa = 0; dup->BRemapSb = 0; dup->BRemapLastState = 0; dup->QRemapPrimDesc.prim = NULL; for (i = 0; i < MAX_UP_REMAP_QUEUE_SIZE; i++) { dup->QRemap[i] = NULL; } for (i = 0; i < UP_REMAP_BUFFER_SIZE; i++) { dup->BRemap[i] = 0; } dup->RiBu.idx.depth = MAX_UPRIM_RIBU_SIZE; INIT_STATE (UP_UL, IW_IDLE); INIT_STATE (UP_LL, ISW_IDLE); INIT_STATE (UP, UP_DISCONNECTED); } /* +------------------------------------------------------------------------------ | Function : up_alloc_prim +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ LOCAL void up_alloc_prim(void) { T_UP *dup = &l2r_data->up; T_PRIM_INDEX m; T_P_UPRIM_DESCRIPTOR primDesc; USHORT sduSize; TRACE_FUNCTION ("up_alloc_prim()"); sduSize = dup->FramesPerPrim * dup->FrameSize * 8; primDesc = dup->RiBu.primDesc[dup->RiBu.alloc]; { PALLOC_SDU(data_req, RLP_DATA_REQ, sduSize); primDesc->prim = data_req; } #ifdef _SIMULATION_ /* Clear SDU for test environment */ { UBYTE *p; UBYTE *pend; p = &primDesc->prim->sdu.buf[0]; pend = p + (sduSize >> 3); while (p < pend) { *p++ = 0; } } #endif primDesc->prim->sdu.o_buf = 0; primDesc->prim->sdu.l_buf = sduSize; primDesc->nFr = dup->FramesPerPrim; primDesc->index = 0; primDesc->offset = 0; primDesc->off_status = 0; primDesc->full = FALSE; primDesc->sa = FL_INACTIVE; primDesc->sb = FL_INACTIVE; /*lint -e416 (Warning -- Likely creation of out-of-bounds) */ for (m = 0; m != dup->FramesPerPrim; m++) { (*primDesc->adr)[m] = (T_P_L2R_FRAME)(primDesc->prim->sdu.buf +L2R_ENCODING_OFFSET + m * dup->FrameSize); } /*lint +e416 (Warning -- Likely creation of out-of-bounds) */ dup->RiBu.alloc++; if (dup->RiBu.alloc EQ dup->RiBu.idx.depth) { dup->RiBu.alloc = 0; } } /* +------------------------------------------------------------------------------ | Function : up_send_prim_timeout +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_prim_timeout(void) { T_UP *dup = &l2r_data->up; TRACE_FUNCTION ("up_send_prim_timeout()"); if (!dup->RiBu.idx.filled) { if (dup->RiBu.alloc EQ dup->RiBu.idx.wi) { /* No primitive is there, so we allocate one */ up_alloc_prim(); } /* No primitive is ready, so we take one away from the relay entity */ cl_ribu_write_index(&dup->RiBu.idx); /* point to next primitive */ } up_send_current_prim(); } /* +------------------------------------------------------------------------------ | Function : up_next_remap_frame +------------------------------------------------------------------------------ | Description : Local function, which is used by up_copy_data_from_l2r | to advance to the next frame in the primitive. | The variable primDesc of the calling function is updated. | | Parameters : primDesc - | | Return : 1 - | 0 - +------------------------------------------------------------------------------ */ LOCAL UBYTE up_next_remap_frame(T_RPRIM_DESCRIPTOR *primDesc) { T_UP *dup = &l2r_data->up; U8 i; T_P_RLP_REMAP_DATA_IND prim; /* next frame */ primDesc->index++; if (primDesc->index >= primDesc->nFr) { /* primitive is completely read out */ PFREE(dup->QRemap [dup->QRemapRead]); /* next primitive */ (dup->QRemapRead)++; if (dup->QRemapRead >= MAX_UP_REMAP_QUEUE_SIZE) { dup->QRemapRead = 0; } if (dup->QRemapRead EQ dup->QRemapWrite) { /* no primitive is ready */ primDesc->prim = NULL; return (1); } /* point to next primitive descriptor */ prim = dup->QRemap[dup->QRemapRead]; primDesc->prim = prim; primDesc->nFr = prim->sdu.l_buf / (8 * prim->data_size + HT_LEN); primDesc->index = 0; for (i = 0; i < primDesc->nFr; i++) { primDesc->adr[i] = (T_P_L2R_FRAME)(prim->sdu.buf + (prim->sdu.o_buf>>3) + HEADER_LEN + i * (prim->data_size + HT_LEN)); } } primDesc->offset = 0; primDesc->off_status = 0; return (0); } /* +------------------------------------------------------------------------------ | Function : up_copy_data_from_rq +------------------------------------------------------------------------------ | Description : | | Parameters : buf - | len - | sa - | sb - | bytesCopied - | | Return : - +------------------------------------------------------------------------------ */ LOCAL void up_copy_data_from_rq(U8 *buf, U16 len, U8 *sa, U8 *sb, U16 *bytesCopied) { T_UP *dup = &l2r_data->up; register ULONG i; register T_P_UBYTE pFrame; register T_P_UBYTE pBuf; register T_P_UBYTE pStat; T_P_RLP_REMAP_DATA_IND prim; T_P_L2R_FRAME frame; T_P_UBYTE pEnd; USHORT bytesToCopy; USHORT blocklen; UBYTE statOct; UBYTE lastState; T_RPRIM_DESCRIPTOR *primDesc = &dup->QRemapPrimDesc; #ifdef _SIMULATION_ TRACE_FUNCTION ("up_copy_data_from_rq()"); #endif bytesToCopy = len; if (primDesc->prim EQ NULL) { prim = dup->QRemap[dup->QRemapRead]; primDesc->prim = prim; primDesc->nFr = prim->sdu.l_buf / ((prim->data_size<<3) + HT_LEN); primDesc->index = 0; primDesc->offset = 0; primDesc->off_status = 0; for (i = 0; i < primDesc->nFr; i++) { primDesc->adr[i] = (T_P_L2R_FRAME)(prim->sdu.buf + (prim->sdu.o_buf>>3) + HEADER_LEN + i * (prim->data_size + HT_LEN)); } } /* skip empty primitive */ if (primDesc->nFr EQ 0) { *bytesCopied = 0; return; } frame = primDesc->adr[primDesc->index]; /* point to current l2r frame in primitive */ pBuf = buf; /* point to destination buffer */ pFrame = &((*frame)[primDesc->offset]); pStat = &((*frame)[primDesc->off_status]); if (pFrame EQ pStat) { /* current byte is status octet */ dup->BRemapLastState = *pFrame & SO_STATUS_BITS_MASK; } lastState = dup->BRemapLastState; *sa = GET_SO_SA_BIT(lastState); *sb = GET_SO_SB_BIT(lastState); /************************************************************************************ * loop until either * - no more data are available or * - status in L2R frame changes or * - buffer for data is full ************************************************************************************/ for (;;) { #ifdef _SIMULATION_ TRACE_FUNCTION ("loop"); #endif blocklen = pStat - pFrame; if (blocklen EQ 0) { /* * current byte is status octet * (only in the first pass of the loop, there may be no status octet) */ /***************************** * evaluate status bits *****************************/ statOct = *pFrame; if (lastState NEQ (statOct & SO_STATUS_BITS_MASK)) { /* * status has changed. We have to stop, * since only one state can be transmitted to the upper layer */ primDesc->offset = primDesc->off_status = pFrame - (T_P_UBYTE)frame; *bytesCopied = len - bytesToCopy; return; } pFrame++; /************************************ * evaluate addrss bits ************************************/ statOct &= SO_ADR_MASK; switch (statOct) { case SO_BREAK_ACK: case SO_BREAK_REQ: case SO_END_EMPTY: /* no more data in this frame */ if (up_next_remap_frame(primDesc) EQ 1) { /* no more data available */ *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frame = primDesc->adr[primDesc->index]; pFrame = (T_P_UBYTE)frame; pStat = (T_P_UBYTE)frame; continue; /* continue with next frame */ case SO_END_FULL: pStat = &((*frame)[primDesc->prim->data_size]); blocklen = pStat - pFrame; break; case SO_TWO_OCTET: blocklen = *pFrame++ & SO_ADR_MASK_TWO_OCT; pStat = pFrame + blocklen; break; default: blocklen = statOct; pStat = pFrame + blocklen; break; } } if (bytesToCopy < blocklen) { /*************************************** * There is not enough space in the * buffer to copy the complete block ***************************************/ pEnd = pFrame + bytesToCopy; while (pFrame < pEnd) { *pBuf++ = *pFrame++; } if (pFrame EQ &((*frame)[primDesc->prim->data_size])) { /* end of frame reached */ up_next_remap_frame(primDesc); } else { primDesc->offset = pFrame - (T_P_UBYTE)frame; primDesc->off_status = pStat - (T_P_UBYTE)frame; } *bytesCopied = len; /* this much data could be copied */ return; } else { /*************************************** * Copy the complete block ***************************************/ bytesToCopy -= blocklen; while (pFrame < pStat) { *pBuf++ = *pFrame++; } if (pFrame EQ &((*frame)[primDesc->prim->data_size])) { /* end of frame reached */ if (up_next_remap_frame(primDesc) EQ 1) { /* no more data available */ *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frame = primDesc->adr[primDesc->index]; pFrame = (T_P_UBYTE)frame; pStat = (T_P_UBYTE)frame; } if (bytesToCopy EQ 0) { primDesc->offset = pFrame - (T_P_UBYTE)frame; primDesc->off_status = pStat - (T_P_UBYTE)frame; *bytesCopied = len; /* this much data could be copied */ return; } } } } /* +------------------------------------------------------------------------------ | Function : up_fill_in_status_octet +------------------------------------------------------------------------------ | Description : local function, which is used patch a status octet into a | l2r frame. This function takes into acount the two octet | format for 14400. | | Parameters : pFrame - points to begin of l2r frame | offstat1 - offset of status octet to be patched | offstat2 - offset of next status octet | | Return : +------------------------------------------------------------------------------ */ LOCAL BOOL up_fill_in_status_octet(T_P_UBYTE pFrame, UBYTE offstat1, UBYTE offstat2) { register T_P_UBYTE pStat, pSrc, pDes, pEnd; register UBYTE dataLen; dataLen = offstat2 - offstat1 - 1; /* number of data bytes between status octets */ pStat = pFrame + offstat1; if (dataLen <= DATA_SIZE_SHORT-2) { *pStat |= dataLen; return (FALSE); } else { /* this is only possible with 14400 */ if (offstat2 < DATA_SIZE_LONG - 1) { /* a two octet status must be inserted */ pSrc = pFrame + offstat2; pDes = pSrc + 1; pEnd = pFrame + offstat1; while (pSrc > pEnd) { *--pDes = *--pSrc; } *pStat |= SO_TWO_OCTET; pStat++; *pStat = dataLen; } else { /* a additional status octet (FULL) must be inserted somewhere in the frame */ pSrc = pFrame + offstat2; pDes = pSrc + 1; pEnd = pFrame + offstat1 + DATA_SIZE_SHORT - 1; while (pSrc > pEnd) { *--pDes = *--pSrc; } *pStat |= DATA_SIZE_SHORT - 2; *pEnd = *pStat & SO_STATUS_BITS_MASK | SO_END_FULL; } return (TRUE); } } /* +------------------------------------------------------------------------------ | Function : up_next_frame +------------------------------------------------------------------------------ | Description : local function, which is used by up_copy_data_into_l2r to | advance to the next frame in the primitive | The variables primDesc, frame and pFrame of the calling function | are updated. Moreover the return values of the calling function | primToSend and bytesCopied are set. | | | Parameters : primDesc - | primToSend - | | Return : +------------------------------------------------------------------------------ */ LOCAL UBYTE up_next_frame(T_P_UPRIM_DESCRIPTOR *primDesc, BOOL *primToSend) { T_UP *dup = &l2r_data->up; TRACE_FUNCTION("up_next_frame()"); (*primDesc)->index++; (*primDesc)->offset = 0; if ((*primDesc)->index >= dup->FramesPerPrim) /* primitive is filled */ { (*primDesc)->full = TRUE; *primToSend = TRUE; cl_ribu_write_index(&dup->RiBu.idx); /* point to next primitive */ if (dup->RiBu.alloc EQ dup->RiBu.idx.wi) { /* no primitive is ready */ return (1); } /* point to next primitive descriptor */ *primDesc = dup->RiBu.primDesc[dup->RiBu.idx.wi]; (*primDesc)->index = 0; } return (0); } LOCAL void up_copy_data_into_l2r(U8 *buf, U16 len, U8 sa, U8 sb, U8 x, BOOL *primToSend, U16 *bytesCopied) { T_UP *dup = &l2r_data->up; T_P_UPRIM_DESCRIPTOR primDesc; T_P_L2R_FRAME frame; register T_P_UBYTE pFrame; register T_P_UBYTE pEnd; register T_P_UBYTE pBuf; USHORT bytesToCopy; UBYTE frameCount; T_FLOW flow = FL_INVALID; #ifdef _SIMULATION_ TRACE_FUNCTION ("up_copy_data_into_l2r()"); #endif switch (x) { case DTI_FLOW_ON: flow = FL_INACTIVE; break; case DTI_FLOW_OFF: flow = FL_ACTIVE; break; } #ifdef _TARGET_ if (dup->DataSize > DATA_SIZE_SHORT) { frameCount = 1; } else { frameCount = 2; } #else { frameCount = 100; } #endif up_store_status(sa, sb, flow); if (dup->LastSentFlow EQ dup->MrgFlow) { *primToSend = FALSE; } else { *primToSend = TRUE; } /* don't copy into primitive if no primitive is ready */ if (dup->RiBu.alloc EQ dup->RiBu.idx.wi) { *bytesCopied = 0; return; } bytesToCopy = len; primDesc = dup->RiBu.primDesc[dup->RiBu.idx.wi]; /* point to current primitive descriptor */ frame = (*primDesc->adr)[primDesc->index]; /* point to current l2r frame in primitive */ pFrame = &(*frame)[primDesc->offset]; /* point to current byte in frame */ pBuf = buf; /* point to source buffer */ /************************************************************************************ * * Handle a partly filled frame, which has been written in the primitive previously * ************************************************************************************/ if (primDesc->offset NEQ 0) { /* partly filled frame is there */ if (bytesToCopy EQ 0) /* no data to copy -> quit without writing status octet */ { *bytesCopied = len; return; } if (sa NEQ primDesc->sa OR sb NEQ primDesc->sb) { /* * status has changed since last time */ /* finish previous status octet */ if ( up_fill_in_status_octet( (T_P_UBYTE)frame, primDesc->off_status, primDesc->offset ) ) { /* frame data has been moved to make space for two octet status */ pFrame++; (primDesc->offset)++; if (primDesc->offset >= (dup->DataSize)) { /* frame is just filled by patching the previous status frame */ if (up_next_frame(&primDesc, primToSend) EQ 1) { /* no more space for data */ *bytesCopied = 0; /* no data could be copied */ return; } frameCount--; #ifdef _TARGET_ if (frameCount EQ 0) { *bytesCopied = 0; /* no data could be copied */ return; } #endif frame = (*primDesc->adr)[primDesc->index]; /* point to current l2r frame in primitive */ pFrame = &(*frame)[primDesc->offset]; /* point to current byte in frame */ } } if (primDesc->offset NEQ 0) { /* write status octet */ *pFrame++ = (U8)(sa << SO_SA_BIT | sb << SO_SB_BIT | 0 << SO_X_BIT); /* x is set to 0 (inactive) by default */ /* store current status for next call */ primDesc->sa = sa; primDesc->sb = sb; primDesc->off_status = primDesc->offset; (primDesc->offset)++; if (primDesc->offset >= (dup->DataSize)) { /* frame is just filled by the status octet */ /* finish previous status octet */ (*frame)[primDesc->off_status] |= SO_END_EMPTY; if (up_next_frame(&primDesc, primToSend) EQ 1) { /* no more space for data */ *bytesCopied = 0; /* no data could be copied */ return; } frameCount--; if (frameCount EQ 0) { *bytesCopied = 0; /* no data could be copied */ return; } frame = (*primDesc->adr)[primDesc->index]; /* point to current l2r frame in primitive */ pFrame = &(*frame)[primDesc->offset]; /* point to current byte in frame */ } } } /* * write data into partly filled frame */ if (primDesc->offset NEQ 0) { if (bytesToCopy >= dup->DataSize - primDesc->offset) { /* enough data to fill frame completly */ for (pEnd = pFrame + dup->DataSize - primDesc->offset; pFrame < pEnd; ) { *pFrame++ = *pBuf++; } /* finish previous status octet */ (*frame)[primDesc->off_status] |= SO_END_FULL; bytesToCopy -= dup->DataSize - primDesc->offset; if (up_next_frame(&primDesc, primToSend) EQ 1) { /* no more space for data */ *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frameCount--; if (frameCount EQ 0) { *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frame = (*primDesc->adr)[primDesc->index]; /* point to current l2r frame in primitive */ pFrame = &(*frame)[primDesc->offset]; /* point to current byte in frame */ } else { /* not enough data to fill frame completly */ for (pEnd = pFrame + bytesToCopy; pFrame < pEnd; ) { *pFrame++ = *pBuf++; } primDesc->offset += bytesToCopy; *bytesCopied = len; return; /* Nothing else to do */ } } } /************************************************************************************ * * Handle consecutive frames, which are filled starting with byte 0 * ************************************************************************************/ while (bytesToCopy > 0) { if (bytesToCopy >= dup->DataSize - 1) { /* * There are enough data to fill a frame completely */ *pFrame++ = sa << SO_SA_BIT | sb << SO_SB_BIT | 0 << SO_X_BIT | SO_END_FULL; /* x is set to 0 (inactive) by default */ /* store current status for next call */ primDesc->sa = sa; primDesc->sb = sb; for (pEnd = pFrame + dup->DataSize - 1; pFrame < pEnd; ) { *pFrame++ = *pBuf++; } bytesToCopy -= dup->DataSize - 1; /* advance to next frame */ if (up_next_frame(&primDesc, primToSend) EQ 1) { /* running out of primitives */ *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frameCount--; if (frameCount EQ 0) { *bytesCopied = len - bytesToCopy; /* this much data could be copied */ return; } frame = (*primDesc->adr)[primDesc->index]; /* point to current l2r frame in primitive */ pFrame = &(*frame)[primDesc->offset]; /* point to current byte in frame */ } else { /* * There are some data, but not enough to fill a frame completely */ *pFrame++ = (U8)(sa << SO_SA_BIT | sb << SO_SB_BIT | 0 << SO_X_BIT); /* x is set to 0 (inactive) by default */ /* store current status for next call */ primDesc->sa = sa; primDesc->sb = sb; for (pEnd = pFrame + bytesToCopy; pFrame < pEnd; ) { *pFrame++ = *pBuf++; } primDesc->off_status = 0; primDesc->offset = bytesToCopy + 1; bytesToCopy = 0; } } *bytesCopied = len; } /* +------------------------------------------------------------------------------ | Function : up_copy_remap_data +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ LOCAL void up_copy_remap_data(void) { T_UP *dup = &l2r_data->up; USHORT bytesCopied; BOOL dummy; #ifdef _SIMULATION_ TRACE_FUNCTION ("up_copy_remap_data()"); #endif do { if (dup->BRemapLen EQ 0) { dup->BRemapAdr = dup->BRemap; up_copy_data_from_rq ( dup->BRemapAdr, UP_REMAP_BUFFER_SIZE, &dup->BRemapSa, &dup->BRemapSb, &dup->BRemapLen ); if (dup->BRemapLen EQ 0) { up_check_flow(); return; } } up_copy_data_into_l2r ( dup->BRemapAdr, dup->BRemapLen, dup->BRemapSa, dup->BRemapSb, DTI_FLOW_OFF, &dummy, &bytesCopied ); dup->BRemapAdr += bytesCopied; dup->BRemapLen -= bytesCopied; } while (bytesCopied NEQ 0); } /* +------------------------------------------------------------------------------ | Function : up_check_alloc +------------------------------------------------------------------------------ | Description : This procedure allocates new primitives until there are | UP_RIBU_PREALLOC primitives ready. | | I.e.: alloc = write + UP_RIBU_PREALLOC | | It may be less than this, if otherwise the alloc pointer | would reach the read pointer. | | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_check_alloc(void) { T_UP *dup = &l2r_data->up; S8 i_from, i_to; TRACE_FUNCTION ("up_check_alloc()"); i_to = dup->RiBu.idx.ri - dup->RiBu.idx.wi - 1; if (i_to < 0) { i_to = i_to + dup->RiBu.idx.depth; } if (i_to > UP_RIBU_PREALLOC) { i_to = UP_RIBU_PREALLOC; } i_from = dup->RiBu.alloc - dup->RiBu.idx.wi; if (i_from < 0) { i_from = i_from + dup->RiBu.idx.depth; } if (i_from >= i_to) { return; } do { up_alloc_prim(); i_from++; } while (i_from < i_to); if (dup->QRemapRead NEQ dup->QRemapWrite) { up_copy_remap_data(); return; } switch (GET_STATE (UP_UL)) { case IW_WAIT: break; case IW_IDLE: if (dup->StoreDataActive EQ FALSE AND dup->Prim NEQ NULL) { up_store_data(); } break; } } /* +------------------------------------------------------------------------------ | Function : up_check_flow +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_check_flow(void) { T_UP *dup = &l2r_data->up; U8 primCount; TRACE_FUNCTION ("up_check_flow()"); if (!dup->FlowCtrlUsed) { return; } primCount = dup->RiBu.idx.filled; switch (dup->UpFlow) { case FL_ACTIVE: if (primCount < dup->FlowThreshLo) { dup->UpFlow = FL_INACTIVE; } else { return; } break; case FL_INACTIVE: if (primCount >= dup->FlowThreshHi) { dup->UpFlow = FL_ACTIVE; } else { return; } break; } sig_up_dn_flow(dup->UpFlow); } /* +------------------------------------------------------------------------------ | Function : up_store_data +------------------------------------------------------------------------------ | Description : This procedure copies data from a dti_data_req primitive | into the uplink ring buffer. | | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_store_data(void) { T_UP *dup = &l2r_data->up; T_P_UBYTE adr; USHORT len; BOOL primToSend; USHORT bytesCopied; USHORT i, j; T_desc2 *desc; TRACE_FUNCTION ("up_store_data()"); dup->StoreDataActive = TRUE; do { desc = (T_desc2*)dup->Prim->desc_list2.first; if (desc) { len = desc->len; adr = desc->buffer; } else { len = 0; adr = NULL; } up_copy_data_into_l2r (adr, len, dup->Prim->parameters.st_lines.st_line_sa, dup->Prim->parameters.st_lines.st_line_sb, dup->Prim->parameters.st_lines.st_flow, &primToSend, &bytesCopied); dup->Prim->desc_list2.list_len -= bytesCopied; if (desc) { if ((bytesCopied EQ len)) { /* * Block has been copied successfully */ dup->Prim->desc_list2.first = desc->next; MFREE (desc); } else if (bytesCopied > 0) { /* * remaining data must be copied to begin of block */ /*lint -e{661} (Warning -- Likely creation of out-of-bounds) */ for (i=0, j = bytesCopied; j < len; i++, j++) { desc->buffer[i] = desc->buffer[j]; } desc->len -= bytesCopied; } } up_check_alloc(); } while (dup->Prim->desc_list2.first NEQ 0 AND dup->RiBu.alloc NEQ dup->RiBu.idx.wi); if (dup->Prim->desc_list2.first EQ 0) { PFREE (dup->Prim); dup->Prim = NULL; up_send_ready(); } dup->StoreDataActive = FALSE; } /* +------------------------------------------------------------------------------ | Function : up_send_ready +------------------------------------------------------------------------------ | Description : only used in test environment | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_ready(void) { TRACE_FUNCTION ("up_send_ready()"); if (GET_STATE (UP_UL) EQ IW_IDLE) { if (l2r_data->up.DtiConnected EQ FALSE) { TRACE_EVENT("DTI not connected, but up_send_ready() called -> break"); return; /* jk: DTI_READY_IND primitive cannot be sent when DTI disconnected (!) */ } dti_start ( l2r_hDTI, L2R_DTI_UP_DEF_INSTANCE, L2R_DTI_UP_INTERFACE, L2R_DTI_UP_CHANNEL ); SET_STATE (UP_UL, IW_WAIT); } } LOCAL void clear_primDesc(T_P_UPRIM_DESCRIPTOR primDesc) { primDesc->prim = NULL; primDesc->nFr = 0; primDesc->index = 0; primDesc->offset = 0; primDesc->off_status = 0; primDesc->full = FALSE; primDesc->sa = FL_INACTIVE; primDesc->sb = FL_INACTIVE; } /* +------------------------------------------------------------------------------ | Function : up_free_prim +------------------------------------------------------------------------------ | Description : | | Parameters : primDesc | | | Return : - +------------------------------------------------------------------------------ */ LOCAL void up_free_prim(T_P_UPRIM_DESCRIPTOR primDesc) { TRACE_FUNCTION ("up_free_prim()"); if (primDesc->prim NEQ NULL) { PFREE (primDesc->prim); clear_primDesc(primDesc); } } /* +------------------------------------------------------------------------------ | Function : up_deinit_ribu +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_deinit_ribu(void) { T_UP *dup = &l2r_data->up; T_PRIM_DESC_RIBU_INDEX n; T_P_UPRIM_DESCRIPTOR primDesc; TRACE_FUNCTION ("up_deinit_ribu()"); for (n = 0; n < dup->RiBu.idx.depth; n++) { primDesc = dup->RiBu.primDesc[n]; if (primDesc->prim NEQ NULL) { up_free_prim(primDesc); } } if (GET_STATE (UP_LL) EQ ISW_SEND) { SET_STATE (UP_LL, ISW_IDLE); } } /* +------------------------------------------------------------------------------ | Function : up_send_status +------------------------------------------------------------------------------ | Description : | | Parameters : sa - | sb - | flow - | adr - | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_status ( T_BIT sa, T_BIT sb, T_FLOW flow, UBYTE adr ) { T_UP *dup = &l2r_data->up; T_P_UPRIM_DESCRIPTOR primDesc; T_P_L2R_FRAME frame; T_BIT x = 0; TRACE_FUNCTION ("up_send_status()"); primDesc = dup->RiBu.primDesc[dup->RiBu.idx.wi]; frame = (*primDesc->adr)[0]; switch (flow) { case FL_ACTIVE: x = 1; break; case FL_INACTIVE: x = 0; break; } (*frame)[0] = sa << SO_SA_BIT | sb << SO_SB_BIT | x << SO_X_BIT | adr; /* jk:030501 - TEST CASE 251 - new funktion parameter 'adr' was introduced in order to cancel the older function 'up_send_break(...)' */ primDesc->sa = sa; /* the status has to be saved in order to be correctly stored later */ primDesc->sb = sb; /* on into "dup->LastSentSa/Sb" [up_send current_prim()] */ primDesc->index = 1; primDesc->offset = 0; cl_ribu_write_index(&dup->RiBu.idx); /* point to next primitive */ } /* +------------------------------------------------------------------------------ | Function : up_set_flow_in_prim +------------------------------------------------------------------------------ | Description : | | Parameters : prim - | | | Return : - +------------------------------------------------------------------------------ */ LOCAL void up_set_flow_in_prim(T_P_RLP_DATA_REQ prim) { T_UP *dup = &l2r_data->up; if (dup->MrgFlow EQ FL_INACTIVE) { TRACE_FUNCTION ("up_set_flow_in_prim(INACTIVE)"); } else { T_PRIM_INDEX frames; T_PRIM_INDEX ind; UBYTE off; register UBYTE statOct; T_P_L2R_FRAME frame; TRACE_FUNCTION ("up_set_flow_in_prim(ACTIVE)"); frames = prim->sdu.l_buf / (8 * dup->FrameSize); frame = (T_P_L2R_FRAME) (prim->sdu.buf + (prim->sdu.o_buf / 8) + HEADER_LEN); off = 0; ind = 0; while (ind < frames) { statOct = (*frame)[off]; SET_BIT(statOct, SO_X_BIT); (*frame)[off] = statOct; switch (statOct & SO_ADR_MASK) { case SO_BREAK_REQ: case SO_BREAK_ACK: case SO_END_EMPTY: case SO_END_FULL: ind++; frame = (T_P_L2R_FRAME)((UBYTE*)frame + dup->FrameSize); off = 0; break; case SO_TWO_OCTET: off++; off += ((*frame)[off] & SO_ADR_MASK_TWO_OCT) + 1; if (off >= dup->DataSize) { ind++; frame = (T_P_L2R_FRAME)((UBYTE*)frame + dup->FrameSize); off = 0; } break; default: off += (statOct & SO_ADR_MASK) + 1; if (off >= dup->DataSize) { ind++; frame = (T_P_L2R_FRAME)((UBYTE*)frame + dup->FrameSize); off = 0; } break; } } } dup->LastSentFlow = dup->MrgFlow; } /* +------------------------------------------------------------------------------ | Function : up_send_current_prim +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_current_prim(void) { T_UP *dup = &l2r_data->up; T_P_UPRIM_DESCRIPTOR primDesc = dup->RiBu.primDesc[dup->RiBu.idx.ri]; TRACE_FUNCTION ("up_send_current_prim()"); if (!primDesc->full AND primDesc->index < primDesc->nFr) { TRACE_FUNCTION ("prim is not full"); if (primDesc->offset > 0) { if (up_fill_in_status_octet((T_P_UBYTE)(*primDesc->adr)[primDesc->index], primDesc->off_status, primDesc->offset)) { primDesc->offset++; if (primDesc->offset >= dup->DataSize) { primDesc->offset = 0; primDesc->index++; } } } if (primDesc->offset > 0 OR primDesc->index EQ 0) { /* * Add status octet, if there is a partly filled frame * or if status has changed since last write */ (*(*primDesc->adr)[primDesc->index])[primDesc->offset] = dup->LastRcvdSa << SO_SA_BIT | dup->LastRcvdSb << SO_SB_BIT | 0 << SO_X_BIT | SO_END_EMPTY; primDesc->sa = dup->LastRcvdSa; primDesc->sb = dup->LastRcvdSb; primDesc->index++; } primDesc->prim->sdu.l_buf = primDesc->index * dup->FrameSize * 8; } dup->LastSentSa = primDesc->sa; dup->LastSentSb = primDesc->sb; up_set_flow_in_prim(primDesc->prim); PSENDX (RLP, primDesc->prim); clear_primDesc(primDesc); /* this primitive doesn't belong to us any longer */ cl_ribu_read_index(&dup->RiBu.idx); /* point to next primitive */ dup->UrgentMsg = FALSE; up_check_alloc(); up_check_flow(); } /* +------------------------------------------------------------------------------ | Function : up_send_prim_cond +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_prim_cond(void) { TRACE_FUNCTION ("up_send_prim_cond()"); switch (GET_STATE (UP_LL)) { case ISW_WAIT: TIMERSTOP (TIMER_TUP_SND); up_send_current_prim(); SET_STATE (UP_LL, ISW_IDLE); break; default: l2r_data->up.UrgentMsg = TRUE; up_check_flow(); up_check_alloc(); SET_STATE (UP_LL, ISW_SEND); break; } } /* +------------------------------------------------------------------------------ | Function : up_init_ribu +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_init_ribu(void) { T_UP *dup = &l2r_data->up; T_PRIM_DESC_RIBU_INDEX n; T_PRIM_INDEX m; TRACE_FUNCTION ("up_init_ribu()"); dup->RiBu.alloc = 0; cl_ribu_init(&dup->RiBu.idx, dup->RiBu.idx.depth); for (n = 0; n < dup->RiBu.idx.depth; n++) { dup->RiBu.primDesc[n] = &(dup->PrimDesc[n]); dup->PrimDesc[n].nFr = 0; dup->PrimDesc[n].adr = (T_P_ADR_VECTOR)&(dup->AdrVec[n]); dup->PrimDesc[n].index = 0; dup->PrimDesc[n].offset = 0; dup->PrimDesc[n].off_status = 0; dup->PrimDesc[n].full = FALSE; dup->PrimDesc[n].sa = FL_INACTIVE; dup->PrimDesc[n].sb = FL_INACTIVE; dup->PrimDesc[n].prim = NULL; for(m = 0;m < L2R_FRAMES_PER_PRIM_MAX; m++) { dup->AdrVec[n][m] = NULL; } if (dup->RiBu.alloc < UP_RIBU_PREALLOC) { up_alloc_prim(); } } } /* +------------------------------------------------------------------------------ | Function : up_store_status +------------------------------------------------------------------------------ | Description : | | Parameters : sa | sb | flow | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_store_status ( T_BIT sa, T_BIT sb, T_FLOW flow ) { T_UP *dup = &l2r_data->up; #ifdef _SIMULATION_ TRACE_FUNCTION ("up_store_status()"); #endif dup->LastRcvdSa = sa; dup->LastRcvdSb = sb; if (dup->FlowCtrlUsed EQ FALSE OR flow EQ dup->ULFlow) { return; } dup->ULFlow = flow; up_merge_flow(); sig_up_dn_ul_flow(dup->ULFlow); } /* +------------------------------------------------------------------------------ | Function : up_send_empty_frame +------------------------------------------------------------------------------ | Description : | | Parameters : sa - | sb - | flow - | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_send_empty_frame(T_BIT sa, T_BIT sb, T_FLOW flow) { T_UP *dup = &l2r_data->up; T_BIT x = 0; USHORT sduSize = dup->FrameSize << 3; PALLOC_SDU(data_req, RLP_DATA_REQ, sduSize); TRACE_FUNCTION ("up_send_empty_frame()"); #ifdef _SIMULATION_ /* Clear SDU for test environment */ { UBYTE *p; UBYTE *pend; p = &data_req->sdu.buf[0]; pend = p + dup->FrameSize; while (p < pend) { *p++ = 0; } } #endif data_req->sdu.o_buf = 0; data_req->sdu.l_buf = sduSize; switch (flow) { case FL_ACTIVE: x = 1; break; case FL_INACTIVE: x = 0; break; } /*lint -e416 (Warning -- Likely creation of out-of-bounds pointer) */ /*lint -e415 (Warning -- Likely access of out-of-bounds pointer) */ data_req->sdu.buf[L2R_ENCODING_OFFSET] = sa << SO_SA_BIT | sb << SO_SB_BIT | x << SO_X_BIT | SO_END_EMPTY; /*lint +e416 (Warning -- Likely creation of out-of-bounds pointer) */ /*lint +e415 (Warning -- Likely access of out-of-bounds pointer) */ dup->LastSentFlow = flow; dup->LastSentSa = sa; dup->LastSentSb = sb; PSENDX (RLP, data_req); } /* +------------------------------------------------------------------------------ | Function : up_merge_flow +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_merge_flow(void) { T_UP *dup = &l2r_data->up; #ifdef _SIMULATION_ TRACE_FUNCTION ("up_merge_flow()"); #endif if (dup->FlowCtrlUsed AND (dup->DnFlow EQ FL_ACTIVE OR dup->ULFlow EQ FL_ACTIVE)) { /* flow control active */ dup->MrgFlow = FL_ACTIVE; } else { /* flow control inactive */ dup->MrgFlow = FL_INACTIVE; } } /* +------------------------------------------------------------------------------ | Function : up_rq_init +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : - +------------------------------------------------------------------------------ */ GLOBAL void up_rq_init(void) { #ifdef _SIMULATION_ TRACE_FUNCTION ("up_rq_init()"); #endif l2r_data->up.QRemapWrite = 0; l2r_data->up.QRemapRead = 0; } /* +------------------------------------------------------------------------------ | Function : up_some_data_to_send +------------------------------------------------------------------------------ | Description : | | Parameters : - | | | Return : TRUE - | FALSE - +------------------------------------------------------------------------------ */ GLOBAL BOOL up_some_data_to_send(void) { T_UP *dup = &l2r_data->up; #ifdef _SIMULATION_ TRACE_EVENT ("check if any data to send"); #endif if ( dup->RiBu.idx.filled OR (dup->RiBu.primDesc[dup->RiBu.idx.ri]->index > 0) OR (dup->RiBu.primDesc[dup->RiBu.idx.ri]->offset > 0) OR (dup->LastRcvdSa NEQ dup->LastSentSa) OR (dup->LastRcvdSb NEQ dup->LastSentSb) ) { return (TRUE); } return (FALSE); }