FreeCalypso > hg > freecalypso-sw
view gsm-fw/ccd/csn1_sx.c @ 944:51f580665110
gsm-fw: C139 works with non-volatile FFS enabled
author | Mychaela Falconia <falcon@ivan.Harhan.ORG> |
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date | Sun, 01 Nov 2015 05:03:35 +0000 |
parents | 970d6199f2c5 |
children |
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/* +----------------------------------------------------------------------------- | Project : CCD | Modul : csn1_sx.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 : Definition of encoding and decoding functions for CSN1_S0 elements +----------------------------------------------------------------------------- */ /* * standard definitions like GLOBAL, UCHAR, ERROR etc. */ #include "typedefs.h" #include "header.h" /* * Prototypes of ccd (USE_DRIVER EQ undef) for prototypes only * look at ccdapi.h */ #undef USE_DRIVER #include "ccdapi.h" /* * Types and functions for bit access and manipulation */ #include "ccd_globs.h" #include "bitfun.h" /* * Prototypes of ccd internal functions */ #include "ccd.h" /* * Declaration of coder/decoder tables */ #include "ccdtable.h" #include "ccddata.h" /* * Need memory allocation functions for dynamic arrays (pointers) */ #ifdef DYNAMIC_ARRAYS #include "vsi.h" #include <string.h> #endif #ifndef RUN_FLASH /* +--------------------------------------------------------------------+ | PROJECT : CCD (6144) MODULE : CCD | | STATE : code ROUTINE : cdc_csn1_sx_decode | +--------------------------------------------------------------------+ PURPOSE : The encoded IE consists of one bit for presence flag and a value part. In case of CSN1_S1 only if the flag bit is equal 1 the value part will follow it. In case of CSN1_S0 only if the flag bit is equal 0 the value part will follow it. */ SHORT cdc_csn1_sx_decode (int flag, const ULONG e_ref, T_CCD_Globs *globs) { ULONG repeat, max_rep, act_offset; ULONG amount = 1; BOOL is_variable; ULONG cix_ref, num_prolog_steps, prolog_step_ref; #ifdef DYNAMIC_ARRAYS U8 *old_pstruct = NULL; U8 *addr = NULL; #endif #ifdef DEBUG_CCD #ifndef CCD_SYMBOLS TRACE_CCD (globs, "cdc_csn1_sx_decode()"); #else TRACE_CCD (globs, "cdc_csn1_sx_decode() %s", ccddata_get_alias((USHORT) e_ref, 1)); #endif #endif globs->SeekTLVExt = FALSE; cix_ref = melem[e_ref].calcIdxRef; num_prolog_steps = calcidx[cix_ref].numPrologSteps; prolog_step_ref = calcidx[cix_ref].prologStepRef; /* * If this element is conditional, check the condition. */ if (calcidx[cix_ref].numCondCalcs NEQ 0 AND ! ccd_conditionOK (e_ref, globs)) return 1; /* * If this element has a defined prologue * we have to process it before decoding the bitstream. */ if (num_prolog_steps) { ccd_performOperations (num_prolog_steps, prolog_step_ref, globs); } if (melem[e_ref].repType NEQ ' ') { is_variable = ccd_calculateRep (e_ref, &repeat, &max_rep, globs); /* Structured IE is to be handeled as bitstring.*/ if (melem[e_ref].repType == 's') { repeat--; } } else { is_variable = FALSE; repeat = 1; } #ifdef DYNAMIC_ARRAYS /* * Check for pointer types; allocate memory if necessary. * May overwrite globs->pstruct (and initialize globs->pstructOffs to 0). */ if ( is_pointer_type(e_ref) ) { U32 cSize; /* * Find size to allocate; * - Read from mcomp or mvar according to type */ cSize = (ULONG)((melem[e_ref].elemType EQ 'F' OR melem[e_ref].elemType EQ 'R') ? mvar[melem[e_ref].elemRef].cSize : mcomp[melem[e_ref].elemRef].cSize ) * repeat; /* * Allocate additional memory */ addr = (U8 *)DP_ALLOC( cSize, globs->alloc_head, DP_NO_FRAME_GUESS); /* If no memory, log error and return immediately */ if (addr EQ NULL) { ccd_setError (globs, ERR_NO_MEM, BREAK, (USHORT) -1); return 1; } else memset (addr, 0, (size_t)cSize); /* * Memory allocated; */ } #endif if (melem[e_ref].elemType NEQ 'S') { /* * Element is not a SPARE. Setup the struct pointer. */ globs->pstructOffs = melem[e_ref].structOffs; if (is_variable) { UBYTE *addr_v_xxx = NULL; UBYTE *addr_c_xxx; UBYTE act_continue_array; if (melem[e_ref].optional) { /* * For optional elements we must set the valid-flag, * if there is at least one element in the message. * Therefore we store the address of the valid flag. */ /* Dynamic array addition. * Postpone optional flag setting for non-code transparent * pointer types ('P', 'Q', 'R'). * For these types, the optional flag is the pointer itself. * These types cannot be set yet, as the pointer may be * preceeded by a counter octet, a union tag id octet etc. */ if (melem[e_ref].elemType < 'P' OR melem[e_ref].elemType > 'R') addr_v_xxx = (UBYTE *) (globs->pstruct + globs->pstructOffs++); } /* * For variable sized elements store the min-value * as counter into the C-Structure (c_xxx). */ addr_c_xxx = (UBYTE *) (globs->pstruct + globs->pstructOffs++); if (max_rep > 255) globs->pstructOffs++; /* * Store the initial offset */ act_offset = (ULONG) globs->pstructOffs; #ifdef DYNAMIC_ARRAYS if ( is_pointer_type(e_ref) ) { /* * 1. Save old "globs->pstruct" variables * 2. Store pointer to freshly allocated memory area in structure * 3. Initialize pstruct to point to the freshly allocated memory area. * 4. Initialize pstructOffs to 0 to start decoding at offset 0 * in the new memory area. */ old_pstruct = globs->pstruct; *(U8 **)(globs->pstruct + globs->pstructOffs) = addr; globs->pstruct = addr; globs->pstructOffs = 0; } #endif /* * repType ='i': * Repeat this element (if it is an array) until we detect a * flag indicating absence. * * repType ='v' and 'c': * Repeat the IE and leave the loop. * * In both cases we expect a 0 at first. */ if ((melem[e_ref].repType == 'v') || (melem[e_ref].repType == 'c')) { amount = repeat; } repeat = 0; act_continue_array = globs->continue_array; globs->continue_array = TRUE; while (globs->continue_array) { if (flag == 0xFF) /* CSN1_SH type*/ { if (bf_readBit(globs) != GET_HL_PREV(1)) break; } else { if (bf_readBit(globs) != flag) break; } /* * Flag is set, we must decode the element */ cdc_decodeElemvalue (e_ref, &amount, globs); if (++repeat > max_rep) { /* * Too many repetitions means error in encoded message. */ ccd_setError (globs, ERR_MAX_REPEAT, BREAK, (USHORT) (globs->bitpos), (USHORT) -1); return 1; } else if (melem[e_ref].repType EQ 'v') { repeat = amount; break; } /* * Recalculate the struct offset for repeatable IEs. */ if (is_variable_type(e_ref)) { globs->pstructOffs = (USHORT)(act_offset + (repeat * mvar[melem[e_ref].elemRef].cSize)); } else { globs->pstructOffs = (USHORT)(act_offset + (repeat * mcomp[melem[e_ref].elemRef].cSize)); } } globs->continue_array = act_continue_array; #ifdef DYNAMIC_ARRAYS /* * Restore globs->pstruct */ if (old_pstruct NEQ NULL) { globs->pstruct = old_pstruct; } #endif if (addr_v_xxx NEQ NULL) { /* * For optional elements set the valid-flag * In this case the pointer addr_c_xxx does not mark * the counter. It points to the valid flag. */ if (repeat > 0) *addr_v_xxx++ = (UBYTE) TRUE; } /* * Store the number of digits into the c_xxx variable if there is one. */ if (max_rep > 65535) { ULONG *addr_c_xxx_u32; addr_c_xxx_u32 = (ULONG *)addr_c_xxx; *addr_c_xxx_u32 = repeat; } else if (max_rep > 255) { USHORT *addr_c_xxx_u16; addr_c_xxx_u16 = (USHORT *)addr_c_xxx; *addr_c_xxx_u16 = (USHORT) repeat; } else *addr_c_xxx = (UBYTE) repeat; } /* * IE is not defined as an array. */ else { BOOL elemPresent; if (flag == 0xFF) elemPresent = (bf_readBit(globs) EQ GET_HL_PREV(1)); else elemPresent = (bf_readBit(globs) == flag); if (elemPresent) { if (melem[e_ref].optional) { /* * For optional elements set the valid-flag. */ globs->pstruct[globs->pstructOffs++] = (UBYTE) TRUE; } /* * Flag is set, we must decode the element. */ cdc_decodeElemvalue (e_ref, &repeat, globs); /* * process the epilogue expression for this element if there is any */ if (num_prolog_steps) { if ( (calc[prolog_step_ref+1].operation EQ 'K') || (calc[prolog_step_ref+1].operation EQ 'C') || (calc[prolog_step_ref+1].operation EQ 's')) { ccd_performOperations (num_prolog_steps, prolog_step_ref, globs); } } } } } return 1; } #endif /* !RUN_FLASH */ #ifndef RUN_FLASH /* +--------------------------------------------------------------------+ | PROJECT : CCD (6144) MODULE : CDC_GSM | | STATE : code ROUTINE : cdc_csn1_sx_encode | +--------------------------------------------------------------------+ PURPOSE : Encoding of the CSN1 element. 1) GSM Type CSN1 S1 element This element consists of a 1 bit valid flag and a value part. If the element is valid (the v_xxx components is TRUE in the decoded message) a 1 bit will be coded followed by the coding of the value part. Otherwise a 0 bit will be coded. 2) GSM Type CSN1 S0 element This element consists of a single bit valid flag and a value part, too. But in this case the presence flag is set to 0. If the element is present (the v_xxx component is TRUE in the decoded message) a 0 bit will be coded followed by the encoded value part. Otherwise a 1 bit will be encoded. */ SHORT cdc_csn1_sx_encode (int flag, const ULONG e_ref, T_CCD_Globs *globs) { ULONG i, repeat=1, amount=1; USHORT cSize = 0, startOffset; int elemPresent; ULONG cix_ref, num_prolog_steps, prolog_step_ref; #ifdef DYNAMIC_ARRAYS U8 *old_pstruct = NULL; #endif #ifdef DEBUG_CCD #ifndef CCD_SYMBOLS TRACE_CCD (globs, "cdc_csn1_sx_encode()"); #else TRACE_CCD (globs, "cdc_csn1_sx_encode() %s", ccddata_get_alias((USHORT) e_ref, 1)); #endif #endif cix_ref = melem[e_ref].calcIdxRef; num_prolog_steps = calcidx[cix_ref].numPrologSteps; prolog_step_ref = calcidx[cix_ref].prologStepRef; /* * If this element is conditional, check the condition. */ if (calcidx[cix_ref].numCondCalcs NEQ 0 AND ! ccd_conditionOK (e_ref, globs)) return 1; /* * If this element has a defined prologue * we have to process it before decoding the bitstream. */ if (num_prolog_steps) { ccd_performOperations (num_prolog_steps, prolog_step_ref, globs); } if (melem[e_ref].elemType NEQ 'S') { UBYTE act_continue_array; act_continue_array = globs->continue_array; globs->continue_array = TRUE; /* * Element is not a SPARE. * Setup the offset into the C-structure for this element */ globs->pstructOffs = melem[e_ref].structOffs; if (melem[e_ref].optional) { /* * For optional elements check the valid-flag in the C-struct. * Spare elements does not have a corresponding valid flag. */ /* Dynamic array addition. * Postpone optional flag setting for non-code transparent * pointer types ('P', 'Q', 'R'). * For these types, the optional flag is the pointer itself. * These types cannot be set yet, as the pointer may be * preceeded by a counter octet, a union tag id octet etc. */ if (melem[e_ref].elemType < 'P' OR melem[e_ref].elemType > 'R') { if (globs->pstruct[globs->pstructOffs++] == FALSE) { /* * The IE should not be present in the message so we code * a single bit * for CSN1_S1 as 0, * for CSN1_S0 as 1 and * for CSN1_SH as GET_HL(0) */ if (flag == 0xFF) elemPresent = GET_HL(0); else elemPresent = flag ^ 0x00000001; bf_writeBit (elemPresent, globs); return 1; } #ifdef DEBUG_CCD else if (globs->pstruct [melem[e_ref].structOffs] != TRUE) { TRACE_CCD (globs, "Ambiguous value for valid flag!\n...assumed 1 for ccdID=%d", e_ref); } #endif } } /* As a default amount =1 due to initialization. */ if (melem[e_ref].repType EQ 'i') { /* The actual number of elements belonging to the array is unknown. * The user should have written the desired number to the C-Structure * (c_xxx). CCD reads the number of these variable repeatable elements * out of this C-Structure (c_xxx) and encodes each element with a * preceeding bit set to '0'. The last element is followed by a bit * set to '1' to indicate the end of this array. * If the number of repeats given by the C-Structure exceeds the * allowed value (maxRepeat) CCD gives a warning! */ if (melem[e_ref].maxRepeat > 255) { ULONG count = (ULONG) (* (USHORT *)(globs->pstruct + globs->pstructOffs++)); repeat = MINIMUM (count, (ULONG) melem[e_ref].maxRepeat); if (repeat < count) ccd_recordFault (globs, ERR_MAX_REPEAT, CONTINUE, (USHORT) e_ref, globs->pstruct + globs->pstructOffs); } else { repeat = (ULONG) MINIMUM (globs->pstruct[globs->pstructOffs], melem[e_ref].maxRepeat); if ( repeat < (ULONG) (globs->pstruct[globs->pstructOffs]) ) ccd_recordFault (globs, ERR_MAX_REPEAT, CONTINUE, (USHORT) e_ref, globs->pstruct + globs->pstructOffs); } amount = 1; globs->pstructOffs++; } else if (melem[e_ref].repType EQ 'v') { /* The number of elements belonging to the array depends on the value * of another element. The user should have written this number to the * C-Structure (c_xxx). * CCD reads the number of these variable repeatable elements out of * this C-Structure (c_xxx). * If the number of repetitions given by the C-Structure exceeds the * allowed value (maxRepeat) CCD gives a warning! */ if (melem[e_ref].maxRepeat > 255) { ULONG count = (ULONG) (* (USHORT *)(globs->pstruct + globs->pstructOffs++)); amount = MINIMUM (count, (ULONG) melem[e_ref].maxRepeat); if (amount < count) ccd_recordFault (globs, ERR_MAX_REPEAT, CONTINUE, (USHORT) e_ref, globs->pstruct + globs->pstructOffs); } else { amount = (ULONG)MINIMUM (globs->pstruct[globs->pstructOffs], melem[e_ref].maxRepeat); if ( amount < (ULONG) (globs->pstruct[globs->pstructOffs]) ) ccd_recordFault (globs, ERR_MAX_REPEAT, CONTINUE, (USHORT) e_ref, globs->pstruct + globs->pstructOffs); } repeat = 1; globs->pstructOffs++; } else if (melem[e_ref].repType EQ 'c') { amount = (ULONG) melem[e_ref].maxRepeat; repeat = 1; } else if (melem[e_ref].repType == 's') { BOOL is_variable; ULONG max_rep; is_variable = ccd_calculateRep (e_ref, &repeat, &max_rep, globs); /* Substract one bit which will be spent on the (CSN.1) flag. */ amount = repeat - 1; repeat = 1; } if (melem[e_ref].repType EQ 'v' OR melem[e_ref].repType EQ 'i') { cSize = (USHORT)((melem[e_ref].elemType EQ 'V' OR melem[e_ref].elemType EQ 'R' OR melem[e_ref].elemType EQ 'F') ? mvar[melem[e_ref].elemRef].cSize : mcomp[melem[e_ref].elemRef].cSize ); startOffset = (USHORT) globs->pstructOffs; } /* Dynamic array addition. * Check for non-code transparent pointer types ('P', 'Q', 'R'). * For these types, the optional flag is the pointer itself. * ASSUMPTION: The pointer may be preceeded by a counter octet, * a union tag id octet etc., but it is up to CCDGEN to ensure * word alignment (by inserting alignment bytes). Therefore * we just read from globs->pstruct[globs->pstructOffs]. */ #ifdef DEBUG_CCD /* Check pointer alignment and re-align if necessary (should never happen) */ if ( is_pointer_type(e_ref) AND ((globs->pstructOffs & 3) NEQ 0)) { TRACE_CCD (globs, "cdc_csn1_sx_encode(): Pointer misaligned! pstruct=0x08x," " pstructOffs=0x%08x", globs->pstruct, globs->pstructOffs); globs->pstructOffs = (globs->pstructOffs + 3) & 3; } #endif #ifdef DYNAMIC_ARRAYS /* * Perform pointer dereference for pointer types. * Also, check optionality for these types. */ if ( is_pointer_type(e_ref) ) { U8 *deref_pstruct; /* Get pointer value */ deref_pstruct = *(U8 **)&globs->pstruct[globs->pstructOffs]; /* * Strictly speaking the 'D' to 'F' types should not need this * check (should have returned after the optionality check above), * but it will catch stray NULL pointers (or uninitialized * valid flags) */ if (ccd_check_pointer(deref_pstruct) != ccdOK ) { ccd_recordFault (globs, ERR_INVALID_PTR, BREAK, (USHORT) e_ref, &globs->pstruct[globs->pstructOffs]); return 1; } /* * Pointer not NULL; * 1. Save old globs->pstruct and assign pointer to globs->pstruct * as new base. * 2. Set pstructOffs to 0 (zero) as the next offset will start * in the new memory area. */ old_pstruct = globs->pstruct; globs->pstruct = deref_pstruct; startOffset = 0; } #endif /* DYNAMIC_ARRAYS */ for (i=0; i < repeat; i++) { /* * The IE should be present in the message so we code 0 bit. */ if (flag == 0xFF) elemPresent = GET_HL(1); else elemPresent = flag; bf_writeBit (elemPresent, globs); if (cSize) { /* * Calculate the offset if it is an array. */ globs->pstructOffs = (USHORT)(startOffset + (i * cSize)); } /* * Encode the value. */ cdc_encodeElemvalue (e_ref, amount, globs); } #ifdef DYNAMIC_ARRAYS if ( old_pstruct NEQ NULL ) globs->pstruct = old_pstruct; #endif if ((melem[e_ref].repType == 'i') && (globs->continue_array == TRUE)) { /* * For fields of variable length we code a 1 flag * to mark the end of the array. */ if (flag == 0xFF) elemPresent = GET_HL(0); else elemPresent = flag ^ 0x00000001; bf_writeBit (elemPresent, globs); } globs->continue_array = act_continue_array; } return 1; } #endif /* !RUN_FLASH */