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osmo-ttcn3-hacks
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osmo-ttcn3-hacks/library/RLCMAC_EncDec.cc

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#include <stdint.h>
#include <endian.h>
#include "RLCMAC_Types.hh"
#include "RLCMAC_Templates.hh"
#include "GSM_Types.hh"
/* Decoding of TS 44.060 GPRS RLC/MAC blocks, portions requiring manual functions
* beyond what TITAN RAW coder can handle internally.
*
* (C) 2017 by Harald Welte <laforge@gnumonks.org>
* All rights reserved.
*
* Released under the terms of GNU General Public License, Version 2 or
* (at your option) any later version.
*
* SPDX-License-Identifier: GPL-2.0-or-later
*/
namespace RLCMAC__Types {
/////////////////////
// INTENRAL HELPERS
/////////////////////
/* TS 04.60 10.3a.4.1.1 */
struct gprs_rlc_ul_header_egprs_1 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t r:1,
si:1,
cv:4,
tfi_hi:2;
uint8_t tfi_lo:3,
bsn1_hi:5;
uint8_t bsn1_lo:6,
bsn2_hi:2;
uint8_t bsn2_lo:8;
uint8_t cps:5,
rsb:1,
pi:1,
spare_hi:1;
uint8_t spare_lo:6,
dummy:2;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:2, cv:4, si:1, r:1;
uint8_t bsn1_hi:5, tfi_lo:3;
uint8_t bsn2_hi:2, bsn1_lo:6;
uint8_t bsn2_lo:8;
uint8_t spare_hi:1, pi:1, rsb:1, cps:5;
uint8_t dummy:2, spare_lo:6;
#endif
} __attribute__ ((packed));
/* TS 04.60 10.3a.4.2.1 */
struct gprs_rlc_ul_header_egprs_2 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t r:1,
si:1,
cv:4,
tfi_hi:2;
uint8_t tfi_lo:3,
bsn1_hi:5;
uint8_t bsn1_lo:6,
cps_hi:2;
uint8_t cps_lo:1,
rsb:1,
pi:1,
spare_hi:5;
uint8_t spare_lo:5,
dummy:3;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:2, cv:4, si:1, r:1;
uint8_t bsn1_hi:5, tfi_lo:3;
uint8_t cps_hi:2, bsn1_lo:6;
uint8_t spare_hi:5, pi:1, rsb:1, cps_lo:1;
uint8_t dummy:3, spare_lo:5;
#endif
} __attribute__ ((packed));
/* TS 04.60 10.3a.4.3.1 */
struct gprs_rlc_ul_header_egprs_3 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t r:1,
si:1,
cv:4,
tfi_hi:2;
uint8_t tfi_lo:3,
bsn1_hi:5;
uint8_t bsn1_lo:6,
cps_hi:2;
uint8_t cps_lo:2,
spb:2,
rsb:1,
pi:1,
spare:1,
dummy:1;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:2, cv:4, si:1, r:1;
uint8_t bsn1_hi:5, tfi_lo:3;
uint8_t cps_hi:2, bsn1_lo:6;
uint8_t dummy:1, spare:1, pi:1, rsb:1, spb:2, cps_lo:2;
#endif
} __attribute__ ((packed));
struct gprs_rlc_dl_header_egprs_1 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t usf:3,
es_p:2,
rrbp:2,
tfi_hi:1;
uint8_t tfi_lo:4,
pr:2,
bsn1_hi:2;
uint8_t bsn1_mid:8;
uint8_t bsn1_lo:1,
bsn2_hi:7;
uint8_t bsn2_lo:3,
cps:5;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:1, rrbp:2, es_p:2, usf:3;
uint8_t bsn1_hi:2, pr:2, tfi_lo:4;
uint8_t bsn1_mid:8;
uint8_t bsn2_hi:7, bsn1_lo:1;
uint8_t cps:5, bsn2_lo:3;
#endif
} __attribute__ ((packed));
struct gprs_rlc_dl_header_egprs_2 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t usf:3,
es_p:2,
rrbp:2,
tfi_hi:1;
uint8_t tfi_lo:4,
pr:2,
bsn1_hi:2;
uint8_t bsn1_mid:8;
uint8_t bsn1_lo:1,
cps:3,
dummy:4;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:1, rrbp:2, es_p:2, usf:3;
uint8_t bsn1_hi:2, pr:2, tfi_lo:4;
uint8_t bsn1_mid:8;
uint8_t dummy:4, cps:3, bsn1_lo:1;
#endif
} __attribute__ ((packed));
struct gprs_rlc_dl_header_egprs_3 {
#if __BYTE_ORDER == __LITTLE_ENDIAN
uint8_t usf:3,
es_p:2,
rrbp:2,
tfi_hi:1;
uint8_t tfi_lo:4,
pr:2,
bsn1_hi:2;
uint8_t bsn1_mid:8;
uint8_t bsn1_lo:1,
cps:4,
spb:2,
dummy:1;
#else
/* auto-generated from the little endian part above (libosmocore/contrib/struct_endianess.py) */
uint8_t tfi_hi:1, rrbp:2, es_p:2, usf:3;
uint8_t bsn1_hi:2, pr:2, tfi_lo:4;
uint8_t bsn1_mid:8;
uint8_t dummy:1, spb:2, cps:4, bsn1_lo:1;
#endif
} __attribute__ ((packed));
/*
static const char hex_chars[] = "0123456789abcdef";
void printbuffer(const char* ptr, TTCN_Buffer& buf) {
int len = buf.get_len();
const unsigned char* cbuf = buf.get_data();
fprintf(stderr, "printbuffer %s (len=%d): [", ptr, len);
for (int i = 0; i < len; i++) {
fprintf(stderr, " %c%c", hex_chars[cbuf[i] >> 4], hex_chars[cbuf[i] & 0xf]);
}
fprintf(stderr, " ]\n");
}
*/
static CodingScheme::enum_type payload_len_2_coding_scheme(size_t payload_len) {
switch (payload_len) {
case 23:
return CodingScheme::CS__1;
case 34:
return CodingScheme::CS__2;
case 40:
return CodingScheme::CS__3;
case 54:
return CodingScheme::CS__4;
case 27:
return CodingScheme::MCS__1;
case 33:
return CodingScheme::MCS__2;
case 42:
return CodingScheme::MCS__3;
case 49:
return CodingScheme::MCS__4;
case 60: /* fall through */
case 61:
return CodingScheme::MCS__5;
case 78: /* fall through */
case 79:
return CodingScheme::MCS__6;
case 118: /* fall through */
case 119:
return CodingScheme::MCS__7;
case 142: /* fall through */
case 143:
return CodingScheme::MCS__8;
case 154: /* fall through */
case 155:
return CodingScheme::MCS__9;
default:
fprintf(stderr, "ERROR: Unknown CodingSCheme for payload_len=%zu\n", payload_len);
return CodingScheme::CS__1;
}
}
static unsigned int coding_scheme_2_data_block_len(CodingScheme::enum_type mcs) {
switch (mcs) {
case CodingScheme::MCS__0:
return 0;
case CodingScheme::MCS__1:
return 22;
case CodingScheme::MCS__2:
return 28;
case CodingScheme::MCS__3:
return 37;
case CodingScheme::MCS__4:
return 44;
case CodingScheme::MCS__5:
return 56;
case CodingScheme::MCS__6:
return 74;
case CodingScheme::MCS__7:
return 56;
case CodingScheme::MCS__8:
return 68;
case CodingScheme::MCS__9:
return 74;
default:
return 22; /* MCS1*/
}
}
static uint8_t bs2uint8(const BITSTRING& bs)
{
int len = bs.lengthof();
int i;
uint8_t res = 0;
for (i = 0; i < len; i++) {
res = res << 1;
res |= (bs[i].get_bit() ? 1 : 0);
}
return res;
}
/* determine the number of rlc data blocks and their size / offsets */
static void
setup_rlc_mac_priv(CodingScheme::enum_type mcs, EgprsHeaderType::enum_type hdrtype, boolean is_uplink,
unsigned int *n_calls, unsigned int *data_block_bits, unsigned int *data_block_offsets)
{
unsigned int nc, dbl = 0, dbo[2] = {0,0};
dbl = coding_scheme_2_data_block_len(mcs);
switch (hdrtype) {
case EgprsHeaderType::RLCMAC__HDR__TYPE__1:
nc = 3;
dbo[0] = is_uplink ? 5*8 + 6 : 5*8 + 0;
dbo[1] = dbo[0] + dbl * 8 + 2;
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__2:
nc = 2;
dbo[0] = is_uplink ? 4*8 + 5 : 3*8 + 4;
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__3:
nc = 2;
dbo[0] = 3*8 + 7;
break;
default:
nc = 1;
break;
}
*n_calls = nc;
*data_block_bits = dbl * 8 + 2;
data_block_offsets[0] = dbo[0];
data_block_offsets[1] = dbo[1];
}
/* bit-shift the entire 'src' of length 'length_bytes' by 'offset_bits'
* and store the result to caller-allocated 'buffer'. The shifting is
* done lsb-first. */
static void clone_aligned_buffer_lsbf(unsigned int offset_bits, unsigned int length_bytes,
const uint8_t *src, uint8_t *buffer)
{
unsigned int hdr_bytes;
unsigned int extra_bits;
unsigned int i;
uint8_t c, last_c;
uint8_t *dst;
hdr_bytes = offset_bits / 8;
extra_bits = offset_bits % 8;
//fprintf(stderr, "RLMAC: clone: hdr_bytes=%u extra_bits=%u (length_bytes=%u)\n", hdr_bytes, extra_bits, length_bytes);
if (extra_bits == 0) {
/* It is aligned already */
memcpy(buffer, src + hdr_bytes, length_bytes);
return;
}
dst = buffer;
src = src + hdr_bytes;
last_c = *(src++);
for (i = 0; i < length_bytes; i++) {
c = src[i];
*(dst++) = (last_c >> extra_bits) | (c << (8 - extra_bits));
last_c = c;
}
}
/* obtain an (aligned) EGPRS data block with given bit-offset and
* bit-length from the parent buffer */
static void get_egprs_data_block(const TTCN_Buffer& orig_ttcn_buffer, unsigned int offset_bits,
unsigned int length_bits, TTCN_Buffer& dst_ttcn_buffer)
{
const unsigned int initial_spare_bits = 6;
unsigned char *aligned_buf = NULL;
size_t min_src_length_bytes = (offset_bits + length_bits + 7) / 8;
size_t length_bytes = (initial_spare_bits + length_bits + 7) / 8;
size_t accepted_len = length_bytes;
//fprintf(stderr, "RLMAC: trying to allocate %u bytes (orig is %zu bytes long with read pos %zu)\n", length_bytes, orig_ttcn_buffer.get_len(), orig_ttcn_buffer.get_pos());
dst_ttcn_buffer.get_end(aligned_buf, accepted_len);
if (accepted_len < length_bytes) {
fprintf(stderr, "RLMAC: ERROR! asked for %zu bytes but got %zu\n", length_bytes, accepted_len);
}
/* Copy the data out of the tvb to an aligned buffer */
clone_aligned_buffer_lsbf(
offset_bits - initial_spare_bits, length_bytes,
orig_ttcn_buffer.get_data(),
aligned_buf);
/* clear spare bits and move block header bits to the right */
aligned_buf[0] = aligned_buf[0] >> initial_spare_bits;
dst_ttcn_buffer.increase_length(length_bytes);
}
/* bit-shift the entire 'src' of length 'length_bytes'
* and store the result to caller-allocated 'buffer' by 'offset_bits'. The shifting is
* done lsb-first. */
static void clone_unaligned_buffer_lsbf(unsigned int offset_bits, unsigned int length_bytes,
const uint8_t *src, uint8_t *buffer)
{
unsigned int hdr_bytes;
unsigned int extra_bits;
unsigned int i;
uint8_t c, last_hdr_c, last_c;
uint8_t *dst;
hdr_bytes = offset_bits / 8;
extra_bits = offset_bits % 8;
//fprintf(stderr, "RLMAC: clone: hdr_bytes=%u extra_bits=%u (length_bytes=%u)\n", hdr_bytes, extra_bits, length_bytes);
if (extra_bits == 0) {
/* It is aligned already */
memcpy(buffer, src + hdr_bytes, length_bytes);
return;
}
/* Copy first header+data byte, it's not handled correctly by loop */
dst = buffer + hdr_bytes;
last_hdr_c = *dst;
last_c = *dst << (8 - extra_bits);
for (i = 0; i < length_bytes; i++) {
c = src[i];
*(dst++) = (last_c >> (8 - extra_bits)) | (c << extra_bits);
last_c = c;
}
/* overwrite the lower extra_bits */
*dst = (*dst & (0xff << extra_bits)) | (last_c >> (8 - extra_bits));
/* Copy back first header+data byte */
dst = buffer + hdr_bytes;
*(dst++) = last_hdr_c | (src[0] << (8 - extra_bits));
*dst |= (src[0] >> (extra_bits)) & (0xff >> (8 - extra_bits));
}
/* put an (aligned) EGPRS data block with given bit-offset and
* bit-length into parent buffer */
static void put_egprs_data_block(const TTCN_Buffer& aligned_data_block_buffer, unsigned int offset_bits,
unsigned int length_bits, TTCN_Buffer& dst_ttcn_buffer)
{
const unsigned int initial_spare_bits = 6;
unsigned char *unaligned_buf = NULL;
char tmpbuf[120];
int tmplen = dst_ttcn_buffer.get_len();
//size_t max_length_bytes = (initial_spare_bits + length_bits + 7) / 8;
size_t length_bytes = tmplen + aligned_data_block_buffer.get_len();
size_t accepted_len = length_bytes;
//fprintf(stderr, "RLMAC: trying to allocate %u bytes\n", length_bytes);
/* API .get_end() is the only one I could find to access writeable
memory in the buffer. It points to the end. Hence, we first copy
(readonly) data to tmpbuf and later clear() so that .get_end()
provides us with a pointer to the start of the buffer. */
memcpy(tmpbuf, dst_ttcn_buffer.get_data(), tmplen);
dst_ttcn_buffer.clear();
dst_ttcn_buffer.get_end(unaligned_buf, accepted_len);
if (accepted_len < tmplen) {
fprintf(stderr, "RLMAC: ERROR! asked for %zu bytes but got %zu\n", length_bytes, accepted_len);
}
memcpy(unaligned_buf, tmpbuf, tmplen);
/* Copy the data out of the tvb to an aligned buffer */
clone_unaligned_buffer_lsbf(
offset_bits - initial_spare_bits, length_bytes,
aligned_data_block_buffer.get_data(),
unaligned_buf);
dst_ttcn_buffer.increase_length(length_bytes);
}
/* Append padding bytes and spare bits at the end of ttcn_buffer, based on requested CS */
static void encode_trailing_padding_spb(TTCN_Buffer& ttcn_buffer, CodingScheme cs)
{
uint8_t buf[256]; /* enough to fit any RLCMAC buffer*/
uint32_t blk_len = RLCMAC__Templates::f__rlcmac__cs__mcs2block__len(cs);
uint32_t blk_len_no_spb = RLCMAC__Templates::f__rlcmac__cs__mcs2block__len__no__spare__bits(cs);
uint32_t data_len = ttcn_buffer.get_len();
if (data_len > blk_len_no_spb) {
fprintf(stderr, "Buffer too large for requested CS! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
// TODO: throw exception?
}
for (int i = 0; i < blk_len_no_spb - data_len; i++)
buf[i] = 0x2b; /* Padding bits if needed */
for (int i = blk_len_no_spb - data_len; i < blk_len - data_len; i++)
buf[i] = 0x00; /* Spare bits if needed */
const OCTETSTRING& pad_octstr = OCTETSTRING(blk_len - data_len, buf);
ttcn_buffer.put_string(pad_octstr);
}
/////////////////////
// DECODE
/////////////////////
/* DECODE DOWNLINK */
RlcmacDlDataBlock dec__RlcmacDlDataBlock(const OCTETSTRING& stream)
{
RlcmacDlDataBlock ret_val;
TTCN_Buffer ttcn_buffer(stream);
int num_llc_blocks = 0;
ret_val.cs() = payload_len_2_coding_scheme(stream.lengthof());
/* use automatic/generated decoder for header */
ret_val.mac__hdr().decode(DlMacDataHeader_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
/* optional extension octets, containing LI+M+E of Llc blocks */
if (ret_val.mac__hdr().hdr__ext().e() == false) {
/* extension octet follows, i.e. optional Llc length octets */
while (1) {
/* decode one more extension octet with LlcBlocHdr inside */
LlcBlock lb;
lb.hdr()().decode(LlcBlockHdr_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
ret_val.blocks()[num_llc_blocks++] = lb;
/* if E == '1'B, we can proceed further */
if (lb.hdr()().e() == true)
break;
}
}
/* RLC blocks at end */
if (ret_val.mac__hdr().hdr__ext().e() == true) {
LlcBlock lb;
unsigned int length = ttcn_buffer.get_read_len();
/* LI not present: The Upper Layer PDU that starts with the current RLC data block either
* fills the current RLC data block precisely or continues in the following in-sequence RLC
* data block */
lb.hdr() = OMIT_VALUE;
lb.payload() = OCTETSTRING(length, ttcn_buffer.get_read_data());
ttcn_buffer.increase_pos(length);
ret_val.blocks()[0] = lb;
} else {
if (ret_val.blocks().is_bound()) {
for (int i = 0; i < ret_val.blocks().size_of(); i++) {
unsigned int length = ret_val.blocks()[i].hdr()().length__ind();
if (length > ttcn_buffer.get_read_len())
length = ttcn_buffer.get_read_len();
ret_val.blocks()[i].payload() = OCTETSTRING(length, ttcn_buffer.get_read_data());
ttcn_buffer.increase_pos(length);
}
}
}
return ret_val;
}
static
EgprsDlMacDataHeader dec__EgprsDlMacDataHeader_type1(const OCTETSTRING& stream)
{
TTCN_Buffer ttcn_buffer(stream);
EgprsDlMacDataHeader ret_val;
const struct gprs_rlc_dl_header_egprs_1 *egprs1;
uint8_t tmp;
egprs1 = static_cast<const struct gprs_rlc_dl_header_egprs_1 *>
((const void *)ttcn_buffer.get_data());
ret_val.header__type() = EgprsHeaderType::RLCMAC__HDR__TYPE__1;
ret_val.tfi() = egprs1->tfi_lo << 1 | egprs1->tfi_hi << 0;
ret_val.rrbp() = egprs1->rrbp;
tmp = egprs1->es_p;
ret_val.esp() = BITSTRING(2, &tmp);
ret_val.usf() = egprs1->usf;
ret_val.bsn1() = egprs1->bsn1_lo << 10 | egprs1->bsn1_mid << 2 | egprs1->bsn1_hi;
ret_val.bsn2__offset() = egprs1->bsn2_lo << 7 | egprs1->bsn2_hi;
ret_val.pr() = egprs1->pr;
ret_val.cps() = egprs1->cps;
ret_val.spb() = OMIT_VALUE;
ttcn_buffer.increase_pos(sizeof(*egprs1));
return ret_val;
}
static
EgprsDlMacDataHeader dec__EgprsDlMacDataHeader_type2(const OCTETSTRING& stream)
{
TTCN_Buffer ttcn_buffer(stream);
EgprsDlMacDataHeader ret_val;
const struct gprs_rlc_dl_header_egprs_2 *egprs2;
uint8_t tmp;
egprs2 = static_cast<const struct gprs_rlc_dl_header_egprs_2 *>
((const void *)ttcn_buffer.get_data());
ret_val.header__type() = EgprsHeaderType::RLCMAC__HDR__TYPE__2;
ret_val.tfi() = egprs2->tfi_lo << 1 | egprs2->tfi_hi << 0;
ret_val.rrbp() = egprs2->rrbp;
tmp = egprs2->es_p;
ret_val.esp() = BITSTRING(2, &tmp);
ret_val.usf() = egprs2->usf;
ret_val.bsn1() = egprs2->bsn1_lo << 10 | egprs2->bsn1_mid << 2 | egprs2->bsn1_hi;
ret_val.bsn2__offset() = 0; /*TODO: mark optional and not set ? */
ret_val.pr() = egprs2->pr;
ret_val.cps() = egprs2->cps;
ret_val.spb() = OMIT_VALUE;
ttcn_buffer.increase_pos(sizeof(*egprs2));
return ret_val;
}
static
EgprsDlMacDataHeader dec__EgprsDlMacDataHeader_type3(const OCTETSTRING& stream)
{
TTCN_Buffer ttcn_buffer(stream);
EgprsDlMacDataHeader ret_val;
const struct gprs_rlc_dl_header_egprs_3 *egprs3;
uint8_t tmp;
egprs3 = static_cast<const struct gprs_rlc_dl_header_egprs_3 *>
((const void *)ttcn_buffer.get_data());
ret_val.header__type() = EgprsHeaderType::RLCMAC__HDR__TYPE__3;
ret_val.tfi() = egprs3->tfi_lo << 1 | egprs3->tfi_hi << 0;
ret_val.rrbp() = egprs3->rrbp;
tmp = egprs3->es_p;
ret_val.esp() = BITSTRING(2, &tmp);
ret_val.usf() = egprs3->usf;
ret_val.bsn1() = egprs3->bsn1_lo << 10 | egprs3->bsn1_mid << 2 | egprs3->bsn1_hi;
ret_val.bsn2__offset() = 0; /*TODO: mark optional and not set ? */
ret_val.pr() = egprs3->pr;
ret_val.spb() = egprs3->spb;
ret_val.cps() = egprs3->cps;
ttcn_buffer.increase_pos(sizeof(*egprs3));
return ret_val;
}
static
RlcmacDlEgprsDataBlock dec__RlcmacDlEgprsDataBlock(const OCTETSTRING& stream)
{
RlcmacDlEgprsDataBlock ret_val;
TTCN_Buffer ttcn_buffer(stream);
TTCN_Buffer aligned_buffer;
int num_llc_blocks = 0;
unsigned int data_block_bits, data_block_offsets[2];
unsigned int num_calls;
const uint8_t *ti_e;
ret_val.mcs() = payload_len_2_coding_scheme(stream.lengthof());
switch (ret_val.mcs()) {
case CodingScheme::MCS__0:
case CodingScheme::MCS__1:
case CodingScheme::MCS__2:
case CodingScheme::MCS__3:
case CodingScheme::MCS__4:
ret_val.mac__hdr() = dec__EgprsDlMacDataHeader_type3(stream);
break;
case CodingScheme::MCS__5:
case CodingScheme::MCS__6:
ret_val.mac__hdr() = dec__EgprsDlMacDataHeader_type2(stream);
break;
case CodingScheme::MCS__7:
case CodingScheme::MCS__8:
case CodingScheme::MCS__9:
ret_val.mac__hdr() = dec__EgprsDlMacDataHeader_type1(stream);
break;
}
setup_rlc_mac_priv(ret_val.mcs(), ret_val.mac__hdr().header__type(), false,
&num_calls, &data_block_bits, data_block_offsets);
get_egprs_data_block(ttcn_buffer, data_block_offsets[0], data_block_bits, aligned_buffer);
ti_e = aligned_buffer.get_read_data();
ret_val.fbi() = *ti_e & 0x02 ? true : false;
ret_val.e() = *ti_e & 0x01 ? true : false;
aligned_buffer.increase_pos(1);
/* optional extension octets, containing LI+E of Llc blocks */
if (ret_val.e() == false) {
/* extension octet follows, i.e. optional Llc length octets */
while (1) {
/* decode one more extension octet with LlcBlocHdr inside */
EgprsLlcBlock lb;
lb.hdr()().decode(EgprsLlcBlockHdr_descr_, aligned_buffer, TTCN_EncDec::CT_RAW);
ret_val.blocks()[num_llc_blocks++] = lb;
/* if E == '1'B, we can proceed further */
if (lb.hdr()().e() == true)
break;
}
}
/* RLC blocks at end */
if (ret_val.e() == true) {
EgprsLlcBlock lb;
unsigned int length = aligned_buffer.get_read_len();
/* LI not present: The Upper Layer PDU that starts with the current RLC data block either
* fills the current RLC data block precisely or continues in the following in-sequence RLC
* data block */
lb.hdr() = OMIT_VALUE;
lb.payload() = OCTETSTRING(length, ttcn_buffer.get_read_data());
aligned_buffer.increase_pos(length);
ret_val.blocks()[0] = lb;
} else {
/* RLC blocks at end */
if (ret_val.blocks().is_bound()) {
for (int i = 0; i < ret_val.blocks().size_of(); i++) {
unsigned int length = ret_val.blocks()[i].hdr()().length__ind();
if (length > aligned_buffer.get_read_len())
length = aligned_buffer.get_read_len();
ret_val.blocks()[i].payload() = OCTETSTRING(length, aligned_buffer.get_read_data());
aligned_buffer.increase_pos(length);
}
}
}
return ret_val;
}
RlcmacDlBlock dec__RlcmacDlBlock(const OCTETSTRING& stream)
{
RlcmacDlBlock ret_val;
size_t stream_len = stream.lengthof();
CodingScheme::enum_type cs_mcs = payload_len_2_coding_scheme(stream_len);
unsigned char pt;
switch (cs_mcs) {
case CodingScheme::CS__1:
case CodingScheme::CS__2:
case CodingScheme::CS__3:
case CodingScheme::CS__4:
pt = stream[0].get_octet() >> 6;
if (pt == MacPayloadType::MAC__PT__RLC__DATA)
ret_val.data() = dec__RlcmacDlDataBlock(stream);
else
ret_val.ctrl() = dec__RlcmacDlCtrlBlock(stream);
break;
case CodingScheme::MCS__0:
case CodingScheme::MCS__1:
case CodingScheme::MCS__2:
case CodingScheme::MCS__3:
case CodingScheme::MCS__4:
case CodingScheme::MCS__5:
case CodingScheme::MCS__6:
case CodingScheme::MCS__7:
case CodingScheme::MCS__8:
case CodingScheme::MCS__9:
ret_val.data__egprs() = dec__RlcmacDlEgprsDataBlock(stream);
break;
}
return ret_val;
}
/* DECODE UPLINK */
RlcmacUlDataBlock dec__RlcmacUlDataBlock(const OCTETSTRING& stream)
{
RlcmacUlDataBlock ret_val;
TTCN_Buffer ttcn_buffer(stream);
int num_llc_blocks = 0;
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("==================================\n"
"dec_RlcmacUlDataBlock(): Stream before decoding: ");
stream.log();
TTCN_Logger::end_event();
ret_val.cs() = payload_len_2_coding_scheme(stream.lengthof());
/* use automatic/generated decoder for header */
ret_val.mac__hdr().decode(UlMacDataHeader_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): Stream after decoding hdr: ");
ttcn_buffer.log();
TTCN_Logger::end_event();
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): ret_val after decoding hdr: ");
ret_val.log();
TTCN_Logger::end_event();
/* Manually decoder remainder of ttcn_buffer, containing optional header octets,
* optional tlli, optional pfi and LLC Blocks */
/* optional extension octets, containing LI+M+E of Llc blocks */
if (ret_val.mac__hdr().e() == false) {
/* extension octet follows, i.e. optional Llc length octets */
while (1) {
/* decode one more extension octet with LlcBlocHdr inside */
LlcBlock lb;
lb.hdr()().decode(LlcBlockHdr_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
ret_val.blocks()[num_llc_blocks++] = lb;
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): Stream after decoding ExtOct: ");
ttcn_buffer.log();
TTCN_Logger::end_event();
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): ret_val after decoding ExtOct: ");
ret_val.log();
TTCN_Logger::end_event();
/* if E == '1'B, we can proceed further */
if (lb.hdr()().e() == true)
break;
}
}
/* parse optional TLLI */
if (ret_val.mac__hdr().tlli__ind()) {
ret_val.tlli() = OCTETSTRING(4, ttcn_buffer.get_read_data());
ttcn_buffer.increase_pos(4);
} else {
ret_val.tlli() = OMIT_VALUE;
}
/* parse optional PFI */
if (ret_val.mac__hdr().pfi__ind()) {
ret_val.pfi().decode(RlcmacUlDataBlock_pfi_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
} else {
ret_val.pfi() = OMIT_VALUE;
}
/* RLC blocks at end */
if (ret_val.mac__hdr().e() == true) {
LlcBlock lb;
unsigned int length = ttcn_buffer.get_read_len();
/* LI not present: The Upper Layer PDU that starts with the current RLC data block either
* fills the current RLC data block precisely or continues in the following in-sequence RLC
* data block */
lb.hdr() = OMIT_VALUE;
lb.payload() = OCTETSTRING(length, ttcn_buffer.get_read_data());
ttcn_buffer.increase_pos(length);
ret_val.blocks()[0] = lb;
} else {
if (ret_val.blocks().is_bound()) {
for (int i = 0; i < ret_val.blocks().size_of(); i++) {
unsigned int length = ret_val.blocks()[i].hdr()().length__ind();
if (length > ttcn_buffer.get_read_len())
length = ttcn_buffer.get_read_len();
ret_val.blocks()[i].payload() = OCTETSTRING(length, ttcn_buffer.get_read_data());
ttcn_buffer.increase_pos(length);
}
}
}
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): Stream before return: ");
ttcn_buffer.log();
TTCN_Logger::end_event();
TTCN_Logger::begin_event(TTCN_Logger::DEBUG_ENCDEC);
TTCN_Logger::log_event_str("dec_RlcmacUlDataBlock(): ret_val before return: ");
ret_val.log();
TTCN_Logger::end_event();
return ret_val;
}
static
EgprsUlMacDataHeader dec__EgprsUlMacDataHeader_type1(const OCTETSTRING& stream)
{
EgprsUlMacDataHeader ret_val;
fprintf(stderr, "FIXME: Not implemented! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
return ret_val;
}
static
EgprsUlMacDataHeader dec__EgprsUlMacDataHeader_type2(const OCTETSTRING& stream)
{
EgprsUlMacDataHeader ret_val;
fprintf(stderr, "FIXME: Not implemented! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
return ret_val;
}
static
EgprsUlMacDataHeader dec__EgprsUlMacDataHeader_type3(const OCTETSTRING& stream)
{
TTCN_Buffer ttcn_buffer(stream);
EgprsUlMacDataHeader ret_val;
const struct gprs_rlc_ul_header_egprs_3 *egprs3;
uint8_t tmp;
egprs3 = static_cast<const struct gprs_rlc_ul_header_egprs_3 *>
((const void *)ttcn_buffer.get_data());
ret_val.header__type() = EgprsHeaderType::RLCMAC__HDR__TYPE__3;
ret_val.tfi() = egprs3->tfi_lo << 2 | egprs3->tfi_hi << 0;
ret_val.countdown() = egprs3->cv;
tmp = egprs3->si;
ret_val.foi__si() = BITSTRING(1, &tmp);
tmp = egprs3->r;
ret_val.r__ri() = BITSTRING(1, &tmp);
ret_val.bsn1() = egprs3->bsn1_lo << 5 | egprs3->bsn1_hi << 0;
ret_val.cps() = egprs3->cps_lo << 2 | egprs3->cps_hi << 0;
ret_val.pfi__ind() = egprs3->pi;
tmp = egprs3->rsb;
ret_val.rsb() = BITSTRING(1, &tmp);
tmp = egprs3->spb;
ret_val.spb() = BITSTRING(2, &tmp);
ttcn_buffer.increase_pos(sizeof(*egprs3));
return ret_val;
}
RlcmacUlEgprsDataBlock dec__RlcmacUlEgprsDataBlock(const OCTETSTRING& stream)
{
RlcmacUlEgprsDataBlock ret_val;
TTCN_Buffer ttcn_buffer(stream);
TTCN_Buffer aligned_buffer;
int num_llc_blocks = 0;
unsigned int data_block_bits, data_block_offsets[2];
unsigned int num_calls;
const uint8_t *ti_e;
ret_val.mcs() = payload_len_2_coding_scheme(stream.lengthof());
switch (ret_val.mcs()) {
case CodingScheme::MCS__1:
case CodingScheme::MCS__2:
case CodingScheme::MCS__3:
case CodingScheme::MCS__4:
ret_val.mac__hdr() = dec__EgprsUlMacDataHeader_type3(stream);
break;
case CodingScheme::MCS__5:
case CodingScheme::MCS__6:
ret_val.mac__hdr() = dec__EgprsUlMacDataHeader_type2(stream);
break;
case CodingScheme::MCS__7:
case CodingScheme::MCS__8:
case CodingScheme::MCS__9:
ret_val.mac__hdr() = dec__EgprsUlMacDataHeader_type1(stream);
break;
}
setup_rlc_mac_priv(ret_val.mcs(), ret_val.mac__hdr().header__type(), true,
&num_calls, &data_block_bits, data_block_offsets);
get_egprs_data_block(ttcn_buffer, data_block_offsets[0], data_block_bits, aligned_buffer);
ti_e = aligned_buffer.get_read_data();
ret_val.tlli__ind() = *ti_e & 0x02 ? true : false;
ret_val.e() = *ti_e & 0x01 ? true : false;
aligned_buffer.increase_pos(1);
/* Manually decoder remainder of aligned_buffer, containing optional header octets,
* optional tlli, optional pfi and LLC Blocks */
/* optional extension octets, containing LI+M+E of Llc blocks */
if (ret_val.e() == false) {
/* extension octet follows, i.e. optional Llc length octets */
while (1) {
/* decode one more extension octet with LlcBlocHdr inside */
EgprsLlcBlock lb;
lb.hdr()().decode(EgprsLlcBlockHdr_descr_, aligned_buffer, TTCN_EncDec::CT_RAW);
ret_val.blocks()[num_llc_blocks++] = lb;
/* if E == '1'B, we can proceed further */
if (lb.hdr()().e() == true)
break;
}
}
/* parse optional TLLI */
if (ret_val.tlli__ind()) {
ret_val.tlli() = OCTETSTRING(4, aligned_buffer.get_read_data());
aligned_buffer.increase_pos(4);
} else {
ret_val.tlli() = OMIT_VALUE;
}
/* parse optional PFI */
if (ret_val.mac__hdr().pfi__ind()) {
ret_val.pfi().decode(RlcmacUlEgprsDataBlock_pfi_descr_, aligned_buffer, TTCN_EncDec::CT_RAW);
} else {
ret_val.pfi() = OMIT_VALUE;
}
/* RLC blocks at end */
if (ret_val.e() == true) {
EgprsLlcBlock lb;
unsigned int length = aligned_buffer.get_read_len();
/* LI not present: The Upper Layer PDU that starts with the current RLC data block either
* fills the current RLC data block precisely or continues in the following in-sequence RLC
* data block */
lb.hdr() = OMIT_VALUE;
lb.payload() = OCTETSTRING(length, aligned_buffer.get_read_data());
aligned_buffer.increase_pos(length);
ret_val.blocks()[0] = lb;
} else {
if (ret_val.blocks().is_bound()) {
for (int i = 0; i < ret_val.blocks().size_of(); i++) {
unsigned int length = ret_val.blocks()[i].hdr()().length__ind();
if (length > aligned_buffer.get_read_len())
length = aligned_buffer.get_read_len();
ret_val.blocks()[i].payload() = OCTETSTRING(length, aligned_buffer.get_read_data());
aligned_buffer.increase_pos(length);
}
}
}
return ret_val;
}
RlcmacUlBlock dec__RlcmacUlBlock(const OCTETSTRING& stream)
{
RlcmacUlBlock ret_val;
size_t stream_len = stream.lengthof();
CodingScheme::enum_type cs_mcs = payload_len_2_coding_scheme(stream_len);
unsigned char pt;
switch (cs_mcs) {
case CodingScheme::CS__1:
case CodingScheme::CS__2:
case CodingScheme::CS__3:
case CodingScheme::CS__4:
pt = stream[0].get_octet() >> 6;
if (pt == MacPayloadType::MAC__PT__RLC__DATA)
ret_val.data() = dec__RlcmacUlDataBlock(stream);
else
ret_val.ctrl() = dec__RlcmacUlCtrlBlock(stream);
break;
case CodingScheme::MCS__1:
case CodingScheme::MCS__2:
case CodingScheme::MCS__3:
case CodingScheme::MCS__4:
case CodingScheme::MCS__5:
case CodingScheme::MCS__6:
case CodingScheme::MCS__7:
case CodingScheme::MCS__8:
case CodingScheme::MCS__9:
ret_val.data__egprs() = dec__RlcmacUlEgprsDataBlock(stream);
break;
}
return ret_val;
}
/////////////////////
// ENCODE
/////////////////////
/* ENCODE DOWNLINK */
OCTETSTRING enc__RlcmacDlDataBlock(const RlcmacDlDataBlock& si)
{
RlcmacDlDataBlock in = si;
OCTETSTRING ret_val;
TTCN_Buffer ttcn_buffer;
int i;
/* Fix 'e' bit of initial header based on following blocks */
if (!in.blocks().is_bound() ||
(in.blocks().size_of() == 1 && !in.blocks()[0].hdr().is_bound()))
in.mac__hdr().hdr__ext().e() = true;
else
in.mac__hdr().hdr__ext().e() = false;
/* use automatic/generated decoder for header */
in.mac__hdr().encode(DlMacDataHeader_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
/* Add LI octets, if any */
if (in.blocks().is_bound() &&
(in.blocks().size_of() != 1 || in.blocks()[0].hdr().is_bound())) {
/* first write LI octets */
for (i = 0; i < in.blocks().size_of(); i++) {
/* fix the 'E' bit in case it is not clear */
if (i < in.blocks().size_of()-1)
in.blocks()[i].hdr()().e() = false;
else
in.blocks()[i].hdr()().e() = true;
in.blocks()[i].hdr()().encode(LlcBlockHdr_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
}
}
if (in.blocks().is_bound()) {
for (i = 0; i < in.blocks().size_of(); i++) {
if (!in.blocks()[i].is_bound())
continue;
ttcn_buffer.put_string(in.blocks()[i].payload());
}
}
encode_trailing_padding_spb(ttcn_buffer, in.cs());
ttcn_buffer.get_string(ret_val);
return ret_val;
}
static
void enc__RlcmacDlEgprsDataHeader_type1(const EgprsDlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
fprintf(stderr, "FIXME: Not implemented! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
}
static
void enc__RlcmacDlEgprsDataHeader_type2(const EgprsDlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
fprintf(stderr, "FIXME: Not implemented! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
}
static
void enc__RlcmacDlEgprsDataHeader_type3(const EgprsDlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
fprintf(stderr, "FIXME: Not implemented! %s (%s:%u)\n", __func__, __FILE__, __LINE__);
}
OCTETSTRING enc__RlcmacDlEgprsDataBlock(const RlcmacDlEgprsDataBlock& si)
{
RlcmacDlEgprsDataBlock in = si;
OCTETSTRING ret_val;
TTCN_Buffer ttcn_buffer;
int i;
/* Fix 'e' bit of initial header based on following blocks */
if (!in.blocks().is_bound() ||
(in.blocks().size_of() == 1 && !in.blocks()[0].hdr().is_bound()))
in.e() = true;
else
in.e() = false;
switch (in.mac__hdr().header__type()) {
case EgprsHeaderType::RLCMAC__HDR__TYPE__1:
enc__RlcmacDlEgprsDataHeader_type1(si.mac__hdr(), ttcn_buffer);
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__2:
enc__RlcmacDlEgprsDataHeader_type2(si.mac__hdr(), ttcn_buffer);
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__3:
enc__RlcmacDlEgprsDataHeader_type3(si.mac__hdr(), ttcn_buffer);
default:
break; /* TODO: error */
}
/* Add LI octets, if any */
if (in.blocks().is_bound() &&
(in.blocks().size_of() != 1 || in.blocks()[0].hdr().is_bound())) {
/* first write LI octets */
for (i = 0; i < in.blocks().size_of(); i++) {
/* fix the 'E' bit in case it is not clear */
if (i < in.blocks().size_of()-1)
in.blocks()[i].hdr()().e() = false;
else
in.blocks()[i].hdr()().e() = true;
in.blocks()[i].hdr()().encode(EgprsLlcBlockHdr_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
}
}
if (in.blocks().is_bound()) {
for (i = 0; i < in.blocks().size_of(); i++) {
if (!in.blocks()[i].is_bound())
continue;
ttcn_buffer.put_string(in.blocks()[i].payload());
}
}
encode_trailing_padding_spb(ttcn_buffer, in.mcs());
ttcn_buffer.get_string(ret_val);
return ret_val;
}
OCTETSTRING enc__RlcmacDlBlock(const RlcmacDlBlock& si)
{
if (si.ischosen(RlcmacDlBlock::ALT_data__egprs))
return enc__RlcmacDlEgprsDataBlock(si.data__egprs());
else if (si.ischosen(RlcmacDlBlock::ALT_data))
return enc__RlcmacDlDataBlock(si.data());
else
return enc__RlcmacDlCtrlBlock(si.ctrl());
}
/* ENCODE UPLINK */
OCTETSTRING enc__RlcmacUlDataBlock(const RlcmacUlDataBlock& si)
{
RlcmacUlDataBlock in = si;
OCTETSTRING ret_val;
TTCN_Buffer ttcn_buffer;
int i;
if (!in.blocks().is_bound()) {
/* we don't have any blocks: Add length value (zero) */
in.mac__hdr().e() = false; /* E=0: extension octet follows */
} else if (in.blocks().size_of() == 1 && in.blocks()[0].hdr() == OMIT_VALUE) {
/* If there's only a single block, and that block has no HDR value defined, */
in.mac__hdr().e() = true; /* E=0: extension octet follows */
} else {
/* Length value */
in.mac__hdr().e() = false;
}
/* Fix other presence indications */
in.mac__hdr().tlli__ind() = in.tlli().is_bound() && in.tlli() != OMIT_VALUE;
in.mac__hdr().pfi__ind() = in.pfi().is_bound() && in.pfi() != OMIT_VALUE;
/* use automatic/generated encoder for header */
in.mac__hdr().encode(UlMacDataHeader_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
if (in.mac__hdr().e() == false) {
/* Add LI octets, if any */
if (!in.blocks().is_bound()) {
ttcn_buffer.put_c(0x01); /* M=0, E=1 LEN=0 */
} else {
for (i = 0; i < in.blocks().size_of(); i++) {
#if 0
/* check for penultimate block */
if (i == in.blocks().size_of()-2) {
/* if last block has no header, no more LI */
if (in.blocks()[i+1].hdr() == OMIT_VALUE) {
in.blocks()[i].hdr()().more() = true;
} else {
/* header present, we have to encode LI */
in.blocks()[i].hdr()().more() = false;
in.blocks()[i].hdr()().length__ind() =
in.blocks()[i+1].payload().lengthof();
}
} else if (i < in.blocks().size_of()-2) {
/* one of the first blocks, before the penultimate or last */
in.blocks()[i].hdr()().e() = false; /* LI present */
/* re-compute length */
in.blocks()[i].hdr()().length__ind() =
in.blocks()[i+1].payload().lengthof();
}
/* Encode LI octet if E=0 */
}
#endif
if (in.blocks()[i].hdr() != OMIT_VALUE) {
in.blocks()[i].hdr()().encode(LlcBlockHdr_descr_, ttcn_buffer,
TTCN_EncDec::CT_RAW);
}
}
}
}
if (in.mac__hdr().tlli__ind()) {
ttcn_buffer.put_string(in.tlli());
}
if (in.mac__hdr().pfi__ind()) {
in.pfi().encode(RlcmacUlDataBlock_pfi_descr_, ttcn_buffer, TTCN_EncDec::CT_RAW);
}
if (in.blocks().is_bound()) {
for (i = 0; i < in.blocks().size_of(); i++) {
if (!in.blocks()[i].is_bound())
continue;
ttcn_buffer.put_string(in.blocks()[i].payload());
}
}
encode_trailing_padding_spb(ttcn_buffer, in.cs());
ttcn_buffer.get_string(ret_val);
return ret_val;
}
static
void enc__RlcmacUlEgprsDataHeader_type1(const EgprsUlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
struct gprs_rlc_ul_header_egprs_1 egprs1;
egprs1.r = bs2uint8(si.r__ri());
egprs1.si = bs2uint8(si.foi__si());
egprs1.cv = si.countdown();
egprs1.tfi_hi = si.tfi() >> 0;
egprs1.tfi_lo = si.tfi() >> 2;
egprs1.bsn1_hi = si.bsn1() >> 0;
egprs1.bsn1_lo = si.bsn1() >> 5;
egprs1.bsn2_hi = si.bsn2__offset() >> 0;
egprs1.bsn2_lo = si.bsn2__offset() >> 2;
egprs1.cps = si.cps();
egprs1.rsb = bs2uint8(si.rsb());
egprs1.pi = si.pfi__ind();
egprs1.spare_hi = 0;
egprs1.spare_lo = 0;
egprs1.dummy = 0;
ttcn_buffer.put_s(sizeof(egprs1), (const unsigned char *)&egprs1);
}
static
void enc__RlcmacUlEgprsDataHeader_type2(const EgprsUlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
struct gprs_rlc_ul_header_egprs_2 egprs2;
egprs2.r = bs2uint8(si.r__ri());
egprs2.si = bs2uint8(si.foi__si());
egprs2.cv = si.countdown();
egprs2.tfi_hi = si.tfi() >> 0;
egprs2.tfi_lo = si.tfi() >> 2;
egprs2.bsn1_hi = si.bsn1() >> 0;
egprs2.bsn1_lo = si.bsn1() >> 5;
egprs2.cps_hi = si.cps() >> 0;
egprs2.cps_lo = si.cps() >> 2;
egprs2.rsb = bs2uint8(si.rsb());
egprs2.pi = si.pfi__ind();
egprs2.spare_hi = 0;
egprs2.spare_lo = 0;
egprs2.dummy = 0;
ttcn_buffer.put_s(sizeof(egprs2), (const unsigned char *)&egprs2);
}
static
void enc__RlcmacUlEgprsDataHeader_type3(const EgprsUlMacDataHeader& si, TTCN_Buffer& ttcn_buffer)
{
struct gprs_rlc_ul_header_egprs_3 egprs3;
egprs3.r = bs2uint8(si.r__ri());
egprs3.si = bs2uint8(si.foi__si());
egprs3.cv = si.countdown();
egprs3.tfi_hi = si.tfi() >> 0;
egprs3.tfi_lo = si.tfi() >> 2;
egprs3.bsn1_hi = si.bsn1() >> 0;
egprs3.bsn1_lo = si.bsn1() >> 5;
egprs3.cps_hi = si.cps() >> 0;
egprs3.cps_lo = si.cps() >> 2;
egprs3.spb = bs2uint8(si.spb());
egprs3.rsb = bs2uint8(si.rsb());
egprs3.pi = si.pfi__ind();
egprs3.spare = 0;
egprs3.dummy = 0;
ttcn_buffer.put_s(sizeof(egprs3), (const unsigned char *)&egprs3);
}
OCTETSTRING enc__RlcmacUlEgprsDataBlock(const RlcmacUlEgprsDataBlock& si)
{
RlcmacUlEgprsDataBlock in = si;
OCTETSTRING ret_val;
TTCN_Buffer ttcn_buffer, aligned_buffer;
int i;
unsigned int data_block_bits, data_block_offsets[2];
unsigned int num_calls;
CodingScheme mcs;
mcs = RLCMAC__Templates::f__rlcmac__cps__htype__to__mcs(in.mac__hdr().cps(), in.mac__hdr().header__type());
//fprintf(stderr, "RLCMAC: infered MCS %s (%d)\n", mcs.enum_to_str(static_cast<CodingScheme::enum_type>(mcs.as_int())), mcs.as_int());
if (!in.blocks().is_bound()) {
/* we don't have nay blocks: Add length value (zero) */
in.e() = false; /* E=0: extension octet follows */
} else if (in.blocks().size_of() == 1 && in.blocks()[0].hdr() == OMIT_VALUE) {
/* If there's only a single block, and that block has no HDR value defined, */
in.e() = true; /* E=0: extension octet follows */
} else {
/* Length value */
in.e() = false;
}
/* Fix other presence indications */
in.tlli__ind() = in.tlli().is_bound() && in.tlli() != OMIT_VALUE;
in.mac__hdr().pfi__ind() = in.pfi().is_bound() && in.pfi() != OMIT_VALUE;
switch (in.mac__hdr().header__type()) {
case EgprsHeaderType::RLCMAC__HDR__TYPE__1:
enc__RlcmacUlEgprsDataHeader_type1(in.mac__hdr(), ttcn_buffer);
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__2:
enc__RlcmacUlEgprsDataHeader_type2(in.mac__hdr(), ttcn_buffer);
break;
case EgprsHeaderType::RLCMAC__HDR__TYPE__3:
enc__RlcmacUlEgprsDataHeader_type3(in.mac__hdr(), ttcn_buffer);
default:
break; /* TODO: error */
}
/* Put first TI + E byte */
aligned_buffer.put_c((in.tlli__ind() & 0x01) << 1 | (in.e() & 0x01) << 0);
//printbuffer("After encoding first byte", aligned_buffer);
if (in.e() == false) {
/* Add LI octets, if any */
if (!in.blocks().is_bound()) {
aligned_buffer.put_c(0x01); /* M=0, E=1 LEN=0 */
} else {
for (i = 0; i < in.blocks().size_of(); i++) {
#if 0
/* check for penultimate block */
if (i == in.blocks().size_of()-2) {
/* if last block has no header, no more LI */
if (in.blocks()[i+1].hdr() == OMIT_VALUE) {
in.blocks()[i].hdr()().more() = true;
} else {
/* header present, we have to encode LI */
in.blocks()[i].hdr()().more() = false;
in.blocks()[i].hdr()().length__ind() =
in.blocks()[i+1].payload().lengthof();
}
} else if (i < in.blocks().size_of()-2) {
/* one of the first blocks, before the penultimate or last */
in.blocks()[i].hdr()().e() = false; /* LI present */
/* re-compute length */
in.blocks()[i].hdr()().length__ind() =
in.blocks()[i+1].payload().lengthof();
}
/* Encode LI octet if E=0 */
}
#endif
if (in.blocks()[i].hdr() != OMIT_VALUE) {
in.blocks()[i].hdr()().encode(EgprsLlcBlockHdr_descr_, aligned_buffer,
TTCN_EncDec::CT_RAW);
}
}
}
}
if (in.tlli__ind()) {
/* The TLLI is encoded in little endian for EGPRS (see
* TS 44.060, figure 10.3a.2.1, note 2) */
OCTETSTRING tlli = in.tlli();
aligned_buffer.put_c(tlli[3].get_octet());
aligned_buffer.put_c(tlli[2].get_octet());
aligned_buffer.put_c(tlli[1].get_octet());
aligned_buffer.put_c(tlli[0].get_octet());
}
if (in.mac__hdr().pfi__ind()) {
in.pfi().encode(RlcmacUlEgprsDataBlock_pfi_descr_, aligned_buffer, TTCN_EncDec::CT_RAW);
}
//printbuffer("Before encoding EgprsLlc payload", aligned_buffer);
if (in.blocks().is_bound()) {
for (i = 0; i < in.blocks().size_of(); i++) {
if (!in.blocks()[i].is_bound())
continue;
aligned_buffer.put_string(in.blocks()[i].payload());
}
}
//printbuffer("After encoding EgprsLlc payload", aligned_buffer);
setup_rlc_mac_priv(mcs, in.mac__hdr().header__type(), true,
&num_calls, &data_block_bits, data_block_offsets);
//printbuffer("before merging data block", ttcn_buffer);
put_egprs_data_block(aligned_buffer, data_block_offsets[0], data_block_bits, ttcn_buffer);
//printbuffer("after merging data block", ttcn_buffer);
encode_trailing_padding_spb(ttcn_buffer, in.mcs());
ttcn_buffer.get_string(ret_val);
return ret_val;
}
OCTETSTRING enc__RlcmacUlBlock(const RlcmacUlBlock& si)
{
if (si.ischosen(RlcmacUlBlock::ALT_data__egprs))
return enc__RlcmacUlEgprsDataBlock(si.data__egprs());
else if (si.ischosen(RlcmacUlBlock::ALT_data))
return enc__RlcmacUlDataBlock(si.data());
else
return enc__RlcmacUlCtrlBlock(si.ctrl());
}
} // namespace
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