/*
* EdgeTest.cpp
*
* Copyright (C) 2015 by Sysmocom s.f.m.c. GmbH
*
* All Rights Reserved
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation; either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU Affero General Public License
* along with this program. If not, see .
*
*/
#include "gprs_debug.h"
#include "gprs_coding_scheme.h"
#include "decoding.h"
#include "encoding.h"
#include "rlc.h"
#include "llc.h"
#include "bts.h"
extern "C" {
#include "pcu_vty.h"
#include
#include
#include
#include
#include
#include
}
#include
#include
void *tall_pcu_ctx;
int16_t spoof_mnc = 0, spoof_mcc = 0;
static void check_coding_scheme(GprsCodingScheme& cs, GprsCodingScheme::Mode mode)
{
volatile unsigned expected_size;
bool need_padding;
GprsCodingScheme new_cs;
OSMO_ASSERT(cs.isValid());
OSMO_ASSERT(cs.isCompatible(mode));
/* Check static getBySizeUL() */
expected_size = cs.usedSizeUL();
if (cs.spareBitsUL() > 0 && cs.isGprs())
expected_size += 1;
OSMO_ASSERT(expected_size == cs.sizeUL());
OSMO_ASSERT(cs == GprsCodingScheme::getBySizeUL(expected_size));
/* Check static sizeUL() */
expected_size = cs.usedSizeDL();
if (cs.spareBitsDL() > 0 && cs.isGprs())
expected_size += 1;
OSMO_ASSERT(expected_size == cs.sizeDL());
/* Check data block sizes */
OSMO_ASSERT(cs.maxDataBlockBytes() * cs.numDataBlocks() < cs.maxBytesDL());
OSMO_ASSERT(cs.maxDataBlockBytes() * cs.numDataBlocks() < cs.maxBytesUL());
/* Check inc/dec */
new_cs = cs;
new_cs.inc(mode);
OSMO_ASSERT(new_cs.isCompatible(mode));
if (new_cs != cs) {
new_cs.dec(mode);
OSMO_ASSERT(new_cs.isCompatible(mode));
OSMO_ASSERT(new_cs == cs);
}
new_cs.dec(mode);
OSMO_ASSERT(new_cs.isCompatible(mode));
if (new_cs != cs) {
new_cs.inc(mode);
OSMO_ASSERT(new_cs.isCompatible(mode));
OSMO_ASSERT(new_cs == cs);
}
new_cs = cs;
new_cs.decToSingleBlock(&need_padding);
OSMO_ASSERT(new_cs.isFamilyCompatible(cs));
OSMO_ASSERT(cs.isFamilyCompatible(new_cs));
OSMO_ASSERT(cs.isCompatible(new_cs));
if (need_padding) {
OSMO_ASSERT(new_cs.maxDataBlockBytes() ==
new_cs.optionalPaddingBits()/8 + cs.maxDataBlockBytes());
} else {
OSMO_ASSERT(new_cs.maxDataBlockBytes() == cs.maxDataBlockBytes());
}
}
static void test_coding_scheme()
{
unsigned i;
unsigned last_size_UL;
unsigned last_size_DL;
GprsCodingScheme::Scheme gprs_schemes[] = {
GprsCodingScheme::CS1,
GprsCodingScheme::CS2,
GprsCodingScheme::CS3,
GprsCodingScheme::CS4
};
struct {
GprsCodingScheme::Scheme s;
bool is_gmsk;
} egprs_schemes[] = {
{GprsCodingScheme::MCS1, true},
{GprsCodingScheme::MCS2, true},
{GprsCodingScheme::MCS3, true},
{GprsCodingScheme::MCS4, true},
{GprsCodingScheme::MCS5, false},
{GprsCodingScheme::MCS6, false},
{GprsCodingScheme::MCS7, false},
{GprsCodingScheme::MCS8, false},
{GprsCodingScheme::MCS9, false},
};
printf("=== start %s ===\n", __func__);
GprsCodingScheme cs;
OSMO_ASSERT(!cs);
OSMO_ASSERT(GprsCodingScheme::Scheme(cs) == GprsCodingScheme::UNKNOWN);
OSMO_ASSERT(cs == GprsCodingScheme(GprsCodingScheme::UNKNOWN));
OSMO_ASSERT(!cs.isCompatible(GprsCodingScheme::GPRS));
OSMO_ASSERT(!cs.isCompatible(GprsCodingScheme::EGPRS_GMSK));
OSMO_ASSERT(!cs.isCompatible(GprsCodingScheme::EGPRS));
last_size_UL = 0;
last_size_DL = 0;
for (i = 0; i < ARRAY_SIZE(gprs_schemes); i++) {
GprsCodingScheme current_cs(gprs_schemes[i]);
OSMO_ASSERT(current_cs.isGprs());
OSMO_ASSERT(!current_cs.isEgprs());
OSMO_ASSERT(!current_cs.isEgprsGmsk());
OSMO_ASSERT(GprsCodingScheme::Scheme(current_cs) == gprs_schemes[i]);
OSMO_ASSERT(current_cs == GprsCodingScheme(gprs_schemes[i]));
/* Check strong monotonicity */
OSMO_ASSERT(current_cs.maxBytesUL() > last_size_UL);
OSMO_ASSERT(current_cs.maxBytesDL() > last_size_DL);
last_size_UL = current_cs.maxBytesUL();
last_size_DL = current_cs.maxBytesDL();
/* Check header types */
OSMO_ASSERT(current_cs.headerTypeData() ==
GprsCodingScheme::HEADER_GPRS_DATA);
OSMO_ASSERT(current_cs.headerTypeControl() ==
GprsCodingScheme::HEADER_GPRS_CONTROL);
check_coding_scheme(current_cs, GprsCodingScheme::GPRS);
}
OSMO_ASSERT(i == 4);
last_size_UL = 0;
last_size_DL = 0;
for (i = 0; i < ARRAY_SIZE(egprs_schemes); i++) {
GprsCodingScheme current_cs(egprs_schemes[i].s);
OSMO_ASSERT(!current_cs.isGprs());
OSMO_ASSERT(current_cs.isEgprs());
OSMO_ASSERT(!!current_cs.isEgprsGmsk() == !!egprs_schemes[i].is_gmsk);
OSMO_ASSERT(GprsCodingScheme::Scheme(current_cs) == egprs_schemes[i].s);
OSMO_ASSERT(current_cs == GprsCodingScheme(egprs_schemes[i].s));
/* Check strong monotonicity */
OSMO_ASSERT(current_cs.maxBytesUL() > last_size_UL);
OSMO_ASSERT(current_cs.maxBytesDL() > last_size_DL);
last_size_UL = current_cs.maxBytesUL();
last_size_DL = current_cs.maxBytesDL();
if (egprs_schemes[i].is_gmsk)
check_coding_scheme(current_cs, GprsCodingScheme::EGPRS_GMSK);
check_coding_scheme(current_cs, GprsCodingScheme::EGPRS);
}
OSMO_ASSERT(i == 9);
printf("=== end %s ===\n", __func__);
}
static void test_rlc_unit_decoder()
{
struct gprs_rlc_data_block_info rdbi = {0};
GprsCodingScheme cs;
uint8_t data[74];
Decoding::RlcData chunks[16];
volatile int num_chunks = 0;
uint32_t tlli, tlli2;
unsigned int offs;
printf("=== start %s ===\n", __func__);
/* TS 44.060, B.1 */
cs = GprsCodingScheme::CS4;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (11 << 2) | (1 << 1) | (0 << 0);
data[offs++] = (26 << 2) | (1 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 2);
OSMO_ASSERT(chunks[0].length == 11);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 13);
OSMO_ASSERT(chunks[1].length == 26);
OSMO_ASSERT(chunks[1].is_complete);
OSMO_ASSERT(chunks[2].offset == 39);
OSMO_ASSERT(chunks[2].length == cs.maxDataBlockBytes() - 39);
OSMO_ASSERT(!chunks[2].is_complete);
/* TS 44.060, B.2 */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (0 << 2) | (0 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 1);
OSMO_ASSERT(chunks[0].length == 19);
OSMO_ASSERT(!chunks[0].is_complete);
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (1 << 2) | (1 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 1);
OSMO_ASSERT(chunks[0].length == 1);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 2);
OSMO_ASSERT(chunks[1].length == 18);
OSMO_ASSERT(!chunks[1].is_complete);
/* TS 44.060, B.3 */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (7 << 2) | (1 << 1) | (0 << 0);
data[offs++] = (11 << 2) | (0 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 2);
OSMO_ASSERT(chunks[0].length == 7);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 9);
OSMO_ASSERT(chunks[1].length == 11);
OSMO_ASSERT(chunks[1].is_complete);
/* TS 44.060, B.4 */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 1;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 0);
OSMO_ASSERT(chunks[0].length == 20);
OSMO_ASSERT(!chunks[0].is_complete);
/* TS 44.060, B.6 */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 1;
rdbi.ti = 0;
rdbi.cv = 0;
tlli = 0;
offs = 0;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 0);
OSMO_ASSERT(chunks[0].length == 20);
OSMO_ASSERT(chunks[0].is_complete);
/* TS 44.060, B.8.1 */
cs = GprsCodingScheme::MCS4;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (11 << 1) | (0 << 0);
data[offs++] = (26 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 2);
OSMO_ASSERT(chunks[0].length == 11);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 13);
OSMO_ASSERT(chunks[1].length == 26);
OSMO_ASSERT(chunks[1].is_complete);
OSMO_ASSERT(chunks[2].offset == 39);
OSMO_ASSERT(chunks[2].length == 5);
OSMO_ASSERT(!chunks[2].is_complete);
/* TS 44.060, B.8.2 */
/* Note that the spec confuses the byte numbering here, since it
* includes the FBI/E header bits into the N2 octet count which
* is not consistent with Section 10.3a.1 & 10.3a.2. */
cs = GprsCodingScheme::MCS2;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = (15 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 1);
OSMO_ASSERT(chunks[0].length == 15);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 16);
OSMO_ASSERT(chunks[1].length == 12);
OSMO_ASSERT(!chunks[1].is_complete);
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 15;
tlli = 0;
offs = 0;
data[offs++] = ( 0 << 1) | (0 << 0);
data[offs++] = ( 7 << 1) | (0 << 0);
data[offs++] = (18 << 1) | (1 << 0); /* Differs from spec's N2-11 = 17 */
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 3);
OSMO_ASSERT(chunks[0].length == 0);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 3);
OSMO_ASSERT(chunks[1].length == 7);
OSMO_ASSERT(chunks[1].is_complete);
OSMO_ASSERT(chunks[2].offset == 10);
OSMO_ASSERT(chunks[2].length == 18);
OSMO_ASSERT(chunks[2].is_complete);
rdbi.e = 0;
rdbi.ti = 0;
rdbi.cv = 0;
tlli = 0;
offs = 0;
data[offs++] = ( 6 << 1) | (0 << 0);
data[offs++] = (12 << 1) | (0 << 0);
data[offs++] = (127 << 1) | (1 << 0);
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 3);
OSMO_ASSERT(chunks[0].length == 6);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 9);
OSMO_ASSERT(chunks[1].length == 12);
OSMO_ASSERT(chunks[1].is_complete);
/* TS 44.060, B.8.3 */
/* Note that the spec confuses the byte numbering here, too (see above) */
cs = GprsCodingScheme::MCS2;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 1;
rdbi.ti = 0;
rdbi.cv = 0;
tlli = 0;
offs = 0;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == 0);
OSMO_ASSERT(chunks[0].offset == 0);
OSMO_ASSERT(chunks[0].length == 28);
OSMO_ASSERT(chunks[0].is_complete);
/* CS-1, TLLI, last block, single chunk until the end of the block */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 1;
rdbi.ti = 1;
rdbi.cv = 0;
tlli = 0;
tlli2 = 0xffeeddcc;
offs = 0;
data[offs++] = tlli2 >> 24;
data[offs++] = tlli2 >> 16;
data[offs++] = tlli2 >> 8;
data[offs++] = tlli2 >> 0;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == tlli2);
OSMO_ASSERT(chunks[0].offset == 4);
OSMO_ASSERT(chunks[0].length == 16);
OSMO_ASSERT(chunks[0].is_complete);
/* Like TS 44.060, B.2, first RLC block but with TLLI */
cs = GprsCodingScheme::CS1;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 1;
rdbi.cv = 15;
tlli = 0;
tlli2 = 0xffeeddbb;
offs = 0;
data[offs++] = (0 << 2) | (0 << 1) | (1 << 0);
data[offs++] = tlli2 >> 24;
data[offs++] = tlli2 >> 16;
data[offs++] = tlli2 >> 8;
data[offs++] = tlli2 >> 0;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(tlli == tlli2);
OSMO_ASSERT(chunks[0].offset == 5);
OSMO_ASSERT(chunks[0].length == 15);
OSMO_ASSERT(!chunks[0].is_complete);
/* Like TS 44.060, B.8.1 but with TLLI */
cs = GprsCodingScheme::MCS4;
rdbi.data_len = cs.maxDataBlockBytes();
rdbi.e = 0;
rdbi.ti = 1;
rdbi.cv = 15;
tlli = 0;
tlli2 = 0xffeeddaa;
offs = 0;
data[offs++] = (11 << 1) | (0 << 0);
data[offs++] = (26 << 1) | (1 << 0);
/* Little endian */
data[offs++] = tlli2 >> 0;
data[offs++] = tlli2 >> 8;
data[offs++] = tlli2 >> 16;
data[offs++] = tlli2 >> 24;
num_chunks = Decoding::rlc_data_from_ul_data(&rdbi, cs, data,
chunks, ARRAY_SIZE(chunks), &tlli);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(tlli == tlli2);
OSMO_ASSERT(chunks[0].offset == 6);
OSMO_ASSERT(chunks[0].length == 11);
OSMO_ASSERT(chunks[0].is_complete);
OSMO_ASSERT(chunks[1].offset == 17);
OSMO_ASSERT(chunks[1].length == 26);
OSMO_ASSERT(chunks[1].is_complete);
OSMO_ASSERT(chunks[2].offset == 43);
OSMO_ASSERT(chunks[2].length == 1);
OSMO_ASSERT(!chunks[2].is_complete);
printf("=== end %s ===\n", __func__);
}
static void test_rlc_unit_encoder()
{
struct gprs_rlc_data_block_info rdbi = {0};
GprsCodingScheme cs;
uint8_t data[74];
uint8_t llc_data[1500] = {0,};
int num_chunks = 0;
int write_offset;
int count_payload;
struct gprs_llc llc;
Encoding::AppendResult ar;
printf("=== start %s ===\n", __func__);
llc.init();
/* TS 44.060, B.1 */
cs = GprsCodingScheme::CS4;
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 11);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 11);
OSMO_ASSERT(count_payload == 11);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 26);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 2 + 11 + 26);
OSMO_ASSERT(count_payload == 26);
OSMO_ASSERT(num_chunks == 2);
llc.reset();
llc.put_frame(llc_data, 99);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == 11);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(data[0] == ((11 << 2) | (1 << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((26 << 2) | (1 << 1) | (1 << 0)));
OSMO_ASSERT(data[2] == 0);
/* TS 44.060, B.2 */
cs = GprsCodingScheme::CS1;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 20);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 19);
OSMO_ASSERT(count_payload == 19);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(data[0] == ((0 << 2) | (0 << 1) | (1 << 0)));
OSMO_ASSERT(data[1] == 0);
/* Block 2 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
OSMO_ASSERT(llc.chunk_size() == 1);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 1);
OSMO_ASSERT(count_payload == 1);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 99);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 1 + 18);
OSMO_ASSERT(count_payload == 18);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(data[0] == ((1 << 2) | (1 << 1) | (1 << 0)));
OSMO_ASSERT(data[1] == 0);
/* TS 44.060, B.3 */
cs = GprsCodingScheme::CS1;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 7);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 7);
OSMO_ASSERT(count_payload == 7);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 11);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 2 + 7 + 11);
OSMO_ASSERT(count_payload == 11);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(data[0] == ((7 << 2) | (1 << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((11 << 2) | (0 << 1) | (1 << 0)));
OSMO_ASSERT(data[2] == 0);
/* TS 44.060, B.4 */
cs = GprsCodingScheme::CS1;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 99);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 1);
OSMO_ASSERT(write_offset == 20);
OSMO_ASSERT(count_payload == 20);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(data[0] == 0);
/* TS 44.060, B.5 */
cs = GprsCodingScheme::CS1;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 20);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, true, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 1);
OSMO_ASSERT(write_offset == 20);
OSMO_ASSERT(count_payload == 20);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(rdbi.cv == 0);
OSMO_ASSERT(data[0] == 0);
/* TS 44.060, B.7 */
cs = GprsCodingScheme::CS1;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 30);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 1);
OSMO_ASSERT(write_offset == 20);
OSMO_ASSERT(count_payload == 20);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(data[0] == 0);
/* Block 2 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
OSMO_ASSERT(llc.chunk_size() == 10);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 10);
OSMO_ASSERT(count_payload == 10);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 99);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 10 + 9);
OSMO_ASSERT(count_payload == 9);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(data[0] == ((10 << 2) | (1 << 1) | (1 << 0)));
OSMO_ASSERT(data[1] == 0);
/* TS 44.060, B.8.1 */
cs = GprsCodingScheme::MCS4;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 11);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 11);
OSMO_ASSERT(count_payload == 11);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 26);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 2 + 11 + 26);
OSMO_ASSERT(count_payload == 26);
OSMO_ASSERT(num_chunks == 2);
llc.reset();
llc.put_frame(llc_data, 99);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == 5);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(data[0] == ((11 << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((26 << 1) | (1 << 0)));
OSMO_ASSERT(data[2] == 0);
/* TS 44.060, B.8.2 */
/* Note that the spec confuses the byte numbering here, since it
* includes the FBI/E header bits into the N2 octet count which
* is not consistent with Section 10.3a.1 & 10.3a.2. */
cs = GprsCodingScheme::MCS2;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 15);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 15);
OSMO_ASSERT(count_payload == 15);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 12);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
/* no LI here, becaues there are exact 12 bytes left. Put LI into next frame */
OSMO_ASSERT(ar == Encoding::AR_NEED_MORE_BLOCKS);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == 12);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(data[0] == ((15 << 1) | (1 << 0)));
OSMO_ASSERT(data[1] == 0);
/* Block 2 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
OSMO_ASSERT(llc.chunk_size() == 0);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 0);
OSMO_ASSERT(count_payload == 0);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 7);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(write_offset == 2 + 0 + 7);
OSMO_ASSERT(count_payload == 7);
OSMO_ASSERT(num_chunks == 2);
llc.reset();
llc.put_frame(llc_data, 18);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv != 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == 18);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(data[0] == ((0 << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((7 << 1) | (0 << 0)));
OSMO_ASSERT(data[2] == ((18 << 1) | (1 << 0)));
OSMO_ASSERT(data[3] == 0);
/* Block 3 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, 6);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, false, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_SPACE_LEFT);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(write_offset == 1 + 6);
OSMO_ASSERT(count_payload == 6);
OSMO_ASSERT(num_chunks == 1);
llc.reset();
llc.put_frame(llc_data, 12);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, true, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv == 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == 12);
OSMO_ASSERT(num_chunks == 3);
OSMO_ASSERT(data[0] == ((6 << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((12 << 1) | (0 << 0)));
OSMO_ASSERT(data[2] == ((127 << 1) | (1 << 0)));
OSMO_ASSERT(data[3] == 0);
/* TS 44.060, B.8.3 */
/* Note that the spec confuses the byte numbering here, too (see above) */
cs = GprsCodingScheme::MCS2;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, rdbi.data_len);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, true, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 1);
OSMO_ASSERT(rdbi.cv == 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == rdbi.data_len);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(data[0] == 0);
/* Final block with an LLC of size data_len-1 */
cs = GprsCodingScheme::MCS2;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, rdbi.data_len - 1);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, true, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv == 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == rdbi.data_len - 1);
OSMO_ASSERT(num_chunks == 1);
OSMO_ASSERT(data[0] == (((rdbi.data_len-1) << 1) | (1 << 0)));
OSMO_ASSERT(data[1] == 0);
/* Final block with an LLC of size data_len-2 */
cs = GprsCodingScheme::MCS2;
/* Block 1 */
gprs_rlc_data_block_info_init(&rdbi, cs, false);
num_chunks = 0;
write_offset = 0;
memset(data, 0, sizeof(data));
llc.reset();
llc.put_frame(llc_data, rdbi.data_len - 2);
count_payload = -1;
ar = Encoding::rlc_data_to_dl_append(&rdbi, cs,
&llc, &write_offset, &num_chunks, data, true, &count_payload);
OSMO_ASSERT(ar == Encoding::AR_COMPLETED_BLOCK_FILLED);
OSMO_ASSERT(rdbi.e == 0);
OSMO_ASSERT(rdbi.cv == 0);
OSMO_ASSERT(write_offset == (int)rdbi.data_len);
OSMO_ASSERT(count_payload == rdbi.data_len - 2);
OSMO_ASSERT(num_chunks == 2);
OSMO_ASSERT(data[0] == (((rdbi.data_len-2) << 1) | (0 << 0)));
OSMO_ASSERT(data[1] == ((127 << 1) | (1 << 0)));
OSMO_ASSERT(data[2] == 0);
printf("=== end %s ===\n", __func__);
}
static void test_rlc_unaligned_copy()
{
uint8_t bits[256];
uint8_t saved_block[256];
uint8_t test_block[256];
uint8_t out_block[256];
GprsCodingScheme::Scheme scheme;
int pattern;
volatile unsigned int block_idx, i;
for (scheme = GprsCodingScheme::CS1;
scheme < GprsCodingScheme::NUM_SCHEMES;
scheme = GprsCodingScheme::Scheme(scheme + 1))
{
GprsCodingScheme cs(scheme);
for (pattern = 0; pattern <= 0xff; pattern += 0xff) {
/* prepare test block */
test_block[0] = pattern ^ 0xff;
for (i = 1; i + 1 < cs.maxDataBlockBytes(); i++)
test_block[i] = i;
test_block[cs.maxDataBlockBytes()-1] = pattern ^ 0xff;
for (block_idx = 0;
block_idx < cs.numDataBlocks();
block_idx++)
{
struct gprs_rlc_data_info rlc;
gprs_rlc_data_info_init_dl(&rlc, cs, false);
memset(bits, pattern, sizeof(bits));
Decoding::rlc_copy_to_aligned_buffer(
&rlc, block_idx, bits, saved_block);
fprintf(stderr,
"Test data block: %s\n",
osmo_hexdump(test_block, cs.maxDataBlockBytes()));
Encoding::rlc_copy_from_aligned_buffer(
&rlc, block_idx, bits, test_block);
fprintf(stderr,
"Encoded message block, %s, idx %d, "
"pattern %02x: %s\n",
rlc.cs.name(), block_idx, pattern,
osmo_hexdump(bits, cs.sizeDL()));
Decoding::rlc_copy_to_aligned_buffer(
&rlc, block_idx, bits, out_block);
fprintf(stderr,
"Out data block: %s\n",
osmo_hexdump(out_block, cs.maxDataBlockBytes()));
/* restore original bits */
Encoding::rlc_copy_from_aligned_buffer(
&rlc, block_idx, bits, saved_block);
OSMO_ASSERT(memcmp(test_block, out_block,
rlc.cs.maxDataBlockBytes()) == 0);
for (i = 0; i < sizeof(bits); i++)
OSMO_ASSERT(bits[i] == pattern);
}
}
}
}
static void test_rlc_info_init()
{
struct gprs_rlc_data_info rlc;
printf("=== start %s ===\n", __func__);
gprs_rlc_data_info_init_dl(&rlc, GprsCodingScheme(GprsCodingScheme::CS1), false);
OSMO_ASSERT(rlc.num_data_blocks == 1);
OSMO_ASSERT(rlc.data_offs_bits[0] == 24);
OSMO_ASSERT(rlc.block_info[0].data_len == 20);
gprs_rlc_data_info_init_dl(&rlc, GprsCodingScheme(GprsCodingScheme::MCS1), false);
OSMO_ASSERT(rlc.num_data_blocks == 1);
OSMO_ASSERT(rlc.data_offs_bits[0] == 33);
OSMO_ASSERT(rlc.block_info[0].data_len == 22);
printf("=== end %s ===\n", __func__);
}
static const struct log_info_cat default_categories[] = {
{"DCSN1", "\033[1;31m", "Concrete Syntax Notation One (CSN1)", LOGL_INFO, 0},
{"DL1IF", "\033[1;32m", "GPRS PCU L1 interface (L1IF)", LOGL_DEBUG, 1},
{"DRLCMAC", "\033[0;33m", "GPRS RLC/MAC layer (RLCMAC)", LOGL_DEBUG, 1},
{"DRLCMACDATA", "\033[0;33m", "GPRS RLC/MAC layer Data (RLCMAC)", LOGL_DEBUG, 1},
{"DRLCMACDL", "\033[1;33m", "GPRS RLC/MAC layer Downlink (RLCMAC)", LOGL_DEBUG, 1},
{"DRLCMACUL", "\033[1;36m", "GPRS RLC/MAC layer Uplink (RLCMAC)", LOGL_DEBUG, 1},
{"DRLCMACSCHED", "\033[0;36m", "GPRS RLC/MAC layer Scheduling (RLCMAC)", LOGL_DEBUG, 1},
{"DRLCMACMEAS", "\033[1;31m", "GPRS RLC/MAC layer Measurements (RLCMAC)", LOGL_INFO, 1},
{"DNS","\033[1;34m", "GPRS Network Service Protocol (NS)", LOGL_INFO , 1},
{"DBSSGP","\033[1;34m", "GPRS BSS Gateway Protocol (BSSGP)", LOGL_INFO , 1},
{"DPCU", "\033[1;35m", "GPRS Packet Control Unit (PCU)", LOGL_NOTICE, 1},
};
static int filter_fn(const struct log_context *ctx,
struct log_target *tar)
{
return 1;
}
const struct log_info debug_log_info = {
filter_fn,
(struct log_info_cat*)default_categories,
ARRAY_SIZE(default_categories),
};
static void setup_bts(BTS *the_bts, uint8_t ts_no, uint8_t cs = 1)
{
gprs_rlcmac_bts *bts;
gprs_rlcmac_trx *trx;
bts = the_bts->bts_data();
bts->egprs_enabled = true;
bts->alloc_algorithm = alloc_algorithm_a;
bts->initial_cs_dl = cs;
bts->initial_cs_ul = cs;
trx = &bts->trx[0];
trx->pdch[ts_no].enable();
}
static void uplink_header_type_2_parsing_test(BTS *the_bts,
uint8_t ts_no, uint32_t tlli, uint32_t *fn, uint16_t qta,
uint8_t ms_class)
{
GprsMs *ms;
struct pcu_l1_meas meas;
int tfi = 0;
gprs_rlcmac_bts *bts;
RlcMacUplink_t ulreq = {0};
uint8_t data[79] = {0};
struct gprs_rlc_ul_header_egprs_2 *egprs2 = NULL;
egprs2 = (struct gprs_rlc_ul_header_egprs_2 *) data;
bts = the_bts->bts_data();
tfi = 1;
struct gprs_rlc_data_info rlc;
GprsCodingScheme cs;
int rc, offs;
/*without padding*/
cs = GprsCodingScheme::MCS5;
egprs2 = (struct gprs_rlc_ul_header_egprs_2 *) data;
egprs2->r = 1;
egprs2->si = 1;
egprs2->cv = 7;
egprs2->tfi_hi = tfi & 0x03;
egprs2->tfi_lo = (tfi & 0x1c) >> 2;
egprs2->bsn1_hi = 0;
egprs2->bsn1_lo = 0;
egprs2->cps_hi = 3;
egprs2->cps_lo = 0;
egprs2->rsb = 0;
egprs2->pi = 0;
data[4] = 0x20; /* Setting E field */
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
offs = rlc.data_offs_bits[0] / 8;
OSMO_ASSERT(offs == 4);
OSMO_ASSERT(rlc.tfi == 1);
OSMO_ASSERT(rlc.num_data_blocks == 1);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 0);
/* with padding case */
cs = GprsCodingScheme::MCS6;
egprs2 = (struct gprs_rlc_ul_header_egprs_2 *) data;
egprs2->r = 1;
egprs2->si = 1;
egprs2->cv = 7;
egprs2->tfi_hi = tfi & 0x03;
egprs2->tfi_lo = (tfi & 0x1c) >> 2;
egprs2->bsn1_hi = 0;
egprs2->bsn1_lo = 0;
egprs2->cps_hi = 3;
egprs2->cps_lo = 0;
egprs2->rsb = 0;
egprs2->pi = 0;
data[10] = 0x20; /* Setting E field */
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
offs = rlc.data_offs_bits[0] / 8;
OSMO_ASSERT(offs == 10);
OSMO_ASSERT(rlc.num_data_blocks == 1);
OSMO_ASSERT(rlc.tfi == 1);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 0);
egprs2->r = 1;
egprs2->si = 1;
egprs2->cv = 7;
egprs2->tfi_hi = tfi & 0x03;
egprs2->tfi_lo = (tfi & 0x1c) >> 2;
egprs2->bsn1_hi = 1;
egprs2->bsn1_lo = 0;
egprs2->cps_hi = 2;
egprs2->cps_lo = 0;
egprs2->rsb = 0;
egprs2->pi = 0;
data[10] = 0x20; /* Setting E field */
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
offs = rlc.data_offs_bits[0] / 8;
OSMO_ASSERT(offs == 10);
OSMO_ASSERT(rlc.tfi == 1);
OSMO_ASSERT(rlc.num_data_blocks == 1);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 1);
}
static void uplink_header_type2_test(void)
{
BTS the_bts;
int ts_no = 7;
uint32_t fn = 2654218;
uint16_t qta = 31;
uint32_t tlli = 0xf1223344;
const char *imsi = "0011223344";
uint8_t ms_class = 1;
gprs_rlcmac_ul_tbf *ul_tbf;
GprsMs *ms;
printf("=== start %s ===\n", __func__);
setup_bts(&the_bts, ts_no, 10);
uplink_header_type_2_parsing_test(&the_bts, ts_no,
tlli, &fn, qta, ms_class);
printf("=== end %s ===\n", __func__);
}
static void uplink_header_type_1_parsing_test(BTS *the_bts,
uint8_t ts_no, uint32_t tlli, uint32_t *fn, uint16_t qta,
uint8_t ms_class)
{
uint8_t trx_no = 0;
int tfi = 0;
struct gprs_rlcmac_pdch *pdch;
gprs_rlcmac_bts *bts;
uint8_t data[155] = {0};
struct gprs_rlc_ul_header_egprs_1 *egprs1 = NULL;
struct gprs_rlc_data_info rlc;
GprsCodingScheme cs;
int rc, offs;
egprs1 = (struct gprs_rlc_ul_header_egprs_1 *) data;
bts = the_bts->bts_data();
tfi = 1;
/* MCS 7 */
cs = GprsCodingScheme::MCS7;
egprs1 = (struct gprs_rlc_ul_header_egprs_1 *) data;
egprs1->si = 1;
egprs1->r = 1;
egprs1->cv = 7;
egprs1->tfi_hi = tfi & 0x03;
egprs1->tfi_lo = (tfi & 0x1c) >> 2;
egprs1->bsn1_hi = 0;
egprs1->bsn1_lo = 0;
egprs1->bsn2_hi = 1;
egprs1->bsn2_lo = 0;
egprs1->cps = 15;
egprs1->rsb = 0;
egprs1->pi = 0;
data[5] = 0xc0;
data[5 + 57] = 1;
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
OSMO_ASSERT(rlc.num_data_blocks == 2);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 1);
OSMO_ASSERT(rlc.block_info[1].e == 1);
OSMO_ASSERT(rlc.block_info[1].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 0);
OSMO_ASSERT(rlc.block_info[1].bsn == 1);
OSMO_ASSERT(rlc.tfi == 1);
/* MCS 8 */
cs = GprsCodingScheme::MCS8;
egprs1 = (struct gprs_rlc_ul_header_egprs_1 *) data;
egprs1->si = 1;
egprs1->r = 1;
egprs1->cv = 7;
egprs1->tfi_hi = tfi & 0x03;
egprs1->tfi_lo = (tfi & 0x1c) >> 2;
egprs1->bsn1_hi = 0;
egprs1->bsn1_lo = 0;
egprs1->bsn2_hi = 1;
egprs1->bsn2_lo = 0;
egprs1->cps = 15;
egprs1->rsb = 0;
egprs1->pi = 0;
data[5] = 0xc0;
data[5 + 69] = 1;
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
OSMO_ASSERT(rlc.num_data_blocks == 2);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 1);
OSMO_ASSERT(rlc.block_info[1].e == 1);
OSMO_ASSERT(rlc.block_info[1].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 0);
OSMO_ASSERT(rlc.block_info[1].bsn == 1);
OSMO_ASSERT(rlc.tfi == 1);
/* MCS 9 */
cs = GprsCodingScheme::MCS9;
egprs1 = (struct gprs_rlc_ul_header_egprs_1 *) data;
egprs1->si = 1;
egprs1->r = 1;
egprs1->cv = 7;
egprs1->tfi_hi = tfi & 0x03;
egprs1->tfi_lo = (tfi & 0x1c) >> 2;
egprs1->bsn1_hi = 0;
egprs1->bsn1_lo = 0;
egprs1->bsn2_hi = 1;
egprs1->bsn2_lo = 0;
egprs1->cps = 15;
egprs1->rsb = 0;
egprs1->pi = 0;
data[5] = 0xc0;
data[5 + 75] = 1;
rc = Decoding::rlc_parse_ul_data_header(&rlc, data, cs);
OSMO_ASSERT(rlc.num_data_blocks == 2);
OSMO_ASSERT(rlc.block_info[0].e == 1);
OSMO_ASSERT(rlc.block_info[0].ti == 1);
OSMO_ASSERT(rlc.block_info[1].e == 1);
OSMO_ASSERT(rlc.block_info[1].ti == 0);
OSMO_ASSERT(rlc.block_info[0].bsn == 0);
OSMO_ASSERT(rlc.block_info[1].bsn == 1);
OSMO_ASSERT(rlc.tfi == 1);
}
void uplink_header_type1_test(void)
{
BTS the_bts;
int ts_no = 7;
uint32_t fn = 2654218;
uint16_t qta = 31;
uint32_t tlli = 0xf1223344;
const char *imsi = "0011223344";
uint8_t ms_class = 1;
gprs_rlcmac_ul_tbf *ul_tbf;
GprsMs *ms;
printf("=== start %s ===\n", __func__);
setup_bts(&the_bts, ts_no, 12);
uplink_header_type_1_parsing_test(&the_bts, ts_no, tlli, &fn,
qta, ms_class);
printf("=== end %s ===\n", __func__);
}
int main(int argc, char **argv)
{
struct vty_app_info pcu_vty_info = {0};
tall_pcu_ctx = talloc_named_const(NULL, 1, "EdgeTest context");
if (!tall_pcu_ctx)
abort();
msgb_set_talloc_ctx(tall_pcu_ctx);
osmo_init_logging(&debug_log_info);
log_set_use_color(osmo_stderr_target, 0);
log_set_print_filename(osmo_stderr_target, 0);
vty_init(&pcu_vty_info);
pcu_vty_init(&debug_log_info);
test_coding_scheme();
test_rlc_info_init();
test_rlc_unit_decoder();
test_rlc_unaligned_copy();
test_rlc_unit_encoder();
uplink_header_type2_test();
uplink_header_type1_test();
if (getenv("TALLOC_REPORT_FULL"))
talloc_report_full(tall_pcu_ctx, stderr);
return EXIT_SUCCESS;
}
/*
* stubs that should not be reached
*/
extern "C" {
void l1if_pdch_req() { abort(); }
void l1if_connect_pdch() { abort(); }
void l1if_close_pdch() { abort(); }
void l1if_open_pdch() { abort(); }
}