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srsRAN_4G/srsenb/test/mac/sched_common_test_suite.cc

341 lines
14 KiB
C++

/**
*
* \section COPYRIGHT
*
* Copyright 2013-2020 Software Radio Systems Limited
*
* By using this file, you agree to the terms and conditions set
* forth in the LICENSE file which can be found at the top level of
* the distribution.
*
*/
#include "sched_common_test_suite.h"
#include "lib/include/srslte/phy/phch/prach.h"
#include "srslte/common/test_common.h"
#include <set>
using srslte::tti_point;
namespace srsenb {
int test_pusch_collisions(const sf_output_res_t& sf_out, uint32_t enb_cc_idx, const prbmask_t* expected_ul_mask)
{
auto& cell_params = sf_out.cc_params[enb_cc_idx];
auto& ul_result = sf_out.ul_cc_result[enb_cc_idx];
uint32_t nof_prb = cell_params.nof_prb();
prbmask_t ul_allocs(nof_prb);
auto try_ul_fill = [&](prb_interval alloc, const char* ch_str, bool strict = true) {
CONDERROR(alloc.stop() > nof_prb, "Allocated RBs %s out-of-bounds\n", alloc.to_string().c_str());
CONDERROR(alloc.empty(), "Allocations must have at least one PRB\n");
if (strict and ul_allocs.any(alloc.start(), alloc.stop())) {
TESTERROR("Collision Detected of %s alloc=%s and cumulative_mask=0x%s\n",
ch_str,
alloc.to_string().c_str(),
ul_allocs.to_hex().c_str());
}
ul_allocs.fill(alloc.start(), alloc.stop(), true);
return SRSLTE_SUCCESS;
};
/* TEST: Check if there is space for PRACH */
bool is_prach_tti_tx_ul =
srslte_prach_tti_opportunity_config_fdd(cell_params.cfg.prach_config, to_tx_ul(sf_out.tti_rx).to_uint(), -1);
if (is_prach_tti_tx_ul) {
try_ul_fill({cell_params.cfg.prach_freq_offset, cell_params.cfg.prach_freq_offset + 6}, "PRACH");
}
/* TEST: check collisions in PUCCH */
bool strict = nof_prb != 6 or (not is_prach_tti_tx_ul); // and not tti_data.ul_pending_msg3_present);
try_ul_fill({0, (uint32_t)cell_params.cfg.nrb_pucch}, "PUCCH", strict);
try_ul_fill({cell_params.cfg.cell.nof_prb - cell_params.cfg.nrb_pucch, (uint32_t)cell_params.cfg.cell.nof_prb},
"PUCCH",
strict);
/* TEST: check collisions in the UL PUSCH */
for (uint32_t i = 0; i < ul_result.nof_dci_elems; ++i) {
uint32_t L, RBstart;
srslte_ra_type2_from_riv(ul_result.pusch[i].dci.type2_alloc.riv, &L, &RBstart, nof_prb, nof_prb);
strict = ul_result.pusch[i].needs_pdcch or nof_prb != 6; // Msg3 may collide with PUCCH at PRB==6
try_ul_fill({RBstart, RBstart + L}, "PUSCH", strict);
}
CONDERROR(expected_ul_mask != nullptr and *expected_ul_mask != ul_allocs,
"The derived UL PRB mask %s does not match the expected one %s\n",
ul_allocs.to_string().c_str(),
expected_ul_mask->to_string().c_str());
return SRSLTE_SUCCESS;
}
int extract_dl_prbmask(const srslte_cell_t& cell,
const srslte_dci_dl_t& dci,
srslte::bounded_bitset<100, true>& alloc_mask)
{
srslte_pdsch_grant_t grant;
srslte_dl_sf_cfg_t dl_sf = {};
alloc_mask.resize(cell.nof_prb);
alloc_mask.reset();
CONDERROR(srslte_ra_dl_dci_to_grant(&cell, &dl_sf, SRSLTE_TM1, false, &dci, &grant) == SRSLTE_ERROR,
"Failed to decode PDSCH grant\n");
for (uint32_t j = 0; j < alloc_mask.size(); ++j) {
if (grant.prb_idx[0][j]) {
alloc_mask.set(j);
}
}
return SRSLTE_SUCCESS;
}
int test_pdsch_collisions(const sf_output_res_t& sf_out, uint32_t enb_cc_idx, const rbgmask_t* expected_rbgmask)
{
auto& cell_params = sf_out.cc_params[enb_cc_idx];
auto& dl_result = sf_out.dl_cc_result[enb_cc_idx];
srslte::bounded_bitset<100, true> dl_allocs(cell_params.nof_prb()), alloc_mask(cell_params.nof_prb());
rbgmask_t rbgmask{cell_params.nof_rbgs};
auto try_dl_mask_fill = [&](const srslte_dci_dl_t& dci, const char* channel) {
if (extract_dl_prbmask(cell_params.cfg.cell, dci, alloc_mask) != SRSLTE_SUCCESS) {
return SRSLTE_ERROR;
}
CONDERROR(alloc_mask.none(), "DL allocation must occupy at least one RBG.\n");
if ((dl_allocs & alloc_mask).any()) {
TESTERROR("Detected collision in the DL %s allocation (%s intersects %s)\n",
channel,
dl_allocs.to_string().c_str(),
alloc_mask.to_string().c_str());
}
dl_allocs |= alloc_mask;
return SRSLTE_SUCCESS;
};
// Decode BC allocations, check collisions, and fill cumulative mask
for (uint32_t i = 0; i < dl_result.nof_bc_elems; ++i) {
TESTASSERT(try_dl_mask_fill(dl_result.bc[i].dci, "BC") == SRSLTE_SUCCESS);
}
// Decode RAR allocations, check collisions, and fill cumulative mask
for (uint32_t i = 0; i < dl_result.nof_rar_elems; ++i) {
TESTASSERT(try_dl_mask_fill(dl_result.rar[i].dci, "RAR") == SRSLTE_SUCCESS);
}
// forbid Data in DL if its ACKs conflict with PRACH for PRB==6
if (cell_params.nof_prb() == 6) {
if (srslte_prach_tti_opportunity_config_fdd(
cell_params.cfg.prach_config, to_tx_dl_ack(sf_out.tti_rx).to_uint(), -1)) {
dl_allocs.fill(0, dl_allocs.size());
}
}
// Decode Data allocations, check collisions and fill cumulative mask
for (uint32_t i = 0; i < dl_result.nof_data_elems; ++i) {
TESTASSERT(try_dl_mask_fill(dl_result.data[i].dci, "data") == SRSLTE_SUCCESS);
}
// TEST: check for holes in the PRB mask (RBGs not fully filled)
rbgmask.resize(cell_params.nof_rbgs);
rbgmask.reset();
srslte::bounded_bitset<100, true> rev_alloc = ~dl_allocs;
for (uint32_t i = 0; i < cell_params.nof_rbgs; ++i) {
uint32_t lim = SRSLTE_MIN((i + 1) * cell_params.P, dl_allocs.size());
bool val = dl_allocs.any(i * cell_params.P, lim);
CONDERROR(rev_alloc.any(i * cell_params.P, lim) and val, "No holes can be left in an RBG\n");
if (val) {
rbgmask.set(i);
}
}
CONDERROR(expected_rbgmask != nullptr and *expected_rbgmask != rbgmask,
"The derived DL RBG mask %s does not match the expected one %s\n",
rbgmask.to_string().c_str(),
expected_rbgmask->to_string().c_str());
return SRSLTE_SUCCESS;
}
/**
* - SIB1 is allocated in correct TTIs
* - TB size is adequate for SIB allocation
* - The SIBs with index>1 are allocated in expected TTI windows
*/
int test_sib_scheduling(const sf_output_res_t& sf_out, uint32_t enb_cc_idx)
{
const auto& cell_params = sf_out.cc_params[enb_cc_idx];
const auto& dl_result = sf_out.dl_cc_result[enb_cc_idx];
uint32_t sfn = to_tx_dl(sf_out.tti_rx).to_uint() / 10;
uint32_t sf_idx = to_tx_dl(sf_out.tti_rx).to_uint() % 10;
bool sib1_expected = ((sfn % 2) == 0) and sf_idx == 5;
using bc_elem = const sched_interface::dl_sched_bc_t;
bc_elem* bc_begin = &dl_result.bc[0];
bc_elem* bc_end = &dl_result.bc[dl_result.nof_bc_elems];
/* Test if SIB1 was correctly scheduled */
auto it = std::find_if(bc_begin, bc_end, [](bc_elem& elem) { return elem.index == 0; });
CONDERROR(sib1_expected and it == bc_end, "Failed to allocate SIB1 in even sfn, sf_idx==5\n");
CONDERROR(not sib1_expected and it != bc_end, "SIB1 allocated in wrong TTI.\n");
/* Test if any SIB was scheduled with wrong index, tbs, or outside of its window */
for (bc_elem* bc = bc_begin; bc != bc_end; ++bc) {
if (bc->index == 0) {
continue;
}
CONDERROR(bc->index >= sched_interface::MAX_SIBS, "Invalid SIB idx=%d\n", bc->index + 1);
CONDERROR(bc->tbs < cell_params.cfg.sibs[bc->index].len,
"Allocated BC process with TBS=%d < sib_len=%d\n",
bc->tbs,
cell_params.cfg.sibs[bc->index].len);
uint32_t x = (bc->index - 1) * cell_params.cfg.si_window_ms;
uint32_t sf = x % 10;
uint32_t sfn_start = sfn;
while ((sfn_start % cell_params.cfg.sibs[bc->index].period_rf) != x / 10) {
sfn_start--;
}
srslte::tti_point win_start{sfn_start * 10 + sf};
srslte::tti_interval window{win_start, win_start + cell_params.cfg.si_window_ms};
CONDERROR(not window.contains(to_tx_dl(sf_out.tti_rx)), "Scheduled SIB is outside of its SIB window\n");
}
return SRSLTE_SUCCESS;
}
int test_pdcch_collisions(const sf_output_res_t& sf_out,
uint32_t enb_cc_idx,
const srslte::bounded_bitset<128, true>* expected_cce_mask)
{
const auto& cell_params = sf_out.cc_params[enb_cc_idx];
const auto& dl_result = sf_out.dl_cc_result[enb_cc_idx];
const auto& ul_result = sf_out.ul_cc_result[enb_cc_idx];
int ret = srslte_regs_pdcch_ncce(cell_params.regs.get(), dl_result.cfi);
TESTASSERT(ret > 0);
uint32_t ncce = ret;
srslte::bounded_bitset<128, true> used_cce{ncce};
// Helper Function: checks if there is any collision. If not, fills the PDCCH mask
auto try_cce_fill = [&](const srslte_dci_location_t& dci_loc, const char* ch) {
uint32_t cce_start = dci_loc.ncce, cce_stop = dci_loc.ncce + (1u << dci_loc.L);
CONDERROR(dci_loc.L == 0, "The aggregation level %d is not valid\n", dci_loc.L);
CONDERROR(
cce_start >= ncce or cce_stop > ncce, "The CCE positions (%u, %u) do not fit in PDCCH\n", cce_start, cce_stop);
CONDERROR(used_cce.any(cce_start, cce_stop),
"%s DCI collision between CCE positions (%u, %u)\n",
ch,
cce_start,
cce_stop);
used_cce.fill(cce_start, cce_stop);
return SRSLTE_SUCCESS;
};
/* TEST: verify there are no dci collisions for UL, DL data, BC, RAR */
for (uint32_t i = 0; i < ul_result.nof_dci_elems; ++i) {
const auto& pusch = ul_result.pusch[i];
if (not pusch.needs_pdcch) {
// In case of non-adaptive retx or Msg3
continue;
}
try_cce_fill(pusch.dci.location, "UL");
}
for (uint32_t i = 0; i < dl_result.nof_data_elems; ++i) {
try_cce_fill(dl_result.data[i].dci.location, "DL data");
}
for (uint32_t i = 0; i < dl_result.nof_bc_elems; ++i) {
try_cce_fill(dl_result.bc[i].dci.location, "DL BC");
}
for (uint32_t i = 0; i < dl_result.nof_rar_elems; ++i) {
try_cce_fill(dl_result.rar[i].dci.location, "DL RAR");
}
CONDERROR(expected_cce_mask != nullptr and *expected_cce_mask != used_cce,
"The derived PDCCH mask %s does not match the expected one %s\n",
used_cce.to_string().c_str(),
expected_cce_mask->to_string().c_str());
return SRSLTE_SUCCESS;
}
int test_dci_content_common(const sf_output_res_t& sf_out, uint32_t enb_cc_idx)
{
const auto& cell_params = sf_out.cc_params[enb_cc_idx];
const auto& dl_result = sf_out.dl_cc_result[enb_cc_idx];
const auto& ul_result = sf_out.ul_cc_result[enb_cc_idx];
std::set<uint16_t> alloc_rntis;
for (uint32_t i = 0; i < ul_result.nof_dci_elems; ++i) {
const auto& pusch = ul_result.pusch[i];
uint16_t rnti = pusch.dci.rnti;
CONDERROR(pusch.tbs == 0, "Allocated PUSCH with invalid TBS=%d\n", pusch.tbs);
CONDERROR(alloc_rntis.count(rnti) > 0, "The user rnti=0x%x got allocated multiple times in UL\n", rnti);
alloc_rntis.insert(pusch.dci.rnti);
CONDERROR(not((pusch.current_tx_nb == 0) xor (pusch.dci.tb.rv != 0)), "Number of txs incorrectly set\n");
if (not pusch.needs_pdcch) {
// In case of non-adaptive retx or Msg3
continue;
}
if (pusch.dci.tb.rv == 0) {
// newTx
CONDERROR(pusch.dci.format != SRSLTE_DCI_FORMAT0, "Incorrect UL DCI format\n");
CONDERROR(pusch.dci.tb.mcs_idx > 28, "Incorrect UL MCS index\n");
}
}
alloc_rntis.clear();
for (uint32_t i = 0; i < dl_result.nof_data_elems; ++i) {
auto& data = dl_result.data[i];
uint16_t rnti = data.dci.rnti;
CONDERROR(data.tbs[0] == 0 and data.tbs[1] == 0, "Allocated DL data has empty TBS\n");
CONDERROR(alloc_rntis.count(rnti) > 0, "The user rnti=0x%x got allocated multiple times in DL\n", rnti);
alloc_rntis.insert(data.dci.rnti);
for (uint32_t tb = 0; tb < 2; ++tb) {
if (data.tbs[tb] == 0) {
continue;
}
if (data.dci.tb[tb].rv == 0) {
// newTx
CONDERROR(data.nof_pdu_elems[tb] == 0, "Allocated DL grant does not have MAC SDUs\n");
CONDERROR(data.nof_pdu_elems[tb] > sched_interface::MAX_RLC_PDU_LIST,
"Number of SDUs in DL grant exceeds limit\n");
uint32_t alloc_bytes = 0;
for (uint32_t pdu = 0; pdu < data.nof_pdu_elems[tb]; ++pdu) {
alloc_bytes += data.pdu[tb][pdu].nbytes;
}
CONDERROR(alloc_bytes > data.tbs[tb], "The bytes allocated to individual MAC SDUs is larger than total TBS\n");
CONDERROR(data.dci.tb[tb].mcs_idx > 28, "Incorrect DL MCS index\n");
}
}
}
for (uint32_t i = 0; i < dl_result.nof_bc_elems; ++i) {
auto& bc = dl_result.bc[i];
if (bc.type == sched_interface::dl_sched_bc_t::BCCH) {
CONDERROR(bc.tbs < cell_params.cfg.sibs[bc.index].len,
"Allocated BC process with TBS=%d < sib_len=%d\n",
bc.tbs,
cell_params.cfg.sibs[bc.index].len);
} else if (bc.type == sched_interface::dl_sched_bc_t::PCCH) {
CONDERROR(bc.tbs == 0, "Allocated paging process with invalid TBS=%d\n", bc.tbs);
} else {
TESTERROR("Invalid broadcast process id=%d\n", (int)bc.type);
}
}
for (uint32_t i = 0; i < dl_result.nof_rar_elems; ++i) {
const auto& rar = dl_result.rar[i];
CONDERROR(rar.tbs == 0, "Allocated RAR process with invalid TBS=%d\n", rar.tbs);
}
return SRSLTE_SUCCESS;
}
int test_all_common(const sf_output_res_t& sf_out)
{
for (uint32_t i = 0; i < sf_out.cc_params.size(); ++i) {
TESTASSERT(test_pusch_collisions(sf_out, i, nullptr) == SRSLTE_SUCCESS);
TESTASSERT(test_pdsch_collisions(sf_out, i, nullptr) == SRSLTE_SUCCESS);
TESTASSERT(test_sib_scheduling(sf_out, i) == SRSLTE_SUCCESS);
TESTASSERT(test_pdcch_collisions(sf_out, i, nullptr) == SRSLTE_SUCCESS);
TESTASSERT(test_dci_content_common(sf_out, i) == SRSLTE_SUCCESS);
}
return SRSLTE_SUCCESS;
}
} // namespace srsenb