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/**
* Copyright 2013-2022 Software Radio Systems Limited
*
* This file is part of srsRAN.
*
* srsRAN 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.
*
* srsRAN 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 Affero General Public License for more details.
*
* A copy of the GNU Affero General Public License can be found in
* the LICENSE file in the top-level directory of this distribution
* and at http://www.gnu.org/licenses/.
*
*/
#ifndef SRSRAN_SCHED_NR_RB_H
#define SRSRAN_SCHED_NR_RB_H
#include "srsgnb/hdr/stack/mac/sched_nr_interface.h"
#include "srsran/adt/bounded_bitset.h"
#include "srsran/phy/common/phy_common_nr.h"
namespace srsenb {
namespace sched_nr_impl {
using prb_bitmap = srsran::bounded_bitset<SRSRAN_MAX_PRB_NR, true>;
using rbg_bitmap = srsran::bounded_bitset<SCHED_NR_MAX_NOF_RBGS, true>;
/// TS 38.214, Table 6.1.2.2.1-1 - Nominal RBG size P
uint32_t get_P(uint32_t bwp_nof_prb, bool config_1_or_2);
/// TS 38.214 - total number of RBGs for a uplink bandwidth part of size "bwp_nof_prb" PRBs
uint32_t get_nof_rbgs(uint32_t bwp_nof_prb, uint32_t bwp_start, bool config1_or_2);
/// Struct to express a {min,...,max} range of PRBs
struct prb_interval : public srsran::interval<uint32_t> {
using interval::interval;
};
struct prb_grant {
prb_grant() = default;
prb_grant(const prb_interval& other) noexcept : alloc_type_0(false), alloc(other) {}
prb_grant(const rbg_bitmap& other) noexcept : alloc_type_0(true), alloc(other) {}
prb_grant(const prb_grant& other) noexcept : alloc_type_0(other.alloc_type_0), alloc(other.alloc_type_0, other.alloc)
{}
prb_grant& operator=(const prb_grant& other) noexcept
{
if (this == &other) {
return *this;
}
if (other.alloc_type_0) {
*this = other.rbgs();
} else {
*this = other.prbs();
}
return *this;
}
prb_grant& operator=(const prb_interval& prbs)
{
if (alloc_type_0) {
alloc_type_0 = false;
alloc.rbgs.~rbg_bitmap();
new (&alloc.interv) prb_interval(prbs);
} else {
alloc.interv = prbs;
}
return *this;
}
prb_grant& operator=(const rbg_bitmap& rbgs)
{
if (alloc_type_0) {
alloc.rbgs = rbgs;
} else {
alloc_type_0 = true;
alloc.interv.~prb_interval();
new (&alloc.rbgs) rbg_bitmap(rbgs);
}
return *this;
}
~prb_grant()
{
if (is_alloc_type0()) {
alloc.rbgs.~rbg_bitmap();
} else {
alloc.interv.~prb_interval();
}
}
bool is_alloc_type0() const { return alloc_type_0; }
bool is_alloc_type1() const { return not is_alloc_type0(); }
const rbg_bitmap& rbgs() const
{
srsran_assert(is_alloc_type0(), "Invalid access to rbgs() field of grant with alloc type 1");
return alloc.rbgs;
}
const prb_interval& prbs() const
{
srsran_assert(is_alloc_type1(), "Invalid access to prbs() field of grant with alloc type 0");
return alloc.interv;
}
rbg_bitmap& rbgs()
{
srsran_assert(is_alloc_type0(), "Invalid access to rbgs() field of grant with alloc type 1");
return alloc.rbgs;
}
prb_interval& prbs()
{
srsran_assert(is_alloc_type1(), "Invalid access to prbs() field of grant with alloc type 0");
return alloc.interv;
}
prb_grant& operator&=(const prb_interval interv)
{
if (is_alloc_type0()) {
alloc.rbgs &= rbg_bitmap{alloc.rbgs.size()}.fill(interv.start(), interv.stop());
} else {
alloc.interv.intersect(interv);
}
return *this;
}
private:
bool alloc_type_0 = false;
union alloc_t {
rbg_bitmap rbgs;
prb_interval interv;
alloc_t() : interv(0, 0) {}
explicit alloc_t(const prb_interval& prbs) : interv(prbs) {}
explicit alloc_t(const rbg_bitmap& rbgs_) : rbgs(rbgs_) {}
alloc_t(bool type0, const alloc_t& other)
{
if (type0) {
new (&rbgs) rbg_bitmap(other.rbgs);
} else {
new (&interv) prb_interval(other.interv);
}
}
} alloc;
};
struct bwp_rb_bitmap {
public:
bwp_rb_bitmap() = default;
bwp_rb_bitmap(uint32_t bwp_nof_prbs, uint32_t bwp_prb_start_, bool config1_or_2);
void reset()
{
prbs_.reset();
rbgs_.reset();
}
template <typename T>
void operator|=(const T& grant)
{
add(grant);
}
void add(const prb_interval& prbs)
{
prbs_.fill(prbs.start(), prbs.stop());
add_prbs_to_rbgs(prbs);
}
void add(const prb_bitmap& grant)
{
prbs_ |= grant;
add_prbs_to_rbgs(grant);
}
void add(const rbg_bitmap& grant)
{
rbgs_ |= grant;
add_rbgs_to_prbs(grant);
}
void add(const prb_grant& grant)
{
if (grant.is_alloc_type0()) {
add(grant.rbgs());
} else {
add(grant.prbs());
}
}
bool collides(const prb_grant& grant) const
{
if (grant.is_alloc_type0()) {
return (rbgs() & grant.rbgs()).any();
}
return prbs().any(grant.prbs().start(), grant.prbs().stop());
}
bool test(uint32_t prb_idx) { return prbs().test(prb_idx); }
void set(uint32_t prb_idx)
{
prbs_.set(prb_idx);
rbgs_.set(prb_to_rbg_idx(prb_idx));
}
const prb_bitmap& prbs() const { return prbs_; }
const rbg_bitmap& rbgs() const { return rbgs_; }
uint32_t P() const { return P_; }
uint32_t nof_prbs() const { return prbs_.size(); }
uint32_t nof_rbgs() const { return rbgs_.size(); }
uint32_t prb_to_rbg_idx(uint32_t prb_idx) const;
bwp_rb_bitmap& operator|=(const bwp_rb_bitmap& other)
{
prbs_ |= other.prbs_;
rbgs_ |= other.rbgs_;
return *this;
}
bwp_rb_bitmap& operator|=(const rbg_bitmap& other)
{
add(other);
return *this;
}
bwp_rb_bitmap& operator|=(const prb_bitmap& other)
{
add(other);
return *this;
}
private:
prb_bitmap prbs_;
rbg_bitmap rbgs_;
uint32_t P_ = 0;
uint32_t Pnofbits = 0;
uint32_t first_rbg_size = 0;
void add_prbs_to_rbgs(const prb_bitmap& grant);
void add_prbs_to_rbgs(const prb_interval& grant);
void add_rbgs_to_prbs(const rbg_bitmap& grant);
};
template <typename Other>
bwp_rb_bitmap operator|(const bwp_rb_bitmap& lhs, const Other& rhs)
{
return bwp_rb_bitmap(lhs) |= rhs;
}
inline prb_interval
find_next_empty_interval(const prb_bitmap& mask, size_t start_prb_idx = 0, size_t last_prb_idx = SRSRAN_MAX_PRB_NR)
{
int rb_start = mask.find_lowest(start_prb_idx, std::min(mask.size(), last_prb_idx), false);
if (rb_start != -1) {
int rb_end = mask.find_lowest(rb_start + 1, std::min(mask.size(), last_prb_idx), true);
return {(uint32_t)rb_start, (uint32_t)(rb_end < 0 ? mask.size() : rb_end)};
}
return {};
}
inline prb_interval find_empty_interval_of_length(const prb_bitmap& mask, size_t nof_prbs, uint32_t start_prb_idx = 0)
{
prb_interval max_interv;
do {
prb_interval interv = find_next_empty_interval(mask, start_prb_idx, mask.size());
if (interv.empty()) {
break;
}
if (interv.length() >= nof_prbs) {
max_interv.set(interv.start(), interv.start() + nof_prbs);
break;
}
if (interv.length() > max_interv.length()) {
max_interv = interv;
}
start_prb_idx = interv.stop() + 1;
} while (start_prb_idx < mask.size());
return max_interv;
}
} // namespace sched_nr_impl
} // namespace srsenb
namespace fmt {
template <>
struct formatter<srsenb::sched_nr_impl::prb_grant> : public formatter<srsenb::sched_nr_impl::rbg_bitmap> {
template <typename FormatContext>
auto format(const srsenb::sched_nr_impl::prb_grant& grant, FormatContext& ctx)
-> decltype(std::declval<FormatContext>().out())
{
if (grant.is_alloc_type1()) {
return formatter<srsran::interval<uint32_t> >{}.format(grant.prbs(), ctx);
}
return formatter<srsenb::sched_nr_impl::rbg_bitmap>::format(grant.rbgs(), ctx);
}
};
} // namespace fmt
#endif // SRSRAN_SCHED_NR_RB_H