Merge branch 'next' into agpl_next

master
Codebot 4 years ago committed by Your Name
commit f3da533f6b

@ -130,6 +130,12 @@ if (STOP_ON_WARNING)
add_definitions(-DSTOP_ON_WARNING) add_definitions(-DSTOP_ON_WARNING)
endif() endif()
# Test for Atomics
include(CheckAtomic)
if(NOT HAVE_CXX_ATOMICS_WITHOUT_LIB OR NOT HAVE_CXX_ATOMICS64_WITHOUT_LIB)
set(ATOMIC_LIBS "atomic")
endif()
######################################################################## ########################################################################
# Find dependencies # Find dependencies
######################################################################## ########################################################################

@ -51,6 +51,10 @@ Files: lib/include/srsran/common/backward.hpp
Copyright: 2013, Google Inc. Copyright: 2013, Google Inc.
License: MIT License: MIT
Files: cmake/modules/CheckAtomic.cmake
Copyright: 2015, Charles J. Cliffe
License: MIT
License: AGPL-3+ License: AGPL-3+
This program is free software: you can redistribute it and/or modify This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Affero General Public License as it under the terms of the GNU Affero General Public License as

@ -0,0 +1,92 @@
#
# Copyright 2013-2021 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.
#
# Adopted from https://github.com/pothosware/SoapyRTLSDR
# Copyright: 2015, Charles J. Cliffe
# License: MIT
# - Try to find if atomics need -latomic linking
# Once done this will define
# HAVE_CXX_ATOMICS_WITHOUT_LIB - Wether atomic types work without -latomic
# HAVE_CXX_ATOMICS64_WITHOUT_LIB - Wether 64 bit atomic types work without -latomic
INCLUDE(CheckCXXSourceCompiles)
INCLUDE(CheckLibraryExists)
# Sometimes linking against libatomic is required for atomic ops, if
# the platform doesn't support lock-free atomics.
function(check_working_cxx_atomics varname)
set(OLD_CMAKE_REQUIRED_FLAGS ${CMAKE_REQUIRED_FLAGS})
set(CMAKE_REQUIRED_FLAGS "${CMAKE_REQUIRED_FLAGS} -std=c++11")
CHECK_CXX_SOURCE_COMPILES("
#include <atomic>
std::atomic<int> x;
int main() {
return std::atomic_is_lock_free(&x);
}
" ${varname})
set(CMAKE_REQUIRED_FLAGS ${OLD_CMAKE_REQUIRED_FLAGS})
endfunction(check_working_cxx_atomics)
function(check_working_cxx_atomics64 varname)
set(OLD_CMAKE_REQUIRED_FLAGS ${CMAKE_REQUIRED_FLAGS})
set(CMAKE_REQUIRED_FLAGS "-std=c++11 ${CMAKE_REQUIRED_FLAGS}")
CHECK_CXX_SOURCE_COMPILES("
#include <atomic>
#include <cstdint>
std::atomic<uint64_t> x (0);
int main() {
uint64_t i = x.load(std::memory_order_relaxed);
return std::atomic_is_lock_free(&x);
}
" ${varname})
set(CMAKE_REQUIRED_FLAGS ${OLD_CMAKE_REQUIRED_FLAGS})
endfunction(check_working_cxx_atomics64)
# Check for atomic operations.
if(MSVC)
# This isn't necessary on MSVC.
set(HAVE_CXX_ATOMICS_WITHOUT_LIB True)
else()
# First check if atomics work without the library.
check_working_cxx_atomics(HAVE_CXX_ATOMICS_WITHOUT_LIB)
endif()
# If not, check if the library exists, and atomics work with it.
if(NOT HAVE_CXX_ATOMICS_WITHOUT_LIB)
check_library_exists(atomic __atomic_fetch_add_4 "" HAVE_LIBATOMIC)
if(NOT HAVE_LIBATOMIC)
message(STATUS "Host compiler appears to require libatomic, but cannot locate it.")
endif()
list(APPEND CMAKE_REQUIRED_LIBRARIES "atomic")
check_working_cxx_atomics(HAVE_CXX_ATOMICS_WITH_LIB)
if (NOT HAVE_CXX_ATOMICS_WITH_LIB)
message(FATAL_ERROR "Host compiler must support std::atomic!")
endif()
endif()
# Check for 64 bit atomic operations.
if(MSVC)
set(HAVE_CXX_ATOMICS64_WITHOUT_LIB True)
else()
check_working_cxx_atomics64(HAVE_CXX_ATOMICS64_WITHOUT_LIB)
endif()
# If not, check if the library exists, and atomics work with it.
if(NOT HAVE_CXX_ATOMICS64_WITHOUT_LIB)
check_library_exists(atomic __atomic_load_8 "" HAVE_LIBATOMIC64)
if(NOT HAVE_LIBATOMIC64)
message(STATUS "Host compiler appears to require libatomic, but cannot locate it.")
endif()
list(APPEND CMAKE_REQUIRED_LIBRARIES "atomic")
check_working_cxx_atomics64(HAVE_CXX_ATOMICS64_WITH_LIB)
if (NOT HAVE_CXX_ATOMICS64_WITH_LIB)
message(FATAL_ERROR "Host compiler must support std::atomic!")
endif()
endif()

3
debian/copyright vendored

@ -58,6 +58,9 @@ Files: lib/include/srsran/common/backward.hpp
Copyright: 2013, Google Inc. Copyright: 2013, Google Inc.
License: MIT License: MIT
Files: cmake/modules/CheckAtomic.cmake
Copyright: 2015, Charles J. Cliffe
License: MIT
License: AGPL-3+ License: AGPL-3+
This program is free software: you can redistribute it and/or modify This program is free software: you can redistribute it and/or modify

@ -28,6 +28,7 @@
#ifndef SRSRAN_MULTIQUEUE_H #ifndef SRSRAN_MULTIQUEUE_H
#define SRSRAN_MULTIQUEUE_H #define SRSRAN_MULTIQUEUE_H
#include "srsran/adt/circular_buffer.h"
#include "srsran/adt/move_callback.h" #include "srsran/adt/move_callback.h"
#include <algorithm> #include <algorithm>
#include <condition_variable> #include <condition_variable>
@ -40,92 +41,210 @@ namespace srsran {
#define MULTIQUEUE_DEFAULT_CAPACITY (8192) // Default per-queue capacity #define MULTIQUEUE_DEFAULT_CAPACITY (8192) // Default per-queue capacity
/**
* N-to-1 Message-Passing Broker that manages the creation, destruction of input ports, and popping of messages that
* are pushed to these ports.
* Each port provides a thread-safe push(...) / try_push(...) interface to enqueue messages
* The class will pop from the several created ports in a round-robin fashion.
* The popping() interface is not safe-thread. That means, that it is expected that only one thread will
* be popping tasks.
* @tparam myobj message type
*/
template <typename myobj> template <typename myobj>
class multiqueue_handler class multiqueue_handler
{ {
class circular_buffer class input_port_impl
{ {
public: public:
circular_buffer(uint32_t cap) : buffer(cap + 1) {} input_port_impl(uint32_t cap, multiqueue_handler<myobj>* parent_) : buffer(cap), parent(parent_) {}
circular_buffer(circular_buffer&& other) noexcept input_port_impl(const input_port_impl&) = delete;
input_port_impl(input_port_impl&&) = delete;
input_port_impl& operator=(const input_port_impl&) = delete;
input_port_impl& operator=(input_port_impl&&) = delete;
~input_port_impl() { deactivate_blocking(); }
size_t capacity() const { return buffer.max_size(); }
size_t size() const
{
std::lock_guard<std::mutex> lock(q_mutex);
return buffer.size();
}
bool active() const
{
std::lock_guard<std::mutex> lock(q_mutex);
return active_;
}
void set_active(bool val)
{ {
active = other.active; std::unique_lock<std::mutex> lock(q_mutex);
other.active = false; if (val == active_) {
widx = other.widx; // no-op
ridx = other.ridx; return;
buffer = std::move(other.buffer); }
active_ = val;
consumer_notify_needed = true;
if (not active_) {
buffer.clear();
lock.unlock();
// unlock blocked pushing threads
cv_full.notify_all();
}
} }
std::condition_variable cv_full; void deactivate_blocking()
bool active = true; {
set_active(false);
bool empty() const { return widx == ridx; } // wait for all the pushers to unlock
size_t size() const { return widx >= ridx ? widx - ridx : widx + (buffer.size() - ridx); } std::unique_lock<std::mutex> lock(q_mutex);
bool full() const { return (ridx > 0) ? widx == ridx - 1 : widx == buffer.size() - 1; } while (nof_waiting > 0) {
size_t capacity() const { return buffer.size() - 1; } cv_exit.wait(lock);
}
}
template <typename T> template <typename T>
void push(T&& o) noexcept void push(T&& o) noexcept
{ {
buffer[widx++] = std::forward<T>(o); push_(&o, true);
if (widx >= buffer.size()) {
widx = 0;
}
} }
void pop() noexcept bool try_push(const myobj& o) { return push_(&o, false); }
srsran::error_type<myobj> try_push(myobj&& o)
{ {
ridx++; if (push_(&o, false)) {
if (ridx >= buffer.size()) { return {};
ridx = 0;
} }
return {std::move(o)};
} }
myobj& front() noexcept { return buffer[ridx]; } bool try_pop(myobj& obj)
const myobj& front() const noexcept { return buffer[ridx]; } {
std::unique_lock<std::mutex> lock(q_mutex);
if (buffer.empty()) {
consumer_notify_needed = true;
return false;
}
obj = std::move(buffer.top());
buffer.pop();
consumer_notify_needed = false;
if (nof_waiting > 0) {
lock.unlock();
cv_full.notify_one();
}
return true;
}
private: private:
std::vector<myobj> buffer; template <typename T>
size_t widx = 0, ridx = 0; bool push_(T* o, bool blocking) noexcept
{
std::unique_lock<std::mutex> lock(q_mutex);
if (not blocking) {
// non-blocking case
if (not active_ or buffer.full()) {
return false;
}
} else {
// blocking case
while (active_ and buffer.full()) {
nof_waiting++;
cv_full.wait(lock);
nof_waiting--;
}
if (not active_) {
lock.unlock();
cv_exit.notify_one();
return false;
}
}
buffer.push(std::forward<T>(*o));
if (consumer_notify_needed) {
// Note: The consumer thread only needs to be notified and awaken when queues transition from empty to non-empty
// To ensure that the consumer noticed that the queue was empty before a push, we store the last
// try_pop() return in a member variable.
// Doing this reduces the contention of multiple producers for the same condition variable
consumer_notify_needed = false;
lock.unlock();
parent->signal_pushed_data();
}
return true;
}
multiqueue_handler<myobj>* parent = nullptr;
mutable std::mutex q_mutex;
srsran::dyn_circular_buffer<myobj> buffer;
std::condition_variable cv_full, cv_exit;
bool active_ = true;
bool consumer_notify_needed = true;
int nof_waiting = 0;
}; };
public: public:
class queue_handle class queue_handle
{ {
public: public:
queue_handle() = default; explicit queue_handle(input_port_impl* impl_ = nullptr) : impl(impl_) {}
queue_handle(multiqueue_handler<myobj>* parent_, int id) : parent(parent_), queue_id(id) {}
template <typename FwdRef> template <typename FwdRef>
void push(FwdRef&& value) void push(FwdRef&& value)
{ {
parent->push(queue_id, std::forward<FwdRef>(value)); impl->push(std::forward<FwdRef>(value));
} }
bool try_push(const myobj& value) { return parent->try_push(queue_id, value); } bool try_push(const myobj& value) { return impl->try_push(value); }
std::pair<bool, myobj> try_push(myobj&& value) { return parent->try_push(queue_id, std::move(value)); } srsran::error_type<myobj> try_push(myobj&& value) { return impl->try_push(std::move(value)); }
size_t size() { return parent->size(queue_id); } void reset()
{
if (impl != nullptr) {
impl->deactivate_blocking();
impl = nullptr;
}
}
size_t size() { return impl->size(); }
size_t capacity() { return impl->capacity(); }
bool active() const { return impl != nullptr and impl->active(); }
bool empty() const { return impl->size() == 0; }
bool operator==(const queue_handle& other) const { return impl == other.impl; }
bool operator!=(const queue_handle& other) const { return impl != other.impl; }
private: private:
multiqueue_handler<myobj>* parent = nullptr; struct recycle_op {
int queue_id = -1; void operator()(input_port_impl* p)
{
if (p != nullptr) {
p->deactivate_blocking();
}
}
};
std::unique_ptr<input_port_impl, recycle_op> impl;
}; };
explicit multiqueue_handler(uint32_t capacity_ = MULTIQUEUE_DEFAULT_CAPACITY) : capacity(capacity_) {} explicit multiqueue_handler(uint32_t default_capacity_ = MULTIQUEUE_DEFAULT_CAPACITY) :
~multiqueue_handler() { reset(); } default_capacity(default_capacity_)
{}
~multiqueue_handler() { stop(); }
void reset() void stop()
{ {
std::unique_lock<std::mutex> lock(mutex); std::unique_lock<std::mutex> lock(mutex);
running = false; running = false;
while (nof_threads_waiting > 0) { for (auto& q : queues) {
uint32_t size = queues.size(); // signal deactivation to pushing threads in a non-blocking way
q.set_active(false);
}
while (wait_state) {
pushed_data = true;
cv_empty.notify_one(); cv_empty.notify_one();
for (uint32_t i = 0; i < size; ++i) {
queues[i].cv_full.notify_all();
}
// wait for all threads to unblock
cv_exit.wait(lock); cv_exit.wait(lock);
} }
queues.clear(); for (auto& q : queues) {
// ensure the queues are finished being deactivated
q.deactivate_blocking();
}
} }
/** /**
@ -133,197 +252,108 @@ public:
* @param capacity_ The capacity of the queue. * @param capacity_ The capacity of the queue.
* @return The index of the newly created (or reused) queue within the vector of queues. * @return The index of the newly created (or reused) queue within the vector of queues.
*/ */
int add_queue(uint32_t capacity_) queue_handle add_queue(uint32_t capacity_)
{ {
uint32_t qidx = 0; uint32_t qidx = 0;
std::lock_guard<std::mutex> lock(mutex); std::lock_guard<std::mutex> lock(mutex);
if (not running) { if (not running) {
return -1; return queue_handle();
} }
for (; qidx < queues.size() and queues[qidx].active; ++qidx) for (; qidx < queues.size() and (queues[qidx].active() or (queues[qidx].capacity() != capacity_)); ++qidx)
; ;
// check if there is a free queue of the required size // check if there is a free queue of the required size
if (qidx == queues.size() || queues[qidx].capacity() != capacity_) { if (qidx == queues.size()) {
// create new queue // create new queue
queues.emplace_back(capacity_); queues.emplace_back(capacity_, this);
qidx = queues.size() - 1; // update qidx to the last element qidx = queues.size() - 1; // update qidx to the last element
} else { } else {
queues[qidx].active = true; queues[qidx].set_active(true);
} }
return (int)qidx; return queue_handle(&queues[qidx]);
} }
/** /**
* Add queue using the default capacity of the underlying multiqueue * Add queue using the default capacity of the underlying multiqueue
* @return The queue index * @return The queue index
*/ */
int add_queue() { return add_queue(capacity); } queue_handle add_queue() { return add_queue(default_capacity); }
int nof_queues() uint32_t nof_queues() const
{ {
std::lock_guard<std::mutex> lock(mutex); std::lock_guard<std::mutex> lock(mutex);
uint32_t count = 0; uint32_t count = 0;
for (uint32_t i = 0; i < queues.size(); ++i) { for (uint32_t i = 0; i < queues.size(); ++i) {
count += queues[i].active ? 1 : 0; count += queues[i].active() ? 1 : 0;
} }
return count; return count;
} }
template <typename FwdRef> bool wait_pop(myobj* value)
void push(int q_idx, FwdRef&& value)
{
{
std::unique_lock<std::mutex> lock(mutex);
while (is_queue_active_(q_idx) and queues[q_idx].full()) {
nof_threads_waiting++;
queues[q_idx].cv_full.wait(lock);
nof_threads_waiting--;
}
if (not is_queue_active_(q_idx)) {
cv_exit.notify_one();
return;
}
queues[q_idx].push(std::forward<FwdRef>(value));
}
cv_empty.notify_one();
}
bool try_push(int q_idx, const myobj& value)
{
{
std::lock_guard<std::mutex> lock(mutex);
if (not is_queue_active_(q_idx) or queues[q_idx].full()) {
return false;
}
queues[q_idx].push(value);
}
cv_empty.notify_one();
return true;
}
std::pair<bool, myobj> try_push(int q_idx, myobj&& value)
{
{
std::lock_guard<std::mutex> lck(mutex);
if (not is_queue_active_(q_idx) or queues[q_idx].full()) {
return {false, std::move(value)};
}
queues[q_idx].push(std::move(value));
}
cv_empty.notify_one();
return {true, std::move(value)};
}
int wait_pop(myobj* value)
{ {
std::unique_lock<std::mutex> lock(mutex); std::unique_lock<std::mutex> lock(mutex);
while (running) { while (running) {
if (round_robin_pop_(value)) { if (round_robin_pop_(value)) {
if (nof_threads_waiting > 0) { return true;
lock.unlock();
queues[spin_idx].cv_full.notify_one();
}
return spin_idx;
} }
nof_threads_waiting++; pushed_data = false;
cv_empty.wait(lock); wait_state = true;
nof_threads_waiting--; while (not pushed_data) {
} cv_empty.wait(lock);
cv_exit.notify_one();
return -1;
}
int try_pop(myobj* value)
{
std::unique_lock<std::mutex> lock(mutex);
if (running) {
if (round_robin_pop_(value)) {
if (nof_threads_waiting > 0) {
lock.unlock();
queues[spin_idx].cv_full.notify_one();
}
return spin_idx;
} }
// didn't find any task wait_state = false;
return -1;
} }
cv_exit.notify_one(); cv_exit.notify_one();
return -1; return false;
}
bool empty(int qidx)
{
std::lock_guard<std::mutex> lck(mutex);
return queues[qidx].empty();
}
size_t size(int qidx)
{
std::lock_guard<std::mutex> lck(mutex);
return queues[qidx].size();
}
size_t max_size(int qidx)
{
std::lock_guard<std::mutex> lck(mutex);
return queues[qidx].capacity();
}
const myobj& front(int qidx)
{
std::lock_guard<std::mutex> lck(mutex);
return queues[qidx].front();
}
void erase_queue(int qidx)
{
std::lock_guard<std::mutex> lck(mutex);
if (is_queue_active_(qidx)) {
queues[qidx].active = false;
while (not queues[qidx].empty()) {
queues[qidx].pop();
}
}
} }
bool is_queue_active(int qidx) bool try_pop(myobj* value)
{ {
std::lock_guard<std::mutex> lck(mutex); std::unique_lock<std::mutex> lock(mutex);
return is_queue_active_(qidx); return running and round_robin_pop_(value);
} }
queue_handle get_queue_handler() { return {this, add_queue()}; }
queue_handle get_queue_handler(uint32_t size) { return {this, add_queue(size)}; }
private: private:
bool is_queue_active_(int qidx) const { return running and queues[qidx].active; }
bool round_robin_pop_(myobj* value) bool round_robin_pop_(myobj* value)
{ {
// Round-robin for all queues // Round-robin for all queues
for (const circular_buffer& q : queues) { auto it = queues.begin() + spin_idx;
spin_idx = (spin_idx + 1) % queues.size(); uint32_t count = 0;
if (is_queue_active_(spin_idx) and not queues[spin_idx].empty()) { for (; count < queues.size(); ++count, ++it) {
if (value) { if (it == queues.end()) {
*value = std::move(queues[spin_idx].front()); it = queues.begin(); // wrap-around
} }
queues[spin_idx].pop(); if (it->try_pop(*value)) {
spin_idx = (spin_idx + count + 1) % queues.size();
return true; return true;
} }
} }
return false; return false;
} }
/// Called by the producer threads to signal the consumer to unlock in wait_pop
void signal_pushed_data()
{
{
std::lock_guard<std::mutex> lock(mutex);
if (pushed_data) {
return;
}
pushed_data = true;
}
cv_empty.notify_one();
}
std::mutex mutex; mutable std::mutex mutex;
std::condition_variable cv_empty, cv_exit; std::condition_variable cv_empty, cv_exit;
uint32_t spin_idx = 0; uint32_t spin_idx = 0;
bool running = true; bool running = true, pushed_data = false, wait_state = false;
std::vector<circular_buffer> queues; std::deque<input_port_impl> queues;
uint32_t capacity = 0; uint32_t default_capacity = 0;
uint32_t nof_threads_waiting = 0;
}; };
template <typename T>
using queue_handle = typename multiqueue_handler<T>::queue_handle;
//! Specialization for tasks //! Specialization for tasks
using task_multiqueue = multiqueue_handler<move_task_t>; using task_multiqueue = multiqueue_handler<move_task_t>;
using task_queue_handle = task_multiqueue::queue_handle; using task_queue_handle = task_multiqueue::queue_handle;

@ -35,20 +35,20 @@ public:
explicit task_scheduler(uint32_t default_extern_tasks_size = 512, uint32_t nof_timers_prealloc = 100) : explicit task_scheduler(uint32_t default_extern_tasks_size = 512, uint32_t nof_timers_prealloc = 100) :
external_tasks{default_extern_tasks_size}, timers{nof_timers_prealloc} external_tasks{default_extern_tasks_size}, timers{nof_timers_prealloc}
{ {
background_queue_id = external_tasks.add_queue(); background_queue = external_tasks.add_queue();
} }
task_scheduler(const task_scheduler&) = delete; task_scheduler(const task_scheduler&) = delete;
task_scheduler(task_scheduler&&) = delete; task_scheduler(task_scheduler&&) = delete;
task_scheduler& operator=(const task_scheduler&) = delete; task_scheduler& operator=(const task_scheduler&) = delete;
task_scheduler& operator=(task_scheduler&&) = delete; task_scheduler& operator=(task_scheduler&&) = delete;
void stop() { external_tasks.reset(); } void stop() { external_tasks.stop(); }
srsran::unique_timer get_unique_timer() { return timers.get_unique_timer(); } srsran::unique_timer get_unique_timer() { return timers.get_unique_timer(); }
//! Creates new queue for tasks coming from external thread //! Creates new queue for tasks coming from external thread
srsran::task_queue_handle make_task_queue() { return external_tasks.get_queue_handler(); } srsran::task_queue_handle make_task_queue() { return external_tasks.add_queue(); }
srsran::task_queue_handle make_task_queue(uint32_t qsize) { return external_tasks.get_queue_handler(qsize); } srsran::task_queue_handle make_task_queue(uint32_t qsize) { return external_tasks.add_queue(qsize); }
//! Delays a task processing by duration_ms //! Delays a task processing by duration_ms
template <typename F> template <typename F>
@ -64,7 +64,7 @@ public:
void notify_background_task_result(srsran::move_task_t task) void notify_background_task_result(srsran::move_task_t task)
{ {
// run the notification in next tic // run the notification in next tic
external_tasks.push(background_queue_id, std::move(task)); background_queue.push(std::move(task));
} }
//! Updates timers, and run any pending internal tasks. //! Updates timers, and run any pending internal tasks.
@ -76,7 +76,7 @@ public:
bool run_next_task() bool run_next_task()
{ {
srsran::move_task_t task{}; srsran::move_task_t task{};
if (external_tasks.wait_pop(&task) >= 0) { if (external_tasks.wait_pop(&task)) {
task(); task();
run_all_internal_tasks(); run_all_internal_tasks();
return true; return true;
@ -90,7 +90,7 @@ public:
{ {
run_all_internal_tasks(); run_all_internal_tasks();
srsran::move_task_t task{}; srsran::move_task_t task{};
while (external_tasks.try_pop(&task) >= 0) { while (external_tasks.try_pop(&task)) {
task(); task();
run_all_internal_tasks(); run_all_internal_tasks();
} }
@ -110,9 +110,9 @@ private:
} }
} }
int background_queue_id = -1; ///< Queue for handling the outcomes of tasks run in the background srsran::task_multiqueue external_tasks;
srsran::task_multiqueue external_tasks; srsran::task_queue_handle background_queue; ///< Queue for handling the outcomes of tasks run in the background
srsran::timer_handler timers; srsran::timer_handler timers;
std::deque<srsran::move_task_t> internal_tasks; ///< enqueues stack tasks from within main thread. Avoids locking std::deque<srsran::move_task_t> internal_tasks; ///< enqueues stack tasks from within main thread. Avoids locking
}; };

@ -48,26 +48,6 @@
*/ */
#define SRSRAN_CSI_RS_NOF_FREQ_DOMAIN_ALLOC_OTHER 6 #define SRSRAN_CSI_RS_NOF_FREQ_DOMAIN_ALLOC_OTHER 6
/**
* @brief Describes a measurement for NZP-CSI-RS
* @note Used for fine tracking RSRP, SNR, CFO, SFO, and so on
* @note srsran_csi_channel_measurements_t is used for CSI report generation
*/
typedef struct SRSRAN_API {
float rsrp; ///< Linear scale RSRP
float rsrp_dB; ///< Logarithm scale RSRP relative to full-scale
float epre; ///< Linear scale EPRE
float epre_dB; ///< Logarithm scale EPRE relative to full-scale
float n0; ///< Linear noise level
float n0_dB; ///< Logarithm scale noise level relative to full-scale
float snr_dB; ///< Signal to noise ratio in decibels
float cfo_hz; ///< Carrier frequency offset in Hz. Only set if more than 2 symbols are available in a TRS set
float cfo_hz_max; ///< Maximum CFO in Hz that can be measured. It is set to 0 if CFO cannot be estimated
float delay_us; ///< Average measured delay in microseconds
uint32_t nof_re; ///< Number of available RE for the measurement, it can be used for weighting among different
///< measurements
} srsran_csi_trs_measurements_t;
/** /**
* @brief Calculates if the given periodicity implies a CSI-RS transmission in the given slot * @brief Calculates if the given periodicity implies a CSI-RS transmission in the given slot
* @remark Described in TS 36.211 section 7.4.1.5.3 Mapping to physical resources * @remark Described in TS 36.211 section 7.4.1.5.3 Mapping to physical resources

@ -149,6 +149,53 @@ extern "C" {
*/ */
#define SRSRAN_MAX_HARQ_PROC_UL_NR 16 // 3GPP TS 38.214 version 15.3.0 Sec. 6.1 #define SRSRAN_MAX_HARQ_PROC_UL_NR 16 // 3GPP TS 38.214 version 15.3.0 Sec. 6.1
/**
* @brief SSB bandwidth in subcarriers, described in TS 38.211 section 7.4.3.1 Time-frequency structure of an SS/PBCH
* block
*/
#define SRSRAN_SSB_BW_SUBC 240
/**
* @brief SSB duration in symbols, described in TS 38.211 section 7.4.3.1 Time-frequency structure of an SS/PBCH block
*/
#define SRSRAN_SSB_DURATION_NSYMB 4
/**
* @brief Number of NR N_id_1 Physical Cell Identifier (PCI) as described in TS 38.211 section 7.4.2.1 Physical-layer
* cell identities
*/
#define SRSRAN_NOF_NID_1_NR 336
/**
* @brief Number of NR N_id_2 Physical Cell Identifier (PCI) as described in TS 38.211 section 7.4.2.1 Physical-layer
* cell identities
*/
#define SRSRAN_NOF_NID_2_NR 3
/**
* @brief Number of NR N_id Physical Cell Identifier (PCI) as described in TS 38.211 section 7.4.2.1 Physical-layer
* cell identities
*/
#define SRSRAN_NOF_NID_NR (SRSRAN_NOF_NID_1_NR * SRSRAN_NOF_NID_2_NR)
/**
* @brief Compute N_id_1 from the Physical Cell Identifier (PCI) as described in TS 38.211 section 7.4.2.1
* Physical-layer cell identities
*/
#define SRSRAN_NID_1_NR(N_ID) ((N_ID) / SRSRAN_NOF_NID_2_NR)
/**
* @brief Compute N_id_2 from the Physical Cell Identifier (PCI) as described in TS 38.211 section 7.4.2.1
* Physical-layer cell identities
*/
#define SRSRAN_NID_2_NR(N_ID) ((N_ID) % SRSRAN_NOF_NID_2_NR)
/**
* @brief SSB number of resource elements, described in TS 38.211 section 7.4.3.1 Time-frequency structure of an SS/PBCH
* block
*/
#define SRSRAN_SSB_NOF_RE (SRSRAN_SSB_BW_SUBC * SRSRAN_SSB_DURATION_NSYMB)
typedef enum SRSRAN_API { typedef enum SRSRAN_API {
srsran_coreset_mapping_type_non_interleaved = 0, srsran_coreset_mapping_type_non_interleaved = 0,
srsran_coreset_mapping_type_interleaved, srsran_coreset_mapping_type_interleaved,
@ -385,6 +432,26 @@ typedef struct SRSRAN_API {
srsran_tdd_pattern_t pattern2; srsran_tdd_pattern_t pattern2;
} srsran_tdd_config_nr_t; } srsran_tdd_config_nr_t;
/**
* @brief Describes a measurement based on NZP-CSI-RS or SSB-CSI
* @note Used for tracking RSRP, SNR, CFO, SFO, and so on
* @note srsran_csi_channel_measurements_t is used for CSI report generation
*/
typedef struct SRSRAN_API {
float rsrp; ///< Linear scale RSRP
float rsrp_dB; ///< Logarithm scale RSRP relative to full-scale
float epre; ///< Linear scale EPRE
float epre_dB; ///< Logarithm scale EPRE relative to full-scale
float n0; ///< Linear noise level
float n0_dB; ///< Logarithm scale noise level relative to full-scale
float snr_dB; ///< Signal to noise ratio in decibels
float cfo_hz; ///< Carrier frequency offset in Hz. Only set if more than 2 symbols are available in a TRS set
float cfo_hz_max; ///< Maximum CFO in Hz that can be measured. It is set to 0 if CFO cannot be estimated
float delay_us; ///< Average measured delay in microseconds
uint32_t nof_re; ///< Number of available RE for the measurement, it can be used for weighting among different
///< measurements
} srsran_csi_trs_measurements_t;
/** /**
* @brief Get the RNTI type name for NR * @brief Get the RNTI type name for NR
* @param rnti_type RNTI type name * @param rnti_type RNTI type name
@ -458,10 +525,10 @@ SRSRAN_API uint32_t srsran_min_symbol_sz_rb(uint32_t nof_prb);
* @remark All symbol size reference and values are taken from TS 38.211 section 5.3 OFDM baseband signal generation * @remark All symbol size reference and values are taken from TS 38.211 section 5.3 OFDM baseband signal generation
* @param l0 First symbol index within the slot * @param l0 First symbol index within the slot
* @param l1 Second symbol index within the slot * @param l1 Second symbol index within the slot
* @param numerology NR Carrier numerology * @param scs Subcarrier spacing
* @return Returns the time in seconds between the two symbols if the condition above is satisfied, 0 seconds otherwise * @return Returns the time in seconds between the two symbols if the condition above is satisfied, 0 seconds otherwise
*/ */
SRSRAN_API float srsran_symbol_distance_s(uint32_t l0, uint32_t l1, uint32_t numerology); SRSRAN_API float srsran_symbol_distance_s(uint32_t l0, uint32_t l1, srsran_subcarrier_spacing_t scs);
/** /**
* @brief Decides whether a given slot is configured as Downlink * @brief Decides whether a given slot is configured as Downlink
@ -483,6 +550,15 @@ SRSRAN_API bool srsran_tdd_nr_is_ul(const srsran_tdd_config_nr_t* cfg, uint32_t
SRSRAN_API int srsran_carrier_to_cell(const srsran_carrier_nr_t* carrier, srsran_cell_t* cell); SRSRAN_API int srsran_carrier_to_cell(const srsran_carrier_nr_t* carrier, srsran_cell_t* cell);
/**
* @brief Writes Channel State Information measurement into a string
* @param meas Provides the measurement
* @param str Provides string
* @param str_len Maximum string length
* @return The number of writen characters
*/
SRSRAN_API uint32_t srsran_csi_meas_info(const srsran_csi_trs_measurements_t* meas, char* str, uint32_t str_len);
#ifdef __cplusplus #ifdef __cplusplus
} }
#endif #endif

@ -0,0 +1,25 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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.
*
*/
#ifndef SRSRAN_PBCH_NR_H
#define SRSRAN_PBCH_NR_H
#include "srsran/config.h"
/**
* @brief Descibes the NR PBCH message
*/
typedef struct SRSRAN_API {
// TBD
} srsran_pbch_msg_nr_t;
#endif // SRSRAN_PBCH_NR_H

@ -49,19 +49,20 @@ typedef enum {
} srsran_resampler_mode_t; } srsran_resampler_mode_t;
/** /**
* Resampler internal buffers and subcomponents * @brief Resampler internal buffers and subcomponents
*/ */
typedef struct { typedef struct {
srsran_resampler_mode_t mode; srsran_resampler_mode_t mode; ///< Interpolate or decimate mode
uint32_t ratio; uint32_t ratio; ///< Decimation/Interpolation ratio
uint32_t window_sz; uint32_t window_sz; ///< Maximum number of processed samples
srsran_dft_plan_t fft; uint32_t delay; ///< Filter delay in samples
srsran_dft_plan_t ifft; srsran_dft_plan_t fft; ///< Forward DFT
uint32_t state_len; srsran_dft_plan_t ifft; ///< Backward DFT
cf_t* in_buffer; uint32_t state_len; ///< Number of acccumulated samples in the internal state
cf_t* out_buffer; cf_t* in_buffer; ///< DFT input buffer
cf_t* state; cf_t* out_buffer; ///< DFT output buffer
cf_t* filter; cf_t* state; ///< Filter state
cf_t* filter; ///< Frequency domain filter
} srsran_resampler_fft_t; } srsran_resampler_fft_t;
/** /**

@ -0,0 +1,49 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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.
*
*/
#ifndef SRSRAN_PSS_NR_H
#define SRSRAN_PSS_NR_H
#include "srsran/config.h"
#include "srsran/phy/common/phy_common_nr.h"
#include <inttypes.h>
/**
* @brief NR PSS sequence length in frequency domain
*/
#define SRSRAN_PSS_NR_LEN 127
/**
* @brief NR PSS Symbol number
*/
#define SRSRAN_PSS_NR_SYMBOL_IDX 0
/**
* @brief Put NR PSS sequence in the SSB grid
* @remark Described in TS 38.211 section 7.4.2.2 Primary synchronization signal
* @param ssb_grid SSB resource grid
* @param N_id_2 Physical cell ID 2
* @param beta PSS power allocation
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_pss_nr_put(cf_t ssb_grid[SRSRAN_SSB_NOF_RE], uint32_t N_id_2, float beta);
/**
* @brief Extracts the NR PSS Least Square Estimates (LSE) from the SSB grid
* @param ssb_grid received SSB resource grid
* @param N_id_2 Physical cell ID 2
* @param lse Provides LSE pointer
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_pss_nr_extract_lse(const cf_t* ssb_grid, uint32_t N_id_2, cf_t lse[SRSRAN_PSS_NR_LEN]);
#endif // SRSRAN_PSS_NR_H

@ -0,0 +1,135 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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.
*
*/
#ifndef SRSRAN_SSB_H
#define SRSRAN_SSB_H
#include "srsran/config.h"
#include "srsran/phy/common/phy_common_nr.h"
#include "srsran/phy/dft/dft.h"
#include "srsran/phy/phch/pbch_nr.h"
#include <inttypes.h>
/**
* @brief Default SSB maximum sampling rate
*/
#define SRSRAN_SSB_DEFAULT_MAX_SRATE_HZ 61.44e6
/**
* @brief Default SSB minimum subcarrier spacing
*/
#define SRSRAN_SSB_DEFAULT_MIN_SCS srsran_subcarrier_spacing_15kHz
/**
* @brief Default beta value, used in case they are set to zero
*/
#define SRSRAN_SSB_DEFAULT_BETA 1.0f
/**
* @brief Describes SSB object initialization arguments
*/
typedef struct SRSRAN_API {
double max_srate_hz; ///< Maximum sampling rate in Hz (common for gNb and UE), set to zero to use default
srsran_subcarrier_spacing_t min_scs; ///< Minimum subcarrier spacing
bool enable_correlate; ///< Enables PSS/SSS correlation and peak search (UE cell search)
bool enable_encode; ///< Enables PBCH Encoder (intended for gNb)
bool enable_decode; ///< Enables PBCH Decoder (intented for UE)
bool enable_measure; ///< Enables PSS/SSS CSI measurements
} srsran_ssb_args_t;
/**
* @brief Describes SSB configuration arguments
*/
typedef struct SRSRAN_API {
double srate_hz; ///< Current sampling rate in Hz
double freq_offset_hz; ///< SSB base-band frequency offset
srsran_subcarrier_spacing_t scs; ///< SSB configured Subcarrier spacing
float beta_pss; ////< PSS power allocation
float beta_sss; ////< SSS power allocation
float beta_pbch; ////< PBCH power allocation
float beta_pbch_dmrs; ////< PBCH DMRS power allocation
} srsran_ssb_cfg_t;
/**
* @brief Describes SSB object
*/
typedef struct SRSRAN_API {
srsran_ssb_args_t args; ///< Stores initialization arguments
srsran_ssb_cfg_t cfg; ///< Stores last configuration
/// Sampling rate dependent parameters
float scs_hz; ///< Subcarrier spacing in Hz
uint32_t max_symbol_sz; ///< Maximum symbol size given the minimum supported SCS and sampling rate
uint32_t symbol_sz; ///< Current SSB symbol size (for the given base-band sampling rate)
int32_t offset; ///< Current SSB integer offset (multiple of SCS)
uint32_t cp0_sz; ///< First symbol cyclic prefix size
uint32_t cp_sz; ///< Other symbol cyclic prefix size
/// Internal Objects
srsran_dft_plan_t ifft; ///< IFFT object for modulating the SSB
srsran_dft_plan_t fft; ///< FFT object for demodulate the SSB.
/// Frequency/Time domain temporal data
cf_t* tmp_freq;
cf_t* tmp_time;
} srsran_ssb_t;
/**
* @brief Initialises configures NR SSB with the given arguments
* @param q SSB object
* @param args NR PSS initialization arguments
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_ssb_init(srsran_ssb_t* q, const srsran_ssb_args_t* args);
/**
* @brief Frees NR SSB object
* @param q SSB object
*/
SRSRAN_API void srsran_ssb_free(srsran_ssb_t* q);
/**
* @brief Sets SSB configuration with the current SSB configuration
* @param q SSB object
* @param cfg Current SSB configuration
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_ssb_set_cfg(srsran_ssb_t* q, const srsran_ssb_cfg_t* cfg);
/**
* @brief Decodes PBCH in the given time domain signal
* @param q SSB object
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_ssb_decode_pbch(srsran_ssb_t* q, const cf_t* in, srsran_pbch_msg_nr_t* msg);
/**
* @brief Adds SSB to a given signal in time domain
* @param q SSB object
* @param N_id Physical Cell Identifier
* @param msg NR PBCH message to transmit
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int
srsran_ssb_add(srsran_ssb_t* q, uint32_t N_id, const srsran_pbch_msg_nr_t* msg, const cf_t* in, cf_t* out);
/**
* @brief Perform Channel State Information (CSI) measurement from the SSB
* @param q NR PSS object
* @param N_id Physical Cell Identifier
* @param in Base-band signal
* @param meas SSB-based CSI measurement
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int
srsran_ssb_csi_measure(srsran_ssb_t* q, uint32_t N_id, const cf_t* in, srsran_csi_trs_measurements_t* meas);
#endif // SRSRAN_SSB_H

@ -0,0 +1,64 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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.
*
*/
#ifndef SRSRAN_SSS_NR_H
#define SRSRAN_SSS_NR_H
#include "srsran/config.h"
#include "srsran/phy/common/phy_common_nr.h"
#include <inttypes.h>
/**
* @brief NR SSS sequence length in frequency domain
*/
#define SRSRAN_SSS_NR_LEN 127
/**
* @brief NR SSS Symbol number
*/
#define SRSRAN_SSS_NR_SYMBOL_IDX 2
/**
* @brief Put NR SSS sequence in the SSB grid
* @remark Described in TS 38.211 section 7.4.2.3 Secondary synchronization signal
* @param ssb_grid SSB resource grid
* @param N_id_1 Physical cell ID 1
* @param N_id_2 Physical cell ID 2
* @param beta SSS power allocation
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int srsran_sss_nr_put(cf_t ssb_grid[SRSRAN_SSB_NOF_RE], uint32_t N_id_1, uint32_t N_id_2, float beta);
/**
* @brief Extracts the NR SSS Least Square Estimates (LSE) from the SSB grid
* @param ssb_grid received SSB resource grid
* @param N_id_1 Physical cell ID 1
* @param N_id_2 Physical cell ID 2
* @param lse Provides LSE pointer
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int
srsran_sss_nr_extract_lse(const cf_t* ssb_grid, uint32_t N_id_1, uint32_t N_id_2, cf_t lse[SRSRAN_SSS_NR_LEN]);
/**
* @brief Find the best SSS sequence given the N_id_2 and the SSB resource grid
* @attention Assumes the SSB is synchronized and the average delay is pre-compensated
* @param ssb_grid The SSB resource grid to search
* @param N_id_2 Fix N_id_2 to search, it reduces the search space 1/3
* @param norm_corr Normalised correlation of the best found sequence
* @param found_N_id_1 The N_id_1 of the best sequence
* @return SRSLTE_SUCCESS if the parameters are valid, SRSLTE_ERROR code otherwise
*/
SRSRAN_API int
srsran_sss_nr_find(const cf_t ssb_grid[SRSRAN_SSB_NOF_RE], uint32_t N_id_2, float* norm_corr, uint32_t* found_N_id_1);
#endif // SRSRAN_SSS_NR_H

@ -183,8 +183,10 @@ float srsran_symbol_distance_s(uint32_t l0, uint32_t l1, srsran_subcarrier_spaci
// Compute reference FFT size // Compute reference FFT size
uint32_t N = (2048 + 144) * count + extra_cp; uint32_t N = (2048 + 144) * count + extra_cp;
float TS = SRSRAN_LTE_TS / (float)(1U << (uint32_t)scs);
// Return symbol distance in microseconds // Return symbol distance in microseconds
return (N << (uint32_t)scs) * SRSRAN_LTE_TS; return (float)N * TS;
} }
bool srsran_tdd_nr_is_dl(const srsran_tdd_config_nr_t* cfg, uint32_t numerology, uint32_t slot_idx) bool srsran_tdd_nr_is_dl(const srsran_tdd_config_nr_t* cfg, uint32_t numerology, uint32_t slot_idx)
@ -276,3 +278,21 @@ int srsran_carrier_to_cell(const srsran_carrier_nr_t* carrier, srsran_cell_t* ce
return SRSRAN_SUCCESS; return SRSRAN_SUCCESS;
} }
uint32_t srsran_csi_meas_info(const srsran_csi_trs_measurements_t* meas, char* str, uint32_t str_len)
{
if (meas == NULL || str == NULL || str_len == 0) {
return 0;
}
return srsran_print_check(str,
str_len,
0,
"rsrp=%+.1f epre=%+.1f n0=%+.1f snr=%+.1f cfo=%+.1f delay=%+.1f",
meas->rsrp_dB,
meas->epre_dB,
meas->n0_dB,
meas->snr_dB,
meas->cfo_hz,
meas->delay_us);
}

@ -34,6 +34,11 @@
*/ */
#define RESAMPLER_BETA 0.45 #define RESAMPLER_BETA 0.45
/**
* Filter delay in multiples of ratio
*/
#define RESAMPLER_DELAY 7
/** /**
* The FFT size power is determined from the ratio logarithm in base 2 plus the following parameter * The FFT size power is determined from the ratio logarithm in base 2 plus the following parameter
*/ */
@ -70,21 +75,26 @@ int srsran_resampler_fft_init(srsran_resampler_fft_t* q, srsran_resampler_mode_t
uint32_t output_fft_size = 0; uint32_t output_fft_size = 0;
uint32_t high_size = base_size * ratio; uint32_t high_size = base_size * ratio;
// Select FFT/IFFT sizes filter delay and window size. For best performance and avoid aliasing, the window size shall
// be as big as the input DFT subtracting the filter length at the input rate
switch (mode) { switch (mode) {
case SRSRAN_RESAMPLER_MODE_INTERPOLATE: case SRSRAN_RESAMPLER_MODE_INTERPOLATE:
input_fft_size = base_size; input_fft_size = base_size;
output_fft_size = high_size; output_fft_size = high_size;
q->delay = RESAMPLER_DELAY * ratio;
q->window_sz = input_fft_size - 2 * RESAMPLER_DELAY;
break; break;
case SRSRAN_RESAMPLER_MODE_DECIMATE: case SRSRAN_RESAMPLER_MODE_DECIMATE:
default: default:
input_fft_size = high_size; input_fft_size = high_size;
output_fft_size = base_size; output_fft_size = base_size;
q->delay = RESAMPLER_DELAY * ratio;
q->window_sz = input_fft_size - 2 * q->delay;
break; break;
} }
q->mode = mode; q->mode = mode;
q->ratio = ratio; q->ratio = ratio;
q->window_sz = input_fft_size / 4;
q->in_buffer = srsran_vec_cf_malloc(high_size); q->in_buffer = srsran_vec_cf_malloc(high_size);
if (q->in_buffer == NULL) { if (q->in_buffer == NULL) {
@ -120,11 +130,20 @@ int srsran_resampler_fft_init(srsran_resampler_fft_t* q, srsran_resampler_mode_t
return SRSRAN_ERROR; return SRSRAN_ERROR;
} }
// Calculate absolute filter delay
double delay = (double)q->delay;
if (mode == SRSRAN_RESAMPLER_MODE_INTERPOLATE) {
delay = (double)(high_size - q->delay);
}
// Compute time domain filter coefficients, see raised cosine formula in section "1.2 Impulse Response" of // Compute time domain filter coefficients, see raised cosine formula in section "1.2 Impulse Response" of
// https://dspguru.com/dsp/reference/raised-cosine-and-root-raised-cosine-formulas/ // https://dspguru.com/dsp/reference/raised-cosine-and-root-raised-cosine-formulas/
double T = (double)1.0; double T = (double)1.0;
for (int32_t i = 0; i < high_size; i++) { for (int32_t i = 0; i < high_size; i++) {
double t = ((double)i - (double)high_size / 2.0) / (double)ratio; // Convert to time
double t = ((double)i - delay) / (double)ratio;
// Compute coefficient
double h = 1.0 / T; double h = 1.0 / T;
if (isnormal(t)) { if (isnormal(t)) {
h = sin(M_PI * t / T); h = sin(M_PI * t / T);
@ -135,6 +154,11 @@ int srsran_resampler_fft_init(srsran_resampler_fft_t* q, srsran_resampler_mode_t
q->in_buffer[i] = (float)h; q->in_buffer[i] = (float)h;
} }
if (srsran_verbose >= SRSRAN_VERBOSE_INFO && !handler_registered) {
printf("h_%s=", q->mode == SRSRAN_RESAMPLER_MODE_INTERPOLATE ? "interp" : "decimate");
srsran_vec_fprint_c(stdout, q->in_buffer, high_size);
}
// Compute frequency domain coefficients, since the filter is symmetrical, it does not matter whether FFT or iFFT // Compute frequency domain coefficients, since the filter is symmetrical, it does not matter whether FFT or iFFT
if (mode == SRSRAN_RESAMPLER_MODE_INTERPOLATE) { if (mode == SRSRAN_RESAMPLER_MODE_INTERPOLATE) {
srsran_dft_run_guru_c(&q->ifft); srsran_dft_run_guru_c(&q->ifft);
@ -179,14 +203,11 @@ static void resampler_fft_interpolate(srsran_resampler_fft_t* q, const cf_t* inp
// Execute FFT // Execute FFT
srsran_dft_run_guru_c(&q->fft); srsran_dft_run_guru_c(&q->fft);
// Replicate input spectrum // Replicate input spectrum and filter at same time
for (uint32_t i = 1; i < q->ratio; i++) { for (uint32_t i = 0; i < q->ratio; i++) {
srsran_vec_cf_copy(&q->out_buffer[q->fft.size * i], q->out_buffer, q->fft.size); srsran_vec_prod_ccc(q->out_buffer, &q->filter[q->fft.size * i], &q->in_buffer[q->fft.size * i], q->fft.size);
} }
// Apply filtering
srsran_vec_prod_ccc(q->out_buffer, q->filter, q->in_buffer, q->ifft.size);
// Execute iFFT // Execute iFFT
srsran_dft_run_guru_c(&q->ifft); srsran_dft_run_guru_c(&q->ifft);
} else { } else {
@ -224,7 +245,7 @@ static void resampler_fft_decimate(srsran_resampler_fft_t* q, const cf_t* input,
if (input) { if (input) {
// Copy input samples // Copy input samples
srsran_vec_cf_copy(q->in_buffer, &input[count], q->window_sz); srsran_vec_cf_copy(q->in_buffer, &input[count], n);
// Pad zeroes // Pad zeroes
srsran_vec_cf_zero(&q->in_buffer[n], q->fft.size - n); srsran_vec_cf_zero(&q->in_buffer[n], q->fft.size - n);
@ -232,12 +253,14 @@ static void resampler_fft_decimate(srsran_resampler_fft_t* q, const cf_t* input,
// Execute FFT // Execute FFT
srsran_dft_run_guru_c(&q->fft); srsran_dft_run_guru_c(&q->fft);
// Apply filtering and cut // Apply filter
srsran_vec_prod_ccc(q->out_buffer, q->filter, q->in_buffer, q->ifft.size / 2); srsran_vec_prod_ccc(q->out_buffer, q->filter, q->out_buffer, q->fft.size);
srsran_vec_prod_ccc(&q->out_buffer[q->fft.size - q->ifft.size / 2],
&q->filter[q->fft.size - q->ifft.size / 2], // Decimate
&q->in_buffer[q->ifft.size / 2], srsran_vec_cf_copy(q->in_buffer, q->out_buffer, q->ifft.size);
q->ifft.size / 2); for (uint32_t i = 1; i < q->ratio; i++) {
srsran_vec_sum_ccc(&q->out_buffer[q->ifft.size * i], q->in_buffer, q->in_buffer, q->ifft.size);
}
// Execute iFFT // Execute iFFT
srsran_dft_run_guru_c(&q->ifft); srsran_dft_run_guru_c(&q->ifft);
@ -316,5 +339,5 @@ uint32_t srsran_resampler_fft_get_delay(srsran_resampler_fft_t* q)
return UINT32_MAX; return UINT32_MAX;
} }
return q->ifft.size / 2; return q->delay;
} }

@ -19,6 +19,7 @@
* *
*/ */
#include "srsran/phy/channel/ch_awgn.h"
#include "srsran/phy/resampling/resampler.h" #include "srsran/phy/resampling/resampler.h"
#include "srsran/phy/utils/debug.h" #include "srsran/phy/utils/debug.h"
#include "srsran/phy/utils/vector.h" #include "srsran/phy/utils/vector.h"
@ -29,12 +30,19 @@
static uint32_t buffer_size = 1920; static uint32_t buffer_size = 1920;
static uint32_t factor = 2; static uint32_t factor = 2;
static uint32_t repetitions = 2; static uint32_t repetitions = 2;
static enum {
WAVE_SINE = 0,
WAVE_DELTA,
WAVE_STEP,
WAVE_GAUSS,
} wave = WAVE_SINE;
static void usage(char* prog) static void usage(char* prog)
{ {
printf("Usage: %s [sfr]\n", prog); printf("Usage: %s [sfr]\n", prog);
printf("\t-s Buffer size [Default %d]\n", buffer_size); printf("\t-s Buffer size [Default %d]\n", buffer_size);
printf("\t-f Buffer size [Default %d]\n", factor); printf("\t-f Interpolation/Decimation factor [Default %d]\n", factor);
printf("\t-w Wave type: sine, step, delta [Default sine]\n");
printf("\t-f r [Default %d]\n", repetitions); printf("\t-f r [Default %d]\n", repetitions);
} }
@ -42,7 +50,7 @@ static void parse_args(int argc, char** argv)
{ {
int opt; int opt;
while ((opt = getopt(argc, argv, "sfr")) != -1) { while ((opt = getopt(argc, argv, "sfrvw")) != -1) {
switch (opt) { switch (opt) {
case 's': case 's':
buffer_size = (uint32_t)strtol(argv[optind], NULL, 10); buffer_size = (uint32_t)strtol(argv[optind], NULL, 10);
@ -53,6 +61,33 @@ static void parse_args(int argc, char** argv)
case 'r': case 'r':
repetitions = (uint32_t)strtol(argv[optind], NULL, 10); repetitions = (uint32_t)strtol(argv[optind], NULL, 10);
break; break;
case 'v':
srsran_verbose++;
break;
case 'w':
if (strcmp(argv[optind], "sine") == 0) {
wave = WAVE_SINE;
break;
}
if (strcmp(argv[optind], "delta") == 0) {
wave = WAVE_DELTA;
break;
}
if (strcmp(argv[optind], "step") == 0) {
wave = WAVE_STEP;
break;
}
if (strcmp(argv[optind], "gauss") == 0) {
wave = WAVE_GAUSS;
break;
}
printf("Invalid wave '%s'\n", argv[optind]);
usage(argv[0]);
break;
default: default:
usage(argv[0]); usage(argv[0]);
exit(-1); exit(-1);
@ -65,6 +100,7 @@ int main(int argc, char** argv)
struct timeval t[3] = {}; struct timeval t[3] = {};
srsran_resampler_fft_t interp = {}; srsran_resampler_fft_t interp = {};
srsran_resampler_fft_t decim = {}; srsran_resampler_fft_t decim = {};
srsran_channel_awgn_t awgn = {};
parse_args(argc, argv); parse_args(argc, argv);
@ -81,7 +117,31 @@ int main(int argc, char** argv)
} }
srsran_vec_cf_zero(src, buffer_size); srsran_vec_cf_zero(src, buffer_size);
srsran_vec_gen_sine(1.0f, 0.01f, src, buffer_size / 10);
switch (wave) {
case WAVE_SINE:
srsran_vec_gen_sine(1.0f, 0.01f, src, buffer_size / 2);
break;
case WAVE_DELTA:
src[0] = 1.0f;
break;
case WAVE_STEP:
for (uint32_t i = 0; i < buffer_size; i++) {
src[i] = 1.0f;
}
break;
case WAVE_GAUSS:
srsran_channel_awgn_init(&awgn, 0);
srsran_channel_awgn_set_n0(&awgn, 0);
srsran_channel_awgn_run_c(&awgn, src, src, buffer_size);
srsran_channel_awgn_free(&awgn);
break;
}
if (srsran_verbose >= SRSRAN_VERBOSE_INFO && !handler_registered) {
printf("signal=");
srsran_vec_fprint_c(stdout, src, buffer_size);
}
gettimeofday(&t[1], NULL); gettimeofday(&t[1], NULL);
for (uint32_t r = 0; r < repetitions; r++) { for (uint32_t r = 0; r < repetitions; r++) {
@ -91,22 +151,26 @@ int main(int argc, char** argv)
gettimeofday(&t[2], NULL); gettimeofday(&t[2], NULL);
get_time_interval(t); get_time_interval(t);
uint64_t duration_us = (uint64_t)(t[0].tv_sec * 1000000UL + t[0].tv_usec); uint64_t duration_us = (uint64_t)(t[0].tv_sec * 1000000UL + t[0].tv_usec);
printf("Done %.1f Msps\n", factor * buffer_size * repetitions / (double)duration_us);
// printf("interp="); if (srsran_verbose >= SRSRAN_VERBOSE_INFO && !handler_registered) {
// srsran_vec_fprint_c(stdout, interpolated, buffer_size * factor); printf("interp=");
srsran_vec_fprint_c(stdout, interpolated, buffer_size * factor);
printf("decim=");
srsran_vec_fprint_c(stdout, decimated, buffer_size);
}
// Check error // Check error
uint32_t delay = srsran_resampler_fft_get_delay(&decim) * 2; uint32_t delay = (srsran_resampler_fft_get_delay(&decim) + srsran_resampler_fft_get_delay(&interp)) / factor;
uint32_t nsamples = buffer_size - delay; uint32_t nsamples = buffer_size - delay;
srsran_vec_sub_ccc(src, &decimated[delay], interpolated, nsamples); srsran_vec_sub_ccc(src, &decimated[delay], interpolated, nsamples);
float mse = sqrtf(srsran_vec_avg_power_cf(interpolated, nsamples)); float mse = sqrtf(srsran_vec_avg_power_cf(interpolated, nsamples));
printf("MSE: %f\n", mse);
// printf("src="); if (srsran_verbose >= SRSRAN_VERBOSE_INFO && !handler_registered) {
// srsran_vec_fprint_c(stdout, src, nsamples); printf("recovered=");
// printf("decim="); srsran_vec_fprint_c(stdout, &decimated[delay], nsamples);
// srsran_vec_fprint_c(stdout, &decimated[delay], nsamples); }
printf("Done %.1f Msps; MSE: %.6f\n", factor * buffer_size * repetitions / (double)duration_us, mse);
srsran_resampler_fft_free(&interp); srsran_resampler_fft_free(&interp);
srsran_resampler_fft_free(&decim); srsran_resampler_fft_free(&decim);

@ -0,0 +1,96 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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 "srsran/phy/sync/pss_nr.h"
#include "srsran/phy/utils/vector.h"
/**
* NR PSS First Subcarrier index
*/
#define PSS_NR_SUBC_BEGIN 56
/**
* Calculates Sequence circular offset
*/
#define PSS_NR_SEQUENCE_M(N_id_2) ((43U * (N_id_2)) % SRSRAN_PSS_NR_LEN)
/**
* Pregenerated modulated sequence
*/
static cf_t pss_nr_d[SRSRAN_PSS_NR_LEN] = {};
/**
* Sequence generation as described in TS 38.211 clause 7.4.2.2.1
*/
__attribute__((constructor)) __attribute__((unused)) static void pss_nr_pregen()
{
// Initialise M sequence x
uint32_t x[SRSRAN_PSS_NR_LEN + 7];
x[6] = 1;
x[5] = 1;
x[4] = 1;
x[3] = 0;
x[2] = 1;
x[1] = 1;
x[0] = 0;
// Generate M sequence x
for (uint32_t i = 0; i < SRSRAN_PSS_NR_LEN; i++) {
x[i + 7] = (x[i + 4] + x[i]) % 2;
}
// Modulate M sequence d
for (uint32_t i = 0; i < SRSRAN_PSS_NR_LEN; i++) {
pss_nr_d[i] = 1.0f - 2.0f * (float)x[i];
}
}
int srsran_pss_nr_put(cf_t ssb_grid[SRSRAN_SSB_NOF_RE], uint32_t N_id_2, float beta)
{
// Verify inputs
if (ssb_grid == NULL || N_id_2 >= SRSRAN_NOF_NID_2_NR) {
return SRSRAN_ERROR;
}
// Calculate generation parameters
uint32_t m = PSS_NR_SEQUENCE_M(N_id_2);
uint32_t copy_sz_1 = SRSRAN_PSS_NR_LEN - m;
uint32_t grid_idx_1 = SRSRAN_PSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + PSS_NR_SUBC_BEGIN;
uint32_t grid_idx_2 = grid_idx_1 + copy_sz_1;
// Copy sequence from offset to the end
srsran_vec_sc_prod_cfc(&pss_nr_d[m], beta, &ssb_grid[grid_idx_1], copy_sz_1);
// Copy sequence from 0 to offset
srsran_vec_sc_prod_cfc(&pss_nr_d[0], beta, &ssb_grid[grid_idx_2], m);
return SRSRAN_SUCCESS;
}
int srsran_pss_nr_extract_lse(const cf_t* ssb_grid, uint32_t N_id_2, cf_t lse[SRSRAN_PSS_NR_LEN])
{
// Verify inputs
if (ssb_grid == NULL || N_id_2 >= SRSRAN_NOF_NID_2_NR || lse == NULL) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
// Extract PSS
srsran_vec_cf_copy(
lse, &ssb_grid[SRSRAN_PSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + PSS_NR_SUBC_BEGIN], SRSRAN_PSS_NR_LEN);
// Estimate
uint32_t m = PSS_NR_SEQUENCE_M(N_id_2);
srsran_vec_prod_ccc(&pss_nr_d[m], lse, lse, SRSRAN_PSS_NR_LEN - m);
srsran_vec_prod_ccc(&pss_nr_d[0], &lse[SRSRAN_PSS_NR_LEN - m], &lse[SRSRAN_PSS_NR_LEN - m], m);
return SRSRAN_SUCCESS;
}

@ -0,0 +1,365 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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 "srsran/phy/sync/ssb.h"
#include "srsran/phy/sync/pss_nr.h"
#include "srsran/phy/sync/sss_nr.h"
#include "srsran/phy/utils/debug.h"
#include "srsran/phy/utils/vector.h"
#include <complex.h>
/*
* Maximum allowed maximum sampling rate error in Hz
*/
#define SSB_SRATE_MAX_ERROR_HZ 0.01
/*
* Maximum allowed maximum frequency error offset in Hz
*/
#define SSB_FREQ_OFFSET_MAX_ERROR_HZ 0.01
int srsran_ssb_init(srsran_ssb_t* q, const srsran_ssb_args_t* args)
{
// Verify input parameters
if (q == NULL || args == NULL) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
// Copy arguments
q->args = *args;
// Check if the maximum sampling rate is in range, force default otherwise
if (!isnormal(q->args.max_srate_hz) || q->args.max_srate_hz < 0.0) {
q->args.max_srate_hz = SRSRAN_SSB_DEFAULT_MAX_SRATE_HZ;
}
q->scs_hz = (float)SRSRAN_SUBC_SPACING_NR(q->args.min_scs);
q->max_symbol_sz = (uint32_t)round(q->args.max_srate_hz / q->scs_hz);
// Allocate temporal data
q->tmp_time = srsran_vec_cf_malloc(q->max_symbol_sz);
q->tmp_freq = srsran_vec_cf_malloc(q->max_symbol_sz);
if (q->tmp_time == NULL || q->tmp_time == NULL) {
ERROR("Malloc");
return SRSRAN_ERROR;
}
return SRSRAN_SUCCESS;
}
void srsran_ssb_free(srsran_ssb_t* q)
{
if (q == NULL) {
return;
}
if (q->tmp_time != NULL) {
free(q->tmp_time);
}
if (q->tmp_freq != NULL) {
free(q->tmp_freq);
}
srsran_dft_plan_free(&q->ifft);
srsran_dft_plan_free(&q->fft);
SRSRAN_MEM_ZERO(q, srsran_ssb_t, 1);
}
int srsran_ssb_set_cfg(srsran_ssb_t* q, const srsran_ssb_cfg_t* cfg)
{
// Verify input parameters
if (q == NULL || cfg == NULL) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
// Calculate subcarrier spacing in Hz
q->scs_hz = (double)SRSRAN_SUBC_SPACING_NR(cfg->scs);
// Calculate SSB symbol size and integer offset
uint32_t symbol_sz = (uint32_t)round(cfg->srate_hz / q->scs_hz);
q->offset = (uint32_t)(cfg->freq_offset_hz / q->scs_hz);
q->cp0_sz = (160U * symbol_sz) / 2048U;
q->cp_sz = (144U * symbol_sz) / 2048U;
// Calculate SSB sampling error and check
double ssb_srate_error_Hz = ((double)symbol_sz * q->scs_hz) - cfg->srate_hz;
if (fabs(ssb_srate_error_Hz) > SSB_SRATE_MAX_ERROR_HZ) {
ERROR("Invalid sampling rate (%.2f MHz)", cfg->srate_hz / 1e6);
return SRSRAN_ERROR;
}
// Calculate SSB offset error and check
double ssb_offset_error_Hz = ((double)q->offset * q->scs_hz) - cfg->freq_offset_hz;
if (fabs(ssb_offset_error_Hz) > SSB_FREQ_OFFSET_MAX_ERROR_HZ) {
ERROR("SSB Offset error exceeds maximum allowed");
return SRSRAN_ERROR;
}
// Verify symbol size
if (q->max_symbol_sz < symbol_sz) {
ERROR("New symbol size (%d) exceeds maximum symbol size (%d)", symbol_sz, q->max_symbol_sz);
}
// Replan iFFT
if ((q->args.enable_encode) && q->symbol_sz != symbol_sz) {
// free the current IFFT, it internally checks if the plan was created
srsran_dft_plan_free(&q->ifft);
// Creates DFT plan
if (srsran_dft_plan_guru_c(&q->ifft, (int)symbol_sz, SRSRAN_DFT_BACKWARD, q->tmp_freq, q->tmp_time, 1, 1, 1, 1, 1) <
SRSRAN_SUCCESS) {
ERROR("Error creating iDFT");
return SRSRAN_ERROR;
}
}
// Replan FFT
if ((q->args.enable_measure || q->args.enable_decode) && q->symbol_sz != symbol_sz) {
// free the current FFT, it internally checks if the plan was created
srsran_dft_plan_free(&q->fft);
// Creates DFT plan
if (srsran_dft_plan_guru_c(&q->fft, (int)symbol_sz, SRSRAN_DFT_FORWARD, q->tmp_time, q->tmp_freq, 1, 1, 1, 1, 1) <
SRSRAN_SUCCESS) {
ERROR("Error creating iDFT");
return SRSRAN_ERROR;
}
}
// Finally, copy configuration
q->cfg = *cfg;
q->symbol_sz = symbol_sz;
if (!isnormal(q->cfg.beta_pss)) {
q->cfg.beta_pss = SRSRAN_SSB_DEFAULT_BETA;
}
if (!isnormal(q->cfg.beta_sss)) {
q->cfg.beta_sss = SRSRAN_SSB_DEFAULT_BETA;
}
if (!isnormal(q->cfg.beta_pbch)) {
q->cfg.beta_pbch = SRSRAN_SSB_DEFAULT_BETA;
}
if (!isnormal(q->cfg.beta_pbch_dmrs)) {
q->cfg.beta_pbch = SRSRAN_SSB_DEFAULT_BETA;
}
return SRSRAN_SUCCESS;
}
int srsran_ssb_add(srsran_ssb_t* q, uint32_t N_id, const srsran_pbch_msg_nr_t* msg, const cf_t* in, cf_t* out)
{
// Verify input parameters
if (q == NULL || N_id >= SRSRAN_NOF_NID_NR || msg == NULL || in == NULL || out == NULL) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
if (!q->args.enable_encode) {
ERROR("SSB is not configured for encode");
return SRSRAN_ERROR;
}
uint32_t N_id_1 = SRSRAN_NID_1_NR(N_id);
uint32_t N_id_2 = SRSRAN_NID_2_NR(N_id);
cf_t ssb_grid[SRSRAN_SSB_NOF_RE] = {};
// Put PSS
if (srsran_pss_nr_put(ssb_grid, N_id_2, q->cfg.beta_pss) < SRSRAN_SUCCESS) {
ERROR("Error putting PSS");
return SRSRAN_ERROR;
}
// Put SSS
if (srsran_sss_nr_put(ssb_grid, N_id_1, N_id_2, q->cfg.beta_sss) < SRSRAN_SUCCESS) {
ERROR("Error putting PSS");
return SRSRAN_ERROR;
}
// Put PBCH DMRS
// ...
// Put PBCH payload
// ...
// Initialise frequency domain
srsran_vec_cf_zero(q->tmp_freq, q->symbol_sz);
// Modulate
const cf_t* in_ptr = in;
cf_t* out_ptr = out;
for (uint32_t l = 0; l < SRSRAN_SSB_DURATION_NSYMB; l++) {
// Get CP length
uint32_t cp_len = (l == 0) ? q->cp0_sz : q->cp_sz;
// Select symbol in grid
cf_t* ptr = &ssb_grid[l * SRSRAN_SSB_BW_SUBC];
// Map grid into frequency domain symbol
if (q->offset >= SRSRAN_SSB_BW_SUBC / 2) {
srsran_vec_cf_copy(&q->tmp_freq[q->offset - SRSRAN_SSB_BW_SUBC / 2], ptr, SRSRAN_SSB_BW_SUBC);
} else if (q->offset <= -SRSRAN_SSB_BW_SUBC / 2) {
srsran_vec_cf_copy(&q->tmp_freq[q->symbol_sz + q->offset - SRSRAN_SSB_BW_SUBC / 2], ptr, SRSRAN_SSB_BW_SUBC);
} else {
srsran_vec_cf_copy(&q->tmp_freq[0], &ptr[SRSRAN_SSB_BW_SUBC / 2 - q->offset], SRSRAN_SSB_BW_SUBC / 2 + q->offset);
srsran_vec_cf_copy(
&q->tmp_freq[q->symbol_sz - SRSRAN_SSB_BW_SUBC / 2 + q->offset], &ptr[0], SRSRAN_SSB_BW_SUBC / 2 - q->offset);
}
// Convert to time domain
srsran_dft_run_guru_c(&q->ifft);
// Normalise output
float norm = sqrtf((float)q->symbol_sz);
if (isnormal(norm)) {
srsran_vec_sc_prod_cfc(q->tmp_time, 1.0f / norm, q->tmp_time, q->symbol_sz);
}
// Add cyclic prefix to input;
srsran_vec_sum_ccc(in_ptr, &q->tmp_time[q->symbol_sz - cp_len], out_ptr, cp_len);
in_ptr += cp_len;
out_ptr += cp_len;
// Add symbol to the input baseband
srsran_vec_sum_ccc(in_ptr, q->tmp_time, out_ptr, q->symbol_sz);
in_ptr += q->symbol_sz;
out_ptr += q->symbol_sz;
}
return SRSRAN_SUCCESS;
}
int srsran_ssb_csi_measure(srsran_ssb_t* q, uint32_t N_id, const cf_t* in, srsran_csi_trs_measurements_t* meas)
{
// Verify inputs
if (q == NULL || N_id >= SRSRAN_NOF_NID_NR || in == NULL || meas == NULL || !isnormal(q->scs_hz)) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
if (!q->args.enable_measure) {
ERROR("SSB is not configured for measure");
return SRSRAN_ERROR;
}
uint32_t N_id_1 = SRSRAN_NID_1_NR(N_id);
uint32_t N_id_2 = SRSRAN_NID_2_NR(N_id);
cf_t ssb_grid[SRSRAN_SSB_NOF_RE] = {};
// Demodulate
const cf_t* in_ptr = in;
for (uint32_t l = 0; l < SRSRAN_SSB_DURATION_NSYMB; l++) {
// Get CP length
uint32_t cp_len = (l == 0) ? q->cp0_sz : q->cp_sz;
// Advance half CP, to avoid inter symbol interference
in_ptr += SRSRAN_FLOOR(cp_len, 2);
// Copy FFT window in temporal time domain buffer
srsran_vec_cf_copy(q->tmp_time, in_ptr, q->symbol_sz);
in_ptr += q->symbol_sz + SRSRAN_CEIL(cp_len, 2);
// Convert to frequency domain
srsran_dft_run_guru_c(&q->fft);
// Compensate half CP delay
srsran_vec_apply_cfo(q->tmp_freq, SRSRAN_CEIL(cp_len, 2) / (float)(q->symbol_sz), q->tmp_freq, q->symbol_sz);
// Select symbol in grid
cf_t* ptr = &ssb_grid[l * SRSRAN_SSB_BW_SUBC];
// Map frequency domain symbol into the SSB grid
if (q->offset >= SRSRAN_SSB_BW_SUBC / 2) {
srsran_vec_cf_copy(ptr, &q->tmp_freq[q->offset - SRSRAN_SSB_BW_SUBC / 2], SRSRAN_SSB_BW_SUBC);
} else if (q->offset <= -SRSRAN_SSB_BW_SUBC / 2) {
srsran_vec_cf_copy(ptr, &q->tmp_freq[q->symbol_sz + q->offset - SRSRAN_SSB_BW_SUBC / 2], SRSRAN_SSB_BW_SUBC);
} else {
srsran_vec_cf_copy(&ptr[SRSRAN_SSB_BW_SUBC / 2 - q->offset], &q->tmp_freq[0], SRSRAN_SSB_BW_SUBC / 2 + q->offset);
srsran_vec_cf_copy(
&ptr[0], &q->tmp_freq[q->symbol_sz - SRSRAN_SSB_BW_SUBC / 2 + q->offset], SRSRAN_SSB_BW_SUBC / 2 - q->offset);
}
// Normalize
float norm = sqrtf((float)q->symbol_sz);
if (isnormal(norm)) {
srsran_vec_sc_prod_cfc(ptr, 1.0f / norm, ptr, SRSRAN_SSB_BW_SUBC);
}
}
// Extract PSS LSE
cf_t pss_lse[SRSRAN_PSS_NR_LEN];
cf_t sss_lse[SRSRAN_SSS_NR_LEN];
if (srsran_pss_nr_extract_lse(ssb_grid, N_id_2, pss_lse) < SRSRAN_SUCCESS ||
srsran_sss_nr_extract_lse(ssb_grid, N_id_1, N_id_2, sss_lse) < SRSRAN_SUCCESS) {
ERROR("Error extracting LSE");
return SRSRAN_ERROR;
}
// Estimate average delay
float delay_pss_norm = srsran_vec_estimate_frequency(pss_lse, SRSRAN_PSS_NR_LEN);
float delay_sss_norm = srsran_vec_estimate_frequency(sss_lse, SRSRAN_SSS_NR_LEN);
float delay_avg_norm = (delay_pss_norm + delay_sss_norm) / 2.0f;
float delay_avg_us = 1e6f * delay_avg_norm / q->scs_hz;
// Pre-compensate delay
for (uint32_t l = 0; l < SRSRAN_SSB_DURATION_NSYMB; l++) {
srsran_vec_apply_cfo(
&ssb_grid[SRSRAN_SSB_BW_SUBC * l], delay_avg_norm, &ssb_grid[SRSRAN_SSB_BW_SUBC * l], SRSRAN_SSB_BW_SUBC);
}
// Extract LSE again
if (srsran_pss_nr_extract_lse(ssb_grid, N_id_2, pss_lse) < SRSRAN_SUCCESS ||
srsran_sss_nr_extract_lse(ssb_grid, N_id_1, N_id_2, sss_lse) < SRSRAN_SUCCESS) {
ERROR("Error extracting LSE");
return SRSRAN_ERROR;
}
// Estimate average EPRE
float epre_pss = srsran_vec_avg_power_cf(pss_lse, SRSRAN_PSS_NR_LEN);
float epre_sss = srsran_vec_avg_power_cf(sss_lse, SRSRAN_SSS_NR_LEN);
float epre = (epre_pss + epre_sss) / 2.0f;
// Compute correlation
cf_t corr_pss = srsran_vec_acc_cc(pss_lse, SRSRAN_PSS_NR_LEN) / SRSRAN_PSS_NR_LEN;
cf_t corr_sss = srsran_vec_acc_cc(sss_lse, SRSRAN_SSS_NR_LEN) / SRSRAN_SSS_NR_LEN;
// Compute CFO in Hz
float distance_s = srsran_symbol_distance_s(SRSRAN_PSS_NR_SYMBOL_IDX, SRSRAN_SSS_NR_SYMBOL_IDX, q->cfg.scs);
float cfo_hz_max = 1.0f / distance_s;
float cfo_hz = cargf(corr_pss * conjf(corr_sss)) / (2.0f * M_PI) * cfo_hz_max;
// Compute average RSRP
float rsrp = (SRSRAN_CSQABS(corr_pss) + SRSRAN_CSQABS(corr_sss)) / 2.0f;
// Compute Noise
float n0 = 1e-9; // Almost 0
if (epre > rsrp) {
n0 = epre - rsrp;
}
// Put measurements together
meas->epre = epre;
meas->epre_dB = srsran_convert_power_to_dB(epre);
meas->rsrp = rsrp;
meas->epre_dB = srsran_convert_power_to_dB(rsrp);
meas->n0 = n0;
meas->n0_dB = srsran_convert_power_to_dB(n0);
meas->snr_dB = meas->rsrp_dB - meas->n0_dB;
meas->cfo_hz = cfo_hz;
meas->cfo_hz_max = cfo_hz_max;
meas->delay_us = delay_avg_us; // Convert the delay to microseconds
meas->nof_re = SRSRAN_PSS_NR_LEN + SRSRAN_SSS_NR_LEN;
return SRSRAN_SUCCESS;
}

@ -0,0 +1,208 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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 "srsran/phy/sync/sss_nr.h"
#include "srsran/phy/utils/vector.h"
/**
* NR SSS First Subcarrier index
*/
#define SSS_NR_SUBC_BEGIN 56
/**
* Number of possible M1 shifts
*/
#define SSS_NR_NOF_M1 112U
/**
* Number of possible M0 shifts
*/
#define SSS_NR_NOF_M0 SRSRAN_FLOOR(SRSRAN_NOF_NID_1_NR, SSS_NR_NOF_M1)
/**
* Calculates Sequence circular offset M0 value
*/
#define SSS_NR_SEQUENCE_M0(N_id_1, N_id_2) \
((15U * SRSRAN_FLOOR(N_id_1, SSS_NR_NOF_M1) + 5 * (N_id_2)) % SRSRAN_SSS_NR_LEN)
/**
* Calculates Sequence circular offset M1 value
*/
#define SSS_NR_SEQUENCE_M1(N_id_1) (N_id_1 % SSS_NR_NOF_M1)
/**
* Pregenerated modulated sequences
*/
static cf_t sss_nr_d0[SRSRAN_SSS_NR_LEN] = {};
static cf_t sss_nr_d1[SRSRAN_SSS_NR_LEN] = {};
/**
* Sequence generation as described in TS 38.211 clause 7.4.2.2.1
*/
__attribute__((constructor)) __attribute__((unused)) static void sss_nr_pregen()
{
// Initialise M sequence x0
uint32_t x0[SRSRAN_SSS_NR_LEN + 7];
x0[6] = 0;
x0[5] = 0;
x0[4] = 0;
x0[3] = 0;
x0[2] = 0;
x0[1] = 0;
x0[0] = 1;
// Initialise M sequence x1
uint32_t x1[SRSRAN_SSS_NR_LEN + 7];
x1[6] = 0;
x1[5] = 0;
x1[4] = 0;
x1[3] = 0;
x1[2] = 0;
x1[1] = 0;
x1[0] = 1;
// Generate M sequence x
for (uint32_t i = 0; i < SRSRAN_SSS_NR_LEN; i++) {
x0[i + 7] = (x0[i + 4] + x0[i]) % 2;
x1[i + 7] = (x1[i + 1] + x1[i]) % 2;
}
// Modulate M sequence d
for (uint32_t i = 0; i < SRSRAN_SSS_NR_LEN; i++) {
sss_nr_d0[i] = 1.0f - 2.0f * (float)x0[i];
sss_nr_d1[i] = 1.0f - 2.0f * (float)x1[i];
}
}
int srsran_sss_nr_put(cf_t ssb_grid[SRSRAN_SSB_NOF_RE], uint32_t N_id_1, uint32_t N_id_2, float beta)
{
// Verify inputs
if (ssb_grid == NULL || N_id_1 >= SRSRAN_NOF_NID_1_NR || N_id_2 >= SRSRAN_NOF_NID_2_NR) {
return SRSRAN_ERROR;
}
// Calculate generation parameters
uint32_t m0 = SSS_NR_SEQUENCE_M0(N_id_1, N_id_2);
uint32_t m1 = SSS_NR_SEQUENCE_M1(N_id_1);
uint32_t grid_idx_m0_1 = SRSRAN_SSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + SSS_NR_SUBC_BEGIN;
uint32_t grid_idx_m0_2 = grid_idx_m0_1 + (SRSRAN_SSS_NR_LEN - m0);
uint32_t grid_idx_m1_1 = SRSRAN_SSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + SSS_NR_SUBC_BEGIN;
uint32_t grid_idx_m1_2 = grid_idx_m1_1 + (SRSRAN_SSS_NR_LEN - m1);
// Copy d0 sequence first part from m0 to the end
srsran_vec_sc_prod_cfc(&sss_nr_d0[m0], beta, &ssb_grid[grid_idx_m0_1], SRSRAN_SSS_NR_LEN - m0);
// Copy d0 sequence second part from 0 to m0
srsran_vec_sc_prod_cfc(&sss_nr_d0[0], beta, &ssb_grid[grid_idx_m0_2], m0);
// Multiply d1 sequence first part from m1 to the end
srsran_vec_prod_ccc(&ssb_grid[grid_idx_m1_1], &sss_nr_d1[m1], &ssb_grid[grid_idx_m1_1], SRSRAN_SSS_NR_LEN - m1);
// Multiply d1 sequence second part from 0 to m1
srsran_vec_prod_ccc(&ssb_grid[grid_idx_m1_2], &sss_nr_d1[0], &ssb_grid[grid_idx_m1_2], m1);
return SRSRAN_SUCCESS;
}
int srsran_sss_nr_extract_lse(const cf_t* ssb_grid, uint32_t N_id_1, uint32_t N_id_2, cf_t lse[SRSRAN_SSS_NR_LEN])
{
// Verify inputs
if (ssb_grid == NULL || N_id_2 >= SRSRAN_NOF_NID_2_NR || lse == NULL) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
// Extract SSS
srsran_vec_cf_copy(
lse, &ssb_grid[SRSRAN_SSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + SSS_NR_SUBC_BEGIN], SRSRAN_SSS_NR_LEN);
// Estimate
uint32_t m0 = SSS_NR_SEQUENCE_M0(N_id_1, N_id_2);
srsran_vec_prod_ccc(&sss_nr_d0[m0], lse, lse, SRSRAN_SSS_NR_LEN - m0);
srsran_vec_prod_ccc(&sss_nr_d0[0], &lse[SRSRAN_SSS_NR_LEN - m0], &lse[SRSRAN_SSS_NR_LEN - m0], m0);
uint32_t m1 = SSS_NR_SEQUENCE_M1(N_id_1);
srsran_vec_prod_ccc(&sss_nr_d1[m1], lse, lse, SRSRAN_SSS_NR_LEN - m1);
srsran_vec_prod_ccc(&sss_nr_d1[0], &lse[SRSRAN_SSS_NR_LEN - m1], &lse[SRSRAN_SSS_NR_LEN - m1], m1);
return SRSRAN_SUCCESS;
}
int srsran_sss_nr_find(const cf_t ssb_grid[SRSRAN_SSB_NOF_RE],
uint32_t N_id_2,
float* norm_corr,
uint32_t* found_N_id_1)
{
// Verify inputs
if (ssb_grid == NULL || N_id_2 >= SRSRAN_NOF_NID_2_NR) {
return SRSRAN_ERROR_INVALID_INPUTS;
}
// Extract SSS ptr
const cf_t* sss_ptr = &ssb_grid[SRSRAN_SSS_NR_SYMBOL_IDX * SRSRAN_SSB_BW_SUBC + SSS_NR_SUBC_BEGIN];
// Measure SSS average power
float avg_power = srsran_vec_avg_power_cf(sss_ptr, SRSRAN_SSS_NR_LEN);
// If the measured power is invalid or zero, consider no SSS signal
if (!isnormal(avg_power)) {
if (norm_corr) {
*norm_corr = 0.0f;
}
return SRSRAN_SUCCESS;
}
// Search state
float max_corr = -INFINITY; //< Stores best correlation
uint32_t N_id_1 = 0; //< Best N_id_1
// Iterate over all M1 shifts
for (uint32_t m1 = 0; m1 < SSS_NR_NOF_M1; m1++) {
// Temporal storage of SSS after applying d1 sequence
cf_t sss_seq_m1[SRSRAN_SSS_NR_LEN];
// Apply d1 sequence fist part
srsran_vec_prod_ccc(&sss_ptr[0], &sss_nr_d1[m1], &sss_seq_m1[0], SRSRAN_SSS_NR_LEN - m1);
// Apply d1 sequence second part
srsran_vec_prod_ccc(&sss_ptr[SRSRAN_SSS_NR_LEN - m1], &sss_nr_d1[0], &sss_seq_m1[SRSRAN_SSS_NR_LEN - m1], m1);
// Iterate over all N_id_1 with the given m1 sequence
for (uint32_t N_id_1_blind = m1; N_id_1_blind < SRSRAN_NOF_NID_1; N_id_1_blind += SSS_NR_NOF_M1) {
uint32_t m0 = SSS_NR_SEQUENCE_M0(N_id_1_blind, N_id_2);
cf_t sss_seq_m0[SRSRAN_SSS_NR_LEN];
// Apply d0 sequence fist part
srsran_vec_prod_ccc(&sss_seq_m1[0], &sss_nr_d0[m0], &sss_seq_m0[0], SRSRAN_SSS_NR_LEN - m0);
// Apply d0 sequence second part
srsran_vec_prod_ccc(&sss_seq_m1[SRSRAN_SSS_NR_LEN - m0], &sss_nr_d0[0], &sss_seq_m0[SRSRAN_SSS_NR_LEN - m0], m0);
// Correlate
float corr = SRSRAN_CSQABS(srsran_vec_acc_cc(sss_seq_m0, SRSRAN_SSS_NR_LEN)) / avg_power;
if (corr > max_corr) {
N_id_1 = N_id_1_blind;
max_corr = corr;
}
}
}
if (norm_corr) {
*norm_corr = max_corr;
}
if (found_N_id_1) {
*found_N_id_1 = N_id_1;
}
return SRSRAN_SUCCESS;
}

@ -133,3 +133,13 @@ target_link_libraries(cfo_test srsran_phy)
add_test(cfo_test_1 cfo_test -f 0.12345 -n 1000) add_test(cfo_test_1 cfo_test -f 0.12345 -n 1000)
add_test(cfo_test_2 cfo_test -f 0.99849 -n 1000) add_test(cfo_test_2 cfo_test -f 0.99849 -n 1000)
########################################################################
# NE TEST
########################################################################
add_executable(ssb_measure_test ssb_measure_test.c)
target_link_libraries(ssb_measure_test srsran_phy)
add_test(ssb_measure_test ssb_measure_test)

@ -0,0 +1,183 @@
/**
*
* \section COPYRIGHT
*
* Copyright 2013-2021 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 "srsran/common/test_common.h"
#include "srsran/phy/channel/ch_awgn.h"
#include "srsran/phy/sync/ssb.h"
#include "srsran/phy/utils/debug.h"
#include "srsran/phy/utils/vector.h"
#include <getopt.h>
#include <stdlib.h>
// NR parameters
static uint32_t carrier_nof_prb = 52;
static srsran_subcarrier_spacing_t carrier_scs = srsran_subcarrier_spacing_15kHz;
static srsran_subcarrier_spacing_t ssb_scs = srsran_subcarrier_spacing_30kHz;
// Channel parameters
static int32_t delay_n = 1;
static float cfo_hz = 100.0f;
static float n0_dB = -30.0f;
// Test context
static srsran_channel_awgn_t awgn = {};
static double srate_hz = 0.0f; // Base-band sampling rate
static float delay_us = 0.0f; // Base-band sampling rate
static uint32_t sf_len = 0; // Subframe length
static cf_t* buffer = NULL; // Base-band buffer
#define RSRP_MAX_ERROR 1.0f
#define EPRE_MAX_ERROR 1.0f
#define N0_MAX_ERROR 2.0f
#define SNR_MAX_ERROR 2.0f
#define CFO_MAX_ERROR (cfo_hz * 0.3f)
#define DELAY_MAX_ERROR (delay_us * 0.1f)
static void usage(char* prog)
{
printf("Usage: %s [v]\n", prog);
printf("\t-v [set srsran_verbose to debug, default none]\n");
}
static void parse_args(int argc, char** argv)
{
int opt;
while ((opt = getopt(argc, argv, "v")) != -1) {
switch (opt) {
case 'v':
srsran_verbose++;
break;
default:
usage(argv[0]);
exit(-1);
}
}
}
static void run_channel()
{
// Delay
for (uint32_t i = 0; i < sf_len; i++) {
buffer[i] = buffer[(i + delay_n) % sf_len];
}
// CFO
srsran_vec_apply_cfo(buffer, -cfo_hz / srate_hz, buffer, sf_len);
// AWGN
srsran_channel_awgn_run_c(&awgn, buffer, buffer, sf_len);
}
static int test_case_1(srsran_ssb_t* ssb)
{
uint64_t t_usec = 0;
srsran_ssb_cfg_t ssb_cfg = {};
ssb_cfg.srate_hz = srate_hz;
ssb_cfg.freq_offset_hz = 0.0;
ssb_cfg.scs = ssb_scs;
TESTASSERT(srsran_ssb_set_cfg(ssb, &ssb_cfg) == SRSRAN_SUCCESS);
// Build PBCH message
srsran_pbch_msg_nr_t pbch_msg = {};
for (uint32_t pci = 0; pci < SRSRAN_NOF_NID_NR; pci++) {
struct timeval t[3] = {};
// Initialise baseband
srsran_vec_cf_zero(buffer, sf_len);
// Add the SSB base-band
TESTASSERT(srsran_ssb_add(ssb, pci, &pbch_msg, buffer, buffer) == SRSRAN_SUCCESS);
// Run channel
run_channel();
// Measure
gettimeofday(&t[1], NULL);
srsran_csi_trs_measurements_t meas = {};
TESTASSERT(srsran_ssb_csi_measure(ssb, pci, buffer, &meas) == SRSRAN_SUCCESS);
gettimeofday(&t[2], NULL);
get_time_interval(t);
t_usec += t[0].tv_usec + t[0].tv_sec * 1000000UL;
// Print measurement
char str[512];
srsran_csi_meas_info(&meas, str, sizeof(str));
INFO("test_case_1 - pci=%d %s", pci, str);
// Assert measurements
TESTASSERT(fabsf(meas.rsrp_dB - 0.0f) < RSRP_MAX_ERROR);
TESTASSERT(fabsf(meas.epre_dB - 0.0f) < EPRE_MAX_ERROR);
TESTASSERT(fabsf(meas.n0_dB - n0_dB) < N0_MAX_ERROR);
TESTASSERT(fabsf(meas.snr_dB + n0_dB) < SNR_MAX_ERROR);
TESTASSERT(fabsf(meas.cfo_hz - cfo_hz) < CFO_MAX_ERROR);
TESTASSERT(fabsf(meas.delay_us + delay_us) < DELAY_MAX_ERROR);
}
INFO("test_case_1 - %.1f usec/measurement", (double)t_usec / (double)SRSRAN_NOF_NID_NR);
return SRSRAN_SUCCESS;
}
int main(int argc, char** argv)
{
int ret = SRSRAN_ERROR;
parse_args(argc, argv);
srate_hz = (double)SRSRAN_SUBC_SPACING_NR(carrier_scs) * srsran_min_symbol_sz_rb(carrier_nof_prb);
delay_us = 1e6f * delay_n / (float)srate_hz;
sf_len = (uint32_t)ceil(srate_hz / 1000.0);
buffer = srsran_vec_cf_malloc(sf_len);
srsran_ssb_t ssb = {};
srsran_ssb_args_t ssb_args = {};
ssb_args.enable_encode = true;
ssb_args.enable_measure = true;
if (buffer == NULL) {
ERROR("Malloc");
goto clean_exit;
}
if (srsran_channel_awgn_init(&awgn, 0x0) < SRSRAN_SUCCESS) {
ERROR("AWGN");
goto clean_exit;
}
if (srsran_channel_awgn_set_n0(&awgn, n0_dB) < SRSRAN_SUCCESS) {
ERROR("AWGN");
goto clean_exit;
}
if (srsran_ssb_init(&ssb, &ssb_args) < SRSRAN_SUCCESS) {
ERROR("Init");
goto clean_exit;
}
if (test_case_1(&ssb) != SRSRAN_SUCCESS) {
ERROR("test case failed");
}
ret = SRSRAN_SUCCESS;
clean_exit:
srsran_ssb_free(&ssb);
srsran_channel_awgn_free(&awgn);
if (buffer) {
free(buffer);
}
return ret;
}

@ -21,20 +21,14 @@
#include "srsran/adt/move_callback.h" #include "srsran/adt/move_callback.h"
#include "srsran/common/multiqueue.h" #include "srsran/common/multiqueue.h"
#include "srsran/common/test_common.h"
#include "srsran/common/thread_pool.h" #include "srsran/common/thread_pool.h"
#include <iostream> #include <iostream>
#include <map> #include <map>
#include <random>
#include <thread> #include <thread>
#include <unistd.h> #include <unistd.h>
#define TESTASSERT(cond) \
{ \
if (!(cond)) { \
std::cout << "[" << __FUNCTION__ << "][Line " << __LINE__ << "]: FAIL at " << (#cond) << std::endl; \
return -1; \
} \
}
using namespace srsran; using namespace srsran;
int test_multiqueue() int test_multiqueue()
@ -44,79 +38,80 @@ int test_multiqueue()
int number = 2; int number = 2;
multiqueue_handler<int> multiqueue; multiqueue_handler<int> multiqueue;
TESTASSERT(multiqueue.nof_queues() == 0) TESTASSERT(multiqueue.nof_queues() == 0);
// test push/pop and size for one queue // test push/pop and size for one queue
int qid1 = multiqueue.add_queue(); queue_handle<int> qid1 = multiqueue.add_queue();
TESTASSERT(qid1 == 0 and multiqueue.is_queue_active(qid1)) TESTASSERT(qid1.active());
TESTASSERT(multiqueue.size(qid1) == 0 and multiqueue.empty(qid1)) TESTASSERT(qid1.size() == 0 and qid1.empty());
TESTASSERT(multiqueue.nof_queues() == 1) TESTASSERT(multiqueue.nof_queues() == 1);
TESTASSERT(multiqueue.try_push(qid1, 5).first) TESTASSERT(qid1.try_push(5).has_value());
TESTASSERT(multiqueue.try_push(qid1, number)) TESTASSERT(qid1.try_push(number));
TESTASSERT(multiqueue.size(qid1) == 2 and not multiqueue.empty(qid1)) TESTASSERT(qid1.size() == 2 and not qid1.empty());
TESTASSERT(multiqueue.wait_pop(&number) == qid1) TESTASSERT(multiqueue.wait_pop(&number));
TESTASSERT(number == 5) TESTASSERT(number == 5);
TESTASSERT(multiqueue.wait_pop(&number) == qid1) TESTASSERT(multiqueue.wait_pop(&number));
TESTASSERT(number == 2 and multiqueue.empty(qid1) and multiqueue.size(qid1) == 0) TESTASSERT(number == 2 and qid1.empty());
// test push/pop and size for two queues // test push/pop and size for two queues
int qid2 = multiqueue.add_queue(); queue_handle<int> qid2 = multiqueue.add_queue();
TESTASSERT(qid2 == 1) TESTASSERT(qid2.active());
TESTASSERT(multiqueue.nof_queues() == 2 and multiqueue.is_queue_active(qid1)) TESTASSERT(multiqueue.nof_queues() == 2 and qid1.active());
TESTASSERT(multiqueue.try_push(qid2, 3).first) TESTASSERT(qid2.try_push(3).has_value());
TESTASSERT(multiqueue.size(qid2) == 1 and not multiqueue.empty(qid2)) TESTASSERT(qid2.size() == 1 and not qid2.empty());
TESTASSERT(multiqueue.empty(qid1) and multiqueue.size(qid1) == 0) TESTASSERT(qid1.empty());
// check if erasing a queue breaks anything // check if erasing a queue breaks anything
multiqueue.erase_queue(qid1); qid1.reset();
TESTASSERT(multiqueue.nof_queues() == 1 and not multiqueue.is_queue_active(qid1)) TESTASSERT(multiqueue.nof_queues() == 1 and not qid1.active());
qid1 = multiqueue.add_queue(); qid1 = multiqueue.add_queue();
TESTASSERT(qid1 == 0) TESTASSERT(qid1.empty() and qid1.active());
TESTASSERT(multiqueue.empty(qid1) and multiqueue.is_queue_active(qid1)) TESTASSERT(qid2.size() == 1 and not qid2.empty());
multiqueue.wait_pop(&number); multiqueue.wait_pop(&number);
// check round-robin // check round-robin
for (int i = 0; i < 10; ++i) { for (int i = 0; i < 10; ++i) {
TESTASSERT(multiqueue.try_push(qid1, i)) TESTASSERT(qid1.try_push(i));
} }
for (int i = 20; i < 35; ++i) { for (int i = 20; i < 35; ++i) {
TESTASSERT(multiqueue.try_push(qid2, i)) TESTASSERT(qid2.try_push(i));
} }
TESTASSERT(multiqueue.size(qid1) == 10) TESTASSERT(qid1.size() == 10);
TESTASSERT(multiqueue.size(qid2) == 15) TESTASSERT(qid2.size() == 15);
TESTASSERT(multiqueue.wait_pop(&number) == qid1 and number == 0) TESTASSERT(multiqueue.wait_pop(&number) and number == 0);
TESTASSERT(multiqueue.wait_pop(&number) == qid2 and number == 20) TESTASSERT(multiqueue.wait_pop(&number) and number == 20);
TESTASSERT(multiqueue.wait_pop(&number) == qid1 and number == 1) TESTASSERT(multiqueue.wait_pop(&number) and number == 1);
TESTASSERT(multiqueue.wait_pop(&number) == qid2 and number == 21) TESTASSERT(multiqueue.wait_pop(&number) and number == 21);
TESTASSERT(multiqueue.size(qid1) == 8) TESTASSERT(qid1.size() == 8);
TESTASSERT(multiqueue.size(qid2) == 13) TESTASSERT(qid2.size() == 13);
for (int i = 0; i < 8 * 2; ++i) { for (int i = 0; i < 8 * 2; ++i) {
multiqueue.wait_pop(&number); multiqueue.wait_pop(&number);
} }
TESTASSERT(multiqueue.size(qid1) == 0) TESTASSERT(qid1.size() == 0);
TESTASSERT(multiqueue.size(qid2) == 5) TESTASSERT(qid2.size() == 5);
TESTASSERT(multiqueue.wait_pop(&number) == qid2 and number == 30) TESTASSERT(multiqueue.wait_pop(&number) and number == 30);
// remove existing queues // remove existing queues
multiqueue.erase_queue(qid1); qid1.reset();
multiqueue.erase_queue(qid2); qid2.reset();
TESTASSERT(multiqueue.nof_queues() == 0) TESTASSERT(multiqueue.nof_queues() == 0);
// check that adding a queue of different capacity works // check that adding a queue of different capacity works
{ {
int qid1 = multiqueue.add_queue(); qid1 = multiqueue.add_queue();
int qid2 = multiqueue.add_queue(); qid2 = multiqueue.add_queue();
// remove first queue again // remove first queue again
multiqueue.erase_queue(qid1); qid1.reset();
TESTASSERT(multiqueue.nof_queues() == 1) TESTASSERT(multiqueue.nof_queues() == 1);
// add queue with non-default capacity // add queue with non-default capacity
int qid3 = multiqueue.add_queue(10); auto qid3 = multiqueue.add_queue(10);
TESTASSERT(qid3.capacity() == 10);
// make sure neither a new queue index is returned // make sure neither a new queue index is returned
TESTASSERT(qid1 != qid3) TESTASSERT(qid1 != qid3);
TESTASSERT(qid2 != qid3) TESTASSERT(qid2 != qid3);
} }
std::cout << "outcome: Success\n"; std::cout << "outcome: Success\n";
@ -131,10 +126,10 @@ int test_multiqueue_threading()
int capacity = 4, number = 0, start_number = 2, nof_pushes = capacity + 1; int capacity = 4, number = 0, start_number = 2, nof_pushes = capacity + 1;
multiqueue_handler<int> multiqueue(capacity); multiqueue_handler<int> multiqueue(capacity);
int qid1 = multiqueue.add_queue(); auto qid1 = multiqueue.add_queue();
auto push_blocking_func = [&multiqueue](int qid, int start_value, int nof_pushes, bool* is_running) { auto push_blocking_func = [](queue_handle<int>* qid, int start_value, int nof_pushes, bool* is_running) {
for (int i = 0; i < nof_pushes; ++i) { for (int i = 0; i < nof_pushes; ++i) {
multiqueue.push(qid, start_value + i); qid->push(start_value + i);
std::cout << "t1: pushed item " << i << std::endl; std::cout << "t1: pushed item " << i << std::endl;
} }
std::cout << "t1: pushed all items\n"; std::cout << "t1: pushed all items\n";
@ -142,17 +137,17 @@ int test_multiqueue_threading()
}; };
bool t1_running = true; bool t1_running = true;
std::thread t1(push_blocking_func, qid1, start_number, nof_pushes, &t1_running); std::thread t1(push_blocking_func, &qid1, start_number, nof_pushes, &t1_running);
// Wait for queue to fill // Wait for queue to fill
while ((int)multiqueue.size(qid1) != capacity) { while ((int)qid1.size() != capacity) {
usleep(1000); usleep(1000);
TESTASSERT(t1_running) TESTASSERT(t1_running);
} }
for (int i = 0; i < nof_pushes; ++i) { for (int i = 0; i < nof_pushes; ++i) {
TESTASSERT(multiqueue.wait_pop(&number) == qid1) TESTASSERT(multiqueue.wait_pop(&number));
TESTASSERT(number == start_number + i) TESTASSERT(number == start_number + i);
std::cout << "main: popped item " << i << "\n"; std::cout << "main: popped item " << i << "\n";
} }
std::cout << "main: popped all items\n"; std::cout << "main: popped all items\n";
@ -161,9 +156,9 @@ int test_multiqueue_threading()
while (t1_running) { while (t1_running) {
usleep(1000); usleep(1000);
} }
TESTASSERT(multiqueue.size(qid1) == 0) TESTASSERT(qid1.size() == 0);
multiqueue.reset(); multiqueue.stop();
t1.join(); t1.join();
std::cout << "outcome: Success\n"; std::cout << "outcome: Success\n";
@ -179,25 +174,25 @@ int test_multiqueue_threading2()
int capacity = 4, start_number = 2, nof_pushes = capacity + 1; int capacity = 4, start_number = 2, nof_pushes = capacity + 1;
multiqueue_handler<int> multiqueue(capacity); multiqueue_handler<int> multiqueue(capacity);
int qid1 = multiqueue.add_queue(); auto qid1 = multiqueue.add_queue();
auto push_blocking_func = [&multiqueue](int qid, int start_value, int nof_pushes, bool* is_running) { auto push_blocking_func = [](queue_handle<int>* qid, int start_value, int nof_pushes, bool* is_running) {
for (int i = 0; i < nof_pushes; ++i) { for (int i = 0; i < nof_pushes; ++i) {
multiqueue.push(qid, start_value + i); qid->push(start_value + i);
} }
std::cout << "t1: pushed all items\n"; std::cout << "t1: pushed all items\n";
*is_running = false; *is_running = false;
}; };
bool t1_running = true; bool t1_running = true;
std::thread t1(push_blocking_func, qid1, start_number, nof_pushes, &t1_running); std::thread t1(push_blocking_func, &qid1, start_number, nof_pushes, &t1_running);
// Wait for queue to fill // Wait for queue to fill
while ((int)multiqueue.size(qid1) != capacity) { while ((int)qid1.size() != capacity) {
usleep(1000); usleep(1000);
TESTASSERT(t1_running) TESTASSERT(t1_running);
} }
multiqueue.reset(); multiqueue.stop();
t1.join(); t1.join();
std::cout << "outcome: Success\n"; std::cout << "outcome: Success\n";
@ -213,23 +208,95 @@ int test_multiqueue_threading3()
int capacity = 4; int capacity = 4;
multiqueue_handler<int> multiqueue(capacity); multiqueue_handler<int> multiqueue(capacity);
int qid1 = multiqueue.add_queue(); auto qid1 = multiqueue.add_queue();
auto pop_blocking_func = [&multiqueue](int qid, bool* success) { auto pop_blocking_func = [&multiqueue](bool* success) {
int number = 0; int number = 0;
int id = multiqueue.wait_pop(&number); bool ret = multiqueue.wait_pop(&number);
*success = id < 0; *success = not ret;
}; };
bool t1_success = false; bool t1_success = false;
std::thread t1(pop_blocking_func, qid1, &t1_success); std::thread t1(pop_blocking_func, &t1_success);
TESTASSERT(not t1_success) TESTASSERT(not t1_success);
usleep(1000); usleep(1000);
TESTASSERT(not t1_success) TESTASSERT(not t1_success);
TESTASSERT((int)multiqueue.size(qid1) == 0) TESTASSERT((int)qid1.size() == 0);
// Should be able to unlock all
multiqueue.stop();
TESTASSERT(multiqueue.nof_queues() == 0);
TESTASSERT(not qid1.active());
t1.join();
TESTASSERT(t1_success);
std::cout << "outcome: Success\n";
std::cout << "===================================================\n";
return 0;
}
int test_multiqueue_threading4()
{
std::cout << "\n===== TEST multiqueue threading test 4: start =====\n";
// Description: the consumer will block on popping, but the pushing from different producers
// should be sufficient to awake it when necessary
int capacity = 4;
multiqueue_handler<int> multiqueue(capacity);
auto qid1 = multiqueue.add_queue();
auto qid2 = multiqueue.add_queue();
auto qid3 = multiqueue.add_queue();
auto qid4 = multiqueue.add_queue();
std::mutex mutex;
int last_number = -1;
auto pop_blocking_func = [&multiqueue, &last_number, &mutex](bool* success) {
int number = 0;
while (multiqueue.wait_pop(&number)) {
std::lock_guard<std::mutex> lock(mutex);
last_number = std::max(last_number, number);
}
*success = true;
};
bool t1_success = false;
std::thread t1(pop_blocking_func, &t1_success);
std::random_device rd;
std::mt19937 gen(rd());
std::uniform_int_distribution<> dist{0, 2};
for (int i = 0; i < 10000; ++i) {
int qidx = dist(gen);
switch (qidx) {
case 0:
qid1.push(i);
break;
case 1:
qid2.push(i);
break;
case 2:
qid4.push(i);
break;
default:
break;
}
if (i % 20 == 0) {
int count = 0;
std::unique_lock<std::mutex> lock(mutex);
while (last_number != i) {
lock.unlock();
usleep(100);
count++;
TESTASSERT(count < 100000);
lock.lock();
}
}
}
// Should be able to unlock all // Should be able to unlock all
multiqueue.reset(); multiqueue.stop();
TESTASSERT(multiqueue.nof_queues() == 0);
TESTASSERT(not qid1.active());
t1.join(); t1.join();
TESTASSERT(t1_success); TESTASSERT(t1_success);
@ -430,6 +497,7 @@ int main()
TESTASSERT(test_multiqueue_threading() == 0); TESTASSERT(test_multiqueue_threading() == 0);
TESTASSERT(test_multiqueue_threading2() == 0); TESTASSERT(test_multiqueue_threading2() == 0);
TESTASSERT(test_multiqueue_threading3() == 0); TESTASSERT(test_multiqueue_threading3() == 0);
TESTASSERT(test_multiqueue_threading4() == 0);
TESTASSERT(test_task_thread_pool() == 0); TESTASSERT(test_task_thread_pool() == 0);
TESTASSERT(test_task_thread_pool2() == 0); TESTASSERT(test_task_thread_pool2() == 0);

@ -130,7 +130,7 @@ private:
// task handling // task handling
srsran::task_scheduler task_sched; srsran::task_scheduler task_sched;
srsran::task_queue_handle enb_task_queue, gtpu_task_queue, mme_task_queue, sync_task_queue; srsran::task_queue_handle enb_task_queue, sync_task_queue;
srsenb::mac mac; srsenb::mac mac;
srsenb::rlc rlc; srsenb::rlc rlc;

@ -203,7 +203,7 @@ private:
const static uint32_t LCID_REM_USER = 0xffff0001; const static uint32_t LCID_REM_USER = 0xffff0001;
const static uint32_t LCID_REL_USER = 0xffff0002; const static uint32_t LCID_REL_USER = 0xffff0002;
const static uint32_t LCID_ACT_USER = 0xffff0004; const static uint32_t LCID_ACT_USER = 0xffff0004;
const static uint32_t LCID_RTX_USER = 0xffff0005; const static uint32_t LCID_RLC_RTX = 0xffff0005;
const static uint32_t LCID_RADLINK_DL = 0xffff0006; const static uint32_t LCID_RADLINK_DL = 0xffff0006;
const static uint32_t LCID_RADLINK_UL = 0xffff0007; const static uint32_t LCID_RADLINK_UL = 0xffff0007;

@ -85,13 +85,21 @@ private:
const static size_t nof_paging_subframes = 4; const static size_t nof_paging_subframes = 4;
bool add_paging_record(uint32_t ueid, const asn1::rrc::paging_record_s& paging_record); bool add_paging_record(uint32_t ueid, const asn1::rrc::paging_record_s& paging_record);
pcch_info& get_pcch_info(tti_point tti_tx_dl) pcch_info* get_pcch_info(tti_point tti_tx_dl)
{ {
return pending_paging[tti_tx_dl.sfn() % T][get_sf_idx_key(tti_tx_dl.sf_idx())]; int sf_key = get_sf_idx_key(tti_tx_dl.sf_idx());
if (sf_key < 0) {
return nullptr;
}
return &pending_paging[tti_tx_dl.sfn() % T][sf_key];
} }
const pcch_info& get_pcch_info(tti_point tti_tx_dl) const const pcch_info* get_pcch_info(tti_point tti_tx_dl) const
{ {
return pending_paging[tti_tx_dl.sfn() % T][get_sf_idx_key(tti_tx_dl.sf_idx())]; int sf_key = get_sf_idx_key(tti_tx_dl.sf_idx());
if (sf_key < 0) {
return nullptr;
}
return &pending_paging[tti_tx_dl.sfn() % T][sf_key];
} }
static int get_sf_idx_key(uint32_t sf_idx) static int get_sf_idx_key(uint32_t sf_idx)
{ {
@ -156,12 +164,13 @@ bool paging_manager::add_paging_record(uint32_t ueid, const asn1::rrc::paging_re
logger.error("SF pattern is N/A for Ns=%d, i_s=%d, imsi_decimal=%d", Ns, i_s, ueid); logger.error("SF pattern is N/A for Ns=%d, i_s=%d, imsi_decimal=%d", Ns, i_s, ueid);
return false; return false;
} }
size_t sf_key = static_cast<size_t>(get_sf_idx_key(sf_idx));
size_t sfn_cycle_idx = (T / N) * (ueid % N); size_t sfn_cycle_idx = (T / N) * (ueid % N);
pcch_info& pending_pcch = pending_paging[sfn_cycle_idx][get_sf_idx_key(sf_idx)]; pcch_info& pending_pcch = pending_paging[sfn_cycle_idx][sf_key];
auto& record_list = pending_pcch.pcch_msg.msg.c1().paging().paging_record_list; auto& record_list = pending_pcch.pcch_msg.msg.c1().paging().paging_record_list;
std::lock_guard<std::mutex> lock(sf_idx_mutex[get_sf_idx_key(sf_idx)]); std::lock_guard<std::mutex> lock(sf_idx_mutex[sf_key]);
if (record_list.size() >= ASN1_RRC_MAX_PAGE_REC) { if (record_list.size() >= ASN1_RRC_MAX_PAGE_REC) {
logger.warning("Failed to add new paging record for ueid=%d. Cause: no paging record space left.", ueid); logger.warning("Failed to add new paging record for ueid=%d. Cause: no paging record space left.", ueid);
@ -197,19 +206,19 @@ size_t paging_manager::pending_pcch_bytes(tti_point tti_tx_dl)
return 0; return 0;
} }
std::lock_guard<std::mutex> lock(sf_idx_mutex[sf_key]); std::lock_guard<std::mutex> lock(sf_idx_mutex[static_cast<size_t>(sf_key)]);
// clear old PCCH that has been transmitted at this point // clear old PCCH that has been transmitted at this point
pcch_info& old_pcch = get_pcch_info(tti_tx_dl - SRSRAN_NOF_SF_X_FRAME); pcch_info* old_pcch = get_pcch_info(tti_tx_dl - SRSRAN_NOF_SF_X_FRAME);
if (not old_pcch.empty()) { if (old_pcch != nullptr and not old_pcch->empty()) {
old_pcch.clear(); old_pcch->clear();
} }
const pcch_info& pending_pcch = get_pcch_info(tti_tx_dl); const pcch_info* pending_pcch = get_pcch_info(tti_tx_dl);
if (pending_pcch.empty()) { if (pending_pcch->empty()) {
return 0; return 0;
} }
return pending_pcch.pdu->size(); return pending_pcch->pdu->size();
} }
template <typename Callable> template <typename Callable>
@ -221,18 +230,18 @@ bool paging_manager::read_pdu_pcch(tti_point tti_tx_dl, const Callable& func)
return false; return false;
} }
pcch_info& pending_pcch = get_pcch_info(tti_tx_dl); std::lock_guard<std::mutex> lock(sf_idx_mutex[static_cast<size_t>(sf_key)]);
std::lock_guard<std::mutex> lock(sf_idx_mutex[get_sf_idx_key(tti_tx_dl.sf_idx())]); pcch_info* pending_pcch = get_pcch_info(tti_tx_dl);
if (pending_pcch.empty()) { if (pending_pcch->empty()) {
logger.warning("read_pdu_pdcch(...) called for tti=%d, but there is no pending pcch message", tti_tx_dl.to_uint()); logger.warning("read_pdu_pdcch(...) called for tti=%d, but there is no pending pcch message", tti_tx_dl.to_uint());
return false; return false;
} }
// Call callable for existing PCCH pdu // Call callable for existing PCCH pdu
if (func(*pending_pcch.pdu, pending_pcch.pcch_msg, pending_pcch.tti_tx_dl.is_valid())) { if (func(*pending_pcch->pdu, pending_pcch->pcch_msg, pending_pcch->tti_tx_dl.is_valid())) {
pending_pcch.tti_tx_dl = tti_tx_dl; pending_pcch->tti_tx_dl = tti_tx_dl;
return true; return true;
} }
return false; return false;

@ -50,13 +50,11 @@ public:
std::string to_string(const activity_timeout_type_t& type); std::string to_string(const activity_timeout_type_t& type);
void set_activity_timeout(const activity_timeout_type_t type); void set_activity_timeout(const activity_timeout_type_t type);
void set_activity(); void set_activity();
void start_rlf_timer();
void stop_rlf_timer();
void set_radiolink_dl_state(bool crc_res); void set_radiolink_dl_state(bool crc_res);
void set_radiolink_ul_state(bool crc_res); void set_radiolink_ul_state(bool crc_res);
void activity_timer_expired(const activity_timeout_type_t type); void activity_timer_expired(const activity_timeout_type_t type);
void rlf_timer_expired(); void rlf_timer_expired(uint32_t timeout_id);
void max_retx_reached(); void max_rlc_retx_reached();
rrc_state_t get_state(); rrc_state_t get_state();
void get_metrics(rrc_ue_metrics_t& ue_metrics) const; void get_metrics(rrc_ue_metrics_t& ue_metrics) const;
@ -122,7 +120,6 @@ public:
bool has_erab(uint32_t erab_id) const { return bearer_list.get_erabs().count(erab_id) > 0; } bool has_erab(uint32_t erab_id) const { return bearer_list.get_erabs().count(erab_id) > 0; }
int get_erab_addr_in(uint16_t erab_id, transp_addr_t& addr_in, uint32_t& teid_in) const; int get_erab_addr_in(uint16_t erab_id, transp_addr_t& addr_in, uint32_t& teid_in) const;
bool setup_erabs(const asn1::s1ap::erab_to_be_setup_list_ctxt_su_req_l& e);
bool release_erabs(); bool release_erabs();
int release_erab(uint32_t erab_id); int release_erab(uint32_t erab_id);
int setup_erab(uint16_t erab_id, int setup_erab(uint16_t erab_id,
@ -167,9 +164,12 @@ public:
bool is_csfb = false; bool is_csfb = false;
private: private:
// args srsran::unique_timer activity_timer; // for basic DL/UL activity timeout
srsran::unique_timer activity_timer;
srsran::unique_timer rlf_release_timer; /// Radio link failure handling uses distinct timers for PHY (DL and UL) and RLC signaled RLF
srsran::unique_timer phy_dl_rlf_timer; // can be stopped through recovered DL activity
srsran::unique_timer phy_ul_rlf_timer; // can be stopped through recovered UL activity
srsran::unique_timer rlc_rlf_timer; // can only be stoped through UE reestablishment
/// cached ASN1 fields for RRC config update checking, and ease of context transfer during HO /// cached ASN1 fields for RRC config update checking, and ease of context transfer during HO
ue_var_cfg_t current_ue_cfg; ue_var_cfg_t current_ue_cfg;

@ -44,7 +44,7 @@ public:
ngap(srsran::task_sched_handle task_sched_, ngap(srsran::task_sched_handle task_sched_,
srslog::basic_logger& logger, srslog::basic_logger& logger,
srsran::socket_manager_itf* rx_socket_handler); srsran::socket_manager_itf* rx_socket_handler);
int init(ngap_args_t args_, rrc_interface_ngap_nr* rrc_); int init(const ngap_args_t& args_, rrc_interface_ngap_nr* rrc_);
void stop(); void stop();
// RRC NR interface // RRC NR interface

@ -50,9 +50,7 @@ enb_stack_lte::enb_stack_lte(srslog::sink& log_sink) :
pending_stack_metrics(64) pending_stack_metrics(64)
{ {
get_background_workers().set_nof_workers(2); get_background_workers().set_nof_workers(2);
enb_task_queue = task_sched.make_task_queue(); enb_task_queue = task_sched.make_task_queue();
mme_task_queue = task_sched.make_task_queue();
gtpu_task_queue = task_sched.make_task_queue();
// sync_queue is added in init() // sync_queue is added in init()
} }
@ -227,7 +225,7 @@ bool enb_stack_lte::get_metrics(stack_metrics_t* metrics)
} }
}); });
if (ret.first) { if (ret.has_value()) {
// wait for result // wait for result
*metrics = pending_stack_metrics.pop_blocking(); *metrics = pending_stack_metrics.pop_blocking();
return true; return true;

@ -308,8 +308,10 @@ void mac_controller::handle_ho_prep(const asn1::rrc::ho_prep_info_r8_ies_s& ho_p
void mac_controller::handle_max_retx() void mac_controller::handle_max_retx()
{ {
set_drb_activation(false); for (auto& ue_bearer : current_sched_ue_cfg.ue_bearers) {
update_mac(other); ue_bearer.direction = sched_interface::ue_bearer_cfg_t::IDLE;
}
update_mac(config_tx);
} }
void mac_controller::set_scell_activation(const std::bitset<SRSRAN_MAX_CARRIERS>& scell_mask) void mac_controller::set_scell_activation(const std::bitset<SRSRAN_MAX_CARRIERS>& scell_mask)

@ -183,7 +183,7 @@ uint32_t rrc::get_nof_users()
void rrc::max_retx_attempted(uint16_t rnti) void rrc::max_retx_attempted(uint16_t rnti)
{ {
rrc_pdu p = {rnti, LCID_RTX_USER, false, nullptr}; rrc_pdu p = {rnti, LCID_RLC_RTX, false, nullptr};
if (not rx_pdu_queue.try_push(std::move(p))) { if (not rx_pdu_queue.try_push(std::move(p))) {
logger.error("Failed to push max Retx event to RRC queue"); logger.error("Failed to push max Retx event to RRC queue");
} }
@ -952,8 +952,8 @@ void rrc::tti_clock()
case LCID_RADLINK_UL: case LCID_RADLINK_UL:
user_it->second->set_radiolink_ul_state(p.arg); user_it->second->set_radiolink_ul_state(p.arg);
break; break;
case LCID_RTX_USER: case LCID_RLC_RTX:
user_it->second->max_retx_reached(); user_it->second->max_rlc_retx_reached();
break; break;
case LCID_EXIT: case LCID_EXIT:
logger.info("Exiting thread"); logger.info("Exiting thread");

@ -65,13 +65,18 @@ int rrc::ue::init()
// Configure // Configure
apply_setup_phy_common(parent->cfg.sibs[1].sib2().rr_cfg_common, true); apply_setup_phy_common(parent->cfg.sibs[1].sib2().rr_cfg_common, true);
rlf_release_timer = parent->task_sched.get_unique_timer(); phy_dl_rlf_timer = parent->task_sched.get_unique_timer();
activity_timer = parent->task_sched.get_unique_timer(); phy_ul_rlf_timer = parent->task_sched.get_unique_timer();
rlc_rlf_timer = parent->task_sched.get_unique_timer();
activity_timer = parent->task_sched.get_unique_timer();
set_activity_timeout(MSG3_RX_TIMEOUT); // next UE response is Msg3 set_activity_timeout(MSG3_RX_TIMEOUT); // next UE response is Msg3
// Set timeout to release UE context after RLF detection // Set timeout to release UE context after RLF detection
uint32_t deadline_ms = parent->cfg.rlf_release_timer_ms; uint32_t deadline_ms = parent->cfg.rlf_release_timer_ms;
rlf_release_timer.set(deadline_ms, [this](uint32_t tid) { rlf_timer_expired(); }); auto timer_expire_func = [this](uint32_t tid) { rlf_timer_expired(tid); };
phy_dl_rlf_timer.set(deadline_ms, timer_expire_func);
phy_ul_rlf_timer.set(deadline_ms, timer_expire_func);
rlc_rlf_timer.set(deadline_ms, timer_expire_func);
parent->logger.info("Setting RLF timer for rnti=0x%x to %dms", rnti, deadline_ms); parent->logger.info("Setting RLF timer for rnti=0x%x to %dms", rnti, deadline_ms);
mobility_handler = make_rnti_obj<rrc_mobility>(rnti, this); mobility_handler = make_rnti_obj<rrc_mobility>(rnti, this);
@ -106,44 +111,34 @@ void rrc::ue::set_activity()
} }
} }
void rrc::ue::start_rlf_timer()
{
rlf_release_timer.run();
parent->logger.info("RLF timer started for rnti=0x%x (duration=%dms)", rnti, rlf_release_timer.duration());
}
void rrc::ue::stop_rlf_timer()
{
if (rlf_release_timer.is_running()) {
parent->logger.info("RLF timer stopped for rnti=0x%x (time elapsed=%dms)", rnti, rlf_release_timer.time_elapsed());
}
rlf_release_timer.stop();
}
void rrc::ue::set_radiolink_dl_state(bool crc_res) void rrc::ue::set_radiolink_dl_state(bool crc_res)
{ {
parent->logger.debug( parent->logger.debug(
"Radio-Link downlink state for rnti=0x%x: crc_res=%d, consecutive_ko=%d", rnti, crc_res, consecutive_kos_dl); "Radio-Link downlink state for rnti=0x%x: crc_res=%d, consecutive_ko=%d", rnti, crc_res, consecutive_kos_dl);
// If received OK, restart counter and stop RLF timer // If received OK, restart DL counter and stop RLF timer
if (crc_res) { if (crc_res) {
consecutive_kos_dl = 0; consecutive_kos_dl = 0;
consecutive_kos_ul = 0; if (phy_dl_rlf_timer.is_running()) {
stop_rlf_timer(); parent->logger.info(
"DL RLF timer stopped for rnti=0x%x (time elapsed=%dms)", rnti, phy_dl_rlf_timer.time_elapsed());
phy_dl_rlf_timer.stop();
}
return; return;
} }
// Count KOs in MAC and trigger release if it goes above a certain value. // Count KOs in MAC and trigger release if it goes above a certain value.
// This is done to detect out-of-coverage UEs // This is done to detect out-of-coverage UEs
if (rlf_release_timer.is_running()) { if (phy_dl_rlf_timer.is_running()) {
// RLF timer already running, no need to count KOs // RLF timer already running, no need to count KOs
return; return;
} }
consecutive_kos_dl++; consecutive_kos_dl++;
if (consecutive_kos_dl > parent->cfg.max_mac_dl_kos) { if (consecutive_kos_dl > parent->cfg.max_mac_dl_kos) {
parent->logger.info("Max KOs in DL reached, triggering release rnti=0x%x", rnti); parent->logger.info("Max KOs in DL reached, starting RLF timer rnti=0x%x", rnti);
max_retx_reached(); mac_ctrl.handle_max_retx();
phy_dl_rlf_timer.run();
} }
} }
@ -152,31 +147,34 @@ void rrc::ue::set_radiolink_ul_state(bool crc_res)
parent->logger.debug( parent->logger.debug(
"Radio-Link uplink state for rnti=0x%x: crc_res=%d, consecutive_ko=%d", rnti, crc_res, consecutive_kos_ul); "Radio-Link uplink state for rnti=0x%x: crc_res=%d, consecutive_ko=%d", rnti, crc_res, consecutive_kos_ul);
// If received OK, restart counter and stop RLF timer // If received OK, restart UL counter and stop RLF timer
if (crc_res) { if (crc_res) {
consecutive_kos_dl = 0;
consecutive_kos_ul = 0; consecutive_kos_ul = 0;
stop_rlf_timer(); if (phy_ul_rlf_timer.is_running()) {
parent->logger.info(
"UL RLF timer stopped for rnti=0x%x (time elapsed=%dms)", rnti, phy_ul_rlf_timer.time_elapsed());
phy_ul_rlf_timer.stop();
}
return; return;
} }
// Count KOs in MAC and trigger release if it goes above a certain value. // Count KOs in MAC and trigger release if it goes above a certain value.
// This is done to detect out-of-coverage UEs // This is done to detect out-of-coverage UEs
if (rlf_release_timer.is_running()) { if (phy_ul_rlf_timer.is_running()) {
// RLF timer already running, no need to count KOs // RLF timer already running, no need to count KOs
return; return;
} }
consecutive_kos_ul++; consecutive_kos_ul++;
if (consecutive_kos_ul > parent->cfg.max_mac_ul_kos) { if (consecutive_kos_ul > parent->cfg.max_mac_ul_kos) {
parent->logger.info("Max KOs in UL reached, triggering release rnti=0x%x", rnti); parent->logger.info("Max KOs in UL reached, starting RLF timer rnti=0x%x", rnti);
max_retx_reached(); mac_ctrl.handle_max_retx();
phy_ul_rlf_timer.run();
} }
} }
void rrc::ue::activity_timer_expired(const activity_timeout_type_t type) void rrc::ue::activity_timer_expired(const activity_timeout_type_t type)
{ {
stop_rlf_timer();
if (parent) { if (parent) {
parent->logger.info("Activity timer for rnti=0x%x expired after %d ms", rnti, activity_timer.time_elapsed()); parent->logger.info("Activity timer for rnti=0x%x expired after %d ms", rnti, activity_timer.time_elapsed());
@ -205,11 +203,17 @@ void rrc::ue::activity_timer_expired(const activity_timeout_type_t type)
state = RRC_STATE_RELEASE_REQUEST; state = RRC_STATE_RELEASE_REQUEST;
} }
void rrc::ue::rlf_timer_expired() void rrc::ue::rlf_timer_expired(uint32_t timeout_id)
{ {
activity_timer.stop(); activity_timer.stop();
if (parent) { if (parent) {
parent->logger.info("RLF timer for rnti=0x%x expired after %d ms", rnti, rlf_release_timer.time_elapsed()); if (timeout_id == phy_dl_rlf_timer.id()) {
parent->logger.info("DL RLF timer for rnti=0x%x expired after %d ms", rnti, phy_dl_rlf_timer.time_elapsed());
} else if (timeout_id == phy_ul_rlf_timer.id()) {
parent->logger.info("UL RLF timer for rnti=0x%x expired after %d ms", rnti, phy_ul_rlf_timer.time_elapsed());
} else if (timeout_id == rlc_rlf_timer.id()) {
parent->logger.info("RLC RLF timer for rnti=0x%x expired after %d ms", rnti, rlc_rlf_timer.time_elapsed());
}
if (parent->s1ap->user_exists(rnti)) { if (parent->s1ap->user_exists(rnti)) {
parent->s1ap->user_release(rnti, asn1::s1ap::cause_radio_network_opts::radio_conn_with_ue_lost); parent->s1ap->user_release(rnti, asn1::s1ap::cause_radio_network_opts::radio_conn_with_ue_lost);
@ -224,14 +228,13 @@ void rrc::ue::rlf_timer_expired()
state = RRC_STATE_RELEASE_REQUEST; state = RRC_STATE_RELEASE_REQUEST;
} }
void rrc::ue::max_retx_reached() void rrc::ue::max_rlc_retx_reached()
{ {
if (parent) { if (parent) {
parent->logger.info("Max retx reached for rnti=0x%x", rnti); parent->logger.info("Max RLC retx reached for rnti=0x%x", rnti);
// Give UE time to start re-establishment
start_rlf_timer();
// Turn off DRB scheduling but give UE chance to start re-establishment
rlc_rlf_timer.run();
mac_ctrl.handle_max_retx(); mac_ctrl.handle_max_retx();
} }
} }
@ -397,10 +400,8 @@ void rrc::ue::handle_rrc_con_req(rrc_conn_request_s* msg)
for (auto& user : parent->users) { for (auto& user : parent->users) {
if (user.first != rnti && user.second->has_tmsi && user.second->mmec == mmec && user.second->m_tmsi == m_tmsi) { if (user.first != rnti && user.second->has_tmsi && user.second->mmec == mmec && user.second->m_tmsi == m_tmsi) {
parent->logger.info("RRC connection request: UE context already exists. M-TMSI=%d", m_tmsi); parent->logger.info("RRC connection request: UE context already exists. M-TMSI=%d", m_tmsi);
if (parent->s1ap->user_release(rnti, asn1::s1ap::cause_radio_network_opts::radio_conn_with_ue_lost)) { user.second->state = RRC_STATE_IDLE; // Set old rnti to IDLE so that enb doesn't send RRC Connection Release
// Do not wait for MME response parent->s1ap->user_release(user.first, asn1::s1ap::cause_radio_network_opts::radio_conn_with_ue_lost);
parent->rem_user_thread(user.first);
}
break; break;
} }
} }
@ -528,9 +529,6 @@ void rrc::ue::handle_rrc_con_reest_req(rrc_conn_reest_request_s* msg)
const rrc_conn_reest_request_r8_ies_s& req_r8 = msg->crit_exts.rrc_conn_reest_request_r8(); const rrc_conn_reest_request_r8_ies_s& req_r8 = msg->crit_exts.rrc_conn_reest_request_r8();
uint16_t old_rnti = req_r8.ue_id.c_rnti.to_number(); uint16_t old_rnti = req_r8.ue_id.c_rnti.to_number();
srsran::console(
"User 0x%x requesting RRC Reestablishment as 0x%x. Cause: %s\n", rnti, old_rnti, req_r8.reest_cause.to_string());
if (not parent->s1ap->is_mme_connected()) { if (not parent->s1ap->is_mme_connected()) {
parent->logger.error("MME isn't connected. Sending Connection Reject"); parent->logger.error("MME isn't connected. Sending Connection Reject");
send_connection_reest_rej(procedure_result_code::error_mme_not_connected); send_connection_reest_rej(procedure_result_code::error_mme_not_connected);
@ -542,69 +540,84 @@ void rrc::ue::handle_rrc_con_reest_req(rrc_conn_reest_request_s* msg)
msg->crit_exts.rrc_conn_reest_request_r8().ue_id.pci, msg->crit_exts.rrc_conn_reest_request_r8().ue_id.pci,
(uint32_t)msg->crit_exts.rrc_conn_reest_request_r8().ue_id.short_mac_i.to_number(), (uint32_t)msg->crit_exts.rrc_conn_reest_request_r8().ue_id.short_mac_i.to_number(),
msg->crit_exts.rrc_conn_reest_request_r8().reest_cause.to_string()); msg->crit_exts.rrc_conn_reest_request_r8().reest_cause.to_string());
if (is_idle()) {
uint16_t old_pci = msg->crit_exts.rrc_conn_reest_request_r8().ue_id.pci;
const enb_cell_common* old_cell = parent->cell_common_list->get_pci(old_pci);
auto ue_it = parent->users.find(old_rnti);
// Reject unrecognized rntis, and PCIs that do not belong to eNB
if (ue_it != parent->users.end() and old_cell != nullptr and
ue_it->second->ue_cell_list.get_enb_cc_idx(old_cell->enb_cc_idx) != nullptr) {
parent->logger.info("ConnectionReestablishmentRequest for rnti=0x%x. Sending Connection Reestablishment",
old_rnti);
// Cancel Handover in Target eNB if on-going
asn1::s1ap::cause_c cause;
cause.set_radio_network().value = asn1::s1ap::cause_radio_network_opts::interaction_with_other_proc;
parent->users.at(old_rnti)->mobility_handler->trigger(rrc_mobility::ho_cancel_ev{cause});
// Recover security setup
const enb_cell_common* pcell_cfg = get_ue_cc_cfg(UE_PCELL_CC_IDX);
ue_security_cfg = parent->users.at(old_rnti)->ue_security_cfg;
ue_security_cfg.regenerate_keys_handover(pcell_cfg->cell_cfg.pci, pcell_cfg->cell_cfg.dl_earfcn);
// send reestablishment and restore bearer configuration
send_connection_reest(parent->users.at(old_rnti)->ue_security_cfg.get_ncc());
// Get PDCP entity state (required when using RLC AM)
for (const auto& erab_pair : parent->users.at(old_rnti)->bearer_list.get_erabs()) {
uint16_t lcid = erab_pair.second.id - 2;
old_reest_pdcp_state[lcid] = {};
parent->pdcp->get_bearer_state(old_rnti, lcid, &old_reest_pdcp_state[lcid]);
parent->logger.debug("Getting PDCP state for E-RAB with LCID %d", lcid);
parent->logger.debug("Got PDCP state: TX HFN %d, NEXT_PDCP_TX_SN %d, RX_HFN %d, NEXT_PDCP_RX_SN %d, "
"LAST_SUBMITTED_PDCP_RX_SN %d",
old_reest_pdcp_state[lcid].tx_hfn,
old_reest_pdcp_state[lcid].next_pdcp_tx_sn,
old_reest_pdcp_state[lcid].rx_hfn,
old_reest_pdcp_state[lcid].next_pdcp_rx_sn,
old_reest_pdcp_state[lcid].last_submitted_pdcp_rx_sn);
}
// Make sure UE capabilities are copied over to new RNTI if (not is_idle()) {
eutra_capabilities = parent->users.at(old_rnti)->eutra_capabilities; // The created RNTI has to receive ReestablishmentRequest as first message
eutra_capabilities_unpacked = parent->users.at(old_rnti)->eutra_capabilities_unpacked;
ue_capabilities = parent->users.at(old_rnti)->ue_capabilities;
if (parent->logger.debug.enabled()) {
asn1::json_writer js{};
eutra_capabilities.to_json(js);
parent->logger.debug("rnti=0x%x EUTRA capabilities: %s", rnti, js.to_string().c_str());
}
old_reest_rnti = old_rnti;
state = RRC_STATE_WAIT_FOR_CON_REEST_COMPLETE;
set_activity_timeout(UE_INACTIVITY_TIMEOUT);
} else {
parent->logger.error("Received ConnectionReestablishment for rnti=0x%x without context", old_rnti);
send_connection_reest_rej(procedure_result_code::error_unknown_rnti);
srsran::console(
"User 0x%x RRC Reestablishment Request rejected. Cause: no rnti=0x%x context available\n", rnti, old_rnti);
}
} else {
parent->logger.error("Received ReestablishmentRequest from an rnti=0x%x not in IDLE", rnti); parent->logger.error("Received ReestablishmentRequest from an rnti=0x%x not in IDLE", rnti);
send_connection_reest_rej(procedure_result_code::error_unknown_rnti); send_connection_reest_rej(procedure_result_code::error_unknown_rnti);
srsran::console("ERROR: User 0x%x requesting Reestablishment is not in RRC_IDLE\n", rnti); srsran::console("ERROR: User 0x%x requesting Reestablishment is not in RRC_IDLE\n", rnti);
return;
}
uint16_t old_pci = msg->crit_exts.rrc_conn_reest_request_r8().ue_id.pci;
const enb_cell_common* old_cell = parent->cell_common_list->get_pci(old_pci);
auto old_ue_it = parent->users.find(old_rnti);
// Reject unrecognized rntis, and PCIs that do not belong to eNB
if (old_ue_it == parent->users.end() or old_cell == nullptr or
old_ue_it->second->ue_cell_list.get_enb_cc_idx(old_cell->enb_cc_idx) == nullptr) {
parent->logger.error("Received ConnectionReestablishment for rnti=0x%x without context", old_rnti);
send_connection_reest_rej(procedure_result_code::error_unknown_rnti);
srsran::console(
"User 0x%x RRC Reestablishment Request rejected. Cause: no rnti=0x%x context available\n", rnti, old_rnti);
return;
} }
ue* old_ue = old_ue_it->second.get();
// Reestablishment procedure going forward
parent->logger.info("ConnectionReestablishmentRequest for rnti=0x%x. Sending Connection Reestablishment", old_rnti);
srsran::console(
"User 0x%x requesting RRC Reestablishment as 0x%x. Cause: %s\n", rnti, old_rnti, req_r8.reest_cause.to_string());
// Cancel Handover in Target eNB if on-going
asn1::s1ap::cause_c cause;
cause.set_radio_network().value = asn1::s1ap::cause_radio_network_opts::interaction_with_other_proc;
old_ue->mobility_handler->trigger(rrc_mobility::ho_cancel_ev{cause});
// Recover security setup
const enb_cell_common* pcell_cfg = get_ue_cc_cfg(UE_PCELL_CC_IDX);
ue_security_cfg = old_ue->ue_security_cfg;
ue_security_cfg.regenerate_keys_handover(pcell_cfg->cell_cfg.pci, pcell_cfg->cell_cfg.dl_earfcn);
// send RRC Reestablishment message and restore bearer configuration
send_connection_reest(old_ue->ue_security_cfg.get_ncc());
// Get PDCP entity state (required when using RLC AM)
for (const auto& erab_pair : old_ue->bearer_list.get_erabs()) {
uint16_t lcid = erab_pair.second.id - 2;
old_reest_pdcp_state[lcid] = {};
parent->pdcp->get_bearer_state(old_rnti, lcid, &old_reest_pdcp_state[lcid]);
parent->logger.debug("Getting PDCP state for E-RAB with LCID %d", lcid);
parent->logger.debug("Got PDCP state: TX HFN %d, NEXT_PDCP_TX_SN %d, RX_HFN %d, NEXT_PDCP_RX_SN %d, "
"LAST_SUBMITTED_PDCP_RX_SN %d",
old_reest_pdcp_state[lcid].tx_hfn,
old_reest_pdcp_state[lcid].next_pdcp_tx_sn,
old_reest_pdcp_state[lcid].rx_hfn,
old_reest_pdcp_state[lcid].next_pdcp_rx_sn,
old_reest_pdcp_state[lcid].last_submitted_pdcp_rx_sn);
}
// Make sure UE capabilities are copied over to new RNTI
eutra_capabilities = old_ue->eutra_capabilities;
eutra_capabilities_unpacked = old_ue->eutra_capabilities_unpacked;
ue_capabilities = old_ue->ue_capabilities;
if (parent->logger.debug.enabled()) {
asn1::json_writer js{};
eutra_capabilities.to_json(js);
parent->logger.debug("rnti=0x%x EUTRA capabilities: %s", rnti, js.to_string().c_str());
}
// Stop RLF timers to avoid that old RNTI gets removed during RRC Reestablishment
parent->logger.info("Stopped RLF timers for old rnti=0x%x", old_rnti);
old_ue->rlc_rlf_timer.stop();
old_ue->phy_ul_rlf_timer.stop();
old_ue->phy_dl_rlf_timer.stop();
old_ue->mac_ctrl.set_drb_activation(false);
old_reest_rnti = old_rnti;
state = RRC_STATE_WAIT_FOR_CON_REEST_COMPLETE;
set_activity_timeout(UE_INACTIVITY_TIMEOUT);
} }
void rrc::ue::send_connection_reest(uint8_t ncc) void rrc::ue::send_connection_reest(uint8_t ncc)
@ -659,6 +672,14 @@ void rrc::ue::handle_rrc_con_reest_complete(rrc_conn_reest_complete_s* msg, srsr
parent->logger.info("RRCConnectionReestablishComplete transaction ID: %d", msg->rrc_transaction_id); parent->logger.info("RRCConnectionReestablishComplete transaction ID: %d", msg->rrc_transaction_id);
auto old_ue_it = parent->users.find(old_reest_rnti);
if (old_ue_it == parent->users.end()) {
parent->logger.error("RRC Reestablishment old rnti=0x%x was erased during the procedure", old_reest_rnti);
parent->release_ue(rnti);
return;
}
auto* old_ue = old_ue_it->second.get();
// TODO: msg->selected_plmn_id - used to select PLMN from SIB1 list // TODO: msg->selected_plmn_id - used to select PLMN from SIB1 list
// TODO: if(msg->registered_mme_present) - the indicated MME should be used from a pool // TODO: if(msg->registered_mme_present) - the indicated MME should be used from a pool
@ -675,10 +696,10 @@ void rrc::ue::handle_rrc_con_reest_complete(rrc_conn_reest_complete_s* msg, srsr
parent->pdcp->enable_encryption(rnti, srb_to_lcid(lte_srb::srb1)); parent->pdcp->enable_encryption(rnti, srb_to_lcid(lte_srb::srb1));
// Reestablish E-RABs of old rnti during ConnectionReconfiguration // Reestablish E-RABs of old rnti during ConnectionReconfiguration
bearer_list.reestablish_bearers(std::move(parent->users.at(old_reest_rnti)->bearer_list)); bearer_list.reestablish_bearers(std::move(old_ue->bearer_list));
// remove old RNTI // remove old RNTI
parent->rem_user_thread(old_reest_rnti); parent->rem_user(old_reest_rnti);
state = RRC_STATE_REESTABLISHMENT_COMPLETE; state = RRC_STATE_REESTABLISHMENT_COMPLETE;
@ -1029,35 +1050,6 @@ void rrc::ue::set_bitrates(const asn1::s1ap::ue_aggregate_maximum_bitrate_s& rat
bitrates = rates; bitrates = rates;
} }
bool rrc::ue::setup_erabs(const asn1::s1ap::erab_to_be_setup_list_ctxt_su_req_l& e)
{
for (const auto& item : e) {
const auto& erab = item.value.erab_to_be_setup_item_ctxt_su_req();
if (erab.ext) {
parent->logger.warning("Not handling E-RABToBeSetupListCtxtSURequest extensions");
}
if (erab.ie_exts_present) {
parent->logger.warning("Not handling E-RABToBeSetupListCtxtSURequest extensions");
}
if (erab.transport_layer_address.length() > 32) {
parent->logger.error("IPv6 addresses not currently supported");
return false;
}
uint32_t teid_out = 0;
srsran::uint8_to_uint32(erab.gtp_teid.data(), &teid_out);
srsran::const_span<uint8_t> nas_pdu;
if (erab.nas_pdu_present) {
nas_pdu = erab.nas_pdu;
}
asn1::s1ap::cause_c cause;
bearer_list.add_erab(
erab.erab_id, erab.erab_level_qos_params, erab.transport_layer_address, teid_out, nas_pdu, cause);
bearer_list.add_gtpu_bearer(erab.erab_id);
}
return true;
}
bool rrc::ue::release_erabs() bool rrc::ue::release_erabs()
{ {
bearer_list.release_erabs(); bearer_list.release_erabs();

@ -130,9 +130,11 @@ const gtpu_tunnel* gtpu_tunnel_manager::add_tunnel(uint16_t rnti, uint32_t lcid,
bool gtpu_tunnel_manager::update_rnti(uint16_t old_rnti, uint16_t new_rnti) bool gtpu_tunnel_manager::update_rnti(uint16_t old_rnti, uint16_t new_rnti)
{ {
srsran_assert(find_rnti_tunnels(new_rnti) == nullptr, "New rnti=0x%x already exists", new_rnti);
auto* old_rnti_ptr = find_rnti_tunnels(old_rnti); auto* old_rnti_ptr = find_rnti_tunnels(old_rnti);
if (old_rnti_ptr == nullptr or find_rnti_tunnels(new_rnti) != nullptr) {
logger.error("Modifying bearer rnti. Old rnti=0x%x, new rnti=0x%x", old_rnti, new_rnti);
return false;
}
logger.info("Modifying bearer rnti. Old rnti: 0x%x, new rnti: 0x%x", old_rnti, new_rnti); logger.info("Modifying bearer rnti. Old rnti: 0x%x, new rnti: 0x%x", old_rnti, new_rnti);
// create new RNTI and update TEIDs of old rnti to reflect new rnti // create new RNTI and update TEIDs of old rnti to reflect new rnti
@ -518,11 +520,6 @@ void gtpu::rem_bearer(uint16_t rnti, uint32_t lcid)
void gtpu::mod_bearer_rnti(uint16_t old_rnti, uint16_t new_rnti) void gtpu::mod_bearer_rnti(uint16_t old_rnti, uint16_t new_rnti)
{ {
auto* old_rnti_ptr = tunnels.find_rnti_tunnels(old_rnti);
if (old_rnti_ptr == nullptr or tunnels.find_rnti_tunnels(new_rnti) != nullptr) {
logger.error("Modifying bearer rnti. Old rnti=0x%x, new rnti=0x%x", old_rnti, new_rnti);
return;
}
tunnels.update_rnti(old_rnti, new_rnti); tunnels.update_rnti(old_rnti, new_rnti);
} }

@ -107,7 +107,7 @@ ngap::ngap(srsran::task_sched_handle task_sched_,
amf_task_queue = task_sched.make_task_queue(); amf_task_queue = task_sched.make_task_queue();
} }
int ngap::init(ngap_args_t args_, rrc_interface_ngap_nr* rrc_) int ngap::init(const ngap_args_t& args_, rrc_interface_ngap_nr* rrc_)
{ {
rrc = rrc_; rrc = rrc_;
args = args_; args = args_;

@ -420,24 +420,21 @@ void s1ap::write_pdu(uint16_t rnti, srsran::unique_byte_buffer_t pdu)
bool s1ap::user_release(uint16_t rnti, asn1::s1ap::cause_radio_network_e cause_radio) bool s1ap::user_release(uint16_t rnti, asn1::s1ap::cause_radio_network_e cause_radio)
{ {
logger.info("User inactivity - RNTI:0x%x", rnti);
ue* u = users.find_ue_rnti(rnti); ue* u = users.find_ue_rnti(rnti);
if (u == nullptr) { if (u == nullptr) {
logger.warning("Released UE with rnti=0x%x not found", rnti);
return false; return false;
} }
if (u->was_uectxtrelease_requested() or not u->ctxt.mme_ue_s1ap_id.has_value()) { cause_c cause;
logger.warning("UE context for RNTI:0x%x is in zombie state. Releasing...", rnti); cause.set_radio_network().value = cause_radio.value;
if (not u->send_uectxtreleaserequest(cause)) {
users.erase(u); users.erase(u);
rrc->release_ue(rnti); rrc->release_ue(rnti);
return false; return false;
} }
return true;
cause_c cause;
cause.set_radio_network().value = cause_radio.value;
return u->send_uectxtreleaserequest(cause);
} }
bool s1ap::user_exists(uint16_t rnti) bool s1ap::user_exists(uint16_t rnti)
@ -1385,7 +1382,8 @@ bool s1ap::ue::send_initialuemessage(asn1::s1ap::rrc_establishment_cause_e cause
bool s1ap::ue::send_ulnastransport(srsran::unique_byte_buffer_t pdu) bool s1ap::ue::send_ulnastransport(srsran::unique_byte_buffer_t pdu)
{ {
if (not s1ap_ptr->mme_connected) { if (not ctxt.mme_ue_s1ap_id.has_value()) {
logger.error("Trying to send UL NAS Transport message for rnti=0x%x without MME-S1AP-UE-ID", ctxt.rnti);
return false; return false;
} }
@ -1410,6 +1408,10 @@ bool s1ap::ue::send_ulnastransport(srsran::unique_byte_buffer_t pdu)
bool s1ap::ue::send_uectxtreleaserequest(const cause_c& cause) bool s1ap::ue::send_uectxtreleaserequest(const cause_c& cause)
{ {
if (was_uectxtrelease_requested()) {
logger.warning("UE context for RNTI:0x%x is in zombie state. Releasing...", ctxt.rnti);
return false;
}
if (not ctxt.mme_ue_s1ap_id.has_value()) { if (not ctxt.mme_ue_s1ap_id.has_value()) {
logger.error("Cannot send UE context release request without a MME-UE-S1AP-Id allocated."); logger.error("Cannot send UE context release request without a MME-UE-S1AP-Id allocated.");
return false; return false;

@ -330,13 +330,11 @@ bool cc_worker::measure_csi()
continue; continue;
} }
logger.info("NZP-CSI-RS (TRS): id=%d rsrp=%+.1f epre=%+.1f snr=%+.1f cfo=%+.1f delay=%.1f", if (logger.info.enabled()) {
resource_set_id, std::array<char, 512> str = {};
trs_measurements.rsrp_dB, srsran_csi_meas_info(&trs_measurements, str.data(), (uint32_t)str.size());
trs_measurements.epre_dB, logger.info("NZP-CSI-RS (TRS): id=%d %s", resource_set_id, str.data());
trs_measurements.snr_dB, }
trs_measurements.cfo_hz,
trs_measurements.delay_us);
// Compute channel metrics and push it // Compute channel metrics and push it
ch_metrics_t ch_metrics = {}; ch_metrics_t ch_metrics = {};

@ -20,4 +20,4 @@
set(SOURCES demux.cc dl_harq.cc mac.cc mux.cc proc_bsr.cc proc_phr.cc proc_ra.cc proc_sr.cc ul_harq.cc) set(SOURCES demux.cc dl_harq.cc mac.cc mux.cc proc_bsr.cc proc_phr.cc proc_ra.cc proc_sr.cc ul_harq.cc)
add_library(srsue_mac STATIC ${SOURCES}) add_library(srsue_mac STATIC ${SOURCES})
target_link_libraries(srsue_mac srsue_mac_common) target_link_libraries(srsue_mac srsue_mac_common ${ATOMIC_LIBS})

@ -347,7 +347,7 @@ void mac::bch_decoded_ok(uint32_t cc_idx, uint8_t* payload, uint32_t len)
buf->set_timestamp(); buf->set_timestamp();
auto p = stack_task_dispatch_queue.try_push(std::bind( auto p = stack_task_dispatch_queue.try_push(std::bind(
[this](srsran::unique_byte_buffer_t& buf) { rlc_h->write_pdu_bcch_bch(std::move(buf)); }, std::move(buf))); [this](srsran::unique_byte_buffer_t& buf) { rlc_h->write_pdu_bcch_bch(std::move(buf)); }, std::move(buf)));
if (not p.first) { if (p.is_error()) {
Warning("Failed to dispatch rlc::write_pdu_bcch_bch task to stack"); Warning("Failed to dispatch rlc::write_pdu_bcch_bch task to stack");
} }
} else { } else {
@ -408,7 +408,7 @@ void mac::tb_decoded(uint32_t cc_idx, mac_grant_dl_t grant, bool ack[SRSRAN_MAX_
auto ret = stack_task_dispatch_queue.try_push(std::bind( auto ret = stack_task_dispatch_queue.try_push(std::bind(
[this](srsran::unique_byte_buffer_t& pdu) { rlc_h->write_pdu_pcch(std::move(pdu)); }, std::move(pdu))); [this](srsran::unique_byte_buffer_t& pdu) { rlc_h->write_pdu_pcch(std::move(pdu)); }, std::move(pdu)));
if (not ret.first) { if (ret.is_error()) {
Warning("Failed to dispatch rlc::write_pdu_pcch task to stack"); Warning("Failed to dispatch rlc::write_pdu_pcch task to stack");
} }
} else { } else {
@ -486,7 +486,7 @@ void mac::process_pdus()
have_data = demux_unit.process_pdus(); have_data = demux_unit.process_pdus();
} }
}); });
if (not ret.first) { if (ret.is_error()) {
Warning("Failed to dispatch mac::%s task to stack thread", __func__); Warning("Failed to dispatch mac::%s task to stack thread", __func__);
} }
} }

@ -63,7 +63,7 @@ void proc_ra_nr::set_config(const srsran::rach_nr_cfg_t& rach_cfg_)
} }
rach_cfg = rach_cfg_; rach_cfg = rach_cfg_;
configured = true; configured = true;
logger.info("Set RACH common config (Config Index %d, preambleTransMax %d, Repsonse Window %d)", logger.info("Set RACH common config (Config Index %d, preambleTransMax %d, Response Window %d)",
rach_cfg.prach_ConfigurationIndex, rach_cfg.prach_ConfigurationIndex,
rach_cfg.preambleTransMax, rach_cfg.preambleTransMax,
rach_cfg.ra_responseWindow); rach_cfg.ra_responseWindow);
@ -380,4 +380,5 @@ void proc_ra_nr::reset()
rar_timeout_timer.stop(); rar_timeout_timer.stop();
contention_resolution_timer.stop(); contention_resolution_timer.stop();
} }
} // namespace srsue } // namespace srsue

@ -2076,18 +2076,26 @@ void rrc::handle_ue_capability_enquiry(const ue_cap_enquiry_s& enquiry)
irat_params_nr_r15.supported_band_list_en_dc_r15.push_back(supported_band_nr_r15); irat_params_nr_r15.supported_band_list_en_dc_r15.push_back(supported_band_nr_r15);
ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext.irat_params_nr_r15_present = true; ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext.irat_params_nr_r15_present = true;
ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext.irat_params_nr_r15 = irat_params_nr_r15; ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext.irat_params_nr_r15 = irat_params_nr_r15;
ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext.non_crit_ext_present = true;
// 15.10
ue_eutra_cap_v1510_ies_s* ue_cap_enquiry_v1510_ies = &ue_eutra_cap_v1450_ies->non_crit_ext.non_crit_ext;
ue_cap_enquiry_v1510_ies->pdcp_params_nr_r15_present = true;
ue_cap_enquiry_v1510_ies->pdcp_params_nr_r15.sn_size_lo_r15_present = true;
} }
// Pack caps and copy to cap info // Pack caps and copy to cap info
uint8_t buf[64] = {}; uint8_t buf[64] = {};
asn1::bit_ref bref(buf, sizeof(buf)); asn1::bit_ref bref(buf, sizeof(buf));
cap.pack(bref); if (cap.pack(bref) != asn1::SRSASN_SUCCESS) {
logger.error("Error packing EUTRA capabilities");
return;
}
bref.align_bytes_zero(); bref.align_bytes_zero();
auto cap_len = (uint32_t)bref.distance_bytes(buf); auto cap_len = (uint32_t)bref.distance_bytes(buf);
info->ue_cap_rat_container_list[rat_idx].ue_cap_rat_container.resize(cap_len); info->ue_cap_rat_container_list[rat_idx].ue_cap_rat_container.resize(cap_len);
memcpy(info->ue_cap_rat_container_list[rat_idx].ue_cap_rat_container.data(), buf, cap_len); memcpy(info->ue_cap_rat_container_list[rat_idx].ue_cap_rat_container.data(), buf, cap_len);
rat_idx++; rat_idx++;
} else if (enquiry.crit_exts.c1().ue_cap_enquiry_r8().ue_cap_request[i] == rat_type_e::eutra_nr && has_nr_dc()) { } else if (enquiry.crit_exts.c1().ue_cap_enquiry_r8().ue_cap_request[i] == rat_type_e::eutra_nr && has_nr_dc()) {
info->ue_cap_rat_container_list[rat_idx] = get_eutra_nr_capabilities(); info->ue_cap_rat_container_list[rat_idx] = get_eutra_nr_capabilities();
logger.info("Including EUTRA-NR capabilities in UE Capability Info (%d B)", logger.info("Including EUTRA-NR capabilities in UE Capability Info (%d B)",

@ -350,7 +350,7 @@ void ue_stack_lte::run_thread()
void ue_stack_lte::write_sdu(uint32_t lcid, srsran::unique_byte_buffer_t sdu) void ue_stack_lte::write_sdu(uint32_t lcid, srsran::unique_byte_buffer_t sdu)
{ {
auto task = [this, lcid](srsran::unique_byte_buffer_t& sdu) { pdcp.write_sdu(lcid, std::move(sdu)); }; auto task = [this, lcid](srsran::unique_byte_buffer_t& sdu) { pdcp.write_sdu(lcid, std::move(sdu)); };
bool ret = gw_queue_id.try_push(std::bind(task, std::move(sdu))).first; bool ret = gw_queue_id.try_push(std::bind(task, std::move(sdu))).has_value();
if (not ret) { if (not ret) {
pdcp_logger.info("GW SDU with lcid=%d was discarded.", lcid); pdcp_logger.info("GW SDU with lcid=%d was discarded.", lcid);
ul_dropped_sdus++; ul_dropped_sdus++;

@ -163,9 +163,9 @@ void ue_stack_nr::run_thread()
void ue_stack_nr::write_sdu(uint32_t lcid, srsran::unique_byte_buffer_t sdu) void ue_stack_nr::write_sdu(uint32_t lcid, srsran::unique_byte_buffer_t sdu)
{ {
if (pdcp != nullptr) { if (pdcp != nullptr) {
std::pair<bool, move_task_t> ret = gw_task_queue.try_push(std::bind( auto ret = gw_task_queue.try_push(std::bind(
[this, lcid](srsran::unique_byte_buffer_t& sdu) { pdcp->write_sdu(lcid, std::move(sdu)); }, std::move(sdu))); [this, lcid](srsran::unique_byte_buffer_t& sdu) { pdcp->write_sdu(lcid, std::move(sdu)); }, std::move(sdu)));
if (not ret.first) { if (ret.is_error()) {
pdcp_logger.warning("GW SDU with lcid=%d was discarded.", lcid); pdcp_logger.warning("GW SDU with lcid=%d was discarded.", lcid);
} }
} }

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