/** * * \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_DUMMY_PHY_COMMON_H #define SRSRAN_DUMMY_PHY_COMMON_H #include #include #include #include #include class phy_common : public srsran::phy_common_interface { private: const uint32_t RINGBUFFER_TIMEOUT_MS = 10; std::atomic quit = {false}; srslog::basic_logger& logger; double srate_hz; uint64_t write_ts = 0; uint64_t read_ts = 0; std::vector zero_buffer; ///< Zero buffer for Tx std::vector sink_buffer; ///< Dummy buffer for Rx std::mutex ringbuffers_mutex; std::vector ringbuffers; srsran::tti_semaphore semaphore; void write_zero_padding(uint32_t nof_zeros) { // Skip if no pading is required if (nof_zeros == 0) { return; } logger.debug("Padding %d zeros", nof_zeros); // For each ringbuffer, padd zero int nof_bytes = (int)(nof_zeros * sizeof(cf_t)); for (srsran_ringbuffer_t& rb : ringbuffers) { // If quit is flagged, return instantly if (quit) { return; } // Actual write int err = SRSRAN_SUCCESS; do { err = srsran_ringbuffer_write_timed(&rb, zero_buffer.data(), nof_bytes, RINGBUFFER_TIMEOUT_MS); if (err < SRSRAN_SUCCESS and err != SRSRAN_ERROR_TIMEOUT) { logger.error("Error writing zeros in ringbuffer"); } } while (err < SRSRAN_SUCCESS and not quit); } // Increment write timestamp write_ts += nof_zeros; } void write_baseband(srsran::rf_buffer_t& buffer) { // skip if baseband is not available if (buffer.get_nof_samples() == 0) { return; } // For each ringbuffer, write int nof_bytes = (int)(buffer.get_nof_samples() * sizeof(cf_t)); uint32_t channel_idx = 0; for (srsran_ringbuffer_t& rb : ringbuffers) { // If quit is flagged, return instantly if (quit) { return; } // Extract channel buffer pointer cf_t* channel_buffer = buffer.get(channel_idx); // If the pointer is not set, use the zero buffer if (channel_buffer == nullptr) { channel_buffer = zero_buffer.data(); } // Actual write int err = SRSRAN_SUCCESS; do { err = srsran_ringbuffer_write_timed(&rb, channel_buffer, nof_bytes, RINGBUFFER_TIMEOUT_MS); if (err < SRSRAN_SUCCESS and err != SRSRAN_ERROR_TIMEOUT) { logger.error("Error writing zeros in ringbuffer"); } } while (err < SRSRAN_SUCCESS and not quit); // Increment channel counter channel_idx++; } // Increment write timestamp write_ts += buffer.get_nof_samples(); } void read_baseband(std::vector& buffers, uint32_t nof_samples) { // For each ringbuffer, read int nof_bytes = (int)(nof_samples * sizeof(cf_t)); uint32_t channel_idx = 0; for (srsran_ringbuffer_t& rb : ringbuffers) { // If quit is flagged, return instantly if (quit) { return; } // Extract channel buffer pointer cf_t* channel_buffer = buffers[channel_idx]; // If the pointer is not set, use the zero buffer if (channel_buffer == nullptr) { channel_buffer = sink_buffer.data(); } // Actual write int err = SRSRAN_SUCCESS; do { err = srsran_ringbuffer_read_timed(&rb, channel_buffer, nof_bytes, RINGBUFFER_TIMEOUT_MS); if (err < SRSRAN_SUCCESS and err != SRSRAN_ERROR_TIMEOUT) { logger.error("Error reading zeros in ringbuffer"); } } while (err < SRSRAN_SUCCESS and not quit); // Increment channel counter channel_idx++; } } public: struct args_t { double srate_hz = 11.52e6; uint32_t buffer_sz_ms = 10; ///< Buffer size in milliseconds uint32_t nof_channels = 1; args_t(double srate_hz_, uint32_t buffer_sz_ms_, uint32_t nof_channels_) : srate_hz(srate_hz_), buffer_sz_ms(buffer_sz_ms_), nof_channels(nof_channels_) {} }; phy_common(const args_t& args, srslog::basic_logger& logger_) : srate_hz(args.srate_hz), logger(logger_) { uint32_t buffer_sz = std::ceil((double)args.buffer_sz_ms * srate_hz * 1e-3); uint32_t buffer_sz_bytes = sizeof(cf_t) * buffer_sz; // Allocate data buffer zero_buffer.resize(buffer_sz); sink_buffer.resize(buffer_sz); // Allocate ring buffers ringbuffers.resize(args.nof_channels); // Initialise buffers for (srsran_ringbuffer_t& rb : ringbuffers) { if (srsran_ringbuffer_init(&rb, buffer_sz_bytes) < SRSRAN_SUCCESS) { logger.error("Error ringbuffer init"); } } } ~phy_common() { for (srsran_ringbuffer_t& rb : ringbuffers) { srsran_ringbuffer_free(&rb); } } void push_semaphore(void* worker_ptr) { semaphore.push(worker_ptr); } void worker_end(void* h, bool tx_enable, srsran::rf_buffer_t& buffer, srsran::rf_timestamp_t& tx_time, bool is_nr) override { // Synchronize worker semaphore.wait(h); // Protect internal buffers and states std::unique_lock lock(ringbuffers_mutex); uint64_t tx_ts = srsran_timestamp_uint64(&tx_time.get(0), srate_hz); // Check transmit timestamp is not in the past if (tx_ts < write_ts) { logger.error("Tx time (%f) is %d samples in the past", srsran_timestamp_real(tx_time.get_ptr(0)), (uint32_t)(write_ts - tx_ts)); semaphore.release(); return; } // Write zero padding if necessary write_zero_padding((uint32_t)(tx_ts - write_ts)); // Write baseband if (tx_enable) { write_baseband(buffer); } else { write_zero_padding(buffer.get_nof_samples()); } // Release semaphore, so next worker can be used semaphore.release(); } void read(std::vector& buffers, uint32_t nof_samples, srsran::rf_timestamp_t& timestamp) { // Protect internal buffers and states std::unique_lock lock(ringbuffers_mutex); // Detect if zero padding is necessary if (read_ts + nof_samples > write_ts) { uint32_t nof_zero_pading = (uint32_t)((read_ts + nof_samples) - write_ts); write_zero_padding(nof_zero_pading); } // Actual baseband read read_baseband(buffers, nof_samples); // Write timestamp srsran_timestamp_init_uint64(timestamp.get_ptr(0), read_ts, srate_hz); // Increment Rx timestamp read_ts += nof_samples; } void stop() { quit = true; } }; #endif // SRSRAN_DUMMY_PHY_COMMON_H