/* * Copyright (C) 2014 Jared Boone, ShareBrained Technology, Inc. * * This file is part of PortaPack. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2, or (at your option) * any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #include "ch.h" #include "test.h" #include "lpc43xx_cpp.hpp" #include "portapack_shared_memory.hpp" #include "portapack_dma.hpp" #include "gpdma.hpp" #include "baseband.hpp" #include "baseband_dma.hpp" #include "event_m4.hpp" #include "irq_ipc_m4.hpp" #include "rssi.hpp" #include "rssi_dma.hpp" #include "touch_dma.hpp" #include "modules.h" #include "dsp_decimate.hpp" #include "dsp_demodulate.hpp" #include "dsp_fft.hpp" #include "dsp_fir_taps.hpp" #include "dsp_iir.hpp" #include "dsp_iir_config.hpp" #include "dsp_squelch.hpp" #include "baseband_stats_collector.hpp" #include "rssi_stats_collector.hpp" #include "channel_decimator.hpp" #include "baseband_processor.hpp" #include "proc_am_audio.hpp" #include "proc_nfm_audio.hpp" #include "proc_wfm_audio.hpp" #include "proc_ais.hpp" #include "proc_wideband_spectrum.hpp" #include "proc_tpms.hpp" #include "proc_afskrx.hpp" #include "proc_sigfrx.hpp" #include "clock_recovery.hpp" #include "packet_builder.hpp" #include "message_queue.hpp" #include "utility.hpp" #include "debug.hpp" #include "audio.hpp" #include "audio_dma.hpp" #include "gcc.hpp" #include #include #include #include #include #include static baseband::Direction direction = baseband::Direction::Receive; class ThreadBase { public: constexpr ThreadBase( const char* const name ) : name { name } { } static msg_t fn(void* arg) { auto obj = static_cast(arg); chRegSetThreadName(obj->name); obj->run(); return 0; } virtual void run() = 0; private: const char* const name; }; class BasebandThread : public ThreadBase { public: BasebandThread( ) : ThreadBase { "baseband" } { } Thread* start(const tprio_t priority) { return chThdCreateStatic(wa, sizeof(wa), priority, ThreadBase::fn, this ); } Thread* thread_main { nullptr }; Thread* thread_rssi { nullptr }; BasebandProcessor* baseband_processor { nullptr }; BasebandConfiguration baseband_configuration; private: WORKING_AREA(wa, 2048); void run() override { BasebandStatsCollector stats { chSysGetIdleThread(), thread_main, thread_rssi, chThdSelf() }; while(true) { if (direction == baseband::Direction::Transmit) { const auto buffer_tmp = baseband::dma::wait_for_tx_buffer(); const buffer_c8_t buffer { buffer_tmp.p, buffer_tmp.count, baseband_configuration.sampling_rate }; if( baseband_processor ) { baseband_processor->execute(buffer); } stats.process(buffer, [](const BasebandStatistics statistics) { const BasebandStatisticsMessage message { statistics }; shared_memory.application_queue.push(message); } ); } else { const auto buffer_tmp = baseband::dma::wait_for_rx_buffer(); const buffer_c8_t buffer { buffer_tmp.p, buffer_tmp.count, baseband_configuration.sampling_rate }; if( baseband_processor ) { baseband_processor->execute(buffer); } stats.process(buffer, [](const BasebandStatistics statistics) { const BasebandStatisticsMessage message { statistics }; shared_memory.application_queue.push(message); } ); } } } }; class RSSIThread : public ThreadBase { public: RSSIThread( ) : ThreadBase { "rssi" } { } Thread* start(const tprio_t priority) { return chThdCreateStatic(wa, sizeof(wa), priority, ThreadBase::fn, this ); } uint32_t sampling_rate { 400000 }; private: WORKING_AREA(wa, 128); void run() override { RSSIStatisticsCollector stats; while(true) { // TODO: Place correct sampling rate into buffer returned here: const auto buffer_tmp = rf::rssi::dma::wait_for_buffer(); const rf::rssi::buffer_t buffer { buffer_tmp.p, buffer_tmp.count, sampling_rate }; stats.process( buffer, [](const RSSIStatistics statistics) { const RSSIStatisticsMessage message { statistics }; shared_memory.application_queue.push(message); } ); } } }; extern "C" { void __late_init(void) { /* * System initializations. * - HAL initialization, this also initializes the configured device drivers * and performs the board-specific initializations. * - Kernel initialization, the main() function becomes a thread and the * RTOS is active. */ halInit(); /* After this call, scheduler, systick, heap, etc. are available. */ /* By doing chSysInit() here, it runs before C++ constructors, which may * require the heap. */ chSysInit(); } } static BasebandThread baseband_thread; static RSSIThread rssi_thread; static void init() { i2s::i2s0::configure( audio::i2s0_config_tx, audio::i2s0_config_rx, audio::i2s0_config_dma ); audio::dma::init(); audio::dma::configure(); audio::dma::enable(); i2s::i2s0::tx_start(); i2s::i2s0::rx_start(); LPC_CREG->DMAMUX = portapack::gpdma_mux; gpdma::controller.enable(); nvicEnableVector(DMA_IRQn, CORTEX_PRIORITY_MASK(LPC_DMA_IRQ_PRIORITY)); baseband::dma::init(); rf::rssi::init(); touch::dma::init(); const auto thread_main = chThdSelf(); const auto thread_rssi = rssi_thread.start(NORMALPRIO + 10); baseband_thread.thread_main = thread_main; baseband_thread.thread_rssi = thread_rssi; baseband_thread.start(NORMALPRIO + 20); } static void shutdown() { // TODO: Is this complete? nvicDisableVector(DMA_IRQn); m0apptxevent_interrupt_disable(); chSysDisable(); systick_stop(); } static void halt() { port_disable(); while(true) { port_wait_for_interrupt(); } } class EventDispatcher { public: MessageHandlerMap& message_handlers() { return message_map; } void run() { while(is_running) { const auto events = wait(); dispatch(events); } } void request_stop() { is_running = false; } private: MessageHandlerMap message_map; bool is_running = true; eventmask_t wait() { return chEvtWaitAny(ALL_EVENTS); } void dispatch(const eventmask_t events) { if( events & EVT_MASK_BASEBAND ) { handle_baseband_queue(); } if( events & EVT_MASK_SPECTRUM ) { handle_spectrum(); } } void handle_baseband_queue() { std::array message_buffer; while(Message* const message = shared_memory.baseband_queue.pop(message_buffer)) { message_map.send(message); } } void handle_spectrum() { if( baseband_thread.baseband_processor ) { baseband_thread.baseband_processor->update_spectrum(); } } }; const auto baseband_buffer = new std::array(); char ram_loop[32]; typedef int (*fn_ptr)(void); fn_ptr loop_ptr; void ram_loop_fn(void) { while(1) {} } void wait_for_switch(void) { memcpy(&ram_loop[0], reinterpret_cast(&ram_loop_fn), 32); loop_ptr = reinterpret_cast(&ram_loop[0]); ReadyForSwitchMessage message; shared_memory.application_queue.push(message); (*loop_ptr)(); return; } int main(void) { init(); events_initialize(chThdSelf()); m0apptxevent_interrupt_enable(); EventDispatcher event_dispatcher; auto& message_handlers = event_dispatcher.message_handlers(); message_handlers.register_handler(Message::ID::BasebandConfiguration, [&message_handlers](const Message* const p) { auto message = reinterpret_cast(p); if( message->configuration.mode != baseband_thread.baseband_configuration.mode ) { if( baseband_thread.baseband_processor ) { i2s::i2s0::tx_mute(); baseband::dma::disable(); rf::rssi::stop(); } // TODO: Timing problem around disabling DMA and nulling and deleting old processor auto old_p = baseband_thread.baseband_processor; baseband_thread.baseband_processor = nullptr; delete old_p; switch(message->configuration.mode) { case RX_NBAM_AUDIO: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new NarrowbandAMAudio(); break; case RX_NBFM_AUDIO: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new NarrowbandFMAudio(); break; case RX_WBFM_AUDIO: baseband_thread.baseband_processor = new WidebandFMAudio(); break; case RX_AIS: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new AISProcessor(); break; case RX_WBSPECTRUM: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new WidebandSpectrum(); break; case RX_TPMS: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new TPMSProcessor(); break; case RX_AFSK: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new AFSKRXProcessor(); break; case RX_SIGFOX: direction = baseband::Direction::Receive; baseband_thread.baseband_processor = new SIGFRXProcessor(); break; case SWITCH: wait_for_switch(); default: break; } if( baseband_thread.baseband_processor ) { if( direction == baseband::Direction::Receive ) { rf::rssi::start(); } baseband::dma::enable(direction); rf::rssi::stop(); } } baseband::dma::configure( baseband_buffer->data(), direction ); baseband_thread.baseband_configuration = message->configuration; } ); message_handlers.register_handler(Message::ID::Shutdown, [&event_dispatcher](const Message* const) { event_dispatcher.request_stop(); } ); /* TODO: Ensure DMAs are configured to point at first LLI in chain. */ rf::rssi::dma::allocate(4, 400); touch::dma::allocate(); touch::dma::enable(); baseband::dma::configure( baseband_buffer->data(), direction ); //baseband::dma::allocate(4, 2048); event_dispatcher.run(); shutdown(); ShutdownMessage shutdown_message; shared_memory.application_queue.push(shutdown_message); halt(); return 0; }