// // Copyright 2011-2012 Ettus Research LLC // // 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 3 of the License, 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. If not, see . // #include "e100_ctrl.hpp" #include "e100_regs.hpp" #include #include #include #include //ioctl #include //open, close #include //ioctl structures and constants #include //poll #include //sleep #include #include #include #include #include using namespace uhd; using namespace uhd::transport; /*********************************************************************** * Sysfs GPIO wrapper class **********************************************************************/ class gpio{ public: gpio(const int num, const std::string &dir) : _num(num){ this->set_xport("export"); this->set_dir(dir); _value_file.open(str(boost::format("/sys/class/gpio/gpio%d/value") % num).c_str(), std::ios_base::in | std::ios_base::out); } ~gpio(void){ _value_file.close(); this->set_dir("in"); this->set_xport("unexport"); } void operator()(const int val){ _value_file << val << std::endl << std::flush; } int operator()(void){ std::string val; std::getline(_value_file, val); _value_file.seekg(0); return int(val.at(0) - '0') & 0x1; } private: void set_xport(const std::string &xport){ std::ofstream export_file(("/sys/class/gpio/" + xport).c_str()); export_file << _num << std::endl << std::flush; export_file.close(); } void set_dir(const std::string &dir){ std::ofstream dir_file(str(boost::format("/sys/class/gpio/gpio%d/direction") % _num).c_str()); dir_file << dir << std::endl << std::flush; dir_file.close(); } const int _num; std::fstream _value_file; }; /*********************************************************************** * Protection for dual GPIO access - sometimes MISO, sometimes have resp **********************************************************************/ static boost::mutex gpio_has_resp_mutex; static boost::condition_variable gpio_has_resp_cond; static bool gpio_has_resp_claimed = false; static gpio gpio_has_resp(147, "in"); struct gpio_has_resp_claimer { gpio_has_resp_claimer(void) { boost::mutex::scoped_lock lock(gpio_has_resp_mutex); gpio_has_resp_claimed = true; } ~gpio_has_resp_claimer(void) { boost::mutex::scoped_lock lock(gpio_has_resp_mutex); gpio_has_resp_claimed = false; lock.unlock(); gpio_has_resp_cond.notify_one(); } }; static inline bool gpio_has_resp_value(void) { boost::mutex::scoped_lock lock(gpio_has_resp_mutex); while (gpio_has_resp_claimed) { gpio_has_resp_cond.wait(lock); } return bool(gpio_has_resp()); } static bool inline gpio_has_resp_wait(const double timeout) { if (gpio_has_resp_value()) return true; const boost::system_time exit_time = boost::get_system_time() + boost::posix_time::milliseconds(long(timeout*1e6)); while (boost::get_system_time() < exit_time) { boost::this_thread::sleep(boost::posix_time::milliseconds(1)); if (gpio_has_resp_value()) return true; } return false; } /*********************************************************************** * Aux spi implementation **********************************************************************/ class aux_spi_iface_impl : public spi_iface{ public: aux_spi_iface_impl(void): spi_sclk_gpio(65, "out"), spi_sen_gpio(186, "out"), spi_mosi_gpio(145, "out"), //spi_miso_gpio(147, "in"){} spi_miso_gpio(gpio_has_resp){} boost::uint32_t transact_spi( int, const spi_config_t &, //not used params boost::uint32_t bits, size_t num_bits, bool readback ){ gpio_has_resp_claimer claimer(); boost::uint32_t rb_bits = 0; this->spi_sen_gpio(0); for (size_t i = 0; i < num_bits; i++){ this->spi_sclk_gpio(0); this->spi_mosi_gpio((bits >> (num_bits-i-1)) & 0x1); boost::this_thread::sleep(boost::posix_time::microseconds(10)); if (readback) rb_bits = (rb_bits << 1) | this->spi_miso_gpio(); this->spi_sclk_gpio(1); boost::this_thread::sleep(boost::posix_time::microseconds(10)); } this->spi_sen_gpio(1); boost::this_thread::sleep(boost::posix_time::microseconds(100)); return rb_bits; } private: gpio spi_sclk_gpio, spi_sen_gpio, spi_mosi_gpio, &spi_miso_gpio; }; uhd::spi_iface::sptr e100_ctrl::make_aux_spi_iface(void){ return uhd::spi_iface::sptr(new aux_spi_iface_impl()); } /*********************************************************************** * I2C device node implementation wrapper **********************************************************************/ #include #include class i2c_dev_iface : public i2c_iface{ public: i2c_dev_iface(const std::string &node){ if ((_node_fd = ::open(node.c_str(), O_RDWR)) < 0){ throw uhd::io_error("Failed to open " + node); } } ~i2c_dev_iface(void){ ::close(_node_fd); } void write_i2c(boost::uint8_t addr, const byte_vector_t &bytes){ byte_vector_t rw_bytes(bytes); //setup the message i2c_msg msg; msg.addr = addr; msg.flags = 0; msg.len = bytes.size(); msg.buf = &rw_bytes.front(); //setup the data i2c_rdwr_ioctl_data data; data.msgs = &msg; data.nmsgs = 1; //call the ioctl UHD_ASSERT_THROW(::ioctl(_node_fd, I2C_RDWR, &data) >= 0); } byte_vector_t read_i2c(boost::uint8_t addr, size_t num_bytes){ byte_vector_t bytes(num_bytes); //setup the message i2c_msg msg; msg.addr = addr; msg.flags = I2C_M_RD; msg.len = bytes.size(); msg.buf = &bytes.front(); //setup the data i2c_rdwr_ioctl_data data; data.msgs = &msg; data.nmsgs = 1; //call the ioctl UHD_ASSERT_THROW(::ioctl(_node_fd, I2C_RDWR, &data) >= 0); return bytes; } private: int _node_fd; }; uhd::i2c_iface::sptr e100_ctrl::make_dev_i2c_iface(const std::string &node){ return uhd::i2c_iface::sptr(new i2c_dev_iface(node)); } /*********************************************************************** * UART control implementation **********************************************************************/ #include #include class uart_dev_iface : public uart_iface{ public: uart_dev_iface(const std::string &node){ if ((_node_fd = ::open(node.c_str(), O_RDWR | O_NONBLOCK)) < 0){ throw uhd::io_error("Failed to open " + node); } //init the tty settings w/ termios termios tio; std::memset(&tio,0,sizeof(tio)); tio.c_iflag = IGNCR; //Ignore CR tio.c_oflag = OPOST | ONLCR; //Map NL to CR-NL on output tio.c_cflag = CS8 | CREAD | CLOCAL; // 8n1 tio.c_lflag = 0; cfsetospeed(&tio, B115200); // 115200 baud cfsetispeed(&tio, B115200); // 115200 baud tcsetattr(_node_fd, TCSANOW, &tio); } void write_uart(const std::string &buf){ const ssize_t ret = ::write(_node_fd, buf.c_str(), buf.size()); if (size_t(ret) != buf.size()) UHD_LOG << ret; } std::string read_uart(double timeout){ const boost::system_time exit_time = boost::get_system_time() + boost::posix_time::milliseconds(long(timeout*1000)); std::string line; while(true){ char ch; const ssize_t ret = ::read(_node_fd, &ch, 1); //got a character -> process it if (ret == 1){ const bool flush = ch == '\n' or ch == '\r'; if (flush and line.empty()) continue; //avoid flushing on empty lines line += std::string(1, ch); if (flush) break; } //didnt get a character, check the timeout else if (boost::get_system_time() > exit_time){ break; } //otherwise sleep for a bit else{ boost::this_thread::sleep(boost::posix_time::milliseconds(10)); } } return line; } private: int _node_fd; }; uhd::uart_iface::sptr e100_ctrl::make_gps_uart_iface(const std::string &node){ return uhd::uart_iface::sptr(new uart_dev_iface(node)); } /*********************************************************************** * Simple managed buffers **********************************************************************/ struct e100_simpl_mrb : managed_recv_buffer { usrp_e_ctl32 data; e100_ctrl *ctrl; void release(void) { //NOP } sptr get_new(void) { const size_t max_words32 = 8; //.LAST_ADDR(10'h00f)) resp_fifo_to_gpmc //load the data struct data.offset = 0; data.count = max_words32; //call the ioctl ctrl->ioctl(USRP_E_READ_CTL32, &data); if (data.buf[0] == 0 or ~data.buf[0] == 0) return sptr(); //bad VRT hdr, treat like timeout return make(this, data.buf, sizeof(data.buf)); } }; struct e100_simpl_msb : managed_send_buffer { usrp_e_ctl32 data; e100_ctrl *ctrl; void release(void) { //load the data struct data.offset = 0; data.count = size()/4+1/*1 for flush pad*/; //call the ioctl ctrl->ioctl(USRP_E_WRITE_CTL32, &data); } sptr get_new(void) { return make(this, data.buf, sizeof(data.buf)); } }; /*********************************************************************** * USRP-E100 control implementation **********************************************************************/ class e100_ctrl_impl : public e100_ctrl{ public: int get_file_descriptor(void){ return _node_fd; } /******************************************************************* * Structors ******************************************************************/ e100_ctrl_impl(const std::string &node){ UHD_MSG(status) << "Opening device node " << node << "..." << std::endl; //open the device node and check file descriptor if ((_node_fd = ::open(node.c_str(), O_RDWR)) < 0){ throw uhd::io_error("Failed to open " + node); } //check the module compatibility number int module_compat_num = ::ioctl(_node_fd, USRP_E_GET_COMPAT_NUMBER, NULL); if (module_compat_num != USRP_E_COMPAT_NUMBER){ throw uhd::runtime_error(str(boost::format( "Expected module compatibility number 0x%x, but got 0x%x:\n" "The module build is not compatible with the host code build." ) % USRP_E_COMPAT_NUMBER % module_compat_num)); } //hit the magic arst condition //async_reset <= ~EM_NCS6 && ~EM_NWE && (EM_A[9:2] == 8'hff) && EM_D[0]; usrp_e_ctl16 datax; datax.offset = 0x3fc; datax.count = 2; datax.buf[0] = 1; datax.buf[1] = 0; this->ioctl(USRP_E_WRITE_CTL16, &datax); } ~e100_ctrl_impl(void){ ::close(_node_fd); } /******************************************************************* * IOCTL: provides the communication base for all other calls ******************************************************************/ void ioctl(int request, void *mem){ boost::mutex::scoped_lock lock(_ioctl_mutex); if (::ioctl(_node_fd, request, mem) < 0){ throw uhd::os_error(str( boost::format("ioctl failed with request %d") % request )); } } /******************************************************************* * The managed buffer interface ******************************************************************/ managed_recv_buffer::sptr get_recv_buff(double timeout){ if (not gpio_has_resp_wait(timeout)) { return managed_recv_buffer::sptr(); } _mrb.ctrl = this; return _mrb.get_new(); } managed_send_buffer::sptr get_send_buff(double){ _msb.ctrl = this; return _msb.get_new(); } size_t get_num_recv_frames(void) const{ return 1; } size_t get_recv_frame_size(void) const{ return sizeof(_mrb.data.buf); } size_t get_num_send_frames(void) const{ return 1; } size_t get_send_frame_size(void) const{ return sizeof(_msb.data.buf); } private: int _node_fd; boost::mutex _ioctl_mutex; e100_simpl_mrb _mrb; e100_simpl_msb _msb; }; /*********************************************************************** * Public Make Function **********************************************************************/ e100_ctrl::sptr e100_ctrl::make(const std::string &node){ return sptr(new e100_ctrl_impl(node)); }