// // Copyright 2013-2015 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 "x300_impl.hpp" #include "x300_regs.hpp" #include "x300_lvbitx.hpp" #include "x310_lvbitx.hpp" #include #include #include "apply_corrections.hpp" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define NIUSRPRIO_DEFAULT_RPC_PORT "5444" #define X300_REV(x) ((x) - "A" + 1) using namespace uhd; using namespace uhd::usrp; using namespace uhd::transport; using namespace uhd::niusrprio; namespace asio = boost::asio; /*********************************************************************** * Discovery over the udp and pcie transport **********************************************************************/ static std::string get_fpga_option(wb_iface::sptr zpu_ctrl) { //1G = {0:1G, 1:1G} w/ DRAM, HG = {0:1G, 1:10G} w/ DRAM, XG = {0:10G, 1:10G} w/ DRAM //HGS = {0:1G, 1:10G} w/ SRAM, XGS = {0:10G, 1:10G} w/ SRAM //In the default configuration, UHD does not support the HG and XG images so //they are never autodetected. bool eth0XG = (zpu_ctrl->peek32(SR_ADDR(SET0_BASE, ZPU_RB_ETH_TYPE0)) == 0x1); bool eth1XG = (zpu_ctrl->peek32(SR_ADDR(SET0_BASE, ZPU_RB_ETH_TYPE1)) == 0x1); return (eth0XG && eth1XG) ? "XGS" : (eth1XG ? "HGS" : "1G"); } //@TODO: Refactor the find functions to collapse common code for ethernet and PCIe static device_addrs_t x300_find_with_addr(const device_addr_t &hint) { udp_simple::sptr comm = udp_simple::make_broadcast( hint["addr"], BOOST_STRINGIZE(X300_FW_COMMS_UDP_PORT)); //load request struct x300_fw_comms_t request = x300_fw_comms_t(); request.flags = uhd::htonx(X300_FW_COMMS_FLAGS_ACK); request.sequence = uhd::htonx(std::rand()); //send request comm->send(asio::buffer(&request, sizeof(request))); //loop for replies until timeout device_addrs_t addrs; while (true) { char buff[X300_FW_COMMS_MTU] = {}; const size_t nbytes = comm->recv(asio::buffer(buff), 0.050); if (nbytes == 0) break; const x300_fw_comms_t *reply = (const x300_fw_comms_t *)buff; if (request.flags != reply->flags) break; if (request.sequence != reply->sequence) break; device_addr_t new_addr; new_addr["type"] = "x300"; new_addr["addr"] = comm->get_recv_addr(); //Attempt to read the name from the EEPROM and perform filtering. //This operation can throw due to compatibility mismatch. try { wb_iface::sptr zpu_ctrl = x300_make_ctrl_iface_enet(udp_simple::make_connected(new_addr["addr"], BOOST_STRINGIZE(X300_FW_COMMS_UDP_PORT))); if (x300_impl::is_claimed(zpu_ctrl)) continue; //claimed by another process new_addr["fpga"] = get_fpga_option(zpu_ctrl); i2c_core_100_wb32::sptr zpu_i2c = i2c_core_100_wb32::make(zpu_ctrl, I2C1_BASE); i2c_iface::sptr eeprom16 = zpu_i2c->eeprom16(); const mboard_eeprom_t mb_eeprom(*eeprom16, "X300"); new_addr["name"] = mb_eeprom["name"]; new_addr["serial"] = mb_eeprom["serial"]; switch (x300_impl::get_mb_type_from_eeprom(mb_eeprom)) { case x300_impl::USRP_X300_MB: new_addr["product"] = "X300"; break; case x300_impl::USRP_X310_MB: new_addr["product"] = "X310"; break; default: break; } } catch(const std::exception &) { //set these values as empty string so the device may still be found //and the filter's below can still operate on the discovered device new_addr["name"] = ""; new_addr["serial"] = ""; } //filter the discovered device below by matching optional keys if ( (not hint.has_key("name") or hint["name"] == new_addr["name"]) and (not hint.has_key("serial") or hint["serial"] == new_addr["serial"]) and (not hint.has_key("product") or hint["product"] == new_addr["product"]) ){ addrs.push_back(new_addr); } } return addrs; } //We need a zpu xport registry to ensure synchronization between the static finder method //and the instances of the x300_impl class. typedef uhd::dict< std::string, boost::weak_ptr > pcie_zpu_iface_registry_t; UHD_SINGLETON_FCN(pcie_zpu_iface_registry_t, get_pcie_zpu_iface_registry) static boost::mutex pcie_zpu_iface_registry_mutex; static device_addrs_t x300_find_pcie(const device_addr_t &hint, bool explicit_query) { std::string rpc_port_name(NIUSRPRIO_DEFAULT_RPC_PORT); if (hint.has_key("niusrpriorpc_port")) { rpc_port_name = hint["niusrpriorpc_port"]; } device_addrs_t addrs; niusrprio_session::device_info_vtr dev_info_vtr; nirio_status status = niusrprio_session::enumerate(rpc_port_name, dev_info_vtr); if (explicit_query) nirio_status_to_exception(status, "x300_find_pcie: Error enumerating NI-RIO devices."); BOOST_FOREACH(niusrprio_session::device_info &dev_info, dev_info_vtr) { device_addr_t new_addr; new_addr["type"] = "x300"; new_addr["resource"] = dev_info.resource_name; std::string resource_d(dev_info.resource_name); boost::to_upper(resource_d); switch (x300_impl::get_mb_type_from_pcie(resource_d, rpc_port_name)) { case x300_impl::USRP_X300_MB: new_addr["product"] = "X300"; break; case x300_impl::USRP_X310_MB: new_addr["product"] = "X310"; break; default: continue; } niriok_proxy::sptr kernel_proxy = niriok_proxy::make_and_open(dev_info.interface_path); //Attempt to read the name from the EEPROM and perform filtering. //This operation can throw due to compatibility mismatch. try { //This block could throw an exception if the user is switching to using UHD //after LabVIEW FPGA. In that case, skip reading the name and serial and pick //a default FPGA flavor. During make, a new image will be loaded and everything //will be OK wb_iface::sptr zpu_ctrl; //Hold on to the registry mutex as long as zpu_ctrl is alive //to prevent any use by different threads while enumerating boost::mutex::scoped_lock(pcie_zpu_iface_registry_mutex); if (get_pcie_zpu_iface_registry().has_key(resource_d)) { zpu_ctrl = get_pcie_zpu_iface_registry()[resource_d].lock(); } else { zpu_ctrl = x300_make_ctrl_iface_pcie(kernel_proxy); //We don't put this zpu_ctrl in the registry because we need //a persistent niriok_proxy associated with the object } if (x300_impl::is_claimed(zpu_ctrl)) continue; //claimed by another process //Attempt to autodetect the FPGA type if (not hint.has_key("fpga")) { new_addr["fpga"] = get_fpga_option(zpu_ctrl); } i2c_core_100_wb32::sptr zpu_i2c = i2c_core_100_wb32::make(zpu_ctrl, I2C1_BASE); i2c_iface::sptr eeprom16 = zpu_i2c->eeprom16(); const mboard_eeprom_t mb_eeprom(*eeprom16, "X300"); new_addr["name"] = mb_eeprom["name"]; new_addr["serial"] = mb_eeprom["serial"]; } catch(const std::exception &) { //set these values as empty string so the device may still be found //and the filter's below can still operate on the discovered device if (not hint.has_key("fpga")) { new_addr["fpga"] = "HGS"; } new_addr["name"] = ""; new_addr["serial"] = ""; } //filter the discovered device below by matching optional keys std::string resource_i = hint.has_key("resource") ? hint["resource"] : ""; boost::to_upper(resource_i); if ( (not hint.has_key("resource") or resource_i == resource_d) and (not hint.has_key("name") or hint["name"] == new_addr["name"]) and (not hint.has_key("serial") or hint["serial"] == new_addr["serial"]) and (not hint.has_key("product") or hint["product"] == new_addr["product"]) ){ addrs.push_back(new_addr); } } return addrs; } static device_addrs_t x300_find(const device_addr_t &hint_) { //handle the multi-device discovery device_addrs_t hints = separate_device_addr(hint_); if (hints.size() > 1) { device_addrs_t found_devices; std::string error_msg; BOOST_FOREACH(const device_addr_t &hint_i, hints) { device_addrs_t found_devices_i = x300_find(hint_i); if (found_devices_i.size() != 1) error_msg += str(boost::format( "Could not resolve device hint \"%s\" to a single device." ) % hint_i.to_string()); else found_devices.push_back(found_devices_i[0]); } if (found_devices.empty()) return device_addrs_t(); if (not error_msg.empty()) throw uhd::value_error(error_msg); return device_addrs_t(1, combine_device_addrs(found_devices)); } //initialize the hint for a single device case UHD_ASSERT_THROW(hints.size() <= 1); hints.resize(1); //in case it was empty device_addr_t hint = hints[0]; device_addrs_t addrs; if (hint.has_key("type") and hint["type"] != "x300") return addrs; //use the address given if (hint.has_key("addr")) { device_addrs_t reply_addrs; try { reply_addrs = x300_find_with_addr(hint); } catch(const std::exception &ex) { UHD_MSG(error) << "X300 Network discovery error " << ex.what() << std::endl; } catch(...) { UHD_MSG(error) << "X300 Network discovery unknown error " << std::endl; } BOOST_FOREACH(const device_addr_t &reply_addr, reply_addrs) { device_addrs_t new_addrs = x300_find_with_addr(reply_addr); addrs.insert(addrs.begin(), new_addrs.begin(), new_addrs.end()); } return addrs; } if (!hint.has_key("resource")) { //otherwise, no address was specified, send a broadcast on each interface BOOST_FOREACH(const if_addrs_t &if_addrs, get_if_addrs()) { //avoid the loopback device if (if_addrs.inet == asio::ip::address_v4::loopback().to_string()) continue; //create a new hint with this broadcast address device_addr_t new_hint = hint; new_hint["addr"] = if_addrs.bcast; //call discover with the new hint and append results device_addrs_t new_addrs = x300_find(new_hint); addrs.insert(addrs.begin(), new_addrs.begin(), new_addrs.end()); } } device_addrs_t pcie_addrs = x300_find_pcie(hint, hint.has_key("resource")); if (not pcie_addrs.empty()) addrs.insert(addrs.end(), pcie_addrs.begin(), pcie_addrs.end()); return addrs; } /*********************************************************************** * Make **********************************************************************/ static device::sptr x300_make(const device_addr_t &device_addr) { return device::sptr(new x300_impl(device_addr)); } UHD_STATIC_BLOCK(register_x300_device) { device::register_device(&x300_find, &x300_make, device::USRP); } static void x300_load_fw(wb_iface::sptr fw_reg_ctrl, const std::string &file_name) { UHD_MSG(status) << "Loading firmware " << file_name << std::flush; //load file into memory std::ifstream fw_file(file_name.c_str()); boost::uint32_t fw_file_buff[X300_FW_NUM_BYTES/sizeof(boost::uint32_t)]; fw_file.read((char *)fw_file_buff, sizeof(fw_file_buff)); fw_file.close(); //Poke the fw words into the WB boot loader fw_reg_ctrl->poke32(SR_ADDR(BOOT_LDR_BASE, BL_ADDRESS), 0); for (size_t i = 0; i < X300_FW_NUM_BYTES; i+=sizeof(boost::uint32_t)) { //@TODO: FIXME: Since x300_ctrl_iface acks each write and traps exceptions, the first try for the last word // written will print an error because it triggers a FW reload and fails to reply. fw_reg_ctrl->poke32(SR_ADDR(BOOT_LDR_BASE, BL_DATA), uhd::byteswap(fw_file_buff[i/sizeof(boost::uint32_t)])); if ((i & 0x1fff) == 0) UHD_MSG(status) << "." << std::flush; } UHD_MSG(status) << " done!" << std::endl; } x300_impl::x300_impl(const uhd::device_addr_t &dev_addr) { UHD_MSG(status) << "X300 initialization sequence..." << std::endl; _type = device::USRP; _ignore_cal_file = dev_addr.has_key("ignore-cal-file"); _async_md.reset(new async_md_type(1000/*messages deep*/)); _tree = uhd::property_tree::make(); _tree->create("/name").set("X-Series Device"); _sid_framer = 0; const device_addrs_t device_args = separate_device_addr(dev_addr); _mb.resize(device_args.size()); for (size_t i = 0; i < device_args.size(); i++) { this->setup_mb(i, device_args[i]); } } void x300_impl::setup_mb(const size_t mb_i, const uhd::device_addr_t &dev_addr) { const fs_path mb_path = "/mboards/"+boost::lexical_cast(mb_i); mboard_members_t &mb = _mb[mb_i]; mb.initialization_done = false; mb.addr = dev_addr.has_key("resource") ? dev_addr["resource"] : dev_addr["addr"]; mb.xport_path = dev_addr.has_key("resource") ? "nirio" : "eth"; mb.if_pkt_is_big_endian = mb.xport_path != "nirio"; if (mb.xport_path == "nirio") { nirio_status status = 0; std::string rpc_port_name(NIUSRPRIO_DEFAULT_RPC_PORT); if (dev_addr.has_key("niusrpriorpc_port")) { rpc_port_name = dev_addr["niusrpriorpc_port"]; } UHD_MSG(status) << boost::format("Connecting to niusrpriorpc at localhost:%s...\n") % rpc_port_name; //Instantiate the correct lvbitx object nifpga_lvbitx::sptr lvbitx; switch (get_mb_type_from_pcie(dev_addr["resource"], rpc_port_name)) { case USRP_X300_MB: lvbitx.reset(new x300_lvbitx(dev_addr["fpga"])); break; case USRP_X310_MB: lvbitx.reset(new x310_lvbitx(dev_addr["fpga"])); break; default: nirio_status_to_exception(status, "Motherboard detection error. Please ensure that you \ have a valid USRP X3x0, NI USRP-294xR or NI USRP-295xR device and that all the device \ driver have been loaded."); } //Load the lvbitx onto the device UHD_MSG(status) << boost::format("Using LVBITX bitfile %s...\n") % lvbitx->get_bitfile_path(); mb.rio_fpga_interface.reset(new niusrprio_session(dev_addr["resource"], rpc_port_name)); nirio_status_chain(mb.rio_fpga_interface->open(lvbitx, dev_addr.has_key("download-fpga")), status); nirio_status_to_exception(status, "x300_impl: Could not initialize RIO session."); //Tell the quirks object which FIFOs carry TX stream data const boost::uint32_t tx_data_fifos[2] = {X300_RADIO_DEST_PREFIX_TX, X300_RADIO_DEST_PREFIX_TX + 3}; mb.rio_fpga_interface->get_kernel_proxy()->get_rio_quirks().register_tx_streams(tx_data_fifos); _tree->create(mb_path / "link_max_rate").set(X300_MAX_RATE_PCIE); } BOOST_FOREACH(const std::string &key, dev_addr.keys()) { if (key.find("recv") != std::string::npos) mb.recv_args[key] = dev_addr[key]; if (key.find("send") != std::string::npos) mb.send_args[key] = dev_addr[key]; } if (mb.xport_path == "eth" ) { /* This is an ETH connection. Figure out what the maximum supported frame * size is for the transport in the up and down directions. The frame size * depends on the host PIC's NIC's MTU settings. To determine the frame size, * we test for support up to an expected "ceiling". If the user * specified a frame size, we use that frame size as the ceiling. If no * frame size was specified, we use the maximum UHD frame size. * * To optimize performance, the frame size should be greater than or equal * to the frame size that UHD uses so that frames don't get split across * multiple transmission units - this is why the limits passed into the * 'determine_max_frame_size' function are actually frame sizes. */ frame_size_t req_max_frame_size; req_max_frame_size.recv_frame_size = (mb.recv_args.has_key("recv_frame_size")) \ ? boost::lexical_cast(mb.recv_args["recv_frame_size"]) \ : X300_10GE_DATA_FRAME_MAX_SIZE; req_max_frame_size.send_frame_size = (mb.send_args.has_key("send_frame_size")) \ ? boost::lexical_cast(mb.send_args["send_frame_size"]) \ : X300_10GE_DATA_FRAME_MAX_SIZE; #if defined UHD_PLATFORM_LINUX const std::string mtu_tool("ip link"); #elif defined UHD_PLATFORM_WIN32 const std::string mtu_tool("netsh"); #else const std::string mtu_tool("ifconfig"); #endif // Detect the frame size on the path to the USRP try { _max_frame_sizes = determine_max_frame_size(mb.addr, req_max_frame_size); } catch(std::exception &e) { UHD_MSG(error) << e.what() << std::endl; } if ((mb.recv_args.has_key("recv_frame_size")) && (req_max_frame_size.recv_frame_size < _max_frame_sizes.recv_frame_size)) { UHD_MSG(warning) << boost::format("You requested a receive frame size of (%lu) but your NIC's max frame size is (%lu).") % req_max_frame_size.recv_frame_size << _max_frame_sizes.recv_frame_size << std::endl << boost::format("Please verify your NIC's MTU setting using '%s' or set the recv_frame_size argument appropriately.") % mtu_tool << std::endl << "UHD will use the auto-detected max frame size for this connection." << std::endl; } if ((mb.recv_args.has_key("send_frame_size")) && (req_max_frame_size.send_frame_size < _max_frame_sizes.send_frame_size)) { UHD_MSG(warning) << boost::format("You requested a send frame size of (%lu) but your NIC's max frame size is (%lu).") % req_max_frame_size.send_frame_size << _max_frame_sizes.send_frame_size << std::endl << boost::format("Please verify your NIC's MTU setting using '%s' or set the send_frame_size argument appropriately.") % mtu_tool << std::endl << "UHD will use the auto-detected max frame size for this connection." << std::endl; } _tree->create(mb_path / "link_max_rate").set(X300_MAX_RATE_10GIGE); } //create basic communication UHD_MSG(status) << "Setup basic communication..." << std::endl; if (mb.xport_path == "nirio") { boost::mutex::scoped_lock(pcie_zpu_iface_registry_mutex); if (get_pcie_zpu_iface_registry().has_key(mb.addr)) { throw uhd::assertion_error("Someone else has a ZPU transport to the device open. Internal error!"); } else { mb.zpu_ctrl = x300_make_ctrl_iface_pcie(mb.rio_fpga_interface->get_kernel_proxy()); get_pcie_zpu_iface_registry()[mb.addr] = boost::weak_ptr(mb.zpu_ctrl); } } else { mb.zpu_ctrl = x300_make_ctrl_iface_enet(udp_simple::make_connected(mb.addr, BOOST_STRINGIZE(X300_FW_COMMS_UDP_PORT))); } mb.claimer_task = uhd::task::make(boost::bind(&x300_impl::claimer_loop, this, mb.zpu_ctrl)); //extract the FW path for the X300 //and live load fw over ethernet link if (dev_addr.has_key("fw")) { const std::string x300_fw_image = find_image_path( dev_addr.has_key("fw")? dev_addr["fw"] : X300_FW_FILE_NAME ); x300_load_fw(mb.zpu_ctrl, x300_fw_image); } //check compat -- good place to do after conditional loading this->check_fw_compat(mb_path, mb.zpu_ctrl); this->check_fpga_compat(mb_path, mb.zpu_ctrl); //store which FPGA image is loaded mb.loaded_fpga_image = get_fpga_option(mb.zpu_ctrl); //low speed perif access mb.zpu_spi = spi_core_3000::make(mb.zpu_ctrl, SR_ADDR(SET0_BASE, ZPU_SR_SPI), SR_ADDR(SET0_BASE, ZPU_RB_SPI)); mb.zpu_i2c = i2c_core_100_wb32::make(mb.zpu_ctrl, I2C1_BASE); mb.zpu_i2c->set_clock_rate(X300_BUS_CLOCK_RATE); //////////////////////////////////////////////////////////////////// // print network routes mapping //////////////////////////////////////////////////////////////////// /* const uint32_t routes_addr = mb.zpu_ctrl->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_ROUTE_MAP_ADDR)); const uint32_t routes_len = mb.zpu_ctrl->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_ROUTE_MAP_LEN)); UHD_VAR(routes_len); for (size_t i = 0; i < routes_len; i+=1) { const uint32_t node_addr = mb.zpu_ctrl->peek32(SR_ADDR(routes_addr, i*2+0)); const uint32_t nbor_addr = mb.zpu_ctrl->peek32(SR_ADDR(routes_addr, i*2+1)); if (node_addr != 0 and nbor_addr != 0) { UHD_MSG(status) << boost::format("%u: %s -> %s") % i % asio::ip::address_v4(node_addr).to_string() % asio::ip::address_v4(nbor_addr).to_string() << std::endl; } } */ //////////////////////////////////////////////////////////////////// // setup the mboard eeprom //////////////////////////////////////////////////////////////////// UHD_MSG(status) << "Loading values from EEPROM..." << std::endl; i2c_iface::sptr eeprom16 = mb.zpu_i2c->eeprom16(); if (dev_addr.has_key("blank_eeprom")) { UHD_MSG(warning) << "Obliterating the motherboard EEPROM..." << std::endl; eeprom16->write_eeprom(0x50, 0, byte_vector_t(256, 0xff)); } const mboard_eeprom_t mb_eeprom(*eeprom16, "X300"); _tree->create(mb_path / "eeprom") .set(mb_eeprom) .subscribe(boost::bind(&x300_impl::set_mb_eeprom, this, mb.zpu_i2c, _1)); //////////////////////////////////////////////////////////////////// // parse the product number //////////////////////////////////////////////////////////////////// std::string product_name = "X300?"; switch (get_mb_type_from_eeprom(mb_eeprom)) { case USRP_X300_MB: product_name = "X300"; break; case USRP_X310_MB: product_name = "X310"; break; default: break; } _tree->create(mb_path / "name").set(product_name); _tree->create(mb_path / "codename").set("Yetti"); //////////////////////////////////////////////////////////////////// // determine routing based on address match //////////////////////////////////////////////////////////////////// mb.router_dst_here = X300_XB_DST_E0; //some default if eeprom not match if (mb.xport_path == "nirio") { mb.router_dst_here = X300_XB_DST_PCI; } else { if (mb.addr == mb_eeprom["ip-addr0"]) mb.router_dst_here = X300_XB_DST_E0; else if (mb.addr == mb_eeprom["ip-addr1"]) mb.router_dst_here = X300_XB_DST_E1; else if (mb.addr == mb_eeprom["ip-addr2"]) mb.router_dst_here = X300_XB_DST_E0; else if (mb.addr == mb_eeprom["ip-addr3"]) mb.router_dst_here = X300_XB_DST_E1; else if (mb.addr == boost::asio::ip::address_v4(boost::uint32_t(X300_DEFAULT_IP_ETH0_1G)).to_string()) mb.router_dst_here = X300_XB_DST_E0; else if (mb.addr == boost::asio::ip::address_v4(boost::uint32_t(X300_DEFAULT_IP_ETH1_1G)).to_string()) mb.router_dst_here = X300_XB_DST_E1; else if (mb.addr == boost::asio::ip::address_v4(boost::uint32_t(X300_DEFAULT_IP_ETH0_10G)).to_string()) mb.router_dst_here = X300_XB_DST_E0; else if (mb.addr == boost::asio::ip::address_v4(boost::uint32_t(X300_DEFAULT_IP_ETH1_10G)).to_string()) mb.router_dst_here = X300_XB_DST_E1; } //////////////////////////////////////////////////////////////////// // read dboard eeproms //////////////////////////////////////////////////////////////////// for (size_t i = 0; i < 8; i++) { if (i == 0 or i == 2) continue; //not used mb.db_eeproms[i].load(*mb.zpu_i2c, 0x50 | i); } //////////////////////////////////////////////////////////////////// // create clock control objects //////////////////////////////////////////////////////////////////// UHD_MSG(status) << "Setup RF frontend clocking..." << std::endl; mb.hw_rev = 0; if(mb_eeprom.has_key("revision") and not mb_eeprom["revision"].empty()) { try { mb.hw_rev = boost::lexical_cast(mb_eeprom["revision"]); } catch(...) { UHD_MSG(warning) << "Revision in EEPROM is invalid! Please reprogram your EEPROM." << std::endl; } } else { UHD_MSG(warning) << "No revision detected MB EEPROM must be reprogrammed!" << std::endl; } if(mb.hw_rev == 0) { UHD_MSG(warning) << "Defaulting to X300 RevD Clock Settings. This will result in non-optimal lock times." << std::endl; mb.hw_rev = X300_REV("D"); } //Create clock control. NOTE: This does not configure the LMK yet. initialize_clock_control(mb); mb.clock = x300_clock_ctrl::make(mb.zpu_spi, 1 /*slaveno*/, mb.hw_rev, dev_addr.cast("master_clock_rate", X300_DEFAULT_TICK_RATE), dev_addr.cast("system_ref_rate", X300_DEFAULT_SYSREF_RATE)); //Initialize clock source to use internal reference and generate //a valid radio clock. This may change after configuration is done. //This will configure the LMK and wait for lock update_clock_source(mb, "internal"); //////////////////////////////////////////////////////////////////// // create clock properties //////////////////////////////////////////////////////////////////// _tree->create(mb_path / "tick_rate") .publish(boost::bind(&x300_clock_ctrl::get_master_clock_rate, mb.clock)); _tree->create(mb_path / "time" / "cmd"); UHD_MSG(status) << "Radio 1x clock:" << (mb.clock->get_master_clock_rate()/1e6) << std::endl; //////////////////////////////////////////////////////////////////// // Create the GPSDO control //////////////////////////////////////////////////////////////////// static const boost::uint32_t dont_look_for_gpsdo = 0x1234abcdul; //otherwise if not disabled, look for the internal GPSDO if (mb.zpu_ctrl->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_GPSDO_STATUS)) != dont_look_for_gpsdo) { UHD_MSG(status) << "Detecting internal GPSDO.... " << std::flush; try { mb.gps = gps_ctrl::make(x300_make_uart_iface(mb.zpu_ctrl)); } catch(std::exception &e) { UHD_MSG(error) << "An error occurred making GPSDO control: " << e.what() << std::endl; } if (mb.gps and mb.gps->gps_detected()) { BOOST_FOREACH(const std::string &name, mb.gps->get_sensors()) { _tree->create(mb_path / "sensors" / name) .publish(boost::bind(&gps_ctrl::get_sensor, mb.gps, name)); } } else { mb.zpu_ctrl->poke32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_GPSDO_STATUS), dont_look_for_gpsdo); } } //////////////////////////////////////////////////////////////////// //clear router? //////////////////////////////////////////////////////////////////// for (size_t i = 0; i < 512; i++) { mb.zpu_ctrl->poke32(SR_ADDR(SETXB_BASE, i), 0); } //////////////////////////////////////////////////////////////////// // setup radios //////////////////////////////////////////////////////////////////// UHD_MSG(status) << "Initialize Radio control..." << std::endl; this->setup_radio(mb_i, "A"); this->setup_radio(mb_i, "B"); //////////////////////////////////////////////////////////////////// // front panel gpio //////////////////////////////////////////////////////////////////// mb.fp_gpio = gpio_core_200::make(mb.radio_perifs[0].ctrl, TOREG(SR_FP_GPIO), RB32_FP_GPIO); BOOST_FOREACH(const gpio_attr_map_t::value_type attr, gpio_attr_map) { _tree->create(mb_path / "gpio" / "FP0" / attr.second) .set(0) .subscribe(boost::bind(&x300_impl::set_fp_gpio, this, mb.fp_gpio, attr.first, _1)); } _tree->create(mb_path / "gpio" / "FP0" / "READBACK") .publish(boost::bind(&x300_impl::get_fp_gpio, this, mb.fp_gpio)); //////////////////////////////////////////////////////////////////// // register the time keepers - only one can be the highlander //////////////////////////////////////////////////////////////////// _tree->create(mb_path / "time" / "now") .publish(boost::bind(&time_core_3000::get_time_now, mb.radio_perifs[0].time64)) .subscribe(boost::bind(&time_core_3000::set_time_now, mb.radio_perifs[0].time64, _1)) .subscribe(boost::bind(&time_core_3000::set_time_now, mb.radio_perifs[1].time64, _1)); _tree->create(mb_path / "time" / "pps") .publish(boost::bind(&time_core_3000::get_time_last_pps, mb.radio_perifs[0].time64)) .subscribe(boost::bind(&time_core_3000::set_time_next_pps, mb.radio_perifs[0].time64, _1)) .subscribe(boost::bind(&time_core_3000::set_time_next_pps, mb.radio_perifs[1].time64, _1)); //////////////////////////////////////////////////////////////////// // setup time sources and properties //////////////////////////////////////////////////////////////////// _tree->create(mb_path / "time_source" / "value") .set("internal") .subscribe(boost::bind(&x300_impl::update_time_source, this, boost::ref(mb), _1)); static const std::vector time_sources = boost::assign::list_of("internal")("external")("gpsdo"); _tree->create >(mb_path / "time_source" / "options").set(time_sources); //setup the time output, default to ON _tree->create(mb_path / "time_source" / "output") .subscribe(boost::bind(&x300_impl::set_time_source_out, this, boost::ref(mb), _1)) .set(true); //////////////////////////////////////////////////////////////////// // setup clock sources and properties //////////////////////////////////////////////////////////////////// _tree->create(mb_path / "clock_source" / "value") .set("internal") .subscribe(boost::bind(&x300_impl::update_clock_source, this, boost::ref(mb), _1)) .subscribe(boost::bind(&x300_impl::reset_radios, this, boost::ref(mb))); static const std::vector clock_source_options = boost::assign::list_of("internal")("external")("gpsdo"); _tree->create >(mb_path / "clock_source" / "options").set(clock_source_options); //setup external reference options. default to 10 MHz input reference _tree->create(mb_path / "clock_source" / "external"); static const std::vector external_freq_options = boost::assign::list_of(10e6)(30.72e6)(200e6); _tree->create >(mb_path / "clock_source" / "external" / "freq" / "options") .set(external_freq_options); _tree->create(mb_path / "clock_source" / "external" / "value") .set(mb.clock->get_sysref_clock_rate()); // FIXME the external clock source settings need to be more robust //setup the clock output, default to ON _tree->create(mb_path / "clock_source" / "output") .subscribe(boost::bind(&x300_clock_ctrl::set_ref_out, mb.clock, _1)); //initialize tick rate (must be done before setting time) _tree->access(mb_path / "tick_rate") .subscribe(boost::bind(&x300_impl::set_tick_rate, this, boost::ref(mb), _1)) .subscribe(boost::bind(&x300_impl::update_tick_rate, this, boost::ref(mb), _1)) .set(mb.clock->get_master_clock_rate()); //////////////////////////////////////////////////////////////////// // initialize clock and time sources //////////////////////////////////////////////////////////////////// if (mb.gps and mb.gps->gps_detected()) { UHD_MSG(status) << "Initializing clock and time using GPSDO... " << std::flush; _tree->access(mb_path / "clock_source" / "value").set("gpsdo"); _tree->access(mb_path / "time_source" / "value").set("gpsdo"); const time_t tp = time_t(mb.gps->get_sensor("gps_time").to_int() + 1); _tree->access(mb_path / "time" / "pps").set(time_spec_t(tp)); } else { UHD_MSG(status) << "Initializing clock and time using internal sources... " << std::flush; _tree->access(mb_path / "clock_source" / "value").set("internal"); _tree->access(mb_path / "time_source" / "value").set("internal"); } UHD_MSG(status) << "done" << std::endl; //////////////////////////////////////////////////////////////////// // create frontend mapping //////////////////////////////////////////////////////////////////// std::vector default_map(2, 0); default_map[1] = 1; _tree->create >(mb_path / "rx_chan_dsp_mapping").set(default_map); _tree->create >(mb_path / "tx_chan_dsp_mapping").set(default_map); _tree->create(mb_path / "rx_subdev_spec") .subscribe(boost::bind(&x300_impl::update_subdev_spec, this, "rx", mb_i, _1)); _tree->create(mb_path / "tx_subdev_spec") .subscribe(boost::bind(&x300_impl::update_subdev_spec, this, "tx", mb_i, _1)); //////////////////////////////////////////////////////////////////// // and do the misc mboard sensors //////////////////////////////////////////////////////////////////// _tree->create(mb_path / "sensors" / "ref_locked") .publish(boost::bind(&x300_impl::get_ref_locked, this, mb.zpu_ctrl)); //////////////////////////////////////////////////////////////////// // do some post-init tasks //////////////////////////////////////////////////////////////////// subdev_spec_t rx_fe_spec, tx_fe_spec; rx_fe_spec.push_back(subdev_spec_pair_t("A", _tree->list(mb_path / "dboards" / "A" / "rx_frontends").at(0))); rx_fe_spec.push_back(subdev_spec_pair_t("B", _tree->list(mb_path / "dboards" / "B" / "rx_frontends").at(0))); tx_fe_spec.push_back(subdev_spec_pair_t("A", _tree->list(mb_path / "dboards" / "A" / "tx_frontends").at(0))); tx_fe_spec.push_back(subdev_spec_pair_t("B", _tree->list(mb_path / "dboards" / "B" / "tx_frontends").at(0))); _tree->access(mb_path / "rx_subdev_spec").set(rx_fe_spec); _tree->access(mb_path / "tx_subdev_spec").set(tx_fe_spec); mb.initialization_done = true; } x300_impl::~x300_impl(void) { try { BOOST_FOREACH(mboard_members_t &mb, _mb) { mb.radio_perifs[0].ctrl->poke32(TOREG(SR_MISC_OUTS), (1 << 2)); //disable/reset ADC/DAC mb.radio_perifs[1].ctrl->poke32(TOREG(SR_MISC_OUTS), (1 << 2)); //disable/reset ADC/DAC //kill the claimer task and unclaim the device mb.claimer_task.reset(); { //Critical section boost::mutex::scoped_lock(pcie_zpu_iface_registry_mutex); mb.zpu_ctrl->poke32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_TIME), 0); mb.zpu_ctrl->poke32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_SRC), 0); //If the process is killed, the entire registry will disappear so we //don't need to worry about unclean shutdowns here. get_pcie_zpu_iface_registry().pop(mb.addr); } } } catch(...) { UHD_SAFE_CALL(throw;) } } static void check_adc(wb_iface::sptr iface, const boost::uint32_t val) { boost::uint32_t adc_rb = iface->peek32(RB32_RX); adc_rb ^= 0xfffc0000; //adapt for I inversion in FPGA //UHD_MSG(status) << "adc_rb " << std::hex << adc_rb << " val " << std::hex << val << std::endl; UHD_ASSERT_THROW(adc_rb == val); } void x300_impl::setup_radio(const size_t mb_i, const std::string &slot_name) { const fs_path mb_path = "/mboards/"+boost::lexical_cast(mb_i); UHD_ASSERT_THROW(mb_i < _mb.size()); mboard_members_t &mb = _mb[mb_i]; const size_t radio_index = mb.get_radio_index(slot_name); radio_perifs_t &perif = mb.radio_perifs[radio_index]; //////////////////////////////////////////////////////////////////// // radio control //////////////////////////////////////////////////////////////////// boost::uint8_t dest = (radio_index == 0)? X300_XB_DST_R0 : X300_XB_DST_R1; boost::uint32_t ctrl_sid; both_xports_t xport = this->make_transport(mb_i, dest, X300_RADIO_DEST_PREFIX_CTRL, device_addr_t(), ctrl_sid); perif.ctrl = radio_ctrl_core_3000::make(mb.if_pkt_is_big_endian, xport.recv, xport.send, ctrl_sid, slot_name); perif.ctrl->poke32(TOREG(SR_MISC_OUTS), (1 << 2)); //reset adc + dac perif.ctrl->poke32(TOREG(SR_MISC_OUTS), (1 << 1) | (1 << 0)); //out of reset + dac enable this->register_loopback_self_test(perif.ctrl); perif.spi = spi_core_3000::make(perif.ctrl, TOREG(SR_SPI), RB32_SPI); perif.adc = x300_adc_ctrl::make(perif.spi, DB_ADC_SEN); perif.dac = x300_dac_ctrl::make(perif.spi, DB_DAC_SEN, mb.clock->get_master_clock_rate()); perif.leds = gpio_core_200_32wo::make(perif.ctrl, TOREG(SR_LEDS)); _tree->access(mb_path / "time" / "cmd") .subscribe(boost::bind(&radio_ctrl_core_3000::set_time, perif.ctrl, _1)); _tree->access(mb_path / "tick_rate") .subscribe(boost::bind(&radio_ctrl_core_3000::set_tick_rate, perif.ctrl, _1)); //////////////////////////////////////////////////////////////// // ADC self test //////////////////////////////////////////////////////////////// perif.adc->set_test_word("ones", "ones"); check_adc(perif.ctrl, 0xfffcfffc); perif.adc->set_test_word("zeros", "zeros"); check_adc(perif.ctrl, 0x00000000); perif.adc->set_test_word("ones", "zeros"); check_adc(perif.ctrl, 0xfffc0000); perif.adc->set_test_word("zeros", "ones"); check_adc(perif.ctrl, 0x0000fffc); for (size_t k = 0; k < 14; k++) { perif.adc->set_test_word("zeros", "custom", 1 << k); check_adc(perif.ctrl, 1 << (k+2)); } for (size_t k = 0; k < 14; k++) { perif.adc->set_test_word("custom", "zeros", 1 << k); check_adc(perif.ctrl, 1 << (k+18)); } perif.adc->set_test_word("normal", "normal"); //////////////////////////////////////////////////////////////// // create codec control objects //////////////////////////////////////////////////////////////// _tree->create(mb_path / "rx_codecs" / slot_name / "gains"); //phony property so this dir exists _tree->create(mb_path / "tx_codecs" / slot_name / "gains"); //phony property so this dir exists _tree->create(mb_path / "rx_codecs" / slot_name / "name").set("ads62p48"); _tree->create(mb_path / "tx_codecs" / slot_name / "name").set("ad9146"); _tree->create(mb_path / "rx_codecs" / slot_name / "gains" / "digital" / "range").set(meta_range_t(0, 6.0, 0.5)); _tree->create(mb_path / "rx_codecs" / slot_name / "gains" / "digital" / "value") .subscribe(boost::bind(&x300_adc_ctrl::set_gain, perif.adc, _1)).set(0); //////////////////////////////////////////////////////////////////// // front end corrections //////////////////////////////////////////////////////////////////// perif.rx_fe = rx_frontend_core_200::make(perif.ctrl, TOREG(SR_RX_FRONT)); const fs_path rx_fe_path = mb_path / "rx_frontends" / slot_name; _tree->create >(rx_fe_path / "dc_offset" / "value") .coerce(boost::bind(&rx_frontend_core_200::set_dc_offset, perif.rx_fe, _1)) .set(std::complex(0.0, 0.0)); _tree->create(rx_fe_path / "dc_offset" / "enable") .subscribe(boost::bind(&rx_frontend_core_200::set_dc_offset_auto, perif.rx_fe, _1)) .set(true); _tree->create >(rx_fe_path / "iq_balance" / "value") .subscribe(boost::bind(&rx_frontend_core_200::set_iq_balance, perif.rx_fe, _1)) .set(std::complex(0.0, 0.0)); perif.tx_fe = tx_frontend_core_200::make(perif.ctrl, TOREG(SR_TX_FRONT)); const fs_path tx_fe_path = mb_path / "tx_frontends" / slot_name; _tree->create >(tx_fe_path / "dc_offset" / "value") .coerce(boost::bind(&tx_frontend_core_200::set_dc_offset, perif.tx_fe, _1)) .set(std::complex(0.0, 0.0)); _tree->create >(tx_fe_path / "iq_balance" / "value") .subscribe(boost::bind(&tx_frontend_core_200::set_iq_balance, perif.tx_fe, _1)) .set(std::complex(0.0, 0.0)); //////////////////////////////////////////////////////////////////// // create rx dsp control objects //////////////////////////////////////////////////////////////////// perif.framer = rx_vita_core_3000::make(perif.ctrl, TOREG(SR_RX_CTRL)); perif.ddc = rx_dsp_core_3000::make(perif.ctrl, TOREG(SR_RX_DSP)); perif.ddc->set_link_rate(10e9/8); //whatever _tree->access(mb_path / "tick_rate") .subscribe(boost::bind(&rx_vita_core_3000::set_tick_rate, perif.framer, _1)) .subscribe(boost::bind(&rx_dsp_core_3000::set_tick_rate, perif.ddc, _1)); const fs_path rx_dsp_path = mb_path / "rx_dsps" / str(boost::format("%u") % radio_index); _tree->create(rx_dsp_path / "rate" / "range") .publish(boost::bind(&rx_dsp_core_3000::get_host_rates, perif.ddc)); _tree->create(rx_dsp_path / "rate" / "value") .coerce(boost::bind(&rx_dsp_core_3000::set_host_rate, perif.ddc, _1)) .subscribe(boost::bind(&x300_impl::update_rx_samp_rate, this, boost::ref(mb), radio_index, _1)) .set(1e6); _tree->create(rx_dsp_path / "freq" / "value") .coerce(boost::bind(&rx_dsp_core_3000::set_freq, perif.ddc, _1)) .set(0.0); _tree->create(rx_dsp_path / "freq" / "range") .publish(boost::bind(&rx_dsp_core_3000::get_freq_range, perif.ddc)); _tree->create(rx_dsp_path / "stream_cmd") .subscribe(boost::bind(&rx_vita_core_3000::issue_stream_command, perif.framer, _1)); //////////////////////////////////////////////////////////////////// // create tx dsp control objects //////////////////////////////////////////////////////////////////// perif.deframer = tx_vita_core_3000::make(perif.ctrl, TOREG(SR_TX_CTRL)); perif.duc = tx_dsp_core_3000::make(perif.ctrl, TOREG(SR_TX_DSP)); perif.duc->set_link_rate(10e9/8); //whatever _tree->access(mb_path / "tick_rate") .subscribe(boost::bind(&tx_vita_core_3000::set_tick_rate, perif.deframer, _1)) .subscribe(boost::bind(&tx_dsp_core_3000::set_tick_rate, perif.duc, _1)); const fs_path tx_dsp_path = mb_path / "tx_dsps" / str(boost::format("%u") % radio_index); _tree->create(tx_dsp_path / "rate" / "range") .publish(boost::bind(&tx_dsp_core_3000::get_host_rates, perif.duc)); _tree->create(tx_dsp_path / "rate" / "value") .coerce(boost::bind(&tx_dsp_core_3000::set_host_rate, perif.duc, _1)) .subscribe(boost::bind(&x300_impl::update_tx_samp_rate, this, boost::ref(mb), radio_index, _1)) .set(1e6); _tree->create(tx_dsp_path / "freq" / "value") .coerce(boost::bind(&tx_dsp_core_3000::set_freq, perif.duc, _1)) .set(0.0); _tree->create(tx_dsp_path / "freq" / "range") .publish(boost::bind(&tx_dsp_core_3000::get_freq_range, perif.duc)); //////////////////////////////////////////////////////////////////// // create time control objects //////////////////////////////////////////////////////////////////// time_core_3000::readback_bases_type time64_rb_bases; time64_rb_bases.rb_now = RB64_TIME_NOW; time64_rb_bases.rb_pps = RB64_TIME_PPS; perif.time64 = time_core_3000::make(perif.ctrl, TOREG(SR_TIME), time64_rb_bases); //////////////////////////////////////////////////////////////////// // create RF frontend interfacing //////////////////////////////////////////////////////////////////// const fs_path db_path = (mb_path / "dboards" / slot_name); const size_t j = (slot_name == "B")? 0x2 : 0x0; _tree->create(db_path / "rx_eeprom") .set(mb.db_eeproms[X300_DB0_RX_EEPROM | j]) .subscribe(boost::bind(&x300_impl::set_db_eeprom, this, mb.zpu_i2c, (0x50 | X300_DB0_RX_EEPROM | j), _1)); _tree->create(db_path / "tx_eeprom") .set(mb.db_eeproms[X300_DB0_TX_EEPROM | j]) .subscribe(boost::bind(&x300_impl::set_db_eeprom, this, mb.zpu_i2c, (0x50 | X300_DB0_TX_EEPROM | j), _1)); _tree->create(db_path / "gdb_eeprom") .set(mb.db_eeproms[X300_DB0_GDB_EEPROM | j]) .subscribe(boost::bind(&x300_impl::set_db_eeprom, this, mb.zpu_i2c, (0x50 | X300_DB0_GDB_EEPROM | j), _1)); //create a new dboard interface x300_dboard_iface_config_t db_config; db_config.gpio = gpio_core_200::make(perif.ctrl, TOREG(SR_GPIO), RB32_GPIO); db_config.spi = perif.spi; db_config.rx_spi_slaveno = DB_RX_SEN; db_config.tx_spi_slaveno = DB_TX_SEN; db_config.i2c = mb.zpu_i2c; db_config.clock = mb.clock; db_config.which_rx_clk = (slot_name == "A")? X300_CLOCK_WHICH_DB0_RX : X300_CLOCK_WHICH_DB1_RX; db_config.which_tx_clk = (slot_name == "A")? X300_CLOCK_WHICH_DB0_TX : X300_CLOCK_WHICH_DB1_TX; db_config.dboard_slot = (slot_name == "A")? 0 : 1; _dboard_ifaces[db_path] = x300_make_dboard_iface(db_config); //create a new dboard manager _tree->create(db_path / "iface").set(_dboard_ifaces[db_path]); _dboard_managers[db_path] = dboard_manager::make( mb.db_eeproms[X300_DB0_RX_EEPROM | j].id, mb.db_eeproms[X300_DB0_TX_EEPROM | j].id, mb.db_eeproms[X300_DB0_GDB_EEPROM | j].id, _dboard_ifaces[db_path], _tree->subtree(db_path) ); //now that dboard is created -- register into rx antenna event const std::string fe_name = _tree->list(db_path / "rx_frontends").front(); _tree->access(db_path / "rx_frontends" / fe_name / "antenna" / "value") .subscribe(boost::bind(&x300_impl::update_atr_leds, this, mb.radio_perifs[radio_index].leds, _1)); this->update_atr_leds(mb.radio_perifs[radio_index].leds, ""); //init anyway, even if never called //bind frontend corrections to the dboard freq props const fs_path db_tx_fe_path = db_path / "tx_frontends"; BOOST_FOREACH(const std::string &name, _tree->list(db_tx_fe_path)) { _tree->access(db_tx_fe_path / name / "freq" / "value") .subscribe(boost::bind(&x300_impl::set_tx_fe_corrections, this, mb_path, slot_name, _1)); } const fs_path db_rx_fe_path = db_path / "rx_frontends"; BOOST_FOREACH(const std::string &name, _tree->list(db_rx_fe_path)) { _tree->access(db_rx_fe_path / name / "freq" / "value") .subscribe(boost::bind(&x300_impl::set_rx_fe_corrections, this, mb_path, slot_name, _1)); } } void x300_impl::set_rx_fe_corrections(const uhd::fs_path &mb_path, const std::string &fe_name, const double lo_freq) { if(not _ignore_cal_file){ apply_rx_fe_corrections(this->get_tree()->subtree(mb_path), fe_name, lo_freq); } } void x300_impl::set_tx_fe_corrections(const uhd::fs_path &mb_path, const std::string &fe_name, const double lo_freq) { if(not _ignore_cal_file){ apply_tx_fe_corrections(this->get_tree()->subtree(mb_path), fe_name, lo_freq); } } boost::uint32_t get_pcie_dma_channel(boost::uint8_t destination, boost::uint8_t prefix) { static const boost::uint32_t RADIO_GRP_SIZE = 3; static const boost::uint32_t RADIO0_GRP = 0; static const boost::uint32_t RADIO1_GRP = 1; boost::uint32_t radio_grp = (destination == X300_XB_DST_R0) ? RADIO0_GRP : RADIO1_GRP; return ((radio_grp * RADIO_GRP_SIZE) + prefix); } x300_impl::both_xports_t x300_impl::make_transport( const size_t mb_index, const boost::uint8_t& destination, const boost::uint8_t& prefix, const uhd::device_addr_t& args, boost::uint32_t& sid) { mboard_members_t &mb = _mb[mb_index]; both_xports_t xports; sid_config_t config; config.router_addr_there = X300_DEVICE_THERE; config.dst_prefix = prefix; config.router_dst_there = destination; config.router_dst_here = mb.router_dst_here; sid = this->allocate_sid(mb, config); static const uhd::device_addr_t DEFAULT_XPORT_ARGS; const uhd::device_addr_t& xport_args = (prefix != X300_RADIO_DEST_PREFIX_CTRL) ? args : DEFAULT_XPORT_ARGS; zero_copy_xport_params default_buff_args; if (mb.xport_path == "nirio") { default_buff_args.send_frame_size = (prefix == X300_RADIO_DEST_PREFIX_TX) ? X300_PCIE_TX_DATA_FRAME_SIZE : X300_PCIE_MSG_FRAME_SIZE; default_buff_args.recv_frame_size = (prefix == X300_RADIO_DEST_PREFIX_RX) ? X300_PCIE_RX_DATA_FRAME_SIZE : X300_PCIE_MSG_FRAME_SIZE; default_buff_args.num_send_frames = (prefix == X300_RADIO_DEST_PREFIX_TX) ? X300_PCIE_DATA_NUM_FRAMES : X300_PCIE_MSG_NUM_FRAMES; default_buff_args.num_recv_frames = (prefix == X300_RADIO_DEST_PREFIX_RX) ? X300_PCIE_DATA_NUM_FRAMES : X300_PCIE_MSG_NUM_FRAMES; xports.recv = nirio_zero_copy::make( mb.rio_fpga_interface, get_pcie_dma_channel(destination, prefix), default_buff_args, xport_args); xports.send = xports.recv; //For the nirio transport, buffer size is depends on the frame size and num frames xports.recv_buff_size = xports.recv->get_num_recv_frames() * xports.recv->get_recv_frame_size(); xports.send_buff_size = xports.send->get_num_send_frames() * xports.send->get_send_frame_size(); } else if (mb.xport_path == "eth") { /* Determine what the recommended frame size is for this * connection type.*/ size_t eth_data_rec_frame_size = 0; if (mb.loaded_fpga_image == "HGS") { if (mb.router_dst_here == X300_XB_DST_E0) { eth_data_rec_frame_size = X300_1GE_DATA_FRAME_MAX_SIZE; _tree->access("/mboards/"+boost::lexical_cast(mb_index) / "link_max_rate").set(X300_MAX_RATE_1GIGE); } else if (mb.router_dst_here == X300_XB_DST_E1) { eth_data_rec_frame_size = X300_10GE_DATA_FRAME_MAX_SIZE; _tree->access("/mboards/"+boost::lexical_cast(mb_index) / "link_max_rate").set(X300_MAX_RATE_10GIGE); } } else if (mb.loaded_fpga_image == "XGS") { eth_data_rec_frame_size = X300_10GE_DATA_FRAME_MAX_SIZE; _tree->access("/mboards/"+boost::lexical_cast(mb_index) / "link_max_rate").set(X300_MAX_RATE_10GIGE); } if (eth_data_rec_frame_size == 0) { throw uhd::runtime_error("Unable to determine ETH link type."); } /* Print a warning if the system's max available frame size is less than the most optimal * frame size for this type of connection. */ if (_max_frame_sizes.send_frame_size < eth_data_rec_frame_size) { UHD_MSG(warning) << boost::format("For this connection, UHD recommends a send frame size of at least %lu for best\nperformance, but your system's MTU will only allow %lu.") % eth_data_rec_frame_size % _max_frame_sizes.send_frame_size << std::endl << "This will negatively impact your maximum achievable sample rate." << std::endl; } if (_max_frame_sizes.recv_frame_size < eth_data_rec_frame_size) { UHD_MSG(warning) << boost::format("For this connection, UHD recommends a receive frame size of at least %lu for best\nperformance, but your system's MTU will only allow %lu.") % eth_data_rec_frame_size % _max_frame_sizes.recv_frame_size << std::endl << "This will negatively impact your maximum achievable sample rate." << std::endl; } size_t system_max_send_frame_size = (size_t) _max_frame_sizes.send_frame_size; size_t system_max_recv_frame_size = (size_t) _max_frame_sizes.recv_frame_size; // Make sure frame sizes do not exceed the max available value supported by UHD default_buff_args.send_frame_size = (prefix == X300_RADIO_DEST_PREFIX_TX) ? std::min(system_max_send_frame_size, X300_10GE_DATA_FRAME_MAX_SIZE) : std::min(system_max_send_frame_size, X300_ETH_MSG_FRAME_SIZE); default_buff_args.recv_frame_size = (prefix == X300_RADIO_DEST_PREFIX_RX) ? std::min(system_max_recv_frame_size, X300_10GE_DATA_FRAME_MAX_SIZE) : std::min(system_max_recv_frame_size, X300_ETH_MSG_FRAME_SIZE); default_buff_args.num_send_frames = (prefix == X300_RADIO_DEST_PREFIX_TX) ? X300_ETH_DATA_NUM_FRAMES : X300_ETH_MSG_NUM_FRAMES; default_buff_args.num_recv_frames = (prefix == X300_RADIO_DEST_PREFIX_RX) ? X300_ETH_DATA_NUM_FRAMES : X300_ETH_MSG_NUM_FRAMES; //make a new transport - fpga has no idea how to talk to us on this yet udp_zero_copy::buff_params buff_params; xports.recv = udp_zero_copy::make(mb.addr, BOOST_STRINGIZE(X300_VITA_UDP_PORT), default_buff_args, buff_params, xport_args); xports.send = xports.recv; //For the UDP transport the buffer size if the size of the socket buffer //in the kernel xports.recv_buff_size = buff_params.recv_buff_size; xports.send_buff_size = buff_params.send_buff_size; //clear the ethernet dispatcher's udp port //NOT clearing this, the dispatcher is now intelligent //_zpu_ctrl->poke32(SR_ADDR(SET0_BASE, (ZPU_SR_ETHINT0+8+3)), 0); //send a mini packet with SID into the ZPU //ZPU will reprogram the ethernet framer UHD_LOG << "programming packet for new xport on " << mb.addr << std::hex << "sid 0x" << sid << std::dec << std::endl; //YES, get a __send__ buffer from the __recv__ socket //-- this is the only way to program the framer for recv: managed_send_buffer::sptr buff = xports.recv->get_send_buff(); buff->cast()[0] = 0; //eth dispatch looks for != 0 buff->cast()[1] = uhd::htonx(sid); buff->commit(8); buff.reset(); //reprogram the ethernet dispatcher's udp port (should be safe to always set) UHD_LOG << "reprogram the ethernet dispatcher's udp port" << std::endl; mb.zpu_ctrl->poke32(SR_ADDR(SET0_BASE, (ZPU_SR_ETHINT0+8+3)), X300_VITA_UDP_PORT); mb.zpu_ctrl->poke32(SR_ADDR(SET0_BASE, (ZPU_SR_ETHINT1+8+3)), X300_VITA_UDP_PORT); //Do a peek to an arbitrary address to guarantee that the //ethernet framer has been programmed before we return. mb.zpu_ctrl->peek32(0); } return xports; } boost::uint32_t x300_impl::allocate_sid(mboard_members_t &mb, const sid_config_t &config) { const std::string &xport_path = mb.xport_path; const boost::uint32_t stream = (config.dst_prefix | (config.router_dst_there << 2)) & 0xff; const boost::uint32_t sid = 0 | (X300_DEVICE_HERE << 24) | (_sid_framer << 16) | (config.router_addr_there << 8) | (stream << 0) ; UHD_LOG << std::hex << " sid 0x" << sid << " framer 0x" << _sid_framer << " stream 0x" << stream << " router_dst_there 0x" << int(config.router_dst_there) << " router_addr_there 0x" << int(config.router_addr_there) << std::dec << std::endl; // Program the X300 to recognise it's own local address. mb.zpu_ctrl->poke32(SR_ADDR(SET0_BASE, ZPU_SR_XB_LOCAL), config.router_addr_there); // Program CAM entry for outgoing packets matching a X300 resource (for example a Radio) // This type of packet does matches the XB_LOCAL address and is looked up in the upper half of the CAM mb.zpu_ctrl->poke32(SR_ADDR(SETXB_BASE, 256 + (stream)), config.router_dst_there); // Program CAM entry for returning packets to us (for example GR host via Eth0) // This type of packet does not match the XB_LOCAL address and is looked up in the lower half of the CAM mb.zpu_ctrl->poke32(SR_ADDR(SETXB_BASE, 0 + (X300_DEVICE_HERE)), config.router_dst_here); if (xport_path == "nirio") { boost::uint32_t router_config_word = ((_sid_framer & 0xff) << 16) | //Return SID get_pcie_dma_channel(config.router_dst_there, config.dst_prefix); //Dest mb.rio_fpga_interface->get_kernel_proxy()->poke(PCIE_ROUTER_REG(0), router_config_word); } UHD_LOG << std::hex << "done router config for sid 0x" << sid << std::dec << std::endl; //increment for next setup _sid_framer++; return sid; } void x300_impl::update_atr_leds(gpio_core_200_32wo::sptr leds, const std::string &rx_ant) { const bool is_txrx = (rx_ant == "TX/RX"); const int rx_led = (1 << 2); const int tx_led = (1 << 1); const int txrx_led = (1 << 0); leds->set_atr_reg(dboard_iface::ATR_REG_IDLE, 0); leds->set_atr_reg(dboard_iface::ATR_REG_RX_ONLY, is_txrx? txrx_led : rx_led); leds->set_atr_reg(dboard_iface::ATR_REG_TX_ONLY, tx_led); leds->set_atr_reg(dboard_iface::ATR_REG_FULL_DUPLEX, rx_led | tx_led); } void x300_impl::set_tick_rate(mboard_members_t &mb, const double rate) { BOOST_FOREACH(radio_perifs_t &perif, mb.radio_perifs) perif.time64->set_tick_rate(rate); } void x300_impl::register_loopback_self_test(wb_iface::sptr iface) { bool test_fail = false; UHD_MSG(status) << "Performing register loopback test... " << std::flush; size_t hash = size_t(time(NULL)); for (size_t i = 0; i < 100; i++) { boost::hash_combine(hash, i); iface->poke32(TOREG(SR_TEST), boost::uint32_t(hash)); test_fail = iface->peek32(RB32_TEST) != boost::uint32_t(hash); if (test_fail) break; //exit loop on any failure } UHD_MSG(status) << ((test_fail)? " fail" : "pass") << std::endl; } /*********************************************************************** * clock and time control logic **********************************************************************/ void x300_impl::update_clock_control(mboard_members_t &mb) { const size_t reg = mb.clock_control_regs_clock_source | (mb.clock_control_regs_pps_select << 2) | (mb.clock_control_regs_pps_out_enb << 4) | (mb.clock_control_regs_tcxo_enb << 5) | (mb.clock_control_regs_gpsdo_pwr << 6) ; mb.zpu_ctrl->poke32(SR_ADDR(SET0_BASE, ZPU_SR_CLOCK_CTRL), reg); } void x300_impl::initialize_clock_control(mboard_members_t &mb) { //Initialize clock control register soft copies mb.clock_control_regs_clock_source = ZPU_SR_CLOCK_CTRL_CLK_SRC_INTERNAL; mb.clock_control_regs_pps_select = ZPU_SR_CLOCK_CTRL_PPS_SRC_INTERNAL; mb.clock_control_regs_pps_out_enb = 0; mb.clock_control_regs_tcxo_enb = 1; mb.clock_control_regs_gpsdo_pwr = 1; //GPSDO power always ON this->update_clock_control(mb); } void x300_impl::set_time_source_out(mboard_members_t &mb, const bool enb) { mb.clock_control_regs_pps_out_enb = enb? 1 : 0; this->update_clock_control(mb); } void x300_impl::update_clock_source(mboard_members_t &mb, const std::string &source) { //Optimize for the case when the current source is internal and we are trying //to set it to internal. This is the only case where we are guaranteed that //the clock has not gone away so we can skip setting the MUX and reseting the LMK. if (not (mb.current_refclk_src == "internal" and source == "internal")) { //Update the clock MUX on the motherboard to select the requested source mb.clock_control_regs_clock_source = 0; mb.clock_control_regs_tcxo_enb = 0; if (source == "internal") { mb.clock_control_regs_clock_source = ZPU_SR_CLOCK_CTRL_CLK_SRC_INTERNAL; mb.clock_control_regs_tcxo_enb = 1; } else if (source == "external") { mb.clock_control_regs_clock_source = ZPU_SR_CLOCK_CTRL_CLK_SRC_EXTERNAL; } else if (source == "gpsdo") { mb.clock_control_regs_clock_source = ZPU_SR_CLOCK_CTRL_CLK_SRC_GPSDO; } else { throw uhd::key_error("update_clock_source: unknown source: " + source); } this->update_clock_control(mb); //Reset the LMK to make sure it re-locks to the new reference mb.clock->reset_clocks(); } //Wait for the LMK to lock (always, as a sanity check that the clock is useable) //* Currently the LMK can take as long as 30 seconds to lock to a reference but we don't //* want to wait that long during initialization. //TODO: Need to verify timeout and settings to make sure lock can be achieved in < 1.0 seconds double timeout = mb.initialization_done ? 30.0 : 1.0; //The programming code in x300_clock_ctrl is not compatible with revs <= 4 and may //lead to locking issues. So, disable the ref-locked check for older (unsupported) boards. if (mb.hw_rev > 4) { if (not wait_for_ref_locked(mb.zpu_ctrl, timeout)) { //failed to lock on reference if (mb.initialization_done) { throw uhd::runtime_error((boost::format("Reference Clock failed to lock to %s source.") % source).str()); } else { //TODO: Re-enable this warning when we figure out a reliable lock time //UHD_MSG(warning) << "Reference clock failed to lock to " + source + " during device initialization. " << // "Check for the lock before operation or ignore this warning if using another clock source." << std::endl; } } } //Update cache value mb.current_refclk_src = source; } void x300_impl::update_time_source(mboard_members_t &mb, const std::string &source) { if (source == "internal") { mb.clock_control_regs_pps_select = ZPU_SR_CLOCK_CTRL_PPS_SRC_INTERNAL; } else if (source == "external") { mb.clock_control_regs_pps_select = ZPU_SR_CLOCK_CTRL_PPS_SRC_EXTERNAL; } else if (source == "gpsdo") { mb.clock_control_regs_pps_select = ZPU_SR_CLOCK_CTRL_PPS_SRC_GPSDO; } else { throw uhd::key_error("update_time_source: unknown source: " + source); } this->update_clock_control(mb); //check for valid pps if (!is_pps_present(mb.zpu_ctrl)) { // TODO - Implement intelligent PPS detection /* throw uhd::runtime_error((boost::format("The %d PPS was not detected. Please check the PPS source and try again.") % source).str()); */ } } bool x300_impl::wait_for_ref_locked(wb_iface::sptr ctrl, double timeout) { boost::system_time timeout_time = boost::get_system_time() + boost::posix_time::milliseconds(timeout * 1000.0); do { if (get_ref_locked(ctrl).to_bool()) return true; boost::this_thread::sleep(boost::posix_time::milliseconds(1)); } while (boost::get_system_time() < timeout_time); //Check one last time return get_ref_locked(ctrl).to_bool(); } sensor_value_t x300_impl::get_ref_locked(wb_iface::sptr ctrl) { boost::uint32_t clk_status = ctrl->peek32(SR_ADDR(SET0_BASE, ZPU_RB_CLK_STATUS)); const bool lock = ((clk_status & ZPU_RB_CLK_STATUS_LMK_LOCK) != 0); return sensor_value_t("Ref", lock, "locked", "unlocked"); } bool x300_impl::is_pps_present(wb_iface::sptr ctrl) { // The ZPU_RB_CLK_STATUS_PPS_DETECT bit toggles with each rising edge of the PPS. // We monitor it for up to 1.5 seconds looking for it to toggle. boost::uint32_t pps_detect = ctrl->peek32(SR_ADDR(SET0_BASE, ZPU_RB_CLK_STATUS)) & ZPU_RB_CLK_STATUS_PPS_DETECT; for (int i = 0; i < 15; i++) { boost::this_thread::sleep(boost::posix_time::milliseconds(100)); boost::uint32_t clk_status = ctrl->peek32(SR_ADDR(SET0_BASE, ZPU_RB_CLK_STATUS)); if (pps_detect != (clk_status & ZPU_RB_CLK_STATUS_PPS_DETECT)) return true; } return false; } /*********************************************************************** * reset and synchronization logic **********************************************************************/ void x300_impl::reset_radios(mboard_members_t &mb) { // Reset ADCs and DACs BOOST_FOREACH (radio_perifs_t& perif, mb.radio_perifs) { perif.adc->reset(); perif.dac->reset(); } } void x300_impl::synchronize_dacs(const std::vector& radios) { if (radios.size() < 2) return; //Nothing to synchronize //**PRECONDITION** //This function assumes that all the VITA times in "radios" are synchronized //to a common reference. Currently, this function is called in get_tx_stream //which also has the same precondition. //Reinitialize and resync all DACs for (size_t i = 0; i < radios.size(); i++) { radios[i]->dac->reset_and_resync(); } //Get a rough estimate of the cumulative command latency boost::posix_time::ptime t_start = boost::posix_time::microsec_clock::local_time(); for (size_t i = 0; i < radios.size(); i++) { radios[i]->ctrl->peek64(RB64_TIME_NOW); //Discard value. We are just timing the call } boost::posix_time::time_duration t_elapsed = boost::posix_time::microsec_clock::local_time() - t_start; //Add 100% of headroom + uncertaintly to the command time boost::uint64_t t_sync_us = (t_elapsed.total_microseconds() * 2) + 13000 /*Scheduler latency*/; //Pick radios[0] as the time reference. uhd::time_spec_t sync_time = radios[0]->time64->get_time_now() + uhd::time_spec_t(((double)t_sync_us)/1e6); //Send the sync command for (size_t i = 0; i < radios.size(); i++) { radios[i]->ctrl->set_time(sync_time); radios[i]->ctrl->poke32(TOREG(SR_DACSYNC), 0x1); //Arm FRAMEP/N sync pulse radios[i]->ctrl->set_time(uhd::time_spec_t(0.0)); //Clear command time } //Wait and check status boost::this_thread::sleep(boost::posix_time::microseconds(t_sync_us)); for (size_t i = 0; i < radios.size(); i++) { radios[i]->dac->verify_sync(); } } /*********************************************************************** * eeprom **********************************************************************/ void x300_impl::set_db_eeprom(i2c_iface::sptr i2c, const size_t addr, const uhd::usrp::dboard_eeprom_t &db_eeprom) { db_eeprom.store(*i2c, addr); } void x300_impl::set_mb_eeprom(i2c_iface::sptr i2c, const mboard_eeprom_t &mb_eeprom) { i2c_iface::sptr eeprom16 = i2c->eeprom16(); mb_eeprom.commit(*eeprom16, "X300"); } /*********************************************************************** * front-panel GPIO **********************************************************************/ boost::uint32_t x300_impl::get_fp_gpio(gpio_core_200::sptr gpio) { return boost::uint32_t(gpio->read_gpio(dboard_iface::UNIT_RX)); } void x300_impl::set_fp_gpio(gpio_core_200::sptr gpio, const gpio_attr_t attr, const boost::uint32_t value) { switch (attr) { case GPIO_CTRL: return gpio->set_pin_ctrl(dboard_iface::UNIT_RX, value); case GPIO_DDR: return gpio->set_gpio_ddr(dboard_iface::UNIT_RX, value); case GPIO_OUT: return gpio->set_gpio_out(dboard_iface::UNIT_RX, value); case GPIO_ATR_0X: return gpio->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_IDLE, value); case GPIO_ATR_RX: return gpio->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_RX_ONLY, value); case GPIO_ATR_TX: return gpio->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_TX_ONLY, value); case GPIO_ATR_XX: return gpio->set_atr_reg(dboard_iface::UNIT_RX, dboard_iface::ATR_REG_FULL_DUPLEX, value); default: UHD_THROW_INVALID_CODE_PATH(); } } /*********************************************************************** * claimer logic **********************************************************************/ void x300_impl::claimer_loop(wb_iface::sptr iface) { { //Critical section boost::mutex::scoped_lock(claimer_mutex); iface->poke32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_TIME), uint32_t(time(NULL))); iface->poke32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_SRC), get_process_hash()); } boost::this_thread::sleep(boost::posix_time::milliseconds(1000)); //1 second } bool x300_impl::is_claimed(wb_iface::sptr iface) { boost::mutex::scoped_lock(claimer_mutex); //If timed out then device is definitely unclaimed if (iface->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_STATUS)) == 0) return false; //otherwise check claim src to determine if another thread with the same src has claimed the device return iface->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_CLAIM_SRC)) != get_process_hash(); } /*********************************************************************** * Frame size detection **********************************************************************/ x300_impl::frame_size_t x300_impl::determine_max_frame_size(const std::string &addr, const frame_size_t &user_frame_size) { udp_simple::sptr udp = udp_simple::make_connected(addr, BOOST_STRINGIZE(X300_MTU_DETECT_UDP_PORT)); std::vector buffer(std::max(user_frame_size.recv_frame_size, user_frame_size.send_frame_size)); x300_mtu_t *request = reinterpret_cast(&buffer.front()); static const double echo_timeout = 0.020; //20 ms //test holler - check if its supported in this fw version request->flags = uhd::htonx(X300_MTU_DETECT_ECHO_REQUEST); request->size = uhd::htonx(sizeof(x300_mtu_t)); udp->send(boost::asio::buffer(buffer, sizeof(x300_mtu_t))); udp->recv(boost::asio::buffer(buffer), echo_timeout); if (!(uhd::ntohx(request->flags) & X300_MTU_DETECT_ECHO_REPLY)) throw uhd::not_implemented_error("Holler protocol not implemented"); size_t min_recv_frame_size = sizeof(x300_mtu_t); size_t max_recv_frame_size = user_frame_size.recv_frame_size; size_t min_send_frame_size = sizeof(x300_mtu_t); size_t max_send_frame_size = user_frame_size.send_frame_size; UHD_MSG(status) << "Determining maximum frame size... "; while (min_recv_frame_size < max_recv_frame_size) { size_t test_frame_size = (max_recv_frame_size/2 + min_recv_frame_size/2 + 3) & ~3; request->flags = uhd::htonx(X300_MTU_DETECT_ECHO_REQUEST); request->size = uhd::htonx(test_frame_size); udp->send(boost::asio::buffer(buffer, sizeof(x300_mtu_t))); size_t len = udp->recv(boost::asio::buffer(buffer), echo_timeout); if (len >= test_frame_size) min_recv_frame_size = test_frame_size; else max_recv_frame_size = test_frame_size - 4; } if(min_recv_frame_size < IP_PROTOCOL_MIN_MTU_SIZE-IP_PROTOCOL_UDP_PLUS_IP_HEADER) { throw uhd::runtime_error("System receive MTU size is less than the minimum required by the IP protocol."); } while (min_send_frame_size < max_send_frame_size) { size_t test_frame_size = (max_send_frame_size/2 + min_send_frame_size/2 + 3) & ~3; request->flags = uhd::htonx(X300_MTU_DETECT_ECHO_REQUEST); request->size = uhd::htonx(sizeof(x300_mtu_t)); udp->send(boost::asio::buffer(buffer, test_frame_size)); size_t len = udp->recv(boost::asio::buffer(buffer), echo_timeout); if (len >= sizeof(x300_mtu_t)) len = uhd::ntohx(request->size); if (len >= test_frame_size) min_send_frame_size = test_frame_size; else max_send_frame_size = test_frame_size - 4; } if(min_send_frame_size < IP_PROTOCOL_MIN_MTU_SIZE-IP_PROTOCOL_UDP_PLUS_IP_HEADER) { throw uhd::runtime_error("System send MTU size is less than the minimum required by the IP protocol."); } frame_size_t frame_size; // There are cases when NICs accept oversized packets, in which case we'd falsely // detect a larger-than-possible frame size. A safe and sensible value is the minimum // of the recv and send frame sizes. frame_size.recv_frame_size = std::min(min_recv_frame_size, min_send_frame_size); frame_size.send_frame_size = std::min(min_recv_frame_size, min_send_frame_size); UHD_MSG(status) << frame_size.send_frame_size << " bytes." << std::endl; return frame_size; } /*********************************************************************** * compat checks **********************************************************************/ void x300_impl::check_fw_compat(const fs_path &mb_path, wb_iface::sptr iface) { boost::uint32_t compat_num = iface->peek32(SR_ADDR(X300_FW_SHMEM_BASE, X300_FW_SHMEM_COMPAT_NUM)); boost::uint32_t compat_major = (compat_num >> 16); boost::uint32_t compat_minor = (compat_num & 0xffff); if (compat_major != X300_FW_COMPAT_MAJOR) { throw uhd::runtime_error(str(boost::format( "Expected firmware compatibility number %d.%d, but got %d.%d:\n" "The firmware build is not compatible with the host code build.\n" "%s" ) % int(X300_FW_COMPAT_MAJOR) % int(X300_FW_COMPAT_MINOR) % compat_major % compat_minor % print_utility_error("uhd_images_downloader.py"))); } _tree->create(mb_path / "fw_version").set(str(boost::format("%u.%u") % compat_major % compat_minor)); } void x300_impl::check_fpga_compat(const fs_path &mb_path, wb_iface::sptr iface) { boost::uint32_t compat_num = iface->peek32(SR_ADDR(SET0_BASE, ZPU_RB_COMPAT_NUM)); boost::uint32_t compat_major = (compat_num >> 16); boost::uint32_t compat_minor = (compat_num & 0xffff); if (compat_major != X300_FPGA_COMPAT_MAJOR) { throw uhd::runtime_error(str(boost::format( "Expected FPGA compatibility number %d, but got %d:\n" "The FPGA image on your device is not compatible with this host code build.\n" "Download the appropriate FPGA images for this version of UHD.\n" "%s\n\n" "Then burn a new image to the on-board flash storage of your\n" "USRP X3xx device using the burner utility. %s\n\n" "For more information, refer to the UHD manual:\n\n" " http://files.ettus.com/manual/page_usrp_x3x0.html#x3x0_flash" ) % int(X300_FPGA_COMPAT_MAJOR) % compat_major % print_utility_error("uhd_images_downloader.py") % print_utility_error("usrp_x3xx_fpga_burner"))); } _tree->create(mb_path / "fpga_version").set(str(boost::format("%u.%u") % compat_major % compat_minor)); } x300_impl::x300_mboard_t x300_impl::get_mb_type_from_pcie(const std::string& resource, const std::string& rpc_port) { x300_mboard_t mb_type = UNKNOWN; //Detect the PCIe product ID to distinguish between X300 and X310 nirio_status status = NiRio_Status_Success; boost::uint32_t pid; niriok_proxy::sptr discovery_proxy = niusrprio_session::create_kernel_proxy(resource, rpc_port); if (discovery_proxy) { nirio_status_chain(discovery_proxy->get_attribute(RIO_PRODUCT_NUMBER, pid), status); discovery_proxy->close(); if (nirio_status_not_fatal(status)) { //The PCIe ID -> MB mapping may be different from the EEPROM -> MB mapping switch (pid) { case X300_USRP_PCIE_SSID: mb_type = USRP_X300_MB; break; case X310_USRP_PCIE_SSID: case X310_2940R_40MHz_PCIE_SSID: case X310_2940R_120MHz_PCIE_SSID: case X310_2942R_40MHz_PCIE_SSID: case X310_2942R_120MHz_PCIE_SSID: case X310_2943R_40MHz_PCIE_SSID: case X310_2943R_120MHz_PCIE_SSID: case X310_2944R_40MHz_PCIE_SSID: case X310_2950R_40MHz_PCIE_SSID: case X310_2950R_120MHz_PCIE_SSID: case X310_2952R_40MHz_PCIE_SSID: case X310_2952R_120MHz_PCIE_SSID: case X310_2953R_40MHz_PCIE_SSID: case X310_2953R_120MHz_PCIE_SSID: case X310_2954R_40MHz_PCIE_SSID: mb_type = USRP_X310_MB; break; default: mb_type = UNKNOWN; break; } } } return mb_type; } x300_impl::x300_mboard_t x300_impl::get_mb_type_from_eeprom(const uhd::usrp::mboard_eeprom_t& mb_eeprom) { x300_mboard_t mb_type = UNKNOWN; if (not mb_eeprom["product"].empty()) { boost::uint16_t product_num = 0; try { product_num = boost::lexical_cast(mb_eeprom["product"]); } catch (const boost::bad_lexical_cast &) { product_num = 0; } switch (product_num) { //The PCIe ID -> MB mapping may be different from the EEPROM -> MB mapping case X300_USRP_PCIE_SSID: mb_type = USRP_X300_MB; break; case X310_USRP_PCIE_SSID: case X310_2940R_40MHz_PCIE_SSID: case X310_2940R_120MHz_PCIE_SSID: case X310_2942R_40MHz_PCIE_SSID: case X310_2942R_120MHz_PCIE_SSID: case X310_2943R_40MHz_PCIE_SSID: case X310_2943R_120MHz_PCIE_SSID: case X310_2944R_40MHz_PCIE_SSID: case X310_2950R_40MHz_PCIE_SSID: case X310_2950R_120MHz_PCIE_SSID: case X310_2952R_40MHz_PCIE_SSID: case X310_2952R_120MHz_PCIE_SSID: case X310_2953R_40MHz_PCIE_SSID: case X310_2953R_120MHz_PCIE_SSID: case X310_2954R_40MHz_PCIE_SSID: mb_type = USRP_X310_MB; break; default: UHD_MSG(warning) << "X300 unknown product code in EEPROM: " << product_num << std::endl; mb_type = UNKNOWN; break; } } return mb_type; }