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|
//
// 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 <http://www.gnu.org/licenses/>.
//
#include "x300_impl.hpp"
#include "x300_lvbitx.hpp"
#include "x310_lvbitx.hpp"
#include <boost/algorithm/string.hpp>
#include <boost/asio.hpp>
#include "apply_corrections.hpp"
#include <uhd/utils/static.hpp>
#include <uhd/utils/msg.hpp>
#include <uhd/utils/paths.hpp>
#include <uhd/utils/safe_call.hpp>
#include <uhd/usrp/subdev_spec.hpp>
#include <uhd/transport/if_addrs.hpp>
#include <boost/foreach.hpp>
#include <boost/bind.hpp>
#include <boost/functional/hash.hpp>
#include <boost/assign/list_of.hpp>
#include <fstream>
#include <uhd/transport/udp_zero_copy.hpp>
#include <uhd/transport/udp_constants.hpp>
#include <uhd/transport/nirio_zero_copy.hpp>
#include <uhd/transport/nirio/niusrprio_session.h>
#include <uhd/utils/platform.hpp>
#include <boost/date_time/posix_time/posix_time_io.hpp>
#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<boost::uint32_t>(X300_FW_COMMS_FLAGS_ACK);
request.sequence = uhd::htonx<boost::uint32_t>(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<wb_iface> > 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;
}
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<std::string>("/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<std::string>(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 \
drivers have loaded successfully.");
}
//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<double>(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<size_t>(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<size_t>(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<double>(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<wb_iface>(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 numbers
//check fpga compat before fw compat because the fw is a subset of the fpga image
this->check_fpga_compat(mb_path, mb);
this->check_fw_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<mboard_eeprom_t>(mb_path / "eeprom")
.set(mb_eeprom)
.subscribe(boost::bind(&x300_impl::set_mb_eeprom, this, mb.zpu_i2c, _1));
bool recover_mb_eeprom = dev_addr.has_key("recover_mb_eeprom");
if (recover_mb_eeprom) {
UHD_MSG(warning) << "UHD is operating in EEPROM Recovery Mode which disables hardware version "
"checks.\nOperating in this mode may cause hardware damage and unstable "
"radio performance!"<< std::endl;
}
////////////////////////////////////////////////////////////////////
// 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:
if (not recover_mb_eeprom)
throw uhd::runtime_error("Unrecognized product type.\n"
"Either the software does not support this device in which case please update your driver software to the latest version and retry OR\n"
"The product code in the EEPROM is corrupt and may require reprogramming.");
}
_tree->create<std::string>(mb_path / "name").set(product_name);
_tree->create<std::string>(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);
}
////////////////////////////////////////////////////////////////////
// read hardware revision and compatibility number
////////////////////////////////////////////////////////////////////
mb.hw_rev = 0;
if(mb_eeprom.has_key("revision") and not mb_eeprom["revision"].empty()) {
try {
mb.hw_rev = boost::lexical_cast<size_t>(mb_eeprom["revision"]);
} catch(...) {
if (not recover_mb_eeprom)
throw uhd::runtime_error("Revision in EEPROM is invalid! Please reprogram your EEPROM.");
}
} else {
if (not recover_mb_eeprom)
throw uhd::runtime_error("No revision detected. MB EEPROM must be reprogrammed!");
}
size_t hw_rev_compat = 0;
if (mb.hw_rev >= 7) { //Revision compat was added with revision 7
if (mb_eeprom.has_key("revision_compat") and not mb_eeprom["revision_compat"].empty()) {
try {
hw_rev_compat = boost::lexical_cast<size_t>(mb_eeprom["revision_compat"]);
} catch(...) {
if (not recover_mb_eeprom)
throw uhd::runtime_error("Revision compat in EEPROM is invalid! Please reprogram your EEPROM.");
}
} else {
if (not recover_mb_eeprom)
throw uhd::runtime_error("No revision compat detected. MB EEPROM must be reprogrammed!");
}
} else {
//For older HW just assume that revision_compat = revision
hw_rev_compat = mb.hw_rev;
}
if (hw_rev_compat > X300_REVISION_COMPAT) {
if (not recover_mb_eeprom)
throw uhd::runtime_error(str(boost::format(
"Hardware is too new for this software. Please upgrade to a driver that supports hardware revision %d.")
% mb.hw_rev));
} else if (mb.hw_rev < X300_REVISION_MIN) { //Compare min against the revision (and not compat) to give us more leeway for partial support for a compat
if (not recover_mb_eeprom)
throw uhd::runtime_error(str(boost::format(
"Software is too new for this hardware. Please downgrade to a driver that supports hardware revision %d.")
% mb.hw_rev));
}
////////////////////////////////////////////////////////////////////
// create clock control objects
////////////////////////////////////////////////////////////////////
UHD_MSG(status) << "Setup RF frontend clocking..." << std::endl;
//Initialize clock control registers. 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<double>("master_clock_rate", X300_DEFAULT_TICK_RATE),
dev_addr.cast<double>("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<double>(mb_path / "tick_rate")
.publish(boost::bind(&x300_clock_ctrl::get_master_clock_rate, mb.clock));
_tree->create<time_spec_t>(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<sensor_value_t>(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
////////////////////////////////////////////////////////////////////
this->setup_radio(mb_i, "A", dev_addr);
this->setup_radio(mb_i, "B", dev_addr);
////////////////////////////////////////////////////////////////////
// ADC test and cal
////////////////////////////////////////////////////////////////////
if (dev_addr.has_key("self_cal_adc_delay")) {
self_cal_adc_xfer_delay(mb, true /* Apply ADC delay */);
}
if (dev_addr.has_key("ext_adc_self_test")) {
extended_adc_test(mb, dev_addr.cast<double>("ext_adc_self_test", 30));
} else {
self_test_adcs(mb);
}
////////////////////////////////////////////////////////////////////
// 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<boost::uint32_t>(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<boost::uint32_t>(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<time_spec_t>(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<time_spec_t>(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<std::string>(mb_path / "time_source" / "value")
.set("internal")
.subscribe(boost::bind(&x300_impl::update_time_source, this, boost::ref(mb), _1));
static const std::vector<std::string> time_sources = boost::assign::list_of("internal")("external")("gpsdo");
_tree->create<std::vector<std::string> >(mb_path / "time_source" / "options").set(time_sources);
//setup the time output, default to ON
_tree->create<bool>(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<std::string>(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<std::string> clock_source_options = boost::assign::list_of("internal")("external")("gpsdo");
_tree->create<std::vector<std::string> >(mb_path / "clock_source" / "options").set(clock_source_options);
//setup external reference options. default to 10 MHz input reference
_tree->create<std::string>(mb_path / "clock_source" / "external");
static const std::vector<double> external_freq_options = boost::assign::list_of(10e6)(30.72e6)(200e6);
_tree->create<std::vector<double> >(mb_path / "clock_source" / "external" / "freq" / "options")
.set(external_freq_options);
_tree->create<double>(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<bool>(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<double>(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<std::string>(mb_path / "clock_source" / "value").set("gpsdo");
_tree->access<std::string>(mb_path / "time_source" / "value").set("gpsdo");
const time_t tp = time_t(mb.gps->get_sensor("gps_time").to_int() + 1);
_tree->access<time_spec_t>(mb_path / "time" / "pps").set(time_spec_t(tp));
} else {
UHD_MSG(status) << "Initializing clock and time using internal sources... " << std::flush;
_tree->access<std::string>(mb_path / "clock_source" / "value").set("internal");
_tree->access<std::string>(mb_path / "time_source" / "value").set("internal");
}
UHD_MSG(status) << "done" << std::endl;
////////////////////////////////////////////////////////////////////
// create frontend mapping
////////////////////////////////////////////////////////////////////
std::vector<size_t> default_map(2, 0); default_map[1] = 1;
_tree->create<std::vector<size_t> >(mb_path / "rx_chan_dsp_mapping").set(default_map);
_tree->create<std::vector<size_t> >(mb_path / "tx_chan_dsp_mapping").set(default_map);
_tree->create<subdev_spec_t>(mb_path / "rx_subdev_spec")
.subscribe(boost::bind(&x300_impl::update_subdev_spec, this, "rx", mb_i, _1));
_tree->create<subdev_spec_t>(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<sensor_value_t>(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<subdev_spec_t>(mb_path / "rx_subdev_spec").set(rx_fe_spec);
_tree->access<subdev_spec_t>(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)
{
//disable/reset ADC/DAC
mb.radio_perifs[0].misc_outs->set(radio_misc_outs_reg::ADC_RESET, 1);
mb.radio_perifs[0].misc_outs->set(radio_misc_outs_reg::DAC_RESET_N, 0);
mb.radio_perifs[0].misc_outs->set(radio_misc_outs_reg::DAC_ENABLED, 0);
mb.radio_perifs[0].misc_outs->flush();
mb.radio_perifs[1].misc_outs->set(radio_misc_outs_reg::ADC_RESET, 1);
mb.radio_perifs[1].misc_outs->set(radio_misc_outs_reg::DAC_RESET_N, 0);
mb.radio_perifs[1].misc_outs->set(radio_misc_outs_reg::DAC_ENABLED, 0);
mb.radio_perifs[1].misc_outs->flush();
//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;)
}
}
void x300_impl::setup_radio(const size_t mb_i, const std::string &slot_name, const uhd::device_addr_t &dev_addr)
{
const fs_path mb_path = "/mboards/"+boost::lexical_cast<std::string>(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];
UHD_MSG(status) << boost::format("Initialize Radio%d control...") % radio_index << std::endl;
////////////////////////////////////////////////////////////////////
// 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.misc_outs = boost::make_shared<radio_misc_outs_reg>();
perif.misc_ins = boost::make_shared<radio_misc_ins_reg>();
perif.misc_outs->initialize(*perif.ctrl, true);
perif.misc_ins->initialize(*perif.ctrl);
//reset adc + dac
perif.misc_outs->set(radio_misc_outs_reg::ADC_RESET, 1);
perif.misc_outs->set(radio_misc_outs_reg::DAC_RESET_N, 0);
perif.misc_outs->flush();
perif.misc_outs->set(radio_misc_outs_reg::ADC_RESET, 0);
perif.misc_outs->set(radio_misc_outs_reg::DAC_RESET_N, 1);
perif.misc_outs->set(radio_misc_outs_reg::DAC_ENABLED, 1);
perif.misc_outs->flush();
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));
//Capture delays are calibrated every time. The status is only printed is the user
//asks to run the xfer self cal using "self_cal_adc_delay"
self_cal_adc_capture_delay(mb, radio_index, dev_addr.has_key("self_cal_adc_delay"));
_tree->access<time_spec_t>(mb_path / "time" / "cmd")
.subscribe(boost::bind(&radio_ctrl_core_3000::set_time, perif.ctrl, _1));
_tree->access<double>(mb_path / "tick_rate")
.subscribe(boost::bind(&radio_ctrl_core_3000::set_tick_rate, perif.ctrl, _1));
////////////////////////////////////////////////////////////////
// create codec control objects
////////////////////////////////////////////////////////////////
_tree->create<int>(mb_path / "rx_codecs" / slot_name / "gains"); //phony property so this dir exists
_tree->create<int>(mb_path / "tx_codecs" / slot_name / "gains"); //phony property so this dir exists
_tree->create<std::string>(mb_path / "rx_codecs" / slot_name / "name").set("ads62p48");
_tree->create<std::string>(mb_path / "tx_codecs" / slot_name / "name").set("ad9146");
_tree->create<meta_range_t>(mb_path / "rx_codecs" / slot_name / "gains" / "digital" / "range").set(meta_range_t(0, 6.0, 0.5));
_tree->create<double>(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<std::complex<double> >(rx_fe_path / "dc_offset" / "value")
.coerce(boost::bind(&rx_frontend_core_200::set_dc_offset, perif.rx_fe, _1))
.set(std::complex<double>(0.0, 0.0));
_tree->create<bool>(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<std::complex<double> >(rx_fe_path / "iq_balance" / "value")
.subscribe(boost::bind(&rx_frontend_core_200::set_iq_balance, perif.rx_fe, _1))
.set(std::complex<double>(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<std::complex<double> >(tx_fe_path / "dc_offset" / "value")
.coerce(boost::bind(&tx_frontend_core_200::set_dc_offset, perif.tx_fe, _1))
.set(std::complex<double>(0.0, 0.0));
_tree->create<std::complex<double> >(tx_fe_path / "iq_balance" / "value")
.subscribe(boost::bind(&tx_frontend_core_200::set_iq_balance, perif.tx_fe, _1))
.set(std::complex<double>(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<double>(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<meta_range_t>(rx_dsp_path / "rate" / "range")
.publish(boost::bind(&rx_dsp_core_3000::get_host_rates, perif.ddc));
_tree->create<double>(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<double>(rx_dsp_path / "freq" / "value")
.coerce(boost::bind(&rx_dsp_core_3000::set_freq, perif.ddc, _1))
.set(0.0);
_tree->create<meta_range_t>(rx_dsp_path / "freq" / "range")
.publish(boost::bind(&rx_dsp_core_3000::get_freq_range, perif.ddc));
_tree->create<stream_cmd_t>(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<double>(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<meta_range_t>(tx_dsp_path / "rate" / "range")
.publish(boost::bind(&tx_dsp_core_3000::get_host_rates, perif.duc));
_tree->create<double>(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<double>(tx_dsp_path / "freq" / "value")
.coerce(boost::bind(&tx_dsp_core_3000::set_freq, perif.duc, _1))
.set(0.0);
_tree->create<meta_range_t>(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<dboard_eeprom_t>(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<dboard_eeprom_t>(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<dboard_eeprom_t>(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;
db_config.cmd_time_ctrl = perif.ctrl;
_dboard_ifaces[db_path] = x300_make_dboard_iface(db_config);
//create a new dboard manager
_tree->create<dboard_iface::sptr>(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<std::string>(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<double>(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<double>(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<double>("/mboards/"+boost::lexical_cast<std::string>(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<double>("/mboards/"+boost::lexical_cast<std::string>(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<double>("/mboards/"+boost::lexical_cast<std::string>(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<boost::uint32_t *>()[0] = 0; //eth dispatch looks for != 0
buff->cast<boost::uint32_t *>()[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<radio_perifs_t*>& 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<boost::uint8_t> buffer(std::max(user_frame_size.recv_frame_size, user_frame_size.send_frame_size));
x300_mtu_t *request = reinterpret_cast<x300_mtu_t *>(&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<boost::uint32_t>(X300_MTU_DETECT_ECHO_REQUEST);
request->size = uhd::htonx<boost::uint32_t>(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<boost::uint32_t>(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<boost::uint32_t>(X300_MTU_DETECT_ECHO_REQUEST);
request->size = uhd::htonx<boost::uint32_t>(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<boost::uint32_t>(X300_MTU_DETECT_ECHO_REQUEST);
request->size = uhd::htonx<boost::uint32_t>(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<boost::uint32_t>(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<std::string>(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, const mboard_members_t &members)
{
boost::uint32_t compat_num = members.zpu_ctrl->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)
{
std::string image_loader_path = (fs::path(uhd::get_pkg_path()) / "bin" / "uhd_image_loader").string();
std::string image_loader_cmd = str(boost::format("\"%s\" --args=\"type=x300,%s=%s\"")
% image_loader_path
% (members.xport_path == "eth" ? "addr"
: "resource")
% members.addr);
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 image loader utility. Use this command:\n\n%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")
% image_loader_cmd));
}
_tree->create<std::string>(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_ADC_33:
case X300_USRP_PCIE_SSID_ADC_18:
mb_type = USRP_X300_MB; break;
case X310_USRP_PCIE_SSID_ADC_33:
case X310_2940R_40MHz_PCIE_SSID_ADC_33:
case X310_2940R_120MHz_PCIE_SSID_ADC_33:
case X310_2942R_40MHz_PCIE_SSID_ADC_33:
case X310_2942R_120MHz_PCIE_SSID_ADC_33:
case X310_2943R_40MHz_PCIE_SSID_ADC_33:
case X310_2943R_120MHz_PCIE_SSID_ADC_33:
case X310_2944R_40MHz_PCIE_SSID_ADC_33:
case X310_2950R_40MHz_PCIE_SSID_ADC_33:
case X310_2950R_120MHz_PCIE_SSID_ADC_33:
case X310_2952R_40MHz_PCIE_SSID_ADC_33:
case X310_2952R_120MHz_PCIE_SSID_ADC_33:
case X310_2953R_40MHz_PCIE_SSID_ADC_33:
case X310_2953R_120MHz_PCIE_SSID_ADC_33:
case X310_2954R_40MHz_PCIE_SSID_ADC_33:
case X310_USRP_PCIE_SSID_ADC_18:
case X310_2940R_40MHz_PCIE_SSID_ADC_18:
case X310_2940R_120MHz_PCIE_SSID_ADC_18:
case X310_2942R_40MHz_PCIE_SSID_ADC_18:
case X310_2942R_120MHz_PCIE_SSID_ADC_18:
case X310_2943R_40MHz_PCIE_SSID_ADC_18:
case X310_2943R_120MHz_PCIE_SSID_ADC_18:
case X310_2944R_40MHz_PCIE_SSID_ADC_18:
case X310_2950R_40MHz_PCIE_SSID_ADC_18:
case X310_2950R_120MHz_PCIE_SSID_ADC_18:
case X310_2952R_40MHz_PCIE_SSID_ADC_18:
case X310_2952R_120MHz_PCIE_SSID_ADC_18:
case X310_2953R_40MHz_PCIE_SSID_ADC_18:
case X310_2953R_120MHz_PCIE_SSID_ADC_18:
case X310_2954R_40MHz_PCIE_SSID_ADC_18:
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<boost::uint16_t>(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_ADC_33:
case X300_USRP_PCIE_SSID_ADC_18:
mb_type = USRP_X300_MB; break;
case X310_USRP_PCIE_SSID_ADC_33:
case X310_2940R_40MHz_PCIE_SSID_ADC_33:
case X310_2940R_120MHz_PCIE_SSID_ADC_33:
case X310_2942R_40MHz_PCIE_SSID_ADC_33:
case X310_2942R_120MHz_PCIE_SSID_ADC_33:
case X310_2943R_40MHz_PCIE_SSID_ADC_33:
case X310_2943R_120MHz_PCIE_SSID_ADC_33:
case X310_2944R_40MHz_PCIE_SSID_ADC_33:
case X310_2950R_40MHz_PCIE_SSID_ADC_33:
case X310_2950R_120MHz_PCIE_SSID_ADC_33:
case X310_2952R_40MHz_PCIE_SSID_ADC_33:
case X310_2952R_120MHz_PCIE_SSID_ADC_33:
case X310_2953R_40MHz_PCIE_SSID_ADC_33:
case X310_2953R_120MHz_PCIE_SSID_ADC_33:
case X310_2954R_40MHz_PCIE_SSID_ADC_33:
case X310_USRP_PCIE_SSID_ADC_18:
case X310_2940R_40MHz_PCIE_SSID_ADC_18:
case X310_2940R_120MHz_PCIE_SSID_ADC_18:
case X310_2942R_40MHz_PCIE_SSID_ADC_18:
case X310_2942R_120MHz_PCIE_SSID_ADC_18:
case X310_2943R_40MHz_PCIE_SSID_ADC_18:
case X310_2943R_120MHz_PCIE_SSID_ADC_18:
case X310_2944R_40MHz_PCIE_SSID_ADC_18:
case X310_2950R_40MHz_PCIE_SSID_ADC_18:
case X310_2950R_120MHz_PCIE_SSID_ADC_18:
case X310_2952R_40MHz_PCIE_SSID_ADC_18:
case X310_2952R_120MHz_PCIE_SSID_ADC_18:
case X310_2953R_40MHz_PCIE_SSID_ADC_18:
case X310_2953R_120MHz_PCIE_SSID_ADC_18:
case X310_2954R_40MHz_PCIE_SSID_ADC_18:
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;
}
void x300_impl::self_cal_adc_capture_delay(mboard_members_t& mb, const size_t radio_i, bool print_status)
{
radio_perifs_t& perif = mb.radio_perifs[radio_i];
if (print_status) UHD_MSG(status) << "Running ADC capture delay self-cal..." << std::flush;
static const boost::uint32_t NUM_DELAY_STEPS = 32; //The IDELAYE2 element has 32 steps
static const boost::uint32_t NUM_RETRIES = 2; //Retry self-cal if it fails in warmup situations
static const boost::int32_t MIN_WINDOW_LEN = 4;
boost::int32_t win_start = -1, win_stop = -1;
boost::uint32_t iter = 0;
while (iter++ < NUM_RETRIES) {
for (boost::uint32_t dly_tap = 0; dly_tap < NUM_DELAY_STEPS; dly_tap++) {
//Apply delay
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_VAL, dly_tap);
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_STB, 1);
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_STB, 0);
boost::uint32_t err_code = 0;
// -- Test I Channel --
//Put ADC in ramp test mode. Tie the other channel to all ones.
perif.adc->set_test_word("ramp", "ones");
//Turn on the pattern checker in the FPGA. It will lock when it sees a zero
//and count deviations from the expected value
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 1);
//10ms @ 200MHz = 2 million samples
boost::this_thread::sleep(boost::posix_time::milliseconds(10));
if (perif.misc_ins->read(radio_misc_ins_reg::ADC_CHECKER0_I_LOCKED)) {
err_code += perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER0_I_ERROR);
} else {
err_code += 100; //Increment error code by 100 to indicate no lock
}
// -- Test Q Channel --
//Put ADC in ramp test mode. Tie the other channel to all ones.
perif.adc->set_test_word("ones", "ramp");
//Turn on the pattern checker in the FPGA. It will lock when it sees a zero
//and count deviations from the expected value
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 1);
//10ms @ 200MHz = 2 million samples
boost::this_thread::sleep(boost::posix_time::milliseconds(10));
if (perif.misc_ins->read(radio_misc_ins_reg::ADC_CHECKER0_Q_LOCKED)) {
err_code += perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER0_Q_ERROR);
} else {
err_code += 100; //Increment error code by 100 to indicate no lock
}
if (err_code == 0) {
if (win_start == -1) { //This is the first window
win_start = dly_tap;
win_stop = dly_tap;
} else { //We are extending the window
win_stop = dly_tap;
}
} else {
if (win_start != -1) { //A valid window turned invalid
if (win_stop - win_start >= MIN_WINDOW_LEN) {
break; //Valid window found
} else {
win_start = -1; //Reset window
}
}
}
//UHD_MSG(status) << (boost::format("CapTap=%d, Error=%d\n") % dly_tap % err_code);
}
//Retry the self-cal if it fails
if ((win_start == -1 || (win_stop - win_start) < MIN_WINDOW_LEN) && iter < NUM_RETRIES /*not last iteration*/) {
win_start = -1;
win_stop = -1;
boost::this_thread::sleep(boost::posix_time::milliseconds(2000));
} else {
break;
}
}
perif.adc->set_test_word("normal", "normal");
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
if (win_start == -1) {
throw uhd::runtime_error("self_cal_adc_capture_delay: Self calibration failed. Convergence error.");
}
if (win_stop-win_start < MIN_WINDOW_LEN) {
throw uhd::runtime_error("self_cal_adc_capture_delay: Self calibration failed. Valid window too narrow.");
}
boost::uint32_t ideal_tap = (win_stop + win_start) / 2;
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_VAL, ideal_tap);
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_STB, 1);
perif.misc_outs->write(radio_misc_outs_reg::ADC_DATA_DLY_STB, 0);
if (print_status) {
double tap_delay = (1.0e12 / mb.clock->get_master_clock_rate()) / (2*32); //in ps
UHD_MSG(status) << boost::format(" done (Tap=%d, Window=%d, TapDelay=%.3fps, Iter=%d)\n") % ideal_tap % (win_stop-win_start) % tap_delay % iter;
}
}
double x300_impl::self_cal_adc_xfer_delay(mboard_members_t& mb, bool apply_delay)
{
UHD_MSG(status) << "Running ADC transfer delay self-cal: " << std::flush;
//Effective resolution of the self-cal.
static const size_t NUM_DELAY_STEPS = 100;
double master_clk_period = (1.0e9 / mb.clock->get_master_clock_rate()); //in ns
double delay_start = 0.0;
double delay_range = 2 * master_clk_period;
double delay_incr = delay_range / NUM_DELAY_STEPS;
UHD_MSG(status) << "Measuring..." << std::flush;
double cached_clk_delay = mb.clock->get_clock_delay(X300_CLOCK_WHICH_ADC0);
double fpga_clk_delay = mb.clock->get_clock_delay(X300_CLOCK_WHICH_FPGA);
//Iterate through several values of delays and measure ADC data integrity
std::vector< std::pair<double,bool> > results;
for (size_t i = 0; i < NUM_DELAY_STEPS; i++) {
//Delay the ADC clock (will set both Ch0 and Ch1 delays)
double delay = mb.clock->set_clock_delay(X300_CLOCK_WHICH_ADC0, delay_incr*i + delay_start);
wait_for_ref_locked(mb.zpu_ctrl, 0.1);
boost::uint32_t err_code = 0;
for (size_t r = 0; r < mboard_members_t::NUM_RADIOS; r++) {
//Test each channel (I and Q) individually so as to not accidentally trigger
//on the data from the other channel if there is a swap
// -- Test I Channel --
//Put ADC in ramp test mode. Tie the other channel to all ones.
mb.radio_perifs[r].adc->set_test_word("ramp", "ones");
//Turn on the pattern checker in the FPGA. It will lock when it sees a zero
//and count deviations from the expected value
mb.radio_perifs[r].misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
mb.radio_perifs[r].misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 1);
//50ms @ 200MHz = 10 million samples
boost::this_thread::sleep(boost::posix_time::milliseconds(50));
if (mb.radio_perifs[r].misc_ins->read(radio_misc_ins_reg::ADC_CHECKER1_I_LOCKED)) {
err_code += mb.radio_perifs[r].misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_I_ERROR);
} else {
err_code += 100; //Increment error code by 100 to indicate no lock
}
// -- Test Q Channel --
//Put ADC in ramp test mode. Tie the other channel to all ones.
mb.radio_perifs[r].adc->set_test_word("ones", "ramp");
//Turn on the pattern checker in the FPGA. It will lock when it sees a zero
//and count deviations from the expected value
mb.radio_perifs[r].misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
mb.radio_perifs[r].misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 1);
//50ms @ 200MHz = 10 million samples
boost::this_thread::sleep(boost::posix_time::milliseconds(50));
if (mb.radio_perifs[r].misc_ins->read(radio_misc_ins_reg::ADC_CHECKER1_Q_LOCKED)) {
err_code += mb.radio_perifs[r].misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_Q_ERROR);
} else {
err_code += 100; //Increment error code by 100 to indicate no lock
}
}
//UHD_MSG(status) << (boost::format("XferDelay=%fns, Error=%d\n") % delay % err_code);
results.push_back(std::pair<double,bool>(delay, err_code==0));
}
//Calculate the valid window
int win_start_idx = -1, win_stop_idx = -1, cur_start_idx = -1, cur_stop_idx = -1;
for (size_t i = 0; i < results.size(); i++) {
std::pair<double,bool>& item = results[i];
if (item.second) { //If data is stable
if (cur_start_idx == -1) { //This is the first window
cur_start_idx = i;
cur_stop_idx = i;
} else { //We are extending the window
cur_stop_idx = i;
}
} else {
if (cur_start_idx == -1) { //We haven't yet seen valid data
//Do nothing
} else if (win_start_idx == -1) { //We passed the first valid window
win_start_idx = cur_start_idx;
win_stop_idx = cur_stop_idx;
} else { //Update cached window if current window is larger
double cur_win_len = results[cur_stop_idx].first - results[cur_start_idx].first;
double cached_win_len = results[win_stop_idx].first - results[win_start_idx].first;
if (cur_win_len > cached_win_len) {
win_start_idx = cur_start_idx;
win_stop_idx = cur_stop_idx;
}
}
//Reset current window
cur_start_idx = -1;
cur_stop_idx = -1;
}
}
if (win_start_idx == -1) {
throw uhd::runtime_error("self_cal_adc_xfer_delay: Self calibration failed. Convergence error.");
}
double win_center = (results[win_stop_idx].first + results[win_start_idx].first) / 2.0;
double win_length = results[win_stop_idx].first - results[win_start_idx].first;
if (win_length < master_clk_period/4) {
throw uhd::runtime_error("self_cal_adc_xfer_delay: Self calibration failed. Valid window too narrow.");
}
//Cycle slip the relative delay by a clock cycle to prevent sample misalignment
//fpga_clk_delay > 0 and 0 < win_center < 2*(1/MCR) so one cycle slip is all we need
bool cycle_slip = (win_center-fpga_clk_delay >= master_clk_period);
if (cycle_slip) {
win_center -= master_clk_period;
}
if (apply_delay) {
UHD_MSG(status) << "Validating..." << std::flush;
//Apply delay
win_center = mb.clock->set_clock_delay(X300_CLOCK_WHICH_ADC0, win_center); //Sets ADC0 and ADC1
wait_for_ref_locked(mb.zpu_ctrl, 0.1);
//Validate
self_test_adcs(mb, 2000);
} else {
//Restore delay
mb.clock->set_clock_delay(X300_CLOCK_WHICH_ADC0, cached_clk_delay); //Sets ADC0 and ADC1
}
//Teardown
for (size_t r = 0; r < mboard_members_t::NUM_RADIOS; r++) {
mb.radio_perifs[r].adc->set_test_word("normal", "normal");
mb.radio_perifs[r].misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
}
UHD_MSG(status) << (boost::format(" done (FPGA->ADC=%.3fns%s, Window=%.3fns)\n") %
(win_center-fpga_clk_delay) % (cycle_slip?" +cyc":"") % win_length);
return win_center;
}
static void check_adc(wb_iface::sptr iface, const boost::uint32_t val, const boost::uint32_t i)
{
boost::uint32_t adc_rb = iface->peek32(RB32_RX);
adc_rb ^= 0xfffc0000; //adapt for I inversion in FPGA
if (val != adc_rb) {
throw uhd::runtime_error(
(boost::format("ADC self-test failed for Radio%d. (Exp=0x%x, Got=0x%x)")%i%val%adc_rb).str());
}
}
void x300_impl::self_test_adcs(mboard_members_t& mb, boost::uint32_t ramp_time_ms) {
for (size_t r = 0; r < mboard_members_t::NUM_RADIOS; r++) {
radio_perifs_t &perif = mb.radio_perifs[r];
//First test basic patterns
perif.adc->set_test_word("ones", "ones"); check_adc(perif.ctrl, 0xfffcfffc,r);
perif.adc->set_test_word("zeros", "zeros"); check_adc(perif.ctrl, 0x00000000,r);
perif.adc->set_test_word("ones", "zeros"); check_adc(perif.ctrl, 0xfffc0000,r);
perif.adc->set_test_word("zeros", "ones"); check_adc(perif.ctrl, 0x0000fffc,r);
for (size_t k = 0; k < 14; k++)
{
perif.adc->set_test_word("zeros", "custom", 1 << k);
check_adc(perif.ctrl, 1 << (k+2),r);
}
for (size_t k = 0; k < 14; k++)
{
perif.adc->set_test_word("custom", "zeros", 1 << k);
check_adc(perif.ctrl, 1 << (k+18),r);
}
//Turn on ramp pattern test
perif.adc->set_test_word("ramp", "ramp");
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 0);
perif.misc_outs->write(radio_misc_outs_reg::ADC_CHECKER_ENABLED, 1);
}
boost::this_thread::sleep(boost::posix_time::milliseconds(ramp_time_ms));
bool passed = true;
std::string status_str;
for (size_t r = 0; r < mboard_members_t::NUM_RADIOS; r++) {
radio_perifs_t &perif = mb.radio_perifs[r];
perif.misc_ins->refresh();
std::string i_status, q_status;
if (perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_I_LOCKED))
if (perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_I_ERROR))
i_status = "Bit Errors!";
else
i_status = "Good";
else
i_status = "Not Locked!";
if (perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_Q_LOCKED))
if (perif.misc_ins->get(radio_misc_ins_reg::ADC_CHECKER1_Q_ERROR))
q_status = "Bit Errors!";
else
q_status = "Good";
else
q_status = "Not Locked!";
passed = passed && (i_status == "Good") && (q_status == "Good");
status_str += (boost::format(", ADC%d_I=%s, ADC%d_Q=%s")%r%i_status%r%q_status).str();
//Return to normal mode
perif.adc->set_test_word("normal", "normal");
}
if (not passed) {
throw uhd::runtime_error(
(boost::format("ADC self-test failed! Ramp checker status: {%s}")%status_str.substr(2)).str());
}
}
void x300_impl::extended_adc_test(mboard_members_t& mb, double duration_s)
{
static const size_t SECS_PER_ITER = 5;
UHD_MSG(status) << boost::format("Running Extended ADC Self-Test (Duration=%.0fs, %ds/iteration)...\n")
% duration_s % SECS_PER_ITER;
size_t num_iters = static_cast<size_t>(ceil(duration_s/SECS_PER_ITER));
size_t num_failures = 0;
for (size_t iter = 0; iter < num_iters; iter++) {
//Print date and time
boost::posix_time::time_facet *facet = new boost::posix_time::time_facet("%d-%b-%Y %H:%M:%S");
std::ostringstream time_strm;
time_strm.imbue(std::locale(std::locale::classic(), facet));
time_strm << boost::posix_time::second_clock::local_time();
//Run self-test
UHD_MSG(status) << boost::format("-- [%s] Iteration %06d... ") % time_strm.str() % (iter+1);
try {
self_test_adcs(mb, SECS_PER_ITER*1000);
UHD_MSG(status) << "passed" << std::endl;
} catch(std::exception &e) {
num_failures++;
UHD_MSG(status) << e.what() << std::endl;
}
}
if (num_failures == 0) {
UHD_MSG(status) << "Extended ADC Self-Test PASSED\n";
} else {
throw uhd::runtime_error(
(boost::format("Extended ADC Self-Test FAILED!!! (%d/%d failures)\n") % num_failures % num_iters).str());
}
}
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