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|
//
// Copyright 2017 Ettus Research, a National Instruments Company
//
// SPDX-License-Identifier: GPL-3.0
//
#include "mpmd_impl.hpp"
#include "rpc_block_ctrl.hpp"
#include <../device3/device3_impl.hpp>
#include <uhd/exception.hpp>
#include <uhd/property_tree.hpp>
#include <uhd/transport/if_addrs.hpp>
#include <uhd/transport/udp_simple.hpp>
#include <uhd/utils/static.hpp>
#include <uhd/utils/tasks.hpp>
#include <uhd/types/sensors.hpp>
#include <uhd/types/eeprom.hpp>
#include <uhd/types/component_file.hpp>
#include <uhd/usrp/mboard_eeprom.hpp>
#include <boost/algorithm/string.hpp>
#include <boost/asio.hpp>
#include <boost/make_shared.hpp>
#include <boost/thread.hpp>
#include <memory>
#include <mutex>
#include <random>
#include <string>
#include <vector>
using namespace uhd;
using namespace uhd::mpmd;
namespace {
/*************************************************************************
* Local constants
************************************************************************/
const size_t MPMD_CROSSBAR_MAX_LADDR = 255;
//! How long we wait for discovery responses (in seconds)
const double MPMD_FIND_TIMEOUT = 0.5;
//! Most pessimistic time for a CHDR query to go to device and back
const double MPMD_CHDR_MAX_RTT = 0.02;
//! MPM Compatibility number
const std::vector<size_t> MPM_COMPAT_NUM = {1, 0};
/*************************************************************************
* Helper functions
************************************************************************/
uhd::usrp::component_files_t _update_component(
const uhd::usrp::component_files_t& comps,
mpmd_mboard_impl *mb
) {
// Construct the arguments to update component
std::vector<std::vector<uint8_t>> all_data;
std::vector<std::map<std::string, std::string>> all_metadata;
// Also construct a copy of just the metadata to store in the property tree
uhd::usrp::component_files_t all_comps_copy;
for (const auto& comp : comps) {
// Make a map for update components args
std::map<std::string, std::string> metadata;
// Make a component copy to add to the property tree
uhd::usrp::component_file_t comp_copy;
// Copy the metadata
for (const auto& key : comp.metadata.keys()) {
metadata[key] = comp.metadata[key];
comp_copy.metadata[key] = comp.metadata[key];
}
// Copy to the update component args
all_data.push_back(comp.data);
all_metadata.push_back(metadata);
// Copy to the property tree
all_comps_copy.push_back(comp_copy);
}
// Now call update component
mb->rpc->notify_with_token("update_component", all_metadata, all_data);
return all_comps_copy;
}
void init_property_tree(
uhd::property_tree::sptr tree,
fs_path mb_path,
mpmd_mboard_impl *mb
) {
if (not tree->exists(fs_path("/name"))) {
tree->create<std::string>("/name")
.set(mb->device_info.get("name", "Unknown MPM device"))
;
}
/*** Clocking *******************************************************/
tree->create<std::string>(mb_path / "clock_source/value")
.add_coerced_subscriber([mb](const std::string &clock_source){
// FIXME: Undo these changes
//mb->rpc->notify_with_token("set_clock_source", clock_source);
auto current_src = mb->rpc->request_with_token<std::string>(
"get_clock_source"
);
if (current_src != clock_source) {
UHD_LOG_WARNING("MPMD",
"Setting clock source at runtime is currently not "
"supported. Use clock_source=XXX as a device arg to "
"select a clock source. The current source is: "
<< current_src);
}
})
.set_publisher([mb](){
return mb->rpc->request_with_token<std::string>(
"get_clock_source"
);
})
;
tree->create<std::vector<std::string>>(
mb_path / "clock_source/options")
.set_publisher([mb](){
return mb->rpc->request_with_token<std::vector<std::string>>(
"get_clock_sources"
);
})
;
tree->create<std::string>(mb_path / "time_source/value")
.add_coerced_subscriber([mb](const std::string &time_source){
//mb->rpc->notify_with_token("set_time_source", time_source);
// FIXME: Undo these changes
auto current_src = mb->rpc->request_with_token<std::string>(
"get_time_source"
);
if (current_src != time_source) {
UHD_LOG_WARNING("MPMD",
"Setting time source at runtime is currently not "
"supported. Use time_source=XXX as a device arg to "
"select a time source. The current source is: "
<< current_src);
}
})
.set_publisher([mb](){
return mb->rpc->request_with_token<std::string>(
"get_time_source"
);
})
;
tree->create<std::vector<std::string>>(
mb_path / "time_source/options")
.set_publisher([mb](){
return mb->rpc->request_with_token<std::vector<std::string>>(
"get_time_sources"
);
})
;
/*** Sensors ********************************************************/
auto sensor_list =
mb->rpc->request_with_token<std::vector<std::string>>(
"get_mb_sensors"
);
UHD_LOG_DEBUG("MPMD",
"Found " << sensor_list.size() << " motherboard sensors."
);
for (const auto& sensor_name : sensor_list) {
UHD_LOG_TRACE("MPMD",
"Adding motherboard sensor `" << sensor_name << "'"
);
tree->create<sensor_value_t>(
mb_path / "sensors" / sensor_name)
.set_publisher([mb, sensor_name](){
return sensor_value_t(
mb->rpc->request_with_token<sensor_value_t::sensor_map_t>(
"get_mb_sensor", sensor_name
)
);
})
.set_coercer([](const sensor_value_t &){
throw uhd::runtime_error(
"Trying to write read-only sensor value!"
);
return sensor_value_t("", "", "");
})
;
}
/*** EEPROM *********************************************************/
tree->create<uhd::usrp::mboard_eeprom_t>(mb_path / "eeprom")
.add_coerced_subscriber([mb](const uhd::usrp::mboard_eeprom_t& mb_eeprom){
eeprom_map_t eeprom_map;
for (const auto& key : mb_eeprom.keys()) {
eeprom_map[key] = std::vector<uint8_t>(
mb_eeprom[key].cbegin(),
mb_eeprom[key].cend()
);
}
mb->rpc->notify_with_token("set_mb_eeprom", eeprom_map);
})
.set_publisher([mb](){
auto mb_eeprom =
mb->rpc->request_with_token<std::map<std::string, std::string>>(
"get_mb_eeprom"
);
uhd::usrp::mboard_eeprom_t mb_eeprom_dict(
mb_eeprom.cbegin(), mb_eeprom.cend()
);
return mb_eeprom_dict;
})
;
/*** Updateable Components ******************************************/
std::vector<std::string> updateable_components =
mb->rpc->request<std::vector<std::string>>(
"list_updateable_components"
);
// TODO: Check the 'id' against the registered property
UHD_LOG_DEBUG("MPMD",
"Found " << updateable_components.size() << " updateable motherboard components."
);
for (const auto& comp_name : updateable_components) {
UHD_LOG_TRACE("MPMD",
"Adding motherboard component: " << comp_name);
tree->create<uhd::usrp::component_files_t>(mb_path / "components" / comp_name)
.set_coercer([mb](const uhd::usrp::component_files_t& comp_files) {
return _update_component(
comp_files,
mb
);
})
;
}
/*** MTUs ***********************************************************/
tree->create<size_t>(mb_path / "mtu/recv")
.add_coerced_subscriber([](const size_t){
throw uhd::runtime_error(
"Attempting to write read-only value (MTU)!");
})
.set_publisher([mb](){
return mb->get_mtu(uhd::RX_DIRECTION);
})
;
tree->create<size_t>(mb_path / "mtu/send")
.add_coerced_subscriber([](const size_t){
throw uhd::runtime_error(
"Attempting to write read-only value (MTU)!");
})
.set_publisher([mb](){
return mb->get_mtu(uhd::TX_DIRECTION);
})
;
}
void reset_time_synchronized(uhd::property_tree::sptr tree)
{
const size_t n_mboards = tree->list("/mboards").size();
UHD_LOGGER_DEBUG("MPMD")
<< "Synchronizing " << n_mboards <<" timekeepers...";
auto get_time_last_pps = [tree](){
return tree->access<time_spec_t>(
fs_path("/mboards/0/time/pps")
).get();
};
auto end_time = std::chrono::steady_clock::now()
+ std::chrono::milliseconds(1100);
auto time_last_pps = get_time_last_pps();
UHD_LOG_DEBUG("MPMD", "Waiting for PPS clock edge...");
while (time_last_pps == get_time_last_pps())
{
if (std::chrono::steady_clock::now() > end_time) {
throw uhd::runtime_error(
"Board 0 may not be getting a PPS signal!\n"
"No PPS detected within the time interval.\n"
"See the application notes for your device.\n"
);
}
std::this_thread::sleep_for(std::chrono::milliseconds(10));
}
UHD_LOG_DEBUG("MPMD", "Setting all timekeepers to 0...");
for (size_t mboard_idx = 0; mboard_idx < n_mboards; mboard_idx++) {
tree->access<time_spec_t>(
fs_path("/mboards") / mboard_idx / "time" / "pps"
).set(time_spec_t(0.0));
}
UHD_LOG_DEBUG("MPMD", "Waiting for next PPS edge...");
std::this_thread::sleep_for(std::chrono::seconds(1));
UHD_LOG_DEBUG("MPMD", "Verifying all timekeepers are aligned...");
auto get_time_now = [tree](const size_t mb_index){
return tree->access<time_spec_t>(
fs_path("/mboards") / mb_index / "time/now"
).get();
};
for (size_t m = 1; m < n_mboards; m++){
time_spec_t time_0 = get_time_now(0);
time_spec_t time_i = get_time_now(m);
if (time_i < time_0
or (time_i - time_0) > time_spec_t(MPMD_CHDR_MAX_RTT)) {
UHD_LOGGER_WARNING("MULTI_USRP") << boost::format(
"Detected time deviation between board %d and board 0.\n"
"Board 0 time is %f seconds.\n"
"Board %d time is %f seconds.\n"
) % m % time_0.get_real_secs() % m % time_i.get_real_secs();
}
}
}
}
/*****************************************************************************
* Static class attributes
****************************************************************************/
const std::string mpmd_impl::MPM_RPC_GET_LAST_ERROR_CMD = "get_last_error";
const std::string mpmd_impl::MPM_DISCOVERY_CMD = "MPM-DISC";
const std::string mpmd_impl::MPM_ECHO_CMD = "MPM-ECHO";
/*****************************************************************************
* Structors
****************************************************************************/
mpmd_impl::mpmd_impl(const device_addr_t& device_args)
: usrp::device3_impl()
, _device_args(device_args)
{
UHD_LOGGER_INFO("MPMD")
<< "Initializing device with args: " << device_args.to_string();
const device_addrs_t mb_args = separate_device_addr(device_args);
_mb.reserve(mb_args.size());
// This can theoretically be parallelized, but then we want to make sure
// we're distributing crossbar local addresses in some orderly fashion.
// At the very least, _xbar_local_addr_ctr needs to become atomic.
for (size_t mb_i = 0; mb_i < mb_args.size(); ++mb_i) {
_mb.push_back(setup_mb(mb_i, mb_args[mb_i]));
}
// Init the prop tree before the blocks get set up -- they might need access
// to some of the properties. This also means that the prop tree is pristine
// at this point in time.
for (size_t mb_i = 0; mb_i < mb_args.size(); ++mb_i) {
init_property_tree(_tree, fs_path("/mboards") / mb_i, _mb[mb_i].get());
}
if (not device_args.has_key("skip_init")) {
// This might be parallelized. std::tasks would probably be a good way to
// do that if we want to.
for (size_t mb_i = 0; mb_i < mb_args.size(); ++mb_i) {
setup_rfnoc_blocks(mb_i, mb_args[mb_i]);
}
// FIXME this section only makes sense for when the time source is external.
// So, check for that, or something similar.
// This section of code assumes that the prop tree is set and we have access
// to the timekeepers. So don't move it anywhere else.
if (device_args.has_key("sync_time")) {
reset_time_synchronized(_tree);
}
auto filtered_block_args = device_args; // TODO actually filter
// Blocks will finalize their own setup in this function. They have (and
// might need) full access to the prop tree, the timekeepers, etc.
setup_rpc_blocks(filtered_block_args);
} else {
UHD_LOG_INFO("MPMD", "Claimed device without full initialization.");
}
}
mpmd_impl::~mpmd_impl()
{
/* nop */
}
/*****************************************************************************
* Private methods
****************************************************************************/
mpmd_mboard_impl::uptr mpmd_impl::setup_mb(
const size_t mb_index,
const uhd::device_addr_t& device_args
) {
const std::string rpc_addr = device_args.get(xport::MGMT_ADDR_KEY);
UHD_LOGGER_DEBUG("MPMD")
<< "Initializing mboard " << mb_index
<< ". Device args: `" << device_args.to_string()
<< "'. RPC address: " << rpc_addr
;
if (rpc_addr.empty()) {
UHD_LOG_ERROR("MPMD",
"Could not determine RPC address from device args: "
<< device_args.to_string());
throw uhd::runtime_error("Could not determine device RPC address.");
}
auto mb = mpmd_mboard_impl::make(device_args, rpc_addr);
// Check the compatibility number
UHD_LOGGER_TRACE("MPMD") << boost::format(
"Checking MPM compat number against ours: %i.%i")
% MPM_COMPAT_NUM[0] % MPM_COMPAT_NUM[1];
const auto compat_num = mb->rpc->request<std::vector<size_t>>("get_mpm_compat_num");
UHD_LOGGER_TRACE("MPMD") << boost::format(
"Compat number received: %d.%d")
% compat_num[0] % compat_num[1];
const size_t c_major = compat_num[0], c_minor = compat_num[1];
if (c_major != MPM_COMPAT_NUM[0]) {
UHD_LOGGER_ERROR("MPMD") << boost::format(
"MPM major compat number mismatch."
"Expected %i.%i Actual %i.%i")
% MPM_COMPAT_NUM[0] % MPM_COMPAT_NUM[1] % c_major % c_minor;
throw uhd::runtime_error("MPM compatibility number mismatch.");
}
if (c_minor < MPM_COMPAT_NUM[1]) {
UHD_LOGGER_ERROR("MPMD") << boost::format(
"MPM minor compat number mismatch."
"Expected %d.%d Actual %d.%d")
% MPM_COMPAT_NUM[0] % MPM_COMPAT_NUM[1] % c_major % c_minor;
throw uhd::runtime_error("MPM compatibility number mismatch.");
}
if (device_args.has_key("skip_init")) {
return mb;
}
for (size_t xbar_index = 0; xbar_index < mb->num_xbars; xbar_index++) {
mb->set_xbar_local_addr(xbar_index, allocate_xbar_local_addr());
}
const fs_path mb_path = fs_path("/mboards") / mb_index;
_tree->create<std::string>(mb_path / "name")
.set(mb->device_info.get("type", "UNKNOWN"));
_tree->create<std::string>(mb_path / "serial")
.set(mb->device_info.get("serial", "n/a"));
_tree->create<std::string>(mb_path / "connection")
.set(mb->device_info.get("connection", "remote"));
_tree->create<size_t>(mb_path / "link_max_rate").set(1e9 / 8);
return mb;
}
void mpmd_impl::setup_rfnoc_blocks(
const size_t mb_index,
const uhd::device_addr_t& ctrl_xport_args
) {
auto &mb = _mb[mb_index];
mb->num_xbars = mb->rpc->request<size_t>("get_num_xbars");
UHD_LOG_TRACE("MPM",
"Mboard " << mb_index << " reports " << mb->num_xbars << " crossbar(s)."
);
for (size_t xbar_index = 0; xbar_index < mb->num_xbars; xbar_index++) {
const size_t num_blocks =
mb->rpc->request<size_t>("get_num_blocks", xbar_index);
const size_t base_port =
mb->rpc->request<size_t>("get_base_port", xbar_index);
const size_t local_addr = mb->get_xbar_local_addr(xbar_index);
UHD_LOGGER_TRACE("MPMD")
<< "Enumerating RFNoC blocks for xbar " << xbar_index
<< ". Total blocks: " << num_blocks
<< " Base port: " << base_port
<< " Local address: " << local_addr
;
try {
enumerate_rfnoc_blocks(
mb_index,
num_blocks,
base_port,
uhd::sid_t(0, 0, local_addr, 0),
ctrl_xport_args
);
} catch (const std::exception &ex) {
UHD_LOGGER_ERROR("MPMD")
<< "Failure during block enumeration: "
<< ex.what();
throw uhd::runtime_error("Failed to run enumerate_rfnoc_blocks()");
}
}
}
void mpmd_impl::setup_rpc_blocks(const device_addr_t &block_args)
{
// This could definitely be parallelized. Blocks may do all sorts of stuff
// inside set_rpc_client(), and it can take any amount of time (I mean,
// like, seconds).
for (const auto &block_ctrl: _rfnoc_block_ctrl) {
auto rpc_block_id = block_ctrl->get_block_id();
if (has_block<uhd::rfnoc::rpc_block_ctrl>(block_ctrl->get_block_id())) {
const size_t mboard_idx = rpc_block_id.get_device_no();
UHD_LOGGER_DEBUG("MPMD")
<< "Adding RPC access to block: " << rpc_block_id
<< " Block args: " << block_args.to_string()
;
get_block_ctrl<uhd::rfnoc::rpc_block_ctrl>(rpc_block_id)
->set_rpc_client(_mb[mboard_idx]->rpc, block_args);
}
}
}
size_t mpmd_impl::allocate_xbar_local_addr()
{
const size_t new_local_addr = _xbar_local_addr_ctr++;
if (new_local_addr > MPMD_CROSSBAR_MAX_LADDR) {
throw uhd::runtime_error("Too many crossbars.");
}
return new_local_addr;
}
/*****************************************************************************
* Find, Factory & Registry
****************************************************************************/
device_addrs_t mpmd_find_with_addr(const std::string& mgmt_addr, const device_addr_t& hint_)
{
UHD_ASSERT_THROW(not mgmt_addr.empty());
device_addrs_t addrs;
transport::udp_simple::sptr comm = transport::udp_simple::make_broadcast(
mgmt_addr, std::to_string(mpmd_impl::MPM_DISCOVERY_PORT));
comm->send(
boost::asio::buffer(
mpmd_impl::MPM_DISCOVERY_CMD.c_str(),
mpmd_impl::MPM_DISCOVERY_CMD.size()
)
);
while (true) {
const size_t MAX_MTU = 8000;
char buff[MAX_MTU] = {};
const size_t nbytes = comm->recv(
boost::asio::buffer(buff, MAX_MTU),
MPMD_FIND_TIMEOUT
);
if (nbytes == 0) {
break;
}
const char* reply = (const char*)buff;
std::string reply_string = std::string(reply);
std::vector<std::string> result;
boost::algorithm::split(result, reply_string,
[](const char& in) { return in == ';'; },
boost::token_compress_on);
if (result.empty()) {
continue;
}
// Verify we didn't receive something other than an MPM discovery
// response
if (result[0] != "USRP-MPM") {
continue;
}
const std::string recv_addr = comm->get_recv_addr();
// remove external iface addrs if executed directly on device
bool external_iface = false;
for (const auto& addr : transport::get_if_addrs()) {
if ((addr.inet == comm->get_recv_addr()) &&
recv_addr !=
boost::asio::ip::address_v4::loopback().to_string()) {
external_iface = true;
}
}
if (external_iface) {
continue;
}
// Create result to return
device_addr_t new_addr;
new_addr[xport::MGMT_ADDR_KEY] = recv_addr;
new_addr["type"] = "mpmd"; // hwd will overwrite this
// remove ident string and put other informations into device_args dict
result.erase(result.begin());
// parse key-value pairs in the discovery string and add them to the
// device_args
for (const auto& el : result) {
std::vector<std::string> value;
boost::algorithm::split(value, el,
[](const char& in) { return in == '='; },
boost::token_compress_on);
new_addr[value[0]] = value[1];
}
// 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("type") or hint_["type"] == new_addr["type"])
and (not hint_.has_key("product") or hint_["product"] == new_addr["product"])
){
UHD_LOG_TRACE("MPMD FIND",
"Found device that matches hints: " << new_addr.to_string());
addrs.push_back(new_addr);
} else {
UHD_LOG_DEBUG("MPMD FIND",
"Found device, but does not match hint: " << recv_addr
);
}
}
return addrs;
};
// Implements scenario 1) (see below)
device_addrs_t mpmd_find_with_addrs(const device_addrs_t& hints)
{
UHD_LOG_TRACE("MPMD FIND", "Finding with addrs.");
device_addrs_t found_devices;
found_devices.reserve(hints.size());
for (const auto& hint : hints) {
if (not (hint.has_key(xport::FIRST_ADDR_KEY) or
hint.has_key(xport::MGMT_ADDR_KEY))) {
UHD_LOG_DEBUG("MPMD FIND",
"No address given in hint " << hint.to_string());
continue;
}
const std::string mgmt_addr =
hint.get(xport::MGMT_ADDR_KEY, hint.get(xport::FIRST_ADDR_KEY, ""));
device_addrs_t reply_addrs = mpmd_find_with_addr(mgmt_addr, hint);
if (reply_addrs.size() > 1) {
UHD_LOG_ERROR("MPMD",
"Could not resolve device hint \"" << hint.to_string()
<< "\" to a unique device.");
continue;
} else if (reply_addrs.empty()) {
continue;
}
UHD_LOG_TRACE("MPMD FIND",
"Device responded: " << reply_addrs[0].to_string());
found_devices.push_back(reply_addrs[0]);
}
if (found_devices.size() == 1) {
return found_devices;
} else {
return device_addrs_t(1, combine_device_addrs(found_devices));
}
}
device_addrs_t mpmd_find_with_bcast(const device_addr_t& hint)
{
device_addrs_t addrs;
UHD_LOG_TRACE("MPMD FIND",
"Broadcasting on all available interfaces to find MPM devices.");
for (const transport::if_addrs_t& if_addr : transport::get_if_addrs()) {
device_addrs_t reply_addrs = mpmd_find_with_addr(if_addr.bcast, hint);
addrs.insert(addrs.begin(), reply_addrs.begin(), reply_addrs.end());
}
return addrs;
}
/*! Find MPM devices based on a hint
*
* There are two scenarios:
*
* 1) an addr or mgmt_addr was defined
*
* In this case, we will go through all the addrs. If they point to a device,
* we will then compare the other attributes (serial, etc.). If they match,
* the device goes into a list.
*
* 2) No addrs were defined
*
* In this case, we do a broadcast ping to see if any devices respond. After
* that, we do the same matching.
*
*/
device_addrs_t mpmd_find(const device_addr_t& hint_)
{
device_addrs_t hints = separate_device_addr(hint_);
UHD_LOG_TRACE("MPMD FIND",
"Finding with " << hints.size() << " different hint(s).");
// Scenario 1): User gave us at least one address
if (not hints.empty() and
(hints[0].has_key(xport::FIRST_ADDR_KEY) or
hints[0].has_key(xport::MGMT_ADDR_KEY))) {
return mpmd_find_with_addrs(hints);
}
// Scenario 2): User gave us no address, and we need to broadcast
if (hints.empty()) {
hints.resize(1);
}
return mpmd_find_with_bcast(hints[0]);
}
static device::sptr mpmd_make(const device_addr_t& device_args)
{
return device::sptr(boost::make_shared<mpmd_impl>(device_args));
}
UHD_STATIC_BLOCK(register_mpmd_device)
{
device::register_device(&mpmd_find, &mpmd_make, device::USRP);
}
// vim: sw=4 expandtab:
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