//
// Copyright 2020 Ettus Research, a National Instruments Brand
//
// SPDX-License-Identifier: GPL-3.0-or-later
//
#include "../rfnoc_graph_mock_nodes.hpp"
#include <uhd/rfnoc/actions.hpp>
#include <uhd/rfnoc/ddc_block_control.hpp>
#include <uhd/rfnoc/defaults.hpp>
#include <uhd/rfnoc/duc_block_control.hpp>
#include <uhd/rfnoc/mock_block.hpp>
#include <uhd/rfnoc/null_block_control.hpp>
#include <uhdlib/rfnoc/graph.hpp>
#include <uhdlib/rfnoc/node_accessor.hpp>
#include <uhdlib/utils/narrow.hpp>
#include <boost/test/unit_test.hpp>
#include <iostream>
using namespace uhd::rfnoc;
// Redeclare this here, since it's only defined outside of UHD_API
noc_block_base::make_args_t::~make_args_t() = default;
namespace {
constexpr size_t DEFAULT_MTU = 8000;
} // namespace
BOOST_AUTO_TEST_CASE(test_ddc_block)
{
node_accessor_t node_accessor{};
constexpr uint32_t num_hb = 2;
constexpr uint32_t max_cic = 128;
constexpr size_t num_chans = 4;
constexpr noc_id_t noc_id = DDC_BLOCK;
constexpr int TEST_DECIM = 20;
auto block_container =
get_mock_block(noc_id, num_chans, num_chans, uhd::device_addr_t("foo=bar"));
auto& ddc_reg_iface = block_container.reg_iface;
ddc_reg_iface->read_memory[ddc_block_control::RB_COMPAT_NUM] =
(ddc_block_control::MAJOR_COMPAT << 16) | ddc_block_control::MINOR_COMPAT;
ddc_reg_iface->read_memory[ddc_block_control::RB_NUM_HB] = num_hb;
ddc_reg_iface->read_memory[ddc_block_control::RB_CIC_MAX_DECIM] = max_cic;
auto test_ddc = block_container.get_block<ddc_block_control>();
BOOST_REQUIRE(test_ddc);
BOOST_CHECK_EQUAL(test_ddc->get_block_args().get("foo"), "bar");
node_accessor.init_props(test_ddc.get());
UHD_LOG_DEBUG("TEST", "Init done.");
test_ddc->set_property<int>("decim", TEST_DECIM, 0);
BOOST_REQUIRE(ddc_reg_iface->write_memory.count(ddc_block_control::SR_DECIM_ADDR));
BOOST_CHECK_EQUAL(
ddc_reg_iface->write_memory.at(ddc_block_control::SR_DECIM_ADDR), 2 << 8 | 5);
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::INPUT_EDGE, 0}), DEFAULT_MTU);
// Now plop it in a graph
detail::graph_t graph{};
detail::graph_t::graph_edge_t edge_info;
edge_info.src_port = 0;
edge_info.dst_port = 0;
edge_info.property_propagation_active = true;
edge_info.edge = detail::graph_t::graph_edge_t::DYNAMIC;
mock_terminator_t mock_source_term(1);
mock_terminator_t mock_sink_term(1);
UHD_LOG_INFO("TEST", "Priming mock source node props");
mock_source_term.set_edge_property<std::string>(
"type", "sc16", {res_source_info::OUTPUT_EDGE, 0});
mock_source_term.set_edge_property<double>(
"scaling", 1.0, {res_source_info::OUTPUT_EDGE, 0});
mock_source_term.set_edge_property<double>(
"samp_rate", 1.0, {res_source_info::OUTPUT_EDGE, 0});
constexpr size_t NEW_MTU = 4000;
mock_source_term.set_edge_property<size_t>(
"mtu", NEW_MTU, {res_source_info::OUTPUT_EDGE, 0});
UHD_LOG_INFO("TEST", "Creating graph...");
graph.connect(&mock_source_term, test_ddc.get(), edge_info);
graph.connect(test_ddc.get(), &mock_sink_term, edge_info);
UHD_LOG_INFO("TEST", "Committing graph...");
graph.commit();
UHD_LOG_INFO("TEST", "Commit complete.");
// We need to set the decimation again, because the rates will screw it
// change it w.r.t. to the previous setting
test_ddc->set_property<int>("decim", TEST_DECIM, 0);
BOOST_CHECK_EQUAL(test_ddc->get_property<int>("decim", 0), TEST_DECIM);
BOOST_CHECK(mock_source_term.get_edge_property<double>(
"samp_rate", {res_source_info::OUTPUT_EDGE, 0})
== mock_sink_term.get_edge_property<double>(
"samp_rate", {res_source_info::INPUT_EDGE, 0})
* TEST_DECIM);
BOOST_CHECK(mock_sink_term.get_edge_property<double>(
"scaling", {res_source_info::INPUT_EDGE, 0})
!= 1.0);
UHD_LOG_INFO("TEST", "Setting freq to 1/8 of input rate");
constexpr double TEST_FREQ = 1.0 / 8;
test_ddc->set_property<double>("freq", TEST_FREQ, 0);
const uint32_t freq_word_1 =
ddc_reg_iface->write_memory.at(ddc_block_control::SR_FREQ_ADDR);
BOOST_REQUIRE(freq_word_1 != 0);
UHD_LOG_INFO("TEST", "Doubling input rate (to 2.0)");
// Now this should change the freq word, but not the absolute frequency
mock_source_term.set_edge_property<double>(
"samp_rate", 2.0, {res_source_info::OUTPUT_EDGE, 0});
const double freq_word_2 =
ddc_reg_iface->write_memory.at(ddc_block_control::SR_FREQ_ADDR);
// The frequency word is the phase increment, which will halve. We skirt
// around fixpoint/floating point accuracy issues by using CLOSE.
BOOST_CHECK_CLOSE(double(freq_word_1) / double(freq_word_2), 2.0, 1e-6);
UHD_LOG_INFO("TEST", "Testing DDC MTU propagation");
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::INPUT_EDGE, 0}), NEW_MTU);
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::OUTPUT_EDGE, 0}), NEW_MTU);
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::INPUT_EDGE, 1}), DEFAULT_MTU);
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::OUTPUT_EDGE, 1}), DEFAULT_MTU);
mock_source_term.set_edge_property<size_t>(
"mtu", NEW_MTU / 2, {res_source_info::OUTPUT_EDGE, 0});
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::INPUT_EDGE, 0}), NEW_MTU / 2);
BOOST_CHECK_EQUAL(test_ddc->get_mtu({res_source_info::OUTPUT_EDGE, 0}), NEW_MTU / 2);
// Now reset the props using set_properties
test_ddc->set_properties(uhd::device_addr_t("decim=1,freq=0.0,foo=bar"), 0);
BOOST_CHECK_EQUAL(test_ddc->get_property<int>("decim", 0), 1);
BOOST_CHECK_EQUAL(test_ddc->get_property<double>("freq", 0), 0.0);
}