// // Copyright 2014 Ettus Research LLC // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU General Public License for more details. // // You should have received a copy of the GNU General Public License // along with this program. If not, see . // #include #include #include #include #include #include #include #include using namespace uhd; using namespace uhd::rfnoc; static const uint64_t TEST_NOC_ID = 0xAAAABBBBCCCCDDDD; static const sid_t TEST_SID0 = 0x00000200; // 0.0.2.0 static const sid_t TEST_SID1 = 0x00000210; // 0.0.2.F // Pseudo-wb-iface class pseudo_wb_iface_impl : public uhd::wb_iface { public: pseudo_wb_iface_impl() {}; ~pseudo_wb_iface_impl() {}; void poke64(const wb_addr_type addr, const uint64_t data) { std::cout << str(boost::format("[PSEUDO] poke64 to addr: %016X, data == %016X") % addr % data) << std::endl; }; uint64_t peek64(const wb_addr_type addr) { std::cout << str(boost::format("[PSEUDO] peek64 to addr: %016X") % addr) << std::endl; switch (addr) { case SR_READBACK_REG_ID: return TEST_NOC_ID; case SR_READBACK_REG_FIFOSIZE: return 0x000000000000000B; case SR_READBACK_REG_USER: return 0x0123456789ABCDEF; default: return 0; } return 0; } void poke32(const wb_addr_type addr, const uint32_t data) { std::cout << str(boost::format("poke32 to addr: %08X, data == %08X") % addr % data) << std::endl; } uint32_t peek32(const wb_addr_type addr) { std::cout << str(boost::format("peek32 to addr: %08X") % addr) << std::endl; return 0; } }; // Pseudo-device class pseudo_device3_impl : public uhd::device3 { public: pseudo_device3_impl() { _tree = uhd::property_tree::make(); _tree->create("/name").set("Test Pseudo-Device3"); // We can re-use this: std::map ctrl_ifaces = boost::assign::map_list_of (0, wb_iface::sptr(new pseudo_wb_iface_impl())) ; // Add two block controls: uhd::rfnoc::make_args_t make_args; make_args.ctrl_ifaces = ctrl_ifaces; make_args.base_address = TEST_SID0.get_dst(); make_args.device_index = 0; make_args.tree = _tree; make_args.is_big_endian = false; std::cout << "[PSEUDO] Generating block controls 1/2:" << std::endl; _rfnoc_block_ctrl.push_back( block_ctrl_base::make(make_args) ); std::cout << "[PSEUDO] Generating block controls 2/2:" << std::endl; make_args.base_address = TEST_SID1.get_dst(); _rfnoc_block_ctrl.push_back( block_ctrl::make(make_args) ); } rx_streamer::sptr get_rx_stream(const stream_args_t &args) { throw uhd::not_implemented_error(args.args.to_string()); } tx_streamer::sptr get_tx_stream(const stream_args_t &args) { throw uhd::not_implemented_error(args.args.to_string()); } bool recv_async_msg(async_metadata_t &async_metadata, double timeout) { throw uhd::not_implemented_error(str(boost::format("%d %f") % async_metadata.channel % timeout)); } rfnoc::graph::sptr create_graph(const std::string &) { return rfnoc::graph::sptr(); } }; device3::sptr make_pseudo_device() { return device3::sptr(new pseudo_device3_impl()); } class dummy_block_ctrl : public block_ctrl { int foo; }; BOOST_AUTO_TEST_CASE(test_device3) { device3::sptr my_device = make_pseudo_device(); std::cout << "Checking block 0..." << std::endl; BOOST_REQUIRE(my_device->find_blocks("Block").size()); std::cout << "Getting block 0..." << std::endl; block_ctrl_base::sptr block0 = my_device->get_block_ctrl(my_device->find_blocks("Block")[0]); BOOST_REQUIRE(block0); BOOST_CHECK_EQUAL(block0->get_block_id(), "0/Block_0"); std::cout << "Checking block 1..." << std::endl; BOOST_REQUIRE(my_device->has_block(block_id_t("0/Block_1"))); std::cout << "Getting block 1..." << std::endl; block_ctrl_base::sptr block1 = my_device->get_block_ctrl(block_id_t("0/Block_1")); BOOST_REQUIRE(block1); BOOST_CHECK_EQUAL(block1->get_block_id(), "0/Block_1"); } BOOST_AUTO_TEST_CASE(test_device3_cast) { device3::sptr my_device = make_pseudo_device(); std::cout << "Getting block 0..." << std::endl; block_ctrl::sptr block0 = my_device->get_block_ctrl(block_id_t("0/Block_0")); BOOST_REQUIRE(block0); BOOST_CHECK_EQUAL(block0->get_block_id(), "0/Block_0"); std::cout << "Getting block 1..." << std::endl; block_ctrl_base::sptr block1 = my_device->get_block_ctrl(block_id_t("0/Block_1")); BOOST_CHECK_EQUAL(block1->get_block_id(), "0/Block_1"); } BOOST_AUTO_TEST_CASE(test_device3_fail) { device3::sptr my_device = make_pseudo_device(); BOOST_CHECK(not my_device->has_block(block_id_t("0/FooBarBlock_0"))); BOOST_CHECK(not my_device->has_block(block_id_t("0/Block_1"))); BOOST_CHECK(my_device->find_blocks("FooBarBlock").size() == 0); BOOST_CHECK(my_device->find_blocks("FooBarBlock").size() == 0); BOOST_REQUIRE_THROW( my_device->get_block_ctrl(block_id_t("0/FooBarBlock_17")), uhd::lookup_error ); BOOST_REQUIRE_THROW( my_device->get_block_ctrl(block_id_t("0/Block_1")), uhd::lookup_error ); } // vim: sw=4 et: