/* * This file is part of the PulseView project. * * Copyright (C) 2012 Joel Holdsworth * * 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 2 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, write to the Free Software * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA */ #include #define __STDC_LIMIT_MACROS #include #include #include "../../pv/data/logicsnapshot.h" using namespace std; using pv::data::LogicSnapshot; BOOST_AUTO_TEST_SUITE(LogicSnapshotTest) void push_logic(LogicSnapshot &s, unsigned int length, uint8_t value) { sr_datafeed_logic logic; logic.unitsize = 1; logic.length = length; logic.data = new uint8_t[length]; memset(logic.data, value, length * logic.unitsize); s.append_payload(logic); delete[] (uint8_t*)logic.data; } BOOST_AUTO_TEST_CASE(Pow2) { BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(0, 0), 0); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(1, 0), 1); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(2, 0), 2); BOOST_CHECK_EQUAL( LogicSnapshot::pow2_ceil(INT64_MIN, 0), INT64_MIN); BOOST_CHECK_EQUAL( LogicSnapshot::pow2_ceil(INT64_MAX, 0), INT64_MAX); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(0, 1), 0); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(1, 1), 2); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(2, 1), 2); BOOST_CHECK_EQUAL(LogicSnapshot::pow2_ceil(3, 1), 4); } BOOST_AUTO_TEST_CASE(Basic) { // Create an empty LogicSnapshot object sr_datafeed_logic logic; logic.length = 0; logic.unitsize = 1; logic.data = NULL; LogicSnapshot s(logic); //----- Test LogicSnapshot::push_logic -----// BOOST_CHECK(s.get_sample_count() == 0); for (unsigned int i = 0; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } // Push 8 samples of all zeros push_logic(s, 8, 0); BOOST_CHECK(s.get_sample_count() == 8); // There should not be enough samples to have a single mip map sample for (unsigned int i = 0; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } // Push 8 samples of 0x11s to bring the total up to 16 push_logic(s, 8, 0x11); // There should now be enough data for exactly one sample // in mip map level 0, and that sample should be 0 const LogicSnapshot::MipMapLevel &m0 = s._mip_map[0]; BOOST_CHECK_EQUAL(m0.length, 1); BOOST_CHECK_EQUAL(m0.data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(m0.data != NULL); BOOST_CHECK_EQUAL(((uint8_t*)m0.data)[0], 0x11); // The higher levels should still be empty for (unsigned int i = 1; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } // Push 240 samples of all zeros to bring the total up to 256 push_logic(s, 240, 0); BOOST_CHECK_EQUAL(m0.length, 16); BOOST_CHECK_EQUAL(m0.data_length, LogicSnapshot::MipMapDataUnit); BOOST_CHECK_EQUAL(((uint8_t*)m0.data)[1], 0x11); for (unsigned int i = 2; i < m0.length; i++) BOOST_CHECK_EQUAL(((uint8_t*)m0.data)[i], 0); const LogicSnapshot::MipMapLevel &m1 = s._mip_map[1]; BOOST_CHECK_EQUAL(m1.length, 1); BOOST_CHECK_EQUAL(m1.data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(m1.data != NULL); BOOST_CHECK_EQUAL(((uint8_t*)m1.data)[0], 0x11); //----- Test LogicSnapshot::get_subsampled_edges -----// // Test a full view at full zoom. vector edges; s.get_subsampled_edges(edges, 0, 255, 1, 0); BOOST_REQUIRE_EQUAL(edges.size(), 4); BOOST_CHECK_EQUAL(edges[0].first, 0); BOOST_CHECK_EQUAL(edges[1].first, 8); BOOST_CHECK_EQUAL(edges[2].first, 16); BOOST_CHECK_EQUAL(edges[3].first, 255); // Test a subset at high zoom edges.clear(); s.get_subsampled_edges(edges, 6, 17, 0.05f, 0); BOOST_REQUIRE_EQUAL(edges.size(), 4); BOOST_CHECK_EQUAL(edges[0].first, 6); BOOST_CHECK_EQUAL(edges[1].first, 8); BOOST_CHECK_EQUAL(edges[2].first, 16); BOOST_CHECK_EQUAL(edges[3].first, 17); } BOOST_AUTO_TEST_CASE(LargeData) { uint8_t prev_sample; const unsigned int Length = 1000000; sr_datafeed_logic logic; logic.unitsize = 1; logic.length = Length; logic.data = new uint8_t[Length]; uint8_t *data = (uint8_t*)logic.data; for (unsigned int i = 0; i < Length; i++) *data++ = (uint8_t)(i >> 8); LogicSnapshot s(logic); delete[] (uint8_t*)logic.data; BOOST_CHECK(s.get_sample_count() == Length); // Check mip map level 0 BOOST_CHECK_EQUAL(s._mip_map[0].length, 62500); BOOST_CHECK_EQUAL(s._mip_map[0].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[0].data != NULL); prev_sample = 0; for (unsigned int i = 0; i < s._mip_map[0].length;) { BOOST_TEST_MESSAGE("Testing mip_map[0].data[" << i << "]"); const uint8_t sample = (uint8_t)((i*16) >> 8); BOOST_CHECK_EQUAL(s.get_subsample(0, i++) & 0xFF, prev_sample ^ sample); prev_sample = sample; for (int j = 1; i < s._mip_map[0].length && j < 16; j++) { BOOST_TEST_MESSAGE("Testing mip_map[0].data[" << i << "]"); BOOST_CHECK_EQUAL(s.get_subsample(0, i++) & 0xFF, 0); } } // Check mip map level 1 BOOST_CHECK_EQUAL(s._mip_map[1].length, 3906); BOOST_CHECK_EQUAL(s._mip_map[1].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[1].data != NULL); prev_sample = 0; for (unsigned int i = 0; i < s._mip_map[1].length; i++) { BOOST_TEST_MESSAGE("Testing mip_map[1].data[" << i << "]"); const uint8_t sample = i; const uint8_t expected = sample ^ prev_sample; prev_sample = i; BOOST_CHECK_EQUAL(s.get_subsample(1, i) & 0xFF, expected); } // Check mip map level 2 BOOST_CHECK_EQUAL(s._mip_map[2].length, 244); BOOST_CHECK_EQUAL(s._mip_map[2].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[2].data != NULL); prev_sample = 0; for (unsigned int i = 0; i < s._mip_map[2].length; i++) { BOOST_TEST_MESSAGE("Testing mip_map[2].data[" << i << "]"); const uint8_t sample = i << 4; const uint8_t expected = (sample ^ prev_sample) | 0x0F; prev_sample = sample; BOOST_CHECK_EQUAL(s.get_subsample(2, i) & 0xFF, expected); } // Check mip map level 3 BOOST_CHECK_EQUAL(s._mip_map[3].length, 15); BOOST_CHECK_EQUAL(s._mip_map[3].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[3].data != NULL); for (unsigned int i = 0; i < s._mip_map[3].length; i++) BOOST_CHECK_EQUAL(*((uint8_t*)s._mip_map[3].data + i), 0xFF); // Check the higher levels for (unsigned int i = 4; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } //----- Test LogicSnapshot::get_subsampled_edges -----// // Check in normal case vector edges; s.get_subsampled_edges(edges, 0, Length-1, 1, 7); BOOST_CHECK_EQUAL(edges.size(), 32); for (unsigned int i = 0; i < edges.size() - 1; i++) { BOOST_CHECK_EQUAL(edges[i].first, i * 32768); BOOST_CHECK_EQUAL(edges[i].second, i & 1); } BOOST_CHECK_EQUAL(edges[31].first, 999999); // Check in very low zoom case edges.clear(); s.get_subsampled_edges(edges, 0, Length-1, 50e6f, 7); BOOST_CHECK_EQUAL(edges.size(), 2); } BOOST_AUTO_TEST_CASE(Pulses) { const int Cycles = 3; const int Period = 64; const int Length = Cycles * Period; vector edges; //----- Create a LogicSnapshot -----// sr_datafeed_logic logic; logic.unitsize = 1; logic.length = Length; logic.data = (uint64_t*)new uint8_t[Length]; uint8_t *p = (uint8_t*)logic.data; for (int i = 0; i < Cycles; i++) { *p++ = 0xFF; for (int j = 1; j < Period; j++) *p++ = 0x00; } LogicSnapshot s(logic); delete[] (uint8_t*)logic.data; //----- Check the mip-map -----// // Check mip map level 0 BOOST_CHECK_EQUAL(s._mip_map[0].length, 12); BOOST_CHECK_EQUAL(s._mip_map[0].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[0].data != NULL); for (unsigned int i = 0; i < s._mip_map[0].length;) { BOOST_TEST_MESSAGE("Testing mip_map[0].data[" << i << "]"); BOOST_CHECK_EQUAL(s.get_subsample(0, i++) & 0xFF, 0xFF); for (int j = 1; i < s._mip_map[0].length && j < Period/LogicSnapshot::MipMapScaleFactor; j++) { BOOST_TEST_MESSAGE( "Testing mip_map[0].data[" << i << "]"); BOOST_CHECK_EQUAL(s.get_subsample(0, i++) & 0xFF, 0x00); } } // Check the higher levels are all inactive for (unsigned int i = 1; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } //----- Test get_subsampled_edges at reduced scale -----// s.get_subsampled_edges(edges, 0, Length-1, 16.0f, 2); BOOST_REQUIRE_EQUAL(edges.size(), Cycles + 2); BOOST_CHECK_EQUAL(0, false); for (unsigned int i = 1; i < edges.size(); i++) BOOST_CHECK_EQUAL(edges[i].second, false); } BOOST_AUTO_TEST_CASE(LongPulses) { const int Cycles = 3; const int Period = 64; const int PulseWidth = 16; const int Length = Cycles * Period; int j; vector edges; //----- Create a LogicSnapshot -----// sr_datafeed_logic logic; logic.unitsize = 8; logic.length = Length * 8; logic.data = (uint64_t*)new uint64_t[Length]; uint64_t *p = (uint64_t*)logic.data; for (int i = 0; i < Cycles; i++) { for (j = 0; j < PulseWidth; j++) *p++ = ~0; for (; j < Period; j++) *p++ = 0; } LogicSnapshot s(logic); delete[] (uint64_t*)logic.data; //----- Check the mip-map -----// // Check mip map level 0 BOOST_CHECK_EQUAL(s._mip_map[0].length, 12); BOOST_CHECK_EQUAL(s._mip_map[0].data_length, LogicSnapshot::MipMapDataUnit); BOOST_REQUIRE(s._mip_map[0].data != NULL); for (unsigned int i = 0; i < s._mip_map[0].length;) { for (j = 0; i < s._mip_map[0].length && j < 2; j++) { BOOST_TEST_MESSAGE( "Testing mip_map[0].data[" << i << "]"); BOOST_CHECK_EQUAL(s.get_subsample(0, i++), ~0); } for (; i < s._mip_map[0].length && j < Period/LogicSnapshot::MipMapScaleFactor; j++) { BOOST_TEST_MESSAGE( "Testing mip_map[0].data[" << i << "]"); BOOST_CHECK_EQUAL(s.get_subsample(0, i++), 0); } } // Check the higher levels are all inactive for (unsigned int i = 1; i < LogicSnapshot::ScaleStepCount; i++) { const LogicSnapshot::MipMapLevel &m = s._mip_map[i]; BOOST_CHECK_EQUAL(m.length, 0); BOOST_CHECK_EQUAL(m.data_length, 0); BOOST_CHECK(m.data == NULL); } //----- Test get_subsampled_edges at a full scale -----// s.get_subsampled_edges(edges, 0, Length-1, 16.0f, 2); BOOST_REQUIRE_EQUAL(edges.size(), Cycles * 2 + 1); for (int i = 0; i < Cycles; i++) { BOOST_CHECK_EQUAL(edges[i*2].first, i * Period); BOOST_CHECK_EQUAL(edges[i*2].second, true); BOOST_CHECK_EQUAL(edges[i*2+1].first, i * Period + PulseWidth); BOOST_CHECK_EQUAL(edges[i*2+1].second, false); } BOOST_CHECK_EQUAL(edges.back().first, Length-1); BOOST_CHECK_EQUAL(edges.back().second, false); //----- Test get_subsampled_edges at a simplified scale -----// edges.clear(); s.get_subsampled_edges(edges, 0, Length-1, 17.0f, 2); BOOST_CHECK_EQUAL(edges[0].first, 0); BOOST_CHECK_EQUAL(edges[0].second, true); BOOST_CHECK_EQUAL(edges[1].first, 16); BOOST_CHECK_EQUAL(edges[1].second, false); for (int i = 1; i < Cycles; i++) { BOOST_CHECK_EQUAL(edges[i+1].first, i * Period); BOOST_CHECK_EQUAL(edges[i+1].second, false); } BOOST_CHECK_EQUAL(edges.back().first, Length-1); BOOST_CHECK_EQUAL(edges.back().second, false); } BOOST_AUTO_TEST_CASE(LisaMUsbHid) { /* This test was created from the beginning of the USB_DM signal in * sigrok-dumps-usb/lisa_m_usbhid/lisa_m_usbhid.sr */ const int Edges[] = { 7028, 7033, 7036, 7041, 7044, 7049, 7053, 7066, 7073, 7079, 7086, 7095, 7103, 7108, 7111, 7116, 7119, 7124, 7136, 7141, 7148, 7162, 7500 }; const int Length = Edges[countof(Edges) - 1]; bool state = false; int lastEdgePos = 0; //----- Create a LogicSnapshot -----// sr_datafeed_logic logic; logic.unitsize = 1; logic.length = Length; logic.data = new uint8_t[Length]; uint8_t *data = (uint8_t*)logic.data; for (unsigned int i = 0; i < countof(Edges); i++) { const int edgePos = Edges[i]; memset(&data[lastEdgePos], state ? 0x02 : 0, edgePos - lastEdgePos - 1); lastEdgePos = edgePos; state = !state; } LogicSnapshot s(logic); delete[] (uint64_t*)logic.data; vector edges; /* The trailing edge of the pulse train is falling in the source data. * Check this is always true at different scales */ edges.clear(); s.get_subsampled_edges(edges, 0, Length-1, 33.333332f, 1); BOOST_CHECK_EQUAL(edges[edges.size() - 2].second, false); } /* * This test checks the rendering of wide data (more than 8 probes) * Probe signals are either all-high, or all-low, but are interleaved such that * they would toggle during every sample if treated like 8 probes. * The packet contains a large number of samples, so the mipmap generation kicks * in. * * The signals should not toggle (have exactly two edges: the start and end) */ BOOST_AUTO_TEST_CASE(WideData) { const int Length = 512<<10; uint16_t *data = new uint16_t[Length]; sr_datafeed_logic logic; logic.unitsize = sizeof(data[0]); logic.length = Length * sizeof(data[0]); logic.data = data; for (int i = 0; i < Length; i++) data[i] = 0x0FF0; LogicSnapshot s(logic); vector edges; edges.clear(); s.get_subsampled_edges(edges, 0, Length-1, 1, 0); BOOST_CHECK_EQUAL(edges.size(), 2); edges.clear(); s.get_subsampled_edges(edges, 0, Length-1, 1, 8); BOOST_CHECK_EQUAL(edges.size(), 2); // Cleanup delete [] data; } /* * This test is a replica of sixteen.sr attached to Bug #33. */ BOOST_AUTO_TEST_CASE(Sixteen) { const int Length = 8; uint16_t data[Length]; sr_datafeed_logic logic; logic.unitsize = sizeof(data[0]); logic.length = Length * sizeof(data[0]); logic.data = data; for (int i = 0; i < Length; i++) data[i] = 0xFFFE; LogicSnapshot s(logic); vector edges; s.get_subsampled_edges(edges, 0, 2, 0.0004, 1); BOOST_CHECK_EQUAL(edges.size(), 2); } BOOST_AUTO_TEST_SUITE_END()