/***************************************************************************** * This file is part of Kvazaar HEVC encoder. * * Copyright (C) 2013-2015 Tampere University of Technology and others (see * COPYING file). * * Kvazaar is free software: you can redistribute it and/or modify * it under the terms of the GNU Lesser General Public License version 2.1 as * published by the Free Software Foundation. * * Kvazaar 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU General Public License * along with Kvazaar. If not, see . ****************************************************************************/ #include "greatest/greatest.h" #include "test_strategies.h" #include "src/image.h" #include "src/strategyselector.h" #include ////////////////////////////////////////////////////////////////////////// // MACROS #define NUM_TESTS 2 #define LCU_MAX_LOG_W 6 #define LCU_MIN_LOG_W 2 ////////////////////////////////////////////////////////////////////////// // GLOBALS static kvz_pixel * bufs[NUM_TESTS][7][2]; static struct { int log_width; // for selecting dim from bufs cost_pixel_nxn_func * tested_func; } test_env; ////////////////////////////////////////////////////////////////////////// // SETUP, TEARDOWN AND HELPER FUNCTIONS static void init_gradient(int x_px, int y_px, int width, int slope, kvz_pixel *buf) { for (int y = 0; y < width; ++y) { for (int x = 0; x < width; ++x) { int diff_x = x_px - x; int diff_y = y_px - y; int val = sqrt(diff_x * diff_x + diff_y * diff_y) + 0.5 + slope; buf[y * width + x] = CLIP(0, 255, val); } } } static void setup_tests() { for (int test = 0; test < NUM_TESTS; ++test) { for (int w = LCU_MIN_LOG_W; w <= LCU_MAX_LOG_W; ++w) { bufs[test][w][0] = 0; bufs[test][w][1] = 0; } for (int w = LCU_MIN_LOG_W; w <= LCU_MAX_LOG_W; ++w) { unsigned size = 1 << (w * 2); bufs[test][w][0] = malloc(size * sizeof(kvz_pixel) + SIMD_ALIGNMENT); bufs[test][w][0] = ALIGNED_POINTER(bufs[test][w][0], SIMD_ALIGNMENT); bufs[test][w][1] = malloc(size * sizeof(kvz_pixel) + SIMD_ALIGNMENT); bufs[test][w][1] = ALIGNED_POINTER(bufs[test][w][1], SIMD_ALIGNMENT); } } int test = 0; for (int w = LCU_MIN_LOG_W; w <= LCU_MAX_LOG_W; ++w) { unsigned size = 1 << (w * 2); FILL_ARRAY(bufs[test][w][0], 0, size); FILL_ARRAY(bufs[test][w][1], 255, size); } test = 1; for (int w = LCU_MIN_LOG_W; w <= LCU_MAX_LOG_W; ++w) { unsigned width = 1 << w; unsigned size = 1 << (w * 2); init_gradient(3, 1, width, 1, bufs[test][w][0]); //init_gradient(width / 2, 0, width, 1, bufs[test][w][1]); FILL_ARRAY(bufs[test][w][1], 128, size); } } static void tear_down_tests() { for (int test = 0; test < NUM_TESTS; ++test) { for (int log_width = 2; log_width <= 6; ++log_width) { //free(bufs[test][log_width][0]); //free(bufs[test][log_width][1]); } } } static unsigned test_calc_sad(const kvz_pixel * buf1, const kvz_pixel * buf2, int dim) { unsigned result = 0; for (int i = 0; i < dim * dim; ++i) { result += abs(buf1[i] - buf2[i]); } return result; } ////////////////////////////////////////////////////////////////////////// // TESTS /** * Test that the maximum SAD value for a given buffer size doesn't overflow. */ TEST test_black_and_white(void) { const int test = 0; const int width = 1 << test_env.log_width; kvz_pixel * buf1 = bufs[test][test_env.log_width][0]; kvz_pixel * buf2 = bufs[test][test_env.log_width][1]; unsigned result1 = test_env.tested_func(buf1, buf2); unsigned result2 = test_env.tested_func(buf2, buf1); // Order of parameters must not matter. ASSERT_EQ(result1, result2); // Result matches trivial implementation. ASSERT_EQ(result1, 255 * width * width); PASS(); } /** * Test that the maximum SAD value for a given buffer size doesn't overflow. */ TEST test_gradient(void) { const int test = 1; const int width = 1 << test_env.log_width; kvz_pixel * buf1 = bufs[test][test_env.log_width][0]; kvz_pixel * buf2 = bufs[test][test_env.log_width][1]; unsigned result = test_calc_sad(buf1, buf2, width); unsigned result1 = test_env.tested_func(buf1, buf2); unsigned result2 = test_env.tested_func(buf2, buf1); // Order of parameters must not matter. ASSERT_EQ(result1, result2); // Result matches trivial implementation. ASSERT_EQ(result1, result); PASS(); } ////////////////////////////////////////////////////////////////////////// // TEST FIXTURES SUITE(intra_sad_tests) { //SET_SETUP(sad_setup); //SET_TEARDOWN(sad_teardown); setup_tests(); // Loop through all strategies picking out the intra sad ones and run // selectec strategies though all tests. for (volatile unsigned i = 0; i < strategies.count; ++i) { const char * type = strategies.strategies[i].type; if (strcmp(type, "sad_4x4") == 0) { test_env.log_width = 2; } else if (strcmp(type, "sad_8x8") == 0) { test_env.log_width = 3; } else if (strcmp(type, "sad_16x16") == 0) { test_env.log_width = 4; } else if (strcmp(type, "sad_32x32") == 0) { test_env.log_width = 5; } else if (strcmp(type, "sad_64x64") == 0) { test_env.log_width = 6; } else { continue; } test_env.tested_func = strategies.strategies[i].fptr; // Tests RUN_TEST(test_black_and_white); RUN_TEST(test_gradient); } tear_down_tests(); }