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https://github.com/ultravideo/uvg266.git
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0692375caa
Adds volatile to loop variables in kvazaar tests in order to fix clobbered warnings.
427 lines
12 KiB
C
427 lines
12 KiB
C
/*****************************************************************************
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* This file is part of Kvazaar HEVC encoder.
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*
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* Copyright (C) 2013-2015 Tampere University of Technology and others (see
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* COPYING file).
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*
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* Kvazaar is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Lesser General Public License version 2.1 as
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* published by the Free Software Foundation.
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*
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* Kvazaar is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with Kvazaar. If not, see <http://www.gnu.org/licenses/>.
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****************************************************************************/
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#include "greatest/greatest.h"
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#include "test_strategies.h"
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#include "src/image.h"
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#include "src/threads.h"
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#include <math.h>
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#include <stdlib.h>
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//////////////////////////////////////////////////////////////////////////
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// MACROS
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#define NUM_TESTS 113
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#define NUM_CHUNKS 36
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#define LCU_MAX_LOG_W 6
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#define LCU_MIN_LOG_W 2
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// Time per tested function, in seconds.
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#define TIME_PER_TEST 1.0
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//////////////////////////////////////////////////////////////////////////
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// GLOBALS
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static kvz_pixel * bufs[NUM_TESTS]; // SIMD aligned pointers.
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static kvz_pixel * actual_bufs[NUM_TESTS]; // pointers returned by malloc.
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#define WIDTH_4K 3840
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#define HEIGHT_4K 2160
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static struct test_env_t {
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int width;
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int height;
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void * tested_func;
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const strategy_t * strategy;
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char msg[1024];
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kvz_picture *inter_a;
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kvz_picture *inter_b;
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} test_env;
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//////////////////////////////////////////////////////////////////////////
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// SETUP, TEARDOWN AND HELPER FUNCTIONS
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static void init_gradient(int x_px, int y_px, int width, int slope, kvz_pixel *buf)
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{
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for (int y = 0; y < width; ++y) {
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for (int x = 0; x < width; ++x) {
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int diff_x = x_px - x;
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int diff_y = y_px - y;
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int val = slope * sqrt(diff_x * diff_x + diff_y * diff_y) + 0.5;
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buf[y * width + x] = CLIP(0, 255, val);
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}
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}
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}
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static void setup_tests()
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{
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for (int test = 0; test < NUM_TESTS; ++test) {
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unsigned size = NUM_CHUNKS * 64 * 64;
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actual_bufs[test] = malloc(size * sizeof(kvz_pixel) + SIMD_ALIGNMENT);
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bufs[test] = ALIGNED_POINTER(actual_bufs[test], SIMD_ALIGNMENT);
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}
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for (int test = 0; test < NUM_TESTS; ++test) {
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for (int chunk = 0; chunk < NUM_CHUNKS; ++chunk) {
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const int width = 64;
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int x = (test + chunk) % width;
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int y = (test + chunk) / width;
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init_gradient(width - x, y, width, 255 / width, &bufs[test][chunk * 64*64]);
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}
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}
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test_env.inter_a = kvz_image_alloc(KVZ_CSP_420, WIDTH_4K, HEIGHT_4K);
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test_env.inter_b = kvz_image_alloc(KVZ_CSP_420, WIDTH_4K, HEIGHT_4K);
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for (unsigned i = 0; i < WIDTH_4K * HEIGHT_4K; ++i) {
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kvz_pixel pattern1 = ((i*i >> 10) % 255) >> 2;
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kvz_pixel pattern2 = ((i*i >> 15) % 255) >> 2;
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kvz_pixel gradient = (i >> 12) + i;
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test_env.inter_a->y[i] = (pattern1 + gradient) % PIXEL_MAX;
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test_env.inter_b->y[i] = (pattern2 + gradient) % PIXEL_MAX;
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}
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}
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static void tear_down_tests()
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{
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for (int test = 0; test < NUM_TESTS; ++test) {
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free(actual_bufs[test]);
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}
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kvz_image_free(test_env.inter_a);
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kvz_image_free(test_env.inter_b);
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}
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//////////////////////////////////////////////////////////////////////////
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// TESTS
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TEST test_intra_speed(const int width)
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{
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const int size = width * width;
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uint64_t call_cnt = 0;
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KVZ_CLOCK_T clock_now;
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KVZ_GET_TIME(&clock_now);
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double test_end = KVZ_CLOCK_T_AS_DOUBLE(clock_now) + TIME_PER_TEST;
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// Loop until time allocated for test has passed.
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for (unsigned i = 0;
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test_end > KVZ_CLOCK_T_AS_DOUBLE(clock_now);
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++i)
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{
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int test = i % NUM_TESTS;
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uint64_t sum = 0;
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for (int offset = 0; offset < NUM_CHUNKS * 64 * 64; offset += NUM_CHUNKS * size) {
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// Compare the first chunk against the 35 other chunks to simulate real usage.
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kvz_pixel * buf1 = &bufs[test][offset];
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for (int chunk = 1; chunk < NUM_CHUNKS; ++chunk) {
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kvz_pixel * buf2 = &bufs[test][chunk * size + offset];
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cost_pixel_nxn_func *tested_func = test_env.tested_func;
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sum += tested_func(buf1, buf2);
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++call_cnt;
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}
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}
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ASSERT(sum > 0);
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KVZ_GET_TIME(&clock_now)
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}
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double test_time = TIME_PER_TEST + KVZ_CLOCK_T_AS_DOUBLE(clock_now) - test_end;
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sprintf(test_env.msg, "%.3fM x %s:%s",
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(double)call_cnt / 1000000.0 / test_time,
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test_env.strategy->type,
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test_env.strategy->strategy_name);
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PASSm(test_env.msg);
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}
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TEST test_intra_dual_speed(const int width)
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{
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const int size = width * width;
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uint64_t call_cnt = 0;
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KVZ_CLOCK_T clock_now;
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KVZ_GET_TIME(&clock_now);
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double test_end = KVZ_CLOCK_T_AS_DOUBLE(clock_now) + TIME_PER_TEST;
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// Loop until time allocated for test has passed.
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for (unsigned i = 0;
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test_end > KVZ_CLOCK_T_AS_DOUBLE(clock_now);
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++i)
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{
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int test = i % NUM_TESTS;
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uint64_t sum = 0;
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for (int offset = 0; offset < NUM_CHUNKS * 64 * 64; offset += NUM_CHUNKS * size) {
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// Compare the first chunk against the 35 other chunks to simulate real usage.
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kvz_pixel * buf1 = &bufs[test][offset];
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for (int chunk = 0; chunk < NUM_CHUNKS; chunk += 2) {
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cost_pixel_nxn_multi_func *tested_func = test_env.tested_func;
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const kvz_pixel *buf_pair[2] = { &bufs[test][chunk * size + offset], &bufs[test][(chunk + 1) * size + offset] };
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unsigned costs[2] = { 0, 0 };
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tested_func((pred_buffer)buf_pair, buf1, 2, costs);
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sum += costs[0] + costs[1];
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++call_cnt;
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}
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}
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ASSERT(sum > 0);
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KVZ_GET_TIME(&clock_now)
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}
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double test_time = TIME_PER_TEST + KVZ_CLOCK_T_AS_DOUBLE(clock_now) - test_end;
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sprintf(test_env.msg, "%.3fM x %s:%s",
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(double)call_cnt / 1000000.0 / test_time,
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test_env.strategy->type,
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test_env.strategy->strategy_name);
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PASSm(test_env.msg);
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}
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TEST test_inter_speed(const int width, const int height)
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{
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unsigned call_cnt = 0;
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KVZ_CLOCK_T clock_now;
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KVZ_GET_TIME(&clock_now);
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double test_end = KVZ_CLOCK_T_AS_DOUBLE(clock_now) + TIME_PER_TEST;
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const vector2d_t dims_lcu = { WIDTH_4K / 64 - 2, HEIGHT_4K / 64 - 2 };
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const int step = 3;
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const int range = 2 * step;
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// Loop until time allocated for test has passed.
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for (uint64_t i = 0;
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test_end > KVZ_CLOCK_T_AS_DOUBLE(clock_now);
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++i)
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{
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// Do a sparse full search on the first CU of every LCU.
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uint64_t sum = 0;
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// Go through the non-edge LCU's in raster scan order.
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const vector2d_t lcu = {
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1 + i % dims_lcu.x,
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1 + (i / dims_lcu.y) % dims_lcu.y,
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};
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vector2d_t mv;
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for (mv.y = -range; mv.y <= range; mv.y += step) {
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for (mv.x = -range; mv.x <= range; mv.x += step) {
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reg_sad_func *tested_func = test_env.tested_func;
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int lcu_index = lcu.y * 64 * WIDTH_4K + lcu.x * 64;
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int mv_index = mv.y * WIDTH_4K + mv.x;
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kvz_pixel *buf1 = &test_env.inter_a->y[lcu_index];
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kvz_pixel *buf2 = &test_env.inter_a->y[lcu_index + mv_index];
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sum += tested_func(buf1, buf2, width, height, WIDTH_4K, WIDTH_4K);
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++call_cnt;
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}
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}
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ASSERT(sum > 0);
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KVZ_GET_TIME(&clock_now)
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}
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double test_time = TIME_PER_TEST + KVZ_CLOCK_T_AS_DOUBLE(clock_now) - test_end;
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sprintf(test_env.msg, "%.3fM x %s(%ix%i):%s",
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(double)call_cnt / 1000000.0 / test_time,
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test_env.strategy->type,
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width,
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height,
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test_env.strategy->strategy_name);
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PASSm(test_env.msg);
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}
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TEST dct_speed(const int width)
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{
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const int size = width * width;
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uint64_t call_cnt = 0;
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dct_func * tested_func = test_env.strategy->fptr;
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KVZ_CLOCK_T clock_now;
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KVZ_GET_TIME(&clock_now);
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double test_end = KVZ_CLOCK_T_AS_DOUBLE(clock_now) + TIME_PER_TEST;
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int16_t _tmp_residual[32 * 32 + SIMD_ALIGNMENT];
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int16_t _tmp_coeffs[32 * 32 + SIMD_ALIGNMENT];
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int16_t *tmp_residual = ALIGNED_POINTER(_tmp_residual, SIMD_ALIGNMENT);
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int16_t *tmp_coeffs = ALIGNED_POINTER(_tmp_coeffs, SIMD_ALIGNMENT);
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// Loop until time allocated for test has passed.
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for (unsigned i = 0;
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test_end > KVZ_CLOCK_T_AS_DOUBLE(clock_now);
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++i)
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{
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int test = i % NUM_TESTS;
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uint64_t sum = 0;
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for (int offset = 0; offset < NUM_CHUNKS * 64 * 64; offset += NUM_CHUNKS * size) {
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// Compare the first chunk against the 35 other chunks to simulate real usage.
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for (int chunk = 0; chunk < NUM_CHUNKS; ++chunk) {
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kvz_pixel * buf1 = &bufs[test][offset];
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kvz_pixel * buf2 = &bufs[test][chunk * size + offset];
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for (int p = 0; p < size; ++p) {
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tmp_residual[p] = (int16_t)(buf1[p] - buf2[p]);
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}
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tested_func(8, tmp_residual, tmp_coeffs);
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++call_cnt;
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sum += tmp_coeffs[0];
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}
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}
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ASSERT(sum > 0);
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KVZ_GET_TIME(&clock_now)
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}
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double test_time = TIME_PER_TEST + KVZ_CLOCK_T_AS_DOUBLE(clock_now) - test_end;
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sprintf(test_env.msg, "%.3fM x %s:%s",
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(double)call_cnt / 1000000.0 / test_time,
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test_env.strategy->type,
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test_env.strategy->strategy_name);
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PASSm(test_env.msg);
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}
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TEST intra_sad(void)
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{
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return test_intra_speed(test_env.width);
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}
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TEST intra_sad_dual(void)
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{
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return test_intra_dual_speed(test_env.width);
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}
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TEST intra_satd(void)
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{
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return test_intra_speed(test_env.width);
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}
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TEST intra_satd_dual(void)
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{
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return test_intra_dual_speed(test_env.width);
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}
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TEST inter_sad(void)
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{
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return test_inter_speed(test_env.width, test_env.height);
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}
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TEST fdct(void)
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{
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return dct_speed(test_env.width);
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}
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TEST idct(void)
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{
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return dct_speed(test_env.width);
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}
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//////////////////////////////////////////////////////////////////////////
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// TEST FIXTURES
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SUITE(speed_tests)
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{
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//SET_SETUP(sad_setup);
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//SET_TEARDOWN(sad_teardown);
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setup_tests();
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// Loop through all strategies picking out the intra sad ones and run
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// selectec strategies though all tests
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for (volatile unsigned i = 0; i < strategies.count; ++i) {
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const strategy_t * strategy = &strategies.strategies[i];
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// Select buffer width according to function name.
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if (strstr(strategy->type, "_4x4")) {
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test_env.width = 4;
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test_env.height = 4;
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} else if (strstr(strategy->type, "_8x8")) {
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test_env.width = 8;
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test_env.height = 8;
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} else if (strstr(strategy->type, "_16x16")) {
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test_env.width = 16;
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test_env.height = 16;
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} else if (strstr(strategy->type, "_32x32")) {
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test_env.width = 32;
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test_env.height = 32;
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} else if (strstr(strategy->type, "_64x64")) {
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test_env.width = 64;
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test_env.height = 64;
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} else {
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test_env.width = 0;
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test_env.height = 0;
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}
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test_env.tested_func = strategies.strategies[i].fptr;
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test_env.strategy = strategy;
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// Call different tests depending on type of function.
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// This allows for selecting a subset of tests with -t parameter.
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if (strncmp(strategy->type, "satd_", 5) == 0 && strcmp(strategy->type, "satd_any_size") != 0) {
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if (strlen(strategy->type) <= 10) {
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RUN_TEST(intra_satd);
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} else if (strstr(strategy->type, "_dual")) {
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RUN_TEST(intra_satd_dual);
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}
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} else if (strncmp(strategy->type, "sad_", 4) == 0) {
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if (strlen(strategy->type) <= 9) {
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RUN_TEST(intra_sad);
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} else if (strstr(strategy->type, "_dual")) {
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RUN_TEST(intra_sad_dual);
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}
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} else if (strcmp(strategy->type, "reg_sad") == 0) {
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static const vector2d_t tested_dims[] = {
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{ 8, 8 }, { 16, 16 }, { 32, 32 }, { 64, 64 },
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{ 64, 63 }, { 1, 1 }
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};
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int num_tested_dims = sizeof(tested_dims) / sizeof(*tested_dims);
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// Call reg_sad with all the sizes it is actually called with.
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for (volatile int dim_i = 0; dim_i < num_tested_dims; ++dim_i) {
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test_env.width = tested_dims[dim_i].x;
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test_env.height = tested_dims[dim_i].y;
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RUN_TEST(inter_sad);
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}
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} else if (strncmp(strategy->type, "dct_", 4) == 0 ||
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strcmp(strategy->type, "fast_forward_dst_4x4") == 0)
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{
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RUN_TEST(fdct);
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} else if (strncmp(strategy->type, "idct_", 4) == 0 ||
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strcmp(strategy->type, "fast_inverse_dst_4x4") == 0)
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{
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RUN_TEST(idct);
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}
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}
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tear_down_tests();
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}
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