test/tpl_model_test.cc - aom - Git at Google

 /*
  * Copyright (c) 2021, Alliance for Open Media. All rights reserved
  *
  * This source code is subject to the terms of the BSD 2 Clause License and
  * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
  * was not distributed with this source code in the LICENSE file, you can
  * obtain it at www.aomedia.org/license/software. If the Alliance for Open
  * Media Patent License 1.0 was not distributed with this source code in the
  * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
  */

 #include <cstdlib>
 #include <memory>
 #include <new>
 #include <vector>

 #include "av1/encoder/cost.h"
 #include "av1/encoder/tpl_model.h"
 #include "av1/encoder/encoder.h"
 #include "third_party/googletest/src/googletest/include/gtest/gtest.h"

 namespace {

 #if CONFIG_BITRATE_ACCURACY
 constexpr double epsilon = 0.0000001;
 #endif

 double laplace_prob(double q_step, double b, double zero_bin_ratio,
                     int qcoeff) {
   int abs_qcoeff = abs(qcoeff);
   double z0 = fmax(exp(-zero_bin_ratio / 2 * q_step / b), TPL_EPSILON);
   if (abs_qcoeff == 0) {
     double p0 = 1 - z0;
     return p0;
   } else {
     assert(abs_qcoeff > 0);
     double z = fmax(exp(-q_step / b), TPL_EPSILON);
     double p = z0 / 2 * (1 - z) * pow(z, abs_qcoeff - 1);
     return p;
   }
 }
 TEST(TplModelTest, ExponentialEntropyBoundaryTest1) {
   double b = 0;
   double q_step = 1;
   double entropy = av1_exponential_entropy(q_step, b);
   EXPECT_NEAR(entropy, 0, 0.00001);
 }

 TEST(TplModelTest, TransformCoeffEntropyTest1) {
   // Check the consistency between av1_estimate_coeff_entropy() and
   // laplace_prob()
   double b = 1;
   double q_step = 1;
   double zero_bin_ratio = 2;
   for (int qcoeff = -256; qcoeff < 256; ++qcoeff) {
     double rate = av1_estimate_coeff_entropy(q_step, b, zero_bin_ratio, qcoeff);
     double prob = laplace_prob(q_step, b, zero_bin_ratio, qcoeff);
     double ref_rate = -log2(prob);
     EXPECT_DOUBLE_EQ(rate, ref_rate);
   }
 }

 TEST(TplModelTest, TransformCoeffEntropyTest2) {
   // Check the consistency between av1_estimate_coeff_entropy(), laplace_prob()
   // and av1_laplace_entropy()
   double b = 1;
   double q_step = 1;
   double zero_bin_ratio = 2;
   double est_expected_rate = 0;
   for (int qcoeff = -20; qcoeff < 20; ++qcoeff) {
     double rate = av1_estimate_coeff_entropy(q_step, b, zero_bin_ratio, qcoeff);
     double prob = laplace_prob(q_step, b, zero_bin_ratio, qcoeff);
     est_expected_rate += prob * rate;
   }
   double expected_rate = av1_laplace_entropy(q_step, b, zero_bin_ratio);
   EXPECT_NEAR(expected_rate, est_expected_rate, 0.001);
 }

 TEST(TplModelTest, InitTplStats1) {
   // We use heap allocation instead of stack allocation here to avoid
   // -Wstack-usage warning.
   std::unique_ptr<TplParams> tpl_data(new (std::nothrow) TplParams);
   ASSERT_NE(tpl_data, nullptr);
   av1_zero(*tpl_data);
   tpl_data->ready = 1;
   EXPECT_EQ(sizeof(tpl_data->tpl_stats_buffer),
             MAX_LENGTH_TPL_FRAME_STATS * sizeof(tpl_data->tpl_stats_buffer[0]));
   for (int i = 0; i < MAX_LENGTH_TPL_FRAME_STATS; ++i) {
     // Set it to a random non-zero number
     tpl_data->tpl_stats_buffer[i].is_valid = i + 1;
   }
   av1_init_tpl_stats(tpl_data.get());
   EXPECT_EQ(tpl_data->ready, 0);
   for (int i = 0; i < MAX_LENGTH_TPL_FRAME_STATS; ++i) {
     EXPECT_EQ(tpl_data->tpl_stats_buffer[i].is_valid, 0);
   }
 }

 TEST(TplModelTest, DeltaRateCostZeroFlow) {
   // When srcrf_dist equal to recrf_dist, av1_delta_rate_cost should return 0
   int64_t srcrf_dist = 256;
   int64_t recrf_dist = 256;
   int64_t delta_rate = 512;
   int pixel_num = 256;
   int64_t rate_cost =
       av1_delta_rate_cost(delta_rate, recrf_dist, srcrf_dist, pixel_num);
   EXPECT_EQ(rate_cost, 0);
 }

 // a reference function of av1_delta_rate_cost() with delta_rate using bit as
 // basic unit
 double ref_delta_rate_cost(int64_t delta_rate, double src_rec_ratio,
                            int pixel_count) {
   assert(src_rec_ratio <= 1 && src_rec_ratio >= 0);
   double bits_per_pixel = (double)delta_rate / pixel_count;
   double p = pow(2, bits_per_pixel);
   double flow_rate_per_pixel =
       sqrt(p * p / (src_rec_ratio * p * p + (1 - src_rec_ratio)));
   double rate_cost = pixel_count * log2(flow_rate_per_pixel);
   return rate_cost;
 }

 TEST(TplModelTest, DeltaRateCostReference) {
   const int64_t scale = TPL_DEP_COST_SCALE_LOG2 + AV1_PROB_COST_SHIFT;
   std::vector<int64_t> srcrf_dist_arr = { 256, 257, 312 };
   std::vector<int64_t> recrf_dist_arr = { 512, 288, 620 };
   std::vector<int64_t> delta_rate_arr = { 10, 278, 100 };
   for (size_t t = 0; t < srcrf_dist_arr.size(); ++t) {
     int64_t srcrf_dist = srcrf_dist_arr[t];
     int64_t recrf_dist = recrf_dist_arr[t];
     int64_t delta_rate = delta_rate_arr[t];
     int64_t scaled_delta_rate = delta_rate << scale;
     int pixel_count = 256;
     int64_t rate_cost = av1_delta_rate_cost(scaled_delta_rate, recrf_dist,
                                             srcrf_dist, pixel_count);
     rate_cost >>= scale;
     double src_rec_ratio = (double)srcrf_dist / recrf_dist;
     double ref_rate_cost =
         ref_delta_rate_cost(delta_rate, src_rec_ratio, pixel_count);
     EXPECT_NEAR((double)rate_cost, ref_rate_cost, 1);
   }
 }

 TEST(TplModelTest, GetOverlapAreaHasOverlap) {
   // The block a's area is [10, 17) x [18, 24).
   // The block b's area is [8, 15) x [17, 23).
   // The overlapping area between block a and block b is [10, 15) x [18, 23).
   // Therefore, the size of the area is (15 - 10) * (23 - 18) = 25.
   int row_a = 10;
   int col_a = 18;
   int row_b = 8;
   int col_b = 17;
   int height = 7;
   int width = 6;
   int overlap_area =
       av1_get_overlap_area(row_a, col_a, row_b, col_b, width, height);
   EXPECT_EQ(overlap_area, 25);
 }

 TEST(TplModelTest, GetOverlapAreaNoOverlap) {
   // The block a's area is [10, 14) x [18, 22).
   // The block b's area is [5, 9) x [5, 9).
   // Threre is no overlapping area between block a and block b.
   // Therefore, the return value should be zero.
   int row_a = 10;
   int col_a = 18;
   int row_b = 5;
   int col_b = 5;
   int height = 4;
   int width = 4;
   int overlap_area =
       av1_get_overlap_area(row_a, col_a, row_b, col_b, width, height);
   EXPECT_EQ(overlap_area, 0);
 }

 TEST(TplModelTest, GetQIndexFromQstepRatio) {
   const aom_bit_depth_t bit_depth = AOM_BITS_8;
   // When qstep_ratio is 1, the output q_index should be equal to leaf_qindex.
   double qstep_ratio = 1.0;
   for (int leaf_qindex = 1; leaf_qindex <= 255; ++leaf_qindex) {
     const int q_index =
         av1_get_q_index_from_qstep_ratio(leaf_qindex, qstep_ratio, bit_depth);
     EXPECT_EQ(q_index, leaf_qindex);
   }

   // When qstep_ratio is very low, the output q_index should be 1.
   qstep_ratio = 0.0001;
   for (int leaf_qindex = 1; leaf_qindex <= 255; ++leaf_qindex) {
     const int q_index =
         av1_get_q_index_from_qstep_ratio(leaf_qindex, qstep_ratio, bit_depth);
     EXPECT_EQ(q_index, 0);
   }
 }

 TEST(TplModelTest, TxfmStatsInitTest) {
   TplTxfmStats tpl_txfm_stats;
   av1_init_tpl_txfm_stats(&tpl_txfm_stats);
   EXPECT_EQ(tpl_txfm_stats.coeff_num, 256);
   EXPECT_EQ(tpl_txfm_stats.txfm_block_count, 0);
   for (int i = 0; i < tpl_txfm_stats.coeff_num; ++i) {
     EXPECT_DOUBLE_EQ(tpl_txfm_stats.abs_coeff_sum[i], 0);
   }
 }

 #if CONFIG_BITRATE_ACCURACY
 TEST(TplModelTest, TxfmStatsAccumulateTest) {
   TplTxfmStats sub_stats;
   av1_init_tpl_txfm_stats(&sub_stats);
   sub_stats.txfm_block_count = 17;
   for (int i = 0; i < sub_stats.coeff_num; ++i) {
     sub_stats.abs_coeff_sum[i] = i;
   }

   TplTxfmStats accumulated_stats;
   av1_init_tpl_txfm_stats(&accumulated_stats);
   accumulated_stats.txfm_block_count = 13;
   for (int i = 0; i < accumulated_stats.coeff_num; ++i) {
     accumulated_stats.abs_coeff_sum[i] = 5 * i;
   }

   av1_accumulate_tpl_txfm_stats(&sub_stats, &accumulated_stats);
   EXPECT_DOUBLE_EQ(accumulated_stats.txfm_block_count, 30);
   for (int i = 0; i < accumulated_stats.coeff_num; ++i) {
     EXPECT_DOUBLE_EQ(accumulated_stats.abs_coeff_sum[i], 6 * i);
   }
 }

 TEST(TplModelTest, TxfmStatsRecordTest) {
   TplTxfmStats stats1;
   TplTxfmStats stats2;
   av1_init_tpl_txfm_stats(&stats1);
   av1_init_tpl_txfm_stats(&stats2);

   tran_low_t coeff[256];
   for (int i = 0; i < 256; ++i) {
     coeff[i] = i;
   }
   av1_record_tpl_txfm_block(&stats1, coeff);
   EXPECT_EQ(stats1.txfm_block_count, 1);

   // we record the same transform block twice for testing purpose
   av1_record_tpl_txfm_block(&stats2, coeff);
   av1_record_tpl_txfm_block(&stats2, coeff);
   EXPECT_EQ(stats2.txfm_block_count, 2);

   EXPECT_EQ(stats1.coeff_num, 256);
   EXPECT_EQ(stats2.coeff_num, 256);
   for (int i = 0; i < 256; ++i) {
     EXPECT_DOUBLE_EQ(stats2.abs_coeff_sum[i], 2 * stats1.abs_coeff_sum[i]);
   }
 }
 #endif  // CONFIG_BITRATE_ACCURACY

 TEST(TplModelTest, ComputeMVDifferenceTest) {
   TplDepFrame tpl_frame_small;
   tpl_frame_small.is_valid = true;
   tpl_frame_small.mi_rows = 4;
   tpl_frame_small.mi_cols = 4;
   tpl_frame_small.stride = 1;
   uint8_t right_shift_small = 1;
   int step_small = 1 << right_shift_small;

   // Test values for motion vectors.
   int mv_vals_small[4] = { 1, 2, 3, 4 };
   int index = 0;

   // 4x4 blocks means we need to allocate a 4 size array.
   // According to av1_tpl_ptr_pos:
   // (row >> right_shift) * stride + (col >> right_shift)
   // (4 >> 1) * 1 + (4 >> 1) = 4
   TplDepStats stats_buf_small[4];
   tpl_frame_small.tpl_stats_ptr = stats_buf_small;

   for (int row = 0; row < tpl_frame_small.mi_rows; row += step_small) {
     for (int col = 0; col < tpl_frame_small.mi_cols; col += step_small) {
       TplDepStats tpl_stats;
       tpl_stats.ref_frame_index[0] = 0;
       int_mv mv;
       mv.as_mv.row = mv_vals_small[index];
       mv.as_mv.col = mv_vals_small[index];
       index++;
       tpl_stats.mv[0] = mv;
       tpl_frame_small.tpl_stats_ptr[av1_tpl_ptr_pos(
           row, col, tpl_frame_small.stride, right_shift_small)] = tpl_stats;
     }
   }

   int_mv result_mv =
       av1_compute_mv_difference(&tpl_frame_small, 1, 1, step_small,
                                 tpl_frame_small.stride, right_shift_small);

   // Expect the result to be exactly equal to 1 because this is the difference
   // between neighboring motion vectors in this instance.
   EXPECT_EQ(result_mv.as_mv.row, 1);
   EXPECT_EQ(result_mv.as_mv.col, 1);
 }

 TEST(TplModelTest, ComputeMVBitsTest) {
   TplDepFrame tpl_frame;
   tpl_frame.is_valid = true;
   tpl_frame.mi_rows = 16;
   tpl_frame.mi_cols = 16;
   tpl_frame.stride = 24;
   uint8_t right_shift = 2;
   int step = 1 << right_shift;
   // Test values for motion vectors.
   int mv_vals_ordered[16] = { 1, 2,  3,  4,  5,  6,  7,  8,
                               9, 10, 11, 12, 13, 14, 15, 16 };
   int mv_vals[16] = { 1, 16, 2, 15, 3, 14, 4, 13, 5, 12, 6, 11, 7, 10, 8, 9 };
   int index = 0;

   // 16x16 blocks means we need to allocate a 100 size array.
   // According to av1_tpl_ptr_pos:
   // (row >> right_shift) * stride + (col >> right_shift)
   // (16 >> 2) * 24 + (16 >> 2) = 100
   TplDepStats stats_buf[100];
   tpl_frame.tpl_stats_ptr = stats_buf;

   for (int row = 0; row < tpl_frame.mi_rows; row += step) {
     for (int col = 0; col < tpl_frame.mi_cols; col += step) {
       TplDepStats tpl_stats;
       tpl_stats.ref_frame_index[0] = 0;
       int_mv mv;
       mv.as_mv.row = mv_vals_ordered[index];
       mv.as_mv.col = mv_vals_ordered[index];
       index++;
       tpl_stats.mv[0] = mv;
       tpl_frame.tpl_stats_ptr[av1_tpl_ptr_pos(row, col, tpl_frame.stride,
                                               right_shift)] = tpl_stats;
     }
   }

   double result = av1_tpl_compute_frame_mv_entropy(&tpl_frame, right_shift);

   // Expect the result to be low because the motion vectors are ordered.
   // The estimation algorithm takes this into account and reduces the cost.
   EXPECT_NEAR(result, 20, 5);

   index = 0;
   for (int row = 0; row < tpl_frame.mi_rows; row += step) {
     for (int col = 0; col < tpl_frame.mi_cols; col += step) {
       TplDepStats tpl_stats;
       tpl_stats.ref_frame_index[0] = 0;
       int_mv mv;
       mv.as_mv.row = mv_vals[index];
       mv.as_mv.col = mv_vals[index];
       index++;
       tpl_stats.mv[0] = mv;
       tpl_frame.tpl_stats_ptr[av1_tpl_ptr_pos(row, col, tpl_frame.stride,
                                               right_shift)] = tpl_stats;
     }
   }

   result = av1_tpl_compute_frame_mv_entropy(&tpl_frame, right_shift);

   // Expect the result to be higher because the vectors are not ordered.
   // Neighboring vectors will have different values, increasing the cost.
   EXPECT_NEAR(result, 70, 5);
 }
 #if CONFIG_BITRATE_ACCURACY

 TEST(TplModelTest, VbrRcInfoSetGopBitBudget) {
   VBR_RATECTRL_INFO vbr_rc_info;
   const double total_bit_budget = 2000;
   const int show_frame_count = 8;
   const int gop_show_frame_count = 4;
   av1_vbr_rc_init(&vbr_rc_info, total_bit_budget, show_frame_count);
   av1_vbr_rc_set_gop_bit_budget(&vbr_rc_info, gop_show_frame_count);
   EXPECT_NEAR(vbr_rc_info.gop_bit_budget, 1000, epsilon);
 }

 void init_toy_gf_group(GF_GROUP *gf_group) {
   av1_zero(*gf_group);
   gf_group->size = 4;
   const FRAME_UPDATE_TYPE update_type[4] = { KF_UPDATE, ARF_UPDATE,
                                              INTNL_ARF_UPDATE, LF_UPDATE };
   for (int i = 0; i < gf_group->size; ++i) {
     gf_group->update_type[i] = update_type[i];
   }
 }

 void init_toy_vbr_rc_info(VBR_RATECTRL_INFO *vbr_rc_info, int gop_size) {
   int total_bit_budget = 2000;
   int show_frame_count = 8;
   av1_vbr_rc_init(vbr_rc_info, total_bit_budget, show_frame_count);

   for (int i = 0; i < gop_size; ++i) {
     vbr_rc_info->qstep_ratio_list[i] = 1;
   }
 }

 void init_toy_tpl_txfm_stats(std::vector<TplTxfmStats> *stats_list) {
   for (size_t i = 0; i < stats_list->size(); i++) {
     TplTxfmStats *txfm_stats = &stats_list->at(i);
     av1_init_tpl_txfm_stats(txfm_stats);
     txfm_stats->txfm_block_count = 8;
     for (int j = 0; j < txfm_stats->coeff_num; j++) {
       txfm_stats->abs_coeff_sum[j] = 1000 + j;
     }
     av1_tpl_txfm_stats_update_abs_coeff_mean(txfm_stats);
   }
 }

 /*
  * Helper method to brute-force search for the closest q_index
  * that achieves the specified bit budget.
  */
 int find_gop_q_iterative(double bit_budget, aom_bit_depth_t bit_depth,
                          const double *update_type_scale_factors,
                          int frame_count,
                          const FRAME_UPDATE_TYPE *update_type_list,
                          const double *qstep_ratio_list,
                          const TplTxfmStats *stats_list, int *q_index_list,
                          double *estimated_bitrate_byframe) {
   int best_q = 255;
   double curr_estimate = av1_vbr_rc_info_estimate_gop_bitrate(
       best_q, bit_depth, update_type_scale_factors, frame_count,
       update_type_list, qstep_ratio_list, stats_list, q_index_list,
       estimated_bitrate_byframe);
   double min_bits_diff = fabs(curr_estimate - bit_budget);
   // Start at q = 254 because we already have an estimate for q = 255.
   for (int q = 254; q >= 0; q--) {
     curr_estimate = av1_vbr_rc_info_estimate_gop_bitrate(
         q, bit_depth, update_type_scale_factors, frame_count, update_type_list,
         qstep_ratio_list, stats_list, q_index_list, estimated_bitrate_byframe);
     double bits_diff = fabs(curr_estimate - bit_budget);
     if (bits_diff <= min_bits_diff) {
       min_bits_diff = bits_diff;
       best_q = q;
     }
   }
   return best_q;
 }

 TEST(TplModelTest, EstimateFrameRateTest) {
   GF_GROUP gf_group;
   init_toy_gf_group(&gf_group);

   VBR_RATECTRL_INFO vbr_rc_info;
   init_toy_vbr_rc_info(&vbr_rc_info, gf_group.size);

   std::vector<TplTxfmStats> stats_list(gf_group.size);
   init_toy_tpl_txfm_stats(&stats_list);

   std::vector<double> est_bitrate_list(gf_group.size);
   init_toy_tpl_txfm_stats(&stats_list);
   const aom_bit_depth_t bit_depth = AOM_BITS_8;

   const int q = 125;

   // Case1: all scale factors are 0
   double scale_factors[FRAME_UPDATE_TYPES] = { 0 };
   double estimate = av1_vbr_rc_info_estimate_gop_bitrate(
       q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
       vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
       est_bitrate_list.data());
   EXPECT_NEAR(estimate, 0, epsilon);

   // Case2: all scale factors are 1
   for (int i = 0; i < FRAME_UPDATE_TYPES; i++) {
     scale_factors[i] = 1;
   }
   estimate = av1_vbr_rc_info_estimate_gop_bitrate(
       q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
       vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
       est_bitrate_list.data());
   double ref_estimate = 0;
   for (int i = 0; i < gf_group.size; i++) {
     ref_estimate += est_bitrate_list[i];
   }
   EXPECT_NEAR(estimate, ref_estimate, epsilon);

   // Case3: Key frame scale factor is 0 and others are 1
   for (int i = 0; i < FRAME_UPDATE_TYPES; i++) {
     if (i == KF_UPDATE) {
       scale_factors[i] = 0;
     } else {
       scale_factors[i] = 1;
     }
   }
   estimate = av1_vbr_rc_info_estimate_gop_bitrate(
       q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
       vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
       est_bitrate_list.data());
   ref_estimate = 0;
   for (int i = 0; i < gf_group.size; i++) {
     if (gf_group.update_type[i] != KF_UPDATE) {
       ref_estimate += est_bitrate_list[i];
     }
   }
   EXPECT_NEAR(estimate, ref_estimate, epsilon);
 }

 TEST(TplModelTest, VbrRcInfoEstimateBaseQTest) {
   GF_GROUP gf_group;
   init_toy_gf_group(&gf_group);

   VBR_RATECTRL_INFO vbr_rc_info;
   init_toy_vbr_rc_info(&vbr_rc_info, gf_group.size);

   std::vector<TplTxfmStats> stats_list(gf_group.size);
   init_toy_tpl_txfm_stats(&stats_list);
   const aom_bit_depth_t bit_depth = AOM_BITS_8;

   // Test multiple bit budgets.
   const std::vector<double> bit_budgets = { 0,     2470,  19200,  30750,
                                             41315, 65017, DBL_MAX };

   for (double bit_budget : bit_budgets) {
     // Binary search method to find the optimal q.
     const int base_q = av1_vbr_rc_info_estimate_base_q(
         bit_budget, bit_depth, vbr_rc_info.scale_factors, gf_group.size,
         gf_group.update_type, vbr_rc_info.qstep_ratio_list, stats_list.data(),
         vbr_rc_info.q_index_list, nullptr);
     const int ref_base_q = find_gop_q_iterative(
         bit_budget, bit_depth, vbr_rc_info.scale_factors, gf_group.size,
         gf_group.update_type, vbr_rc_info.qstep_ratio_list, stats_list.data(),
         vbr_rc_info.q_index_list, nullptr);
     if (bit_budget == 0) {
       EXPECT_EQ(base_q, 255);
     } else if (bit_budget == DBL_MAX) {
       EXPECT_EQ(base_q, 0);
     }
     EXPECT_EQ(base_q, ref_base_q);
   }
 }
 #endif  // CONFIG_BITRATE_ACCURACY

 }  // namespace
	/*
	* Copyright (c) 2021, Alliance for Open Media. All rights reserved
	*
	* This source code is subject to the terms of the BSD 2 Clause License and
	* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
	* was not distributed with this source code in the LICENSE file, you can
	* obtain it at www.aomedia.org/license/software. If the Alliance for Open
	* Media Patent License 1.0 was not distributed with this source code in the
	* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
	*/

	#include <cstdlib>
	#include <memory>
	#include <new>
	#include <vector>

	#include "av1/encoder/cost.h"
	#include "av1/encoder/tpl_model.h"
	#include "av1/encoder/encoder.h"
	#include "third_party/googletest/src/googletest/include/gtest/gtest.h"

	namespace {

	#if CONFIG_BITRATE_ACCURACY
	constexpr double epsilon = 0.0000001;
	#endif

	double laplace_prob(double q_step, double b, double zero_bin_ratio,
	int qcoeff) {
	int abs_qcoeff = abs(qcoeff);
	double z0 = fmax(exp(-zero_bin_ratio / 2 * q_step / b), TPL_EPSILON);
	if (abs_qcoeff == 0) {
	double p0 = 1 - z0;
	return p0;
	} else {
	assert(abs_qcoeff > 0);
	double z = fmax(exp(-q_step / b), TPL_EPSILON);
	double p = z0 / 2 * (1 - z) * pow(z, abs_qcoeff - 1);
	return p;
	}
	}
	TEST(TplModelTest, ExponentialEntropyBoundaryTest1) {
	double b = 0;
	double q_step = 1;
	double entropy = av1_exponential_entropy(q_step, b);
	EXPECT_NEAR(entropy, 0, 0.00001);
	}

	TEST(TplModelTest, TransformCoeffEntropyTest1) {
	// Check the consistency between av1_estimate_coeff_entropy() and
	// laplace_prob()
	double b = 1;
	double q_step = 1;
	double zero_bin_ratio = 2;
	for (int qcoeff = -256; qcoeff < 256; ++qcoeff) {
	double rate = av1_estimate_coeff_entropy(q_step, b, zero_bin_ratio, qcoeff);
	double prob = laplace_prob(q_step, b, zero_bin_ratio, qcoeff);
	double ref_rate = -log2(prob);
	EXPECT_DOUBLE_EQ(rate, ref_rate);
	}
	}

	TEST(TplModelTest, TransformCoeffEntropyTest2) {
	// Check the consistency between av1_estimate_coeff_entropy(), laplace_prob()
	// and av1_laplace_entropy()
	double b = 1;
	double q_step = 1;
	double zero_bin_ratio = 2;
	double est_expected_rate = 0;
	for (int qcoeff = -20; qcoeff < 20; ++qcoeff) {
	double rate = av1_estimate_coeff_entropy(q_step, b, zero_bin_ratio, qcoeff);
	double prob = laplace_prob(q_step, b, zero_bin_ratio, qcoeff);
	est_expected_rate += prob * rate;
	}
	double expected_rate = av1_laplace_entropy(q_step, b, zero_bin_ratio);
	EXPECT_NEAR(expected_rate, est_expected_rate, 0.001);
	}

	TEST(TplModelTest, InitTplStats1) {
	// We use heap allocation instead of stack allocation here to avoid
	// -Wstack-usage warning.
	std::unique_ptr<TplParams> tpl_data(new (std::nothrow) TplParams);
	ASSERT_NE(tpl_data, nullptr);
	av1_zero(*tpl_data);
	tpl_data->ready = 1;
	EXPECT_EQ(sizeof(tpl_data->tpl_stats_buffer),
	MAX_LENGTH_TPL_FRAME_STATS * sizeof(tpl_data->tpl_stats_buffer[0]));
	for (int i = 0; i < MAX_LENGTH_TPL_FRAME_STATS; ++i) {
	// Set it to a random non-zero number
	tpl_data->tpl_stats_buffer[i].is_valid = i + 1;
	}
	av1_init_tpl_stats(tpl_data.get());
	EXPECT_EQ(tpl_data->ready, 0);
	for (int i = 0; i < MAX_LENGTH_TPL_FRAME_STATS; ++i) {
	EXPECT_EQ(tpl_data->tpl_stats_buffer[i].is_valid, 0);
	}
	}

	TEST(TplModelTest, DeltaRateCostZeroFlow) {
	// When srcrf_dist equal to recrf_dist, av1_delta_rate_cost should return 0
	int64_t srcrf_dist = 256;
	int64_t recrf_dist = 256;
	int64_t delta_rate = 512;
	int pixel_num = 256;
	int64_t rate_cost =
	av1_delta_rate_cost(delta_rate, recrf_dist, srcrf_dist, pixel_num);
	EXPECT_EQ(rate_cost, 0);
	}

	// a reference function of av1_delta_rate_cost() with delta_rate using bit as
	// basic unit
	double ref_delta_rate_cost(int64_t delta_rate, double src_rec_ratio,
	int pixel_count) {
	assert(src_rec_ratio <= 1 && src_rec_ratio >= 0);
	double bits_per_pixel = (double)delta_rate / pixel_count;
	double p = pow(2, bits_per_pixel);
	double flow_rate_per_pixel =
	sqrt(p * p / (src_rec_ratio * p * p + (1 - src_rec_ratio)));
	double rate_cost = pixel_count * log2(flow_rate_per_pixel);
	return rate_cost;
	}

	TEST(TplModelTest, DeltaRateCostReference) {
	const int64_t scale = TPL_DEP_COST_SCALE_LOG2 + AV1_PROB_COST_SHIFT;
	std::vector<int64_t> srcrf_dist_arr = { 256, 257, 312 };
	std::vector<int64_t> recrf_dist_arr = { 512, 288, 620 };
	std::vector<int64_t> delta_rate_arr = { 10, 278, 100 };
	for (size_t t = 0; t < srcrf_dist_arr.size(); ++t) {
	int64_t srcrf_dist = srcrf_dist_arr[t];
	int64_t recrf_dist = recrf_dist_arr[t];
	int64_t delta_rate = delta_rate_arr[t];
	int64_t scaled_delta_rate = delta_rate << scale;
	int pixel_count = 256;
	int64_t rate_cost = av1_delta_rate_cost(scaled_delta_rate, recrf_dist,
	srcrf_dist, pixel_count);
	rate_cost >>= scale;
	double src_rec_ratio = (double)srcrf_dist / recrf_dist;
	double ref_rate_cost =
	ref_delta_rate_cost(delta_rate, src_rec_ratio, pixel_count);
	EXPECT_NEAR((double)rate_cost, ref_rate_cost, 1);
	}
	}

	TEST(TplModelTest, GetOverlapAreaHasOverlap) {
	// The block a's area is [10, 17) x [18, 24).
	// The block b's area is [8, 15) x [17, 23).
	// The overlapping area between block a and block b is [10, 15) x [18, 23).
	// Therefore, the size of the area is (15 - 10) * (23 - 18) = 25.
	int row_a = 10;
	int col_a = 18;
	int row_b = 8;
	int col_b = 17;
	int height = 7;
	int width = 6;
	int overlap_area =
	av1_get_overlap_area(row_a, col_a, row_b, col_b, width, height);
	EXPECT_EQ(overlap_area, 25);
	}

	TEST(TplModelTest, GetOverlapAreaNoOverlap) {
	// The block a's area is [10, 14) x [18, 22).
	// The block b's area is [5, 9) x [5, 9).
	// Threre is no overlapping area between block a and block b.
	// Therefore, the return value should be zero.
	int row_a = 10;
	int col_a = 18;
	int row_b = 5;
	int col_b = 5;
	int height = 4;
	int width = 4;
	int overlap_area =
	av1_get_overlap_area(row_a, col_a, row_b, col_b, width, height);
	EXPECT_EQ(overlap_area, 0);
	}

	TEST(TplModelTest, GetQIndexFromQstepRatio) {
	const aom_bit_depth_t bit_depth = AOM_BITS_8;
	// When qstep_ratio is 1, the output q_index should be equal to leaf_qindex.
	double qstep_ratio = 1.0;
	for (int leaf_qindex = 1; leaf_qindex <= 255; ++leaf_qindex) {
	const int q_index =
	av1_get_q_index_from_qstep_ratio(leaf_qindex, qstep_ratio, bit_depth);
	EXPECT_EQ(q_index, leaf_qindex);
	}

	// When qstep_ratio is very low, the output q_index should be 1.
	qstep_ratio = 0.0001;
	for (int leaf_qindex = 1; leaf_qindex <= 255; ++leaf_qindex) {
	const int q_index =
	av1_get_q_index_from_qstep_ratio(leaf_qindex, qstep_ratio, bit_depth);
	EXPECT_EQ(q_index, 0);
	}
	}

	TEST(TplModelTest, TxfmStatsInitTest) {
	TplTxfmStats tpl_txfm_stats;
	av1_init_tpl_txfm_stats(&tpl_txfm_stats);
	EXPECT_EQ(tpl_txfm_stats.coeff_num, 256);
	EXPECT_EQ(tpl_txfm_stats.txfm_block_count, 0);
	for (int i = 0; i < tpl_txfm_stats.coeff_num; ++i) {
	EXPECT_DOUBLE_EQ(tpl_txfm_stats.abs_coeff_sum[i], 0);
	}
	}

	#if CONFIG_BITRATE_ACCURACY
	TEST(TplModelTest, TxfmStatsAccumulateTest) {
	TplTxfmStats sub_stats;
	av1_init_tpl_txfm_stats(&sub_stats);
	sub_stats.txfm_block_count = 17;
	for (int i = 0; i < sub_stats.coeff_num; ++i) {
	sub_stats.abs_coeff_sum[i] = i;
	}

	TplTxfmStats accumulated_stats;
	av1_init_tpl_txfm_stats(&accumulated_stats);
	accumulated_stats.txfm_block_count = 13;
	for (int i = 0; i < accumulated_stats.coeff_num; ++i) {
	accumulated_stats.abs_coeff_sum[i] = 5 * i;
	}

	av1_accumulate_tpl_txfm_stats(&sub_stats, &accumulated_stats);
	EXPECT_DOUBLE_EQ(accumulated_stats.txfm_block_count, 30);
	for (int i = 0; i < accumulated_stats.coeff_num; ++i) {
	EXPECT_DOUBLE_EQ(accumulated_stats.abs_coeff_sum[i], 6 * i);
	}
	}

	TEST(TplModelTest, TxfmStatsRecordTest) {
	TplTxfmStats stats1;
	TplTxfmStats stats2;
	av1_init_tpl_txfm_stats(&stats1);
	av1_init_tpl_txfm_stats(&stats2);

	tran_low_t coeff[256];
	for (int i = 0; i < 256; ++i) {
	coeff[i] = i;
	}
	av1_record_tpl_txfm_block(&stats1, coeff);
	EXPECT_EQ(stats1.txfm_block_count, 1);

	// we record the same transform block twice for testing purpose
	av1_record_tpl_txfm_block(&stats2, coeff);
	av1_record_tpl_txfm_block(&stats2, coeff);
	EXPECT_EQ(stats2.txfm_block_count, 2);

	EXPECT_EQ(stats1.coeff_num, 256);
	EXPECT_EQ(stats2.coeff_num, 256);
	for (int i = 0; i < 256; ++i) {
	EXPECT_DOUBLE_EQ(stats2.abs_coeff_sum[i], 2 * stats1.abs_coeff_sum[i]);
	}
	}
	#endif // CONFIG_BITRATE_ACCURACY

	TEST(TplModelTest, ComputeMVDifferenceTest) {
	TplDepFrame tpl_frame_small;
	tpl_frame_small.is_valid = true;
	tpl_frame_small.mi_rows = 4;
	tpl_frame_small.mi_cols = 4;
	tpl_frame_small.stride = 1;
	uint8_t right_shift_small = 1;
	int step_small = 1 << right_shift_small;

	// Test values for motion vectors.
	int mv_vals_small[4] = { 1, 2, 3, 4 };
	int index = 0;

	// 4x4 blocks means we need to allocate a 4 size array.
	// According to av1_tpl_ptr_pos:
	// (row >> right_shift) * stride + (col >> right_shift)
	// (4 >> 1) * 1 + (4 >> 1) = 4
	TplDepStats stats_buf_small[4];
	tpl_frame_small.tpl_stats_ptr = stats_buf_small;

	for (int row = 0; row < tpl_frame_small.mi_rows; row += step_small) {
	for (int col = 0; col < tpl_frame_small.mi_cols; col += step_small) {
	TplDepStats tpl_stats;
	tpl_stats.ref_frame_index[0] = 0;
	int_mv mv;
	mv.as_mv.row = mv_vals_small[index];
	mv.as_mv.col = mv_vals_small[index];
	index++;
	tpl_stats.mv[0] = mv;
	tpl_frame_small.tpl_stats_ptr[av1_tpl_ptr_pos(
	row, col, tpl_frame_small.stride, right_shift_small)] = tpl_stats;
	}
	}

	int_mv result_mv =
	av1_compute_mv_difference(&tpl_frame_small, 1, 1, step_small,
	tpl_frame_small.stride, right_shift_small);

	// Expect the result to be exactly equal to 1 because this is the difference
	// between neighboring motion vectors in this instance.
	EXPECT_EQ(result_mv.as_mv.row, 1);
	EXPECT_EQ(result_mv.as_mv.col, 1);
	}

	TEST(TplModelTest, ComputeMVBitsTest) {
	TplDepFrame tpl_frame;
	tpl_frame.is_valid = true;
	tpl_frame.mi_rows = 16;
	tpl_frame.mi_cols = 16;
	tpl_frame.stride = 24;
	uint8_t right_shift = 2;
	int step = 1 << right_shift;
	// Test values for motion vectors.
	int mv_vals_ordered[16] = { 1, 2, 3, 4, 5, 6, 7, 8,
	9, 10, 11, 12, 13, 14, 15, 16 };
	int mv_vals[16] = { 1, 16, 2, 15, 3, 14, 4, 13, 5, 12, 6, 11, 7, 10, 8, 9 };
	int index = 0;

	// 16x16 blocks means we need to allocate a 100 size array.
	// According to av1_tpl_ptr_pos:
	// (row >> right_shift) * stride + (col >> right_shift)
	// (16 >> 2) * 24 + (16 >> 2) = 100
	TplDepStats stats_buf[100];
	tpl_frame.tpl_stats_ptr = stats_buf;

	for (int row = 0; row < tpl_frame.mi_rows; row += step) {
	for (int col = 0; col < tpl_frame.mi_cols; col += step) {
	TplDepStats tpl_stats;
	tpl_stats.ref_frame_index[0] = 0;
	int_mv mv;
	mv.as_mv.row = mv_vals_ordered[index];
	mv.as_mv.col = mv_vals_ordered[index];
	index++;
	tpl_stats.mv[0] = mv;
	tpl_frame.tpl_stats_ptr[av1_tpl_ptr_pos(row, col, tpl_frame.stride,
	right_shift)] = tpl_stats;
	}
	}

	double result = av1_tpl_compute_frame_mv_entropy(&tpl_frame, right_shift);

	// Expect the result to be low because the motion vectors are ordered.
	// The estimation algorithm takes this into account and reduces the cost.
	EXPECT_NEAR(result, 20, 5);

	index = 0;
	for (int row = 0; row < tpl_frame.mi_rows; row += step) {
	for (int col = 0; col < tpl_frame.mi_cols; col += step) {
	TplDepStats tpl_stats;
	tpl_stats.ref_frame_index[0] = 0;
	int_mv mv;
	mv.as_mv.row = mv_vals[index];
	mv.as_mv.col = mv_vals[index];
	index++;
	tpl_stats.mv[0] = mv;
	tpl_frame.tpl_stats_ptr[av1_tpl_ptr_pos(row, col, tpl_frame.stride,
	right_shift)] = tpl_stats;
	}
	}

	result = av1_tpl_compute_frame_mv_entropy(&tpl_frame, right_shift);

	// Expect the result to be higher because the vectors are not ordered.
	// Neighboring vectors will have different values, increasing the cost.
	EXPECT_NEAR(result, 70, 5);
	}
	#if CONFIG_BITRATE_ACCURACY

	TEST(TplModelTest, VbrRcInfoSetGopBitBudget) {
	VBR_RATECTRL_INFO vbr_rc_info;
	const double total_bit_budget = 2000;
	const int show_frame_count = 8;
	const int gop_show_frame_count = 4;
	av1_vbr_rc_init(&vbr_rc_info, total_bit_budget, show_frame_count);
	av1_vbr_rc_set_gop_bit_budget(&vbr_rc_info, gop_show_frame_count);
	EXPECT_NEAR(vbr_rc_info.gop_bit_budget, 1000, epsilon);
	}

	void init_toy_gf_group(GF_GROUP *gf_group) {
	av1_zero(*gf_group);
	gf_group->size = 4;
	const FRAME_UPDATE_TYPE update_type[4] = { KF_UPDATE, ARF_UPDATE,
	INTNL_ARF_UPDATE, LF_UPDATE };
	for (int i = 0; i < gf_group->size; ++i) {
	gf_group->update_type[i] = update_type[i];
	}
	}

	void init_toy_vbr_rc_info(VBR_RATECTRL_INFO *vbr_rc_info, int gop_size) {
	int total_bit_budget = 2000;
	int show_frame_count = 8;
	av1_vbr_rc_init(vbr_rc_info, total_bit_budget, show_frame_count);

	for (int i = 0; i < gop_size; ++i) {
	vbr_rc_info->qstep_ratio_list[i] = 1;
	}
	}

	void init_toy_tpl_txfm_stats(std::vector<TplTxfmStats> *stats_list) {
	for (size_t i = 0; i < stats_list->size(); i++) {
	TplTxfmStats *txfm_stats = &stats_list->at(i);
	av1_init_tpl_txfm_stats(txfm_stats);
	txfm_stats->txfm_block_count = 8;
	for (int j = 0; j < txfm_stats->coeff_num; j++) {
	txfm_stats->abs_coeff_sum[j] = 1000 + j;
	}
	av1_tpl_txfm_stats_update_abs_coeff_mean(txfm_stats);
	}
	}

	/*
	* Helper method to brute-force search for the closest q_index
	* that achieves the specified bit budget.
	*/
	int find_gop_q_iterative(double bit_budget, aom_bit_depth_t bit_depth,
	const double *update_type_scale_factors,
	int frame_count,
	const FRAME_UPDATE_TYPE *update_type_list,
	const double *qstep_ratio_list,
	const TplTxfmStats stats_list, int q_index_list,
	double *estimated_bitrate_byframe) {
	int best_q = 255;
	double curr_estimate = av1_vbr_rc_info_estimate_gop_bitrate(
	best_q, bit_depth, update_type_scale_factors, frame_count,
	update_type_list, qstep_ratio_list, stats_list, q_index_list,
	estimated_bitrate_byframe);
	double min_bits_diff = fabs(curr_estimate - bit_budget);
	// Start at q = 254 because we already have an estimate for q = 255.
	for (int q = 254; q >= 0; q--) {
	curr_estimate = av1_vbr_rc_info_estimate_gop_bitrate(
	q, bit_depth, update_type_scale_factors, frame_count, update_type_list,
	qstep_ratio_list, stats_list, q_index_list, estimated_bitrate_byframe);
	double bits_diff = fabs(curr_estimate - bit_budget);
	if (bits_diff <= min_bits_diff) {
	min_bits_diff = bits_diff;
	best_q = q;
	}
	}
	return best_q;
	}

	TEST(TplModelTest, EstimateFrameRateTest) {
	GF_GROUP gf_group;
	init_toy_gf_group(&gf_group);

	VBR_RATECTRL_INFO vbr_rc_info;
	init_toy_vbr_rc_info(&vbr_rc_info, gf_group.size);

	std::vector<TplTxfmStats> stats_list(gf_group.size);
	init_toy_tpl_txfm_stats(&stats_list);

	std::vector<double> est_bitrate_list(gf_group.size);
	init_toy_tpl_txfm_stats(&stats_list);
	const aom_bit_depth_t bit_depth = AOM_BITS_8;

	const int q = 125;

	// Case1: all scale factors are 0
	double scale_factors[FRAME_UPDATE_TYPES] = { 0 };
	double estimate = av1_vbr_rc_info_estimate_gop_bitrate(
	q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
	vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
	est_bitrate_list.data());
	EXPECT_NEAR(estimate, 0, epsilon);

	// Case2: all scale factors are 1
	for (int i = 0; i < FRAME_UPDATE_TYPES; i++) {
	scale_factors[i] = 1;
	}
	estimate = av1_vbr_rc_info_estimate_gop_bitrate(
	q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
	vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
	est_bitrate_list.data());
	double ref_estimate = 0;
	for (int i = 0; i < gf_group.size; i++) {
	ref_estimate += est_bitrate_list[i];
	}
	EXPECT_NEAR(estimate, ref_estimate, epsilon);

	// Case3: Key frame scale factor is 0 and others are 1
	for (int i = 0; i < FRAME_UPDATE_TYPES; i++) {
	if (i == KF_UPDATE) {
	scale_factors[i] = 0;
	} else {
	scale_factors[i] = 1;
	}
	}
	estimate = av1_vbr_rc_info_estimate_gop_bitrate(
	q, bit_depth, scale_factors, gf_group.size, gf_group.update_type,
	vbr_rc_info.qstep_ratio_list, stats_list.data(), vbr_rc_info.q_index_list,
	est_bitrate_list.data());
	ref_estimate = 0;
	for (int i = 0; i < gf_group.size; i++) {
	if (gf_group.update_type[i] != KF_UPDATE) {
	ref_estimate += est_bitrate_list[i];
	}
	}
	EXPECT_NEAR(estimate, ref_estimate, epsilon);
	}

	TEST(TplModelTest, VbrRcInfoEstimateBaseQTest) {
	GF_GROUP gf_group;
	init_toy_gf_group(&gf_group);

	VBR_RATECTRL_INFO vbr_rc_info;
	init_toy_vbr_rc_info(&vbr_rc_info, gf_group.size);

	std::vector<TplTxfmStats> stats_list(gf_group.size);
	init_toy_tpl_txfm_stats(&stats_list);
	const aom_bit_depth_t bit_depth = AOM_BITS_8;

	// Test multiple bit budgets.
	const std::vector<double> bit_budgets = { 0, 2470, 19200, 30750,
	41315, 65017, DBL_MAX };

	for (double bit_budget : bit_budgets) {
	// Binary search method to find the optimal q.
	const int base_q = av1_vbr_rc_info_estimate_base_q(
	bit_budget, bit_depth, vbr_rc_info.scale_factors, gf_group.size,
	gf_group.update_type, vbr_rc_info.qstep_ratio_list, stats_list.data(),
	vbr_rc_info.q_index_list, nullptr);
	const int ref_base_q = find_gop_q_iterative(
	bit_budget, bit_depth, vbr_rc_info.scale_factors, gf_group.size,
	gf_group.update_type, vbr_rc_info.qstep_ratio_list, stats_list.data(),
	vbr_rc_info.q_index_list, nullptr);
	if (bit_budget == 0) {
	EXPECT_EQ(base_q, 255);
	} else if (bit_budget == DBL_MAX) {
	EXPECT_EQ(base_q, 0);
	}
	EXPECT_EQ(base_q, ref_base_q);
	}
	}
	#endif // CONFIG_BITRATE_ACCURACY

	} // namespace