test/av1_txfm_test.cc - aom - Git at Google

 /*
  * Copyright (c) 2016, 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 <stdio.h>
 #include "test/av1_txfm_test.h"

 namespace libaom_test {

 int get_txfm1d_size(TX_SIZE tx_size) { return tx_size_wide[tx_size]; }

 void get_txfm1d_type(TX_TYPE txfm2d_type, TYPE_TXFM *type0, TYPE_TXFM *type1) {
   switch (txfm2d_type) {
     case DCT_DCT:
       *type0 = TYPE_DCT;
       *type1 = TYPE_DCT;
       break;
     case ADST_DCT:
       *type0 = TYPE_ADST;
       *type1 = TYPE_DCT;
       break;
     case DCT_ADST:
       *type0 = TYPE_DCT;
       *type1 = TYPE_ADST;
       break;
     case ADST_ADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_ADST;
       break;
     case FLIPADST_DCT:
       *type0 = TYPE_ADST;
       *type1 = TYPE_DCT;
       break;
     case DCT_FLIPADST:
       *type0 = TYPE_DCT;
       *type1 = TYPE_ADST;
       break;
     case FLIPADST_FLIPADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_ADST;
       break;
     case ADST_FLIPADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_ADST;
       break;
     case FLIPADST_ADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_ADST;
       break;
     case IDTX:
       *type0 = TYPE_IDTX;
       *type1 = TYPE_IDTX;
       break;
     case H_DCT:
       *type0 = TYPE_IDTX;
       *type1 = TYPE_DCT;
       break;
     case V_DCT:
       *type0 = TYPE_DCT;
       *type1 = TYPE_IDTX;
       break;
     case H_ADST:
       *type0 = TYPE_IDTX;
       *type1 = TYPE_ADST;
       break;
     case V_ADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_IDTX;
       break;
     case H_FLIPADST:
       *type0 = TYPE_IDTX;
       *type1 = TYPE_ADST;
       break;
     case V_FLIPADST:
       *type0 = TYPE_ADST;
       *type1 = TYPE_IDTX;
       break;
     default:
       *type0 = TYPE_DCT;
       *type1 = TYPE_DCT;
       assert(0);
       break;
   }
 }

 double Sqrt2 = pow(2, 0.5);
 double invSqrt2 = 1 / pow(2, 0.5);

 double dct_matrix(double n, double k, int size) {
   return cos(PI * (2 * n + 1) * k / (2 * size));
 }

 void reference_dct_1d(const double *in, double *out, int size) {
   for (int k = 0; k < size; ++k) {
     out[k] = 0;
     for (int n = 0; n < size; ++n) {
       out[k] += in[n] * dct_matrix(n, k, size);
     }
     if (k == 0) out[k] = out[k] * invSqrt2;
   }
 }

 void reference_idct_1d(const double *in, double *out, int size) {
   for (int k = 0; k < size; ++k) {
     out[k] = 0;
     for (int n = 0; n < size; ++n) {
       if (n == 0)
         out[k] += invSqrt2 * in[n] * dct_matrix(k, n, size);
       else
         out[k] += in[n] * dct_matrix(k, n, size);
     }
   }
 }

 // TODO(any): Copied from the old 'fadst4' (same as the new 'av1_fadst4_new'
 // function). Should be replaced by a proper reference function that takes
 // 'double' input & output.
 static void fadst4_new(const tran_low_t *input, tran_low_t *output) {
   tran_high_t x0, x1, x2, x3;
   tran_high_t s0, s1, s2, s3, s4, s5, s6, s7;

   x0 = input[0];
   x1 = input[1];
   x2 = input[2];
   x3 = input[3];

   if (!(x0 | x1 | x2 | x3)) {
     output[0] = output[1] = output[2] = output[3] = 0;
     return;
   }

   s0 = sinpi_1_9 * x0;
   s1 = sinpi_4_9 * x0;
   s2 = sinpi_2_9 * x1;
   s3 = sinpi_1_9 * x1;
   s4 = sinpi_3_9 * x2;
   s5 = sinpi_4_9 * x3;
   s6 = sinpi_2_9 * x3;
   s7 = x0 + x1 - x3;

   x0 = s0 + s2 + s5;
   x1 = sinpi_3_9 * s7;
   x2 = s1 - s3 + s6;
   x3 = s4;

   s0 = x0 + x3;
   s1 = x1;
   s2 = x2 - x3;
   s3 = x2 - x0 + x3;

   // 1-D transform scaling factor is sqrt(2).
   output[0] = (tran_low_t)fdct_round_shift(s0);
   output[1] = (tran_low_t)fdct_round_shift(s1);
   output[2] = (tran_low_t)fdct_round_shift(s2);
   output[3] = (tran_low_t)fdct_round_shift(s3);
 }

 void reference_adst_1d(const double *in, double *out, int size) {
   if (size == 4) {  // Special case.
     tran_low_t int_input[4];
     for (int i = 0; i < 4; ++i) {
       int_input[i] = static_cast<tran_low_t>(round(in[i]));
     }
     tran_low_t int_output[4];
     fadst4_new(int_input, int_output);
     for (int i = 0; i < 4; ++i) {
       out[i] = int_output[i];
     }
     return;
   }

   for (int k = 0; k < size; ++k) {
     out[k] = 0;
     for (int n = 0; n < size; ++n) {
       out[k] += in[n] * sin(PI * (2 * n + 1) * (2 * k + 1) / (4 * size));
     }
   }
 }

 void reference_idtx_1d(const double *in, double *out, int size) {
   double scale = 0;
   if (size == 4)
     scale = Sqrt2;
   else if (size == 8)
     scale = 2;
   else if (size == 16)
     scale = 2 * Sqrt2;
   else if (size == 32)
     scale = 4;
   else if (size == 64)
     scale = 4 * Sqrt2;
   for (int k = 0; k < size; ++k) {
     out[k] = in[k] * scale;
   }
 }

 void reference_hybrid_1d(double *in, double *out, int size, int type) {
   if (type == TYPE_DCT)
     reference_dct_1d(in, out, size);
   else if (type == TYPE_ADST)
     reference_adst_1d(in, out, size);
   else
     reference_idtx_1d(in, out, size);
 }

 double get_amplification_factor(TX_TYPE tx_type, TX_SIZE tx_size) {
   TXFM_2D_FLIP_CFG fwd_txfm_flip_cfg;
   av1_get_fwd_txfm_cfg(tx_type, tx_size, &fwd_txfm_flip_cfg);
   const int tx_width = tx_size_wide[fwd_txfm_flip_cfg.tx_size];
   const int tx_height = tx_size_high[fwd_txfm_flip_cfg.tx_size];
   const int8_t *shift = fwd_txfm_flip_cfg.shift;
   const int amplify_bit = shift[0] + shift[1] + shift[2];
   double amplify_factor =
       amplify_bit >= 0 ? (1 << amplify_bit) : (1.0 / (1 << -amplify_bit));

   // For rectangular transforms, we need to multiply by an extra factor.
   const int rect_type = get_rect_tx_log_ratio(tx_width, tx_height);
   if (abs(rect_type) == 1) {
     amplify_factor *= pow(2, 0.5);
   }
   return amplify_factor;
 }

 void reference_hybrid_2d(double *in, double *out, TX_TYPE tx_type,
                          TX_SIZE tx_size) {
   // Get transform type and size of each dimension.
   TYPE_TXFM type0;
   TYPE_TXFM type1;
   get_txfm1d_type(tx_type, &type0, &type1);
   const int tx_width = tx_size_wide[tx_size];
   const int tx_height = tx_size_high[tx_size];

   double *const temp_in = new double[AOMMAX(tx_width, tx_height)];
   double *const temp_out = new double[AOMMAX(tx_width, tx_height)];
   double *const out_interm = new double[tx_width * tx_height];
   const int stride = tx_width;

   // Transform columns.
   for (int c = 0; c < tx_width; ++c) {
     for (int r = 0; r < tx_height; ++r) {
       temp_in[r] = in[r * stride + c];
     }
     reference_hybrid_1d(temp_in, temp_out, tx_height, type0);
     for (int r = 0; r < tx_height; ++r) {
       out_interm[r * stride + c] = temp_out[r];
     }
   }

   // Transform rows.
   for (int r = 0; r < tx_height; ++r) {
     reference_hybrid_1d(out_interm + r * stride, out + r * stride, tx_width,
                         type1);
   }

   delete[] temp_in;
   delete[] temp_out;
   delete[] out_interm;

   // These transforms use an approximate 2D DCT transform, by only keeping the
   // top-left quarter of the coefficients, and repacking them in the first
   // quarter indices.
   // TODO(urvang): Refactor this code.
   if (tx_width == 64 && tx_height == 64) {  // tx_size == TX_64X64
     // Zero out top-right 32x32 area.
     for (int row = 0; row < 32; ++row) {
       memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
     }
     // Zero out the bottom 64x32 area.
     memset(out + 32 * 64, 0, 32 * 64 * sizeof(*out));
     // Re-pack non-zero coeffs in the first 32x32 indices.
     for (int row = 1; row < 32; ++row) {
       memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
     }
   } else if (tx_width == 32 && tx_height == 64) {  // tx_size == TX_32X64
     // Zero out the bottom 32x32 area.
     memset(out + 32 * 32, 0, 32 * 32 * sizeof(*out));
     // Note: no repacking needed here.
   } else if (tx_width == 64 && tx_height == 32) {  // tx_size == TX_64X32
     // Zero out right 32x32 area.
     for (int row = 0; row < 32; ++row) {
       memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
     }
     // Re-pack non-zero coeffs in the first 32x32 indices.
     for (int row = 1; row < 32; ++row) {
       memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
     }
   } else if (tx_width == 16 && tx_height == 64) {  // tx_size == TX_16X64
     // Zero out the bottom 16x32 area.
     memset(out + 16 * 32, 0, 16 * 32 * sizeof(*out));
     // Note: no repacking needed here.
   } else if (tx_width == 64 && tx_height == 16) {  // tx_size == TX_64X16
     // Zero out right 32x16 area.
     for (int row = 0; row < 16; ++row) {
       memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
     }
     // Re-pack non-zero coeffs in the first 32x16 indices.
     for (int row = 1; row < 16; ++row) {
       memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
     }
   }

   // Apply appropriate scale.
   const double amplify_factor = get_amplification_factor(tx_type, tx_size);
   for (int c = 0; c < tx_width; ++c) {
     for (int r = 0; r < tx_height; ++r) {
       out[r * stride + c] *= amplify_factor;
     }
   }
 }

 template <typename Type>
 void fliplr(Type *dest, int width, int height, int stride) {
   for (int r = 0; r < height; ++r) {
     for (int c = 0; c < width / 2; ++c) {
       const Type tmp = dest[r * stride + c];
       dest[r * stride + c] = dest[r * stride + width - 1 - c];
       dest[r * stride + width - 1 - c] = tmp;
     }
   }
 }

 template <typename Type>
 void flipud(Type *dest, int width, int height, int stride) {
   for (int c = 0; c < width; ++c) {
     for (int r = 0; r < height / 2; ++r) {
       const Type tmp = dest[r * stride + c];
       dest[r * stride + c] = dest[(height - 1 - r) * stride + c];
       dest[(height - 1 - r) * stride + c] = tmp;
     }
   }
 }

 template <typename Type>
 void fliplrud(Type *dest, int width, int height, int stride) {
   for (int r = 0; r < height / 2; ++r) {
     for (int c = 0; c < width; ++c) {
       const Type tmp = dest[r * stride + c];
       dest[r * stride + c] = dest[(height - 1 - r) * stride + width - 1 - c];
       dest[(height - 1 - r) * stride + width - 1 - c] = tmp;
     }
   }
 }

 template void fliplr<double>(double *dest, int width, int height, int stride);
 template void flipud<double>(double *dest, int width, int height, int stride);
 template void fliplrud<double>(double *dest, int width, int height, int stride);

 int bd_arr[BD_NUM] = { 8, 10, 12 };

 int8_t low_range_arr[BD_NUM] = { 18, 32, 32 };
 int8_t high_range_arr[BD_NUM] = { 32, 32, 32 };

 void txfm_stage_range_check(const int8_t *stage_range, int stage_num,
                             int8_t cos_bit, int low_range, int high_range) {
   for (int i = 0; i < stage_num; ++i) {
     EXPECT_LE(stage_range[i], low_range);
     ASSERT_LE(stage_range[i] + cos_bit, high_range) << "stage = " << i;
   }
   for (int i = 0; i < stage_num - 1; ++i) {
     // make sure there is no overflow while doing half_btf()
     ASSERT_LE(stage_range[i + 1] + cos_bit, high_range) << "stage = " << i;
   }
 }
 }  // namespace libaom_test
	/*
	* Copyright (c) 2016, 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 <stdio.h>
	#include "test/av1_txfm_test.h"

	namespace libaom_test {

	int get_txfm1d_size(TX_SIZE tx_size) { return tx_size_wide[tx_size]; }

	void get_txfm1d_type(TX_TYPE txfm2d_type, TYPE_TXFM type0, TYPE_TXFM type1) {
	switch (txfm2d_type) {
	case DCT_DCT:
	*type0 = TYPE_DCT;
	*type1 = TYPE_DCT;
	break;
	case ADST_DCT:
	*type0 = TYPE_ADST;
	*type1 = TYPE_DCT;
	break;
	case DCT_ADST:
	*type0 = TYPE_DCT;
	*type1 = TYPE_ADST;
	break;
	case ADST_ADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_ADST;
	break;
	case FLIPADST_DCT:
	*type0 = TYPE_ADST;
	*type1 = TYPE_DCT;
	break;
	case DCT_FLIPADST:
	*type0 = TYPE_DCT;
	*type1 = TYPE_ADST;
	break;
	case FLIPADST_FLIPADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_ADST;
	break;
	case ADST_FLIPADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_ADST;
	break;
	case FLIPADST_ADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_ADST;
	break;
	case IDTX:
	*type0 = TYPE_IDTX;
	*type1 = TYPE_IDTX;
	break;
	case H_DCT:
	*type0 = TYPE_IDTX;
	*type1 = TYPE_DCT;
	break;
	case V_DCT:
	*type0 = TYPE_DCT;
	*type1 = TYPE_IDTX;
	break;
	case H_ADST:
	*type0 = TYPE_IDTX;
	*type1 = TYPE_ADST;
	break;
	case V_ADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_IDTX;
	break;
	case H_FLIPADST:
	*type0 = TYPE_IDTX;
	*type1 = TYPE_ADST;
	break;
	case V_FLIPADST:
	*type0 = TYPE_ADST;
	*type1 = TYPE_IDTX;
	break;
	default:
	*type0 = TYPE_DCT;
	*type1 = TYPE_DCT;
	assert(0);
	break;
	}
	}

	double Sqrt2 = pow(2, 0.5);
	double invSqrt2 = 1 / pow(2, 0.5);

	double dct_matrix(double n, double k, int size) {
	return cos(PI * (2 * n + 1) * k / (2 * size));
	}

	void reference_dct_1d(const double in, double out, int size) {
	for (int k = 0; k < size; ++k) {
	out[k] = 0;
	for (int n = 0; n < size; ++n) {
	out[k] += in[n] * dct_matrix(n, k, size);
	}
	if (k == 0) out[k] = out[k] * invSqrt2;
	}
	}

	void reference_idct_1d(const double in, double out, int size) {
	for (int k = 0; k < size; ++k) {
	out[k] = 0;
	for (int n = 0; n < size; ++n) {
	if (n == 0)
	out[k] += invSqrt2 * in[n] * dct_matrix(k, n, size);
	else
	out[k] += in[n] * dct_matrix(k, n, size);
	}
	}
	}

	// TODO(any): Copied from the old 'fadst4' (same as the new 'av1_fadst4_new'
	// function). Should be replaced by a proper reference function that takes
	// 'double' input & output.
	static void fadst4_new(const tran_low_t input, tran_low_t output) {
	tran_high_t x0, x1, x2, x3;
	tran_high_t s0, s1, s2, s3, s4, s5, s6, s7;

	x0 = input[0];
	x1 = input[1];
	x2 = input[2];
	x3 = input[3];

	if (!(x0 \| x1 \| x2 \| x3)) {
	output[0] = output[1] = output[2] = output[3] = 0;
	return;
	}

	s0 = sinpi_1_9 * x0;
	s1 = sinpi_4_9 * x0;
	s2 = sinpi_2_9 * x1;
	s3 = sinpi_1_9 * x1;
	s4 = sinpi_3_9 * x2;
	s5 = sinpi_4_9 * x3;
	s6 = sinpi_2_9 * x3;
	s7 = x0 + x1 - x3;

	x0 = s0 + s2 + s5;
	x1 = sinpi_3_9 * s7;
	x2 = s1 - s3 + s6;
	x3 = s4;

	s0 = x0 + x3;
	s1 = x1;
	s2 = x2 - x3;
	s3 = x2 - x0 + x3;

	// 1-D transform scaling factor is sqrt(2).
	output[0] = (tran_low_t)fdct_round_shift(s0);
	output[1] = (tran_low_t)fdct_round_shift(s1);
	output[2] = (tran_low_t)fdct_round_shift(s2);
	output[3] = (tran_low_t)fdct_round_shift(s3);
	}

	void reference_adst_1d(const double in, double out, int size) {
	if (size == 4) { // Special case.
	tran_low_t int_input[4];
	for (int i = 0; i < 4; ++i) {
	int_input[i] = static_cast<tran_low_t>(round(in[i]));
	}
	tran_low_t int_output[4];
	fadst4_new(int_input, int_output);
	for (int i = 0; i < 4; ++i) {
	out[i] = int_output[i];
	}
	return;
	}

	for (int k = 0; k < size; ++k) {
	out[k] = 0;
	for (int n = 0; n < size; ++n) {
	out[k] += in[n] * sin(PI * (2 * n + 1) * (2 * k + 1) / (4 * size));
	}
	}
	}

	void reference_idtx_1d(const double in, double out, int size) {
	double scale = 0;
	if (size == 4)
	scale = Sqrt2;
	else if (size == 8)
	scale = 2;
	else if (size == 16)
	scale = 2 * Sqrt2;
	else if (size == 32)
	scale = 4;
	else if (size == 64)
	scale = 4 * Sqrt2;
	for (int k = 0; k < size; ++k) {
	out[k] = in[k] * scale;
	}
	}

	void reference_hybrid_1d(double in, double out, int size, int type) {
	if (type == TYPE_DCT)
	reference_dct_1d(in, out, size);
	else if (type == TYPE_ADST)
	reference_adst_1d(in, out, size);
	else
	reference_idtx_1d(in, out, size);
	}

	double get_amplification_factor(TX_TYPE tx_type, TX_SIZE tx_size) {
	TXFM_2D_FLIP_CFG fwd_txfm_flip_cfg;
	av1_get_fwd_txfm_cfg(tx_type, tx_size, &fwd_txfm_flip_cfg);
	const int tx_width = tx_size_wide[fwd_txfm_flip_cfg.tx_size];
	const int tx_height = tx_size_high[fwd_txfm_flip_cfg.tx_size];
	const int8_t *shift = fwd_txfm_flip_cfg.shift;
	const int amplify_bit = shift[0] + shift[1] + shift[2];
	double amplify_factor =
	amplify_bit >= 0 ? (1 << amplify_bit) : (1.0 / (1 << -amplify_bit));

	// For rectangular transforms, we need to multiply by an extra factor.
	const int rect_type = get_rect_tx_log_ratio(tx_width, tx_height);
	if (abs(rect_type) == 1) {
	amplify_factor *= pow(2, 0.5);
	}
	return amplify_factor;
	}

	void reference_hybrid_2d(double in, double out, TX_TYPE tx_type,
	TX_SIZE tx_size) {
	// Get transform type and size of each dimension.
	TYPE_TXFM type0;
	TYPE_TXFM type1;
	get_txfm1d_type(tx_type, &type0, &type1);
	const int tx_width = tx_size_wide[tx_size];
	const int tx_height = tx_size_high[tx_size];

	double *const temp_in = new double[AOMMAX(tx_width, tx_height)];
	double *const temp_out = new double[AOMMAX(tx_width, tx_height)];
	double const out_interm = new double[tx_width tx_height];
	const int stride = tx_width;

	// Transform columns.
	for (int c = 0; c < tx_width; ++c) {
	for (int r = 0; r < tx_height; ++r) {
	temp_in[r] = in[r * stride + c];
	}
	reference_hybrid_1d(temp_in, temp_out, tx_height, type0);
	for (int r = 0; r < tx_height; ++r) {
	out_interm[r * stride + c] = temp_out[r];
	}
	}

	// Transform rows.
	for (int r = 0; r < tx_height; ++r) {
	reference_hybrid_1d(out_interm + r * stride, out + r * stride, tx_width,
	type1);
	}

	delete[] temp_in;
	delete[] temp_out;
	delete[] out_interm;

	// These transforms use an approximate 2D DCT transform, by only keeping the
	// top-left quarter of the coefficients, and repacking them in the first
	// quarter indices.
	// TODO(urvang): Refactor this code.
	if (tx_width == 64 && tx_height == 64) { // tx_size == TX_64X64
	// Zero out top-right 32x32 area.
	for (int row = 0; row < 32; ++row) {
	memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
	}
	// Zero out the bottom 64x32 area.
	memset(out + 32 * 64, 0, 32 * 64 * sizeof(*out));
	// Re-pack non-zero coeffs in the first 32x32 indices.
	for (int row = 1; row < 32; ++row) {
	memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
	}
	} else if (tx_width == 32 && tx_height == 64) { // tx_size == TX_32X64
	// Zero out the bottom 32x32 area.
	memset(out + 32 * 32, 0, 32 * 32 * sizeof(*out));
	// Note: no repacking needed here.
	} else if (tx_width == 64 && tx_height == 32) { // tx_size == TX_64X32
	// Zero out right 32x32 area.
	for (int row = 0; row < 32; ++row) {
	memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
	}
	// Re-pack non-zero coeffs in the first 32x32 indices.
	for (int row = 1; row < 32; ++row) {
	memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
	}
	} else if (tx_width == 16 && tx_height == 64) { // tx_size == TX_16X64
	// Zero out the bottom 16x32 area.
	memset(out + 16 * 32, 0, 16 * 32 * sizeof(*out));
	// Note: no repacking needed here.
	} else if (tx_width == 64 && tx_height == 16) { // tx_size == TX_64X16
	// Zero out right 32x16 area.
	for (int row = 0; row < 16; ++row) {
	memset(out + row * 64 + 32, 0, 32 * sizeof(*out));
	}
	// Re-pack non-zero coeffs in the first 32x16 indices.
	for (int row = 1; row < 16; ++row) {
	memcpy(out + row * 32, out + row * 64, 32 * sizeof(*out));
	}
	}

	// Apply appropriate scale.
	const double amplify_factor = get_amplification_factor(tx_type, tx_size);
	for (int c = 0; c < tx_width; ++c) {
	for (int r = 0; r < tx_height; ++r) {
	out[r * stride + c] *= amplify_factor;
	}
	}
	}

	template <typename Type>
	void fliplr(Type *dest, int width, int height, int stride) {
	for (int r = 0; r < height; ++r) {
	for (int c = 0; c < width / 2; ++c) {
	const Type tmp = dest[r * stride + c];
	dest[r * stride + c] = dest[r * stride + width - 1 - c];
	dest[r * stride + width - 1 - c] = tmp;
	}
	}
	}

	template <typename Type>
	void flipud(Type *dest, int width, int height, int stride) {
	for (int c = 0; c < width; ++c) {
	for (int r = 0; r < height / 2; ++r) {
	const Type tmp = dest[r * stride + c];
	dest[r * stride + c] = dest[(height - 1 - r) * stride + c];
	dest[(height - 1 - r) * stride + c] = tmp;
	}
	}
	}

	template <typename Type>
	void fliplrud(Type *dest, int width, int height, int stride) {
	for (int r = 0; r < height / 2; ++r) {
	for (int c = 0; c < width; ++c) {
	const Type tmp = dest[r * stride + c];
	dest[r * stride + c] = dest[(height - 1 - r) * stride + width - 1 - c];
	dest[(height - 1 - r) * stride + width - 1 - c] = tmp;
	}
	}
	}

	template void fliplr<double>(double *dest, int width, int height, int stride);
	template void flipud<double>(double *dest, int width, int height, int stride);
	template void fliplrud<double>(double *dest, int width, int height, int stride);

	int bd_arr[BD_NUM] = { 8, 10, 12 };

	int8_t low_range_arr[BD_NUM] = { 18, 32, 32 };
	int8_t high_range_arr[BD_NUM] = { 32, 32, 32 };

	void txfm_stage_range_check(const int8_t *stage_range, int stage_num,
	int8_t cos_bit, int low_range, int high_range) {
	for (int i = 0; i < stage_num; ++i) {
	EXPECT_LE(stage_range[i], low_range);
	ASSERT_LE(stage_range[i] + cos_bit, high_range) << "stage = " << i;
	}
	for (int i = 0; i < stage_num - 1; ++i) {
	// make sure there is no overflow while doing half_btf()
	ASSERT_LE(stage_range[i + 1] + cos_bit, high_range) << "stage = " << i;
	}
	}
	} // namespace libaom_test