unit_test/scale_argb_test.cc - platform/external/chromium_org/third_party/libyuv - Git at Google

 /*
  *  Copyright 2011 The LibYuv Project Authors. All rights reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS. All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */

 #include <stdlib.h>
 #include <time.h>

 #include "libyuv/cpu_id.h"
 #include "libyuv/scale_argb.h"
 #include "libyuv/row.h"
 #include "../unit_test/unit_test.h"

 namespace libyuv {

 // Test scaling with C vs Opt and return maximum pixel difference. 0 = exact.
 static int ARGBTestFilter(int src_width, int src_height,
                           int dst_width, int dst_height,
                           FilterMode f, int benchmark_iterations) {
   int i, j;
   const int b = 0;  // 128 to test for padding/stride.
   int src_argb_plane_size = (Abs(src_width) + b * 2) *
       (Abs(src_height) + b * 2) * 4;
   int src_stride_argb = (b * 2 + Abs(src_width)) * 4;

   align_buffer_page_end(src_argb, src_argb_plane_size);
   srandom(time(NULL));
   MemRandomize(src_argb, src_argb_plane_size);

   int dst_argb_plane_size = (dst_width + b * 2) * (dst_height + b * 2) * 4;
   int dst_stride_argb = (b * 2 + dst_width) * 4;

   align_buffer_page_end(dst_argb_c, dst_argb_plane_size);
   align_buffer_page_end(dst_argb_opt, dst_argb_plane_size);
   memset(dst_argb_c, 2, dst_argb_plane_size);
   memset(dst_argb_opt, 3, dst_argb_plane_size);

   // Warm up both versions for consistent benchmarks.
   MaskCpuFlags(0);  // Disable all CPU optimization.
   ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
             src_width, src_height,
             dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
             dst_width, dst_height, f);
   MaskCpuFlags(-1);  // Enable all CPU optimization.
   ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
             src_width, src_height,
             dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
             dst_width, dst_height, f);

   MaskCpuFlags(0);  // Disable all CPU optimization.
   double c_time = get_time();
   ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
             src_width, src_height,
             dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
             dst_width, dst_height, f);

   c_time = (get_time() - c_time);

   MaskCpuFlags(-1);  // Enable all CPU optimization.
   double opt_time = get_time();
   for (i = 0; i < benchmark_iterations; ++i) {
     ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
               src_width, src_height,
               dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
               dst_width, dst_height, f);
   }
   opt_time = (get_time() - opt_time) / benchmark_iterations;

   // Report performance of C vs OPT
   printf("filter %d - %8d us C - %8d us OPT\n",
          f, static_cast<int>(c_time * 1e6), static_cast<int>(opt_time * 1e6));

   // C version may be a little off from the optimized. Order of
   //  operations may introduce rounding somewhere. So do a difference
   //  of the buffers and look to see that the max difference isn't
   //  over 2.
   int max_diff = 0;
   for (i = b; i < (dst_height + b); ++i) {
     for (j = b * 4; j < (dst_width + b) * 4; ++j) {
       int abs_diff = Abs(dst_argb_c[(i * dst_stride_argb) + j] -
                          dst_argb_opt[(i * dst_stride_argb) + j]);
       if (abs_diff > max_diff) {
         max_diff = abs_diff;
       }
     }
   }

   free_aligned_buffer_page_end(dst_argb_c);
   free_aligned_buffer_page_end(dst_argb_opt);
   free_aligned_buffer_page_end(src_argb);
   return max_diff;
 }

 static const int kTileX = 8;
 static const int kTileY = 8;

 static int TileARGBScale(const uint8* src_argb, int src_stride_argb,
                          int src_width, int src_height,
                          uint8* dst_argb, int dst_stride_argb,
                          int dst_width, int dst_height,
                          FilterMode filtering) {
   for (int y = 0; y < dst_height; y += kTileY) {
     for (int x = 0; x < dst_width; x += kTileX) {
       int clip_width = kTileX;
       if (x + clip_width > dst_width) {
         clip_width = dst_width - x;
       }
       int clip_height = kTileY;
       if (y + clip_height > dst_height) {
         clip_height = dst_height - y;
       }
       int r = ARGBScaleClip(src_argb, src_stride_argb,
                             src_width, src_height,
                             dst_argb, dst_stride_argb,
                             dst_width, dst_height,
                             x, y, clip_width, clip_height, filtering);
       if (r) {
         return r;
       }
     }
   }
   return 0;
 }

 static int ARGBClipTestFilter(int src_width, int src_height,
                               int dst_width, int dst_height,
                               FilterMode f, int benchmark_iterations) {
   const int b = 128;
   int src_argb_plane_size = (Abs(src_width) + b * 2) *
       (Abs(src_height) + b * 2) * 4;
   int src_stride_argb = (b * 2 + Abs(src_width)) * 4;

   align_buffer_64(src_argb, src_argb_plane_size);
   memset(src_argb, 1, src_argb_plane_size);

   int dst_argb_plane_size = (dst_width + b * 2) * (dst_height + b * 2) * 4;
   int dst_stride_argb = (b * 2 + dst_width) * 4;

   srandom(time(NULL));

   int i, j;
   for (i = b; i < (Abs(src_height) + b); ++i) {
     for (j = b; j < (Abs(src_width) + b) * 4; ++j) {
       src_argb[(i * src_stride_argb) + j] = (random() & 0xff);
     }
   }

   align_buffer_64(dst_argb_c, dst_argb_plane_size);
   align_buffer_64(dst_argb_opt, dst_argb_plane_size);
   memset(dst_argb_c, 2, dst_argb_plane_size);
   memset(dst_argb_opt, 3, dst_argb_plane_size);

   // Do full image, no clipping.
   double c_time = get_time();
   ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
             src_width, src_height,
             dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
             dst_width, dst_height, f);
   c_time = (get_time() - c_time);

   // Do tiled image, clipping scale to a tile at a time.
   double opt_time = get_time();
   for (i = 0; i < benchmark_iterations; ++i) {
     TileARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
                   src_width, src_height,
                   dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
                   dst_width, dst_height, f);
   }
   opt_time = (get_time() - opt_time) / benchmark_iterations;

   // Report performance of Full vs Tiled.
   printf("filter %d - %8d us Full - %8d us Tiled\n",
          f, static_cast<int>(c_time * 1e6), static_cast<int>(opt_time * 1e6));

   // Compare full scaled image vs tiled image.
   int max_diff = 0;
   for (i = b; i < (dst_height + b); ++i) {
     for (j = b * 4; j < (dst_width + b) * 4; ++j) {
       int abs_diff = Abs(dst_argb_c[(i * dst_stride_argb) + j] -
                          dst_argb_opt[(i * dst_stride_argb) + j]);
       if (abs_diff > max_diff) {
         max_diff = abs_diff;
       }
     }
   }

   free_aligned_buffer_64(dst_argb_c);
   free_aligned_buffer_64(dst_argb_opt);
   free_aligned_buffer_64(src_argb);
   return max_diff;
 }

 #define TEST_FACTOR1(name, filter, hfactor, vfactor, max_diff)                 \
     TEST_F(libyuvTest, ARGBScaleDownBy##name##_##filter) {                     \
       int diff = ARGBTestFilter(benchmark_width_, benchmark_height_,           \
                                 Abs(benchmark_width_) * hfactor,               \
                                 Abs(benchmark_height_) * vfactor,              \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }                                                                          \
     TEST_F(libyuvTest, ARGBScaleDownClipBy##name##_##filter) {                 \
       int diff = ARGBClipTestFilter(benchmark_width_, benchmark_height_,       \
                                 Abs(benchmark_width_) * hfactor,               \
                                 Abs(benchmark_height_) * vfactor,              \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }

 // Test a scale factor with 2 filters.  Expect unfiltered to be exact, but
 // filtering is different fixed point implementations for SSSE3, Neon and C.
 #define TEST_FACTOR(name, hfactor, vfactor)                                    \
     TEST_FACTOR1(name, None, hfactor, vfactor, 2)                              \
     TEST_FACTOR1(name, Linear, hfactor, vfactor, 2)                            \
     TEST_FACTOR1(name, Bilinear, hfactor, vfactor, 2)                          \
     TEST_FACTOR1(name, Box, hfactor, vfactor, 2)

 TEST_FACTOR(2, 1 / 2, 1 / 2)
 TEST_FACTOR(4, 1 / 4, 1 / 4)
 TEST_FACTOR(8, 1 / 8, 1 / 8)
 TEST_FACTOR(3by4, 3 / 4, 3 / 4)
 TEST_FACTOR(3by8, 3 / 8, 3 / 8)
 #undef TEST_FACTOR1
 #undef TEST_FACTOR

 #define TEST_SCALETO1(name, width, height, filter, max_diff)                   \
     TEST_F(libyuvTest, name##To##width##x##height##_##filter) {                \
       int diff = ARGBTestFilter(benchmark_width_, benchmark_height_,           \
                                 width, height,                                 \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }                                                                          \
     TEST_F(libyuvTest, name##From##width##x##height##_##filter) {              \
       int diff = ARGBTestFilter(width, height,                                 \
                                 Abs(benchmark_width_), Abs(benchmark_height_), \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }                                                                          \
     TEST_F(libyuvTest, name##ClipTo##width##x##height##_##filter) {            \
       int diff = ARGBClipTestFilter(benchmark_width_, benchmark_height_,       \
                                 width, height,                                 \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }                                                                          \
     TEST_F(libyuvTest, name##ClipFrom##width##x##height##_##filter) {          \
       int diff = ARGBClipTestFilter(width, height,                             \
                                 Abs(benchmark_width_), Abs(benchmark_height_), \
                                 kFilter##filter, benchmark_iterations_);       \
       EXPECT_LE(diff, max_diff);                                               \
     }

 /// Test scale to a specified size with all 4 filters.
 #define TEST_SCALETO(name, width, height)                                      \
     TEST_SCALETO1(name, width, height, None, 0)                                \
     TEST_SCALETO1(name, width, height, Linear, 3)                              \
     TEST_SCALETO1(name, width, height, Bilinear, 3)                            \
     TEST_SCALETO1(name, width, height, Box, 3)

 TEST_SCALETO(ARGBScale, 1, 1)
 TEST_SCALETO(ARGBScale, 320, 240)
 TEST_SCALETO(ARGBScale, 352, 288)
 TEST_SCALETO(ARGBScale, 569, 480)
 TEST_SCALETO(ARGBScale, 640, 360)
 TEST_SCALETO(ARGBScale, 1280, 720)
 #undef TEST_SCALETO1
 #undef TEST_SCALETO

 }  // namespace libyuv
	/*
	* Copyright 2011 The LibYuv Project Authors. All rights reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/

	#include <stdlib.h>
	#include <time.h>

	#include "libyuv/cpu_id.h"
	#include "libyuv/scale_argb.h"
	#include "libyuv/row.h"
	#include "../unit_test/unit_test.h"

	namespace libyuv {

	// Test scaling with C vs Opt and return maximum pixel difference. 0 = exact.
	static int ARGBTestFilter(int src_width, int src_height,
	int dst_width, int dst_height,
	FilterMode f, int benchmark_iterations) {
	int i, j;
	const int b = 0; // 128 to test for padding/stride.
	int src_argb_plane_size = (Abs(src_width) + b * 2) *
	(Abs(src_height) + b * 2) * 4;
	int src_stride_argb = (b * 2 + Abs(src_width)) * 4;

	align_buffer_page_end(src_argb, src_argb_plane_size);
	srandom(time(NULL));
	MemRandomize(src_argb, src_argb_plane_size);

	int dst_argb_plane_size = (dst_width + b * 2) * (dst_height + b * 2) * 4;
	int dst_stride_argb = (b * 2 + dst_width) * 4;

	align_buffer_page_end(dst_argb_c, dst_argb_plane_size);
	align_buffer_page_end(dst_argb_opt, dst_argb_plane_size);
	memset(dst_argb_c, 2, dst_argb_plane_size);
	memset(dst_argb_opt, 3, dst_argb_plane_size);

	// Warm up both versions for consistent benchmarks.
	MaskCpuFlags(0); // Disable all CPU optimization.
	ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);
	MaskCpuFlags(-1); // Enable all CPU optimization.
	ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);

	MaskCpuFlags(0); // Disable all CPU optimization.
	double c_time = get_time();
	ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);

	c_time = (get_time() - c_time);

	MaskCpuFlags(-1); // Enable all CPU optimization.
	double opt_time = get_time();
	for (i = 0; i < benchmark_iterations; ++i) {
	ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);
	}
	opt_time = (get_time() - opt_time) / benchmark_iterations;

	// Report performance of C vs OPT
	printf("filter %d - %8d us C - %8d us OPT\n",
	f, static_cast<int>(c_time * 1e6), static_cast<int>(opt_time * 1e6));

	// C version may be a little off from the optimized. Order of
	// operations may introduce rounding somewhere. So do a difference
	// of the buffers and look to see that the max difference isn't
	// over 2.
	int max_diff = 0;
	for (i = b; i < (dst_height + b); ++i) {
	for (j = b * 4; j < (dst_width + b) * 4; ++j) {
	int abs_diff = Abs(dst_argb_c[(i * dst_stride_argb) + j] -
	dst_argb_opt[(i * dst_stride_argb) + j]);
	if (abs_diff > max_diff) {
	max_diff = abs_diff;
	}
	}
	}

	free_aligned_buffer_page_end(dst_argb_c);
	free_aligned_buffer_page_end(dst_argb_opt);
	free_aligned_buffer_page_end(src_argb);
	return max_diff;
	}

	static const int kTileX = 8;
	static const int kTileY = 8;

	static int TileARGBScale(const uint8* src_argb, int src_stride_argb,
	int src_width, int src_height,
	uint8* dst_argb, int dst_stride_argb,
	int dst_width, int dst_height,
	FilterMode filtering) {
	for (int y = 0; y < dst_height; y += kTileY) {
	for (int x = 0; x < dst_width; x += kTileX) {
	int clip_width = kTileX;
	if (x + clip_width > dst_width) {
	clip_width = dst_width - x;
	}
	int clip_height = kTileY;
	if (y + clip_height > dst_height) {
	clip_height = dst_height - y;
	}
	int r = ARGBScaleClip(src_argb, src_stride_argb,
	src_width, src_height,
	dst_argb, dst_stride_argb,
	dst_width, dst_height,
	x, y, clip_width, clip_height, filtering);
	if (r) {
	return r;
	}
	}
	}
	return 0;
	}

	static int ARGBClipTestFilter(int src_width, int src_height,
	int dst_width, int dst_height,
	FilterMode f, int benchmark_iterations) {
	const int b = 128;
	int src_argb_plane_size = (Abs(src_width) + b * 2) *
	(Abs(src_height) + b * 2) * 4;
	int src_stride_argb = (b * 2 + Abs(src_width)) * 4;

	align_buffer_64(src_argb, src_argb_plane_size);
	memset(src_argb, 1, src_argb_plane_size);

	int dst_argb_plane_size = (dst_width + b * 2) * (dst_height + b * 2) * 4;
	int dst_stride_argb = (b * 2 + dst_width) * 4;

	srandom(time(NULL));

	int i, j;
	for (i = b; i < (Abs(src_height) + b); ++i) {
	for (j = b; j < (Abs(src_width) + b) * 4; ++j) {
	src_argb[(i * src_stride_argb) + j] = (random() & 0xff);
	}
	}

	align_buffer_64(dst_argb_c, dst_argb_plane_size);
	align_buffer_64(dst_argb_opt, dst_argb_plane_size);
	memset(dst_argb_c, 2, dst_argb_plane_size);
	memset(dst_argb_opt, 3, dst_argb_plane_size);

	// Do full image, no clipping.
	double c_time = get_time();
	ARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_c + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);
	c_time = (get_time() - c_time);

	// Do tiled image, clipping scale to a tile at a time.
	double opt_time = get_time();
	for (i = 0; i < benchmark_iterations; ++i) {
	TileARGBScale(src_argb + (src_stride_argb * b) + b * 4, src_stride_argb,
	src_width, src_height,
	dst_argb_opt + (dst_stride_argb * b) + b * 4, dst_stride_argb,
	dst_width, dst_height, f);
	}
	opt_time = (get_time() - opt_time) / benchmark_iterations;

	// Report performance of Full vs Tiled.
	printf("filter %d - %8d us Full - %8d us Tiled\n",
	f, static_cast<int>(c_time * 1e6), static_cast<int>(opt_time * 1e6));

	// Compare full scaled image vs tiled image.
	int max_diff = 0;
	for (i = b; i < (dst_height + b); ++i) {
	for (j = b * 4; j < (dst_width + b) * 4; ++j) {
	int abs_diff = Abs(dst_argb_c[(i * dst_stride_argb) + j] -
	dst_argb_opt[(i * dst_stride_argb) + j]);
	if (abs_diff > max_diff) {
	max_diff = abs_diff;
	}
	}
	}

	free_aligned_buffer_64(dst_argb_c);
	free_aligned_buffer_64(dst_argb_opt);
	free_aligned_buffer_64(src_argb);
	return max_diff;
	}

	#define TEST_FACTOR1(name, filter, hfactor, vfactor, max_diff) \
	TEST_F(libyuvTest, ARGBScaleDownBy##name##_##filter) { \
	int diff = ARGBTestFilter(benchmark_width_, benchmark_height_, \
	Abs(benchmark_width_) * hfactor, \
	Abs(benchmark_height_) * vfactor, \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	} \
	TEST_F(libyuvTest, ARGBScaleDownClipBy##name##_##filter) { \
	int diff = ARGBClipTestFilter(benchmark_width_, benchmark_height_, \
	Abs(benchmark_width_) * hfactor, \
	Abs(benchmark_height_) * vfactor, \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	}

	// Test a scale factor with 2 filters. Expect unfiltered to be exact, but
	// filtering is different fixed point implementations for SSSE3, Neon and C.
	#define TEST_FACTOR(name, hfactor, vfactor) \
	TEST_FACTOR1(name, None, hfactor, vfactor, 2) \
	TEST_FACTOR1(name, Linear, hfactor, vfactor, 2) \
	TEST_FACTOR1(name, Bilinear, hfactor, vfactor, 2) \
	TEST_FACTOR1(name, Box, hfactor, vfactor, 2)

	TEST_FACTOR(2, 1 / 2, 1 / 2)
	TEST_FACTOR(4, 1 / 4, 1 / 4)
	TEST_FACTOR(8, 1 / 8, 1 / 8)
	TEST_FACTOR(3by4, 3 / 4, 3 / 4)
	TEST_FACTOR(3by8, 3 / 8, 3 / 8)
	#undef TEST_FACTOR1
	#undef TEST_FACTOR

	#define TEST_SCALETO1(name, width, height, filter, max_diff) \
	TEST_F(libyuvTest, name##To##width##x##height##_##filter) { \
	int diff = ARGBTestFilter(benchmark_width_, benchmark_height_, \
	width, height, \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	} \
	TEST_F(libyuvTest, name##From##width##x##height##_##filter) { \
	int diff = ARGBTestFilter(width, height, \
	Abs(benchmark_width_), Abs(benchmark_height_), \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	} \
	TEST_F(libyuvTest, name##ClipTo##width##x##height##_##filter) { \
	int diff = ARGBClipTestFilter(benchmark_width_, benchmark_height_, \
	width, height, \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	} \
	TEST_F(libyuvTest, name##ClipFrom##width##x##height##_##filter) { \
	int diff = ARGBClipTestFilter(width, height, \
	Abs(benchmark_width_), Abs(benchmark_height_), \
	kFilter##filter, benchmark_iterations_); \
	EXPECT_LE(diff, max_diff); \
	}

	/// Test scale to a specified size with all 4 filters.
	#define TEST_SCALETO(name, width, height) \
	TEST_SCALETO1(name, width, height, None, 0) \
	TEST_SCALETO1(name, width, height, Linear, 3) \
	TEST_SCALETO1(name, width, height, Bilinear, 3) \
	TEST_SCALETO1(name, width, height, Box, 3)

	TEST_SCALETO(ARGBScale, 1, 1)
	TEST_SCALETO(ARGBScale, 320, 240)
	TEST_SCALETO(ARGBScale, 352, 288)
	TEST_SCALETO(ARGBScale, 569, 480)
	TEST_SCALETO(ARGBScale, 640, 360)
	TEST_SCALETO(ARGBScale, 1280, 720)
	#undef TEST_SCALETO1
	#undef TEST_SCALETO

	} // namespace libyuv